Cellular Division

1. Cellular Division

2. I. Introduction • According to the CELL THEORY, new cells • are only produced by existing cells… • THUS, cell division is essential for the • continuation of life! • Why do cells DIVIDE? • Maintain Homeostasis • Reproduction: create new,independent • organisms (i.e. prokaryotes) •  divide by binary fission • 3. Growth and repair of damage cells • (e.g. next slide)

4. About 2 trillion cells are produced by an • adult human body every day. • These new cells are formed when • older cells REPRODUCE (i.e. divide), • which is known as CELL DIVISION.  When cells divide, the DNA is: 1. replicated (i.e. copied) 2. distributed - each new cell receives a complete set (copy) of parent DNA

5. Cell Division involves DIFFERENTIATION • Differentiation is the process by which • cells grow into specialized tissues When cells differentiate, they develop specific structures or contain more of a certain organelle that allow them to perform particular functions in the body Example: - RBC’s have large amount of hemoglobin enabling them to carry large amts of O2 - Nerve cells have special receptors to react to stimuli and conduct impulses - Muscle cells have large amounts of mitochondria for extra ATP production

6. Cell Differentiation

7.  Differentiation involves SPECIALIZATION • - Due to the complexity of multicellular • organisms, cells must become highly • organized, in which their cells perform • specific functions • - It means that every cell doesn’t perform • the exact same function all of the time, • this would waste NRG • Thus, cells can shut off certain genes: • lung cells don’t need proteins used by liver • hair cells don’t need dental enamel

8. Cell Specialization

9. There are two phases of cell division: • 1. Nuclear Division • a. division of the genetic material • (i.e. nucleus) • b. two types: • Mitosis – produces two • genetically identical nuclei 2. Meiosis – produces 4 nuclei w/ half the genetic material as the original cell 2. Cytoplasmic Division (Cytokinesis)  divides the cytoplasmic contents

10. II. VOCABULARY!!!!! The “uncoiled” complex of DNA wrapped around proteins (similar to plate of tangled spaghetti) • Chromatin – • Histones – 8 proteins that form • a core that DNA wraps itself • around. Why does DNA do this? • It’s too large, needs to be wound up to fit into nucleus 2. Nucleosome – the complex of DNA wrapped around histones  strung together like a thin strand of beads

13. B. Chromatid – 1. A single strand of tightly coiled up chromatin

14. C. Chromosome - • 1. A tightly coiled structure of DNA • and proteins which contains genes • 2. When DNA replicates; chromosomes • consist of 2 chromatid strands • (i.e. sister chromatids, exact copies)  centromere – the region on a chromosome where sister chromatids are attached

17. III. Chromosome # A. Humans contain two types of cells: 1. SEX CELLS (a.k.a. gametes)  the egg and sperm 2. SOMATIC CELLS (a.k.a. body cells)  Any cell that is not egg or sperm B. Humans have 2 types of chromosomes: 1. sex chromosomes (i.e. X and Y) 2. autosomes – all other chromosomes

18. C. Sets of chromosomes • Every human somatic cell has 2 SETS • (i.e. copies, 1 from MOM & 1 from DAD) • of 23 different chromosomes •  23 pairs of Homologous chromosomes • (identical in size, shape, genetic info, • genes found in same location) • - 22 pairs of autosomes • - 1 pair of sex chromosomes •  TOTAL = 46 CHROMOSOMES

19. 2. Every human sex cell has only ONE SET of chromosomes (i.e. 23 TOTAL)  Sex cells fuse together during FERTILIZATION to form a ZYGOTE, which now has 46 chromosomes.

20. 3. PLOIDY Levels  represents the number of complete sets of chromosomes present in an organism’s cells. • Sex cells (i.e. gametes) are: •  HAPLOID (n) = • b. Somatic cells are: •  DIPLOID (2n) = • What about strawberries? 23 chromosomes 46 chromosomes • Octoploid (8n)

21. 4. KARYOTYPE – a photograph that shows the 23 sets of chromosomes arranged by size 22 pairs autosomes 1 pair sex-chrom.

22. D. Changes to chromosomes (Disorders) • Disorders can result from STRUCTURAL • mutations (discuss this later…genetics) 2. Disorders can result from mutations in NUMBER (i.e. extra chromosomes). Ex…

23. IV. The Cell Cycle • Background •  Cells are not always engaged • in division; cells go thru • different stages of life… •  some cells’ division is ongoing • (e.g. stem cells – skin, bone, • bone marrow) •  some cells lose ability to divide • (e.g. muscle, neurons, RBC’s)

24. B. Overview of Cell Cycle 1. Definition – the orderly events in the lifetime of a cell 2. One cycle is the period b/n a cells creation by mitosis and its subsequent division into two new daughter cells. 3. Broken into two phases: a. INTERPHASE – the longer period b/n divisions 1. G1 phase – Growth; normal activity 2. S phase – DNA synthesis 3. G2 phase – Preparation for division b. MITOSIS & CYTOKINESIS – nuclear & cytoplasmic division

27. C. Two main stages: 1. Interphase a. cells are NOT dividing b. eukaryotic cells spend most of their life in this stage c. the cell does normal tasks associated w/ its specialized fxns and maintenance d. DNA in the form of chromatin e. three phases: G1, S, G2

28. * the three phases of interphase: G1 (gap/growth 1):  DNA is relaxed & unreplicated (chromatin) in order to direct normal cell activity (e.g. protein synthesis)  organelles are duplicated  G1 checkpoint – ensures that everything is ready for synthesis  S-cyclins – proteins that help activate a protein complex called MPF. An active MPF then activates multiple other enzymes in a cascade effect. This essentially signals DNA to move into the next phase (synthesis/replication)

30. S phase (DNA Synthesis)  all 46 chromosomes and the DNA they contain will be replicated  each chromosome is now composed of sister chromatids  MPF will begin to degrade the S-cyclins and once again becomes inactive

32. G2 (gap/growth 2)  the cell “double checks” the duplicated chromosomes and other contents & repairs any errors  G2 checkpoint – ensures the cell is ready for mitosis  M-cyclins will activate a different MPF complex, creating another cascade which tells the cell to move into the final phase (i.e. mitosis)

34. 2. Mitosis  the contents of the nucleus will be divided into 2 genetically identical daughter cells  M checkpoint – ensures that cell is ready to complete division  MPF will degrade the M-cyclins and become inactive  cells re-enter G1 phase after finish dividing

37. G0 (gap/growth 0)  Cells that cease cell division will enter this phase and remain there until cell death (e.g. RBC)

38. http://highered.mcgraw-hill.com/sites/0072495855/student_view0/chapter2/animation__how_the_cell_cycle_works.htmlhttp://highered.mcgraw-hill.com/sites/0072495855/student_view0/chapter2/animation__how_the_cell_cycle_works.html

39. SOMATIC V. Mitosis (nuclear division of ________ cells)  Definition – the replication & division of ONE PARENT NUCLEUS into 2 IDENTICAL DAUGHTER NUCLEI, each receiving an EXACT COPY of parent’s chromosomes.

40. A. Preparation for mitosis  Interphase 1. nuclear envelope & nucleolus intact 2. “uncoiled” chromatin 3. centrosomes w/ centrioles form (this will direct chromosome mov’t)

42. B. Phases of Mitosis (5 total) 1. Prophase: longest * centrosomes move toward opposite poles * spindle fibers begin to form * chromatin coils tightly (chromosomes now visible; 2 sister chromatids) Early prophase

43. Late Prophase: * kinetochores develop on centromeres (this is where spindle fibers will attach)

45. 2. Prometaphase * nuclear envelope & nucleolus dismantle * spindle fibers attach to kinetochores and begin moving chromosomes toward center of cell

46. 3. Metaphase * all chromosomes are aligned in the in the center of the cell (equatorial plate)

48. 4. Anaphase * centromeres divide * spindles shorten & pull chromatids apart * each chromatid, now a daughter chromosome, moves to opposite poles * “V-shaped” (centromeres being pulled) (20 ATP)

50. 5. Telophase * chromosomes reach poles & spindles break down * chromosomes “uncoil” to form chromatin * nuclear envelope & nucleolus reform