Effect of glucose and insulin on small intestinal brush border enzymes in fasted rats

Fasting reduced small intestinal length. It also decreased mucosal weight, DNA and protein content, and concentrations of enterokinase, maltase, and sucrase in both duodenal and jejunal segments. In contrast, the concentrations of lactase and leucine aminopeptidase were not affected. Concomitantly, serum insulin levels dropped to one-fifth of the control levels while serum glucose concentrations showed a lesser degree of reduction. Glucose supplementation alone raised the serum insulin level, prevented the decrease in DNA content, and showed a protective effect on mucosal protein, mucosal weight, mucosal thickness, and villus height. Glucose also protected the sucrase and maltase concentrations; more significantly for maltase in the jejunal segment. Insulin alone, although it increased the serum insulin level to that found with glucose supplementation alone, had no protective effect on the loss in protein, DNA, and most enzymes except for maltase concentration in the jejunal segment. Addition of insulin to glucose did not modify the glucose effect on the contents of DNA, protein, and concentrations of sucrase and maltase. These results suggest that the glucose effect on the mucosa is not mediated by insulin. In addition, the retention of both maltase and sucrase activities through only glucose supplementation suggests the loss of maltase and sucrase in fasting is due to nutrient rather than specific substrate restriction.     

Influences of dexamethasone on the maturation of fetal mouse intestinal mucosa in organ culture

The effects of glucocorticoids on the maturation of the fetal small intestinal mucosa have been studied using duodenal explants resected at 17 days of gestation and cultured in a serum-free medium in the presence or absence of dexamethasone (30-300 ng/ml). Dexamethasone (a) increases specifically alkaline phosphatase, maltase, trehalase and sucrase activities and (b) allows an accumulation of goblet cells along the villi at a faster rate than that occurring in utero. These results indicate that glucocorticoids influence directly the differentiation of absorptive cells and goblet cells in the small intestine during the fetal period.     

Disaccharidases in the small intestine of the mouse: normal development and influence of cortisone, actinomycin D, and cycloheximide

The development of maltase, sucrase, and lactase activity has been examined in the small intestine of the mouse. After increasing during 2 days before birth, maltase remains unchanged for 14 days, after which activity surges up throughout the intestine. Sucrase is absent during the first 14 days, but then rises in a pattern similar to, but distinct from, that for maltase. Both enzymes rise faster in the proximal third of the intestine than in the terminal third. Lactase, which is high in the infant intestine, falls after 12 days in the proximal segment, but only after 16 days in the more posterior segments.Cortisone administered at 8 days causes a rise of maltase activity that continues for at least 72 hours. At 4 days the same treatment causes an increase that ceases after 48 hours. Sucrase activity is elicited by cortisone at 8 days but not at 4 days. Between 10 and 13 days both actinomycin D and cycloheximide evoke significant increases of both maltase and sucrase activity in all regions of the intestine. When administered in concert with cortisone, actinomycin D inhibits, but does not prevent, the stimulatory influence of the hormone on sucrase; with maltase activity, significant inhibition occurs only in the middle third of the intestine. Cycloheximide does not interfere with the effects of cortisone. No additive effects between hormone and antibiotics were obtained.These results are discussed in relation to results of similar studies on intestinal alkaline phosphatase and leucylnaphthylamidase.     

Development of the small intestine in the hypophysectomized rat. II. Influence of cortisone, thyroxine, growth hormone, and prolactin.

The intestinal deficiencies caused by hypophysectomy of rats at 6 days of age can be repaired to varying degrees by thyroxine or cortisone but not by growth hormone or prolactin. Administration of daily doses of thyroxine alone from 19–22 days raises duodenal alkaline phosphatase activity to normal levels at 24 days; it has a strong effect on jejunal sucrase and maltase, although these activities remain below those of controls. Thyroxine causes a marked increase in rough endoplasmic reticulum and restores the Golgi complexes to their normal appearance. It also elicits an intensification of periodic acid-Schiff (PAS) stainability of the brush border. Cortisone acetate given from 19 to 22 days elevates sucrase and maltase to normal levels but does not fully restore phosphatase activity. Like thyroxine, cortisone causes intensification of PAS staining of the brush border and also increases rough endoplasmic reticulum. It seems to stimulate Golgi activity, but results in the appearance of a variety of abnormal forms. The defects in Golgi configuration, brush border carbohydrate content, and activity of glycoprotein enzymes that are bound to the brush border may all reflect impaired glycosylation in the hypophyseoprivic state; the results of thyroxine or cortisone administration suggest that both hormones may affect glycosylation but in different ways.     

小鼠小肠四种消化酶活力的胎后发育模式

为明确晚成型小鼠胎后发育肠道消化酶活力的建立过程和发育模式,探讨其与适应性调节假说的关系,测定了从出生后至27日龄小鼠小肠前、中、后段的乳糖酶、蔗糖酶、麦芽糖酶和氨基肽酶的酶活力。结果发现单位组织酶活力方面,乳糖酶活力先增后降,小肠前段在9日龄而中后段在12日龄达到最高,至27日龄时仅中段有微弱的酶活力;蔗糖酶活力12日龄始出现,前段和后段自15日龄迅速升高,至18日龄达最高,但随后显著降低,而中段在15日龄后持续升高至21日龄达到最高,此后维持在较高水平;麦芽糖酶出生时已具有活力,但在15日龄前维持较低水平,此后迅速升高,前后段在18日龄,中段在21日龄达到峰值,此后下降;小肠前段的氨基肽酶活力出生后至27日龄持续下降,而后段和中段从出生到断乳前则持续升高,断乳后略有下降。除乳糖酶总酶活力先增后降,在15日龄达峰值外,其余3种酶的总酶活力均持续增加。在小肠不同位置4种酶活力的分布具有显著差异,且日龄对不同位置酶活力的影响趋势不同。总之,小鼠小肠4种消化酶的酶活力随时间的变化能够与其食物转变的消化需求相匹配,部分地支持适应性调节假说。     

Effect of somatostatin on small intestine enzyme activities in rat and chick

The influence of somatostatin injection on intestinal disaccharidase and alkaline phosphatase activity in rat and chick was investigated. Disaccharidase and alkaline phosphatase activities of rat and chick homogenates were not modified. In rat the activities of mucosal brush-border maltase and sucrase were significantly increased. In chick brush-border a significant increase of duodenal mucosal activity and duodenal and jejunal sucrase activity is observed.     

Disaccharidase activities after jejunoileal bypass in rat

Digestive enzymatic activities (maltase, lactase and sucrase) have been determined in the intestinal mucosa of rats subjected to a jejunoileal bypass of 45 cm. The weight and protein content of the mucosa (mg/cm) were significantly decreased in the bypassed segment and significantly increased in the unbypassed segment, as compared to control rats. Maltase, lactase and sucrase specific (U/g protein) and total activity (U/cm intestine) were significantly decreased in the bypassed jejunum, compared to sham-operated rats. In the ileum, maltase specific and total activities increased in bypassed animals while the lactase and sucrase activities remained unchanged.     

Effect of neonatal hypoxia on the development of hepatic lipase in the rat

Increases in plasma lipids occur during hypoxia in suckling but not in weaned rats and may result from altered hepatic enzyme activity. We exposed rats to 7 days of hypoxia from birth to 7 days of age (suckling) or from 28 to 35 days of age (weaned at day 21). Hypoxia led to an increase in hepatic lipid content in the suckling rat only. Hepatic lipase was decreased to approximately 45% of control in 7-day-old rats exposed to hypoxia but not in hypoxic 35-day-old rats. Hypoxic suckling rats also had a 50% reduction in lactate dehydrogenase activity, whereas transaminase activity and CYP1A and CYP3A protein content were not different between hypoxic and normoxic groups. Additional rats were studied 7 and 14 days after recovery from hypoxic exposure from birth to 7 days of age; hepatic lipase activity had recovered to 85% by 7 days and to 100% by 14 days in the rats previously exposed to hypoxia. Administration of dexamethasone to neonatal rats to simulate the hyperglucocorticoid state found in hypoxic 7-day-old rats led to a moderate decrease ( approximately 75% of control) in hepatic lipases. Developmentally, in the normoxic state, hepatic lipases increased rapidly after birth and reached levels more than twofold that of the newborn by 7 days of age. Hypoxia delays the maturation of hepatic lipases. We suggest that the decrease in hepatic lipase activity contributes to hyperlipemia in the hypoxic newborn rats.     

Circadian rhythms in digestive enzymes in the small intestine of rats. I. Patterns of the rhythms in various regions of the small intestine.

The activities of the digestive enzymes, maltase [EC 3.2.1.20], sucrase [EC 3.2.1.26], trehalase [EC 3.2.1.28], Leucine aminopeptidase [EC 3.4.11.1], and alkaline phosphatase [EC 3.1.3.1] were measured in various regions of the small intestine of rats. The activities of all these enzymes were much higher in the jejunum than in the ileum, and in the distal regions of the ileum no sucrase, trehalase or alkaline phosphatase activity was detected. In the jejunum, the activities of all the enzymes tested exhibited clear circadian variations with the highest activity at 0000-0400 h and the lowest at 1200 h when the rats were fed ad libitum. In the ileum, maltase and sucrase also exhibited circadian variations, but the amplitude of the rhythm was smaller than that in the jejenum. Trehalase and alkaline phosphatase did not show any circadian variation in the ileum. Leucine aminopeptidase showed a circadian variation in the ileum with the same amplitude as in the jejunum. The phase of the circadian variations shifted about half a day when the rats were fed in the daytime, but the amplitude of the rhythm did not change.     

Autonomous biochemical and morphological differentiation in fetal rat intestine transplanted at 17 and 20 days of gestation

The morphological and biochemical development of fetal rat intestine was examined for up to 5 weeks following transplantation to syngeneic hosts at 17 and 20 days of gestation. In transplants of both ages, normal villi bearing mature enterocytes developed. In addition, the disaccharidases lactase, maltase, and sucrase, as well as alkaline phosphatase, underwent normal patterns of development. Lactase activity, initially high, fell significantly, while maltase and sucrase activities increased significantly in the interval between 2 and 5 weeks following transplantation. During this same period, alkaline phosphatase developed the proximally located, high-activity form. The transplanted intestine also developed normal topographical distributions of enzyme activities. Measurement of corticosterone levels demonstrated that, except for a transient upsurge at the time of operation, hormone levels did not change significantly during the period of transplant maturation. These data indicate that the brush-border enzymes of the small intestine develop according to an intrinsic program which is already established as early as 17 days of gestation.     

Pancreatic and Pancreatic-Like Microbial Proteases Accelerate Gut Maturation in Neonatal Rats

ObjectivesPostnatal gut maturation in neonatal mammals, either at natural weaning or after precocious inducement, is coinciding with enhanced enzymes production by exocrine pancreas. Since the involvement of enzymes in gut functional maturation was overlooked, the present study aimed to investigate the role of enzymes in gut functional maturation using neonatal rats.MethodsSuckling rats (Rattus norvegicus) were instagastrically gavaged with porcine pancreatic enzymes (Creon), microbial-derived amylase, protease, lipase and mixture thereof, while controls received α-lactalbumin or water once per day during 14–16 d of age. At 17 d of age the animals were euthanized and visceral organs were dissected, weighed and analyzed for structural and functional properties. For some of the rats, gavage with the macromolecular markers such as bovine serum albumin and bovine IgG was performed 3 hours prior to blood collection to assess the intestinal permeability.ResultsGavage with the pancreatic or pancreatic-like enzymes resulted in stimulated gut growth, increased gastric acid secretion and switched intestinal disaccharidases, with decreased lactase and increased maltase and sucrase activities. The fetal-type vacuolated enterocytes were replaced by the adult-type in the distal intestine, and macromolecular transfer to the blood was declined. Enzyme exposure also promoted pancreas growth with increased amylase and trypsin production. These effects were confined to the proteases in a dose-dependent manner.ConclusionFeeding exogenous enzymes, containing proteases, induced precocious gut maturation in suckling rats. This suggests that luminal exposure to proteases by oral loading or, possibly, via enhanced pancreatic secretion involves in the gut maturation of young mammals.     

Role of epithelial-mesenchymal interactions in the ontogenesis of intestinal brush-border enzymes

The respective roles of embryonic intestinal mesenchyme and endoderm in the biochemical differentiation of brushborder enzymes have been investigated. As a first step of this study, the prenatal developmental pattern of several enzymes (maltase, sucrase, lactase, alkaline phosphatase), measured in brush-border membranes purified from chick and rat intestine, has been established. Xenoplastic recombinations between the intestinal tissue components of $\text{5-}\text{1}\text{2}\text{-}\text{day-old}$ chick embryos and 14-day-old fetal rats have been performed. After 11 days of intracoelomic graft in 3-day-old chick embryos, the combinations composed of chick mesenchyme and rat endoderm (Cm/Re) showed enzyme activities characteristic of the fetal rat intestine: high lactase activity and traces of sucrase activity. The inverse combinations composed of rat mesenchyme and chick endoderm (Rm/Ce) exhibited a chicken-like pattern: high sucrase activity and traces of lactase activity. In the latter combinations, the specific enzyme activities were similar to those present in the intestine of 15- to 16-day-old chick embryos (theoretical level reached after the grafting period). Conversely, the levels of enzyme activities of the Cm/Re combinations remained lower than those present in the normally developed rat intestine. These results show that the endodermal tissue carries the specific characteristics of its future biochemical differentiation. They also suggest that the important maturation events, which occur shortly before birth in the rat, are dependent upon other factors, presumably hormones.     

Alterations in jejunal transport and (Na+-K+)-ATPase in an experimental model of hypoxia in rats

Hypoxia was induced by exposing rats to an atmosphere of 93% N2, 7% O2 for 4-48 hr. The animals became hypoxic as indicated by a decreased blood PaO2 (mean +/- SEM: 48 +/- 10 mm Hg). Hypoxia was accompanied by metabolic acidosis (pH 7.22 +/- 0.02) and decreased serum bicarbonate levels (9.0 +/- 4.0 meq/liter). Hypoxic rats also showed evidence of tissue hypoxia; liver tryptophan oxygenase levels were increased to 21 +/- 2 nmole/min/mg protein. In the hypoxic animals there was decreased jejunal mucosal (Na+-K+)-ATPase activity and an inhibition of active intestinal transport of sodium, glucose, 3-O-methylglucose, galactose, tyrosine, phenylalanine, and glycine as determined by in vivo perfusion studies. Jejunal fructose transport, which has a large passive component, was unaffected by hypoxia. The electrolyte, carbohydrate, and amino acid transport alterations produced by hypoxia were seen in the absence of an effect on jejunal cell number, DNA synthesis, or cell turnover. There was also no evidence of histological or ultrastructural damage. Furthermore, studies with a luminal macromolecular tracer, horseradish peroxidase, indicated that the jejunal lumen-to-blood barrier to macromolecules was also unaltered in these hypoxic animals. In vitro local oxygenation of the jejunum, by bubbling of 95% O2:5% CO2, markedly improved sodium and glucose (but not 3-O-methylglucose) absorption in hypoxic rats and control rats. The (Na+-K+)-ATPase activity of the jejunal mucosa of hypoxic rats was significantly enhanced by the local bubbling of 95% O2:5% CO2. Overall, our data indicate that during relatively mild conditions of hypoxia there is an inhibition of jejunal (Na+-K+)-ATPase activity and related transport processes that is prevented by in situ oxygenation.     

Effect of protein deficiency in the female rat diet during pregnancy and lactation on the activity of the membrane and soluble forms of digestive enzymes in the offspring small intestine

Protein deficiency in female rats diet during pregnancy and lactation resulted in deceleration of induction of sucrase both forms in the jejunum and ileum; in acceleration of induction of the maltase membrane from in the jejunum; and in suppression of the lactase membrane form in the ileum; in earlier forming of the adult-type distribution of activity of the membrane form of intestinal alkaline phosphatase and in a decrease in activity of the enzyme soluble form. The findings are corroborated by a suppression of activities of the membrane and soluble forms of the small intestine digestive enzymes in 30-day old rat pups fed with a control (adequate) ration starting 21 days after the birth.     

Effects of hydrocortisone on carbohydrase concentrations, de novo synthesis and turnover patterns in immature rat intestine

Hydrocortisone administration to infant rats enhanced cellobiase and maltase activities and induced precocious expression of sucrase and trehalase activities along the length of the small intestine. These activity changes reflected proportional concentration increases in the enzymes lactase (EC 3.2.1.23), maltase/glucoamylase (EC 3.2.1.20) and sucrase-isomaltase (EC 3.2.1.48/10). Administration of an equivalent tracer dose of [3H]leucine (by body weight) to control and hydrocortisone-treated infant rats resulted in greater accumulation of label in the carbohydrase pools of the treated rats, suggesting their increased de novo synthesis. The increased concentrations of lactase and maltase/glucoamylase induced by exogenous hydrocortisone were matched by the presence of corresponding greater amounts of label in their brush border pools. Accumulation of label in each of the lactase, maltase/glucoamylase and sucrase-isomaltase pools was generally similar in the hydrocortisone-treated rats, suggesting equivalent stimulation of their synthesis as a group by the humoral agent. The turnover rates of the carbohydrases as a group were found to be similar and did not appear to differ in control and hydrocortisone-treated rats. Total protein synthesis rates were slightly greater in the intestine of the hydrocortisone-treated group of rats.     

Metabolic/nutrition programming of the enzyme system in the offspring small intestine

Protein deficiency in female rats diet during pregnancy and lactation resulted in changes of the intestine enzymes activity in posterity in early and late periods of ontogenesis. In the former period, deceleration of sucrase induction, acceleration of lactase suppression and maltase induction, and an earlier occurrence of the adult-type distribution of the intestine alkaline phosphatase, were found. At 2 to 4-month age a reduction of the latter enzyme activity was revealed in the doudenum, jejunum and ileum. The changes in the intestine enzymes activities led to a disorder in intermediary metabolism and to occurrence of "risk diseases".     

Effect of adrenalectomy on the activity of small intestine enzymes in monosodium glutamate obese rats

It is well known that adrenalectomy (ADX) reverses the eating and energy balance disturbances in a variety of models of obesity associated with elevated food intake. We have previously demonstrated enhanced functional activity in the small intestine of neonatally monosodium glutamate-treated (MSG) obese rats despite the absence of overeating and we concluded that these changes might also contribute to the development of MSG obesity. The objective of the present experiments was to investigate whether ADX would affect the small intestinal functions and whether their changes would counteract attenuation or prevention of obesity development in MSG rats. Therefore the investigation was carried out in MSG-obese Wistar male rats and untreated intact rats adrenalectomized on day 40, as well as in lean littermates of MSG rats and intact rats subjected to Sham-ADX surgery. All animals had free access to a standard pellet diet after weaning. At the age of 80 days, body mass, body fat content and food consumption as well as changes of the brush-border-bound duodenal and jejunal alkaline phosphatase (AP), the dipeptidyl(amino)peptidase IV (DPP IV) and maltase activity were measured. During the postoperative period, ADX resulted in a significant decrease of mass gain in both MSG and control rats (P<0.05). ADX fully prevented the development of obesity in MSG rats (significantly decreased epididymal+retroperitoneal fat pad mass, P<0.05) and increased mean daily food intake (P<0.001). These effects were only minimal in the ADX controls suggesting that enhanced adrenal secretion is involved in the expression of MSG obesity and its complications. The AP activity in obese MSG rats was increased by about 21 % (P<0.01) in both intestinal segments when compared to the lean controls, whereas no parallel variations in the activities of DPP IV and maltase were observed in the intestinal parts mentioned. In MSG rats, ADX significantly reduced the AP activity in the duodenum and jejunum (P<0.01). A similar tendency was also seen in the DPP IV activity of adrenalectomized MSG rats as well as in lean control rats. Nevertheless, no significant effect of adrenal withdrawal on maltase activity was found. These results indicate that the decrease of enzyme activities in the small intestine and the different effectiveness of nutrient absorption might be a significant factor preventing the development of excess adiposity in glutamate-treated rats. This information contributes to a better understanding of the importance of small intestinal function for the development of obesity and its maintenance in later life.     

Development of the small intestine in the hypophysectomized rat. I. Growth histology, and activity of alkaline phosphatase, maltase, and sucrase.

Rats hypophysectomized at 6 days of age continue to grow but at a subnormal rate. At 24 days, when maturation of the intestinal epithelium normally culminates, the intestine is disproportionately small. The crypts are shallow and the mitotic rate low. The villi are short, and they fail to achieve the broad, leaflike form found in controls. The absorptive cells acquire a deep subnuclear zone, and their surfaces apparently cease to carry on pinocytosis. Rough endoplasmic reticulum is however sparse, and the Golgi complexes are small and atypical in structure. Duodenal alkaline phosphatase remains at the low level characteristic of the neonatal intestine. Sucrase activity appears in the jejunum, and maltase activity increases slightly, but both activities are less than a third of those in intact animals at 24 days. If the pituitary is removed later than 6 days, enzyme activities are higher than after early ablation, but they remain deficient even when the operation is performed at 16 days.     

The effect of spermine on the disaccharidase activities in suckling rats of different age.

The influence of the age of the rat on the maturation of disaccharidase activities induced by spermine was studied. Three-day- and 9-day-old rats were used in the experiment. Spermine was administered orally or directly into the stomach using thin tubing daily for 3 days, and disaccharidase activities in the jejunum were measured. While spermine caused maturation of not only lactase activity but also maltase and sucrase activities in 9-day-old rats, it only caused maturation of lactase activity in 3-day-old rats. Histological studies showed no significant changes in the jejunum of 3-day-old rats treated with spermine.     

Heat inactivation and Sephadex chromatography of the small-intestine disaccharidases of the chick

1. The maltase, sucrase, isomaltase and palatinase activities of the chick small intestine are localized in particles that sediment when centrifuged at 100000g for 90min. 2. Solubilization of the particle-bound disaccharidases without loss of activity was achieved by digestion with papain. Trypsin was less effective and caused a preferential solubilization of the sucrase, isomaltase and palatinase activities. 3. On Sephadex G-200 columns, the solubilized preparations yielded two disaccharidase peaks. The first peak was eluted close to the void volume of the column and contained all the sucrase, isomaltase and palatinase activities and some of the maltase activity. The remainder of the maltase activity was eluted beyond the total volume of the column. 4. Precipitation with ethanol did not affect the behaviour of the disaccharidases of gel filtration. 5. The maltase activity of the second peak on rechromatography in a buffer containing 0.01m-maltose was eluted close to the void volume. 6. Similar pH optima but different K(m) values were obtained for the maltase activities of the two peaks. 7. Heat-inactivation studies showed that the first peak contained two disaccharidase enzymes; one hydrolysed sucrose and maltose and the other hydrolysed isomaltose, palatinose and maltose. The second peak contained three disaccharidase enzymes all specific for the hydrolysis of maltose. 8. It is proposed that the intestinal disaccharidases of the chick exist in the form of two complexes: a sucrase-isomaltase complex and a maltase complex.