Английская Википедия:Amitosis

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Шаблон:Short description Шаблон:Multiple issues Amitosis (a- + mitosis), also called karyostenosis, direct cell division, or binary fission, is a form of asexual cell division used by most prokaryotes. It differs from other forms of cell division (e.g., mitosis, meiosis) as it does not involve the mitotic apparatus (spindle formation) nor the condensation of chromatin into chromosomes prior to cellular division.

Note that several instances of cell division formerly thought to belong to this "non-mitotic" class, such as the division of some unicellular eukaryotes, may actually occur by the process of "closed mitosis" different from open or semi-closed mitotic processes, all involving mitotic chromosomes and classified by the fate of the nuclear envelope.

Processes

Amitosis is defined as the division of cells in the interphase state, usually accomplished by a simple constriction into two sometimes unequal halves, without any regular segregation of genetic material.[1] This can lead to random numbers of parental chromosomes being distributed in the subsequent daughter cells. This is in contrast to mitosis which involves precise distribution of chromosomes in the resulting daughter cells. This phenomenon does not involve maximal condensation of chromatin into chromosomes, a molecular event that is observable by light microscopy as chromatins line up in pairs along the metaphase plate. Amitosis has been reported in ciliates, yet its role in mammalian cell proliferation continues to be met with skepticism. Interestingly, the discovery of copy number variations (CNVs) in mammalian cells within an organ[2] has challenged the age-old assumption that every cell in an organism must inherit an exact copy of the parental genome to be functional. Instead of CNVs stemming from mitosis gone awry, such variations could have arisen from amitosis, and may even be beneficial to the cells. Furthermore, ciliates possess a mechanism for adjusting copy numbers of individual genes during amitosis of the macronucleus.[3]

Discovery

Amitosis was first described in 1880 by Walther Flemming (more celebrated for describing mitosis) and others.[4] For a few years thereafter, it was common for biologists to think of cells having both the capability to divide mitotically and amitotically.[5] However, since the turn of the twentieth century, amitosis has not received much attention. Using "mitosis in mammalian cells" as a search term in the Medline database calls up more than 10,000 studies dealing with mitosis, whereas "amitosis in mammalian cells" retrieves the titles of fewer than 50 papers. This absence of data has led many scientists to conclude that amitosis does not exist, or is minimally important.

Despite that, a resurgence of interest in the role of amitosis in mammalian proliferation has been building over the past several decades. A review of the resulting literature not only affirms the involvement of amitosis in cell proliferation, but also explores the existence of more than one amitotic mechanism capable of producing "progeny nuclei" without the involvement of "mitotic chromosomes." One form of amitosis involves fissioning, a nucleus splitting in two without the involvement of chromosomes, which has been reported to occur in placental tissues and in cells grown from such tissues in rats,[6] as well as in human and mouse trophoblasts[7],.[8] Amitosis by fissioning has also been reported in mammalian liver cells[9] and human adrenal cells.[10] Chen and Wan[11] reported amitosis in rat liver and presented a mechanism for a four-stage amitotic process whereby chromatin threads are reproduced and equally distributed to daughter cells as the nucleus splits in two.

Functional role

Additional reports of non-mitotic proliferation as well as insights into its underlying mechanisms, have emerged from extensive work with polyploid cells. Such cells, long acknowledged to exist, were once believed simply to be anomalous. Accumulating research, including those involving liver cells[12] now suggest that multiple copies of the genome in a cell population may be involved in the cell's adaptation to the environment.

A couple of decades of research has shown that polyploid cells are frequently "reduced" to diploid cells by amitosis.[13] For instance, naturally occurring polyploid placental cells have been shown to be capable of producing nuclei with diploid or near-diploid complements of DNA. Furthermore, Zybina and colleagues have demonstrated that such nuclei, derived from polyploid placental cells, receive one or more copies of a microscopically identifiable region of the chromatin, demonstrating that this particular amitotic process can actually result in representative transmission of chromatin. Studying rat polyploid trophoblasts, they have also shown that the nuclear envelope of the giant nucleus is involved in this subdivision.[14] Polyploid cells may also be key to the survival processes underlying chemotherapy resistance in certain cells.

Erenpreisa et al. reported that following treatment of cultured cells with mitosis-inhibiting chemicals (similar to those used in certain chemotherapeutic protocols), a small population of induced polyploid cells survived. Eventually, this population gave rise to "normal" diploid cells by the formation of polyploid chromatin bouquets that return to an interphase state, before separating into several secondary nuclei.[15] Intriguing phenomena including controlled autophagic degradation of DNA as well as the production of nuclear envelope-limited sheets[16] accompany the process.[17] Since this process of depolyploidization involves mitotic chromosomes, it conforms to the broad definition of amitosis.

Current literature

There are also multiple reports of amitosis occurring when nuclei bud out through the plasma membrane of a polyploid cell. Such a process has been shown to occur in amniotic cells transformed by a virus[18] and in mouse embryo fibroblast lines exposed to carcinogens.[19] A similar process called extrusion has been described for mink trophoblasts, a tissue in which fissioning is also observed.[20] Asymmetric cell division has also been described in polyploid giant cancer cells and low eukaryotic cells and reported to occur by the amitotic processes of splitting, budding, or burst-like mechanisms.[21] Similarly, two different kinds of amitosis have been described in monolayers of Ishikawa endometrial cells.[22]

An example of amitosis particularly suited to the formation of multiple differentiated nuclei in a reasonably short period of time has been shown to occur during the differentiation of fluid-enclosing hemispheres called domes from adherent Ishikawa endometrial monolayer cells during an approximately 20-hour period [23],.[24] Aggregates of nuclei from monolayer syncytia become enveloped in mitochondrial membranes, forming structures (mitonucleons) that become elevated as a result of vacuole formation during the initial 6 hours of differentiation [25],.[26] Over the next 4 to 5 hours, chromatin from these aggregated nuclei becomes increasingly pycnotic, eventually undergoing karyolysis and karyorrhexis in the now-elevated predome structures.[27] In other systems, such changes accompany apoptosis but not in the differentiating Ishikawa cells, where the processes appear to accompany changes in DNA essential for the newly created, differentiated dome cells. Finally, the chromatin filaments emerging from these processes form a mass from which dozens of dome nuclei are amitotically generated[28] over a period of approximately 3 hours with the apparent involvement of nuclear envelope-limited sheets.[29]

That all of this may be an iceberg tip is suggested by research from William Thilly's laboratory. Examination of fetal gut (5 to 7 weeks), colonic adenomas, and adenocarcinomas has revealed nuclei that look like hollow bells encased in tubular syncytia. These structures can either divide symmetrically by an amitotic nuclear fission process, forming new "bells", or undergo fission asymmetrically, resulting in one of seven other nuclear morphotypes, five of which appear to be specific to development since they are rarely observed in adult organisms.[30]

In conclusion, current body of literature suggests that amitosis may very well be involved in cellular development [31] in humans, likely during the fetal and embryonic phases of development when the majority of these cells are produced, perhaps within the complexity of implantation, perhaps when large numbers of cells are being differentiated, or perhaps in cancerous cells.

References

Further reading

Child CM. 1907 Amitosis as a factor in normal and regulatory growth. Anat Anz. 30: 271–97.

Coleman SJ, Gerza L, JonesCJ, Sibley CP, Aplin JD, Heazell AEP. 2013. Syncytial nuclear

Fleming H. 1995 Differentiation in human endometrial cells in monolayer culture: Dependence on a factor in fetal bovine serum J.Cell Biochem. 57:262-270.

Fleming H, Condon R, Peterson G, Guck I, Prescott E, Chatfield K, Duff M. 1998. Role of biotin-containing membranes and nuclear distribution in differentiating human endometrial cells. Journal of Cellular Biochemistry. 71(3): 400–415.

Fleming H. 1999 Structure and function of cultured endometrial epithelial cells. Semin Reprod Endocrinol.17(1):93-106.

Fleming H. 2014 Unusual characteristics of opaque Ishikawa endometrial cells include the envelopment of chromosomes with material containing endogenous biotin in the latter stages of cytokinesis Шаблон:Doi

Fleming H. 2016a. Mitonucleons formed during Differentiation of Ishikawa Endometrial Epithelial Cells are involved in Vacuole Formation that Elevates Monolayer Cells into Domes. Differentiation of Ishikawa Domes, Part 1, Шаблон:Doi

Fleming H. 2016b. Pyknotic chromatin in mitonucleons elevating in syncytia undergo karyorhhexis and karyolysis before coalescing into an irregular chromatin mass: Differentiation of Ishikawa Domes, Part 2, Шаблон:Doi

Fleming H. 2016c. Chromatin mass from previously aggregated, pyknotic, and fragmented monolayer nuclei is a source for dome cell nuclei generated by amitosis: Differentiation of Ishikawa Domes, Part 3, Шаблон:Doi

Güttinger, S; Laurell, E; Kutay, U (2009), "Orchestrating nuclear envelope disassembly and reassembly during mitosis", Nat Rev Mol Cell Biol 10 (3): 178–191, Шаблон:Doi, Шаблон:PMID

Isakova GK, Shilova IE. 2000. Reproduction by "budding" of the trophoblast cells in the mink implanting blastocysts. Dokl Biol Sci. 371:214-6.

Schoenfelder KP, Fox DT 2015 The expanding implications of polyploidy. J Cell Biol. 25;209(4):485-91. Шаблон:Doi.

Thilly WG, Gostjeva EV, Koledova VV, Zukerberg LR, Chung D, Fomina JN, Darroudi F, Stollar BD. 2014. Metakaryotic stem cell nuclei use pangenomic dsRNA/DNA intermediates in genome replication and segregation. Organogenesis. 10(1):44-52. Шаблон:Doi. Epub 2014 Jan 13.

Walen KH. 2004. Spontaneous cell transformation: karyoplasts derived from multinucleated cells produce new cell growth in senescent human epithelial cell cultures. In Vitro Cell Dev Biol Anim. 40(5-6):150-8.

Zybina EV, Zybina TG, Bogdanova MS, Stein GI 2005 Cell Biol Int. 29 (12): 1066-1070