The chart at right shows some frequent DNA damaging agents, examples of DNA lesions they cause, and the pathways that deal with these DNA damages. At least 169 enzymes are either directly employed in DNA repair or influence DNA repair processes. Of these, 83 are directly employed in repairing the 5 types of DNA damages illustrated in the chart. Some of the more well studied genes central to these repair processes are shown in the chart. The gene designations shown in red, gray or cyan indicate genes frequently epigenetically altered in various types of cancers. Two broad experimental survey articles also document most of these epigenetic DNA repair deficiencies in cancers. Red-highlighted genes are frequently reduced or silenced by epigenetic mechanisms in various cancers. When these genes have low or absent expression, DNA damages can accumulate. Replication errors past these damages (see
translesion synthesis) can lead to increased mutations and, ultimately, cancer. Epigenetic repression of DNA repair genes in
accurate DNA repair pathways appear to be central to
carcinogenesis. The two gray-highlighted genes
RAD51 and
BRCA2, are required for
homologous recombinational repair. They are sometimes epigenetically over-expressed and sometimes under-expressed in certain cancers. These cancers ordinarily have epigenetic deficiencies in other DNA repair genes such as
RAD51 and
BRCA2. These repair deficiencies would likely cause increased unrepaired DNA damages. The over-expression of
RAD51 and
BRCA2 seen in these cancers may reflect selective pressures for compensatory
RAD51 or
BRCA2 over-expression and increased homologous recombinational repair to at least partially deal with such excess DNA damages. In those cases where
RAD51 or
BRCA2 are under-expressed, this would itself lead to increased unrepaired DNA damages. Replication errors past these damages (see
translesion synthesis) could cause increased mutations and cancer, so that under-expression of
RAD51 or
BRCA2 would be carcinogenic in itself. Cyan-highlighted genes are in the
microhomology-mediated end joining (MMEJ) pathway and are up-regulated in cancer. MMEJ is an additional error-prone
inaccurate repair pathway for double-strand breaks. In MMEJ repair of a double-strand break, an homology of 5-25 complementary base pairs between both paired strands is sufficient to align the strands, but mismatched ends (flaps) are usually present. MMEJ removes the extra nucleotides (flaps) where strands are joined, and then ligates the strands to create an intact DNA double helix. MMEJ almost always involves at least a small deletion, so that it is a mutagenic pathway.
FEN1, the flap endonuclease in MMEJ, is epigenetically increased by promoter hypomethylation and is over-expressed in the majority of cancers of the breast, prostate, stomach, neuroblastomas, pancreas, and lung. PARP1 is also over-expressed when its promoter region
ETS site is epigenetically hypomethylated, and this contributes to progression to endometrial cancer, BRCA-mutated ovarian cancer, and BRCA-mutated serous ovarian cancer. Other genes in the
MMEJ pathway are also over-expressed in a number of cancers (see
MMEJ for summary), and are also shown in blue.
Frequencies of epimutations in DNA repair genes Deficiencies in DNA repair proteins that function in accurate DNA repair pathways increase the risk of mutation. Mutation rates are strongly increased in cells with mutations in
DNA mismatch repair or in
homologous recombinational repair (HRR). Individuals with inherited mutations in any of 34 DNA repair genes are at increased risk of cancer (see
DNA repair defects and increased cancer risk). In sporadic cancers, a deficiency in DNA repair is occasionally found to be due to a mutation in a DNA repair gene, but much more frequently reduced or absent expression of DNA repair genes is due to epigenetic alterations that reduce or silence gene expression. For example, for 113 colorectal cancers examined in sequence, only four had a
missense mutation in the DNA repair gene
MGMT, while the majority had reduced
MGMT expression due to methylation of the
MGMT promoter region (an epigenetic alteration). Similarly, out of 119 cases of mismatch repair-deficient colorectal cancers that lacked DNA repair gene
PMS2 expression, PMS2 protein was deficient in 6 due to mutations in the
PMS2 gene, while in 103 cases PMS2 expression was deficient because its pairing partner MLH1 was repressed due to promoter methylation (PMS2 protein is unstable in the absence of MLH1). (Also see
Mutation frequencies in cancers.) By comparison, the mutation frequency in the whole genome between generations for humans (parent to child) is about 70 new mutations per generation. In the protein coding regions of the genome, there are only about 0.35 mutations between parent/child generations (less than one mutated protein per generation). Whole genome sequencing in blood cells for a pair of identical twin 100-year-old centenarians only found 8 somatic differences, though somatic variation occurring in less than 20% of blood cells would be undetected. While DNA damages may give rise to mutations through error prone
translesion synthesis, DNA damages can also give rise to epigenetic alterations during faulty DNA repair processes. The DNA damages that accumulate due to epigenetic DNA repair defects can be a source of the increased epigenetic alterations found in many genes in cancers. In an early study, looking at a limited set of transcriptional promoters, Fernandez et al. examined the DNA methylation profiles of 855 primary tumors. Comparing each tumor type with its corresponding normal tissue, 729 CpG island sites (55% of the 1322 CpG sites evaluated) showed differential DNA methylation. Of these sites, 496 were hypermethylated (repressed) and 233 were hypomethylated (activated). Thus, there is a high level of epigenetic promoter methylation alterations in tumors. Some of these epigenetic alterations may contribute to cancer progression. ==Epigenetic carcinogens==