The male sterility and histoincompatibility (mshi) mutation in mice is a natural variant of microtubule-associated protein 7 (Mtap7).

Males homozygous for the mouse male sterility and histoincompatibility (mshi) mutation exhibit small testes and produce no sperm. In addition, mshi generates an "antigen-loss" histoincompatibility barrier, such that homozygous mutants reject skin grafts from wild type co-isogenic BALB/cByJ donors. To facilitate the molecular characterization of the pleiotropic mshi mutation, we genetically mapped mshi into a 0.68 megabasepair region which contains fewer than 10 candidate genes. Complementation testing showed that one of these, Mtap7, is disrupted in mshi mice. Sequence analysis has revealed a 13 kilobasepair deletion in BALB/cByJ-mshi/J mice that begins in Intron 10-11 of Mtap7, and ends less than 2000 base pairs downstream of the wild type gene. Analysis of the mutant cDNA predicts that Mtap7(mshi) encodes a 457 amino acid protein, the first 423 of which are identical to wild type, and the last 34 of which are due to aberrant mRNA splicing with two cryptic exons in the Mtap7 to P04Rik intergenic region. This molecular assignment for the mshi mutation further supports an essential role for microtubule stabilization in spermatogenesis and indicates a new role in allograft transplantation.

The rat shorn mutation (shn) maps between D7Got143 and D7Rat94.

The recessive shorn (shn) mutation in the rat generates an almost complete absence of normal hair. Previous analysis of 85 backcross rats typed for shn-generated hypotrichosis located this marker between the telomere and D7Mgh1 on distal rat Chromosome 7. Here, we present a microsatellite polymorphism analysis of a 184-member backcross panel-including 99 new rats-that places shn within a 2.7cM interval between markers D7Got143 and D7Rat94. In addition, this analysis has allowed meiotic ordering of 18 microsatellite markers-including 10 D7Got markers previously positioned only by radiation reduced hybrid analysis-across the 16.8cM region between D7Mit16 (Cyp2d4) and D7Rat94. Our inability to meiotically separate shn from 8 microsatellite markers (mapped by others over some 2-4cM or more than 40cR of genetic distance) suggests that the shn mutation may result from a chromosomal rearrangement that suppresses recombination throughout this interval.

The Charles River "hairless" rat mutation maps to chromosome 1: allelic with fuzzy and a likely orthologue of mouse frizzy.

Recent evidence has indicated that the recessive mutation affecting hypotrichosis in the Charles River (CR) "hairless" rat does not involve the hairless gene (hr) on rat chromosome 15. To determine if this mutation might be allelic (or orthologous) with any other previously mapped hypotrichosis-generating mutation in mammals, we have produced a panel of backcross rats segregating for the CR hairless rat mutation as well as numerous other markers from throughout the rat genome. Analysis of this panel has located the CR hairless rat's hypotrichosis-generating mutation on chromosome 1, near Myl2, where only the fuzzy mutation in rat (fz) and the frizzy mutation in mouse (fr) have been previously localized. Intercrossing fz/fz and CR hairless rats produced hybrid offspring with abnormal hair, showing that these two rat mutations are allelic. We suggest that the CR hairless rat mutation and fuzzy be renamed frizzy-Charles River (fr(CR)) and frizzy-Harlan (fr(H)), respectively, to reflect their likely orthology with the mouse fr mutation.

Using a phage display library to identify basic residues in A-Raf required to mediate binding to the Src homology 2 domains of the p85 subunit of phosphatidylinositol 3'-kinase.

Src homology 2 (SH2) domains are found in a variety of cytoplasmic proteins involved in mediating signals from cell surface receptors to various intracellular pathways. They fold as modular units and are capable of recognizing and binding to short linear peptide sequences containing a phosphorylated tyrosine residue. Here we show that each of the SH2 domains of the p85 subunit of phosphatidylinositol 3-kinase selects phage displayed peptide sequences containing the core (L/I)-A-(R/K)-I-R. The serine/threonine kinase A-Raf, containing the sequence LQRIRS, is associated with the p85 protein in both quiescent and growth factor stimulated cells. This suggests that p85 and A-Raf exist in a protein complex in cells and that complex formation does not require growth factor stimulation. We also show that p85 and A-Raf can bind directly to each other in vitro and that this interaction is mediated in part by the p85 SH2 domains. Further, the p85 SH2 domains require at least one of four distinct basic-X-basic sequence motifs within A-Raf for binding. This is the first description of a phosphotyrosine-independent SH2 domain interaction that requires basic residues on the SH2 ligand.

The hypotrichosis-generating shorn (shn) mutation maps to distal chromosome 7 in the Norway rat.

We have recently identified an autosomal recessive mutation in the Norway rat that generates an almost complete absence of normal hair. Here we describe a multilocus backcross analysis that was used to map this mutation, named shorn (gene symbol shn), to the distal end of rat chromosome 7. Although this region in rat carries no previously mapped similar mutations, the homologous genomic regions in mouse and human contain several potential homologues and candidate genes.

The H-mshi antigen is conserved among standard BALB/cBy, C57BL/6J, and wild-derived CAST/Ei and SPRET/Ei inbred strains of mice.

The recessive male sterility and histoincompatibility mutation (mshi) arose spontaneously in the standard inbred mouse strain BALB/cBy. In addition to generating sterility in homozygous males, mshi controls the loss of a minor histocompatibility antigen designated H-mshi. To determine whether the H-mshi antigen normally expressed by the BALB/cBy strain (H-mshi(c)) is the same as or different from the antigen (H-mshi(x)) expressed by the standard inbred C57BL/6J strain or the wild-derived CAST/Ei and SPRET/Ei strains, animals heterozygous for the mutant antigen-loss allele (H-mshi-) and H-mshi(x) were grafted with tail skin from BALB/cBy mice. The long-term retention of grafts by these hosts indicates that the H-mshi antigen encoded by the BALB/cBy, C57BL/6J, CAST/Ei, and SPRET/Ei strains is histogenically identical. Conservation of this minor histocompatibility antigen among these evolutionarily diverse strains suggests that H-mshi encodes a functionally important cellular product(s).

Mouse male sterility and histoincompatibility (mshi) maps between the D10Mit51/168/212 cluster and D10Mit213.

The recessive male sterility and histoincompatibility (mshi) mutation in the mouse generates pleiotropic effects on graft transplantation and male reproduction. Previous analysis of backcross mice typed for mshi either by testicular morphology or by allograft rejection has located each trait to a 20-cM region on proximal mouse Chr 10. Here we present the microsatellite polymorphism analysis of a new 276-member intraspecific backcross panel--including a set of 135 males typed for sterility and histoincompatibility--that places both features controlled by mshi within a 1.7-cM interval between markers D10Mit51/168/212 and D10Mit213. In addition, this analysis has allowed an explicit test of a two-gene model for the mshi locus and has provided a measurement of the penetrance of the mshi-generated histogenic phenotype in both male (88.4 +/- 3.9%) and female (91.0 +/- 3.5%) mutants. The fine-structure map presented should facilitate a chromosome walk across this region and, ultimately, the molecular identification of the gene or genes affected by this interesting mutation.

Shorn (shn): a new mutation causing hypotrichosis in the Norway rat.

We report the identification of an autosomal recessive mutation in the Norway rat that causes an almost complete absence of normal hair. The mutation, named shorn (gene symbol shn), is distinct from fuzzy, hairless, and Rowett nude, and is not closely linked with any of these markers or with albino.

Seamless tiling of amorphous silicon photodiode-TFT arrays for very large area X-ray image sensors.

We propose a method for producing a truly seamless tiled image sensor from four identical subarrays, such that the resulting tiled image sensor has no missing pixels. Four standard amorphous silicon photodiode-TFT (thin film transistor) arrays are cut parallel to the bus-bars, in the space between the bus-bar and the preceding pixel electrode. The cut is done in such a way that it is adjacent to the pixel electrode on the active plate. The four subarrays are then rotated by 90 degrees, with respect to their neighbors, and butted together. In this way, the seam between each tile has no adjacent bus-bar, and it is possible to reproduce the pixel pitch between neighboring tiles, with an acceptable alignment tolerance of the tiles. We have demonstrated the feasibility of the method, with the aid of a small prototype, based on a 192 x 192 pixel array, with a 200-microm pitch. Some image processing is necessary to rotate the images back for display on a conventional display monitor. This can cause artefacts, in some fast moving scenes, in which case an alternative scheme, which uses two mirror image arrays, each rotated by 180 degrees, can be used. However, for static X-ray images and most images in dynamic medical X-ray applications this is not necessary and we can obtain good quality seamless images, free from any significant artefacts.

Molecular genetic mapping of the mouse male sterility and histoincompatibility (mshi) mutation on proximal chromosome 10.

The recessive male sterility and histoincompatibility (mshi) mutation in the mouse generates pleiotropic effects on histocompatibility and male reproduction, while female mutants appear to be reproductively normal. We have mapped the mshi mutation to mouse Chromosome (Chr) 10 by analysis of 126 progeny from an intraspecific backcross. Our analysis both places the male sterility and histoincompatibility controlled by mshi within a 20-cM interval between the markers D10Mit51/D10Mit212 and D10Mit170 and has allowed the ordering of several other microsatellite markers on Chr 10 that were previously unresolved. The high-resolution backcross panel we describe should facilitate the isolation of more tightly linked probe sequences and, ultimately, the molecular identification of the gene or genes affected by this interesting mutation.

Simultaneous immunoselection in vitro for H-Y or H-2D antigen-loss variants of a mouse-derived B cell line.

Cytotoxic T lymphocytes (CTL) specifically reactive with the male transplantation antigen (H-Y) were used to immunoselect in vitro for antigen loss among cells from an Abelson murine leukemia virus (AbMuLV) transformed lymphoblastoid cell line. Numerous variant cell clones were recovered that had lost expression of either H-Y or the restricting major histocompatibility class I molecule, H-2D. In all experiments, low-level gamma-irradiation applied prior to immunoselection increased the frequency of antigen loss, but when different time intervals between mutagenesis and immunoselection were used, the proportion of H-Y to H-2D antigen loss was affected, suggesting that the antigens selected against remain on the surface of the cell for differing amounts of time following allele loss.

Deletion mapping by immunoselection against the H-Y histocompatibility antigen further resolves the Sxra region of the mouse Y chromosome and reveals complexity of the Hya locus.

A genetic map of the mammalian Y chromosome cannot be produced by standard Mendelian methods because the Y does not participate in meiotic exchange over the majority of its length. However, deletion mapping of the mouse Y chromosome is facilitated by the fact that its short arm carries the histocompatibility-Y (Hya) locus. This locus encodes male-specific (H-Y) antigens that can be selected against in tissue culture by the technique of immunoselection. To produce cells carrying deletions, cytotoxic T lymphocytes (CTLs) specific for H-Y antigens were cocultured with a lymphoblastoid cell line derived from a mouse carrying the portion of the short arm defined by the Sxra translocation on the distal end of its X chromosome. H-Y antigen-loss variant cells that contained Y-specific deletions were identified. Molecular, karyotypic, and immunological analysis of the deletion variants allowed us to define up to 16 ordered intervals and suggested an overall organization of Sxra. The analysis also suggests that at least two and up to five distinct loci encode H-Y antigens.

Genetic and molecular analysis of recessive alleles at the pink-eyed dilution (p) locus of the mouse.

Recessive mutant alleles at the pink-eyed dilution (p) locus on mouse chromosome 7 reduce pigmentation of both the coat and eyes. Here we describe the properties and complementation interactions of 10 p alleles, including 6 not previously reported. Several alleles that cause additional phenotypes affecting development, reproduction, and behavior were shown to be deletions by using DNA probes derived from the p region. An alignment of functional and marker-defined units is proposed, giving a linear complementation map that orders at least four functional loci. The characterization of a nested set of deletions around p will facilitate detailed molecular analyses of the genes and developmental functions associated with this part of the mouse genome.

Telomere-related markers for the pseudoautosomal region of the mouse genome.

The pseudoautosomal (PA) region of the mammalian genome is the region of the X and Y chromosomes that shares extensive DNA sequence homology and is of special interest because it may play an essential role during male meiosis. We have identified three telomere-related restriction fragments from the PA region of the mouse genome, using an oligonucleotide probe composed of the mammalian telomere consensus sequence TTAGGG. PA assignment of two C57BL/6J-derived fragments was initially suggested by analysis of DNAs from progeny sired by C57BL/6J males carrying the rearranged Y chromosome, Y*: the hybridization intensity of both fragments was concordant with the sex-chromosome complement of the offspring. Further analysis indicated that both fragments were present in female and male F1, mice regardless of the sex of their C57BL/6J parent--a criterion for autosomal or PA linkage. Both fragments were closely linked to each other and located on the X chromosome distal to amelogenin (Amg)--in agreement with X or PA linkage. Confirmation of the PA derivation of these fragments was accomplished by following their segregation in a cross involving XY* males mated to DBA/2J females. A similar experiment identified a third PA-derived restriction fragment of LT/SvEi origin. Identification of PA-derived telomere-related restriction fragments will enable further genetic analysis of this region of the mouse genome.

Mapping anti-müllerian hormone (Amh) and related sequences in the mouse: identification of a new region of homology between MMU10 and HSA19p.

A panel of 78 backcross progeny, BALB/cJ x (BALB/cJ x CAST/Ei)F1, was used to map the gene encoding anti-Müllerian hormone (Amh), also called Müllerian inhibiting substance, to mouse Chromosome 10 (MMU10). This analysis identified a new region of linkage homology between human Chromosome 19p (HSA 19p) and MMU10 and localized an apparent recombinational hot spot in (C57BL/6J x Mus spretus)F1 females [compared with (BALB/cJ x CAST/Ei)F1 males] to the interval between phenylalanine hydroxylase (Pah) and mast cell growth factor (Mgf). In addition, eight unlinked polymorphic sequences, provisionally designated Amh-related sequences (Amh-rs1 through Amh-rs8), were identified by Southern blot analysis using Amh probes. Amh-rs1, -rs2, -rs4, and -rs7 were mapped to MMU1, 13, 12, and 15, respectively, by recombinant inbred (RI) strain and intraspecific backcross analyses. The NXSM RI strain distribution patterns for the four unmapped loci are also presented.

Partial complementation by murine t haplotypes: deficit of males among t6/tw5 double heterozygotes and correlation with transmission-ratio distortion.

To evaluate whether sex reversal contributes to sex-ratio imbalance among t6/tw5 double heterozygotes, the cross performed by K. B. Bechtol (Genetical Research 39, 1982, 79-84), T/t6 x T/tw5, was repeated. Significantly more normal-tailed (t6/tw5) females than males were recovered. By contrast, sex ratios were normal among tailless progeny resulting from this cross and among all classes produced by control crosses. Hybridization of a Y-specific DNA probe with genomic DNA from phenotypic females revealed no XY, sex-reversed males. On the genetic backgrounds that generated only moderate transmission distortion of tw5 (81-85%), the overall viability of the doubly heterozygous progeny was only 50% and the sex-ratio skew among this class was strong. However, on a genetic background that displayed extreme tw5 transmission (99%), embryonic viability was more than 80% and the sex-ratio imbalance was weak.

The mouse Y* chromosome involves a complex rearrangement, including interstitial positioning of the pseudoautosomal region.

Cytological analysis of the mouse Y* chromosome revealed a complex rearrangement involving acquisition of a functional centromere and centromeric heterochromatin and attachment of this chromosomal segment to the distal end of a normal Y* chromosome. This rearrangement positioned the Y* short-arm region at the distal end of the Y* chromosome and the pseudoautosomal region interstitially, just distal to the newly acquired centromere. In addition, the majority of the pseudoautosomal region was inverted. Recombination between the X and the Y* chromosomes generates two new sex chromosomes: (1) a large chromosome comprised of the X chromosome attached at its distal end to all of the Y* chromosome but missing the centromeric region (XY*) and (2) a small chromosome containing the centromeric portion of the Y* chromosome attached to G-band-negative material from the X chromosome (YX). Mice that inherit the XY* chromosome develop as sterile males, whereas mice that inherit the Y*X chromosome develop as fertile females. Recovery of equal numbers of recombinant and nonrecombinant offspring from XY* males supports the hypothesis that recombination between the mammalian X and Y chromosomes is necessary for primary spermatocytes to successfully complete spermatogenesis and form functional sperm.

Meiotic mapping of murine chromosome 17: the string of loci around l(17)-2Pas.

We describe a genetic analysis of l(17)-2Pas, an embryonic lethal mutation on murine chromosome 17. Males transmitted the l(17)-2 allele to only 38% of their offspring, whereas females transmitted this allele at 50%. Two-point crosses revealed tight linkage between l(17)-2 and brachyury (T), and deletion mapping placed l(17)-2 outside of the hairpin-tail deletion (Thp). To map this mutation more precisely, we intercrossed hybrid mice that carry distinct alleles at many classical and DNA loci on chromosome 17 and obtained 172 animals recombinant in the T to H-2 region. Strong positive interference was observed over the 14 cM interval from T to H-2K. Thus, a single recombinant can be informative; one such recombinant places l(17)-2 distal of the molecular marker D17Leh66D. Robust genetic maps can be constructed with multilocus crosses that share anchor loci. DNA markers can be interpolated onto these maps retrospectively.

Pleiotropic action of the murine quaking locus: structure of the qkv allele.

The spontaneous allele quakingviable (qkv) exerts effects on myelination and spermiogenesis. The defects generated by qkv were not separated in a multilocus mapping cross that provided a mapping resolution of 0.1 centiMorgans (cM). Furthermore, no distortions suggestive of a large chromosomal anomaly associated with qkv were apparent. One plausible interpretation is that the quaking locus contains more than one functional domain, either organized into overlapping genes or expressed by alternative splicing mechanisms. The cloning needed to analyze this locus will be enhanced by the very high resolution of the meiotic mapping cross reported here. The recombinational distances on this qkv map were compressed compared with those previously reported in a high-resolution map for qkl-1, an embryonic lethal allele of quaking induced by ethylnitrosourea. Additional crosses confirmed prior reports that the sex and the genetic background of the heterozygous parent can affect recombinational distances. These joint effects on recombination are strong enough to account for the discrepancy between the two maps. This variability of two-factor map values leads to the preferred multilocus map-building protocol discussed in the accompanying paper.

Cloning of the T gene required in mesoderm formation in the mouse.

The murine developmental mutation T identifies an essential gene in mesoderm formation. Embryos lacking normal gene activity fail to form the notochord, the entire posterior region and the allantois, and die at about 10 days of gestation. We have isolated the T gene using a combination of molecular and genetic techniques, thus making molecular tools available to study processes underlying mesoderm formation in the mouse.