MSH2 and Human Nonpolyposis Colon Cancer

1. MSH2 and Human Nonpolyposis Colon Cancer Yael Aschner

2. Presentation Outline • What is MMR? • What is MSH2? • What is HNPCC?

3. DNA Mismatch Repair (MMR) • Identified in bacteria • Mechanism for fixing errors in DNA replication • The frequency of mutations introduced by DNA polymerase during DNA replication is 1/1012 base pairs; of these, 99.9% are repaired by MMR.

4. MMR in E. coli Three proteins • MutS • MutL • MutH

5. MMR in E. coli • MutS performs first step of MMR: recognition of base/base mismatches and small insertion or deletion loops (IDL) • ATPase acting as an asymmetric homodimer • Translocates along DNA and promotes DNA loop formation

6. MMR in E. coli • MutS undergoes conformation change and interacts with MutL in the presence of ATP • MutL stimulates MutH endonuclease activity, which removes newly replicated DNA fragment with mismatch • DNA polymerase fills in the gap

7. MMR in E. coli

8. MutS Homolog 2 (MSH2) • Human homolog of E. coli MutS • Chromosme 2p • 15 exons • Encodes a 934 amino acid protein • Involved in the recognition of mismatched bases and the initiation of the MMR reaction

9. E. coli MutS Crystal Structure The MutS monomer (green) recognizes the G:T mismatch in the DNA (red) and has ADP bound (at the bottom of the figure in red). The monomer in blue provides the non-specific DNA binding domains and an empty ATPase domain

10. Eukaryotic MMR • Highly conserved • No MutH homolog • Six homologs of MutS (MSH1-MSH6) • Three are needed for initiation of the repair process: MSH2, MSH3, MSH6 • MSH2 forms a heteroduplex with MSH6 or MSH3, forming MutSa and MutSb, respectively

11. MutSa • MutSa can bind to most base-base mismatches and loops of one or a few nucleotides • Present at higher concentrations • Primary mismatch recognition factor • Responsible for most mismatch recognition

12. MutSb • MutSb can bind to IDLs with up to ~8 unpaired nucleotides • Not involved in base-base mismatches • Backup system • Some overlap between the complexes • MSH2 acts as a scaffold while MSH3 and MSH6 provide specific binding

13. Mismatch Recognition

14. MSH2 Inactivation • Inability to repair base-base mismatches and small nucleotide insertions and deletions that occur as the result of misalignment or erroneous DNA replication • Acts as a TS gene  CANCER

15. Human Nonpolyposis Colon Cancer (HNPCC) • Associated with deficiency in MMR • Syndrome characterized by familial predisposition to colorectal carcinoma and extracolonic cancers • Gastrointestinal, urological, female reproductive tracts • Most common hereditary colorectal cancer syndrome • 2%-5% of all colon cancers in Western population • Very high penetrance (~85%) • Early onset • 42 years • Autosomal dominant inheritance (cellular level recessive) • Treatment: removal of all or most of the colon

16. Colon Adenoma of the Large Intestine • Precursor polyps (or adenomas) appears to be no greater than the number found in the general population • These polyps are thought to progress more rapidly to cancer and form at earlier ages

17. How is MSH2 Mutated in HNPCC? • 40% of HNPCC mutations are in MSH2 gene • Predominantly small deletions, insertions, splice site alterations, nonsense or missense mutations • MSH2 is the most common gene to have deletions • Range from one exon to whole gene • MSH2 or MLH1 mutations responsible for 50%-80% of HNPCC families • 20% of sporadic colorectal cancers due to MMR mutations

18. HNPCC Inheritance • Individuals heterozygous for mutations • Two Hit Hypothesis • Functional wild type allele lost by somatic mutation event • MMR inactivated • Accumulation of mutations

19. Loss of Heterozygosity

20. Mouse Models for HNPCC(Wei, et al) • Msh2+/- mutants indistinguishable from wild type • Homozygous Msh2-/- mice all died by 12 months (50% by 6 months) • Strong predisposition for tumor phenotype • Cell extracts lost ability to repair single-base mispairs and IDLs of up to four nucleotides • Tissues displayed high mutation frequencies • Small intestinal tumors, lymphoid tumors