Date Palm Tissue Culture and Genetical Identification of ...

Date Palm Tissue Culture and Genetical

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in Saudi Arabia

�� Ejaz Askari

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Date Palm Tissue Culture and Genetical��

in Saudi Arabia

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�� Ejaz Askari

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C King Abdulaziz City for Science and Technology 2012 King Fahad National Library Cataloging-in-Publication Data

Al Khalifah, Nasser Saleh Date Palm tissue culture and genetical and �� Saudi Arabia./ Nasser Saleh AlKhalifah; Ejaz ��!� �"#$%#

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L.D. no.1433/1202ISBN :978-603-8049-45-7

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1��The place of the Kingdom of Saudi Arabia is in the forefront of all

leading dates producing countries of the world. The number of date palm

trees in the Kingdom is estimated as 23 million and the different date

varieties is more than 450, spreading across the vast landscape of Saudi

Arabia. Saudi Arabia has given utmost importance to the research activities

on date palms and dates related to crop improvement, micropropagation,

agriculture practices, disease and pest management, harvest and post

harvest techniques, storage, value addition and marketing. The effort made

for this book by the authors is a pioneer attempt to correlate the molecular

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cultivars of date palm. This book was written for those individuals who are

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designed to serve as a reference book for the professionals engaged in date

palm culture and research. The appendices given at the end of the book

serve as quick reference for the researchers as well as farmers.

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issue of a series covering all known cultivars of date palm grown in Saudi

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+��"��#��#��0��..��2�� &��!��#��$�$��%�1��3�"��!%

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�� The research work presented in this book is the product of almost ten

years of experience of the authors in utilizing modern biotechnology tools �� !�� of the tree form monocots that have immense genetic diversity within the � ��of date palm incited the authors to take a pioneer attempt in this regard. This �� "�� second chapter covers the culture practices of date palms including tissue �� about the key diagnostic features based on fruit characters and PCR based !#�� $�� different Universities in Saudi Arabia, expert breeders and farmers. The fruit samples and leaf samples were taken from the same trees.

This book has been written to suit the needs of researchers on genetic diversity and molecular biology, students, teachers, farmers and those who have some basic knowledge on date palms. Simple and easy to understand language has been used in the text, but some technical terms and words were inevitable. To ease the understanding of these technical terms, a pictorial glossary is given at the end of this book.

The authors gratefully acknowledge the facilities provided by King Abdulaziz City for Science and Technology, Riyadh, Saudi Arabia for completion of this research work and publication of this book. A word of thanks also goes to the farmers of Saudi Arabia who whole-heartedly donated date palm leaf and fruit samples for this study and extended full �� %� �� !��&��$��"&�� '(��"&��'&��")��'*��"��'+��&��'!�/��+�1$��

�� Ejaz Askari��

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!�� IPhoenix dactyliferaG�J��

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Africa. Almost every part of this tree is used and its food and industrial

products play an important role in the rural communities and economies

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of the world and marketed worldwide as high value confectionary

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encompasses the dry desert regions of the world between 10o#��DFo#

��#�� 7o S to 33 o 51' S in the Southern

hemisphere. Large distribution of this highly out-breeding, dioecious

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cultivars popular to the date palm growers of the different regions of the

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evolved through natural hybridization with several wild species of Phoenix

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vegetative propagation. The natural hybridization followed by human

selection had brought about many cultivars, which were given local names

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these areas due to many reasons.

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of the leading date producing countries that harbours about 450 cultivars

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is 1052400 tons, worth over 2 billion Saudi riyals is coming from an area of

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in the Kingdom are known for its own cultivars like Ajwa and Ambara in

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these cultivars is generally maintained through off-shoot multiplication.

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expansion of elite cultivars was made possible and transportation of the

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last decade, several small and large-scale growers adopted this innovative

technique of propagation to expand their farming. They imported tissue

culture derived plantlets of their choice from well known tissue culture

laboratories of Europe. This eventually helped in spreading the cultivars to

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mostly they are seed borne and are hardly identical to any female cultivar.

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cultivars from their experience. Several workers attempted to describe and

enlist the date palm cultivars grown in their country of interest. Rhouma

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Bashah provided fruit description of 30 cultivars grown in Saudi Arabia.

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which can be used as a model for detailed description of other cultivars.

As more and more cultivars of date palms are being described,

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important. The morphological markers used to describe cultivars are mainly

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those of the fruit, but these are affected by the environmental and edaphic

conditions. Some date palm cultivars have similar or narrow distinguishing

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thus demand genetic evidence to prove phylogenetic relationships at the intra

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Tisserat used leaf isozymes as markers in identifying genetic diversity in

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date palm cultivars.

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E�� \ Phoenix L.

Species : Phoenix dactylifera L.

About 15 wild species of Phoenix are native to tropics and subtropics

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were an important major crop from about 3000 B.C. Phoenix dactylifera �� I&��"�F@�J��

pollinated with P. rectinata and P. atlantica ��

Pakistan it is pollinated with P. sylvestris and in Spain with P. canariensis

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some of the leading date producers of the world.

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major breakfast food during the fasting of Ramadan. Because of its high

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introduced the species into Spain in medieval days. The Spanish voyagers

spread the dates to America and neighbouring areas.

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many countries including United States of America and Australia.

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�� from the base and rarely from the leaf axil. The trunk is covered

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feather-like, composed of spiny petiole, stout midrib and many pinnae.

Pinnae are 20-40 cm long, grey-green or bluish-green, folded lengthwise.

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edible, yellowish-brown to reddish-brown. Seeds stony, acute at apex,

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per year. Being a heterozygous, out breeding plant chances of cross

pollination are very high and this may lead to the formation of inferior

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propagation is seldom used in date palms. But for the hybridization

purpose plants are produced through seeds. The most popular way of date

palm multiplication is through ��. An adult date palm in its life

time produces 5-15 ��. Using adequate technique and skill these

off-shoots can be separated from the mother plants and planted separately.

#��'�� to raise a

plantation is the main constraint to the rapidly growing plantation industry.

The availability of tissue culture technology in date palm has revolutionized

the farming industry and many growers adopted this innovative technique

for the rapid expansion of their farms. This special facility helps to provide

thousands of plantlets from a single ��, which would be true-to-

type to the mother plant.

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Seeds are soaked in cold water for 24 hours then washed thoroughly in

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in raised sand or loamy soil beds or polythene pots of 30 cm high. Seeds

have to be placed 3-5 cm deep from the top of the soil and watered

daily. The juvenile leafy shoot appears above the soil after one month.

The six month old seedlings can be transplanted to polythene pots for

the ease of transferring.

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of them originate from the leaf axils but the former is from the older ones

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type and moisture a palm produce a few to many off-shoots.

)��G��. B. Aerial �� from the crown area.

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by regular pruning of leaves. The lateral �� are more prone to root

development than the aerial ��. A healthy �� of 20-25 cm

diameter can be detached from the mother plant and nurtured in nursery

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needs special skill and experience. Any damage to the apical meristem of

the detached �� may lead to the death and serious wounds on the

mother plant may attract insects and pests.

Tissue culture

Since the beginning of domestication and cultivation of plants,

human beings are looking for techniques that could help to produce

maximum number of individuals from the minimum number/quantity

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multiplication of plants using minimum quantity of propagules. Some

of the advantages of this technique are that heterozygous materials may

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perpetuating clones that do not produce �� and viable seeds or

that do not produce seeds at all.

Tissue culture refers to the aseptic growth of cells, tissues or organs in

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been a tool of the plant physiologists, this technique is now increasingly

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or micro propagation of plants involves three distinct steps, each of which

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plantlets. These steps involve the use of different chemicals, management

of light, humidity, temperature etc.

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successfully produced date palm plantlets through tissue culture. After

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W��" �F:8] ��'E��" �FFD] ��'+��" <��D" <��7] ��'+��"

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9��" <��@] ��'+��" <��:] �� } +��" <��F" +��

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micropropagation of date palms. The differential behavior of date palm

cultivars to the medium and cultural conditions attracted the attention of

tissue culturists and many elite varieties in their respective areas have been

subjected to micro propagation techniques.

Series of experiments conducted on the micro propagation of date

palms has resulted in the standardization of some techniques, which can be

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of techniques are successfully employed in the tissue culture of date palms.

The most popular technique used is somatic embryogenesis, which has

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date palm plantlets through repetitive somatic embryogenesis. This method

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some undesirable genetic variability in the derived plants, resulting some

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methods used now is direct organogenesis. The success full development

of this new technique is expected to reduce the number of steps in culture,

shortening the duration of culture with higher concentrations of auxines

may lead to reduce somaclonal variations.

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This term refers to the development of a complete embryo from

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produced from in vitro produced friable callus cells. The selection of

the explant source material is the most critical decision and may require

a systematic analysis of embryogenic potential of different explant

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embryogenic potential in the callus is achieved through the transfer of

cells to a basal medium with high concentration of auxin. The most

effective auxin used in date palm is 2,4-dichlorophenoxyacetic acid

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smaller cells can be sub cultured in the same media for continued

production of somatic embryos. Proembryo masses are cultured in

an auxin free basal medium. Somatic embryos develop from single

cells in clumps or small masses, develop polarity and grow like zygotic

embryos. Regeneration of the somatic embryo is the next step involved

for which an agar medium devoid of any auxin but containing a low

level of cytokinin is required. This technique has been employed in the

mass production of many date palm cultivars.

Regeneration of date palm by somatic embryogenesis has been

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Shoot apices extracted from the lateral and axillary off-shoots are

used to induce embryogenic callus. Large number of somatic embryos

were produced by sub culturing with low concentrations of growth

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large scale but the use of high level of hormones in the media may cause

somaclonal variations.

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This term refers to the development of adventitious shoots from the

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This process usually occurs after an intervening period of callus growth.

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a suitable medium or sequence of media that promotes proliferation of

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transformed into cyclic nodules from which shoots or roots are developed.

Shoot formation followed by rooting is the general characteristic of

organogenesis. Generally high concentrations of cytokinin favours shoot

bud formation whereas high level of auxin promotes rooting.

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shoot may not cause mutations in the plants due to the use of low level

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of use of low concentrations of plant growth regulators and consequently

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culture period is limited by frequent renewal of the plant material.

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The apical meristamatic tissues extracted from the axillary and lateral

off-shoots gave promising results and are now used as the widely accepted

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are not recommended. Two-three year old �� can be used as explant

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then the leaf-sheaths are removed one by one from the outer ring towards

the center. Care must be taken to avoid any kind of shock or damage to the

��B�� heart is about 2 to 3cm in

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to a sterilized bottle containing chilled aqueous solution of citric acid and

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The explant must be kept in one percent sodium hypochlorite solution

mixed with one drop/100ml of Tween-20 for 20 minutes followed by 4-5

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solution for 5 minutes, followed by 4-5 washes in sterilized distilled water.

Sterilized explants of date palms are kept in a cold sterilized solution of

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ml of medium can be dispensed in 40 mm culture tubes and sterilized for

15 min. at 121o1��I��7�-1J��

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cultures must be incubated in a growth chamber at 25+1oC under dark

conditions. Embryogenesis and embryo multiplication can be carried out

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from the embryogenic callus and cultured in fresh media for multiplication

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must be increased to 3000 lux. The regenerated plants are allowed for shoot

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different stages of date palm tissue culture starting from explants to

rooted plant.

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several subcultures and serious attention. Acclimatization process of the

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tissue culture-derived plantlets also needs careful attention, otherwise

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reported in date palm culture during acclimatization. An in vitro cultured

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develop various abnormalities in their morphological, physiological and

biochemical characteristics. Transfer of such plants to a new environment

with less relative humidity and varying temperature may lead to health

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of plantlets of date palms through

micropropagation. A. Explant in the

medium. B. Callus formation. C.

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embryos.

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base of 15 mm or more diameter and with adequate rooting has to

be transferred. Planting operation has to be done as quickly as possible

after washing off any traces of culture media and disinfecting with broad

spectrum fungicides. A sterilized medium comprising of peat moss,

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the medium must be regulated to minimum and relative humidity of the

growth tub must be maintained high.

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Macronutrients

(Stock solution 10x)

g-l

W o r k i n g

s o l u t i o n

(1x)

Potassium nitrate

Ammonium nitrate

Calcium chloride

Magnesium sulfate

KNO3

NH4NO

3

CaCl2.2H

2O

MgSO4.7H

2O

19.0

16.5

4.4

3.7

100 ml

Sodium mono phosphate NaH2PO

4 1.7

Potassium phosphate

Micronutrients

KH2PO

4

1.7

mg- l

100 ml

Boric acid

Manganese sulphate

Zinc sulphate

Sodium molybdate

Copper sulphate

Cobalt chloride

H3 BO

3

MnSO4 H

2O

ZnSO4 .7H

2O

N a2

M o O4

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2H2O

CuSO4 .5H

2O

CoCl2.7H

2O

620

2230

860

25

2.5

2.5

10 ml

Potassium iodide

KI

83

10 ml

Sodium EDTA

Ferrous sulphate

Na2EDTA

Fe SO4.7H

2O

3730

2780

10 ml

Vitamins mg/100ml

Glycine

Nicotinic acid

Pyridoxine-HCl

Thiamine-HCl

Pantothenic acid

100

25

25

50

25

3 ml

10 ml

Glutamine 10g-l

20 ml

"#��)��0��0��0��.� ��4�.��

3%

require more sugar in the medium while others need more vitamins,

nitrogen, calcium and different growth regulators. Table 2 shows the

� �� /��

�� !� �� " ��

conditions and growth regulator requirements also vary. A general

evaluation of the growth regulator requirement and culture conditions for

different morphogenesis is given in table-3.

Growth regulators

2,4-dichlorophenoxy

acetic acid

1-naphthaleneacetic acid

6-γ- γ-dimethyl-

aminopurine

N-(2-furanylmethyl)-1H-

purine-6-amine

2,4-D

NAA

2iP

Kinetin

1mg/ml

1mg/ml

1mg/ml

1mg/ml

Myo-inositol 6.25g-l

20 ml

Sucrose 30 g-l

Agar 8 g-l

Activated charcoal 1.5 g-l

��V�� (�7�@��

Growth hormones given in the table are used for different morphogenesis.

3#

"#��'��0��8��.�� 4�.��

Sl.

No

Media

(mg/l)

Growth

regulators

Purpose Cultivar Reference

1 MS+glutamine

200+biotin

0.5+adenine sul-

phate 20+ thia-

mine 10+Ca-

panto 10+40g

sugar (pH5.6)

NOA

0.5+BA

1+K1+2iP

1

Axillary

bud

prolifera-

tion from

shoot tip

Medjhool

Hegazy and

Aboshama 2010

(Acta Hort

882:167-176).

2

MS+glutamine

200+biotin

0.5+adenine sul-

phate 20+ thia-

mine 10+Ca-

panto 10+40g

sugar (pH5.6)

Putrescine

150

Bud for-

mation

Medjhool Putrescine

100

Embryo

multiplica-

tion

IBA 1 Rooting

3 Modified

MS+KH2SO

4 170

2,4-D

200uM

Callusing 5 Nigerian

vars.

Sani et al.,2010

(Acta Hort

882:177-184)

4 MS+Morel

vitamins

2,4-D

2+IPA 3

Callusing D.Noor Chabane et al.,

2010 (Acta

Hort.882:185-191)

5

MS+ vitamins 2iP 2+BA

1+NAA

1+NoA 1

Bud for-

mation

Maktoum

Khierella and

Bader,2007.(Acta

Hort.736:213-

232).

Liquid MS 2ip 4+BA

2+NAA

1+NoA 1

Bud multi-

plication

MS GA3 0.5+

NAA 0.1

Elongation

MS NAA 1 Rooting

6

MS+

Na2PO

4.2H

2O

170+Inositol

100+Sugar

30g+Charcoal 3g

NAA

1+2iP 6

Callus

multiplica-

tion

Sefri

Al-Ghamdi 1996.

(Proc.3rd

Symp.

date palm,Al-

Hassa pp 1-12).

Contd….

33

27

7

MS+

Na2PO

4.2H

2O

170+Inositol

100+adenine sul-

phate 0.04+ thia-

mine HCL 0.4+

glutamine

100+Sugar

30g+Charcoal

3g+ agar 6g

2,4-D

100+2ip 3

Callus

formation

Barta-

muda

Gondila

Shamia

Amal et al.,2006.

(Acta

Hort.736:233-

240).

2,4-D

10+2ip 3

Friable

callus

NAA

0.1+BA0.

05

Embryo-

genic

callus

NAA

0.1+BA0.

05

Germina-

tion of

embryo

¼ strength MS NAA 2 Rooting

8 MS+Meso inosi-

tol 100+thiamine-

HCl 4+ agar 8g+

charcoal 3g

2,4-D

100+2ip 3

Callus

production

Excised

zygotic

embryos

from dif-

ferent

cultivars

Tisserat, 1983.

(Proc. First symp.

Date palm, Al-

Hassa 126-139.) Modified Ms No PGR Embyo-

genesis

Modified Ms NAA 0.1 Rooting

9

MS+sugar

30g+agar

8.5g+inositol

100+aneuric hy-

drochloride

0.002%+ charcoal

3g

NAA 100

or 2,4-D

100+2iP

3mg

Callus

induction

Different

cultivars

Asemota et al.,

2010. (Acta

Hort.882:225-

231.) NAA

0.05+2iP

1

Embryo

induction

GA3 2 Shoot

elongation

NAA 0.05

-0.1

Rooting

10

MS +

Na2PO

4.2H

2O

170+Inositol

125+Glutamine

200+ nicotinic

acid 1+pyridoxine

HCl 1+thiamine

5+Sugar

30g+Charcoal

1.5g+ agar 7g

2,4-D

100+2iP 3

Callus

induction

Khanizi

Mordarsing

Eshraghi et al.,

2005.

(Afr.J.Biotechnol.

4(11):1309-1312.)

NAA 10+

2iP 30

Regenera-

tion

Contd….

3'

11

MS +

Na2PO

4.2H

2O

170+Inositol

125+Glutamine

200+ ascorbic acid

100+ citric acid

100+ nicotinic

acid 1+pyridoxine

HCl 1+thiamine

1+ ca-pantothenate

1+biotin 1+Sugar

30g+Charcoal

1.5g+ agar 7g

NAA

10+2iP

1.5

Callus

multiplica-

tion

Not men-

tioned

Al-Khayri, 2005.

(Current Science

84(5):680-683.)

No PGR

Somatic

embryo-

genesis

½ strength MS IBA 0.2-

0.4

Regenera-

tion

12

MS

2,4-D

100+ 2iP

3

Culture

initiation

Sukary

Al-Khateeb.2008.

(Am.J.Biochem.

& Biotech.4

(1):19-23.) NAA

10+2iP

30

Culture

swelling

NAA 10+

2iP 6

Embryo-

genic cal-

lus

13

MS

2,4-D

100

Callus

induction

Khalas

Aslam &

Khan.A.2009.

(J. Fruit Orna-

mental Plant Re-

search 17(1):15-

27.)

BAP 2 or

K 2

Regenera-

tion

14

MS

NAA 0.1

Rooting

Kapkap

Tharlaj

Kamla Ibrahim et

al., 2009.(Am-

Euras.J.Agric.&

Environ.6(1):100

-103.)

3(

Stages Growth

hormones

(mg-l

)

Culture

condi-

tions

Period

(weeks)

Morphogenesis

Culture ini-

tiation

2,4-D-100

2iP-3

Activated char-

coal 1500

Dark 9

Tissue protru-

sion

Callus in-

duction

NAA-10

2iP-3

Activated char-

coal 1500

Dark 3

Callus formation

begins

Callus mul-

tiplication

NAA-10

Activated char-

coal 1500

Dark 9

Rapid multipli-

cation

Embryo-

genic callus

NAA-10, 2iP

6 AC 1500

Dark 9 Embryogenic

callus develops

Embryo-

genesis

Basal me-

dium

Light 12

Somatic em-

bryos develop

and germinate

Rooting NAA-0.2 Light 12

Root formation

and develop-

ment

Acclimati-

zation

Sterilized

potting me-

dium

Light 12

Development of

plantlets under

soil conditions

"#��*��!��8�� 4�.��

3&

�#��.��"��4�.�

Y�� '�� '�'�� (��"��palms that originate from tissue culture are generally detected. McCubbin ��I<��J�� {��"�� "��"��'{�� '�� {��@'8�� I)��7��'EJ�� I��'+��"<��8]��'%��" <��" <��] !V��" <��] 1�� " <��>J �� "N��"#��$��(�� '=��(��I<��8J��' �� ?�� " ��" �� " ��malformation, single leaf chlorosis, twisted leaf, spreading lower leaves ��"��"��'��"��"�� {��" �� ?�� '+�� I<��8J �� X��=�� $��

�� '�� ?�� I!��"�F88J� �� phenotype may be genetic in nature, which are heritable through sexual �� I+�� "�FF7]N��"<��J�1�� " ��" ��"caused by delayed replication of heterochromatin under in vitro conditions �� /�� " �� I(��!��"<��<J�

Y�� ? �� ? �� somaclonal variations in the tissue culture derived plants. Kaeppler et al. I<��J �� generated during the in vitro process. During in vitro culture, phenomena ��?��I1��1��"<��]N��"<��DJ"��!#�� IN��"<��"<��<]9��"<��>]��"<��>J"�� I;��"�FF�]1��"<��J��

31

� �� '�� abnormal fruit setting is higher and it declines with ageing of plants IE��"<��7]1��"<��>J�� epigenetic nature of this abnormality. Gradual elimination of epigenetic �� !#�� and actions of transposons/retrotrasposons by cellular repair mechanism I(��"�FF@]9��!��"�FF�J�;�� <">'! �� (�� !#�� I��'$��" �FF7] G�$�� "�F:FJ�� I1��"�F:@J�!#�methylation is reported to increase with increase in concentrations of auxin I<">'!J��I��JIG�$��"�F:FJ�&�� I��'%��"<��"<��]H��"<��>J�X��'� � �� plants at maturity stage thus escaping selection and screening, resulting economic loss to the farmers.

)��7�)�� '�#�� "�'��

fruit development.

32

&��H�;!I��'+�� " <��8] $�� " <��] ��'+�� " <��D" <��8J�� B�� I�B�/�� " <��<J �� ? ��V��)G;��E��I<��7J��9�� !#�� phenotypes.

1�� I�F:@J�� '�� IElaeis guineensisN��/�J�� !#�� IN��<��<]&��"<��J��'+��I<��8J�� )G;�� +�� embryogenesis and organogenesis. Since the leaf samples for analysis were ��'�� '�� '+�� I<��8J �� !#� �� /�� 1'�� H�� 1�� I<��>J �� growth regulator regimen on Exacum L. in tissue culture and found that different regimes caused genotypic variation in the form of varied ploidy levels. The trend of somaclonal variants that differ with respect to height, �� {�� with regard to two species of PiceaG��I��"�FFFJ�$�� N�� I�F8@J�� differed from original explants with changes in plant and organ size, leaf �� {�� X��recently micropropagation of date palm cultivars was carried out through somatic embryogenesis that originated from callus tissues induced by the higher concentration of auxins and cytokinins. The long phase of callus induction and somatic embryo formation with growth regulators might have generated genetic and epigenetic changes in the resulting plants.

30

��

Date Palm has adapted to areas with long, dry summers and mild winters. It thrives well in different types of soil but the most preferred ��'��'��!�� /�� /��?��/�� $��<<�� (�� %�� D�� /��8��/��/��I$��"<��J��/�� big stones and weeds from the planting area. Spacing between the trees and rows is depending upon the cultivar proposed to plant. Most of the date ��'��D'>�7��!��'��?�� advisable to provide a little more space after two rows so as to facilitate the easy accessibility of vehicles and machineries to each tree.

Planting

Size of the pit generally depends upon the size and age of the plant. Nowadays it has become a practice to transfer mature trees of uniform size from one place to another, as part of landscaping. In this case digging a pit of exactly the same size of the base of the tree may give more support to stand erect otherwise more loose soil around the tree may cause falling �� )�� have a pit of 75 x 75 x 75 cm size. The pit should be allowed to keep � �� organic manure, which should be covered by 10 cm thick sand layer before �� )��/�� /�� germination of chance weeds that came along with the organic manures. �� "��/�� >�'>7��then can be regulated to twice or thrice per week. It is advised to keep ��" ��"��/��/��<7��I#J�� I+J��87� �� I;J�!��;��

'$

�� 7��:"��1'��plants start yielding at the age of 4.

��

!�� {��different plants. Pollination in large extent takes place by wind for which �� /�� "��7��I<^J�� is not enough for chance pollination by wind. The most popular way of �� {�� {��)��{��"��{��$��{�� 7'�:��9�� is done immediately after the bursting of spathe. This will help to avoid chances of missing pollination and production of multicarpelled fruits. Mechanical pollination is adopted in certain countries where labour is very �? ��!�� ?��V�� "�� "��\�� mechanical devices.

1��+��4.��

��{�� I)��7�'9J�)��of effective pollination leads to the formation of triple parthenocarpic �� I��'+��" <��8] H��"�F:@" W�� }%�"�FFF�J�(�� 1'�� 7'8�� *��the reasons of this fruiting abnormality may be pollination failure due to �� !V�� I�FF7J�� dates cultivars had better yield when pollinated with selected males rather than with others.

��B��'��V�� "��?��'��{�� IN��"�F8FJ�

'%

By pollination, the pollen is not only affecting the size of fruits and �� I$��" �F<:J� �� {�� I#�?��" �F<8" �F<:] $��"�F<:]%��"�FDD]$��}#�?��"�F7:];��'��H��"�F7:]1��"�F@�]��}�� "�F@�] ��"�F@<]��'!��}��"�F@F] =�'%��}��"�F@F]*��"�F8>]#�?��}1�� "�F8:] =�'(��"�F88]=�'$��"�F8F] (��B��"�F:D]=�'E��"�F:DJ��'+��I<��@J��{�� {��B��period of fruits. Most of the male palms available are of seedling origin with �� /�� " ��B�" /�� combination with different female cultivars.

)��B��"�� palms it takes an average 200 days to reach a fully ripened stage. During this ��"�� \

� (�� pollinated.

� Kemri follows and lasts for 9 weeks when the fruit is rapidly ��:7^��!��"��and hard.

� Beser during in which weight gain slows, moisture level drops to 50 to 60%, sugar content rises and colour of the fruit changes.

� ��H�� "��I��D7�>�^J��

� Tamar, a dried stage with 20 to 24% moisture content. This fruit is harvested and sent for processing, packaging or value addition ��(��the fruit is spread out on mats for further drying to tamar stage.

'#

5��0�!�.��

�� 7�'<�� =�� {�� {�� /��B��)�� /�� \

��H��

��H�� the bunch.

�� H�� strands.

This practice provides good aeration and more room to the fruits to grow.

9� �4��!

Depending on variety, date palm leaves can remain alive for at least ��?�� /��*��need to be cut periodically. Pruning is done at any time after harvest before ��?{��"��"��from the tree. During the pruning operation, unwanted �� should also be removed to foster growth of those retained with mother plant.

Diseases and Pests

!�� I+��B"�FD�] 1��"�F7F] 1�� } =��" �F:8] !V��"�F:D] W�� "<��<J�W��I�FFFJ�� )�*�� '!�� 1�� the fungal diseases, Bayoud disease caused by Fusarium oxysporum Schl. �� &�� Symptom of disease appears on one or more leaves in the middle of crown, characterized by discoloration and withering of leaves. Gradually, all the leaves in the crown are affected and ultimately plant dies. Since Bayoud is a soil borne disease, selection of suitable disease resistant varieties for ��%��

'3

by other Oxysporum� ��{��Mauginiella scaettae are other important diseases of concern in date palm cultivation. Effective management of plantation, controlling humidity in the orchard and periodic application of fungicides are recommended to control these ��V��Ceratocystis paradoxa and C. radicicola are generally seen on the trees growing in the salinity and drought affected areas. Starting from necrotic lesions, leading to cankers, bud rot and ultimate death resulting in bare trunks are the symptoms of this disease. ;�� " ��{�� !� ��'��"�� leaf spot, belaat disease, leaf spot disease and root rot caused by various fungi are also of serious concern to date palm cultivation. In addition to fungal diseases various diseases caused by phytoplasma were also reported in date palm. The table 4 provides a brief account of diseases in date palms.

Pest control in date palm orchards is a continuing process with the main �� IRhynchophorus ferrugineusJ"��IMeloidogyne incognitaJ" ��IPsammotermes hypostomaJ"�� IParlatoria blanchardiiJ" �� IBatrachedra amydraulaJ��IDysmicoccus brevipesJ�)�� of Fusarium and Phytophthora are generally associated with borer activity, creating access for fungal spores to the interior of the palm. Borer and termites cause degeneration of the palm trunk, nematodes work at the roots, weevils work on the trunk, scale and mealy bugs suck the sap from the leaves. Scale insect sucks the sap from the palm leaves and at certain times of the year it is very active and exudes a sweet syrupy substance. The syrup provides a perfect food for certain moulds which have black fruiting spores �� the scale by carrying them to other palms and stroking the abdomen of the scale insects to stimulate the production of sweet exudates.

In addition to the diseases caused by living organisms, many physiological disorders are also seen in date palms due to climatic extremes and phytosanitary mismanagement.

''

Disease Causative organism Symptoms Control measures

Bayoud Fusarium oxysporum

ssp albedinis

Ash colour appears on

the middle leaf, then

withers from bottom to

top. When terminal bud

is infected, the plant

dies.

Growing resistant

varieties is the best

way.

Wilt

Fusarium proliferatum

Gradual yellowing and

wilting of leaves fol-

lowed by death of palm.

Application of

fungicides during

early stages.

Black

scorch

Ceratocystis paradoxa Scorch on the leaves,

trunk and bud rot, inflo-

rescence blight

Remove affected

tissues. Apply

copper fungicides.

Brown leaf

spot

Mycosphaerella tassi-

ana

Dark lesions with red-

dish brown margins

appears on leaves.

Annual pruning of

the dead leaves

help to control

spreading of

disease.

Diplodia

Diplodia phoenicum

Offshoots are most

commonly affected.

Long streaks appear on

the midrib and dies.

Disinfect all the

tools used for

removing off-

shoots. Apply fun-

gicides.

Graphiola

leaf spot

Graphiola phoenicis

Small ball like sori ap-

pears on the terminal

pinnae of the old

leaves.

Life of the leaf is re-

duced to 2-3 years af-

fecting the productivity

of the tree.

Leaf - pruning and

application of fun-

gicides.

Inflores-

cence rot

Mauginiella scattae

Brownish or rusty areas

appear on the inflores-

cence. Gradually all

flowers in the inflores-

cence decay. In severe

cases spathe do not

open and dies prema-

turely.

Phyto sanitary

measures followed

by fungicide appli-

cation.

Omphalia

root rot

Omphalia tralucida

and O. pigmentata

Premature death of

leaves and cessation of

growth

Fungicide applica-

tion

"#��,��1��!��4�%��4��.�� 4�.�

'(

Belaat Phytophthora sp. White leaves appears in

the central crown and

plant dies.

Phytosanitation

and application of

copper fungicides.

Fruit rot Aspergillus niger and

Alternaria sp.

Fruit decay and prema-

ture fall

Thinning of

bunches and spray-

ing fungicides

Lethal

yellowing

Mycoplasma Fronds became dessi-

cated. In severe case

crown topples from the

palm leaving a naked

tree.

Select resistant

varieties.

Al wijam Mycoplasma ? Growth retardation,

productivity loss and

final death of the tree.

Phytosanitation

'1

��4��*

��

There is a controversy over the total number of date palm cultivars �� 9�� I�FF@J��7��"W��I�FFFJ��D��$��I<��J �� @�� " �� '�� &�� ' � ��"known by different names at different places or one name is assigned to different cultivars at different places. This has created lot of ambiguity �� characterizing cultivars and assigning a more acceptable legitimate name to the cultivars was seldom attempted in this species, especially in Saudi �� V�� V��$��"+��X�="��(�VV�� /" $�� (�� =�� " !�� #�� "H�B��B"9��"#��$�� 9�� *�� I$��"<��J��"{��"��"��?��$�� in the market at the beginning of the season while some others appear very ��cultivars across the world is pointing towards the necessity of an authentic and reliable enumerative study using standard morphological and molecular markers.

E�� ?�� I$�� " �FF:J� $�� have attempted to enumerate cultivars available in their respective areas. Most of them focused on fruit morphology and names were given according ��!��'��inevitable and several descriptors were proposed and evaluated by many ��I�;EH�"<��7];��}E��"�F::]H��"�FF>"<��7]$��"<��]=��B��"<��<J�=�� cultivars have shown that there is a lot of variability among cultivars and selecting one or two common descriptors for distinguishing cultivars is a ��

'2

0��4��!��+��4��#%�� $��4�.��

................................................................................................................Length of leafLength of midribLength of pinnated partLength of spined part%�� %��%��Maximal leaf width%�� Number of pinnaePercentage of antrorse pinnaePercentage of introrse pinnaePercentage of retrorse pinnaeMaximal pinna width at the middleLength of pinnae at the middleLength of pinnae at the topMaximal pinnae width at the topIndex of spacingNumber of spinesPercentage of solitary spinesPercentage of paired spinesPercentage of triple spinesLength of spine at the middleMaximal spine width at the middleSpine angle.................................................................................................................. )�� " ��

development along with the leaf morphology has shown promising results ��)�� "��200 days to reach a fully ripened stage. During this process, the fruit passes through many stages of development beginning with hababauk.

'0

Colour variations during beser, rutab, and tamar stages are good diagnostic markers for distinguishing cultivars. Shape and size of the �� B� ��{�� )�� I ��?J ��also considered as a marker for distinguishing cultivars. In some varieties fruit cap completely cover the fruit base whereas in others it covers only the central portion. Seed characters like shape, size, position and type of germ pore, type and margins of the ventral canal, etc. can also be used to distinguish between cultivars.

0��%�� Characterization of biodiversity can be done at the primary, secondary

and tertiary levels that in turn refers to analysis of variability at the morphological, chemical and genetic levels respectively. Morphological variations is the product of interaction of environmental parameters with phenotype development and therefore likely to change with regard to ��'��;�� respect to variation in economically or biologically important secondary metabolites constitutes the secondary level screening of biodiversity. Tertiary screening apparently negotiates involvement of genetic factors in the observed variability at the primary and secondary levels.

Genotyping of biodiversity is therefore to characterize variability in � ��!#��/��?��and nature of distribution of this variation can be assessed with the help of appropriate marker technology. Conventional strategies include markers based on comparative morphology, anatomy, phylogeny and embryology ��(��" �� molecular markers has complemented the classical strategies. Molecular �� screened to evaluate genetic variation that could belong to the class of secondary metabolites, proteins or nucleic acids. Protein markers are used as genetic markers on the assumption that any variation between proteins ��{��/��(��of protein markers is debated for its stability and accuracy.

Therefore, markers employed should be ideally neutral to environmental ��" �� {�� (�� " !#� ��

($

��/�� "��/��"��

"%4�� +��.��!#��B��'��

��;��1��H��I;1HJ��"!#� ��B�� !#�� /��=?�� \H)G;IH��)��G��;�� J"HGE$IH��G��E��$��J�

��;1H'��in vitro�� /�� =?�� \H�;!IH�� ;�� !#�J"�)G;I�� )��G��;�� J"$$HI$�� $�/��H� ��J��$$HI��$�� $�/��H� ��J�

&��.��.4��%.��4��+��:&��+;��%��H�;!��FF��

��/�� !#� �� '�� I%��}&�1��"�FF�]%��"�FF�J��;��1�� H�� I;1HJ'�� /��" �� !#�� "��!#� ��$��/��H�;!�� and easy methodology its level of genetic resolution is comparable with H)G;I1��/��&��"�FF>J�� !#�� '�� markers for the analysis of genetic diversity and to study the phylogenetic �� H�;! �� help in proper collection and cataloguing of germplasm of date palms.

(%

��%.��&��:��&;��;1H��;1H ��H�;!

��/��I��'��J* �� H�;!�� "�� H�;!�� B��<��D�� B�� !#�� H�;! ��"�� H�;! ��X��H)G;�� " H�;! �� markers which can easily be scored and statistically analyzed.

&��+�"��8�� Some date palms have similar or narrow distinguishing morphological

�� H�� ;�� !#�IH�;!J�� "/��? �� I%��}&�1��"�FF�]%��"�FF�J�� !#�� !#�� H�;!��B��\

Individual varieties of cultivated cropTesting and assurance of cultivar purityY�� Measurement of genetic diversityDetection of somaclonal variation, andProtection of proprietary rights.

(#

��/�� of �� I1��/��}&��"�FF>]$��}&��"�FFF]$��"<��]1��}1��"<��<]��'+��}��"<��D]��"<��D]��'+��"<��@�]��'+��"<��@J�1�� studies and genomic similarity of some selected date palm cultivars in Saudi �� {��I��'+��"<��8J�1�� IX;E&�J �� ?��'��$�� !#�� I1�� " �FFF]!��}1��"<��D]��'+��}��"<��8J

9#��%�� &��+��%��

��.��+��7��

� �� ?�� /�� !#� �� I��'� ��"��J��

��4�<I&��!�� "�F:DJ1. Turn on the water bath and set at 65oC and preheat the extraction

buffer.<� ;�� /��D� 1��7�'<7�� "��

��"�� /��nitrogen.

4. Transfer the powdered tissue to a 1.5 ml microtube and add 600 ��I<?��J�� ?��the frozen powder starts thawing.

5. Mix gently by inverting the tube several times and then add 50 ml of 10% SDS and 4 ml of 20 mg/ml Proteinase K, and mix gently.

6. Incubate at 65oC in water bath for 30 minutes with occasional swirling.

8� ��<��7& ��"��?�� <�� '<�oC for 2 minutes.

:� 1��<�� I<��?�J��<��>oC and

(3

�� I�� /�� Jto a new tube.

F� ��/�� mix gently to precipitate nucleic acids.

�� 1��<�� I<��?�J��<��>oC and pour off the supernatant. Precipitated nucleic acids will be ��%�� 8�^�� D��'�� 7�� 7��?�=��I (:J�

�� <�7��H#��I��J��incubate for one hour at 37oC. Store at –20 oC for further use.

�=�� +�� D&��

��?��/�� !#��

2. Spin at 13000 rpm for 10 minutes, discard the supernatant and wash the pellet with 70% ethanol.

D� ��'�� 7�� ?�=��I (:J�

>� &��!#��!�#�O��<��{��$��'<�oC until use.

��%.��&��:��&;

&�!��8��<

)��+��$�� B��

'��6��&6��.�� !��*;=H*# ��I��J��'

��+� ��"9"''''''W I<� �� J" ��*;=H*#��"$��:"��"1�F>7��"X$��

&��%�� 4��.�� /�� = �� I ( :J � ��

lyophilized primers to make a stock concentration of 1 mg/��=�� accompanying the primers supplied by the company.

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2. Make a dilution of 100 times of the stock solution by adding �F:��=��<��I��J��10 �g/ml.

*��Taq�+��%.��

1��<8'�8FF'�D"��;��9��":��1��";��"#N�::77"X$��1��\7X��1�� B��'<�oC.

>��+��< 1 Unit will catalyze the incorporation of 10 nmol of total ��'�� D��8�oC utilizing M13 � �:!#��

,��&�#� ��0!��2

1��<8'�8FF'�D�$� ��/!#�;��;1H�� 7��&+1�" �7�&MgCl

2"��&��'(1�I (F�� J�

@��.4��"��<

&��&��#�;��<�7�&��/��7��87�l in 0.5 ml microfuge tubes and keep frozen until further use.

)�� ;1H �� \

Reagents\�(<*��;1H��#�;�I<�7�&J* ��;��I��J��/ ��I7X��J�� !#�I<7��J

Total volume

((

0��0�7�

1�� ?�� !#� �� /��<D��;1H�� !#��tube separately.

��!#�� )��?�� ;1H�� !#��be 25 ��!#�� water.

"��.��%��

��;1H��;1Hmachine. Thermal cycler has a metal block which can be heated and cooled to a desirable temperature very precisely within a short period of time. X��!#�� H�;!��/��"D7�>��run.

=�� \

)��+��!#��F>oC

'��! of primers at 36oC, and

*��7��!#��8<oC.

�� !#��9��!#�� "�� B��;1H��

(&

�!��4��

��>^��"<�:��<��9=buffer by heating in microwave oven. Make sure that agarose has fully dissolved. Cool a little and then add 6 μl of Ethidium bromide solution I��J�&�?�� 7��D�� /��%��remove the comb vertically and then dip the gel in the electrophoresis tank ��9=��

��;1H��7�� ' � ��G��'�7��the samples. Connect the electrophoresis tank with a power supply unit and ��:��>��/��"��the end of the gel.

+��.��%��

�� XY'��B��!#�� ;1H�� gels are then documented by taking photographs either by using Gel !��$��I9��H��J�� ;��

�� !#� �� V�� $�� )�� !#� �� phylogeny among the samples several softwares are available in the market, ��&�;&�+=H"#�$��"!��!��9��I9��H��J"��!#�� !#��!#� ��;1H�� !��1��#��I�F8:J��#��G�I�F8FJ��$��?��idea of the similarity and or diversity among the individual samples and �� *� �� ? �phylogenetic tree or dendrogram is constructed using Unweighted Paired E�� &��IX;E&�J��

(1

�� +�

�� H�;!�� $�� )�� names we relied on farmers, and at maximum possible occasions cross �� ? �� $ �� )��H�;!��"�� 7�� B�� *;=H*# �� H�;! �� case with exceptions in certain cases. Photographs of fruits at beser, rutab ��/�� '{�� including colour, shape, and size of the fruit, shape of fruit base, size of fruit cap, size and shape of seed, position of germpore, characteristics of ventral canal, etc. are also given. It is presumed that a cultivar having given morphologic characters will produce a similar banding pattern with �� *;=H*# �� *��over, duplications can be detected and a legitimate name can be assigned to the cultivar with maximum available synonyms. The presentation of the �� /��

(2

1. Adhlah ��

OPA7 OPB13 OPC14

*;�8*;9�D*;1�>

)��

��"�� ?"�D�7?3.0 cm. In beser stage it is light green turning red during rutab. In tamar ��)��"��8�^��)�� @�^ �� '��" �� $�� " � <�� ?1.1 cm, obtuse at apex, dirty white throughout. Germpore in the middle, �� Y��"��"�?��few millimeter below the apex.

(0

2. Adhuhaibah ا��ه��

OPA2 OPC5 OPB13

*;�<*;17*;9�D

'��#��

)�� /�� ?"�D�7?<�7��ripening process brings reddish brown colour from the tip. In tamar stage ��)��"��7�^��)�� >�^��'��"��$�� "�<�D?��"obtuse at apex, brown coloured throughout. Germpore in the middle, ��Y��"��"�?��towards the tip.

&$

3. Aediyah ��

OPA02 OPA11 OPB20

*;��<*;��*;9<�

*��%��

)�� ?" �5.5 x 2.5 cm. In beser stage lemon yellow in colour and during rutab ripening process brings amber colour from the tip. In tamar stage it is amber coloured with broadly wrinkled skin, which is almost adpressed ��{��)��"��@�^��)�� >�^��'��"��$�� '��"<�:?��8��"�� ?"�� E�� " �� Y��groove slightly broader at base, edges smooth, extending towards the tip.

&%

4. Ajwah ة��

OP A06 OP C10 OP C14

*;��@*;1��*;1�>

,��B��

)�� ?�D�D:?<�@:��beser stage scarlet red in colour and during rutab ripening process brings black colour from the tip. In tamar stage' it is black in colour with wrinkled ��"�� {��)�� "��@�^��)�� >�^��'��"��$��'��"<��?1.1cm, rounded at apex, rough, ash coloured throughout. Germpore in the ��"�� Y��"��"��"�?�� *��? ��highly demanded date having historical/religious importance. It is widely cultivated in Madinah area and the pilgrims are very much interested in procuring this precious date fruit.

&#

5. Al-Asree ي ا��

OPA02 OPA11 OPB20

*;��<*;��*;9<�

@��

)�� /�� ?" � >�@x 2.2cm. In beser stage lemon yellow in colour and during rutab ripening process brings amber colour from the tip. In tamar stage it is amber coloured with broadly wrinkled skin, which is almost adpressed to ��{��)��"��7�^��)�� 8�^��'��"��$��"�<�:?��F��"�� ?"��E�� " ��Y��"��"extending to a few millimeters below the tip.

&3

6. Al-Haizah ا��

OPA02 OPA11 OPB20 *;��<*;��*;9<�

F��-�$��

)�� ?" � >�: ?2.4 cm. In beser stage greenish yellow in colour and during rutab ripening process brings amber colour from the tip. In tamar stage it is amber coloured with a dull white base and broadly wrinkled skin, which is almost free from ��{��)��"��@�^��)�� :�^��'��"��$��"�<�:?��F��"�� ?"��E�� "�� Y��"��smooth, extending to a few millimeters below the tip.

&'

7. Al-Seateah ا��

OPA02 OPA11 OPB20

)��'�� ?">�:?2.4 cm. In beser stage bright yellow in colour and during rutab ripening process brings amber colour from the tip. In tamar stage it is reddish brown ��"��{��)��"��"��>�^��)�� :�^�� '��" �� $��'��"�D��?��:��"�� ?"��E�� "�� Y��"��smooth, extending towards the tip.

*;��<*;��*;9<�

H��

&(

8. Anbarah ة ��

OPA10 OPB12

��'��B��"��'�� ?" � 7�� ? <�7 �� E�� )��"��8�^��)�� 8�^��"�� V��"��$��'��apiculate apex. Germpore a small pit, situated little above the middle. Y�� " �� " �?�� ?�*��? ��$��

*;��*;9�<

I��#��

&&

9. Ashraisi ا��

OPA2 OPA10 OPC5

)�� ?" � D�7x 2.5 cm. In beser stage greenish yellow in colour and during rutab ripening process brings reddish brown colour from the tip. Usually during rutab some white dots are seen on the fruits. In tamar stage it is yellowish brown in colour with wrinkled skin which is almost adpressed to ��{��)��"��@�^��)�� >�^��'��"��$��" ��: ? ��: ��" �� ?" �� E�� "�� Y��"edges smooth, extending towards the tip.

*;�<*;��*;17

J��

&1

10. Bareem ��

OPB08 OPB05 OPA09

)�� /�� ?�� "�D�>?<�>��E��in rutab. Presence of white irregular bands at the rutab stage is one of the diagnostic features of this cultivar. In tamar stage it is transparent amber �� )�� @�^ �� )�� @�^ �� " ��embedded within the fruit, easily detachable when young. Seeds ellipsoid �� ?"��"�<�>?��E�� Y��"�?��below the apex.

*;9�:*;9�7*;��F

)(��5��.��!�"

&2

11. Barhy ��

OP A06 OP C10 OP B13

)�� {�� ?"�3.5 x 2.7 cm. In beser stage lemon yellow, turns amber colour from the � ��Y�� " �� " �� )��"��"��@�^��)�� >�^��"��{�� $��'��"��"�� ?"�� "��E�� Y��groove wide and deep, wider near the base, edges wrinkled, extending up to the pointed tip.

*;��@*;1��*;9�D

))��5��%��#�"

&0

12. Barni ��

OPA12 OPC10 OPA07

)��/�� ?"�D�F?<��cm. Pale yellow in beser turning amber colour from the tip during rutab. During tamar stage it is amber coloured throughout, with smooth skin, not ��"��)��"��87^��)�� 7�^��"�� V��$�� ?"��Germpore is represented by a feebly visible circular pit situated below the �� Y�� " �� " �?��towards the tip.

*;��<*;1��*;��8

)'��5��$�"

1$

13. Buyedha ��

OPA02 OPA11 OPB20

)�� ?"�>�<?<�D��beser stage golden yellow in colour and during rutab ripening process brings amber colour from the tip. In tamar stage it is brown with broadly wrinkled ��)��"��@�^��)�� F�^��'��"��$��"�D��?��"�� ?"��E�� "�� Y��"�� ?"edges wavy, extending to a few millimeters below the apex.

*;��<*;��*;9<�

��)*��5�%��"

1%

14. Deglat Noor ر�� د

OP A11 OP B01 OP C10

)��'��"��{�"�� ?"�>�<?��@��light yellow, turns reddish brown during rutab. In tamar stage transparent ��" �� )�� " �� 7�^ �� )�� F�^ �� '��" �� {��$��" ��"�� ?"�<�@?��8��E�� Y�� " �� " �� "extending towards the tip.

*;��*;9��*;1��

),��+�!��%�$&��'(

1#

��Deglat Obaid � �� د

1

OPA02 OPA11 OPB20

)��'�� /�� ?" �D�: ? ��F �� ripening process brings amber colour from the tip. In tamar stage it is reddish brown with broadly wrinkled skin, which is almost free from the {��)��"��"��@�^��)�� F�^��'��"��/��$��'��"�<�>?��F��"�� ?"��E�� "�� Y��edges smooth, extending towards the tip.

*;��<*;��*;9<�

)@��+�!��6#�� &��'(

13

16. Duhaibeeah ذه��

OPC5 OPA7 OPB13

)�� ?"�3.5 x 2.5 cm. In beser stage it is green turning yellow in colour and during rutab ripening process brings brown colour from the base. In tamar stage it is blackish brown in colour with broadly wrinkled skin, which is almost �� {��)�� "��7�^�� )�� D�^ �� '��"��$�� "�<�<?��F��"�� ?"�� E�� " ��Y��groove broader at both ends, edges smooth, extending a few millimeters below the apex.

*;17*;�8*;9�D

)F��+��#��)

1'

17. Faaizeah ��"

OPA15 OPB13 OPC5

)�� ?"�D�:?<�:�� brings brown colour from the tip. In tamar stage it is dark brown with ��)��"��8�^��)�� D�^��'��"��$��"�<�D?��"�� ?"��E�� "�� Y��"edges smooth, extending towards the tip.

*;��7*;9�D*;17

)H��1�$��*

1(

18. Faqah �$ّ%ا�

OPA02 OPA11 OPA12

H�� ?" �7� 7 ? D�� " �� ripening process brings amber colour from the tip. In tamar stage it is ��"��)��"��7�^��)�� @�^�� '��"�� $�� " � D��x 1.1 cm, rounded at apex, light brown. Germpore above the middle, not �� Y�� " �� " ��smooth, extending to a few mm below the apex.

*;��<*;��*;��<

)I��18�� +,-�

1&

19. Graini �� &

OPA11 OPA02 OPA10

)�� "��{�� ?"�D��?<��E��H� �� )�� "�� 87^ �� )�� @7^ �� "{��$��"�� ?"�<��?��>7��E�� "V��Y��throughout, margins smooth, extending a few millimeters below the tip.

*;��*;��<*;��

)J��.

77

20. Hamra Rashood د اء ر)+�

OPA02 OPA11 OPB20

)��'�� ?"�7�<?<�>��during rutab ripening process brings reddish brown from the tip. In tamar stage it is black or reddish brown with broadly wrinkled skin, which is ��{��)��"��"��@�^�� )�� :�^��'��"��$��"�D��?��"�� ?"��E�� "�� Y��groove narrow, wider at both ends, edges smooth, extending to a few millimeters below the tip.

*;��<*;��*;9<�

'(��-.��&��(��% /��0#

78

21. Haqeeyah��

OPA02 OPA11 OPB20

)�� ?"�D�<?2.4 cm. In beser stage red in colour and during rutab ripening process brings reddish brown from the tip. In tamar stage it is reddish brown with broadly ��"��{��)��"��"��7�^��)�� :�^��'��"��$�� "��:?��:cm, rounded at apex, brown coloured. Germpore in the middle, prominent. Y��"��"��"�?��few millimeters below the tip.

*;��<*;��*;9<�

')��-8��%��,#

79

22. Hasawi� ��وي

OPA02 OPA11 OPB20

)��/�� ?"�>�7?<�<��stage lemon yellow in colour and during rutab ripening process brings amber colur from the tip. In tamar stage it is amber coloured with broadly ��"��{��)��"��"��7�^��)�� :�^��'��"��/��$��"�<�7?��:cm, obtuse at apex, brown coloured. Germpore in the middle, prominent. Y�� " �� " �� " �?��towards the tip.

*;��<*;��*;9<�

''��-��1��#

2$

23. Hilali � ه,�

OPA12 OPA06 OPC10

)��{�� ?"�D�>?D��stage yellow with rose tinge and during rutab amber from tip. Sometimes ripening process begins from both ends. In tamar stage reddish brown I(�� J" ��" �� " ��" �� )��"��8�^��)�� F�^ �� '�� $�� " � ��: ? ��8 ��" �� ?"smooth, dull white below the germ pore, reddish brown above. Germpore �� V��"��Y��wide, edges smooth, extending up to the tip of the seed.

*;��<*;��@*;1��

'*��-��2�

2%

24. Hilwah Al-Jouf� ��ة ا��ف��

OPA02 OPA11 OPB20

)�� ?"�7�:?<�Fcm. In beser stage crimson red and during rutab ripening process brings ��'�� )��"��7�^��)�� :�^��'��"��$�� "�D��?��"�� ?"��E�� " ��Y��"wider at apex, edges smooth, extending to few millimeters below the tip.

*;��<*;��*;9<�

',��-��K�� 3�4�&��#

2#

25. Hilwah ة��

OPA06 OPC10 OPB13

��"��"�� ?"�7�>?<�8cm. In beser scarlet red with golden yellow. During rutab blackening starts from the tip, sometimes from the base also. In tamar stage shiny black, with �� " �� )�� " ��@7^�� '��)�� 7�^�� " ��"�� V��$��"� �� ?"�� "��"�<�:?��F��E�� "��Y��towards the apex and the base, extending to a few millimeters below the apex.

*;��@*;1��*;9�D

'@��-��#

23

OPA02 OPA11 OPB20

26. Hoshana �-�( ه

)�� ?"�D��?<�7cm. In beser stage light yellow in colour and during rutab ripening process brings amber colour from the tip. In tamar stage it is amber coloured ��"��{��)��"��"��@�^��)�� 7�^��'��"��$��"��7?��:��"�� ?"��E�� " ��Y��"��"�?��few millimeters below the tip.

*;��<*;��*;9<�

'F��-��$��

2'

27. Kasabah ��.

OPB14 OPA15 OP C05

)�� "��/��"��"�� ?"�D�>?<�>��)��"��"��87^��)�� :�^�� '��"�� $�� "apiculate at apex, silvery white below the germ pore, reddish brown ��"��F?��: ��E�� " �� V��" �� Y�� "margins wavy, extending to the tip.

*;9�>*;��7*;1�7

'H��#��"��5

2(

28. Khalas ص,.

OPA07 OPA01 OPC10

)��'��"�� ?"�>�>?D��"��amber coloured from tip. In tamar stage shining amber, with broadly ��)��"��8�^��)��'�� "��D�^��'��$��<�@?��:7��"�� ?"��"�� "��E�� Y��at the tip, edges smooth, extending to a few millimeters below the tip.

*;��8*;��*;1��

'I��625

2&

OPA02 OPA11 OPB20

29. Khasaba Al-Quwaiah ا��

)�� '�� ?"�D�7?<�<�� ripening process brings amber colour from the tip. In tamar stage it is reddish brown with broadly wrinkled skin, which is almost free from the {��)�� "��@�^�� )�� 8�^��'��"��$��"�<�<?��F��"�� ?"��E�� " ��Y��"��"�?��towards the tip.

*;��<*;��*;9<�

'J��#��=��,�&�"��5

87

30. Khashab ��0.

OPB14 OPA01 OPC05

)�� " �� "� �� ?"�D�D?<�>��"��'��)��" ��" �� :�^ �� '�� )��'�� 8�^ �� " �� $�� '��" ��" �� " �� ?" � <�D ? �� E�� "��Y��"��"��"extending towards the beaked apex.

*;9�>*;��*;1�7

*(��#��"�75

88

31. Khudri ي �.

OPA06 0PF05 OPC10

)��'��"��/�� ?"�D�F?<��cm. In beser stage pale green turning yellow with a reddish tinge in rutab. H� �� )��"��@�^��)�� 7�^��$�� '��"�<�7?��8��"�� ?"��"��brown, whitish below the germpore. Germpore a circular pit, little above ��Y��"��"�?��towards the beaked tip.

*;��@�;)�7*;1��

*)��5

89

32. Khunaizi ي��.

OPA02 OPA11 OPB20

� � � �

)�� ?"�D�<?<�>��beser stage crimson red in colour and during rutab ripening process brings reddish brown colour from the tip. In tamar stage it is black or reddish �� " �� {�� )�� "��@�^��)�� 8�^��'��"��$�� "�<�>?��:��"�� ?"��E�� " �� Y�� " �� ?" �?�� millimeters below the tip.

*;��<*;��*;9<�

*'��$��5

0$

33. Koweriah �� آ

OP A11 OP A15 OP A01

)�� " �� /�� ?"�D�@?<�>�� the tip during rutab. In tamar stage golden brown in colour with thick, ��$��)��?�"��"��@�^��)�� @�^��"��$�� '��"�� ?"��"�� "��"�<�<?��F��Y��"��"�?��few millimeters below the tip.

*;��*;��7*;��

**��8

0%

34. Labana �-��

OPA02 OPA11 OPB20

)�� ?" � D�: ?2.4 cm. In beser stage golden yellow in colour and during rutab ripening process brings golden brown colour from the tip. In tamar stage it is golden �� " �� {��)��"��D�^��)�� @�^ �� '��" �� $��"�<�D?��F��"�� ?"��E�� " ��Y��"�?��few millimeters below the tip.

*;��<*;��*;9<�

*,��9#��$��

0#

35. Madaq ا�+�ق

OPA02 OPA11 OPB20

)�� ?"�D��?<�<��beser stage light yellow in colour and during rutab ripening process brings amber colour from the tip. In tamar stage it is reddish brown with broadly �� " �� {�� )�� "��@�^��)�� @�^��'��"��$��"�<�<?��Fcm, obtuse at apex, brown coloured. Germpore in the middle, prominent. Y��"�?��

*;��<*;��*;9<�

*@��0�8�9 :�

03

36. Madjhool ل4�5

OPA15 OPF05 OPB13

�� " �� '�� ?"�7�<?D�<��*��'��amber colour from the tip during rutab. In tamar it is transparent dark ��)��"�� @7^ �� )�� 7�^ �� "almost engulfed by the swollen base. Seeds obovoid with acute apex and ��'�� " �� " �� E�� Y��"��wavy margin, extending a few millimeters below the apex.

*;��7*;)�7*;9�D

*F��0�B��;�' <

0'

37. Majnoon ن��5

OPA11 OPC10 OPB14

)�� ?"�>��?<��stage it is lemon yellow in colour and during rutab ripening process brings amber colour from the tip. In tamar stage it is amber coloured with broadly ��)��"��8�^��)�� :�^��'��"��$��"�<�7?��F��"�� ?"��E�� "�� Y�� "��wider, edges smooth, extending towards the tip.

*;��*;1��*;9�>

*H��0B��=��<

0(

38. Makhtomi ��

OP A04 OP A06 OP A05

��"��"��{�� ?"�D�:?<�@��'��tip during rutab. In tamar amber colored with thick, broadly wrinkled skin. )��"��@�^�� )�� @�^��'��"��" ��'��$��obovate, apiculate at apex, dirty white below the germpore, reddish brown ��"�<�7?��E�� "��Y��groove almost uniformly wider throughout, margin smooth, extending to few millimeters below the apex.

*;��>*;��@*;��7

*I��0��.��<�>?<

0&

39. Mareeah �� 5

OPA02 OPA11 OPB20

)�� /�� ?"�>��?2.5 cm. In beser stage lemon yellow in colour and during rutab ripening process brings amber colour from the tip. In tamar stage it is reddish brown ��"��{��)��"��@�^��)�� :�^��'��"��/��$��2.7 x 0.9 cm, acute at apex, brown coloured. Germpore above the middle, ��Y��"�?��

*;��<*;��*;9<�

*J��0��<

97

40. Maseeha ��5

OPA02 OPA11 OPB20

)�� )�� ?"�>�:?D�� yellow in colour and during rutab ripening process brings amber colour from the tip. In tamar stage it is reddish brown with broadly wrinkled skin. )�� " �� 8�^ �� )�� @�^��'��"��$�� "�<�@?��" �� ?"��E�� " �� Y�� ?"extending to a few millimeters below the apex.

*;��<*;��*;9<�

,(��0��@��<

98

41. Miniah� ��

OPA02 OPA11 OPB20

)�� ?" �>��?2.5 cm. In beser stage light yellow with more reddish towards base and during rutab ripening process brings amber colour from the tip. In tamar ��)��"��"��>�^��)�� @�^��'��"��$�� <�:?��<��"�� ?"��E�� " ��Y��"�?��mm below the apex.

*;��<*;��*;9<�

,)��0��<

99

42. Moneifi �%��5

OP C10 OP B13 OP A15

)�� "��{�" � �� ?"�>�>?<�F��In beser light yellow, turns to amber from the tip or sometimes from both ��"��)��"��8�^��'��)�� 7�^��the base, attached to the surface. Seeds ellipsoid, acute at apex, dirty white �� "��"�<�>?��F��E�� " �� Y�� " �� "extending to few millimeters below the apex.

*;1��*;9�D*;��7

,'��0��-��<

%$$

43. Mosaifah ��

OPC04 OPB13 OPA15

)��"��"�� ?"�>�>?<�@��"�� '��"��)��"��8�^�� )�� 7�^ �� " ��enclosed within the base. Seed oblong, acute at apex, silvery white below �� "��"�<�>?��:��E�� V��"��Y��"��towards the tip, edges smooth, extending to the acute tip.

*;1�>*;9�D*;��7

,*��0�� -��<

%$%

44. Mudawiyah �5او��

OPA7 OPB14 OPC10

)�� ?"�>�<?<�7��In beser stage light green turning to yellow during rutab ripening process brings reddish brown colour from the tip. In tamar stage it is reddish brown in colour with broadly wrinkled skin, which is almost adpressed to ��{��)��"��7�^��)�� D�^��'��"��$��"�<�7?��:��"� �� ?"��E�� " � �� Y�� "edges smooth, extending towards the tip.

*;�8*;9�>*;1��

,,��0��%��1� <

%$#

45. Muskani Ahmar +�� ا-�8�5

OPA02 OPA10 OPA12

)�� /�� ?"�<�>?<��H� ��apex, brings brown colour to the fruits. During tamar it is reddish brown �� " �� " �� )��"��8�^��)�� @7^��"�� V��$�� apex, brownish above and whitish below the germpore. Germpore a circular ��Y�� ?"��margin, extending towards the apex.

*;��<*;��*;��<

,@��0��.��0# &�$�?�<

%$3

46. Muskani Asfar � ا%9-�8�5

OPA02 OPA10 OPA12

)�� ?"�<�>?<��H� �� ?"brings brown colour to the fruits. During tamar it is brown in colour with ��"�� "��)��"��8�^��)�� @7^��"�� V��$�� ?"��whitish below the germpore. Germpore a circular pit little below the centre. Y��"��"�?��a few millimeters below the apex.

*;��<*;��*;��<

,F��0�� -A &�$�?�<

%$'

47. Mutuah اع;5

OPA10 OPA02 OPA11

)�� " �� ?"�>��?<�>�� H� �� In tamar they are uniformly more reddish brown. Skin broadly wrinkled. )��"��"��8�^��)�� >�^��"{��$��"��"�<��?��:��E�� "��Y�� " �� " �� below the tip.

*;��*;��<*;��

,H��0��B��C<

%$(

48. Nabtet Al-Atti � -�>� ا��>

OPA02 OPA11 OPA12

)�� ?"�>��?<�:cm. In beser stage lemon yellow and during rutab ripening process brings amber colour from the tip. In tamar stage it is amber coloured with broadly ��)��"��@�^��)�� :�^��'��"�� $�� "�<�8?��: ��" � �� ?"��E�� " ��Y��at both ends, extending towards the apex.

*;��<*;��*;��<

,I��#��>��&�>�$

%$&

��Nabtet Al-Awad� �� ا��اد

OPA02 OPA11 OPA12

)�� " �� ?"�>�<?D�7��ripening process brings amber colour from the tip. In tamar stage it is amber ��)��"��@�^�� )�� 7�^��'��"��$�� "�<�:?��Dcm, acute at apex, brown coloured. Germpore in the middle, prominent. Y��"�?��the apex.

*;��<*;��*;��<

,J��#��(��&�>�$

%$1

50. Nabtet Al-Hassan ا��ن �<�-

OPA10 OPA06 OPB14

��"�� ?"�>�7?D�<��In beser stage crimson red in colour and during rutab ripening process brings reddish brown colour from the tip. In tamar stage it is reddish brown ��)��"��@�^��)�� D�^��'��"��$��"�<�>?��"�� ?"��E�� " ��Y��wider, edges smooth, extending a few millimeters below the apex.

*;��*;��@*;9�>

@(��#��-��=��&�>�$

%$2

51. Nabtat Al-Jeeda ا��ا� �<�-

OPA02 OPA11 OPA12

)�� ?"�D��?2.5 cm. In beser stage greenish yellow and during rutab ripening process brings reddish brown colour from the tip. In tamar stage it is reddish ��)��"��7�^�� )�� 7�^��'��"��$�� F?��:cm, obtuse at apex, brown coloured. Germpore in the middle, prominent. Y��"�?�� ?�

*;��<*;��*;��<

@)��#��K�� 4�&�>�$

%$0

52. Nabtet Ali �� <�-

OPA07 OPA06 OPC10

)�� '��"��"�� ?" � >�< ? <�F �� turns reddish brown from the tip during rutab. In tamar reddish brown, ��)��"��8�^��)�� <7^��" ��base. Seeds obovoid or ellipsoid, apiculate at apex, dirty white throughout, � <�D ? ��F �� E�� Y�� narrow but deep, edges not smooth, extending to the tip.

*;��8*;��@*;1��

@'��#��&�>�$

%%$

53. Nabtet Al-Thuraiah �� -�>� ا�=

OPA10 OPA15 OPB13

)�� ?"�>�7?3.0 cm. In beser stage lemon yellow in colour and during rutab ripening process brings reddish brown colour from the tip. In tamar stage it is reddish ��)��"��>�^��)�� D7^��'��"��$�� '��"�<�>?��"��slightly apiculate at apex, dirty white throughout. Germpore in the middle, �� Y��"��"�?��towards the tip.

*;��*;��7*;9�D

@*��#��"��D�&�>�$

%%%

54. Nabtet Hamd �+� �<�-

OPC10 OPA10 OPA7

)�� ?"�D�>?<�@cm. In beser stage dark red in colour and during rutab ripening process brings reddish brown colour from the tip. In tamar stage it is reddish brown ��"�� {��)�� " �� 7�^ �� )�� " �� 7�^�� '��" ��$��"�<�<?��"�� ?"��E�� " �� Y�� wider at both ends, edges wavy, extending towards the tip.

*;1��*;��*;�8

@,��#��-.�� 0#&�>�$

%%#

55. Nabtet Hoshana �-�(� �<�-

OPA2 OPC5 OPC10

)�� ?" �D��?2.5 cm. In beser stage lemon yellow in colour and during rutab ripening process brings brown colour from the tip. In tamar stage it is reddish ��)��"��@�^�� )�� >�^�� '��"��$��"��7?��:��"�� ?"��E�� "�� Y��base, edges smooth, extending a few millimeters below the apex.

*;�<*;17*;1��

@@��#��-��$��#&�>�$

%%3

56. Nabtet ilib >�� <�-

OPC15 OPA10 OPA12

)�� /�� " �� ?"�D�8?<�7��"��"��)��"��:�^��)�� >�^��"{�� V��"��$��" ��base, dirty white below the germpore, light brown above, acute at apex, � <�> ? ��: �� E�� " �� Y�� uniformly wider, margin smooth, extending towards the tip.

*;1�7*;��*;��<

@F��#��#��E��&�>�$

%%'

57. Nabtet Matlaq ?�;5 �<�-

OPA12 OPC2 OPA2

)�� ?"�D�8?<�7cm. In beser stage it is crimson red and during rutab ripening process brings reddish brown colour from the tip. In tamar stage it is reddish brown in colour with broadly wrinkled skin, which is almost adpressed to ��{��)��"��@�^��)�� 7�^��'��"��$�� "�<�D?��:��"�� ?"��E�� "�� Y��"edges smooth, extending a few millimeters below the apex.

*;��<*;1<*;�<

@H��#��0��8�F�C<&�>�$

%%(

58. Nabtet Milfi �%�5 �<�-

OPA02 OPA11 OPB20

)�� ?"�7�<?<�:�� process brings reddish brown from the tip. In tamar stage it is amber ��)��"��77^��)�� :�^��'��"�� $�� " <�: ? ��F ��" �� ?"��E�� " ��Y��uniformly wider through out, extending to a few millimeters below the apex.

*;��<*;��*;9<�

@I��#��0��-�<&�>�$

%%&

59. Nabtet Mujalli ��5 �<�-

OPC5 OPC10 OPB14

)�� ?�� "�>��?<�@:��colour and during rutab ripening process brings brown colour from the tip. ��)��"��>�^��)�� D7^��'��"��$�� "�<�<?��Fcm, apiculate at apex, brown coloured throughout. Germpore below the ��"�� Y��"��"extending a few millimeters below the apex.

*;17*;1��*;9�>

@J��#��0�B��<&�>�$

%%1

60.Nabtet Mujaidel ل��5 �<�-

OPA1 OPA2 OPC2

)�� ?" � >�: ? <�:cm. In beser stage light red in colour and during rutab ripening process brings amber colour from the tip. In tamar stage it is amber coloured with �� {�� )�� "��@�^��)�� >�^��'��"��$��"�<�:?��cm, obtuse at apex, brown throughout. Germpore below the middle, not ��Y��"��"�?��few millimeters below the apex.

*;��*;�<*;1<

F(��#��0�B��; ��<&�>�$

%%2

61.Nabtet Naser 9�- �<�-

OPA4 OPB13 OPA2

)�� ?"�D�F?<�� ripening process brings reddish brown colour from the tip. In tamar stage � �� )�� " �� 8�^ �� )�� 8�^ �� '��" �� $�� "�<�>?��"�� ?"��E�� "�� Y��"edges wavy, extending a few millimeters below the apex.

*;�>*;9�D*;�<

F)��#��A�$&�>�$

%%0

62.Nabtet Rasheed ��(ر �<�-

OPB14 OPA2 OPA1

)��'�� ?"�D�7x 2.5 cm. In beser stage yellow in colour and during rutab ripening process brings amber colour from the tip. In tamar stage it is amber coloured with ��)��"��@�^��)�� D�^��'��"��base. Seeds elliptic, 2.0 x 0.9 cm, obtuse at apex, reddish brown throughout. E�� "�� Y��both ends, edges smooth, extending a few millimeters below the apex.

*;9�>*;�<*;��

F'��#��&�� %&�>�$

%#$

63. Nabtet-Saif ��

OPC10 OPA06 OPA01

)�� "��{��"� �?��"�D�@7?<�:7��"��from the tip and basal portions light orange. In tamar reddish brown, with ��)��"��8�^��)�� <7^��'��"��$�� '��"�� ?"�� "�<��?��F��E�� V��Y��length, edges wrinkled, extending towards the tip.

*;1��*;��@*;��

F*��#�� G��&�>�$

%#%

64.Nabtet Salma� !"# ��

OPA02 OPA11 OPB20

)�� ?"�>��?<�Dcm. In beser stage lemon yellow in colour and during rutab ripening process brings reddish brown from the tip. In tamar stage it is amber coloured ��)�� "��7�^�� )�� >�^ �� '��"��$��"�<�@?��"�� ?" �� E�� " �� Y��groove narrow, slightly wider at both ends , extending to a few millimeters below the apex.

*;��<*;��*;9<�

F,��#��.��H0��&�>�$

%##

65. Nabtet Sheikh @�( �<�-

OPB5 OPA2 OPC10

H��"�� ?"�>�D?D�7�� brings amber colour from the tip. In tamar it is amber coloured with smooth ��)��"��8�^��)��cap covering almost 40% of the fruit base, attached to the shallow base. $�� '��" � <�7 ? �� " �� ?" ��'��E�� " � �� Y�� " �� both ends, edges wavy, extending to the tip.

*;97*;�<*;1��

F@��#��I��&�>�$

%#3

66. Nabtet Sulthan ن�;�A �<�-

OPC10 OPC14 OPA15

)��"��{�� ?"�>��?D�<��yellow with rose tinge. During rutab amber colour starts from the tip. In �� "��)��"��8�^��'��)�� @7̂ ��fruit base, attached to the surface. Seeds oblong, apiculate at apex, silvery �� "��<��?��F��E�� Y��"��towards both ends, margins wrinkled, extending up to the tip.

*;1��*;1�>*;��7

FF��#��=�C��&�>�$

%#'

67. Nabtet Suwaid ��A �<�-

OPA6 OPA4 OPB13

)�� '��/�� ?"�>�7?<�7��beser stage light yellow in colour and during rutab ripening process brings amber colour from the tip. In tamar stage it is amber coloured with broadly ��)��"��@�^�� )�� @�^�� '��"��$�� '��"�<�:?��:��"�� ?"�� E�� " �� Y��groove shallow, uniformly wider, edges smooth, extending towards the tip.

*;�@*;�>*;9�D

FH��#�� &�>�$

%#(

68. Nabtet Turaiqui �8� B �<�-

OPA12 OPC2 OPC15

)�� ?"�D�7?3.3cm. In beser stage red coloured and during rutab ripening process brings amber colour from the tip. In tamar stage it is reddish brown with broadly ��"��{��)��"��@�^��)�� 8�^��"��$�� '��"�<�<?��:��"obtuse at apex, ash coloured throughout. Germpore below the middle, not ��Y��"��"�?��towards the tip.

*;��<*;1<*;1�7

FI��#��"��8��?��J&�>�$

%#&

69. Nabtet Zamil C5زا �<�-

OPB14 OPC05 OPA01

)�� ?"�D�F?<�:��)��"��@7^ �� )�� @�^ �� "�� V��" ��$��'��"�<�@?��E�� V��Y��but more wider at the apex, margins smooth, extending a few millimeters below the apex.

*;9�>*;1�7*;��

FJ��#��L.��K<�L&�>�$

%#1

70. Om Al-Khashab >0Eام ا�

OP C10 OP A15 OP A06

)�� "��{�" � ��"�>�:?<�@�� '��" �� tamar stage very transparent amber, with wrinkled, thin skin, intact with {��)��"��@�^��)�� @�^��"�� $�� '��"� ��"�<�:?��"��only towards the base, reddish brown. Germpore very clear, deep, in the ��Y�� "�?��

*;1��*;��7*;��@

H(��6.��#��E7M�&N

%#2

71. Qarawiyah و�� &

OPA02 OPA11 OPB20

)�� ?"�D�:?2.2 cm. In beser stage light yellow with a reddish tinge and during rutab ripening process brings amber colour from the tip. In tamar stage it is �� )�� "��7�^��)�� >�^��'��"��$�� "�<�>?��"�� ?"��'��E�� " ��Y��"�?��millimeters below the apex.

*;��<*;��*;9<�

H)��=��%��1��.

%#0

72. Qathara رة�$%

OPA02 OPA11 OPB20

)�� ?"�D�<?<�7��stage light yellow and during rutab ripening process brings reddish colour from the tip. In tamar stage it is reddish brown coloured with broadly �� )�� " �� 8�^ �� )�� "�� D�^�� '��"��$�� "��:?��F��"�� ?"�� E�� " �� Y�� "slightly wider at both ends , extending to a few millimeters below the apex.

*;��<*;��*;9<�

H'��=��%�C.

%3$

73. Rabeeah �� ر

OPA07 OPA10 OPB02

)�� '��"�� ?"�D��?<�7�� '��"��" �� " �� )�� " �� 7�^ �� '�� )�� @�^ �� 'base, attached to the shallowly cordate base or partially inserted to the incurved base. Seeds oblong, obtuse or acute at apex, dirty white below the �� "��"�<�<?��E�� Y��"��smooth, extending towards the tip.

*;��8*;��*;9�<

H*��&#��"%

%3%

74. Reziz رز��ي

OPA06 OPA12 OPA01

)�� "��{�� ?"�D�@x 2.4 cm. In beser light red in colour. During rutab turns amber from the tip and basal portions become more red. In tamar amber coloured, with ��" ��)��"��"��@7^�� '��)�� 8�^�� "�� $�� " �� ?" �� "��"�<�<?��F��E�� "��Y��throughout, margin smooth, extending towards the tip.

*;��@*;��<*;��

H,��&�$�$��L%

%3#

75. Roshoudiyah د�� ر)

OPF05 OPC10 OPB02

)��"��"�� ?"�>�7?<�@��In beser light yellow in colour and turns to amber color from the tip during rutab. In tamar reddish brown in colour with silvery white towards the base. $��)��"��@�^��'��)�� D�^��"��the fruit base. Seeds oblong, obtuse at apex, rough, dirty white below the �� "��"�<�7?��F��E�� "��Y��both ends, extending towards the tip.

*;)�7*;1��*;9�<

H@��&��%��(��%

%33

76. Rothana Al-Madeenah ��+ا� �-�Gرو

OPA02 OPA11 OPB20

)�� ?"�>��?2.5 cm. In beser stage yellow with reddish tinge, during rutab ripening process brings amber colour from the tip. In tamar stage it is reddish brown ��)��"��@�^��)�� 7�^��'��"��$�� "��:?��"� �� ?"��E�� " ��Y�� "slightly wider at base, extending to a few millimeters below the apex.

*;��<*;��*;9<�

HF��&��0��$�O1%

%3'

77. Rothanah �-�Gرو

OPA06 OPC10 OPB13

)�� "�� "�� ?"�D�:x 2.7 cm. In beser lemon yellow in colour and during rutab amber coloured �� '��$��)��"��8�^��)�� D�^��" ��'��$�� "�� ?"��<�<?��E�� "��Y��"��"��"�?��millimeters below the apex.

*;��@*;1��*;9�D

HH��&��$�O1%

%3(

78. Rumanah �� رو

OPA02 OPA11 OPB20

)�� ?"�D�<?3.0 cm. In beser stage greenish yellow with reddish tinge. In tamar stage ��)��"��@�^��)�� :�^��'��"��$��"�<��?��Dcm, obtuse at apex, brown coloured. Germpore in the middle, prominent. Y�� " �� " �?�� millimeters below the apex.

*;��<*;��*;9<�

HI��&�.��$�<1%

%3&

79. Sabbakah آ��A

OPC10 OPF05 OPA07

)��"��{�� ?"�>�<?<�:��"�� '��]��" �� " �� )�� " ��8�^��'��)�� 7�^��'��"attached to the surface of the base or partially inserted to the incurved base. Seeds oblong or obovoid, obtuse or acute at apex, dirty white throughout, �<�<?��F��E�� V��Y��"�� "��"�?��towards the tip.

*;1��*;)�7*;��8

��HJ��##��8��

%31

80. Safra Sulaiman ن�+��A اء %9

OPA02 OPA11 OPB20

)�� ?" � D�< ?2.2 cm. In beser stage yellow in colour and during rutab ripening process brings amber colour from the tip. In tamar stage it is amber coloured with ��)��"��8�^��)�� 8�^��'��"��$�� "�<�<?��"�� ?"��E�� " ��Y�� "slightly wider at both ends , extending towards the tip.

*;��<*;��*;9<�

I(�� .��=�0�� /��-A

%32

81. Safri ي %9

OPA12 OPA01 OPC05

)��"��{�� ?"�>�>?<�<��stage pale yellow in colour turning to dark brown from the tip during rutab. ��"��)��"��"��@�^��)�� :�^�� " {�� $�� " � <�� ? ��7 ��" � �� ?" ��"light brown. Germpore is represented by a small pit little above the middle. Y��"��"�?��millimeters below the apex.

*;��<*;��*;1�7

I)�� -A

%30

82. Shaqra اء $(

OPB13 OPB16 OPA06

)��'��"��/��"��"��"�� ?" � >�< ? D�� many minute red dots. During rutab more reddish at the base and tip turns brown. Irregular bands of browning is one of the characters to distinguish ��'��"��"��)��"��"��"��>�^��'��)�� DD^�� '��$�� '��"�<�7?��"�� " ��E�� "��"��Y��groove moderately broad, more wider near the base, extending to the tip.

*;9�D*;9�@*;��@

I'��8��/��,�

%'$

83.Shamshoola ��0+(

��OPA10 OPA2 OPC10

)��"�� ?"�7�<?<�@��In beser stage greenish yellow in colour and during rutab ripening process brings golden brown colour from the tip. In tamar stage it is reddish ��)��"��@�^�� )�� 7�^�� '��"��$��"�<�@?��"� ��apex, brown coloured throughout. Germpore above the middle, prominent. Y��"��"�?��below the apex.

*;��*;�<*;1��

I*��.��70�

%'%

84. Shehel ء��

OPA07 OPC10 OPA15

)�� " �� /��" ��/�� "� �� ?"�<�F?<�� turning to light pink during rutab. In tamar stage dark brown with broadly �� )�� " �� 87^ �� )�� 8�^��'��"��fruit base. Seeds oblong, obtuse or apiculate at apex, silvery white below �� "��"��>?��>��E�� Y��"��"�?��to the tip

*;��8*;1��*;��7

I,��/2P�

%'#

85. Sheshi �0�(

OPA15 OPA12 OPA06

)��'�� ?"�D�@?<�<��E��*�� $��)��@7^��)�� 77^��"{�� V��$�� " ��"�<�<?��@��E�� "��Y��canal broader at both ends, constricted at the middle.

*;��7*;��<*;��@

I@��7��

%'3

86. Sillej H�A

OPC04 OPB13 OPA15

)��"��{��/��"� �?��"�D�@?��F��"��from the apex during rutab. In tamar reddish brown, with broadly wrinkled ��)��"��@�^��)�� F�^��"��$��'��"�� ?"��"��"�<�@?��8��E�� V��"��Y��"��"�?��

*;1�>*;9�D*;��7

IF��B��Q��

%''

87. Sugei ��$9

OPA11 OPB13 OPA02

)��"��{��"�� ?"�>�<x 2.1 cm. In beser yellow, turns to amber from the tip. In tamar transparent ��'�� " �� " �� )��"��"��@�^��'��)��'�� D�^��"��$��"�� " �� " �� ?" �<�<?��F��E�� "��Y��shallow, wider towards the base, margin smooth, extending towards the tip.

*;��*;9�D*;��<

IH��!��,A

%'(

88. Sugei Iraqi � ا&� ��$9

OPA11 OPA02 OPB13

)��"��"�� ?"�D��?��@�� " �� '��]��"��)��"��"��@7^��'�� )��'�� F�^ �� " �� $��obovoid, dirty white below the germpore, light brown above, obtuse at � �?"��@?��>��E�� "��Y��shallow, uniformly wider, margin smooth, extending towards the tip.

*;��*;��<*;9�D

II��!��8��.��&��,A

%'&

89. Sukkary Asfar ي 8A

OPA02 OPA04 OPC10

)�� " �� " � �? ��" � >�� ? D�� golden yellow turns to reddish brown from the tip during rutab. In tamar �� )�� " �� 77^�� '��)�� @�^��"��'��$��broadly ellipsoid, obtuse at apex, silvery white below, reddish brown above, �<��?��D ��E�� " �� Y��groove narrow but deep, edges smooth, extending towards the tip.

*;��<*;��>*;1��

IJ��%�� ?�

%'1

90. Sukkary Hamrah اء +� �� 8A

OPA15 OPA07 OPC10

)�� " �� " � �? ��" � >�@ ? D�< �� yellowish red turned to reddish brown from the tip during rutab. In tamar �� )�� " �� @�^�� )�� >�^��"��'��$��broadly elliptic or oblong, apiculate at apex, silvery white below, reddish ��"�<�7?��<��E�� Y��groove narrow but deep, edges smooth, extending towards the tip.

*;��7*;��8*;1��

J(��%�-.��/��0#&��?�

%'2

91. Sultana �-�;�A

OPA02 OPA11 OPB20

H�� "�� ?"�>��?D�<�� ]�� reddish brown colour from the tip. In tamar stage it is golden brown ��)��"��8�^��)�� >�^��'��"��$�� "�<�7?��"�� ?"��E�� " ��Y�� "slightly wider at both ends , extending to a few millimeters below the tip.

*;��<*;��*;9<�

J)��$�C��

%'0

92. Thawi ذاوي

OPA15 OPA02 OPA10

)�� " �� /��" � �?��"�>�D?<��"��brown from the apex during rutab. In tamar dark brown, with wrinkled ��)��"��8�^��)�� covering 60% of the base, attached to the surface. Seeds oblong, obtuse or �� ?"��"��"�<�<?��>��E�� "��Y��groove narrow, uniformly wider, edges smooth, extending towards the tip.

*;��7*;��<*;��

J'��"��1�)

%($

93. Um Aduhain Iأم ا��ه

OPC05 OPA01 OPA11

)�� "�� /�� ?"�<�7?��8��E�� )��"��"��7�^��)�� covering 90% of the base, attached to the surface. Seeds oblong with obtuse �� ?" ��" �<�< ? �� E�� Y��"��"�?��

*;1�7*;��*;��

J*��>.��R� �&N

%(%

94 . Um Al-Hamam م ا��+�مأ

OPA04 OPA07 OPA09

)��'�� ?"�D�:?<�7�� process brings amber colour from the tip. In tamar stage it is reddish brown �� )�� " ��8�^��)�� :�^��'��"��$��"�<�7?��:��"� ��at apex, light brown coloured throughout. Germpore an elliptic pit in the ��Y��"��"�?��millimeters below the apex.

*;��>*;��8*;��F

J,��>.��-..��N�0��&N

%(#

95. Um Al-zahb >هKأم ا�

OPA2

)�� ?"�7��x 2.0 cm. In beser stage it is golden yellow in colour and during rutab ripening process brings amber colour from the tip. In tamar stage it is ��)�� "��7�^��)�� :�^��'��"��$�� '��"�D��?��8��"obtuse at apex, brown coloured. Germpore above the middle, a sunken ��Y��"��"��"extending towards the tip.

*;�<

J@��>.��$�#��E��&N

%(3

96. Um-Khobar ام آ��ر

OPA06 OPB13 OPC10

� �� " �� " �� " ��/��"�� ?"�>�D?D�D��E��"��to amber colour from the tip during rutab. In tamar amber coloured, with �� )�� " �� @7^ �� )�� >�^ �� fruit. Seeds broadly ellipsoid, rough, obtuse at apex, dirty white below �� " � <�7 ? ��< �� E�� " �� Y�� "�� " �?��towards the apex.

*;��@*;9�D*;1��

��JF��>.��#��%��8&N

%('

97. Usailah ��

OPA01 OPA11 OPC05

)��'��"�� ?"�D�:?<��cm. Greenish yellow in beser turning to pale yellow in rutab. In tamar amber coloured throughout with smooth skin without much wrinkling. )��" ��@�^�� )�� :�^��" ��V��$�� '��"�� "�� ?"��@?��@��E�� Y��almost uniformly wider throughout, margins smooth, extending a few millimeters below the apex.

*;��*;��*;1�7

JH��>��

%((

98. Wannanah �-�-و

OPA06 OPA11 OPB13

� �� " ��" �� /�� ?"�>�F?D�>�� with many minute red dots, during rutab ripening from the tip brings black colour. Tamar black in colour, with broadly wrinkled, easily removable ��)��"��'��"��@7^��'��)��'�� "��D�^��"�� {�� $�� '��"�<�@?1.1 cm, obtuse at apex, smooth, dirty white below the germpore, reddish �� E�� " V�� Y��groove wider near the base, edges irregularly wrinkled, extending to a few millimeters below the tip.

*;��@*;��*;9�D

��JI��M��$�$1

%(&

99. Zahaqa �&ز��

OPC5 OPB14 OPC10

)��/�� ?"�>�7?D��cm. In beser stage it is reddish yellow turning to dark red, during rutab ripening process brings golden brown colour from the tip. In tamar stage it ��)��"��>�^��'��)�� >�^��'base, attached to cordate base. Seeds obovoid with two prominent wings, �� ?" ��'�� E�� "�� Y��"��"extending towards the tip.

*;17*;9�>*;1��

JJ��L�8��.��L

%(1

100. Zahaya زه��

OPB13 OPA2 OPA15

)�� ?"�D�7?<�:cm. In beser stage lemon yellow in colour and during rutab ripening process brings amber colour from the tip. In tamar stage it is golden brown in colour �� )�� " �� 8�^ �� )�� @�^��'��"��$��"��:?��F��"�� ?"��E�� "�� Y��broader at both ends, edges smooth, extending towards the tip.

*;9�D*;�<*;��7

)((��L�%��L

%(2

Glossary of technical terms used in the description of Fruits

and Seeds

Shape of Fruits

Globose: Length and diameter of the fruit is almost same e.g. Barhy,

Rothana

Ovoid: The broadest part is towards the base e.g. Sukkary

Oblong: Almost uniform diameter for a length, giving cylindrical shape;

two to three times as thick e.g. Madjhool.

%(0

Linear-Oblong: Length is two to four times more than the diameter giving

a narrow cylindrical shape e.g. Deglet Noor

Ellipsiod: Largest diameter in the middle of the length e.g. Reziz

Rhomboid: Largest diameter is little above the middle, then sharply

pointing towards apex e.g. Sillej.

%&$

Base of the fruit

Cordate Shallowly Truncate Oblique

Cordate

Tip of the fruit

Rounded Obtuse

Shape of seeds

Ovoid Obovoid Ovoid-oblong Ellipsoid-oblong Ellipsoid

Tip of seeds

Obtuse Acute Apiculate

%&%

Variations of ventral canal

Margins smooth Margins wavy

Broader at base Broader at apex Broader at both ends

Extending towards tip. Extending a few millimeters to tip.

162

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172

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173

Appendix I. List of some Date palm Cultivars known in Saudi Arabia and their popular locatio.

Cultivar Arabic Name Popular Locations

Adhlah �� QassimAdhuhaibah �� QassimAediyah �� QassimAjwah �� MadinahAl-Asree �� Northern regionAl-Haizah �� Northern regionAl-Seateah �� Northern regionAnbarah �� MadinahAshraisi �� IntroducedBareem �! QassimBarhy �"�! Central regionBarni �#�! Northern ,MadinahBuyedha ��! Northern regionDeglat Noor $�#%��&' IntroducedDeglat Obaid ��%��&' QassimDuhaibeeah ��( QassimFaaizeah ��) QassimFaqah � *+,� Northern regionE�� - Central regionHamra Rashood '��$ .��/" Northern regionHaqeeyah ��+" Qassim regionHasawi �0��" IntoducedHilali �1� Central regionHilwah ��" Central regionHilwah Al-Jouf 2�3�%��" Northern regionHoshana �#�� QassimKasabah �!��4 Central regionKhalas 514 Eastern regionKhasaba Al-Quwaiah ��+�%�!��4 QassimKhashab �!�64 Central regionKhudri ��4 Central regionKhunaizi ��4 Eastern regionKoweriah ��7 Qassim

174


Labana �#�� QassimMadaq 8 9� Northern regionMadjhool :�& ; IntroducedMajnoon <��; QassimMakhtomi �;�=>; Central region Mareeah ��; Northern regionMaseeha ��?��; Northern regionMiniah ��; Qassim&�� ,��; Central regionMosaifah �,��; Central regionMudawiyah ��0� ; QassimMuskani Ahmar �/"�%�#�>�; Central regionMuskani Asfar �,@�%�#�>�; Central regionMutuah A��B; Central regionNabtet Al-Atti �=��%�=�# AlkharjNabtet Al-Awad '��%�=�# Northern regionNabtet Al-Hassan <��%�=�# QassimNabtet Al- Jeeda � �3�%�=�# QassimNabtet Ali ��%�=�# QassimNabtet Al-Thuraiah ��C�%�=�# QassimNabtet Hamd /"%�=�# QassimNabtet Hoshana �#��"%�=�# QassimNabtet ilib D��%�=�# Qassim,CentralNabtet Matlaq E�B;%�=�# Qassim#��&�� ,�;%�=�# Northern regionNabtet Mujalli ��;%�=�# QassimNabtet Mujaidel : ��;%�=�# QassimNabtet Naser �@�#%�=�# QassimNabtet Rasheed ��$%�=�# QassimNabtet Saif F��%�=�# Central regionNabtet Salma G/��%�=�# Northern regionNabtet Sheikh H��%�=�# QassimNabtet Sulthan <�B��%�=�# Central regionNabtet Suwaid ��%�=�# QassimNabtet Turaiqui �>��I%�=�# Qassim

175


Nabtet Zamil J;�K%�=�# QassimOm Al-Khashab D6L�%MR QassimQarawiyah ��0��- QassimQathara �$�B- QassimRabeeah ��!$ MadinahReziz ��K$ Eastern regionRoshoudiyah ��'��$ QassimRothanah �#�N0$ MadinahRothanah Al-Madeena �� 9�%�#�N0$ MadinahRumanah �#�;0$ QassimSabbakah �7�� Eastern regionSafra Sulaiman <�/�� .��,@ QassimSafri ��,@ Bishah, CentralShaqra .��+� Qassim, CentralShamshoola ��6/� QassimShehel .1O� QassimSheshi �6�� Eastern regionSillej P�� QassimSugei ��+@ Central regionSugei Iraqui �-��%��+@ IntroducedSukkary Asfar ��>� QassimSukkary Hamra .��/"%��>� QassimSultana �#�B�� QassimThawi �0�( Eastern regionUm Aduhain Q� �%MR IntroducedUm Al-Hamam M�/��%MR QassimUm Al-Zahb D��%MR Central regionUm Khobar $��7%MR QassimUsailah �� QassimWannanah �#�#0 QassimZahaqa �-��K QassimZahaya ��K Qassim

176

Bold numbers given above the strips indicate primer numbers. Numbers

given below the strips refer to cultivars. For cultivar names refer pages

Appendix-II. RAPD profiles of Date Palms produced by OPERON primers

OPA

01 01 01 01 01 01 01

OPA

01 01 01 01 02 02 02

74 81 93 97 02 03 05

28 30 33 60 62 63 69

196

177

OPA

02 02 02 02 02 02 02

20 21 22 24 26 29 32

OPA

02 02 02 02 02 02 02

06 07 09 13 15 18 19

RAPD profiles of Date Palms produced by OPERON primers contd.


given below the strips refer to cultivars. For cultivar names refer pages 196

178

OPA

02 02 02 02 02 02 02

34 35 39 40 41 45 46

OPA

02 02 02 02 02 02 02

47 48 49 51 55 57 58




179

OPA

02 02

60 61 62 64 65 71 72

OPA

02 02 02

76 78 80 83 87 88 89




180

OPA

02 02 02 02 04 04 04

91 92 95 100 38 61 67

OPA

04 04 05 06 06 06 06

89 94 38 04 11 23 25




181

31 38 50 52 63 67 70 74

OPA

06 06 06 06 06 06 06 06

OPA

06 06 06 06 06 07 07 07

RAPD profiles of Date palms produced by OPERON primers contd.

77 82 85 96 98 01 12 16




182


OPA

07 07 07 07 07 07 07 07 07

28 44 52 54 73 79 84 90

OPA

09 09 10 10 10 10 10 10

10 94 08 09 19 45 46 47



192 193

196

10 94 08 09 19 45 46 47

183


OPA

10 10 10 10 10 10 10 11

50 53 54 56 73 83 92 03

05 06 07 13 14 15 18 19

OPA

11 11 11 11 11 11 11 11



184


20 21 22 24 29 33 32

OPA

11 11 11 11 11 11 11

OPA

11 11 11 11 11 11 11



34 35 37 39 40 41 47

196

185


48 49 51 58 64 71 72

OPA

11 11 11 11 11 11 11

76 78 80 87 88 91 93 97

OPA

11 11 11 11 11 11 11 11



186


OPA

11 12 12 12 12 12 12

98 12 18 23 45 46 49

OPA

12 12 12 12 12 12 15

56 57 68 74 81 85 17



187


27 33 36 42 43 53 66 70

OPA

15 15 15 15 15 15 15 15

OPA

15 15 15 15 15 15

84 85 86 90 92 100



Marker 100 bp

196

188

OPB

13 13 13 13 14 14 14 16

02 11 16 17 25 36 42 43

OPB

01 02 02 05 05 08 12 13

01 73 75 10 65 10 08 01




189


OPB

13 13 13 13 13 13 13 13 13

53 61 67 77 82 86 87 88 96

OPB

13 13 14 14 14 14 14 14

98 100 27 30 37 44 50 59 62



190

OPB

14 14 16 20 20 20 20 20


6 27 82 03 05 06 07 13

OPB

20 20 20 20 20 20 20 20

15 20 21 22 24 26 29 32



191

OPB

20 20 20 20 20 20 20 20

OPB

20 20 20 20 20 Marker 100 bp

34 35 39 40 41 58 64 71

72 76 78 80 91




192

OPC

02 02 02 04 04 05 05 05 05

OPC

05 05 05 05 05 05 05 05

57 60 68 43 86 02 09 16 17

27 55 59 69 81 93 97 99

RAPD profiles of Date Palm s produced by OPERON primers contd.



193

OPC

10 10 10 10 10 10 10 10

RAPD profiles of Date Palm s produced by OPERON primers contd.

04 11 12 14 23 25 28 31

OPC

10 10 10 10 10 10 10 10

37 42 52 54 55 59 63 65



194

OPC

10 10 10 10 10 10 10 10

66 70 75 77 79 83 84 89




OPC

10 10 10 10 14 14 14 Marker 100 bp

90 96 99 44 01 04 66

196

195

OPC OPF

15 15 Marker 100 bp 05 05 05 05

56 68 31 36 75 79

RAPD profiles of Date Palms produced by OPERON primers.



196

Cultivar names and numbers

1.Adhlah 2.Adhuhaibah 3.Aediyah, 4.Ajwah

5.Al-Asree 6.Al-Haizah 7.Al-Seateah 8.Anbarah

9.Ashraisi 10.Bareem 11.Barhy 12.Barni

13.Buyedha 14.DeglatNoor 15.DeglatObaid 16.Duhaibeeah

17.Faaizeah 18.Faqah �F�E�� 20.Hamra Rashood

21.Haqeeyah 22.Hasawi 23.Hilali 24.Hilwa Al-Jouf

25.Hilwah 26.Hoshana 27.Kasabah 28.Khalas

29.Khasab Al-Quwaiah

30.Khashab 31.Khudri 32.Khunaizi

33.Koweriah 34.Labana 35.Madaq 36.Madjhool

37.Majnoon 38.Makhtomi 39.Mareeah 40.Maseeha

41.Miniah ><�&�� 43.Mosaifah 44.Mudawiyah

45.Muskani Ahmar 46.Muskani Asfar 47.Mutuah 48.Nabtet Al-Atti

49.Nabtet Al-Awad 50.Nabtet Al-Hassan 51.Nabtet Al- Jeeda 52.Nabtet Ali

53.Nabtet Al-Thuraiah 54.Nabtet Hamd 55.Nabtet Hoshana 56.Nabtet ilib

57.Nabtet Matlaq 7:�#��&�� 59.Nabtet Mujalli 60.Nabtet Mujaidel

61.Nabtet Naser 62.Nabtet Rasheed 63.Nabtet Saif 64.Nabtet Salma

65.Nabtet Sheikh 66.Nabtet Sulthan 67.Nabtet Suwaid 68.Nabtet Turaiqui

69.Nabtet Zamil 70.Om Al-khashab 71.Qarawiyah 72.Qathara

73.Rabeeah 74.Reziz 75.Roshoudiyah 76.Rothana Al-Madeena

77.Rothanah 78.Rumanah 79.Sabakah 80.Safra Sulaiman

81.Safri 82.Shaqra 83.Shamshoola 84.Shehel

85.Sheshi 86.Sillej 87.Sugei Iraqi 88.Sugei

89.Sukkary Asfar 90.Sukkary Hamra 91.Sultana 92.Thawee

93.Um-Aduhain 94. Um Al-Hamam 95.Um Al-zahb 96.Um-Khobar

97.Usailah 98.Wannanah 99.Zahaqa 100.Zahaya

197

Adhlah Adhuhaibah Aediyah Ajwah

Al-Asree Al-Haizah Al-Seateah Anbarah

Ashraisi Bareem Barhy Barni

Buyedha Deglet Noor Deglat Obaid Duhaibeeah

Appendix III. Fruit shape of date palm cultivars

198

Faaizeiah Faqah Graini Hamra Rashood

Haqeeyah Hasawi Hilali Hilwah Al-Jouf

Hilwa Hoshana Kasabah Khalas

Khasab Al-Quwaiah Khashab Khudri Khunaizi


199

Koweriah Labanah Madaq Madjhool

Majnoon Maktomi Mareeah Maseeha

Mineiah Moneifi Mosaifah Mudawiyah

Muskani Ahmar Muskani Asfar Mutuah N.Al-Atti


200

N.Al-Awad N.Al-Hassan N.Al-Jeeda N.Ali

N.Al-Thuraiah Nabtet Hamd Nabtet Hoshana Nabtet ilib

N.Matlaq N.Milfi N.Mujelli N.Mujaidel

N.Nasser N. Rasheed N.Saif N.Salma


201

198

N.Sheikh N.Sulthan N.Suwaid N.Turaiqi

Nabtet Zamil Om Al-Khashab Qarawiyah Qathara

Rabeeah Reziz Roshoudiah R. Al-Madeenah

Rothana Rumanah Sabakah Safra Sulaiman


202

Safri Shaqra Shamshoola Shehel

Sheshi Sillej Sugei Iraqi Sugei

Sukkary Asfar Sukkary Hamrah Sultana Thawee

Um– Aduhain Um Al-Hamam Um Al-Zahb Um Khobar


203

Usailah Wannanah Zahagha Zahaya

Fruit shape of date palm cultivars

204

Appendix IV Date Palm cultivars and OPERON primers used

1. Adhlah �� OPA07 OPB13 OPC14

2. Adhahabiah �� OPA02 OPC05 OPB13

3. Aediyah �� OPA02 OPA11 OPB20

4. Ajwah �� OPA6 OPC10 OPC14

5 .Al-Asree �� OPA02 OPA11 OPB20

6. Al-Haizah �� OPA02 OPA11 OPB20

7. Al-Seateah �� OPA02 OPA11 OPB20

8. Anbarah �� OPA10 OPB12

9. Ashraisi ��R OPA02 OPA10 OPC05

10. Bareem �! OPB08 OPB05 OPA09

11. Barhy �"�! OPA06 OPC10 OPB13

12. Barni �#�! OPA12 OPC10 OPA07

13. Buyedha ��! OPA02 OPA11 OPB20

14. Deglat Noor $�#%��&' OPA11 OPB01 OPC10

15. Deglat Obaid ��%��&' OPA02 OPA11 OPB20

16. Duhaibeeah ��( OPC05 OPA07 OPB13

17. Faizeah ��) OPA15 OPB13 OPC05

18. Faqah � *+,� OPA02 OPA11 OPA12

�F�E�� - OPA11 OPA02 OPA10

20. Hamra Rashood '��$ .��/" OPA02 OPA11 OPB20

21. Haqeeyah ��+" OPA02 OPA11 OPB20

22. Hasawi �0��" OPA02 OPA11 OPB20

23. Hilali �1� OPA12 OPA06 OPC10

24. Hilwah Al-Jouf 2�3�%��" OPA02 OPA11 OPB20

25. Hilwah ��" OPA06 OPC10 OPB13

26. Hoshana �#�� OPA02 OPA11 OPB20

205

27. Khasabah �!��4 OPB14 OPA15 OPC05

28. Khalas 514 OPA07 OPA01 OPC10

29. Khasab Al-Quwaiah �!��4 ��+�

OPA02 OPA11 OPB20

30. Khashabah �!�64 OPB14 OPA01 OPC05

31. Khudri ��4 OPA06 OPF05 OPC10

32. Khunaizi ��4 OPA02 OPA11 OPB20

33. Koweriah ��7 OPA11 OPA15 OPA01

34. Labanah �#�� OPA02 OPA11 OPB20

35. Madaq 8 ; OPA02 OPA11 OPB20

36. Madjhool :�& ; OPA15 OPF05 OPB13

37. Majnoon <��; OPA11 OPC10 OPB14

38. Maktomi �;�=>; OPA04 OPA06 OPA05

39. Marieah ��; OPA02 OPA11 OPB20

40. Maseeha �?��; OPA02 OPA11 OPB20

41. Miniah ��; OPA02 OPA11 OPB20

><�&�� ,��; OPC10 OPB13 OPA15

43. Mosaifah �,��; OPC04 OPB13 OPA15

44. Mudawiyah ��0� ; OPA07 OPB14 OPC10

45. Muskani Ahmar �/"R%�#�>�; OPA02 OPA10 OPA12

46 Muskani Asfar �,@R%�#�>�; OPA02 OPA10 OPA12

47. Mutwah A��B; OPA10 OPA02 OPA11

48. Nabtet Al-Atti �=��%�=�# OPA02 OPA11 OPA12

49. Nabtet Al-Awad '��%�=�# OPA02 OPA11 OPA12

50. Nabtet Al-Hassan <��%�=�# OPA10 OPA06 OPB14

51. Nabtet Al- Jeeda � �3�%�=�# OPA02 OPA11 OPA12

52. Nabtet Ali ��%�=�# OPA07 OPA06 OPC10

206

53. Nabtet Al-Thuraiah ��C�%�=�# OPA10 OPA15 OPB13

54. Nabtet Hamd /"%�=�# OPC10 OPA7 OPA10

55. Nabtet Hoshana �#��"%�=�# OPA02 OPC05 OPC10

56. Nabtet ilib D��%�=�# OPC15 OPA10 OPA12

57. Nabtet Mutlaq E�B;%�=�# OPA12 OPC02 OPA02

7:�#��&�� ,�;%�=�# OPA02 OPA11 OPB20

59. Nabtet Mujalli ��;%�=�# OPC05 OPC10 OPB14

60. Nabtet Mujaidel : ��;%�=�# OPA01 OPA02 OPC02

61. Nabtet Nasser �@�#%�=�# OPA04 OPB13 OPA02

62. Nabtet Rasheed ��$%�=�# OPB14 OPA02 OPA01

63. Nabtet-Saif F��%�=�# OPC10 OPA06 OPA01

64. Nabtet Salma G/��%�=�# OPA02 OPA11 OPB20

65. Nabtet Sheikh H��%�=�# OPB05 OPA02 OPC10

66. Nabtet-Sultan <�B��%�=�# OPC10 OPC14 OPA15

67. Nabtet Suwaid ��%�=�# OPA06 OPA04 OPB13

68. Nabtet Turaiqi �>��I%�=�# OPA12 OPC02 OPC15

69. Nabtet Zamil J;�K%�=�# OPB14 OPC05 OPA01

70. Om Al-khashab D6L�%MR OPC10 OPA15 OPA06

71. Qarawiyah ��0��- OPA02 OPA11 OPB20

72. Qatarah �$�B- OPA02 OPA11 OPB20

73. Rabeeah ��!$ OPA07 OPA10 OPB02

74. Reziz ��K$ OPA06 OPA12 OPA01

75. Roshudiyah ��'��$ OPF05 OPC10 OPB02

76. Rothana Al-Madeena �� 9�%�#�N0$ OPA02 OPA11 OPB20

77. Rothanah �#�N0$ OPA06 OPC10 OPB13

78. Rumanah �#�;$ OPA02 OPA11 OPB20

79. Sabakah �7�� OPC10 OPF05 OPA07

207

80. Safra Sulaiman <�/�� .��,@ OPA02 OPA11 OPB20

81. Safri ��,@ OPA12 OPA01 OPC05

82. Shaqra .��+� OPB13 OPB16 OPA06

83. Shamshoola ��6/� OPA10 OPA02 OPC10

84. Shehel .1O� OPA07 OPC10 OPA15

85. Sheshi �6�� OPA15 OPA12 OPA06

86. Sillej P�� OPC04 OPB13 OPA15

87. Sugei ��+@ OPA11 OPB13 OPA02

88. Sugei Iraqi �-��%��+@ OPA11 OPA02 OPB13

89. Sukkary Asfar ��>� OPA02 OPA04 OPC10

90. Sukkary-Hamrah .��/"%��>� OPA15 OPA07 OPC10

91. Sultana �#�B�� OPA02 OPA11 OPB20

92. Thawi �0�( OPA15 OPA02 OPA10

93. Um-Aduhain Q� �%MR OPC05 OPA01 OPA11

94. Um Al-Hamam M�/��%MR OPA04 OPA07 OP09

95. Um Al-Zahb D��%MR OPA02

96. Um-Khobar $��7%MR OPA06 OPB13 OPC10

97. Usailah �� OPA01 OPA11 OPC05

98. Wannanah �#�#0 OPA06 OPA11 OPB13

99. Zahaqa �-��K OPC05 OPB14 OPC10

100. Zahaya ��K OPB13 OPA02 OPA15

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