Candida tropicalis Etr1p and Saccharomyces cerevisiae Ybr026p (Mrf1'p), 2-enoyl thioester reductases essential for mitochondrial respiratory competence.

We report here on the identification and characterization of novel 2-enoyl thioester reductases of fatty acid metabolism, Etr1p from Candida tropicalis and its homolog Ybr026p (Mrf1'p) from Saccharomyces cerevisiae. Overexpression of these proteins in S. cerevisiae led to the development of significantly enlarged mitochondria, whereas deletion of the S. cerevisiae YBR026c gene resulted in rudimentary mitochondria with decreased contents of cytochromes and a respiration-deficient phenotype. Immunolocalization and in vivo targeting experiments showed these proteins to be predominantly mitochondrial. Mitochondrial targeting was essential for complementation of the mutant phenotype, since targeting of the reductases to other subcellular locations failed to reestablish respiratory growth. The mutant phenotype was also complemented by a mitochondrially targeted FabI protein from Escherichia coli. FabI represents a nonhomologous 2-enoyl-acyl carrier protein reductase that participates in the last step of the type II fatty acid synthesis. This indicated that 2-enoyl thioester reductase activity was critical for the mitochondrial function. We conclude that Etr1p and Ybr026p are novel 2-enoyl thioester reductases required for respiration and the maintenance of the mitochondrial compartment, putatively acting in mitochondrial synthesis of fatty acids.

Differential expression of mouse laminin gamma2 and gamma2* chain transcripts.

Laminins are large heterotrimeric basement membrane proteins that consist of alpha, beta, and gamma chains. We have previously shown that the human gamma2 and gamma2* transcripts result from the alternative use of the LAMC2 gene 3'-end exons. To explore the biological significance of the alternative gamma2 transcripts, we isolated the cDNA coding for the mouse laminin gamma2* transcript, characterized the 3'-end of the murine LAMC2 gene, and studied the expression of alternative gamma2 transcripts in several mouse tissues. The sequence reported here is the first one containing a full-length gamma2* 3'-UTR from any species. The mouse gamma2* transcript is 4110 bases and encodes a putative polypeptide of 1110 amino acids. This polypeptide lacks the C-terminal cysteine residue thought to be important for heterotrimer formation. The mouse gamma2* transcript was found to be expressed in several tissues by polymerase chain reaction (PCR), but at very low levels. The clearest signals were obtained on embryonic day 7, and in heart and testis of adult tissues. When the laminin gamma2* transcript expression pattern was compared with that of the gamma2 chain, a similar tissue distribution was observed. There was, however, a significant difference in expression levels. The longer gamma2 transcript was found to be much more abundant than the shorter gamma2* variant. Moreover, by whole-mount in situ hybridization, the shorter gamma2* form was localized in the mesenchyme of the developing kidney whereas the longer gamma2 form was exclusively present in the epithelium of the Wolffian (nephric) duct and ureteric bud. The results indicate different functions for the gamma2 variants.

Laminin gamma2 expression is developmentally regulated during murine tooth morphogenesis and is intense in ameloblasts.

Mutations in the laminin gamma2 gene cause junctional epidermolysis bullosa, and enamel hypoplasias are frequently seen in these patients. Laminin gamma2 is one of the three polypeptide chains forming the basement membrane glycoprotein laminin-5. We have localized the expression of the laminin gamma2 gene by in situ hybridization during mouse tooth development from early morphogenesis to completion of crown development. The expression was restricted to epithelial cells. During the early morphogenesis of the tooth germ, laminin gamma2 was expressed by the outer dental epithelium and by the stellate reticulum cells. No expression was detected in the cells of the inner dental epithelium giving rise to ameloblasts. The pre-ameloblasts remained negative during the early bell stage, but, interestingly, expression was very prominently upregulated as the cells differentiated into ameloblasts. This upregulation appeared to coincide with the start of enamel matrix secretion. The ameloblasts expressed laminin gamma2 intensely throughout the period of active enamel deposition. The expression continued at a lower level in the maturation-stage ameloblasts covering the enamel surface. Immunolocalization of laminin-5 with polyclonal antibodies indicated that the protein formed a continuous lining at the basal surfaces of the cells expressing the laminin gamma2 transcripts. We suggest that the role of laminin-5 during enamel formation may be to strengthen the anchorage of the ameloblasts to the enamel matrix, and that the pathogenesis of enamel hypoplasias in cases of laminin-5 mutations could be associated with detachment of the ameloblast cell layer from the enamel surface.

The epithelium-tooth interface--a basal lamina rich in laminin-5 and lacking other known laminin isoforms.

The attachment of the marginal gingiva to the tooth surface is mediated by a thin nonkeratinized epithelium termed the junctional epithelium (JE). Ultrastructural studies have revealed that the attachment of the JE to the tooth surface occurs through hemidesmosomes (HD) and a basal lamina-like extracellular matrix termed the internal basal lamina (IBL). We have previously shown that neither type IV collagen nor prototypic laminin, two common components of basement membranes (BM), is present in the IBL between the epithelium and the tooth. In the present study, we show that laminin-5 is a major component of the IBL in both rodent and human tissues. By using in situ hybridization, we also show that the cells of the JE express the LAMC2 gene of laminin-5. In other parts of gingival epithelium, LAMC2 gene expression is less prominent. Our results indicate that the epithelium-tooth interface is a unique structure wherein epithelial cells are induced to secrete a basal lamina containing laminin-5 and no other presently known laminin isoform.

Detection of novel LAMC2 mutations in Herlitz junctional epidermolysis Bullosa.

BACKGROUND: Laminin 5, an anchoring filament attachment protein within the lamina lucida of the basement membrane zone involved in the pathogenesis of junctional epidermolysis bullosa (JEB), consists of three polypeptide subunits, the alpha 3, beta 3, and gamma 2 chains which are encoded by the LAMA3, LAMB3, and LAMC2 genes, respectively. To facilitate identification of pathogenetic mutations in LAMC2, a strategy based on direct amplification of genomic DNA by PCR or mRNA by RT-PCR, followed by heteroduplex analysis of the PCR products, was developed. MATERIALS AND METHODS: Primer pairs for amplification of the complete cDNA as well as the 23 individual exons in the genomic DNA, which encode the entire gamma 2 chain of laminin 5, were established. The primers for amplification of exons from genomic DNA were positioned at least 24 bp away from the intron-exon borders in the flanking intronic sequences. For amplification of cDNA generated by RT-PCR, eight primer pairs covering overlapping segments of the entire coding sequence of LAMC2 mRNA were used. The amplified sequences were scanned for pathogenetic mutations and sequence variations in JEB patients and unrelated control individuals by heteroduplex analysis by means of conformation sensitive gel electrophoresis (CSGE). RESULTS: Utilizing the strategy developed in this study, we identified pathogenetic mutations in three patients with the Herlitz (lethal) variant of JEB, and eight intragenic normal polymorphisms, which are useful for linkage analysis, in the LAMC2 gene. CONCLUSIONS: The methodology described in this study is capable of detecting single-base substitutions or small insertions and deletions in the LAMC2 gene. Demonstration of mutations in this gene in JEB patients further emphasizes the role of laminin 5 in providing integrity to the cutaneous basement membrane zone.

Structure of the human laminin gamma 2 chain gene (LAMC2): alternative splicing with different tissue distribution of two transcripts.

We have determined the structure of the human laminin gamma 2 chain gene (LAMC2), which is mutated in some patients with junctional epidermolysis bullosa. Eight lambda phage clones isolated from a genomic library and three subgenomic lambda phage clones made from a plasmid artificial chromosome clone spanned 75 kb, including the 55-kb gene. The LAMC2 gene contains 23 exons and is structurally highly homologous with the 28-exon LAMC1 gene (Kallunki et al., 1991, J. Biol. Chem. 266: 221-228), with 16 exons having identical sizes in the two genes. The gene analysis demonstrated that two previously described different size gamma 2 chain cDNAs (Kallunki et al., 1992, J. Cell Biol. 119: 679-693) are the result of alternative splicing. The longer gamma 2 chain is formed by using the coding sequence of the last exon 23, while the shorter gamma 2* chain is formed by using only 22 exons, together with part of the 5' end of intron 22. The two mRNAs were shown to have different expression patterns in 17-week-old human embryonic tissues, with the longer gamma 2 chain transcript strongly expressed in epithelia of all tissues studied, while distinct expression of the shorter gamma 2* chain mRNA was observed only in the cerebral cortex, in lung, and in distal tubules of the kidney.

Mutations in the gamma 2 chain gene (LAMC2) of kalinin/laminin 5 in the junctional forms of epidermolysis bullosa.

Junctional epidermolysis bullosa (JEB) is an autosomal recessive disorder characterized by blister formation within the dermal-epidermal basement membrane. Genes for the lamina lucida protein, kalinin/laminin 5, have been proposed as candidates for some forms of JEB, based on immunofluorescence analysis recognizing kalinin epitopes. We studied the cDNA of laminin gamma 2 chain for mutations in JEB using heteroduplex analysis. One patient showed a homozygous splice site mutation while another was heterozygous for a deletion-insertion, resulting in a premature termination codon in one allele. Our data implicate mutations in the laminin gamma 2 chain gene (LAMC2) in some forms of JEB.