The cell cycle is an ordered series of
events involving cell growth and cell division that produces two new daughter
cells. Cells on the path to cell division
proceed through a series of precisely timed
and carefully regulated stages of growth, DNA replication, and division
that produces two identical (clone)
cells. The cell cycle has two major phases: interphase and the mitotic phase (Figure 1). During interphase,
the cell grows and DNA is replicated. During the mitotic phase, the replicated DNA
and cytoplasmic contents are separated, and the cell divides.
Figure 1 The cell cycle consists of interphase and the mitotic phase. During interphase, the cell grows and the nuclear DNA is duplicated. Interphase is followed by the mitotic phase. During
the mitotic phase, the duplicated chromosomes are
segregated
and distributed into daughter nuclei. The cytoplasm is usually
divided as well, resulting
in two daughter cells.
Interphase
During interphase, the cell undergoes normal growth processes
while also preparing
for cell division.
In order for a cell to move from interphase into the
mitotic phase, many internal and external conditions must be met. The three
stages of interphase are called G1, S, and G2.
G1 Phase (First Gap)
The first stage of
interphase is called the G1 phase (first gap) because, from
a microscopic aspect, little change is visible. However, during the G1 stage,
the cell is quite active at the biochemical level. The cell is accumulating the
building blocks of chromosomal DNA and the associated proteins
as well as accumulating sufficient energy reserves
to complete the task
of replicating each chromosome in the nucleus.
S Phase (Synthesis of DNA)
Throughout
interphase, nuclear DNA remains in a semi-condensed chromatin configuration. In
the S phase, DNA replication can
proceed through the mechanisms that result in the formation of identical pairs
of DNA molecules—sister chromatids—that are firmly attached to the centromeric
region. The centrosome is duplicated during the S phase. The two centrosomes
will give rise to the mitotic spindle,
the apparatus that orchestrates the movement of chromosomes during mitosis. At
the center of each animal cell, the centrosomes of animal cells are associated
with a pair of rod-like objects, the centrioles,
which are at right angles to each other.
Centrioles help organize cell
division. Centrioles are not present in the centrosomes of other eukaryotic species, such as plants and most fungi.
G2 Phase (Second Gap)
In the G2 phase,
the cell replenishes its energy
stores and synthesizes proteins necessary for chromosome manipulation. Some
cell organelles are duplicated, and
the cytoskeleton is dismantled to provide resources for the mitotic phase.
There may be additional cell growth during G2. The
final preparations for the mitotic phase must be completed before the cell is
able to enter the first stage of
mitosis.
The Mitotic Phase
The mitotic phase is
a multistep process during which the duplicated chromosomes are aligned, separated,
and move into two new, identical
daughter cells. The first portion of the mitotic phase is called karyokinesis, or nuclear division. The
second portion of the mitotic phase, called cytokinesis, is the physical
separation of the cytoplasmic components into the two daughter cells.
Karyokinesis (Mitosis)
Karyokinesis, also known as mitosis, is divided into a series
of phases—prophase, prometaphase, metaphase, anaphase, and telophase—that result in the
division of the cell nucleus
(Figure
2). Karyokinesis is also called mitosis.
Figure 2 Karyokinesis (or mitosis) is divided into five stages-prophase,
prometaphase, metaphase, anaphase, and
telophase.
The pictures at the bottom
were
taken
by fluorescence microscopy (hence, the black background) of cells artificially stained by fluorescent dyes: blue fluorescence indicates DNA (chromosomes)
and green fluorescence indicates microtubules (spindle apparatus). (credit “mitosis drawings”: modification of work by Mariana Ruiz Villareal; credit “micrographs”: modification of work by Roy van Heesbeen; credit “cytokinesis
micrograph”: Wadsworth Center/New York State Department of Health; scale-bar data from Matt Russell)
Which of the following is the correct order
of events in mitosis?
a. Sister
chromatids
line up at the metaphase plate.
The kinetochore becomes attached to
the mitotic
spindle. The nucleus reforms and the cell divides. Cohesin
proteins break down and the sister
chromatids separate.
b. The kinetochore becomes
attached to the mitotic spindle. Cohesin proteins break down and the sister chromatids separate. Sister chromatids line up at the metaphase plate.
The nucleus reforms and the cell divides.
c. Thekinetochore becomes
attached to the cohesin proteins.
Sister chromatids line up at themetaphase
plate. Thekinetochore breaks
downand thesister chromatids separate.Thenucleus reforms and the cell divides.
d.
The kinetochore becomes
attached to the mitotic spindle. Sister chromatids line up at the metaphase plate. Cohesin proteins break down and the
sister chromatids separate.
The nucleus reforms
and
the cell divides.
During prophase,
the “first phase,” the nuclear envelope starts to dissociate into small
vesicles, and the membranous organelles (such
as the Golgi complex or Golgi apparatus, and endoplasmic reticulum), fragment and disperse
toward the periphery of the cell. The nucleolus
disappears (disperses). The centrosomes begin to move to opposite poles of the
cell. Microtubules that will form the mitotic spindle extend between the
centrosomes, pushing them farther apart as the microtubule fibers lengthen. The sister chromatids begin to coil more tightly
with the aid of condensin proteins and become visible under a light microscope.
During prometaphase,
the “first change phase,” many processes that were begun in prophase continue
to advance. The remnants of the nuclear envelope fragment. The mitotic spindle
continues to develop as more microtubules assemble and stretch across the
length of the former nuclear area. Chromosomes become more condensed and
discrete. Each sister chromatid develops a protein structure called a kinetochore in the centromeric region
(Figure 3). The proteins
of the kinetochore attract and bind mitotic spindle microtubules. As the
spindle microtubules extend from the centrosomes, some of these microtubules come into contact
with and firmly bind to the kinetochores. Once a mitotic
fiber attaches to a
chromosome, the chromosome will be oriented until the kinetochores of sister
chromatids face the opposite poles. Eventually,
all the sister chromatids will be attached via their kinetochores to
microtubules from opposing poles. Spindle microtubules that do not engage the
chromosomes are called polar microtubules. These microtubules overlap each other
midway between the two poles and contribute to cell elongation. Astral
microtubules are located near the poles, aid in spindle orientation, and are
required for the regulation of
mitosis.
Figure 3 During prometaphase, mitotic spindle microtubules from opposite poles attach to each sister chromatid at the kinetochore. In anaphase, the
connection between the sister chromatids breaks down,
and the microtubules pull the chromosomes toward opposite poles.
During metaphase, the “change phase,” all the
chromosomes are aligned in a plane called the metaphase plate, or the equatorial plane, midway between the two
poles of the cell. The sister chromatids are still tightly attached to each
other by cohesin proteins. At this time, the chromosomes are
maximally condensed.
During anaphase, the “upward phase,” the
cohesin proteins degrade, and the sister chromatids separate at the centromere.
Each chromatid, now called a chromosome, is pulled rapidly toward the
centrosome to which its microtubule is attached. The cell becomes visibly
elongated (oval shaped) as the polar microtubules slide against each other at
the metaphase plate where they overlap.
During telophase, the “distance phase,” the
chromosomes reach the opposite poles and begin to decondense (unravel),
relaxing into a chromatin configuration. The mitotic spindles
are depolymerized into tubulin monomers
that will be used to assemble cytoskeletal
components for each daughter cell. Nuclear envelopes form around the
chromosomes, and nucleosomes appear
within the nuclear area.
Cytokinesis
Cytokinesis, or “cell motion,” is the second main stage of the mitotic phase during which cell division is completed
via the physical separation of the cytoplasmic components into two
daughter cells. Division is not complete until the cell components have been apportioned and completely separated into the two daughter cells.
Although the stages
of mitosis are similar for most eukaryotes, the
process of cytokinesis is quite different
for eukaryotes that have cell walls, such as plant cells.
In cells such as
animal cells that lack cell walls, cytokinesis follows the onset of anaphase. A
contractile ring composed of actin filaments forms just inside the plasma
membrane at the former metaphase plate. The actin filaments pull the equator of the cell inward,
forming a fissure.
This fissure, or “crack,” is called the cleavage
furrow. The furrow deepens
as the actin ring contracts, and
eventually the membrane is cleaved in two (Figure 4).
In plant cells, a new
cell wall must form between the daughter cells. During interphase, the Golgi
apparatus accumulates enzymes, structural proteins, and glucose molecules prior
to breaking into vesicles and dispersing throughout the dividing cell. During telophase, these Golgi vesicles
are transported on microtubules to form a phragmoplast (a vesicular structure) at the metaphase plate. There, the vesicles fuse and coalesce
from the center toward the cell walls; this structure
is called a cell plate. As more vesicles fuse, the
cell plate enlarges until it merges with the cell walls at the periphery
of the cell. Enzymes use the glucose
that has accumulated between the membrane
layers to build
a new cell wall. The Golgi membranes become parts of the plasma membrane on either side of the new cell wall (Figure 4).
Figure 4 During cytokinesis in animal cells, a ring of actin
filaments
forms
at
the
metaphase plate.
The
ring contracts, forming a cleavage furrow, which divides
the cell in two. In plant cells,
Golgi vesicles coalesce at
the former metaphase plate, forming a phragmoplast. A cell plate formed by the fusion of the vesicles of
the phragmoplast grows from the center toward the cell walls, and the membranes of the vesicles fuse to form a plasma membrane that divides the cell in two.