A novel progranulin mutation associated with variable clinical presentation and tau, TDP43 and alpha-synuclein pathology.

Mutations in the progranulin (GRN) gene have recently been reported as a cause of the frontotemporal dementia (FTD) syndrome. We performed a clinical, neuropathological and molecular genetic study of two families with FTD and the same novel mutation in GRN. Age of onset ranged from 35 to 75 years and all individuals progressed to a severe dementia syndrome with a mean disease duration of approximately 6-10 years. Variable clinical presentations included language impairment, behaviour change or parkinsonism. Seven total autopsies in the families (five in Family 1, two in Family 2) showed gross and microscopic evidence of neuronal loss in the neocortex, striatum, hippocampus and substantia nigra. All cases with material available for immunohistochemistry had cytoplasmic and intranuclear ubiquitin positive, tau negative inclusions that stained best with an antibody to the TDP43 protein. In addition, all but one had evidence of distinctive tau pathology. Two cases in Family 1 also had alpha-synuclein (SNCA) pathology, one with diffuse neocortical inclusions and neurites and unusual striatal cytoplasmic inclusions. Affected persons in both families had the same mutation in GRN (c.709-2A>G). A minigene construct showed that this mutation alters splicing of exon 7 and results in reduced mRNA message in brain. A single GRN mutation in these two families was associated with variable clinical presentations consistent with the FTD syndrome. All cases had ubiquitin/TDP43 immuno-positive inclusions and most had additional tau pathology. Two cases had SNCA pathology. These findings suggest a link between mutations in GRN and aggregation of tau, TDP43 and SNCA.

Age-related changes in activities of mitochondrial electron transport complexes in various tissues of the mouse.

The purpose of the present study was to examine the role of mitochondria in the aging process by determining whether the activities of various electron transport chain oxidoreductases are deleteriously affected during aging and whether the hypothesized age-related alterations in different tissues follow a common pattern. Activities of respiratory complexes I, II, III, and IV were measured in mitochondria isolated from brain, heart, skeletal muscle, liver, and kidney of young (3.5 months), adult (12-14 months), and old (28-30 months) C57BL/6 mice. Activities of some individual complexes were decreased in old animals, but no common pattern can be discerned among various tissues. In general, activities of the complexes were more adversely affected in tissues such as brain, heart, and skeletal muscle, whose parenchyma is composed of postmitotic cells, than those in the liver and kidney, which are composed of slowly dividing cells. The main feature of age-related potentially dysfunctional alterations in tissues was the development of a shift in activity ratios among different complexes, such that it would tend to hinder the ability of mitochondria to effectively transfer electrons down the respiratory chain and thus adversely affect oxidative phosphorylation and/or autooxidizability of the respiratory components.

Decreased mitochondrial hydrogen peroxide release in transgenic Drosophila melanogaster expressing intramitochondrial catalase.

The objective of this study was to develop strategies for manipulating oxidative stress transgenically in a multicellular organism. Ectopic catalase was introduced into the mitochondrial matrix, which is the main intracellular site of H2O2 formation and where catalase is normally absent. Transgenic Drosophila melanogaster were generated by microinjection of a P element construct, containing the genomic catalase sequence of Drosophila, with the mitochondrial leader sequence of ornithine aminotransferase inserted upstream of the coding region. Total catalase activities in whole-body homogenates of 10-day-old flies from four transgenic lines were approximately 30-160% higher than those from the parental and four vector-only control lines. Expression of catalase in the mitochondrial matrix was confirmed by immunoblotting and catalase activity assays. Mitochondrial release of H2O2 was decreased by approximately 90% in the transgenic lines when compared to levels in vector-only controls. This in vivo system provides a novel model for examining the functional significance of decreased mitochondrial H2O2 release.

Effect of age and caloric restriction on bleomycin-chelatable and nonheme iron in different tissues of C57BL/6 mice.

The objective of this study was to test the hypothesis that the widely observed age-associated increase in the amounts of macromolecular oxidative damage is due to an elevation in the availability of redox-active iron, that is believed to catalyze the scission of H2O2 to generate the highly reactive hydroxyl radical. Concentrations of bleomycin-chelatable iron and nonheme iron were measured in various tissues and different regions of the brain of mice fed on ad libitum (AL) or a calorically restricted (to 60% of AL) diet at different ages. The concentrations of these two pools of iron varied markedly as a function of tissue, age, and caloric intake. There was no consistent ratio between the amounts of nonheme and the bleomycin-chelatable iron pools across these conditions. Nonheme iron concentration increased with age in the liver, kidney, heart, striatum, hippocampus, midbrain and cerebellum of AL animals, whereas bleomycin-chelatable iron increased significantly with age only in the liver. Amounts of both nonheme and bleomycin-chelatable iron remained unaltered during aging in the cerebral cortex and hindbrain of AL mice. Caloric restriction had no effect on iron concentration in the brain or heart, but caused a marked increase in the concentration of both bleomycin-chelatable and nonheme iron in the liver and the kidney. The results do not support the hypothesis that accumulation of oxidative damage with age, or its attenuation by CR, are associated with corresponding variations in redox-active iron.

Substrate and site specificity of hydrogen peroxide generation in mouse mitochondria.

The objective of this study was to elucidate the mechanisms of mitochondrial H2O2 generation in mouse organs by determining the nature of their differences in substrate utilization, inhibitor sensitivity, and the site specificity affecting H2O2 production. Mitochondria were isolated from heart, brain, and kidney and the rate of H2O2 generation was measured using the FADH-linked substrates succinate and alpha-glycerophosphate as well as the NADH-linked substrates pyruvate/malate, beta-hydroxybutyrate, and glutamate. Respiratory inhibitors, antimycin and rotenone, were added singly and sequentially to each substrate-supported H2O2 generation reaction mixture to determine the mitochondrial site(s) of generation and the optimal condition(s) for maximal rates of generation. Succinate supported the highest rate of mitochondrial H2O2 generation. Moreover, it was the preferred substrate for the heart mitochondria. alpha-Glycerophosphate is a poor substrate for H2O2 generation in heart mitochondria. Inhibitor studies showed that heart mitochondria were the most sensitive and responsive to antimycin, while brain was the most sensitive to rotenone. A surprising finding was that NADH-linked substrate-supported H2O2 generation in kidney mitochondria was not responsive to rotenone. The contribution from each of the three sites (ubiquinone, NADH dehydrogenase, and alpha-glycerophosphate dehydrogenase) of mitochondrial H2O2 generation to the total was both substrate and organ dependent. Results indicate that assay conditions must be considered before comparisons of sites and rates of mitochondrial H2O2 generation among different organs can be made.

Acute dyslipoproteinemia induced by interleukin-2: lecithin:cholesteryl acyltransferase, lipoprotein lipase, and hepatic lipase deficiencies.

Recombinant human interleukin-2 (rIL-2) is used to treat refractory cancers. During such treatment, patients develop severe hypocholesterolemia along with striking alterations in the concentration and composition of the circulating lipoproteins. The present study was undertaken to gather information about the pathogenesis of these abnormalities. Patients were studied before-, during- and after a 5-day course of high dose i.v. rIL-2. Whole plasma cholesterol was markedly reduced by rIL-2 administration (52%; P < 0.001), whereas the triglyceride concentration did not change. Thus, the lipoproteins became triglyceride enriched (P = 0.004). Low density lipoprotein cholesterol, apolipoprotein B (apoB), high density lipoprotein cholesterol, and apoA-I concentrations all decreased. Esterified cholesterol levels were markedly reduced. Total plasma apoE increased markedly, and two kinds of abnormal particles appeared: 1) beta-migrating, very low density lipoproteins; and 2) discoidal, apoE- and phospholipid-containing particles with abnormal density and electrophoretic mobility. The activities of two lipoprotein triglyceride hydrolases, lipoprotein lipase and hepatic lipase, fell significantly during treatment and returned promptly to pretreatment levels after rIL-2 was discontinued. Lecithin:cholesteryl acyltransferase (LCAT) activity also decreased significantly (64%) during treatment, but in contrast to the lipases, remained low for at least 5 days after the last dose of rIL-2 (P < 0.001). High dose i.v. rIL-2 induces severe dyslipidemia with deficiencies of both postheparin lipases and acute LCAT deficiency. Most, if not all, of the lipoprotein changes observed are explained by the LCAT deficiency that follows IL-2-induced hepatocellular injury and cholestasis.

Molecular screening of the lipoprotein lipase gene in hypertriglyceridemic members of familial noninsulin-dependent diabetes mellitus families.

Hypertriglyceridemia is common among individuals with noninsulin-dependent diabetes mellitus (NIDDM), and heterozygous lipoprotein lipase (LPL) mutations may result in the syndrome of familial hypertriglyceridemia and low levels of high density lipoprotein (HDL) cholesterol. To test the hypothesis that heterozygous LPL mutations predispose to the hypertriglyceridemia and low HDL cholesterol levels observed among members of familial NIDDM families, we examined 36 members and 3 unrelated spouses selected from members of 20 pedigrees for triglyceride levels exceeding the age- and sex-specific 95th percentile. Eighteen pedigree members and 2 spouses were diabetic. LPL exons 1-9 were screened by single strand conformation polymorphism analysis. Six different variants were detected in exons 2, 3, 4, 8, and 9, including 4 (exons 3, 4, and 8) silent nucleotide substitutions. A common nonsense mutation (exon 9; Ser-->Ter) was present in 2 pedigrees, and a missense mutation (exon 2; Asp-->Asn) was also present in members of 2 pedigrees. Analysis of members of these families suggested an association of the exon 2 variant with hypertriglyceridemia, although this trend was no longer significant when individuals with diabetes were excluded from the analysis. The variant enzyme was not present among 83 random control individuals, and when expressed in COS-1 cells, it was similar to the wild type with respect to specific activity, heparin binding, and heat stability. Our data suggest that coding region mutations of the LPL gene cannot account for the elevated triglyceride and low HDL levels noted in diabetic individuals and their relatives in most NIDDM pedigrees, but the exon 2 Asn variant may contribute to the hypertriglyceridemia in some families.

Diabetes increases hepatic hydroxymethyl glutaryl coenzyme A reductase protein and mRNA levels in the small intestine.

Previous studies have shown that both cholesterol synthesis and the activity of hepatic hydroxymethyl glutaryl coenzyme A (HMG CoA) reductase, the rate-limiting enzyme in cholesterol synthesis, are increased in the small intestine of a wide variety of different animal models of diabetes. In the present study, we demonstrate that the mass of HMG CoA reductase protein is increased in the small intestine of both streptozocin-induced diabetic rats (2.5-fold) and streptozocin/alloxan-induced diabetic dogs (2.4-fold). These increases in HMG CoA reductase protein mass are of a magnitude similar to the previously observed increases in either HMG CoA reductase activity and/or cholesterol synthesis in the small intestine of diabetic animals. Furthermore, mRNA levels for HMG CoA reductase in the small intestine of diabetic rats and diabetic dogs are increased 2.1- and 1.7-fold, respectively. These results suggest that the increase in HMG CoA reductase protein levels in the small intestine of diabetic animals is due to an increase in mRNA levels. In contrast, mRNA levels for HMG CoA reductase in the liver of diabetic rats are not increased. Additionally, mRNA levels for the low-density lipoprotein (LDL) receptor are also increased in the small intestine of diabetic animals (rats, 43%; dogs, 59%). The increase in small-intestinal cholesterol synthesis has the potential for adversely affecting lipoprotein metabolism and increasing the risk of atherosclerosis in diabetes.

Genetic predisposition to hyperlipidaemia in diabetes: the end of the beginning?

Diabetes mellitus leads to disturbances in lipoprotein homeostasis particularly when there is poor glycaemic control. The resulting abnormalities in concentration and composition of the circulating lipoproteins are modified by inherited variation in the genes coding for apolipoproteins, for the lipoprotein-processing enzymes, and possibly for lipoprotein receptors. Thus, poorly controlled diabetes provides an opportunity to observe the phenotypic effects of recessive mutant alleles that would otherwise be silent. This phenomenon should be considered when one attempts to understand the pathogenesis of variant phenotypes, ones differing from those typical of diabetes mellitus alone. Our understanding of how genetic variation modulates the expression of hyperlipidaemia in diabetes is still rudimentary--it now seems probable that many other genetic conditions affecting lipoprotein metabolism in diabetes will eventually be brought to light.

Mutations in exon 3 of the lipoprotein lipase gene segregating in a family with hypertriglyceridemia, pancreatitis, and non-insulin-dependent diabetes.

A proband with chylomicronemia, pancreatitis, and non-insulin-dependent diabetes (NIDDM) bears two different mutations in exon 3 of the lipoprotein lipase (LPL) gene: a missense mutation, 75Arg-->Ser, inherited through the paternal line and a truncation, 73Tyr-->Ter, through the maternal line. NIDDM appeared to be independently segregating. The R75S mutant was studied in extracts and media from transfected COS-1 cells. Detectable amounts of catalytically competent R75S LPL suggested destabilization of the active homodimer as with exon 5 mutants (Hata et al. 1992. J. Biol. Chem. 267:20132-20139). Hydrolysis of a short-chain fatty acid ester indicated that R75S does not directly affect activation of LPL by apoC-II. Subjects with NIDDM and wild-type LPL, and nondiabetic middle-aged carriers of the 73Tyr-->Ter truncation had moderate hypertriglyceridemia (260-521 mg/dl) and reduced high density lipoprotein cholesterol. A maternal aunt with NIDDM carried the truncation. Her phenotype (triglycerides of 5,300 mg/dl, eruptive xanthomatosis, and recurrent pancreatitis) was as severe as that in homozygotes or compound heterozygotes. We conclude: (a) diabetic carriers of dysfunctional LPL alleles are at risk for severe lipemia; and (b) the physiologic defects in NIDDM may be additive or synergistic with heterozygous LPL deficiency.

Missense mutations in exon 5 of the human lipoprotein lipase gene. Inactivation correlates with loss of dimerization.

Most missense mutations of the lipoprotein lipase (LPL) gene identified among LPL-deficient subjects cluster in a segment of the sequence that encodes the catalytic triad as well as functional elements involved in the activation of the lipase at lipid-water interfaces. Consequently, loss of activity may result either from direct alterations of such functional elements or from less specific effects on protein folding and stability. This issue was addressed by examining biochemical properties of four such variants (A176T, G188E, G195E, and S244T) in a heterologous expression system (COS-1 cells). Variant G195E (GGA----GAA) was previously unreported. In all instances, inactive enzyme was recovered in medium, albeit at reduced levels. Cellular synthesis and extracellular degradation were similar to those for wild type, suggesting that reduced secretion resulted from increased intracellular degradation. When cell extracts were subjected to heparin-Superose affinity chromatography followed by elution on a linear salt gradient, all variants exhibited a single, inactive, low affinity immunoreactive peak. By contrast, wild-type enzyme presented an additional, high affinity, active species, which we interpret as homodimeric enzyme. Substitution of the active-site serine (S132A) led to loss of activity but maintenance of the high affinity species. When large amounts of the G188E variant were applied to the column, small but significant amounts of high affinity, active enzyme were recovered. Systematic substitutions at residue 188 showed that only glycine could accommodate structural constraints at this position. We conclude that the mutations examined did not impart lipase deficiency by affecting specific functional elements of the enzyme. Rather, they appear to affect protein folding and stability, and thereby formation and maintenance of subunit assembly.

Mechanism of maturational decline of rat intestinal lactase-phlorizin hydrolase.

The maturational decline in lactase-phlorizin hydrolase (LPH) activity was studied in groups of young rats ranging from suckling to early post-weaned states. Associated maturational increases in sucrase-isomaltase (SI) and maltase-glucoamylase (MG) activities were also examined as a comparison. Over this time period changes in cellular concentrations of the three enzymes were observed, reflecting corresponding changes in enzyme activities. Synthesis patterns accompanying these maturational changes in concentration were examined using labelled leucine as a marker. Synthesis of LPH was found to be maintained at constant rates independent of the maturation-associated decline in its concentration, whereas the increases in cellular concentrations of SI and MG were due to accelerated synthesis of the enzyme. Turnover of LPH, based on both the fractional synthesis rate and the disappearance rate of labelled leucine from prelabelled LPH pools, was increased in a quantitatively similar way to the decline in LPH concentration. These findings are consistent with our earlier proposal that the maturational decline of LPH occurs because of accelerated turnover, without a decrease in its rate of synthesis.

Maturation of jejunoileal gradients in rat intestine: the role of intraluminal nutrients.

Jejunoileal gradients of intestinal function are thought to be established during the third week of life in the rat when postnatal intestinal maturation occurs. In order to investigate the normal development of jejunoileal gradients and whether either the absence of intraluminal nutrients or the form in which they are provided affected the development of jejunoileal gradients, gradients for mucosal DNA, protein, lactase and sucrase were studied in suckling rats undergoing normal weaning and compared to gradients in rats receiving no intraluminal nutrients or rats receiving nutrients in elemental form. In suckling animals, preexisting jejunoileal gradients for DNA and protein persisted through the weaning period, gradients for lactase formed by rapid decline of ileal function and sucrase gradients formed by rapid increase in jejunal activities. Intraluminal nutrients in elemental form resulted in the formation of jejunoileal gradients similar to those in intestines of normally weaned rats. The lack of intraluminal nutrients resulted in no qualitative differences in the expression of jejunoileal gradients for sucrase, but provision of elemental nutrients resulted in increased jejunoileal differences for this enzyme. The lack of intraluminal nutrients resulted in no gradients for DNA, less pronounced jejunoileal differences for protein and delayed maturational decline of ileal lactase which prevented development of jejunoileal gradients for the enzyme. These studies indicate that the formation of jejunoileal gradients in the maturing rat intestine for the parameters investigated require intraluminal nutrients regardless of the form in which they are provided for their normal expression.

Intestinal and hepatic cholesterogenesis in hypercholesterolemic dyslipidemia of experimental diabetes in dogs.

We previously reported that dog diabetes results in hypercholesterolemia and the accumulation of a high-density lipoprotein (HDL) subclass, HDL1. Hypercholesterolemic diabetic rodents exhibit hyperphagia, intestinal hypertrophy, and increased intestinal cholesterol synthesis and absorption; intestinal 3-hydroxy-3-methylglutaryl (HMG) CoA reductase activity is increased, whereas hepatic activity is unchanged or reduced. To determine whether similar mechanisms operate in the hypercholesterolemic diabetic dog, we measured hepatic and intestinal cholesterologenesis. Streptozocin-alloxan-induced diabetic dogs allowed access to food ad libitum were hyperphagic and hypercholesterolemic (10.1 vs. 4.47 mM) but normotriglyceridemic. Plasma HDL1 concentrations were markedly increased. Differences in renal and hepatic function were not statistically significant, except serum alkaline phosphatase, which was elevated 4-fold (P = 0.0003). Urinary mevalonate, an index of whole-body cholesterol synthesis, was increased 6-fold. Intestinal and hepatic weights were both increased, and direct measurements showed crypt and villus thickening. The activity of HMG CoA reductase per gram organ weight was increased 1.7-fold in liver and 2.1-fold in intestine. Calculated whole-organ activity in intestine was nearly twice that in liver. These observations provide strong evidence that intestinal cholesterogenesis is involved in the pathogenesis of hypercholesterolemia in dog diabetes and support the conclusion that increased cholesterol synthesis plays a role in the hypercholesterolemia of diabetes.

Synthesis and accumulation of protein and carbohydrases along the rat villus column.

Enterocytes of the intestinal mucosa of infant and adult rats continuously proliferate in the crypt, mature as they migrate along the villus column, and are discharged from the villus tip. We examined the synthesis patterns of total protein, lactase-phlorizin hydrolase, sucrase-isomaltase, and maltase-glucoamylase as well as the accumulation of these enzymes in cells during migration along the villus. Labeled leucine was administered intraperitoneally to suckling and young adult rats, and radioactivity was determined in protein and digestive carbohydrase pools of developing villus cells separated sequentially from tip to base of the villus column. The developing cells were found to continuously accumulate protein and carbohydrates as they ascended the villus column. In addition, incorporation of radioactivity into total protein and carbohydrase pools occurred at generally constant rates along the length of the villus. These studies showed that the differentiated enterocyte of both infant and young adult rat intestine exhibits a pattern of continuous growth while migrating the length of the villus column and maintains synthesis of protein and digestive carbohydrates at generally constant rates during this time.

Altered maturation of small intestinal function in the absence of intraluminal nutrients: rapid normalization with refeeding.

The absence of intraluminal nutrients during weaning in rats was shown to result in altered intestinal growth and maturation. In this study intestinal length, mucosal weight, DNA, protein, and total disaccharidase activities were significantly lower in animals sustained by intravenous nutrients over the normal weaning age than were normally weaned controls but were greater than preweaning values. Absorptive capacity for sucrose (assessed by hydrogen-gas production) was diminished, directly linking incomplete maturation of sucrase to diminished intestinal function. To determine whether these alterations were permanent, rats previously deprived of intraluminal nutrients over the weaning period were refed. Eight days after refeeding, all variables except total lactase had attained values found in normally weaned age-matched controls, including absorptive capacity for sucrose. Although intestinal growth and maturation is abnormal in the absence of intraluminal nutrients during weaning, the abnormalities are not permanent and are rapidly corrected upon refeeding.

Intestinal lactase in the neonatal rat. Maturational changes in intracellular processing and brush-border degradation.

The mechanism of decline in the catalytic activity of intestinal lactase during neonatal maturation has not been defined, but a shift in the lactase subunit synthesis from an active 130-kDa subunit to an inactive 100-kDa species has now been noted in the adult rat (Quan, R., Santiago, N. A., Tsuboi, K. K., and Gray, G. M. (1990) J. Biol. Chem. 265, 15882-15888). The subunit structure, synthesis, intracellular assembly, and subsequent degradation of lactase from the brush-border surface membrane was examined in 15-day-old pre-weaned and 30-day-old post-weaned intact rats. Lactase was labeled intraintestinally with [35S]methionine, isolated from Triton-solubilized membranes with monospecific polyclonal anti-lactase, and analyzed by sodium dodecyl sulfate-polyacrylamide gel electrophoresis and autoradiography. The protein-stained gel revealed subunits of 225 and 130 kDa, the latter species predominating in both the pre- and post-weaned state. The distinct adult-type 100-kDa moiety was present in post-weaned animals while only a trace of a slightly larger (approximately 110 kDa) species was observed in pre-weaned animals. Quantitation of radioactivity in newly synthesized lactase revealed an increasing prominence of the 100-kDa species in post-weaned rats (130/100 incorporation ratio: pre-weaned 6.2; post-weaned 3.3). Accumulation of newly labeled lactase in brush-border membranes after intraperitoneal [35S]methionine labeling was similar in both groups at 3 h. Despite these comparable rates of lactase synthesis, assembly and insertion in the pre- and post-weaned state, subsequent removal of the 130-kDa unit was more rapid in post-weaned animals (t1/2 = 11 h; pre-weaned t1/2 = 37 h). In intact rats, the neonatal maturational decline in lactase catalytic activities involves both a shift to production of the inactive 100-kDa subunit and increased membrane surface degradation of the active 130-kDa subunit.

Regulation of intestinal ontogeny by intraluminal nutrients.

Major events in gastrointestinal ontogeny occur in the infant rat in association with weaning, resulting in striking alterations in small intestinal structure and function. Although the dietary changes attendant to weaning are not essential for the initiation of these events, dietary nutrients have been shown to participate in the maturation of some intestinal parameters. In order to define more precisely the role of intraluminal nutrients in the regulation of small intestinal ontogeny, a longitudinal study was conducted using a unique animal model in which intraluminal nutrients were excluded from the intact maturing intestine in vivo throughout the entire weaning period without major compromise in nutritional status. The absence of intraluminal nutrients over the weaning period resulted in diminished lengthening and accretion of mucosal mass, suggesting a slower rate of intestinal growth. Lower mucosal DNA, protein, and mitotic indices in intestines of animals receiving no intraluminal nutrients suggested that the lack of intraluminal nutrients resulted in the blunting of the striking increases in cellular proliferation normally exhibited by the developing intestinal mucosa at this time. Maturation of intestinal lactase-phlorizin hydrolase and maltase-glucoamylase was not affected by the absence of intraluminal nutrients. Although the appearance of sucrase-isomaltase was not altered by the absence of intraluminal nutrients, activity levels rose to only 50% of control levels. These data suggest that during this period of rapid intestinal maturation, intestinal growth is more dependent upon intraluminal nutrients than are the characteristic enzymic alterations normally expressed during this period.(ABSTRACT TRUNCATED AT 250 WORDS)

Human intestinal lactase-phlorizin hydrolase: isolation and preparation of a specific antiserum.

Human intestinal lactase-phlorizin hydrolase (lactase) was selectively isolated with monospecific polyclonal antibodies to rat lactase. In addition to their immunologic similarities indicated by this isolation, human and rat lactase have similar kinetic characteristics but different subunit structure when analyzed by gel electrophoresis under reducing conditions. Rabbits immunized by injecting human lactase complexed with anti-rat lactase produced specific antibodies to human lactase that exhibited little cross-reactivity to the rat enzyme. The simple single-step procedure allows isolation of human lactase in high purity from small biologic samples and preparation of specific antisera to the human enzyme.

Dietary CHO and stimulation of carbohydrases along villus column of fasted rat jejunum.

Adult rats when fed a high carbohydrate diet of 70% sucrose or glucose for 24 h following a 4-day fast showed increased concentrations of intestinal sucrase-isomaltase (EC 3.2.1.48, EC 3.2.1.10) and maltase-glucoamylase (EC 3.2.1.20) but not lactase-phlorizin hydrolase (EC 3.2.1.23, EC 3.2.1.62). The concentration increases of these enzymes were accompanied by corresponding acceleration of their synthesis rates. Contrary to earlier studies by others, suggesting that upper villus cells in the fasted intestine are unresponsive to stimulation of sucrase activity by refeeding a high-sucrose diet, the concentration increases of both sucrase-isomaltase and maltase-glucoamylase were seen to occur in cells all along the length of the villus column. The earlier studies differed from the present study by basing enzyme assays relative to protein rather than the DNA content of villus cell fractions. We have shown that villus cells increase their protein content severalfold while migrating to villus tip, providing the basis for the difference between earlier and the present findings. Further evidence that stimulation of sucrase-isomaltase and maltase-glucoamylase by high carbohydrate is not restricted to the crypt and lower villus region was obtained by the finding that their synthesis rates appeared to be equally stimulated along the length of the villus column.