Multifactorial genetics of exencephaly in SELH/Bc mice

BACKGROUND: The SELH/Bc mouse strain has 10-30% exencephaly and is an animal model for human neural tube closure defects. This study examined the number of causative genes, their dominance relationships, and linkage map positions. METHODS: The SELH/Bc strain (S) was crossed to the normal LM/Bc strain (L) and frequencies of exencephaly were observed in the F(1), BC(1), and F(2) generations. 102 F(2) males were individually testcrossed by SELH/Bc. The extremes, the 10 highest and 10 zero exencephaly-producing F(2) sires, were typed for 109 SSLP marker loci in a genome screen. Next, the resultant five provisional chromosomal regions were tested for linkage in 31 F(2) exencephalic embryos. Finally, 12 males, SS or LL for the Chr 13 region on an LM/Bc background, were testcrossed by SELH/Bc. RESULTS: The exencephaly frequencies in the F(1) (0.3%), BC(1) (4.4%), and F(2) (3.7%), and the distribution of F(2) males' testcross values (0-15.5%), indicated that the high risk of exencephaly in SELH/Bc is due to the cumulative effect of two or three loci. Linkage studies indicated the location of semidominant exencephaly-risk genes on Chr 13 near D13Mit13 (P < 0.001), Chr 5 near D5Mit168 (P < 0.025), and possibly Chr 11 near D11Mit10 (P < 0.07). The gene on Chr 13, Exen1, and the strong role of other loci were confirmed by the congenic males. CONCLUSIONS: The high risk of exencephaly in SELH/Bc mice is caused by the cumulative effect of two to three semidominant genes. Candidate genes include Msx2, Madh5, Ptch, and Irx1 (Chr 13) and Actb and Rac1 (Chr 5).     

Genetic analysis of the cause of exencephaly in the SELH/Bc mouse stock

A new mouse stock, SELH/Bc, having a high liability to exencephaly has been developed. About 17% of SELH fetuses are exencephalic. The genetic cause of this exencephaly was investigated in a cross to a normal related ICR/Bc strain and in subsequent classical genetic crosses (F2, first and second backcrosses). The data were compared with a number of genetic models, including that of a single recessive mutation with 17% penetrance. The data did not fit single-locus inheritance. The expectations from the multifactorial threshold model based on an underlying quantitative liability trait with additive inheritance were found to fit the data very well. The number of loci involved was estimated to be about two or three. About 70% of exencephalic SELH fetuses are female, and there is no overall deficiency of males. The relatively higher risk in females was constant across the genetic backgrounds in the experiment. In summary, the liability to exencephaly in SELH mice appears to be a multifactorial threshold trait, and it therefore resembles human neural tube defects in type of genetic etiology. SELH therefore may be a valuable animal model in the study of neural tube defects.     

Maternal diet alters exencephaly frequency in SELH/Bc strain mouse embryos

BACKGROUND: The SELH/Bc mouse inbred strain, with a high frequency of nonsyndromic, genetically-multifactorial exencephaly, is a model for human cranial neural tube defects (NTDs). Maternal diet affects risk of human NTDs. METHODS: Exencephaly frequencies in SELH/Bc embryos were compared in 8 studies in which dams were fed alternative commercial Purina diets (5015 and 5001) or semisynthetic diets, and in several studies in which maternal diet was supplemented with a specific nutrient, either in drinking water or food before and during pregnancy, or by intraperitoneal injection on E7 and/or E8. RESULTS: The exencephaly frequency in SELH/Bc embryos was 2- to 8-fold higher when the dams were fed Purina 5015 (averaging 23% exencephaly) or a semisynthetic diet modeled on Purina 5015 (averaging 28%) or NIH-31 standard diet (23%), compared with Purina 5001 (averaging 7%). The exencephaly frequency remained high (41%) on a semisynthetic diet modeled on Purina 5001. The exencephaly frequency was not reduced significantly by maternal supplementation with folic acid, nor with each of zinc, methionine, niacin, brewers' yeast, riboflavin, vitamin B12, or inositol. Nor was it reduced by maternal diets with supplemental methyl donors and cofactors or with reduced fat. CONCLUSIONS: The frequency of exencephaly in SELH/Bc embryos is strongly influenced by a specific unidentified aspect of the commercial ration Purina 5001 that prevents 55-85% of exencephaly in SELH/Bc embryos, when directly compared with an alternative commercial ration Purina 5015 or its semisynthetic mimic. This strong maternal diet effect on NTD frequency may point to novel nutritional approaches to prevention of human NTDs.     

Stage-specificity of spontaneous mutation at a tandem repeat DNA locus in the mouse germline

Mouse expanded simple tandem repeat (ESTR) loci are the most unstable loci in the mouse genome. Despite the fact that over the last decade these loci have been extensively used for studying germline mutation induction in mice, to date little is known about the mechanisms underlying spontaneous and induced ESTR mutation. Here we used flow cytometry and single-molecule PCR to compare the frequency of ESTR mutation in four flow-sorted fractions of the mouse male germ cells – spermatogonia, spermatocytes I, round and elongated spermatids. The frequency and the spectrum of ESTR mutation did not significantly differ between different stages of mouse spermatogenesis. Considering these data and the results of other publications, we propose that spontaneous ESTR mutation is mostly attributed to replication slippage in spermatogonia and these loci may be regarded as a class of expanded microsatellites.     

Insertional DNA and spontaneous mutation at the white locus in Drosophila simulans

A large body of data on molecular analyses of several multiallelic loci in Drosophila melanogaster has demonstrated a high incidence of mobile DNA element insertions among spontaneous mutations. In the sibling species D. simulans, the dispersed, middle repetitive, nomadic sequences are reduced to about one-seventh that of its sibling species (Dowsett and Young 1982). Does this reduced amount of middle repetitive DNA (or mobile DNA sequences) mean that in D. simulans the occurrence of insertion mutants will be rare compared with that of D. melanogaster? To test this possibility, we collected seven different spontaneous white mutants of D. simulans and studied their molecular gene structures. Five out of seven mutants had insertion sequences which varied in length from 0.4 kb to 16 kb. One bore a deletion spanning the w region and another showed no gross structural alteration. Thus the proportion of insertional mutations at the white locus in D. simulans is equivalent to that observed in D. melanogaster. Among the five insertional mutants, one, wmky, showed genetic instability; the other four were stable. wmky was found to mutate at a frequency of 2.1 x 10(-5) in meiotic cells and may also be unstable in somatic cells.     

Molecular basis of spontaneous mutation at the aprt locus of hamster cells

Mutations occurring spontaneously at the hamster aprt locus were examined at the base-pair level by amplifying target sequences using the polymerase chain reaction and then directly sequencing the double-stranded products. In a collection of 89 sequenced genes, all types of mutations were found, with transitions (mostly G.C to A.T) constituting the largest class (35%), transversions accounting for 27%, and small deletions/duplications for 25%. Simple base substitutions were distributed throughout the aprt structural gene with few sites having recurring mutations and G.C base-pairs being the predominant substitution target. Small deletions, on the other hand, were not distributed so evenly, being concentrated in a region of aprt rich in short direct and inverted repeat sequences. The base substitutions were predominantly missense, while about 10% produced nonsense codons. Splice junctions, and start and stop codons were also significant targets for mutation. No alterations were detected in three aprt-deficient strains after sequencing all exons and substantial upstream and downstream regions.     

Glutamine synthetase in newborn mice homozygous for lethal albino alleles.

Glutamine synthetase (GS) activity was studied in newborn mice homozygous for radiation-induced lethal albino alleles that cause multiple biochemical deficiencies. GS was found to be decreased in the liver of both homozygous mutants studied, whereas enzyme levels were normal in the eye and brain. The results support the interpretation that the neonatal lethal deletion alleles are mutations of a regulatory genome that normally controls the activities of multiple enzymes.     

Genetic association of mutation at agouti locus with adrenal x zone morphology in BALB/c mice.

The genetic association of the agouti (a) locus with mouse adrenal X zone morphology on a specific genetic background has been suggested. To confirm this, the adrenal cortices of virgin females were compared histologically between BALB/c (A/A) and its mutant, BALB/c-a/a (a/a). The X zone was similar in the number of constituting cell layers, but different in morphology between the A/A and a/a genotypes. At 70 days of age, it was constituted of vacuolated cells exclusively in A/A and of non-vacuolated and a few vacuolated cells in a/a. At 140 days of age, the X zones contained only vacuolated cells in both genotypes. Therefore, the a (non-agouti) allele might have 2 effects upon the X zone morphology on the BALB/c background; the a allele might suppress vacuolation and delay its onset. However, the zona reticularis seemed to have no association with this locus.     

The Drosophila Tumorous lethal hematopoietic oncogene is a dominant mutation in the hopscotch locus

The Drosophila Tumorous-lethal (Tum-l) mutation acts as an activated oncogene, causing hematopoietic neoplasms, overproliferation, and premature differentiation. Tum-l is a dominant mutation in the hopscotch (hop) locus, which is required for cell division and for proper embryonic segmentation. The Tum-l temperature-sensitive period for melanotic tumor formation includes most of larval and pupal development.     

Further genetic studies of the cause of exencephaly in SELH mice.

We have developed an inbred stock of mice called SELH that has a high frequency of the neural tube defect exencephaly at birth. A previous genetic study indicated that the exencephaly is due to two to three additive loci differing between SELH and a closely related normal strain, ICR/Bc, but this analysis was not designed to detect genetic maternal effects. Recently, we demonstrated that there is genetic polymorphism among normal mouse strains leading to differences in site of initiation of closure of the cranial neural tube. In the present study, an inbred substrain of SELH mice, with 24% exencephaly among embryos, was crossed with an unrelated normal strain, SWV/Bc, and the frequency of exencephaly in subsequent generations used to extend our understanding of the genetic cause of exencephaly in SELH mice. The purposes of the genetic studies reported here were twofold. First, based on the influence of genetic maternal effects on other genetically complex birth defects in mice, we hypothesized that the exencephaly of SELH mice would exhibit strong genetic maternal effects. This hypothesis was tested by comparisons among the four possible reciprocal backcrosses to SELH. The result was an overall frequency of 2.3% exencephaly in first backcross embryos with no difference among the four crosses and no evidence of genetic maternal effects. Second, the frequency of exencephaly recovered in the backcross and F1 embryos was compared with the previous genetic study and with various genetic models. The frequencies were similar to those obtained from the cross to ICR/Bc mice and were compatible with a hypothesis of additive gene action at a few loci.(ABSTRACT TRUNCATED AT 250 WORDS)     

Genetic and molecular analyses of vgal: a spontaneous and unstable mutation at the vestigial locus in Drosophila melanogaster

We describe herein, a new unstable mutant of the vestigial locus, isolated from a French natural population. From this mutant vestigial almost (vgal) wild-type flies (vgal+) and extreme vg phenotypes (vge) arose spontaneously without genomic shock. The occurrence of vgal+ or vge alleles depends mostly on the breeding temperature; vgal+ revertants arose principally at low temperature (21 degrees C) and vge at 28 degrees C. These events occur mainly in the male germ line and the phenomenon appears to be premeiotic. Our results with in situ hybridization experiments and Southern blots show that the vgal mutation is due to a 2 kb DNA insertion, which is a deleted hobo element. Genetic and molecular analyses show that two distinct events may underly the wild-type revertants. One is the excision of the resident hobo element, the other a further deletion (about 300 bp in the example characterized herein). The vge mutation is probably due to a deletion of vestigial sequences flanking the hobo insertion.     

Dense cataract and microphthalmia--new spontaneous mutation in BALB/c mice

We describe a new spontaneous mutation in BALB/c mice that causes abnormal phenotype, such as congenital cataract and microphthalmia. This abnormality was found to be inheritable because offspring with the same abnormality were produced by backcrossing the abnormal male to its normal female parent. Results of various crosses made to determine the mode of inheritance indicated that this abnormality is attributable to mutation of an autosomal recessive gene. Slit lamp examination of the mutant eyes revealed total lenticular opacity, disturbed typical iris pattern, and abnormal pupillary muscle development. Histologic changes in mutant eyes between gestation day 13 and postnatal day 1 indicated various eye and lens abnormalities, including microphthalmia; underdeveloped iris, optic stalk, cornea, and retina; degenerated lens fibers with lost fibrillar structure; and vacuoles of various sizes at the posterior border of the lens. Mild opacity of the lens was found to progress with age and became denser, resembling mature cataract, and occupying the lens completely at the age of six to eight weeks. We, therefore, temporarily designated this abnormality as dense cataract and microphthalmia, with the gene symbol dcm.     

Selection and mutation at a diallelic X-linked locus

Equilibria and convergence of gene frequencies are studied in the case of a diallelic X-linked locus under the influence of selection and mutation. The model used is that of an infinite diploid population with nonoverlapping discrete generations and random mating. It is proved that if the mutation rates and fitnesses are constant and the mutation rates are less than one-third, then global convergence of gene frequencies to equilibria occurs. The phase portraits of the dynamical system describing the change of allelic frequencies from one generation to the next are determined. Convergence of gene frequencies is monotone from a certain generation on if every other generation is skipped. In the case without mutation, our proof of this monotone convergence simplifies G. Palm's original proof [37].