Relative zinc-binding activities of ligands in the cytosol of rat small intestine

Relative zinc-binding activities of high-molecular-weight zinc-binding ligand (HMW-ZBL), metallothionein (MT) and low-molecular-weight zinc-binding ligand (LMW-ZBL) in the cytosols of rat small intestines under various experimental conditions were examined. Zinc-binding activities of MT decreased and those of LMW-ZBL increased in the intestinal cytosols from most of the experimental rat groups after incubating at 37 degrees C for 2 hr. The relative zinc-binding activity of MT increased with increasing doses of injected zinc and decreased with orally-administered zinc. Isolated MT did not lose zinc-binding activity during incubation at 37 degrees C for 48 hr, but moved from the MT eluting peak to the LMW-ZBL eluting peak after 1 week.     

Metabolism of zinc-binding ligands in rat small intestine

Studies were conducted to determine the effects of zinc deficiency and excess zinc intake on the relative⁶⁵Zn-binding activities of metallothionein (MT) and low-molecular-weight zinc-binding ligand (LMW-ZBL) in vitro and in vivo. Zinc-binding ligands of small intestine from four groups, each of five rats (normal, zinc-deficient, excess zinc injected, and excess zinc given orally), were separated by column chromatography on Sephadex G-75. The ratio of⁶⁵Zn binding activities of MT to LMW-ZBL (MT/LMW-ZBL) in zinc-deficient rats was decreased both in vitro and in vivo compared to the control. When excess zinc was administered orally,⁶⁵Zn-binding activity of MT was low in vitro and substantially increased in vivo. However, when excess zinc was injected intraperitoneally,⁶⁵Zn-binding activity of MT in vitro greatly increased, but⁶⁵Zn-binding activities of both MT and LMW-ZBL were significantly reduced in vivo as compared to the control. Based onA ₂₈₀ readings of isolated MT and densities of protein bands in disc gel electrophoresis, the⁶⁵Zn-binding activity of MT in vitro appeared to be proportional to the MT content. Hence, these data indicate that oral administration of excess zinc decreases MT whereas intraperitoneal injection of excess zinc stimulates its synthesis. Zinc deficiency has little to no effect on the intestinal MT metabolism. These results suggest that MT may be important in zinc secretion but not involved in zinc absorption; while LMW-ZBL participates both in zinc absorption and secretion.     

Toward a molecular understanding of zinc metabolism

The absorption of zinc is increased when the dietary zinc supply is low. This is caused by increased intestinal transport and reduced secretion of endogenous zinc into the intestine. Kinetic analysis of zinc transport, based on data from either the isolated perfused intestine or brush border membrane vesicles, demonstrates uptake velocity is increased homeostatically by a carrier-mediated phase of transport in response to low dietary zinc. Zinc within intestinal cells binds to high molecular weight proteins and metallothionein. Expression of the metallothionein gene is altered by zinc status and the protein appears to have a function in intestinal cells. Zinc transport across the basolateral membrane is also carrier-mediated and may be ATP-driven. Newly absorbed zinc is transported via albumin, first to the liver and then is redistributed to other tissues, particularly muscle and bone which provide the greatest reserves. Plasma zinc levels remain relatively constant except during periods of dietary zinc depletion and acute responses to stress, infection or inflammation where they are depressed. Experiments with intact rats and isolated rat liver parenchymal cells have shown that hepatic zinc turnover is rapid. Stimulation of liver cells by glucocorticoids, glucagon, epinephrine, cAMP or interleukin-1-like factors alters uptake/exchange kinetics such that there is a net accumulation of cellular zinc. Metallothionein gene expression is enhanced by these hormonal signals, and a considerable portion of the newly accumulated zinc is accounted for as that associated with this zinc-binding protein.(ABSTRACT TRUNCATED AT 250 WORDS)     

Isolation of an intestinal metallothionein induced by parenteral zinc

An intestinal zinc-binding protein, induced by parenteral zinc administration, has been isolated and characterized. Based upon its elution behavior in two chromatographic systems, Zn²⁺/protein ratio of 5.0–5.6 gram atoms/mole, a Zn²⁺/SH ratio of about 3.0, paucity of both aromatic amino acids and absorbance at 280 nm, abundance of cysteic acid residues (28–31%), and low molecular weight (6,000–7,000 daltons), the protein meets the criteria for classification as a metallothionein and is more properly named zinc-thionein. Orally administered ⁶⁵Zn was found to bind to intestinal zinc-thionein and thus this intracellular protein may function as a component of the mechanism responsible for mammalian zinc homeostasis at the level of intestinal absorption.     

Absorption and localization of zinc in the ileum of chicks dependent on provision with vitamin A

Vitamin A increase the accumulation and transport of zinc in the chick ileal mucosa. Regulating effect of this vitamin on the mentioned processes was already observed in the initial stage zinc uptake in the intestinal mucosa--its storage in the mucus layer. Stimulation of zinc absorption by vitamin A can be related to a specific carrier-vitamin A-dependent zinc-binding protein. Presence of zinc in the smooth endoplasmic reticulum of the enterocyte apical zone suggests the role of this organelle in the cation homeostasis in the cell.     

Using primary murine intestinal enteroids to study dietary TAG absorption,lipoprotein synthesis,and the role of apoC-III in the intestine

Since its initial report in 2009, the intestinal enteroid culture system has been a powerful tool used to study stem cell biology and development in the gastrointestinal tract. However, a major question is whether enteroids retain intestinal function and physiology. There have been significant contributions describing ion transport physiology of human intestinal organoid cultures, as well as physiology of gastric organoids, but critical studies on dietary fat absorption and chylomicron synthesis in primary intestinal enteroids have not been undertaken. Here we report that primary murine enteroid cultures recapitulate in vivo intestinal lipoprotein synthesis and secretion, and reflect key aspects of the physiology of intact intestine in regard to dietary fat absorption. We also show that enteroids can be used to elucidate intestinal mechanisms behind CVD risk factors, including tissue-specific apolipoprotein functions. Using enteroids, we show that intestinal apoC-III overexpression results in the secretion of smaller, less dense chylomicron particles along with reduced triacylglycerol secretion from the intestine. This model significantly expands our ability to test how specific genes or genetic polymorphisms function in dietary fat absorption and the precise intestinal mechanisms that are critical in the etiology of metabolic disease.     

Proteins involved in uptake, intracellular transport and basolateral secretion of fat-soluble vitamins and carotenoids by mammalian enterocytes

Our understanding of the molecular mechanisms responsible for fat-soluble vitamin uptake and transport at the intestinal level has advanced considerably over the past decade. On one hand, it has long been considered that vitamin D and E as well as β-carotene (the main provitamin A carotenoid in human diet) were absorbed by a passive diffusion process, although this could not explain the broad inter-individual variability in the absorption efficiency of these molecules. On the other hand, it was assumed that preformed vitamin A (retinol) and vitamin K1 (phylloquinone) absorption occurred via energy-dependent processes, but the transporters involved have not yet been identified. The recent discovery of intestinal proteins able to facilitate vitamin E and carotenoid uptake and secretion by the enterocyte has spurred renewed interest in studying the fundamental mechanisms involved in the absorption of these micronutrients. The proteins identified so far are cholesterol transporters such as SR-BI (scavenger receptor class B type I), CD36 (cluster determinant 36), NPC1L1 (Niemann–Pick C1-like 1) or ABCA1 (ATP-Binding Cassette A1) displaying a broad substrate specificity, but it is likely that other membrane proteins are also involved. After overviewing the metabolism of fat-soluble vitamins and carotenoids in the human upper gastrointestinal lumen, we will focus on the putative or identified proteins participating in the intestinal uptake, intracellular transport and basolateral secretion of these fat-soluble vitamins and carotenoids, and outline the uncertainties that need to be explored in the future. Identifying the proteins involved in intestinal uptake and transport of fat-soluble vitamins and carotenoids across the enterocyte is of great importance, especially as some of them are already targets for the development of drugs able to slow cholesterol absorption. Indeed, these drugs may also interfere with lipid vitamin uptake. A better understanding of the molecular mechanisms involved in fat-soluble vitamin and carotenoid absorption is a priority to better optimize their bioavailability.     

Zinc uptake by isolated rat enterocytes: effect of low molecular weight ligands

The luminal phase of zinc intestinal absorption has not been well characterized. This study was intended to elucidate the possible role of low molecular weight (LMW) ligands in zinc intestinal transport in an isolated rat enterocyte system. Under these in vitro conditions, zinc uptake by the isolated enterocytes was rapid, leveling off within 1 min. Kinetic analysis revealed that both a mediated and diffusion component were involved in zinc uptake in the absence of LMW ligands by the cells. For the mediated component of zinc transport, the Kt and Vmax were 64.1 microM and 13.9 nmol/20 sec/mg protein, respectively. Zinc uptake was not affected by the addition of metabolic inhibitors. In the presence of histidine or cysteine (2:1 ligand:zinc molar ratio), zinc uptake was greatly reduced and occurred solely via mediated transport. Zinc uptake was also significantly decreased upon the addition of EDTA to the assay media. Other amino acids tested had no effect on zinc uptake by the cells. Albumin markedly reduced zinc uptake by the cells. Histidine and other potential LMW ligands were unable to facilitate albumin-inhibited zinc uptake. The results of this study suggest that the intestinal absorption of zinc may not be effected in the form of chelates with LMW ligands. Amino acids such as histidine and cysteine significantly reduce the uptake of the metal by isolated rat enterocytes, making questionable their putative role as necessary vehicles in the luminal phase of zinc absorption.     

1,25-Dihydroxyvitamin D3 increases the expression of the CaT1 epithelial calcium channel in the Caco-2 human intestinal cell line

Background  

The active hormonal form of vitamin D (1,25-dihydroxyvitamin D) is the primary regulator of intestinal calcium absorption efficiency. In vitamin D deficiency, intestinal calcium absorption is low leading to an increased risk of developing negative calcium balance and bone loss. 1,25-dihydroxyvitamin D has been shown to stimulate calcium absorption in experimental animals and in human subjects. However, the molecular details of calcium transport across the enterocyte are not fully defined. Recently, two novel epithelial calcium channels (CaT1/ECaC2 and ECaC1/CaT2) have been cloned and suggested to be important in regulating intestinal calcium absorption. However, to date neither gene has been shown to be regulated by vitamin D status. We have previously shown that 1,25-dihydroxyvitamin stimulates transcellular calcium transport in Caco-2 cells, a human intestinal cell line.     

Molecular mechanism of intestinal iron absorption

Iron is an essential trace metal in the human diet because of its role in a number of metabolic processes including oxygen transport. In the diet, iron is present in two fundamental forms, heme and non-heme iron. This article presents a brief overview of the molecular mechanisms of intestinal iron absorption and its regulation. While many proteins that orchestrate iron transport pathway have been identified, a number of key factors that control the regulation of iron absorption still remain to be elucidated. This review also summarizes new and emerging information about iron metabolic regulators that coordinate regulation of intestinal iron absorption.     

The effects of severe zinc deficiency on intestinal amino acid losses in the rat

To determine whether intestinal amino acid losses might occur during zinc deficiency, labeled aminoisobutyric acid was given parenterally to zinc deficient rats and to appropriate zinc-sufficient controls. After 24 hours, the aminoisobutyric acid loss into the intestinal lumen was measured by in situ perfusion of isolated intestinal segments under conditions of either net water absorption or water secretion. Net amino acid losses were larger in the jejunum of the zinc deficient rats and losses were exacerbated during net water secretion in the jejunum and colon segments. The contribution of amino acid losses to fecal nitrogen, particularly during osmotic diarrhea, may be important in the growth retardation of zinc deficiency. Further, these alterations may indicate defective enterocyte transport functions during severe deficiency.     

Purification and Some Properties of Metal-binding Proteins in Housefly Larvae (Musca domestica)

Cadmium and zinc-binding proteins similar to metallothionein have been isolated from housefly larvae (Musca domestica) exposed to cadmium chloride. Amino acid composition analysis found a high half-cystine content and an apparent minimum molecular weight of 5225. Metal-binding proteins of Musca domestica contained 3.9 g-atoms and 4.5 g-atoms of heavy metals per mole, respectively, and showed the spectral characteristic of cadmium-thionein, i.e., a broad shoulder at 250 nm and low residual absorption at 280 nm. The simple and specific replacement of cadmium and zinc bound to the protein with a cupric ion indicates that proteins have mercaptide bonding with a high affinity for copper. The molecular weight of the proteins modified with Ellman’s reagent was 5300 ± 250 when measured by gel filtration in the presence of 6 M guanidine hydrochloride.     

The Presence of Zinc-Binding Proteins in Brain

Abstract: Zinc is one of the most abundant divalent metal ions in the brain, its concentration being greater than those of copper and manganese. Since free zinc ion is a potent inhibitor of sulfhydryl enzymes, we postulated that zinc in the brain most probably exists bound to macromolecules. As zinc-binding proteins in brain have not been characterized, we attempted to discover the occurrence and properties of these proteins. By using Sephadex G-75 column chromatography calibrated with proteins of known molecular weights, and by other techniques, we detected separate zinc-binding proteins, with apparent estimated molecular weights ranging from 15,000 to 210,000. Unlike the hepatic or renal zinc thioneins, the zinc-binding proteins in brain are not inducible following administration of zinc. Our interpretation of the results is that the major portion of the existing zinc in the brain is bound, and does not exist in free form.     

Development and characterization of simulant pancreatic islets

Insulin is stored in pancreatic islets as a zinc-insulin complex, and stimulating the islets results in the release of insulin and zinc. Simulant pancreatic islet beads have been developed using agarose beads (50-250 micro m diameter) derivatized with iminodiacetic acid that have been loaded with zinc. A qualitative comparison of the simulant beads with pancreatic islets has been made by staining with dithizone and a zinc-binding fluorescent dye, TSQ. The binding capacity of simulant beads was determined to be 34 micro mol Zn(2+)/g of dried beads using anodic stripping voltammetry. Hydrochloric acid was used to release zinc from beads to mimic the secretion of insulin from pancreatic islets and a release profile was established. The simulant beads can be used to optimize the islet isolation process and reduce the use of real islets in method development.     

Characterization of the low mol. wt zinc-binding ligand from rat small intestine by comparison to the organic zinc-binding ligands

1. 65Zn complexes of picolinate (PA), citrate (CA), L-histidine (L-his), arachidonic acid (AA) or low mol. wt zinc-binding ligand from rat intestine (LMW-ZBL) gave 65Zn eluting peak fraction numbers of 53, 53, 56, 59 and 59 respectively, in a Sephadex G-75 column chromatography. 2. The 65Zn eluting peak fraction numbers with CA, L-his, PA, prostaglandin (PG)E2, AA, no ligand, arachidonate (AT) or LMW-ZBL were 49, 50, 54, 55, 58, 64, 75 and 76 respectively in a Sephadex G-25 column chromatography. 3. In a Sephadex G-15 column chromatography, the 65Zn eluting peak fraction numbers with CA, PGE2, AA, L-his, LMW-ZBL or PA were 49, 50, 51, 52, 52 and 55 respectively. 4. The LMW-ZBL in rat small intestine appears to be an AA-like substance.     

Plasma zinc concentrations in snakes and other vertebrates correlate with specific zinc-binding plasma proteins

We have demonstrated that snakes and some other reptiles normally possess high plasma zinc concentrations. These levels are similar to those measured in teleost fish. Plasma zinc levels in the range of snakes and teleosts have been shown to be toxic to crocodilians and mammals. Zinc has been shown to bind to a specific protein in albacore and winter flounder serum. Previous experiments suggested a similar protein in snake plasma. Western blot techniques were used to search for proteins capable of binding large quantities of zinc with high affinity in the plasma of a wide range of vertebrate species. These data were compared to plasma zinc concentrations measured by atomic absorption spectrophotometry. A correlation between high zinc levels and the presence of specific zinc-binding proteins different from mammalian albumin was observed. Snakes and teleost fish demonstrated both very high plasma zinc concentrations and a zinc-binding protein. Teleosts and snakes have significantly higher levels of plasma zinc than birds and mammals.     

Effect of zinc depletion/repletion on intestinal iron absorption and iron status in rats

Iron and zinc deficiencies likely coexist in general population. We have previously demonstrated that zinc treatment induces while zinc deficiency inhibits iron absorption in intestinal cell culture models, but this needs to be tested in vivo. In the present study we assessed intestinal iron absorption, iron status (haemoglobin), red blood cell number, plasma ferritin, transferrin receptor, hepcidin) and tissue iron levels in zinc depleted, replete and pair fed control rats. Zinc depletion led to reduction in body weight, tissue zinc levels, intestinal iron absorption, protein and mRNA expression of iron transporters, the divalent metal ion transporter-1, hephaestin and ferroportin, but elevated the intestinal and liver tissue iron levels compared with the pair fed control rats. Zinc repletion led to a significant weight gain compared to zinc deficient rats and normalized the iron absorption, iron transporter expression, tissue iron levels to that of pair fed control rats. Surprisingly, haemoglobin levels and red blood cell number reduced significantly in zinc repleted rats, which could be due to rapid weight gain. Together, these results indicate that whole body zinc status has profound influence on growth, intestinal absorption and systemic utilization of iron, mediated via modulation of iron transporter expression.     

In vitro studies on intestinal calcium and phosphate transport in horses

Transepithelial transport mechanisms play a key role in regulating the absorption and secretion of calcium (Ca^2 +) and inorganic phosphate (P_i) in the gastrointestinal tract. Although intestinal disorders with imbalances in macromineral homeostasis are frequently observed in horses, available data on intestinal Ca^2 + and P_i transport are limited. The aim of the present study was to characterize the intestinal Ca^2 + and P_i transport functionally by using the in vitro radioisotope tracer technique with Ussing chambers and to identify components involved in Ca^2 + transport at both mRNA and protein level. Among the different intestinal segments, the duodenum showed significant and highest active Ca^2 + absorption. The findings from RT-PCR and Western blot analysis suggest that the epithelial Ca^2 + channel TRPV6, the cytosolic calcium binding protein calbindin-D_9K and the plasma membrane calcium ATPase PMCA may be involved in active transcellular Ca^2 + transport. Regarding the P_i transport, the results indicate significant active P_i secretion in the jejunum, but the contributing mechanisms remain unclear. A significant inhibiting effect of ouabain as an antagonist of the basolateral Na⁺/K⁺-ATPase on the serosal-to-mucosal P_i transport suggests a pivotal role of Na⁺ in jejunal P_i transport in the horse.     

Bacterial zinc uptake and regulators

Many bacteria use an ABC transporter for high-affinity uptake of zinc with a cluster 9 solute-binding protein. Other members of this protein family transport manganese. At present, it is not always possible to distinguish zinc-specific and manganese-specific transporters on the basis of sequence analysis. Low-affinity ZIP-type zinc transporters in bacteria have also been identified. Most high-affinity zinc uptake systems are regulated by Zur proteins, which form at least three unrelated subgroups of the Fur protein family (regulators of iron transport). High-affinity transport of zinc out of the periplasmic space poses a problem to the cell because zinc is a cofactor of several periplasmic enzymes. Certain zinc-binding proteins in the periplasm might function as chaperones to supply these enzymes with zinc.