MSH2-dependent germinal CTG repeat expansions are produced continuously in spermatogonia from DM1 transgenic mice.

Myotonic dystrophy type 1 is a neuromuscular affection associated with the expansion of an unstable CTG repeat in the DM protein kinase gene. The disease is characterized by somatic tissue-specific mosaicism and very high intergenerational instability with a strong bias towards expansions. We used transgenic mice carrying more than 300 unstable CTG repeats within their large human genomic environment to investigate the dynamics of CTG repeat germinal mosaicism in males. Germinal mosaicism towards expansions was already present in spermatozoa at 7 weeks of age and continued to increase with age, suggesting that expansions are continuously produced throughout life. To determine the precise stage at which germinal expansions occur during spermatogenesis, we sorted and collected the different germ cell types produced during spermatogenesis from males of different ages and analyzed the CTG repeat mosaicism in each fraction. Strong mosaicisms towards expansions were already observed in spermatogonia before meiosis. In transgenic Msh2-deficient mice, germinal instability of the CTG repeats (only contractions) also occurs premeiotically. No significant difference in mosaicism was detected between spermatogonia and spermatozoa, arguing against continued expansions during postmeiotic stages. This indicates that germinal expansions are produced at the beginning of spermatogenesis, in spermatogonia, by a meiosis-independent mechanism involving MSH2.

Analysis of CTG repeats using DM1 model mice.

This chapter describes how transgenic mice can be made with human genomic DNA fragments cloned from DM1 patients' DNA and how the CTG repeat instability is assessed over generations and in different tissues. Construction of cosmid libraries is fully reported from the extraction of high-molecular-weight DNA from patients' lymphoid cell lines, to the screening and mapping of the positive clones. After establishment of transgenic lines, we explained the methods used to analyze (a) the CTG repeats that are inherited from the transgenic parents, with regard to age, sex, and parental CTG repeat sizes, and (b) the CTG repeat-length variations that can be observed in somatic tissues and in sperm.

Msh3 is a limiting factor in the formation of intergenerational CTG expansions in DM1 transgenic mice.

The CTG repeat involved in myotonic dystrophy is one of the most unstable trinucleotide repeats. However, the molecular mechanisms underlying this particular form of genetic instability-biased towards expansions-have not yet been completely elucidated. We previously showed, with highly unstable CTG repeat arrays in DM1 transgenic mice, that Msh2 is required for the formation of intergenerational and somatic expansions. To identify the partners of Msh2 in the formation of intergenerational CTG repeat expansions, we investigated the involvement of Msh3 and Msh6, partners of Msh2 in mismatch repair. Transgenic mice with CTG expansions were crossed with Msh3- or Msh6-deficient mice and CTG repeats were analysed after maternal and paternal transmissions. We demonstrated that Msh3 but not Msh6 plays also a key role in the formation of expansions over successive generation. Furthermore, the absence of one Msh3 allele was sufficient to decrease the formation of expansions, indicating that Msh3 is rate-limiting in this process. In the absence of Msh6, the frequency of expansions decreased only in maternal transmissions. However, the significantly lower levels of Msh2 and Msh3 proteins in Msh6 -/- ovaries suggest that the absence of Msh6 may have an indirect effect.

CTG repeat instability and size variation timing in DNA repair-deficient mice.

Type 1 myotonic dystrophy is caused by the expansion of an unstable CTG repeat in the DMPK gene. We have investigated the molecular mechanisms underlying the CTG repeat instability by crossing transgenic mice carrying >300 unstable CTG repeats in their human chromatin environment with mice knockout for genes involved in various DNA repair pathways: Msh2 (mismatch repair), Rad52 and Rad54 (homologous recombination) and DNA-PKcs (non-homologous end-joining). Genes of the non-homologous end-joining and homologous recombination pathways did not seem to affect repeat instability. Only lack of Rad52 led to a slight decrease in expansion range. Unexpectedly, the absence of Msh2 did not result in stabilization of the CTG repeats in our model. Instead, it shifted the instability towards contractions rather than expansions, both in tissues and through generations. Furthermore, we carefully analyzed repeat transmissions with different Msh2 genotypes to determine the timing of intergenerational instability. We found that instability over generations depends not only on parental germinal instability, but also on a second event taking place after fertilization.