Coordinated control of fetal gastric epithelial functions by insulin-like growth factors and their binding proteins.

The influence of insulin-like growth factors (IGFs) and their binding proteins (IGFBPs) on human gastric functions are unknown. This study was undertaken to evaluate the ability of fetal gastric mucosa to produce IGFBPs and to test the effects of IGF-I, IGF-II, and synthetic truncated IGFs that do not interact with IGFBPs on epithelial cell proliferation and glandular zymogenic function. Western blots, Far Western blots, and immunohistochemistry were performed to characterize the expression of IGFBP-1 to -6 and IGF-I receptor. The effects of growth factors on DNA synthesis and lipase and pepsin activities were determined in gastric explants maintained in serum-free organ culture. All gastric epithelial cells expressed the IGF-I receptor. IGFBP-2 to -6 were produced endogenously, and they were differentially localized along the foveolus-gland axis and modulated in culture. Exogenous IGF-I and IGF-II were able to reduce lipase activity without affecting pepsin, whereas they exerted different effects on cellular proliferation: IGF-I was stimulatory and IGF-II had no influence. Illustrating the complex regulatory effect that IGFBPs exert on IGF bioactivity, both truncated IGF-I and IGF-II stimulated DNA synthesis more than IGF-I. Moreover, the striking difference in mitogenic activity between truncated and native forms of IGF-II probably reflects the abundance of IGFBP-2 and IGFBP-6, two IGF-II carriers, in the foveolus/neck region, including the proliferative compartment. This study provides new evidence for the involvement of an intragastric IGF/IGFBP system in the fine regulation of epithelial cell division and also in the control of zymogen synthesis. Moreover, the specific influence of IGF-II as a mitogen appears to be tightly regulated by IGFBP isoforms preferentially associated with this growth factor and proliferative cells.

Gastric cancer cell lines as models to study human digestive functions.

The present investigation aims at defining the functional status of several gastric cancer cell lines in order to assess their usefulness as adequate cellular models to study the regulation of gastric digestive functions. Compared to AGS, Hs746t and KATO-III cells, NCI-N87 exhibited an unique differentiation status. They formed coherent monolayers expressing E-cadherin and ZO-1 junctional proteins; their integrity and epithelial morphology were maintained at post-confluency for up to 10 days. All cell lines synthesized PAS-reactive (mucous-type) glycoconjugates. However, only NCI-N87 cells expressed MUC6 glycoprotein suggesting a mucopeptic phenotype. Immunostaining, enzymatic assays, Western blotting and Reverse Transcriptase polymerase chain reaction (RT-PCR) revealed that all cell lines contained varying levels of pepsinogen (Pg5) and human gastric lipase (HGL). Only NCI-N87 cells were able to express zymogens at higher levels, in granule-like structures, and to efficiently secrete both HGL and Pg5. The addition of epidermal growth factor (EGF) to post-confluent NCI-N87 cells, which exhibit an abundant membrane staining for EGF-receptors, modulated HGL activity without affecting Pg5. In conclusion, this investigation enlightens the potential usefulness of the gastric cell line NCI-N87 as a model for elucidating the cellular and molecular mechanisms involved in the regulation of human gastric epithelial functions.

Expression of integrin subunits correlates with differentiation of epithelial cell lineages in developing human gastric mucosa.

Laminins may play important roles in gastric gland development due to the differential localization of their alpha chains in human fetal fundic (oxyntic) mucosa. To extend this hypothesis, the current investigation was undertaken to compare the anatomical and cellular distribution of epithelial integrin subunits with those of laminin alpha chains in the human stomach at different ages (8-22 weeks of gestation) using indirect immunofluorescence. In the body, fundus and antrum regions, the beta1 and alpha6 subunits were associated with the entire epithelium at all developmental stages in the same way as laminin chains (alpha1/alpha5) detected with 4C7 monoclonal antibody. By contrast, the alpha3 and beta4 subunits of alpha3beta1 and alpha6beta4 integrins together with the laminin alpha3-chain were concentrated in the surface and foveolus compartments composed of differentiating mucous cells. Most importantly, the alpha2 integrin subunit was expressed in a rather complex pattern: (1) it was located at the base and at cell-cell boundaries of surface/foveolar epithelium, (2) was specifically repressed in differentiating parietal cells, and (3) its expression increased in maturing glands, where it became concentrated at the basal pole of epithelial cells simultaneously exhibiting a strong reactivity for laminin-2 (alpha2-chain). Taken altogether, our observations provide new evidence for the implication of different laminins and their receptors in the development of all human gastric epithelial lineages, surface mucous cells or glandular cells. The coordinated expression of alpha2 and alpha3 integrin subunits as well as the cellular re-distribution of alpha2beta1 integrin likely represent key events for the differentiation of glandular secretory cell types, especially maturing chief cells responsible for the synthesis/secretion of gastric digestive enzymes in fundic-type glands.

Functional characterization of the keratinocyte growth factor system in human fetal gastrointestinal tract.

Keratinocyte growth factor (KGF) is a paracrine growth factor whose mRNA has been detected in human adult and rodent gut tissues together with its associated receptor. Our objectives were to assess the presence of immunoreactive KGF ligand and receptor proteins in human fetal gastrointestinal (GI) tract segments and to evaluate the role of exogenous KGF on cell proliferation and intestinal digestive functions. KGF (26-28 kD doublet) was identified in esophagus, stomach, small intestine, and colon by Western blot. Its receptor (135 kD) was ubiquitously detected in proliferative and differentiated epithelial cells of each GI segment by use of indirect immunofluorescence (anti-bek, anti-K-sam). The addition of KGF to explants cultured in serum-free conditions greatly stimulated DNA synthesis in all GI tract tissues. The growth factor up-regulated intestinal sucrase-isomaltase and gamma-glutamyl-transpeptidase activities in jejunal explants, whereas it down-regulated these activities in colon explants. It is suggested that the KGF system likely represents an important paracrine pathway that is able to stimulate cell proliferation in all segments of the human fetal GI tract and to differentially regulate intestinal digestive functions.

A new primary culture system representative of the human gastric epithelium.

The gastric pit-gland unit is a highly dynamic and compartimentalized structure which assumes important key functions such as acid secretion, digestion of dietary proteins and triglycerides, protection, and epithelial restitution following injury. However, in vitro models representative of the intact gastric epithelium are still lacking. The current study was undertaken to investigate the possibility of generating such primary cultures from human fetal stomach. The use of Matrisperse, a nonenzymatic solution, allowed complete dissociation of the epithelial layer and the maintenance for at least 7 days of all gastric epithelial cell types in primary culture on plastic. Indirect immunofluorescence and Western blot analyses confirmed the purity of epithelial cultures, composed of 60% mucus-secreting cells, 25% zymogenic chief cells, 5% parietal cells, and a small proportion of mitotic precursors. Their functionality was demonstrated by the presence of zonulae occludens and adherens at cell to cell contacts, [(3)H]thymidine incorporation, Periodic acid Schiff staining, and expression of growth factor receptors (EGF/TGFalpha, IGF1, HGF, KGF), gastric H(+)/K(+)-ATPase, pepsinogen (Pg5), and human gastric lipase (HGL). Chief cells were able to produce and secrete both Pg5 and HGL and to respond to EGF treatment. In conclusion, we developed a new primary culture system of human gastric epithelium characterized for the first time by the absence of added matrix and the maintenance of functional chief cells. It represents an experimental breakthrough that will serve applications in investigating the actions of hormones, mesenchymal growth factors, and basement membrane proteins on human gastric functions in vitro.

Loss of Hoxa5 gene function in mice perturbs intestinal maturation.

The Hox gene family of transcription factors constitutes candidate regulators in the molecular cascade of events that governs establishment of normal terminal differentiation along the duodenum to colon axis. One member of this family, Hoxa5, displays a dynamic pattern of expression during gut development. Hoxa5 transcripts are present in midgut mesenchyme at the time of remodeling, supporting a role for this gene in digestive tract specification. To study the role of Hoxa5 in proper intestinal development and maturation, we examined whether Hoxa5 mutant mice exhibit any defect in this process. We report here that even though Hoxa5 is not required for midgut morphogenesis, its loss of function perturbs the acquisition of adult mode of digestion, which normally is temporally coordinated with the process of spontaneous weaning. Impaired maturation of the digestive tract might be related to altered specification of intestinal epithelial cells. Our findings provide evidence that Hoxa5 expression in the gut mesoderm is important for the region-specific differentiation of the adjacent endoderm.

Ontogeny of EGF receptors in the human gut.

Epidermal growth factor and related substances mediate their effects on epithelial cells through binding to high-affinity receptors (EGF-R) at their basolateral surface and it is hypothesized that this growth factor system play a major role in gut morphogenesis and maintenance. The current review emphasizes on analyzing the expression and the biochemical characteristics of EGF-R in human fetal gut segments and correlating the biological actions of EGF-R ligands. They appear to be primarily involved in the local regulation of epithelial cell proliferation in which EGF-R are abundant. Alternatively, EGF-R ligands exert some precocious maturative effects by increasing intestinal lactase activity and decreasing brush border hydrolases in colon while they down modulate the expression of segment-specific markers of terminal differentiation such as sucrase, trehalase and glucoamylase in the intestine and chief cell lipase in the stomach. Such effects are consistent with the identification of receptors at the surface of all epithelial cell types, illustrating the modulatory role of EGF on differentiated gut epithelial cells. Comparison with animal models illustrates similar biochemical properties of receptors and underlines physiological aspects specific to human gut development. The relevance for ligand heterogeneity is also discussed and tentatively associated with different delivery pathways or physiological responses.

Mitogenic effects of EGF/TGF alpha and immunolocalization of cognate receptors in human fetal kidneys.

The involvement of epidermal growth factor (EGF) and homologous transforming growth factor (TGF) in human kidney development was studied by analyzing their effects on the regulation of DNA synthesis in organ culture and by localizing their cognate receptors. Both peptides significantly increased 3H-thymidine incorporation when added at 10-100 ng/ml, but not at 1-5 ng/ml. Furthermore, addition of an anti-EGF receptor antibody not only reduced the effect of exogenous EGF (100 ng/ml) on DNA synthesis but decreased basal 3H-thymidine incorporation. These results indicate that EGF/TGF alpha are both mitogenic in vitro and further suggest that human fetal kidneys release an endogenous EGF-related substance masking the effects of low amounts of growth factors added to culture medium. Radioautographic analyses show that EGF (100 ng/ml) increased DNA synthesis in poorly-differentiated cells of the nephrogenic zone, particularly in subcapsular mesenchyme and peritubular cells; although less responsive, epithelial cells in early nephric tubules represented another target of EGF action. The pattern of EGF/TGF alpha receptor expression was revealed immunohistochemically at different gestational ages and was shown to be related to the proliferation status. It was maximal in condensing nephrogenic cells, relatively high in newly-induced epithelium and cortical branches of ureteric epithelium, low in differentiating nephronic cells and nearly absent from renal stroma and medullary collecting ducts. Together, our results indicate that the EGF/TGF alpha system is directly involved in the regulation of nephrogenic cell proliferation during human metanephrogenesis and it is progressively down-regulated after conversion of mesenchyme into epithelium.

Pasteurella multocida toxin stimulates mitogenesis and cytoskeleton reorganization in Swiss 3T3 fibroblasts.

Pasteurella multocida toxin (PMT) causes cytoplasmic retraction in epithelial cells, activates osteoclast neoformation, and is a potent mitogen for Swiss 3T3 fibroblasts. In the present study designed to further investigate the effects of PMT on cell shape and proliferation, we report that the mitogenic effect of affinitypurified PMT on quiescent 3T3 cells was even superior at 5 ng/ml to that of fetal bovine serum or bombesin. This positive effect was inhibited by heat denaturation and methylamine treatment (this agent blocks internalization). Preincubation of PMT with gangliosides GM1, GM2, or GM3 counteracted its effect on DNA synthesis, suggesting that the toxin binds to GM-type ceramides on target cells. The distribution of F-actin was analyzed in control/treated cells using FITC-conjugated phalloidin. In comparison with FBS and bombesin, PMT triggered a more rapid and profound reorganization of cortical actin into prominent stress fibers after only 5-10 min. This event lead to the retraction of cells after only 30 min and ultimately to the induction of mitotic figures. Interestingly, methylamine blocked the effects of PMT on stress fiber formation and cell retraction but not the ruffling response, suggesting that some early events may not require toxin internalization. In summary, these findings indicate that PMT concomitantly exerts a strong mitogenic activity and a rapid stimulation of cytoskeletal rearrangements, possibly after binding to membrane gangliosides and subsequent internalization. We propose that this toxin could be used in the future as a defined inducer of transduction signals involved in cellular proliferation and control of cell shape.

Okadaic acid interferes with the maturation of human fetal kidney in serum-free culture.

A chemically-defined culture model has been established in our laboratory, enabling the study of the respective effects of growth factors on the developing kidney. Since this system involves the use of defined medium unsupplemented with serum, hormones or glucose, these limited conditions induce a decrease in DNA synthesis. Addition of insulin and transferrin significantly restores this important cellular function. The objective of the present study was to verify the influence of okadaic acid, a specific inhibitor of protein phosphatases 1 and 2A, in order to determine whether the latter modulate insulin action on human fetal kidney. Okadaic acid was found to decrease 3H-thymidine incorporation below control (L-15) levels in a dose-dependent manner. The influence of 0.01 microM okadaic acid could be detected as early as the 4th h of culture, and was progressive until the 48th h; at 0.4 microM, the effect was more dramatic with maximum inhibition obtained between 8 and 12 h. Moreover, at both concentrations, the drug completely abolished the stimulating effect of insulin plus transferrin over a 5-day period. Following removal of the toxin after 24 h of culture, DNA synthesis after 5 days still remained at levels observed in the presence of okadaic acid and insulin plus transferrin on day 1. This result indicates that the inhibitory influence of okadaic acid remained at the same level once the drug was removed, and that this effect is irreversible. In addition, okadaic acid at 0.4 microM induced cell death and morphological changes possibly associated with apoptosis.(ABSTRACT TRUNCATED AT 250 WORDS)

Positive influence of tetracycline on human fetal kidney in serum-free organ culture.

Human fetal kidney explants can be maintained during 5 days in Leibovitz's L15, a basic serum-free medium. Because culture conditions are minimal for growth and differentiation, DNA synthesis drastically decreases during the first 48 h, but stabilizes thereafter. The addition of insulin plus transferrin significantly restores this important cellular function in kidneys of fetuses younger than 16 wk. However, renal explants from older fetuses are more difficult to culture: they respond less to growth factors and are more prone to necrosis. The objective of this study was to verify the influence of tetracycline, an antibiotic with anti-collagenase potential, on cultured kidney explants aged 17 to 20 wk. The addition of 20 micrograms/ml tetracycline did not influence DNA synthesis nor the effectiveness of insulin plus transferrin on cell proliferation. Nor did it change the activities of alkaline phosphatase and gamma-glutamyltransferase, two enzymic markers of brush border differentiation. After 5 days in L15 alone, explants often showed necrosis and an important reduction in both weight and volume. Insulin plus transferrin significantly restored these parameters to control values observed at Day 0, but evidence of necrosis was still present. Tetracycline alone markedly reduced explant necrosis resulting in a significant increase in weight and volume. The effectiveness of insulin plus transferrin on explant morphometry was not improved when tetracycline was added as third factor. These results indicate that insulin plus transferrin restores explant mass through cell proliferation, whereas tetracycline does so possibly through a reduction in extracellular matrix degradation. The two effects are not additive in cultured mid-term fetal kidneys.

Synergistic bombesin and insulin stimulation of DNA synthesis in human fetal kidney in serum-free culture.

The respective influences of growth factors during kidney development can be directly evaluated using the chemically-defined serum-free culture system perfected in our laboratory. Since, in this culture model, conditions are minimal for growth and differentiation, DNA synthesis sharply decreases during the first 48 h. The addition of epidermal growth factor (EGF, 100 ng/ml), insulin (5 micrograms/ml) and transferrin (5 micrograms/ml) significantly restores this important cellular function. The objective of the present study was to determine the influence of bombesin, a potent mitogen, supplemented alone or in combination with insulin, transferrin and/or EGF. Cortical explants of human fetal kidneys (17-20 weeks) were maintained during 5 days in culture. When compared with 5 day controls (L-15 medium only), bombesin generated a maximal though weak effect on DNA synthesis at a concentration of 0.3 nM, corresponding to a stimulation index (SI) of 22%. When combined with either transferrin or EGF, or with transferrin plus EGF, bombesin did not alter the SI of individual factors. Insulin, in turn, greatly increased DNA synthesis (SI = 169%), while bombesin strongly potentiated this effect (SI = 275%). Transferrin also enhanced insulin SI from 169 to 240%. When added as a third factor, bombesin further potentiated the effectiveness (SI = 338%) of the combination insulin plus transferrin. These results indicate that bombesin controls cell proliferation in synergism with other regulators and hence may act as a competence growth factor during nephrogenesis.

Growth regulatory properties of endothelins.

Endothelins are produced by endothelial and epithelial cells, macrophages, fibroblasts, and many other types of cells. Their receptors are present in numerous cells, including smooth muscle cells, myocytes, and fibroblasts. Evidence now suggests that the three isoforms of endothelins (ET-1 and the other two related isopeptides, ET-2 and ET-3) regulate growth in several of these cells. Endothelin-1 influences DNA synthesis, the expression of protooncogenes, cell proliferation, and hypertrophy. The participation of ET in mitogenesis involves activation of multiple transduction pathways, such as the production of second messengers, the release of intracellular pools of calcium, and influx of extracellular calcium. Moreover, ET-1 acts in synergism with various factors, such as EGF, PDGF, bFGF, TGFs, insulin, etc., to potentiate cellular transformation or replication. Several of these factors may in turn stimulate the synthesis and/or the release of endothelins. The production and release of endothelins are also increased in acute and chronic pathological processes, e.g., atherosclerosis, postangioplastic restenosis, hypertension, and carcinogenesis. It is postulated that endothelins act in a paracrine/autocrine manner in growth regulation and play an important role mediating vascular remodeling in some cardiovascular diseases. The present review analyses the implication of endothelins (ET-1, -2, and -3) in physiopathology related to their growth regulatory properties.

Minimal growth factor requirements of human fetal kidney in serum- and glucose-free culture.

The addition of insulin plus transferrin to Leibovitz's L-15 medium was previously shown to restore important cellular functions in a serum-free system developed in our laboratory for human fetal kidney explants. The objective of the present study was to compare the effectiveness of this insulin plus transferrin combination with one used in other in vitro systems whereby serum is substituted by a mixture of five hormones (insulin, transferrin, hydrocortisone, triiodothyronine and prostaglandin E1). In fetal kidney it was found that the combination of insulin plus transferrin was as effective as the five-hormone mixture on DNA synthesis after 5 days of culture and was even more effective in younger fetuses (10-13 weeks) compared with older fetuses (16-19 weeks). However, protein synthesis was more sensitive to the five-hormone combination. Selective deletion of individual hormones showed that insulin is the essential factor for the growth of cultured kidney explants. Differentiation of brush border membranes in nephrons, as evaluated by alkaline phosphatase and gamma-glutamyl-transferase activities, was not significantly modified by either of the two combinations. The present results indicate that insulin plus transferrin represents the optimizing condition for our culture model. The response to supplements varies according to fetal age and possibly to tissue proliferation states and/or cell type.

Insulin alters cell proliferation during the early development of rodent kidney.

The effects of insulin on early differentiated 15-day fetal mouse kidneys were assessed using an organotypic culture system. High concentrations (30 to 125 mU/ml) of the hormone drastically reduced (50%) the incorporation of 3H-thymidine in replicating cells without affecting either differentiation of forming nephrons or epithelio-mesenchymal relationships. When compared to insulin-like growth factor-I or the potent phorbol ester PMA, the action of insulin seemed to specifically deregulate some components of the transductional machinery controlling cell proliferation. This is opposed to the previous demonstration of a positive influence of insulin on cell proliferation in the human fetal kidney. The results suggest that the common definition of insulin as a fetal growth promoter may depend on the developmental stage of each organ, particularly for the mammalian kidney.

Synergistic influence of epidermal growth factor, insulin and transferrin on human fetal kidney in culture.

In human fetal kidneys (15-21 weeks of gestation) maintained in serum-free organ culture, protein synthesis remained relatively constant, but DNA synthesis decreased dramatically after 2 days. The addition of transferrin alone had no influence, but insulin and epidermal growth factor (EGF) both significantly stimulated DNA and protein synthesis. When supplemented in combination, transferrin strongly potentiated the insulin effect and after 5 days of culture DNA synthesis was practically restored to values observed in control uncultured renal explants (day 0). When EGF, a potent mitogen, was added as a third factor, the stimulating effectiveness of the (insulin plus transferrin) combination was significantly reduced. However, EGF had no such inhibiting influence on protein synthesis. Differentiation of brush border membranes, as evaluated by hydrolase activities, was not importantly induced nor retarded by any of the three factors supplemented either alone or in combination. The present results indicate that the individual effects of the three factors are not additive, but suggest that they rather act synergistically through a complex mechanism of receptor cross-talk. In our laboratory, there is convincing indication that the response of fetal organs varies according to age, proliferative state of tissues as well as stage of differentiation.

Insulin and transferrin restore important cellular functions of human fetal kidney in serum-free organ culture.

A model previously developed in our laboratory to culture human fetal kidneys in serum-free chemically defined medium was used to evaluate the direct influence of potential regulators on nephrogenesis. The aim of the present work was to verify the effects of insulin and transferrin, two hormones considered as essential in other serum-free culture systems. Explants of renal cortex from human fetuses (15-21 weeks) were cultured for 2 and 5 days in serum-free Leibovitz's L-15 medium (37 degrees C, 95% air - 5% CO2). The addition of transferrin (5 micrograms/mL) had no effect, but insulin (30, 60, and 125 mU/mL) increased DNA and protein syntheses in a dose-dependent manner. The influence of insulin (125 mU/mL) was potentiated by the addition of transferrin and the combination of the two stimulated DNA synthesis by threefold on day 2 when compared with controls and by sixfold on day 5 of culture. After 5 days, synthesis was restored to values observed at day 0. Transferrin did not modify the insulin effect on protein synthesis, since the latter was already maximally stimulated as early as day 2 of culture and at levels well above that of uncultured explants (day 0). The activities of four hydrolases considered as markers of brush border differentiation were not importantly changed by any of the hormones, supplemented alone or in combination. The results indicate that proliferation rather than differentiation is the parameter mostly influenced by these two hormones. The combination of insulin plus transferrin restores cellular functions of human fetal kidney explants cultured in serum-free medium.(ABSTRACT TRUNCATED AT 250 WORDS)

Integration of proliferation and differentiation phenomena during rodent kidney ontogeny.

In order to integrate proliferation and differentiation patterns during kidney development, precise ontogenic profiles of several morphometric and biochemical parameters were determined in the mouse. During early nephron formation (before the age of 15 days postnatal), rates of kidney growth and cell proliferation proceed in an independent fashion. DNA synthesis, as measured by 3H-thymidine incorporation, falls rapidly during early metanephrogenesis and is characterized by 3 transitional phases or plateaus. On the other hand, brush border enzyme activities, namely alkaline phosphatase and gamma-glutamyltransferase, increase progressively during this period, although both ontogenic profiles also reveal 3 distinct transitory phases. The plateaus occur synchronously: all are initiated at 16 days of gestation, at birth and at 6 days postnatally. During the final phase of metanephrogenesis (from 15 days onward), kidney and body weights now increase proportionally. In fact, kidney/body (K/B) weight ratios remain remarkably uniform, as defined by the function: K = 12.1 x B.84. Considered together, these results demonstrate that global metanephric development can be separated into early and final stages. The early stage is characterized by complex organo-genetic processes in which proliferation and differentiation profiles seem to be reciprocally related. The late phase, on the other hand, is associated with the interruption of nephronic induction and a constant relationship between organ weight and body weight. Establishing precise developmental profiles of nephronic proliferation and differentiation should provide for a better understanding of metanephrogenesis regulation.

Fetal mouse kidney maturation in vitro: coordinated influences of epidermal growth factor, transferrin and hydrocortisone.

We have investigated the individual and combined actions of epidermal growth factor (EGF), transferrin and hydrocortisone on the maturation of whole fetal mouse metanephroi maintained in serum-free conditions for up to 5 days. The presence of EGF (100 ng/ml) resulted in elevated levels of [3H]-thymidine incorporation when compared to controls; autoradiograms showed that the proliferation of mesenchymal cells in the nephrogenic zone is particularly enhanced as verified by cell counting. Brush border hydrolase activities (alkaline phosphatase and gamma-glutamyltransferase), on the other hand, were significantly diminished. Transferrin (5 micrograms/ml) slightly stimulated DNA synthesis and potentiated EGF mitogenic action. The activation of DNA replication by the growth factor seems to be mediated through the protein kinase C pathway. When added alone, hydrocortisone (10(-6) M) strongly inhibited DNA synthesis, stimulated hydrolase activities and exerted a positive effect on brush border differentiation. When combined with EGF or to EGF + transferrin, hydrocortisone counteracted the effects of these latter peptides on DNA synthesis and enzyme activities. Considering the earlier observation of a reciprocal relation between proliferation and differentiation during the neotubulogenic phase of kidney development, the results described in the current study suggest that synergistic and synarchic actions of these heterologous factors are involved in the regulation of tubulogenesis.

Secretion of gamma-glutamyltranspeptidase by the pancreas: evidence for a membrane shedding process during exocytosis.

Gamma Glutamyltranspeptidase (GGT) is a membrane-bound enzyme involved in glutathione metabolism. It is present in rat exocrine pancreas at a level which is only exceeded by the kidney. It has been previously shown that most of the enzyme activity is located in the apical area of the acinar cell, more precisely at the level of zymogen granules and plasma membrane. The aim of the present study was to examine the secretory behavior of that enzyme. Under resting conditions, in vivo, high levels of GGT were found in pancreatic juice and its level was not related to protein concentration. Under secretin infusion, a relatively constant level of GGT was released, and again, there was no correlation between enzyme activity and protein concentration. Following a bolus injection of caerulein, an analog of cholecystokinin, marked and concomitant rises in protein and GGT levels were observed. Ultracentrifugation, as well as gel filtration on Sepharose 4B, demonstrated that the enzyme was not released in a soluble form. This observation is in agreement with in vitro determinations on isolated zymogen granules showing that GGT is totally associated with the ZG membrane and undetect-able in the content of these organelles. The present data show that 1 degree GGT is released from the rat pancreas acinar cells in a particulate form; 2 degree GGT release is elicited by hormonal stimulation coinciding with the exocytotic release of secretory proteins. Our observations lead us to propose that in rat pancreas, ZG membrane fragments are released along with secretory proteins during exocytosis.