Comparison of sucrase-free isomaltase with sucrase-isomaltase purified from the house musk shrew Suncus murinus

We purified sucrase-isomaltase and sucrase-free isomaltase from a normal and a sucrase-deficient line, respectively, of the house musk shrew Suncus murinus and examined the effects of mutation on enzyme structure and activities. Recent cDNA cloning studies have predicted that sucrase-free mutant isomaltase lacks the C-terminal 69 amino acids of normal isomaltase, as well as the entire sucrase. On SDS-polyacrylamide gel electrophoresis purified sucrase-free isomaltase gave a single protein band of 103 kDa, while sucrase-isomaltase gave two major protein bands of 106 and 115 kDa. The 115, but not 106, kDa band was quite similar to the 103 kDa band on Western blotting with Aleuria aurantia lectin and antibody against shrew sucrase-isomaltase, suggesting that the 115 and 103 kDa bands are due to normal and mutant isomaltases, respectively, in accordance with the above prediction. Purified isomaltase and sucrase-isomaltase were similar in Km and Vmax (based on isomaltase mass) values for isomaltose hydrolysis and in inhibition of isomaltase activity by antibody against rabbit sucrase-isomaltase, suggesting that the enzymatic properties of isomaltase are mostly unaffected by mutation.     

Inhibition of beta-fructofuranosidases and alpha-glucosidases by synthetic thio-fructofuranoside

A synthetic beta-thio-fructofuranoside of mercaptoethanol inhibited not only beta-fructofuranosidases but also alpha-glucosidases. The compound was hardly hydrolyzed by the glycosidases. The thio-fructoside competitively inhibited beta-fructofuranosidases from Aspergillus niger, Candida sp., and Saccharomyces cerevisiae, but not Arthrobacter beta-fructofuranosidase at all. Sucrase activity of rat intestinal sucrase/isomaltase complex was also suppressed in the presence of the thio-fructoside. The thio-fructoside showed noncompetitive inhibition toward maltase activity of the rat intestinal enzyme complex and Saccharomyces sp. alpha-glucosidase. Inhibition against the Bacillus stearothermophilus alpha-glucosidase, Rhizopus glucoamylase, and porcine kidney trehalase were more slight than that against these two alpha-glucosidases.     

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.     

A two-active site one-polypeptide enzyme: the isomaltase from sea lion small intestinal brush-border membrane. Its possible phylogenetic relationship with sucrase-isomaltase

The enzyme responsible for all of the isomaltase activity and much of the maltase activity in the small intestine of the Californian sea lion (Zalophus californianus) was isolated by detergent solubilization of the brush-border membrane, followed by immunoadsorption chromatography using antibodies directed against rabbit sucrase-isomaltase. In 0.1% Triton X-100, sea lion isomaltase occurs as a monomer of Mr = 245,000 and is composed of a single polypeptide chain. As judged from the stoichiometry of the covalent binding of the affinity label, conduritol-B-epoxide, this polypeptide chain carries two enzymatically active sites; they are apparently identical and do not show either positive or negative cooperativity. In addition to cross-reacting immunologically with rabbit sucrase-isomaltase, sea lion isomaltase has similar overall enzymatic properties, with the exception of not hydrolyzing sucrose. The Alaskan fur seal (Collarhinus ursinus) has a two-active site isomaltase; however, in contrast to the sea lion, this animal is endowed with a small but significant sucrase activity. Along with (fully active) pro-sucrase-isomaltase, sea lion isomaltase is one of the very few examples of enzymes with more than one active site on a single polypeptide chain acting "in parallel" (rather than "in series"). Furthermore, this enzyme triggers some interesting questions on the phylogenetical pedigree of small intestinal sucrase-isomaltase.     

Dissociation of small-intestinal sucrase - isomaltase complex into enzymatically active subunits.

1. The sucrase - isomaltase complex from rabbit small intestine dissociated into its subunits upon reaction with citraconic anhydride. They can recombine after deacylation under mild acidic conditions. 2. When citraconylated, the subunits could be separated and isolated in a catalytically active form. 3. The previously reported procedure for separation of the subunits by alkaline treatment at pH 9.6 is apparently not due to contaminating degradative enzymes (possibly still present at undetectable levels in the isolated sucrase - isomaltase complex) but to the action of alkali.     

Intestinal lactase and other disaccharidase activities of a suckling crabeater seal (Lobodon carcinophagus)

1. The intestinal disaccharidase activities of a suckling crabeater seal were investigated. 2. Lactase, maltase, isomaltase and cellobiase activities were readily detected but trehalase and sucrase activities were absent. 3. The intestinal homogenates were separated into a soluble (S2) fraction and a particulate brush border (P2) fraction. The lactase activities of the two fractions had different properties corresponding to those of an acid and a neutral beta-galactosidase respectively. Approximately two-thirds of the total lactase activity measured at pH 6.0 was due to the acid beta-galactosidase. 4. The isomaltase and cellobiase activities were found almost exclusively in the particulate fractions but about one third of the maltase activity was in the S2 fraction. This soluble maltase activity appeared to be due to an acid maltase.     

Alleles at plasma alpha-amylase locus(Amy-1) of the house musk shrew(Suncus murinus): frequency distribution and new variants in laboratory lines and local Asian populations

Among nine laboratory shrew lines originating from the Japanese islands (Nag, Tok, TKU, Ize, Tr and OKI lines), West Java (Bog), Bangladesh (BAN) and Sri Lanka (SRI), Nag, Tr and Bog were fixed with Amy-1b and SRI with Amy-1a. The remaining lines were still highly polymorphic with the two alleles. A new electrophoretic band C was found in the BAN line and concluded to be expressed by a codominant allele, Amy-1c, which was carried by a single heterozygous female from among eleven wild shrews of the original breeding stock. In most local populations of the Asian shrews surveyed, Amy-1b was more common than Amy-1a. The Sri Lanka population was clearly distinguishable from the others, being nearly fixed with Amy-1a. The C band was found in eleven (one homozygous) of 86 wild shrews caught in Bangladesh. Of a total of 234 wild shrews collected from four Japanese and two Indonesian islands, Bangladesh, and Sri Lanka, only two showed different AMY-bands from AMY-A, -B and -C, and such bands were not found in the laboratory-bred shrews examined.     

Inhibition of S-adenosylmethionine-linked methylation can lead to neurite extension in neuroblastoma cells

The hog sucrase—isomaltase complex is anchored to the small-intestinal brush border membrane, as in the rabbit, via a hydrophobic segment located in the N-terminal region of the isomaltase subunit. The immediate precursor of the ‘final’ sucrase—isomaltase (i.e., pro-sucrase—isomaltase as prepared from adult hogs whose pancreas had been disconnected from the duodenum) is an amphiphilic single polypeptide chain of M_r 260 000–265 000. Its N-terminal sequence is virtually identical with (not merely homologous to) the corresponding region of the isomaltase subunit of ‘final’ sucrase-isomaltase. This shows that the isomaltase portion of pro-sucrase—isomaltase in the N-terminal ‘half’ of the precursor polypeptide chain. Thus the succession of domains in pro-sucrase—isomaltase and its mode of anchoring in the membrane could be deduced. On this basis a likely mechanism of biosynthesis and insertion is proposed.     

Intestinal brush border membrane-bound disaccharidases of the American alligator, Alligator mississippiensis

1. The disaccharidase activities of the small intestines of American alligators (Alligator mississippiensis) were studied in epithelial scrapes and brush-border membrane preparations. 2. Maltase, isomaltase and trehalase activities were found. Activities of these enzymes were higher in the proximal small intestine and decreased distally. 3. Disaccharidase activities were enriched 12-15 times in brush-border membrane preparations, compared with mucosa/enterocyte crude homogenates and were co-enriched with the brush-border membrane marker alkaline phosphatase. 3. The pH optima were: maltase 6.5; isomaltase 5.6; and trehalase 5.8. The Q10 of maltase, the most active enzyme, was equal to 1.82. 4. In reptiles, as in mammals, disaccharidase activities may be correlated with feeding habits. The co-occurrence of sucrase and isomaltase may not be a common feature of vertebrates.     

Column chromatography of human small-intestinal maltase, isomaltase and invertase activities

1. The maltase, isomaltase and invertase (sucrase) activities of solubilized mucosal preparations from human jejunum and ileum were studied with column chromatography on anion-exchange (diethylaminoethyl- and triethylaminoethyl-)cellulose and Sephadex G-200 gel. 2. On ion-exchange cellulose columns both kinds of enzyme preparations yielded two major disaccharidase peaks. The first peak contained maltase Ia (=isomaltase) and maltase Ib (=invertase). The second peak contained maltase II and maltase III. 3. On Sephadex G-200 gel columns jejunal preparations yielded the corresponding peaks as on ion-exchange columns, but the peaks appeared in the reverse order in the effluent. The ileal preparation studied yielded a single peak on gel columns, containing all the activities studied and eluted with the `void volume'. 4. Precipitation with ethanol did not affect the behaviour of the enzymes during ion-exchange chromatography. When gel filtration was performed after ethanol precipitation of the enzymes, however, two peaks were obtained also with the ileal preparation, and subfractionation of the invertase was obtained with both kinds of preparations. 5. The second peak from ion-exchange chromatograms, containing maltase II and maltase III, on concentration was found to have very weak isomaltase activity, probably exerted by these enzymes as such. This activity accounts for only about 1% of the total isomaltase activity of the mucosa. 6. The results support the concept of the specificity of the human small-intestinal disaccharidases previously described after heat-inactivation experiments. The subfractionation of the invertase that under certain conditions is seen on Sephadex G-200 columns appears most likely to be an artifact. Consequently the nomenclature for the human maltose-, isomaltose- and sucrose-splitting enzymes proposed by another research group after gel-filtration chromatography studies should be abandoned. It seems more logical to keep the nomenclature based on heat inactivation [maltase Ia (=isomaltase), maltase Ib (=invertase or sucrase), maltase II and maltase III] until increased knowledge about the specificity and structure of these enzymes makes possible a more rational nomenclature.     

Tryptic digestion of native small-intestinal sucrase - isomaltase complex: isolation of the sucrase subunit.

Limited tryptic digestion of native sucrase - isomaltase complex produced a more rapid destruction of isomaltase activity than sucrase activity. It was possible to isolate a partially fragmented sucrase subunits in high yields with a specific activity twice that of the native complex. Amino acid and carbohydrate analyses are reported and compared with the results obtained for sucrase - isomaltase complex and isomaltase subunit obtained by a different method.     

Studies on the distribution, food, breeding biology and relative abundance of the Pygmy and Common shrews (Sorex minutus andS. araneus) in upland areas of northern Engl and.

The distribution and relative abundance of the Pygmy and Common shrews were investigated over two years at 42 sites across northern England and at a further seven sites in one year. Most of the sites were in upland areas above 250m in altitude. At almost all sites, the Pygmy shrew was more abundant than the Common shrew, often by a considerable
A correlation exists between the numbers of shrews captured at a site and the abundance of invertebrates revealed by pitfall trapping. I t is recorded that Common shrews fed on earthworms (which are almost completely absent on peatlands) whilst Pygmy shrews did     

Time-dependent inhibition of sucrase and isomaltase from rat small intestine by castanospermine

Castanospermine (1,6,7,8-tetrahydroxyoctahydroindolizine) is a potent time-dependent inhibitor of the sucrase-isomaltase complex purified from rat small intestine, in vitro. First-order kinetics for the inactivation of sucrase and isomaltase by castanospermine were observed. Protection studies showed that castanospermine competes for the glucosyl subsite with the substrates of sucrase and isomaltase. The second-order rate constants (k1) for the association reaction between castanospermine and the protein complex were calculated to be 6.5 X 10(3) and 0.3 X 10(3) M-1 s-1 for sucrase and isomaltase, respectively. Only barely detectable reactivation of the inhibited isomaltase was detectable over 24 h, whereas about 30% reactivation of the inhibited sucrase was observed in 24 h (k2 = 3.6 X 10(-6) s-1). These results suggest that castanospermine functions as a transition-state analog that binds extremely tightly to sucrase and isomaltase.     

Topology and quaternary structure of pro-sucrase/isomaltase and final-form sucrase/isomaltase.

Pig sucrase/isomaltase (EC 3.2.1.48/10) was purified from intestinal microvillar vesicles prepared from animals with and without pancreatic-duct ligation to obtain the single-chain pro form and the proteolytically cleaved final form respectively. The purified enzymes were re-incorporated into phosphatidylcholine vesicles and analysed by electron microscopy after negative staining. The two forms of the enzyme were observed as identical series of characteristic projected views that could be unified in a single dimeric model, containing two sucrase and two isomaltase units. This shows a homodimeric functional organization similar to that of other microvillar hydrolases. The bulk of the dimer was separated from the membrane by a maximal gap of 3.5 nm, representing a junctional segment connecting the intramembrane section of the anchor to the catalytically active domain of sucrase/isomaltase. The enzyme complex protrudes from the membrane for a distance of up to 17 nm. From charge-shift immunoelectrophoresic studies of hydrophilic prosucrase/isomaltase and from electron microscopy of reconstituted pro-sucrase/isomaltase, there was no evidence to suggest the presence of anchoring sequences between the sucrase and isomaltase subunits.     

The occurrence of the Pigmy shrew Sorex minutus on moorland, and the implications for its presence in Ireland

Throughout most of its range in western Europe, the Pigmy shrew Sorex minutus is sympatricwith the Common shrew Sorex araneus but greatly outnumbered by it. This makes it difficult to explain the presence of the Pigmy shrew, in the absence of its congener, in Ireland. A limited pitfall trapping exercise in England has shown that in moorland on deep peat, the Pigmy shrew may in fact outnumber the Common shrew. Reference to the literature on the ecology of the two shrews shows that this result is readily explained by existing knowledge of their diet; earthworms are a major prey for Common shrews and are absent from waterlogged, acidic, peats. Further, evidence on the nature of the possible land bridge from Scotland to Ireland suggests that it was at best low-lying, and probably partly flooded. By analogy with moorland, such a land bridge might have been suitable for Pigmy shrews but not for Common shrews.     

Studies on the intestinal disaccharidases of the pigeon. II. Subcellular localization and solubilization

In the pigeon, 70-80% of the activities of maltase (alpha-D-glucoside glucohydrolase EC 3.2.1.20), sucrase (alpha-glucohydrolase, EC 3.2.1.48), isomaltase (dextran 6-alpha-D-glucan hydrolase, EC 3.2.1.10) and glucoamylase (1,4-alpha-D-glucan glucohydrolase, EC 3.2.1.3) were found to be localized in the brush-border membrane of intestinal epithelial cells. Of the total glycosidase activities in the mucosal homogenate, nearly 60 to 70% were recovered in the microsomal (105 000 X g) fraction, about 30% in the mitochondrial (22 000 X g) fraction and less than 5% from the cytosol (105 000 X g supernatant) fraction. The hydrolases were solubilized by digestion with papain but not with trypsin, and the phosphate ion had a protective effect in the solubilization. Amongst detergents, Triton X-100 but not sodium deoxycholate, was found to truly solubilize these enzymes.     

Inheritance and breeding of the waltzing mutant in the musk shrew (Suncus murinus, Insectivora) characterized by the circling and head-shaking behaviors.

A behavioral mutant was found in the laboratory-bred musk shrew (Suncus murinus). The affected shrews were characterized by the behaviors of tight circling in both directions and frequent head shaking in horizontal. They could definitely be identified by at least day 10 after birth. These abnormal behaviors were steady and permanent through life. Mating experiments demonstrated that the mutant character is expressed by a single autosomal recessive gene in homozygote with complete penetrance. The pedigree analysis indicated that the gene was derived from one heterozygous male captured in Ginowan city, Okinawa. The name, waltzing, was proposed for this mutant character with the gene symbol wz. An abnormality of the balance organ was predicted for a cause of the abnormal behaviors, since, besides the circling and head shaking behaviors, the affected shrews could not keep the body stretching but twisted it frequently when they were held up by the tail and further they could not keep the head on the water surface at all. Nevertheless, the affected shrews were almost normal in gestation period, litter size, weaning ratio and body weight in comparison with the phenotypically normal ones. The mutant shrews have been maintained as a closed colony, the WZ line involved more than 30 individuals at every one generation.