Induction of the autolytic system of Escherichia coli by specific insertion of bacteriophage MS2 lysis protein into the bacterial cell envelope.

Bacterial lysis induced by the expression of the cloned lysis gene of the RNA bacteriophage MS2 in Escherichia coli was shown to be under the same regulatory control mechanisms as penicillin-induced lysis. It was controlled by the stringent response and showed the phenomenon of tolerance when E. coli was grown at pH 5. Changes in the fine structure of the murein were found to be the earliest physiological changes in the cell, taking place 10 min before the onset of cellular lysis and inhibition of murein synthesis. Both the average length of the glycan strands and, with a time lag, the degree of cross-linkage were altered, indicating that a lytic transglycosylase and a DD-endopeptidase had been triggered. After extensive separation of the membranes by isopycnic sucrose gradient centrifugation, the lysis protein was present predominantly in the cytoplasmic membrane and in a fraction of intermediate density and, to a lesser degree, in the outer membrane, irrespective of the conditions of growth. However, only under lysis-permissive conditions could a 17% increase in the number of adhesion sites between the inner and outer membranes be observed. Thus, a casual relationship between lysis and the formation of lysis protein-induced adhesion sites seems to exist.     

Zones of membrane adhesion in the cryofixed envelope of Escherichia coli

The envelopes of Escherichia coli B and E. coli K29 were examined using cryofixation and freeze substitution. Emphasis was directed toward the question whether membrane adhesion zones (which connect inner membrane (IM) and outer membrane (OM) after plasmolysis in 10-20% sucrose) can be visualized with the use of cryotechniques. Plasmolysis in 10-20% sucrose was observed to have no effect on cell viability. We found that simple plunge-freezing methods preserve adhesion sites, whereas these sites were not observed after impact-freezing. Also, plasmolysis "bays," visible in light microscopic preparations of living cells, were seen to be maintained intact after plunge-freezing. Employment of photocrosslinking with UV-flashes before or after plasmolysis showed a significant increase in the number of adhesion areas compared to noncrosslinked specimens. To control the contact speed of the specimen during immersion into the cryogen, a hollow rotor was constructed in which the cryogenic liquid is moving at desired high speeds. Adhesion sites presented themselves in the plasmolyzed cell as sites of close contact of the outer and inner membrane, an arrangement that would leave very limited space for peptidoglycan layers at the contact site of the two membranes. Adhesion sites may occur either as single, isolated sites or within stretches of IM/OM apposition where they appear to function as "spot welds" between the two membranes. Exposure of cells to sucrose concentrations of 35% caused rupture of adhesions with cytoplasmic fragments remaining attached to the envelope. The cryofixation procedures described here do not presently yield the number of membrane adhesions obtainable with conventional aldehyde fixation. However, since the combination of millisecond photocrosslinking and cryofixation of plasmolyzed cells resulted in a higher membrane stabilization and in an increase of the number of adhesion sites, this combination appears to be a useful tool for the analysis of sensitive membrane structures.     

Localization of penicillin-binding protein 1b in Escherichia coli: immunoelectron microscopy and immunotransfer studies.

We report the localization of penicillin-binding protein 1b (PBP 1b) in Escherichia coli KN126 and in an overproducing construct containing plasmid pHK231. We used PBP 1b-specific antiserum for the immunoelectron microscopy of ultrathin sections of whole cells and for immunoelectrophoresis of cytoplasm and isolated membrane fractions. We studied ultrathin sections of both glutaraldehyde-fixed cells that had been embedded after progressively lowering the temperature and cryofixed cells that had been freeze-substituted in Lowicryl K4M and HM20. Most of the PBP 1b-specific label was observed in the inner membrane (IM) and the adjacent cytoplasm, much less was observed in the outer membrane (OM); appreciable amounts were also seen in the bulk cytoplasm. Distribution and intensity of label were both temperature dependent: temperature shift-up to 37 degrees C, causing PBP 1b overproduction in the construct, showed a statistically highly significant increase in label of the IM, including a cytoplasmic zone (of at least 30 nm in depth) adjacent to the IM, a zone we termed the membrane-associated area. Concomitant with the temperature shift-up, a decrease in label density was observed in the bulk cytoplasm. Increased label was also found in IM-OM contact areas (zones of membrane adhesion). The periplasm did not show significant label. Western blotting (immunoblotting) revealed PBP 1b in most of the isolated membrane fractions; however, the highest label density was found in membrane fractions of intermediate density, supporting the suggestion of an increased concentration of PBP 1b in the membrane adhesion zones. In summarizing, we propose that PBP 1b is present in the membrane-associated area of the cytoplasm, from where proteins (such as PBP 1b or thioredoxin) gain access to their specific insertion sites in the envelope. The use of several methods of immunoelectron microscopy provided the first unequivocal evidence for localization of PBP 1b at membrane adhesion sites. Since such sites are specifically labeled with anti-PBP 1b serum, we hypothesize that they contain parts of the machinery for assembly and growth of the murein layer.     

Phospholipase-A-independent damage caused by the colicin A lysis protein during its assembly into the inner and outer membranes of Escherichia coli

The requirement for the activation of phospholipase A by the colicin A lysis protein (Cal) in the efficient release of colicin A by Escherichia coli cells containing colicin A plasmids was studied. In particular, we wished to determine if this activation is the primary effect of Cal or whether it reflects more generalized damage to the envelope caused by the presence of large quantities of this small acylated protein. E. coli tolQ cells, which were shown to be leaky for periplasmic proteins, were transduced to pldA and then transformed with the recombinant colicin A plasmid pKA. Both the pldA and pldA+ strains released large quantities of colicin A following induction, indicating that in these cells phospholipase A activation is not required for colicin release. This release was, however, still dependent on a functioning Cal protein. The assembly and processing of Cal in situ in the cell envelope was studied by combining pulse-chase labelling with isopycnic sucrose density gradient centrifugation of the cell membranes. Precursor Cal and lipid-modified precursor Cal were found in the inner membrane at early times of chase, and gave rise to mature Cal which accumulated in both the inner and outer membrane after further chase. The signal peptide was also visible on these gradients, and its distribution too was restricted to the inner membrane. Gradient centrifugation of envelopes of cells which were overproducing Cal resulted in very poor separation of the membranes. The results of these studies provide evidence that the colicin A lysis protein causes phospholipase A-independent alterations in the integrity of the E. coli envelope.(ABSTRACT TRUNCATED AT 250 WORDS)     

Association of thioredoxin with the inner membrane and adhesion sites in Escherichia coli.

The intracellular localization of thioredoxin in Escherichia coli was determined by immunoelectron microscopy and correlated to previous biochemical data which had suggested that thioredoxin resides at inner-outer membrane adhesion sites. Since a considerable amount of thioredoxin was lost during preparation of cells for electron microscopy, we immobilized the protein with the heterobifunctional photoactivatable cross-linker p-azidophenacylbromide before the cells were fixed with aldehyde and embedded in Lowicryl K4M. Thin sections were labeled with affinity-purified antithioredoxin antiserum and protein A-gold complexes. Densities of immunolabel in a designated membrane-associated area and in the rest of the cytoplasm were compared and the data were statistically evaluated. Wild-type strain W3110 and strain SK3981, an overproducer of thioredoxin, exhibited increased labeling at the inner membrane and its adjacent cytoplasmic area. In contrast, the more centrally located cytoplasm of both strains showed much lower label density. This label distribution did not change with cell growth or in the stationary phase. Immunolabel was often found at bridges between the inner and outer membranes; this result is consistent with a model which places at least a portion of the thioredoxin at membrane adhesion sites, corresponding to an osmotically sensitive cytoplasmic compartment bounded by a hybrid inner-outer membrane (C.A. Lunn and V. Pigiet, J. Biol. Chem. 257:11424-11430, 1982; C.A. Lunn and V. Pigiet, J. Biol. Chem. 261:832-838, 1986). Specific label was absent in the periplasmic space.     

Identification of a GTP-binding protein in the contact sites between inner and outer mitochondrial membranes

Whilst investigating whether GTP hydrolysis may be required for the import of preproteins into mitochondria we have found that a GTP-binding protein is located at the contact sites between mitochondrial inner and outer membranes. When mitochondrial outer membranes purified from rat liver were UV-irradiated in the presence of [alpha-32P]GTP, a 52 kDa protein was radiolabelled, whereas [alpha-32P]ATP did not label this protein. GTP-binding proteins were also labelled in the cytosolic and microsomal fractions, but the 52 kDa protein was concentrated in mitochondrial membranes and was the only protein specifically labelled by GTP in these membranes. Fractionation of mitochondrial membrane vesicles into outer membranes, inner membranes and contact sites between outer and inner membranes showed that the GTP-binding activity was highly enriched in contact sites, the location at which preprotein import is believed to occur. A protein of almost identical size was also found to be labelled in mitochondria from yeast.     

Immunocytochemical demonstration of ecto-galactosyltransferase in absorptive intestinal cells

Galactosyltransferase immunoreactive sites were localized in human duodenal enterocytes by the protein A-gold technique on thin sections from low temperature Lowicryl K4M embedded biopsy specimens. Antigenic sites detected with affinity-purified, monospecific antibodies were found at the plasma membrane of absorptive enterocytes with the most intense labeling appearing along the brush border membrane. The lateral plasma membrane exhibited a lower degree of labeling at the level of the junctional complexes but the membrane interdigitations were intensely labeled. The labeling intensity decreased progressively towards the basal part of the enterocytes and reached the lowest degree along the basal plasma membrane. Quantitative evaluation of the distribution of gold-particle label proved its preferential orientation to the outer surface of the plasma membrane. In addition to this membrane-associated labeling, the glycocalyx extending from the microvillus tips was heavily labeled. Occasionally, cells without plasma membrane labeling were found adjacent to positive cells. The demonstration of ecto-galactosyltransferase on membranes other than Golgi membranes precludes its general use as a marker for Golgi membrane fractions. The possible function of galactosyltransferase on a luminal plasma membrane is unclear at present, but a role in adhesion appears possible on the basolateral plasma membrane.     

Localization of cathepsin L in rat kidney revealed by immunoenzyme and immunogold techniques

Localization of cathepsin L in rat kidney was investigated by immunocytochemical techniques. Kidneys were fixed by perfusion and embedded in Epon or Lowicryl K4M without postosmication. For light microscopy (LM), semi-thin sections of the Epon-embedded material were stained by the immunoenzyme technique after removal of epoxy resin. For electron microscopy (EM), ultra-thin sections of Lowicryl K4M-embedded material were stained by the protein A-gold technique. By LM, reaction deposits for cathepsin L were present in the cytoplasmic granules of proximal tubule cells, but little or no reaction product was noted in distal tubule, collecting tubule, and most of urinary tubules in the medulla. By EM, heavy gold label for cathepsin L was confined exclusively to lysosomes of the proximal tubule cells, but little or no label to those of the other segments. In immunocytochemical control sections, no reaction was observed. These results indicate that a main container of cathepsin L is lysosomes of the proximal tubule and suggest that the enzyme plays a role in the degradation of endocytosed proteins.     

Localization of cathepsin L in rat kidney revealed by immunoenzyme and immunogold techniques

Summary Localization of cathepsin L in rat kidney was investigated by immunocytochemical techniques. Kidneys were fixed by perfusion and embedded in Epon or Lowicryl K4M without postomication. For light microscopy (LM), semi-thin sections of the Epon-embedded material were stained by the immunoenzyme technique after removal of epoxy resin. For electron microscopy (EM), ultra-thin sections of Lowicryl K4M-embedded material were stained by the protein A-gold technique. By LM, reaction deposits for cathepsin L were present in the cytoplasmic granules of proximal tubule cells, but little or no reaction product was noted in distal tubule, collecting tubule, and most of urinary tubules in the medulla. By EM, heavy gold label for cathepsin L was confined exclusively to lysosomes of the proximal tubule cells, but little or no label to those of the other segments. In immunocytochemical control sections, no reaction was observed. These results indicate that a main container of cathepsin L is lysosomes of the proximal tubule and suggest that the enzyme plays a role in the degradation of endocytosed proteins.     

Lysis induction of Escherichia coli by the cloned lysis protein of the phage MS2 depends on the presence of osmoregulatory membrane-derived oligosaccharides

Expression of the cloned lysis protein of phage MS2, which is sufficient to lyse wild type Escherichia coli, does not cause lysis of mutants lacking the osmoregulatory membrane-derived oligosaccharides (MDO). The lysis gene product normally found in the membrane fraction was not stably inserted into the membranes of a mdoA mutant; rather degradation and release from the membrane occurred. Gentle plasmolysis of the MDO-lacking mutant clearly showed an increased periplasmic space as compared to wild type cells. It is concluded that the MDOs play an important role in maintaining a proper arrangement of inner and outer membrane, a prerequisite for a functional insertion of the MS2 lysis protein.     

Membrane proteins of Escherichia coli K-12: two-dimensional polyacrylamide gel electrophoresis of inner and outer membranes.

Protein compositions of the inner and outer membranes of Escherichia coli K-12 have been analyzed by two-dimensional gel electrophoresis in which proteins are separated according to apparent isoelectric point (first dimension) and to apparent molecular weight (second dimension). Membrane proteins except for a pair of major outer membrane proteins (proteins Ia and Ib) were found to be solubilized effectively by lysis buffer containing urea, Triton X-100, ampholines and 2-mercaptoethanol. The latter two proteins could be solubilized after precipitation of membrane fraction with trichloroacetic acid; they formed a pair of spots at an acidic region on the electropherogram. Another major protein of the outer membrane, protein II, was also identified. Most of the inner and outer membrane proteins were shown to be focused at a pH range between 4 and 6.5. Specific protein patterns characteristic for both the inner and outer membranes could thous be visualized by the present system. At least 120 and 50 protein species were detected for the inner and outer membranes, respectively.     

Isolation and characterization of outer and inner membranes of Selenomonas ruminantium: lipid compositions.

The isolation procedure and characterization of the outer and inner membranes from Selenomonas ruminatium cells, a strictly anaerobic bacterium, are described. The metabolic fate of [14C]decanoate incorporated into the outer and inner membranes was examined. The percent distribution of radioactivities in the outer and inner membranes was about 40 and 50% of the total incorporated activity, respectively. Approximately 47% of the radioactivity incorporated into the outer membrane was recovered in the phospholipid fraction, and the remaining radioactivity was found in both aqueous and phenol layers when the outer membrane was treated with phenol-water. In contrast to [14C]decanoate, the percent distribution of [3H]glycerol in the outer and inner membranes was about 25 and 70% of the total incorporated activity, respectively. Most of the assimilated 3H was located in the phospholipid fraction of both membranes. However, no significant label was detected in either the protein or cell wall fraction. The following observations were made concerning lipid compositions in the outer and inner membranes by chemical and isotopic analyses. (i) The outer and inner membranes contained no detectable phosphatidyl glycerol or cardiolipin. (ii) A prominent radioactive compound, designated band III lipid, was found mainly in the outer membrane as a major radioactive spot when cells were grown with [14C]decanoate. This lipid contained phosphorus, 2-keto-3-deoxyoctulosonic acid and 3-OH fatty acid but no detectable glycerol. This lipid was identified tentatively to be 2-keto-3-deoxyoctulosonic acid-lipid A. (iii) Although the ubiquity of phosphatidyl ethanolamine plasmalogen in both outer and inner membranes was confirmed, the occurrence of the molecular species of phosphatidyl ethanolamine plasmalogen was quite different in the outer and inner membranes.     

The efficiency of immunolabel on Lowicryl sections compared to theoretical predictions

The surface of thin sections of aldehyde-fixed biological material shows a specimen-related relief of 2-6 nm with Lowicryl. Epon sections are about three times smoother. The relief is the consequence of thin-sectioning being in reality a cleavage. Epitopes are supposed to be laid open (or set free) because cleavage follows the interfaces between protein and Lowicryl. We have developed a simple theory on this basis and have theoretically estimated the efficiency of on-section labeling and compared it with experimental data. For randomly dispersed proteins in cytoplasm, Lowicryl sections will yield significant label only when the concentration of the antigen is about 10 microM or more. The complex situation of more compact proteins, as represented by fibers, sheets, and biological membranes is discussed and the difficulty of significant calculations is explained. Pre-embedding labeling and melted cryosections should give 10-30 times more label. The possible reasons for the observed much smaller gain of not more than two to three times are discussed.     

In vivo labeling of Escherichia coli cell envelope proteins with N-hydroxysuccinimide esters of biotin.

The primary amine coupling reagents succinimidyl-6-biotinamido-hexanoate (NHS-A-biotin) and sulfosuccinimidyl-6-biotinamido-hexanoate (NHS-LC-biotin) were tested for their ability to selectively label Escherichia coli cell envelope proteins in vivo. Probe localization was determined by examining membrane, periplasmic, and cytosolic protein fractions. Both hydrophobic NHS-A-biotin and hydrophilic NHS-LC-biotin were shown to preferentially label outer membrane, periplasmic, and inner membrane proteins. NHS-A- and NHS-LC-biotin were also shown to label a specific inner membrane marker protein (Tet-LacZ). Both probes, however, failed to label a cytosolic marker (the omega fragment of beta-galactosidase). The labeling procedure was also used to label E. coli cells grown in low-salt Luria broth medium supplemented with 0, 10, and 20% sucrose. Outer membrane protein A (OmpA) and OmpC were labeled by both NHS-A- and NHS-LC-biotin at all three sucrose concentrations. In contrast, OmpF was labeled by NHS-A-biotin but not by NHS-LC-biotin in media containing 0 and 10% sucrose. OmpF was not labeled by either NHS-A- or NHS-LC-biotin in E. coli cells grown in medium containing 20% sucrose. Coomassie-stained gels, however, revealed similar quantities of OmpF in E. coli cells grown at all three sucrose concentrations. These data indicate that there was a change in outer membrane structure due to increased osmolarity, which limits accessibility of NHS-A-biotin to OmpF.     

Two-stage model for integration of the lysis protein E of ΦX174 into the cell envelope of Escherichia coli

Abstract: As a tool for determining the topology of the small, 91-amino acid ΦX174 lysis protein E within the envelope complex of Escherichia coli , a lysis active fusion of protein E with streptavidin (E-FXa-StrpA) was used. The E-FXa-StrpA fusion protein was visualised using immune electron microscopy with gold-conjugated anti-streptavidin antibodies within the envelope complex in different orientations. At the distinct areas of lysis characteristic for protein E, the C-terminal end of the fusion protein was detected at the surface of the outer membrane, whereas at other areas the C-terminal portion of the protein was located at the cytoplasmic side of the inner membrane. These results suggest that a conformational change of protein E is necessary to induce the lysis process, an assumption supported by proteinase K protection studies. The immune electron microscopic data and the proteinase K accessibility studies of the E-FXa-StrA fusion protein were used for the working model of the E-mediated lysis divided into three phases: phase 1 is characterised by integration of protein E into the inner membrane without a cytoplasmic status in a conformation with its C-terminal part facing the cytoplasmic side; phase 2 is characterised by a conformational change of the protein transferring the C-terminus across the inner membrane; phase 3 is characterised by a fusion of the inner and outer membranes and is associated with a transfer of the C-terminal domain of protein E towards the surface of the outer membrane of E. coli.     

Immuno-ultrastructural localization of involucrin in squamous epithelium and cultured keratinocytes

Involucrin immunoreactivity was localized ultrastructurally with protein A--gold in epidermis and cultured keratinocytes embedded in Lowicryl K4M. In the skin, immunoreactivity was found predominantly in cells of the granular layer and inner stratum corneum. The label was associated primarily with amorphous cytoplasmic material and especially keratohyaline granules. Some labeling was observed at the cell periphery, but little with keratin filaments. Tissue samples examined without aldehyde fixation showed relatively greater labeling in the outer stratum corneum than fixed tissue. In cultured cells, the labeling was also associated primarily with cytoplasmic granular material and to a lesser extent with the cell periphery. Upon treatment with the ionophore X537A, keratin filaments were found in aggregated arrays and the plasma membranes became convoluted. That involucrin immunoreactivity persisted in the cytoplasm in cultured cells and in vivo after cross-linking occurs could account for considerable isopeptide bonding detected in epidermal keratin fractions and indicates that not all the involucrin participates in envelope formation.     

Specific location of penicillin-binding proteins within the cell envelope of Escherichia coli.

This communication deals with the location of penicillin-binding proteins in the cell envelope of Escherichia coli. For this purpose, bacterial cells have been broken by various procedures and their envelopes have been fractioned. To do so, inner (cytoplasmic) and outer membranes were separated by isopycnic centrifugation in sucrose gradients. Some separation methods (Osborn et al., J. Biol. Chem. 247:3962-3972, 1972; J. Smit, Y. Kamio, and H. Nikaido, J. Bacteriol. 124:942-958, 1975) revealed that penicillin-binding proteins are not exclusively located in the inner membrane. They are also found in the outer membrane (A. Rodríguez-Tébar, J. A. Barbas, and D. Vásquez, J. Bacteriol. 161:243-248, 1985). Under the milder conditions for cell rupture used in this work, an intermembrane fraction, sedimenting between the inner and outer membrane, can be recovered from the gradients. This fraction has a high content of both penicillin-binding proteins and phospholipase B activity and may correspond to the intermembrane adhesion sites (M. H. Bayer, G. P. Costello, and M. E. Bayer, J. Bacteriol. 149:758-769, 1982). We postulate that this intermembrane fraction is a labile structure that contains a high amount of all penicillin-binding proteins which are usually found in both the inner and outer membranes when the adhesion sites are destroyed by the cell breakage and fractionation procedures.     

Induction of membrane permeability in Escherichia coli mediated by lysis protein of the ColE7 operon

Induction of the lysis protein of the ColE operon is known to be essential for colicin release. Thus far, the involvement of inner membrane in this unique protein exportation process has not been elucidated. In this work, fluorescent dyes were used to monitor the permeability change of both inner and outer membranes in response to induction of the lysis protein. We found that induction of permeability of the inner membrane appeared earlier than that of the outer membrane before the occurrence of the decline in culture turbidity. Interestingly, we also found that change of outer membrane permeability was alleviated in the outer membrane phospholipase A (OMPLA)-deficient mutant 135 min after induction. Thus, in this work, we show that permeability change of the inner membrane induced by the lysis protein is likely involved in the basal level of colicin release. A greater release of colicin coincided with the decline in culture turbidity and should be associated with the activation of OMPLA at the late stage of induction of the lysis protein.     

Proline 21, a residue within the α-helical domain of ΦX174 lysis protein E, is required for its function in Escherichia coli

ΦX174 lysis protein E-mediated lysis of Escherichia coli is characterized by a protein E-specific fusion of the inner and outer membrane and formation of a transmembrane tunnel structure. In order to understand the fusion process, the topology of protein E within the envelope complex of E. coli was investigated. Proteinase K protection studies showed that, during the time course of protein E-mediated lysis process, more of the fusion protein E-FXa-streptavidin gradually became accessible to the protease at the cell surface. These observations postulate a conformational change in protein E during induction of the lysis process by movement of the C-terminal end of the protein throughout the envelope complex from the inner side to the outer side spanning the entire pore and fusing the inner and outer membranes at distinct areas. The initiation mechanism for such a conformational change could be the cis–trans isomerization of proline residues within α-helical membrane-spanning segments. Conversion of proline 21, presumed to be in the membrane-embedded α-helix of protein E, to alanine, glycine, serine and valine, respectively, resulted in lysis-negative E mutant proteins. Proteinase K accessibility studies using streptavidin as a reporter fused to the P21G mutant protein showed that the C-terminal part of the fusion protein is not translocated to the outer side of the membrane, suggesting that this proline residue is essential for the correct folding of protein E within the cell wall complex of E. coli . Oligomerization of protein P21G-StrpA was not disturbed.     

Localization of pepsinogen and cellular differentiation in the human gastric mucosa using lowicryl K4M

The localization of pepsinogens (PG A and PG C) was studied intracellularly in human gastric biopsies embedded in Lowicryl K4M, using affinity purified antibodies and protein A-gold. The homogeneous secretory granules of the chief cells contained both PG A and PG C, as was proved in serial sections. Identical reaction was seen in the core of the biphasic mocous neck cell granules, whereas the mantle did not label. Even the rough endoplasmic reticulum (RER) and Golgi complex of the chief- and mucous neck cells contained label. Transitional cells identified by the presence of granules of both chief- and mucous neck cells were seen. This type of mucous neck cell is thought to transform into a chief cell. However an increase of RER that could explain an increase of the pepsinogen production was not observed. A mixture of these granules were also found in morphologically characterized young parietal cells, suggesting a common precursor for these three cell-types. These observations makes the transformation from mucous neck- into chief cells questionable. In conclusion Lowicryl K4M appeared to be a significant improvement compared to the Epon 812. Its shows a better preservation of both cytoplasmic antigens and cellular fine structure. This improvement adds information on the transformation hypothesis. Lowicryl K4M enables us, firstly to distinguish PG A and C synthesizing RER in different types of cell and secondly to recognize immature cells with the characteristics of chief-, mucous neck-, and parietal cells in the fundic gland. Very likely these three cell-types all arise from a common precursor. It is questionable that in normal human gastric mucosa the mucous neck cells transform into chief cells.