Genetics analysis of mouse mutations Abnormal feet and tail and rough coat, which cause developmental abnormalities and alopecia.

Mutations in the mouse Brachyury (T) gene are characterized by a dominant reduction of tail length and recessive lethality. Two quantitative trait loci, Brachyury-modifier 1 and 2 (Brm1 and Brm2) are defined by alleles that enhance the short-tail Brachyury phenotype. Here we report on a genetic analysis of a visible dominant mutation Abnormal feet and tail (Aft) located in the vicinity of Brm1.

Mapping and expression analysis of the mouse ortholog of Xenopus Eomesodermin.

The T-box gene family has been conserved throughout metazoan evolution. The genes code for putative transcription factors which share a uniquely defining DNA binding domain, known as the T-box ([Bollag et al., 1994]).

Cloning, mapping, and expression analysis of TBX15, a new member of the T-Box gene family.

The T-box gene family has been conserved throughout metazoan evolution and codes for putative transcription factors that share a uniquely defining DNA-binding domain. We have previously uncovered six mouse T-box genes with discrete spatial and temporal patterns of expression during embryogenesis. Here, we report a novel mouse T-box gene, Tbx15.

Involvement of T-box genes Tbx2-Tbx5 in vertebrate limb specification and development.

We have recently shown in mice that four members of the T-box family of transcription factors (Tbx2-Tbx5) are expressed in developing limb buds, and that expression of two of these genes, Tbx4 and Tbx5, is primarily restricted to the developing hindlimbs and forelimbs, respectively. In this report, we investigate the role of these genes in limb specification and development, using the chick as a model system. We induced the formation of ectopic limbs in the flank of chick embryos to examine the relationship between the identity of the limb-specific T-box genes being expressed and the identity of limb structures that subsequently develop.

Sequence divergence within the sperm-specific polypeptide TCTE1 is correlated with species-specific differences in sperm binding to zona-intact eggs.

The T-complex-associated testes-expressed (TCTE1) gene encodes a novel sperm cell-specific polypeptide (TCTE1) that is conserved across vertebrate species. TCTE1 is absolutely required for fertilization and is expressed in earlier stages of spermatogenesis. When the amino acid sequence of the TCTE1 gene product is compared among various mammalian species, a large, highly conserved domain is observed, along with a divergent domain encoding the 56-58 residues at the N terminus.

Sex-specific modifiers of tail development in mice heterozygous for the brachyury (T) mutation.

The brachyury, or T, locus encodes a transcription factor that plays a crucial role in the early development of all animals. In the mouse, animals heterozygous for a null mutation at this locus are born with a characteristic short tail. Expressivity of the short tail phenotype is greatly affected by genetic background.

Three novel T-box genes in Caenorhabditis elegans.

The T-box gene family consists of members that share a unique DNA binding domain. The best characterized T-box gene, Brachyury or T, encodes a transcription factor that plays an important role in early vertebrate development. Seven other recently described mouse T-box genes are also expressed during development.

Analysis of mutation rates in the SMCY/SMCX genes shows that mammalian evolution is male driven.

Mammalian evolution is believed to be male driven because the greater number of germ cell divisions per generation in males increases the opportunity for errors in DNA replication. Since the Y Chromosome (Chr) replicates exclusively in males, its genes should also evolve faster than X or autosomal genes. In addition, estimating the overall male-to-female mutation ratio (alpha m) is of great importance as a large alpha m implies that replication-independent mutagenic events play a relatively small role in evolution.

Evolution of mouse T-box genes by tandem duplication and cluster dispersion.

The T-box genes comprise an ancient family of putative transcription factors conserved across species as divergent as Mus musculus and Caenorhabditis elegans. All T-box gene products are characterized by a novel 174-186-amino acid DNA binding domain called the T-box that was first discovered in the polypeptide products of the mouse T locus and the Drosophila melanogaster optomotor-blind gene. Earlier studies allowed the identification of five mouse T-box genes, T, Tbx1-3, and Tbr1, that all map to different chromosomal locations and are expressed in unique temporal and spatial patterns during embryogenesis.

Expression of the T-box family genes, Tbx1-Tbx5, during early mouse development.

A novel family of genes, characterized by the presence of a region of homology to the DNA-binding domain of the Brachyury (T) locus product, has recently been identified. The region of homology has been named the T-box, and the new mouse genes that contain the T-box domain have been named T-box 1-6 (Tbx1 through Tbx6). As the basis for further study of the function and evolution of these genes, we have examined the expression of 5 of these genes, Tbx1-Tbx5, across a wide range of embryonic stages from blastocyst through gastrulation and early organogenesis by in situ hybridization of wholemounts and tissue sections.

Evidence of a role for T-box genes in the evolution of limb morphogenesis and the specification of forelimb/hindlimb identity.

Tetrapod fore-and hindlimbs have evolved from the pectoral and pelvic fins of an ancient vertebrate ancestor. In this ancestor, the pectoral fin appears to have arisen following the rostral homeotic recapitulation of an existing pelvic appendage (Tabin and Laufer (1993), Nature 361, 692-693). Thus the basic appendage outgrowth program is reiterated in both tetrapod fore- and hindlimbs and the pectoral and pelvic fins of extant teleost fishes (Sordino et al.

The Cairo spiny mouse Acomys cahirinus shows a strong affinity to the Mongolian gerbil Meriones unguiculatus.

The classification of the African spiny mice (genus Acomys) within the Muridae family of rodents has been fraught with controversy. Morphological data suggest a close affinity between this group and true old world mice of the genus Mus. However, the combined results of immunological, biochemical, and DNA melting studies suggest that spiny mice should not even be considered as members of the Murinae subfamily.

Identification, characterization, and localization to chromosome 17q21-22 of the human TBX2 homolog, member of a conserved developmental gene family.

The T-box motif is present in a family of genes whose structural features and expression patterns support their involvement in developmental gene regulation. Previously, sequence comparisons among the T-box domains of ten vertebrate and invertebrate T-box (Tbx) genes established a phylogenetic tree with three major branches. The Tbx2-related branch includes mouse Mm-Tbx2 and Mm-Tbx3, Drosophila optomotor-blind (Dm-Omb), and Caenorhabditis elegans Ce-Tbx2 and Ce-Tbx2 and Ce-Tbx7 genes.

Conservation of the T-box gene family from Mus musculus to Caenorhabditis elegans.

Recently, a novel family of genes with a region of homology to the mouse T locus, which is known to play a crucial, and conserved, role in vertebrate development, has been discovered. The region of homology has been named the T-box. The T-box domain of the prototypical T locus product is associated with sequence-specific DNA binding activity.

Evolution of a long-range repeat family in chromosome 1 of the genus Mus.

Copy numbers and variation of a clustered long-range repeat family on chromosome (Chr) 1 have been studied in different species of the genus Mus. The repeat sequence was present in all, as inferred from cross-hybridization with probes derived from the Mus musculus repeat family. Copy numbers determined by dot blot hybridization were very low, from three to six per haploid genome in M.

Population dynamics of aberrant chromosome 1 in mice.

Natural populations of two semispecies of house mouse, Mus musculus domesticus and M.m. musculus, were found to be polymorphic for an aberrant chromosome 1 bearing a large inserted block of homogeneously staining heterochromatin.

Effect of sperm genotype on chromatid segregation in female mice heterozygous for aberrant chromosome 1.

An aberrant chromosome 1 with two large homogeneously staining insertions was isolated from wild populations of Mus musculus musculus. The specific features of the aberrant chromosome have been described elsewhere (Agulnik et al. 1990).

Meiotic drive on aberrant chromosome 1 in the mouse is determined by a linked distorter.

An aberrant chromosome 1 carrying an inverted fragment with two amplified DNA regions was isolated from wild populations of Mus musculus. Meiotic drive favouring the aberrant chromosome was demonstrated for heterozygous females. Its cause was preferential passage of aberrant chromosome 1 to the oocyte.

[Effect of sperm genotype on the segregation of homologs in male mice, heterozygous for an aberrant chromosome 1].

The aberrant chromosome 1 with two large homogeneously staining insertions was isolated from wild populations of Mus musculus. Specific features of aberrant chromosome were described elsewhere. These include preferential entry of the chromosome into the oocyte of heterozygous females, increased mortality of homozygotes, decreased fertility of homozygous females.

Zoogeography of the chromosome 1 HSR in natural populations of the house mouse (Mus musculus).

A polymorphism of the central part of chromosome 1 has been described from natural populations of the house mouse (Mus musculus). The region shows up as a C band-positive homogeneously staining region (HSR) under the light microscope. M.

[Meiotic drive for aberrant chromosome 1 in mice is determined by a linked distorter].

An aberrant chromosome 1 carrying an inverted fragment with two amplified DNA regions was isolated from natural populations of Mus musculus. A meiotic drive favouring the aberrant chromosome was previously demonstrated for heterozygous females. The cause for this was the preferential passage of the chromosome 1 to the oocyte.

Chromosome pairing and recombination in mice heterozygous for different translocations in chromosomes 16 and 17.

In order to clarify the relationship between meiotic pairing and recombination, an electron microscopic (EM) study of synaptonemal complexes (SC) and an analysis of chiasma frequency and distribution were made in male mice singly and doubly heterozygous for Robertsonian [Rb(16.17)7Bnr] and reciprocal [T(16:17)43H] translocations and also in tertiary trisomics for the proximal region of chromosome 17. In all these genotypes an extensive zone of asynapsis/desynapsis around the breakpoints was revealed.

Two doses of the paternal Tme gene do not compensate the lethality of the Thp deletion.

The hairpin-tail (Thp) deletion in chromosome 17 is lethal when it is inherited from the mother, whereas heterozygotes with Thp deletion that is paternal in origin are viable. The lethal effect of maternal Thp is due to a deficiency of the Tme gene that is located in the Thp-deleted region. In this article we describe analysis of the viability of mice with tertiary trisomy of chromosome 17, Ts(17(16]43H, with different doses of the paternal and maternal Tme alleles.

Functional analysis of mutations of murine chromosome 17 with the use of tertiary trisomy.

Analysis of the functional nature of mutations can be based on comparisons of their manifestation in organisms with a deletion or duplication of a particular chromosome segment. With the use of reciprocal translocation T(16;17)43H, it is feasible to produce mice with tertiary trisomy of the proximal region of chromosome 17. The mutations on chromosome 17 we tested included brachyury (T), hairpin tail (Thp), kinky (Fuki), quaking (qk), tufted (tf), as well as tct (t complex tail interaction), and tcl (t complex lethal) that are specific to t haplotypes.