Cell Reproduction Chapter 19
Welcome message from author
This document is posted to help you gain knowledge. Please leave a comment to let me know what you think about it! Share it to your friends and learn new things together.
Transcript
Cell Reproduction
Chapter 19
Understanding Cell Division
• What instructions are necessary for inheritance?
• How are those instructions duplicated for distribution into daughter cells?
• By what mechanisms are instructions parceled out to daughter cells?
Reproduction
• Parents produce a new generation of cells or multicelled individuals like themselves
• Parents must provide daughter cells with hereditary instructions, encoded in DNA, and enough metabolic machinery to start up their own operation
Eukaryotic Cell Division
• Mitosis, division of cytoplasm
– Body growth and tissue repair
• Meiosis, division of cytoplasm
– Formation of gametes, sexual reproduction
Chromosome
• A DNA molecule & attached proteins
• Duplicated in preparation for mitosis
one chromosome (unduplicated)
one chromosome (duplicated)
Chromosome Number
• Sum total of chromosomes in a cell
• Somatic cells– Chromosome number is diploid (2n)
– Two of each type of chromosome
• Gametes– Chromosome number is haploid (n)
– One of each chromosome type
Human Chromosome Number
• Diploid chromosome number (n) = 46
• Two sets of 23 chromosomes each– One set from father– One set from mother
• Mitosis produces cells with 46 chromosomes--two of each type
Cell Cycle
• Cycle starts when a new cell forms
• During cycle, cell increases in mass and duplicates its chromosomes
• Cycle ends when the new cell divides
Interphase
• Usually longest part of the cycle
• Cell increases in mass
• Number of cytoplasmic components
doubles
• DNA is duplicated
Stages of Interphase
• G1 – Interval or gap after cell division
• S– Time of DNA synthesis (replication)
• G2– Interval or gap after DNA replication
HeLa Cells
• Line of human cancer cells that can be grown in culture
• Descendants of tumor cells from a woman named Henrietta Lacks
• Lacks died at 31, but her cells continue to live and divide in labs around the world
Mitosis
• Period of nuclear division
• Usually followed by cytoplasmic division
• Four stages:Prophase
Metaphase
Anaphase
Telophase
Stages of Mitosis
Prophase
Metaphase
Anaphase
Telophase
Early Prophase - Mitosis Begins
Duplicated chromosomes begin to condense
Late Prophase
• New microtubules are assembled
• One centriole pair is moved toward opposite pole of spindle
• Nuclear envelope starts to break up
Transition to Metaphase
• Spindle forms
• Spindle microtubules become attached to the two sister chromatids of each chromosome
Metaphase
• All chromosomes are lined up at the spindle equator
• Chromosomes are maximally condensed
Anaphase
• Sister chromatids of each chromosome are pulled apart
• Once separated, each chromatid is a chromosome
Telophase
• Chromosomes decondense
• Two nuclear membranes form, one around each set of unduplicated chromosomes
Results of Mitosis
• Two daughter nuclei
• Each with same chromosome number as parent cell
• Chromosomes in unduplicated form
Cytoplasmic Division
• Usually occurs between late anaphase
and end of telophase
Effects of Irradiation
• Ionizing radiation– May break apart chromosomes, alter
genes
• Large doses destroy cells
• Small doses over long time less damaging
• Medical X rays, radiation therapy
Irradiated Food
• Foods irradiated to kill microorganisms, prolong shelf life
• Not radioactive
• No evidence it is a health risk
• Critics worry about selecting for radiation-resistant strains, changes in food composition
Control of the Cycle
• Once S begins, the cycle automatically
runs through G2 and mitosis
• The cycle has a built-in molecular brake
in G1
• Cancer involves a loss of control over
the cycle, malfunction of the “brakes”
Stopping the Cycle
• Some cells normally stop in interphase
– Neurons in human brain
– Arrested cells do not divide
• Adverse conditions can stop cycle
– Nutrient-deprived amoebas get stuck in interphase
Organization of Chromosomes
DNA and proteinsarranged as cylindrical fiber
DNA
histone
one nucleosome
The Spindle Apparatus
• Consists of two distinct sets of
microtubules
– Each set extends from one of the cell poles
– Two sets overlap at spindle equator
• Moves chromosomes during mitosis
Sexual Reproduction
• Chromosomes are duplicated in germ cells
• Germ cells undergo meiosis and cytoplasmic division
• Cellular descendants of germ cells become gametes
• Gametes meet at fertilization
Gamete Formation
• Gametes are sex cells (sperm, eggs)
• Arise from germ cells
testes
ovaries
Meiosis: Two Divisions
• Two consecutive nuclear divisions
– Meiosis I
– Meiosis II
• DNA is not duplicated between divisions
• Four haploid nuclei form
Meiosis I
Each homologue in the cell pairs with its partner,
then the partners separate
Meiosis II
• The two sister chromatids of each duplicated chromosome are separated from each other
one chromosome (duplicated)
two chromosomes (unduplicated)
Spermatogenesis
GrowthMitosis I,
Cytoplasmic divisionMeiosis II,
Cytoplasmic division
spermatids (haploid)
secondary spermatocytes
(haploid)
primary spermatocyte
(diploid)
spermato-gonium
(diploid male- reproductive
cell)
Oogenesis
Growth Mitosis I,Cytoplasmic division
Meiosis II,Cytoplasmic division
ovum (haploid)
primary oocyte (diploid)
oogonium (diploid
reproductive cell) secondary
oocyte (haploid)
first polar body
(haploid)
three polar bodies
(haploid)
Stages of Meiosis
Meiosis I
• Prophase I
• Metaphase I
• Anaphase I
• Telophase I
Meiosis II
• Prophase II
• Metaphase II
• Anaphase II
• Telophase II
Meiosis I - Stages
Prophase I Metaphase I Anaphase I Telophase I
Meiosis II - Stages
Prophase II Metaphase II Anaphase II Telophase II
Crossing Over
•Each chromosome
becomes zippered to its
homologue
•All four chromatids are
closely aligned
•Nonsister chromosomes
exchange segments
Effect of Crossing Over
• After crossing over, each chromosome
contains both maternal and parental
segments
• Creates new allele combinations in
offspring
Random Alignment
• During transition between prophase I and metaphase I, microtubules from spindle poles attach to kinetochores of chromosomes
• Initial contacts between microtubules and chromosomes are random
Random Alignment
• Either the maternal or paternal member of a homologous pair can end up at either pole
• The chromosomes in a gamete are a mix of chromosomes from the two parents
Possible Chromosome Combinations
As a result of random alignment, the number of possible combinations of
chromosomes in a gamete is:
2n
(n is number of chromosome types)
Possible Chromosome
Combinations
or
or
or
1 2 3
Fertilization
• Male and female gametes unite and
nuclei fuse
• Fusion of two haploid nuclei produces
diploid nucleus in the zygote
• Which two gametes unite is random
– Adds to variation among offspring
Factors Contributing to Variation among Offspring
• Crossing over during prophase I
• Random alignment of
chromosomes at metaphase I
• Random combination of gametes at
fertilization
Mitosis• Functions
– Asexual reproduction– Growth, repair
• Occurs in somatic cells
• Produces clones
Mitosis & Meiosis Compared
Meiosis• Function
– Sexual reproduction
• Occurs in germ cells
• Produces variable offspring
Prophase vs. Prophase I
• Prophase (Mitosis)
– Homologous pairs do not interact with each
other
• Prophase I (Meiosis)
– Homologous pairs become zippered
together and crossing over occurs
Anaphase, Anaphase I, and Anaphase II
• Anaphase I (Meiosis)
– Homologous chromosomes are separated from
each other
• Anaphase/Anaphase II (Mitosis/Meiosis)
– Sister chromatids of a chromosome are separated
from each other
Results of Mitosis and Meiosis
• Mitosis
– Two diploid cells produced
– Each identical to parent
• Meiosis
– Four haploid cells produced
– Differ from parent and one another
Related Documents
