S.A. Marlow

EVIDENCE FOR ADENINE METHYLATION WITHIN THE MOUSE MYOGENIC GENE MYO-D1

Previous studies have indicated that there may be uncleavable TaqI sites (TCGA) within the mouse myogenic gene, Myo-D1. Fragments of DNA bearing most of the presumed insensitive TaqI sites have been reproduced using PCR. The presence of each of the originally uncleavable TaqI sites has been confirmed and each TaqI site has been shown to be sensitive to TaqI hydrolysis in PCR-synthesized genomic DNA. Since TaqI is inhibited by methylation of the adenine residue within its recognition sequence (but not by cytosine methylation), it is suggested that specific adenine bases are methylated in the coding region of Myo-DI and maintained throughout cell division. The same TaqI recognition sequences are insensitive to digestion in genomic DNA isolated from various mouse tissues including fetus, regenerating skeletal muscle and a myogenic cell line, all of which express Myo-D1. Thus, adenine methylation is not a modification of DNA following gametic fusion nor does it appear to play a major role in regulation of Myo-D1 expression.

STUDIES ON THE EVOLUTION AND FUNCTION OF DIFFERENT FORMS OF THE MOUSE MYOGENIC GENE MYO-D1 AND UPSTREAM FLANKING REGION

The product of the murine Myo-D1 gene is able to initiate the complete sequence of genetic events required for formation of skeletal muscle. Because efficiency of regeneration of skeletal muscle is more pronounced in SJL/J mice, as compared to other strains, differences in the structure of Myo-D1 and the upstream regulatory region were sought to determine whether efficiency of tissue repair was influenced by the structure of the gene itself. Analysis of the restriction-fragment length polymorphism (RFLP) of genomic DNA from SJL/J and different sub-strains of mouse indicated that there are at least three different structural forms of Myo-D1, one of which is unique to SJL/J mice and may have been derived from a double recombinational event involving founder forms of Myo-D1. The unique form of Myo-D1 in SJL/J mice also exhibits a PvuII RFLP upstream from the gene, which may reflect some form of rearrangement or variation in methylation of a potential Myo-D1-binding region. Reference to the size of fragments hybridising with the Myo-D1 probe, following digestion of genomic DNA with TaqI, suggests that in most tissues, adenine residues within Myo-D1 may be extensively methylated. Segregation of Myo-D1 allotypes with response to mechanical injury to skeletal muscle in F2 offspring derived from SJL/J and BALB/c parental strains reveals that increased efficiency of tissue repair is associated with the SJL/J type of Myo-D1 gene. These observations provide new approaches to investigation of genetic control of tissue regeneration and cellular differentiation and proliferation in general.

Polymorphism of the mouse transcription factor-encoding gene E2A

Southern blotting analysis using a cDNA probe consisting of the central portion of the E12 coding region has revealed two distinct forms of E2A, one which is common to all inbred and wild mouse strains derived from Mus musculus musculus and Mus musculus domesticus, whereas the other is less common and has only been found in the wild mouse population of Mus musculus domesticus.

Investigation of the influence of the Mm musculus MyoD1 allele on the efficiency of skeletal muscle regeneration

MyoD1 alleles distinguish between the Mm musculus and Mm domesticus subspecies of Mus musculus. SJL/J mice, which belong to the Mm musculus subspecies, are able to regenerate skeletal muscle more efficiently than BALB/c mice which possess the Mm domesticus MyoD1 allele. Hence the possibility that regeneration responses are due to species‐specific genetic differences including MyoD1 was investigated in this study. Quantitative morphometric analysis following muscle crush injury of 2 Mm musculus strains, MBK and MGL, has indicated that regeneration phenotype is not species‐specific and may not be directly related to MyoD1 alleles. These results contrast with prior investigations conducted in SJL/J and BALB/c mice, and indicate that other genes may have a direct influence on skeletal muscle regeneration.

POLYMORPHISM OF THE MOUSE E2A GENE DUE TO AN INTRONIC DELETION OF 536 BP

Examination of genetic polymorphism of the transcription factor-encoding gene E2A in laboratory and wild mice by Southern blotting has revealed the presence of two alleles. The most frequent allele is found in Mus musculus (Mm) musculus, as well as Mm domesticus. The less common allele is restricted to the Mm domesticus subspecies. Characterisation of these alleles has shown that the less common allele contains a deletion of approx. 500 bp located within a 1.8-kb intron immediately upstream from the E12 basic helix-loop-helix exon. DNA sequencing determined the deletion to span 536 bp including nucleotides 1045-1580 of the intron within the common allele. The deleted region includes several sequences with similarity to gene regulatory motifs; however, expression of E12 and intron splicing appeat unaltered. The occurrence of an identical deletion in mice from different geographical regions suggests that the uncommon allele may have a long evolutionary history.

Polymorphism of the murine inhibitor of differentiation-controlling gene, Id

The structure of Id was examined by Southern analysis in inbred mouse lines which included five subspecies of Mus musculus. No variation was detected within this species. The species Mus cookii shares the same form found in mice of M. musculus derivation, indicative of a long evolutionary history and a common origin. However, five TaqI polymorphisms were found among several Mus species, suggesting that Id has been modified throughout species diversification. Whether these variants impart functional changes is yet to be determined.