Epidermal type I transglutaminase (TGM1) is assigned to human chromosome 14.

Human epidermal type I transglutaminase coexists in keratinocytes with another cross-linking enzyme, tissue type II transglutaminase. There are at least five different forms of the enzyme in mammals. Gene mapping studies allowed us to determine whether the different transglutaminases are products of the same gene or separate genes. The gene encoding factor XIII subunit a transglutaminase (F13A1) was previously assigned to human chromosome 6, p24----p25. We demonstrate using somatic cell hybrids that the human epidermal type I transglutaminase gene (gene symbol is designated TGM1) is located on human chromosome 14, providing evidence that at least two human transglutaminases are encoded by separate genes.     

Organization and chromosomal mapping of mouse Gh/tissue transglutaminase gene (Tgm2).

The mouse Gh/tissue transglutaminase gene (Tgm2), coding a dual-function protein that both binds guanosine triphosphate (GTP) and catalyzes the posttranslational modification of proteins by transamidation of glutamine residues, has been cloned. Sequence analysis of Tgm2 and comparison with the TGase sequences of other species allowed correction of several apparent sequencing artifacts in the Tgm2 cDNA. Tgm2 spans approximately 34 kb and has 13 exons and 12 introns. Although the structure of Tgm2 shows similarity to that of other transglutaminase genes, with introns ranging from 921 bp to >5 kb, several introns differ considerably in size from those of the human Gh gene, TGM2. Tgm2 maps to the distal region of mouse chromosome 2, a region syntenic to human chromosome 20q containing TGM2. Tgm2 is in the vicinity of two uncloned mouse mutations, diminutive (dm) and blind-sterile (bs). Genomic DNA from dm mice was unavailable; however, Southern blot analysis of bs DNA showed no gross rearrangements of Tgm2.     

DNA sequence and physical mapping of the canine transglutaminase 1 gene

The transglutaminase 1 gene (TGM1) encodes an enzyme necessary for cross-linking the structural proteins that form the cornified envelope, an essential component of the outermost layer of the skin, the stratum corneum. Reported here is the complete coding region of canine TGM1, its chromosome localization, and its map position in the integrated canine linkage-radiation hybrid map. Canine TGM1 consists of 2,448 nucleotides distributed over 15 exons. The nucleotide sequence has 90% identity to human TGM1. The deduced canine TGM1 protein is 816 amino acids long and is 92% identical to human TGM1. Using fluorescence in situ hybridization, we localized canine TGM1 to dog (Canis familiaris) chromosome 8 (CFA 8q). Canine TGM1 localized to CFA 8 on the integrated linkage-radiation hybrid map in the interval FH2149-MYH7. Characterizing the coding region of canine TGM1 is a first step in examining the role of this enzyme in normal and defective cornification in the dog.     

Structure and organization of the human transglutaminase 1 gene.

Membrane-associated transglutaminases (TGase1) have recently been found to be common in mammalian cells, but it is not clear whether these derive from the same or different genes. In order to determine the complexity of this system, we have isolated and characterized the human gene (TGM1). The gene of 14,133 base pairs was found to contain 15 exons spliced by 14 introns. Interestingly, the positions of these introns have been conserved in comparison with the genes of two other transglutaminase-like activities described in the literature, but the TGM1 gene is by far the smallest characterized to date because its introns are relatively smaller. On the other hand, the TGase1 enzyme is the largest known transglutaminase (about 90 kDa), apparently because its gene acquired tracts that encode additional sequences on its amino and carboxyl termini that confer its unique properties. Southern blot analyses of total human genomic DNA cut with several restriction enzymes reveal only one band. Use of human-rodent cell hybrid panels and chromosomal in situ hybridization with biotin-labeled probes revealed that the human TGM1 gene maps to chromosome position 14q11.2-13. Such data suggest there is a single gene copy per haploid human genome. Comparisons of sequence identities and homologies indicate that the transglutaminase family of genes arose by duplications and subsequent divergent evolution from a common ancestor but later became scattered in the human genome. Although our present Southern blot and chromosomal localization studies revealed no restriction fragment length polymorphisms, comparisons of published sequences and our genomic clone indicate there are two sequence variants for TGase1 within the human population. The rare smaller variant contains a two-nucleotide deletion near the 5'-end, uses an alternate initiation codon, and differs from the common larger variant only in the first 15 amino acids. Furthermore, the DNA sequences of intron 14 possess several tracts of dinucleotide repeats that by polymerase chain reaction analysis show wide size polymorphism within the human population. Accordingly, this gene system constitutes a useful polymorphic marker for genetic linkage analyses.     

Construction of a 1.2-Mb BAC/PAC contig of the porcine gene RYR1 region on SSC 6q1.2 and comparative analysis with HSA 19q13.13

We screened a porcine bacterial artificial chromosome (BAC) and a P1 derived artificial chromosome (PAC) library to construct a sequence-ready approximately 1.2-Mb BAC/PAC contig of the ryanodine receptor-1 gene (RYR1) region on porcine chromosome (SSC) 6q1.2. This genomic segment is of special interest because it harbors the locus for stress susceptibility in pigs and a putative quantitative trait locus for muscle growth. Detailed physical mapping of this gene-rich region allowed us to assign to this contig 17 porcine genes orthologous to known human chromosome 19 genes. Apart from the relatively well-characterized porcine gene RYR1, the other 16 genes represent novel chromosomal assignments and 14 genes have been cloned for the first time in pig. Comparative analysis of the porcine BAC/PAC contig with the human chromosome (HSA) 19q13.13 map revealed a completely conserved gene order of this segment between pig and human. A detailed porcine-human-mouse comparative map of this region was constructed.     

Divergent human and mouse orthologs of a novel gene (WBSCR15/Wbscr15) reside within the genomic interval commonly deleted in Williams syndrome

Williams syndrome (WS) is a contiguous gene deletion disorder resulting in complex and intriguing clinical features. Detailed molecular characterization studies of the genomic segment on human chromosome 7q11.23 commonly deleted in WS have uncovered numerous genes, each of which is being actively studied for its possible role in the etiology of the syndrome. Our efforts have focused on the comparative mapping and sequencing of the WS region in human and mouse. In previous studies, we uncovered important differences in the long-range organization of these human and mouse genomic regions; in particular, the notable absence of large duplicated blocks of DNA in mouse that are present in human. Aided by available genomic sequence data, we have used a combination of gene-prediction programs and cDNA isolation to identify the human and mouse orthologs of a novel gene (WBSCR15 and Wbscr15, respectively) residing within the genomic segment commonly deleted in WS. Unlike the flanking genes, which are closely related in human and mouse, WBSCR15 and Wbscr15 are strikingly different with respect to their cDNA and corresponding protein sequences as well as tissue-expression pattern. Neither the WBSCR15- nor Wbscr15-encoded amino acid sequence shows a statistically significant similarity to any characterized protein. These findings reveal another interesting evolutionary difference between the human and mouse WS regions and provide an additional candidate gene to evaluate with respect to its possible role in the pathogenesis of WS.     

Linkage of autosomal recessive lamellar ichthyosis to chromosome 14q.

We have mapped the locus for lamellar ichthyosis (LI), an autosomal recessive skin disease characterized by abnormal cornification of the epidermis. Analysis using both inbred and outbred families manifesting severe LI showed complete linkage to several markers within a 9.3-cM region on chromosome 14q11. Affected individuals in inbred families were also found to have striking homozygosity for markers in this region. Linkage-based genetic counseling and prenatal diagnosis is now available for informative at-risk families. Several transcribed genes have been mapped to the chromosome 14 region containing the LI gene. The transglutaminase 1 gene (TGM1), which encodes one of the enzymes responsible for cross-linking epidermal proteins during formation of the stratum corneum, maps to this interval. The TGM1 locus was completely linked to LI (Z = 9.11), suggesting that TGM1 is a good candidate for further investigation of this disorder. The genes for four serine proteases also map to this region but are expressed only in hematopoietic or mast cells, making them less likely candidates.     

Isolation and characterization of a novel human gene (HFB30) which encodes a protein with a RING finger motif.

A human cDNA, HFB30, encoding a novel protein that contains a RING finger (C3HC4-type zinc finger) motif was isolated. This cDNA clone consists of 3056 nucleotides and encodes an open reading frame of a 474 amino acid protein. From RT-PCR analysis, the messenger RNA was ubiquitously expressed in various human tissues. The gene was located to the chromosome 5q23.3-q31.1 region by PCR-based analyses with both a human/rodent monochromosomal hybrid cell panel and a radiation hybrid mapping panel. Furthermore, the gene consists of nine exons that span about 20 kb of genome DNA.     

Molecular cloning and characterization of a novel human gene (NESCA) which encodes a putative adapter protein containing SH3

A full-length cDNA encoding a novel protein was isolated and sequenced from a human placental cDNA library. This cDNA consists of 1990 bp and has a predicted open reading frame encoding 433 amino acids. It possesses an Src homology 3 (SH3) motif, a leucine zipper motif and no catalytic domain, suggesting that it seems to be an adapter protein. PCR-based mapping with both a monochromosomal hybrid panel and radiation hybrid cell panels placed the gene to human chromosome 1q21-22.     

A homozygous missense mutation in TGM5 abolishes epidermal transglutaminase 5 activity and causes acral peeling skin syndrome

Peeling skin syndrome is an autosomal recessive genodermatosis characterized by the shedding of the outer epidermis. In the acral form, the dorsa of the hands and feet are predominantly affected. Ultrastructural analysis has revealed tissue separation at the junction between the granular cells and the stratum corneum in the outer epidermis. Genomewide linkage analysis in a consanguineous Dutch kindred mapped the gene to 15q15.2 in the interval between markers D15S1040 and D15S1016. Two homozygous missense mutations, T109M and G113C, were found in TGM5, which encodes transglutaminase 5 (TG5), in all affected persons in two unrelated families. The mutation was present on the same haplotype in both kindreds, indicating a probable ancestral mutation. TG5 is strongly expressed in the epidermal granular cells, where it cross-links a variety of structural proteins in the terminal differentiation of the epidermis to form the cornified cell envelope. An established, in vitro, biochemical cross-linking assay revealed that, although T109M is not pathogenic, G113C completely abolishes TG5 activity. Three-dimensional modeling of TG5 showed that G113C lies close to the catalytic domain, and, furthermore, that this glycine residue is conserved in all known transglutaminases, which is consistent with pathogenicity. Other families with more-widespread peeling skin phenotypes lacked TGM5 mutations. This study identifies the first causative gene in this heterogeneous group of skin disorders and demonstrates that the protein cross-linking function performed by TG5 is vital for maintaining cell-cell adhesion between the outermost layers of the epidermis.     

Spinocerebellar ataxia type 35 (SCA35)-associated transglutaminase 6 mutants sensitize cells to apoptosis

Spinocerebellar ataxia type 35 (SCA35) is an autosomal dominant neurodegenerative disorder. In our previous study, using exome sequencing and linkage analysis, two missense mutations of the transglutaminase 6 (TGM6) gene were identified as causative for SCA35. TGM6 encodes transglutaminase 6 (TG6), a member of the transglutaminase family of enzymes that catalyze the formation of a covalent bond between a free amine group and the γ-carboxamide group of protein- or peptide-bound glutamine. However, the precise role of TG6 in contributing to SCA35 remains unclear. In this study, we analyzed the subcellular distribution, expression and in vitro activity of two missense mutations of TG6 (D327G, L517W) and found that both mutants exhibited decreased transglutaminase activity and stability. Furthermore, overexpressing the TG6 mutants sensitized cells to staurosporine-induced apoptosis by increasing the activity of caspases. We propose that the pro-apoptotic role of these mutants might underlie the pathogenesis of SCA35.     

Genetic and immunohistochemical detection of mutations inactivating the keratinocyte transglutaminase in patients with lamellar ichthyosis

Autosomal recessive lamellar ichthyosis is a clinically heterogeneous group of severe congenital keratinization disorders that is characterized by generalized hyperkeratosis and variable erythema. About half of the patients have mutations in the TGM1 gene, which encodes the keratinocyte transglutaminase. Linkage studies have shown that at least two further loci for autosomal recessive lamellar ichthyosis must exist. We present here two patients with lamellar ichthyosis caused by mutations in the TGM1 gene. The first patient is compound heterozygous for the novel missense mutation C53S and the splice mutation A3447G. The second patient, a child of consanguineous parents from Tunisia, is homozygous for the unknown nonsense mutation W263X. This is the first report of a mutation, C53S, that affects the region of the keratinocyte transglutaminase that is essential for anchorage of the enzyme to the plasma membrane. A novel, rapid in situ transglutaminase activity assay revealed the absence of keratinocyte transglutaminase activity in both patients. The mutations described are hence causative for the ichthyosis phenotype. Received: 27 October 1997 / Accepted: 24 November 1997