The murine genes Hox-5.1 and Hox-4.1 belong to the same HOX complex on chromosome 2

Localized and transient transcription of Hox genes suggests a link between patterning and the segmentation clock

During development, Hox gene transcription is activated in presomitic mesoderm with a time sequence that follows the order of the genes along the chromosome. Here, we show that Hoxd1 and other Hox genes display dynamic stripes of expression within presomitic mesoderm. The underlying transcriptional bursts may reflect the mechanism that coordinates Hox gene activation with somitogenesis. This mechanism appears to depend upon Notch signaling, as mice deficient for RBPJk, the effector of the Notch pathway, showed severely reduced Hoxd gene expression in presomitic mesoderm. These results suggest a molecular link between Hox gene activation and the segmentation clock. Such a linkage would efficiently keep in phase the production of novel segments with their morphological specification.

Differential gene expression of mammalian SPO11/TOP6A homologs during meiosis

As the initiator of DNA double-strand breaks during meiosis in Saccharomyces cerevisiae, the SPO11 protein is essential for recombination. Similarity between SPO11 and archaebacterial TOP6A proteins points to evolutionary specialization of a DNA cleavage function for meiotic recombination. To determine whether this extends to mammals, we isolated and characterized mouse and human SPO11 cDNAs. Mammalian SPO11 genes were found to be expressed at high levels only in testis, wherein mouse Spo11 transcript is restricted primarily to meiotic germ cells and is maximally expressed at midpachynema. Mouse Spo11 is located near the distal end of chromosome 2, while human SPO11 is found in the homologous position of chromosome 20q13.2-13.3, a region that is amplified in some breast cancers. Sequence homology and differential expression together support a highly conserved role for SPO11 in the enzymatic cleavage of DNA that accompanies meiotic recombination.

A new mouse insertional mutation that causes sensorineural deafness and vestibular defects

This article describes a new recessive insertional mutation in the transgenic line TgN2742Rpw that causes deafness and circling behavior in mice. Histologic analysis revealed virtually complete loss of the cochlear neuroepithelium (the organ of Corti) in adult mutant mice. In association with the neuroepithelial changes, there is a dramatic reduction of the cochlear nerve supply. Adult mutants also show morphological defects of the vestibular apparatus, including degeneration of the saccular neuroepithelium and occasional malformation of utricular otoconia. Audiometric evaluations demonstrated that the mice displaying the circling phenotype are completely deaf. Molecular analysis of this mutant line revealed that the transgenic insertion occurred without creating a large deletion of the host DNA sequences. The mutant locus was mapped to a region on mouse chromosome 10, where other spontaneous, recessive mutations causing deafness in mice have been mapped.

Molecular cloning of a novel mouse gene with predominant muscle and neural expression

Because numerous diseases affect the muscle and nervous systems, it is important to identify and characterize genes that may play functional roles in these tissues. Sequence analysis of a 106-kb region of human Chromosome (Chr) 19q13.2 revealed a novel gene with homology to the Neuroendocrine-specific protein (NSP), and it has, therefore, been designated NSP-like 1 (Nspl1). We isolated the mouse homolog of this gene and performed extensive expression analysis of both the mouse and human genes. The mouse Nspl1 gene is alternatively spliced to produce two major transcripts: a 2.1-kb mRNA that is expressed at highest levels in the brain, and a 1.2-kb transcript that is primarily expressed in muscle. The larger message contains 10 exons, whereas the smaller transcript contains 7 exons. The last 6 exons, which are present in both transcripts, share significant amino acid sequence identity with the endoplasmic reticulum-bound portion of NSP. Mouse and human Nspl1/NSPL1 genes have expression patterns that are similar to that of the dystrophin gene. In addition, the putative regulatory domains of Nspl1 appear similar in composition and distribution to the defined dystrophin regulatory sequences.

Mutations in the Cacnl1a4 calcium channel gene are associated with seizures, cerebellar degeneration, and ataxia in tottering and leaner mutant mice

Tottering and leaner, two mutations of the mouse tottering locus, have been studied extensively as models for human epilepsy. Here we describe the isolation, mapping, and expression analysis of Cacnl1a4, a gene encoding the alpha subunit of a proposed P-type calcium channel, and also report the physical mapping and expression patterns of the orthologous human gene. DNA sequencing and gene expression data demonstrate that Cacnl1a4 mutations are the primary cause of seizures and ataxia in tottering and leaner mutant mice, and suggest that tottering locus mutations and human diseases, episodic ataxia 2 and familial hemiplegic migraine, represent mutations in mouse and human versions of the same channel-encoding gene.

Sequence and expression of the murine Hoxd-3 homeobox gene

Murine Hoxd-3 (Hox 4.1) genomic DNA and cDNA and Hoxa-3 (Hox 1.5) cDNA were cloned and sequenced. The homeodomains of Hoxd-3 and Hoxa-3 and regions before and after the homeodomain are highly conserved. Both Hoxa-3 and Hoxa-3 proteins have a proline-rich region that contains consensus amino acid sequences for binding to Src homology 3 domains of some signal transduction proteins. Northern blot analysis of RNA from 8- to 11-day-old mouse embryos revealed a 4.3-kb species of Hoxd-3 RNA, whereas a less abundant 3.0-kb species of Hoxd-3 RNA was found in RNA from 9- to 11-day-old embryos. Two species of Hoxd-3 poly(A)+ RNA, 4.3 and 6.0 kb in length, were found in poly(A)+ RNA from adult mouse kidney, but not in RNA from other adult tissues tested. Hoxd-3 mRNA was detected by in situ hybridization in 12-, 14-, and 17-day-old mouse embryos in the posterior half of the myelencephalon, spinal cord, dorsal root ganglia, first cervical vertebra, thyroid gland, kidney tubules, esophagus, stomach, and intestines.

Checklist: vertebrate homeobox genes

Up to now around 170 different homeobox genes have been cloned from vertebrate genomes. A compilation of the various isolates from mouse, chick, frog, fish and man is presented in the form of a concise checklist, including the designations from the original publications. Putative homologs from different species are aligned, and key characteristics of embryonic or adult expression domains, as well as mutant phenotypes are briefly indicated.

Analysis of the Hoxd-3 gene: structure and localization of its sense and natural antisense transcripts

This study set out to investigate the structure and localized expression of the mouse homeobox-containing gene Hoxd-3. In addition to identifying a transcript of the type known from other Antennapedia (Antp)-like mammalian homeobox cDNAs, an antisense transcript was also detected. The antisense form of Hoxd-3 overlaps with 603 bp of the sense transcript including the homeobox. Active antisense transcription has been confirmed by RNA blot analysis with single-stranded probes and by the direction of splicing of an intron in the antisense transcript. The localized expression of sense and antisense transcripts was compared by in situ hybridization. Hoxd-3 expression was observed from 8.5 days p.c., in the neural tube with a sharp border in the hind brain at the level of rhombomeres 4-5. In contrast, the earliest antisense expression was detected at 10.5 days p.c. in cDNA libraries. At 12.5 days p.c., sense and antisense transcripts colocalized in the liver. The possible role of antisense homeobox transcripts during liver and the hematopoietic development is discussed.

The nucleotide sequence of the murine Hox-D3 (Hox-4.1) gene reveals extensive identity with the human protein

We report the sequence of the murine Hox-D3 gene, formerly referred to as Hox-4, Hox-4.1 and Hox-4A. This gene is located on murine chromosome 2 in the Hox-D complex. The predicted Hox-D3 protein comprises 417 amino acids and displays 95% identity to the human protein. We have demonstrated that Hox-D3 is expressed in the skin, kidney and thymus, but not in lung, liver, spleen or stomach.

Isolation and analysis of embryonic expression of Hox-4.9, a member of the murine labial-like gene family

Two members of the murine labial (lab) subfamily of Antennapedia-like homeobox-containing genes, Hox-1.6 and Hox-2.9, have been identified previously. Here we describe a third member genetically linked to the Hox-4 cluster on chromosome 2. This gene, designated Hox-4.9, is similar in structure to the other lab subfamily members. However, little coding sequence other than the homeobox and sequences immediately upstream of it have been conserved. By in situ hybridization analysis, Hox-4.9 mRNA is first detected at the end of the late streak stage (E7.75) in presumptive lateral and extraembryonic mesoderm. During early neurogenesis (E8.0-8.5), Hox-4.9 is detected solely in lateral mesoderm; its lack of expression in somitic mesoderm and the neural tube makes it unique among the Hox genes. By late neurogenesis and through mid-gestation (E9.0-E11.5), Hox-4.9 is no longer detected in lateral mesoderm but is found instead in a restricted region of presumed trunk neural crest and in the dermatome. These data are discussed in comparison with what is known about expression of the other members of the lab subfamily.

Disruption of the Hox-1.6 homeobox gene results in defects in a region corresponding to its rostral domain of expression

The Hox-1.6 gene disrupted in embryonic stem cells by homologous recombination was introduced into the mouse germline. Heterozygous mice were normal, but homozygous mice died at birth from anoxia and had numerous defects that were centered at the level of rhombomeres 4 to 7 and included delayed hindbrain neural tube closure, absence of certain cranial nerves and ganglia, and malformed inner ears and bones of the skull. Thus, Hox-1.6 is involved in regional specification along the rostrocaudal axis, but only in its most rostral domain of expression. Hox-1.6 appears to specify neurogenic neural crest cells prior to specification of mesenchymal neural crest cells by Hox-1.5. Thus, within the same region of the presumptive hindbrain, two HOX-1 genes are involved in the patterning of two different populations of neural crest cells. The implication of these results for the function of the Hox network during mouse embryogenesis is discussed.