n.
Formation and development of spermatozoa by meiosis and spermiogenesis.
spermatogenetic sper·mat'o·ge·net'ic (-jə-nĕt'ĭk) or sper·mat'o·gen'ic (-jĕn'ĭk) adj.
spermatogenesis
Dictionary:
sper·mat·o·gen·e·sis (spər-măt'ə-jĕn'ĭ-sĭs, spûr'mə-tə-)  |
| Sci-Tech Encyclopedia: Spermatogenesis |
The differentiation of spermatogonial cells (primordial germ cells in the testes) into spermatozoa (see illustration).
Cellular events in human spermatogenesis.
Spermatogonial divisions occur continuously throughout the life of mammals; these divisions both maintain the stem cell population (spermatogonial cells) and supply cells which develop into sperm. Clusters of spermatogonia maintain communication through cytoplasmic bridges, and these groups become primary spermatocytes when they synchronously enter the first meiotic prophase. The first meiotic prophase is characterized by a series of remarkable changes in chromosome morphology, which are identical to those seen in the corresponding stage of oogenesis. The secondary spermatocyte produced by this division then undergoes a division in which the chromosomes are not replicated; the resulting spermatids contain half the somatic number of chromosomes. See also Meiosis.
The spermatids become embedded in the cytoplasm of Sertoli cells, and there undergo the distinctive changes which result in formation of spermatozoa. These morphological transformations include the conversion of the Golgi apparatus into the acrosome and progressive condensation of the chromatin in the nucleus. A centriole migrates to a position distal to the nucleus and begins organizing the axial filament which will form the motile tail of the sperm. Mitochondria may fuse to form a nebenkern as is the case for many vertebrates, or there may be less extensive fusion as in mammals. In all cases the resulting structures become located around the axial filament in the midpiece. The cytoplasm of the spermatid is reflected distally away from the nucleus during spermatid maturation; eventually, most of the cytoplasm is sloughed off and discarded.
The Sertoli cells are thought to provide nutrition for the developing sperm, because their cytoplasm contains large stores of glycogen which diminish as spermatids mature. There is no direct evidence for this nutritive function, but some forms of male sterility are associated with the failure to produce normal Sertoli cells. Electron microscopy has revealed distinct plasma membranes surrounding the two cell types at the points of contact, and thus the Sertoli cell-spermatid relationship is not syncytial as once thought.
Spermatogenesis is cyclical to a varying extent depending on the species, and under endocrine control. Spermatogenesis is maintained and regulated by male steroid hormones such as testosterone, which is produced by the interstitial or Leydig cells found in the connective tissue of the testis. Interstitial cells, in turn, are stimulated by luteinizing hormone (LH) which is produced by the pituitary gland. The male testis-regulating hormone was formerly known as interstital cell-stimulating hormone (ICSH), but it is now known to be identical to LH. See also Gametogenesis.
| Veterinary Dictionary: spermatogenic |
Giving rise to spermatozoa.
- s. cycle — duration of the cycle which separates consecutive cell divisions of spermatogonia (pig is 8 days, sheep 10, cattle 14) to produce spermatocytes.
- s. wave — spermatogenesis occurs in sequential waves along the length of the seminiferous tubules so that spermatozoa are produced in waves; the phenomenon which ensures that spermatozoa are produced continuously, except for seasonal pauses when spermatogenesis is initiated and terminated each year.
| Wikipedia: Spermatogenesis |
Spermatogenesis is the process by which male spermatogonia develop into mature spermatozoa, also known as a sperm cell. Spermatozoa are the mature male gametes in many sexually reproducing organisms. Thus, spermatogenesis is the male version of gametogenesis. In mammals it occurs in the male testes and epididymis in a stepwise fashion, and for humans takes approximately 64 days.[1] Spermatogenesis is highly dependent upon optimal conditions for the process to occur correctly, and is essential for sexual reproduction. It starts at puberty and usually continues uninterrupted until death, although a slight decrease can be discerned in the quantity of produced sperm with increase in age. The entire process can be broken up into several distinct stages, each corresponding to a particular type of cell:
| Cell type | ploidy/chromosomes | chromatids | Process |
| spermatogonium (types Ad, Ap and B) | diploid/46 | 2N | spermatocytogenesis (mitosis) |
| primary spermatocyte | diploid/46 | 4N | spermatidogenesis (meiosis 1) |
| secondary spermatocyte | haploid/23 | 2N | spermatidogenesis (meiosis 2) |
| spermatid | haploid/23 | 1N | spermiogenesis |
| sperm | haploid/23 | 1N | spermiation |
Contents |
Purpose
Spermatogenesis produces mature male gametes, commonly called sperm but specifically known as spermatozoa, which are able to fertilize the counterpart female gamete, the oocyte, during conception to produce a single-celled individual known as a zygote. This is the cornerstone of sexual reproduction and involves the two gametes both contributing half the normal set of chromosomes (haploid) to result in a chromosomally normal (diploid) zygote.
To preserve the number of chromosomes in the offspring – which differs between species – each gamete must have half the usual number of chromosomes present in other body cells. Otherwise, the offspring will have twice the normal number of chromosomes, and serious abnormalities may result. In humans, chromosomal abnormalities arising from incorrect spermatogenesis can result in Down Syndrome, Klinefelter's Syndrome, and spontaneous abortion. Most chromosomally abnormal zygotes will not survive for long after conception; however, dollenme plant reproduction is a little more robust, and viable new species may arise from cases of polyploidy.
Location
Spermatogenesis takes place within several structures of the male reproductive system. The initial stages occur within the testes and progress to the epididymis where the developing gametes mature and are stored until ejaculation. The seminiferous tubules of the testes are the starting point for the process, where stem cells adjacent to the inner tubule wall divide in a centripetal direction—beginning at the walls and proceeding into the innermost part, or lumen—to produce immature sperm. Maturation occurs in the epididymis and involves the acquisition of a tail and hence motility.
Stages
Spermatocytogenesis
Main article: Spermatocytogenesis
Spermatocytogenesis is the male form of gametocytogenesis and results in the formation of spermatocytes possessing half the normal complement of genetic material. In spermatocytogenesis, a diploid spermatogonium which resides in the basal compartment of seminiferous tubules, divides mitotically to produce two diploid intermediate cell called a primary spermatocyte. Each primary spermatocyte then moves into the adluminal compartment of the seminiferous tubules and duplicates its DNA and subsequently undergoes meiosis I to produce two haploid secondary spermatocytes. This division implicates sources of genetic variation, such as random inclusion of either parental chromosomes, and chromosomal crossover, to increase the genetic variability of the gamete.
Each cell division from a spermatogonium to a spermatid is incomplete; the cells remain connected to one another by bridges of cytoplasm to allow synchronous development. It should also be noted that not all spermatogonia divide to produce spermatocytes, otherwise the supply would run out. Instead, certain types of spermatogonia divide to produce copies of themselves, thereby ensuring a constant supply of gametogonia to fuel spermatogenesis.
Spermatidogenesis
Main article: Spermatidogenesis
Spermatidogenesis is the creation of spermatids from secondary spermatocytes. Secondary spermatocytes produced earlier rapidly enter meiosis II and divide to produce haploid spermatids. The brevity of this stage means that secondary spermatocytes are rarely seen in histological preparations.
Spermiogenesis
Main article: Spermiogenesis
During spermiogenesis, the spermatids begin to grow a tail, and develop a thickened mid-piece, where the mitochondria gather and form an axoneme. Spermatid DNA also undergoes packaging, becoming highly condensed. The DNA is packaged firstly with specific nuclear basic proteins, which are subsequently replaced with protamines during spermatid elongation. The resultant tightly packed chromatin is transcriptionally inactive. The Golgi apparatus surrounds the now condensed nucleus, becoming the acrosome. One of the centrioles of the cell elongates to become the tail of the sperm.
Maturation then takes place under the influence of testosterone, which removes the remaining unnecessary cytoplasm and organelles. The excess cytoplasm, known as residual bodies, is phagocytosed by surrounding Sertoli cells in the testes. The resulting spermatozoa are now mature but lack motility, rendering them sterile. The mature spermatozoa are released from the protective Sertoli cells into the lumen of the seminiferous tubule in a process called spermiation.
The non-motile spermatozoa are transported to the epididymis in testicular fluid secreted by the Sertoli cells with the aid of peristaltic contraction. While in the epididymis the spermatozoa gain motility and become capable of fertilisation. However, transport of the mature spermatozoa through the remainder of the male reproductive system is achieved via muscle contraction rather than the spermatozoon's recently acquired motility.
Role of Sertoli cells
Main article: Sertoli cell
At all stages of differentiation, the spermatogenic cells are in close contact with Sertoli cells which are thought to provide structural and metabolic support to the developing sperm cells. A single Sertoli cell extends from the basement membrane to the lumen of the seminiferous tubule, although the cytoplasmic processes are difficult to distinguish at the light microscopic level.
Sertoli cells serve a number of functions during spermatogenesis, they support the developing gametes in the following ways:
- Maintain the environment necessary for development and maturation via the blood-testis barrier
- Secrete substances initiating meiosis
- Secrete supporting testicular fluid
- Secrete androgen-binding protein, which concentrates testosterone in close proximity to the developing gametes
- Testosterone is needed in very high quantities for maintenance of the reproductive tract, and ABP allows a much higher level of fertility
- Secrete hormones effecting pituitary gland control of spermatogenesis, particularly the polypeptide hormone, inhibin
- Phagocytose residual cytoplasm left over from spermiogenesis
- They release Antimullerian hormone which prevents formation of the Mullerian Duct / Oviduct.
Influencing factors
The process of spermatogenesis is highly sensitive to fluctuations in the environment, particularly hormones and temperature. Testosterone is required in large local concentrations to maintain the process, which is achieved via the binding of testosterone by androgen binding protein present in the seminiferous tubules. Testosterone is produced by interstitial cells, also known as Leydig cells, which reside adjacent to the seminiferous tubules.
Seminiferous epithelium is sensitive to elevated temperature in humans and some other species, and will be adversely affected by temperatures as high as normal body temperature. Consequently, the testes are located outside the body in a sack of skin called the scrotum. The optimal temperature is maintained at 2 °C (man) - 8 °C (mouse) below body temperature. This is achieved by regulation of blood flow[2] and positioning towards and away from the heat of the body by the cremasteric muscle and the dartos smooth muscle in the scrotum.
Dietary deficiencies (such as vitamins B, E and A), anabolic steroids, metals (cadmium and lead), x-ray exposure, dioxin, alcohol, and infectious diseases will also adversely affect the rate of spermatogenesis.
Hormonal control
Hormonal control of spermatogenesis varies among species. In humans the mechanism are not completely understood, however it is known that initiation of spermatogenesis occurs at puberty due to the interaction of the hypothalamus, pituitary gland and Leydig cells. If the pituitary gland is removed, spermatogenesis can still be initiated by follicle stimulating hormone and testosterone.
Follicle stimulating hormone stimulates both the production of androgen binding protein by Sertoli cells, and the formation of the blood-testis barrier. Androgen binding protein is essential to concentrating testosterone in levels high enough to initiate and maintain spermatogenesis, which can be 20-50 times higher than the concentration found in blood. Follicle stimulating hormone may initiate the sequestering of testosterone in the testes, but once developed only testosterone is required to maintain spermatogenesis. However, increasing the levels of follicle stimulating hormone will increase the production of spermatozoa by preventing the apoptosis of type A spermatogonia. The hormone inhibin acts to decrease the levels of follicle stimulating hormone. Studies from rodent models suggest that gonadotropin hormones (both LH and FSH) support the process of spermatogenesis by suppressing the proapoptotic signals and therefore promote spermatogenic cell survival. [3]
The Sertoli cells themselves mediate parts of spermatogenesis though hormone production. They are capable of producing the hormones estradiol and inhibin. The Leydig cells are also capable of producing estradiol in addition to their main product testosterone.
See also
References
- ^ Heller, C.G.; Clermont, Y. (April 1963). "Spermatogenesis in Man: An Estimate of Its Duration". Science 140 (3563): 184–6. doi:. PMID 13953583. http://www.sciencemag.org/cgi/content/abstract/140/3563/184.
- ^ Harrison, R.G.; Weiner, J.S. (1949). "Vascular Patterns of the Mammalian Testis and Their Functional Significance". Journal of Experimental Biology: 304–16, plates 9 & 10. http://jeb.biologists.org/cgi/reprint/26/3/304.pdf.]
- ^ Insights into male germ cell apoptosis due to depletion of gonadotropins caused by GnRH antagonists.Pareek TK, Joshi AR, Sanyal A, Dighe RR Apoptosis. 2007 Jun;12(6):1085-100
- "The testes and spermatogenesis". University of Wisconsin. 1998. http://www.wisc.edu/ansci_repro/lec/handouts/hd5.html. Retrieved 2006-11-27.
- Johnson, L (1997). "Factors affecting spermatogenesis in the stallion". Theriogenology 48 (7): 1199–1216. doi:. http://www.sciencedirect.com/science?_ob=ArticleURL&_udi=B6TCM-3RM01S4-G&_coverDate=11%2F30%2F1997&_alid=496201858&_rdoc=1&_fmt=&_orig=search&_qd=1&_cdi=5174&_sort=d&view=c&_acct=C000050221&_version=1&_urlVersion=0&_userid=10&md5=038f066d33248ee72545b48d21e1dd8c.
- BARDIN CW: Pituitary-testicular axis. In: YEN SS , JAFFEE RB , eds: Reproductive Endocrinology, 3rd ed. Philadelphia: WB Saunders, 1991
- CHAMBERS CV , SHAFER MA , ADGER H , et al.: Microflora of the urethra in adolescent boys: relationships to sexual activity and nongonococcal urethritis. J Ped 110:314-321, 1987
- CZYBA JC , GIROD C: Development of normal testis. In: HAFEZ ESE , ed: Descended and Cryptorchid Testis. The Hague, Martinus Nijhoff, 1980.
- Whitmore WF, Kars L, Gittes RF: The role of germinal epithelium and spermatogenesis in the privileged survival of intratesticular grafts. J Urol 1985;134:782.
External links
- Spermatogenesis - male reproductive physiology - Am Fam Physician 2000;62:1095.
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