Naming progastrin-derived peptides

The antral hormone gastrin continues to be in focus, because its hormonal and growth promoting effects are essential both for the function of the normal stomach and for the pathogenesis of major dyspeptic and neoplastic diseases. Deduction of the progastrin structure has improved the insight in the cellular synthesis of gastrin, but has also revealed that the biosynthetic machinery is complex, and, accordingly, that progastrin is processed to a multitude of more or less bioactive fragments. The naming of these fragments has, however, become inconsistent and confusing. Therefore, we propose a systematic nomenclature for progastrin-derived peptides of which there are three classes: (I) The gastrins with the evolutionary preserved tetrapeptide amide (Trp-Met-Asp-PheNH₂) at the C-terminus, which ensures high-affinity binding to the gastrin (CCK-B) receptor. Among the gastrins, gastrin-34 and gastrin-17 constitute the primary forms. (II) Processing intermediates, which are early products of progastrin that contain the structure of the primary gastrins within their sequence, but still cannot bind the gastrin receptor due to insufficient processing at their C-terminus. (III) Flanking fragments from the N- and C-termini of progastrin that do not contain any primary gastrin in their sequence, but nevertheless may undergo posttranslational processing. Each fragment can be specified with suffixes corresponding to the derived sequence in progastrin.     

Selective, high-affinity binding of ferric ions by glycine-extended gastrin(17)

Uptake of dietary iron is essential for replenishment of body stores. A role for the hormone gastrin in iron uptake as a chelator of ferric ions in the gastric lumen has been proposed previously [Baldwin, G. S. (1992) Med. Hypotheses 38, 70-74]. Here, spectroscopic evidence of selective, high-affinity binding of ferric ions to progastrin-derived peptides in aqueous solution at low pH is provided. The maximum at 281 nm in the absorption spectrum of glycine-extended gastrin(17) at pH 4.0 increased (2.07 +/- 0.30)-fold in the presence of > or =2 equiv of ferric ions. Titration of glycine-extended gastrin(17) with ferric ions under stoichiometric conditions indicated that the stoichiometry of binding was 2.00 +/- 0.28 mol of Fe(3+)/mol of peptide. Fluorescence quenching experiments yielded values for the stoichiometry and apparent dissociation constant of the ferric ion-glycine-extended gastrin(17) complex at pH 4.0 of 2.39 +/- 0.17 mol of Fe(3+)/mol and 0.62 +/- 0.19 microM, respectively. No interaction was detected with Co(2+), Cu(2+), Mn(2+), or Cr(3+). Electron paramagnetic resonance spectroscopy suggested that the iron ligands were either oxygen or sulfur atoms. Fluorescence quenching experiments with peptides derived from the glycine-extended gastrin(17) sequence indicated that one or more of the five glutamic acid residues were necessary for iron binding. The binding of ferric ions by glycine-extended gastrin(17) at low pH is consistent with a role for progastrin-derived peptides in iron uptake from the lumen of the gastrointestinal tract.     

The constitution and properties of phosphorylated and unphosphorylated C-terminal fragments of progastrin from dog and ferret antrum

Antibodies to the extreme C-terminal tryptic (nona-) peptide fragment of porcine progastrin have been used in radioimmunoassay to identify progastrin fragments in dog, ferret and pig antral mucosa extracts and to monitor their purification. In addition to previously characterised phosphorylated and unphosphorylated C-terminal tryptic peptides of porcine progastrin a minor form corresponding to the C-terminal octapeptide (i.e. des-Ser C-terminal nonapeptide) was isolated and characterised. The latter form together with phosphorylated and unphosphorylated forms of the nonapeptides were also isolated and chemically characterised from dog antrum, and the unphosphorylated nonapeptide was characterised from ferret antrum. The primary amino acid sequences of the dog, ferret and pig nonapeptides were identical. In ferret the unphosphorylated nonapeptide predominated, and in dog the phosphorylated form predominated; in pig both forms of the nonapeptide were well represented. Intact progastrin was identified in gel filtration eluates of extracts of all 3 species, but occurred only in relatively low concentrations. The nonapeptides did not stimulate acid secretion in the conscious gastric fistula rat and they did not modify the acid response to G17. Phosphorylation of progastrin-derived peptides is evidently well conserved across a range of species even though there appear to be differences in the relative proportions of phosphorylated and unphosphorylated forms.     

Gastrin biosynthesis in canine G cells

Gastrin requires extensive posttranslational processing for full biological activity. It is presumed that progastrin is cleaved at pairs of basic amino acids by a prohormone convertase to form a glycine-extended intermediate (G-Gly) that serves as a substrate for peptidyl-glycine alpha-amidating monooxygenase (PAM), resulting in COOH-terminally amidated gastrin. To confirm the nature of progastrin processing in a primary cell line, we performed [(35)S]methionine-labeled pulse-chase biosynthetic experiments in canine antral G cells. Radiolabeled progastrin reached a peak earlier than observed for G-Gly or amidated gastrin. G-Gly radioactivity accumulated in G cells and preceded the appearance of radioactivity in amidated gastrin. The conversion of G-Gly to amidated gastrin was enhanced by the PAM cofactor ascorbic acid. To determine whether one member of the prohormone convertase family (PC2) was responsible for progastrin cleavage, G cells were incubated with PC2 antisense oligonucleotide probes. Cells treated with antisense probes had reduced PC2 expression, an accumulation of radiolabeled progastrin, and a delay in the formation of amidated gastrin. Progastrin in antral G cells is cleaved via PC2 to form G-Gly that is converted to amidated gastrin via the actions of PAM.     

Diminished prohormone convertase 3 expression (PC1/PC3) inhibits progastrin post-translational processing

Gastrin is initially synthesized as a large precursor that requires endoproteolytic cleavage by a prohormone convertase (PC) for bioactivation. Gastric antral G-cells process progastrin at Arg(94)Arg(95) and Lys(74)Lys(75) residues generating gastrin heptadecapeptide (G17-NH(2)). Conversely, duodenal G-cells process progastrin to gastrin tetratriacontapeptide (G34-NH(2)) with little processing at Lys(74)Lys(75). Both tissues express PC1/PC3 and PC2. Previously, we demonstrated that heterologous expression of progastrin in an endocrine cell line that expresses PC1/PC3 and little PC2 (AtT-20) resulted in the formation of G34-NH(2). To confirm that PC1/PC3 was responsible for progastrin processing in AtT-20 cells and capable of processing progastrin in vivo we coexpressed either human wild-type (Lys(74)Lys(75)) or mutant (Arg(74)Arg(75), Lys(74)Arg(75), and Arg(74)Lys(75)) progastrins in AtT-20 cells with two different antisense PC1/PC3 constructs. Coexpression of either antisense construct resulted in a consistent decrease in G34-NH(2) formation. Gastrin mRNA expression and progastrin synthesis were equivalent in each cell line. Although mutation of the Lys(74)Lys(75) site within G34-NH(2) to Lys(74)Arg(75) resulted in the production of primarily G17-NH(2) rather than G34-NH(2), inhibition of PC1/PC3 did not significantly inhibit processing at the Lys(74)Arg(75) site. We conclude that PC1/PC3 is a progastrin processing enzyme, suggesting a role for PC1/PC3 progastrin processing in G-cells.     

Progastrin-like immunoreactivity in porcine antrum: identification and characterization with region-specific antisera

In an effort to identify and characterize precursors of gastrin in tissues, we generated region-specific antisera against a synthetic progastrin peptide, Try-Gly-Trp-Met-Asp-Phe-Gly-Arg-Arg (GL9), as deduced from the nucleotide sequence of gastrin mRNA. This antisera did not cross-react with gastrin or progastrin peptides with shorter carboxyl-terminal extensions. Progastrin-like immunoreactivity (PGLI) was measured in porcine antrum at a concentration of 6.8 +/- 1.2 pmol/g wet weight (mean +/- SE, n = 5), or roughly 0.2% of that of gastrin. On Sephadex G50 chromatography, a major peak of PGLI was eluted as a slightly larger molecule than gastrin heptadecapeptide (G17) but possessed the same N-terminal immunoreactivity. These findings suggest that G17 may be formed by processing of a carboxyl-terminally extended precursor as an alternative to cleavage of big gastrin (G34).     

The fibronectin cell attachment sequence Arg-Gly-Asp-Ser promotes focal contact formation during early fibroblast attachment and spreading

Cultured fibroblasts form focal contacts (FCs) associated with actin microfilament bundles (MFBs) during attachment and spreading on serum- or fibronectin (FN)-coated substrates. To determine if the minimum cellular adhesion receptor recognition signal Arg-Gly-Asp-Ser (RGDS) is sufficient to promote FC and MFB formation, rat (NRK), hamster (Nil 8), and mouse (Balb/c 3T3) fibroblasts in serum-free media were plated on substrates derivatized with small synthetic peptides containing RGDS. These cultures were studied with interference reflection microscopy to detect FCs, Normarski optics to identify MFBs, and immunofluorescence microscopy to observe endogenous FN fiber formation. By 1 h, 72-78% of the NRK and Nil 8 cells plated on RGDS-containing peptide had focal contacts without accompanying FN fibers, while these fibroblasts lacked FCs on control peptide. This early FC formation was followed by the appearance of coincident MFBs and colinear FN fibers forming fibronexuses at 4 h. NRK and Nil 8 cultures on substrates coated with native FN or 75,000-D FN-cell binding fragment showed similar kinetics of FC and MFB formation. In contrast, the Balb/c 3T3 mouse fibroblasts plated on Gly-Arg-Gly-Asp-Ser peptide-derivatized substrates, or on coverslips coated with 75,000-D FN cell-binding fragment, were defective in FC formation. These results demonstrate that the apparent binding of substrate-linked RGDS sequences to cell surface adhesion receptors is sufficient to promote early focal contact formation followed by the appearance of fibronexuses in some, but not all, fibroblast lines.     

Lessons from the gastrin knockout mice

The gastrointestinal hormone, gastrin, was discovered a century ago as the second hormone in history. Subsequently, gastrin peptides have been identified and the genes encoding the hormone as well as its receptor have been cloned in several mammalian species including the mouse. This has facilitated the development of gastrin and gastrin receptor deficient mice as models for genetic dissection of the role of gastrins in maintaining gastric homeostasis and control of acid secretion. The gastrin knockout mice are achlorhydric due to inactivation of the ECL and parietal cells. Moreover, this achlorhydria is associated with the development of intestinal metaplasia and bacterial overgrowth, which ultimately lead to development of gastric tumors. Outside the stomach, gastrin deficiency alters pancreatic islet physiology and is associated with a moderate fasting hypoglycemia in the fasting state. But lack of gastrin does not impair islet regeneration. The association between progastrin, progastrin-derived processing intermediates and colorectal carcinogenesis has also been examined through genetic or chemical cancer induction in several mouse models, although the clinical relevance of these studies still remains to be proven. While others have focused on models of increased gastrin production, the present review will describe the lessons learned from the gastrin deficient mice. These mice help understand how dysregulation of gastrin secretion may be implicated in human disease.     

Rat progastrin processing yields peptides with altered potency at the CCK-B receptor

Details of prohormone processing patterns are revealed by purification and characterization of molecular forms stored in the tissues where the hormones are expressed. Molecular forms of rat gastrin were purified from antral extracts by gel permeation, anion exchange, and reverse-phase HPLC. Amidated and glycine-extended gastrins were detected with specific antisera and their structures determined by mass spectrometry. In rats, the only form shorter than gastrin-17 observed contained 16 amino acids. These data suggest that two enzymes process the amino terminus of gastrin-17. Pyrrolidone carboxylic acid peptidase removes the amino terminal pyrrolidone carboxylic acid (pyroGlu), forming gastrin-16. In mammals other than rat, gastrin-16 is then cleaved by dipeptidyl peptidase IV to form gastrin-14. In rat, this reaction does not take place because of proline residues Pro(2)-Pro(3)- in gastrin-16. Gastrin-16 is found in sulfated and nonsulfated forms and comprises 28% of the total gastrin immunoreactivity. Glycine-extended forms of gastrin-16 and gastrin-17 comprises 45% of the total gastrin immunoreactivity. The sulfated forms of gastrin-16 and gastrin-17 bind to the CCK-B receptor transfected into CHO cells with 10-fold higher affinity than the nonsulfated forms of these peptides. Therefore, processing of rat progastrin may modulate the expression of gastrin biological activity.     

Processing of the gastrin precursor. Modulation of phosphorylated, sulfated, and amidated products.

Post-translational processing of the precursor for rat gastrin yields products that include peptides phosphorylated at Ser96, amidated at Phe92, and sulfated at Tyr87 or Tyr103. The phosphorylation site is immediately adjacent to the processing point that gives rise to the biologically active amidated gastrins. We have examined changes in post-translational processing which occur in gastrin cells from rats that are physiologically stimulated (by feeding) or unstimulated (by fasting). Peptides were identified using site-directed radioimmunoassays and chromatographic systems that resolve phosphorylated, amidated, and sulfated progastrin products, including intermediates generated prior to amidation (i.e. C-terminal glycine-extended variants). Assays for Phe92-amidated peptides and for the C-terminal tryptic fragment of progastrin indicated decreases in the total tissue concentrations of immunoreactive peptide with fasting; in contrast, the tissue concentrations of glycine-extended biosynthetic intermediates were similar in fasted and fed rats. Taken together the data suggest a relative failure in amidation mechanisms in unstimulated cells. The endopeptidase cleavage of progastrin was not influenced significantly by fasting. However, the phosphorylation of peptide products containing Ser96 was depressed significantly in fasted rats. The proportions of amidated peptides sulfated at Tyr87 were generally lower than their corresponding glycine-extended biosynthetic precursors, but in both cases the proportion of peptide in the sulfated form was lower than for peptides sulfated at Tyr103. Feeding did not change the sulfation of amidated heptadecapeptide gastrin or its glycine-extended variant. The results suggest that the mechanisms determining phosphorylation and amidation of progastrin-related peptides depend on the patterns of stimulation of gastrin cells. The observation that decreased phosphorylation is associated with a failure to produce active amidated products is consistent with a regulatory function for phosphorylation in gastrin production.     

Prostaglandin E1 binding and adenylate cyclase activation in normal and transformed fibroblasts

The binding of [3H]prostaglandin E1 to membranes of clones of normal rat kidney fibroblasts (NRK cells) has been measured. Cell lines that responded to prostaglandin E1, such as NRK and NRK transformed with Schmitt-Ruppin strain of Rous sarcoma virus (SR-NRK cells), have a high affinity prostaglandin E1 binding site. Murine-sarcoma-virus-transformed lines of NRK cells are unresponsive to prostaglandin E1 and have reduced prostaglandin E1 binding Exposure of cells to prostaglandin E1 results both in decreased prostaglandin E1 responsiveness and reduced prostaglandin E1 binding. Activation of adenylate cyclase is correlated to binding of prostaglandin E1 to receptors in both NRK and SR-NRK cell membranes. Mathematical models suggest that GTP decreases the affinity of hormone for its receptor while increasing the catalytic efficiency of adenylate cyclase, and that aggregates of occupied receptors may play an important role in the activation of adenylate cyclase.     

Trimetazidine increases phosppholipid turnover in ventricular myocyte

Ehrlich ascites tumor cells incorporate [methyl-3H]thymidine into DNA independently of exogenous growth factors or fetal calf serum. Using an acid/ethanol extraction procedure we have obtained from these tumor cells a fraction that induces both the proliferation and the formation of cell foci by Swiss 3T3 mouse fibroblasts in the presence of insulin; inhibits the proliferation of Mv1Lu mink lung epithelial cells; and stimulates the growth of NRK rat kidney fibroblasts in soft-agar in the presence of epidermal growth factor. An antibody against transforming growth factor- (TGF) prevents both the tumor extract-induced proliferation of Swiss 3T3 fibroblasts and the tumor extract-induced proliferative arrest of Mv1Lu cells. The tumor cells secrete a TGF-like activity to the extracellular medium in a partially-activated form. However, authentic TGF does not affect their proliferation, and no TGF receptors were detected using [125I]TGF as a ligand. Therefore, the absence of TGF receptors with ligand-binding capacity in these tumor cells may bypass the negative control that this factor exerts on the proliferation of their normal cell counterparts.     

Spontaneous Conversion of Nontransformed Avian Sarcoma Virus-Infected Rat Cells to the Transformed Phenotype

Normal rat kidney (NRK) fibroblasts were infected with the Schmidt-Ruppin strain (SR-D) of avian sarcoma virus (ASV) and cloned 20 h after infection without selection for the transformed phenotype. Most infected clones initially exhibited the flat, nontransformed morphology that is characteristic of uninfected NRK cells. In long-term culture, however, the majority of the SR-D NRK clones began segregating typical ASV-transformed cells. Transforming ASV could be rescued by fusion with chicken embryo fibroblasts from most of the infected clones tested. Three predominantly flat, independently infected clones were further analyzed by subcloning 8 to 10 weeks after infection. Most flat progeny subclones derived at random from two of these "parental" SR-D NRK clonal lines did not yield virus upon fusion with chicken embryo fibroblasts, although a nondefective transforming ASV was repeatedly recovered from the parental clones. This observation suggested that most, but not all, daughter cells in these SR-D NRK clones lost the ASV provirus after cloning. The progeny of the third independent parental cell clone, c17, gave rise to both flat and transformed subclones that carried ASV. In this case, ASV recovery by fusion and transfection from the progeny subclones was equally efficient regardless of the transformation phenotype of the cells. The 60,000-dalton phosphoprotein product of the ASV src gene was, however, expressed at high level only in the transformed variants. The results of a Luria-Delbruck fluctuation analysis and of Newcombe's respreading test indicated that the event leading to the spontaneous conversion to the transformed state occurred at random in dividing cultures of these flat ASV NRK cells at a rate predicted for somatic mutation.     

Binding, surface mobility, internalization, and degradation of rhodamine-labeled alpha 2-macroglobulin

We have used quantitative fluorescence methods to examine the fate of rhodamine-labeled alpha 2-macroglobulin (R-alpha 2 M) after binding to cell-surface receptors on NRK and Swiss 3T3 cells. From measurements of fluorescence intensities in NRK cells fixed after incubation with R-alpha 2M, we found that uptake was saturable and that half-maximal uptake occurred at 130 nM R-alpha 2M. Fluorescence measurements on cell extracts of NRK and Swiss 3T3 cells also showed a half-maximal uptake of R-alpha 2M near 130 nM. We estimate that NRK cells can take up 10(6) molecules of R-alpha 2M per hour via receptor-mediated endocytosis. The mobility of alpha 2-macroglobulin receptors on the surface of Swiss 3T3 cells was measured by using fluorescence photobleaching recovery. The two-dimensional effective diffusion coefficient of R-alpha 2M receptors was approximately 8 X 10(-10) cm2 s-1, a value close to that previously obtained for insulin and epidermal growth factor receptors. Degradation of R-alpha 2M by the cells was followed by using the loss of fluorescence from the 185000-dalton band in sodium dodecyl sulfate--polyacrylamide gels. Rhodamine fluorescence was detected in the gels by using a microscope fluorescence spectrophotometer. NRK cells degraded alpha 2M to low molecular weight fragments with a t 1/2 of 15 min. Swiss 3T3 cells degraded about 75% of the alpha 2M with a t 1/2 of 1 h. The remaining 25% remained as the intact 185000-dalton peptide after 24 h. No significant accumulation of large breakdown products was observed in Swiss 3T3 or NRK cells.     

Flow cytometric detection of progastrin interaction with gastrointestinal cells

The unprocessed gastrin precursor, progastrin (PG), is often overexpressed in colon cancer and other malignancies where it appears to stimulate colonic growth. Overexpression of progastrin also stimulates proliferation of normal colonic mucosa, but the receptors mediating these effects have not been identified. Here we report the development of a non-radioactive assay for assessment of PG binding to normal and transformed cells. Progastrin was labeled using biotinylation, and binding of biotinylated PG to cells was assessed using flow cytometry. Using this approach, we show strong and specific binding of PG to some cell lines (IEC-6, IEC-18, HT-29, COLO320) and minimal binding to others (HeLa, DC2.4, Jurkat). We also found PG binding to several non-gut epithelial lines, such as CHO-K1, COS-6 and HEK293 cells. The specificity of binding was confirmed by competition with cold, unlabeled PG but not with glycine-extended gastrin or amidated gastrin-17. Binding was not influenced by the presence of the classical CCK-2 receptor, but was partially dependent on the charged glycosaminoglycans (GAG). The analysis of primary colonic tissues isolated from wild type C57BL/6 mouse, revealed a small epithelial subpopulation of non-hematopoietic (CD45-negative) cells that strongly interacted with PG. Surprisingly, this population was greatly expanded in gastrin knockout mice. This non-radioactive, FACS-based assay should prove useful for further characterization of cells expressing the progastrin receptor.     

Ferric ions inhibit proteolytic processing of progastrin

The gastrointestinal hormone gastrin is generated from an 80 amino acid precursor (progastrin) by cleavage after dibasic residues by prohormone convertase 1. Phosphorylation of Ser₇₅ has previously been suggested, on the basis of indirect evidence, to inhibit cleavage of progastrin after Arg₇₃Arg₇₄. Gastrins bind two ferric ions with high affinity, and iron binding is essential for the biological activity of non-amidated gastrins in vitro and in vivo. This study directly investigated the effect of iron binding and of serine phosphorylation on the cleavage of synthetic progastrin-derived peptides. The affinity of synthetic progastrin_55–80 for ferric ions, and the rate of cleavage by prohormone convertase 1, were not affected by phosphorylation of Ser₇₅. In contrast, in the presence of ferric ions the rate of cleavage of both progastrin_55–80 and phosphoSer₇₅progastrin_55–80 by prohormone convertase 1 was significantly reduced. Hence iron binding to progastrin may regulate processing and secretion in vivo, and regulation may be particularly important in diseases with altered iron homeostasis.     

Distinguishing bombesin receptor subtypes using the oocyte assay.

Physiological responses to mammalian bombesin-like peptides were studied in Xenopus oocytes injected with mRNA isolated from Swiss 3T3 cells and rat esophagus in order to identify and characterize bombesin receptor subtypes. Both groups respond similarly to either gastrin releasing peptide or neuromedin B, but only the response to neuromedin B in oocytes expressing the esophagus mRNA is not blocked by a specific gastrin releasing peptide receptor antagonist, des-Met-[D-Phe6]Bn(6-13) ethyl ester. Complete desensitization of gastrin releasing peptide-evoked responses in oocytes expressing esophagus mRNA does not abolish neuromedin B-evoked responses. A single application of neuromedin B abolishes responses to subsequently applied gastrin releasing peptide in oocytes expressing esophagus, but not Swiss 3T3, mRNA. RNA blot hybridization studies using a Swiss 3T3 gastrin releasing peptide receptor cDNA probe show no detectable hybridization in esophagus mRNA samples. These data suggest that a gastrin releasing peptide receptor is expressed in the esophagus and that it is distinct from that expressed in Swiss 3T3 cells and may represent a third subtype of mammalian bombesin receptor.     

PPARalpha agonists stimulate progastrin production in human colorectal carcinoma cells

The three subtypes of peroxisome proliferator activated-receptors (PPARalpha, delta and gamma) control the storage and metabolism of fatty acids. Treatment of rats with the PPARalpha ligand ciprofibrate increases serum gastrin concentrations, and several lines of evidence suggest that non-amidated gastrins act as growth factors for the colonic mucosa. The aim of the present study was to investigate the expression of PPARs and the effect of PPAR ligands on gastrin production and cell proliferation in human colorectal carcinoma (CRC) cell lines. mRNAs for all three PPAR subtypes were detected by PCR in all CRC cell lines tested. The concentrations of progastrin, but not of glycine-extended or amidated gastrin, measured by radioimmunoassay in LIM 1899 conditioned media and cell extracts were significantly increased by treatment with the PPARalpha ligand clofibrate. Similar increases in progastrin were seen following treatment with the PPARalpha ligands ciprofibrate and fenofibrate, but not with bezafibrate, gemfibrozil or Wy 14643. The PPARgamma agonist rosiglitazone had no significant effect on progastrin production. The PPARalpha ligand clofibrate also stimulated proliferation of the LIM 1899 cell line. We conclude that some PPARalpha ligands increase progastrin production by the human CRC cell line LIM 1899, and that clofibrate increases proliferation of LIM 1899 cells. These studies have revealed a relationship between PPARs and gastrin, two regulatory molecules implicated in the pathogenesis of CRC.     

Identification and characterization of glycine-extended post-translational processing intermediates of progastrin in porcine stomach

We developed a radioimmunoassay specific for glycine-extended progastrin processing intermediates (G-Gly) using antisera generated against the synthetic peptide Tyr-Gly-Trp-Met-Asp-Phe-Gly. Distribution of immunoreactivity in the porcine gastrointestinal tract obtained with this antibody paralleled that of gastrin with the mucosa containing the highest quantity, 116 +/- 22 pmol/g, wet weight (mean +/- S.E., n = 5), or roughly 4% of gastrin concentration. This immunoreactivity was localized specifically to antral mucosal G-cells by immunohistochemistry. On Sephadex G-50 column chromatography of porcine antral mucosal extracts glycine-extended progastrin processing intermediates were separated into three principal molecular forms, each corresponding to known molecular forms of gastrin, component I, tetratriacontagastrin (G34) and heptadecagastrin (G17). Following purification by antibody-coupled affinity chromatography, one molecular form corresponding to G17 in size was shown to have an amino terminus identical to that of G17. Another molecular form corresponding to G34 in size could be converted to the molecular form corresponding to G17 by tryptic digestion. Our findings indicate that glycine-extended progastrin processing intermediates may serve as immediate precursors for each molecular form of gastrin, thus suggesting an alternative pathway for gastrin biosynthesis more complex than that previously conceived.     

Type beta transforming growth factor from feline sarcoma virus-transformed rat cells. Isolation and biological properties

We have isolated a strongly mitogenic, type beta transforming growth factor (beta TGF) released by Snyder-Theilen feline sarcoma virus-transformed rat embryo (FeSV-Fre) cells that induces phenotypic transformation of normal NRK cells when they are concomitantly stimulated by analogues of epidermal growth factor (EGF). Molecule filtration chromatography separates beta TGF from an EGF-like TGF (eTGF) which is also present in acid extracts from medium conditioned by FeSV-Fre cells (J. Massagué, (1983) J. Biol. Chem. 258, 13606-13613). Final purification of beta TGF is achieved by reverse phase high pressure liquid chromatography (HPLC) on octadecyl support, molecular filtration HPLC, and nonreducing dodecyl sulfate-polyacrylamide gel electrophoresis steps, yielding a 300,000-fold purified polypeptide with a final recovery of 21%. The purified rat beta TGF consists of two Mr = 11,000-12,000 polypeptide chains disulfide-linked as a Mr = 23,000 dimer. Induction of anchorage-independent proliferation of NRK cells by rat beta TGF depends on the simultaneous presence of eTGF or EGF. In the presence of a saturating (300 pM) concentration of either rat eTGF or mouse EGF, half-maximal anchorage-independent proliferation of NRK cells is obtained with 4-6 pM rat beta TGF. In the presence of a saturating (20 pM) concentration of rat beta TGF, half-maximal anchorage-independent proliferation of NRK cells is obtained with either rat eTGF or mouse EGF at a 50-70 pM concentration. Rat beta TGF is also able to induce DNA synthesis and cell proliferation on growth-arrested NRK, human lung, and Swiss mouse 3T3 fibroblast monolayers, this effect being half-maximal at 2-3 pM beta TGF for NRK cells. These results identify eTGF and beta TGF as the two synergistically acting factors responsible for the transforming action of culture fluids from FeSV-Fre cells.