Intermediate homocysteinemia: a thermolabile variant of methylenetetrahydrofolate reductase.

A "newly detected" variant of methylenetetrahydrofolate (MTHF) reductase (E.C.1.1.1.68) deficiency associated with an 8-15-fold increase in plasma total homocysteine was discovered in two unrelated patients who had subnormal serum folate. However, the homocysteinemia was corrected by oral folic acid supplement. When MTHF reductase activities in lymphocyte extracts before and after heat treatment at 46 C for 5 min were compared, there was a consistent difference in heat stability between the enzyme from the controls and that from the patients. The mean residual activities after heat treatment were 37.0% (34.1%-42.6%) in the controls and 15.2% and 15.1% in the two patients, respectively. Two obligate heterozygotes for severe MTHF reductase deficiency had residual activities of 39.6% and 37.7%. A similar difference in thermostability was demonstrated in cultured skin fibroblasts and lymphoblasts. Studies with a mixture of lymphoblast extracts from a control and a patient and with partially purified enzyme suggested that the thermostability was an independent characteristic of MTHF reductase. These observations provided evidence of a hitherto undescribed mutant MTHF reductase in our two patients with intermediate homocysteinemia. Unlike previously reported patients with MTHF reductase deficiency, there was no apparent clinical problem related to the abnormal folate or homocysteine metabolism during infancy or childhood in these two subjects, but one of them had vascular disorders in adulthood. The observations in these two subjects suggested that a moderate deficiency of MTHF reductase might be associated with vascular disorders in adult life.

Developmental regulation of SPO13, a gene required for separation of homologous chromosomes at meiosis I.

Previous studies have demonstrated that the SPO13 gene is required for chromosome separation during meiosis I in Saccharomyces cerevisiae. In the presence of the spo13-1 nonsense mutation, MATa/MAT alpha diploid cells complete a number of events typical of meiosis I including premeiotic DNA synthesis, genetic recombination, and spindle formation. Disjunction of homologous chromosomes, however, fails to occur. Instead, cells proceed through a single meiosis II-like division and form two diploid spores. In this paper, we report the cloning of this essential meiotic gene and an analysis of its transcription during vegetative growth and sporulation. Disruptions of SPO13 in haploid and diploid cells show that it is dispensible for mitotic cell division. Diploids homozygous for the disruptions behave similarly to spo13-1 mutants; they sporulate at wild-type levels and produce two-spored asci. The DNA region complementing spo13-1 encodes two overlapping transcripts, which have the same 3' end but different 5' ends. The major transcript is 400 bases shorter than the larger, less abundant one. The shorter RNA is sufficient to complement the spo13-1 mutation. While both transcripts are undetectable or just barely detectable in vegetative cultures, they each undergo a greater than 70-fold induction early during sporulation, reaching a maximum level about the time of the first meiotic division. In synchronously sporulating populations, the transcripts nearly disappear before the completion of ascus formation. Nonsporulating cells homozygous for the mating-type locus show a small increase in abundance (less than 5% of the increase in sporulating cells) of both transcripts in sporulation medium. These results indicate that expression of the SPO13 gene is developmentally regulated and starvation alone, independent of the genotype at MAT, can trigger initial induction.