Gastrointestinal absorption of estrone sulfate in germfree and conventional rats

Steroids are extensively excreted in the bile of rats. There was no significant difference in biliary excretion of steroid following administration of [3H]-estrone sulfate into the proximal small intestine (PSI) of conventional (CVL; 17.8 +/- 62%; mean +/- SD) or germfree (GF; 28.2 +/- 5.3) rats. A similar finding resulted from administration into the distal small intestine (DSI)-CVL, 22.3 +/- 11.8%; GF, 11.4 +/- 3.7%. However, when the drug was given into the caecum, excretion in the bile of CVL rats after 5 h was 59.1% whereas in GF rats it was only 1.7%. When estrone was injected into the PSI and DSI of CVL and GF rats, absorption (as judged by excretion in bile) was more rapid than that seen with estrone sulfate. Five hours after injection into the PSI, biliary excretion was, in CVL 88.2% and in GF 81.7% and after injection into the DSI excretion was, in CVL 84.7% and in GF 83.6%. Absorption of estrone from the caeca of GF rats was apparently reduced (49.0% and 25.3% excreted in the bile of CVL and GF rats respectively). There was no significant difference in bile flow rate between CVL and GF rats. These results give unequivocal evidence of intact absorption of estrone sulfate from the small intestine of the rat. The rate of absorption is however very much reduced compared to the non-sulphated steroid. Estrone sulfate is not absorbed intact in the caecum but is hydrolysed by the gut microflora prior to absorption.     

Glutamine and ketone-body metabolism in the gut of streptozotocin-diabetic rats.

1. In short- and long-term diabetic rats there is a marked increase in size of both the small intestine and colon, which was accompanied by marked decreases (P less than 0.001) and increases (P less than 0.001) in the arterial concentrations of glutamine and ketone bodies respectively. 2. Portal-drained viscera blood flow increased by approx. 14-37% when expressed as ml/100 g body wt., but was approximately unchanged when expressed as ml/g of small intestine of diabetic rats. 3. Arteriovenous-difference measurements for ketone bodies across the gut were markedly increased in diabetic rats, and the gut extracted ketone bodies at approx. 7 and 60 nmol/min per g of small intestine in control and 42-day-diabetic rats respectively. 4. Glutamine was extracted by the gut of control rats at a rate of 49 nmol/min per g of small intestine, which was diminished by 45, 76 and 86% in 7-, 21- and 42-day-diabetic rats respectively. 5. Colonocytes isolated from 7- or 42-day-diabetic rats showed increased and decreased rates of ketone-body and glutamine metabolism respectively, whereas enterocytes of the same animals showed no apparent differences in the rates of acetoacetate utilization as compared with control animals. 6. Prolonged diabetes had no effects on the maximal activities of either glutaminase or ketone-body-utilizing enzymes of colonic tissue preparations. 7. It is concluded that, although the epithelial cells of the small intestine and the colon during streptozotocin-induced diabetes exhibit decreased rates of metabolism of glutamine, such decreases were partially compensated for by enhanced ketone-body utilization by the gut mucosa of diabetic rats.     

Effect of exercise on tissue protein synthesis in rats.

The effect of exercise on the protein metabolism in skeletal muscles (gastrocnemius and soleus), liver and small intestine was investigated in rats. Treadmill treatment for 7 d resulted in atrophy of the liver and small intestine, which was associated with a reduction in protein content. The rates of protein synthesis in the liver and small intestine were significantly suppressed in rats subjected to exercise. The change in protein synthesis in the visceral organs was mediated by the change in RNA activity (protein synthesis per unit RNA) but not by the change in RNA concentration. The tissue weight and the rate of protein synthesis in the gastrocnemius and soleus muscles were not affected by exercise. The results suggest that these changes in protein synthesis in the liver and small intestine may explain, at least partly, the atrophy of these organs which was observed after 7 d of exercise.     

Multiple forms of mutarotases from the kidney, liver, and small intestine of rats: purification, properties, subcellular localization and developmental changes

Comparative studies of mutarotase [aldose 1-epimerase, EC 5.1.3.3] from the kidney, liver and small intestine of rats were performed placing in the focus on the study of multiple forms. The findings obtained are as follows. Mutarotases from the kidney and liver of adult rats were both separated into four forms (types I-IV) by DEAE-cellulose column chromatography, whereas only two forms (types I and II) were detected in the small intestine. Liver mutarotase type I was further separated into types I1 and I2 by column chromatography on hydroxylapatite. Types I and II from the kidney and type II from the liver were purified to homogeneity as judged by isoelectric focusing on thin layer polyacrylamide gel. Of various physicochemical properties, only the Km for alpha-D-xylose and the isoelectric point were different among the multiple forms. Liver mutarotase was immunohistochemically localized in the nuclei of parenchymal cells and small intestine enzyme in the nuclei of mucosal cells, indicating similarity with the localization of kidney enzyme (in the nuclei of epithelial cells of renal tubules and glomeruli) which was reported in our previous paper [Experientia (1979) 35, 1094-1097]. The kidney mutarotase level increased gradually after birth and reached a maximum near adult level within 20 days. This developmental pattern was essentially the same as that in the liver but clearly different from that in the small intestine, in which the mutarotase activity of suckling rats was several times higher than that of adult rats. Distribution patterns of multiple forms (types I-IV) of the enzyme in the kidney and liver of 10-day-old rats were similar to those in respective tissues of adult rats. On the other hand, the small intestine of 10-day-old rats contained four forms (types I-IV), whereas there were only two forms (types I and II) in adult rats.     

The maximal activity of phosphate-dependent glutaminase and glutamine metabolism in late-pregnant and peak-lactating rats.

The maximal activity of phosphate-dependent glutaminase was increased in the small intestine, decreased in the liver and unchanged in the kidney of late-pregnant rats. This was accompanied by increases in the size of both the small intestine and the liver. The maximal activity of phosphate-dependent glutaminase was increased in both the small intestine and liver but unchanged in the kidney of peak-lactating rats. Enterocytes isolated from late-pregnant or peak-lactating rats exhibited an enhanced rate of utilization of glutamine and production of glutamate, alanine and ammonia. Arteriovenous-difference measurements across the gut showed an increase in the net glutamine removed from the circulation in late-pregnant and peak-lactating rats, which was accompanied by enhanced rates of release of glutamate, alanine and ammonia. Arteriovenous-difference measurements for glutamine showed that both renal uptake and skeletal-muscle release of glutamine were not markedly changed during late pregnancy or peak lactation; but pregnant rats showed a hepatic release of the amino acid. It is concluded that, during late pregnancy and peak lactation, the adaptive changes in glutamine metabolism by the small intestine, kidneys and skeletal muscle of hindlimb are similar; however, the liver appears to release glutamine during late pregnancy, but to utilize glutamine during peak lactation.     

Effects of CCK on gastrointestinal function in lean and obese Zucker rats

Cholecystokinin (CCK), a hormone affecting several gastrointestinal functions, has also been shown to elicit satiety and affect daily meal patterns. Since Zucker obese rats are less sensitive to the satiety effects of CCK, two experiments were designed to determine if they are also less sensitive to the gastric emptying and intestinal transit rate effects of CCK. In the first experiment phenol red was administered to 5.5 hr fasted rats 15 minutes after intraperitoneal injection of CCK-8 or saline. Rats were sacrificed after 30 minutes, the stomach and small intestine were removed, and phenol red content was measured. More phenol red was in the stomach of obese but not lean rats treated with CCK-8. The rate of transit of the contents of the small intestine was increased by CCK-8 and the percent of phenol red in the fourth quarter of the small intestine was greater in obese than lean rats (91 vs 37%, p<0.05). In the second experiment gastrointestinal transit of ferric oxide was measured during the light and dark phases of the diurnal cycle, and when obese rats were ad lib or yoke-fed to lean pair-mates. Total gastrointestinal transit time of the ferric oxide was decreased 15% when CCK-8 was administered to yoke-fed obese rats in either the light or dark portions of the diurnal cycle but was not affected in ad lib-fed obese rats or lean rats. Thus, while Zucker obese rats are less sensitive to satiety effects of CCK, they appear to be more sensitive to the gastrointestinal effects of CCK, and therefore it is not clear what role these gastrointestinal responses have on the feeding behavior responses.     

Inhibition of NaCl appetite when DOCA-treated rats drink saline

Marked increases in the consumption of concentrated NaCl solution were elicited in rats by daily injection of the synthetic mineralocorticoid, deoxycorticosterone acetate (DOCA). DOCA-treated rats drank different volumes of NaCl solution depending on its concentration (between 0.15 M and 0.50 M), with less consumed (in milliliters) the more concentrated the fluid was. In consequence, total Na(+) intake (in milliequivalents) was roughly similar in all groups. Gastric emptying of Na(+) also diminished as the concentration of the ingested NaCl solution increased, and the delivery of Na(+) to the small intestine was remarkably similar in all groups. Cumulative volume of ingested fluid in the stomach and small intestine was very closely related to intake (in milliliters) of the concentrated NaCl solutions. Systemic plasma Na(+) levels did not increase until after rats stopped consuming concentrated NaCl solution, although they were elevated at the onset of water ingestion. The situation appeared to be different when 0.15 M NaCl was consumed. This isotonic solution emptied and was absorbed relatively rapidly, and DOCA-treated rats drank larger amounts of it throughout a 1-h test period than when they drank concentrated NaCl solutions. Collectively, these findings suggest that saline consumption by DOCA-treated rats may be inhibited by two presystemic factors, one related to the volume of ingested fluid (i.e., distension of the stomach and small intestine) and one related to its concentration (i.e., elevated osmolality of fluid in the small intestine and/or in adjacent visceral tissue).     

Gastrointestinal flora of cotton rats

The gastrointestinal (GI) flora of cotton rats was examined. No lactobacilli were detected in any part of the GI tract. Anaerobes, including Peptococcaceae, Bacteroidaceae, bifidobacteria and eubacteria, were the predominant bacteria in the stomach, small intestine, caecum and faeces. Aerobes and facultative anaerobes, including Enterobacteriaceae and streptococci, were detected at low numbers and very low frequency of occurrence in all parts of the GI tract. Sixty-one isolates of bifidobacteria were recovered from the stomach, small intestine, caecum and faeces of cotton rats. They were identified as Bifidobacterium animalis, B. pseudolongum biovar a and b. The study showed that the GI flora of cotton rats seem to be very different from the GI flora in other rodents.     

Short-term effects of spermine ingestion on the small intestine: a comparison of suckling and weaned rats

We have previously shown that spermine, shortly after its ingestion, can induce the alteration of the morphology of the small intestine of suckling rats. It was proposed that this alteration is due to polyamine accumulation inside the epithelial cells. This could also be related to the fact that the intestine of the suckling rat is in an immature state. To shed light on this issue, disaccharidase and alkaline phosphatase activity assays, protein, DNA and RNA content measurements and polyamine concentration analysis were performed on the small intestine of suckling and weaned Wistar rats treated with spermine. Spermine did not induce the same intestinal alterations in weaned rats compared to suckling animals. Indeed, in sucklings, spermine administration induced a decrease of the protein, DNA, putrescine and spermidine intestinal content, suggesting a cell loss. The cell loss impaired the activity of intestinal enzymes: lactase, maltase and alkaline phosphatase. In weaned rats, the same treatment did not alter these parameters. Exogenous spermine by itself is not sufficient to induce the alterations described here and previously. The maturity degree of the small intestine could be the basis of this process.     

Study of glucose concentrated solution consumption in rats and simulation of glucose distribution along the intestine

Free ingestion of glucose solution (200 or 400 g/l) by Wistar rats, previously starved for 18-20 Hrs, was investigated in two groups of the animals: with intact small intestine (group 1, n = 9), and a shortened small intestine following the Thiry-Wella isolation of its one third proximal part (group 2, n = 9). In the rats of the group 2, the isolated intestinal loops were perfused in chronic experiments with soulutions of different glucose concentrations to estimate a permeability of the pre-epithelial ("unstirred") layer and "true" kinetic constants of glucose active transport. The rate of glusouse ingestion was found to be 1.3-fold as high in the of rats fgroup 1 than in the rats of group 2 (p < 0.01). According to results of mathematical modeling, the rate of glucose ingestion by rats corresponds to glucose concentration in the initial solutions and to the absorbing capacity of the small intestine due to the substrate regulation of gastric emptying. The model predicts that, during free ingestion by rats of 400 g/l (2200 mM) glucose solution, the substrate concentration in the intestinal lumen under steady state conditions hardly exceeds 75 mM. This fact contradicts a recently proposed hypothesis about a facilitated transport mediated by GLUT2 as the main mechanism of glucose absorption in the small intestine under normal conditions.     

Glycosphingolipid patterns of the gastrointestinal tract and feces of germ-free and conventional rats

Acid and non-acid glycosphingolipids of stomach, small and large intestine, and stimulated feces of germ-free and conventional rats of the same stain have been isolated and characterized. The glycosphingolipid patterns of the intestinal organs were chemically and immunologically very similar between the two groups of rats and relatively unaffected by the presence of an intestinal microbial flora. The major exception was the presence of hematoside with N-glycoloylneuraminic acid (NeuGc) (NeuGc alpha 2----3Gal beta 1----4Glc beta 1----1Cer) in the stomach of conventional rats not found in the stomach of germ-free animals. Glycosphingolipids of stimulated feces of germ-free animals were derived from epithelial cells mainly of the small intestine and showed no signs of degradation. Glycosphingolipids of feces of conventional rats completely retained the pattern of blood group A-, B-, and H-active glycolipids as found in sterile feces but contained less of hematoside and more of lactosylceramide. This effect was probably due to degradation by bacteria, as demonstrated in vitro with the production of lactosylceramide after treatment of the isolated acid glycolipids of sterile feces with neuraminidase from Clostridium perfringens. The amount of total non-acid glycosphingolipids per dry weight was similar for stomach, was 50% higher for small intestine, and 300% higher for large intestine of germ-free animals compared to conventional animals. Due to the presence of large amounts of mucins the dry sterile feces contained 12% less non-acid glycolipids than conventional feces. However, calculated per rat per day the germ-free animal excreted more of non-acid glycosphingolipids (1.8 and 1.2 mg, respectively).     

Levels of cellular retinol-binding proteins in the small intestine of rats during pregnancy and lactation

The movement and metabolism of vitamin A is dependent on a number of specific carrier proteins. The small intestine contains both cellular retinol-binding protein (type two) (CRBP(II], restricted to the villus-associated enterocytes, and cellular retinol-binding protein (CRBP), present primarily in supporting mesenchymal cells. The content of these proteins in the small intestine of prepartum and postpartum Sprague-Dawley rats was determined by radioimmunoassay. Levels of CRBP(II), but not CRBP, changed dramatically during this period. Total content of CRBP(II) in the small intestine rose precipitously in late pregnancy and continued to rise throughout lactation to a peak at day 21 postpartum more than 300% greater than in nulliparous, nonpregnant controls. In contrast, total small intestinal weight and CRBP content increased only approximately 100% from late pregnancy to day 21 of lactation. CRBP(II) concentration in the proximal and middle segments of small intestine (expressed on a g wet tissue, mg protein, or mg DNA basis) remained at control levels through day 17 of pregnancy, increased 50-100% in late pregnancy, then rose markedly at parturition to levels two- to threefold greater than controls. CRBP(II) concentration was then maintained at a relatively constant elevated level during the remainder of lactation, but decreased markedly after weaning, approaching control levels within 1 week. The concentrations of CRBP(II) in enterocytes isolated from the proximal two-thirds of the small intestine from rats on day 20 of pregnancy and days 1 and 16 of lactation, expressed on a mg DNA basis, were similar and approximately 60% greater than controls.(ABSTRACT TRUNCATED AT 250 WORDS)     

Thyrotropin-releasing hormone stimulates intestinal transit in young rats

The effect of intracisternal injection of thyrotropin-releasing hormone (TRH) on small intestinal transit of a charcoal bolus was investigated in 14-, 21-, 28- and 35-day-old and adult rats. Intracisternal TRH (15 micrograms in 2 microliters) was administered, and transit (distance traveled by the charcoal) was measured 120 min later. In all age groups, intracisternal TRH increased charcoal transit significantly (P less than 0.05) as compared to saline-treated controls. This increase in transit was not mimicked by intravascular TRH, and it was blocked in all age groups by prior intraperitoneal injection of atropine (2 micrograms/g body weight). Vagotomy blocked TRH-induced increases in small intestine transit in rats of 28 days and older. Prior intraperitoneal injection of the antiserotonin compound, cyproheptadine (1 microgram/g body weight) reduced TRH-induced increases in small intestine transit in all age groups. These results demonstrate that centrally administered TRH stimulates small intestine transit through both cholinergic and serotonergic mechanisms in rats as early as 14 days of age.     

Effects of soybean agglutinin on nitrogen metabolism and on characteristics of intestinal tissues and pancreas in rats

Two experiments were conducted to investigate the effects of increasing concentrations of supplemental purified soybean agglutinin on performance, apparent nitrogen digestibility, plasma insulin and cholecystokinine (CCK) levels in rats as well as on the growth of the small intestine and pancreas. In Experiment 1, a 10-day nitrogen balance trial was conducted with 24 male Sprague-Dawley rats (mean BW 85 g) that were randomly allotted to one of four dietary treatments. Rats in each group were provided daily with 7 g of a casein-cornstarch based diet (control) or a diet supplemented with purified soybean agglutinin at 0.4, 0.6 or 0.8 mg/g. Urine and faeces were collected daily and stored at ? 20°C until analysis. In Experiment 2, 30 male Sprague-Dawley rats (mean BW 75 g) were divided into five groups for a 20-day growth experiment. Each rat was fed daily 7 g of a casein-cornstarch based diet (control) or a diet supplemented with purified soybean agglutinin at 0.4, 0.8, 1.2 or 2.0 mg/g. All experimental diets were adjusted to contain a similar level of nutrients. Results from the two experiments showed that supplementation of soybean agglutinin below 2.0 mg/g diet had no significant effect on rat performance. However, rats receiving 2.0 mg soybean agglutinin per gram of diet showed a significant reduction in weight gain compared to the control group. Incorporation of soybean agglutinin in the diet reduced apparent nitrogen digestibility and the retention of dietary nitrogen by increasing nitrogen loss from the faeces and urine. In addition, plasma CCK level increased with increasing inclusion of soybean agglutinin in the diet. On the contrary, the plasma insulin level declined as soybean agglutinin level increased. Soybean agglutinin induced a polyamine-dependent hyperplastic and hypertrophic growth of the small intestine and pancreas by increasing the contents of protein, RNA and DNA, though the increase in weight of small intestine was not significant. Furthermore, 1.2 and 2.0 mg soybean agglutinin per gram of diet promoted proliferation of the jejunum mucosa, while the structure of the brush border epithelium of small intestinal had no damaging change and no diarrhoea was observed in any treatment group. Based on these results, supplementation of low doses of soybean agglutinin or soy protein to parenterally-fed animals affected by atrophic small intestine may promote small intestinal growth.     

Distribution of estrone sulfatase activity in the intestine of germfree and conventional rats

The intestinal content, the mucosa and the rest of the intestinal wall of germfree (GF) and conventional ( CVL ) rats were tested for in vitro hydrolysis of [3H]estrone sulfate. In homogenates from GF rat intestine some estrone sulfate hydrolysis was detected in those from the proximal small intestine (PSI) (4.2 +/- 0.1% hydrolyzed after 4 h), but not in those from the distal small intestine (DSI) and the caecum. Estrone sulfate was also hydrolyzed by the homogenates of the mucosa and the rest of the intestinal wall from each of the segments tested (PSI: 12.8 +/- 0.4% (mucosa) and 21.5 +/- 2.1 (wall); DSI: 8.2 +/- 0.9% (mucosa) and 17.3 +/- 1.7% (wall); caecum: 8.8 +/- 1.6% (mucosa) and 17.3 +/- 0.5% (wall) ). In the homogenates of CVL rat intestine, the estrone sulfatase activity in the rest of the intestinal wall did not differ considerably from the values for GF rats, when expressed per mg protein of the homogenate. The mucosa of the CVL rats, however, showed higher rates of hydrolysis than the mucosa of the GF rats. The microbial estrone sulfatase activity in the intestinal content of CVL rats, tested by anaerobic incubation, was high in the caecum (91.7 +/- 6.6% after 4 h), but very low in the PSI (2.2 +/- 0.7%) and DSI (1.3 +/- 0.5%). Serial dilutions of the caecal content also showed higher viable numbers of estrone sulfate hydrolyzing bacteria. These results add further weight to the suggestion that estrone sulfate may be absorbed from the small intestine, but has to be hydrolyzed in the caecum by the gut microflora prior to absorption.     

Lymphoid regulation of the proliferative stage in regeneration of the intestines and esophagus of rats

After the removal of a half of small intestine in the rats, the lymphocytes acquired the ability to stimulate the mitotic activity of crypts of the small intestine, large intestine and oesephagus in syngenic recipients. The ratio of mitotic phases in the experimental animals suffered no changes, the number of cells in the crypts increased reliably thus suggesting the true stimulation of proliferation. The lymphocytes of pseudooperated rats had no such ability.     

Circadian rhythm of ornithine decarboxylase activity in small intestine of fasted rats.

The aim of this study was to determine whether the circadian changes in ornithine decarboxylase (ODC) activity of different segments of the small intestine were governed by factors other than food intake. First, the effects of fasting on mucosal ODC activity were examined. The results indicate that mucosal ODC activity in 24 hr and 48 hr fasted rats decreased significantly compared with ad libitum-fed rats. Second, the circadian rhythm of mucosal ODC activity was characterized by measuring mucosal ODC activity in fasted rats at four time points (09:00, 15:00, 21:00, and 03:00 hr; light period: 06:00-18:00 hr). The results from this study indicate that there is a detectable baseline ODC activity in different segments of fasting intestine. In duodenum, mucosal ODC activity was highest at 15:00 hr (light period), a time at which the rat was normally not eating. In jejunum and ileum, mucosal ODC activity increased between 21:00 and 03:00 hr (dark period). The observation that small intestine exhibits a distinct circadian rhythm of ODC activity in fasted rats suggests that not only food but also intrinsic factors can modulate physiologic oscillations in mucosal ODC activity.     

Impacts of high-sucrose diet on circadian rhythms in the small intestine of rats

Excessive sucrose intake, known as fructose toxicity, leads to fatty liver, hyperlipidemia, and metabolic syndrome. Circadian disorders also contribute to metabolic syndrome. Here, we investigated the effect of excessive sucrose intake on circadian rhythms of the small intestine, the main location of sucrose absorption, to elucidate a mechanism of sucrose-induced abnormal lipid metabolism. Male Wistar rats were fed control starch or high-sucrose diets for 4 weeks. High-sucrose diet-induced fatty liver and hypertriglyceridemia in rats. Amplitudes of PER1/2 expression oscillations in the small intestine were reduced by excessive sucrose, while gene expression of GLUT5 and gluconeogenic enzymes was enhanced. These changes would contribute to interfering in lipid homeostasis as well as adaptive responses to control fructose toxicity in rats.     

The spatial and temporal concentrations of choline in the lumen contents of the small intestine of uninfected and Hymenolepis diminuta infected rats

The spatial and temporal concentrations of free choline in the lumen of the small intestine of the uninfected and Hymenolepis diminuta-infected rat were investigated. In the unfed infected or uninfected rat, the choline concentrations ranged from approximately 500 microM in the duodenum to approximately 20 microM in the posterior ileum, with some segments in infected rats containing significantly higher choline levels than in uninfected rats. Following feeding, choline levels were significantly elevated to approximately 3 mM by 6 h, although these concentrations fell rapidly in transit down the intestine. By 12 h the choline levels were similar to those in the unfed rat. An initial small shift in the worm biomass toward the duodenum after feeding was followed by a redistribution of biomass along the length of the small intestine. The worm biomass, however, had little or no effect on the choline levels. The high concentrations of free choline observed in the anterior regions of the intestine are postulated to be predominantly determined by nutritional intake while the concentrations in the posterior region may in part be determined by blood choline levels. The high levels of choline indicate that choline is not limiting to support the growth of the worms.     

Hydroxylation of CMP-NeuAc controls the expression of N-glycolylneuraminic acid in GM3 ganglioside of the small intestine of inbred rats

An enzymatic activity responsible for the hydroxylation of CMP-NeuAc into CMP-N-glycolylneuraminic acid (CMP-NeuGc) was found in the cytosolic fraction after cellular fractionation of the mucosa of rat small intestine. It was maximum in the presence of NADPH or NADH, but it was reduced by 50% by addition of 1 mM EDTA. The Km value for CMP-NeuAc was 0.6 microM. The CMP-NeuAc hydroxylase activity paralleled the expression of the GM3 (NeuGc) phenotype in the epithelium of the small intestine and was not measurable in the mutant rats BN and SHR that only expressed GM3 (NeuAc). Furthermore, the only form of CMP-sialic acid present in the intestinal mucosa of the mutants was CMP-NeuAc, whereas in the other strains CMP-NeuGc accounted for 70-85% of the native CMP-sialic acids. Wild-type and CMP-NeuAc hydroxylase-deficient inbred rats were mated. Individuals of F1 and backcross generations were typed for the phenotypes GM3(NeuGc)/GM3(NeuAc) and the activity of CMP-NeuAc hydroxylase in the small intestine. It was found that the expression of NeuGc in GM3 depends on a single autosomal dominant gene and correlates with the activity of CMP-NeuAc hydroxylase. Two tissues other than small intestine, kidney and spleen, which expressed GM3(NeuGc) in BN and SHR, also expressed the CMP-NeuAc hydroxylase activity, as in the other strains. It was concluded that the key enzyme responsible for the presence of NeuGc in GM3 is a CMP-NeuAc hydroxylase and that mutant rats carry a defect that is specific to intestine. The comparative analysis of the respective contribution of NeuGc and NeuAc to the glycoprotein sialic acids of the small intestine showed that CMP-NeuAc hydroxylase is also responsible for part of the NeuGc present in the glycoproteins. However, the occurrence of 20-30% of NeuGc in the intestinal glycoproteins of the CMP-NeuAc hydroxylase-deficient rats indicated that there is another enzyme providing intestinal glycoproteins with NeuGc and operating under a different genetic control.