Genetic and Molecular Characterization of New Natural Haplotype t wMP1 Found in House Mouse Mus domesticus R. from Peru

A new natural haplotype, t ^wMP1, found in a population of house mouse Mus domesticus from Peru, was subjected to genetic and molecular analyses. Experiments were performed to study the complementation of the new haplotype, fertility of t ^wMP1/t ^x heterozygotes, and transmission ratio distortion (TRD) of the t-carrying chromosome in the progeny of heterozygous males. Molecular analysis included blot hybridization with t-specific probes Tu48, Tu66, and Tu119. The results were collated with the structure and properties of the t complex, and the new haplotype was identified as a complete lethal one.     

Characterization of a novel wild-type t(wMPI) haplotype of the house mouse (Mus domesticus L.) from Peru]

Data on molecular genetic analysis of the novel wild-type twMP1 haplotype found in a population of Mus domesticus from Peru are presented. Complementation attribution of the novel haplotype as well as fertility of heterozygotes and transmission ratio distortion (TRD) of the t-carrying chromosome in the progeny of the heterozygous males were studied. Molecular analysis was carried out by means of blot hybridization with the four t-specific probes (Tu48, Tu66, Tu119, and Tu122). Comparison of the results obtained with the data on the structure and properties of the t complexes permitted conclusion on the complete lethality of the haplotype described.     

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.     

Structure and evolution of the D17LeH80-like locus in the murine t-complex]

The t complex in the proximal part of chromosome 17 is one of the most thoroughly studied regions of the mouse genome. We determined the sequence of Tu80, a molecular clone derived from microdissected fragments of chromosome 17. The sequence data demonstrated that the total length being 324 bp, Tu80 contains an open-reading frame (ORF) of 204 bp. Two fragments were detected within the ORF, one homologous to the LINE1-element, the other to the first intron of the C epsilon gene of mouse immunoglobin. A sequence designated NOV1 was isolated from the genomic library of mouse chromosome 17. NOV1 was found to contain a B2 insert, making in structurally different from Tu80. The sequences of Tu80 and NOV1 were compared with those of LINE1 and the first intron of the C epsilon gene. The results suggested that the ancestor of the Tu80-like sequence might have arisen through illegitimate recombination between the fragments of LINE1 and the C epsilon gene. It is concluded that Tu80 and NOV1 might have resulted from duplication of the ancestral sequence and following divergence. The comparative analysis also demonstrated high degree of conservation of the LINE1 fragments in Tu80 and NOV1, as well as in the LINE1 in a number of mammalian species. Based on the structure of human, rat, rabbit and mouse LINE1 fragments, and also on that of NOV1 and Tu80, phylogenetic tree has been constructed. Its topology is consistent with the accepted phylogenetic relationships among the species studied. The data available tend to support the assumption that the ancestor for the Tu80-like sequence might have arisen not later than 27-33 million years ago.     

Polymorphism of Unique Noncoding DNA Sequences in Wild and Laboratory Mice

Two DNA probes, D17Tu1 and D17Tu2, were isolated from a genomic DNA library containing only two mouse chromosomes, one of which is chromosome 17, carrying the major histocompatibility complex (H-2), as well as the t complex genes. The D17Tu1 probe was mapped to the centromeric region of chromosome 17 and the D17Tu2 probe to the S region of the H-2 complex. Neither of the two probes appeared to detect any genes, but both contained unique, nonrepetitive sequences. Typing of DNA obtained from a large panel of mice revealed the presence of four D17Tu1 patterns in inbred mouse strains, one very common, one less common, and two present in one strain each. The two common patterns could not be detected in appreciable frequencies in the European wild mice tested (one of the two patterns was, however, found in Australian wild mice). Conversely, the patterns found frequently in European wild mice are absent in the laboratory mice. We therefore conclude that wild mice from the sampled regions of Europe could not have provided the ancestral stocks from which inbred strains were derived. Only one D17Tu1 pattern was found in all the populations of Mus musculus tested, while eight patterns were found in Mus domesticus, with virtually all the populations being polymorphic. We suggest that this difference reflects different modes in which the two species colonized Europe. The distribution of the D17Tu2 patterns in inbred strains correlates with the distribution of H-2 haplotypes.     

Repetitive sequences of the tree shrew genome (Mammalia, Scandentia)

Copies of two repetitive elements of the genome of common tree shrew (Tupaia glis) were cloned and sequenced. The first element, Tu III, is a approximately 260 bp long short interspersed element (SINE) with the 5'-end derived from glycine RNA. Tu III carries long polypurine- and polypyrimidine-rich tracts, which may contribute to the specific secondary structure of Tu III RNA. This SINE was also found in the genome of smooth-tailed tree shrew of another genus (Dendrogale). Tu III seems to be confined to the order Scandentia (tree shrews) since it was not found in DNA of other tested mammals. The second element Tu-SAT1 is a tandem repeat with a monomer length of 365 bp. Some properties of its nucleotide sequence suggest that Tu-SAT1 is a centromeric satellite.     

Genetic polymorphism of mitochondrial DNA HVS-I and HVS-Ⅱ of Chinese Tu ethnic minority group

We analyzed the two hypervariable segments HVS-Ⅰ and HVS-Ⅱ of 108 Chinese Tu ethnic minority group samples for forensic and population genetics purposes.Comparing with Anderson sequence,79 polymorphic loci in HVS-Ⅰ and 40 in HVS-Ⅱ were found in Chi-nese Tu ethnic minority group mtDNA sequences,and 90 and 64 haplotypes were then defined.Haplotype diversity and the mean pair-wise differences were 0.9903±0.0013 and 5.7785 in HVS-Ⅰ,and 0.9777±0.0013 and 3.5819 in HVS-Ⅱ,respectively.By analyzing the hypervariable domain from nucleotide 1,6180 to 1,6193 in HVS-Ⅰ,we defined some new types of sequence variations.We also compared the relationship between Tu population and other populations using mtDNA HVS-Ⅰ sequences.According to Rst genetic distances,the phylogenetic tree showed that the Tu population,the Xi'an Han population,the Chinese Korean,and the Mongol ethnic group were in a clade.This indicated a close genetic relationship between them.There were far relations between the Tu population and other Chinese southern Han populations,Siberian,European,African,and other foreign populations.The results suggest that Tu population has a multi-origin and has also merged with other local populations.     

Molecular organization and evolution of the D17Leh80-like loci in the mouse t complex

We determined the sequence of Tu80, one of the molecular clones derived from microdissected fragments of Chromosome (Chr) 17. The sequence data demonstrated that Tu80 contains an open reading frame (ORF) of 204 bp. Two sequences within the ORF, one homologous to the LINE1 element and the other to the first intron of the C gene of mouse immunoglobulin, were observed. A separate sequence, homologous to Tu80, designated as NOV1, was isolated from a genomic library of mouse Chr 17. NOV1 was found to contain an inserted B2 repeat, making it structurally different from Tu80. The sequences of Tu80 and NOV1 were compared with those of LINE1 and the first intron of the C gene. The results suggest that the ancestor of the Tu80-like sequence might have arisen through recombination between a LINE1 element and the C gene. It is concluded that Tu80 and NOV1 might have resulted from duplication of an ancestral sequence followed by divergence. The comparative analysis also demonstrated a high degree of conservation of the LINE1-like sequence in Tu80 and NOV1. Based on the structure of human, rat, rabbit, and mouse LINE1 fragments, as well as those of NOV1 and Tu80, a phylogenetic tree was constructed. The available data tend to support the assumption that the ancestor for the Tu80-like sequence might have arisen not later than 27–33 million years ago.     

Repetitive sequences of the tree shrew genome (Mammalia, Scandentia)

Copies of two repetitive elements of the common tree shrew (Tupaia glis) genome were cloned and sequenced. The first element, Tu III, is a ～260 bp long short interspersed element (SINE) with the 5′ end derived from glycine RNA. Tu III carries long polypurine-and polypyrimidine-rich tracts, which may contribute to the specific secondary structure of Tu III RNA. This SINE was also found in the genome of the smooth-tailed tree shrew of another genus (Dendrogale). Tu III appears to be confined to the order Scandentia since it was not found in the DNA of other tested mammals. The second element, Tu-SAT1, is a tandem repeat with a monomer length of 365 bp. Some properties of its nucleotide sequence suggest that Tu-SAT1 is a centromeric satellite.     

Genetic polymorphism of mitochondrial DNA HVS-I and HVS-Ⅱ of Chinese Tu ethnic minority group

We analyzed the two hypervariable segments HVS-Ⅰ and HVS-Ⅱ of 108 Chinese Tu ethnic minority group samples for forensic and population genetics purposes.Comparing with Anderson sequence,79 polymorphic loci in HVS-Ⅰ and 40 in HVS-Ⅱ were found in Chi-nese Tu ethnic minority group mtDNA sequences,and 90 and 64 haplotypes were then defined.Haplotype diversity and the mean pair-wise differences were 0.9903:±0.0013 and 5.7785 in HVS-Ⅰ,and 0.9777±0.0013 and 3.5819 in HVS-Ⅱ,respectively.By analyzing the hypervariable domain from nucleotide 1,6180 to 1,6193 in HVS-Ⅰ,we defined some new types of sequence variations.We also compared the relationship between Tu population and other populations using mtDNA HVS-Ⅰ sequences.According to Rst genetic distances,the phylogenetic tree showed that the Tu population,the Xi'an Han population,the Chinese Korean,and the Mongol ethnic group were in a clade.This indicated a close genetic relationship between them.There were far relations between the Tu population and other Chinese southern Han populations,Siberian,European,African,and other foreign populations.The results suggest that Tu population has a multi-origin and has also merged with other local populations.     

乌拉尔图小麦(Triticum urartu)1Ay高分子量麦谷蛋白亚基基因编码区的克隆与鉴定

应用简并性引物和基因组PCR反应从乌拉尔图小麦(Triticum urartu)不同种质材料中获得并测定了表达型和沉默型1Ay高分子量麦谷蛋白亚基基因全长编码区的基因组DNA序列.表达型1Ay基因编码区的序列与前人已发表的y型高分子量麦谷蛋白亚基基因编码区的序列高度同源,由其推导的1Ay亚基的一级结构与已知的高分子量麦谷蛋白亚基相似.在细菌细胞中,表达型1Ay基因编码区的克隆序列可经诱导而产生1Ay蛋白,该蛋白与种子中1Ay亚基在电泳迁移率和抗原性上类似,表明所克隆的序列真实地代表了表达型1Ay基因的全长编码区.但是,本研究所克隆的沉默型1Av基因的编码区序列因含有3个提前终止子而不能翻译成完整的1Ay蛋白.讨论了表达型1Ay基因在小麦籽粒加工品质改良中的潜在利用价值以及lAy基因沉默的机制.     

乌拉尔图小麦(Triticum urartu)1Ay高分子量麦谷蛋白亚基基因编码区的克隆与鉴定(英文)

应用简并性引物和基因组PCR反应从乌拉尔图小麦(Triticum urartu)不同种质材料中获得并测定了表达型和沉默型1Ay高分子量麦谷蛋白亚基基因全长编码区的基因组DNA序列。表达型1Ay基因编码区的序列与前人已发表的y型高分子量麦谷蛋白亚基基因编码区的序列高度同源,由其推导的1Ay亚基的一级结构与已知的高分子量麦谷蛋白亚基相似。在细菌细胞中,表达型1Ay基因编码区的克隆序列可经诱导而产生1Ay蛋白,该蛋白与种子中1Ay亚基在电泳迁移率和抗原性上类似,表明所克隆的序列真实地代表了表达型1Ay基因的全长编码区。但是,本研究所克隆的沉默型1Ay基因的编码区序列因含有3个提前终止子而不能翻译成完整的1Ay蛋白。讨论了表达型1Ay基因在小麦籽粒加工品质改良中的潜在利用价值以及1Ay基因沉默的机制。     

我国几个民族中毛发根葡糖磷酸变位酶—1的亚型分布

本文报道了利用等电聚焦的方法,从毛发根鞘细胞分析了我国汉、苗、土家、撒拉、土、达斡尔和赫哲等民族的葡糖磷酸变位酶-1(PGM_1)10亚型的分布,并且与其他人群的基因频率作了比较。     

Expression pattern of acetylated α‐tubulin in porcine spermatogonia

Mammalian spermatogonial stem cells reside on the basement membrane of the seminiferous tubules. The mechanisms responsible for maintenance of spermatogonia at the basement membrane are unclear. Since acetylated α‐tubulin (Ac‐α‐Tu) is a component of long‐lived, stable microtubules and deacetylation of α‐tubulin enhances cell motility, we hypothesized that acetylation of α‐tubulin might be associated with positioning of spermatogonia at the basement membrane. The expression pattern of Ac‐α‐Tu at different stages of testis development was characterized by immunohistochemistry for Ac‐α‐Tu and spermatogonia‐specific proteins (PGP 9.5, DAZL). In immature pig testes, Ac‐α‐Tu was present exclusively in gonocytes at 1 week of age, and in a subset of spermatogonia at 10 weeks of age. At this age, spermatogonia are migrating toward the tubule periphery and Ac‐α‐Tu appeared polarized toward the basement membrane. In adult pig testes, Ac‐α‐Tu was detected in few single or paired spermatogonia at the basement membrane as well as in spermatids and spermatozoa. Only undifferentiated (DAZL?), proliferating (determined by BrdU incorporation) spermatogonia expressed high levels of Ac‐α‐Tu. Comparison with the expression pattern of β‐tubulin and tyrosinated α‐tubulin confirmed that only Ac‐α‐Tu is specific to germ cells. The unique pattern of Ac‐α‐Tu in undifferentiated germ cells during postnatal development suggests that posttranslational modifications of microtubules may play an important role in recruiting and anchoring spermatogonia at the basement membrane. Mol. Reprod. Dev. 77: 348–352, 2010. © 2009 Wiley‐Liss, Inc.     

Selective Irreversible Inactivation of Replicating Mengovirus by Nucleoside Analogues: a New Form of Viral Interference

We describe the selective irreversible inhibition of mengovirus growth in cultured cells by a combination of two pyrrolopyrimidine nucleoside analogues, 5-bromotubercidin (BrTu) and tubercidin (Tu). At a concentration of 5 microgram/ml, BrTu reversibly blocked the synthesis of cellular mRNA and rRNA but did not inhibit either mengovirus RNA synthesis or multiplication. BrTu is a potent inhibitor of adenosine kinase, and low concentrations of BrTu (e.g., 0.5 microgram/ml), which did not by themselves inhibit cell growth, blocked phosphorylation of Tu and thus protected uninfected cells against irreversible cytotoxicity resulting from Tu incorporation into nucleic acids. In contrast, in mengovirus-infected cells, BrTu did not completely inhibit Tu incorporation into mengovirus RNA, allowing the formation of Tu-containing functionally defective polynucleotides that aborted the virus development cycle. This increased incorporation of Tu coupled to mengovirus infection could be attributed either to a reduction in the inhibitory action of BrTu and/or its nucleotide derivatives at the level of nucleoside and nucleotide kinases and/or, perhaps, to an effect upon the nucleoside transport system. The virus life cycle in nucleoside-treated cells progressed to the point of synthesis of negative strands and probably to the production of a few defective new positive strands. Irreversible virus growth arrest was achieved if the nucleoside mixture of BrTu (0.5 to 10 microgram/ml) and Tu (1 to 20 microgram/ml) was added no later than 30 min after virus infection and maintained for periods of 2 to 8 h. The cultures thus "cured" of mengovirus infection could be maintained and transferred for several weeks, during which they neither produced detectable virus nor showed a visible cytopathic effect; however, the infected and cured cells themselves, while metabolically viable, were permanently impaired in RNA synthesis and unable to divide. Although completely resistant to superinfecting picornaviruses, they retained the ability to support the growth of several other viruses (vaccinia virus, reovirus, and vesicular stomatitis virus), showing that cured cells had, in general, retained the metabolic and structural machinery needed for virus production. The resistance of cured cells to superinfection with picornaviruses seemed attributable neither to interferon action nor to destruction or blockade of virus receptors but more likely to the consumption of some host factor(s) involved in the expression of early viral functions during the original infection.     

Phenylketonuria in U.S. blacks: molecular analysis of the phenylalanine hydroxylase gene

We investigated the frequency, origin, and molecular basis of phenylketonuria (PKU) in U.S. blacks. On the basis of 10 years of Maryland newborn-screening data, we found the frequency to be 1/50,000, or one-third that in whites. We performed haplotype analysis of the phenylalanine hydroxylase (PAH) gene of 36 U.S. blacks, 16 from individuals with classical PKU and 20 from controls. In blacks, 20% of wild-type PAH alleles have a common Caucasian haplotype (i.e., haplotype 1), whereas 80% had a variety of haplotypes, all rare in Caucasians and Asians. One of these, haplotype 15, accounted for a large fraction (30%). Among black mutant PAH alleles, 20% have a haplotype (i.e., either haplotype 1 or haplotype 4) common in Caucasians; 40% have a haplotype rare in Caucasians and Asians, and 40% have one of two previously undescribed haplotypes. Both can be derived from known haplotypes by a single event. One of these haplotypes is characterized by a new MspI restriction site, located in intron 8, which was present in five of 16 black mutant alleles but was not present in 60 U.S. black control, 20 U.S. Caucasian control, or 20 Caucasian mutant PAH alleles. Sequence analysis of DNA from a single individual, homozygous for the new MspI associated haplotype, shows homozygosity for a C----T transition at nucleotide 896 in exon 7 of the PAH cDNA, resulting in the conversion of leucine 255 to serine (L255S).