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Phases of the Cell Cycle
The increased size and more complex organization of eu- karyotic genomes over those of bacteria required radical changes in the process by which the two replicas of the genome are partitioned into the daughter cells during cell division. This division process is diagrammed as a cell cycle, consisting of five phases (figure 11.8).
The Five Phases
G 1 is the primary growth phase of the cell. For many or- ganisms, this encompasses the major portion of the cell’s life span. S is the phase in which the cell synthesizes a replica of the genome. G 2 is the second growth phase, in which preparations are made for genomic separation. During this phase, mitochondria and other organelles replicate, chromosomes condense, and microtubules begin to assemble at a spindle. G 1 , S, and G 2 together constitute interphase, the portion of the cell cycle be- tween cell divisions. M is the phase of the cell cycle in which the microtubu- lar apparatus assembles, binds to the chromosomes, and moves the sister chromatids apart. Called mitosis, this process is the essential step in the separation of the two daughter genomes. We will discuss mitosis as it occurs in animals and plants, where the process does not vary much (it is somewhat different among fungi and some protists). Although mitosis is a continuous process, it is traditionally subdivided into four stages: prophase, metaphase, anaphase, and telophase. C is the phase of the cell cycle when the cytoplasm di- vides, creating two daughter cells. This phase is called cytokinesis. In animal cells, the microtubule spindle helps position a contracting ring of actin that constricts like a drawstring to pinch the cell in two. In cells with a cell wall, such as plant cells, a plate forms between the di- viding cells.
Duration of the Cell Cycle
The time it takes to complete a cell cycle varies greatly among organisms. Cells in growing embryos can com- plete their cell cycle in under 20 minutes; the shortest known animal nuclear division cycles occur in fruit fly embryos (8 minutes). Cells such as these simply divide their nuclei as quickly as they can replicate their DNA, without cell growth. Half of the cycle is taken up by S, half by M, and essentially none by G 1 or G 2. Because ma- ture cells require time to grow, most of their cycles are much longer than those of embryonic tissue. Typically, a dividing mammalian cell completes its cell cycle in about
24 hours, but some cells, like certain cells in the human liver, have cell cycles lasting more than a year. During the cycle, growth occurs throughout the G 1 and G (^2) phases (referred to as “gap” phases, as they separate S from M), as well as during the S phase. The M phase takes only about an hour, a small fraction of the entire cycle. Most of the variation in the length of the cell cycle from one organism or tissue to the next occurs in the G (^1) phase. Cells often pause in G 1 before DNA replication and enter a resting state called G 0 phase; they may re- main in this phase for days to years before resuming cell division. At any given time, most of the cells in an ani- mal’s body are in G 0 phase. Some, such as muscle and nerve cells, remain there permanently; others, such as liver cells, can resume G 1 phase in response to factors re- leased during injury.
Most eukaryotic cells repeat a process of growth and division referred to as the cell cycle. The cycle can vary in length from a few minutes to several years.
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11.3 Mitosis is a key phase of the cell cycle.
G 2
S G 1
C
Metaphase Prophase
Anaphase Telophase
M
Interphase ( G 1 , S , G 2 phases) Mitosis ( M ) Cytokinesis ( C )
FIGURE 11. The cell cycle. Each wedge represents one hour of the 22-hour cell cycle in human cells growing in culture. G 1 represents the primary growth phase of the cell cycle, S the phase during which a replica of the genome is synthesized, and G 2 the second growth phase.
Interphase: Preparing for Mitosis
The events that occur during interphase, made up of the G 1 , S, and G 2 phases, are very important for the successful com- pletion of mitosis. During G 1 , cells undergo the major por- tion of their growth. During the S phase, each chromosome replicates to produce two sister chromatids, which remain at- tached to each other at the centromere. The centromere is a point of constriction on the chromosome, containing a specific DNA sequence to which is bound a disk of protein called a kinetochore. This disk functions as an attachment site for fibers that assist in cell division (figure 11.9). Each chromosome’s centromere is located at a characteristic site. The cell grows throughout interphase. The G 1 and G (^2) segments of interphase are periods of active growth, when proteins are synthesized and cell organelles produced. The cell’s DNA replicates only during the S phase of the cell cycle. After the chromosomes have replicated in S phase, they remain fully extended and uncoiled. This makes them invis- ible under the light microscope. In G 2 phase, they begin the long process of condensation, coiling ever more tightly. Special motor proteins are involved in the rapid final conden- sation of the chromosomes that occurs early in mitosis. Also during G 2 phase, the cells begin to assemble the machinery they will later use to move the chromosomes to opposite poles of the cell. In animal cells, a pair of microtubule- organizing centers called centrioles replicate. All eukary- otic cells undertake an extensive synthesis of tubulin, the protein of which microtubules are formed.
Interphase is that portion of the cell cycle in which the chromosomes are invisible under the light microscope because they are not yet condensed. It includes the G 1 , S, and G 2 phases. In the G 2 phase, the cell mobilizes its resources for cell division.
Chapter 11 How Cells Divide 213
Metaphase chromosome
Kinetochore
Kinetochore microtubules
Centromere region of chromosome
Chromatid
FIGURE 11. Kinetochores. In a metaphase chromosome, kinetochore microtubules are anchored to proteins at the centromere.
A Vocabulary of
Cell Division
chromatin The complex of DNA and proteins of which eukaryotic chromosomes are composed. chromosome The structure within cells that contains the genes. In eukaryotes, it consists of a single linear DNA molecule as- sociated with proteins. The DNA is repli- cated during S phase, and the replicas sepa- rated during M phase. cytokinesis Division of the cytoplasm of a cell after nuclear division. euchromatin The portion of a chromo- some that is extended except during cell di- vision, and from which RNA is transcribed. heterochromatin The portion of a chro- mosome that remains permanently con- densed and, therefore, is not transcribed into RNA. Most centromere regions are heterochromatic. homologues Homologous chromosomes; in diploid cells, one of a pair of chromo- somes that carry equivalent genes.
kinetochore A disk of protein bound to the centromere and attached to micro- tubules during mitosis, linking each chro- matid to the spindle apparatus. microtubule A hollow cylinder, about 25 nanometers in diameter, composed of sub- units of the protein tubulin. Microtubules lengthen by the addition of tubulin subunits to their end(s) and shorten by the removal of subunits. mitosis Nuclear division in which repli- cated chromosomes separate to form two genetically identical daughter nuclei. When accompanied by cytokinesis, it produces two identical daughter cells. nucleosome The basic packaging unit of eukaryotic chromosomes, in which the DNA molecule is wound around a cluster of histone proteins. Chromatin is composed of long strings of nucleosomes that resemble beads on a string.
binary fission Asexual reproduction of a cell by division into two equal or nearly equal parts. Bacteria divide by binary fission.
centromere A constricted region of a chromosome about 220 nucleotides in length, composed of highly repeated DNA sequences (satellite DNA). During mitosis, the centromere joins the two sister chro- matids and is the site to which the kineto- chores are attached.
chromatid One of the two copies of a replicated chromosome, joined by a single centromere to the other strand.
Chapter 11 How Cells Divide 215
CYTOKINESIS
- plant cells: cell plate forms, dividing daughter cells
- animal cells: cleavage furrow forms at equator of cell and pinches inward until cell divides in two
Prophase
- nuclear membrane disintegrates
- nucleolus disappears
- chromosomes condense
- mitotic spindle begins to form between centrioles
- kinetochores begin to mature and attach to spindle
Metaphase
- kinetochores attach chromosomes to mitotic spindle and align them along metaphase plate at equator of cell
Anaphase
- kinetochore microtubules shorten, separating chromosomes to opposite poles
- polar microtubules elongate, preparing cell for cytokinesis
Telophase
- chromosomes reach poles of cell
- kinetochores disappear
- polar microtubules continue to elongate, preparing cell for cytokinesis
- nuclear membrane re-forms
- nucleolus reappears
- chromosomes decondense
Nucleolus Nucleus Cytoplasm
Cell wall
Microtubules
Cell nucleus
Condensed chromosomes
Chromosomes
Centromere and kinetochore
Mitotic spindle
Mitotic spindle microtubules
Chromosomes aligned on metaphase plate
Kinetochore microtubules
Polar Chromatids microtubules Spindle microtubules (pink)
Daughter nuclei Cell plate and nucleoli
Microtubule
FIGURE 11. Mitosis and cytokinesis. Mitosis (separation of the two genomes) occurs in four stages—prophase, metaphase, anaphase, and telophase— and is followed by cytokinesis (division into two separate cells). In this depiction, the chromosomes of the African blood lily, Haemanthus katharinae, are stained blue, and microtubules are stained red.
Anaphase and Telophase: Separation of the
Chromatids and Reformation of the Nuclei
Of all the stages of mitosis, anaphase is the shortest and the most beautiful to watch. It starts when the centromeres divide. Each centromere splits in two, freeing the two sister chromatids from each other. The centromeres of all the chromosomes separate simultaneously, but the mechanism that achieves this synchrony is not known. Freed from each other, the sister chromatids are pulled rapidly toward the poles to which their kinetochores are at- tached. In the process, two forms of movement take place simultaneously, each driven by microtubules. First, the poles move apart as microtubular spindle fibers physically anchored to opposite poles slide past each other, away from the center of the cell (figure 11.12). Because an- other group of microtubules attach the chromosomes to the poles, the chromosomes move apart, too. If a flexible membrane surrounds the cell, it becomes visibly elongated. Second, the centromeres move toward the poles as the mi- crotubules that connect them to the poles shorten. This shortening process is not a contraction; the microtubules do not get any thicker. Instead, tubulin subunits are re- moved from the kinetochore ends of the microtubules by the organizing center. As more subunits are removed, the chromatid-bearing microtubules are progressively disas- sembled, and the chromatids are pulled ever closer to the poles of the cell.
When the sister chromatids separate in anaphase, the accurate partitioning of the replicated genome—the es- sential element of mitosis—is complete. In telophase, the spindle apparatus disassembles, as the microtubules are broken down into tubulin monomers that can be used to construct the cytoskeletons of the daughter cells. A nu- clear envelope forms around each set of sister chromatids, which can now be called chromosomes because each has its own centromere. The chromosomes soon begin to un- coil into the more extended form that permits gene ex- pression. One of the early group of genes expressed are the rRNA genes, resulting in the reappearance of the nucleolus.
During prophase, microtubules attach the centromeres joining pairs of sister chromatids to opposite poles of the spindle apparatus. During metaphase, each chromosome is drawn to a ring along the inner circumference of the cell by the microtubules extending from the centromere to the two poles of the spindle apparatus. During anaphase, the poles of the cell are pushed apart by microtubular sliding, and the sister chromatids are drawn to opposite poles by the shortening of the microtubules attached to them. During telophase, the spindle is disassembled, nuclear envelopes are reestablished, and the normal expression of genes present in the chromosomes is reinitiated.
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Metaphase Late anaphase
Pole Overlapping microtubules Pole Pole Overlapping microtubules 2 μm Pole
FIGURE 11. Microtubules slide past each other as the chromosomes separate. In these electron micrographs of dividing diatoms, the overlap of the microtubules lessens markedly during spindle elongation as the cell passes from metaphase to anaphase.
