The acrodermatitis enteropathica gene ZIP4 encodes a tissue-specific,zinc-regulated zinc transporter in mice

The human ZIP4 gene (SLC39A4) is a candidate for the genetic disorder of zinc metabolism acrodermatitis enteropathica. To understand its role in zinc homeostasis, we examined the function and expression of mouse ZIP4. This gene encodes a well conserved eight-transmembrane protein that can specifically increase the influx of zinc into transfected cells. Expression of this gene is robust in tissues involved in nutrient uptake, such as the intestines and embryonic visceral yolk sac, and is dynamically regulated by zinc. Dietary zinc deficiency causes a marked increase in the accumulation of ZIP4 mRNA in these tissues, whereas injection of zinc or increasing zinc content of the diet rapidly reduces its abundance. Zinc can also regulate the accumulation of ZIP4 protein at the apical surface of enterocytes and visceral endoderm cells. These results provide compelling evidence that ZIP4 is a zinc transporter that plays an important role in zinc homeostasis, a process that is defective in acrodermatitis enteropathica in humans.     

Stimulated release of exogenous GABA and glutamate from cerebral cortical synaptosomes and brain slices by bis (acetato) tetrakis (imidazole) copper(II) complex

Severe matermal zinc deficiency has a devastating effect on pregnancy outcome. Studies of humans and experimental animals show that matermal zinc deficiency can cause infertility, prolonged labor, intrauterine growth retardation, teratogenesis, severe immunological deficiencies, or fetal death. The additional need for zinc during pregnancy can be met by an increase in zinc intake. An increase in zinc supplements, when excessive, can cause a decrease in copper. Therefore, it is important to determine the zinc and copper concentrations in embryonic tissue in experimental models and their relationship with embryo number and viability. BALB/c mice were divided into groups according to zinc oral supplementation and gestational age. Phagocytosis was assesed in peritoneal macrophages from dams. The zinc and copper concentrations were obtained by inductively coupled plasma-optical emission spectrometry. Zn and Cu data concentrations in all the analyzed samples were above the detection limits. No spectral interferences were found in both elements (standard reference material was used). Zinc concentrations show a tendency to increase in embryos (14 gestational days and 21 gestational days) supplemented with zinc. Copper concentrations showed a noticeable tendency to diminish (36% and 27%, respectively) in the same period. In contrast, in placenta Zn values were increased by 30% and Cu values were decreased by 26%. We suggest a pivotal role of the placenta metabolism with its homeostatic mechanisms, in these findings. An important increment appeared in the +Zn embryo number (40%) relative to control (−Zn) embryos at 21 d gestational age. Embryo mortality was at 6% in +Zn embryos and at 20% in −Zn embryos. We consider these findings, both in the number and in the viability of +Zn embryos, outstanding.     

Review on the role of dietary zinc in poultry nutrition, immunity, and reproduction

Zinc is an important nutrient in animal metabolism. In poultry, zinc serves not only as a nutrient but can also be used as a dietary supplement to manipulate the reproductive system of the bird. This article summarizes the general biochemistry, physiology, and nutritional aspects of zinc metabolism to provide a brief overview on what is known regarding zinc. The potential role of zinc in poultry immune response, Salmonella infection, and molting are emphasized.     

Plasmodium falciparum regulatory subunit of cAMP-dependent PKA and anion channel conductance

Malaria symptoms occur during Plasmodium falciparum development into red blood cells. During this process, the parasites make substantial modifications to the host cell in order to facilitate nutrient uptake and aid in parasite metabolism. One significant alteration that is required for parasite development is the establishment of an anion channel, as part of the establishment of New Permeation Pathways (NPPs) in the red blood cell plasma membrane, and we have shown previously that one channel can be activated in uninfected cells by exogenous protein kinase A. Here, we present evidence that in P. falciparum-infected red blood cells, a cAMP pathway modulates anion conductance of the erythrocyte membrane. In patch-clamp experiments on infected erythrocytes, addition of recombinant PfPKA-R to the pipette in vitro, or overexpression of PfPKA-R in transgenic parasites lead to down-regulation of anion conductance. Moreover, this overexpressing PfPKA-R strain has a growth defect that can be restored by increasing the levels of intracellular cAMP. Our data demonstrate that the anion channel is indeed regulated by a cAMP-dependent pathway in P. falciparum-infected red blood cells. The discovery of a parasite regulatory pathway responsible for modulating anion channel activity in the membranes of P. falciparum-infected red blood cells represents an important insight into how parasites modify host cell permeation pathways. These findings may also provide an avenue for the development of new intervention strategies targeting this important anion channel and its regulation.     

Many genomic regions are required for normal embryonic programmed cell death in Caenorhabditis elegans

To identify genes involved in programmed cell death (PCD) in Caenorhabditis elegans, we screened a comprehensive set of chromosomal deficiencies for alterations in the pattern of PCD throughout embryonic development. From a set of 58 deficiencies, which collectively remove approximately 74% of the genome, four distinct classes were identified. In class I (20 deficiencies), no significant deviation from wild type in the temporal pattern of cell corpses was observed, indicating that much of the genome does not contain zygotic genes that perform conspicuous roles in embryonic PCD. The class II deficiencies (16 deficiencies defining at least 11 distinct genomic regions) led to no or fewer-than-normal cell corpses. Some of these cause premature cell division arrest, probably explaining the diminution in cell corpse number; however, others have little effect on cell proliferation, indicating that the reduced cell corpse number is not a direct result of premature embryonic arrest. In class III (18 deficiencies defining at least 16 unique regions), an excess of cell corpses was observed. The developmental stage at which the extra corpses were observed varied among the class III deficiencies, suggesting the existence of genes that perform temporal-specific functions in PCD. The four deficiencies in class IV (defining at least three unique regions), showed unusually large corpses that were, in some cases, attributable to extremely premature arrest in cell division without a concomitant block in PCD. Deficiencies in this last class suggest that the cell death program does not require normal embryonic cell proliferation to be activated and suggest that while some genes required for cell division might also be required for cell death, others are not. Most of the regions identified by these deficiencies do not contain previously identified zygotic cell death genes. There are, therefore, a substantial number of as yet unidentified genes required for normal PCD in C. elegans.     

Poly(ADP-ribose) metabolism is essential for proper nucleoprotein exchange during mouse spermiogenesis

Sperm chromatin is organized in a protamine-based, highly condensed form, which protects the paternal chromosome complement in transit, facilitates fertilization, and supports correct gene expression in the early embryo. Very few histones remain selectively associated with genes and defined regulatory sequences essential to embryonic development, while most of the genome becomes bound to protamine during spermiogenesis. Chromatin remodeling processes resulting in the dramatically different nuclear structure of sperm are poorly understood. This study shows that perturbation of poly(ADP-ribose) (PAR) metabolism, which is mediated by PAR polymerases and PAR glycohydrolase in response to naturally occurring endogenous DNA strand breaks during spermatogenesis, results in the abnormal retention of core histones and histone linker HIST1H1T (H1t) and H1-like linker protein HILS1 in mature sperm. Moreover, genetic or pharmacological alteration of PAR metabolism caused poor sperm chromatin quality and an abnormal nuclear structure in mice, thus reducing male fertility.     

Improving iron, zinc and vitamin A nutrition through plant biotechnology

Recent understanding of plant metabolism has made it possible to increase the iron, zinc and beta-carotene (provitamin A) content in staple foods by both conventional plant breeding and genetic engineering. Improving the micronutrient composition of plant foods may become a sustainable strategy to combat deficiencies in human populations, replacing or complementing other strategies such as food fortification or nutrient supplementation.     

Use of laboratory animals to define physiological functions and bioavailability of zinc

For the past 50 years laboratory animals have been used to ascertain the metabolic bases for signs of zinc deficiency such as sharply reduced food intake, severe dermatitis, slow wound healing, delayed sexual development and function, reduced immunocompetence, severe teratogenic abnormalities, and abnormal metabolism of carbohydrate, lipid, and protein. Current evidence indicates that many of these symptoms may be consequences of inhibition of early steps in nucleic acid metabolism that lead to problems with cellular replication and growth and also that zinc plays an important role in membrane structure and function. Bioavailability of zinc to experimental animals was early shown to be reduced by plant protein diets and to be further reduced by feeding excess calcium. Current evidence indicates phytic acid in plant proteins to be a major inhibitor of zinc absorption, although food-processing methods can either increase or decrease zinc bioavailability. The inhibitory effect of phytic acid is very dependent on dietary calcium in association with phytate and zinc. Usual calcium intakes by humans are much below those demonstrated in animals to cause phytate inhibition of dietary zinc availability.     

Zinc and human development: A review

In the last few years, considerable evidence has been obtained regarding the importance of zinc in human nutrition. Zinc is an important component of many metalloenzymes and is also required for metabolism of nucleic acids and synthesis of protein. Human requirements for zinc vary at different times in development, but appear to be particularly high during embryonic life, during periods of rapid growth, and during pregnancy. Although zinc is widely distributed in foods, a number of types of diets appear to be deficient or marginal in terms of available zinc. In addition, there is physiological loss of zinc in bleeding and sweating which may lead to low levels of body zinc. A syndrome characterized by markedly retarded growth and sexual development that occurs in the Middle East has been shown to be due to zinc deficiency. This syndrome is reviewed. It is thought that the zinc deficiency syndrome is only one end of a continuum of growth-related problems associated with low levels of physiologically available zinc. In rats, zinc deficiency during pregnancy has been shown to lead to congenital malformations in a large percentage of the offspring. A number of these malformations involve the central nervous system. We have suggested that epidemiological data support the possible importance of maternal zinc deficiency as an etiological factor in human CNS malformations. These data are discussed.This work was supported in part by NIH grants GM15253 and HD02274.Presented at a symposium Trends in Nutrition, sponsored by the California Dietetic Association, Los Altos, California, February 2, 1974.     

Zinc and diabetes mellitus: is there a need of zinc supplementation in diabetes mellitus patients?

Diabetes mellitus is a group of metabolic disorders, the incidence of which varies widely throughout the world. The treatment of diabetes mellitus includes insulin, oral antidiabetic agents, and dietary regimens. Although the emphasis is on macronutrients intakes, there is strong evidence that there is an abnormal metabolism of several micronutrients in diabetic individuals. Zinc is one of the essential micronutrients of which status and metabolism is altered in this condition. This work is a short review about the close relation among zinc, glucose metabolism, and insulin physiology, as well as about the few experimental data about zinc absorption and zinc supplementation in diabetes mellitus patients.     

Interrelationships between zinc and immune function

Zinc deficiency is a common nutritional problem observed both in human and in animal populations that has profound effects on host defense mechanisms. Using the young adult mouse as a model, it has been demonstrated that a moderate period of suboptimal zinc causes thymic atrophy, lymphopenia, and alterations in the proportions of the various subsets of lymphocytes and mononuclear phagocytes. As a result, antibody-mediated responses to both T cell-dependent and T cell independent antigens are significantly reduced. Cytolytic T cell responses, natural killer (NK) cell activity, and delayed-type hypersensitivity (DTH) reactions are also depressed. Suboptimal zinc during in utero development of mice causes persistent states of immunodeficiency in the offspring that can even be transferred to subsequent generations. In regard to human immunological consequences of zinc deficiency, patients with the genetic disorder of zinc absorption, acrodermatitis enteropathica, also exhibit atrophic thymuses, lymphopenia, anergic DTH responses, and reduced NK cell activity. Patients suffering from sickle cell anemia or uremia with associated deficiencies in zinc exhibit similar immune deficiencies. An additional outcome of these studies has been shown to be an essential cofactor for thymulin, one of the thymic hormones. Furthermore, addition of zinc salts to culture can polyclonally activate lymphocytes as well as augment responses to mitogens in adjuvant-like manner.     

Expressional changes of ganglioside GM3 during ovarian maturation and early embryonic development in db/db mice

Diabetes and obesity cause abnormal development of reproductive processes in a variety of species, but the mechanisms that underlie this effect have not been fully elucidated. This study examined the expressional changes of ganglioside GM3 during ovarian maturation, in vitro fertilization (IVF) and early embryonic development in diabetic/obese db/db mice. In high-performance thin-layer chromatography studies, GM3 expression was conspicuously low in the ovaries of db/db mice compared to non-diabetic db/+ mice. Signal detected by anti-GM3 monoclonal antibody was greatly reduced in the primary, secondary and graffian follicles of db/db mice compared to control mice. Results from IVF with ova and sperm from db/db mice showed that GM3 expression during early embryonic development was obviously decreased compared to db/+ mice. This study also elucidated the effects of high glucose (20 and 30 mm) on early embryonic development in ICR strain mice. High glucose caused a decrease in GM3 expression during early embryonic development. Taken together, the results of this study indicate decreased GM3 expression during ovarian maturation and embryonic development of db/db mice, suggesting that alteration of ganglioside expression induced by the diabetic condition may be implicated in the abnormal follicular embryonic development.     

Mineral and vitamin deficiencies can accelerate the mitochondrial decay of aging

Mitochondrial oxidative decay, which is a major contributor to aging, is accelerated by many common micronutrient deficiencies. One major mechanism is inhibition of the pathway of heme biosynthesis in mitochondria, which causes a deficit of heme-a. Heme-a, only found in Complex IV, is selectively diminished, resulting in oxidant leakage and accelerated mitochondrial decay, which leads to DNA damage, neural decay, and aging. We emphasize those deficiencies, which appear to cause damage through this mechanism, particularly minerals such as iron (25% of menstruating women ingest <50% of the RDA) or zinc (10% of the population ingest <50% of the RDA). Several vitamin deficiencies, such as biotin or pantothenic acid, also increase mitochondrial oxidants through this mechanism. Additionally, other minerals such as magnesium and manganese that play a role in mitochondrial metabolism, but do not affect heme directly, are discussed. An optimum intake of micronutrients could tune up metabolism and give a marked increase in health, particularly for the poor, elderly, and obese, at little cost.     

The transmembrane protein TMEM16A is required for normal development of the murine trachea

Pathological collapsibility of the upper airways, caused by many different genetic and environmental insults, is known as tracheomalacia in humans. We determined that Tmem16a, a member of an evolutionarily conserved family of predicted transmembrane proteins, is expressed in the developing trachea. We report that all mice homozygous for a null allele of Tmem16a died within one month of birth and exhibited severe tracheomalacia with gaps in the tracheal cartilage rings along the entire length of the trachea. In addition, the development of the trachealis muscle that spans the dorsal aspect of the trachea was abnormal in Tmem16a mutants. Since the chondrogenic mesenchyme does not express Tmem16a at any time, we propose that the cartilage ring defect observed in Tmem16a mutants is secondary to an expansion of the embryonic trachea that might result from improper stratification of the embryonic tracheal epithelium or the abnormal trachealis muscle. Our data identify Tmem16a as a novel regulator of epithelial and smooth muscle cell organization in murine development. This mutant, the first knockout of a vertebrate TMEM16 family member, provides a mouse model of tracheomalacia.     

Tumor-host zinc metabolism the central role of metallothionein

Features of tumor and host zinc metabolism are described. Emphasis is placed on tumor-host interactions. Using the model of the Ehrlich ascites tumor in mice, one clear site of modulation of cellular zinc by the amount of nutrient zinc available in the host is a zinc-binding protein with the properties of metallothionein. The selective depletion of zinc from this protein is correlated with the loss of cell proliferation by tumors injected into zinc-deficient animals. The properties of isolated metallothionein are consistent with a role for it as a reactive pool of intracellular zinc which can be donated to apozinc proteins and other structures. The presence of the Ehrlich tumor in mice also perturbs their distribution of zinc: zinc leaves the plasma and is accumulated by liver in the form of newly synthesized zinc metallothionein. During host zinc deficiency, this redistribution is not observed. This may be caused not only by a lack of mobile plasma zinc, but also by an inhibition of the initiation of this host response at the site of the tumor in the peritoneum.     

Minor anomalies: Diagnostic clues to aberrant human morphogenesis

Assessment of the degree of fluctuating asymmetry has been used in a variety of organisms as a measure of genetic and/or environmental stresses encountered during embryonic development. However, fluctuating asymmetry has not been widely used in humans in the diagnosis of congenital anomalies. Rather, assessment of patterns of minor anomalies has been utilized to infer the degree of embryonic developmental instability accompanying either genetic or teratogenic insults. A minor anomaly is a structural feature seen in less than 4% of the general population, which is of no cosmetic or functional significance to the affected individual. Minor anomalies may or may not have functional or diagnostic significance when taken in the context of the entire child. In dysmorphology, minor anomalies have been useful in three distinct ways. First, some minor anomalies have been external markers of specific occult major anomalies. In addition, the vast majority of malformation syndromes in clinical genetics are recognizable as patterns of minor anomalies. Finally, although 15% of normal newborns have one or more minor anomalies, the finding of three or more minor anomalies is distinctly unusual. The risk of having a major occult abnormality increases proportionately with the number of minor defects present, with three or more minor anomalies signalling a 20% risk of a major occult structural defect. In summary, just as fluctuating asymmetry may be a marker of abnormal environmental or genetic stress in the developing embryo, the presence of minor anomalies can be utilized to assess developmental instability.