Faculty Bibliography

We have identified the molecular basis of the GAA*4 allozyme as a G to A transition at nt2065 which predicts the substitution of glutamic acid by lysine at codon 689 (E689K). The conclusion that this change represents the molecular basis of the GAA*4 allozyme is based on 1) presence of the G2065A in homozygosity in a known GAA*4 homozygote, 2) transient expression studies showing normal enzyme activity expressed by cDNA containing the G2065A transition and 3) isoelectric focusing studies showing a more cathodal pattern for the expressed product as compared to the common GAA*1, analogous to the patterns seen in normal and known GAA*4 lymphoid cells

Genomic DNA clones of human acid alpha glucosidase (GAA) and thymidine kinase (TK1) were used to map the exact location and order of these genes on human chromosome 17. Both genes were localized to the 17q25-qter band (17q25.2-q25.3), with GAA distal to TK1. They were also shown to be, respectively, distal and proximal to an anonymous cosmid (cK17.71) previously mapped to this region

Northern analyses revealed normal levels of acidic alpha-glucosidase mRNA in cultured fibroblasts from a Shorthorn calf affected with glycogenosis but a gross deficiency in an affected Brahman calf. Analyses of acidic alpha-glucosidase activity, relative to that of other lysosomal enzymes, in blood mononuclear cells revealed greater variation within and between Brahman herds than Shorthorn herds. A Msp1 restriction fragment length polymorphism associated with glycogenosis in Brahmans was not found in Shorthorns. These results are considered in relation to molecular heterogeneity for AAG deficiency in cattle and its implications for disease control programs

Two newly identified splice site mutations (IVS1 -13T-->G and IVS10 +1GT-->CT) were found in a patient with adult onset of the autosomal recessive disorder glycogen storage disease type II (GSDII). The IVS1 -13T-->G transversion in the acceptor splice site was found on one allele in over two thirds of adult onset GSDII patients studied (28/41), but was not seen in 58 normal or 12 infantile onset GSDII chromosomes. Molecular analysis of cDNA from the index patient and four additional, ethnically different, individuals carrying the IVS1 -13T-->G transversion showed splicing out of the first coding exon as well as rare utilization of a cryptic splice site in the exon. An IVS10 +1GT-->CT transversion, unique to the index patient, was detected on the second chromosome. The IVS10 +1GT-->CT results in splicing out of exon 10 including part of the enzyme catalytic site. Additionally, a large deletion encompassing exon 18, previously described in four unrelated patients, was also detected in three unrelated adult GSDII patients, two of whom carried the IVS1 -13T-->G transversion. The frequency of the IVS1 splice site mutation suggests that detection of this mutation could potentially aid in the diagnosis of the phenotypically variable syndrome of adult onset GSDII. The finding that the -13T-->G mutation is a very common mutation in adult onset GSDII patients of varying ethnic and racial backgrounds, suggests that it is either an ancient mutation or confers a selective advantage. Although to our knowledge these are the first splice site mutations to be reported for GSDII, additional splice site mutations are likely and could provide the basis for later onset disease in GSDII

We identified the presumably rare event of de novo mutation in an autosomal recessive disorder, glycogen storage disease type II (GSDII). GSDII results from inherited deficiency of acid alpha-glucosidase (acid maltase) and both the expressed and structural gene (designated GAA) have been isolated. The mutation was a deletion of 13 nt of coding sequence (delta nt 1456-1468) on the paternally derived allele of the proband. The delta nt 1456-1468 results in a reading frameshift and a premature termination signal upstream of the enzyme catalytic site. Paternity was confirmed by presence of two downstream, uncommon amino acid substitutions (E689K, W746C) in both proband and father and by comparison of nine short tandem repeats. The maternal allele carried a newly identified deleterious C647W missense mutation in a highly conserved area of the protein. The C647W mutation was also found in a second unrelated proband, heteroallelic with a deletion extending from IVS17 to IVS18

Absent or severely reduced adenosine deaminase (ADA) activity produces inherited immunodeficiency of varying severity, with defects of both cellular and humoral immunity. We report somatic mosaicism as the basis for a delayed presentation and unusual course of a currently healthy young adult receiving no therapy. He was diagnosed at age 2 1/2 years because of life-threatening pneumonia, recurrent infections, failure of normal growth, and lymphopenia, but he retained significant cellular immune function. A fibroblast cell line and a B cell line, established at diagnosis, lacked ADA activity and were heteroallelic for splice-donor-site mutation in IVS 1 (+1GT-->CT) and a missense mutation (Arg101Gln). All clones (17/17) isolated from the B cell mRNA carried the missense mutation, indicating that the allele with the splice-site mutation produced unstable mRNA. In striking contrast, a B cell line established at age 16 years expressed 50% of normal ADA; 50% of ADA mRNA had normal sequence, and 50% had the missense mutation. Genomic DNA contained the missense mutation but not the splice-site mutation. All three cell lines were identical for multiple polymorphic markers and the presence of a Y chromosome. In vivo somatic mosaicism was demonstrated in genomic DNA from peripheral blood cells obtained at 16 years of age, in that less than half the DNA carried the splice-site mutation (P < .002, vs. original B cell line). Consistent with mosaicism, erythrocyte content of the toxic metabolite deoxyATP was only minimally elevated. Somatic mosaicism could have arisen either by somatic mutation or by reversion at the site of mutation. Selection in vivo for ADA normal hematopoietic cells may have played a role in the return to normal health, in the absence of therapy

Mutations at the adenosine deaminase (ADA) locus can result in varying degrees of immunodeficiency, including rapidly fulminant severe combined immunodeficiency (SCID) as well as a slowly progressive immunodeficiency not diagnosed until later in childhood. Genetic heterogeneity is a factor in the clinical heterogeneity. We have now identified, by direct sequencing of PCR-amplified genomic DNA, a G to A transition at a CpG dinucleotide predicting a glycine to arginine substitution at codon 20 (G20R). The mutation, in homozygosity, was associated with neonatal-onset rapidly fatal SCID. Consistent with homozygosity, the child was derived from a small isolated inbred community in Newfoundland. The mutation abolishes a site for the restriction enzyme BamHI and can be simply detected by agarose gel electrophoresis following amplification of exon 2 from genomic DNA and digestion with BamHI. The majority of ADA missense mutations can now be detected by similar amplification and enzyme digestion. We demonstrated that the G20R mutation is deleterious since introduction of the mutation into a normal ADA minigene abolished enzyme activity, as determined by transient expression in monkey kidney (Cos) cells. The amino acid substitution occurs in an area of the molecule conserved from Escherichia coli to man and that, as shown by crystallographic analysis, is involved in the binding of Zn2+ at the catalytic site. Although the mutation is in a CpG dinucleotide, known 'hotspots' for G to A transitions, it was not found in a series of 43 additional ADA- chromosomes. Identification of mutations in additional ADA- patients with immunodeficiency of varying severity should further define the role that genotype plays in determining the extent of immunologic dysfunction