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The Cell Cycle Chapter 12A.P. Biology • Overview: The Key Roles of Cell Division • The continuity of life: – is based upon the reproduction of cells, or cell division Figure 12.1 Unicellular organisms: – Reproduce by cell division. (a) Reproduction. An amoeba, a single-celled eukaryote, is dividing into two cells. Each new cell will be an individual organism (LM). Figure 12.2 A 100 µm • In binary fission: – The bacterial chromosome replicates – The two daughter chromosomes actively move apart 1 Chromosome replication begins. Soon thereafter, one copy of the origin moves rapidly toward the other end of the cell. Origin of replication Cell wall Plasma Membrane E. coli cell Two copies of origin 2 3 4 Replication continues. One copy of the origin is now at each end of the cell. Replication finishes. The plasma membrane grows inward, and new cell wall is deposited. Two daughter cells result. Figure 12.11 Origin Bacterial Chromosome Origin Cell Replication in Bacteria • Cell division in bacteria is controlled by the size of the cell; volume of the cytoplasm. • Bacteria replicate by binary fission. • >22 enzymes copy the DNA as a circle. • Both copies of the DNA are attached to the plasma membrane. The Evolution of Mitosis • Since prokaryotes preceded eukaryotes by billions of years: –It is likely that mitosis evolved from bacterial cell division • Certain protists: –Exhibit types of cell division that seem intermediate between binary fission and mitosis carried out by most eukaryotic cells A hypothetical sequence for the evolution of (a) Prokaryotes. During binary fission, the origins of mitosis the daughter Bacterial chromosomes move to opposite ends of the cell. The mechanism is not fully understood, but proteins may anchor the daughter chromosomes to specific sites on the plasma membrane. chromosome Chromosomes (b) Dinoflagellates. In unicellular protists called dinoflagellates, the nuclear envelope remains intact during cell division, and the chromosomes attach to the nuclear envelope. Microtubules pass through the nucleus inside cytoplasmic tunnels, reinforcing the spatial orientation of the nucleus, which then divides in a fission process reminiscent of bacterial division. (c) Diatoms. In another group of unicellular protists, the diatoms, the nuclear envelope also remains intact during cell division. But in these organisms, the microtubules form a spindle within the nucleus. Microtubules separate the chromosomes, and the nucleus splits into two daughter nuclei. (d) Most eukaryotes. In most other eukaryotes, including plants and animals, the spindle forms outside the nucleus, and the nuclear envelope breaks down during mitosis. Microtubules separate the chromosomes, and the nuclear envelope then re-forms. Figure 12.12 A-D Microtubules Intact nuclear envelope Kinetochore microtubules Intact nuclear envelope Kinetochore microtubules Centrosome Fragments of nuclear envelope Multicellular organisms depend on cell division for: – Development from a fertilized cell – Growth – Repair 200 µm (b) Growth and development. This micrograph shows a sand dollar embryo shortly after the fertilized egg divided, forming two cells (LM). Figure 12.2 B, C (c) Tissue renewal. These dividing bone marrow cells (arrow) will give rise to new blood cells (LM). 20 µm Cell Division in Eukaryotic Cells • Eukaryotic cells are much larger. • Also have larger genomes (the sum of an organisms’s genetic information). • Eukaryotic DNA is organized into much more complex structures. • Why? The DNA molecules in a cell – Are packaged into chromosomes. Figure 12.3 50 µm Chromosomes of Eukaryotes • Chromosomes are composed of chromatin - a DNA/protein complex. • Chromatin = 40% DNA + 60% Protein. • Every 200 nucleotides , the DNA duplex coils around a core of eight histone proteins = Nucleosome. Regions of Chromosomes are Not the Same • Condensed portions of chromatin Heterochromatin - are not being expressed; genes are turned off. May never be turned on. • Other portions of chromosome are decondensed and are being actively transcribed - Euchromatin. These areas are only condensed during cell division. Karyotype How Many Chromosomes are in Cells? • Most body or somatic cells have two copies of almost identical chromosomes - diploid. Ex. Humans have 23 types of chromosomes X 2 = 46 (2n or diploid number). • Sex cells or gametes (egg and sperm) have only one copy of each chromosome - haploid. Ex. Human sperm/egg = 23 chromosomes. Continued • Some somatic cells are truly unusual. • Human liver cells have 4 copies of all chromosomes - tetraploid. • Other cells RBC’s have no nucleus and therefore, no chromosomes. Phases of the Cell Cycle • The cell cycle consists of – The mitotic phase – Interphase INTERPHASE G0 G1 S (DNA synthesis) G2 Figure 12.5 Chromosome Terminology • The two copies of each chromosome in somatic cells - homologous chromosomes (homologues). Are these the same? • Before cell division, each homologue replicates --> two sister chromatids that are joined at the centromere. • Each duplicated chromosome: – Has two sister chromatids, which separate during cell division A eukaryotic cell has multiple chromosomes, one of which is represented here. Before duplication, each chromosome has a single DNA molecule. Once duplicated, a chromosome consists of two sister chromatids connected at the centromere. Each chromatid contains a copy of the DNA molecule. Mechanical processes separate the sister chromatids into two chromosomes and distribute them to two daughter cells. Figure 12.4 0.5 µm Chromosome duplication (including DNA synthesis) Centromere Separation of sister chromatids Centromeres Sister chromatids Sister chromatids • Mitosis consists of five distinct phases – Prophase – Prometaphase G2 OF INTERPHASE Centrosomes (with centriole pairs) Figure 12.6 Nucleolus Nuclear envelope Chromatin (duplicated) Plasma membrane PROPHASE Early mitotic spindle Aster Centromere Chromosome, consisting of two sister chromatids PROMETAPHASE Fragments of nuclear envelope Kinetochore Nonkinetochore microtubules Kinetochore microtubule – Metaphase – Anaphase – Telophase METAPHASE ANAPHASE Metaphase plate Figure 12.6 Spindle Centrosome at one spindle pole TELOPHASE AND CYTOKINESIS Cleavage furrow Daughter chromosomes Nuclear envelope forming Nucleolus forming The Mitotic Spindle: A Closer Look • The mitotic spindle: – Is an apparatus of microtubules that controls chromosome movement during mitosis. • Some spindle microtubules: – Attach to the kinetochores of chromosomes and move the chromosomes Centrosome to the metaphase Aster plate Sister chromatids Metaphase Plate Kinetochores Overlapping nonkinetochore microtubules Kinetochores microtubules Microtubules Figure 12.7 0.5 µm Chromosomes Centrosome 1 µm • In anaphase, sister chromatids separate: – And move along the kinetochore microtubules toward opposite ends of the cell EXPERIMENT 1 The microtubules of a cell in early anaphase were labeled with a fluorescent dye that glows in the microscope (yellow). Kinetochore Spindle pole Figure 12.8 • Nonkinetechore microtubules from opposite poles –Overlap and push against each other, elongating the cell • In telophase: –Genetically identical daughter nuclei form at opposite ends of the cell Animal Cells have Centrioles Cell Cycle G0 Enter Mitosis! Interphase Prophase Prophase and Microtubules Metaphase Anaphase Telophase • Cytokinesis: A Closer Look In animal cells – Cytokinesis occurs by a process known as cleavage, forming a cleavage furrow Cleavage furrow 100 µm Contractile ring of microfilaments Figure 12.9 A Daughter cells (a) Cleavage of an animal cell (SEM) • In plant cells, during cytokinesis: – A cell plate forms. Vesicles forming cell plate Wall of patent cell 1 µm Cell plate New cell wall Daughter cells Figure 12.9 B (b) Cell plate formation in a plant cell (SEM) Plant vs. Animal Mitosis • • • • Plant Cells Lack centrioles No aster Assemble membrane components in the interior- cell plate Deposts cellulosenew cell wall. Animal Cells • Use centrioles • Centrioles develop an aster • Actin filaments constrict the cell -cleavage furrow. What’s the overall goal of mitosis? What happens when cells divide out of control? Cell Cycle Control • Internal clocks are not flexible. • Eukaryotic cells use Check Pointsenzymes that survey conditions of the cell and act as “go/no go” switches. • Regulated by feedback from the cell. The Cell Cycle Control System • The sequential events of the cell cycle – Are directed by a distinct cell cycle control system, which is similar to a clock G1 checkpoint Control system G1 M G2 M checkpoint Figure 12.14 G2 checkpoint S • The clock has specific checkpoints: – Where the cell cycle stops until a go-ahead signal is received G0 G1 checkpoint G1 Figure 12.15 A, B (a) If a cell receives a go-ahead signal at the G1 checkpoint, the cell continues on in the cell cycle. G1 (b) If a cell does not receive a go-ahead signal at the G1checkpoint, the cell exits the cell cycle and goes into G0, a nondividing state. Three Principal Checkpoints • G1 Checkpoint (also called START)end of G1/beginning of S- decision to replicate DNA. • Surveys cell size and environmental conditions. G1 Checkpoint Replicate DNA Cell Size? Favorable Conditions? Yes No Grow or G G2 Checkpoint • Occurs at the end of G2 and triggers mitosis. G2 Checkpoint DNA Replicated? Cell Size? Growth Conditions? Mitosis Yes No Pause M Check Point • Occurs at metaphase, triggers exit from mitosis and beginning of G1. M Check Point Are Anaphase All Yes Chromosomes Aligned? No Pause Checkpoints Regulated by Enzymes • Cyclins- proteins that appear and disappear at different points in the cell cycle. • Cyclin-Dependent Kinases(Cdk’s)- enzymes that phosphorylate other enzymes and proteins. Not active w/o cyclins. The activity of cyclins and Cdks fluctuates during the cell cycle (a) Fluctuation of MPF activity and cyclin concentration during the cell cycle M G1 S G2 M G1 S G2 M MPF activity Cyclin Time (b) Molecular mechanisms that help regulate the cell cycle 1 Synthesis of cyclin begins in late S phase and continues through G2. Because cyclin is protected from degradation during this stage, it accumulates. 5 During G , conditions in 1 the cell favor degradation of cyclin, and the Cdk component of MPF is recycled. Cdk Degraded Cyclin Cyclin is degraded 4 During anaphase, the cyclin component Figure 12.16 A, B of MPF is degraded, terminating the M phase. The cell enters the G1 phase. G2 Cdk checkpoint MPF Cyclin 2 Accumulated cyclin molecules combine with recycled Cdk molecules, producing enough molecules of MPF to pass the G2 checkpoint and initiate the events of mitosis. 3 MPF promotes mitosis by phosphorylating various proteins. MPF‘s activity peaks during metaphase. Regulating the Cell Cycle Example: Figure 11.23 • At the G2 checkpoint, use Cdk + cyclin -----> MPF (Mitosis Promoting Factor) Evidence for Cytoplasmic Signals • Molecules present in the cytoplasm – Regulate progress through the cell cycle EXPERIMENTS In each experiment, cultured mammalian cells at two different phases of the cell cycle were induced to fuse. Experiment 1 Experiment 2 S G1 M S M G1 RESULTS S When a cell in the S phase was fused with a cell in G1, the G1 cell immediately entered the S phase—DNA was synthesized. M When a cell in the M phase was fused with a cell in G1, the G1 cell immediately began mitosis— a spindle formed and chromatin condensed, even though the chromosome had not been duplicated. CONCLUSION The results of fusing cells at two different phases of the cell cycle suggest that molecules present in the Figure 12.13 A, B cytoplasm of cells in the S or M phase control the progression of phases. Controlling the Cell Cycle • Growth Factors. Over 50 so far, many work at G1 checkpoint; bind to surface receptors of cells. Ex. PDGF. • Contact Inhibition. Normal cells stop growing when they make contact with other cells; use surface receptors. • Growth factors: – Stimulate other cells to divide EXPERIMENT Scalpels 1 A sample of connective tissue was cut up into small pieces. Petri plate 2 Enzymes were used to digest the extracellular matrix, resulting in a suspension of free fibroblast cells. 3 Cells were transferred to sterile culture vessels containing a basic growth medium consisting of glucose, amino acids, salts, and antibiotics (as a precaution against bacterial growth). PDGF was added to half the vessels. The culture vessels were incubated at 37°C. Figure 12.17 With PDGF Without PDGF • In density-dependent inhibition (contact inhibition): – Crowded cells stop dividing • Most animal cells exhibit anchorage dependence – In which they must be attached to a substratum to divide (a) Normal mammalian cells. The availability of nutrients, growth factors, and a substratum for attachment limits cell density to a single layer. Cells anchor to dish surface and divide (anchorage dependence). When cells have formed a complete single layer, they stop dividing (density-dependent inhibition). If some cells are scraped away, the remaining cells divide to fill the gap and then stop (density-dependent inhibition). Figure 12.18 A 25 µm • Cancer cells – Exhibit neither density-dependent inhibition nor anchorage dependence. Cancer cells do not exhibit anchorage dependence or density-dependent inhibition. (b) Cancer cells. Cancer cells usually continue to divide well beyond a single layer, forming a clump of overlapping cells. Figure 12.18 B 25 µm • Malignant tumors invade surrounding tissues and can metastasize – Exporting cancer cells to other parts of the body where they may form secondary tumors Tumor Lymph vessel Blood vessel Glandular tissue Cancer cell 1 A tumor grows from a single cancer cell. Figure 12.19 2 Cancer cells invade neighboring tissue. 3 Cancer cells spread through lymph and blood vessels to other parts of the body. Metastatic Tumor 4 A small percentage of cancer cells may survive and establish a new tumor in another part of the body. Controlling the Cell Cycle-17.6 lb tumor! How do Growth Factors Work? • G. F.’s allow passage through G1 checkpoint by causing more cyclins to be formed. • Some genes normally stimulate cell division- protooncogenes. Two Types of Cell Division Control • Positive Controls- like growth factors, stimulate cell division. • Negative Controls- like tumor suppressors, prevent cell division. Ex. p53. p53 Tumor Suppressor Delays cycle at G1 until DNA repaired. Is DNA p53 Damaged? If irrepairable,causes apoptosis(programmed cell death). If p53 is not functioning, leads to mutations->cancer. Controlling Cell Growth • The case of retinoblastoma. • Some genes normally inhibit cell division- tumor suppressor genes. • Example: In GO, Rb protein is dephosphorylated and binds to the Myc protein, preventing its promoting of cell division. A Fun Review of the Cell Cycle