MLH1


MutL homolog 1, colon cancer, nonpolyposis type 2 is a protein that in humans is encoded by the MLH1 gene located on chromosome 3. It is a gene commonly associated with hereditary nonpolyposis colorectal cancer. Orthologs of human MLH1 have also been studied in other organisms including mouse and the budding yeast Saccharomyces cerevisiae.

Function

This gene was identified as a locus frequently mutated in hereditary nonpolyposis colon cancer. It is a human homolog of the E. coli DNA mismatch repair gene, mutL, which mediates protein-protein interactions during mismatch recognition, strand discrimination, and strand removal. Defects in MLH1 are associated with the microsatellite instability observed in hereditary nonpolyposis colon cancer. Alternatively spliced transcript variants encoding different isoforms have been described, but their full-length natures have not been determined.

Role in DNA mismatch repair

MLH1 protein is one component of a system of seven DNA mismatch repair proteins that work coordinately in sequential steps to initiate repair of DNA mismatches in humans. Defects in mismatch repair, found in about 13% of colorectal cancers, are much more frequently due to deficiency of MLH1 than deficiencies of other DNA mismatch repair proteins. The seven DNA mismatch repair proteins in humans are MLH1, MLH3, MSH2, MSH3, MSH6, PMS1 and PMS2. In addition, there are Exo1-dependent and Exo1-independent DNA mismatch repair subpathways.
DNA mismatches occur where one base is improperly paired with another base, or where there is a short addition or deletion in one strand of DNA that is not matched in the other strand. Mismatches commonly occur as a result of DNA replication errors or during genetic recombination. Recognizing those mismatches and repairing them is important for cells because failure to do so results in microsatellite instability] and an elevated spontaneous mutation rate. Among 20 cancers evaluated, microsatellite instable colon cancer had the second highest frequency of mutations.
A heterodimer between MSH2 and MSH6 first recognizes the mismatch, although a heterodimer between MSH2 and MSH3 also can start the process. The formation of the MSH2-MSH6 heterodimer accommodates a second heterodimer of MLH1 and PMS2, although a heterodimer between MLH1 and either PMS3 or MLH3 can substitute for PMS2. This protein complex formed between the 2 sets of heterodimers enables initiation of repair of the mismatch defect.
Other gene products involved in mismatch repair include DNA polymerase delta, PCNA, RPA, HMGB1, RFC and DNA ligase I, plus histone and chromatin modifying factors.

Deficient expression in cancer

Cancer typeFrequency of deficiency in cancerFrequency of deficiency in adjacent field defect
Stomach32%24%-28%
Stomach 74%71%
Stomach in high-incidence Kashmir Valley73%20%
Esophageal73%27%
Head and neck squamous cell carcinoma 31%-33%20%-25%
Non-small cell lung cancer 69%72%
Colorectal10%

Epigenetic repression

Only a minority of sporadic cancers with a DNA repair deficiency have a mutation in a DNA repair gene. However, a majority of sporadic cancers with a DNA repair deficiency do have one or more epigenetic alterations that reduce or silence DNA repair gene expression. In the table above, the majority of deficiencies of MLH1 were due to methylation of the promoter region of the MLH1 gene. Another epigenetic mechanism reducing MLH1 expression is over-expression of miR-155. MiR-155 targets MLH1 and MSH2 and an inverse correlation between the expression of miR-155 and the expression of MLH1 or MSH2 proteins was found in human colorectal cancer.

Deficiency in field defects

A field defect is an area or "field" of epithelium that has been preconditioned by epigenetic changes and/or mutations so as to predispose it towards development of cancer. As pointed out by Rubin, "The vast majority of studies in cancer research has been done on well-defined tumors in vivo, or on discrete neoplastic foci in vitro. Yet there is evidence that more than 80% of the somatic mutations found in mutator phenotype human colorectal tumors occur before the onset of terminal clonal expansion." Similarly, Vogelstein et al. point out that more than half of somatic mutations identified in tumors occurred in a pre-neoplastic phase, during growth of apparently normal cells.
In the Table above, MLH1 deficiencies were noted in the field defects surrounding most of the cancers. If MLH1 is epigenetically reduced or silenced, it would not likely confer a selective advantage upon a stem cell. However, reduced or absent expression of MLH1 would cause increased rates of mutation, and one or more of the mutated genes may provide the cell with a selective advantage. The expression-deficient MLH1 gene could then be carried along as a selectively neutral or only slightly deleterious passenger gene when the mutated stem cell generates an expanded clone. The continued presence of a clone with an epigenetically repressed MLH1 would continue to generate further mutations, some of which could produce a tumor.

Repression in coordination with other DNA repair genes

In a cancer, multiple DNA repair genes are often found to be simultaneously repressed. In one example, involving MLH1, Jiang et al. conducted a study where they evaluated the mRNA expression of 27 DNA repair genes in 40 astrocytomas compared to normal brain tissues from non-astrocytoma individuals. Among the 27 DNA repair genes evaluated, 13 DNA repair genes, MLH1, MLH3, MGMT, NTHL1, OGG1, SMUG1, ERCC1, ERCC2, ERCC3, ERCC4, RAD50, XRCC4 and XRCC5 were all significantly down-regulated in all three grades of astrocytomas. The repression of these 13 genes in lower grade as well as in higher grade astrocytomas suggested that they may be important in early as well as in later stages of astrocytoma. In another example, Kitajima et al. found that immunoreactivity for MLH1 and MGMT expression was closely correlated in 135 specimens of gastric cancer and loss of MLH1 and MGMTappeared to be synchronously accelerated during tumor progression.
Deficient expression of multiple DNA repair genes are often found in cancers, and may contribute to the thousands of mutations usually found in cancers.

Meiosis

In addition to its role in DNA mismatch repair, MLH1 protein is also involved in meiotic crossing over. MLH1 forms a heterodimer with MLH3 that appears to be necessary for oocytes to progress through metaphase II of meiosis. Female and male MLH1 mutant mice are infertile, and sterility is associated with a reduced level of chiasmata. During spermatogenesis in MLH1 mutant mice chromosomes often separate prematurely and there is frequent arrest in the first division of meiosis. In humans, a common variant of the MLH1 gene is associated with increased risk of sperm damage and male infertility.
MLH1 protein appears to localize to sites of crossing over in meiotic chromosomes. Recombination during meiosis is often initiated by a DNA double-strand break as illustrated in the accompanying diagram. During recombination, sections of DNA at the 5' ends of the break are cut away in a process called resection. In the strand invasion step that follows, an overhanging 3' end of the broken DNA molecule then "invades" the DNA of an homologous chromosome that is not broken forming a displacement loop. After strand invasion, the further sequence of events may follow either of two main pathways leading to a crossover or a non-crossover recombinant. The pathway leading to a CO involves a double Holliday junction intermediate. Holliday junctions need to be resolved for CO recombination to be completed.
In the budding yeast Saccharomyces cerevisiae, as in the mouse, MLH1 forms a heterodimer with MLH3. Meiotic CO requires resolution of Holliday junctions through actions of the MLH1-MLH3 heterodimer. The MLH1-MLH3 heterodimer is an endonuclease that makes single-strand breaks in supercoiled double-stranded DNA. MLH1-MLH3 binds specifically to Holliday junctions and may act as part of a larger complex to process Holliday junctions during meiosis. MLH1-MLH3 heterodimer together with EXO1 and Sgs1 define a joint molecule resolution pathway that produces the majority of crossovers in budding yeast and, by inference, in mammals.

Clinical significance

It can also be associated with Turcot syndrome.

Interactions

MLH1 has been shown to interact with: