Mouse albino-deletions: from genetics to genes in development.

Six essential genes located near the mouse albino locus have been identified as required during specific periods of development. Amongst these six, each is required either during the preimplantation stages of development, at specific times during gastrulation, within 12 hrs after birth or during juvenile development. These genes were identified as a result of extensive genetic complementation analysis using embryos homozygous for the albino deletions. Although, in principal, the associated developmental abnormalities could result from loss of multiple genes, the deletion phenotype in one case is identical to that induced by chemical mutagenesis. These results indicate that the abnormalities observed in deletion homozygotes may result from single gene loss. The deletions have proven useful not only as genetic tools to localize the position of the genes, but also as molecular entry points to the regions containing these genes. The current methodology being used to isolate candidate genes from the albino region is also reviewed here.

Genomic mapping within the albino-deletion complex using individual early postimplantation mouse embryos.

Sensitive methods for analysis of DNA from limited amounts of tissue are often difficult, error prone, and time consuming. Here, we describe a procedure for molecular analysis of individual early postimplantation mouse embryos by Southern analysis. The procedure involves embedding single embryos in agarose before lysing and deproteinizing in situ. The embedded DNA can be digested with restriction enzymes and analyzed by standard Southern-blotting procedures. The procedure is sensitive enough to detect single-copy sequences in embryos as early as day 6.5 of development. We have used the technique to genotype embryos homozygous for an embryonic lethal deletion. Normally, the lethal phenotype associated with such mutations is identified by a retrospective statistical analysis of abnormal embryos produced from a heterozygous cross as compared to those produced from a control cross. Now, if associated with a detectable DNA abnormality, the mutant embryo can be genotyped directly. We also report the use of this method for mapping cloned markers relative to deletion breakpoints. This approach can save considerable time since mapping would conventionally be done using restriction fragment length polymorphisms (RFLPs) detected in Mus musculus/Mus spretus interspecies hybrids. Using this procedure, we have been able to redefine the distal limits of the region of Chromosome (Chr) 7 containing a gene (eed) needed for development of the embryonic ectoderm.

The albino-deletion complex of the mouse: molecular mapping of deletion breakpoints that define regions necessary for development of the embryonic and extraembryonic ectoderm.

Previous complementation analyses with five (c11DSD, c5FR60Hg, c2YPSj, c4FR60Hd, c6H) of the mouse albino deletions defined at least two genes on chromosome 7, known as eed and exed, which are necessary for development of the embryonic and extraembryonic ectoderm, respectively, of early postimplantation embryos. The region of chromosome 7 containing these two genes has now been accessed at the molecular level by cloning two of the deletion breakpoint-fusion fragments. The c2YPSj breakpoints were isolated by cloning an EcoRI fragment containing a copy of an albino region-specific repeat unique to c2YPSj DNA. Similarly, the c11DSD breakpoints were isolated by cloning a c11DSD EcoRI fragment detected by a unique-sequence probe mapping proximal to the albino-coat-color locus. By mapping the cloned breakpoints relative to the remaining three deletions, the c11DSD distal breakpoint was found to define the distal limit of the region containing eed, whereas the c2YPSj and c6H distal breakpoints were found to define the proximal and distal limits, respectively, of the region containing exed.

Molecular mapping of albino deletions associated with early embryonic lethality in the mouse.

The albino-deletion complex consists of more than 37 deletions that remove an area of mouse chromosome 7 including the albino coat-color locus. Previous genetic and embryological studies with five of these deletions (C11DSD, c5FR60Hg, c4FR60Hd, c2YPSj, c6H) defined at least two genes required for normal development of the embryonic and extraembryonic ectoderm of early postimplantation embryos. A molecular genetic analysis of this region has been initiated using palb18, a genomic clone that defines the D7TM18 locus that maps to a region of chromosome 7 removed by the c11DSD deletion but not by the c5FR60Hg, c4FR60Hd, c2YPSj, or c6H deletions. palb18 was obtained by chromosomal microdissection and microcloning of the wild-type albino region. A genomic clone isolated with palb18 contains a repeat sequence localized primarily to the proximal region of the five deletions. The repeat sequence hybridizes differentially to the five deletion DNAs. The patterns of hybridization associated with these DNAs were used to define the order of the proximal breakpoints as centromere-c11DSD-c2YPSj-(c5FR60Hg-c4FR60Hd)- c6H. This order was confirmed by isolation of additional single-copy sequences. The molecular probes described here should allow for identification and isolation of the deletion breakpoints and thus provide immediate access to the distal side of the deletions where the genes affecting the development of the embryonic and extraembryonic ectoderm are located.

A naturally occurring deletion in the mouse Hbbs beta-globin gene cluster.

A restriction fragment size difference of 1.9 kilobases exists between the C57BL/10 (Hbbs) and BALB/c (Hbbd) beta-globin gene clusters in the vicinity of the Hbb-y and Hbb-bh0 genes. This length difference is the result of a deletion that removes the majority of the C57BL/10 Hbb-bh0 gene. The Hbb-bh0 deletion appears to be widespread among Hbbs-carrying mice. In addition to the deletion, 119 base pairs of DNA of unknown origin are found in C57BL/10 DNA at the point of discontinuity. The existence of this deletion is inconsistent with reports of transcripts homologous to the third exon of the Hbb-bh0 gene in both C57BL/10 embryos and in a cell line carrying the Hbbs haplotype. We propose that the Hbb-bh0 gene is a recently disabled pseudogene.