Characterization of the human adenylyl cyclase gene family: cDNA,gene structure,and tissue distribution of the nine isoforms

The membrane-bound adenylyl cyclases (ACs) represent one of the major families of effector enzymes for G protein-coupled receptors. Eight human AC isoforms, encoded by separate genes, have been identified up to now. However, in several cases only partial cDNA sequences are available (ADCY1,2,5). A ninth expected isoform, the human ortholog of rat ADCY4, has not been described yet. Using the high inter-species homology of mammalian AC isoforms, we searched the human genome and we succeeded to identify full-length coding sequences for all enzymes. Where required, missing sequence information was provided experimentally. Analysis of genomic sequences from the Celera database also allowed us to determine the exon-intron boundaries for ADCY1-9 and to establish the gene structures. We found that human AC genes comprise 11 to 26 exons, which are distributed over 16 to 430kb. We further report expression profiles for the nine ACs in a panel of 16 human tissues and in human embryonic kidney (HEK) cells.     

一个抑制AP-1活性的人类新基因AC3-33的克隆和初步功能研究

Activator protein-1(AP-1)是重要的转录因子, 其活性失调与肿瘤等多种疾病直接相关。本文运用“高通量高内涵细胞筛选技术(high throughput-high content cell-based screening technology)”对650个以未知功能基因为主的人类基因进行AP-1双荧光素酶报告基因筛选(Dual-Luciferase reporter gene screening), 获得了一个可抑制佛波酯(PMA)加离子霉素(Inonmycin)诱导的AP-1活性的人类新基因AC3-33(GenBank中该基因名为C3orf33, No. FLJ31139)。生物信息学分析该基因序列全长1 931 bp, 由6 个外显子和5 个内含子组成, 定位于3q25.31, 从271~1026 有一个编码251 个氨基酸的可读框, 编码一个约29 kDa 的蛋白, 在肾上腺和宫颈等多种组织都有表达。AC3-33 与其他人类已知蛋白质没有明显的同源性, 亚细胞定位于细胞质中, 许多氨基酸序列高度保守。初步实验结果显示AC3-33是一个有重要功能的人类新基因。     

CHARACTERIZATION OF THE HUMAN ADENYLYL CYCLASE GENE FAMILY: cDNA,GENE STRUCTURE,AND TISSUE DISTRIBUTION OF THE NINE ISOFORMS

ABSTRACT

The membrane-bound adenylyl cyclases (ACs) represent one of the major families of effector enzymes for G protein-coupled receptors. Eight human AC isoforms, encoded by separate genes, have been identified up to now. However, in several cases only partial cDNA sequences are available (ADCY1,2,5). A ninth expected isoform, the human ortholog of rat ADCY4, has not been described yet. Using the high inter-species homology of mammalian AC isoforms, we searched the human genome and we succeeded to identify full-length coding sequences for all enzymes. Where required, missing sequence information was provided experimentally. Analysis of genomic sequences from the Celera database also allowed us to determine the exon–intron boundaries for ADCY1–9 and to establish the gene structures. We found that human AC genes comprise 11 to 26 exons, which are distributed over 16 to 430?kb. We further report expression profiles for the nine ACs in a panel of 16 human tissues and in human embryonic kidney (HEK) cells.     

Complete Structure of the Human Gc Gene: Differences and Similarities between Members of the Albumin Gene Family

The sequence of the human Gc gene, including 4228 base pairs of the 5′-flanking region and 8514 base pairs of the 3′ flanking region (55,136 in total), was determined from five overlapping λ phage clones. The sequence spans 42,394 base pairs from the cap site to the polyadenylation site, and it reveals that the gene is composed of 13 exons, which are symmetrically placed within the three domains of the Gc protein. The first exon is partially untranslated, as is exon 12, which contains the termination codon TAG. Exon 13 is entirely untranslated, but contains the polyadenylation signal AATAAA. Ten central introns split the coding sequence between codon positions 2 and 3 and between codon positions 3 and 1 in an alternating pattern, exactly as has been observed in the structure of the albumin and α-fetoprotein genes. The Gc gene has several distinctive features which set it apart from the other members of the family. First, the gene is smaller by two exons, which results in a protein some 130 amino acids shorter than albumin or AFP. This decrease in size may result from the loss of two internal exons during the evolutionary history of the Gc gene. Second, exons 6, 8, 9, and 11 are smaller than their counterparts in albumin or AFP by a total of 8 codons (1, 4, 1, and 2, respectively). Although the mRNA and protein expressed from the Gc gene are significantly smaller, the gene itself is about 2.5 times larger than the other genes of the family. There are 13 interspersed DNA repeats within the human Gc gene which are absent from the same positions in the albumin or AFP genes, and hence must have been inserted after the triplication event(s) that gave rise to the gene family. Despite the differences, the Gc gene is nonetheless recognizable as a member of the albumin family.     

Two mRNA species encoding calcium-dependent protein kinases are differentially expressed in sexual organs of Marchantia polymorpha through alternative splicing

In plants, calcium-dependent calmodulin-independent protein kinases (CDPKs) are the predominant calcium-regulated protein kinases and their genes are encoded by a multigene family. A CDPK gene was cloned from a liverwort, Marchantia polymorpha, which showed a high level of sequence similarities to other higher plant CDPK genes. The liverwort CDPK gene consisted of 9 exons and 8 introns. The 6th and 7th exons (Exon 6A and Exon 6B) were almost identical except for 4-amino acid substitutions, both of which coded for EF-hands in the calcium-binding domain. RT-PCR analysis revealed that two species of mature mRNA containing either Exon 6A or Exon 6B were generated from a single CDPK gene by mutually exclusive alternative splicing. Both histidine-tagged fusion proteins derived from cDNAs containing either Exon 6A or Exon 6B exhibited calcium-dependent protein kinase activity in vitro. Preferential accumulation of the mature mRNA with Exon 6A detected in male sexual organ implies possible sexual control of the ratio between the two CDPK isozymes through alternative splicing. Functions and evolution of CDPKs are discussed based on the structure and expression of the liverwort CDPK gene.     

Analysis of the genomic organization of the human cationic amino acid transporters CAT-1, CAT-2 and CAT-4

Summary. By screening nucleotide databases, sequences containing the complete genes of the human cationic amino acid transporters (hCATs) 1, 2 and 4 were identified. Analysis of the genomic organization revealed that hCAT-2 consists of 12 translated exons and most likely of 2 untranslated exons. The splice variants hCAT-2A and hCAT-2B use exon 7 and 6, respectively. The hCAT-2 gene structure is closely related to the structure of hCAT-1, suggesting that they belong to a common gene family. hCAT-4 consists of only 4 translated exons and 3 short introns. Exons of identical size and highly homologous to exon 3 of hCAT-4 are present in hCAT-1 and hCAT-2. Received September 8, 2000 Accepted January 8, 2001     

Localized Na+/H+ exchanger 1 expression protects Ca2+-regulated adenylyl cyclases from changes in intracellular pH

The Ca2+-sensitive adenylyl cyclases (ACs) are exclusively regulated by capacitative Ca2+ entry (CCE) in nonexcitable cells. The present study investigates whether this Ca2+-dependent modulation of AC activity is further regulated by local pH changes that can arise beneath the plasma membrane as a consequence of cellular activity. Ca2+ stimulation of AC8 expressed in HEK 293 cells and inhibition of endogenous AC6 in C6-2B glioma cells exhibited clear sensitivity to modest pH changes in vitro. Acid pH (pH 7.14) reduced the Ca2+ sensitivity of both ACs, whereas alkaline pH (pH 7.85) enhanced the responsiveness of the enzymes to Ca2+, compared with controls (pH 7.50). Surprisingly, in the intact cell, the response of AC8 and AC6 to CCE was largely unperturbed by similar changes in intracellular pH (pH(i)), imposed using a weak acid (propionate) or weak base (trimethylamine). A range of hypotheses were tested to identify the mechanism(s) that could underlie this lack of pH effect in the intact cell. The pH sensitivity of CCE in HEK 293 cells is likely to dampen the effects of pH(i) on Ca2+-regulated ACs and may partly explain the discrepancy between in vitro and in vivo data. However, we have found that the Na+/H+ exchanger (NHE), NHE1, is functionally active in these cells, and like AC8 (and AC6) it resides in lipid rafts or caveolae, which may create cellular microdomains where pH(i) is tightly regulated. An abundance of NHE1 in these cellular subdomains may generate a privileged environment that protects the Ca2+-sensitive ACs and other caveolar proteins from local acid shifts.     

Genomic organization and chromosomal location of the human gene encoding the B-lymphocyte activation antigen B7

The human B lymphocyte activation antigen B7 provides regulatory signals for T lymphocytes as a consequence of binding to its ligands CD28 and CTLA-4. The cDNA for B7 has previously been isolated and predicted to encode a type I membrane protein. The predicted polypeptide has a secretory signal peptide followed by two contiguous Ig-like domains, a hydrophobic transmembrane region and a short cytoplasmic tail. Here we report the exon-intron genomic organization of human B7 and the chromosomal location. The gene has six exons that span approximately 32 kilobases of DNA. Exon 1 is not translated and the second exon contains the initiation ATG codon and encodes a predicted signal peptide. This gene structure is characteristic for several eukaryotic genes with tissue-specific expression. The third and fourth exons correspond to two Ig-like domains whereas the fifth and sixth exons encode respectively the trans-membrane portion and the cytoplasmic tail. This close relationship between exons and functional domains is a characteristic feature of genes of the Ig superfamily. Cell surface expression of the B7 gene product has previously been mapped to human chromosome 12 by antibody reactivity with the B7-specific monoclonal antibody BB-1. We here demonstrate that theB7 gene is located to theq21-qter region of chromosome 3 by DNA blot analysis of human × rodent somatic cell hybrids.The nucleotide sequence data reported in this paper have been submitted to the GenBank nucleotide sequence database and have been assigned the accession numbers M83071-M83075, M83077. Address correspondence and offprint requests to: B. Dupont, Sloan-Kettering Institute for Cancer Research, 1275 York Avenue (Room S709), New York, NY 10021, USA.     

Characterization of the human gene for a polypeptide that acts both as the beta subunit of prolyl 4-hydroxylase and as protein disulfide isomerase

A single polypeptide acts as the beta subunit of prolyl 4-hydroxylase and the enzyme protein disulfide isomerase and may also function as a cellular thyroid hormone binding protein. We report here that the human gene for this polypeptide is about 18 kilobase pairs and consists of 11 exons. The two thioredoxin-like regions are coded by exons 1-2 and 8-9, respectively. The codons for the two presumed active sites of protein disulfide isomerase, each a Cys-Gly-His-Cys sequence, are located 12 base pairs from the beginning of exons 2 and 9. The last 3 amino acids coded by exons 1 and 8 and the first 9 amino acids coded by exons 2 and 9, including a broken codon for Tyr, are identical in the respective exon-intron junctions. These regions are also highly homologous to the active sites of bacterial thioredoxins. The data suggest that evolution of this gene has involved exon shuffling and duplication of a two-exon unit, in which the internal exon-intron junctions have been entirely conserved. The region between exons 1-2 and 8-9 appears to contain other duplications. The 5' flanking sequences contain a TATA box, six CCAAT boxes, and other elements which may be involved in regulation of the cellular amounts of this polypeptide.     

The Rhizobium etli cyaC product: characterization of a novel adenylate cyclase class

Adenylate cyclases (ACs) catalyze the formation of 3',5'-cyclic AMP (cAMP) from ATP. A novel AC-encoding gene, cyaC, was isolated from Rhizobium etli by phenotypic complementation of an Escherichia coli cya mutant. The functionality of the cyaC gene was corroborated by its ability to restore cAMP accumulation in an E. coli cya mutant. Further, overexpression of a malE::cyaC fusion protein allowed the detection of significant AC activity levels in cell extracts of an E. coli cya mutant. CyaC is unrelated to any known AC or to any other protein exhibiting a currently known function. Thus, CyaC represents the first member of a novel class of ACs (class VI). Hypothetical genes of unknown function similar to cyaC have been identified in the genomes of the related bacterial species Mesorhizobium loti, Sinorhizobium meliloti, and Agrobacterium tumefaciens. The cyaC gene is cotranscribed with a gene similar to ohr of Xanthomonas campestris and is expressed only in the presence of organic hydroperoxides. The physiological performance of an R. etli cyaC mutant was indistinguishable from that of the wild-type parent strain both under free-living conditions and during symbiosis.     

Genomic structure, chromosomal localization, and expression pattern of the human LIM-homeobox3 (LHX 3) gene

Lhx3 is a LIM-homeobox protein essential for pituitary development in mice. The human homologue gene spans 7.2 kb and contains 7 exons, including two alternatively spliced first exons. This structure encodes two distinct protein isoforms, LHX3a and LHX3b, that differ exclusively in their amino-terminus. The LHX3 gene was localized at 9q34.2-34.3. The predicted protein sequence is highly homologous to other known Lhx3 proteins, the highest degree of homology being in the conserved domains. The highest expression of LHX3 was found in pituitary gland, spinal cord, and lung. Among different pituitary cell types, corticotrophs appear to express preferentially LHX3b isoform, suggesting a distinct role of the b-form in the development of this cell lineage. Although the human LHX3 gene structure would provide a ground for clarification of the molecular basis of complete anterior pituitary deficiency, we were unable to identify any mutation in the LHX3 gene of 46 such patients.     

Assembling genes from predicted exons in linear time with dynamic programming.

In a number of programs for gene structure prediction in higher eukaryotic genomic sequences, exon prediction is decoupled from gene assembly: a large pool of candidate exons is predicted and scored from features located in the query DNA sequence, and candidate genes are assembled from such a pool as sequences of nonoverlapping frame-compatible exons. Genes are scored as a function of the scores of the assembled exons, and the highest scoring candidate gene is assumed to be the most likely gene encoded by the query DNA sequence. Considering additive gene scoring functions, currently available algorithms to determine such a highest scoring candidate gene run in time proportional to the square of the number of predicted exons. Here, we present an algorithm whose running time grows only linearly with the size of the set of predicted exons. Polynomial algorithms rely on the fact that, while scanning the set of predicted exons, the highest scoring gene ending in a given exon can be obtained by appending the exon to the highest scoring among the highest scoring genes ending at each compatible preceding exon. The algorithm here relies on the simple fact that such highest scoring gene can be stored and updated. This requires scanning the set of predicted exons simultaneously by increasing acceptor and donor position. On the other hand, the algorithm described here does not assume an underlying gene structure model. Indeed, the definition of valid gene structures is externally defined in the so-called Gene Model. The Gene Model specifies simply which gene features are allowed immediately upstream which other gene features in valid gene structures. This allows for great flexibility in formulating the gene identification problem. In particular it allows for multiple-gene two-strand predictions and for considering gene features other than coding exons (such as promoter elements) in valid gene structures.