Identification of clathrin and clathrin adaptors on tubulovesicles of gastric acid secretory (oxyntic) cells

gamma-Adaptin and clathrin heavy chain were identified on tubulovesicles of gastric oxyntic cells with the anti-gamma-adaptin monoclonal antibody (MAb) 100/3 and an anti-clathrin heavy chain MAb (MAb 23), respectively. In Western blots, crude gastric microsomes from rabbit and rat and density gradient-purified, H-K-ATPase-rich microsomes from these same species were immunoreactive for gamma-adaptin and clathrin. In immunofluorescent labeling of isolated rabbit gastric glands, anti-gamma-adaptin and anti-clathrin heavy chain immunoreactivity appeared to be concentrated in oxyntic cells. In primary cultures of rabbit oxyntic cells, the immunocytochemical distribution of gamma-adaptin immunoreactivity was similar to that of the tubulovesicular membrane marker in oxyntic cells, the H-K-ATPase. Further biochemical characterization of the tubulovesicular gamma-adaptin-containing complex suggested that it has a subunit composition that is typical of that for a clathrin adaptor: in addition to the gamma-adaptin subunit, it contains a beta-adaptin subunit and other subunits of apparent molecular masses of 50 kDa and 19 kDa. From solubilized gastric microsomes from rabbit, gamma-adaptin could be copurified with the major cargo protein of tubulovesicles, the H-K-ATPase. Thus this tubulovesicular coat may bind directly to the H-K-ATPase and may thereby mediate the regulated trafficking of the H-K-ATPase at the apical membrane of the oxyntic cell during the gastric acid secretory cycle. Given the similarities of the regulated trafficking of the H-K-ATPase with recycling of cargo through the apical recycling endosome of many epithelial cells, we propose that tubulovesicular clathrin and adaptors may regulate some part of an apical recycling pathway in other epithelial cells.

Cell lineage relationship in the stomach of normal and genetically manipulated mice

The oxyntic mucosa of the mouse stomach is lined with a heterogeneous population of cells that form numerous short pits continuous with long tubular glands. Tritiated thymidine radioautography has made it possible to pinpoint the origin of all cell types and to follow the differentiation/migration of different cell lineages along the pit-gland unit. The proliferating multipotent stem cells functionally anchored in the upper glandular region, the isthmus, give rise to three main lineage precursors: 1) pre-pit cells, which migrate upward to the pit while differentiating into mucus-producing pit cells; 2) pre-neck cells, which migrate downward to the glandular neck while differentiating into mucus-producing neck cells that, by approaching the glandular base, gradually change their phenotype into pepsinogen- and intrinsic factor-producing zymogenic cells; 3) pre-parietal cells, which differentiate into acid-producing parietal cells in the isthmus and then undergo bipolar migration towards the pit and the glandular base. Thus, parietal cells are the only cells that complete their differentiation in the isthmus and then migrate to be scattered throughout the pit-gland unit. To determine whether parietal cells play a role in controlling decisions about cell fate within the pit-gland unit, the gastric epithelium has been examined in transgenic mice expressing the H,K-ATPase beta-subunit-1035 to +24/simian virus 40 large T antigen fusion gene. The blockade in parietal cell differentiation in these mice produces an amplification of lineage precursors, a marked depletion of zymogenic cells and an increase in pit cell census. Ablation of parietal cells in another transgenic mouse model expressing the H,K-ATPase beta-subunit-1035 to +24/diphtheria toxin fragment A fusion gene also produces amplification of lineage precursors, and similar effects on zymogenic and pit cell census. These findings strongly suggest that parietal cells produce regulatory signals that control the cellular differentiation program of both pit and zymogenic cell lineages, and would hopefully improve our ability to identify the cellular pathways leading to malignant transformation.

Stimulation of activin receptor II signaling pathways inhibits differentiation of multiple gastric epithelial lineages

Activins are TGFbeta family members known to mediate a variety of developmental events. We examined the effects of activins on the self-renewing epithelial lineages present in gastric units of the adult mouse stomach. These lineages are descended from multipotent stem cells located in the midportion of each unit. The stem cell and its immediate descendants can be identified by their morphological features. Studies of knockout mice lacking activins A or B, and/or activin type II receptors (ActRII) revealed that ActRII-mediated signaling is not required for normal gastric epithelial morphogenesis or homeostasis. Mice homozygous for a null allele of the alpha-inhibin gene (inha[m1/m1]) develop gonadal sex cord stromal tumors that secrete large amounts of activins A and B. Analysis of inha(m1/m1) mice, with or without gonads, established that supraphysiological levels of activins block differentiation of preparietal to acid-producing parietal cells, differentiation of neck cells to pepsinogen-producing zymogenic cells, and terminal differentiation of mucus-producing pit cells. ActRII mRNA is normally present in pit, parietal, and zymogenic cells. inha(m1/m1)actRII(m1/m1) compound homozygotes develop activin-secreting gonadal tumors but have no abnormalities in their gastric epithelium, indicating that persistent stimulation of ActRII-dependent signaling pathways produces pleiotrophic effects on gastric epithelial differentiation. When a lineage-specific promoter is used to ablate mature parietal cells with an attenuated diphtheria toxin A fragment in transgenic mice, there is increased proliferation of the multipotent gastric stem cell and its committed daughters and subsequent development of gastric neoplasia. Parietal cell loss in inha(m1/m1) mice is not associated with this proliferative response. These different responses to parietal cell loss suggest that stimulation of ActRII-dependent signaling pathways in inha(m1/m1) animals affects the proliferative activity of the stem cell and its immediate descendents. This finding may have therapeutic significance.

Gastric epithelial morphogenesis in normal and transgenic mice

The epithelium located in the corpus of the adult mouse stomach forms mucosal invaginations known as gastric units. Gastric units are populated by members of the pit, parietal, and neck-zymogenic cell lineages all of which are derived from multipotent stem cells. Gastric unit morphogenesis was examined in normal embryonic day 18 (E18) to postnatal day 28 (P28) FVB/N mice with electron microscopy and multilabel immunohistochemistry. E18 units appear as short, solid infoldings (primordial buds), 92% of whose cells represent pit, parietal, and neck cell precursors. Although the total number of cells per bud does not change from P1 to P7, immature cells decrease to 22% as differentiated pit, neck, and parietal cells appear. From P7 to P15, lineage precursors and their differentiated progeny increase and buds elongate. Between P15 and P21 the multipotent stem cell and its descendants are assembled into a distinct proliferative zone (isthmus) located in the midportion of each unit, and cellular migration-differentiation programs become compartmentalized. To examine the role of parietal cells in regulating gastric unit morphogenesis, nucleotides -1035 to +24 of the mouse H(+)-K(+)-adenosinetriphosphatase beta-subunit gene were used to express simian virus 40 large T antigen (SV40 TAg) exclusively in this lineage. SV40 TAg amplified the normally rare pre-parietal cell and disclosed a pre-parietal cell precursor. Pre-parietal cells and their precursors were the predominant cells in E18-P1 transgenic buds. At later stages of development (P1-P28) there was a block in differentiation of pre-parietal to mature parietal cells, a decrease in neck cells, and a marked depletion of zymogenic cells. These findings suggest that members of the parietal cell lineage are the source of instructions that affect the neck-zymogenic cell lineage, even before the gastric unit is compartmentalized into its anatomically distinct pit, isthmus, neck, and base regions.

Functional heterogeneity of parietal cells along the pit-gland axis

The gastric epithelium forms numerous short pits continuous with long tubular glands divisible into isthmus neck, and base regions. Parietal cells are produced in the isthmus and migrate down to the neck and base regions as they mature and age. Stimulation of parietal cells is manifested by translocation of H(+)-K(+)-adenosinetriphosphatase-rich tubulovesicles (TV) from the cytoplasm into the secretory-apical (SA) membrane. In this study we used rabbit isolated gastric glands to examine the physiological responses of parietal cells to graded levels of stimulation. Quantitative morphometry was used to evaluate parietal cell response along the longitudinal axis of the gland. Acid secretion as estimated by [14C]aminopyrine uptake was well correlated with parallel enzymatic and immunoblot assays for the redistribution of H(+)-K(+)-ATPase from TV to SA membranes. These responses also correlated well with morphological transformations of parietal cells within the isthmus and neck regions of the gastric gland; however, parietal cells in the base of the gland showed very little morphological change in response to any of the stimuli used. The poor responsiveness of basal parietal cells is in agreement with observations of intact mucosa and suggests that older parietal cells may serve some function other than acid secretion.

Stimulation of gastric acid secretion by cAMP in a novel alpha-toxin-permeabilized gland model

It is generally believed that histamine-stimulated gastric acid secretion involves a transient elevation of intracellular Ca2+ and the adenosine 3',5'-cyclic monophosphate (cAMP)-dependent protein kinase (PKA) cascade through phosphorylation, whose actions ultimately effect the fusion of H(+)-K(+)-adenosinetriphosphatase (ATPase)-containing vesicles to the apical plasma membrane of parietal cells. To dissect the signaling events underlying gastric acid secretion, we have developed a permeabilized gastric gland model using Staphylococcus alpha-toxin. The advantage of this model is its ability to retain cytosolic components that are required for the secretory machinery. Here we show that acid secretion in alpha-toxin-permeabilized glands is a cAMP-dependent process, reaching a maximal stimulation at 100 microM cAMP. The cAMP-elicited acid secretion, as monitored by the accumulation of the weak base aminopyrine (AP), required functional mitochondria or exogenously supplied ATP. Maximal stimulation elicited by cAMP for AP uptake by permeabilized glands was 51-85% of intact glands. Moreover, secretory activity was potentiated by 0.1 mM ATP. The recruitment of H(+)-K(+)-ATPase-rich tubulovesicles into the apical plasma membrane was measured using biochemical and morphological assays, thus validating the cell activation processes in response to cAMP. From this permeabilized model, [gamma-32P]ATP was used to directly phosphorylate target proteins. A number of proteins whose phosphorylation-dephosphorylation is specifically modulated by cAMP were found. These studies establish the first permeabilized gland model in which the resting-to-secreting transition can be triggered and show that cAMP-mediated phosphorylation is correlated with secretory activity.

Diphtheria toxin-mediated ablation of parietal cells in the stomach of transgenic mice

The self-renewing epithelial populations present in the gastric units of the mouse stomach are descended from a multipotent stem cell and undergo an orderly migration-associated differentiation followed by apoptosis. The steady state census of the three principal cell types (acid-producing parietal cells, mucus-producing pit cells, and pepsinogen and intrinsic factor-producing zymogenic cells) is accurately controlled, despite marked differences in the rates of migration of each lineage. A transgenic mouse model has been created to define functional interrelationships between the proliferation, differentiation, and death programs of these lineages. Nucleotides -1035 to +24 of the noncatalytic beta subunit gene of mouse H+/K+-ATPase were used to direct expression of an attenuated diphtheria toxin A subunit in the parietal cell lineage. These transcriptional regulatory elements are not active in members of the pit and zymogenic lineages. Stomachs, prepared from postnatal day 28-80 transgenic mice and their normal littermates, were subjected to single- and multilabel immunohistochemical studies as well as qualitative and quantitative light and electron microscopic morphologic analyses. The toxin produced complete ablation of differentiated parietal cells. Loss of parietal cells was accompanied by a 5-fold increase in the number of undifferentiated granule-free cells located in the proliferative compartment of gastric units. This amplified population of granule-free cells included the multipotent stem cell as well as committed precursors of the pit and zymogenic lineages. Loss of mature parietal cells was also associated with (i) a block in the differentiation program of the zymogenic lineage with an accumulation of pre-neck cells and a depletion of their neck and mature zymogenic cell descendants, and (ii) an approximately 2-fold amplification of pit cells. These findings are consistent with the notion that epithelial homeostasis within gastric units is maintained by instructive interactions between their different cell lineages. Unlike pit and zymogenic cells, parietal cells complete their differentiation in the gastric unit's proliferative compartment before undergoing a bipolar migration along the unit. Thus, the mature parietal cell is in a strategic position to influence decision-making among gastric epithelial cell precursors and to modulate the migration-associated terminal differentiation programs of the pit and zymogenic lineages.

New insights into the stem cells and the precursors of the gastric epithelium

It is believed that stomach neoplasia represents the end result of a multistep journey that starts with derangement of the cellular proliferation and commitment program of the epithelium. The epithelium is normally made up of a single layer of cells that invaginates to form numerous short pits continuous with long tubular glands divisible into isthmus, neck, and base regions. Three main cell lineages populate these pit-gland units: 1) mucus-secreting pit, 2) pepsinogen-secreting zymogenic, and 3) acid-secreting parietal cell lineages. The immature cells of the unit are located in the isthmus region; they include undifferentiated stem cells that undergo frequent asymmetric mitosis to reproduce themselves and give rise to two partially committed precursors: 1) prepit-cell precursors, which become prepit cells in the isthmus and then migrate outward into the pit and mature into pit cells, and 2) preneck cell precursors, which become preneck cells in the isthmus and then migrate inward to the neck region and transform into neck cells. The latter continue their inward migration and eventually reach the base region where they gradually change their phenotype through a prezymogenic step to become zymogenic cells. The stem cells, as well as the prepit and preneck cell precursors, share in the production of preparietal cells that, in the isthmus, mature into parietal cells and then migrate outward into the pit or inward into the neck and base. The stem cells also give rise to preenteroendocrine and precaveolated cells. These become, respectively, enteroendocrine and caveolated cells that proceed to follow the bidirectional migratory route of parietal cells. The production of rare nonproliferating preparietal cells is enhanced after blocking the secretory activity of their mature forms by continuous infusion of the histamine H2-receptor antagonist, ranitidine, for 42 h. Thus, the presence of active mature parietal cells is necessary to maintain the normal cellular proliferation and commitment program in the gastric epithelium.

Simian virus 40 T antigen-induced amplification of pre-parietal cells in transgenic mice. Effects on other gastric epithelial cell lineages and evidence for a p53-independent apoptotic mechanism that operates in a committed progenitor

Gastric units in the glandular epithelium of the mouse stomach contain several types of continuously renewing epithelial cells. Acid-producing parietal cells are derived from a multipotent stem cell that also gives rise to mucus-producing pit cells and pepsinogen- and intrinsic factor-producing zymogenic cells. We used nucleotides -1035 to +24 of the mouse H+/K(+)-ATPase beta subunit gene (H+/K(+)-ATPase beta subunit-1035 to +24) to examine the consequences of expressing simian virus 40 T antigen (SV 40 TAg) in the normally rare, nonproliferating, short-lived pre-parietal cell progenitor. Light and electron microscopic morphologic studies plus multilabel immunohistochemical analyses of postnatal day (P) 14-80-day transgenic mice revealed that SV40 TAg produces a 50-70-fold amplification of pre-parietal cells which become the predominant cell type in gastric units. Differentiation to mature parietal cells is blocked, resulting in hypochlorhydria and an associated systemic iron deficiency. SV40 TAg-induced pre-parietal proliferation is accompanied by apoptosis. Examination of adult transgenic mice homozygous for p53 wild type or p53 null alleles established that the apoptosis occurs through a p53-independent pathway. H+/K(+)-ATPase beta subunit -1035 to +24/SV40 Tag is not expressed during differentiation of the zymogenic lineage. Nonetheless, P28-P80 transgenic mice exhibit an apparent block in the conversion of pre-zymogenic to zymogenic cells. This block appears to be quite specific: conversion of preneck to neck cells and neck to pre-zymogenic cells is not affected. Comparison of normal and transgenic mice that are p53+/+ or p53-/- confirmed that the loss of mature zymogenic cells is not dependent upon p53. Although H+/K(+)-ATPase beta subunit -1035 to +24 is not active in pit cell progenitors or their differentiated descendants, there is a 2-3-fold increase in mature pit cells in transgenic animals. Our findings (i) demonstrate an approach for amplifying and characterizing pre-parietal or other progenitor cell populations in gastric units, (ii) reveal an SV40 TAg-inducible, p53-independent apoptotic mechanism that operates in a committed epithelial progenitor cell, and (iii) provide a transgenic mouse model for defining factors that may mediate progression through specific points in the differentiation programs of the parietal and zymogenic cell lineages or that may influence decisions about allocation to the pit cell lineage.

Origin and migratory pathways of the eleven epithelial cell types present in the body of the mouse stomach

The secretions of the mammalian stomach are produced by cells present in invaginations of the epithelium, which in the mouse are straight tubules referred to as "zymogenic units." These units comprise four regions, namely pit, isthmus, neck, and base, in which there are several cell lineages with different phenotypes and migratory pathways. In the isthmus, stem cells designated "undifferentiated granule-free cells" undergo division so as to maintain their own number and produce several differently oriented progenitors: (1) "Pre-pit cell precursors" are characterized by prosecretory Golgi vesicles with a uniform, fine particulate content. They give rise to "pre-pit cells" defined by the presence of few dense mucous granules. These cells migrate outward from the isthmus to the pit, where they become the dense granule-rich "pit cells" which populate the pit region and migrate to the gastric surface where they are lost. (2) "Pre-neck cell precursors" are identified by prosecretory Golgi vesicles containing an irregular dense center and a light rim. They give rise to "pre-neck cells" defined by a few mucous secretory granules with a clear-cut core. These cells migrate inward from the isthmus to the neck where they become "neck cells," which contain many such granules. Even though neck cells are mature mucus-producers, they are not end cells. As they enter the base region, they become "prezymogenic cells" whose phenotype gradually changes from mucous to serous. These cells eventually lose the ability to produce mucus and thus become the typical zymogenic cells that populate the base region. (3) "Pre-parietal cells" are classified into three variants, which probably come from three different sources, that is, pre-pit cell precursors, pre-neck precursors, and the undifferentiated granule-free cells themselves. The preparietal cells mature into parietal cells which migrate either outward to the pit or inward to the neck and base. As a result, parietal cells are scattered in the four regions of the unit. (4) Precursors of "entero-endocrine" and "caveolated" cells give rise in the isthmus to these cells, which may also migrate outward or inward.

Inhibiting gastric H(+)-K(+)-ATPase activity by omeprazole promotes degeneration and production of parietal cells

Parietal cell morphology was studied after chronic inhibition of gastric H(+)-K(+)-adenosinetriphosphatase (ATPase) by omeprazole. Gastric mucosa from rabbits treated with omeprazole every 12 h (1 mg/kg sc) for 5 days were compared with sham-injected animals using immunohistochemistry and electron microscopy. Three immunocytochemical markers, including antibodies against the alpha- and beta-subunits of the H(+)-K(+)-ATPase, showed that some parietal cells in omeprazole-treated rabbits displayed light areas and granularity in their cytoplasm. These abnormalities were also apparent in semithin sections. Electron microscopy was used to categorize and quantitate the specific structural abnormalities in parietal cells. Cells were classified as normal, altered, or degenerated. For control tissues, altered and degenerated parietal cells were few; they collectively represented 6% of total parietal cells and were located mainly deep in the gland base. For omeprazole-treated tissues, altered and degenerated parietal cells occurred throughout the gland and averaged 62% of total parietal cells. In addition, macrophages invaded the mucosa presumably to eliminate degenerated cells. Although there was an increase in parietal cell degeneration, enhanced parietal cell generation was suggested by increases in mitosis among proliferative cells and, more specifically, in the number of preparietal cells. After 3 days of recovery from the omeprazole regimen, parietal cells and the gastric mucosa appeared to recover the normal morphology. In conclusion, blocking H(+)-K(+)-ATPase by omeprazole enhances degeneration and macrophage-mediated elimination of parietal cells and also causes an increase in preparietal cell production. Thus omeprazole temporarily changes the dynamic features of parietal cells in the rabbit to make them die early and grow fast.

Dynamics of epithelial cells in the corpus of the mouse stomach. V. Behavior of entero-endocrine and caveolated cells: general conclusions on cell kinetics in the oxyntic epithelium

Entero-endocrine cells and the rare cells named caveolated or brush cells have been examined in light microscopic radioautographs of the mouse corpus after various periods of continuous 3H-thymidine infusion. Moreover a search for immature forms and mitoses of these cells was undertaken in the electron microscope. Entero-endocrine cells are present in the four regions of the epithelial units, but their number is low in the pit, intermediate in the isthmus and neck, and high in the base. The labeling pattern after continuous 3H-thymidine infusion indicates that these cells are produced in the isthmus from undifferentiated granule-free cells presumed to be the stem cells of the epithelium, and may retain a limited ability to divide. A few of the newly formed entero-endocrine cells migrate to the pit, but the majority goes to the neck and, from there, to the base where they are present in relatively high numbers. Little information is available on the dynamics of caveolated cells. Since immature forms are present in the isthmus and mature ones in the other regions, it is concluded that they arise in the isthmus and migrate away in both directions. Finally, concluding remarks are presented on the kinetics of each one of the cell lineages described in this and the four previous articles.

Dynamics of epithelial cells in the corpus of the mouse stomach. III. Inward migration of neck cells followed by progressive transformation into zymogenic cells

The neck cells (or mucous neck cells) present in the neck region and the zymogenic cells (or chief cells) present in the base region of the units in the mouse corpus were examined in the electron microscope (EM) and in radioautographs prepared after administration of 3H-thymidine by single or multiple injections or by continuous infusion for 1-52 days. For these studies, the neck region of the units has been subdivided into three equal segments, respectively named high neck, mid neck, and low neck, while the base region has been similarly subdivided into high base, mid base, and low base. The neck region includes an average of 12.6 neck cells, characterized in the EM by dark, mucous secretory granules that frequently exhibit a light, pepsinogenic core. Continuous 3H-thymidine infusion reveals that neck cells come from pre-neck cells, which are believed to arise in the isthmus region from the undifferentiated granule-free cells through a pre-neck cell precursor stage. The pre-neck cells, characterized by the presence of a few cored secretory granules, migrate inward (i.e., in the direction of the blind end of the units) and enter the neck region to become neck cells. It is estimated that 59% of the neck cells arise from differentiation of pre-neck cells, whereas the other 41% are derived from their own mitoses. Neck cells migrate inward in 1-2 weeks from the high through the mid and low neck segments, while they keep on producing more and larger secretory granules and thus further differentiate as mucus-producing cells. When neck cells reach the high base segment, they become pre-zymogenic cells that produce secretory granules in which appear light, irregular, pepsinogenic patches which encroach on the dark mucous content. With time, the pre-zymogenic cells, of which there are 5.0 per unit on the average, keep on producing new granules with larger and larger light patches, so that in the end the cells produce granules which are entirely filled by light, pepsinogenic material. At this stage, the cells are zymogenic cells. Zymogenic cells, which average 67.5 per unit, further migrate inward, while gradually enlarging and producing pepsinogenic granules of increasing size. In the low base segment, some zymogenic cells show signs of degeneration leading to death by either necrosis or apoptosis.(ABSTRACT TRUNCATED AT 400 WORDS)

Dynamics of epithelial cells in the corpus of the mouse stomach. II. Outward migration of pit cells

The pit cells (or surface mucous cells) present along pit walls and gastric surface have been investigated by electron microscopy and radioautography after a pulse or continuous infusion of 3H-thymidine. For these studies, the pit region has been subdivided into four segments: three of equal length along the pit wall, respectively named low pit, mid pit and high pit, and a last one at the surface named pit top. The pit region includes an average of 37 pit cells, characterized by dense mucous granules accumulated along the apical membrane in an organelle-free zone referred to as ectoplasm. Continuous 3H-thymidine infusion reveals that pit cells come from pre-pit cells, which are believed to arise in the isthmus region from the undifferentiated granule-free cells through a pre-pit cell precursor stage. The pre-pit cells, characterized by the presence of a few mucous secretory granules scattered in the cytoplasm, migrate outward (i.e., in the direction of the gastric lumen). When the secretory granules line up along the apical membrane in the ectoplasm, the pre-pit cell becomes pit cell. It is estimated that 87% of pit cells differentiate from pre-pit cells, while the remaining 13% come from their own mitoses. Observations at successive times after a 3H-thymidine pulse demonstrate that pit cells, like pre-pit cells, migrate toward the gastric surface where they are eventually lost. The continuous 3H-thymidine infusion results indicate that this migration takes 3.1 days on the average. Cells spend almost a day in each pit wall segment. In the low pit segment, cells produce more and larger mucous secretory granules than do pre-pit cells. In the mid and high pit segments, the number and size of the granules generally keeps on increasing, thus indicating that mucous differentiation is progressing. The secretory granules arising in the Golgi apparatus of pit wall cells are mostly spherical; they retain this shape during the few minutes taken to cross the cytoplasm and enter the apical ectoplasm. They spend about an hour in the ectoplasm, where they change to an ovoid shape as they approach the apical membrane to finally release their content by exocytosis. The mucous differentiation along the pit wall is associated with a progressive decline in the organelles: nucleoli and mitochondria decrease in size while the amount of free ribosomes diminishes. When pit cells reach the free surface, they produce fewer, smaller secretory granules and at a lower rate than in mid and high pit.(ABSTRACT TRUNCATED AT 400 WORDS)

Dynamics of epithelial cells in the corpus of the mouse stomach. IV. Bidirectional migration of parietal cells ending in their gradual degeneration and loss

The life story of parietal cells has been investigated in the corpus of the mouse stomach using electron microscopy and 3H-thymidine radioautography. Parietal cells are scattered in the four regions of the unit. On the average 3.6 cells are in the pit, 6.2 in the isthmus, 5.6 in the neck, and 10.6 in the base. Parietal cells do not divide. They arise from partially differentiated pre-parietal cells, which are believed to be derived in the isthmus from the three subtypes of granule-free cells: undifferentiated cells, pre-pit cell precursors, and pre-neck cell precursors. Radioautography indicates that the transformation of granule-free cells into pre-parietal cells takes at least one day. The pre-parietal cells, of which there are 0.6 per unit on the average, develop into parietal cells through three successive stages. Stage 1 is characterized by small immature cells that are identified by long apical microvilli. Stage 2 is characterized by larger cells, about one-third the size of parietal cells, and by an incipient canaliculus and a few apical tubulovesicles. Stage 3 is characterized by the expansion of the canalicular and tubulovesicular systems as well as mitochondrial enlargement, which cause the pre-parietal cell to gradually approach the size of, and eventually become, a parietal cell. This cell sequence mainly takes place in the isthmus, but may extend to the neck region. Continuous infusion of 3H-thymidine confirms that parietal cells originate in the isthmus and that they migrate in two directions: some go outward to the pit and the others migrate inward to the neck and eventually to the base. It has been estimated that for every six parietal cells produced per month in the isthmus, three migrate to the pit and three migrate to the neck to eventually reach the base. While almost all parietal cells in the isthmus and neck appear normal, a large proportion of those reaching the pit (21%) and base (23%) undergo gradual alteration and degeneration. After the ensuing death, parietal cells are eliminated in one of two major ways: 1) extrusion into the gastric lumen, if they appear necrotic, or 2) phagocytosis by a neighboring cell or even by an invading connective tissue macrophage, if they are apoptotic. The overall turnover time of parietal cells averages 54 days.(ABSTRACT TRUNCATED AT 400 WORDS)

Dynamics of epithelial cells in the corpus of the mouse stomach. I. Identification of proliferative cell types and pinpointing of the stem cell

In a recent study of the corpus epithelium in the mouse stomach, eleven cell types have been identified and enumerated (Karam and Leblond: Anat. Rec. 232:231-246, 1992). The dynamics of these cells will be examined in a series of five articles, of which this is the first. This article focuses on the proliferative ability of the cells, as measured by the labeling index in radioautographs from mice sacrificed 30 min after an intravenous injection of 3H-thymidine. Furthermore, the ultrastructure of the cells found to be proliferative was examined in the hope of finding features characteristic of stem cells. On the basis of their labeling index, the epithelial cells have been classified into four groups. The first includes three cell types which do not take up any label and accordingly are non-dividing: parietal or oxyntic cells, cells named pre-parietal as they are immature cells suspected of being parietal cell precursors, and the rare caveolated or brush cells. The second group is composed of three cell types which are only rarely labeled and, therefore, divide only occasionally: zymogenic or chief cells, entero-endocrine cells, and cells named pre-zymogenic cells as they are suspected of being zymogenic cell precursors. The third group includes two cell types which are always labeled at a low degree and, therefore, divide regularly, but at a low rate: surface mucous cells, herein called pit cells, whose labeling index is 0.8%, and mucous neck cells, simply known as neck cells, 1.8%. The final group consists of three immature cell types with high labeling indices indicating a high rate of division: granule-free cells, which are devoid of secretory granules and have the highest labeling index, 32.4%, pre-pit cells, which possess a few dense secretory granules similar to, but smaller than, those in pit cells, 24.6%, and pre-neck cells, with a small number of secretory granules similar to, but smaller than, those in neck cells, 11.3%. These three cell types, as well as pre-parietal cells, are rapidly renewed, with the turnover times estimated at 3.0 days for pre-neck and pre-parietal cells and less than 2.6 days for granule-free and pre-pit cells.(ABSTRACT TRUNCATED AT 400 WORDS)

Identifying and counting epithelial cell types in the "corpus" of the mouse stomach

The epithelial cells lining the oxyntic mucosa in the stomach "corpus" were identified, localized, and counted in 2-month-old male C57BL-6 mice, using glutaraldehyde-formaldehyde fixation and osmium tetroxide postfixation for studies in the light microscope (LM) while adding tannic acid to the fixative and postfixing in ferrocyanide-osmium for studies in the electron microscope (EM). The cells form a single epithelium, which invaginates into blind tubular units. Each unit is divided into four successive regions: pit, isthmus, neck, and base. On the average, a unit contains 194.2 cells. The cells have been classified into three groups totaling 11 types, listed with their mean number per unit. The first group is composed of three well-characterized cell types, each restricted to a region: (1) 37.0 surface mucous cells, hereafter called pit cells, in the "pit" region, (2) 12.6 mucous neck cells, simply called neck cells, in the "neck" region, and (3) 67.4 zymogenic cells in the "base" region. The second group is also composed of three well-characterized cell types, distributed over the four regions: (1) 26.0 parietal cells, (2) 13.2 entero-endocrine cells, and (3) 0.6 caveolated cell. The third group consists of five cell types, which have been little or not characterized in the past. Four are located in the "isthmus" region and show EM features indicative of immaturity, that is, a nucleus with mainly diffuse chromatin and large reticulated nucleoli, and a scanty cytoplasm rich in free ribosomes: (1) 17.2 cells are the least differentiated in the epithelium; they are devoid of secretory granules and accordingly named granule-free cells, (2) 10.0 cells contain a few dense secretory granules smaller than, but otherwise similar to, those in pit cells; they are referred to as pre-pit cells, (3) 1.8 cells possess a few marbled secretory granules that often exhibit a pale core and are smaller than, but otherwise similar to, those in neck cells; they are called pre-neck cells, (4) 0.6 cells display long microvilli and/or small canaliculi similar to those in parietal cells; they are named pre-parietal cells, and (5) 5.6 cells restricted to the base region are characterized by secretory granules with features intermediate between those of neck and zymogenic cells; they are named pre-zymogenic cells. The observations suggest the following hypothesis on cell filiation.(ABSTRACT TRUNCATED AT 400 WORDS)