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Accepted Manuscript
Title: Precision breeding of grapevine (Vitis vinifera L.) forimproved traits
Author: Dennis J. Gray T. Li Zhijian A. Dhekney Sadanand
PII: S0168-9452(14)00075-2DOI: http://dx.doi.org/doi:10.1016/j.plantsci.2014.03.023Reference: PSL 8963
To appear in: Plant Science
Received date: 31-1-2014Revised date: 24-3-2014Accepted date: 31-3-2014
Please cite this article as: D.J. Gray, T.L. Zhijian, A.D. Sadanand, Precisionbreeding of grapevine (Vitis vinifera L.) for improved traits, Plant Science (2014),http://dx.doi.org/10.1016/j.plantsci.2014.03.023
This is a PDF file of an unedited manuscript that has been accepted for publication.As a service to our customers we are providing this early version of the manuscript.The manuscript will undergo copyediting, typesetting, and review of the resulting proofbefore it is published in its final form. Please note that during the production processerrors may be discovered which could affect the content, and all legal disclaimers thatapply to the journal pertain.
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Title: Precision breeding of grapevine (Vitis vinifera L.) for improved traits
Authors: Gray, Dennis J.1 *, Zhijian T. Li1, Sadanand A. Dhekney2
Address:
1. Grape Biotechnology Core Laboratory
Mid-Florida Research and Education Center
University of Florida/IFAS
2725 Binion Road
Apopka, FL 32703-8504
USA
2. Department of Plant Sciences
Sheridan Research and Extension Center
University of Wyoming
663 Wyarno Road
Sheridan, WY 82801
USA
* Corresponding author
Email: djg@ ufl.edu
Phone: (407)41--6946
Fax: (407)814-6186
Date of manuscript receipt:
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Abstract
This review provides an overview of recent technological advancements that enable precision
breeding to genetically improve elite cultivars of grapevine (Vitis vinifera L.). Precision
breeding, previously termed “cisgenic” or “intragenic” genetic improvement, necessitates a
better understanding and use of genomic resources now becoming accessible. Although it is now
a relatively simple task to identify genetic elements and genes from numerous “omics” databases,
the control of major agronomic and enological traits often involves the currently unknown
participation of many genes and regulatory machineries. In addition, genetic evolution has left
numerous vestigial genes and sequences without tangible functions. Thus, it is critical to
functionally test each of these genetic entities to determine their real-world functionality or
contribution to trait attributes. Towards this goal, several diverse techniques now are in place,
including cell culture systems to allow efficient plant regeneration, advanced gene insertion
techniques, and, very recently, resources for genomic analyses. Currently, these techniques are
being used for high-throughput expression analysis of a wide range of grapevine-derived
promoters and disease-related genes. It is envisioned that future research efforts will be extended
to the study of promoters and genes functioning to enhance other important traits, such as fruit
quality and vigor.
Keywords: Grapevine, Vitis vinifera, cisgenics, intragenics, genetic engineering, disease
resistance, anthocyanin marker, expression analysis
Introduction
Genetic improvement of grapevine (Vitis vinifera L.) is one of the critical needs to enhance crop
productivity and foster profitable wine industries throughout the world [1]. Although numerous
unique hybrids were developed over the years, genetic improvement of elite hybrids, the
mainstays of worldwide production, is deemed to be largely unsuccessful, especially in areas
ravaged by severe disease/pest infestations and/or that require extensive chemical control to
maintain. For example, the bacterial pathogen that incites Pierce’s disease, Xylella fastidiosa, has
no proven method of durable control other than well-known genetic resistance and the
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unsustainable mass spraying of pesticides to inhibit insect vectors, despite well over 50 million
dollars expended, apparently unsuccessfully, by Federal and State governments since 1999 [2].
However, genetic resistance (tolerance) among native Vitis species was identified by 1958 [3].
The practical use of genetic resistance was subsequently confirmed through hybridization with V.
vinifera cultivars to instill durable and near complete control of the pathogen [4-6]. Particularly
urgent now is the introduction of specific traits for durable tolerance to diseases, pests, and
abiotic stresses, while maintaining the essential quality of highly desired elite cultivars [7,8].
However, it is not possible to rely on conventional breeding to improve elite cultivars so that
they can adapt to the production environment, while still meeting the strict expectations of
oenophiles [9,10]. Conventional breeding cannot practically be used to add desired disease
resistance traits to elite cultivars of Vitis because of a long lifecycle, severe inbreeding
depression, and complex genetic control of enological qualities [11]. A majority of the relatively
few elite grape cultivars currently cultivated worldwide are centuries-old and maintained
primarily through a stringently managed system of vegetative propagation [12,13]. However,
elite cultivars often lack other desirable traits such as durable disease and pest resistance that are
demanded by today's intensive agricultural conditions. As such, producers rely on frequent use of
pesticides to control diseases, particularly in areas of higher humidity; this is in spite of
increasing public outcry against such practices and resulting environmental issues [14]. To
mitigate such increasingly crucial agricultural and health concerns, modern biotechnology has
advanced to the point where it is now possible to expedite genetic improvement of existing elite
cultivars via precision breeding [7,15]. This review is intended to provide an overview of current
technological advancement, particularly genomic analyses, for the development of resistance to
biotic and abiotic stresses, as well as other traits, via precision breeding of elite cultivars.
1. Advances in gene insertion technology
The methodology to insert specific genes into plants without inducing significant genetic
rearrangement has been in development for over thirty years. Such technology is particularly
attractive for perennial crops like grapevine that have severe genetic obstacles to conventional
breeding and require multi-year evaluation for durability of desired traits due to their long
lifecycle and longevity. In order to provide a reliable working platform for genetic testing,
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efficient cell regeneration systems were developed [16-20]. An increasing number of scientists
used such regeneration systems to document insertion of single or few genes into grapevine [11].
The precise methods of gene insertion employed either biolistic particle bombardment [21, 22] or,
more commonly, Agrobacterium-mediated gene insertion into regenerative cells, followed by
plant recovery [11, 23-25]. Both methods have been meticulously refined and optimized over the
years and are now capable of producing hundreds of genetically modified plants. The majority of
plants modified via the Agrobacterium approach tended to harbor low-gene copy number and
defined gene insertion [24, 26]. A large number of modified plants is critical for identification of
lines with a desirable level of gene expression and performance to meet overall improvement
objectives [27]. The need to test many plant lines, as is the norm with conventional breeding, is
critical in order to select outstanding individuals.
During the early years of technology development aimed towards precision breeding, it
was necessary to test genetic elements from non-plant hosts, including animals and bacteria, due
to the relatively primitive state of biotechnology. This approach was generally referred to as
“transgenic” modification. This early discovery research was absolutely essential so that cell
culture and gene insertion methods could be refined to the point of being fully functional [28].
Subsequently, as pointed out by Rommens [29], many non-plant genes and promoters with
known functionality were utilized to display the technological marvel of biotechnology. This
approach to crop improvement inevitably invited arguments and ongoing worries as to whether
such plants with foreign genes and promoters were healthy, represented an environmental threat
and/or were otherwise dangerous in some way. The use of foreign genetic material in food crops
including grapevine remains to be the pivot of social and ethical public debate [7,29,30].
Along with the refinement of cell culture and gene insertion methods, the final
technology required to enable precision breeding was completion of the genomic sequence of V.
vinifera ‘Pinot Noir’ in 2007 and the relatively new-found and simplified availability of
computational analysis [31,32]. It is now possible to identify grapevine genes, along with their
associated genetic elements, isolate them, from sexually-compatible disease-resistant relatives,
and insert them into elite cultivars. While still in its infancy, the application of precision breeding
to grapevine improvement is well underway, with a number of modified plants in approved field
trials and more on the way [1, 33-35].
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Application of precision breeding is the logical and biologically conservative extension
of conventional breeding, made possible only by long-term scientific research. Studies have
suggested that application of precision breeding will boost consumer's confidence and
acceptance of improved crop products as well [36-38].
As we continue to refine precision breeding, more remains to be discovered. We require a
better understanding of genome structure organization and sequence/function associations. It is
estimated that grape genome contains over 30,400 genes, which is more than that found in most
animals [39]. Many important agronomic traits are controlled by a complex network of
regulatory sequences and factors and often influenced by dynamic sequence alterations, such as
gene duplication, transposon insertion and loss- or gain-of-function mutations [40].
Environmental factors also play an important role in gene expression and interaction [41]. Thus,
the actual function and sustainability of any isolated genetic material, whether a gene or a
promoter, has to be confirmed within its intricate genetic milieu and then rigorously tested over a
prolonged time in the environment; this is the fundamental way to determine durable
structure/function relationships. Although we are making rapid progress in sequence analysis and
functional annotation of the grapevine genome [31,32,42-44], progress in functional
characterization of important genes/promoters is slow, creating a significant obstacle to the
practical utilization of the genetic resources already available. Since precision breeding is
biologically consistent with conventionally bred crops and, indeed, the entire plant lifecycle, it
constitutes a technical refinement of existing breeding methodologies. The solution to
accelerating the crucial functional analyses needed to both test the technology and produce
improved cultivars is to not regulate evaluation of precision bred grapevine, so that individual
lines can be tested in quantity and in grower fields, as has always been the manner for
conventionally bred crops. As with all crop breeding, many progeny must be evaluated to find
the desired individual(s) expressing the desired traits.
2. Development of a grape gene-based marker system
2.1 Traditional marker genes
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Marker genes are utilized to facilitate identification and selection of engineered cells; which is
akin to finding a needle in a haystack. Such genes may provide growth advantages for modified
cells to outgrow the large number of non-modified cells and/or signify the successful integration
of new genetic elements [45]. Presently, the markers in use are not derived from the grapevine
genome. Among these genetic marker genes, some confer resistance/tolerance to antibiotics or
cytotoxic chemicals such as herbicides. Others encode selectable metabolic enzymes such as
visible green fluorescence protein (GFP) and the assayable β-glucuronidase (GUS) enzyme [30,
46, 47]. These marker genes were also successfully tested in grapevine [21, 25, 48]. Thus far, the
majority of previous genetically modified grape plants were generated primarily by using the
NPTII gene for kanamycin-based selection and GFP for visual selection; this allowed for the
identification and selection of modified cells, which typically are present in very low numbers.
Although current regulatory guidelines recognize NPTII, among other microbe-derived
marker genes used in modified plants, to be safe, they are no longer needed and their use
continues to remain an issue causing polarized public debate and governmental regulation [45].
Recently, a co-transformation system was tested to achieve marker-free genetically
modified grapevine [26]. In this system, two strains of Agrobacterium were used to treat target
explants: one strain harboring a binary vector containing the target gene expression unit only,
whereas the other strain contained a binary vector with a dual gene codA/nptII selection marker
expression unit. By using a brief exposure to kanamycin, modified cells with the target gene are
encouraged to grow along with cells containing the dual gene cassette. Upon applying negative
selection based on the codA function, the codA/nptII-containing cells cease to grow and the only
survival is from target gene-containing cells. Although the efficiency of plant recovery needs
further improvement, this system offers a working example of marker gene elimination for
perennial plants such as grapevine.
2.2 Grapevine gene-derived anthocyanin marker system
A grapevine gene, VvMybA1 isolated from ‘Merlot’ was recently tested as a new visible reporter
marker for non-destructive and quantitative analysis of gene expression [49, 50]. VvMybA1
belongs to the MYB transcription factor superfamily functioning in the grapevine anthocyanin
biosynthesis pathway. It activates the expression of UDP-glucose flavonoid 3-O-
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glucosyltransferase (UFGT), an enzyme catalyzing the final reaction in the modification and
stabilization of anthocyanin [51]. The ectopic expression of VvMybA1 results in production of
anthocyanin, an easily discernible coloration in otherwise non-pigmented cells/tissues.
VvMybA1 can serve as visual reporter to identify modified cells and subsequent
regenerants, which was first demonstrated by the recovery of stably transformed grapevine
without relying on the use of NPTII expression and kanamycin selection [49]. However, the
VvMybA1-expressing grapevines ('Thompson Seedless') that were recovered lacked vigor and did
not persist in the field environment. These plants produced intensely pigmented, curly and highly
brittle leaves as a result of the over-accumulation of non-recyclable anthocyanin in cell vacuoles
[49]. Such undesirable phenotypic consequences of VvMybA1 as a reporter marker now are
being mitigated by employing promoters with tissue-specific and/or developmentally regulated
expression capability to avoid unwanted hyper-accumulation [52]. Recently, VvMybA1 was
placed under control of a late embryogenesis abundant protein Dc3 gene promoter of carrot
(Daucus carota) and shown to be capable of rendering pigment production exclusively in
embryos but not in vegetative tissues of citrus [53,54]. The tissue-specific expression strategy
may provide a solution to utilize VvMybA1 as an indicator marker. Current endeavors in the
discovery and mining of grapevine promoters should take such findings into consideration. An
effective plant-based marker system eliminates reliance on microbe-derived genes and/or
complicated and inefficient gene elimination technologies for the development of genetically
modified grapevine [46].
In addition to its potential as a visible selectable marker, VvMybA1 currently is used for
real-time monitoring of transgene expression at the whole plant level. Quite often the expression
of previously-used marker genes varied greatly between plants and throughout the entire course
of plant development due to factors associated with gene integration and environmental
interactions. Using multiple modified plant lines with a consistent level of gene expression,
facilitates the accurate assessment of trait analyses. Reporter markers such as GUS and GFP are
widely utilized to monitor transgene expression [55, 56]. However, there has been no suitable
marker for expression analysis at the whole plant level that does not require special equipment,
detection reagents or destructive assays, and that can be readily adapted to high-throughput
experiments involving selection of hundreds of genetically modified grapevines.
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Anthocyanin is a self-revealing pigment that can be easily discerned with the naked eye
due to its vibrant pink-to-red color. It also remains relatively stable in vivo and accumulates in
insoluble anthocyanic vacuolar inclusions (AVIs) [57]. As illustrated previously, pigmented
inflorescences as a result of VvMybA1 expression were consistently observed in modified
tobacco [49,50]. This unique utility demonstrated that VvMybA1 provides a highly efficient and
reliable monitoring system for gene activity in grapevine. Currently VvMybA1 has been
incorporated into transformation vector platforms controlled by a constitutively active grapevine-
derived ubiquitin gene promoter for high throughput analysis of genes and promoters [50].
3. Promoter mining and functional analysis
3.1 A non-destructive anthocyanin-based promoter assay system
Promoters play an indispensable role in the regulatory process of gene expression [58]. The
employment of appropriate native promoters for precision breeding dictates the final outcome of
trait development and durability. In recent years, extensive analysis of the genome and
transcriptome uncovered a plethora of functional genes. For instance, the sequence identity of at
least 18,725 grapevine genes have been confirmed [44]. The functional annotation of these genes
also provided a significant opportunity to evaluate their promoters, which direct gene expression
in response to developmental, environmental and regulatory network cues. For better utilization,
it is critical to acquire a thorough understanding of the important features of these promoters
including their sequences, activation capacity, regulatory interaction and stability throughout
plant development. However, over the years, progress in functional analysis of promoters of
grapevine has lagged behind other academically or economically important plant species such as
Arabidopsis and rice. Some major reasons for such stagnation include the limited ability to
initiate and maintain a large quantity of suitable explants and the lack of reporter systems for
efficient expression analysis. Currently, only a few labs worldwide are capable of transforming
grapevine, but many are still facing major obstacles in efforts to expand the efficacy to the level
comparable to that in other model plant species. Furthermore, use of non-grapevine-derived
reporter markers like GFP and GUS are hampered by requirement of a large quantity of explant
materials and by laborious destructive assay procedures.
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In order to expedite progress, the nondestructive reporter marker VvMybA1 in
combination with an efficient Clonase cloning system (Life Technologies, CA, USA)
significantly facilitates characterization of promoters from grapevine [49]. The amount of
anthocyanin accumulation in grapevine or tobacco explants due to VvMybA1 expression
correlates with the expression activity of a controlling promoter. Such correlation is readily
determined using a non-destructive, quantitative color histogram analysis method in both
transient and stable expression materials [49]. The expression reporting capability of VvMybA1
conforms to the common criteria for previously used quantitative reporter markers [45,59]. The
VvMybA1-based expression assay system offers an efficient and versatile alternative for high-
throughput promoter analysis in grapevine and other plants.
3.2 Constitutively active promoters
Early studies inserted useful genes into grapevine under control of constitutive viral promoters to
provide high levels of gene expression at the whole explant/plant level [18,23,55,56]. These
promoters were used to drive the expression of either marker genes for identification of
genetically modified plants or of target genes for trait development, mostly aimed at increasing
disease resistance in modified plants. To eliminate the need for such constitutive viral promoters,
a number of putatively constitutive ubiquitin gene promoters were identified and their expression
capabilities characterized using the anthocyanin-based assay method [50]. The study revealed
that among 7 VvUb promoters analyzed, many were inactive and appeared to be older in
evolutionary lineage, with a higher level of sequence abnormality, whereas two highly active
promoters, VvUb6 and VvUb7, were identified that possessed fewer nucleotide deletions or
substitutions between cultivars and contained more cis-acting elements, which are commonly
involved in up-regulation of gene expression. These latter promoters supported an activity level
equivalent to or higher than that of the commonly-used double-enhanced CaMV 35S promoter in
both transient and stable expression analyses [50]. Such constitutively active grapevine
promoters provide a key tool needed to add durable traits via precision breeding technology
3.3 Tissue-specific, inducible and developmentally regulated promoters
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Tissue-specific promoters activate gene expression only in particular types of cells, tissues, or
organs, whereas inducible and developmentally regulated promoters are activated in response to
specific cues and at certain stages of plant development, respectively. The development of a
novel trait using precision breeding necessitates the availability of plant regulated promoters. For
instance, engineering a fruit quality trait requires the use of a fruit-active promoter such as the V.
vinifera thaumatin-like protein (VvTL-1) gene promoter [60]; likewise, improvement of root
growth requires root-specific promoters. Thus far, only an extremely limited number of regulated
promoters in grapevine are known. They include a seed-specific 2S albumin gene VvAlb1
promoter, two alcohol dehydrogenase gene promoters; a stilbene synthase gene promoter and a
number of PR1 gene promoters [50,52,61-63]. The lack of characterized regulated promoters
limits the deployment of grapevine regulatory elements via precision breeding and inevitably
attracts the use of non-grapevine materials that are not biologically consistent with the Vitis
lifecycle [64]. Therefore, the discovery and functional verification of candidate grapevine
promoters is crucial to further progress in precision breeding [65-68].
4. Resistance/tolerance genes to biotic and abiotic stresses
4.1 Antifungal genes
The development of highly reproducible genetic engineering protocols for a wide array of
grapevine cultivars and rootstocks now allows identification and screening of grapevine-derived
genes for introducing desirable traits, particularly disease resistance. A number of field studies
for screening precision-bred grapevines are currently in advanced stages of testing prior to
commercialization [see 69 for a complete list].
Grapevines are affected by a number of fungal pathogens worldwide and require
intensive fungicide spray regimes for sustainable crop production [70,71]. Major improvement
efforts have been directed towards enhancing fungal-disease resistance in table and wine grape
cultivars [69]. A number of pathogenesis-related (PR) proteins were screened for their response
to fungal pathogen infection. Genetically modified ‘Neo Muscat’ and ‘Pusa Seedless’
grapevines constitutively expressing rice chitinase genes exhibited enhanced resistance to
anthracnose and powdery mildew [72,73]. However, no resistance to powdery mildew was
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observed in ‘Seyval Blanc’ plants expressing barley chitinase genes [74]. Enhanced resistance to
Eutypa lata was observed in ‘Richter 110’ grapevines that constitutively expressed a Vigna
radiata eutypine detoxyfing gene (Vr-ERE), which converts eutypine toxin produced by the
pathogen to non-toxic eutypinol [75]. Stilbene synthase genes encoding resveratrol were isolated
from several Vitis species and engineered for constitutive expression to improve fungal
resistance [76, 77]. A VvTL-1 gene previously reported to inhibit Elsinoe ampelina spore
germination and hyphal growth was constitutively expressed in ‘Thompson Seedless’ grapevines
[35, 78]. Enhanced resistance to foliar fungal diseases and decreased incidence of sour bunch rot
in berries was observed in greenhouse and field tests. Constitutive expression of a V. vinifera
WRKY1 (VvWRKY1) transcription factor gene in ‘41B’ rootstock plantlets resulted in activation
of regulatory genes in the jasmonic acid pathway and upregulation of several defense related
proteins. A reduction in downy mildew symptoms caused by Plasmopora viticola was observed
on in vitro-derived genetically modified plant leaves compared to the controls, when inoculated
under similar conditions [79]. Other non-grapevine derived genes such as lytic peptides encoding
magainin and polygalactouranase inhibiting proteins (PGIP) were demonstrated to improve
fungal disease resistance [80,81].
4.2 Antibacterial genes
Significant efforts have been directed towards improving grapevine resistance to bacterial crown
gall disease (Agrobacterium vitis) and Pierce’s disease (PD) (Xylella fastidiosa). A number of
non-plant antimicrobial peptides from various sources were tested for their in vitro efficacy
against A. vitis and X. fastidiosa prior to functional analyses [82, 83]. Genetically modified
grapevines expressing the animal-derived lytic peptide, magainin, and truncated Agrobacterium
virE2 protein, exhibited decreased crown gall symptoms caused by A. vitis [81,84]. Other lytic
peptides such as cecropin, mellitin and their hybrid derivatives, LIMA1 and LIMA 2, were
inserted into elite table and wine grape cultivars [85-89]. Lytic peptides were detected in such
genetically modified grapevines using ELISA, and enhanced PD resistance was observed in
repeated greenhouse trials and field tests for several years [69]. A chimeric peptide to
incorporate bacterial resistance was developed by fusing a pear-derived bacterial cell surface
recognition domain with a cecropin-derived lytic domain [90]. A significant reduction in
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bacterial colonization and leaf scorching symptoms associated with PD were observed in
modified ‘Thompson Seedless’ and ‘Chardonnay’ grapevines in the greenhouse environment,
however resistance in the field was not reported.
The possibility of imparting PD resistance to unmodified scions grafted on genetically
modified rootstocks expressing lytic peptide genes also was studied [91]. Non-modified
‘Cabernet Sauvignon’ scions grafted onto modified ‘Thompson Seedless’ plants expressing an
animal-based synthetic lytic peptide were used as an experimental rootstock [92]. Lytic peptide
could be detected in xylem sap of unmodified scions at levels similar to that of genetically
modified rootstocks. In other studies, a non-grapevine PGIP protein could be detected in xylem
sap of unmodified scions grafted onto modified ‘Thompson Seedless’ and ‘Chardonnay’ vines
constitutively expressing PGIP [80]. Factors including protein size that can be transmitted from a
modified rootstock to a grafted unmodified scion via the xylem and its threshold concentration
necessary to impart disease resistance in grafted vines are being evaluated [93]. Conferring PD
resistance using a mobile rootstock-derived anti-bacterial peptide would eliminate the need for
creating genetically modified versions of multiple scion cultivars.
4.3 Antiviral genes
Virus resistance was obtained using the strategies of parasite derived resistance and RNA
interference [94,95]. The coat protein gene of several viral pathogens including Arabis mosaic
virus (ArMV), Grapevine fanleaf virus (GFLV), Grapevine chrome mosaic virus (GCMV),
Grapevine virus A and B (GVA and GVB) were expressed in modified grapevines [96-98].
Unmodified scions grafted onto modified rootstocks expressing GFLV CP exhibited no visual
disease symptoms after 3 years of natural infection in two vineyard sites [99]. No viral
recombination between modified and native GFLV isolates was observed in field tests, thus
demonstrating the safety of this approach. In other studies, an inverted repeat construct and
artificial microRNAs (amiRNA) were inserted into grapevine plants to evaluate GFLV resistance
using RNA interference [100, 101].
4.4 Abiotic stress tolerance genes
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Phenotypic plasticity may cause the same genotype to exhibit significant variability in fruit yield
and quality in different environmental conditions [102]. The availability of the sequenced
grapevine genome combined with high-throughput expression profiling technologies such as
microarrays, differential display and RNA sequencing now makes it possible to analyze gene
expression in several Vitis species under varying environmental conditions. Transcriptome
analysis was successfully applied to identify genes involved in vegetative and reproductive
growth and to study vine response to abiotic and biotic stress factors. It has also was proposed to
be an alternative to reference genome sequencing for studying variability that might exist among
cultivars with respect to enological characteristics [103].
Transcriptome analysis of grapevine tissues at various developmental stages revealed
significant differences in gene expression between actively growing, green/vegetative tissues and
mature woody tissues [104]. Differential gene expression was observed during tissue maturation
as a result of coactivation of pathways that were not expressed in actively growing tissues. Such
transcriptome reprogramming during maturation has been specifically observed in woody plants.
Transcriptome analysis of berry tissues during various stages of development and ripening has
provided a significant amount of information on the expression of transcription factors and genes
involved in the production of organic acids, tannins and other secondary metabolites [105].
Drought, salinity and temperature fluctuations adversely affect grapevine production
worldwide. These stresses reduce crop yield and quality, although irrigation management
strategies may be used to concentrate pigments and flavor of wine grapes and improve enological
qualities [106]. Response to abiotic stress primarily occurs through altered physiological
processes, which ultimately affects vegetative and reproductive growth patterns [107]. Grapevine
species exhibit significant differences in transcriptome and protein patterns under conditions of
abiotic stress; such information may be useful to elucidate underlying differences in phenotypic
response and ultimately improve performance under adverse growing environments.
Microarray analyses of salt and water stressed ‘Cabernet Sauvignon’ grapevines
demonstrated that more than 2000 genes were differentially expressed, and expression was
influenced by both drought and ABA [108]. Significant differences as well as common attributes
were observed in gene response to varying stress factors. These included transcription factors,
genes involved in signal transduction and carbohydrate metabolism, which may ultimately
contribute to enhanced abiotic stress tolerance [109]. Water deficit imposed by drought appeared
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to have a more severe effect than that imposed from salinity. Differences in protein expression
were observed between V. vinifera cultivars Chardonnay and Cabernet Sauvignon exposed to
drought and salinity stress. Decrease in growth parameters were correlated with corresponding
reductions in the amounts of proteins involved in photosynthesis [110].
A number of cold-inducible transcription factors recently were isolated from grapevines
and shown to act as master switches for stress-induced activation of several genes [67,111,112].
Transcriptome analysis of V. amurensis and V. vinifera ‘Hamburg Muscat’ grapevines indicated
large differences when vines were exposed to cold-stress [113]. A higher number of unidentified
sequences were obtained in cold-hardy V. amurensis when compared with the reference genome,
possibly due to the large phylogenetic distance between the two species.
Results of genetic engineering of grapevine to improve abiotic stress tolerance and
qualitative traits are just emerging. For instance, modified grapevines expressing a Medicago
sativa ferritin gene and Arabidopsis CBF1 transcription factor were shown to exhibit improved
abiotic stress tolerance [114,115]. Enhanced freezing tolerance was observed in Vitis
interspecific hybrid ‘Freedom’ that constitutively expressed a V. vinifera CBF4 transcription
factor [116]. Genetically engineered grapevines with improved fecundity and reduced berry
browning currently are being evaluated [117,118]. Nevertheless, with the tremendous amount of
information being accumulated through genome mining and expression analysis, more critical
genes/promoters will be revealed and become available for use in grapevine improvement.
4.5 Precision bred plants under field testing
The majority of previous attempts to increase stress resistance in grapevine employed non-grape
genes or promoters. However, in ongoing research, a number of grapevine-derived genetic
elements, including several pathogenesis-related genes were isolated from disease resistant,
sexually-compatible V. vinifera hybrids and plants overexpressing these genes were placed under
field conditions [1,119]. These plants contain genes encoding the PR1 variants [119], VvTL1
(PR5) [35], VvAlb1 [52], homologues of VvAMP1 and VvAMP2/defensin [120] and an
orthologue of Snakin-1 [121]. It is expected that results from the long-term, real world tests will
enhance understanding of gene function and expand our ability to engineer resistant grapevine
using only genetic materials from sexually-compatible grapevines.
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Conclusion
Significant advancements in cell culture, gene discovery and gene insertion technologies were
only recently merged to fully enable precision breeding for the genetic improvement of
grapevine. It should be noted that the results of precision breeding are fully in sync with the
developmental biology of grapevine, but provide a significantly more efficient and predictable
method of genetic improvement compared to that of conventional breeding. With precision
breeding, only genetic elements from grapevine are used, but certain key obstacles, including
inbreeding depression (resulting in the inability to “self” desirable lines), that stifle improvement
via conventional breeding are completely overcome. The results obtained by precision breeding
are more predictable than that of conventional breeding, lowering the risk of unintended
outcomes. With precision breeding, a major goal is to create new versions of elite cultivars that
not only maintain their desirable traits, but are able to be managed with less-to-no chemical
intervention. Such precise modification cannot be obtained through conventional breeding
within any practical timeframe. Currently, prototype plants harboring putative grapevine
resistance genes and promoters are in the field to test for trait expression. Plants containing only
genetic elements from grapevine will begin to be planted for testing within the next year.
However, more widespread and robust evaluations, as is the norm for conventional breeding,
must occur to confirm the utility of cultivars produced by precision breeding.
Acknowledgements
This research was supported in part by the Florida Agricultural Experiment Station and grants
from the Florida Department of Agriculture and Consumer Services’ Viticulture Trust Fund and
the USDA/NIFA Specialty Crops Research Initiative.
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