Two Novel Human Members of an Emerging Mammalian Gene Family Related to Mono-ADP-Ribosylating Bacterial Toxins

Mono-ADP-ribosylation is one of the posttranslational protein modifications regulating cellular metabolism, e.g., nitrogen fixation, in prokaryotes. Several bacterial toxins mono-ADP-ribosylate and inactivate specific proteins in their animal hosts. Recently, two mammalian GPI-anchored cell surface enzymes with similar activities were cloned (designated ART1 and ART2). We have now identified six related expressed sequence tags (ESTs) in the public database and cloned the two novel human genes from which these are derived (designatedART3andART4). The deduced amino acid sequences of the predicted gene products show 28% sequence identity to one another and 32–41% identity vs the muscle and T cell enzymes. They contain signal peptide sequences characteristic of GPI anchorage. Southern Zoo blot analyses suggest the presence of related genes in other mammalian species. By PCR screening of somatic cell hybrids and byin situhybridization, we have mapped the two genes to human chromosomes 4p14–p15.1 and 12q13.2–q13.3. Northern blot analyses show that these genes are specifically expressed in testis and spleen, respectively. Comparison of genomic and cDNA sequences reveals a conserved exon/intron structure, with an unusually large exon encoding the predicted mature membrane proteins. Secondary structure prediction analyses indicate conserved motifs and amino acid residues consistent with a common ancestry of this emerging mammalian enzyme family and bacterial mono(ADP-ribosyl)transferases. It is possible that the four human gene family members identified so far represent the “tip of an iceberg,” i.e., a larger family of enzymes that influences the function of target proteins via mono-ADP-ribosylation.     

Human Indolethylamine N-Methyltransferase: cDNA Cloning and Expression, Gene Cloning, and Chromosomal Localization

Indolethylamine N-methyltransferase (INMT) catalyzes the N-methylation of tryptamine and structurally related compounds. We recently cloned and characterized the rabbit INMT cDNA and gene as a step toward cloning the cDNA and gene for this enzyme in humans. We have now used a PCR-based approach to clone a human INMT cDNA that had a 792-bp open reading frame that encoded a 263-amino-acid protein 88% identical in sequence to rabbit INMT. Northern blot analysis of 35 tissues showed that a 2.7-kb INMT mRNA species was expressed in most tissues. When the cDNA was expressed in COS-1 cells, the recombinant enzyme catalyzed the methylation of tryptamine with an apparent K_m value of 2.9 mM. The human cDNA was then used to clone the human INMT gene from a human genomic BAC library. The gene was 5471 bp in length, consisted of three exons, and was structurally similar to the rabbit INMT gene as well as genes for nicotinamide N-methyltransferase and phenylethanolamine N-methyltransferase in several species. All INMT exon–intron splice junctions conformed to the “GT-AG” rule, and no canonical TATA or CAAT sequences were present within the 5′-flanking region of the gene. Human INMT mapped to chromosome 7p15.2–p15.3 on the basis of both PCR analysis and fluorescence in situ hybridization. Finally, two possible single nucleotide polymorphisms were identified within exon 3, both of which altered the encoded amino acid. The cloning and expression of a human INMT cDNA, as well as the cloning, structural characterization, and mapping of its gene represent steps toward future studies of the function and regulation of this methyltransferase enzyme in humans.     

Gibberellin Biosynthetic Pathway inGibberella fujikuroi:Evidence for a Gene Cluster

Differential screening of aGibberella fujikuroicDNA library was used to successfully clone and identify genes involved in the pathway of gibberellin biosynthesis. Several cDNA clones that hybridized preferentially to a cDNA probe prepared from mycelium induced for gibberellin production were isolated and characterized. The deduced amino acid sequences of two (identical) clones contained the conserved heme-binding motif of cytochrome P450 monooxygenases (FXXGXXXCXG). One of these cDNA fragments was used as a homologous probe for the screening of a genomic library. A hybridizing 6.7-kb genomicSalI fragment was cloned into pUC19. The sequencing of this clone revealed that a second cytochrome P450 monooxygenase gene was closely linked to the first one. Since at least four cytochrome P450 monooxygenase-catalyzed steps are involved in the synthesis of gibberellins, chromosome walking was performed to find a further gene of this family or other genes involved in gibberellin pathway. Next to the two P450 monooxygenase genes, a putative geranylgeranyl diphosphate synthase gene, the copalyl diphosphate synthase gene, which is the first specific gene of the gibberellin pathway, and a third P450 monooxygenase gene were identified. These results suggest that at least some of the genes involved in the biosynthesis of gibberellins are closely linked in a gene cluster inG. fujikuroi,as has been recently found for other “dispensable” pathways in fungi.     

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.     

Assignment of the βB1 Crystallin Gene (CRYBB1) to Human Chromosome 22 and Mouse Chromosome 5

By using primers complementary to the rat βB1 crystallin gene sequence, we amplified exons 5 and 6 of the orthologous human gene (CRYBB1). The amplified human segments displayed greater than 88% sequence homology to the corresponding rat and bovine sequences.CRYBB1was assigned to the group 5 region in 22q11.2–q12.1 by hybridizing the exon 6 PCR product to somatic cell hybrids containing defined portions of human chromosome 22. The exon 5 and exon 6 PCR products ofCRYBB1were used to localize, by interspecific backcross mapping, the mouse gene (Crybb1) to the central portion of chromosome 5. Three other β crystallin genes (βB2(−1), βB3, and βA4) have previously been mapped to the same regions in human and mouse. We demonstrate that the βB1 and βA4 crystallin genes are very closely linked in the two species. These assignments complete the mapping and identification of the human and mouse homologues of the major β crystallins genes that are expressed in the bovine lens.     

Characterization of Three Novel Human Cadherin Genes (CDH7, CDH19, and CDH20) Clustered on Chromosome 18q22–q23 and with High Homology to Chicken Cadherin-7

Full-length coding sequences of two novel human cadherin cDNAs were obtained by sequence analysis of several EST clones and 5′ and 3′ rapid amplification of cDNA ends (RACE) products. Exons for a third cDNA sequence were identified in a public-domain human genomic sequence, and the coding sequence was completed by 3′ RACE. One of the sequences (CDH7L1, HGMW-approved gene symbol CDH7) is so similar to chicken cadherin-7 gene that we consider it to be the human orthologue. In contrast, the published partial sequence of human cadherin-7 is identical to our second cadherin sequence (CDH7L2), for which we propose CDH19 as the new name. The third sequence (CDH7L3, HGMW-approved gene symbol CDH20) is almost identical to the mouse “cadherin-7” cDNA. According to phylogenetic analysis, this mouse cadherin-7 and its here presented human homologue are most likely the orthologues of Xenopus F-cadherin. These novel human genes, CDH7, CDH19, and CDH20, are localized on chromosome 18q22–q23, distal of both the gene CDH2 (18q11) encoding N-cadherin and the locus of the six desmosomal cadherin genes (18q12). Based on genetic linkage maps, this genomic region is close to the region to which Paget's disease was linked. Interestingly, the expression patterns of these three closely related cadherins are strikingly different.     

Cloning and Characterization of a Novel Member of the Human Mad Gene Family (MADH6)

MAD (mothers against decapentaplegic)-related proteins (MADRs) are intracellular components that play critical roles in signal-transduction pathways involving the transforming growth factor β (TGFβ) superfamily. Some Mad genes are candidates for tumor-suppressor functions. From a human fetal brain cDNA library we have isolated a novel Mad-related gene. Two alternatively transcribed mRNAs encode deduced 430- and 467-amino-acid peptides that showed high levels of similarity to MADR1/Smad1/hMAD1 (about 80% identity at the amino acid level). This gene, which we designated MADH6, resides on 13q12–q14 between BRCA2 and RB, a region that frequently displays loss of heterozygosity in breast, liver, and prostate cancers.     

Identification and Characterization of Human cDNAs Specific to BCS1, PET112, SCO1, COX15, and COX11, Five Genes Involved in the Formation and Function of the Mitochondrial Respiratory Chain

We have successfully applied a strategy based on the “cyberscreening” of the expressed sequence tags database using yeast protein sequences as “probes” to identify the human gene orthologs to BCS1, COX15, PET112, COX11, and SCO1, five yeast genes involved in the biogenesis of the mitochondrial respiratory chain complexes. In yeast, BCS1 is involved mainly in the assembly of complex III, while the other genes appear to control the structure/function of cytochrome-coxidase. Significant amino acid identity and similarity were demonstrated by comparison of the human with the corresponding yeast polypeptides. Sequence alignment revealed numerous colinear identical regions and the conservation of functional domains. Mitochondrial targeting of the human gene products, suggested by computer analysis of the protein sequences, was confirmed by anin vitroimport and protease-protection assay. These data strongly suggest that the human gene products share similar or identical functions with their yeast homologues. Genes controlling the structure/function of the respiratory chain complexes are attractive candidates for human mitochondrial disorders such as Leigh disease. However, both sequence analysis and functional complementation assays on an index patient do not support an etiological role for any of these genes.     

Characterization of an HSP70 Cognate Gene Family in Arabidopsis

Analysis of the polypeptide composition of extracts from heat-shocked leaves of Arabidopsis indicated the presence of at least 12 HSP70-related polypeptides, most of which were constitutively expressed. In vitro translation of mRNA from heat-shocked and control leaves indicated that the amount of mRNA encoding four HSP70 polypeptides was increased strongly by heat-shock. Three Arabidopsis genes which exhibit homology to a Drosophila HSP70 gene were cloned. Two of the three genes are arranged in direct orientation approximately 1.5 kilobases apart. The third gene is not closely linked to the other two. Nucleotide sequence analysis of the 5′ regions of the two linked genes revealed that both contain a TATA box, the CAAT motif, and several short sequences which are homologous to the Drosophila heat-shock consensus sequence. The deduced partial amino acid sequence of the open reading frames were 79 and 72% homologous to the corresponding regions of the Drosophila HSP70-cognate and HSP70 sequences, respectively. As with the two maize HSP70 genes which have been characterized, and the Drosophila HSP70-cognate genes, the Arabidopsis genes contained a putative intron in the codon specifying amino acid 72. Analysis of mRNA levels with gene-specific oligonucleotide probes indicated that two of the genes were not expressed or were expressed at very low levels in leaves during normal growth or after heat-shock, whereas the other gene was constitutively expressed. By analogy with the results of similar studies of other organisms, it appears that the three cloned genes are members of a small family which are most closely related to the HSP70-cognate genes found in other species.     

A Novel Imprinted Gene, HYMAI, Is Located within an Imprinted Domain on Human Chromosome 6 Containing ZAC

Transient neonatal diabetes mellitus (TNDM) is a rare disease characterized by intrauterine growth retardation, dehydration, and failure to thrive due to a lack of normal insulin secretion. This disease is associated with paternal uniparental disomy or paternal duplication of chromosome 6, suggesting that the causative gene(s) for TNDM is imprinted. Recently, Gardner et al. (1999, J. Med. Genet. 36: 192–196) proposed that a candidate gene for TNDM lies within chromosome 6q24.1–q24.3. To find human imprinted genes, we performed a database search for EST sequences that mapped to this region, followed by RT-PCR analysis using monochromosomal hybrid cells with a human chromosome 6 of defined parental origin. Here we report the identification of a novel imprinted gene, HYMAI. This gene exhibits differential DNA methylation between the two parental alleles at an adjacent CpG island and is expressed only from the paternal chromosome. A previously characterized imprinted gene, ZAC/LOT1, is located 70 kb downstream of HYMAI and is also expressed only from the paternal allele. In the pancreas, both genes are moderately expressed. HYMAI and ZAC/LOT1 are therefore candidate genes involved in TNDM. Furthermore, the human chromosome 6q24 region is syntenic to mouse chromosome 10 and represents a novel imprinted domain.     

The Structure and Organization of the Human Erythroid Anion Exchanger (AE1) Gene

The AE1 (anion exchanger, band 3) protein is expressed in erythrocytes and in the A-type intercalated cells of the kidney distal collecting tubule. In both cell types it mediates the electroneutral transport of chloride and bicarbonate ions across the lipid bilayer, and, in erythrocytes, it also serves as the critical attachment site of the peripheral membrane skeleton. We have characterized the human AE1 gene using overlapping clones isolated from a phage library of human genomic DNA. The gene spans 20 kb and consists of 20 exons separated by 19 introns. The structure of the human AE1 gene corresponds closely with that of the previously characterized mouse AE1 gene, with a high degree of conservation of exon/intron junctions, as well as exon and intron nucleotide sequences. The putative upstream and internal promoter sequences of the human AE1 gene used in erythroid and kidney cells, respectively, are described. We also report the nucleotide sequence of the entire 3′ noncoding region of exon 20, which was lacking in the published cDNA sequences. In addition, we have characterized 9 Alu repeat elements found within the body of the human AE1 gene that are members of 4 related subfamilies that appear to have entered the genome at different times during primate evolution.     

Cloning, Mapping, and Expression of Two Novel Actin Genes, Actin-like-7A (ACTL7A) and Actin-like-7B (ACTL7B), from the Familial Dysautonomia Candidate Region on 9q31

Two novel human actin-like genes, ACTL7A and ACTL7B, were identified by cDNA selection and direct genomic sequencing from the familial dysautonomia candidate region on 9q31. ACTL7A encodes a 435-amino-acid protein (predicted molecular mass 48.6 kDa) and ACTL7B encodes a 415-amino-acid protein (predicted molecular mass 45.2 kDa) that show greater than 65% amino acid identity to each other. Genomic analysis revealed ACTL7A and ACTL7B to be intronless genes contained on a common 8-kb HindIII fragment in a “head-to-head” orientation. The murine homologues were cloned and mapped by linkage analysis to mouse chromosome 4 in a region of gene order conserved with human chromosome 9q31. No recombinants were observed between the two genes, indicating a close physical proximity in mouse. ACTL7A is expressed in a wide variety of adult tissues, while the ACTL7B message was detected only in the testis and, to a lesser extent, in the prostate. No coding sequence mutations, genomic rearrangements, or differences in expression were detected for either gene in familial dysautonomia patients.     

Localization of a Human Homolog of the Mouse Pericentrin Gene (PCNT) to Chromosome 21qter

Exon trapping was used to identify portions of genes from cosmid DNA of a human chromosome 21-specific library LL21NC02-Q. More than 650 potential exons have been cloned and characterized to date. Among these, 3 trapped “exons” showed strong homology to different regions of the cDNA for the mouse pericentrin (Pcnt) gene (Doxseyet al., Cell76: 639–650, 1994), indicating that these 3 exons are portions of a human homolog of the mouse pericentrin gene. With PCR amplification, Southern blot analysis, and FISH, we have mapped this presumed human pericentrin gene (PCNT) to the long arm of chromosome 21 between marker PFKL and 21qter. Pericentrin is a conserved protein component of the filamentous matrix of the centrosome involved in the initial establishment of the organized microtubule array. No candidate hereditary disorder for pericentrin deficiency/abnormality has yet been mapped in the most distal region of 21q; in addition the role of triplication of the pericentrin gene in the pathophysiology or etiology of trisomy 21 is currently unknown.     

The HOX-5 and surfeit gene clusters are linked in the proximal portion of mouse chromosome 2

Using an interspecies backcross, we have mapped the HOX-5 and surfeit (surf) gene clusters within the proximal portion of mouse chromosome 2. While the HOX-5 cluster of homeobox-containing genes has been localized to chromosome 2, bands C3-E1, by in situ hybridization, its more precise position relative to the genes and cloned markers of chromosome 2 was not known. Surfeit, a tight cluster of at least six highly conserved “housekeeping” genes, has not been previously mapped in mouse, but has been localized to human chromosome 9q, a region of the human genome with strong homology to proximal mouse chromosome 2. The data presented here place HOX-5 in the vicinity of the closely linked set of developmental mutations rachiterata, lethargic, and fidget and place surf close to the proto-oncogene Abl, near the centromere of chromosome 2.     

Structural Characterization and Chromosomal Location of the Mouse Macrophage Migration Inhibitory Factor Gene and Pseudogenes

Macrophage migration inhibitory factor, MIF, is a cytokine released by T-lymphocytes, macrophanges, and the pituitary gland that serves to integrate peripheral and central inflammatory responses. Ubiquitous expression and developmental regulation suggest that MIF may have additional roles outside of the immune system. Here we report the structure and chromosomal location of the mouse Mif gene and the partial characterization of five Mif pseudogenes. The mouse Mif gene spans less than 0.7 kb of chromosomal DNA and is composed of three exons. A comparison between the mouse and the human genes shows a similar gene structure and common regulatory elements in both promoter regions. The mouse Mif gene maps to the middle region of chromosome 10, between Bcr and S100b, which have been mapped to human chromosomes 22q11 and 21q22.3, respectively. The entire sequence of two pseudogenes demonstrates the absence of introns, the presence of the 5′ untranslated region of the cDNA, a 3′ poly(A) tail, and the lack of sequence similarity with untranscribed regions of the gene. The five pseudogenes are highly homologous to the cDNA, but contain a variable number of mutations that would produce mutated or truncated MIF-like proteins. Phylogenetic analyses of MIF genes and pseudogenes indicate several independent genetic events that can account for multiple genomic integrations. Three of the Mif pseudogenes were also mapped by interspecific backcross to chromosomes 1, 9, and 17. These results suggest that Mif pseudogenes originated by retrotransposition.     

Chemokine PARC Gene (SCYA18) Generated by Fusion of Two MIP-1α/LD78α-like Genes

Two loci in the human genome, chromosomes 4q12–q21 and 17q11.2, contain clusters of CXC and CC chemokine subfamily genes, respectively. Since mice appear to contain fewer chemokine genes than humans, numerous gene duplications might have occurred in each locus of the human genome. Here we describe the genomic organization of the human pulmonary and activation-regulated CC chemokine (PARC), also known as DC-CK1 and AMAC-1. Despite high sequence similarity to a CC chemokine macrophage inflammatory protein-1α (MIP-1α)/LD78α, PARC is chemotactic for lymphocytes and not for monocytes and does not share its receptor with MIP-1α. Analyses of the BAC clones containing the humanPARCgene indicated that the gene is located most closely toMIP-1α(HGMW-approved symbolSCYA3) andMIP-1β(HGMW-approved symbolSCYA4) on chromosome 17q11.2. Dot-plot comparison suggested that thePARCgene had been generated by fusion of twoMIP-1α-like genes with deletion and selective usage of exons. Base changes accumulated before and after the fusion might have adapted the gene to a new function. Since there are variably duplicated copies of theMIP-1αgene calledLD78β(HGMW-approved symbolSCYA3L) in the vicinity of theMIP-1αgene, the locus surrounding theMIP-1αgene seems to be a “hot spring” that continuously produces new family genes. This evidence provides a new model, duplication and fusion, of the molecular basis for diversity within a gene family.     

Bovine Mammary Gene Expression Profiling during the Onset of Lactation

Background

Lactogenesis includes two stages. Stage I begins a few weeks before parturition. Stage II is initiated around the time of parturition and extends for several days afterwards.

Methodology/Principal Findings

To better understand the molecular events underlying these changes, genome-wide gene expression profiling was conducted using digital gene expression (DGE) on bovine mammary tissue at three time points (on approximately day 35 before parturition (−35 d), day 7 before parturition (−7 d) and day 3 after parturition (+3 d)). Approximately 6.2 million (M), 5.8 million (M) and 6.1 million (M) 21-nt cDNA tags were sequenced in the three cDNA libraries (−35 d, −7 d and +3 d), respectively. After aligning to the reference sequences, the three cDNA libraries included 8,662, 8,363 and 8,359 genes, respectively. With a fold change cutoff criteria of ≥2 or ≤−2 and a false discovery rate (FDR) of ≤0.001, a total of 812 genes were significantly differentially expressed at −7 d compared with −35 d (stage I). Gene ontology analysis showed that those significantly differentially expressed genes were mainly associated with cell cycle, lipid metabolism, immune response and biological adhesion. A total of 1,189 genes were significantly differentially expressed at +3 d compared with −7 d (stage II), and these genes were mainly associated with the immune response and cell cycle. Moreover, there were 1,672 genes significantly differentially expressed at +3 d compared with −35 d. Gene ontology analysis showed that the main differentially expressed genes were those associated with metabolic processes.

Conclusions

The results suggest that the mammary gland begins to lactate not only by a gain of function but also by a broad suppression of function to effectively push most of the cell''s resources towards lactation.