Cortisone and thyroxine modulate intestinal lactase and sucrase mRNA levels and activities in the suckling rat.

Glucocorticoids and thyroxine modulate postnatal intestinal sucrase and lactase activities. Whether changes in enzyme activity are accompanied by changes in enzyme mRNA levels were determined in day 6 rats given thyroxine, cortisone, or thyroxine plus cortisone and killed 3 days later. Cortisone induced precocious expression of jejunal sucrase activity which was enhanced when cortisone plus thyroxine was administered; sucrase mRNA changed in parallel. Jejunal lactase activity was unaffected by thyroxine and was increased after cortisone, but not after thyroxine plus cortisone. Jejunal lactase mRNA levels increased equally after cortisone or after cortisone plus thyroxine. Thus, cortisone induces coordinated increases in sucrase and lactase activities and in corresponding mRNA levels. Thyroxine only enhances cortisone induced sucrase expression and antagonizes cortisone by depressing lactase activity post-translationally.     

Modulation by thyroxine of the amount of lactase protein in the jejunum of adult rats

Adult rats starved for 48 h received a daily injection of thyroxine over a 3-day period before they were killed. When compared to nourished animals, starvation provoked a 4- to 5-fold increase in immunoreactive lactase protein, which paralleled a similar stimulation of lactase activity in the brush border membranes of the proximal jejunum. Exogenous thyroxine completely inhibited the starvation-induced increase in immunoreactive lactase protein in both the intracellular and the brush border membranes.     

Hormone induced changes in lactase glycosylation in developing rat intestine

Lactase exists in both soluble and membrane-bound forms in suckling rat intestine. The distribution of lactase and its glycosylated isoforms in response to thyroxine or cortisone administration has been studied in suckling rats. 75% of lactase activity was detected, associated with brush borders, compared to 24% in the soluble fraction of 8-day-old rats. Thyroxine treatment enhanced soluble lactase activity to 34%, whereas particulate fraction was reduced to 67% compared to controls. Cortisone administration reduced soluble lactase activity from 24% in controls to 12% with a concomitant increase in membrane-bound activity to 89%. Western blot analysis revealed lactase signal, corresponding to 220 kDa in both the soluble and membrane fractions, which corroborated the enzyme activity data. The elution pattern of papain solubilized lactase from agarose-Wheat Germ agglutinin, or Concanavalin A or Jacalin agglutinin columns was different in the suckling and adult rat intestines. Also the elution profile of lactase activity from agarose-lectin columns was modulated in cortisone, thyroxine, and insulin injected pups, which suggests differences in glycosylated isoforms of lactase under these conditions. These findings suggest the role of these hormones in inducing changes in lactase glycosylation during postnatal development of intestine, which may contribute to adult-type hypolactasia in rats.     

Regulation of NAD- and NADP-linked isocitrate dehydrogenase by thyroxine in the brain and liver of female rats of various ages

The specific activity of NAD- and NADP-linked isocitrate dehydrogenase and their regulation by thyroxine in the brain and liver of female rats of various ages were studied with the ultimate goal of better understanding the decreased physiological functioning of the brain and liver during old age. Both thyroidectomy and thyroxine treatment have differential age-dependent effects on the activities of these enzymes in both tissues. The activity of NAD-ICDH decreases whereas both cytoplasmic and mitochondrial NADP-ICDH increase simultaneously following thyroidectomy. Thyroxine administration induces NAD-ICDH and depresses NADP-ICDH. The degree of induction and/or repression is lowest in old rats. These effects of thyroxine are actinomycin D sensitive in both the tissues of rats.     

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.     

Roles of extracellular lactose hydrolysis in cellulase production by Trichoderma reesei Rut C30 using lactose as inducing substrate

Lactose, an inexpensive, soluble substrate, offers reasonably good induction for cellulase production by Trichoderma reesei. The fungus does not uptake lactose directly. Lactose is hydrolyzed to extracellular glucose and galactose for subsequent ingestion. The roles of this extracellular hydrolysis step were investigated in this study. Batch and continuous cultures were grown on the following substrates: lactose, lactose–glycerol mixtures, glucose, galactose, and glucose–galactose mixtures. Cell growth, substrate consumption, lactose hydrolysis, and lactase and cellulase production were followed and modeled. Cells grew much faster on glucose than on galactose, but with comparable cell yields. Glucose (at >0.3 g/L) repressed the galactose consumption. Cellulase synthesis was growth-independent while lactase synthesis was growth-dependent, except at D < ∼0.065 h⁻¹ where a basal level lactase production was observed. For cellulase production the optimal D was 0.055–0.065 h⁻¹ where the enzyme activity and productivity were both near maxima. The model suggested that lactase synthesis was subject to weak galactose repression. As the galactose concentration increased at high D (>0.1 h⁻¹), lactase synthesis became repressed. The insufficient lactase synthesis limited the lactose hydrolysis rate. Extracellular lactose hydrolysis was concluded to be the rate-limiting step for growth of T. reesei Rut C30 on lactose.     

Comparative study of the effect of hydrocortisone and thyroxine on suckling mouse small intestine in organ culture

The influence of hydrocortisone (10(-8)--10(-5) M) and thyroxine (10 (-9)--10(-6) M) on intestinal epithelial cell differentiation and proliferation have been studied using explants of suckling mouse jejunum maintained in serum-free organ culture. Hydrocortisone induced the appearance of sucrase activity and increased trehalase, glucoamylase, lactase and alkaline phosphatase activities. Thyroxine was completely ineffective at all the concentrations used. None of these hormones affected the mitotic activity or the 3H-thymidine incorporation into DNA. These results demonstrate that hydrocortisone but not thyroxine acts directly on intestinal brush border membrane differentiation and that both hormones do not influence the proliferation of the epithelial cells during postnatal development.     

Formation of the Digestive-Transport Conveyer of Carbohydrates in Rat Ontogenesis

The absorption of free glucose and glucose released from hydrolysis of different oligosaccharides has been studied using the procedure of perfusion of the isolated segment of the small intestine of rat pups, with the simultaneous determination of activities of intestinal disaccharidases by glucoseoxidase method. It has been established that: (1) the active transport of glucose in the small intestine is sufficiently pronounced during the breast feeding and gradually decreases by the time of transition of the pups to the definitive nutrition; (2) at this period, activities of lactase and of lactase-transport complexes are rather high, with the low level of activities of maltase and of maltase-transport ensembles, or complexes; (3) during the transition to the definitive feeding, simultaneously with the lactase activity repression, the activity of the lactase-transport ensembles is reduced, and digestive-transport complexes are formed, which provide high rates of hydrolysis of carbohydrates, the main component of the food.     

The nature of maturational decline of intestinal lactase activity

We have examined the nature of the decline of lactase (EC 3.2.1.23) activity in the maturing rat intestine. It was established in an initial study that the activity decline reflected a proportional reduction in the concentration of the enzyme protein. Accumulation patterns of label into lactase, total intestinal proteins and sucrase (EC 3.2.1.48)-isomaltase (EC 3.2.1.10) were compared, 4 h following administration of a tracer dose of [3H]leucine to weanling rats exhibiting a wide range of lactase decline. Accumulation of increasing amounts of label in total intestinal proteins and sucrase-isomaltase pools was found to accompany the lactase decline, in contrast to accumulation of a constant amount of label in the declining lactase pools. The pattern of increased label accumulation in total intestinal proteins was shown in a corollary study to reflect a corresponding acceleration of total protein synthesis. On this basis, the finding of a constant amount of label in the declining lactase pools suggested a constant synthesis of lactase. We proposed earlier that associated reductions in enterocyte life-span (leading to correspondingly less lactase accumulation) rather than suppressed synthesis may provide the primary causal basis of lactase decline in the postweaned mammal.     

Regulation of beta-D-galactosidase synthesis in Candida pseudotropicalis.

Regulation of lactose (beta-D-galactosidase) synthesis in the lactose-utilizing yeast Candida pseudotropicalis was studied. The enzyme was inducible by lactose and galactose. When grown on these sugars the enzyme level of the yeast was 20 times or higher than when grown on glycerol. The Km and optimal pH were similar for the lactase induced either by lactose or galactose. The hydrolysis of o-nitrophenyl-beta-D-galactopyranoside by the lactase was inhibited by galactose and several analogs and galactosides, but not by glucose. Lactose uptake activity observed in lactose-grown cells was very reduced in cells grown on glucose or galactose. Glucose repressed the induction of lactase, but not the metabolic system for galactose utilization. In continuous culture on lactose medium at dilution rates below 0.2 h-1 the specific lactase activity was higher than in batch cultures and decreased with increases in dilution rate. Lactase was induced by pulses of lactose and galactose in cells growing on glucose, but only at low dilution rates were the steady-state concentration of glucose was very low.     

Human small-intestinal β-galactosidases. Separation and characterization of one lactase and one hetero β-galactosidase

1. Two beta-galactosidases from human small-intestinal mucosa were separated by gel-filtration chromatography and the properties of the two enzymes were studied. Lactose and four hetero beta-galactosides were used as substrates. 2. One of the enzymes was particle-bound and could be partially solubilized with papain. Of the substrates hydrolysed by this enzyme, lactose was hydrolysed most rapidly. This enzyme is thus essentially a disaccharidase and is named lactase. It is presumably identical with the ;lactase 1' described earlier. 3. The other enzyme was mainly soluble and hydrolysed all artificial substrates used, whereas no lactase activity could be detected. This enzyme has therefore been designated hetero beta-galactosidase. 4. p-Chloromercuribenzoate (0.1mm) inhibited the hetero beta-galactosidase completely but did not influence the activity of the lactase. Tris was a competitive inhibitor of both enzymes. 5. The residual lactase activity in the mucosa of lactose-intolerant patients may be exerted by a small amount of remaining lactase as such, or possibly by a third enzyme with a more acid pH optimum.     

Catabolite repression during single and multiple induction inEscherichia coli

Intracellular concentration of cAMP regulates the synthesis of enzymes sensitive to catabolite repression. The relationship between the single and multiple induction of beta-galactosidase (EC 3.2.1.23), L-tryptophanase (EC 4.1.99.1), D-serine deaminase (EC 4.2.1.14), L-asparaginase (EC 3.5.1.1) and L-malate dehydrogenase (EC 1.1.1.37) was studied and the effect of cAMP level on the induction in Escherichia coli Crookes (ATCC 8739) was investigated. A varying degree of catabolite repression was observed during induction of individual enzymes induced separately on different energy sources. The synthesis of l-tryptophanase was most sensitive, whereas l-asparaginase was not influenced at all. Exogenous cAMP was found to overcome partially the catabolite repression of beta-galactosidase and D-serine deaminase, both during single induction. The synthesis of l-malate dehydrogenase was negatively influenced by the multiple induction even in the presence of cAMP; on the other hand, the synthesis of l-tryptophanase was stimulated, independently of the level of the exogenous cAMP. Similarly, the activity of L-asparaginase slightly but significantly increased during the multiple induction of all five enzymes; here too the activity increase did not depend on exogenous cAMP.     

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".     

Regulation of phosphatidylserine decarboxylase in Saccharomyces cerevisiae by inositol and choline: kinetics of repression and derepression

The biosynthesis of phosphatidylserine (PS) and its conversion to phosphatidylcholine (PC) are regulated coordinately by inositol and choline in Saccharomyces cerevisiae (G. M. Carman and S. A. Henry, 1989, Annu. Rev. Biochem. 58, 635-669). In this study, PS decarboxylase activity is shown to be partially repressed when inositol is added to the medium of cells in the log phase of growth, and the extent of repression is augmented by the inclusion of choline, but not ethanolamine. The kinetics of repression and derepression of PS decarboxylase, PS synthase, and phospholipid N-methyltransferase (PNMT) activities, as regulatory responses to the availability of exogenous inositol and choline, have been characterized. When inositol was added to the medium of cell cultures growing exponentially, the three biosynthetic enzyme activities reached an intermediate level of repression (50-85% of control) within 60 min. After the addition of the combination of inositol and choline, PS decarboxylase, PS synthase, and PNMT activities decreased to the intermediate levels of repression in 60 min and were subsequently reduced to 15-40% of control values during a later stage of regulation (2-3 h). In a derepression study, the three enzyme activities remained relatively stable for approximately 60 min following the removal of choline and/or inositol from the growth medium, but the specific activities of PS decarboxylase, PS synthase, and PNMT increased to maximally derepressed levels within 2-3 h. The induction of the three biosynthetic activities was blocked by cycloheximide, but not by chloramphenicol. In summary, the level of PS decarboxylase activity in S. cerevisiae is partially and reversibly suppressed by inositol and further diminished by the combination of inositol and choline. The biphasic kinetics of repression by inositol and choline suggest that the effect of choline is dependent on earlier events mediated by inositol and possibly involves a separate regulatory factor(s).