Biology:Spermatocyte

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Short description: Sperm precursor cell that undergoes meiosis
Spermatogenesis as the cells progress from spermatogium, to primary spermatocytes, to secondary spermatocytes, to spermatids and to Sperm.

Spermatocytes are a type of male gametocyte in animals. They derive from immature germ cells called spermatogonia. They are found in the testis, in a structure known as the seminiferous tubules.[1] There are two types of spermatocytes, primary and secondary spermatocytes. Primary and secondary spermatocytes are formed through the process of spermatocytogenesis.[2]

Primary spermatocytes are diploid (2N) cells. After meiosis I, two secondary spermatocytes are formed. Secondary spermatocytes are haploid (N) cells that contain half the number of chromosomes.[1]

In all animals, males produce spermatocytes, even hermaphrodites such as C. elegans, which exist as a male or hermaphrodite. In hermaphrodite C. elegans, sperm production occurs first and is then stored in the spermatheca. Once the eggs are formed, they are able to self-fertilize and produce up to 350 progeny.[3]

Development

Spermatogonia going through mitosis to form primary spermatocytes in Grasshopper testes.
Spermatocytogenesis

At puberty, spermatogonia located along the walls of the seminiferous tubules within the testis will be initiated and start to divide mitotically, forming two types of A cells that contain an oval shaped nucleus with a nucleolus attached to the nuclear envelope; one is dark (Ad) and the other is pale (Ap). The Ad cells are spermatogonia that will stay in the basal compartment (outer region of the tubule); these cells are reserve spermatogonial stem cells that do not usually undergo mitosis. Type Ap are actively-dividing spermatogonial stem cells which begin differentiation to type B spermatogonia, which have round nuclei and heterochromatin attached to the nuclear envelope and the center of nucleolus.[4] Type B cells will move on to the adluminal compartment (towards the inner region of tubule) and become primary spermatocytes; this process takes about 16 days to complete.[2][5]

The primary spermatocytes within the adluminal compartment will continue on to Meiosis I and divide into two daughters cells, known as secondary spermatocytes, a process which takes 24 days to complete. Each secondary spermatocyte will form two spermatids after Meiosis II.[1]

Although spermatocytes that divide mitotically and meiotically are sensitive to radiation and cancer, spermatogonial stem cells are not. Therefore, after termination of radiation therapy or chemotherapy, the spermatognia stems cells may re-initiate the formation of spermatogenesis.[6]

Hormones produced by the Pituitary gland. GnRH is secreted by the hypothalamus, which induces anterior pituitary to produce FSH and LH upon puberty.

Role of hormones

The formation of primary spermatocytes (a process known as spermatocytogenesis) begins in humans when a male is sexually matured at puberty, around the age of 10 through 14.[7] Formation is initiated upon the pulsated surges of gonadotropin-releasing hormone (GnRH) from the hypothalamus, which leads to the secretion of follicle-stimulating hormone (FSH) and luteinizing hormone (LH) produced by the anterior pituitary gland. The release of FSH into the testes will enhance spermatogenesis and lead to the development of Sertoli cells, which act as nursing cells where spermatids will go to mature after Meiosis II. LH promotes Leydig cell secretion of testosterone into the testes and blood, which induce spermatogenesis and aid the formation of secondary sex characteristics. From this point on, the secretion of FSH and LH (inducing production of testosterone) will stimulate spermatogenesis until the male dies.[8] Increasing the hormones FSH and LH in males will not increase the rate of spermatogenesis. However, with age, the rate of production will decrease, even when the amount of hormone that is secreted is constant; this is due to higher rates of degeneration of germ cells during meiotic prophase.[1]

Cell type summary

In the following table, ploidy, copy number and chromosome/chromatid counts listed are for a single cell, generally prior to DNA synthesis and division (in G1 if applicable). Primary spermatocytes are arrested after DNA synthesis and prior to division.[1][2]

Cell Type Ploidy/Chromosomes in human DNA copy number/Chromatids in human Process entered by cell Duration
spermatogonium (types Ad, Ap and B) germ cells diploid (2N) / 46 2C / 46 spermatocytogenesis (Mitosis) 16 days
primary spermatocyte male gametocyte diploid (2N) / 46 4C / 2x46 spermatocytogenesis (Meiosis I ) 24 days
secondary spermatocyte male gametocyte haploid (N) / 23 2C / 46 spermatidogenesis (Meiosis II ) A few hours
spermatids male gametid haploid (N) / 23 1C / 23 spermiogenesis 24 days
spermatozoids sperm haploid (N) / 23 1C / 23 spermiation 64 days (total)

Physiology

Damage, repair, and failure

Spermatocytes regularly overcome double-strand breaks and other DNA damages in the prophase stage of meiosis. These damages can arise by the programmed activity of Spo11, an enzyme employed in meiotic recombination, as well as by un-programmed breakages in DNA, such as those caused by oxidative free radicals produced as products of normal metabolism. These damages are repaired by homologous recombination pathways and utilize RAD1 and γH2AX, which recognize double strand breaks and modify chromatin, respectively. As a result, double strand breaks in meiotic cells, unlike mitotic cells, do not typically lead to apoptosis, or cell death.[9] Homologous recombinational repair (HRR) of double-strand breaks occurs in mice during sequential stages of spermatogenesis but is most prominent in spermatocytes.[10] In spermatocytes, HRR events occur mainly in the pachytene stage of meiosis and the gene conversion type of HRR is predominant, whereas in other stages of spermatogenesis the reciprocal exchange type of HRR is more frequent.[10] During mouse spermatogenesis, the mutation frequencies of cells at the different stages, including pachytene spermatocytes, are 5 to 10-fold lower than the mutation frequencies in somatic cells.[11] Because of their elevated DNA repair capability, spermatocytes likely play a central role in the maintenance of these lower mutation rates, and thus in the preservation of the genetic integrity of the male germ line.

It is known that heterozygous chromosomal rearrangements lead to spermatogenic disturbance or failure; however the molecular mechanisms that cause this are not as well known. It is suggested that a passive mechanism involving asynaptic region clustering in spermatocytes is a possible cause. Asynaptic regions are associated with BRCA1, kinase ATR and γH2AX presence in pachytene spermatocytes.[12]

Specific mutations

Wild-type spermatocyte progression compared to repro4 mutated spermatocytes.

The gene Stimulated By Retinoic Acid 8 (STRA8) is required for the retinoic-acid signaling pathway in humans, which leads to meiosis initiation. STRA8 expression is higher in preleptotene spermatocytes (at the earliest stage of Prophase I in meiosis) than in spermatogonia. STRA8-mutant spermatocytes have been shown to be capable of meiosis initiation; however, they cannot complete the process. Mutations in leptotene spermatocytes can result in premature chromosome condensation.[13]

Mutations in Mtap2, a microtubule-associated protein, as observed in repro4 mutant spermatocytes, have been shown to arrest spermatogenesis progress during the prophase of Meiosis I. This is observed by a reduction in spermatid presence in repro4 mutants.[14]

Recombinant-defective mutations can occur in Spo11, DMC1, ATM and MSH5 genes of spermatocytes. These mutations involve double strand break repair impairment, which can result in arrest of spermatogenesis at stage IV of the seminiferous epithelium cycle.[15]

History

Meiosis in Grasshopper testes (primary spermatocytes in zygotene, pachytene, prophase I).

The spermatogenesis process has been elucidated throughout the years by researchers who divided the process into multiple stages or phases, depending on intrinsic (germ and Sertoli cells) and extrinsic (FSH and LH) factors.[16] The spermatogenesis process in mammals as a whole, involving cellular transformation, mitosis, and meiosis, has been well studied and documented from the 1950s to 1980s. However, during the 1990s and 2000s researchers have focused around increasing understanding of the regulation of spermatogenesis via genes, proteins, and signaling pathways, and the biochemical and molecular mechanisms involved in these processes. Most recently, the environmental effects on spermatogenesis have become a focus as male infertility in men has become more prevalent.[17]

An important discovery in the spermatogenesis process was the identification of the seminiferous epithelial cycle in mammals—work by C.P. Leblound and Y. Clermont in 1952 that studied the spermatogonia, spermatocyte layers and spermatids in rat seminiferous tubules. Another critical discovery was that of the hypothalamic-pituitary-testicular hormone chain, which plays a role in spermatogenesis regulation; this was studied by R. M. Sharpe in 1994.[17]

Other animals

Mesostoma ehrenbergii

Primary cilia are common organelles found in eukaryotic cells; they play an important role in development of animals. Drosophila have unique properties in their spermatocyte primary cilia—they are assembled by four centrioles independently in the G2 phase and are sensitive to microtubule-targeting drugs. Normally, primary cilia will develop from one centriole in the G0/G1 phase and are not affected by microtubule targeting drugs.[18]

Mesostoma ehrenbergii is a rhabdocoel flatworm with a distinctive male meiosis stage within the formation of spermatocytes. During the pre-anaphase stage, cleavage furrows are formed in the spermatocyte cells containing four univalent chromosomes. By the end of the anaphase stage, there is one at each pole moving between the spindle poles without actually having physical interactions with one another (also known as distance segregation). These unique traits allow researchers to study the force created by the spindle poles to allow the chromosomes to move, cleavage furrow management and distance segregation.[19][20]

See also

References

  1. 1.0 1.1 1.2 1.3 1.4 Boron, Walter F., MD, Ph.D., Editor; Boulpaep, Emile L. (2012). "54". Medical physiology a cellular and molecular approach (Print) (Updated second ed.). Philadelphia: Saunders Elsevier. ISBN 978-1-4377-1753-2. [page needed]
  2. 2.0 2.1 2.2 Schöni-Affolter, Dubuis-Grieder, Strauch, Franzisk, Christine, Erik Strauch. "Spermatogenesis". http://www.embryology.ch/anglais/cgametogen/spermato03.html#entwicklung. 
  3. C. elegans II (2nd ed.). Cold Spring Harbor. NY: Cold Spring Harbor Laboratory Press. 1997. https://www.ncbi.nlm.nih.gov/books/NBK20086/. Retrieved April 13, 2014. 
  4. Boitani, Carla; Di Persio, Sara; Esposito, Valentina; Vicini, Elena (2016-03-05). "Spermatogonial cells: mouse, monkey and man comparison". Seminars in Cell & Developmental Biology 59: 79–88. doi:10.1016/j.semcdb.2016.03.002. ISSN 1096-3634. PMID 26957475. 
  5. Y, Clermont (1966). "Renewal of spermatogonia in man". American Journal of Anatomy 118 (2): 509–524. doi:10.1002/aja.1001180211. PMID 5917196. 
  6. Tres, Abraham L. Kierszenbaum, Laura L. (2012). Histology and cell biology : an introduction to pathology (3rd ed.). Philadelphia, PA: Saunders. pp. Chapter 20. ISBN 9780323078429. https://www.inkling.com/read/histology-cell-biology-kierszenbaum-tres-3rd/chapter-20/the-testes. 
  7. Starr, Taggart, Evers, Starr, Cecie, Ralph, Christine, Lisa (January 1, 2012). Animal Structure & Function. Cengage Learning. pp. 736. ISBN 9781133714071. 
  8. Sherwood, Lauralee (2010). Human physiology : from cells to systems (7th ed.). Australia: Brooks/Cole, Cengage Learning. p. 751. ISBN 978-0495391845. 
  9. "Spermatocyte responses in vitro to induced DNA damage". Molecular Reproduction and Development 73 (8): 1061–72. August 2006. doi:10.1002/mrd.20508. PMID 16700071. 
  10. 10.0 10.1 "Homologous recombination-mediated double-strand break repair in mouse testicular extracts and comparison with different germ cell stages". Cell Biochem. Funct. 25 (1): 75–86. 2007. doi:10.1002/cbf.1375. PMID 16989005. 
  11. "Mutation frequency declines during spermatogenesis in young mice but increases in old mice". Proc. Natl. Acad. Sci. U.S.A. 95 (17): 10015–9. 1998. doi:10.1073/pnas.95.17.10015. PMID 9707592. Bibcode1998PNAS...9510015W. 
  12. "The role of asynapsis in human spermatocyte failure". International Journal of Andrology 35 (4): 541–9. August 2012. doi:10.1111/j.1365-2605.2011.01221.x. PMID 21977946. 
  13. Mark, Manuel; Hugues Jacobs; Mustapha Oulad-Abdelghani; Christine Dennefeld; Betty Feret; Nadege Vernet; Carmen-Alina Codreanu; Pierre Chambon et al. (7 July 2008). "STRA8-deficient spermatocytes initiate, but fail to complete, meiosis and undergo premature chromosome condensation". Journal of Cell Science 121 (19): 3233–3242. doi:10.1242/jcs.035071. PMID 18799790. 
  14. Sun, Fengyun; Mary Ann Handel (10 January 2011). "A Mutation in Mtap2 is Associated with Arrest of Mammalian Spermatocytes before the First Meiotic Division". Genes 2 (1): 21–35. doi:10.3390/genes2010021. PMID 24501684. 
  15. Barchi, Marco; S. Mahadevaiah; M. Di Giacomo; F. Baudat; D. de Rooij; P. Burgoyne; M. Jasin; S. Keeney (August 2005). "Surveillance of Different Recombination Defects in Mouse Spermatocytes Yields Distinct Responses despite Elimination at an Identical Developmental Stage". Molecular and Cellular Biology 25 (16): 7203–7215. doi:10.1128/MCB.25.16.7203-7215.2005. PMID 16055729. 
  16. Cheng, C. Yan, ed (2008). Molecular mechanisms in spermatogenesis. New York: Springer Science+Business Media. pp. Chapter 1, page 1. ISBN 978-0-387-79990-2. https://archive.org/details/molecularmechani00cych. 
  17. 17.0 17.1 Cheng, C. Yan; Dolores D. Mruk (19 April 2010). "The biology of spermatogenesis: the past, present and future". Phil. Trans. R. Soc. B. 1546 365 (1546): 1459–1463. doi:10.1098/rstb.2010.0024. PMID 20403863. 
  18. "Unique properties of Drosophila spermatocyte primary cilia". Biology Open 2 (11): 1137–47. 2013. doi:10.1242/bio.20135355. PMID 24244850. 
  19. "Meiosis-I in Mesostoma ehrenbergii spermatocytes includes distance segregation and inter-polar movements of univalents, and vigorous oscillations of bivalents". Protoplasma 251 (1): 127–43. January 2014. doi:10.1007/s00709-013-0532-9. PMID 23921676. 
  20. "Mesostoma ehrenbergii spermatocytes--a unique and advantageous cell for studying meiosis". Cell Biology International 37 (9): 892–8. September 2013. doi:10.1002/cbin.10130. PMID 23686688. 

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