Plant Cell Biology Lecture 4 Part II - Fall2024 PDF

Summary

This lecture covers Plant Cell Biology, specifically focusing on the cell cycle control systems, including mitosis, and meiosis. Presented by Dr. Fatma M. Ashour, this part II of lecture 4 is part of the Fall2024 course.

Full Transcript

040407221: PLANT CELL BIOLOGY
‫بيولوچيا الخلية النباتية‬
Lecture 4
Part II

DR. FATMA M. ASHOUR 1

Dr.Fatma Ashour
 CELL CYCLE CONTROL SYSTEMS

The eukaryotic cell cycle is driven by cell cycle “engines”, a
set of interacting proteins, the cyclin- dependent kinases
(Cdks).
CDKs are relatively small proteins, with molecular weights
ranging from 34 to 40 kDa, and contain little more than the
kinase domain. By definition, a CDK binds a regulatory
protein called a cyclin. Without cyclin, CDK has little kinase
activity; only the cyclin-CDK complex is an active kinase.
1- Cyclin
2- Kinase (cyclin-dependent kinase) 1
3- Inhibitor (cyclin-dependent kinase inhibitor) 3

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 CELL CYCLE CONTROL SYSTEMS

A kinase is an enzyme that catalyzes the transfer of phosphate
groups from high-energy, phosphate-donating molecules to
specific substrates. This process is known as
phosphorylation, where the substrate gains a phosphate group
and the high-energy ATP molecule donates a phosphate group.

Cyclin is a family of proteins that controls the progression of
a cell through the cell cycle by activating cyclin-dependent
kinase (CDK) enzymes or group of enzymes required for
synthesis of cell cycle.

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 CELL CYCLE CONTROL SYSTEMS

Other proteins act as rate-limiting steps in cell cycle
progression and are able to induce cell cycle arrest
at defined stages (checkpoints).
The cyclic pattern of cyclin expression to produce
progression through the cell cycle is under
transcriptional control.

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 figure 1.

Cell cycle
and
checkpoints

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FIGURE 2 : CELL CYCLE CONTROL SYSTEMS

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 Activation of CdKs requires their dephosphorylation;
kinase activity can also be blocked by cyclin- dependent
kinase inhibitors (CKIs).
One CKI, known as P16, is in fact a tumor suppressor,
deficiencies in which are associated with many cancers.
In yeast, there is a single kinase that interacts with different
cyclins to promote different cell- cycle transitions.
In mammals and plants, the situation is more complicated,
with different kinases binding different cyclins to promote
the different transitions.

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There are three major classes of cyclin- CDK
complexes that control passage through the cell cycle:
1- G1, cyclin- CDK
2- S-phase, cyclin- CDK
3-Mitotic cyclin- CDK complexes.
When cells are stimulated to replicate, G1 cyclin-
CDK complexes are expressed first.

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 G1 CYCLIN-CDK COMPLEXES

G1 cyclin-CDK complexes prepare the cell for the S phase by
activating transcription factors.
These factors promote transcription of:
1- Genes encoding enzymes required for DNA synthesis.
2- The genes encoding S-phase cyclins and CDKs.
Note: The activity of S-phase cyclin-CDK complexes initially
held in check by inhibitors.

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FIGURE 3: Control of the G1 → S phase transition in S. cerevisiae by regulated
proteolysis of the S-phase inhibitor Sic1. The S-phase cyclin-CDK complexes
begin to accumulate in G1, but are inhibited by Sic1.
This inhibition prevents initiation of DNA replication until the cell is fully
prepared.
G1 cyclin-CDK complexes assembled in late G1 phosphorylate Sic1 (step
1), marking it for polyubiquitination, and subsequent proteasomal
degradation (step 2).
The active S-phase cyclin-CDK complexes then trigger initiation of DNA
synthesis (step 3) by phosphorylating substrates that remain to be identified.
[Adapted from R. W. King et al., 1996, Science 274:1652.
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In late G1, the G1 cyclin-CDK complexes induce degradation
of the S-phase inhibitors releases active S-phase cyclin-CDK
complexes.
The function of active S-phase cyclin-CDK complexes :
1- activate initiation of DNA replication
2- prevent (inhibit) re-replication of the DNA molecule
Because of this inhibition, each chromosome is replicated just
once during passage through the cell cycle, ensuring that the
proper chromosome number is maintained in the daughter cells.

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The most important exception to this is
Endoreduplication, in which successive rounds of
replication occur without cell or chromosomal division
This is the process by which polytene chromosomes are
formed. Interband
(euchromatin)

Band
(heterochromatin)

The normal mitotic cell cycle controls are modified to
that DNA replication is not followed by mitosis.
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3- S cyclin- CDK activates helicases, which unwind the
parental DNA strands.

4- A complex of DNA polymerase (pol. α ) and primase
initiates the synthesis of daughter strands.

5- DNA polymerase δ plus its accessory factors, elongate
daughter strands initiated by pol α - primase.

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MITOTIC CYCLIN- CDK COMPLEXES

Mitotic cyclin- CDK complexes are synthesized during the S phase and G2, but
their activities are held until DNA synthesis is completed.

Mitotic cyclin-CDK complexes is activated by dephosphorylation by
phosphatases.

Active M cyclin- CDK activates early mitotic events, these events are:
1- Chromosome condensation,
2- Retraction of the nuclear envelope,
3- Assembly of the mitotic spindle apparatus, and
4-Alignment of condensed chromosomes at the metaphase plate.

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At metaphase, the spindle is in a state of tension with forces
pulling the two kinetochores toward the opposite spindle
poles balanced by forces pushing the spindle poles apart.
Sister chromatids do not separate because they are held
together at their centromere and multiple positions along
the chromosome arms by multiprotein complexes called
cohesions.

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THE ANAPHASE PROMOTING COMPLEX (APC)

This sequence of events initiates anaphase by freeing sister
chromatids to segregate to opposite spindle poles.
Late in anaphase, the APC also directs the degradation of the
mitotic cyclins.
The degradation of the mitotic cyclins by APC is inhibited until the
segregating chromosomes have reached the proper location in the
dividing cell.
Degradation of the mitotic cyclins leads to decrease in mitotic CDK
activity.

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FIGURE 4: MODEL FOR CONTROL OF ENTRY INTO ANAPHASE BY APC-
REGULATED DEGRADATION OF THE COHESIN LINK BETWEEN SISTER
CHROMATIDS.

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 THE ANAPHASE PROMOTING COMPLEX
(APC)
As a result, the decrease in mitotic CDK activity permits to:
1- de- condense of separated chromosomes ,
2- the nuclear envelope re-forms around daughter-cell nuclei, and
3- the Golgi apparatus reassembles.
Finally during Telophase; the cytoplasm divides at cytokinesis, yielding the two
daughter cells.
Passage through three critical cell-cycle transitions:
G1 → S phase,
metaphase → anaphase, and
anaphase → telophase and cytokinesis, is irreversible because these transitions
are triggered by the regulated degradation of proteins, and irreversible process.
As a consequence, cells are forced to traverse the cell cycle in one direction
only.
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MEIOSIS: A SPECIAL TYPE OF CELL DIVISION

Meiosis involves one cycle of chromosome replication followed by two
cycles of cell division to produce haploid germ cells from a diploid
premeiotic cell.
During meiosis I, replicated homologous chromosomes pair along their
lengths in a process called synapsis. At least one recombination
between chromatids of homologous chromosomes almost in variably
occurs.
Most of the cell-cycle proteins that function in mitotically dividing cells
also function in cells undergoing meiosis, but some proteins are unique
to meiosis.

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Figure 5.

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 MEIOSIS: A SPECIAL TYPE OF CELL
DIVISION
In S. cerevisiae, expression of G1 cyclins is repressed throughout meiosis.
Meiosis-specific Ime2 performs the function of G1 cyclin-CDK
complexes in promoting initiation of DNA replication during meiosis I.
DNA replication does not occur during meiosis II because neither Ime2
nor G1 cyclins are expressed.
In S. cerevisiae, recombination (crossing over) between chromatids of
homologous parental chromatids and cohesin cross-links between
chromatids distal to the crossover are responsible for synapsis of
homologous chromosomes during prophase and metaphase of meiosis I. A
specialized cohesin subunit, Rec8, replaces the Scc1 cohesin subunit during
meiosis. Dr.Fatma Ashour 21
MEIOSIS: A SPECIAL TYPE OF CELL DIVISION

During early anaphase of meiosis I, Rec8 in the chromosome arms is
cleaved, but a meiosis-specific protein associated with the kinetochore
protects Rec8 in the region of the centromere from cleavage.
As a result, the chromatids of homologous chromosomes remain
associated during segregation in meiosis I.

Cleavage of centromeric Rec8 during anaphase of meiosis II allows
individual chromatids to segregate into germ cells.
Monopolin, another meiosis-specific protein, is required for both
chromatids of homologous chromosomes to associate with
microtubules emanating from the same spindle poles during meiosis I.

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FIGURE 6. Cohesin function during mitosis and
meiosis.
(a) During mitosis, sister chromatids generated by
DNA replication in the S phase are initially
associated by cohesin complexes along the full
length of the chromatids. During chromosome
condensation, cohesin complexes (yellow) become
restricted to the region of the centromere at
metaphase, as depicted here. Once separase cleaves
the Scc1 cohesin subunit, sister chromatids can
separate, marking the onset of anaphase.

(b) In metaphase of meiosis I, crossing over between
maternal and paternal chromatids produces synapsis of
homologous parental chromosomes. The chromatids of
each replicated chromosome are cross-linked by cohesin
complexes along their full length. Rec8, a meiosis-
specific homolog of Scc1, is cleaved in chromosome arms
but not in the centromere, allowing homologous
chromosome pairs to segregate to daughter cells.

Centromeric Rec8 is cleaved during meiosis II, allowing
individual chromatids to segregate to daughter cells.
[Modified from F. Uhlmann, 2001, Curr. Opin. Cell Biol.
13:754.]

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 MEIOTIC ARREST

In the mitotic cell cycle, the main variable in the length of the cell
cycle is the length of G1, and once the cell is committed to divided,
it proceeds through S, G2 and mitosis without delay.
Similarly, male meiosis is generally a continuous process, designed
to produce vast quantities of spermatocytes with the minimum delay.
Female germ cells, however, can arrest in meiosis, often for years,
at a variety of different stages, according to the species.
- In many invertebrates this arrest is at metaphase I.
- In most vertebrates it is at metaphase II.
The stimulus for completion of meiosis is usually fertilization.

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 MEIOTIC ARREST

Meiotic arrest also occurs commonly at diplotene. In
mammals, female meiosis starts in the embryo, and
proceeds as far as diplotene, when the chromosomes
become diffuse and the cells are referred to as being in the
dictyate stage. This arrest is under hormonal control, and
the oocyte recommences growth and passage through
meiosis in response to luteinizing hormone in adult life.

The dictyate or dictyotene is a prolonged resting phase
in oogenesis

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