Formaldehyde-induced and spontaneous alterations in human hprt DNA sequence and mRNA expression.

Human lymphoblast mutants at the X-linked hprt locus have been examined by Southern blot, Northern blot and DNA sequence analysis. A previous study had shown that approximately a third of the spontaneously-arising mutants and half those induced by formaldehyde showed no alteration in restriction fragment pattern and thus were classified as point mutations. In this report, Northern blot analysis was used to show that these point mutants fall into 4 categories: normal size and amount of RNA, normal size but reduced amounts, reduced size of RNA or no RNA. Sequence analyses of cDNAs prepared from hprt mRNAs were performed on 1 spontaneous and 7 formaldehyde-induced mutants with normal Northern blots. The spontaneous mutant was caused by an AT----GC transition. 6 of the formaldehyde-induced mutants were base substitutions, all of which occurred at AT base-pairs. There was an apparent hot spot, in that 4/6 independent mutants were AT----CG transversions at one specific site. The remaining mutant had lost exon 8.

The molecular nature of mutants induced by X rays is altered by the presence of the radioprotector cysteamine.

The molecular structure of mutants induced in human lymphoblast cells by 500 cGy X rays in the presence of the radioprotector cysteamine (25 mM) has been compared with that induced by an equally mutagenic treatment of 150 cGy X rays alone. Sets of mutants at the hypoxanthine-guanine phosphoribosyl transferase locus were analyzed by Southern blot. Of 24 mutants induced by X rays in the presence of cysteamine, 67% exhibited no change in the restriction fragment pattern and thus were defined as point mutations; 8% appeared to be total gene deletions and 25% were partial deletions or rearrangements. In contrast, among 28 mutants induced by X rays alone (Liber et al., Mutat. Res. 178, 143-153 (1987)), 46% were point mutations, while 50% were total gene deletions and only 1 mutant (4%) was a partial deletion or rearrangement. Thus mutants isolated in the presence of cysteamine consisted of more point mutations and partial deletions/rearrangements, and considerably fewer total gene deletions. These results suggest that cysteamine may protect selectively against processes which lead to large-scale molecular changes.

Molecular analysis of formaldehyde-induced mutations in human lymphoblasts and E. coli.

The molecular nature of formaldehyde (HCHO)-induced mutations was studied in both human lymphoblasts and E. coli. Thirty HPRT- human lymphoblast colonies induced by eight repetitive 150 microM HCHO treatments were characterized by Southern blot analysis. Fourteen of these mutants (47%) had visible deletions of some or all of the X-linked HPRT bands, indicating that HCHO can induce large losses of DNA in human lymphoblasts. In E. coli, DNA alterations induced by HCHO were characterized with use of the xanthine guanine phosphoribosyl transferase (gpt) gene as the genetic target. Exposure of E. coli to 4 mM HCHO for 1 hr induced large insertions (41%), large deletions (18%), and point mutations (41%). Dideoxy DNA sequencing revealed that most of the point mutations were transversions at GC base pairs. In contrast, exposure of E. coli to 40 mM HCHO for 1 hr produced 92% point mutations, 62% of which were transitions at a single AT base pair in the gene. Therefore, HCHO is capable of producing different genetic alterations in E. coli at different concentrations, suggesting fundamental differences in the mutagenic mechanisms operating at the two concentrations used. Naked pSV2gpt plasmid DNA was exposed to 3.3 or 10 mM HCHO and transformed into E. coli. Most of the resulting mutations were frameshifts, again suggesting a different mutagenic mechanism.

A simple technique using skin implants to produce histocompatability (BoLA) typing sera.

We describe a technique to produce high-titered bovine lymphocytotoxic antisera using skin implants. The main advantage of this technique is that the skin does not need to be processed prior to implantation and no surgical skill is required. In addition, the skin can be stored for up to 2 weeks and can be shipped to other laboratories without special handling and without loss of immunogenicity.

The bovine major histocompatibility complex (BoLa): close linkage of the genes controlling serologically defined antigens and mixed lymphocyte reactivity.

Detection of linkage between genetic loci in cattle has been hampered by the lack of large full -sib families. A unique source of full-sib families is now available from embryo transplantation. Lymphocytes from six full-sib families, ranging in size from three to seven siblings, were tested for serologically defined BoLA antigens (BoLA-A). In addition, mixed lymphocyte reactivity (MLR) was tested between all paired combinations of cells within each family to distinguish BoLA-D specificities. Serologically identical siblings within each family were reciprocally nonreactive in MLR, and vice versa; thus, no recombinants were detected between the BoLA-A and the BoLA-D loci. Classical genetic linkage analysis revealed that these loci are significantly closer than 11.9 centimorgans.