Identification and distribution of CCK-related peptides and mRNAs in the rainbow trout, Oncorhynchus mykiss.

Peptides homologous to mammalian cholecystokinin (CCK), and their corresponding cDNAs, have been isolated and sequenced from the rainbow trout, Oncorhynchus mykiss. Three cDNAs encoding CCK-like preprohormones were identified from the brain. The cDNAs encode three different putative CCK-8 peptides containing Asn, Leu or Thr, in position 6 (counting from the C-terminus). Hence, the trout CCKs are named CCK-N, CCK-L and CCK-T respectively. RT-PCR showed differential expression of the three mRNAs although all were detected in the brain and intestine, similar to the expression pattern of CCK in tetrapods. In situ hybridization on trout brain sections using (35)S-labeled gene-specific antisense oligonucleotides showed that the three mRNAs were present in different parts, suggesting that the three CCK peptides may have different functions in the brain. Purification of CCK-immunoreactive material from the trout brain resulted in two CCK octapeptides: DYNGWMDF(.)NH2 (CCK-N) and DYLGWMDF(.)NH2 (CCK-L) present in equal amounts. In the pyloric caeca, three forms of CCK-L were identified, consisting of 7, 8 and 21 residues, respectively. The last was dominating and had the sequence ASGPGPSHKIKDRDYLGWMDF(.)NH2. All isolated peptides were fully sulfated. The trout is the first species in which three different CCK-like cDNAs have been identified.

Identification and expression of gastrin and cholecystokinin mRNAs from the turtle, Pseudemys scripta: evidence of tissue-specific tyrosyl sulfation(1).

Gastrin and cholecystokinin (CCK) are related peptide hormones expressed in the brain and gut of vertebrates. In this study, complementary DNAs have been characterised from the red-eared slider turtle, Pseudemys scripta. The encoded preproCCK contains mono and dibasic endoproteolytic processing sites for formation of the previously identified CCK-70, CCK-40 and CCK-8 products, whereas preprogastrin contains two dibasic processing sites for the generation of gastrin-52. Alignment of the predicted preprohormone structures with those of other species, showed that preproCCK has been well conserved among all vertebrates, whereas progastrin is less conserved. Both gastrin and CCK mRNA display expression patterns similar to their mammalian counterparts, with CCK being expressed in the brain, duodenum and small intestine, and gastrin in the antrum. Heterologous expression of turtle preprogastrin in a mammalian endocrine cell line led to production of carboxyamidated gastrin-52 as observed in turtle antrum. However, in contrast to the non-sulfated endogenous peptide, the heterologously expressed gastrin was completely Tyr sulfated. Consequently, it appears that either gastrin producing cells in the turtle gut do not express tyrosylprotein sulfotransferases or the enzyme(s) present in turtle antrum is unable to sulfate turtle gastrin.

Negative cooperativity between juxtaposed E-box and cAMP/TPA responsive elements in the cholecystokinin gene promoter.

The promoter of the cholecystokinin (CCK) gene possesses evolutionary conserved juxtaposed E-box and cAMP/TPA responsive elements (CRE/TRE). We have examined the functional interaction of these two sites. As previously noted, c-Jun/c-Fos heterodimers greatly increase promoter activity through association with the CRE/TRE. Mutation of the E-box enhanced the activation by c-Jun/c-Fos, as well as stimulation by forskolin and bFGF, that acts through the CRE/TRE site. Moreover, c-Jun/c-Fos stimulation was inhibited by co-expression of c-Myc and Max. The results indicate that factors associating with the E-box exhibit a negative cooperative effect on the activation via the CRE/TRE element. We propose that this mechanism plays a significant role in CCK gene transcription and other genes with juxtaposed E-box and CRE/TRE.

Rel-dependent induction of A1 transcription is required to protect B cells from antigen receptor ligation-induced apoptosis.

In response to different extracellular signals, Rel/NF-kappaB transcription factors are critical regulators of apoptosis in a variety of cell types. Here we show that in normal B and T cells, expression of the Bcl-2 prosurvival homolog, A1, is rapidly induced in a Rel-dependent manner by mitogens. In B-cell lines derived from c-rel-/- mice, which like primary cells lacking Rel undergo apoptosis in response to antigen receptor ligation, constitutive expression of an A1 transgene inhibits this pathway to cell death. These findings are the first to show that Rel/NF-kappaB regulates physiologically the expression of a Bcl-2-like protein that is critical for the control of cell survival during lymphocyte activation.

Unique progastrin processing in equine G-cells suggests marginal tyrosyl sulfotransferase activity.

Previous studies have indicated that equine G-cell processing of progastrin differs from that of other species. Since the difference may be due to structural features, we have identified equine gastrin-17 and -34 (

B lymphocytes differentially use the Rel and nuclear factor kappaB1 (NF-kappaB1) transcription factors to regulate cell cycle progression and apoptosis in quiescent and mitogen-activated cells.

Rel and nuclear factor (NF)-kappaB1, two members of the Rel/NF-kappaB transcription factor family, are essential for mitogen-induced B cell proliferation. Using mice with inactivated Rel or NF-kappaB1 genes, we show that these transcription factors differentially regulate cell cycle progression and apoptosis in B lymphocytes. Consistent with an increased rate of mature B cell turnover in naive nfkb1-/- mice, the level of apoptosis in cultures of quiescent nfkb1-/-, but not c-rel-/-, B cells is higher. The failure of c-rel-/- or nfkb1-/- B cells to proliferate in response to particular mitogens coincides with a cell cycle block early in G1 and elevated cell death. Expression of a bcl-2 transgene prevents apoptosis in resting and activated c-rel-/- and nfkb1-/- B cells, but does not overcome the block in cell cycle progression, suggesting that the impaired proliferation is not simply a consequence of apoptosis and that Rel/NF-kappaB proteins regulate cell survival and cell cycle control through independent mechanisms. In contrast to certain B lymphoma cell lines in which mitogen-induced cell death can result from Rel/NF-kappaB-dependent downregulation of c-myc, expression of c-myc is normal in resting and stimulated c-rel-/- B cells, indicating that target gene(s) regulated by Rel that are important for preventing apoptosis may differ in normal and immortalized B cells. Collectively, these results are the first to demonstrate that in normal B cells, NF-kappaB1 regulates survival of cells in G0, whereas mitogenic activation induced by distinct stimuli requires different Rel/NF-kappaB factors to control cell cycle progression and prevent apoptosis.

Elasmobranchs express separate cholecystokinin and gastrin genes.

The peptide hormone gastrin was long believed to be specific for higher vertebrates, whereas its homologue, cholecystokinin (CCK), has been assumed to represent the original ancestor of the CCK/gastrin family. To trace the divergence of the CCK/gastrin family beyond birds, reptiles, and amphibians we have now examined sharks. Distinct CCK and gastrin peptides were identified in two shark species, the spiny dogfish (Squalus acanthias) and the porbeagle (Lamna cornubica). The corresponding genes and cDNAs were isolated and sequenced from the spiny dogfish. Comparison with several vertebrate species show that the CCK gene and peptide structures have been considerably more conserved than the corresponding gastrin structures. Alignment of the dogfish prepropeptides displays similarities that support the hypothesis that they share a common ancestor. Our findings move the CCK/gastrin family segregation back to at least 350 million years ago. This event must have occurred before, or perhaps during, the evolution of cartilagenous fishes, probably concomitant with the occurrence of gastric acid secretion.

Heterologous expression of human cholecystokinin in Saccharomyces cerevisiae. Evidence for a lysine-specific endopeptidase in the yeast secretory pathway.

Precursors of the human regulatory peptide cholecystokinin (CCK) have been expressed in Saccharomyces cerevisiae, and the post-translational processing of secreted CCK-related products analyzed. Recombinant plasmids expressing native human prepro-CCK and a hybrid molecule encompassing the prepro leader of the yeast alpha-mating pheromone fused to pro-CCK were examined. The latter construct resulted in considerably higher levels of pro-CCK secretion and was therefore analyzed in more detail. Two of the protein modifications essential for CCK bioactivity, C-terminal alpha-amidation and tyrosyl sulfation, were not detected in S. cerevisiae. Proteolytic cleavage of pro-CCK occurred C-terminally of three basic sites; (i) Arg105-Arg106 which, upon exposure to carboxypeptidase activity, leads to the production of glycine-extended CCK; (ii) Arg95 to produce CCK-8 related processing intermediates; and (iii) Lys81 resulting in CCK-22 related products. To elucidate which protease(s) are involved in these endoproteolytic cleavage events, pro-CCK was expressed in yeast mutants lacking various combinations of the Mkc7, Yap3, and Kex2 proteases. Only in S. cerevisiae strains deficient in Kex2 function was any of the above mentioned pro-CCK cleavages abolished, namely processing at the Arg105-Arg106 and Arg95 sites. This suggests that mammalian Kex2-like serine proteases may process pro-CCK at single arginine residues. Our data suggests that an as yet uncharacterized endopeptidase(s) in the S. cerevisiae secretory pathway is responsible for the lysine-specific cleavage of pro-CCK.

Characterization of the cholecystokinin and gastrin genes from the bullfrog, Rana catesbeiana: evolutionary conservation of primary and secondary sites of gene expression.

The gastrin and cholecystokinin (CCK) genes, and the complementary DNAs they encode, have been isolated and sequenced from the bullfrog, Rana catesbeiana. The CCK gene promoter region possess the same four well characterized transcriptional control elements as the human CCK gene, namely an E-box, AP-1 binding site, Sp1 site, and TATA box. In contrast, no obvious regulatory motifs are conserved in the gastrin gene. Alignment of the bullfrog preprohormone sequences with other members of the CCK/gastrin peptide family showed that preproCCK has been conserved to a greater degree during evolution than preprogastrin. In mammalian species, gastrin gene expression is typically associated with the antrum, and CCK with the small intestine and brain. However numerous secondary sites of CCK/gastrin gene expression have also been found. RT-PCR showed a high degree of conservation of both primary and secondary sites of CCK/gastrin production between mammals and the bullfrog, with gastrin messenger RNA being detected in the antrum, duodenum, colon, pancreas, brain, and testes, whereas CCK mRNA was observed in the brain, lung, testes, and throughout the length of the small intestine. In situ hybridization using radiolabeled gene specific antisense oligonucleotides uncovered CCK and gastrin messenger RNA in distinct areas of the bullfrog central nervous system and pituitary gland. Notably, the gastrin gene was expressed in the pituitary gland and hypothalamus of the bullfrog, as previously seen in mammals. This highly preserved tissue expression pattern suggests that gastrin plays specific roles in the hypothalamus and pituitary gland that are distinct from those of CCK. Our findings show that in spite of the structural resemblance, bullfrog CCK and gastrin constitute independent neuroendocrine peptide systems.

Evidence for gene conversion between tandemly duplicated cytoplasmic actin genes of Helicoverpa armigera (Lepidoptera:Noctuidae)

Tandemly duplicated actin genes have been isolated from a Helicoverpa armigera genomic library. Sequence comparisons with actin genes from other species suggest they encode cytoplasmic actins, being most closely related to the Bombyx mori A3 actin gene. The duplicated H. armigera actin genes, termed A3a and A3b, share 98.3% nucleotide sequence identity over their entire putative coding region. Analysis of the distribution of nucleotide differences shows the first 763 bp are identical between the two coding regions, with the 18 nucleotide changes occurring in the remaining 366 bp. This observation suggests a gene conversion event has taken place between the duplicated H. armigera A3a and A3b actin genes. Translation of the open-reading frames indicates the products of these genes are identical, apart from a single amino acid difference at codon 273. Polymerase chain reaction and northern blot analysis have shown both H. armigera A3a and A3b genes are expressed during pupal development and in the brain of newly enclosed adults. A region 5' of the H. armigera A3a actin gene start codon has been identified which contains regulatory sequences commonly found in the promoter region of actin genes, including TATA, CAAT, and CArG motifs.

Molecular structure and genetic mapping of the mouse gastrin gene.

The mouse gastrin gene has three exons totalling 460 bp and a deduced preprogastrin of 101 amino acids. The sequence of murine gastrin-34 is 94% identical to rat gastrin-34 and 76% identical to human gastrin-34. At Arg79, mouse progastrin has a unique cleavage site that might allow species-specific synthesis of gastrin-13. Northern analysis and RT-PCR demonstrated that gastrin gene transcripts are abundant in mouse stomach and duodenum and present at low levels in brain, ovary and pancreas, similar to the pattern described for other mammals. The gastrin gene was mapped to the distal region of mouse chromosome 11.

Transcriptional regulation of the human cholecystokinin gene: composite action of upstream stimulatory factor, Sp1, and members of the CREB/ATF-AP-1 family of transcription factors.

We have examined cis-elements and trans-acting factors that regulate transcription of the human cholecystokinin (CCK) gene. Transient expression of CCK promoter deletion constructs in human SK-N-MC neuroblastoma cells depicted positive cis-elements between the positions -100 to -92, -84 to -74, and -58 to -37, 5' to the transcription initiation site. Correspondingly, DNase I protection analysis showed that transacting factors bound to elements within these regions. The sequences encompass a putative basic helix-loop-helix leucine zipper (bHLH-ZIP) element, an Sp1 element, and a combined cAMP- and TPA-responsive element (CRE/TRE) at positions -97 to -92, -39 to -34, and -80 to -73, respectively. Mobility and supershift assays demonstrated that upstream stimulatory factor (USF) and Sp1 bind to the former elements and competition experiments confirmed that CREB/ATF and AP-1 bind to the CRE/TRE element. Mutation of the bHLH-ZIP and CRE/TRE elements decreased the activity of the promoter by 65% and 42%, respectively. The activity of the promoter was increased six- and two-fold after stimulation with forskolin and TPA, respectively. Stimulation was eliminated after mutation of the CRE/TRE element. Co-transfection experiments with pRSV-c-jun, pSV-fos, and pRC-RSV-CREB constructs showed that jun, CREB, and AP-1 stimulate transcription. We conclude that USF, Sp1, and members of the CREB/ATF and AP-1 family of transcription factors are the major determinants of CCK gene transcription.

A distal Sp1-element is necessary for maximal activity of the human gastrin gene promoter.

Studies of transgenic mice have shown that transcriptional control of the gastrin gene exhibits significant species differences. Transfection of the human gastrin promoter in murine cells have depicted proximal Sp1, E-box and CACC elements as the major determinants of transcription. We have examined cis-regulatory elements of the human promoter on a human gastrin expressing cell line and find that a distal -135 to -142 Sp1 element is necessary for maximal activity. Alignment of the mouse and human promoters shows that the proximal human Sp1 and CACC elements are not conserved, whereas the E-box element is retained. The distal Sp1 element is present in mouse but exhibits a C to T transition in the core that is likely to reduce binding affinity of Sp1. We conclude that gastrin gene transcription is regulated by distinct elements in man and rodents.