1 / 22

8.2

8.2. Cell Growth and Reproduction. Why Do Cells Divide?. Multicellular organisms have different sizes, growth rates, and timing for cell division. Multicellular organisms divide to replace lost or damaged cells and to allow the organism to grow. Unicellular organisms divide to reproduce

dianne
Télécharger la présentation

8.2

An Image/Link below is provided (as is) to download presentation Download Policy: Content on the Website is provided to you AS IS for your information and personal use and may not be sold / licensed / shared on other websites without getting consent from its author. Content is provided to you AS IS for your information and personal use only. Download presentation by click this link. While downloading, if for some reason you are not able to download a presentation, the publisher may have deleted the file from their server. During download, if you can't get a presentation, the file might be deleted by the publisher.

E N D

Presentation Transcript


  1. 8.2 Cell Growth and Reproduction

  2. Why Do Cells Divide? • Multicellular organisms have different sizes, growth rates, and timing for cell division. • Multicellular organisms divide to replace lost or damaged cells and to allow the organism to grow. • Unicellular organisms divide to reproduce • Cells MUST divide for 2 main reasons: • Not enough DNA to provide the information a cell needs to survive • The surface area of a cell does not increase as fast as the volume of the cell. Diffusion is too slow for the cell to get the nutrients it needs to survive.

  3. Cell Reproduction • The cell theory states that all cells come from preexisting cells and cell division is the process by which new cells are produced from one cell • The result of cell division are identical cells to the original, parent cell • All organisms grow and change with worn-out tissues are repaired or are replaced by newly produced cells

  4. Early biologists observed that before cell division, several short, stringy structures, suddenly appeared in the nucleus and these structures seemed to vanish soon after division of a cell • Chromosomes are structures that contain genetic material that is copied and passed from generation to generation • Because genetic material is crucial to identity of the cell, accurate transmission of chromosomes during cell division is critical • For most of a cell’s lifetime, chromosomes exists as chromatin, long strands of DNA wrapped around proteins called histones

  5. Chromatin actually looks like beads on a string and each bead is a group of histones called a nucleosome • Before the cell can divide, the chromatin must be reorganized and as the nucleus begins to divide, chromosomes take on a different structure in which the chromatin becomes tightly packed. CHROMATID CENTROMERE CHROMATID

  6. The Cell Cycle • The cell cycle is the sequence of growth and division of a cell • A cell goes through 2 general periods: a period of growth and a period of division • The majority of a cell’s life is spent in the growth period known as interphase • The 2nd stage of the cell cycle is mitosis, the process by which two daughter cells are formed, each containing a complete set of chromosomes

  7. Interphase: A Busy Time • Interphase is the busiest phase of the cell cycle and happens in three parts • G1: the cell grows and protein production is high • S phase: the cell copies its chromosomes. DNA synthesis does not occur all through interphase • G3: after the chromosomes have duplicated, the cell enters another shorter growth period in which mitochondria and other organelles are manufactured and cell parts needed for cell division are assembled

  8. Prophase: 1st phase of mitosis • The longest phase of mitosis • The long, stringy chromatin coils up into visible chromosomes • Each duplicated chromosome is made up of 2 halves known as sister chromatids, which are exact copies of each other and are formed when DNA is copied during interphase • Sister chromatids are held together by a structure called the centromere, which plays a role in movement during mitosis • the nucleus begins to disappear as the nuclear envelope and nucleolus disintegrate

  9. In animal cells, the centrioles begin to migrate to opposite ends • as the centrioles move to opposite ends, the spindle, begins to form Prophase: Prepare

  10. Metaphase: 2nd phase of mitosis • The chromosomes become attached to the spindle fibers by their centromeres • The chromosomes are pulled apart by the spindle fibers and begin to line up on the equator of the spindle • Each sister chromatid is attached to its own spindle fiber and they are pulled in opposite directions • This arrangement ensures that each new cell receives an identical and complete set of chromosomes

  11. Metaphase: Middle

  12. Anaphase: 3rd phase of mitosis • The separation of sister chromatids marks the beginning of anaphase • the centromeres split apart and chromatid pairs from each chromosome separate from each other • The chromatids are pulled apart by the shortening of the microtubules in the spindle fibers

  13. Anaphase: Apart

  14. Telophase: 4th phase of mitosis • Telophase begins as chromatids reach the opposite poles of the cell • Many of the changes that occurred during prophase are reversed as the new cells prepare for their own independent existence • The chromosomes unwind so they can begin to direct the metabolic activities of the new cells • The spindle breaks down, the nucleolus reappears, and a new nuclear envelope forms around each set of chromosomes • A new double membrane begins to form between the 2 new nuclei

  15. Telophase: Tear Apart

  16. Cytokinesis • 3rd phase of the cell cycle, cytokinesis is the process in which the cell’s cytoplasm divides • Cytokinesis differs between plant and animal cells • In animal cells towards the end of telophase, the plasma membrane pinches in along the equator • Because plant cells have a cell wall, the plasma membrane does not pinch in, rather a structure called the cell plate is laid down across the cell’s equator • A new cell membrane forms around each cell and new cell walls form on each side of the cell plate until separation is complete

  17. Results of Mitosis • Mitosis guarantees genetic continuity • In unicellular organisms, the organism remains a single cell it just simply multiplied • In multicellular organisms, cell growth and reproduction result in groups of cells that work together as tissue to perform a specific function • Tissues organize to form organs • Multiple organs work together to form organ systems • Organ systems work together for the survival of the organism

  18. There are roughly 200 different types of human cells. Most cell types divide in very young children as they grow, but in the adult human, there are cells that (1) do not divide, (2) can be forced to divide but usually do not, and (3) cells that are constantly being renewed at various rates… then there are the unique cases of cancer cells and stem cells for example. • Don’t Divide: nerve, brain, and heart muscle cells • Forced: liver and kidney cells • Constant: skin and blood cells, cells in the lining of your gut

More Related