Mus musculus and Mus spretus homologues of the human telomere-associated protein TIN2

Telomere length is regulated by TRF1, which binds telomeric DNA, and TIN2, which binds TRF1. Laboratory mice (Mus musculus) have long telomeres, although a related mouse species, Mus spretus, has human-sized telomeres. Because differences in TIN2 might explain these differences in telomere length, we cloned cDNAs encoding murine TIN2s and compared their sequence to that of human TIN2. M. musculus (Mm) and M. spretus TIN2s were >95% identical, but shared only 67% identity with human TIN2. An N-terminal truncation, or N-terminal fragment, of MmTIN2 elongated M. spretus telomeres. These findings suggest that mouse TIN2, like human TIN2, negatively regulates telomere length, and that N-terminal perturbations have dominant-negative effects. Our findings suggest that differences in TIN2 cannot explain the telomere length differences among Homo sapiens, M. musculus, and M. spretus. Nonetheless, M. spretus cells appear be a good system for studying the function of mouse telomere-associated proteins.     

Mapping of alpha-spectrin on distal mouse chromosome 1

DNAs from different strains of inbred mice and feral Mus spretus were found to exhibit restriction fragment length polymorphisms (RFLP) when hybridized with a probe prepared from a c-DNA clone of the mouse alpha-spectrin (Spna-1) gene. Studies of five recombinant inbred strains and (C57BL/6 X M. spretus) F1 X C57BL/6 backcross mice demonstrated that these RFLPs were allelic and that Spna-1 is closely linked to Ly-9 and Ly-17 on the distal region of chromosome 1.     

Purine nucleoside phosphorylase heterogeneity in the mouse as analyzed by isoelectric focusing and specific activity

1. Isoelectric focusing in polyacrylamide gels identified three erythrocytic electrophoretic patterns of purine nucleoside phosphorylase in a survey of 16 mouse strains. 2. Three strain-specific electrophoretic types were also evident in liver, kidney and spleen leukocytes. 3. There are 3-fold differences in purine nucleoside phosphorylase activities between strains for several tissues; C57BL/6J and Mus spretus having the greatest and the least activity, respectively. 4. Within strains there were up to 8-fold tissue-specific differences in activity with the order from greatest to least being: liver, kidney, spleen leukocyte, erythrocyte, heart.     

Telomere Length Correlations among Somatic Tissues in Adult Zebra Finches

Telomeres are repetitive non coding DNA sequences located at the end of eukaryotic chromosomes, which maintain the integrity of the genome by hiding the chromosome ends from being recognised as double stranded breaks. Telomeres are emerging as biomarkers for ageing and survival, and are susceptible to reflect different individual life history trajectories. In particular, the telomere length with which one starts in life has been shown to be linked with individual life-long survival, suggesting that telomere dynamics can be a proxy for individual fitness and thereby be implicated in evolutionary trade-offs. As a consequence, an increasing number of studies were conducted on telomeres in the fields of ecology and evolutionary biology, in which telomere length was almost exclusively measured from blood samples. However, not only do the number of repeats of the telomeric sequences vary among species, but also within species with great inter-individual telomere lengths variability with age, tissues, and chromosomes. This raises the issue of the exact biological meaning of telomere measurement in blood cells and stimulated the study of the correlation of telomere lengths among tissues over age. By measuring telomere length in adult zebra finches (Taeniopygia guttata) in different somatic tissues displaying variable cell turnovers (bone marrow, brain, spleen, pectoral muscle, heart, liver and in red blood cells), we checked that the measure of telomere length in red blood cells is related to telomere lengths in the other tissues. Here we show significant relationships between the telomere lengths of red blood cells and several somatic tissues at adulthood. As red blood cells are easily accessible and suitable for the longitudinal monitoring of the individual rate of telomere loss, our study confirms that telomere length measured in red blood cells could serve as a surrogate for telomere length in the whole avian organism.     

Segregation of restriction fragment length polymorphism in an interspecies cross of laboratory and wild mice indicates tight linkage of the murine IFN-beta gene to the murine IFN-alpha genes.

Southern blot analysis with murine (Mu) interferon (IFN)-alpha cDNA of restricted genomic DNA of three inbred strains of mice belonging to the species Mus musculus domesticus (BALB/c, C57BL/6, and DBA/2) revealed only a limited degree of polymorphism. For example, with HindIII there were only two polymorphic bands out of 14 hybridizing fragments. With Mu IFN-beta cDNA there was no polymorphism at all between BALB/c and C57BL/6 in DNA restricted with seven different enzymes. In contrast, HindIII-restricted DNA of an inbred strain of wild mice (M. spretus Lataste) hybridized with the IFN-alpha probe displayed a high degree of polymorphism compared with the three strains of laboratory mice and was also polymorphic when probed with IFN-beta cDNA. Although M. musculus domesticus and M. spretus Lataste represent different species, certain interspecies crosses are possible in the laboratory. This enabled us to follow segregation of restriction fragment length polymorphism in HindIII-restricted DNA obtained from 18 backcross progeny of a (DBA/2 X M. spretus)F1 X DBA/2 interspecies cross. There was complete coincidence between the segregation of parental (DBA/2) and (DBA/2 X M. spretus)F1-type IFN-beta and IFN-alpha restriction fragment length polymorphism, indicating tight linkage of the IFN-beta and IFN-alpha genes. In addition, in 15 of 18 progeny the segregation coincided with that of the brown locus on chromosome 4, in accord with previous results obtained with the IFN-alpha probe in strains derived from crosses between BALB/c and C57BL/6 mice. Thus, the Mu IFN-beta gene is tightly linked to the Mu IFN-alpha gene cluster on chromosome 4 near the brown locus.     

Induction of tolerance to parental marrow grafts in F1 hybrid mice. Evidence for recognition of self-antigens

Lethally irradiated (C57BL/6xC3H)F1 mice are able to acutely reject parental C57BL/6 but not C3H marrow grafts, a phenomenon called hybrid resistance (HR). In attempts to inactivate this rejection mechanism we found that parental spleen cells activated with LPS are very potent in inducing tolerance to a subsequent C57BL/6 marrow graft. Tolerance is likely due to elimination of effector cells responsible for graft rejection as adoptive transfer of spleen cells from normal into tolerized mice reconstitutes responsiveness. Evidence is presented that the Ag on LPS-activated spleen cells responsible for induction of unresponsiveness are expressed on both C57BL/6 and (C57BL/6xC3H)F1 cells. This suggests that the HR effector cells recognize autoantigens. In support of this, induction of tolerance to C57BL/6 parental marrow grafts leads to a concomitant dramatic increase in endogenous CFU-spleen after a dose of gamma-irradiation. Moreover, elimination of the cells responsible for HR by injection of anti-ASGM1 antibody results in a similar increase of endogenous CFU-spleen after irradiation. It is concluded that HR is a reflection of autoimmunity, able to limit the proliferation of syngeneic marrow stem cells.     

Mus Spretus Line-1 Sequences Detected in the Mus Musculus Inbred Strain C57bl/6j Using Line-1 DNA Probes

The inbred mouse strain, C57BL/6J, was derived from mice of the Mus musculus complex. C57BL/6J can be crossed in the laboratory with a closely related mouse species, M. spretus to produce fertile offspring; however there has been no previous evidence of gene flow between M. spretus and M. musculus in nature. Analysis of the repetitive sequence LINE-1, using both direct sequence analysis and genomic Southern blot hybridization to species-specific LINE-1 hybridization probes, demonstrates the presence of LINE-1 elements in C57BL/6J that were derived from the species M. spretus. These spretus-like LINE-1 elements in C57BL/6J reveal a cross to M. spretus somewhere in the history of C57BL/6J. It is unclear if the spretus-like LINE-1 elements are still embedded in flanking DNA derived from M. spretus or if they have transposed to new sites. The number of spretus-like elements detected suggests a maximum of 6.5% of the C57BL/6J genome may be derived from M. spretus.     

Lactate dehydrogenase isozymes in xenotropic virus producing mice

Lactate dehydrogenase (LDH; E.C. 1.1.1.27) isozymes were compared in three inbred strains of mice, and two strains of wild mice, as well as the F1 hybrids and other genetic crosses involving two of the inbred strains. The strains examined were NZB/B1NJ, 129/J and C57BL/6J, Mus musculus molossinus and M. musculus castaneus. Genetic crosses were made between the xenotropic virus-producing NZB and the non-virus producing 129/J mice. Tissue specificity of LDH in these strains was studied using homogenates of kidney, liver, spleen and thymus. Polymorphism of the enzyme was studied by agarose gel electrophoresis. Enzyme polymorphism in the tissues of NZB and 129/J has not been previously reported. The liver and spleen tissues of 129/J showed the absence of LDH-1 and LDH-2 isozymes. Thymic homogenates of NZB showed a lack of expression of LDH-1, LDH-2 and LDH-3 isozymes. The F1, F2 and the backcross progeny from genetic crosses involving NZB, and 129/J mice showed an isozyme pattern more similar to the non-virus-producing 129/J strain than the virus-producing NZB. Evidence of genetic regulation at the LDH-B subunit appears to be the reason for the differential expression of the isozymes in NZB and 129/J strains. The other inbred strain of mice, C57BL/6J, also showed a greater similarity to the 129/J strain than NZB. The two strains of wild mice were similar in their expression of LDH-isozymes between each other and to the 129/J strain, with respect to the liver and spleen tissues.     

An X-encoded alloantigenicity between BALB/c and C57BL/6 strains of mice

To detect minor barriers to histocompatibility that might be encoded on the X chromosome in mice, we grafted reciprocal sets of (C57BL/6xBALB/c)F1, (C57BL/6xDBA/2)F1, and (BALB/cxDBA/2)F1 mice with tail skin from the respective paternal inbred strain. Our histogenic analysis suggests that, compared with the C57BL/6 mouse strain, the BALB/c strain generates X-linked antigen loss. In contrast, we detected no X-linked histogenic differences between strains C57BL/6 and DBA/2, or DBA/2 and BALB/c. To localize this X-linked barrier to histocompatibility, we produced a panel of 25 [(BALB/cxC57BL/6)F1xC57BL/6]N2 males that were grafted with C57BL/6 skin to determine which carried the BALB/c-derived component(s) necessary for graft rejection. DNA marker analysis showed one region of overlapping BALB/c-derived X-chromosomal segments among the graft rejecters, suggesting that this antigen-loss haplotype ( H-hix(c), for histoincompatibility on the X chromosome, c haplotype) may be restricted within the DXMit55 to the Xq telomere interval (which excludes only the centromeric tip of the X). Further backcrossing of H-hix(c) to C57BL/6 resulted in fewer rejecter mice than expected by the N4 generation, suggesting that a second, unlinked locus is also involved in this X-linked alloantigenicity. The vigorous rejection of male (C57BL/6xBALB)F1 and female (B6.C- H2(d)xC57BL/6)F1 skin by (BALB/cxC57BL/6)F1 males, as well as the assessment of markers on Chromosome 17 among N2 and N4 graft-recipient males, suggests that this second locus is H2, and that H-hix(b)-encoded alloantigens require both H2(b) and H2(d)-encoded presentation molecules for efficient graft rejection.     

Ageing and telomeres: a study into organ- and gender-specific telomere shortening

Telomeres, the non-coding sequences at the ends of chromosomes, in the absence of telomerase, progressively shorten with each cell division. Shortening of telomeres can induce cell cycle arrest and apoptosis. The aim of this study was to investigate age- and gender-related changes in telomere length in the rat and to detect possible tissue- specific rates of telomere shortening. Changes with age in telomere lengths were assessed by Southern blotting in the kidney, pancreas, liver, lung and brain of male and female rats. We determined the percentage of telomeres in various molecular size regions rather than measuring the average telomere length. The latter was unable to detect telomere shortening in the tissues. The percentage of short telomeres increased with age in the kidney, liver, pancreas and lung of both males and females, but not in the brain. Males had shorter telomeres than females in all organs analysed except the brain, where the lengths were similar. These findings indicate that telomeres shorten in the rat kidney, liver, pancreas and the lung in an age-dependent manner. These data also provide a novel mechanism for the gender-related differences in lifespan and suggest a tissue-specific regulation of telomere length during development and ageing in the rat.     

Regulation of murine telomere length by Rtel: an essential gene encoding a helicase-like protein

Little is known about the genes that regulate telomere length diversity between mammalian species. A candidate gene locus was previously mapped to a region on distal mouse Chr 2q. Within this region, we identified a gene similar to the dog-1 DNA helicase-like gene in C. elegans. We cloned this Regulator of telomere length (Rtel) gene and inactivated its expression in mice. Rtel(-/-) mice died between days 10 and 11.5 of gestation with defects in the nervous system, heart, vasculature, and extraembryonic tissues. Rtel(-/-) embryonic stem cells showed telomere loss and displayed many chromosome breaks and fusions upon differentiation in vitro. Crosses of Rtel(+/-) mice with Mus spretus showed that Rtel from the Mus musculus parent is required for telomere elongation of M. spretus chromosomes in F1 cells. We conclude that Rtel is an essential gene that regulates telomere length and prevents genetic instability.     

Characterization of a novel gene, sperm-tail-associated protein (Stap), in mouse post-meiotic testicular germ cells

During mammalian spermatogenesis, many specific molecules show the dynamics of expression and elimination, corresponding with the morphological differentiation of germ cells. We have isolated a novel cDNA designated F77 from mouse testis by cDNA subtractive hybridization between normal and sterile mice, using the C57BL/6 congenic strain for the hybrid sterilityhyphen;3 lpar;Hsthyphen;3rpar; allele from Mus spretus. The full-length F77 mRNA was 3.4 kb and showed significant nonmatching with entries in the databases. F77 was mapped at a proximal position between D8Mit212 and D8Mit138 on mouse chromosome 8, in which no corresponding genes related to its nucleotide sequence were found. F77 mRNA was not detected in any other organs except the testis of adult fertile mice. F77 protein was only seen in normal adult testis and epididymis. In contrast to normal C57BL/6 mice, F77 mRNA and protein were not seen in germ cell-deficient Kit(W)/Kit(Wv) mice. By in situ hybridization, F77 mRNA was detected mainly at round spermatids in the sexually mature testis, and immunohistochemical analysis revealed that F77 protein was located at the tail of elongated spermatids. We are proposing the name, sperm-tail-associated protein (Stap), for the gene encoding F77 cDNA. Mol. Reprod. Dev. 59: 350-358, 2001.     

Tissue distribution of bufuralol hydroxylase activity in Sprague-Dawley rats

This study has characterised the distribution of bufuralol 1'-hydroxylase activity in various organs of male and female Sprague-Dawley rats. Microsomes were prepared from the liver, kidney, brain, kidney, spleen and adrenals of male and female rats. Measurement of 1'-hydroxybufuralol produced by the incubation of racemic, (+) and (-) bufuralol with the microsomes was by HPLC. The specific activity (nmol/min/mg protein) of bufuralol 1'-hydroxylase in various tissues were: liver (M 12.3; F 10.2), kidney (M 12.3; F 11.7), brain (M 8.9; F 9.0), adrenal (M 0.9; F 0.3), lung (M 4.6; F 3.6) and spleen (M 8.8; F 10.0). Stereoselective preference (+/-) of the isozyme for (+) bufuralol was: Liver (M 2.2; F 2.2), kidney (M 2.2; F 2.1), brain (M 1.0; F 0.9), lung (M 0.74; F 0.95) and spleen (M 1.0; F 1.32).     

Upregulation of telomerase function during tissue regeneration

Telomerase plays a primary role in the maintenance of telomeres in immortal, germ, and tumor cells in humans but is lacking in most somatic cells and tissues. However, many species, including fish and inbred mice, express telomerase in most cells and tissues. Little is known about the expression of telomerase in aquatic species, although the importance of telomerase for longevity has been suggested. We compared telomerase activity and telomere lengths among a broad range of tissues from aquatic species and found telomerase at significant levels in both long- and short-lived aquatic species, suggesting constitutive telomerase expression has an alternative function. Telomere lengths in these aquatic species were comparable to those observed in normal human tissues and cell strains. Given that a host of aquatic species with short life spans have telomerase and a tremendous capacity to regenerate, we tested the hypothesis that telomerase upregulation is important for tissue regeneration. During regeneration, telomerase activity was upregulated and telomere lengths are maintained with the shortest telomeres being elongated, indicating the importance for maintaining telomere length and integrity during tissue regeneration. Thus, the expression of telomerase in aquatic animals is likely not related to longevity but to their ability to regenerate injured tissue.     

Variation in the Major Urinary Protein Multigene Family in Wild-Derived Mice

The levels of expression and genomic organization of genes coding for the major urinary proteins (MUPs) were examined in several stocks of wild-derived mice. Levels of MUP mRNA in the liver varied considerably with M. musculus Brno and M. castaneus males having several-fold more MUP RNA than inbred C57BL/6 males, whereas M. hortulanus, M. caroli and M. cervicolor displayed levels much lower than C57BL/6. Analysis of RNA with MUP cDNAs specific to two different subfamilies of MUP genes revealed that M. caroli and M. cervicolor primarily expressed a MUP mRNA that was less abundant in C57BL/6, suggesting differential expression of subfamilies of genes within the MUP multigene complex. Although inbred males usually have five-fold more MUP mRNA than inbred females, male to female ratios for wild-derived stocks ranged from one to several hundred. Southern blots of genomic DNA hybridized to MUP subfamily probes revealed differences in restriction fragment sizes as well as possible variation in the number of MUP genes in some species. Analysis of urinary proteins from hybrids between C57BL/6 and M. spretus suggested that low MUP expression in M. spretus females was due to cis-acting genetic elements.     

Telomere Length Profiles in Humans: All Ends are Not Equal

Telomere length is an important parameter of telomere function since it determines number of aspects controlling chromosome stability and cell division. Since telomeres shorten with age in humans and premature aging syndromes are often associated with the presence of short telomeres, it has been proposed that telomere length is also an important parameter for organismal aging. How mean telomere lengths are determined in humans remains puzzling, but it is clear that genetic and epigenetic factors appear to be of great importance. Experimental evidence obtained from many different organisms has provided the basis for a widely accepted counting mechanism based on a negative feedback loop for telomerase activity at the level of individual telomeres. In addition, recent studies in both normal and pathological contexts point to the existence of chromosome-specific mechanisms of telomere length regulation determining a telomere length profile, which is inherited and maintained throughout life. In this review, we recapitulate the available data, propose a synthetic view of telomere length control mechanisms in humans and suggest new approaches to test current hypotheses.     

Analysis of sex-chromosome aneuploidy in interspecific backcross progeny between the laboratory mouse strain C57BL/6 and Mus spretus.

Sex-chromosomal aneuploidy was identified in four female progeny of 200 interspecific backcrosses between laboratory mice (C57BL/6Ros) and Mus spretus. The progeny included two 39,XO monosomy mice resulting from a backcross with M. spretus, as well as a 41,XXX trisomic mouse and a 40,XX/41,XXX mosaic mouse resulting from two separate backcrosses with C57BL/6 mice. The parental origin and meiotic stage of the aneuploidies was determined for each of the mice using a series of markers that identified allelic differences in the parental X-chromosome genes present in the hybrid female. Two of the probes identified differences in repeated elements between the M. spretus and laboratory mouse X chromosomes, whereas the remaining sites involved restriction fragment length differences of single-copy genes detectable by Southern analysis. These markers indicated that the aneuploidies were most likely of maternal origin and that the trisomy resulted from a nondisjunction at the second meiotic division. In contrast, the mosaic female could have originated either from a trisomic embryo that had lost a single X in a portion of its cells or from a mitotic nondisjunction during early embryogenesis that resulted in XXX and XO daughter cells, with subsequent loss of the XO cells.     

QTL for body composition on chromosome 7 detected using a chromosome substitution mouse strain

Objective: Previous studies in mice have detected quantitative trait loci (QTLs) on chromosome 7 that affect body composition. As a step toward identifying the responsible genes, we compared a chromosome 7 substitution strain C57BL/6J‐Chr7^129S1/SvImJ/Na (CSS‐7) to its host (C57BL/6J) strain. Methods and Procedures: Fourteen‐week‐old mice were measured for body size (weight, length), organ weight (brain, heart, liver, kidneys, and spleen), body and bone composition (fat and lean weight; bone area, mineral content, and density), and individual adipose depot weights (gonadal, retroperitoneal, mesenteric, inguinal, and subscapular). Differences between the CSS‐7 strain and the host strain were interpreted as evidence for the presence of one or more QTLs on chromosome 7. Results: Using this criterion, we detected QTLs for body weight, bone area, bone mineral content, brain, and heart weight, most adipose depot weights and some indices of fatness. A few strain differences were more pronounced in males (e.g., most adiposity measures) and others were more pronounced in females (e.g., bone area). QTLs for body length, lean weight, bone mineral density, and kidney, spleen, and liver weight were not detected. Discussion: This study found several associations that suggest one or more QTLs specific to the weight of select tissues and organs exist on mouse chromosome 7. Because these loci are detectable on a fixed and uniform genetic background, they are reasonable targets for high‐resolution mapping and gene identification using a congenic approach.