Plant Cell Cycle: Mitosis and Meiosis PDF

Summary

This document is a lecture presentation on the plant cell cycle, covering mitosis and meiosis. It includes detailed explanations of various stages, processes, and key components, such as chromosomes, and the importance of each stage within the cell cycle. This is useful for biology students learning about cell reproduction.

Full Transcript

Lecture No. 3
Plant Cell Cycle
(Mitosis and Meiosis)
Prepared by: CHRISTINE JOY S. LUNA
 LEARNING OUTCOMES

01 02

Describe the events Compare and
of the cell cycle in contrast mitosis
plants and meiosis
 Growth
❖Dictated by continuous
generation of new cells

❖Achieved through cell
expansion and cell
division

❖ Cell cycle

❖ “Telomeres”
 Chromosome
Thread-like structures in a cell’s
nucleus that are visible under
the microscope only during cell
division

Consists of proteins and a
single large molecule of DNA
that contains hundreds of
thousands of different genes
 Chromosome number
The number of chromosomes within a nucleus varies from one
species to another, but every somatic cell in an organism of a
given species contains a characteristic number of chromosomes.

Cabbage: 20 chromosomes per cell (10 pairs per cell)
Haplopappus gracilis: 4 chromosomes per cell (2 pairs per cell)
Olea europea: 46 chromosomes (23 pairs per cell)
Ophioglossum reticulatum: 1262 chromosomes per cell (631 pairs
per cell)
 Homologous chromosomes
Members of a chromosome pair that are similar in size, shape, and genetic
constitution.
Carry information governing the same genetic traits, although is not
necessarily identical.
Example: A homologous pair carrying a gene that specifies flower color, but
each chromosome may specify different colors of petals.
 Diploid vs. Haploid

Diploid (2n)- A cell in which each chromosome occurs in pairs
Haploid (n)- A cell that has a single set of chromosomes

Diploid Haploid

Two chromosomes Single Chromosome
Represented by 2n Represented by n
Somatic cells Gametes
Created by Mitosis Created by Meiosis
 The Cell Cycle
The cell cycle is the successive
series of events in the life of a
dividing eukaryotic cell.

Often represented as a circle and
consists of two main phases
(interphase and M phase)

The period between two successive
divisions, represented by a
complete revolution of the circle, is
The cell cycle the generation time.
 Cell Cycle

M
INTERPHASE (MITOSIS/ MEIOSIS)
PHASE

Preparatory phase Mitosis
Performs Cell growth and DNA Meiosis I
duplication Meiosis II
 Meristems
Localized areas of the plant body where mitosis and cytokinesis take
place most of the time.

Occur in the shoot and root tips (the apical meristems) and in some
plants, in thin cylindrical regions that run the entire lengths of stems and
roots except at the tips (the lateral meristems)

Apical meristems: allows the production and subsequent
elongation of new cells, causing an increase to the length of
growing stems and roots.
Lateral meristems: produce additional wood and bark tissues that
add girth to stems and roots of trees and shrubs.
 Interphase
The stage between successive cell divisions

Interphase: “between phases”

The cell synthesizes needed materials and grows

Chromosomes undergo duplication during interphase (not readily visible)
Interphase

SUBPHASES:

1. Gap I Phase (GI Phase)
or Pre-synthesis gap

2. Synthesis phase (S
Phase)

3. Gap II (GII Phase) or
Post-synthesis
Interphase: First Gap Phase (G1)

First stage in Interphase
Pre-synthesis phase
Cell growth
Duplication of organelles
Cell’s nucleus contains single
nucleolus and light chromatin
materials
Does not involve DNA
replication
GI checkpoint
 Interphase: Synthesis Phase (S)

Second stage of
Interphase
Duplication of
nucleus
Synthesis of DNA
and protein
“Replicated
chromosomes”-
chromosomes after
S phase
Interphase: Secondary Gap Phase (G2)
Third step, next to S Phase
Post-synthesis phase
Allows the cells to grow
more
More proteins and
organelles (e.g.mitochondria,
chloroplasts, etc.) are being
made
Larger nucleus; nucleus
contain two nucleoli and
darker chromatin materials.
Prepares the cell for the actual
division (M Phase)
Interphase: Gap Zer0 Phase (G0)
Gap zero phase or Resting Phase
Cells may opt to enter this phase or may
directly enter the G1 phase up to cell
division
Intrinsic and extrinsic factors
(resource availability, nutritional
deprivation, etc.)
A cell is performing its function without
actively preparing to divide
Quiescent stage
Cells enter G0 phase, phase
temporarily
Senescent stage
Cells enter G0 phase permanently
Interphase and M Phase
Important processes under Interphase
1. DNA Replication
❑ a process of duplicating DNA through
semi-conservative replication
❑ Initiation, Transcription, and
Translation

2. Transcription
❑ the genetic information in the DNA is
transferred to RNA through the
catalytic action of RNA polymerase

3. Translation
❑ Translation is the synthesis of a
protein from an mRNA template.
❑ Synthesize proteins, which are used
for millions of cellular functions.
DNA REPLICATION

Source: https://www.youtube.com/watch?v=Qqe4thU-os8
Transription and Translation

Source: https://www.youtube.com/watch?v=oefAI2x2CQM
Transription and Translation

Source: https://www.youtube.com/watch?v=bKIpDtJdK8Q
M PHASE
Mitosis or Meiosis
 Mitosis
Indicates or signals the completion of interphase

Visible changes associated with the division of the nucleus take
place

Most cellular activities (e.g. Protein synthesis) are suspended
during this phase

It is divided into four stages
 M Phase: Mitosis
Facilitates plant growth and repair through mitotic cell division

A mechanism that maintains the equal distribution of chromosome content
hence, producing two identical cells from a single parent cell.

A nuclear division (karyokinesis) that involves condensation and separation of
replicated chromosomes.

Four stages (PMAP)
1. Prophase
2. Metaphase
3. Anaphase
4. Telophase.
 M Phase: Mitosis

Mitosis is a carefully controlled process
that organizes and separates the
chromosomes correctly. After the cells
separate the chromosomes and build
new nuclei, they divide their
cytoplasm by cytokinesis and form
two distinct cells.
Mitosis
 Mitosis: Prophase
❑ Duplicated
chromosomes
condense and become
visible during
prophase

❑ Chromatin begins to
condense and coil into
visible chromosomes.

❑ Chromosomes become
shorter and thicker
and are individually
visible under light
microscope
 Mitosis: Prophase
Chromosomes become shorter and thicker and are
individually visible under the light microscope.

Each chromosome is a duplicated chromosome,
consisting of sister chromatids

Centromere- A specialized region of a chromosome.
At prophase, sister chromatids are joined in the
vicinity of their centromeres.

Kinetochore- The portion of the chromosome
centromere to which the mitotic spindle fibers
attach.

Microtubules- function in chromosome distribution
during mitosis
 Mitosis: Prophase
The nuclear envelope breaks apart.
Vesicles- small, membrane-enclosed
sacs
The nucleolus shrinks and
disappears
Spindle- The structure consisting
mainly of microtubules that provides
the framework for chromosome
movement during cell division
 Mitosis: Prophase
The spindle microtubules grow and shrink as they move toward
the center of the cell in a “search and capture” process.

If a microtubule comes near the centromere of a chromosome,
the microtubule “captures” it.

As the now-tethered chromosome continues moving toward the
cell’s midplane, a spindle microtubule from the cell’s other pole
attaches to the opposite side of the centromere.
 Mitosis: Metaphase
Duplicated chromosomes line up on the midplane of the cell

Mitotic spindle: completely visible and composed of numerous
microtubules that extend from pole to pole.

Each chromatid is quite condensed and appears thick and distinct.

Individual chromosomes are more distinct in this phase
 Mitosis: Anaphase
Chromosomes move toward the poles during anaphase

This phase begins as the sister chromatids separate

Chromatids that are no longer attached to their duplicates
are considered independent chromosome

Anaphase ends when all the chromosomes have reached
the poles
 Mitosis: Telophase
The final stage of mitosis in which chromosomes arrive at the poles and
return to their interphase condition.

The chromosomes begin to elongate by uncoiling and then become invisible
chromatin threads

Two separate nuclei form
 Cytokinesis in Plant Cells
The division of the cytoplasm that usually
accompanies mitosis, generally begins during
telophase.

Occurs by the formation of a cell plate, a partition
between the newly formed nuclei in the equatorial
region of the cell.

Forms two daughter cells
Cytokinesis in Plant Cells
 Sexual Reproduction
Gametes
Reproductive cells (egg and sperm cells) which
have half the diploid number of chromosomes.
Form a complete, new organism by uniting
Zygote
A fertilized egg produced upon union of the
female gamete (egg) and the male gamete (sperm
cell).
 Meiosis
Reduces the number of chromosomes in reproductive
cells by half

Meiosis means “to make smaller”

As a result of meiosis, each gamete has only one
chromosome of each pair, resulting in an egg or sperm
cell with a haploid, or n, number of chromosomes.
 Meiosis
❖ Each new cell that results from meiosis is a haploid
cell; it has n, not 2n, chromosomes

❖Meiosis separates the members of each homologous
pair of chromosomes→ No two offspring of the same
parents will be exactly alike.

❖Consists of two cell divisions: first and second meiotic
divisions (meiosis I and meiosis II)
Meiosis I: Prophase I
❖ The chromosomes duplicate during the S
Phase of Interphase before the complex
movements of meiosis actually begin.

❖ The homologous chromosomes come
together to lie side by side lengthwise.

❖ Synapsis- Pairing of homologous
chromosomes
 Meiosis I: Prophase I
❖ Crossing over
The sharing of genetic material between two non-sister
chromatids of paired homologous chromosomes
Produces new combination of genes
 Meiosis I: Prophase I
❖ A spindle forms consisting of microtubules.

❖ The nuclear envelope and nucleolus disappear

❖ In cells with large chromosomes, the association of
the four chromatids of each
Meiosis I: Metaphase I
❖ Homologous chromosomes line up in
pairs along the midplane.

❖ Both kinetochores of one duplicated
chromosome are attached by spindle
microtubules to the same pole.

❖ Both kinetochores of the duplicated
homologous chromosome are attached
to the opposite pole
 Meiosis I: Metaphase I

Spindle
microtubules

Equatorial plane

Metaphase in Mitosis

Centromere Chromatid/s

Key stages in Plant Meiosis
Meiosis I: Anaphase I
❖ The paired homologous chromosomes
separate, with one chromosome moving
toward one pole and its homologue
moving toward the other pole.

❖ Each pole receives a random combination of
maternal and paternal chromosomes, but
only one member of each homologous pair
is present at each pole
 Meiosis I: Anaphase I
1. At the onset of anaphase I, each bivalent separate

Cell pole
Spindle Fibers

Key stages in Plant Meiosis
Meiosis I: Telophase I
❖ There would be two
duplicated chromosomes,
one of each homologous
pair, at each pole.

❖ The nuclei often reorganize,
the chromatids generally
elongate, and cytokinesis
may take place.
Meiosis I: Telophase I
Two haploid cells
are formed at the end
of Meiosis I
 Meiosis II: Prophase II
❖ Sister chromatids separate

❖ There is no pairing of
homologous chromosomes and
no crossing over occurs

❖ Main features: Chromosomes
become shorter and thicker, and
their two-stranded nature once
more becomes apparent
 Meiosis II: Metaphase II
❖ The chromosomes, each consisting
of two sister chromatids, line up on
the midplanes of their cells

❖ There are two chromatids of a
single chromosome

❖ Main features:
1. The centromeres of the chromosomes
become aligned along the equator.
2. New spindles become conspicuous
and complete
Meiosis II: Anaphase II
❖ The paired chromosomes separate,
with one chromosome moving
toward one pole and its homologue
moving toward the other pole.

❖ Only one member of each
homologous pair is present at each
pole.

❖ Main features: The centromeres and
chromatids of each chromosome
separate and migrate to opposite
poles.
Meiosis II: Telophase II
❖ There is one member of each homologous
chromosome pair at each pole. Each
chromosome is in an unduplicated state.
❖ Nuclear enveloped then re-form around each
set of chromosomes.
❖ The chromosomes gradually elongate into
threadlike chromatin
❖ Cytokinesis occurs
❖ Main features:
1. The coils of the chromatids (now called
chromosomes again) relax so that the
chromosomes become longer and
thinner
2. New nuclear envelopes and nucleoli
reappear for each group of
chromosomes.
 Meiosis I and II
❖ Result in four haploid daughter cells, each containing one of each kind
of chromosome.

❖ Each resulting haploid cell has a different combination of genes.

❖ Two sources of genetic variation:
1. DNA segments are exchanged between maternal and paternal
homologues during crossing over
2. During Meiosis, the maternal and paternal chromosomes of
homologous pairs separate independently so that each member of a
pair is randomly distributed to one of the poles at anaphase.
A Comparison of Mitosis and Meiosis
Importance of Plant Cell Cycle: Mitosis and Meiosis

Source: https://www.youtube.com/watch?v=WNkUpdZmM0I
Importance of Plant Cell Cycle: Mitosis and Meiosis

Source: https://www.youtube.com/watch?v=iRKu2MN4T04
 LEARNING OUTCOMES

01 02

Describe the events Compare and
of the cell cycle in contrast mitosis
plants and meiosis
 Any
questions?
Email: [email protected]
Contact number: 09478446564