Illegitimate pairing of the X and Y chromosomes in Sxr mice

X/Y male mice carrying the sex reversal factor, Sxr, on their Y chromosomes typically produce 4 classes of progeny (recombinant X/X Sxr male male and X/Y non-Sxr male male, and non-recombinant X/X female female and X/Y Sxr male male) in equal frequencies, these deriving from obligatory crossing over between the chromatids of the X and Y during meiosis. Here we show that X/Y males that, exceptionally, carry Sxr on their X chromosome, rather than their Y, produce fewer recombinants than expected. Cytological studies confirmed that X-Y univalence is frequent (58%) at diakinesis as in X/Y Sxr males, but among those cells with X-Y bivalents only 38% showed normal X-Y pseudo-autosomal pairing. The majority of such cells (62%) instead showed an illegitimate pairing between the short arms of the Y and the Sxr region located at the distal end of the X, and this can be understood in terms of the known homology between the testis-determining region of the Y short arm and that of the Sxr region. This pairing was sufficiently tenacious to suggest that crossing over took place between the 2 regions, and misalignment and unequal exchange were suggested by indications of bivalent asymmetry. Metaphase II cells deriving from meiosis I divisions in which the normal X-Y exchange had not occurred were also found. The cytological data are therefore consistent with the breeding results and suggest that normal pseudo-autosomal pairing and crossing over is not a prerequisite for functional germ cell formation.(ABSTRACT TRUNCATED AT 250 WORDS)     

Genetic localization of Hao-1, blind-sterile (bs), and Emv-13 on mouse chromosome 2.

The blind-sterile (bs) mutation in the mouse was localized on Chromosome 2 between Hao-1 and Emv-13. N2 progeny from a backcross between congenic female 129.AKR-bs Emv-13 mice and (129.AKR-bs/bs x Mus musculus molossinus) F1 male mice were typed by analysis of isozyme variants for Hao-1, visible inspection for bs, and restriction fragment length polymorphism for Emv-13 and Emv-15. Comparison between markers on mouse Chromosome 2 and corresponding markers on human chromosomes suggest that the human homolog of bs will be located on 20q11-q13.     

Genetically regulated expression of UDP-N-acetylgalactosamine: GM3(NeuGc) N-acetylgalactosaminyltransferase [EC 2.4.1.92] activity in mouse liver

GM2 containing NeuGc was a major ganglioside in the liver of mouse strains such as BALB/c, DBA/2, C3H/He, and C57BL/10, whereas WHT/Ht mouse liver did not contain GM2(NeuGc) but contained GM3(NeuGc) as a major ganglioside. Since GM3(NeuGc) is a biosynthetic precursor of GM2(NeuGc), WHT/Ht liver was considered to lack the ability to synthesize GM2(NeuGc) from GM3(NeuGc) (Hashimoto, Y., et al. (1983) J. Biochem. 93, 895-901). In this study we measured the activity of UDP-N-acetylgalactosamine : GM3(NeuGc) N-acetylgalactosaminyltransferase in the liver of BALB/c, WHT/Ht, and their progeny. The transferase activity in the microsomal fraction of BALB/c liver was 2.10 +/- 0.32 X 10(-5) units/mg protein (means +/- S.D.), whereas no activity was detected in that of WHT/Ht liver, F1 hybrids between BALB/c and WHT/Ht expressed GM2(NeuGc) as well as the enzyme activity, the level of which was almost half that in BALB/c liver 1.10 +/- 0.12 X 10(-5) units/mg protein). The backcross generation of F1 to WHT/Ht segregated into two groups with respect to expression of GM2(NeuGc) and the transferase activity: 11 of the 21 mice analyzed expressed both GM2(NeuGc) and the transferase activity (1.28 +/- 0.18 X 10(-5) units/mg protein), whereas the rest expressed neither. These results suggest that the expression of GM2(NeuGc) is directly regulated by the activity of UDP-N-acetylgalactosamine: GM3(NeuGc) N-acetylgalactosaminyltransferase in mouse liver.     

Mapping of PRM1 to human chromosome 16 and tight linkage of Prm-1 and Prm-2 on mouse chromosome 16

The protamines are small, arginine-rich nuclear proteins that replace histones and transition proteins late in the haploid phase of spermatogenesis in mammals. The two mouse genes encoding protamines--Prm-1 and Prm-2--have been molecularly cloned and mapped to mouse chromosome 16 (MMU 16). A cDNA clone of mouse Prm-1 that hybridized to the corresponding human gene was used to analyze a panel of somatic cell hybrids made between human lymphoblasts and the E36 hamster cell line. The human gene, which we have designated PRM 1, was syntenic with human chromosome 16 (HSA 16) and discordant with all other human chromosomes. Linkage analysis in the mouse was accomplished using the backcross (Czech II x BALB/c Pt) x Czech II to map Prm-1 and Prm-2 to a position near the 5' terminus of MMU 16. No recombination between Prm-1 and Prm-2 was observed among 89 progeny of the Czech II x BALB/c cross or among 94 progeny of the backcross (CBA/J x BALB/cJ) x BALB/cJ, demonstrating that the two loci are separated by less than 1.6 cM on MMU 16. This tight linkage may be of functional significance, as Prm-1 and Prm-2 are among a limited number of genes known to be expressed postmeiotically in male haploid germ cells.     

A new erythrocytic antigen of C57BL/10 (B10) mice

A new antigen, detectable on murine erythrocytes by hemagglutination assay with a (BALB/cCrl X SWR/J)F1 anti-B10.D2n/Sn alloantiserum, is described. Among the inbred and congenic mouse strains tested for reactivity with the antiserum, only the immunizing strain, B10.D2, and its congenic resistant partner, C57BL/10 (B10), reacted. Three other C57 strains, C57BL/6J, C57BL/6By, and C57L, were negative for the antigen. F1 hybrids between B10 and BALB/c, an antigen-negative strain, were positive for the antigen indicating that its expression is dominant. Typing of 39 (BALB/c X (BALB/c X B10)F1) and 62 [BALB/c X B10)F1 X BALB/c) backcross mice revealed that a single gene controls expression of the antigen. The gene is autosomal and not linked to H-2, Ly-4, or the c (albino) or b coat color genes.     

Recombination between the X and Y chromosomes and the Sxr region of the mouse.

The Sxr (sex-reversed) region that carries a copy of the mouse Y chromosomal testis-determining gene can be attached to the distal end of either the Y or the X chromosome. During male meiosis, Sxr recombined freely between the X and Y chromosomes, with an estimated recombination frequency not significantly different from 50% in either direction. During female meiosis, Sxr recombined freely between the X chromosome to which it was attached and an X-autosome translocation. A male mouse carrying the original Sxra region on its Y chromosome, and the shorter Sxrb variant on the X, also showed 50% recombination between the sex chromosomes. Evidence of unequal crossing-over between the two Sxr regions was obtained: using five markers deleted from Sxrb, 3 variant Sxr regions were detected in 159 progeny (1.9%). Four other variants (one from the original cross and three from later generations) were presumed to have been derived from illegitimate pairing and crossing-over between Sxrb and the homologous region on the short arm of the Y chromosome. The generation of new variants throws light on the arrangement of gene loci and other markers within the short arm of the mouse Y chromosome.     

Synapsis and obligate recombination between the sex chromosomes of male laboratory mice carrying the Y* rearrangement.

The synaptic and recombinational behavior of the sex chromosomes in male laboratory mice carrying the Y* rearrangement was analyzed by light and electron microscopy. Examination of zygotene and pachytene X-Y* configurations revealed a surprising paucity of the staggered pairing configuration predicted from the distal position of the X pseudoautosomal region and the subcentromeric position of the Y* pseudoautosomal region. When paired at pachynema, the X and Y* chromosomes usually assumed configurations similar to those of typical sex bivalents from normal male laboratory mice. The X and Y* chromosomes were present as univalents in more than half of the early- and mid-pachytene nuclei, presumably as a result of steric difficulties associated with homologous alignment of the pseudoautosomal regions. When paired at diakinesis and metaphase I, the X and Y* chromosomes exhibited an asymmetrical chiasmatic association indicative of recombination within the staggered synaptic configuration. Both pairing disruption and recombinational failure apparently contribute to diakinesis/metaphase I sex-chromosome univalency, as most cells at these stages possessed X and Y* univalents lacking evidence of prior recombination. Recombinant X or Y* chromosomes were detected in all metaphase II complements examined, thus substantiating the hypothesis that X-Y recombination is a prerequisite for the normal progression of male meiosis.     

Nonecotropic murine leukemia viruses in BALB/c and NFS/N mice: characterization of the BALB/c Bxv-1 provirus and the single NFS endogenous xenotrope

We used hybridization probes that react specifically with xenotropic and mink cell focus-forming virus envelope sequences to characterize the nonecotropic proviruses of BALB/c and NFS/N mice. Analysis of somatic cell hybrids with different BALB/c chromosomes showed that the 9 xenotropic and more than 20 MCF virus-related proviral sequences in this mouse were present on more than nine BALB/c chromosomes. Multiple copies were found on chromosomes 1, 4, 7, 12, and probably 11, and the copies found on a single chromosome were not identical by restriction enzyme mapping. We also identified and characterized the proviral sequences that give rise to infectious xenotropic virus in both BALB/c and NFS/N mice. BALB/c contains the major locus for induction of infectious virus in inbred mice, Bxv-1, which is on chromosome 1. We showed that this locus contains a single xenotropic provirus on an 18-kilobase HindIII fragment. Restriction enzyme analysis of a hybrid cell DNA that contains only the Bxv-1 xenotropic provirus showed that the Bxv-1 provirus contains restriction enzyme sites characteristic of the infectious virus induced from BALB/c fibroblasts. The Bxv-1 provirus and its flanking sequences also contain the same restriction sites as the provirus thought to contribute U3 long terminal repeat sequences to leukemogenic (class I) AKR MCF viruses. Analysis of cell hybrids made with the nonvirus-inducible strain NFS/N showed that the single xenotropic virus env gene of NFS mice, here termed Nfxv-1, is not on chromosome 1. Unlike that of Bxv-1, the restriction map of Nfxv-1 does not resemble that of any known infectious xenotropic virus including xenotropic viruses isolated from NFS mice. These data suggest that Bxv-1, but not Nfxv-1, is a full-length xenotropic provirus that can be transcribed directly to produce infectious virus.     

Differential impact of T cell repertoire diversity in diabetes-prone or -resistant IL-10 transgenic mice

Expression of IL-10 transgene (tg) in pancreatic beta cells failed to induce autoimmune insulitis and diabetes in (BALB/c x NOD)F1 mice. However, IL-10-expressing tg littermates from backcrosses (N2 and N3) with NOD mice became diabetic at 5 to 10 weeks of age in an MHC-dependent manner. In this study, we tested the possibility that enhancement in frequency of islet antigen (Ag)-specific T cells overrides the protective effects of a diabetes-resistant genetic background and promotes diabetes in IL-10 tg (BALB/c x NOD)F1 mice. For this test, we introduced the IL-10 transgene into tg BDC2.5 mice expressing the islet Ag-specific Vbeta4 T cell repertoire by breeding Ins-IL-10+/BALB/c mice with BDC2.5 mice. The progeny (Ins-IL-10+/BALB/c x BDC2.5+)F1 mice doubly tg for IL-10 and Vbeta4 (BDC2.5) T cell repertoire, developed diabetes at 10 to 18 weeks of age with a much more aggressive T cell infiltrate in the pancreatic islets than in single tg mice. Surprisingly, these diabetic mice were free from acute pancreatitis but had apoptotic beta cells in the islet infiltrate. Conversely, mice tg for Vbeta4 (BDC2.5) T cell repertoire but not IL-10 had no diabetes and no apoptotic beta cells in the islet infiltrate. Therefore, an increase in the frequency of islet-specific T cells apparently overcomes the protection from diabetes by a resistant genetic background. Interestingly, N2 backcross mice doubly tg for Vbeta4 (BDC2.5) T cell repertoire and IL-10, compared to N2 backcross mice tg for IL-10 only, eventually became diabetic but with a delayed onset and reduced incidence of disease. These findings demonstrate that, along with IL-10, an increase in frequency of islet antigen-specific T cells (a) overrides the protective effect of genetic resistance to autoimmune diabetes in F1 mice and (b) delays the onset of an otherwise accelerated diabetes in (Ins-IL-10+/NOD)N2 backcross mice.     

Adding the heterochromatic YL arm to an X chromosome reduces reproductive fitnesses in Drosophila melanogaster: implications for the evolution of rDNA, heterochromatin, and reproductive isolation

For X-Y exchange to be of importance in the coevolution of X and Y rDNA, there must be a mechanism to maintain cytologically normal X chromosomes in the face of continual infusions of X.YL chromosomes produced by X-Y exchanges. Replicated populations were founded with different frequencies of isogenic X and X.YL chromosomes. The X.YL chromosome declined in frequency over time in all lines. Relative fitnesses, estimated from chromosome frequency trajectories, were 0.40, 1.01, and 1.0 for X.YL/X.YL, X.YL/X, and X/X females and 0.75 and 1.0 for X.YL/Y and X/Y males, respectively. The equilibrium frequency for the X.YL chromosome due to the balance between X-Y exchange and selection was predicted to be 4-16 x 10(-4). The results strengthen the evidence for the involvement of X-Y exchange in the coevolution of X and Y rDNA arrays. Conditions for the evolution of reproductive isolation by sex-chromosome translocation are much less probable than previously supposed since the X.YL translocation chromosome is at a selective disadvantage to cytologically normal X chromosomes. Additional heterochromatin was not neutral but was only deleterious beyond a threshold, as one dose of the heterochromatic XL arm did not reduce female reproductive fitness, but two doses did.     

Interferon-gamma receptor polymorphisms determine strain differences in accessibility of activated lymphocyte NK-triggering antigens to recognition by self-reactive NK cells

The "NK-triggering-antigen regulator" (Nktar) gene is a locus identified in the C57BL/6 genome which regulates the ability of unlabeled activated Con A blasts to compete for recognition of labeled syngeneic Con A blasts by BALB/c NK cells. Linkage analysis on Con A blasts from (BALB/c x CByB6F1) N2 backcross progeny for (1) relative level of competitive inhibition of BALB/c NK lysis of syngeneic Con A blasts and (2) genotypes at polymorphic microsatellite markers distributed throughout the mouse genome mapped the Nktar gene locus to a 5-cM region of chromosome 10 containing the interferon-gamma receptor (Ifngr) gene locus. N2 Con A blasts exhibited an inverse relationship between (a) their cell surface density of IFN-gammaR molecules detected by FACS with monoclonal anti-CD119 and (b) their cold target inhibition of BALB/c NK self-reactivity. Con A blasts from Ifngr(-/-) knockout mice showed a relatively high level of inhibition of BALB/c NK self-lysis and a relatively low level of class I MHC, which were both reversed by transient transfection with the Ifngr gene. Sequencing studies showed that Balb/c Ifngr encodes a Gly(69) whereas C57BL/6 Ifngr encodes Glu(69) due to a difference at nucleotide 284. Sequencing studies of N2 progeny demonstrated 100% concordance between their Nktar inhibitory phenotype and their Ifngr genotype. These findings demonstrate that the Nktar and Ifngr loci are identical. They further indicate that polymorphisms related to the Ifngr locus and affecting expression of cell surface IFN-gammaR may underlie genetic differences in the availability of NK-triggering antigens (NKTAgs) to recognition by self-reactive BALB/c NK cells by differentially affecting the ability of IFN-gammaR molecules to mediate up-regulation of NKTAg-masking class I molecules.     

Characterization of single nucleotide polymorphisms for a forward genetics approach using genetic crosses in C57BL/6 and BALB/c substrains of mice

Forward genetics is a powerful approach based on chromosomal mapping of phenotypes and has successfully led to the discovery of many mouse mutations in genes responsible for various phenotypes. Although crossing between genetically remote strains can produce F₂ and backcross mice for chromosomal mapping, the phenotypes are often affected by background effects from the partner strains in genetic crosses. Genetic crosses between substrains might be useful in genetic mapping to avoid genetic background effects. In this study, we investigated single nucleotide polymorphisms (SNPs) available for genetic mapping using substrains of C57BL/6 and BALB/c mice. In C57BL/6 mice, 114 SNP markers were developed and assigned to locations on all chromosomes for full utilization for genetic mapping using genetic crosses between the C57BL/6J and C57BL/6N substrains. Moreover, genetic differences were identified in the 114 SNP markers among the seven C57BL/6 substrains from five production breeders. In addition, 106 SNPs were detected on all chromosomes of BALB/cAJcl and BALB/cByJJcl substrains. These SNPs could be used for genotyping in BALB/cJ, BALB/cAJcl, BALB/cAnNCrlCrlj, and BALB/cCrSlc mice, and they are particularly useful for genetic mapping using crosses between BALB/cByJJcl and other BALB/c substrains. The SNPs characterized in this study can be utilized for genetic mapping to identify the causative mutations of the phenotypes induced by N-ethyl-N-nitrosourea mutagenesis and the SNPs responsible for phenotypic differences between the substrains of C57BL/6 and BALB/c mice.     

Drosophila ribosomal RNA genes function as an X-Y pairing site during male meiosis

In Drosophila melanogaster males, the sex chromosomes pair during meiosis in the centric X heterochromatin and at the base of the short arm of the Y (YS), in the vicinity of the nucleolus organizers. X chromosomes deficient for the pairing region segregate randomly from the Y. In this report we show that a single ribosomal RNA (rRNA) gene stimulates X-Y pairing and disjunction when inserted onto a heterochromatically deficient X chromosome by P element-mediated transformation. We also show that insert-containing X chromosomes pair at the site of insertion, that autosomal rDNA inserts do not affect X-Y pairing or disjunction, and that the strength of an X pairing site is proportional to the dose of ectopic rRNA genes. These results demonstrate that rRNA genes can promote X-Y pairing and disjunction and imply that the nucleolus organizers function as X-Y pairing sites in wild-type Drosophila males.     

Gene with Quantitative Effect on Circulating Interferon Induced by Newcastle Disease Virus

Circulating interferon production, induced by Newcastle disease virus, is about seven times higher in C(57) Black mice than i Balb/c/Gif mice. A Mendelian analysis was carried out and circulating interferon production was measured in reciprocal F(1) hybrids, in the F(2) generation, in progeny of backcrosses of F(1) hybrids to either parent strain, and in second backcross progeny. The results indicate that a single, partly dominant, autosomal factor is responsible for the difference in circulating interferon production between both parent strains.     

Relationship between genetic differentiation of the thymus in mice of different strains and malignant growth. IV. Genetic analysis of the thymic index in mice]

Relative thymus weight was estimated in C3H/He, C57BL/6 mice, their F1 and backcross hybrids, as well as in the progeny of complete diallel crosses between the BALB/c, C3H/He, C57BL/6 and AKR/J strains. On the basis of the analysis of these measurements, a conclusion is drawn that this character is inherited with incomplete dominance of smaller relative weight. The genes determining greater thymus weight are concentrated in the genetic pool of AKR/J and C57BL/6 strains. These genes are characterized by some degree of recessivity with respect to the genes determining smaller thymus weight which are concentrated in the genetic pool of C3H/He and BALB/c strains. The highest concentration of the "plus" and "minus" genes is found in the genetic pools of AKR/J and C3H/He strains respectively.     

IL9 maps to mouse chromosome 13 and human chromosome 5

Mouse and human cDNA clones encoding the T-cell and mast cell growth factor P40, now designated IL-9, were used to identify DNA restriction fragment length polymorphisms (RFLPs) in sets of somatic cell hybrids and between inbred strains of mice and interspecific backcross progeny. Segregation of mouse and human chromosomes among somatic cell hybrids indicated a location on mouse chromosome 13 and human chromosome 5. RFLPs were identified among inbred strains of mice. Analysis of chromosome 13 alleles for Tcrg, Dhfr, and Il-9 in an interspecific cross between Mus musculus and NFS/N or C58/J mice indicates that IL-9 is distal to Tcrg and Proximal to Dhfr.     

Fertility in intersubspecific hybrids of laboratory mice (Mus musculus domesticus) and molossinus mice (M. m. molossinus)

We studied the reproductive performance of F1 and F2 hybrids of laboratory mice (C57BL/6, B6 and BALB/c) and molossinus mice (MOM and Mol-A). The F1 x F1 crosses were fully fertile. In the F2 x F2 crosses, the copulation rate was slightly lower and the pregnancy rate was markedly depressed: only 5 out of 18 copulated females (27.8%) became pregnant in the F2 hybrids derived from the reciprocal crosses of B6 x MOM, and in the F2 hybrids from BALB/c x Mol-A crosses, the pregnancy rate was 51.4% (18/35). This low fertility was attributed mainly to the F2 females, because there was a much lower pregnancy rate (56.5%; 26/46) in the (B6 x MOM)F2 female x B6 male crosses compared with the B6 female x (B6 x MOM)F2 male crosses (80.6%; 26/32). On the other hand, the pregnant F2 females were judged to have normal reproductive ability, based on observations of the numbers of corpora lutea, implantations and live fetuses at day 14 of pregnancy. Apparently there is segregation of fertile and sterile females at the F2 generation, but it remains to be determined how the loss of fertility is brought about in the sterile F2 females.     

Strain variation in interferon gamma production of BCG-sensitized mice challenged with PPD II. Importance of one major autosomal locus and additional sexual influences

Interferon-gamma (IFN-gamma) production in BCG-sensitized mice challenged with PPD was examined in the sera from BALB/c and C57BL/6 mice. C57BL/6 mice produce about ten times more IFN-gamma than BALB/c mice. Studies on F1, F2, and backcross generations indicate that one partially dominant autosomal locus is involved. Furthermore, females consistently produce more IFN-gamma than males in all of these crosses, though the X chromosome cannot be held responsible for this.     

Multiple sex-chromosome system in a loach fish

This study shows an X1X1X2X2/X1X2Y type of multiple sex-chromosome system in the genus Cobitis (Pisces, Ostariophysi). Observation of C-banded male meioses revealed that one arm of the neo-Y always associates end-to-end with one of the X chromosomes. This finding implies that a mechanism might be present that has prevented crossing-over between the ancestral X and Y chromosomes without morphological differentiation. This is the first reported case of multiple sex chromosomes among cyprinoid fish.