Structure and expression of a cluster of human hematopoietic serine protease genes found on chromosome 14q11.2

We previously identified a cluster of hematopoietic serine protease genes on chromosome 14 at band q11.2. This cluster contains the cathepsin G gene and the two related cathepsin G-like genes CGL-1 and CGL-2. The CGL-1 gene is identical with the cytotoxic T cell serine protease CSP-B (also called SECT, and in mice, CCP1, granzyme B, or CTLA-1). In this report, we determined that CGL-2 is identical with a recently described gene called h-CCPX. The coding sequences of CG, CGL-1, and CGL-2 are 65-75% identical at the DNA level. The intervening sequences are much less conserved, except for introns 3 of the CGL-1 and CGL-2 genes, which are 93% identical. Each of the genes has the same overall organization, with 5 exons and 4 introns, very short 5' untranslated regions, and identical splice phases for all of the introns. Cathepsin G is expressed at high levels in promyelocytes/promonocytes, and CGL-1/CSP-B is expressed at high levels in activated cytolytic T cells, lymphokine-activated killer (LAK), and natural killer (NK) cells. CGL-2/h-CCPX is expressed at much lower levels in activated peripheral blood lymphocytes, LAK and NK cells. To begin to define the regulatory elements that target expression of each of these genes to their specific lineages at specific times, the 5' flanking region of each gene was sequenced. The 5' flanking regions are minimally related and have few conserved consensus elements. Further experiments will be required to determine the critical cis-acting regulatory sequences required for tissue- and development-specific expression of each of these genes.     

Characterization of the gene for prostate-specific antigen, a human glandular kallikrein

The gene for the human glandular kallikrein, prostate-specific antigen, has been cloned. The sequence of 7130 nucleotides encompassing the gene and 633 bp of 5' and 639 bp of 3' flanking DNA has been determined. The translation initiation site was slightly heterogeneous, yielding 5' non-translated leader sequences of 41 and 35 bp. The gene is divided into five exons, with introns located at positions identical with those found in other glandular kallikrein genes. The nucleotide sequence is very similar to that of the human kallikrein gene hGK-1, with 76 to 93% of the nucleotides being identical in the exons and 76 to 87% in the introns. The similarity also extends approximately 200 bp into the sequence flanking the 5' end of hGK-1 and several other, both human and rodent, glandular kallikrein genes.     

Characterization of the gene encoding mouse mast cell protease 8 (mMCP-8), and a comparative analysis of hematopoietic serine protease genes

Serine proteases are important granule constituents in several of the major hematopoietic cell lineages. We present here the nucleotide sequence of the gene encoding mouse mast cell protease 8 (mMCP-8). mMCP-8 was initially isolated as a cDNA from a mouse mast cell line, but has recently been found to be expressed primarily by mouse basophils. mMCP-8 and its rat homologues, rMCP-8, -9, and -10, form a new group of mast cell/basophil proteases, which are more closely related to the T-cell granzymes and neutrophil cathepsin G than to the mast cell tryptases and chymases. A dot matrix comparison of the mMCP-8 gene with other closely related hematopoietic serine protease genes shows detectable homology only in the exonic regions of the genes. No indication for conservation in the promoter region or introns was observed. This latter finding indicates that the upstream regulatory region has evolved at a relatively high rate. However, despite the low degree of direct sequence conservation, no major differences in the sizes of introns or exons were observed between mMCP-8 and genes for the closest related hematopoietic serine proteases, the mouse T-cell granzymes and cathepsin G, indicating that after evolutionary separation from the T-cell granzymes and cathepsin G, the majority of mutations primarily involved single base pair substitutions or short insertions or deletions.     

The Human Mast Cell Chymase Gene (CMA1): Mapping to the Cathepsin G/Granzyme Gene Cluster and Lineage-Restricted Expression

Genes encoding T-cell-receptor α/δ chains, neutrophil cathepsin G, and lymphocyte CGL/granzymes are closely linked on chromosomal band 14q11.2. The current work identifies the human mast cell chymase gene (CMA1) as the fourth protease in this cluster and maps the gene to within 150 kb of the cathepsin G gene. The gene order is centromere-T cell receptor α/δ-CGL-1/granzyme B-CGL-2/granzyme H-cathepsin G-chymase. Chymase and cathepsin G genes are shown to be cotranscribed in the human mast cell line HMC-1 and in U-937 cells. Other cells transcribe cathepsin G or CGL/granzyme genes, but not chymase genes, suggesting a capacity for independent regulation. Comparison of the 5′ flank of the chymase gene with those of cathepsin G and CGL/granzymes reveals little overall homology. Only short regions of the 5′ flanks of the human and murine chymase genes sequenced to date are similar, suggesting that they are more distantly related than human and rodent CGL-1/granzyme B, the flanks of which are highly homologous. The expression patterns and clustering of genes provide possible clues to the presence of locus control regions that orchestrate lineage-restricted expression of leukocyte and mast cell proteases.     

Isolation and complete nucleotide sequence of the gene for bovine parathyroid hormone

The structure of the bovine parathyroid hormone (PTH) gene has been analyzed by Southern blot hybridization of genomic DNA and by nucleotide sequence analysis of a cloned PTH gene. In the Southern analysis, several restriction enzymes produced single fragments that hybridized to PTH cDNA suggesting that there is a single bovine PTH gene. The restriction map of the cloned gene is the same as that determined by Southern blot analysis of bovine DNA. The sequence of 3154 bp of the cloned gene has been determined including 510 bp and 139 bp in the 5' and 3' flanking regions, respectively. The gene contains two introns which separate three exons that code primarily for: (i) the 5' untranslated region, (ii) the pre-sequence of preProPTH, and (iii) PTH and the 3' untranslated region. The gene contains 68% A + T and unusually long stretches of 100- to 150-bp sequences containing alternating A and T nucleotides in the 5' flanking region and intron A. The 5' flanking region contains two TATA sequences, both of which appear to be functional as determined by S1 nuclease mapping. Compared to the rat and human genes, the locations of the introns are identical but the sizes differ. Comparable human and bovine sequences in the flanking regions and introns are about 80% homologous.     

Isolation and complete structure of the lymphocyte serine protease granzyme G, a novel member of the granzyme multigene family in murine cytolytic T lymphocytes. Evolutionary origin of lymphocyte proteases

A cDNA clone that is closely related to the granule-associated serine proteases of cytolytic T lymphocytes (CTL), called granzymes A-F, was isolated from a CTL expression library. The encoded serine protease, granzyme G, shows 70%-89% nucleotide identities to the granzymes C-F and, like those, consists of 228 amino acids preceded by the short propeptide Glu-Glu and a 18 residue long signal peptide. Granzyme G was identified by amino-terminal sequence analysis as a correctly processed and sorted protein stored in lysosome-like granules. The phylogenetic history of the granzyme multigene family was reconstructed by two tree-making methods and by Southern blot analyses of human, rat, and mouse DNA. Our results indicate differences in the evolutionary pathway between these species. The murine granzymes C-G descended from a progenitor present at the time of mammalian radiation. Granzyme C branched off first after the primate-rodent split and was involved in a recombination event with granzyme B before the rat-mouse divergence. Granzymes D and E have diverged after the mouse-rat speciation. However, no experimental evidence for the existence of a granzyme C-D-E-F-G equivalent was found in humans, and loss of the ancestral gene in the primate lineage is discussed. In view of the species differences in the number of granzyme gene copies during recent evolution, we propose that the murine granzymes B-G play several distinct roles in CTL-mediated effector functions as a response to quite recent changes of the biochemical environment.     

Organization of the gene encoding the mouse T-cell-specific serine proteinase "granzyme A".

The mouse serine protease granzyme A is a member of a closely related family of T-cell-associated proteolytic enzymes, designated granzymes A-G. Previous studies have indicated that granzymes A and B are involved in various T-cell-mediated processes. Here we report the genomic organization of the granzyme A gene. We have cloned a 15-kb DNA fragment from a genomic library of a cloned CD8+ T-cell line and sequenced the exon-intron boundaries. The gene consists of five exons, and its genomic organization is very similar to that described for granzymes B, C, and F. In addition, we have sequenced 1.4 kb of the 5'-region and 1.1 kb of the 3'-region flanking the granzyme A gene. Putative promoter and enhancer elements were identified by sequence comparison with known consensus sequences. Some of these regulatory elements seem to be associated exclusively with granzyme A, whereas others are shared by members of the granzyme family.     

The structure of the human apolipoprotein C-II gene. Electron microscopic analysis of RNA:DNA hybrids, complete nucleotide sequence, and identification of 5' homologous sequences among apolipoprotein genes

Cloned human apo-C-II cDNA was used as a hybridization probe to identify the human apo-C-II gene in a genomic library constructed in our laboratory. The isolated apo-C-II DNA was studied both by electron microscopy and by direct sequence analysis. Ultrastructural morphological analysis of RNA-DNA hybrids revealed that the apo-C-II gene had complex structures because of regions of inverted complementary sequences in and around the gene forming stem-and-loop structures which interfere with the formation of stable RNA:DNA hybrids. Extensive morphological analysis revealed a minimum of 3 intervening sequences (IVS), and their lengths were measured. Direct sequence analysis of the cloned gene confirmed the presence of 3 IVS. There are 4 Alu type sequences in IVS-I. We sequenced 4340 nucleotides which include 545 nucleotides in the 5' flanking region, the entire gene which spans 3320 nucleotides, and 475 nucleotides in the 3' flanking region which also encompasses an additional Alu sequence. The 5' end of the gene was identified by primer extension and sequencing of the primer extended cDNA. Apo-C-II mRNA structure was deduced from the cDNA sequence, the primer extension experiments, and the genomic sequence. It is 494 nucleotides in length. Its sequence differs from previously published sequences in that there are 7 additional nucleotides before the polyadenylate tail. In the 5' flanking region, nucleotides -234 to -213 encompass a GC-rich region which exhibits high homology (greater than 70%) to the 5' flanking regions of the genes of all the apolipoproteins published to date, namely, apo-A-II (-497 to -471), apo-A-I (approximately -196 to -179), apo-E (-409 to -391), and apo-C-III (approximately -116 to -103). This highly conserved region might represent some evolutionarily conserved sequences from these related genes and/or might represent a region with regulatory function.     

Nucleotide sequence of the gene for human factor IX (antihemophilic factor B)

Two different human genomic DNA libraries were screened for the gene for blood coagulation factor IX by employing a cDNA for the human protein as a hybridization probe. Five overlapping lambda phages were identified that contained the gene for factor IX. The complete DNA sequence of about 38 kilobases for the gene and the adjacent 5' and 3' flanking regions was established by the dideoxy chain termination and chemical degradation methods. The gene contained about 33.5 kilobases of DNA, including seven introns and eight exons within the coding and 3' noncoding regions of the gene. The eight exons code for a prepro leader sequence and 415 amino acids that make up the mature protein circulating in plasma. The intervening sequences range in size from 188 to 9473 nucleotides and contain four Alu repetitive sequences, including one in intron A and three in intron F. A fifth Alu repetitive sequence was found immediately flanking the 3' end of the gene. A 50 base pair insert in intron A was found in a clone from one of the genomic libraries but was absent in clones from the other library. Intron A as well as the 3' noncoding region of the gene also contained alternating purine-pyrimidine sequences that provide potential left-handed helical DNA or Z-DNA structures for the gene. KpnI repetitive sequences were identified in intron D and the region flanking the 5' end of the gene. The 5' flanking region also contained a 1.9-kb HindIII subfamily repeat. The seven introns in the gene for factor IX were located in essentially the same position as the seven introns in the gene for human protein C, while the first three were found in positions identical with those in the gene for human prothrombin.     

The human alpha-fetoprotein gene. Sequence organization and the 5' flanking region

The human alpha-fetoprotein (AFP) gene was isolated into three overlapping clones in bacteriophage lambda vectors and its sequence organization analyzed by restriction endonuclease mapping and nucleotide sequencing. The human AFP gene is about 20 kilobase pairs long and contains 15 exons and 14 introns. The overall organization of the human AFP gene is similar to that of the mouse AFP gene, with all but two exons showing identical sizes. Nucleotide sequences at all exon/intron junctions display similarity to the consensus boundary sequence (Breathnach, R., and Chambon, P. (1981) Annu. Rev. Biochem. 50, 349-383), with the GT-AG rule applied to the splicing point. The cap site maps 44 nucleotides upstream from the translation initiation site. The "TATA box" is located 27 nucleotides upstream from the putative cap site and is flanked by sequences with dyad symmetry. The TATA box can thus be placed in the loop portion of a possible stem-loop structure formed by intrastrand base-pairing. Other characteristic nucleotide sequences in the 5' flanking region include a CCAAC pentamer, a 14-base pair (bp) enhancer-like sequence, and a 9-bp sequence homologous to the glucocorticoid responsive element. A long (90 bp) direct repeat and several alternating purine/pyrimidine sequences are also present in the 5' flanking region. A 736-bp sequence of the 5' flanking region adjacent to the cap site of the human AFP gene shows a 61% similarity with the corresponding region of the mouse AFP gene. There are two Alu family sequences and two poly(dT-dG) repeats in the human AFP gene that show different distribution patterns from those in the mouse AFP gene.