fbpx
Wikipedia

Malignant transformation

January 01, 1970

Not to be confused with Transformation (genetics), the incorporation of foreign DNA by bacteria.

Malignant transformation is the process by which cells acquire the properties of cancer. This may occur as a primary process in normal tissue, or secondarily as malignant degeneration of a previously existing benign tumor.

Causes edit

There are many causes of primary malignant transformation, or tumorigenesis. Most human cancers in the United States are caused by external factors, and these factors are largely avoidable.[1][2][3] These factors were summarized by Doll and Peto in 1981,[1] and were still considered to be valid in 2015.[2] These factors are listed in the table.

External factors in cancer
Factor Estimated percent of cancer deaths
Diet 35
Tobacco 30
Infection 10
Reproductive and sexual behaviora 7
Occupation 4
Alcohol 3
Sunlight (UV) 3
Pollution 2
Medicines and medical procedures 1
Food additives <1
Industrial products <1

a Reproductive and sexual behaviors include: number of partners; age at first menstruation; zero versus one or more live births

Examples of diet-related malignant transformation edit

Diet and colon cancer edit

Colon cancer provides one example of the mechanisms by which diet, the top factor listed in the table, is an external factor in cancer. The Western diet of African Americans in the United States is associated with a yearly colon cancer rate of 65 per 100,000 individuals, while the high fiber/low fat diet of rural Native Africans in South Africa is associated with a yearly colon cancer rate of <5 per 100,000.[4] Feeding the Western diet for two weeks to Native Africans increased their secondary bile acids, including carcinogenic deoxycholic acid,[5] by 400%, and also changed the colonic microbiota.[4] Evidence reviewed by Sun and Kato[6] indicates that differences in human colonic microbiota play an important role in the progression of colon cancer.

Diet and lung cancer edit

A second example, relating a dietary component to a cancer, is illustrated by lung cancer. Two large population-based studies were performed, one in Italy and one in the United States.[7] In Italy, the study population consisted of two cohorts: the first, 1721 individuals diagnosed with lung cancer and no severe disease, and the second, 1918 control individuals with absence of lung cancer history or any advanced diseases. All individuals filled out a food frequency questionnaire including consumption of walnuts, hazelnuts, almonds, and peanuts, and indicating smoking status. In the United States, 495,785 members of AARP were questioned on consumption of peanuts, walnuts, seeds, or other nuts in addition to other foods and smoking status. In this U.S. study 18,533 incident lung cancer cases were identified during up to 16 years of follow-up. Overall, individuals in the highest quintile of frequency of nut consumption had a 26% lower risk of lung cancer in the Italian study and a 14% lower risk of lung cancer in the U.S. study. Similar results were obtained among individuals who were smokers.

Due to tobacco edit

The most important chemical compounds in smoked tobacco that are carcinogenic are those that produce DNA damage since such damage appears to be the primary underlying cause of cancer.[8] Cunningham et al.[9] combined the microgram weight of the compound in the smoke of one cigarette with the known genotoxic effect per microgram to identify the most carcinogenic compounds in cigarette smoke. These compounds and their genotoxic effects are listed in the article Cigarette. The top three compounds are acrolein, formaldehyde and acrylonitrile, all known carcinogens.

Due to infection edit

Viruses edit

In 2002 the World Health Organizations International Agency for Research on Cancer[10] estimated that 11.9% of human cancers are caused by one of seven viruses (see Oncovirus overview table). These are Epstein-Barr virus (EBV or HHV4); Kaposi's sarcoma-associated herpesvirus (KSHV or HHV8); Hepatitis B and Hepatitis C viruses (HBV and HCV); Human T-lymphotrophic virus 1 (HTLV-1); Merkel cell polyomavirus (MCPyV); and a group of alpha Human papillomaviruses (HPVs).[11]

Bacteria edit

Helicobacter pylori and gastric cancer edit

In 1995 epidemiologic evidence indicated that Helicobacter pylori infection increases the risk for gastric carcinoma.[12] More recently, experimental evidence showed that infection with Helicobacter pylori cagA-positive bacterial strains results in severe degrees of inflammation and oxidative DNA damage, leading to progression to gastric cancer.[13]

Other bacterial roles in carcinogenesis edit

Perera et al.[14] referred to a number of articles pointing to roles of bacteria in other cancers. They pointed to single studies on the role of Chlamydia trachomatis in cervical cancer, Salmonella typhi in gallbladder cancer, and both Bacteroides fragilis and Fusobacterium nucleatum in colon cancer. Meurman has recently summarized evidence connecting oral microbiota with carcinogenesis.[15] Although suggestive, these studies need further confirmation.

Common underlying factors in cancer edit

Mutations edit

One underlying commonality in cancers is genetic mutation, acquired either by inheritance, or, more commonly, by mutations in one's somatic DNA over time. The mutations considered important in cancers are those that alter protein coding genes (the exome). As Vogelstein et al. point out, a typical tumor contains two to eight exome "driver gene" mutations, and a larger number of exome mutations that are "passengers" that confer no selective growth advantage.[16]

Cancers also generally have genome instability, that includes a high frequency of mutations in the noncoding DNA that makes up about 98% of the human genome. The average number of DNA sequence mutations in the entire genome of breast cancer tissue is about 20,000.[17] In an average melanoma (where melanomas have a higher exome mutation frequency[16]) the total number of DNA sequence mutations is about 80,000.[18]

Epigenetic alterations edit

Transcription silencing edit

A second underlying commonality in cancers is altered epigenetic regulation of transcription. In cancers, loss of gene expression occurs about 10 times more frequently by epigenetic transcription silencing (caused, for example, by promoter hypermethylation of CpG islands) than by mutations. As Vogelstein et al.[16] point out, in a colorectal cancer there are usually about 3 to 6 driver mutations and 33 to 66 hitchhiker, or passenger, mutations.[16] In contrast, the frequency of epigenetic alterations is much higher. In colon tumors compared to adjacent normal-appearing colonic mucosa, there are about 600 to 800 heavily methylated CpG islands in promoters of genes in the tumors while the corresponding CpG islands are not methylated in the adjacent mucosa.[19][20][21] Such methylation turns off expression of a gene as completely as a mutation would. Around 60–70% of human genes have a CpG island in their promoter region.[22][23] In colon cancers, in addition to hypermethylated genes, several hundred other genes have hypomethylated (under-methylated) promoters, thereby causing these genes to be turned on when they ordinarily would be turned off.[21]

Post-transcriptional silencing edit

Epigenetic alterations are also carried out by another major regulatory element, that of microRNAs (miRNAs). In mammals, these small non-coding RNA molecules regulate about 60% of the transcriptional activity of protein-encoding genes.[24] Epigenetic silencing or epigenetic over-expression of miRNA genes, caused by aberrant DNA methylation of the promoter regions controlling their expression, is a frequent event in cancer cells. Almost one third of miRNA promoters active in normal mammary cells were found to be hypermethylated in breast cancer cells, and that is a several fold greater proportion of promoters with altered methylation than is usually observed for protein coding genes.[25] Other microRNA promoters are hypomethylated in breast cancers, and, as a result, these microRNAs are over-expressed. Several of these over-expressed microRNAs have a major influence in progression to breast cancer. BRCA1 is normally expressed in the cells of breast and other tissue, where it helps repair damaged DNA, or destroy cells if DNA cannot be repaired.[26] BRCA1 is involved in the repair of chromosomal damage with an important role in the error-free repair of DNA double-strand breaks.[27] BRCA1 expression is reduced or undetectable in the majority of high grade, ductal breast cancers.[28] Only about 3–8% of all women with breast cancer carry a mutation in BRCA1 or BRCA2.[29] BRCA1 promoter hypermethylation was present in only 13% of unselected primary breast carcinomas.[30] However, breast cancers were found to have an average of about 100-fold increase in miR-182, compared to normal breast tissue.[31] In breast cancer cell lines, there is an inverse correlation of BRCA1 protein levels with miR-182 expression.[32] Thus it appears that much of the reduction or absence of BRCA1 in high grade ductal breast cancers may be due to over-expressed miR-182. In addition to miR-182, a pair of almost identical microRNAs, miR-146a and miR-146b-5p, also repress BRCA1 expression. These two microRNAs are over-expressed in triple-negative tumors and their over-expression results in BRCA1 inactivation.[33] Thus, miR-146a and/or miR-146b-5p may also contribute to reduced expression of BRCA1 in these triple-negative breast cancers.

Post-transcriptional regulation by microRNA occurs either through translational silencing of the target mRNA or through degradation of the target mRNA, via complementary binding, mostly to specific sequences in the three prime untranslated region of the target gene's mRNA.[34] The mechanism of translational silencing or degradation of target mRNA is implemented through the RNA-induced silencing complex (RISC).

DNA repair gene silencing edit

Main articles: DNA methylation in cancer and Regulation of transcription in cancer

Silencing of a DNA repair gene by hypermethylation or other epigenetic alteration appears to be a frequent step in progression to cancer. As summarized in a review,[citation needed] promoter hypermethylation of DNA repair gene MGMT occurs in 93% of bladder cancers, 88% of stomach cancers, 74% of thyroid cancers, 40%-90% of colorectal cancers and 50% of brain cancers. In addition, promoter hypermethylation of DNA repair genes LIG4, NEIL1, ATM, MLH1 or FANCB occurs at frequencies of between 33% and 82% in one or more of head and neck cancers, non-small-cell lung cancers or non-small-cell lung cancer squamous cell carcinomas. Further, the article Werner syndrome ATP-dependent helicase indicates the DNA repair gene WRN has a promoter that is often hypermethylated in a variety of cancers, with WRN hypermethylation occurring in 11% to 38% of colorectal, head and neck, stomach, prostate, breast, thyroid, non-Hodgkin lymphoma, chondrosarcoma and osteosarcoma cancers.

Such silencing likely acts similarly to a germ-line mutation in a DNA repair gene, and predisposes the cell and its descendants to progression to cancer.[35] Another review[36] points out that when a gene necessary for DNA repair is epigenetically silenced, DNA repair would tend to be deficient and DNA damages can accumulate. Increased DNA damage can cause increased errors during DNA synthesis, leading to mutations that give rise to cancer.

Induced by heavy metals edit

The heavy metals cadmium, arsenic and nickel are all carcinogenic when present above certain levels.[37][38][39][40]

Cadmium is known to be carcinogenic, possibly due to reduction of DNA repair. Lei et al.[41] evaluated five DNA repair genes in rats after exposure of the rats to low levels of cadmium. They found that cadmium caused repression of three of the DNA repair genes: XRCC1 needed for base excision repair, OGG1 needed for base excision repair, and ERCC1 needed for nucleotide excision repair. Repression of these genes was not due to methylation of their promoters.

Arsenic carcinogenicity was reviewed by Bhattacharjee et al.[39] They summarized the role of arsenic and its metabolites in generating oxidative stress, resulting in DNA damage. In addition to causing DNA damage, arsenic also causes repression of several DNA repair enzymes in both the base excision repair pathway and the nucleotide excision repair pathway. Bhattacharjee et al. further reviewed the role of arsenic in causing telomere dysfunction, mitotic arrest, defective apoptosis, as well as altered promoter methylation and miRNA expression. Each of these alterations could contribute to arsenic-induced carcinogenesis.

Nickel compounds are carcinogenic and occupational exposure to nickel is associated with an increased risk of lung and nasal cancers.[42] Nickel compounds exhibit weak mutagenic activity, but they considerably alter the transcriptional landscape of the DNA of exposed individuals.[42] Arita et al.[42] examined the peripheral blood mononuclear cells of eight nickel-refinery workers and ten non-exposed workers. They found 2756 differentially expressed genes with 770 up-regulated genes and 1986 down-regulated genes. DNA repair genes were significantly over-represented among the differentially expressed genes, with 29 DNA repair genes repressed in the nickel-refinery workers and two over-expressed. The alterations in gene expression appear to be due to epigenetic alterations of histones, methylations of gene promoters, and hypermethylation of at least microRNA miR-152.[40][43]

Clinical signs edit

Malignant transformation of cells in a benign tumor may be detected by pathologic examination of tissues. Often the clinical signs and symptoms are suggestive of a malignant tumor. The physician, during the medical history examination, can find that there have been changes in size or patient sensation and, upon direct examination, that there has been a change in the lesion itself.

Risk assessments can be done and are known for certain types of benign tumor which are known to undergo malignant transformation. One of the better-known examples of this phenomenon is the progression of a nevus to melanoma.

See also edit

References edit

  1. ^ a b Doll R, Peto R (1981). "The causes of cancer: quantitative estimates of avoidable risks of cancer in the United States today". J. Natl. Cancer Inst. 66 (6): 1191–308. doi:10.1093/jnci/66.6.1192. PMID 7017215.
  2. ^ a b Blot WJ, Tarone RE (2015). "Doll and Peto's quantitative estimates of cancer risks: holding generally true for 35 years". J. Natl. Cancer Inst. 107 (4): djv044. doi:10.1093/jnci/djv044. PMID 25739419.
  3. ^ Song M, Giovannucci EL (2015). "RE: Doll and Peto's Quantitative Estimates of Cancer Risks: Holding Generally True for 35 Years". J. Natl. Cancer Inst. 107 (10): djv240. doi:10.1093/jnci/djv240. PMID 26271254.
  4. ^ a b O'Keefe SJ, Li JV, Lahti L, Ou J, Carbonero F, Mohammed K, Posma JM, Kinross J, Wahl E, Ruder E, Vipperla K, Naidoo V, Mtshali L, Tims S, Puylaert PG, DeLany J, Krasinskas A, Benefiel AC, Kaseb HO, Newton K, Nicholson JK, de Vos WM, Gaskins HR, Zoetendal EG (2015). "Fat, fibre and cancer risk in African Americans and rural Africans". Nat Commun. 6: 6342. Bibcode:2015NatCo...6.6342O. doi:10.1038/ncomms7342. PMC 4415091. PMID 25919227.
  5. ^ Bernstein C, Holubec H, Bhattacharyya AK, Nguyen H, Payne CM, Zaitlin B, Bernstein H (2011). "Carcinogenicity of deoxycholate, a secondary bile acid". Arch. Toxicol. 85 (8): 863–71. doi:10.1007/s00204-011-0648-7. PMC 3149672. PMID 21267546.
  6. ^ Sun J, Kato I (2016). "Gut microbiota, inflammation and colorectal cancer". Genes & Diseases. 3 (2): 130–143. doi:10.1016/j.gendis.2016.03.004. PMC 5221561. PMID 28078319.
  7. ^ Lee JT, Lai GY, Liao LM, Subar AF, Bertazzi PA, Pesatori AC, Freedman ND, Landi MT, Lam TK (2017). "Nut consumption and lung cancer risk: Results from two large observational studies". Cancer Epidemiol. Biomarkers Prev. 26 (6): 826–836. doi:10.1158/1055-9965.EPI-16-0806. PMC 6020049. PMID 28077426.
  8. ^ Kastan MB (2008). "DNA damage responses: mechanisms and roles in human disease: 2007 G.H.A. Clowes Memorial Award Lecture". Mol. Cancer Res. 6 (4): 517–24. doi:10.1158/1541-7786.MCR-08-0020. PMID 18403632.
  9. ^ Cunningham FH, Fiebelkorn S, Johnson M, Meredith C (2011). "A novel application of the Margin of Exposure approach: segregation of tobacco smoke toxicants". Food Chem. Toxicol. 49 (11): 2921–33. doi:10.1016/j.fct.2011.07.019. PMID 21802474.
  10. ^ Parkin, Donald Maxwell (2006). "The global health burden of infection-associated cancers in the year 2002". International Journal of Cancer. 118 (12): 3030–44. doi:10.1002/ijc.21731. PMID 16404738.
  11. ^ McBride AA (2017). "Perspective: The Promise of Proteomics in the Study of Oncogenic Viruses". Mol. Cell. Proteomics. 16 (4 suppl 1): S65–S74. doi:10.1074/mcp.O116.065201. PMC 5393395. PMID 28104704.
  12. ^ Correa P (1995). "Helicobacter pylori and gastric carcinogenesis". Am. J. Surg. Pathol. 19 (Suppl 1): S37–43. PMID 7762738.
  13. ^ Raza Y, Khan A, Farooqui A, Mubarak M, Facista A, Akhtar SS, Khan S, Kazi JI, Bernstein C, Kazmi SU (2014). "Oxidative DNA damage as a potential early biomarker of Helicobacter pylori associated carcinogenesis". Pathol. Oncol. Res. 20 (4): 839–46. doi:10.1007/s12253-014-9762-1. PMID 24664859. S2CID 18727504.
  14. ^ Perera M, Al-Hebshi NN, Speicher DJ, Perera I, Johnson NW (2016). "Emerging role of bacteria in oral carcinogenesis: a review with special reference to perio-pathogenic bacteria". J Oral Microbiol. 8: 32762. doi:10.3402/jom.v8.32762. PMC 5039235. PMID 27677454.
  15. ^ Meurman JH (2010). "Oral microbiota and cancer". J Oral Microbiol. 2: 5195. doi:10.3402/jom.v2i0.5195. PMC 3084564. PMID 21523227.
  16. ^ a b c d Vogelstein B, Papadopoulos N, Velculescu VE, Zhou S, Diaz LA, Kinzler KW (2013). "Cancer genome landscapes". Science. 339 (6127): 1546–58. Bibcode:2013Sci...339.1546V. doi:10.1126/science.1235122. PMC 3749880. PMID 23539594.
  17. ^ Yost SE; Smith EN; Schwab RB; Bao L; Jung H; Wang X; Voest E; Pierce JP; Messer K; Parker BA; Harismendy O; Frazer KA (August 2012). "Identification of high-confidence somatic mutations in whole genome sequence of formalin-fixed breast cancer specimens". Nucleic Acids Res. 40 (14): e107. doi:10.1093/nar/gks299. PMC 3413110. PMID 22492626.
  18. ^ Berger MF; Hodis E; Heffernan TP; Deribe YL; Lawrence MS; Protopopov A; Ivanova E; Watson IR; Nickerson E; Ghosh P; Zhang H; Zeid R; Ren X; Cibulskis K; Sivachenko AY; Wagle N; Sucker A; Sougnez C; Onofrio R; Ambrogio L; Auclair D; Fennell T; Carter SL; Drier Y; Stojanov P; Singer MA; Voet D; Jing R; Saksena G; Barretina J; Ramos AH; Pugh TJ; Stransky N; Parkin M; Winckler W; Mahan S; Ardlie K; Baldwin J; Wargo J; Schadendorf D; Meyerson M; Gabriel SB; Golub TR; Wagner SN; Lander ES; Getz G; Chin L; Garraway LA (May 2012). "Melanoma genome sequencing reveals frequent PREX2 mutations". Nature. 485 (7399): 502–6. Bibcode:2012Natur.485..502B. doi:10.1038/nature11071. PMC 3367798. PMID 22622578.
  19. ^ Illingworth RS, Gruenewald-Schneider U, Webb S, Kerr AR, James KD, Turner DJ, Smith C, Harrison DJ, Andrews R, Bird AP (2010). "Orphan CpG islands identify numerous conserved promoters in the mammalian genome". PLOS Genet. 6 (9): e1001134. doi:10.1371/journal.pgen.1001134. PMC 2944787. PMID 20885785.
  20. ^ Wei J, Li G, Dang S, Zhou Y, Zeng K, Liu M (2016). "Discovery and Validation of Hypermethylated Markers for Colorectal Cancer". Dis. Markers. 2016: 1–7. doi:10.1155/2016/2192853. PMC 4963574. PMID 27493446.
  21. ^ a b Beggs AD, Jones A, El-Bahrawy M, El-Bahwary M, Abulafi M, Hodgson SV, Tomlinson IP (2013). "Whole-genome methylation analysis of benign and malignant colorectal tumours". J. Pathol. 229 (5): 697–704. doi:10.1002/path.4132. PMC 3619233. PMID 23096130.
  22. ^ Illingworth, Robert S.; Gruenewald-Schneider, Ulrike; Webb, Shaun; Kerr, Alastair R. W.; James, Keith D.; Turner, Daniel J.; Smith, Colin; Harrison, David J.; Andrews, Robert (2010-09-23). "Orphan CpG Islands Identify Numerous Conserved Promoters in the Mammalian Genome". PLOS Genetics. 6 (9): e1001134. doi:10.1371/journal.pgen.1001134. ISSN 1553-7404. PMC 2944787. PMID 20885785.
  23. ^ Saxonov, Serge; Berg, Paul; Brutlag, Douglas L. (2006-01-31). "A genome-wide analysis of CpG dinucleotides in the human genome distinguishes two distinct classes of promoters". Proceedings of the National Academy of Sciences. 103 (5): 1412–1417. Bibcode:2006PNAS..103.1412S. doi:10.1073/pnas.0510310103. ISSN 0027-8424. PMC 1345710. PMID 16432200.
  24. ^ Friedman, RC; Farh, KK; Burge, CB; Bartel, DP (January 2009). "Most mammalian mRNAs are conserved targets of microRNAs". Genome Res. 19 (1): 92–105. doi:10.1101/gr.082701.108. PMC 2612969. PMID 18955434.
  25. ^ Vrba, L; Muñoz-Rodríguez, JL; Stampfer, MR; Futscher, BW (2013). "miRNA Gene Promoters Are Frequent Targets of Aberrant DNA Methylation in Human Breast Cancer". PLOS ONE. 8 (1): e54398. Bibcode:2013PLoSO...854398V. doi:10.1371/journal.pone.0054398. PMC 3547033. PMID 23342147.
  26. ^ Bernstein C, Bernstein H, Payne CM, Garewal H (2002). "DNA repair/pro-apoptotic dual-role proteins in five major DNA repair pathways: fail-safe protection against carcinogenesis". Mutat. Res. 511 (2): 145–78. doi:10.1016/s1383-5742(02)00009-1. PMID 12052432.
  27. ^ Friedenson B (2007). "The BRCA1/2 pathway prevents hematologic cancers in addition to breast and ovarian cancers". BMC Cancer. 7: 152. doi:10.1186/1471-2407-7-152. PMC 1959234. PMID 17683622.
  28. ^ Wilson CA, Ramos L, Villaseñor MR, Anders KH, Press MF, Clarke K, Karlan B, Chen JJ, Scully R, Livingston D, Zuch RH, Kanter MH, Cohen S, Calzone FJ, Slamon DJ (1999). "Localization of human BRCA1 and its loss in high-grade, non-inherited breast carcinomas". Nat. Genet. 21 (2): 236–40. doi:10.1038/6029. PMID 9988281. S2CID 7988460.
  29. ^ Brody LC, Biesecker BB (1998). "Breast cancer susceptibility genes. BRCA1 and BRCA2". Medicine (Baltimore). 77 (3): 208–26. doi:10.1097/00005792-199805000-00006. PMID 9653432.
  30. ^ Esteller M, Silva JM, Dominguez G, Bonilla F, Matias-Guiu X, Lerma E, Bussaglia E, Prat J, Harkes IC, Repasky EA, Gabrielson E, Schutte M, Baylin SB, Herman JG (2000). "Promoter hypermethylation and BRCA1 inactivation in sporadic breast and ovarian tumors". J. Natl. Cancer Inst. 92 (7): 564–9. doi:10.1093/jnci/92.7.564. PMID 10749912.
  31. ^ Krishnan K, Steptoe AL, Martin HC, Wani S, Nones K, Waddell N, Mariasegaram M, Simpson PT, Lakhani SR, Gabrielli B, Vlassov A, Cloonan N, Grimmond SM (2013). "MicroRNA-182-5p targets a network of genes involved in DNA repair". RNA. 19 (2): 230–42. doi:10.1261/rna.034926.112. PMC 3543090. PMID 23249749.
  32. ^ Moskwa P, Buffa FM, Pan Y, Panchakshari R, Gottipati P, Muschel RJ, Beech J, Kulshrestha R, Abdelmohsen K, Weinstock DM, Gorospe M, Harris AL, Helleday T, Chowdhury D (2011). "miR-182-mediated downregulation of BRCA1 impacts DNA repair and sensitivity to PARP inhibitors". Mol. Cell. 41 (2): 210–20. doi:10.1016/j.molcel.2010.12.005. PMC 3249932. PMID 21195000.
  33. ^ Garcia AI, Buisson M, Bertrand P, Rimokh R, Rouleau E, Lopez BS, Lidereau R, Mikaélian I, Mazoyer S (2011). "Down-regulation of BRCA1 expression by miR-146a and miR-146b-5p in triple negative sporadic breast cancers". EMBO Mol Med. 3 (5): 279–90. doi:10.1002/emmm.201100136. PMC 3377076. PMID 21472990.
  34. ^ Hu W, Coller J (2012). "What comes first: translational repression or mRNA degradation? The deepening mystery of microRNA function". Cell Res. 22 (9): 1322–4. doi:10.1038/cr.2012.80. PMC 3434348. PMID 22613951.
  35. ^ Jin B, Robertson KD (2013). "DNA Methyltransferases, DNA Damage Repair, and Cancer". Epigenetic Alterations in Oncogenesis. Advances in Experimental Medicine and Biology. Vol. 754. pp. 3–29. doi:10.1007/978-1-4419-9967-2_1. ISBN 978-1-4419-9966-5. PMC 3707278. PMID 22956494.
  36. ^ Bernstein C, Nfonsam V, Prasad AR, Bernstein H (2013). "Epigenetic field defects in progression to cancer". World J Gastrointest Oncol. 5 (3): 43–9. doi:10.4251/wjgo.v5.i3.43. PMC 3648662. PMID 23671730.
  37. ^ Nawrot TS, Martens DS, Hara A, Plusquin M, Vangronsveld J, Roels HA, Staessen JA (2015). "Association of total cancer and lung cancer with environmental exposure to cadmium: the meta-analytical evidence". Cancer Causes Control. 26 (9): 1281–8. doi:10.1007/s10552-015-0621-5. PMID 26109463. S2CID 9729454.
  38. ^ Cohen SM, Arnold LL, Beck BD, Lewis AS, Eldan M (2013). "Evaluation of the carcinogenicity of inorganic arsenic". Crit. Rev. Toxicol. 43 (9): 711–52. doi:10.3109/10408444.2013.827152. PMID 24040994. S2CID 26873122.
  39. ^ a b Bhattacharjee P, Banerjee M, Giri AK (2013). "Role of genomic instability in arsenic-induced carcinogenicity. A review". Environ Int. 53: 29–40. Bibcode:2013EnInt..53...29B. doi:10.1016/j.envint.2012.12.004. PMID 23314041.[permanent dead link]
  40. ^ a b Ji W, Yang L, Yuan J, Yang L, Zhang M, Qi D, Duan X, Xuan A, Zhang W, Lu J, Zhuang Z, Zeng G (2013). "MicroRNA-152 targets DNA methyltransferase 1 in NiS-transformed cells via a feedback mechanism". Carcinogenesis. 34 (2): 446–53. doi:10.1093/carcin/bgs343. PMID 23125218.
  41. ^ Lei YX, Lu Q, Shao C, He CC, Lei ZN, Lian YY (2015). "Expression profiles of DNA repair-related genes in rat target organs under subchronic cadmium exposure". Genet. Mol. Res. 14 (1): 515–24. doi:10.4238/2015.January.26.5. PMID 25729986.
  42. ^ a b c Arita A, Muñoz A, Chervona Y, Niu J, Qu Q, Zhao N, Ruan Y, Kiok K, Kluz T, Sun H, Clancy HA, Shamy M, Costa M (2013). "Gene expression profiles in peripheral blood mononuclear cells of Chinese nickel refinery workers with high exposures to nickel and control subjects". Cancer Epidemiol. Biomarkers Prev. 22 (2): 261–9. doi:10.1158/1055-9965.EPI-12-1011. PMC 3565097. PMID 23195993.
  43. ^ Sun H, Shamy M, Costa M (2013). "Nickel and epigenetic gene silencing". Genes. 4 (4): 583–95. doi:10.3390/genes4040583. PMC 3927569. PMID 24705264.
  • Monti M (2000). L'ulcera cutanea: approccio multidisciplinare alla diagnosi ed al trattamento (in Italian). Milan: Springer. ISBN 978-88-470-0072-8.
  • Francesco M (2001). Trattato di clinica e terapia chirurgica (in Italian). Padua: Piccin. ISBN 978-88-299-1566-8.
  • Fishman JR, Parker MG (1991). "Malignancy and chronic wounds: Marjolin's Ulcer". J. Burn Care Rehabil. 12 (3): 218–23. doi:10.1097/00004630-199105000-00004. PMID 1885637.[unreliable medical source?]

January 01, 1970
malignant, transformation, confused, with, transformation, genetics, incorporation, foreign, bacteria, process, which, cells, acquire, properties, cancer, this, occur, primary, process, normal, tissue, secondarily, malignant, degeneration, previously, existing. Not to be confused with Transformation genetics the incorporation of foreign DNA by bacteria Malignant transformation is the process by which cells acquire the properties of cancer This may occur as a primary process in normal tissue or secondarily as malignant degeneration of a previously existing benign tumor Contents 1 Causes 2 Examples of diet related malignant transformation 2 1 Diet and colon cancer 2 2 Diet and lung cancer 3 Due to tobacco 4 Due to infection 4 1 Viruses 4 2 Bacteria 4 2 1 Helicobacter pylori and gastric cancer 4 2 2 Other bacterial roles in carcinogenesis 5 Common underlying factors in cancer 5 1 Mutations 5 2 Epigenetic alterations 5 2 1 Transcription silencing 5 2 2 Post transcriptional silencing 6 DNA repair gene silencing 7 Induced by heavy metals 8 Clinical signs 9 See also 10 ReferencesCauses editThere are many causes of primary malignant transformation or tumorigenesis Most human cancers in the United States are caused by external factors and these factors are largely avoidable 1 2 3 These factors were summarized by Doll and Peto in 1981 1 and were still considered to be valid in 2015 2 These factors are listed in the table External factors in cancer Factor Estimated percent of cancer deaths Diet 35 Tobacco 30 Infection 10 Reproductive and sexual behaviora 7 Occupation 4 Alcohol 3 Sunlight UV 3 Pollution 2 Medicines and medical procedures 1 Food additives lt 1 Industrial products lt 1 a Reproductive and sexual behaviors include number of partners age at first menstruation zero versus one or more live birthsExamples of diet related malignant transformation editDiet and colon cancer edit Colon cancer provides one example of the mechanisms by which diet the top factor listed in the table is an external factor in cancer The Western diet of African Americans in the United States is associated with a yearly colon cancer rate of 65 per 100 000 individuals while the high fiber low fat diet of rural Native Africans in South Africa is associated with a yearly colon cancer rate of lt 5 per 100 000 4 Feeding the Western diet for two weeks to Native Africans increased their secondary bile acids including carcinogenic deoxycholic acid 5 by 400 and also changed the colonic microbiota 4 Evidence reviewed by Sun and Kato 6 indicates that differences in human colonic microbiota play an important role in the progression of colon cancer Diet and lung cancer edit A second example relating a dietary component to a cancer is illustrated by lung cancer Two large population based studies were performed one in Italy and one in the United States 7 In Italy the study population consisted of two cohorts the first 1721 individuals diagnosed with lung cancer and no severe disease and the second 1918 control individuals with absence of lung cancer history or any advanced diseases All individuals filled out a food frequency questionnaire including consumption of walnuts hazelnuts almonds and peanuts and indicating smoking status In the United States 495 785 members of AARP were questioned on consumption of peanuts walnuts seeds or other nuts in addition to other foods and smoking status In this U S study 18 533 incident lung cancer cases were identified during up to 16 years of follow up Overall individuals in the highest quintile of frequency of nut consumption had a 26 lower risk of lung cancer in the Italian study and a 14 lower risk of lung cancer in the U S study Similar results were obtained among individuals who were smokers Due to tobacco editThe most important chemical compounds in smoked tobacco that are carcinogenic are those that produce DNA damage since such damage appears to be the primary underlying cause of cancer 8 Cunningham et al 9 combined the microgram weight of the compound in the smoke of one cigarette with the known genotoxic effect per microgram to identify the most carcinogenic compounds in cigarette smoke These compounds and their genotoxic effects are listed in the article Cigarette The top three compounds are acrolein formaldehyde and acrylonitrile all known carcinogens Due to infection editViruses edit In 2002 the World Health Organizations International Agency for Research on Cancer 10 estimated that 11 9 of human cancers are caused by one of seven viruses see Oncovirus overview table These are Epstein Barr virus EBV or HHV4 Kaposi s sarcoma associated herpesvirus KSHV or HHV8 Hepatitis B and Hepatitis C viruses HBV and HCV Human T lymphotrophic virus 1 HTLV 1 Merkel cell polyomavirus MCPyV and a group of alpha Human papillomaviruses HPVs 11 Bacteria edit Helicobacter pylori and gastric cancer edit In 1995 epidemiologic evidence indicated that Helicobacter pylori infection increases the risk for gastric carcinoma 12 More recently experimental evidence showed that infection with Helicobacter pylori cagA positive bacterial strains results in severe degrees of inflammation and oxidative DNA damage leading to progression to gastric cancer 13 Other bacterial roles in carcinogenesis edit Perera et al 14 referred to a number of articles pointing to roles of bacteria in other cancers They pointed to single studies on the role of Chlamydia trachomatis in cervical cancer Salmonella typhi in gallbladder cancer and both Bacteroides fragilis and Fusobacterium nucleatum in colon cancer Meurman has recently summarized evidence connecting oral microbiota with carcinogenesis 15 Although suggestive these studies need further confirmation Common underlying factors in cancer editMutations edit One underlying commonality in cancers is genetic mutation acquired either by inheritance or more commonly by mutations in one s somatic DNA over time The mutations considered important in cancers are those that alter protein coding genes the exome As Vogelstein et al point out a typical tumor contains two to eight exome driver gene mutations and a larger number of exome mutations that are passengers that confer no selective growth advantage 16 Cancers also generally have genome instability that includes a high frequency of mutations in the noncoding DNA that makes up about 98 of the human genome The average number of DNA sequence mutations in the entire genome of breast cancer tissue is about 20 000 17 In an average melanoma where melanomas have a higher exome mutation frequency 16 the total number of DNA sequence mutations is about 80 000 18 Epigenetic alterations edit Transcription silencing edit A second underlying commonality in cancers is altered epigenetic regulation of transcription In cancers loss of gene expression occurs about 10 times more frequently by epigenetic transcription silencing caused for example by promoter hypermethylation of CpG islands than by mutations As Vogelstein et al 16 point out in a colorectal cancer there are usually about 3 to 6 driver mutations and 33 to 66 hitchhiker or passenger mutations 16 In contrast the frequency of epigenetic alterations is much higher In colon tumors compared to adjacent normal appearing colonic mucosa there are about 600 to 800 heavily methylated CpG islands in promoters of genes in the tumors while the corresponding CpG islands are not methylated in the adjacent mucosa 19 20 21 Such methylation turns off expression of a gene as completely as a mutation would Around 60 70 of human genes have a CpG island in their promoter region 22 23 In colon cancers in addition to hypermethylated genes several hundred other genes have hypomethylated under methylated promoters thereby causing these genes to be turned on when they ordinarily would be turned off 21 Post transcriptional silencing edit Epigenetic alterations are also carried out by another major regulatory element that of microRNAs miRNAs In mammals these small non coding RNA molecules regulate about 60 of the transcriptional activity of protein encoding genes 24 Epigenetic silencing or epigenetic over expression of miRNA genes caused by aberrant DNA methylation of the promoter regions controlling their expression is a frequent event in cancer cells Almost one third of miRNA promoters active in normal mammary cells were found to be hypermethylated in breast cancer cells and that is a several fold greater proportion of promoters with altered methylation than is usually observed for protein coding genes 25 Other microRNA promoters are hypomethylated in breast cancers and as a result these microRNAs are over expressed Several of these over expressed microRNAs have a major influence in progression to breast cancer BRCA1 is normally expressed in the cells of breast and other tissue where it helps repair damaged DNA or destroy cells if DNA cannot be repaired 26 BRCA1 is involved in the repair of chromosomal damage with an important role in the error free repair of DNA double strand breaks 27 BRCA1 expression is reduced or undetectable in the majority of high grade ductal breast cancers 28 Only about 3 8 of all women with breast cancer carry a mutation in BRCA1 or BRCA2 29 BRCA1 promoter hypermethylation was present in only 13 of unselected primary breast carcinomas 30 However breast cancers were found to have an average of about 100 fold increase in miR 182 compared to normal breast tissue 31 In breast cancer cell lines there is an inverse correlation of BRCA1 protein levels with miR 182 expression 32 Thus it appears that much of the reduction or absence of BRCA1 in high grade ductal breast cancers may be due to over expressed miR 182 In addition to miR 182 a pair of almost identical microRNAs miR 146a and miR 146b 5p also repress BRCA1 expression These two microRNAs are over expressed in triple negative tumors and their over expression results in BRCA1 inactivation 33 Thus miR 146a and or miR 146b 5p may also contribute to reduced expression of BRCA1 in these triple negative breast cancers Post transcriptional regulation by microRNA occurs either through translational silencing of the target mRNA or through degradation of the target mRNA via complementary binding mostly to specific sequences in the three prime untranslated region of the target gene s mRNA 34 The mechanism of translational silencing or degradation of target mRNA is implemented through the RNA induced silencing complex RISC DNA repair gene silencing editMain articles DNA methylation in cancer and Regulation of transcription in cancer Silencing of a DNA repair gene by hypermethylation or other epigenetic alteration appears to be a frequent step in progression to cancer As summarized in a review citation needed promoter hypermethylation of DNA repair gene MGMT occurs in 93 of bladder cancers 88 of stomach cancers 74 of thyroid cancers 40 90 of colorectal cancers and 50 of brain cancers In addition promoter hypermethylation of DNA repair genes LIG4 NEIL1 ATM MLH1 or FANCB occurs at frequencies of between 33 and 82 in one or more of head and neck cancers non small cell lung cancers or non small cell lung cancer squamous cell carcinomas Further the article Werner syndrome ATP dependent helicase indicates the DNA repair gene WRN has a promoter that is often hypermethylated in a variety of cancers with WRN hypermethylation occurring in 11 to 38 of colorectal head and neck stomach prostate breast thyroid non Hodgkin lymphoma chondrosarcoma and osteosarcoma cancers Such silencing likely acts similarly to a germ line mutation in a DNA repair gene and predisposes the cell and its descendants to progression to cancer 35 Another review 36 points out that when a gene necessary for DNA repair is epigenetically silenced DNA repair would tend to be deficient and DNA damages can accumulate Increased DNA damage can cause increased errors during DNA synthesis leading to mutations that give rise to cancer Induced by heavy metals editThe heavy metals cadmium arsenic and nickel are all carcinogenic when present above certain levels 37 38 39 40 Cadmium is known to be carcinogenic possibly due to reduction of DNA repair Lei et al 41 evaluated five DNA repair genes in rats after exposure of the rats to low levels of cadmium They found that cadmium caused repression of three of the DNA repair genes XRCC1 needed for base excision repair OGG1 needed for base excision repair and ERCC1 needed for nucleotide excision repair Repression of these genes was not due to methylation of their promoters Arsenic carcinogenicity was reviewed by Bhattacharjee et al 39 They summarized the role of arsenic and its metabolites in generating oxidative stress resulting in DNA damage In addition to causing DNA damage arsenic also causes repression of several DNA repair enzymes in both the base excision repair pathway and the nucleotide excision repair pathway Bhattacharjee et al further reviewed the role of arsenic in causing telomere dysfunction mitotic arrest defective apoptosis as well as altered promoter methylation and miRNA expression Each of these alterations could contribute to arsenic induced carcinogenesis Nickel compounds are carcinogenic and occupational exposure to nickel is associated with an increased risk of lung and nasal cancers 42 Nickel compounds exhibit weak mutagenic activity but they considerably alter the transcriptional landscape of the DNA of exposed individuals 42 Arita et al 42 examined the peripheral blood mononuclear cells of eight nickel refinery workers and ten non exposed workers They found 2756 differentially expressed genes with 770 up regulated genes and 1986 down regulated genes DNA repair genes were significantly over represented among the differentially expressed genes with 29 DNA repair genes repressed in the nickel refinery workers and two over expressed The alterations in gene expression appear to be due to epigenetic alterations of histones methylations of gene promoters and hypermethylation of at least microRNA miR 152 40 43 Clinical signs editMalignant transformation of cells in a benign tumor may be detected by pathologic examination of tissues Often the clinical signs and symptoms are suggestive of a malignant tumor The physician during the medical history examination can find that there have been changes in size or patient sensation and upon direct examination that there has been a change in the lesion itself Risk assessments can be done and are known for certain types of benign tumor which are known to undergo malignant transformation One of the better known examples of this phenomenon is the progression of a nevus to melanoma See also editAbortive transformationReferences edit a b Doll R Peto R 1981 The causes of cancer quantitative estimates of avoidable risks of cancer in the United States today J Natl Cancer Inst 66 6 1191 308 doi 10 1093 jnci 66 6 1192 PMID 7017215 a b Blot WJ Tarone RE 2015 Doll and Peto s quantitative estimates of cancer risks holding generally true for 35 years J Natl Cancer Inst 107 4 djv044 doi 10 1093 jnci djv044 PMID 25739419 Song M Giovannucci EL 2015 RE Doll and Peto s Quantitative Estimates of Cancer Risks Holding Generally True for 35 Years J Natl Cancer Inst 107 10 djv240 doi 10 1093 jnci djv240 PMID 26271254 a b O Keefe SJ Li JV Lahti L Ou J Carbonero F Mohammed K Posma JM Kinross J Wahl E Ruder E Vipperla K Naidoo V Mtshali L Tims S Puylaert PG DeLany J Krasinskas A Benefiel AC Kaseb HO Newton K Nicholson JK de Vos WM Gaskins HR Zoetendal EG 2015 Fat fibre and cancer risk in African Americans and rural Africans Nat Commun 6 6342 Bibcode 2015NatCo 6 6342O doi 10 1038 ncomms7342 PMC 4415091 PMID 25919227 Bernstein C Holubec H Bhattacharyya AK Nguyen H Payne CM Zaitlin B Bernstein H 2011 Carcinogenicity of deoxycholate a secondary bile acid Arch Toxicol 85 8 863 71 doi 10 1007 s00204 011 0648 7 PMC 3149672 PMID 21267546 Sun J Kato I 2016 Gut microbiota inflammation and colorectal cancer Genes amp Diseases 3 2 130 143 doi 10 1016 j gendis 2016 03 004 PMC 5221561 PMID 28078319 Lee JT Lai GY Liao LM Subar AF Bertazzi PA Pesatori AC Freedman ND Landi MT Lam TK 2017 Nut consumption and lung cancer risk Results from two large observational studies Cancer Epidemiol Biomarkers Prev 26 6 826 836 doi 10 1158 1055 9965 EPI 16 0806 PMC 6020049 PMID 28077426 Kastan MB 2008 DNA damage responses mechanisms and roles in human disease 2007 G H A Clowes Memorial Award Lecture Mol Cancer Res 6 4 517 24 doi 10 1158 1541 7786 MCR 08 0020 PMID 18403632 Cunningham FH Fiebelkorn S Johnson M Meredith C 2011 A novel application of the Margin of Exposure approach segregation of tobacco smoke toxicants Food Chem Toxicol 49 11 2921 33 doi 10 1016 j fct 2011 07 019 PMID 21802474 Parkin Donald Maxwell 2006 The global health burden of infection associated cancers in the year 2002 International Journal of Cancer 118 12 3030 44 doi 10 1002 ijc 21731 PMID 16404738 McBride AA 2017 Perspective The Promise of Proteomics in the Study of Oncogenic Viruses Mol Cell Proteomics 16 4 suppl 1 S65 S74 doi 10 1074 mcp O116 065201 PMC 5393395 PMID 28104704 Correa P 1995 Helicobacter pylori and gastric carcinogenesis Am J Surg Pathol 19 Suppl 1 S37 43 PMID 7762738 Raza Y Khan A Farooqui A Mubarak M Facista A Akhtar SS Khan S Kazi JI Bernstein C Kazmi SU 2014 Oxidative DNA damage as a potential early biomarker of Helicobacter pylori associated carcinogenesis Pathol Oncol Res 20 4 839 46 doi 10 1007 s12253 014 9762 1 PMID 24664859 S2CID 18727504 Perera M Al Hebshi NN Speicher DJ Perera I Johnson NW 2016 Emerging role of bacteria in oral carcinogenesis a review with special reference to perio pathogenic bacteria J Oral Microbiol 8 32762 doi 10 3402 jom v8 32762 PMC 5039235 PMID 27677454 Meurman JH 2010 Oral microbiota and cancer J Oral Microbiol 2 5195 doi 10 3402 jom v2i0 5195 PMC 3084564 PMID 21523227 a b c d Vogelstein B Papadopoulos N Velculescu VE Zhou S Diaz LA Kinzler KW 2013 Cancer genome landscapes Science 339 6127 1546 58 Bibcode 2013Sci 339 1546V doi 10 1126 science 1235122 PMC 3749880 PMID 23539594 Yost SE Smith EN Schwab RB Bao L Jung H Wang X Voest E Pierce JP Messer K Parker BA Harismendy O Frazer KA August 2012 Identification of high confidence somatic mutations in whole genome sequence of formalin fixed breast cancer specimens Nucleic Acids Res 40 14 e107 doi 10 1093 nar gks299 PMC 3413110 PMID 22492626 Berger MF Hodis E Heffernan TP Deribe YL Lawrence MS Protopopov A Ivanova E Watson IR Nickerson E Ghosh P Zhang H Zeid R Ren X Cibulskis K Sivachenko AY Wagle N Sucker A Sougnez C Onofrio R Ambrogio L Auclair D Fennell T Carter SL Drier Y Stojanov P Singer MA Voet D Jing R Saksena G Barretina J Ramos AH Pugh TJ Stransky N Parkin M Winckler W Mahan S Ardlie K Baldwin J Wargo J Schadendorf D Meyerson M Gabriel SB Golub TR Wagner SN Lander ES Getz G Chin L Garraway LA May 2012 Melanoma genome sequencing reveals frequent PREX2 mutations Nature 485 7399 502 6 Bibcode 2012Natur 485 502B doi 10 1038 nature11071 PMC 3367798 PMID 22622578 Illingworth RS Gruenewald Schneider U Webb S Kerr AR James KD Turner DJ Smith C Harrison DJ Andrews R Bird AP 2010 Orphan CpG islands identify numerous conserved promoters in the mammalian genome PLOS Genet 6 9 e1001134 doi 10 1371 journal pgen 1001134 PMC 2944787 PMID 20885785 Wei J Li G Dang S Zhou Y Zeng K Liu M 2016 Discovery and Validation of Hypermethylated Markers for Colorectal Cancer Dis Markers 2016 1 7 doi 10 1155 2016 2192853 PMC 4963574 PMID 27493446 a b Beggs AD Jones A El Bahrawy M El Bahwary M Abulafi M Hodgson SV Tomlinson IP 2013 Whole genome methylation analysis of benign and malignant colorectal tumours J Pathol 229 5 697 704 doi 10 1002 path 4132 PMC 3619233 PMID 23096130 Illingworth Robert S Gruenewald Schneider Ulrike Webb Shaun Kerr Alastair R W James Keith D Turner Daniel J Smith Colin Harrison David J Andrews Robert 2010 09 23 Orphan CpG Islands Identify Numerous Conserved Promoters in the Mammalian Genome PLOS Genetics 6 9 e1001134 doi 10 1371 journal pgen 1001134 ISSN 1553 7404 PMC 2944787 PMID 20885785 Saxonov Serge Berg Paul Brutlag Douglas L 2006 01 31 A genome wide analysis of CpG dinucleotides in the human genome distinguishes two distinct classes of promoters Proceedings of the National Academy of Sciences 103 5 1412 1417 Bibcode 2006PNAS 103 1412S doi 10 1073 pnas 0510310103 ISSN 0027 8424 PMC 1345710 PMID 16432200 Friedman RC Farh KK Burge CB Bartel DP January 2009 Most mammalian mRNAs are conserved targets of microRNAs Genome Res 19 1 92 105 doi 10 1101 gr 082701 108 PMC 2612969 PMID 18955434 Vrba L Munoz Rodriguez JL Stampfer MR Futscher BW 2013 miRNA Gene Promoters Are Frequent Targets of Aberrant DNA Methylation in Human Breast Cancer PLOS ONE 8 1 e54398 Bibcode 2013PLoSO 854398V doi 10 1371 journal pone 0054398 PMC 3547033 PMID 23342147 Bernstein C Bernstein H Payne CM Garewal H 2002 DNA repair pro apoptotic dual role proteins in five major DNA repair pathways fail safe protection against carcinogenesis Mutat Res 511 2 145 78 doi 10 1016 s1383 5742 02 00009 1 PMID 12052432 Friedenson B 2007 The BRCA1 2 pathway prevents hematologic cancers in addition to breast and ovarian cancers BMC Cancer 7 152 doi 10 1186 1471 2407 7 152 PMC 1959234 PMID 17683622 Wilson CA Ramos L Villasenor MR Anders KH Press MF Clarke K Karlan B Chen JJ Scully R Livingston D Zuch RH Kanter MH Cohen S Calzone FJ Slamon DJ 1999 Localization of human BRCA1 and its loss in high grade non inherited breast carcinomas Nat Genet 21 2 236 40 doi 10 1038 6029 PMID 9988281 S2CID 7988460 Brody LC Biesecker BB 1998 Breast cancer susceptibility genes BRCA1 and BRCA2 Medicine Baltimore 77 3 208 26 doi 10 1097 00005792 199805000 00006 PMID 9653432 Esteller M Silva JM Dominguez G Bonilla F Matias Guiu X Lerma E Bussaglia E Prat J Harkes IC Repasky EA Gabrielson E Schutte M Baylin SB Herman JG 2000 Promoter hypermethylation and BRCA1 inactivation in sporadic breast and ovarian tumors J Natl Cancer Inst 92 7 564 9 doi 10 1093 jnci 92 7 564 PMID 10749912 Krishnan K Steptoe AL Martin HC Wani S Nones K Waddell N Mariasegaram M Simpson PT Lakhani SR Gabrielli B Vlassov A Cloonan N Grimmond SM 2013 MicroRNA 182 5p targets a network of genes involved in DNA repair RNA 19 2 230 42 doi 10 1261 rna 034926 112 PMC 3543090 PMID 23249749 Moskwa P Buffa FM Pan Y Panchakshari R Gottipati P Muschel RJ Beech J Kulshrestha R Abdelmohsen K Weinstock DM Gorospe M Harris AL Helleday T Chowdhury D 2011 miR 182 mediated downregulation of BRCA1 impacts DNA repair and sensitivity to PARP inhibitors Mol Cell 41 2 210 20 doi 10 1016 j molcel 2010 12 005 PMC 3249932 PMID 21195000 Garcia AI Buisson M Bertrand P Rimokh R Rouleau E Lopez BS Lidereau R Mikaelian I Mazoyer S 2011 Down regulation of BRCA1 expression by miR 146a and miR 146b 5p in triple negative sporadic breast cancers EMBO Mol Med 3 5 279 90 doi 10 1002 emmm 201100136 PMC 3377076 PMID 21472990 Hu W Coller J 2012 What comes first translational repression or mRNA degradation The deepening mystery of microRNA function Cell Res 22 9 1322 4 doi 10 1038 cr 2012 80 PMC 3434348 PMID 22613951 Jin B Robertson KD 2013 DNA Methyltransferases DNA Damage Repair and Cancer Epigenetic Alterations in Oncogenesis Advances in Experimental Medicine and Biology Vol 754 pp 3 29 doi 10 1007 978 1 4419 9967 2 1 ISBN 978 1 4419 9966 5 PMC 3707278 PMID 22956494 Bernstein C Nfonsam V Prasad AR Bernstein H 2013 Epigenetic field defects in progression to cancer World J Gastrointest Oncol 5 3 43 9 doi 10 4251 wjgo v5 i3 43 PMC 3648662 PMID 23671730 Nawrot TS Martens DS Hara A Plusquin M Vangronsveld J Roels HA Staessen JA 2015 Association of total cancer and lung cancer with environmental exposure to cadmium the meta analytical evidence Cancer Causes Control 26 9 1281 8 doi 10 1007 s10552 015 0621 5 PMID 26109463 S2CID 9729454 Cohen SM Arnold LL Beck BD Lewis AS Eldan M 2013 Evaluation of the carcinogenicity of inorganic arsenic Crit Rev Toxicol 43 9 711 52 doi 10 3109 10408444 2013 827152 PMID 24040994 S2CID 26873122 a b Bhattacharjee P Banerjee M Giri AK 2013 Role of genomic instability in arsenic induced carcinogenicity A review Environ Int 53 29 40 Bibcode 2013EnInt 53 29B doi 10 1016 j envint 2012 12 004 PMID 23314041 permanent dead link a b Ji W Yang L Yuan J Yang L Zhang M Qi D Duan X Xuan A Zhang W Lu J Zhuang Z Zeng G 2013 MicroRNA 152 targets DNA methyltransferase 1 in NiS transformed cells via a feedback mechanism Carcinogenesis 34 2 446 53 doi 10 1093 carcin bgs343 PMID 23125218 Lei YX Lu Q Shao C He CC Lei ZN Lian YY 2015 Expression profiles of DNA repair related genes in rat target organs under subchronic cadmium exposure Genet Mol Res 14 1 515 24 doi 10 4238 2015 January 26 5 PMID 25729986 a b c Arita A Munoz A Chervona Y Niu J Qu Q Zhao N Ruan Y Kiok K Kluz T Sun H Clancy HA Shamy M Costa M 2013 Gene expression profiles in peripheral blood mononuclear cells of Chinese nickel refinery workers with high exposures to nickel and control subjects Cancer Epidemiol Biomarkers Prev 22 2 261 9 doi 10 1158 1055 9965 EPI 12 1011 PMC 3565097 PMID 23195993 Sun H Shamy M Costa M 2013 Nickel and epigenetic gene silencing Genes 4 4 583 95 doi 10 3390 genes4040583 PMC 3927569 PMID 24705264 Monti M 2000 L ulcera cutanea approccio multidisciplinare alla diagnosi ed al trattamento in Italian Milan Springer ISBN 978 88 470 0072 8 Francesco M 2001 Trattato di clinica e terapia chirurgica in Italian Padua Piccin ISBN 978 88 299 1566 8 Fishman JR Parker MG 1991 Malignancy and chronic wounds Marjolin s Ulcer J Burn Care Rehabil 12 3 218 23 doi 10 1097 00004630 199105000 00004 PMID 1885637 unreliable medical source Retrieved from https en wikipedia org w index php title Malignant transformation amp oldid 1217047814, wikipedia, wiki, book, books, library,

article

, read, download, free, free download, mp3, video, mp4, 3gp, jpg, jpeg, gif, png, picture, music, song, movie, book, game, games.