Candidate gene associated with a mutation causing recessive polycystic kidney disease in mice.

A line of transgenic mice was generated that contains an insertional mutation causing a phenotype similar to human autosomal recessive polycystic kidney disease. Homozygotes displayed a complex phenotype that included bilateral polycystic kidneys and an unusual liver lesion. The mutant locus was cloned and characterized through use of the transgene as a molecular marker. Additionally, a candidate polycystic kidney disease (PKD) gene was identified whose structure and expression are directly associated with the mutant locus. A complementary DNA derived from this gene predicted a peptide containing a motif that was originally identified in several genes involved in cell cycle control.

Molecular and phenotypic characterization of a new mouse insertional mutation that causes a defect in the distal vertebrae of the spine.

We have identified and characterized the phenotype of a new insertional mutation in one line of transgenic mice. Mice carrying this mutation, which we have designated TgN(Imusd)370Rpw, display undulations of the vertebrae giving rise to a novel kinky-tail phenotype. Molecular characterization of the insertion site indicates that the transgene integration has occurred without any substantial alterations in the structure of the host sequences. Using probes that flank the insertion site, we have mapped the mutation to chromosome 5 near the semidominant mutation, thick tail (Tht). Thick tail does not complement the TgN(Imusd)370Rpw mutation; compound mutants containing one copy of each mutation display a more severe phenotype than either mutation individually.

cDNA cloning, mapping and expression of the mouse propionyl CoA carboxylase beta (pccb), the gene for human type II propionic acidaemia.

Propionyl CoA carboxylase (PCC) is a mitochondrial, biotin-dependent enzyme involved in the catabolism of amino acids, odd-chained fatty acids and other metabolites. PCC is composed of two equal subunits, alpha and beta, which are encoded by two separate genes at two distinct human loci. Mutations of either gene in humans results in propionic acidemia (PA). To identify the mouse cDNA for the propionyl CoA carboxylase beta-subunit (pccb), we have screened the mouse EST database using the human sequence. The murine mRNA transcript is approximately 2.3 kb, nearly 500 bps larger than the human approximately 1.8 kb transcript. A PAC genomic DNA clone from the mouse was also isolated and used to generate probes and PCR primers for mapping the pccb locus in the mouse. Both the C57Bl/6JEi and Spret/Ei alleles for regions flanking the pccb gene were sequenced to identify RFLPs. The Jackson Laboratory BSS and BSB backcross panel DNAs were then analyzed using a DdeI polymorphism placing the pccb locus on mouse chromosome 9. Northern blots of adult tissue show that the pccb gene is broadly expressed in the mouse. The approximately 2.3 kb transcript is most abundantly expressed in the kidney, liver, small intestine and stomach tissues.

Characterization of the lung Krüppel-like transcription factor gene and upstream regulatory elements.

We previously described the isolation and characterization of the cDNA for lung Krüppel-like factor (LKLF), a zinc finger transcription factor that is predominately expressed in the lung of adult mice. In this study, we report the complete structure and nucleotide sequence of the mouse LKLF gene, which is comprised of three exons and two small introns. Moreover, the identification of critical sequence elements required for expression is described using reporter constructs with the LKLF promoter transfected into LA-4 lung cells. Results from these constructs reveal an important region for transcriptional activity that lies between the -490/-72bp upstream sequence. This region contains two canonical Sp1 binding sites that affect expression levels in a non tissue-specific manner. In addition, using a base-pair mutagenesis strategy, a region from -157/-72bp was found to be necessary for upregulating expression. In transfection assays, mutations of the -138/-111bp region resulted in approximately 70-80% loss of promoter activity. This cis-element does not appear to correspond to any known transcription factor consensus sequence. Moreover, mutations within this cis-region disrupt the binding of a protein complex from nuclear extracts of various tissues.

Scanning tunneling microscopy of DNA: a novel technique using radiolabeled DNA to evaluate chemically mediated attachment of DNA to surfaces.

pBS+ plasmid deoxyribonucleic acid (DNA) was imaged by scanning tunneling microscopy (STM) after mounting microdroplets by aerosol deposition onto heated epitaxial gold surfaces. However, the instability of the adsorbate to forces exerted by the tunneling tip points out the need for more aggressive bonding of molecules to surfaces. We describe a sensitive assay for the qualitative and quantitative evaluation of chemical agents to influence binding of DNA to surfaces using 32P-labeled pBS+ plasmid DNA. We propose that such an assay can make an important contribution to immobilization techniques prior to STM imaging.

The thick tail mutation contains anomalies of the axial skeleton.

Analysis of the skeletal effects of thick tail (Tht), a radiation-induced mutation, has revealed numerous anomalies in the axial skeleton. The affected regions include the atlantal-occipital region as well as the lumbar (Lu) and caudal (Ca) vertebrae in which the ossified adult structures are either missing or reduced in size. Skeletons of juvenile Tht heterozygotes exhibit a malformed occipital bone, atlas, smaller Ca vertebrae, and delayed ossification of the affected adult structures. The diminished amount of cartilage and bone suggests that the Tht gene may be functioning during the formation of these tissues.

Haploinsufficient phenotypes in Bmp4 heterozygous null mice and modification by mutations in Gli3 and Alx4.

Bone morphogenetic protein 4 (Bmp4), a vertebrate homolog of Drosophila decapentaplegic (dpp), encodes a signaling protein with multiple functions during embryogenesis. Most mouse embryos homozygous for the Bmp4(tm1blh) null allele die around the time of gastrulation, with little or no mesoderm. Two independently derived Bmp4(tm1) mutations were backcrossed onto the C57BL/6 genetic background. Several independently expressed, incompletely penetrant abnormalities were observed in heterozygotes, including cystic kidney, craniofacial malformations, microphthalmia, and preaxial polydactyly of the right hindlimb. In addition, heterozygotes were consistently underrepresented at weaning. These results indicate that Bmp4 gene dosage is essential for the normal development of a variety of organs and for neonatal viability. Two mutations that enhance the penetrance and expressivity of the polydactylous phenotype were identified: Gli3(XtJ), a deletion mutation involving a gene encoding a zinc-finger protein related to Drosophila cubitus interruptus, and Alx4(tm1rwm), a targeted null mutation in a gene encoding a paired class homeoprotein related to Drosophila aristaless. All double Bmp4(tm1); Gli3(XtJ) heterozygotes have extensive anterior digit abnormalities of both fore- and hindlimbs, while all double Bmp4(tm1); Alx4(tm1) heterozygotes display ectopic anterior digits only on the hindlimbs. These genetic interactions suggest a model for the multigenic control of anterior digit patterning during vertebrate limb development.

Atomic force microscopy of DNA on mica and chemically modified mica.

Atomic force microscopy (AFM) was used to image circular DNA adsorbed on freshly cleaved mica and mica chemically modified with Mg(II), Co(II), La(III), and Zr(IV). Images obtained on unmodified mica show coiling of DNA due to forces involved during the drying process. The coiling or super twisting appeared to be right handed and the extent of super twisting could be controlled by the drying conditions. Images of DNA observed on chemically modified surfaces show isolated open circular DNA that is free from super twisting, presumably due to strong binding of DNA on chemically modified surfaces.

Immobilization of DNA for scanning probe microscopy.

Reproducible scanning tunneling microscope and atomic force microscope images of entire molecules of uncoated plasmid DNA chemically bound to surfaces are presented. The chemically mediated immobilization of DNA to surfaces and subsequent scanning tunneling microscope imaging of DNA molecules demonstrate that the problem of molecular instability to forces exerted by the probe tip, inherent with scanning probe microscopes, can be prevented.

Characterization of the human homologue of the mouse Tg737 candidate polycystic kidney disease gene.

We previously identified a gene from the mutant locus in a new mouse mutation that causes recessive polycystic kidney disease. Here we describe the cloning, characterization and mapping of the homologous human gene. The human and mouse genes are 95% identical at the predicted amino acid sequence level, and both genes encode a putative protein that contains a tetratricopeptide repeat motif. The human gene, called hTg737, is expressed with a broad tissue distribution that includes the the kidney and liver, and gives rise to a 2.9 kb mRNA. The gene contains 26 exons and spans a genomic region greater than 100 kb. Chromosome mapping experiments revealed that the hTg737 gene maps near the centromere on the long arm of human chromosome 13, at position 13q12.1. While this gene does not map to the primary locus that has been identified for ARPKD in humans, it may represent a candidate gene for other recessive renal disorders that have yet to be mapped.

Sequence analysis of the human hTg737 gene and its polymorphic sites in patients with autosomal recessive polycystic kidney disease.

DNA sequence analysis of the human Tg737 gene was performed in 36 patients with the autosomal recessive form of polycystic kidney disease (ARPKD). Coding exons and their adjacent splice sites were screened for mutations. Pathogenic exon or splice region mutations were not identified although one exonic and two intronic polymorphic sites were discovered. These results are in agreement with another study that has recently reported linkage to Chromosome (Chr) 6p21-cen in a set of 16 ARPKD families. STS mapping has localized the gene to a YAC contig that includes D13S175 on chromosome 13q12.1. The polymorphisms found in the htG737 gene will permit its future evaluation as a candidate gene for other recessive cystic renal diseases and as a modifier gene in human PKD.

Novel strategy yields candidate Gsh-1 homeobox gene targets using hypothalamus progenitor cell lines.

We describe the successful application of a strategy that potentially provides for an efficient and universal screen for downstream gene targets. We used the promoter of the Gsh-1 homeobox gene to drive expression of the SV40 T-antigen gene in transgenic mice. We have previously shown that the Gsh-1 homeobox gene is expressed in discrete domains of the ganglionic eminences, diencephalon, and hindbrain during brain development. Gsh-1-SV40 T transgenic mice showed cellular hyperplasia in regions of the brain coincident with Gsh-1 expression. The Gsh-1-SV40 T transgene was introduced, by breeding, into Gsh-1 homozygous mutant mice, and Gsh-1 -/- cell lines were made. Clonal cell lines were generated and analyzed by Northern blot hybridizations and Affymetrix GeneChip probe arrays to determine gene expression profiles. The results indicate that the cell lines remain representative of early developmental stages. Further, immunocytochemistry showed uniformly high levels of nestin expression, typical of central nervous system progenitor cells, and the absence of terminal differentiation markers of neuronal cells. One clonal cell line, No. 14, was then stably transfected with a tet-inducible Gsh-1 expression construct and subcloned. The starting clone 14, together with the uninduced and induced subclones, provided cell populations with varying levels of Gsh-1 expression. Differential display and Affymetrix GeneChip probe arrays were then used to identify transcript differences that represent candidate Gsh-1 target genes. Of particular interest, the drm and gas1 genes, which repress cell proliferation, were observed to be activated in Gsh-1-expressing cells. These observations support models predicting that homeobox genes function in the regulation of cell proliferation.