The Profile of Antioxidant Systems and Lipid Peroxidation Across the Crypt-Villus Axis in Rat Intestine

The distribution of lipid peroxiation and profile of antioxidant-pro-oxidant enzyme systems have been studied in rat intestinal enterocyte across the length of villi. The MDA levels estimated as a measure of lipid peroxidation, under induced or uninduced in vitro conditions, indicated markedly high levels at villus tip cells compared to that in the crypt base. The activities of glutathione-S-transferase and glutathione reductase were three- to sixfold higher in villus tip cells compared to that in the crypt base. However the levels of catalase and superoxide dismutase showed a reverse pattern, being high in the crypt base and lowest in the villus tip region. Feeding coconut oil, sunflower oil, or groundnut oil did not modify the distribution pattern of these systems across crypt-villus unit in rat intestine. These findings suggest that the large amount of free radicals generated in villus tip cells may be responsible for the release of enterocytes from the villus tip as a consequence of apoptosis.     

Characterization of isolated duodenal epithelial cells along a cryptvillus axis in rats fed diets with different iron content

The intestinal mucosa is characterized by cell proliferation, commitment, differentiation, digestion and absorption. These processes occur at specified locations along the crypt to villus axis. A technique is reported for the isolation of cells along this axis which allows the study of any one of these processes in an enriched population of cells. As an example, the uptake of transferrin-bound iron by enterocytes was studied. Rats were fed diets normal, high (3% carbonyl iron) or low in iron for 12 days. Cells from either the duodenum or ileum were isolated by incubating in a Ca²⁺-, Mg²⁺-free, cation chelating solution for varying periods. The incorporation of thymidine into DNA was measured in these cells as a marker of the crypt region, while alkaline phosphatase and sucrase activities marked mature enterocytes. The in vivo uptake of transferrin-bound ⁵⁹Fe was measured in cells isolated either 2 or 4 h after intravenous injection. This procedure resulted in the isolation of 10 fractions of viable cells. Earlier fractions were enriched at least 10-fold in villus cells and the last fractions in crypt cells. Cells in intermediate fractions were at various stages of development. Uptake of transferrin-bound iron into enterocytes was highest with feeding an iron-loaded diet compared with control or iron-deficient diets. However, with all diets uptake was highest in crypt cells and this fell at the crypt-villus junction to be only 25%, as high at the villus tip as the crypt. A technique for the reproducible isolation of viable enterocytes along a crypt-villus axis is described. Transferrin receptor activity changes with maturation of the enterocyte.     

Cholesterol synthesis and low density lipoprotein uptake are regulated independently in rat small intestinal epithelium.

We have compared the rates of low density lipoprotein (LDL) uptake and cholesterol synthesis in the rat intestine. By using a constant infusion technique, total and receptor-independent uptake was determined with homologous rat LDL (rLDL) and methylated human LDL (Me-hLDL), respectively. The absolute rates of sterol synthesis were measured with [1-(14) C]-octanoate and [3H]water. The rates of rLDL uptake in whole gut segments were similar along the length of the small intestine, whereas the rates of sterol synthesis varied over a 5-fold range and were highest in the duodenum and distal ileum. When the mucosal epithelium was fractionated along the villus/crypt axis, both rLDL and Me-hLDL clearance by the enterocytes increased approximately 3-fold in going from the upper villus to the crypt cell fractions, in both jejunum and ileum. In both the whole gut segments and isolated cells, approximately 60% of LDL uptake was receptor dependent. When the rates of rLDL cholesterol uptake were calculated and related to the absolute rates of sterol synthesis in the same cell fractions in vivo, both processes were found to be distributed similarly along the villus/crypt axis. Furthermore, the majority of mucosal cholesterol (64-86%) was derived from local synthesis rather than from rLDL uptake at all locations along the intestinal villus. Finally, when sterol synthesis in the epithelial cells was varied up to 7-fold by feeding cholesterol, triglyceride, cholestyramine, or surfomer, rLDL uptake was essentially unchanged. Thus, in intestinal epithelial cells in vivo, the rate of LDL uptake was constant under circumstances in which changing needs for cellular cholesterol were met by changes in the rates of sterol synthesis.     

Gene expression profiling of intestinal epithelial cell maturation along the crypt-villus axis

BACKGROUND & AIMS: To define the genetic reprogramming that drives intestinal epithelial cell maturation along the crypt-villus axis, enterocytes were sequentially isolated from the villus tip to the crypts of mouse small intestine. METHODS: Changes in gene expression were assessed using 27,405-element complementary DNA microarrays (14,685 unique genes) and specific changes validated by Western blotting. RESULTS: A total of 1113 genes differentially expressed between the crypt and villus were identified. Among these, established markers of absorptive and goblet cell differentiation were up-regulated in villus cells, whereas Paneth cell markers were maximally expressed in crypt cells. The 1113 differentially expressed genes were significantly enriched for genes involved in cell cycle progression, RNA processing, and translation (all predominantly down-regulated during maturation) and genes involved in cytoskeleton assembly and lipid uptake (predominantly up-regulated during maturation). No enrichment for apoptosis-regulating genes was observed. We confirmed that Wnt signaling was maximal in the proliferative compartment and observed a decrease in MYC and an increase in MAD and MAX expression during the maturation program. Consistent with these changes, the 1113 genes were enriched for MYC targets, establishing the importance of this network in intestinal cell maturation. CONCLUSIONS: This database serves as a resource for understanding the molecular mechanisms of intestinal cell maturation and for dissection of how perturbations in the maturation process can lead to changes in gastrointestinal physiology and pathology, particularly intestinal tumorigenesis.     

Induction of apoptosis before shedding of human intestinal epithelial cells

OBJECTIVES: Human intestinal epithelial cells (IECs) derive from stem cells at the crypt base and migrate along the so-called crypt-villus axis toward the intestinal lumen. As they reach the luminal surface in the colon or the villus tip in the small intestine, IECs are shed and their life cycle is terminated. The role of apoptosis during IEC migration along the crypt-villus axis has been subject to studies with conflicting results. In this study we use a novel approach to identify the initiation of apoptosis within normal human IECs. METHODS: Normal mucosa from the large and small human intestine was analyzed employing a novel antibody directed against activated caspase-3--an early marker of apoptosis. RESULTS: IECs initiate the apoptotic cascade as they approach the area of shedding before displaying evident morphological features of apoptosis. IECs of the small bowel also show caspase-3 activation in the small intestinal crypt base, whereas IECs of the colononic crypt base rarely show evidence of ongoing apoptosis. CONCLUSIONS: These findings indicate that apoptosis is initiated in human IECs as they reach the luminal surface/villus tip and before shedding. Furthermore, they show that different sections of the intestinal tract vary significantly in the rate of IEC apoptosis, possibly reflecting their difference in susceptibility to epithelial cell neoplasia.     

Regulation of intestinal epithelial cell growth by transforming growth factor type beta.

A nontransformed rat jejunal crypt cell line (IEC-6) expresses transforming growth factor type beta 1 (TGF-beta 1) mRNA, secretes latent 125I-labeled TGF-beta 1 competing activity into culture medium, and binds 125I-labeled TGF-beta 1 to specific, high-affinity (Kd = 3.7 pM) cell surface receptors. IEC-6 cell growth is markedly inhibited by TGF-beta 1 and TGF-beta 2 with half-maximal inhibition occurring between 0.1 and 1.0 ng of TGF-beta 1 per ml. TGF-beta 1-mediated growth inhibition is not associated with the appearance of biochemical markers of enterocyte differentiation such as alkaline phosphatase expression and sucrase activity. TGF-beta 1 (10 ng/ml) increases steady-state levels of its own mRNA expression within 8 hr of treatment of rapidly growing IEC-6 cells. In freshly isolated rat jejunal enterocytes that are sequentially eluted from the crypt villus axis, TGF-beta 1 mRNA expression is most abundant in terminally differentiated villus tip cells and least abundant in the less differentiated, mitotically active crypt cells. We conclude that TGF-beta 1 is an autoregulated growth inhibitor in IEC-6 cells that potentially functions in an autocrine manner. In the rat jejunal epithelium, TGF-beta 1 expression is most prominently localized to the villus tip--i.e., the region of the crypt villus unit that is characterized by the terminally differentiated phenotype. These data suggest that TGF-beta 1 may function in coordination of the rapid cell turnover typical for the intestinal epithelium.     

gamma-glutamyl transpeptidase of rat intestine: localization and possible role in amino acid transport.

gamma-Glutamyl transpeptidase (gamma-GT), an enzyme possibly involved in amino acid transport, was investigated in rat small intestine using the synthetic substrate L-gamma-glutamyl-p-nitroanilide. Enzyme localization and characteristics were correlated with features of amino acid uptake. gamma-GT activity copurified with sucrase and alkaline phosphatase. Activity was maximal at pH 8.2 and was stimulated by monovalent cations. The relative specificity of the gamma-GT reaction with diglycine and eight essential amino acids as substrates correlated well with the rate of intestinal absorption of this dipeptide and these amino acids as observed by others. gamma-GT activity was 12-fold greater in the jejunum than in the ileum, again in agreement with relative rates of amino acid absorption along the length of rat intestine. The specific activity of gamma-GT in villus tip cells was 10 times greater than in crypt cells, and amino acid uptake was 2 to 6 times greater with villus tip than with crypt cells. Bromosulfophthalein, a noncompetitive inhibitor of gamma-GT, inhibited amino acid uptake. These studies support the concept that membrane gamma-GT may be involved in amino acid and dipeptide uptake, and indicate that further investigation of such involvement may be conveniently pursued using mammalian small bowel.     

Intestinal morphology and cytokinetics in pancreatic insufficiency

Intraluminal pancreatic enzymes influence intestinal function, adaptation, and susceptibility to injury. These effects may be mediated partly through changes in the rate of epithelial cell turnover. We assessed intestinal morphology and cytokinetics in a rat model of exocrine pancreatic insufficiency that does not alter anatomic relationships or animal growth. Pancreatic duct occlusion was performed by applying metal clips on both sides along the common bile duct. Control animals underwent sham-operation with exposure and manipulation of the pancreas without duct occlusion. Twelve days later, pulse labeling with tritiated thymidine was performed, and mitotic arrest was induced with colcemid. Groups of animals were sacrificed at 0 and 2 hr after colcemid injection. Specimens for histopathology, morphometry, and autoradiography were obtained from duodenum, proximal jejunum, distal jejunum, and ileum. Labeling index, grain counts, mitoses per crypt, cells per crypt, cells per villus, crypt depth, villus height, and number of goblet cells per villus were used as end points. Pancreatic duct occlusion resulted in increased labeling index across intestinal segments relative to sham-operated controls (P<0.01) and increased labeling index and mitotic rate in distal compared to proximal intestine (P<0.05). Grain-count histograms were similar in the two experimental groups. There were no significant morphologic differences between pancreatic duct-occluded animals and controls. Exocrine pancreatic insufficiency increases crypt cell proliferation in distal small intestine but does not alter the duration of S phase. These changes are most likely due to an increase in the size of the proliferative compartment and may be partly responsible for changes in small bowel function and response to injury.Supported by grant 88.616 from The Norwegian Cancer Society.     

Cholesterol synthesis and high density lipoprotein uptake are regulated independently in rat small intestinal epithelium.

The rates of high density lipoprotein HDL uptake and cholesterol synthesis were compared in the normocholesterolaemic (SW) and genetically hypercholesterolaemic (RICO) rat intestine. The RICO rat has a hyperintestinal cholesterol synthesis. 14C sucrose, a marker which becomes irreversibly entrapped within the cells, was used to measure total rat HDL uptake over 24 hours in the various cells of the small intestinal mucosa. The rates of sterol synthesis were estimated in vivo with 1-14C acetate, as previously validated. The rates of HDL uptake in the upper villus cells were similar along the length of the small intestine in both types of rat, but the rates of sterol synthesis varied up to eightfold. When the mucosal epithelium was divided along the villus/crypt axis, HDL uptake increased two to threefold and cholesterol synthesis two to fivefold in the upper villus compared with the crypt cells in both SW and RICO rats. The high cholesterogenesis in the mucosal cells of the RICO rat is not related to a modified HDL cholesterol uptake. Thus, cholesterol synthesis and HDL uptake seem to be regulated independently in the rat small intestinal mucosa.     

Glutathione and gamma-glutamyl cycle enzymes in crypt and villus tip cells of rat jejunal mucosa.

Villus tip cells and crypt cells of rat jejunal mucosa were separated by the planning procedure of Imondi et al. and were studied with respect to their activities of the enzymes of the gamma-glutamyl cycle and glutathione content. The villus tip cells exhibit much higher gamma-glutamyl transpeptidase activities than do the crypt cells: thus, gamma-glutamyl trnaspeptidase appears to be a villus-specific enzyme. gamma-Glutamyl cyclotransferase and the enzymes required for glutathione synthesis are not specifically localized to either the crypt or villus tip cells but are present in both. The crypt cells have a high concentration of glutathione (4-5 mM) comparable to the levels found in liver and kidney; in contrast, the villus tip cells have much lower concentrations. On fasting, the glutathione concentration decreased markedly in both villus tip and crypt cells; feeding of protein, but not of sucrose, led to increased glutathione concentrations. The migration of cells from the undifferentiated crypt cell region to the villus tip is associated with structural and biochemical changes that equip the cell for its mature functional activities, which include transport. The present findings indicate that such cellular differentiation and migration is associated with a marked increase in gamma-glutamyl transpeptidase activity and in the utilization of glutathione.     

Na+ transport in jejunal crypt cells.

As enterocytes migrate from crypts to villi they differentiate and mature. To examine the effect of epithelial differentiation on ion transport we studied 22Na+ efflux and (Na+--K+)-adenosine triphosphatase activity in suspensions of epithelial cells selectively isolated from different regions of the villus to compare crypt cells with villous tip cells. Enterocytes were isolated from rat jejunum by a dilation-vibration technique. Thymidine kinase, sucrase, and alkaline phosphatase activities were measured as markers of specific cell populations. Compared to villous cells, cells from the crypt region demonstrated lower (Na"--K+)-adenosine triphosphatase activity, lower total and passive Na+ efflux rate constants, and failure of Na+ transport to respond to an actively transported nonelectrolyte.     

Localization of endotoxin in the rat intestinal epithelium

High levels of circulating lipopolysaccharide (LPS) cause intestinal inflammation and increased permeability to bacteria and toxins. To better understand the effects of LPS on the gut, confocal microscopy and immunofluorescence staining were used to examine the distribution of LPS in the rat intestine after intravenous or enteral administration. LPS was localized in macrophages in the lamina propria from 1 h to >28 days after intravenous injection. LPS was also detected in the epithelial cells from 8 h to 7 days after injection. In contrast, LPS administered enterally was found in the gut lumen in close proximity to the mucosa but was not detected in enterocytes at any time. The concentration of LPS in enterocytes near the villus tip provides a mechanism for the clearance of endotoxin, by the turnover and shedding of LPS-containing enterocytes into the gut lumen, that has not been previously described.     

Glucose increases hepatic lipase expression in HepG2 liver cells through upregulation of upstream stimulatory factors 1 and 2

Aims/hypothesis  Elevated hepatic lipase (HL, also known as LIPC) expression is a key factor in the development of the atherogenic lipid profile in type 2 diabetes and insulin resistance. Recently, genetic screens revealed a possible association of type 2 diabetes and familial combined hyperlipidaemia with the USF1 gene. Therefore, we investigated the role of upstream stimulatory factors (USFs) in the regulation of HL. Methods  Levels of USF1, USF2 and HL were measured in HepG2 cells cultured in normal- or high-glucose medium (4.5 and 22.5 mmol/l, respectively) and in livers of streptozotocin-treated rats. Results  Nuclear extracts of cells cultured in high glucose contained 2.5 ± 0.5-fold more USF1 and 1.4 ± 0.2-fold more USF2 protein than cells cultured in normal glucose (mean ± SD, n = 3). This coincided with higher DNA binding of nuclear proteins to the USF consensus DNA binding site. Secretion of HL (2.9 ± 0.5-fold), abundance of HL mRNA (1.5 ± 0.2-fold) and HL (–685/+13) promoter activity (1.8 ± 0.3-fold) increased in parallel. In chromatin immunoprecipitation assays, the proximal HL promoter region was immunoprecipitated with anti-USF1 and anti-USF2 antibodies. Co-transfection with USF1 or USF2 cDNA stimulated HL promoter activity 6- to 16-fold. USF and glucose responsiveness were significantly reduced by removal of the −310E-box from the HL promoter. Silencing of the USF1 gene by RNA interference reduced glucose responsiveness of the HL (−685/+13) promoter region by 50%. The hyperglycaemia in streptozotocin-treated rats was associated with similar increases in USF abundance in rat liver nuclei, but not with increased binding of USF to the rat Hl promoter region. Conclusions/interpretation  Glucose increases HL expression in HepG2 cells via elevation of USF1 and USF2. This mechanism may contribute to the development of the dyslipidaemia that is typical of type 2 diabetes.     

Distribution of immunoreactive alkaline phosphatase in the adult rat ileum by immunoperoxidase staining at the light microscopic level

Our prior immunocytochemical studies using monospecific antibody to alkaline phosphatase, Bouin's fixation, and paraffin sections demonstrated a decreasing gradient of villus brush border staining from the proximal to the distal rat small intestine. In addition, we noted an unusual pattern of staining in the terminal centimeter of the adult rat ileum: the villus brush border staining was less intense than crypt brush border staining. To determine whether this pattern of staining was present throughout the entire ileum, we examined alkaline phosphatase staining in two separate jejunal sites and the entire lowest third of the intestine of adult Wistar rats. With Bouin's fixation and paraffin embedding, both conventional and germ-free rats showed the same unusual staining pattern throughout the entire ileum. This pattern suggested that bacterial proteases were not responsible for the diminished ileal brush border alkaline phosphatase. However, when acetone fixation and cryostat sections were used with the avidin-biotin-peroxidase complex system, the previously noted reversed gradient of staining between the ileal villus and crypt areas was no longer present. Rather, ileal crypt brush border staining was less than ileal villus brush border staining. With either methodology, jejunal villus brush border staining was significantly more intense than ileal brush border staining, whereas the deep crypt brush border staining was not significantly different between the two regions. The present study reinforces the need for a combination of methodologies in order to best and most accurately localize certain antigens with immunocytochemistry. It also confirms a decreasing proximal to distal gradient for villus brush border alkaline phosphatase despite similar deep crypt brush border staining throughout the small intestine.     

Developmental characteristics of adapting mouse small intestine crypt cells

BACKGROUND & AIMS: Following massive small bowel resection (SBR), the remnant intestine undergoes an adaptive process characterized by increases in a number of physiologic and morphologic parameters. These changes are the result of a stimulus that increases crypt cell mitosis and augments cellular progression along the villus axis. To better define this process, we identified patterns of gene expression specifically within adapting intestinal crypt cells following SBR. METHODS: Laser capture microdissection was used to isolate mouse intestinal crypt cells following SBR or sham operation. Multiple biological and technical complementary DNA microarray replicates allowed rigorous statistical analyses for identification of important expression profiles. Major groups of genes were classified as to site of action, functional pathway, and possible regulatory groups. RESULTS: A total of 300 genes differentially expressed at significant levels within adapting crypt enterocytes were analyzed. Comparison of this list of differentially expressed adapting crypt cell genes with a generalized mouse gene expression database (from 82 developing and adult mouse tissues) showed the greatest overlap with developing and immature intestinal tissues. We identified prominent groups of genes involved with cell growth, signal transduction, and nucleic acid binding. Genes not previously shown to be involved with adaptation or development and maturation were identified. CONCLUSIONS: Identification of similar genes coordinately regulated during both adaptation and development, processes that share key morphologic features, provides a basis for new mechanistic insights into these shared characteristics.     

Crypt/villus site of substrate-dependent regulation of mouse intestinal glucose transporters.

The intestinal epithelium is in a constant state of turnover, with cells differentiating at the crypts and then migrating toward the tips of the villi. Does substrate-dependent regulation of intestinal Na+/D-glucose cotransporters occur only in crypt cells, or can transport activity be subsequently reprogrammed in mature enterocytes? We used in situ, glucose-protectable specific phlorizin binding to determine site density of brush border glucose transporters in enterocytes fractionated along the crypt/villus axis of mice that were killed shortly after drastic changes in carbohydrate levels of their diets. Dietary carbohydrate-induced changes in site density of specific phlorizin binding initially appeared only in crypt cells before spreading, over the course of several days, to the villus tips. Thus, only crypt cells perceive the signal for glucose transporter regulation, and the observed time lag of diet-induced changes in intestinal glucose uptake is due mainly to cell migration times.     

Site Specific Delivery of Microencapsulated Fish Oil to the Gastrointestinal Tract of the Rat

The aim of this study was to design food grade matrices to deliver microencapsulated fish oil to the large bowel of the rat where the potential exists to retard inflammation and cancer development. Digestion in simulated gastric fluid and intestinal fluid demonstrated that only 4–6% of oil was released from the following dried emulsion formulations: 50% fish oil encapsulated in heated casein-glucose-dried glucose syrup (1:1:1) (Cas-Glu-DGS-50); 25% fish oil in casein-modified resistant starch (Hylon VII) (1:1) (Cas-Hylon-25); or 25% fish oil in Cas-Glu-Hylon (1:1:1) (Cas-Glu-Hylon-25). A short-term gavage study (0–12 h) with fish oil and Cas-Glu-DGS-50 demonstrated the appearance of fish oil long chain (LC) n-3 polyunsaturated fatty acids (PUFA) into the plasma indicating specific small intestinal absorption with little LC n-3 PUFA reaching the large bowel. In a 2-week-long term, daily gavage study, the bioavailability of fish oil and fish oil in Cas-Glu-DGS-50 or Cas-Hylon-25 demonstrated that fish oil and Cas-Glu-DGS-50 LC n-3 PUFA were incorporated into the tissue of the small intestine and colon, whereas Cas-Hylon-25 was resistant to degradation in the small intestine. The use of modified Hylon VII for targeted colonic delivery was confirmed in the final short-term gavage study (0–14 h) using Cas-Glu-Hylon-25 with [¹⁴C]-trilinolenin as a marker incorporated into the microcapsules, where up to 60% of the labeled oil reached the large bowel. Depending on the microencapsulating matrix employed, fish oil can be delivered selectively to the small intestine or to a high degree to the large bowel.