Effect of t12 haplotype on the manifestation and inheritance of fused and kinky genes in house mice

The influence of some t-haplotypes on the phenotypic manifestation of fused and kinky genes located on chromosome 17 of the house mouse was studied. It was shown that t12-haplotype decreases the penetrance of these genes to 59-70%. The effect was observed when the Fu gene (or Ki) is transmitted from the females heterozygous for t12-haplotype. This haplotype only affects manifestation of the Fu and Ki genes in the F1.     

Meiotic drive of t haplotypes: chromosome segregation in mice with tertiary trisomy

The properties of the t haplotypes, specific mutant states of the proximal region of chromosomes 17 in the house mouse, are of continuing interest. One such property is increased transmission of the t haplotype by heterozygous t/+ males to offspring. Using the reciprocal translocation T(16;17)43H we have constructed males with tertiary trisomy of chromosome 17 (+T43/+ +/Rb7+) carrying the Robertsonian translocation Rb(16.17)7Bnr. Only the progeny of these males which had inherited either T43/+ or Rb7 from their male parent were viable. The segregation patterns in the offspring of t-bearing trisomics were analysed on days 16-18 of embryonic development. It was found that, when the t12 haplotype is in the normal acrocentric (males+ +T43/+ t12 + /Rb7+ +), its presence in the gamete +t12+/+ + T43 does not produce meiotic drive. However, when t6 is in Rb7, meiotic drive was observed: 80% of offspring carried the t haplotype. It is concluded that the meiotic drive is probably inhibited by the presence of a normal homologue of chromosome 17 in the same sperm. Possible mechanisms for the t haplotype effect are discussed.     

Meiotic drive of t-haplotypes: segregation of chromosomes in mice with partial trisomy

The properties of the t haplotypes, specific mutant states of the proximal region of chromosome 17 in the house mouse keep renewing interest. One such property is increased transmission of the t haplotype from heterozygous t/+ males to their offspring. By means of reciprocal translocation T (16; 17)43H, we have constructed males with tertiary trisomy 17 (+T43/++/RB7+) carrying Robertsonian translocation Rb(16.17)7Bnr. The offspring of these males was viable when sperm of +T43/++ and Rb7+ was used. The segregation patterns in the offspring of t-bearing trisomics were analysed on days 16-18 of embryonic development. It was found that in the case when the t haplotype is on the normal acrocentric (male male ++T43/+t12+/Rb7++), its presence in the gamete +t12+/++T43 does not produce meiotic drive. However, when t6 is on Rb7, meiotic drive was equal to 80%. It is concluded that the presence of a normal homolog and a t-bearing chromosome in sperm does not result in meiotic drive. Possible mechanisms of meiotic drive of the t haplotypes are discussed.     

Gametic imprinting and expression of the gene Fused in the house mice

The discovery of the gametic imprinting phenomena in mammals makes it possible to have a new look at some facts concerning the expression and inheritance of genes with variable penetrance. Fused (Fu) is a dominant mutation located on chromosome 17, one of the few examples uses to demonstrate gametic imprinting in mice. This mutation has maternal effect connected with decrease in its penetrance. It was shown that t12 haplotype significantly reduces penetrance of the Fu in the progeny of Fu/t12 females. The results of reciprocal crosses of heterozygotes for t12 haplotypes indicate that penetrance of maternal Fu gene is reduced. Far more strong influence on the fused penetrance have the dominant suppressors, located beyond the chromosome 17. The penetrance of the fused gene decreases in that case up to 8-17%. Results of the experiments show strong influence of gametic pathway on penetrance of the gene by which the gene is transmitted to the next generation. The results also made it possible to describe the regularities of gametic imprinting. This phenomenon clearly indicates the existence of gametic and zygotic ontogenetic phases. According to the hypothesis proposed gametic phase of ontogenesis in mammals starts after initialization, i. e. after a process of chromosome erasing from epigenetic information and preparing to enter the next ontogenetic cycle.     

Gametic imprinting and the manifestation of the fused gene in the house mouse

The phenomenon of gametic imprinting in mammals has raised developmentally relevant questions concerning the manifestation and inheritance of genes with variable penetrance. The dominant fused (Fu) gene located on chromosome 17 is one of the few good cases demonstrating the phenomenon in mice. The Fu mutation has a maternal effect. We have previously shown that the t12 haplotype significantly lowers the penetrance of Fu in female Fu/t12 offspring. Results of reciprocal matings of the heterozygotes for Fu indicated that the Fu of maternal origin has a lowered level of penetrance. The dominant suppressors located outside chromosome 17, in contrast to t12 residing in it, had stronger effects on the manifestation of Fu, decreasing its penetrance to 8-17%. Experimental evidence is presented that the pathway via which Fu passes to the zygote nucleus during gametogenesis through successive generations has a marked effect on its penetrance. Based on this evidence, patterns of genetic imprinting are described. A survey of genetic imprinting allowed us to distinguish two developmental phases, gametic and zygotic. The hypothesis for the gametic phase of the development of multicellular organisms suggests that it proceeds from initialization, a process thought to ensure the freeing of chromosomes from redundant epigenetic information and their preparation for the consecutive developmental cycle.     

Analysis of hypotheses and simulation of selection for a suppressor affecting the manifestations of the fused gene in mice

The t12 haplotype decreases sharply manifestation of fused gene in mice. The selection for increasing the penetrance of fused gene was made in Fu/t12 stock. The different computer models of selection process were compared. The hypothesis giving the best coincidence with experimental data supposes the presence of a semidominant gene suppressing the effect of t12 on Fu gene in chromosome 8.     

Molecular cloning and sequence analysis of a haploid expressed gene encoding t complex polypeptide 1

The mouse t haplotypes show defects in spermatogenesis attributed to multiple loci on chromosome 17. We have cloned the gene for an abundant testicular germ cell protein, t complex polypeptide 1, which has a variant form in t haplotypes, TCP-1A. A cDNA clone, pB1.4, which hybridizes to a 19S mRNA that is abundant in haploid cells during mouse spermatogenesis, derives from the 3' end of the mRNA encoding TCP-1B. The Tcp-1 gene appears to be a member of a novel gene family and shows multiple changes between the predicted amino acid sequences of TCP-1B and TCP-1A. An additional Taq1 site is created by a T to C transition in the predicted open reading frame of the Tcp-1a gene. The resultant RFLP has allowed typing of the Tcp-1 gene cluster in 54 complete and partial t haplotype chromosomes. DNA sequence comparison of the Tcp-1 genes suggests that the t haplotype chromosome arose within the genus Mus more than one million years ago.     

Targeted Mutagenesis of a Candidate T Complex Responder Gene in Mouse T Haplotypes Does Not Eliminate Transmission Ratio Distortion

Transmission ratio distortion (TRD) associated with mouse t haplotypes causes +/t males to transmit the t-bearing chromosome to nearly all their offspring. Of the several genes involved in this phenomenon, the t complex responder (Tcr(t)) locus is absolutely essential for TRD to occur. A candidate Tcr(t) gene called Tcp10b(t) was previously cloned from the genetically defined Tcr(t) region. Its location, restricted expression in testis, and a unique postmeiotic alternative splicing pattern supported the idea that Tcp10b(t) was Tcr(t). To test this hypothesis in a functional assay, ES cells were derived from a viable partial t haplotype, and the Tcp10b(t) gene was mutated by homologous recombination. Mutant mice were mated to appropriate partial t haplotypes to determine whether the targeted chromosome exhibited transmission ratios characteristic of the responder. The results demonstrated that the targeted chromosome retained full responder activity. Hence, Tcp10b(t) does not appear to be Tcr(t). These and other observations necessitate a reevaluation of genetic mapping data and the actual nature of the responder.     

Characterization of novel partial t-haplotypes tM1, tM2, tM3, tM4]

The results of genetic analysis of the effects of four novel partial mouse TM-haplotypes are presented in this work. Fertility and viability of tM/tM homozygotes and tM/t6 compounds, transmission ratio distortion (trd) in males heterozygous for tM, suppression of recombination and taillessness effects were studied. Three novel t-haplotypes tM1,2,4 are viable and heterozygous for these haplotypes males T/tM show low trd (20-30%). Comparison of these data and the t6-haplotype structure suggests that the tM1,2,4-haplotypes were derived as a result of recombination events in the non-inverted T-complex fragment located between two inversions. The tM3-haplotype is semilethal and heterozygous T/tM3 males show the trd equal to that of t6-heterozygotes. Homozygous tM3/tM3 and tM3/t6 male compounds are fertile or subfertile. Potential recombination ways of derivation of tM3 are discussed.     

The in vivo and in vitro transmission frequencies of the tw5-haplotype in mice

The recessive tw5-haplotype, a complete haplotype, is transmitted by heterozygous male mice at very high frequencies (greater than 0.90) in normal matings. The present studies were undertaken to determine the effects of delayed matings and in vitro fertilizations on this phenotypic expression. Males carrying the tw5-haplotype (+/tw5) were first tested for their frequencies of transmission of the mutant 17th chromosome in both normal and delayed matings. Spermatozoa obtained from these same males were then used to fertilize eggs in vitro. The in vivo and in vitro transmission frequencies were found to be statistically equivalent in all types of inseminations. An in vitro fertilization time course study showed that the same percentages of eggs are fertilized by tw5-bearing spermatozoa when the gametes are coincubated for either 2 or 6 h. The data lead to the conclusion that the transmission frequency of the tw5-haplotype is not affected either by the length of time elapsing between insemination and fertilization or by the environment in which fertilization occurs.     

LC2, the Chlamydomonas Homologue of the t Complex-encoded Protein Tctex2, Is Essential for Outer Dynein Arm Assembly

Tctex2 is thought to be one of the distorter genes of the mouse t haplotype. This complex greatly biases the segregation of the chromosome that carries it such that in heterozygous +/t males, the t haplotype is transmitted to >95% of the offspring, a phenomenon known as transmission ratio distortion. The LC2 outer dynein arm light chain of Chlamydomonas reinhardtii is a homologue of the mouse protein Tctex2. We have identified Chlamydomonas insertional mutants with deletions in the gene encoding LC2 and demonstrate that the LC2 gene is the same as the ODA12 gene, the product of which had not been identified previously. Complete deletion of the LC2/ODA12 gene causes loss of all outer arms and a slow jerky swimming phenotype. Transformation of the deletion mutant with the cloned LC2/ODA12 gene restores the outer arms and rescues the motility phenotype. Therefore, LC2 is required for outer arm assembly. The fact that LC2 is an essential subunit of flagellar outer dynein arms allows us to propose a detailed mechanism whereby transmission ratio distortion is explained by the differential binding of mutant (t haplotype encoded) and wild-type dyneins to the axonemal microtubules of t-bearing or wild-type sperm, with resulting differences in their motility.     

Ancestral Asian source(s) of new world Y-chromosome founder haplotypes

Haplotypes constructed from Y-chromosome markers were used to trace the origins of Native Americans. Our sample consisted of 2,198 males from 60 global populations, including 19 Native American and 15 indigenous North Asian groups. A set of 12 biallelic polymorphisms gave rise to 14 unique Y-chromosome haplotypes that were unevenly distributed among the populations. Combining multiallelic variation at two Y-linked microsatellites (DYS19 and DXYS156Y) with the unique haplotypes results in a total of 95 combination haplotypes. Contra previous findings based on Y- chromosome data, our new results suggest the possibility of more than one Native American paternal founder haplotype. We postulate that, of the nine unique haplotypes found in Native Americans, haplotypes 1C and 1F are the best candidates for major New World founder haplotypes, whereas haplotypes 1B, 1I, and 1U may either be founder haplotypes and/or have arrived in the New World via recent admixture. Two of the other four haplotypes (YAP+ haplotypes 4 and 5) are probably present because of post-Columbian admixture, whereas haplotype 1G may have originated in the New World, and the Old World source of the final New World haplotype (1D) remains unresolved. The contrasting distribution patterns of the two major candidate founder haplotypes in Asia and the New World, as well as the results of a nested cladistic analysis, suggest the possibility of more than one paternal migration from the general region of Lake Baikal to the Americas.     

The dynamic of the t-haplotype in wild populations of the house mouse Mus musculus domesticus in Israel

The t-haplotype, a variant of the proximal part of the mouse chromosome 17, is composed of at least four inversions and is inherited as a single genetic unit. The haplotype causes embryonic mortality or male sterility when homozygous. Genes within the complex are responsible for distortion of Mendelian transmission ratio in males. Thus, the t-haplotype in heterozygous males is transferred to over 95% of the progeny. We examined the dynamic and behavior of the t-haplotype in wild populations of the house mouse in Israel. The Israeli populations show high frequency (15%–20%) of both partial and complete t-carrying mice, supporting the suggestion that the t-complex evolved in the M. domesticus line in the Israeli region. In one population that had the highest frequency of t-carrying individuals, we compared the level of gene diversity between t-carrying and normal mice in the marker’s loci: H-2 locus of the major histocompatibility complex (MHC) on the t-haplotype of chromosome 17, three microsatellites on other chromosomes, and the mitochondrial D-loop. Genetic variability was high in all tested loci in both t and (+) mice. All t mice carried the same chromosome and showed the same H-2 haplotype. While t-carrying mice showed significant H-2 heterozygotes access, (+) mice expressed significant H-2 heterozygote deficiency. There were no differences in the level of gene diversity between t and (+) mice in the other loci. Heterozygosity level at the MHC may be an additional factor in the selective forces balancing the t-haplotype polymorphism.     

Mutation and haplotype analyses of the Werner’s syndrome gene based on its genomic structure: genetic epidemiology in the Japanese population

The correlation between mutations in the Werner’s syndrome (WRN) gene and the haplotypes of surrounding markers was studied in Japanese patients. We have elucidated the genomic structure of WRN helicase, and found five additional mutations, designated mutations 6–10. Mutations 4 and 6 were found to be the two major mutations in this population; these mutations comprised 50.8% and 17.5%, respectively, of the total in a sample of 126 apparently unrelated chromosomes. Almost all the patients homozygous for mutation 4 shared a haplotype around the WRN gene, consistent with the view that they are derived from a single ancestor. This important advantage demonstrated in the identification of the WRN gene suggests that the Japanese present a unique population for the cloning of other disease genes. The conserved haplotype was observed across 19 loci, extending a distance estimated to be more than 1.4 Mbp around the WRN gene. This haplotype is rare among random Japanese individuals. Unexpectedly, all the nine patients homozygous for mutation 6 shared a haplotype that was identical to this haplotype at 18 of these 19 markers. These results suggest that mutations 4 and 6 arose independently in almost identical rare haplotypes. The remaining mutations (1, 5, 7, 8, 9, and 10) occurred rarely, and were each associated with different haplotypes. Received: 16 December 1996 / Accepted: 16 February 1997     

The Putative Oncogene Pim-1 in the Mouse: Its Linkage and Variation among t Haplotypes

Pim-1, a putative oncogene involved in T-cell lymphomagenesis, was mapped between the pseudo-alpha globin gene Hba-4ps and the alpha-crystallin gene Crya-1 on mouse chromosome 17 and therefore within the t complex. Pim-1 restriction fragment variants were identified among t haplotypes. Analysis of restriction fragment sizes obtained with 12 endonucleases demonstrated that the Pim-1 genes in some t haplotypes were indistinguishable from the sizes for the Pim-1b allele in BALB/c inbred mice. There are now three genes, Pim-1, Crya-1 and H-2 I-E, that vary among independently derived t haplotypes and that have indistinguishable alleles in t haplotypes and inbred strains. These genes are closely linked within the distal inversion of the t complex. Because it is unlikely that these variants arose independently in t haplotypes and their wild-type homologues, we propose that an exchange of chromosomal segments, probably through double crossingover, was responsible for indistinguishable Pim-1 genes shared by certain t haplotypes and their wild-type homologues. There was, however, no apparent association between variant alleles of these three genes among t haplotypes as would be expected if a single exchange introduced these alleles into t haplotypes. If these variant alleles can be shown to be identical to the wild-type allele, then lack of association suggests that multiple exchanges have occurred during the evolution of the t complex.     

CYP27B1 polymorphisms variants are associated with type 1 diabetes mellitus in Germans

CYP27B1 (25-hydroxyvitamin D(3)-1alpha-hydroxylase) catalyzes the metabolization of 25-hydroxyvitamin D(3) to 1,25(OH)(2)D(3) the most active natural Vitamin D metabolite. 1,25(OH)(2)D(3) plays a role in the regulation of autoimmunity and cell proliferation and prevents the development of autoimmune diabetes mellitus in animal models besides other autoimmune disorders. One hundred and eighty-seven families with one offspring affected with type1diabetes mellitus were genotyped for the polymorphisms in the promoter region (-1260 C/A) and intron 6 (2338 T/C) of the CYP27B1 gene on chromosome 12 q13.1-13.3 and extended transmission disequilibrium tests (ETDT) were performed. The haplotype CT (-1260 A/2338 T) was significantly more often transmitted to affected offspring (96 transmitted (T) versus 63 not transmitted (NT), P = 0.0089). While the AT (-1260 C/2838 T) was significantly less often transmitted (37 T versus 60 NT, P = 0.0195). This study suggests that CYP27B1 haplotypes may confer susceptibility to type 1 diabetes mellitus in Germans.     

Mitochondrial DNA and Y‐chromosome diversity in East Adriatic sheep

Variation in mitochondrial DNA (mtDNA) and Y‐chromosome haplotypes was analysed in nine domestic sheep breeds (159 rams) and 21 mouflon ( Ovis musimon) sampled in the East Adriatic. Mitochondrial DNA analyses revealed a high frequency of type B haplotypes, predominantly in European breeds, and a very low frequency of type A haplotypes, which are more frequent in some Asian breeds. Mitochondrial haplotype Hmt‐3 was the most frequent (26.4%), and 37.1%, 20.8% and 7.6% of rams had haplotypes one, two and three mutations remote from Hmt‐3 respectively. In contrast, Y‐chromosome analyses revealed extraordinary paternal allelic richness: HY‐6, 89.3%; HY‐8, 5.0%; HY‐18, 3.1%; HY‐7, 1.3%; and HY‐5, 1.3%. In fact, the number of haplotypes observed is comparable to the number found in Turkish breeds and greater than the number found in European breeds so far. Haplotype HY‐18 (A‐oY1/135‐SRYM18), identified here for the first time, provides a link between the haplotype HY‐12 (A‐oY1/139‐SRYM18) found in a few rams in Turkey and haplotype HY‐9 (A‐oY1/131‐SRYM18) found in one ram in Ethiopia. All mouflons had type B mtDNA haplotypes, including the private haplotype (Hmt‐55), and all were paternally monomorphic for haplotype HY‐6. Our data support a quite homogeneous maternal origin of East Adriatic sheep, which is a characteristic of European breeds. At the same time, the high number of haplotypes found was surprising and intriguing, and it begs for further analysis. Simultaneous analysis of mtDNA and Y‐chromosome information allowed us to detect a large discrepancy between maternal and paternal lineages in some populations. This is most likely the result of breeder efforts to ‘upgrade’ local populations using rams with different paternal origins.     

Angiotensin‐Converting Enzyme Gene Polymorphisms and Obesity: An Examination of Three Black Populations

We examined the association between obesity and 13 angiotensin‐converting enzyme (ACE) gene polymorphisms, including the presence (I) or absence (D) of an Alu element in intron 16 (I/D polymorphism), and performed haplotype analysis using data collected from participants of a community survey of hypertension among blacks living in Ibadan, Nigeria; Spanish Town, Jamaica; and Chicago, IL. Transmission distortion of ACE gene polymorphisms and haplotypes from heterozygous parents to affected offspring was examined in each study population. To estimate haplotypes, polymorphisms were divided into three groups based on their position on the ACE gene. No ACE gene polymorphism was consistently overtransmitted from parents to obese offspring among the three populations. However, the haplotype ACE1‐ACE5 TACAT, located in the promoter region, was significantly overtransmitted from parents to obese offspring in both the U.S. and Nigerian populations. No haplotype was significantly overtransmitted from parents to obese offspring among the Jamaicans. In conclusion, we noted the overtransmission of a particular ACE gene promoter region haplotype from parents to obese offspring in two separate black populations. These data suggest that ACE gene polymorphisms may influence the development of weight gain.     

Polymorphisms distinguishing different mouse species and t haplotypes.

Three anonymous chromosome 17 DNA markers, D17Tu36, D17Tu43, and D17Le66B, differentiate between house mouse species and/or between t chromosomes. The D17Tu36 probe, which maps near the Fu locus and to the In(17)4 on t chromosomes, identifies at least 15 haplotypes, each haplotype characterized by a particular combination of DNA fragments obtained after digestion with the Taq I restriction endonuclease. Ten of these haplotypes occur in Mus domesticus, while the remaining five occur in M. musculus. In each of these two species, one haplotype is borne by t chromosomes while the other haplotypes are present on non-t chromosomes. The D17Tu43 probe, which maps near the D17Leh122 locus and to the In(17)3 on t chromosomes, also identifies at least 15 haplotypes in Taq I DNA digests, of which nine occur in M. domesticus and six in M. musculus. One of the nine M. domesticus haplotypes is borne by t chromosomes, the other haplotypes are borne by non-t chromosomes; two of the six M. musculus haplotypes are borne by t chromosomes and the remaining four by non-t chromosomes. Some of the D17Tu43 haplotypes are widely distributed in a given species, while others appear to be population-specific. Exceptions to species-specificity are found only in a few mice captured near the M. domesticus-M. musculus hybrid zone or in t chromosomes that appear to be of hybrid origin. The D17Leh66B probe, which maps to the In(17)2, distinguishes three haplotypes of M. domesticus-derived t chromosomes and one haplotype of M. musculus-derived t chromosomes. Because of these characteristics, the three markers are well suited for the study of mouse population genetics in general and of t chromosome population genetics in particular. A preliminary survey of wild M. domesticus and M. musculus populations has not uncovered any evidence of widespread introgression of genes from one species to the other; possible minor introgressions were found only in the vicinity of the hybrid zone. Typing of inbred strains has revealed the contribution of only M. domesticus DNA to the chromosome 17 of the laboratory mouse.     

Y chromosome haplotype analysis in Portuguese cattle breeds using SNPs and STRs

DNA samples from 307 males of 13 Portuguese native cattle breeds, 57 males of the 3 major exotic breeds in Portugal (Charolais, Friesian, and Limousin), and 5 Brahman (Bos indicus) were tested for 5 single nucleotide polymorphisms, 1 "indel," and 7 microsatellites specific to the Y chromosome. The 13 Y-haplotypes defined included 3 previously described patrilines (Y1, Y2, and Y3) and 10 new haplotypes within Bos taurus. Native cattle contained most of the diversity with 7 haplotypes (H2Y1, H3Y1, H5Y1, H7Y2, H8Y2, H10Y2, and H12Y2) found only in these breeds. H6Y2 and H11Y2 occurred in high frequency across breeds including the exotics. Introgression of Friesian cattle into Ramo Grande was inferred through their sharing of haplotype H4Y1. Among the native breeds, Mertolenga had the highest haplotype diversity (0.68 +/- 0.07), Brava de Lide was the least differentiated. The analyses of molecular variance showed significant (P < 0.0001) differences between breeds with more than 64% of the total genetic variation found among breeds within groups and 33-35% within breeds. The detection of INRA189-104 allele in 8 native breeds suggested influence of African cattle in breeds of the Iberian Peninsula. The presence in Portuguese breeds of Y1 patrilines, also found in aurochs, could represent more ancient local haplotypes.