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Chapter 8. Sections 1-3 Chromosomes ,Cell Division & Meiosis . Section 1 Chromosomes: Objectives. Describe the structure of a chromosome Identify the differences in structure between prokaryotic chromosomes and eukaryotic chromosomes Compare the numbers of chromosomes in different species
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Chapter 8 Sections 1-3 Chromosomes ,Cell Division & Meiosis
Section 1 Chromosomes: Objectives • Describe the structure of a chromosome • Identify the differences in structure between prokaryotic chromosomes and eukaryotic chromosomes • Compare the numbers of chromosomes in different species • Explain the differences between sex chromosomes and autosomes • Distinguish between diploid and haploid cells
Chromosome Structure DNA Coiling Animation • Chromosomes are rod-shaped structures made of DNA and protein. • In eukaryotes, DNA wraps around proteins called histones to help maintain the compact structure of chromosomes so it fits within the cell • Each human cell has ~1.8m of DNA; wound on histones it’s about 0.09mm
Chromosome Structure • Chromatids are duplicate halves of a chromosome • The point at which both chromatids are attached is called centromere
Chromosome Structure • Looking more closely at prokaryotes and eukaryotes… • Prokaryotic chromosomes are simpler than eukaryotic chromosomes
Chromosome Numbers • Every species has a characteristic number of chromosomes in each cell
Chromosome Numbers • Sex chromosomes are chromosomes that determine the sex of an organism • In humans, sex chromosomes are either X or Y • Females: XX; Males: XY • All other chromosomes in an organism are autosomes • Humans have 46 chromosomes total: • 2 sex chromosomes • 44 autosomes • A karyotype is a pictomicrograph of chromosomes in a normal dividing cell found in a human
Chromosome Numbers • Diploid cells: have two homologues of each chromosome, are designated by the symbol ‘2n’, and have chromosomes found in pairs • Haploid cells: are reproductive cells (sperm and egg) in humans, have ½ the number of chromosomes present in a diploid, and are designated by the symbol ‘1n’ • When a sperm cell (1n) and an egg cell (1n) combine, they create a new diploid cell (2n). If they were diploid, the new cell would have too many chromosomes to function
Section 2 Cell Division: Objectives • Describe the events of cell division in prokaryotes • Name the two parts of the cell that are equally divided during cell division in eukaryotes • Summarize the events of interphase • Describe the stages of mitosis • Compare cytokinesis in animal cells with cytokinesis in plant cells • Explain how cell division is controlled
Cell Division in Prokaryotes • Cell division is the process by which cells reproduce themselves • Binary fission is the process of cell division in prokaryotes • Bacteria = prokaryotes → divide by binary fission
Cell Division in Eukaryotes • Cell Cycle • The cell cycle is the repeating set of 5 events in the life of a cell • It consists of interphase and cell division • Cell division in eukaryotes includes: • Nuclear division (mitosis) • Division of the cytoplasm (cytokinesis)
Cell Division in Eukaryotes • The cell cycle starts at G1 and continues through cytokinesis • In order: G1-S-G2-M-C • Interphaseconsists of: • G1: growth • S: DNA replication (“synthesis”) • G2: preparation for cell division • Interphase occupies most of a cell’s life How the Cell Cycle Works Animation
Stages of Mitosis • Mitosis is divided into 4 stages: • Prophase • Metaphase • Anaphase • Telophase • Mitosis results in two offspring cells identical to the original cell
Stages of Mitosis • Phase 1: Prophase • Uncoiled DNA coils into chromosomes inside the nuclear membrane • Nuclear membrane breaks down and disappears • Centrosomes move to the poles of the cell and start forming spindle fibers (specialized microtubules) • Phase 2: Metaphase • Fibers from centrosomes move chromosomes to the center of the splitting cell
Stages of Mitosis • Phase 3: Anaphase • Chromatids of each chromosome split from their centromere, becoming individual chromosomes • Phase 4: Telophase • Individual chromosomes reach either end of the original cell • Spindle fibers disassemble • Chromosomes are packed together in a nuclear envelope
Cytokinesis • Cytokinesis • NOT a phase of mitosis • Splits a cell into two cells that are genetically identical to original cell How the Cell Cycle Works Animation
Stages of Mitosis Prophase Interphase Metaphase Cytokinesis Anaphase Telophase
Stages of Mitosis • Put the four pictures in order. • At which stage are the centromeres dividing? • Which picture is the starting point for mitosis?
Stages of Mitosis • Put the four pictures in order. • 3, 2, 1, 4 • At which stage are the centromeres dividing? • 1 (anaphase) • Which picture is the starting point for mitosis? • 3 (prophase)
Cytokinesis – Plants v. Animals • During cytokinesis in animal cells, a cleavage furrow pinches in and eventually separates the diving cell into two cells
Cytokinesis – Plants v. Animals • During cytokinesis in animal cells, a cleavage furrow pinches in and eventually separates the diving cell into two cells • In plant cells, a cell plate separates the dividing cells into two cells and eventually transforms into a cell wall
Control of Cell Division • Cell division in eukaryotes is controlled by many proteins • Control occurs at three main checkpoints: • G1: if cell is healthy and has suitable size, proteins initiate DNA synthesis (S phase starts). It not, division stops. • G2: DNA repair enzymes check DNA replication. If good, cycle continues; if not, division stops. • Mitosis checkpoint: if the cell passes this checkpoint, proteins signal the cell to exit mitosis and it enters G1 again.
When Control is Lost: Cancer • Cancer may result if cells do not respond to control mechanisms • Cancer is uncontrolled cell growth • Some mutations cause cancer by overproducing growth-promoting molecules leading to increased cell division • Other mutations may interfere with the ability of control proteins to slow or stop the cell cycle
Section 3 Meiosis: Objectives • Compare the end products of meiosis with those of mitosis • Summarize the events of meiosis I • Explain crossing-over and how it contributes to the production of unique individuals • Summarize the events of meiosis II • Compare spermatogenesis and oogenesis • Define sexual reproduction
Formation of Haploid Cells • Meiosis is the process of nuclear division that reduces the number of chromosomes in new cells to half the number in the original cell. • Cells undergoing meiosis divide twice so diploid (2n) cells that divide meiotically produce four haploid (1n) cells instead of two diploid (2n) cells • Meiosis results in four haploid cells (gametes) and not two diploid cells as in mitosis
Meiosis I • Meiosis I includes prophase I, metaphase I, anaphase I, and telophase I • Be careful: these are not exactly the same as the mitosis phases! • Crossing over is when homologous chromosomes exchange corresponding segments of genetic material (DNA) during prophase I resulting in genetic recombination • Crossing over is a source of variation in a species!
Meiosis I • Prophase I: DNA coils into chromosomes which line up next to their homolog (this does not happen in mitosis!). This pairing up is called synapsis. Each pair of homologue chromosomes is called a tetrad. During synapsis, the chromatids in the pairs twist around each other and cross over. • Metaphase I: tetrads line up randomly along the midline of the dividing cell. Spindle fibers from the poles connect to the chromosomes.
Meiosis I • Anaphase I: each homologous chromosome moves to the opposite pole of the dividing cell. • The random separation of homologous chromosomes is called independent assortment and results in genetic variation • Telophase I & Cytokinesis I: the chromosomes reach opposite ends of the cell and cytokinesis begins. The new cells are haploid.
Meiosis I Summary • Meiosis I: the original cell produces 2 new cells, each containing one chromosome from each homologous pair • The new cells contain half the number of chromosomes, but each contains two copies (as chromatids) because the original cell copied its DNA before meiosis I Meiosis and Crossing Over
Meiosis II • Meiosis II occurs in each cell formed during meiosis I • It is NOT preceded by the copying of DNA • Meiosis II includes prophase II, metaphase II, anaphase II, and telophase II • Four new haploid cells result
Meiosis II • Prophase II: spindle fibers from and begin to move chromosomes toward the midline of the dividing cell. • Metaphase II: chromosomes move to the midline of the dividing cell, with each chromatid facing the opposite end of the dividing cell.
Meiosis I • Anaphase II: chromatids separate and move toward opposite poles of the cell. • Telophase II: a nuclear membrane forms around the chromosomes in each of the four new (almost) cells • Cytokinesis II: forms the four new cells. Each cell contains half of the original cell’s number of chromosomes
The Chromosome Thing: NOVA Comparison Animation
Development of Gametes • Spermatogenesis is the process by which sperm cells are produced. • Oogenesis is that process that produces mature egg cells.
Sexual Reproduction • Sexual reproduction is the formation of offspring through meiosis and the union of a sperm and an egg. • Offspring produced by sexual reproduction are genetically different from the parents.