Isolation of rat intestinal crypt cells

A technique is presented which yields single cells and intact crypts in suspension from unfixed rat intestinal mucosal epithelium. Everted lengths of intestine were digested by 27 mM sodium citrate in phosphate-buffered saline (pH = 7.3) at 37 degrees C. Mucosal cells were dislodged by vibratory stress (hand vortexing) following incubation for prescribed intervals at 37 degrees C in 1.5 mM ethylenediamine tetraacetic acid (EDTA) and 0.5 mM dithiothreitol (dtt). Alkaline phosphatase determinations, phase microscopy, and in vivo and in vitro evaluations of tritiated thymidine ([3H]TdR) incorporation were performed on isolated intestinal cells. Data indicate that cells were sequentially derived from villus tip to crypt base as judged by cellular morphology, alkaline phosphatase activity/mg protein and radioactivity per microgram protein. Upon completion of the intestinal cell isolation assay, scanning electron microscopy of the remaining intestine revealed that approximately 95% of the crypt openings were vacant; the villi were totally denuded; the supporting structures, including the lamina propria, appeared intact. In vitro radiolabelling of intestinal cell fractions enriched with crypts revealed a linear incorporation of [3H]TdR from 0-60 min which was strongly influenced by the presence of foetal calf serum (FCS). Measurements of the compensatory response of the mucosa to resection of 70% of the small bowel indicated that the mucosal cell separation is capable of detecting alterations in crypt cell proliferation. Previously, such alterations were monitored by other methods utilizing microdissection procedures or stathmokinetic agents.     

Improved isolation of villus and crypt cells from rat small intestinal mucosa.

An enzymic method is described which allows the isolation under comparable conditions of crypt and villus cells from rat jejunum with normal morphologic appearance and high metabolic activity when compared with previous preparations. The method is based on a differential scraping of short lengths of everted small intestine to yield two villus cell fractions and a gut wall residue. The scrapings and the gut tube are incubated for the same length of time in a HEPES-buffered modified Hanks' balanced salt solution containing hyaluronidase, DNase, and soybean trypsin inhibitor. The cells of the crypt region are recovered by a further scraping of the digested gut wall. Cells from all fractions are dispersed by gentle agitation, washed, and harvested by centrifugation. The final crypt and villus cells are 95--99% viable by dye exclusion and exhibit 5--20% cross-contamination on the basis of differential marker enzymes. The isolated crypt and villus cells prepared by the new procedure are suitable for comparative studies of metabolic activity in the absence of chelation-induced structural and metabolic abnormalities.     

Fluorescent labelling of intestinal epithelial cells reveals independent long-lived intestinal stem cells in a crypt

Background and aims

The dynamics of intestinal stem cells are crucial for regulation of intestinal function and maintenance. Although crypt stem cells have been identified in the intestine by genetic marking methods, identification of plural crypt stem cells has not yet been achieved as they are visualised in the same colour.

Methods

Intestinal organoids were transferred into Matrigel® mixed with lentivirus encoding mCherry. The dynamics of mCherry-positive cells was analysed using time-lapse imaging, and the localisation of mCherry-positive cells was analysed using 3D immunofluorescence.

Results

We established an original method for the introduction of a transgene into an organoid generated from mouse small intestine that resulted in continuous fluorescence of the mCherry protein in a portion of organoid cells. Three-dimensional analysis using confocal microscopy showed a single mCherry-positive cell in an organoid crypt that had been cultured for >1 year, which suggested the presence of long-lived mCherry-positive and -negative stem cells in the same crypt. Moreover, a single mCherry-positive stem cell in a crypt gave rise to both crypt base columnar cells and transit amplifying cells. Each mCherry-positive and -negative cell contributed to the generation of organoids.

Conclusions

The use of our original lentiviral transgene system to mark individual organoid crypt stem cells showed that long-lived plural crypt stem cells might independently serve as intestinal epithelial cells, resulting in the formation of a completely functional villus.     

Bacterial lipopolysaccharide reduced intestinal barrier function and altered localization of 7H6 antigen in IEC-6 rat intestinal crypt cells

The intestinal epithelial barrier restricts the passage of potentially toxic substances into the systemic circulation and is considered to be mostly mediated by tight junctions, though the mechanisms involved in the regulation of intestinal tight junctions are not yet fully understood. In the present study, we examined whether bacterial lipopolysaccharide (LPS) altered the barrier function of tight junction and localization of tight junctional proteins, ZO-1 and 7H6 antigen, in IEC-6 intestinal cells. Administration of LPS to the basolateral surface of IEC-6 cells disrupted the barrier function and caused the disappearance of 7H6 antigen from the cell border, whereas LPS administered to the apical surface altered neither the barrier function nor the localization of 7H6 antigen in IEC-6 cells. On the other hand, the localization of ZO-1 was not influenced by these treatments of LPS. These results suggest that the interaction of LPS with the basolateral surface of intestinal epithelial cells disrupts the barrier function and 7H6 antigen take part in the maintenance of the barrier function in IEC-6 cells. J. Cell. Physiol. 171:284–290, 1997. © 1997 Wiley-Liss, Inc.     

Changes in tight junctions of rat intestinal crypt cells associated with changes in their mitotic activity.

The freeze-fracture appearance of tight junctions between rat duodenal crypt cells was studied in normal, mitotically suppressed, and mitotically enhanced animals. In normal animals crypt cell tight junctions present a pleomorphic appearance. The population includes junctions resembling postmitotic junctions of the intestinal villus, junctions composed largely or completely of particle chains, and regions at the cell apex in which junctions are absent for 3-4 micron distances laterally. Mitotic suppression by inhibition of DNA synthesis with cytosine arabinoside results in the disappearance of pleomorphism and crypt tight junctions progressively come to resemble those of the intestinal villus. With recovery from the drug and further synchronization with Colcemid, the crypt cells undergo a mitotic burst, and all varieties of unusual junctional configurations are observed with increased frequency.     

Protein kinase C and leucine metabolism in intestinal crypt cells

Intestinal cells were separated into fractions rich in villous or crypt cells. Alkaline phosphatase, present in villous cells, but absent from crypt cells, was used as a marker. Crypt cells were 3-6 times as active as villous cells in the metabolism of leucine or mevalonate. The previously reported stimulatory effect of albumin was twice as strong in crypt cells as that in villous cells. Reduced glutathione, spermidine HCl and ethanolamine (0.5-10 mM) did not replace albumin, the effect of which was maximal at 0.02 mM. Protein kinase C was shown to be present mainly in crypt cells.     

Modulation of EGF-receptors by phorbol ester in small intestinal crypt cells

We have previously shown that EGF promotes growth and proliferation of enterocytes isolated from the crypts of the rat small intestine (IEC-6). In the present studies we have measured the affinity of EGF for its receptor, and estimated the number of surface EGF receptors on IEC-6 cells. Scatchard analysis indicates IEC-6 cells display 45,000 EGF receptors per cell with a dissociation constant of 41 pM. Treatment with phorbol-12-myristate-13-acetate (PMA) results in a dose-dependent inhibition of cell growth which is paralleled by reduced binding of 125I-EGF. Incubation of IEC-6 cells with 10 nM PMA results in a 70 percent decrease in the number of EGF receptors without a significant change of receptor affinity (kd 68 pM vs 41 pM). PMA treatment is also associated with a significant increase of protein kinase-C activity in IEC-6 cells. The reciprocal relationship between protein kinase-C activation and EGF receptors suggests in this cell line of crypt enterocytes, protein kinase-C may inhibit cellular proliferation by modulating EGF receptors.     

Posttranslational regulation of sucrase-isomaltase expression in intestinal crypt and villus cells

Expression and synthesis of sucrase-isomaltase (SI) were studied in human jejunum and in the colon tumor cell lines Caco-2 and HT-29. Twelve monoclonal antibodies produced against the adult human intestinal enzyme were shown to recognize specifically SI by immunoprecipitation of 14C-labeled membrane proteins, analysis of enzyme activities in the immunoprecipitates, and immunoblotting. These antibodies produced markedly different patterns of immunofluorescent staining of the intestinal mucosa. Three of them were specific for the absorptive villus cells, while the other nine also stained the luminal membrane of the proliferative crypt cells, with different intensities which paralleled their ability to recognize SI in immunoblots. Sequential immunoprecipitation of SI solubilized from purified brush borders or entire jejunum with four selected antibodies demonstrated the presence of different forms of the enzyme, expressed by either villus or crypt cells. Two immunologically distinct forms of high mannose precursor (hmP1 and hmP2) were also identified in both jejunal mucosa and colon tumor cells. They were present as monomers and their immunological differences were preserved under various ionic and pH conditions. Pulse-chase studies indicated that, in Caco-2 cells, hmP1 is converted into hmP2 within 30 min of chase, and hmP2 is then processed into the complex-glycosylated precursor destined for the brush border membrane. hmP1 was immunologically related to the mature SI present in crypt cells and lacked the epitopes specific for mature SI expressed by villus cells. These results demonstrated that sucrase-isomaltase is synthesized by both crypt and villus cells, but processing of the cotranslationally glycosylated high mannose precursor is dependent on the state of differentiation of the enterocytes. This may represent a general mechanism for the regulation of expression of differentiated cell products at the post-translational level.     

RNA synthesis by villus and crypt cell nuclei of rat intestinal mucosa

Rat intestinal mucosa was separated by eversion and vibration to provide a sequence of fractions from predominantly villus cells to predominantly crypt cells. The proportions of these cell types in each fraction were computed from the concentrations of alkaline phosphatase (villus cells) and thymidine kinase (crypt cells) in each population. The isolated mucosal fractions varied from about 90% villus cells to 90% crypt cells. Following injection of the rats with [³H]thymidine, the nuclei were isolated from each mucosal cell fraction and the amount of radioactivity incorporated into DNA was measured as an index of crypt cell abundance. The isolated nuclei were also incubated with ribonucleoside triphosphates and the amount of RNA synthesized was measured. Nuclei labeled with [³H]thymidine were found only in fractions rich in crypt cells, whereas capacity for RNA synthesis remained very active in mucosal fractions consisting predominantly of villus cells. It is concluded that non-dividing villus cells continue to make RNA.     

Sodium-dependent D-glucose transport in brush-border membrane vesicles from isolated rat small intestinal villus and crypt epithelial cells

Differentiation and maturation of enterocytes occur with migration from the crypt to villus compartments. To investigate the effect of epithelial cell differentiation on sodium-dependent D-glucose transport, brush-border membrane vesicles were prepared from small intestinal epithelial cell suspensions selectively isolated from villus and crypt populations. Enterocytes were isolated with a morphologically monitored sequential cell dissociation method. Thymidine kinase, sucrase, and alkaline phosphatase activities were measured as differentiation markers of specific cell populations. Brush-border membrane vesicles were purified and their kinetic characteristics defined with a rapid filtration method under conditions of a zero-trans, 100 mM cis-NaSCN gradient. Typical "overshoot" phenomena characteristic of sodium D-glucose cotransport were observed for both villus (five- to eight-fold equilibrium values) and crypt brush-border membrane vesicles (two- to four-fold equilibrium values). Kinetics analyses of the initial D-glucose flux in brush-border membrane vesicles suggested the presence of at least two sodium-dependent D-glucose carriers in the villus and only a single carrier in the crypt compartments. These data indicate that sodium D-glucose cotransport occurs in brush-border membranes of both villus and crypt populations. Moreover, quantitative and qualitative differences between these two membrane populations suggest that epithelial D-glucose transport processes are differentiation dependent and reflect the degree of enterocyte development.     

Keratin expression in rat intestinal crypt and villus cells. Analysis with a panel of monoclonal antibodies.

Seven monoclonal antibodies were prepared against cytoskeletal components of rat intestinal brush borders. In the following paper (Chandler, J. S., Calnek, D., and Quaroni, A., J. Biol. Chem. 266, 11932-11938), three of them were shown to be specific for, respectively, keratin 8 (RK4), keratin 19 (RK7), and a newly identified type I keratin (keratin 21) (RK5). With these antibodies we have investigated the changes in keratin gene expression accompanying intestinal cell differentiation. Keratin 21 was detected exclusively in differentiated villus cells and in goblet, enteroendocrine, and Paneth cells in the crypts; in the proliferative crypt cells keratin 19 was predominant. Analysis of keratins expressed by cultured rat crypt cells (IEC cells) confirmed the absence of keratin 21 in undifferentiated intestinal cells. Changes in keratin's expression similar to those observed with cell differentiation in the adult intestinal mucosa were also demonstrated during early fetal intestinal development: the stratified epithelium present at 15-16 days of gestation contained predominantly keratin 19 with only a small amount of keratin 8; keratin 21 was first detected at 18-19 days of gestation, concomitant with the appearance of a well formed brush border and an apical cytoplasmic terminal web. These results suggest that keratin tonofilaments may play a role in the morphological and structural alterations accompanying intestinal cell differentiation in vivo.     

Mucosal mast cells. I. Isolation and functional characteristics of rat intestinal mast cells

We have developed a procedure for the dispersion of mast cells from the intestinal lamina propria (LP) and epithelium of rats infected with the intestinal nematode, Nippostrongylus brasiliensis. The dispersed cells are morphologically and histochemically similar to intestinal mucosal mast cells (MMC) in situ and are distinguishable from peritoneal mast cells (PMC). MMC derived from the LP or epithelium of parasitized animals secrete histamine in response to the specific parasite antigens as well as anti-IgE. Unlike PMC, these cells are unresponsive to the basic secretagogues 48/80 and bee venom peptide 401. Similarly, bee venom peptide 401 conjugated with dansyl chloride binds to PMC and mast cells in the thymus and intestinal serosa, but not to mast cells in or derived from the intestinal LP and epithelium. Studies on PMC treated by the intestinal cell isolation procedure show that the functional characteristics of the MMC cannot be solely attributed to the isolation procedure. Thus, MMC have been isolated and shown to be morphologically, histochemically, and functionally different from PMC, as suggested by previous in vivo studies of the normal intestine.     

Compartmentalization of cholesterol metabolism and cellular growth in cultured intestinal crypt cells

Growth of rat intestinal crypt derived cells IEC-6 ceased when the key enzyme of cholesterol synthesis, hydroxymethylglutaryl-CoA reductase, was blocked by the competitive inhibitor mevinolin. This effect was reversed by the addition of mevalonolactone. LDL suppressed reductase activity as well as cholesterol synthesis from [14C]octanoate and stimulated acyl-CoA cholesterol acyltransferase, but failed to support cell growth despite rapid receptor mediated degradation even in the presence of low mevalonolactone concentrations. Inhibition of cholesterol esterification by Sandoz-Compound 58-035 enhanced cell growth in the presence of mevinolin, but did not promote proliferation in the additional presence of low-density lipoproteins. HDL3 but not HDL2 or tetranitromethane-modified HDL3 totally reversed the mevinolin induced inhibition of cell growth. This rescue by HDL3 was overcome by an increased dose of mevinolin. HDL3 derepressed reductase, stimulated cholesterol synthesis and reduced cholesterol esterification, but did not reverse the cholesterol synthesis inhibition by mevinolin. It is concluded that IEC-6 cells preferentially use endogenously synthesized cholesterol for membrane formation rather than low-density lipoprotein cholesterol. High-density lipoproteins appear to normalize cell growth in the presence of mevinolin by inhibition of cholesterol esterification and probably by inducing the formation of non sterol products of mevalonate.     

Fetal gut mesenchyme induces differentiation of cultured intestinal endodermal and crypt cells

An experimental model was designed to analyze the effect of fetal gut mesenchyme on the cytodifferentiation of crypt cells and of embryonic progenitor cells. The cells used were the rat intestinal crypt cell line, IEC-17, and primary cell cultures prepared form isolated 14-day-old fetal intestinal endoderm (EC). Both cultures prepared from isolated 14-day-old fetal rat intestinal endoderm (EC). Both types of cells were associated with 14-day-old fetal rat gut mesenchyme (Rm) and grafted under the kidney capsule of adult rats. Seventy percent of the Rm/EC and ten percent of the Rm/IEC recombinants, recovered after 9 days, exhibited well-vascularized structures in which the mesenchyme had induced morphogenesis of the cells into a villus epithelium. The four main intestinal epithelial cell types, absorptive, goblet, endocrine, and Paneth cells, were identified using electron microscopy. Biochemical determinations of enzyme activities associated with brush border membranes revealed that alkaline phosphatase, lactase, sucrase, and maltase were expressed in both types of associations. These results were confirmed by immunofluorescence staining using monoclonal antibodies to brush border enzymes. Both enzyme assays and immunocytochemistry showed that the amount of enzymes present in the brush border membrane of Rm/IEC grafts was in general lower than that of the Rm/EC recombinants. The results indicate that fetal rat gut mesenchyme enables morphogenesis and cytodifferentiation of both crypt and embryonic progenitor cells.     

Stem cell self-renewal in intestinal crypt

As a rapidly cycling tissue capable of fast repair and regeneration, the intestinal epithelium has emerged as a favored model system to explore the principles of adult stem cell biology. However, until recently, the identity and characteristics of the stem cell population in both the small intestine and colon has remained the subject of debate. Recent studies based on targeted lineage tracing strategies, combined with the development of an organotypic culture system, have identified the crypt base columnar cell as the intestinal stem cell, and have unveiled the strategy by which the balance between proliferation and differentiation is maintained. These results show that intestinal stem cells operate in a dynamic environment in which frequent and stochastic stem cell loss is compensated by the proliferation of neighboring stem cells. We review the basis of these experimental findings and the insights they offer into the mechanisms of homeostatic stem cell regulation.     

Puma: mauling the intestinal crypt

Cancer therapies utilizing chemotherapy or radiotherapy are constrained by risk of intestinal stem cell death. In this issue of Cell Stem Cell, Qiu et al. report that Puma deletion prevents intestinal degeneration following DNA damage, thus offering a target protein for the design of enhanced cancer treatments.