Genetic structure of phenotypic robustness in the collaborative cross mouse diallel panel.

Developmental stability and canalization describe the ability of developmental systems to minimize phenotypic variation in the face of stochastic micro-environmental effects, genetic variation and environmental influences. Canalization is the ability to minimize the effects of genetic or environmental effects, whereas developmental stability is the ability to minimize the effects of micro-environmental effects within individuals. Despite much attention, the mechanisms that underlie these two components of phenotypic robustness remain unknown. We investigated the genetic structure of phenotypic robustness in the collaborative cross (CC) mouse reference population. We analysed the magnitude of fluctuating asymmetry (FA) and among-individual variation of cranial shape in reciprocal crosses among the eight parental strains, using geometric morphometrics and a diallel analysis based on a Bayesian approach. Significant differences among genotypes were found for both measures, although they were poorly correlated at the level of individuals. An overall positive effect of inbreeding was found for both components of variation. The strain CAST/EiJ exerted a positive additive effect on FA and, to a lesser extent, among-individual variance. Sex- and other strain-specific effects were not significant. Neither FA nor among-individual variation was associated with phenotypic extremeness. Our results support the existence of genetic variation for both developmental stability and canalization. This finding is important because robustness is a key feature of developmental systems. Our finding that robustness is not related to phenotypic extremeness is consistent with theoretical work that suggests that its relationship to stabilizing selection is not straightforward.

Perinatal nutrition interacts with genetic background to alter behavior in a parent-of-origin-dependent manner in adult Collaborative Cross mice.

Previous studies in animal models and humans have shown that exposure to nutritional deficiencies in the perinatal period increases the risk of psychiatric disease. Less well understood is how such effects are modulated by the combination of genetic background and parent-of-origin (PO). To explore this, we exposed female mice from 20 Collaborative Cross (CC) strains to protein deficient, vitamin D deficient, methyl donor enriched or standard diet during the perinatal period. These CC females were then crossed to a male from a different CC strain to produce reciprocal F1 hybrid females comprising 10 distinct genetic backgrounds. The adult F1 females were then tested in the open field, light/dark, stress-induced hyperthermia, forced swim and restraint stress assays. Our experimental design allowed us to estimate effects of genetic background, perinatal diet, PO and their interactions on behavior. Genetic background significantly affected all assessed phenotypes. Perinatal diet exposure interacted with genetic background to affect body weight, basal body temperature, anxiety-like behavior and stress response. In 8 of 9 genetic backgrounds, PO effects were observed on multiple phenotypes. Additionally, we identified a small number of diet-by-PO effects on body weight, stress response, anxiety- and depressive-like behavior. Our data show that rodent behaviors that model psychiatric disorders are affected by genetic background, PO and perinatal diet, as well as interactions among these factors.

Natural selection and the function of genome imprinting: beyond the silenced minority.

Most hypotheses of the evolutionary origin of genome imprinting assume that the biochemical character on which natural selection has operated is the expression of the allele from only one parent at an affected locus. We propose an alternative - that natural selection has operated on differences in the chromatin structure of maternal and paternal chromosomes to facilitate pairing during meiosis and to maintain the distinction between homologues during DNA repair and recombination in both meiotic and mitotic cells. Maintenance of differences in chromatin structure in somatic cells can sometimes result in the transcription of only one allele at a locus. This pattern of transcription might be selected, in some instances, for reasons that are unrelated to the original establishment of the imprint. Differences in the chromatin structure of homologous chromosomes might facilitate pairing and recombination during meiosis, but some such differences could also result in non-random segregation of chromosomes, leading to parental-origin-dependent transmission ratio distortion. This hypothesis unites two broad classes of parental origin effects under a single selective force and identifies a single substrate through which Mendel's first and second laws might be violated.

Female meiosis drives karyotypic evolution in mammals.

Speciation is often accompanied by changes in chromosomal number or form even though such changes significantly reduce the fertility of hybrid intermediates. We have addressed this evolutionary paradox by expanding the principle that nonrandom segregation of chromosomes takes place whenever human or mouse females are heterozygous carriers of Robertsonian translocations, a common form of chromosome rearrangement in mammals. Our analysis of 1170 mammalian karyotypes provides strong evidence that karyotypic evolution is driven by nonrandom segregation during female meiosis. The pertinent variable in this form of meiotic drive is the presence of differing numbers of centromeres on paired homologous chromosomes. This situation is encountered in all heterozygous carriers of Robertsonian translocations. Whenever paired chromosomes have different numbers of centromeres, the inherent asymmetry of female meiosis and the polarity of the meiotic spindle dictate that the partner with the greater number of centromeres will attach preferentially to the pole that is most efficient at capturing centromeres. This mechanism explains how chromosomal variants become fixed in populations, as well as why closely related species often appear to have evolved by directional adjustment of the karyotype toward or away from a particular chromosome form. If differences in the ability of particular DNA sequences or chromosomal regions to function as centromeres are also considered, nonrandom segregation is likely to affect karyotype evolution across a very broad phylogenetic range.

A genetic test to determine the origin of maternal transmission ratio distortion. Meiotic drive at the mouse Om locus.

We have shown previously that the progeny of crosses between heterozygous females and C57BL/6 males show transmission ratio distortion at the Om locus on mouse chromosome 11. This result has been replicated in several independent experiments. Here we show that the distortion maps to a single locus on chromosome 11, closely linked to Om, and that gene conversion is not implicated in the origin of this phenomenon. To further investigate the origin of the transmission ratio distortion we generated a test using the well-known effect of recombination on maternal meiotic drive. The genetic test presented here discriminates between unequal segregation of alleles during meiosis and lethality, based on the analysis of genotype at both the distorted locus and the centromere of the same chromosome. We used this test to determine the cause of the transmission ratio distortion observed at the Om locus. Our results indicate that transmission ratio distortion at Om is due to unequal segregation of alleles to the polar body at the second meiotic division. Because the presence of segregation distortion at Om also depends on the genotype of the sire, our results confirm that the sperm can influence segregation of maternal chromosomes to the second polar body.

Heritability of the maternal meiotic drive system linked to Om and high-resolution mapping of the Responder locus in mouse.

Matings between (C57BL/6 x DDK)F(1) females and C57BL/6 males result in a significant excess of offspring inheriting maternal DDK alleles in the central region of mouse chromosome 11 due to meiotic drive at the second meiotic division. We have shown previously that the locus subject to selection is in the vicinity of D11Mit66, a marker closely linked to the Om locus that controls the preimplantation embryo-lethal phenotype known as the "DDK syndrome." We have also shown that observation of meiotic drive in this system depends upon the genotype of the sire. Here we show that females that are heterozygous at Om retain the meiotic drive phenotype and define a 0.32-cM candidate interval for the Responder locus in this drive system. In addition, analysis of the inheritance of alleles at Om among the offspring of F(1) intercrosses indicates that the effect of the sire is determined by the sperm genotype at Om or a locus linked to Om.

Sex-of-offspring-specific transmission ratio distortion on mouse chromosome X.

During our study of the DDK syndrome, we observed sex ratio distortion in favor of males among the offspring of F(1) backcrosses between the C57BL/6 and DDK strains. We also observed significant and reproducible transmission ratio distortion in favor of the inheritance of DDK alleles at loci on chromosome X among female offspring but not among male offspring in (C57BL/6 x DDK)F(1) x C57BL/6 and (C57BL/6-Pgk1(a) x DDK)F(1) x C57BL/6 backcrosses. The observed transmission ratio distortion is maximum at DXMit210 in the central region of chromosome X and decreases progressively at proximal and distal loci, in a manner consistent with the predictions of a single distorted locus model. DXMit210 is closely linked to two distortion-controlling loci (Dcsx1 and Dcsx2) described previously in interspecific backcrosses. Our analysis suggests that the female-offspring-specific transmission ratio distortion we observe is likely to be the result of the death of embryos of particular genotypic combinations. In addition, we confirm the previous suggestion that the transmission ratio distortion observed on chromosome X in interspecific backcrosses is also the result of loss of embryos.

Male-offspring-specific, haplotype-dependent, nonrandom cosegregation of alleles at loci on two mouse chromosomes.

F(1) backcrosses involving the DDK and C57BL/6 inbred mouse strains show transmission ratio distortion at loci on two different chromosomes, 11 and X. Transmission ratio distortion on chromosome X is restricted to female offspring while that on chromosome 11 is present in offspring of both sexes. In this article we investigate whether the inheritance of alleles at loci on one chromosome is independent of inheritance of alleles on the other. A strong nonrandom association between the inheritance of alleles at loci on both chromosomes is found among male offspring, while independent assortment occurs among female offspring. We also provide evidence that the mechanism by which this phenomenon occurs involves preferential cosegregation of nonparental chromatids of both chromosomes at the second meiotic division, after the ova has been fertilized by a C57BL/6 sperm bearing a Y chromosome. These observations confirm the influence of the sperm in the segregation of chromatids during female meiosis, and indicate that a locus or loci on the Y chromosome are involved in this instance of meiotic drive.

Transmission ratio distortion in offspring of heterozygous female carriers of Robertsonian translocations.

Robertsonian translocations are the most common structural rearrangements of human chromosomes. Although segregation of Robertsonian chromosomes has been examined in many families, there is little consensus on whether inheritance in the balanced progeny conforms to Mendelian ratios. To address this question, we have compiled previously reported segregation data, by sex of parent, for 677 balanced offspring of Robertsonian carriers from 82 informative families and from a prenatal diagnosis study on the risk of unbalanced offspring in carriers of chromosome rearrangements. Care was taken to avoid any source of ascertainment bias. Our analysis supports the following conclusions: (1) the transmission ratio is not independent of the sex of the carrier; (2) the transmission ratio distortion is observed consistently only among the offspring of carrier females; (3) the transmission ratio distortion does not appear to be dependent on the presence of a specific acrocentric chromosome in the rearrangement. The sex-of-parent-specific origin of the non-Mendelian inheritance, the finding that the rearranged ("mutant") chromosomes are recovered at significantly higher frequency than the acrocentric ("normal") chromosomes, and the similarities between these observations and the segregation of analogous rearrangements through female meiosis in other vertebrates strongly support the hypothesis that the transmission ratio distortion in favor of Robertsonian translocations in the human results from the preferential segregation of chromosomes during the first meiotic division. This non-Mendelian inheritance will result in increased overall risk of aneuploidies in the families of Robertsonian translocation carriers, independently of the origin of the transmission ratio distortion.

Nonrandom segregation during meiosis: the unfairness of females.

Most geneticists assume that chromosome segregation during meiosis is Mendelian (i.e., each allele at each locus is represented equally in the gametes). The great majority of reports that discuss non-Mendelian transmission have focused on systems of gametic selection, such as the mouse t-haplotype and Segregation distorter in Drosophila, or on systems in which post-fertilization selection takes place. Because the segregation of chromosomes in such systems is Mendelian and unequal representation of alleles among offspring is achieved through gamete dysfunction or embryonic death, there is a common perception that true disturbances in the randomness of chromosome segregation are rare and of limited biological significance. In this review we summarize data on nonrandom segregation in a wide variety of genetic systems. Despite apparent differences between some systems, the basic requirements for nonrandom segregation can be deduced from their shared characteristics: i) asymmetrical meiotic division(s); ii) functional asymmetry of the meiotic spindle poles; and iii) functional heterozygosity at a locus that mediates attachment of a chromosome to the spindle. The frequency with which all three of these requirements are fulfilled in natural populations is unknown, but our analyses indicate that nonrandom segregation occurs with sufficient frequency during female meiosis, and in exceptional cases of male meiosis, that it has important biological, clinical, and evolutionary consequences.

Ordering of the human regulator of complement activation gene cluster on 1q32 by two-colour FISH.

The regulator of complement activation (RCA) gene cluster and PTPRC and REN genes have been mapped to the 1q31-->q32 band interval. We have used two-colour in situ hybridization to determine the chromosomal position of these genes. We report here that HF1/F13B are proximal to the C4BP/MCP genes. We also propose that PTPRC and REN genes map to a region of the RCA gene cluster between the HF1/F13B and C4BP/MCP regions. In summary, we propose the following gene order: centromere-HF1/F13B-PTPRC-REN-C4BP/MCP-telomere.

Regional localization of the human vitronectin receptor alpha subunit gene (VNRA) to chromosome 2q31-->q32.

The vitronectin receptor (av:beta 3; CD51/CD61), a member of the beta 3 integrin subfamily (cytoadhesins), functions as a receptor for a group of proteins that includes vitronectin, fibrinogen, thrombospondin, and von Willebrand factor. The human locus for the av gene (VNRA) was previously mapped to the long arm of chromosome 2 by DNA analysis of somatic cell hybrids. By using fluorescence in situ hybridization, coupled with GTG-banding, we have regionally mapped the human av gene to chromosome 2q31-->q32. An identical location was previously reported for the human gene coding for the integrin VLA-alpha 4 subunit (CD49D). These data, therefore, suggest the existence of a cluster of integrin genes at this chromosomal location.

Confirmation of maternal transmission ratio distortion at Om and direct evidence that the maternal and paternal "DDK syndrome" genes are linked.

The polar, preimplantation-embryo lethal phenotype known as the "DDK syndrome" in the mouse is the result of the complex interaction of genetic factors and a parental-origin effect. We previously observed a modest degree of transmission-ratio distortion in favor of the inheritance of DDK alleles in the Ovum mutant (Om) region of Chromosome (Chr) 11, among offspring of reciprocal F1-hybrid females and C57BL/6 males. In this study, we confirm that a significant excess of offspring inherit DDK alleles from F1 mothers and demonstrate that the preference for the inheritance of DDK alleles is not a specific bias against the C57BL/6 allele or a simple preference for offspring that are heterozygous at Om. Because none of the previous genetic models for the inheritance of the "DDK syndrome" predicted transmission-ratio distortion through F1 females, we reconsidered the possibility that the genes encoding the maternal and paternal components of this phenotype were not linked. We have examined the fertility phenotype of N2 females and demonstrate that the inter-strain fertility of these females is correlated with their genotype in the Om region. This result establishes, directly, that the genes encoding the maternal and paternal components of the DDK syndrome are genetically linked.

The maternal DDK syndrome phenotype is determined by modifier genes that are not linked to Om.

The DDK syndrome is a polar, early embryonic lethal phenotype caused by incompatibility between a maternal factor of DDK origin and a paternal gene of non-DDK origin. Both maternal factor and paternal gene have been mapped to the Om locus on mouse Chromosome (Chr) 11. The paternal contribution to the syndrome has been shown to segregate as a single locus. Although the inheritance of the maternal contribution has not been characterized in depth, it as been assumed to segregate as a single locus. We have now characterized the segregation of the DDK fertility phenotype in over 240 females. Our results demonstrate that females require at least one DDK allele at Om to manifest the syndrome. However, the DDK syndrome inter-strain cross-fertility phenotype of heterozygous females is highly variable and spans the gamut from completely infertile to completely fertile. Our results indicate that this phenotypic variability has a genetic basis and that the modifiers of the DDK syndrome segregate independently of Om.

C4BPAL1, a member of the human regulator of complement activation (RCA) gene cluster that resulted from the duplication of the gene coding for the alpha-chain of C4b-binding protein.

The regulator of complement activation (RCA) gene cluster evolved by multiple gene duplications to produce a family of genes coding for proteins that collectively control the activation of the complement system. We report here the characterization of C4BPAL1, a member of the human RCA gene cluster that arose from the duplication of the C4BPA gene after the separation of the rodent and primate lineages. C4BPAL1 maps 20 kb downstream of the C4BPA gene and is the same 5' to 3' orientation found for all RCA genes characterized thus far. It includes nine exon-like regions homologous to exons 2-8, 11, and 12 of the C4BPA gene. Analysis of the C4BPAL1 sequence suggests that it is currently a pseudogene in humans. However, comparisons between C4BPAL1 and the human and murine C4BPA genes show sequence conservation, which strongly suggests that, for a long period of time, C4BPAL1 has been a functional gene coding for a protein with structural requirements similar to those of the alpha-chain of C4b-binding protein.

Mapping of the human VLA-alpha 4 gene to chromosome 2q31-q32.

The integrin VLA-4 (alpha 4: beta 1; CD49d/CD29) is involved in both cellular adhesion to extracellular matrix and cell-cell interactions. We have determined that the human gene coding for VLA-alpha 4 is located on the long arm of chromosome 2 by using fluorescence in situ hybridization. The VLA-alpha 4 gene has been more precisely mapped to the 2q31-q32 region after GTG banding (G-bands by trypsin using Giemsa). These data suggest that the VLA-4 gene belongs to the COL3A1-(ELN-FN)-COL6A3 linkage group and establishes a potential genetic relationship between the alpha 4 and alpha v integrin subunits.

The gene coding for the beta-chain of C4b-binding protein (C4BPB) has become a pseudogene in the mouse.

C4BP beta is one of the two polypeptides that in humans compose the plasma glycoprotein C4b-binding protein (C4BP). C4BP beta binds the anticoagulant vitamin K-dependent protein S. Two, nonmutually exclusive, roles have been proposed for the C4BP-protein S interaction. It has been suggested to play a role in the control of the protein C anticoagulatory pathway. In addition, it may serve an important role in localizing C4BP to the surface of injured or activated cells. While the physiological significance of C4BP-protein S interaction is unclear, it has clinical relevance because elevated plasma levels of C4BP are associated with increased risk for thromboembolic disorders in humans, due to an inactivation of the protein C anticoagulatory pathway. Using a human C4BP beta cDNA probe, we have isolated and characterized a genomic DNA fragment that includes the murine C4BPB gene. Murine C4BPB is a single-copy gene that maps close to the C4BPA gene in chromosome 1. It contains two exons homologous to the exons coding for the SCR-1 and SCR-2 repeats of the human C4BP beta polypeptide chain. Sequence analysis of the C4BPB exons in the Mus musculus inbred strains CBA, Balb/c, and C57BL/6, in pen-bred Swiss mice, and in Mus spretus demonstrated the presence of two in-phase stop codons that are incompatible with the expression of a functional C4BP beta polypeptide. Thus, the characterization of the murine C4BPB gene documents the peculiar situation of a single-copy gene that is functional in humans but has become a pseudogene in the mouse.(ABSTRACT TRUNCATED AT 250 WORDS)