DNA-PKcs

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DNA-dependent protein kinase, catalytic subunit, also known as DNA-PKcs, is an enzyme that in humans is encoded by the gene designated as PRKDC or XRCC7.[1] DNA-PKcs belongs to the phosphatidylinositol 3-kinase-related kinase protein family. The DNA-Pkcs protein is a serine/threonine protein kinase comprising a single polypeptide chain of 4,128 amino acids.[2][3]

Function

DNA-PKcs is the catalytic subunit of a nuclear DNA-dependent serine/threonine protein kinase called DNA-PK. The second component is the autoimmune antigen Ku. On its own, DNA-PKcs is inactive and relies on Ku to direct it to DNA ends and trigger its kinase activity.[4] DNA-PKcs is required for the non-homologous end joining (NHEJ) pathway of DNA repair, which rejoins double-strand breaks. It is also required for V(D)J recombination, a process that utilizes NHEJ to promote immune system diversity. DNA-PKcs knockout mice have severe combined immunodeficiency due to their V(D)J recombination defect.

Many proteins have been identified as substrates for the kinase activity of DNA-PK. Autophosphorylation of DNA-PKcs appears to play a key role in NHEJ and is thought to induce a conformational change that allows end processing enzymes to access the ends of the double-strand break.[5] DNA-PK also cooperates with ATR and ATM to phosphorylate proteins involved in the DNA damage checkpoint.

Cancer

DNA damage appears to be the primary underlying cause of cancer,[6][7] and deficiencies in DNA repair genes likely underlie many forms of cancer.[8][9] If DNA repair is deficient, DNA damage tends to accumulate. Such excess DNA damage may increase mutations due to error-prone translesion synthesis. Excess DNA damage may also increase epigenetic alterations due to errors during DNA repair.[10][11] Such mutations and epigenetic alterations may give rise to cancer.

PRKDC (DNA-PKcs) mutations were found in 3 out of 10 of endometriosis-associated ovarian cancers, as well as in the field defects from which they arose.[12] They were also found in 10% of breast and pancreatic cancers.[13]

Reductions in expression of DNA repair genes (usually caused by epigenetic alterations) are very common in cancers, and are ordinarily even more frequent than mutational defects in DNA repair genes in cancers.[14] DNA-PKcs expression was reduced by 23% to 57% in six cancers as indicated in the table.

Frequency of reduced expression of DNA-PKcs in sporadic cancers
Cancer Frequency of reduction in cancer Ref.
Breast cancer 57% [15]
Prostate cancer 51% [16]
Cervical carcinoma 32% [17]
Nasopharyngeal carcinoma 30% [18]
Epithelial ovarian cancer 29% [19]
Gastric cancer 23% [20]

It is not clear what causes reduced expression of DNA-PKcs in cancers. MicroRNA-101 targets DNA-PKcs via binding to the 3'- UTR of DNA-PKcs mRNA and efficiently reduces protein levels of DNA-PKcs.[21] But miR-101 is more often decreased in cancers, rather than increased.[22][23]

HMGA2 protein could also have an effect on DNA-PKcs. HMGA2 delays the release of DNA-PKcs from sites of double-strand breaks, interfering with DNA repair by non-homologous end joining and causing chromosomal aberrations.[24] The let-7a microRNA normally represses the HMGA2 gene.[25][26] In normal adult tissues, almost no HMGA2 protein is present. In many cancers, let-7 microRNA is repressed. As an example, in breast cancers the promoter region controlling let-7a-3/let-7b microRNA is frequently repressed by hypermethylation.[27] Epigenetic reduction or absence of let-7a microRNA allows high expression of the HMGA2 protein and this would lead to defective expression of DNA-PKcs.

DNA-PKcs can be up-regulated by stressful conditions such as in Helicobacter pylori-associated gastritis.[28] After ionizing radiation DNA-PKcs was increased in the surviving cells of oral squamous cell carcinoma tissues.[29]

The ATM protein is important in homologous recombinational repair (HRR) of DNA double strand breaks. When cancer cells are deficient in ATM the cells are "addicted" to DNA-PKcs, important in the alternative DNA repair pathway for double-strand breaks, non-homologous end joining (NHEJ).[30] That is, in ATM-mutant cells, an inhibitor of DNA-PKcs causes high levels of apoptotic cell death. In ATM mutant cells, additional loss of DNA-PKcs leaves the cells without either major pathway (HRR and NHEJ) for repair of DNA double-strand breaks.

Elevated DNA-PKcs expression is found in a large fraction (40% to 90%) of some cancers (the remaining fraction of cancers often has reduced or absent expression of DNA-PKcs). The elevation of DNA-PKcs is thought to reflect the induction of a compensatory DNA repair capability, due to the genome instability in these cancers.[31] (As indicated in the article Genome instability, such genome instability may be due to deficiencies in other DNA repair genes present in the cancers.) Elevated DNA-PKcs is thought to be "beneficial to the tumor cells",[31] though it would be at the expense of the patient. As indicated in a table listing 12 types of cancer reported in 20 publications,[31] the fraction of cancers with over-expression of DNA-PKcs is often associated with an advanced stage of the cancer and shorter survival time for the patient. However, the table also indicates that for some cancers, the fraction of cancers with reduced or absent DNA-PKcs is also associated with advanced stage and poor patient survival.

Aging

Non-homologous end joining (NHEJ) is the principal DNA repair process used by mammalian somatic cells to cope with double-strand breaks that continually occur in the genome. DNA-PKcs is one of the key components of the NHEJ machinery. DNA-PKcs deficient mice have a shorter lifespan and show an earlier onset of numerous aging related pathologies than corresponding wild-type littermates.[32][33] These findings suggest that failure to efficiently repair DNA double-strand breaks results in premature aging, consistent with the DNA damage theory of aging. (See also Bernstein et al.[34])

Interactions

DNA-PKcs has been shown to interact with:

See also

References

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  2. Sibanda BL, Chirgadze DY, Blundell TL (2010). "Crystal structure of DNA-PKcs reveals a large open-ring cradle comprised of HEAT repeats". Nature. 463 (7277): 118–21. doi:10.1038/nature08648. PMC 2811870. PMID 20023628.
  3. Hartley KO, Gell D, Smith GC, Zhang H, Divecha N, Connelly MA, Admon A, Lees-Miller SP, Anderson CW, Jackson SP (1995). "DNA-dependent protein kinase catalytic subunit: a relative of phosphatidylinositol 3-kinase and the ataxia telangiectasia gene product". Cell. 82 (5): 849–56. doi:10.1016/0092-8674(95)90482-4. PMID 7671312.
  4. "Entrez Gene: PRKDC protein kinase, DNA-activated, catalytic polypeptide".
  5. Meek K, Dang V, Lees-Miller SP (2008). DNA-PK: the means to justify the ends?. Adv. Immunol. Advances in Immunology. 99. pp. 33–58. doi:10.1016/S0065-2776(08)00602-0. ISBN 9780123743251. PMID 19117531.
  6. 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.
  7. Bernstein C, Prasad AR, Nfonsam V, Bernstein H. (2013). DNA Damage, DNA Repair and Cancer, New Research Directions in DNA Repair, Prof. Clark Chen (Ed.), ISBN 978-953-51-1114-6, InTech, http://www.intechopen.com/books/new-research-directions-in-dna-repair/dna-damage-dna-repair-and-cancer
  8. Harper JW, Elledge SJ (2007). "The DNA damage response: ten years after". Mol. Cell. 28 (5): 739–45. doi:10.1016/j.molcel.2007.11.015. PMID 18082599.
  9. Dietlein F, Reinhardt HC (2014). "Molecular pathways: exploiting tumor-specific molecular defects in DNA repair pathways for precision cancer therapy". Clin. Cancer Res. 20 (23): 5882–7. doi:10.1158/1078-0432.CCR-14-1165. PMID 25451105.
  10. O'Hagan HM, Mohammad HP, Baylin SB (2008). "Double strand breaks can initiate gene silencing and SIRT1-dependent onset of DNA methylation in an exogenous promoter CpG island". PLoS Genetics. 4 (8): e1000155. doi:10.1371/journal.pgen.1000155. PMC 2491723. PMID 18704159.
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  12. Er TK, Su YF, Wu CC, Chen CC, Wang J, Hsieh TH, Herreros-Villanueva M, Chen WT, Chen YT, Liu TC, Chen HS, Tsai EM (2016). "Targeted next-generation sequencing for molecular diagnosis of endometriosis-associated ovarian cancer". J. Mol. Med. 94 (7): 835–47. doi:10.1007/s00109-016-1395-2. PMID 26920370.
  13. Wang X, Szabo C, Qian C, Amadio PG, Thibodeau SN, Cerhan JR, Petersen GM, Liu W, Couch FJ (2008). "Mutational analysis of thirty-two double-strand DNA break repair genes in breast and pancreatic cancers". Cancer Res. 68 (4): 971–5. doi:10.1158/0008-5472.CAN-07-6272. PMID 18281469.
  14. Carol Bernstein and Harris Bernstein (2015). Epigenetic Reduction of DNA Repair in Progression to Cancer, Advances in DNA Repair, Prof. Clark Chen (Ed.), ISBN 978-953-51-2209-8, InTech, Available from: http://www.intechopen.com/books/advances-in-dna-repair/epigenetic-reduction-of-dna-repair-in-progression-to-cancer
  15. Söderlund Leifler K, Queseth S, Fornander T, Askmalm MS (2010). "Low expression of Ku70/80, but high expression of DNA-PKcs, predict good response to radiotherapy in early breast cancer". Int. J. Oncol. 37 (6): 1547–54. doi:10.3892/ijo_00000808. PMID 21042724.
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  17. Zhuang L, Yu SY, Huang XY, Cao Y, Xiong HH (2007). "[Potentials of DNA-PKcs, Ku80, and ATM in enhancing radiosensitivity of cervical carcinoma cells]". AI Zheng (in Chinese). 26 (7): 724–9. PMID 17626748.
  18. Lee SW, Cho KJ, Park JH, Kim SY, Nam SY, Lee BJ, Kim SB, Choi SH, Kim JH, Ahn SD, Shin SS, Choi EK, Yu E (2005). "Expressions of Ku70 and DNA-PKcs as prognostic indicators of local control in nasopharyngeal carcinoma". Int. J. Radiat. Oncol. Biol. Phys. 62 (5): 1451–7. doi:10.1016/j.ijrobp.2004.12.049. PMID 16029807.
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