Transcription regulatory elements of the first intron control human transglutaminase type I gene expression in epidermal keratinocytes.

Expression of the transglutaminase type1 gene (TGM1), which encodes an epithelial cell-specific protein cross-linking enzyme, is limited to particular stages of epidermal development and keratinocyte differentiation. As a result, transglutaminase type 1 (TGase1) enzyme activity in epidermal cells increases with the onset of keratinization in vivo and in vitro. We determined, by functional mapping of deletion mutations in the TGM1 5' untranslated region, that an element in first intron of the human TGM1 gene, in addition to the 5' proximal promoter, initiates transcription and upregulates transcriptional activity. These two transcription control elements function interdependently to regulate the expression of the human TGM1 gene in keratinocytes. We also identified distinct regulatory elements that cooperatively modify the 5' proximal and intron 1 promoter activities in response to environmental variations in retinoic acid and calcium ion concentrations. In conclusion, we report that TGM1 differential gene expression is controlled by two distinct elements, proximal and intronic, which function cooperatively to initiate and modulate TGM1 gene transcription in response to regulatory signals. We propose that in nonexpressing cells these regulatory signals repress a default mechanism that operates in their absence. The specificity of their function is integrated into the default mechanism and consists of the tissue-, developmental-, and differentiation-specific interplay of 5' URR and intron 1 elements tuned to physiological status.

Organization and evolution of the human epidermal keratinocyte transglutaminase I gene.

Transglutaminases (TGases; protein-glutamine:amine gamma-glutamyltransferase, EC 2.3.2.13) are calcium-dependent crosslinking enzymes that modify proteins posttranslationally. Several distinct types of TGases have been identified, which appear to be encoded by a family of closely related genes. We isolated the gene encoding human keratinocyte-specific type I TGase (TGase I) and characterized its chromosomal organization. The TGase I gene consists of 15 exons separated by 14 introns and exhibits a restriction fragment length polymorphism. Exons appear to encode functional and/or structural domains: exon I and part of exon XV encode untranslated regions, whereas exons VII and XI contain the active site and a presumptive calcium-binding domain, respectively. Interestingly, exon VI of TGase I contains a consensus Arg-Gly-Asp tripeptide sequence whose presence suggests an intriguing extracellular function for the enzyme. We present a likely phylogenetic tree for seven known members of the TGase family based on amino acid sequence similarity. Arguments presented suggest that the active enzyme evolved first and the structural human erythrocyte membrane protein 4.2 (band 4.2) has undergone a rapid change in amino acid sequence. It follows that band 4.2 evolved from the type II TGases, whereas factor XIII subunit a evolved from the type I group.

Inhibition of human epidermal transglutaminases in vitro and in vivo by tyrosinamidomethyl dihydrohaloisoxazoles.

Tyrosinamidomethyl dihydrohaloisoxazoles (THX) irreversibly inhibit isolated epidermal transglutaminases and ionophore-induced cell envelope formation in malignant human keratinocytes. In cultured human foreskin keratinocytes cultured in 10(-5) M THX for 5 days, soluble and particulate transglutaminases were inhibited by 90% and 44-51%, respectively. Spontaneous cell envelope formation was inhibited up to 54%. When THX-treated keratinocytes were simultaneously incubated with 10(-5) M retinoic acid (RA), there was enhanced inhibition of cell envelope formation compared to either agent alone. The inhibitors were equally effective in keratinocytes incubated with fetal calf serum or delipidized serum. After THX was applied to normal human thoracic skin in vivo for 9 d, the soluble and particulate transglutaminases isolated from suction blister epidermis were inhibited 30% and 40%, respectively. THX may be effective in inhibiting both soluble and particulate transglutaminase activity in disorders with increased transglutaminase activity.