Cell biology notes gametogenesis
The gametogenesis (Gr.,gamos=marriage; genesis= origin) is the process of gamete formation in the sexually reproducing animals. The sexually reproducing animals contain two types of cells in their body, e.g., somatic cells and the germinal cells. Both types of cells have diploid number of chromosomes but each type has its different destiny. The somatic cells form various organs of the body and provide a phase for the maturation, development and formation of the germinal cells. The somatic cells always multiply by mitotic division. The germinal cells form the gonads (testes and ovaries) in the animal body. These cells produce the gamete cells by successive mitotic and meiotic divisions. The male gamete is known as spermatozoon or sperm and the female gamete is known as ovum or egg. The process of sperm production is known as the spermatogenesis (Gr., sperma= sperm or seed; genesis= origin) and the process of production of ovum is known as oogenesis (Gr., oon= egg; genesis= origin). Both the processes can be studied in detail under separate headings.
SPERMATOGENESIS
The process of spermatogenesis occurs in the male gonads or testes. The testes of the vertebrates are composed of many seminiferous tubules which are lined by the cells of germinal epithelium. The cells of the germinal epithelium form sperms by the process of spermatogenesis. But in certain animals, e.g., mammals and Mollusca, etc., there are somatic cells lying in between germinal cells, these somatic cells are known as Sertoli cells. The Sertoli cells anchor the differentiating cells and provide nourishment to the developing sperms. 1. Formation of spermatids; 2. Spermiogenesis.
1. Formation of Spermatids The male germinal cells which produce the sperms are known as the primary germinal cells or primordial cells. The primordial cells pass through following three phases for the formation of spermatids : (i) Multiplication phase. The undifferentiated germ cells or primordial cells contain large-sized and chromatin-rich nuclei. These cells multiply by repeated mitotic divisions and produce the cells which are known as the spermatogonia (Gr.,sperma=sperm or seed; gone=offspring). Each spermatogonium is diploid and contains 2X number of chromosomes. (ii) The growth phase. In the growth phase, the spermatogonial cells accumulate large amount of nutrition and chromatin material. Now each spermatogonial cell is known as the primary spermatocyte. (iii) The maturation phase. The primary spermatocytes are ready for first meiotic or maturation division. The homologous chromosomes start pairing (synapsis), each homologous chromosome splits longitudinally and by the chiasma formation the exchange of genetic material or crossing over takes place between the chromatids of the homologous chromosomes. The DNA amount is duplicated in the beginning of the division. By first meiotic division or homotypic division two secondary spermatocytes are formed. Each secondary spermatocyte is haploid and contains x number of chromosomes. Each secondary spermatocyte passes through the second maturation or second meiotic or heterotypic division and produces two spermatids. Thus, by a meiotic or maturation division a diploid spermatogonium produces four haploid spermatids. These spermatids cannot act directly as the gametes so they have to pass through the next phase, the spermiogenesis.
2. Spermiogenesis The metamorphosis or differentiation of the spermatids into the sperms is known as spermiogenesis. Because the sperm or spermatozoon is a very active and mobile cell so to provide great amount of mobility to the sperm, the superfluous material of the developing sperms is discarded. For the reduction of the weight of the sperms following changes occur in the spermatids: (i) Changes in the nucleus. The nucleus loses water from the nuclear sap, shrinks and assumes different shapes in the different animals. The sperm nucleus in man and bull becomes ovoid and laterally flattened. In rodents and amphibians the sperm nucleus becomes scimitar-shaped withpointed tip. In birds and molluscsthe nucleus becomes spirally twisted like a cork screw. The bivalve mollusks have the round sperm nucleus. The shape of the nucleus also determines the shape of the sperm head which becomes fully adopted for the active propulsion through the water. The RNA contents of the nucleus and the nucleolus are greatly reduced. The DNA becomes more concentrated and the chromatin material becomes losely packed into small volume. (ii) Acrosome formation. The acrosome occurs at the anterior side of the sperm nucleus and contains protease enzymes which help its easy penetration inside the egg. The acrosome is formed by the Golgi apparatus. The Golgi apparatus is concentrated near the anterior end of the sperm nucleus to form the acrosome. One or two vaculoes of the apparatus become large and occupy the place between the tubules of Golgi apparatus. Soon after a dense granule known as the proacrosomal granule develops inside the vacuole.which is rich in the mucopolysaccharides. The proacrosomal granule attaches with the anterior end of the nucleus and enlarges into the acrosome. The membranes of Golgi vacuoles form the double membrane (unit membrane of lipoprotein) sheath around the acrosome and forms the cap-like structure of the spermatozoa. The rest of the Golgi apparatus becomes reduced and discarded from the sperm as Golgi rest. In the sperms of certain animals an acrosomal cone or axial body also develops in between the acrosome and the nucleus. (iii) The centrioles. The two centrioles of the spermatids become arranged one after the other behind the nucleus. The anterior one is known as the proximal centriole and the posterior one is known as the distal centriole. The distal centriole changes into the basal bodies and gives rise to the axial filament of the sperm. The axial filament or the flagellum is composed of a pair of central longitudinal fibres and nine peripheral fibres. The distal centriole and the basal part of the axial filament occur in the middle piece of the spermatozoa. The mitochondria of the spermatids fuse together and twist spirally around the axial filament.Thus, most of the cytoplasmic portion of the spermatid except the nucleus, acrosome, centriole,mitochondria and axial filament is discarded during the spermiogenesis.
OOGENESIS
The process of oogenesis occurs in the cells of the germinal epithelium of the ovary, such cells are known as primordial germinal cells. The oogenesis is completed in the following three successive stages :
1. Multiplication phase;
2. Growthphase; 3. Maturation phase.
1. Multiplication Phase The primordial germinal cells divide repeatedly to form the oogonia (Gr., oon=egg). The oogonia multiply by the mitotic divisions and form the primary oocytes which pass through the growth phase.
2. Growth Phase The growth phase of the oogenesis is comparatively longer than the growth phase of the spermatogenesis. In the growth phase, the size of the primary oocyte increases enormously. For Eg., the primary oocyte of the frog in the beginning has the diameter about 50 mm but after the growth phase the diameter of the mature egg reaches about 1000mm to 2000mm. In the primary oocyte, large amount of fats and proteins becomes accumulated in the form of yolk and due to its heavy weight (or gravity) it is usually concentrated towards the lower portion of the egg forming the vegetal pole. The portion of the cytoplasm containing the egg pronucleus remains often separated from the yolk and occurs towards the upper side of egg forming the animal pole. The cytoplasm of the oocyte becomes rich in RNA, DNA, ATP and enzymes. Moreover, the mitochondria, Golgi apparatus, ribosomes, etc., become concentrated in the cytoplasm of the oocyte. In certain oocytes (Amphibia and birds) the mitochondria become accumulated at some place in the oocyte cytoplasm and forming the mitochondrial clouds. During the growth phase, tremendous changes also occur in the nucleus of the primary oocyte.The nucleus becomes large due to the increased amount of the nucleoplasm and is called germinal vesicle. The nucleolus becomes large or its number is multiplied due to excessive synthesis of ribosomal RNA by rDNA of nucleolar organizer region of chromosomes. The chromosomes change their shape and become giant lampbrush chromosomes which are directly related with increased transcription of mRNA molecules and active protein synthesis in the cytoplasm. When the growth of the cytoplasm and nucleus of the primary oocyte is completed it becomes ready for the maturation phase.
3. Maturation Phase
The maturation phase is accompanied by the maturation or meiotic division. The maturation division of the primary oocyte differs greatly from the maturation division of the spermatocyte. Here after the meiotic division of the nucleus, the cytoplasm of the oocyte divides unequally to form a single largesized haploid egg and three small haploid polar bodies or polocytes at the end. This type of unequal division has the great significance for the egg. If the equal divisions of the primary oocyte might have been resulted, the stored food amount would have been distributed equally to the four daughter cells and which might prove insufficient for the developing embryo. Therefore, these unequal divisions allow one cell out of the four daughter cells to contain most of the cytoplasm and reserve food material which is sufficient for the developing embryo. (i) First maturation division. During the first maturation division or first meiosis, the homologous chromosomes of the primary oocyte nucleus pass through the pairing or synapsis, duplication, chiasma formation and crossing over. Soon after the nuclear membrane breaks and the bivalent chromosomes move towards the opposite poles due to contraction of chromosomal fibres.
A new nuclear envelope is developed around the daughter chromosomes by the endoplasmic reticulum. After the karyokinesis the unequal cytokinesis occurs and a small haploid polar body or polocyteand a large haploid secondary oocyte or ootid are formed. (ii) Second meiotic division. The haploid secondary oocyte and first polocyte pass through the second meiotic division. Due to the second meiotic division the secondary oocyte forms a mature egg and a second polocyte. By the second meiotic division the first polocyte also divides into two secondary polocytes : These polocytes ooze out from the egg and degenerate while the haploid eggcell becomes ready for the fertilization.
The gametogenesis (Gr.,gamos=marriage; genesis= origin) is the process of gamete formation in the sexually reproducing animals. The sexually reproducing animals contain two types of cells in their body, e.g., somatic cells and the germinal cells. Both types of cells have diploid number of chromosomes but each type has its different destiny. The somatic cells form various organs of the body and provide a phase for the maturation, development and formation of the germinal cells. The somatic cells always multiply by mitotic division. The germinal cells form the gonads (testes and ovaries) in the animal body. These cells produce the gamete cells by successive mitotic and meiotic divisions. The male gamete is known as spermatozoon or sperm and the female gamete is known as ovum or egg. The process of sperm production is known as the spermatogenesis (Gr., sperma= sperm or seed; genesis= origin) and the process of production of ovum is known as oogenesis (Gr., oon= egg; genesis= origin). Both the processes can be studied in detail under separate headings.
SPERMATOGENESIS
The process of spermatogenesis occurs in the male gonads or testes. The testes of the vertebrates are composed of many seminiferous tubules which are lined by the cells of germinal epithelium. The cells of the germinal epithelium form sperms by the process of spermatogenesis. But in certain animals, e.g., mammals and Mollusca, etc., there are somatic cells lying in between germinal cells, these somatic cells are known as Sertoli cells. The Sertoli cells anchor the differentiating cells and provide nourishment to the developing sperms. 1. Formation of spermatids; 2. Spermiogenesis.
1. Formation of Spermatids The male germinal cells which produce the sperms are known as the primary germinal cells or primordial cells. The primordial cells pass through following three phases for the formation of spermatids : (i) Multiplication phase. The undifferentiated germ cells or primordial cells contain large-sized and chromatin-rich nuclei. These cells multiply by repeated mitotic divisions and produce the cells which are known as the spermatogonia (Gr.,sperma=sperm or seed; gone=offspring). Each spermatogonium is diploid and contains 2X number of chromosomes. (ii) The growth phase. In the growth phase, the spermatogonial cells accumulate large amount of nutrition and chromatin material. Now each spermatogonial cell is known as the primary spermatocyte. (iii) The maturation phase. The primary spermatocytes are ready for first meiotic or maturation division. The homologous chromosomes start pairing (synapsis), each homologous chromosome splits longitudinally and by the chiasma formation the exchange of genetic material or crossing over takes place between the chromatids of the homologous chromosomes. The DNA amount is duplicated in the beginning of the division. By first meiotic division or homotypic division two secondary spermatocytes are formed. Each secondary spermatocyte is haploid and contains x number of chromosomes. Each secondary spermatocyte passes through the second maturation or second meiotic or heterotypic division and produces two spermatids. Thus, by a meiotic or maturation division a diploid spermatogonium produces four haploid spermatids. These spermatids cannot act directly as the gametes so they have to pass through the next phase, the spermiogenesis.
2. Spermiogenesis The metamorphosis or differentiation of the spermatids into the sperms is known as spermiogenesis. Because the sperm or spermatozoon is a very active and mobile cell so to provide great amount of mobility to the sperm, the superfluous material of the developing sperms is discarded. For the reduction of the weight of the sperms following changes occur in the spermatids: (i) Changes in the nucleus. The nucleus loses water from the nuclear sap, shrinks and assumes different shapes in the different animals. The sperm nucleus in man and bull becomes ovoid and laterally flattened. In rodents and amphibians the sperm nucleus becomes scimitar-shaped withpointed tip. In birds and molluscsthe nucleus becomes spirally twisted like a cork screw. The bivalve mollusks have the round sperm nucleus. The shape of the nucleus also determines the shape of the sperm head which becomes fully adopted for the active propulsion through the water. The RNA contents of the nucleus and the nucleolus are greatly reduced. The DNA becomes more concentrated and the chromatin material becomes losely packed into small volume. (ii) Acrosome formation. The acrosome occurs at the anterior side of the sperm nucleus and contains protease enzymes which help its easy penetration inside the egg. The acrosome is formed by the Golgi apparatus. The Golgi apparatus is concentrated near the anterior end of the sperm nucleus to form the acrosome. One or two vaculoes of the apparatus become large and occupy the place between the tubules of Golgi apparatus. Soon after a dense granule known as the proacrosomal granule develops inside the vacuole.which is rich in the mucopolysaccharides. The proacrosomal granule attaches with the anterior end of the nucleus and enlarges into the acrosome. The membranes of Golgi vacuoles form the double membrane (unit membrane of lipoprotein) sheath around the acrosome and forms the cap-like structure of the spermatozoa. The rest of the Golgi apparatus becomes reduced and discarded from the sperm as Golgi rest. In the sperms of certain animals an acrosomal cone or axial body also develops in between the acrosome and the nucleus. (iii) The centrioles. The two centrioles of the spermatids become arranged one after the other behind the nucleus. The anterior one is known as the proximal centriole and the posterior one is known as the distal centriole. The distal centriole changes into the basal bodies and gives rise to the axial filament of the sperm. The axial filament or the flagellum is composed of a pair of central longitudinal fibres and nine peripheral fibres. The distal centriole and the basal part of the axial filament occur in the middle piece of the spermatozoa. The mitochondria of the spermatids fuse together and twist spirally around the axial filament.Thus, most of the cytoplasmic portion of the spermatid except the nucleus, acrosome, centriole,mitochondria and axial filament is discarded during the spermiogenesis.
OOGENESIS
The process of oogenesis occurs in the cells of the germinal epithelium of the ovary, such cells are known as primordial germinal cells. The oogenesis is completed in the following three successive stages :
1. Multiplication phase;
2. Growthphase; 3. Maturation phase.
1. Multiplication Phase The primordial germinal cells divide repeatedly to form the oogonia (Gr., oon=egg). The oogonia multiply by the mitotic divisions and form the primary oocytes which pass through the growth phase.
2. Growth Phase The growth phase of the oogenesis is comparatively longer than the growth phase of the spermatogenesis. In the growth phase, the size of the primary oocyte increases enormously. For Eg., the primary oocyte of the frog in the beginning has the diameter about 50 mm but after the growth phase the diameter of the mature egg reaches about 1000mm to 2000mm. In the primary oocyte, large amount of fats and proteins becomes accumulated in the form of yolk and due to its heavy weight (or gravity) it is usually concentrated towards the lower portion of the egg forming the vegetal pole. The portion of the cytoplasm containing the egg pronucleus remains often separated from the yolk and occurs towards the upper side of egg forming the animal pole. The cytoplasm of the oocyte becomes rich in RNA, DNA, ATP and enzymes. Moreover, the mitochondria, Golgi apparatus, ribosomes, etc., become concentrated in the cytoplasm of the oocyte. In certain oocytes (Amphibia and birds) the mitochondria become accumulated at some place in the oocyte cytoplasm and forming the mitochondrial clouds. During the growth phase, tremendous changes also occur in the nucleus of the primary oocyte.The nucleus becomes large due to the increased amount of the nucleoplasm and is called germinal vesicle. The nucleolus becomes large or its number is multiplied due to excessive synthesis of ribosomal RNA by rDNA of nucleolar organizer region of chromosomes. The chromosomes change their shape and become giant lampbrush chromosomes which are directly related with increased transcription of mRNA molecules and active protein synthesis in the cytoplasm. When the growth of the cytoplasm and nucleus of the primary oocyte is completed it becomes ready for the maturation phase.
3. Maturation Phase
The maturation phase is accompanied by the maturation or meiotic division. The maturation division of the primary oocyte differs greatly from the maturation division of the spermatocyte. Here after the meiotic division of the nucleus, the cytoplasm of the oocyte divides unequally to form a single largesized haploid egg and three small haploid polar bodies or polocytes at the end. This type of unequal division has the great significance for the egg. If the equal divisions of the primary oocyte might have been resulted, the stored food amount would have been distributed equally to the four daughter cells and which might prove insufficient for the developing embryo. Therefore, these unequal divisions allow one cell out of the four daughter cells to contain most of the cytoplasm and reserve food material which is sufficient for the developing embryo. (i) First maturation division. During the first maturation division or first meiosis, the homologous chromosomes of the primary oocyte nucleus pass through the pairing or synapsis, duplication, chiasma formation and crossing over. Soon after the nuclear membrane breaks and the bivalent chromosomes move towards the opposite poles due to contraction of chromosomal fibres.
A new nuclear envelope is developed around the daughter chromosomes by the endoplasmic reticulum. After the karyokinesis the unequal cytokinesis occurs and a small haploid polar body or polocyteand a large haploid secondary oocyte or ootid are formed. (ii) Second meiotic division. The haploid secondary oocyte and first polocyte pass through the second meiotic division. Due to the second meiotic division the secondary oocyte forms a mature egg and a second polocyte. By the second meiotic division the first polocyte also divides into two secondary polocytes : These polocytes ooze out from the egg and degenerate while the haploid eggcell becomes ready for the fertilization.
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