Kim I G, McBride O W, Wang M, Kim S Y, Idler W W, Steinert P M
Laboratory of Skin Biology, National Institute of Arthritis and Musculoskeletal and Skin Diseases, National Institutes of Health, Bethesda, Maryland 20892.
J Biol Chem. 1992 Apr 15;267(11):7710-7.
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.
膜相关转谷氨酰胺酶(TGase1)最近被发现普遍存在于哺乳动物细胞中,但尚不清楚这些酶是源自相同还是不同的基因。为了确定该系统的复杂性,我们分离并鉴定了人类基因(TGM1)。发现该基因由14133个碱基对组成,包含15个外显子,由14个内含子剪接而成。有趣的是,与文献中描述的另外两种具有转谷氨酰胺酶样活性的基因相比,这些内含子的位置是保守的,但TGM1基因是迄今为止已鉴定的最小基因,因为其内含子相对较小。另一方面,TGase1酶是已知最大的转谷氨酰胺酶(约90 kDa),显然是因为其基因获得了在其氨基和羧基末端编码额外序列的片段,这些片段赋予了它独特的特性。用几种限制性内切酶切割人类基因组总DNA进行的Southern印迹分析仅显示一条带。使用人-鼠细胞杂交板以及用生物素标记的探针进行染色体原位杂交表明,人类TGM1基因定位于染色体位置14q11.2 - 13。这些数据表明单倍体人类基因组中每个基因有一个拷贝。序列同一性和同源性的比较表明,转谷氨酰胺酶基因家族是通过复制以及随后从共同祖先的趋异进化产生的,但后来分散在人类基因组中。尽管我们目前的Southern印迹和染色体定位研究未发现限制性片段长度多态性,但已发表序列与我们的基因组克隆的比较表明,人群中TGase1存在两种序列变体。罕见的较小变体在5'端附近有一个两核苷酸缺失,使用一个替代起始密码子,并且仅在前15个氨基酸上与常见的较大变体不同。此外,内含子14的DNA序列具有几个二核苷酸重复片段,通过聚合酶链反应分析表明在人群中具有广泛的大小多态性。因此,该基因系统构成了用于遗传连锁分析的有用多态性标记。
