User:Nafeezaa1/Clastogen/Bibliography

Bibliography

Bignold.,

Inhibition of DNA synthesis by certain clastogens has been observed in respect of radiations and alkylating agents from the earliest studies of chromosomal aberrations [30,32,42,82,84,165]. However, certain clastogens do not have this effect. (Those which do not may be, in general, those which do not damage DNA, such as caffeine [85].) Moreover, many inhibitors of DNA synthesis are not clastogens (notably phenformin and tacrine [84]).^[1]

Yeast DEL Assay

Currently, the in vitro micronucleus assay (IVMN) is a widely used screening tool in drug discovery. The IVMN assay detects clastogenic and aneugenic activity and IVMN data possess a good concordance with the standard chromosome aberration assays [9]. An assay that can detect clastogenic activity is expected to be a good predictor of chromosome aberration inducing activity. This is because formation of DNA strand breakage can lead to genomic rearrangements such as chromosomal deletions, translocations, amplifications and chromosome breakage [10], [11], which together are referred to as chromosome aberrations. In principle, the assay detects membrane bound fragments of DNA that have been separated from the nuclei during cell division [12]. Micronuclei can be produced as a consequence of chromosome breakage (clastogenicity) or chromosome loss (aneugenicity). Clastogenic activity leads to the inclusion of fragments of chromosomes in the micronuclei, whereas aneugenic activity would lead to the inclusion of an entire chromosome^[2]

Bolzan, Alejandro D

Telomere instability can take place in the short (at first cell division after the induction of chromosome damage by a given clastogen) or in the long term (i.e., several cell generations after treatment or exposure). Once telomere instability arises, the involved chromosomes tend to associate or fuse with each other, leading to genomic instability (Bolzán 2012; Murnane 2012). Finally, genomic instability refers to “an increased tendency of genome alteration during cell division” (Yao and Dai 2014), is a common event in cancer cells, and arises from many different pathways.

Telomere instability due to chromosome end loss or true telomere loss can be generated by any mutagen which breaks the chromosome (i.e., a clastogen) and thus induces the formation of “incomplete chromosome elements”

In addition, telomere instability due to telomere dysfunction may be produced by “stress-dependent telomere shortening”, which is produced by stress-inducing factors such as ultraviolet radiation and any mutagen capable of generating active oxygen species (ionizing radiation, radiomimetic clastogens like bleomycin or streptonigrin, etc.) (Ahmed and Lingner 2018; Barnes et al. 2019; Bolzán 2012, 2016; von Zglinicki 2002).

Moreover, chemical clastogens induce telomere dysfunction–related aberrations in human lymphocytes and cancer cell lines, and non-human established cell lines, being telomere loss and duplications the most frequent types of aberrations observed in the exposed cells. Furthermore, studies in rat cells exposed to chemical clastogens show that telomere dysfunction can persist for several cell generations after treatment.

Further studies in mammalian cells (especially human cells) will be needed to fully elucidate the long-term effects of anticancer drugs, ionizing radiation, and viruses on telomere stability and the mechanisms of long-term-induced telomere instability, and also to determine whether some telomere aberrations like ICE can be used as biomarkers of radiation exposure (Zeegers et al. 2017). In addition, since the above reviewed studies show that the type and the frequency of the induced telomere-related chromosomal aberrations depend on the clastogen and the cell type exposed, it will be very important to perform additional studies comparing the effects of different clastogens on different cell types, including other human or animal cell lines (both primary and cancer cell lines), non-human lymphocytes, or even ALT-positive cell lines, in which the telomeres are already affected by the formation of T-SCEs (a common event needed for telomere maintenance in these cells). Also, due to the scarcity of data regarding the induction of some types of telomeric aberrations (like, for example, T-SCEs), further studies will be needed to determine the whole spectrum of telomeric aberrations induced by chemical clastogens. ^[3]

V. S. Kharitonov*, V. V. Semenov, and B. I. Barabanshchiko

some ligands (adenosine, ADP, DAP) more effectively inhibit the clastogenic activity of ethylmethane sulfonate, others (CGA, PIA) are more active towards cyclophosphamide, while ATP similarly decreases the damaging effects of both mutagens^[4]

Ragini Bhargava,‡§ Felicia Wednesday Lopezcolorado,‡ L. Jillianne Tsai,‡§ and Jeremy M. Stark‡§,1

Clastogen exposure can result in chromosomal rearrangements, including large deletions and inversions that are associated with cancer development. ^[5]

1,2-dimethylhydrazine (DMH), a colon carcinogen with clastogenic activity^[6]

micronucleus test^[7]on gut cells is able to detect clastogens and aneugens, some of which do not show activity in the bone marrow micronucleus test after oral exposure.^[6]

Rats

Brevetoxin B (PbTx2) treated rats showed a two to three-fold increase in the amount of DNA in the comet tails, indicating that brevetoxin has in vivo clastogenic activity

after intratracheal administration to the rat. ^[8]

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1. Bignold, L. P. (2009-03-XX). "Mechanisms of clastogen-induced chromosomal aberrations: a critical review and description of a model based on failures of tethering of DNA strand ends to strand-breaking enzymes". Mutation Research. 681 (2–3): 271–298. doi:10.1016/j.mrrev.2008.11.004. ISSN 0027-5107. PMID 19103303. {{cite journal}}: Check date values in: |date= (help)
2. Kirpnick, Zhanna; Homiski, Michael; Rubitski, Elizabeth; Repnevskaya, Marina; Howlett, Niall; Aubrecht, Jiri; Schiestl, Robert H. (2005-04-04). "Yeast DEL assay detects clastogens". Mutation Research. 582 (1–2): 116–134. doi:10.1016/j.mrgentox.2005.01.005. ISSN 0027-5107. PMID 15781217.
3. "Using telomeric chromosomal aberrations to evaluate clastogen-induced genomic instability in mammalian cells". link.springer.com. Retrieved 2021-04-23.
4. "Purine Receptor Agonists protect the genome of Plant and Animal cells from Clastogen Damage". link.springer.com. Retrieved 2021-04-23.
5. Bhargava, Ragini; Lopezcolorado, Felicia Wednesday; Tsai, L. Jillianne; Stark, Jeremy M. (2020-01-XX). "The canonical non-homologous end joining factor XLF promotes chromosomal deletion rearrangements in human cells". Journal of Biological Chemistry. 295 (1): 125–137. doi:10.1074/jbc.RA119.010421. PMC 6952595. PMID 31753920. {{cite journal}}: Check date values in: |date= (help)
6. Vanhauwaert, A. (2001-01-01). "The in vivo gut micronucleus test detects clastogens and aneugens given by gavage". Mutagenesis. 16 (1): 39–50. doi:10.1093/mutage/16.1.39. ISSN 1464-3804.
7. "Micronucleus test", Wikipedia, 2019-10-04, retrieved 2021-04-29
8. Leighfield, Tod A.; Muha, Noah; Ramsdell, John S. (2009-11-XX). "Brevetoxin B is a clastogen in rats, but lacks mutagenic potential in the SP-98/100 Ames test". Toxicon. 54 (6): 851–856. doi:10.1016/j.toxicon.2009.06.018. {{cite journal}}: Check date values in: |date= (help)