Distinct TPEF/HPP1 gene methylation patterns in gastric cancer indicate a field effect in gastric carcinogenesis.

BACKGROUND: Aberrant methylation of the transmembrane protein containing epidermal growth factor and folistatin domains/hyperplastic polyposis 1 gene was recently reported in hyperplastic colon polyps, colorectal adenomas and carcinomas. However, there are only limited data on significance of transmembrane protein containing epidermal growth factor and folistatin domains/hyperplastic polyposis 1 gene methylation in gastric adenocarcinomas. AIM: The aim of this study was to determine the prevalence of transmembrane protein containing epidermal growth factor and folistatin domains/hyperplastic polyposis 1 promoter methylation in gastric adenocarcinomas. PATIENTS: Study population consists of 48 patients with gastric cancer and 11 dyspeptic patients. METHODS: Using the Methylight assay, transmembrane protein containing epidermal growth factor and folistatin domains/hyperplastic polyposis 1 gene methylation was assessed in fresh frozen cancer tissue and matched tumoural-free area of patients with gastric cancer and in the gastric mucosa of dyspeptic patients. RESULTS: Transmembrane protein containing epidermal growth factor and folistatin domains/hyperplastic polyposis 1 promoter gene methylation was observed in 35 of 48 (73%) gastric adenocarcinomas, and in 27 of 48 (56%) matched tumoural-free area cases (p=0.087). In contrast, the occurrence of transmembrane protein containing epidermal growth factor and folistatin domains/hyperplastic polyposis 1 methylation was much lower in gastric mucosa of dyspeptics (1 of 11; 9%) and the difference was significant in comparison with both tumoural tissue (p=0.0001) and tumoural-free area (p=0.0047) of cancer patients. Transmembrane protein containing epidermal growth factor and folistatin domains/hyperplastic polyposis 1 gene expression was significantly reduced in adenocarcinomas in comparison with matched tumoural-free area (p=0.022). CONCLUSION: Our data suggest that methylation of transmembrane protein containing epidermal growth factor and folistatin domains/hyperplastic polyposis 1 is present in the majority of gastric adenocarcinomas and in the surrounding tumoural-free area, indicating that this epigenetic change may point to a field effect in the gastric mucosa.

Interleukin 21 and its receptor are involved in NK cell expansion and regulation of lymphocyte function.

Cytokines are important in the regulation of haematopoiesis and immune responses, and can influence lymphocyte development. Here we have identified a class I cytokine receptor that is selectively expressed in lymphoid tissues and is capable of signal transduction. The full-length receptor was expressed in BaF3 cells, which created a functional assay for ligand detection and cloning. Conditioned media from activated human CD3+ T cells supported proliferation of the assay cell line. We constructed a complementary DNA expression library from activated human CD3+ T cells, and identified a cytokine with a four-helix-bundle structure using functional cloning. This cytokine is most closely related to IL2 and IL15, and has been designated IL21 with the receptor designated IL21 R. In vitro assays suggest that IL21 has a role in the proliferation and maturation of natural killer (NK) cell populations from bone marrow, in the proliferation of mature B-cell populations co-stimulated with anti-CD40, and in the proliferation of T cells co-stimulated with anti-CD3.

Human secretin (SCT): gene structure, chromosome location, and distribution of mRNA.

Secretin is an endocrine hormone that stimulates the secretion of bicarbonate-rich pancreatic fluids. Recently, it has been discussed that secretin deficiency may be implicated in autistic syndrome, suggesting that the hormone could have a neuroendocrine function in addition to its role in digestion. In the present study, the human secretin gene (SCT) was isolated from a bacterial artificial chromosome genomic library. SCT contains four exons, with the protein coding regions spanning 713 bp of genomic DNA. Human SCT is similar structurally to the secretin genes of other species. Amino acid conservation, however, is most pronounced within the exon encoding the biologically active mature peptide. Northern blot analysis shows that human SCT transcripts are located in the spleen, intestinal tract, and brain. Radiation hybrid mapping places the SCT locus on chromosome 11p15.5.

TACI and BCMA are receptors for a TNF homologue implicated in B-cell autoimmune disease.

B cells are important in the development of autoimmune disorders by mechanisms involving dysregulated polyclonal B-cell activation, production of pathogenic antibodies, and co-stimulation of autoreactive T cells. zTNF4 (BLyS, BAFF, TALL-1, THANK) is a member of the tumour necrosis factor (TNF) ligand family that is a potent co-activator of B cells in vitro and in vivo. Here we identify two receptors for zTNF4 and demonstrate a relationship between zTNF4 and autoimmune disease. Transgenic animals overexpressing zTNF4 in lymphoid cells develop symptoms characteristic of systemic lupus erythaematosus (SLE) and expand a rare population of splenic B-Ia lymphocytes. In addition, circulating zTNF4 is more abundant in NZBWF1 and MRL-lpr/lpr mice during the onset and progression of SLE. We have identified two TNF receptor family members, TACI and BCMA, that bind zTNF4. Treatment of NZBWF1 mice with soluble TACI-Ig fusion protein inhibits the development of proteinuria and prolongs survival of the animals. These findings demonstrate the involvement of zTNF4 and its receptors in the development of SLE and identify TACI-Ig as a promising treatment of autoimmune disease in humans.

Identification of INSL6, a new member of the insulin family that is expressed in the testis of the human and rat.

A new member of the insulin gene family (INSL6) was identified from an Expressed Sequence Tag database through a search for proteins containing the insulin family B-chain cysteine motif. Human and rat INSL6 encoded polypeptides of 213 and 188 amino acids, respectively. These orthologous sequences contained the B-chain, C-peptide, and A-chain motif found in other members of the insulin family. Human INSL6 was 43% identical to human relaxin H2 in the B- and A-chain regions. As with other family members, human and rat INSL6 had predicted dibasic sequences at the junction of the C-peptide and A-chain. Human INSL6 sequence had an additional dibasic site near the C-terminus of the A-chain. The presence of a single basic residue at the predicted junction of the B-chain and C-peptide suggests that multiple prohormone convertases are required to produce the fully mature hormone. INSL6 was found to be expressed at high levels in the testis as determined by Northern blot analysis and specifically within the seminiferous tubules in spermatocytes and round spermatids as detected by in situ hybridization analysis. Radiation hybrid mapping placed the human INSL6 locus at chromosome 9p24 near the placenta insulin-like homologue INSL4 and the autosomal testis-determining factor (TDFA) locus.

Identification of INSL5, a new member of the insulin superfamily.

A new member of the insulin gene superfamily (INSL5) was identified by searching EST databases for the presence of the conserved insulin B-chain cysteine motif. Human and murine INSL5 are both polypeptides of 135 amino acids, matching the classical signature of the insulin superfamily. Through the B- and A-chain regions, human INSL5 has 48% identity to shark relaxin, 40% identity to human relaxin, and 34% identity to human Leydig insulin-like factor. Northern blot analysis detected expression of human INSL5 in rectal, colon, and uterine tissue and of murine INSL5 only in thymic tissue. Using quantitative RT-PCR, expression of murine INSL5 was detected in the highest quantity in colon followed by thymus, and minimal expression was seen in testis. By radiation hybrid mapping and the use of surrounding markers, human INSL5 maps to chromosome 1 in the 1p31.1 to 1p22.3 region.

A novel human GnRH receptor homolog gene: abundant and wide tissue distribution of the antisense transcript.

Gonadotropin releasing hormone (GnRH) regulates the reproductive system through a specific G-protein-coupled receptor (GPCR) in pituitary gonadotropes. The existence of two (or more) forms of GnRH in most vertebrates suggested the existence of GnRH receptor subtypes (I and II). Using sequence information for extracellular loop 3 of a putative Type II GnRH receptor from a reptile species, we have looked for a Type II GnRH receptor gene in the human genome EST (expressed sequence tag) database. A homolog was identified which has 45% and 41% amino acid identity with exons 2 and 3 of the known human GnRH pituitary receptor (designated Type I) and much lower homology with all other GPCRs. A total of 27 contiguous ESTs was found and comprised a continuous sequence of 1642 nucleotides. The EST sequences were confirmed in the cloned human gene and in PCR products of cDNA from several tissues. All EST transcripts detected were in the antisense orientation with respect to the novel GnRH receptor sequence and were highly expressed in a wide range of human brain and peripheral tissues. PCR of cDNA from a wide range of tissues revealed that intronic sequence equivalent to intron 2 of the Type I GnRH receptor was retained. The failure to splice out putative intron sequences in transcripts which spanned exon-intron boundaries is expected in antisense transcripts, as candidate donor and acceptor sites were only present in the gene when transcribed in the orientation encoding the GnRH receptor homolog. No transcripts extended 5' to the sequence corresponding to intron 2 of the Type I GnRH as the antisense transcripts terminated in poly A due to the presence of a polyadenylation signal sequence in the putative intron 2 when transcribed in the antisense orientation. These findings suggest that a Type II GnRH receptor gene has arisen during vertebrate evolution and is also present in the human. However, the receptor may have become vestigial in the human, possibly due to the abundant and universal tissue transcription of the opposite DNA strand to produce antisense RNA.

An islet-cell protein tyrosine phosphatase is a likely precursor to the 37-kDa autoantigen in type 1 diabetes: human and macaque sequences, tissue distribution, unique and shared epitopes, and predictive autoantibodies.

BACKGROUND: We sought to identify novel islet-cell autoantigens to better understand the pathogenesis, prediction, and immunotherapy of type 1 diabetes. MATERIALS AND METHODS: Macaque and human islet cDNA libraries expressed in mammalian cells were screened with human diabetes sera. A positive clone was sequenced directly and after 5' rapid amplification of cDNA ends (RACE). Northern blotting and in situ hybridization revealed the tissue distribution of the corresponding protein. Antigen, expressed by in vitro translation, and tryptic peptides were analyzed by SDS-PAGE. For the immunoprecipitations, 183 diabetic, 60 prediabetic, and 91 control sera were used. Truncated antigens were used in immunoprecipitations for epitope mapping. Recombinant antigen expressed in transfected fibroblasts was used in competition assays. RESULTS: Sequencing yielded an 111-kDa, 1,013 amino acid, transmembrane protein (M1851) containing consensus protein tyrosine phosphatase (PTPase) sequence. M1851 was 77% identical in the intracellular domain, but only 31% identical extracellularly, to the islet-cell autoantigen ICA512. mRNA localized to brain, prostate, pancreatic islets, and adrenal medulla. After limited trypsinization, the in vitro translated antigen was 37 kDa. M1851 was recognized by 47% of prediabetes sera, 31% of new diabetes sera, but only 1% of healthy controls. Only 1/73 sera binding M1851 failed to bind ICA512, whereas 42/114 binding ICA512 did not bind M1851. M1851 reactivity was not fully displaced by ICA512 in 24/49 sera. Removing the C-terminal 27, 80, or 160 amino acids of M1851 decreased reactivity by 70%, 90%, and 100%, respectively. CONCLUSIONS: This new islet-cell PTPase is likely to be the precursor to the 37-kDa tryptic fragment antigen. It is structurally related to ICA512 but has distinct diabetes autoantibody epitopes located at the C terminus.

Do the preclinical effects of thrombopoietin correlate with its in vitro properties?

In the short time since its cloning, much has been learned of the in vitro properties of thrombopoietin (TPO). In addition to effects on the differentiation of megakaryocytes, TPO has also been shown to stimulate the proliferation of megakaryocytic progenitor cells, colony-forming units-megakaryocytes (CFU-MK), to act in synergy with interleukin 3 or c-kit ligand and erythropoietin (Epo) to stimulate the development of early and the generation of late erythroid progenitor cells, and to affect the rate of entry into the cell cycle and proliferative capacity of hematopoietic stem cells. An important question posed by these observations, for both TPO and for hematopoietic research in general, is whether the in vitro effects of a cytokine are mirrored by its preclinical and clinical biology. The results of recent studies in mice and nonhuman primates will be presented which have attempted to address this issue. In normal animals, TPO increases the numbers of marrow and spleen CFU-granulocyte/erythroid/macrophage/megakaryocyte, CFU-MK, CFU-GM and BFU-E, but its effects in the peripheral blood are limited to marked increases in the platelet count. The reason for widespread progenitor cell effects, yet stable leukocyte and erythrocyte blood counts, is likely the predominant regulatory effects of G-CSF and Epo; in the absence of elevated levels of the lineage-dominant regulator of each of these cell types, expanded progenitor cell numbers are not translated into increased peripheral blood counts. However, in states of increased blood cell demand such as follows myelosuppressive therapy, elevated levels of Epo and G-CSF allow the effects of TPO on erythropoiesis and myelopoiesis to become manifest. The administration of TPO to myelosuppressed animals is associated with not only greatly expanded hematopoietic progenitor cell recovery, but also improvement in platelet, red cell and leukocyte nadir levels and greatly accelerated recovery of all three cell lineages. These results indicate that the panhematopoietic properties of TPO identified by in vitro culture techniques correlate well with its effects in animals. The results of ongoing clinical trials should soon establish whether these conclusions can be extended to patient care.

Recombinant ob protein reduces feeding and body weight in the ob/ob mouse.

To determine whether the product of the recently cloned ob gene functions as an adipose-related satiety factor, recombinant murine ob protein was administered intraperitoneally to ob/ob mice. Monomeric ob protein given as single morning injections to groups of three animals at seven doses ranging from 5 to 100 micrograms reduced 24-h chow consumption in a dose-dependent manner from values of 81 +/- 6.8% of control (10-micrograms dose, P = 0.04) to 29 +/- 7.7% of control (100-micrograms dose, P < 0.0001). Daily injections of 80 micrograms of ob protein into six ob/ob mice for 2 wk led to an 11 +/- 1.6% decrease in body weight (P = 0.0009) and suppressed feeding to 26 +/- 4.9% of baseline (P < 0.0001), with significant reduction of serum insulin and glucose levels. The effect of recombinant ob protein on feeding was not augmented by cofactors secreted by adipose tissue, nor did exposure of adipose tissue to ob protein affect intracellular ob mRNA levels. Posttranslational modification of ob protein was not required for activity; however, addition of a hexahistidine tag to the amino terminus of the mature ob protein resulted in prolonged suppression of feeding after injection into ob/ob mice. These results demonstrate a direct effect of the ob protein to suppress feeding in the ob/ob mouse and suggest that this molecule plays a critical role in regulating total body fat content.

Thrombopoietin, the Mp1 ligand, is essential for full megakaryocyte development.

The development of megakaryocytes (MKs) from their marrow precursors is one of the least understood aspects of hematopoiesis. Current models suggest that early-acting MK colony-stimulating factors, such as interleukin (IL) 3 or c-kit ligand, are required for expansion of hematopoietic progenitors into cells capable of responding to late-acting MK potentiators, including IL-6 and IL-11. Recently, the Mp1 ligand, or thrombopoietin (Tpo), has been shown to display both MK colony-stimulating factor and potentiator activities, at potencies far greater than that of other cytokines. In light of these findings, we tested the hypothesis that Tpo is absolutely necessary for MK development. In this report we demonstrate that neutralizing the biological activity of Tpo eliminates MK formation in response to c-kit ligand, IL-6, and IL-11, alone and in combination, but that these reagents only partially reduce MK formation in the presence of combinations of cytokines including IL-3. However, despite the capacity of IL-3 to support the proliferation and initial stages of MK differentiation, elimination of Tpo prevents the full maturation of IL-3-induced MK. These data indicate that two populations of MK progenitors can be identified: one that is responsive to IL-3 but can fully develop only in the presence of Tpo and a second that is dependent on Tpo for both proliferation and differentiation. Thus, our results strongly suggest that Tpo is the primary regulator of MK development and platelet production.

Cloning and expression of murine thrombopoietin cDNA and stimulation of platelet production in vivo.

The major regulator of circulating platelet levels is believed to be a cytokine termed thrombopoietin. It is thought to be a lineage-specific cytokine affecting the proliferation and maturation of committed cells resulting in the production of megakaryocytes and platelets. Despite considerable efforts by a number of laboratories, the unequivocal identification of thrombopoietin has proven elusive. Here we report the functional cloning of a murine complementary DNA encoding a ligand for the receptor encoded by the c-mpl proto-oncogene (c-Mpl). The encoded polypeptide has a predicted molecular mass of 35,000 (M(r) 35K). The protein has a novel two-domain structure with an amino-terminal domain homologous with erythropoietin and a carboxy-terminal domain rich in serine, threonine and proline residues and containing seven potential N-linked glycosylation sites. Intraperitoneal injections of mice with recombinant protein increase circulating platelet levels by greater than fourfold after 7 days. These results along with those presented in the accompanying report strongly suggest that the ligand for c-Mpl is thrombopoietin.

Complete cDNA encoding human phospholipid transfer protein from human endothelial cells.

Phospholipid transfer protein, with an apparent molecular mass of 81 kDa, was purified from human plasma. The NH2-terminal amino acid sequence of a 51-kDa proteolytic fragment obtained from phospholipid transfer protein allowed degenerate primers to be designed for polymerase chain reaction and the eventual isolation of a full-length cDNA from a human endothelial cDNA library. The cDNA is 1,750 base pairs in length and contains an open reading frame of 1,518 nucleotides encoding a leader of 17 amino acids and a mature protein of 476 residues. Northern blot analysis shows a single mRNA transcript of approximately 1.8 kilobases with a wide tissue distribution. The gene was mapped to chromosome 20 using a human/rodent somatic cell hybrid mapping panel. Phospholipid transfer protein was found to be homologous to human cholesteryl ester transfer protein, human lipopolysaccharide-binding protein, and human neutrophil bactericidal permeability increasing protein (20, 24, and 26% identity, respectively).

Molecular cloning and sequence analysis of the cDNA encoding human apolipoprotein H (beta 2-glycoprotein I).

Apolipoprotein H, also known as beta-2-glycoprotein I, was purified from human serum, and antiserum produced to denatured apolipoprotein H detected a cDNA clone from a lambda gt11 library derived from human liver. This cDNA coded for the complete sequence of the mature protein. The cDNA insert, along with a polymerase chain reaction product which extended the 5' end of the message, were subcloned and both strands were sequenced. The apolipoprotein H precursor was found to code for 345 amino acids, 326 of which appear in the mature protein. The deduced amino acid sequence of human apolipoprotein H differs from its rat homologue by the presence of a 48-amino acid stretch which is absent from the rat protein. The remainder of the proteins share a greater than 80% similarity. The amino acid sequence of apolipoprotein H consists largely of repeated units approximately 60 amino acids in length. These repeats are comparable to "sushi structures" found in a large number of diverse proteins, including complement components, receptors and regulators of complement activation, serum proteins, membrane-associated adhesion proteins, and other structural and catalytic proteins. Apolipoprotein H was shown to be transcribed by human hepatoma cell lines Hep 3B and Hep G2, and rat liver by detection of mRNA using northern blot analysis.