Mitosis Vs Meiosis
Mitosis: Meiosis: Interphase Interphase is the period between cell divisions. During this time, chromosomes replicate—each DNA strand unzips into two strands while free-floating bases attach to. Meiosis vs Mitosis. Mitosis and meiosis are two processes by which eukaryotic cells may divide and share several similarities: They are both preceded by interphase (which includes DNA replication) They both divide according to a common pathway.
NOVA Online Life's Greatest Miracle How Cells Divide: Mitosis vs. Meiosis 2 (text version)How Cells Divide: Mitosis vs.
MeiosisPage 2 of 15 MitosisMeiosisInterphaseInterphase is the period between cell divisions. During this time, chromosomes replicate—each DNA strand unzips into two strands while free-floating bases attach to the unzipped strands. The chromosomes are loosely packed and not visible with a microscope.Two pair of centrioles lie just outside the nucleus, next to each other. A centriole is a cylindrical structure within the cell that plays a part in cell reproduction.Interphase IThe activities within this cell are the same as in the mitosis-dividing cell.NOTE: Blue indicates chromosomes from the father; orange indicates chromosomes from the mother.
The titles used for each step—e.g., 'Interphase,' Interphase I'—are those used in biology textbooks. Updated November 2001.
› › ›Cells divide and reproduce in two ways: mitosis and meiosis. Mitosis is a process of cell division that results in two genetically identical daughter cells developing from a single parent cell. Meiosis, on the other hand, is the division of a involving two fissions of the nucleus and giving rise to four, or sex cells, each possessing half the number of of the original cell.Mitosis is used by single-celled organisms to reproduce; it is also used for the organic growth of tissues, fibers, and membranes. Meiosis is found in sexual reproduction of organisms. The male and female sex cells (i.e., egg and sperm) are the end result of meiosis; they combine to create new, genetically different offspring. Differences in PurposeThough both types of cell division are found in many animals, plants, and fungi, mitosis is more common than meiosis and has a wider variety of functions.
Not only is mitosis responsible for asexual reproduction in single-celled organisms, but it is also what enables cellular growth and repair in multicellular organisms, such as humans. In mitosis, a cell makes an exact clone of itself. This process is what is behind the growth of children into adults, the healing of cuts and bruises, and even the regrowth of skin, limbs, and appendages in animals like.Meiosis is a more specific type of cell division (of germ cells, in particular) that results in, either eggs or sperm, that contain half of the chromosomes found in a parent cell. Unlike mitosis with its many functions, meiosis has a narrow but significant purpose: assisting.
It is the process that enables children to be related but still different from their two parents.Meiosis and Genetic DiversitySexual reproduction uses the process of meiosis to increase genetic diversity. Offspring created through asexual reproduction (mitosis) are genetically identical to their parent, but the germ cells created during meiosis are different from their parent cells. Some mutations frequently occur during meiosis. Further, germ cells have only one set of chromosomes, so two germ cells are required to make a complete set of genetic material for the offspring. The offspring is therefore able to inherit from both parents and both sets of grandparents.Genetic diversity makes a population more resilient and adaptable to the environment, which increases chances of survival and for the long term.Mitosis as a form of reproduction for single-cell organisms originated with life itself, around 3.8 billion years ago.
Meiosis is thought to have appeared around 1.4 billion years ago.Mitosis and Meiosis StagesCells spend about 90% of their existence in a stage known as interphase. Because cells function more efficiently and reliably when small, most cells carry out regular metabolic tasks, divide, or die, rather than simply grow larger in the interphase. Cells 'prepare' for division by and duplicating protein-based.
When cell division begins, the cells enter into either mitotic or meiotic phases.In mitosis, the end product is two cells: the original parent cell and a new, genetically identical daughter cell. Meiosis is more complex and goes through additional phases to create four genetically different haploid cells which then have the potential to combine and form a new, genetically diverse diploid offspring. A diagram showing the differences between meiosis and mitosis. Stages of MitosisThere are four mitotic phases: prophase, metaphase, anaphase, and telophase. Have an additional phase, preprophase, that occurs before prophase. During the mitotic prophase, the nuclear membrane (sometimes called 'envelope') dissolves.
Interphase's tightly coils and condenses until it becomes chromosomes. These chromosomes are made up of two genetically identical sister that are joined together by a. Move away from the nucleus in opposite directions, leaving behind a. In metaphase, found on either side of the chromosomes' centromeres help move the chromosomes according to the pull of the opposing centrosomes, eventually placing them in a vertical line down the center of the cell; this is sometimes known as the metaphase plate or spindle equator.
The spindle fibers begin to shorten during anaphase, pulling the sister chromatids apart at their centromeres. These split chromosomes are dragged toward the centrosomes found at opposite ends of the cell, making many of the chromatids briefly appear 'V' shaped. The two split portions of the cell are officially known as 'daughter chromosomes' at this point in the cell cycle. Telophase is the final phase of mitotic cell division. During telophase, the daughter chromosomes attach to their respective ends of the parent cell. Previous phases are repeated, only in reverse.
The spindle apparatus dissolves, and nuclear membranes form around the separated daughter chromosomes. Within these newly formed nuclei, the chromosomes uncoil and return to a chromatin state.
One final process— cytokinesis—is required for the daughter chromosomes to become daughter cells. Cytokinesis is not part of the cell division process, but it marks the end of the cell cycle and is the process by which the daughter chromosomes separate into two new, unique cells. Thanks to mitosis, these two new cells are genetically identical to each other and to their original parent cell; they now enter their own individual interphases.Stages of MeiosisThere are two primary meiosis stages in which cell division occurs:. Both primary stages have four stages of their own. Meiosis 1 has prophase 1, metaphase 1, anaphase 1, and telophase 1, while meiosis 2 has prophase 2, metaphase 2, anaphase 2, and telophase 2. Cytokinesis plays a role in meiosis, too; however, as in mitosis, it is a separate process from meiosis itself, and cytokinesis shows up at a different point in the division.Meiosis I vs. Meiosis IIFor a more detailed explanation, see.In meiosis 1, a germ cell divides into two cells (halving the number of chromosomes in the process), and the main focus is on the exchange of similar genetic material (e.g., a hair gene; see also ).
In meiosis 2, which is quite similar to mitosis, the two diploid cells further divide into four cells.Stages of Meiosis I. The first meiotic phase is prophase 1.
As in mitosis, the nuclear membrane dissolves, chromosomes develop from the chromatin, and the centrosomes push apart, creating the spindle apparatus. From both parents pair up and exchange DNA in a process known as. This results in genetic diversity.
These paired up chromosomes—two from each parent—are called tetrads. In metaphase 1, some of the spindle fibers attach to the chromosomes' centromeres. The fibers pull the tetrads into a vertical line along the center of the cell. Anaphase 1 is when the tetrads are pulled apart from each other, with half the pairs going to one side of the cell and the other half going to the opposite side. It is important to understand that whole chromosomes are moving in this process, not chromatids, as is the case in mitosis. At some point between the end of anaphase 1 and the developments of telophase 1, cytokinesis begins splitting the cell into two daughter cells. In telophase 1, The spindle apparatus dissolves, and nuclear membranes develop around the chromosomes that are now found at opposite sides of the parent cell / new cells.Stages of Meiosis II.
In prophase 2, centrosomes form and push apart in the two new cells. A spindle apparatus develops, and the cells' nuclear membranes dissolve. Spindle fibers connect to chromosome centromeres in metaphase 2 and line the chromosomes up along the cell equator. During anaphase 2, the chromosomes' centromeres break, and the spindle fibers pull the chromatids apart. The two split portions of the cells are officially known as 'sister chromosomes' at this point.
As in telophase 1, telophase 2 is aided by cytokinesis, which splits both cells yet again, resulting in four haploid cells called. Nuclear membranes develop in these cells, which again enter their own interphases.References. (Also see ). Anonymous comments (5)June 11, 2013, 7:34amwow this is really helpful thanks!
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