Intestinal Microvillus Membrane Research Articles

Congenital Sucrase‐Isomaltase Deficiency

Congenital Sucrase‐Isomaltase Deficiency

Disruption of the meprin α and β genes in mice alters homeostasis of monocytes and natural killer cells

Meprin metalloproteases are implicated in inflammatory bowel disease, which involves dysfunction of immune cells. However, the roles of meprins in the immune and hematological system remain uncharacterized. In this report, we demonstrate that meprins were expressed in the hematological system, and meprin alpha/beta null (alpha(-/-)/beta(-/-)) mice had decreased prevalence of resident monocytes and natural killer (NK) cells in blood, with a concomitant accumulation of inflammatory monocytes and NK cells in bone marrow. In contrast, T and B lymphocytes were not affected by meprin deficiency. In response to acute inflammation induced by intraperitoneal injection of thioglycollate, meprin-deficient mice exhibited higher body temperature than wild-type mice, which was correlated with retention of inflammatory monocytes, but persistent low prevalence of NK cells in blood. These results indicate that meprin metalloproteases play important roles in the homeostasis of monocytes and NK cells, and possibly are involved in egress of these two type cells from bone marrow and homing to the periphery. Our findings are the first report to demonstrate that metalloproteases affect homeostasis of leukocytes, which have important implications for understanding physiology of and pathogenesis in the hematological system.

Effects of bile diversion in rats on intestinal sphingomyelinases and ceramidase

Alkaline sphingomyelinase (Alk-SMase) and neutral ceramidase (N-CDase) in the intestinal microvillar membrane are responsible for dietary sphingomyelin digestion. The activities of the enzymes require the presence of bile salt, and the enzymes can be released into the gut lumen in active forms by bile salts and trypsin. It is unclear to what extent that the intestinal presence of bile salts is critical for the intraluminal activity of these enzymes. We compared the activities of Alk-SMase, N-CDase, and other types of SMases in control and permanently bile diverted rats. In the intestinal tract of control rats, the activity of Alk-SMase was profoundly higher than those of acid and neutral SMases. Bile diversion reduced Alk-SMase activity by 85% in the small intestinal content, and by 68% in the faeces, but did not significantly change the activity in the intestinal mucosa. Western blot showed a marked reduction of the enzyme in the intestinal lumen but not mucosa. N-CDase activities both in the intestinal mucosa and content were reduced by bile diversion. Bile diversion also decreased aminopeptidase N activity in the content and increased that in the mucosa, but had no effects on that of alkaline phosphatase. In conclusion, the presence of bile salts is important for maintaining high intraluminal levels of Alk-SMase and N-CDase, two key enzymes for hydrolysis of sphingomyelin in the gut. We speculate that the sphingomyelin hydrolysis in cholestatic conditions is impaired not only by reduced hydrolytic activity but also by deficient dissociation of the enzymes from the membrane.

Giardia lamblia: Expression of alkaline phosphatase activity in infected rat intestine

Alkaline phosphatase (IAP) is a marker of intestinal microvillus membrane. Changes in IAP activity have been studied as a function of Giardia lamblia ( G. lamblia) infection using rat as the experimental model. At day 11 and 15 post-infection, enzyme activity was reduced ( p < 0.01) compared to controls. The enzyme levels were essentially similar to control values by day 30 post-infection. Analysis of the enzyme activity in cell fractions across crypt–villus axis revealed a marked decrease in enzyme activity in the villus tip and mid villus regions but a considerable increase ( p < 0.01) in enzyme activity in the crypt base of 11 day post-infected animals compared to that in controls. The observed changes in IAP activity were confirmed by assaying the enzyme activity in acrylamide gels using bromo-chloro-indolyl phosphate staining under non-denaturing conditions. These findings indicate differential changes across the crypt–villus axis, but impaired alkaline phosphatase levels in G. lamblia infected rat intestine.

Ethanol-Induced Changes in Lipid Composition of Intestinal Microvillus Membrane in Rats Fed Different Dietary Fats

Background/Method: The effect of feeding ethanol for 5 weeks on the lipid composition of the intestinal microvillus membrane (MVM) was studied in rats fed a commercial rat pellet (RP) diet or purified diets containing 10% coconut oil (CCO), corn oil (CO) or fish oil (FO). Results: A low cholesterol/phospholipid ratio and increased saturated fatty acid level were observed in MVM from the CCO or FO groups. Chronic administration of ethanol to RP- or CO-fed animals increased phospholipids, total and free cholesterol, and the triglyceride and ganglioside content of MVM. The free cholesterol and phospholipid content was reduced while the triglyceride level remained unaffected by ethanol treatment in the CCO or FO groups. Ethanol ingestion decreased 10:2 and 20:4 (n–6 fatty acids) but increased the saturated fatty acid content of MVM in all the dietary groups except in CCO-fed animals where the 18:2 level was not affected. An elevated 18:1, but decreased 22:6 percentage was observed in the ethanol-fed FO group. The fatty acid composition of MVM from the CCO-fed group was least affected by ethanol treatment. Conclusion: These observations suggest that the type of dietary fat modifies ethanol-mediated alterations in MVM lipid composition.

Overview

This symposium entitled, "Bacterial Colonization of the Gut and the Use of Pre- and Probiotics" was organized by the Shanghai Children's Medical Center of the Second Shanghai Medical University in conjunction with the Combined Program in Pediatric Gastroenterology and Nutrition at Harvard Medical School to underscore a 10-year agreement between both medical centers to provide training of academic pediatricians from China in basic and translational research. The training program is supported by a training grant from the National Institute of Child Health and Development (NICHD)/Fogarty Center (1-U01A145441-01), and research projects are, in part, supported by a research grant from Wyeth Nutritionals International, Inc., (Philadelphia, PA, U.S.A.) The symposium, itself, was sponsored from an educational grant from Wyeth Nutritionals International, Inc. for which the the organizers are grateful. The topic for this initial Sino-American symposium represents an important area of research in pediatrics and a major research interest of the two organizing groups. Dr. W. Allan Walker, a pediatric gastroenterologist with a strong research interest in the development of host defense, introduces the topic of the symposium by considering the importance of pre- and probiotics in the development of intestinal host defense in the extrauterine environment. He reviews the effects of initial colonization of the gut on the development of the effector immune response to antigen stimulation. At birth, the gut's lymphoid tissue has the capacity to respond to microbial-food antigens. However, the initial colonization of the newborn gut with indigenous microflora provides the appropriate "adjuvant effect" to activate antibody production and T-cell activation. Furthermore, the nature of initial oral feedings (breast-milk vs. formula) helps to determine the nature of colonizing bacteria (lactobacilli and bifidobacteria vs. enterobacteria and Escherichia coli). In addition, specific nutrients such as nucleotides, omega-3 fatty acids, and lactoferrin can enhance the effects of indigenous flora on strengthening the mucosal barrier and minimizing inflammatory responses to pathologic bacteria colonization. Dr. David S. Newburg, a glycobiologist from Harvard Medical School, reviews the importance of oligosaccharides in human milk on the attachment of pathologic bacteria to glycoconjugates and glycolipids and proteins in the intestinal microvillus membrane. Oligosaccharides, a natural prebiotic, has an influence on the nature of colonizing bacteria. He notes that enterocyte cell surface glycoconjugates are pathogen receptors and help to influence pathologic colonization of the newborn gut. In contrast, soluble oligosaccharides in breast milk can attach to "adhesions" on pathogens and thereby block their interaction with the intestinal surface and reduce their colonization. He cites examples of breast milk protection by oligosaccharides for Campylobacter and rotaviral infection. These studies may help to identify additives to future infant formula. Dr. Michael S. Caplan, a neonatologist from North-western University with a strong research interest in necrotizing enterocolitis, and Dr. Tamas Jilling reviews the possible role of probiotics in the treatment of necrotizing enterocolitis. The immature human enteric surface has an immature glycosylation pattern favoring colonization with pathologic organisms. In the premature neonate, this process may contribute to the pathogenesis of necrotizing enterocolitis. If probiotics are introduced into the diet of the newborn at birth, their presence could block pathologic colonization and thereby reduce the incidence of necrotizing enterocolitis. The authors provide evidence in an experimental model for necrotizing enterocolitis that the use of probiotics (Lactobacillus GG) can prevent the upregulation of platelet-activating factor, an inflammatory cytokine and indicator of early necrotizing enterocolitis. Dr. Dingwei Dai, an investigator at the Shanghai Children's Medical Center and a research fellow in the Developmental Gastroenterology Laboratory of the Combined Program in Pediatric Gastroenterology and Nutrition at Harvard Medical School, and colleagues from the United States present exciting new data to support the notion that glycosylation of microvillus membrane lipids and protein through glycosyltransferase activity is developmentally regulated and that cortisone treatment of pregnant or newborn animals can activate the maturation of this process. They also provide preliminary evidence that glycosylation in the human fetus is also under developmental regulation. These observations help explain pathologic colonization of the human newborn and the potential for treatment of this process with growth factors such as cortisone. Finally, Dr. Jon A. Vanderhoof, a pediatric gastroenterologist from the University of Nebraska Medical Center, reviews the use of probiotics in the treatment inflammatory disorders in infants and children. He reviews clinical studies to suggest that Lactobacillus GG administered orally to children who have rotaviral infection reduces the severity and length of time of the clinical illness. He also reviews its use in the treatment of allergic dermatitis of children and its preliminary use in the treatment of inflammatory bowel disease. These presentations provide an excellent review of the current state of our knowledge of the role of nutrients in bacterial colonization in health and disease of infants and children.

Angiotensin-converting enzyme secretase is inhibited by zinc metalloprotease inhibitors and requires its substrate to be inserted in a lipid bilayer.

Mammalian angiotensin-converting enzyme (ACE; EC 3.4.15.1) is one of several proteins that exist in both membrane-bound and soluble forms as a result of a post-translational proteolytic processing event. For ACE we have previously identified a metalloprotease (secretase) responsible for this proteolytic cleavage. The effect of a range of structurally related zinc metalloprotease inhibitors on the activity of the secretase has been examined. Batimastat (BB94) was the most potent inhibitor of the secretase in pig kidney microvillar membranes, displaying an IC50 of 0.47 microM, whereas TAPI-2 was slightly less potent (IC50 18 microM). Removal of the thienothiomethyl substituent adjacent to the hydroxamic acid moiety or the substitution of the P2' substituent decreased the inhibitory potency of batimastat towards the secretase. Several other non-hydroxamate-based collagenase inhibitors were without inhibitory effect on the secretase, indicating that ACE secretase is a novel zinc metalloprotease that is realted to, but distinct from, the matrix metalloproteases. The full-length amphipathic form of ACE was labelled selectively with 3-trifluoromethyl-3-(m-[125I]iodophenyl)diazirine in the membrane-spanning hydrophobic region. Although trypsin was able to cleave the hydrophobic anchoring domain from the bulk of the protein, there was no cleavage of full-length ACE by a Triton X-100-solubilized pig kidney secretase preparation when the substrate was in detergent solution. In contrast, the Triton X-100-solubilized secretase preparation released ACE from pig intestinal microvillar membranes, which lack endogenous secretase activity, and cleaved the purified amphipathic form of ACE when it was incorporated into artificial lipid vesicles. Thus the secretase has an absolute requirement for its substrate to be inserted in a lipid bilayer, a factor that might have implications for the development of cell-free assays for other membrane protein secretases. ACE secretase could be solubilized from the membrane with Triton-X-100 and CHAPS, but not with n-octyl beta-D-glucopyranoside. Furthermore trypsin could release the secretase from the membrane, implying that like its substrate, ACE, it too is a stalked integral membrane protein.

Total Intestinal Lactase and Sucrase Activities Are Reduced in Aged Rats , ,

Lactase-phlorizin hydrolase (LPH) and sucrase-isomaltase (SI) are intestinal microvillus membrane hydrolases that play important roles in carbohydrate digestion. Although the expression of these enzymes during postnatal development has been characterized, the effect of old age on disaccharidase activity is poorly understood. In the present investigation, we examined the effect of aging on lactase and sucrase activities and their mRNA levels in the small intestines of 3-, 12- and 24- mo-old rats by sampling from nine equidistant segments of small intestine. Total intestinal disaccharidase activity or mRNA abundance was determined from areas under the proximal-to-distal curves. Rats 24 mo of age had total intestinal lactase and sucrase activities that were 12 and 38% lower, respectively, than the 3-mo-old animals (P < 0.05). In contrast, total LPH and SI mRNA abundance did not change significantly. Thus, total intestinal lactase and sucrase activities decrease with age in a manner that likely involves a posttranscriptional process. The age-related decline in disaccharidase activity, if extrapolated to humans, may have important implications for the digestion of carbohydrate contained in the diet of the elderly.

Simplified preparation of a refined milk formula comparable to rat's milk: influence of the formula on development of the gut and brain in artificially reared rat pups.

Milk formulas for artificially reared (AR) rat pups are mostly based on complex cow's milk products, prepared by laborious and time-consuming processes. The aim of this study was to develop a simplified procedure for preparing a refined formula and to examine its influences on gut and brain development. The formula comprised a combination of purified cow's casein and whey proteins, five kinds of edible oil, minerals, and vitamins. Detailed analyses showed that the composition of macro- and micro-nutrients, osmolarity, and pH of the new formula closely resembled those of rat's milk. Rat pups, each with an intragastric cannula implanted at age 5 days, were artificially reared for the following 10-15 days. The body weight gain of AR pups matched that of mother-reared (MR) pups. Histoplanimetrical analyses showed that the small intestine in AR pups was more developed in relation to area of a transverse section, number and length of villi, and thickness of tunica muscularis than that of MR pups. Fat components in the formula influenced the fatty acid composition and the cholesterol-to-phospholipid ratio in the small intestinal microvillus membrane (MVM) of AR pups, but not the MVM fluidity. Brain weight was not significantly different between the two groups at age 15-20 days. This formula is useful for artificial rearing of rats and for identifying dietary components contributing to metabolic adaptation during the suckling period.

Proteolytic fragmentation reveals the oligomeric and domain structure of porcine aminopeptidase A.

Aminopeptidase A (glutamyl aminopeptidase; EC 3.4.11.7) has been cloned from porcine brain and kidney cortex cDNA libraries and the complete primary sequence of the enzyme deduced. This predicts a type II integral membrane protein of 942 amino acids with 14 potential N-linked glycosylation sites and a His-Glu-Xaa-Xaa-His zinc binding motif. Aminopeptidase A was purified from porcine kidney cortex by a combination of anion exchange and hydrophobic interaction chromatographies following its release from the membrane by trypsin. The purified protein migrated as three major polypeptides on SDS-polyacrylamide gel electrophoresis of M(r) 147,000, 107,000, and 45,000. N-Terminal sequencing revealed that both the Mr 147,000 and 107,000 polypeptides had the same N-terminal sequence resulting from cleavage of aminopeptidase A by trypsin at the Lys-42-Asp-43 bond just outside the membrane-spanning hydrophobic region. Immunoelectrophoretic blot analysis following electrophoresis under nonreducing conditions revealed that the trypsin-cleaved form of the enzyme no longer migrated as a disulfide-linked dimer, placing the interchain disulfide link N-terminal to Lys-42. N-Terminal sequencing of the M(r) 45,000 polypeptide in the purified preparation of aminopeptidase A revealed that it resulted from cleavage at the Asn-602-Gly-603 bond by an endogenous protease. This posttranslational proteolytic cleavage occurred in porcine kidney cortex microvillar membranes but not in porcine intestinal microvillar membranes. Incubation of purified porcine kidney aminopeptidase N (membrane alanyl aminopeptidase; EC 3.4.11.2) with trypsin resulted in a similar fragmentation pattern to that observed in aminopeptidase A, suggesting that these and other members of the type II membrane-spanning zinc aminopeptidase family may have two distinct domains: an N-terminal domain, containing the zinc binding site and residues identified as being involved in catalysis, and a C-terminal domain of unknown function, that are separated by a protease-susceptible region.

Verification of the lactase site of rat lactase-phlorizin hydrolase by site-directed mutagenesis

Background & Aims : Lactase-phlorizin hydrolase (LPH) is an intestinal microvillus membrane glycoprotein that hydrolyzes lactose and phlorizin. These enzymatic activities have been assigned to glutamic acid (E) residues 1271 and 1747 in rabbit LPH. The aim of this study was to determine directly if this assignment was correct and if these two amino acids are the only nucleophiles required for LPH enzyme activity. Methods : Site-directed mutagenesis of a full-length rat LPH complementary DNA was used to convert the rat homologues E1274 and E1750 to aspartic acid or glycine. Mutants were analyzed by enzyme activity assays. Results : All tested activities of E1274D and E1274G were virtually unaffected. In contrast, mutations E1750D and E1750G resulted in total loss of lactase and cellobiose activities, leaving only low ONP-glc and ONP-gal hydrolase activities detectable. A double mutant containing both E1274G and E1750G had no activity. Conclusions: These studies directly confirm that the two previously identified glutamic acids are essential to the enzymatic activity of rat LPH. Rat lactase activity is not associated with the E1274 site. This study provides the first evidence that rat LPH has its major catalytic site at E1750, representing all of the lactase and the majority of the phlorizin hydrolase activity.

Sialylation of intestinal microvillar membranes in newborn, sucking and weaned pigs.

Affinity cytochemistry and biochemistry revealed distinctive temporal changes in the expression of sialylated and compositionally related membrane glycoconjugates in the pig small intestine between birth and weaning. The expression of membrane NeuAc alpha 2,6 moieties, recognized by Sambucus nigra agglutinin-1, was high in newborn pigs, declined slightly during sucking and was very low in weaned animals. Conversely, the expression of membrane NeuAc alpha 2.3 moieties, recognized by Maackia amurensis agglutinin-2, was low at birth but higher in sucking and weaned animals. Histoblood group O- and A-antigen expression was first detected in a minority of sucking pigs, but was evident in all weaned pigs examined. Lactase glycoforms were isolated from solubilized microvillar membranes of newborn and weaned pigs. The newborn (predominantly alpha 2,6-sialylated) and weaned (predominantly alpha 1,2-fucosylated) glycoforms exhibited similar specific activity, indicating that postnatal lactase decline in the pig intestine is unrelated to temporal changes in membrane sialylation and fucosylation.

Developmentally regulated Gb3 galactosyltransferase and alpha-galactosidase determine Shiga toxin receptors in intestine

The receptor for Shiga toxin on rabbit intestinal microvillus membranes (MVMs) has been identified as a developmentally regulated glycolipid, globotriaosylceramide [galactose alpha 1-4 galactose beta 1-4 glucose beta 1-1 ceramide (Gb3)]. MVM Gb3 levels increase markedly in the third week of life, concomitant with fluid secretory responses to the toxin. To study mechanisms controlling developmental regulation of MVM Gb3, we measured the specific synthetic Gb3 galactosyltransferase and degradative alpha-galactosidase activities and subcellular distribution of Gb3 at various ages. Quantitative high-performance liquid chromatography demonstrated a similar developmental pattern in both microsomal and MVM Gb3, indicating that late expression of MVM Gb3 is not due to delayed migration of Gb3 from the microsomal to the MVM. The specific Gb3 galactosyltransferase activity increased with age, with a sharp increase seen at 18 days of age, whereas alpha-galactosidase activity followed an inverse pattern. Thus, regulation of both synthetic and degradative pathways for Gb3 appears to explain the observed changes in Gb3 levels with age. The nature of the signals for developmental regulation of Gb3 levels is unknown, as are the physiological consequences of altered MVM glycolipid composition other than mediating response to Shiga toxin.

Effects of acute and chronic ethanol exposure on intestinal microvillus membrane lipid composition and fluidity.

Chronic ethanol consumption produces nutrient malabsorption. The mechanisms by which this occurs are poorly understood. One potential mechanism is an alteration in microvillus membrane (MVM) composition and fluidity. The effects of in vivo ethanol exposure on MVM lipid composition and fluidity were determined in rats fed either a standard diet or 15% ethanol in water for 2 months. Acute jejunal exposure to 4% ethanol was also performed in vivo in each feeding group. Acute exposure to ethanol produced an increase in static and dynamic membrane fluidity associated with a decrease in MVM cholesterol regardless of prior ethanol exposure. Chronic ethanol feeding alone did not alter membrane fluidity. Changes in membrane fatty acid composition were minor and variable after both acute and chronic ethanol exposure. Prior chronic ethanol feeding did not prevent the acute effects of ethanol on MVM composition or fluidity. These data support the theory that ethanol acutely disrupts nutrient transport by changing MVM lipid fluidity. The absence of adaptive changes in membrane composition and fluidity may also explain the persistent absorptive defects seen with chronic alcoholism.

Metabolism of aspartame by human and pig intestinal microvillar peptidases.

The artificial sweetener aspartame (N-L-alpha-aspartyl-L-phenyl-alanine-1-methyl ester; Nutrasweet), its decomposition product alpha Asp-Phe and the related peptide alpha Asp-PheNH2 were rapidly hydrolysed by microvillar membranes prepared from human duodenum, jejunum and ileum, and from pig duodenum and kidney. The metabolism of aspartame by the human and pig intestinal microvillar membrane preparations was inhibited significantly (> 78%) by amastatin or 1,10-phenanthroline, and partially (> 38%) by actinonin or bestatin, and was activated 2.9-4.5-fold by CaCl2. The inhibition by amastatin and 1,10-phenanthroline, and the activation by CaCl2 are characteristic of the cell-surface ectoenzyme aminopeptidase A (EC 3.4.11.7) and a purified preparation of this enzyme hydrolysed aspartame with a Km of 0.25 mM and a Vmax of 126 mumol/min per mg. A purified preparation of aminopeptidase W (EC 3.4.11.16) also hydrolysed aspartame but with a Km of 4.96 mM and a Vmax of 110 mumol/min per mg. However, rentiapril, an inhibitor of aminopeptidase W, caused only slight inhibition (maximally 19%) of the hydrolysis of aspartame by the microvillar membrane preparations. Similar patterns of inhibition and kinetic parameters were observed for alpha Asp-Phe and alpha Asp-PheNH2. Two other decomposition products of aspartame, beta Asp-PheMe and cyclo-Asp-Phe, were essentially resistant to hydrolysis by both the human and pig intestinal microvillar membrane preparations and the purified preparations of aminopeptidases A and W. Although the relatively selective inhibitor of aminopeptidase N (EC 3.4.11.2), actinonin, partially inhibited the metabolism of aspartame, alpha Asp-Phe and alpha Asp-PheNH2 by the human and pig intestinal microvillar membrane preparations, these peptides were not hydrolysed by a purified preparation of aminopeptidase N. Membrane dipeptidase (EC 3.4.13.19) only hydrolysed the unblocked dipeptide, alpha Asp-Phe, but the selective inhibitor of this enzyme, cilastatin, did not block the metabolism of alpha Asp-Phe by the microvillar membrane preparations.

Effect of Ethanol Administration Together with High- or Low-Protein Diet on Lipid Composition of Intestinal Microvillus Membrane in Rats.

Ethanol feeding daily for 40 days to rats enhanced cholesterol, triglycerides, phospholipids (PL), and glycolipids contents of intestinal brush borders. The observed increase in membrane PL was reflected in phosphatidyl serine, phosphatidyl inositol, phosphatidyl choline, and phosphatidyl ethanolamine. Feeding of an 8% protein (low protein; LP) diet to rats reduced the cholesterol content but augmented PL, triglyceride, and cerebroside contents of brush borders compared with the control values. Membranes from ethanol-fed, malnourished animals revealed a decrease in membrane PL and triglyceride contents compared with those values for LP-fed rats. Feeding of a 30% protein (high protein; HP) diet to rats significantly increased various lipid fractions (cholesterol, PL, cerebrosides, and gangliosides) of intestinal microvillus membrane (MVM) compared with those of the controls. Ethanol administration together with the HP diet reduced membrane cholesterol, PL, triglycerides and glycolipids contents compared with those values for HP-fed animals. Thus, the feeding of a HP diet prevented the lipid accumulation in the rat intestine induced by chronic ethanol feeding. These results suggest that lipid composition of intestinal MVM is modified by ethanol and dietary protein regimens. The sensitivity of MVM lipid composition to ethanol is influenced by the dietary protein content of the animals.

Effect of Chronic Ethanol Administration on Intestinal Microvillus Membrane Glycosylation in Rats Fed Rat Pellet Diet and Protein-Rich Diet.

Effect of chronic ethanol administration daily for 40 days together with 30% protein (HP) diet on microvillus membrane (MVM) glycosylation in rat intestine was studied. Ethanol administration to rats on a normal diet enhanced the hexose and sialic acid contents of brush borders but significantly reduced (p<0.05) membrane fucose levels. Feeding of the HP diet induced a generalized increase in MVM glycosylation. Ethanol feeding of rats maintained on the HP diet differently affected membrane glycosylation. Hexosamine content was enhanced, fucose and hexose contents were reduced, and sialic acid levels were unaltered under these conditions. The binding of 125I-wheat-germ agglutinin and 125I-peanut agglutinin to MVM was compatible with the chemical analysis of sugars in the various experimental groups. Incorporation of [14C] mannose or [14C]glucosamine into MVM from different groups of rats revealed an increase in mannosylation but a decrease in glucosamine incorporation into MVM from ethanol- or HP-fed animals. Ethanol feeding along with HP diet enhanced the incorporation of labelled sugars into MVM compared with that of the HP-fed controls. Electrophoretic distribution of radiolabelled membrane glycoproteins from the different groups revealed that glycoproteins of Mr 60, 000 were highly labelled. These results suggest that ethanol ingestion along with control or HP diet markedly modifies the intestinal MVM glycosylation but that these effects vary under different dietary regimens.

The potential value of integral membrane proteins in the vaccination of lambs against Haemonchus conortus

An extract of adult Haemonchus contortus enriched in the parasite's intestinal microvillar membrane protein H11 and other integral membrane proteins but free of the protein contortin was evaluated as a potential vaccine in two breeds of sheep. The worm burdens of Clun Forest sheep injected with the extract and challenged with 25,000 infective larvae were reduced 89% by weight compared to the average for the controls. The worm burdens of Dorset sheep (challenged with 10,000 infective larvae) were reduced 72%. In both breeds the reduction in the number of female worms, 92 and 71.8%, respectively, was greater than the reduction in the males (86.5 and 46%). Parasite egg output, determined only for the Dorsets, was reduced 92%. protection correlated with serum antibody titre. Most of the antibodies were directed against H 11.

Molecular cloning of the α-subunit of rat endopeptidase-24.18 (endopeptidase-2) and co-localization with endopeptidase-24.11 in rat kidney by in situ hybridization

Endopeptidase-24.18 (endopeptidase-2, EC 3.4.24.18, E-24.18) is a Zn-ectoenzyme of rat renal and intestinal microvillar membranes exhibiting an oligometric structure, α 2-β 2. The primary structure of the α-subunit of E-24.18 has been defined by molecular cloning and its expression mapped in rat kidney by in situ hybridization. A 2.9-kb cDNA coding for the α-subunit was isolated and sequenced. It had an open reading frame of 2.244 base pairs coding for a type I membrane protein of 748 amino acids. The deduced amino acid sequence showed 87% identity with that of meprin A, a mouse metallo-endopeptidase, sharing common properties with the rat enzyme, and 85% identity with the human intestinal enzyme, ‘PABA-peptide hydrolase’. Northern blot analysis revealed the α-subunit to be encoded by a single mRNA species of 3.2-kb. In situ hybridization performed on rat kidney showed a co-localization of E-24.18 with endopeptidase-24.11 in proximal tubules of juxtamedullary nephrons, suggesting that the two enzymes have similar or complementary physiological functions in kidney.

Dietary Fish Oil Modulates the Alkaline Phosphatase Activity and not the Fluidity of Rat Intestinal Microvillus Membrane

The effect of dietary fish (mackerel) oil on the function and fluidity of the intestinal microvillus membrane in 1-y-old rats was compared with that of coconut and soybean oils. The animals were fed diets containing 10% protein (derived from casein) and 15% oil. Intestinal microvillus membranes and RBC ghosts were isolated after a 6-wk feeding period and examined for fluidity by fluorescence polarization with 1,6-diphenyl-1,3,5-hexatriene. The functionality of the microvillus membrane was assessed by the activity of the intrinsic enzyme alkaline phosphatase. No differences in the fluidity were observed between the microvillus membranes or between the RBC ghosts derived from the various dietary groups. The alkaline phosphatase activity of the microvillus membrane was found to be the lowest in the membranes isolated from the fish oil-fed rats. In these membranes the contents of 20:5(n-3) and 22:6(n-3) fatty acids were higher than in the membranes derived from the coconut and soybean oil-fed animals. The cholesterol to phospholipid molar ratio was lower in the coconut oil-fed group than in the other two groups. It is suggested that the compensatory effect of the elevated cholesterol to phospholipid molar ratio on the membrane fluidity was such that no differences in the overall fluidity were detected. It is likely that the incorporation of these long chain fatty acids might have caused compositional changes in the lipid microenvironment of the enzyme. Such changes could alter the fluidity of these microdomains, thereby affecting the activity of the integral enzyme alkaline phosphatase.