Avian hepatic T3 generation by 5'-monodeiodination: characterization of two enzymatic pathways and the effects of goitrogens

The enzymatic nature of 5'-monodeiodination (5'-D) in avian liver homogenates was demonstrated by abolishment of activity by iopanoic acid (IOP). T3 production from T4 was dependent on enzyme and substrate concentrations, incubation time, incubation temperature, and pH. Two pathways of 5'-D activity were present in avian liver and exhibited characteristics similar to those described in mammalian tissues. Type II activity was identified as propylthiouracil (PTU)-insensitive activity. Type I (PTU-sensitive) was determined by difference between Total and Type II. Km values were 1.58 microM T4 for Total activity and 0.90 nM T4 for Type II, corresponding to the characteristics of the mammalian pathways. The effects of goitrogens on avian hepatic 5'-D were equivalent to those reported for the mammalian enzyme.     

Unique and conserved aspects of gut development in zebrafish

Although the development of the digestive system of humans and vertebrate model organisms has been well characterized, relatively little is known about how the zebrafish digestive system forms. We define developmental milestones during organogenesis of the zebrafish digestive tract, liver, and pancreas and identify important differences in the way the digestive endoderm of zebrafish and amniotes is organized. Such differences account for the finding that the zebrafish digestive system is assembled from individual organ anlagen, whereas the digestive anlagen of amniotes arise from a primitive gut tube. Despite differences of organ morphogenesis, conserved molecular programs regulate pharynx, esophagus, liver, and pancreas development in teleosts and mammals. Specifically, we show that zebrafish faust/gata-5 is a functional ortholog of gata-4, a gene that is essential for the formation of the mammalian and avian foregut. Further, extraembryonic gata activity is required for this function in zebrafish as has been shown in other vertebrates. We also show that a loss-of-function mutation that perturbs sonic hedgehog causes defects in the development of the esophagus that parallel those associated with targeted disruption of this gene in mammals. Perturbation of sonic hedgehog also affects zebrafish liver and pancreas development, and these effects occur in a reciprocal fashion, as has been described during mammalian liver and ventral pancreas development. Together, these data define aspects of digestive system development necessary for the characterization of zebrafish mutants. Given the similarities of teleost and mammalian digestive physiology and anatomy, these findings have implications for developmental and evolutionary studies as well as research of human diseases, such as diabetes, liver cirrhosis, and cancer.     

A unique gene for 5-aminolevulinate synthase in chickens. Evidence for expression of an identical messenger RNA in hepatic and erythroid tissues

Reports to date have led to the conclusion that there are isozymes for 5-aminolevulinate synthase in the liver and erythroid tissue of chicken. Indeed, the existence of a multigene family for chicken 5-aminolevulinate synthase has been proposed. We find no evidence to support these proposals. In this work we show that 5-aminolevulinate synthase mRNA from chicken liver and reticulocytes is identical as determined by RNase mapping and primer extension studies and that the 5-aminolevulinate synthase protein from these tissues is the same size as judged by immunoblot analysis. We also show that a single mRNA species for 5-aminolevulinate synthase is present in chicken liver, reticulocytes, brain, and heart and an avian erythroblastosis virus-transformed chicken erythroblast cell line. Southern analysis shows the presence of only one gene copy for 5-aminolevulinate synthase in the chicken haploid genome. Overall, these results lead to the conclusion that in chickens 5-aminolevulinate synthase is encoded by a unique gene and is expressed as a single mRNA species in all tissues.     

Control enzyme levels in the plasma, brain and liver from wild birds and mammals in Britain

Brain from 47 avian and 17 mammalian species and the liver from 19 avian and 7 mammalian species has been examined for acetyl cholinesterase and nitrophenyl acetate esterase activities. Plasma from 27 avian and 7 mammalian species has been examined for acetyl cholinesterase, cholinesterase, nitrophenyl acetate esterase, glutamate, oxaloacetate transaminase, glutamate pyruvate transaminase, glutamate dehydrogenase, sorbitol dehydrogenase and lactate dehydrogenase activities. The studies have revealed that variations in enzyme activities occur between species but that there are discernible trends within families. The results indicate that comprehensive control enzyme data is necessary in order to assess the effects of exposure to agricultural chemicals in wildlife.     

Intercellular adhesive selectivity. III. Species selectivity of embryonic liver intercellular adhesion

A species difference in the intercellular adhesive selectivity of mixtures of embryonic liver cells is reported. This is first quantitative assessment of species differences in the intercellular adhesive properties of embryonic cells. A collecting aggregate assay, a new double-label assay procedure, and histological and autoradiographic procedures were used to elucidate the intercellular adhesive selectivity of developing mammalian and avian liver cells. Evidence is presented that the reported adhesive differences are not due to the different cell types composing the respective embryonic mammalian and avian livers. Finally, such heterolgous-homotypic selectivity of adhesion is not a property of all tissues, since it is shown that developing brain cells (mesencephalon) do not exhibit the avove intercellular adhesive selectivity (mammalian vs. avian). These findings provide further support for the hypothesis that generic identity as well as cell type may play an important part in determining the intercellular adhesive behavior of heterologous-homotypic mixtures of embryonic cells. A possible evolutionary divergence of morphogenetic mechanisms is discussed.     

Of birds and mice: hematopoietic stem cell development

For many years it has been assumed that the ontogeny of the mammalian hematopoietic system involves sequential transfers of hematopoietic stem cells (HSCs) generated in the yolk sac blood islands, to successive hematopoietic organs as these become active in the embryo (fetal liver, thymus, spleen and eventually bone marrow). Very little was known about early events related to hematopoiesis that could take place during the 4.5 day gap separating the appearance of the yolk sac blood islands and the stage of a fully active fetal liver. Experiments performed in birds documented that the yolk sac only produce erythro-myeloid precursors that become extinct after the emergence of a second wave of intra-embryonic HSCs from the region neighbouring the dorsal aorta. The experimental approaches undertaken over the last ten years in the murine model, which are reviewed here, led to the conclusion that the rules governing avian hematopoietic development basically apply to higher vertebrates.     

In vitro phosphorylation of chicken erythrocyte histone by various protein kinases : Absence of phosphorylation from F1 histone

In spite of the presence of nucleus, genetic activity and mitosis are totally depressed in avian erythrocytes. If phosphorylation of histone is involved in such genetic depression, a comparative study of phosphorylation of avian erythrocyte histone can be expected to furnish information about the mechanism of gene control. The present study is the examination of susceptibility of chicken erythrocyte histone to histologically different (liver and muscle) and phylogenically different (avian, mammalian and ichthic) protein kinases. It was found that chicken erythrocyte F1 histone was phosphorylated not only by heterologous (rat and trout liver) but also by homologous (chicken liver and muscle) protein kinases. Addition of cAMP could not elicit phosphorylation of this histone, while phosphorylation of other histones was significantly enhanced by this drug. Avian erythrocyte-specific histone, F2c, was markedly phosphorylated not only by avian enzymes but also by mammalian enzyme. All the enzymes tested phosphorylated F2b histone. F3 histone was phosphorylated at least by avian and mammalian enzymes. F2a1 and F2a2 histones were poor substrate to all the enzymes tested.     

Comparison of kinetic and regulatory properties of high S0.5 form of AMP deaminase from chicken and pigeon liver with AMP deaminase from rat and ox liver

1. The high S0.5 form of AMP deaminase from avian liver was shown to display a two times lower S0.5 value than the single mammalian enzyme form. 2. Avian enzymes showed several fold higher affinity to the activator (ATP) but lower affinity to inhibitors (GTP and Pi) than the mammalian AMP deaminases. 3. GTP was shown to exert a biphasic: activating and inhibitory effect on all the enzymes tested, the chicken and pigeon enzymes being activated within a much broader range of effector concentration. 4. In the presence of 3 mM ATP the activity of avian enzymes was not affected by high GTP and Pi concentrations, in contrast to AMP diaminase from rat liver which was strongly inhibited by GTP under the same experimental conditions. 5. The differences of the regulatory properties described are discussed in terms of adjustment of avian liver AMP deaminase to a faster adenylates' catabolism and thus urate synthesis.     

Efficient Hepatitis Delta Virus RNA Replication in Avian Cells Requires a Permissive Factor(s) from Mammalian Cells

Hepatitis delta virus (HDV) is a highly pathogenic human RNA virus whose genome is structurally related to those of plant viroids. Although its spread from cell to cell requires helper functions supplied by hepatitis B virus (HBV), intracellular HDV RNA replication can proceed in the absence of HBV proteins. As HDV encodes no RNA-dependent RNA polymerase, the identity of the (presumably cellular) enzyme responsible for this reaction remains unknown. Here we show that, in contrast to mammalian cells, avian cells do not support efficient HDV RNA replication and that this defect cannot be rescued by provision of HDV gene products in trans. Contrary to earlier assertions, this defect is not due to enhanced apoptosis triggered in avian cells by HDV. Fusion of avian cells to mammalian cells rescues HDV replication in avian nuclei, indicating that the nonpermissive phenotype of avian cells is not due to the presence of dominantly acting inhibitors of replication. Rather, avian cells lack one or more essential permissive factors present in mammalian cells. These results set the stage for the identification of such factors and also explain the failure of earlier efforts to transmit HDV infection to avian hosts harboring indigenous hepadnaviruses.     

Intracellular localization of the 3-hydroxy-3-methylglutaryl coenzme A cycle enzymes in liver. Separate cytoplasmic and mitochondrial 3-hydroxy-3-methylglutaryl coenzyme A generating systems for cholesterogenesis and ketogenesis.

Acetoacetyl-CoA thiolase and 3-hydroxy-3-methylglutaryl coenzyme synthase which comprise the 3-hydroxy-3-methylglutaryl-CoA-generating system(s) for hepatic cholesterogenesis and ketogenesis exhibit dual mitochondrial and cytoplasmic localization. Twenty to forty per cent of the thiolase and synthase of avian and rat liver are localized in the cytoplasmic compartment, the remainder residing in the mitochondria. In contrast, 3-hydroxy-3 methylglutaryl-CoA lyase, an enzyme unique to the "3-hydroxy-3-methylglutaryl-CoA cycle" of ketogenesis, appears to be localized in the mitochondrion. The small proportion, 4 to 8 percent, of this enzyme found in the cytoplasmic fraction appears to arise via leakage from the mitochondria during cell fractionation in that its properties, pI and stability, are identical to those of the mitochondrial lyase. These results are consistent with the view that ketogenesis which involves all three enzymes, acetoacetyl-CoA thiolase, 3-hydroxy-3-methylglutaryl-CoA synthase and 3-hydroxy-3-methylglutaryl-CoA lyase, occurs exclusively in the mitochondrion, whereas cholesterogenesis, a pathway which involves only the 3-hydroxy-3-methylglutaryl-CoA synthesizing enzymes, is restricted to the cytoplasm. Further fractionation of isolated mitochondria from chicken and rat liver showed that all three of the 3-hydroxy-3-methylglutaryl-CoA cycle enzymes are soluble and are localized within the matrix compartment of the mitochondrion. Likewise, cytoplasmic acetoacetyl-CoA thiolase and 3-hydroxy-3-methylglutaryl-CoA synthase are soluble cytosolic enzymes, no thiolase or synthase activity being detectable in the microsomal fraction. Chicken liver mitochondrial 3-hydroxy-3methylglutaryl-CoA synthase activity consists of a single enzymic species with a pI of 7.2, whereas the cytoplasmic activity is composed of at least two species with pI values of 4.8 and 6.7. Thus it is evident that the mitochondrial and cytoplasmic species are molecularly distinct as has been shown to be the case for the mitochondrial and cytoplasmic acetoacetyl-CoA thiolases from avian liver (Clinkenbeard, K. D., Sugiyama, T., Moss, J., Reed, W. D., and Lane, M. D. (1973) J. Biol. Chem. 248, 2275). Substantial mitochondrial 3-hydroxy-3-methylglutaryl-CoA lyase activity is present in all tissues surveyed, while only liver and kidney possess significant mitochondrial 3-hydroxy-3-methylglutaryl-CoA synthase activity. Therefore, it is proposed that tissues other than liver and kidney are unable to generate acetoacetate because they lack the mitochondrial synthase.     

Exoerythrocytic development of Plasmodium gallinaceum in the White Leghorn chicken

Plasmodium gallinaceum typically causes sub-clinical disease with low mortality in its primary host, the Indian jungle fowl Gallus sonnerati. Domestic chickens of European origin, however, are highly susceptible to this avian malaria parasite. Here we describe the development of P. gallinaceum in young White Leghorn chicks with emphasis on the primary exoerythrocytic phase of the infection. Using various regimens for infection, we found that P. gallinaceum induced a transient primary exoerythrocytic infection followed by a fulminant lethal erythrocytic phase. Prerequisite for the appearance of secondary exoerythrocytic stages was the development of a certain level of parasitaemia. Once established, secondary exoerythrocytic stages could be propagated from bird to bird for several generations without causing fatalities. Infected brains contained large secondary exoerythrocytic stages in capillary endothelia, while in the liver primary and secondary erythrocytic stages developed primarily in Kupffer cells and remained smaller. At later stages, livers exhibited focal hepatocyte necrosis, Kupffer cell hyperplasia, stellate cell proliferation, inflammatory cell infiltration and granuloma formation. Because P. gallinaceum selectively infected Kupffer cells in the liver and caused a histopathology strikingly similar to mammalian species, this avian Plasmodium species represents an evolutionarily closely related model for studies on the hepatic phase of mammalian malaria.     

Egg extracellular coat proteins: from fish to mammals

The extracellular coat surrounding fish (vitelline envelope; VE) and mammalian (zona pellucida; ZP) eggs is composed of long, interconnected filaments. Fish VE and mammalian ZP proteins that make up the filaments are highly conserved groups of proteins that are related to each other, as well as to their amphibian and avian egg counterparts. The rainbow trout (O. mykiss) egg VE is composed of 3 proteins, called VEalpha (approximately 58 kDa), VEbeta (approximately 54 kDa), and VEgamma (approximately 47 kDa). The mouse (M. musculus) egg ZP also is composed of 3 proteins, called ZP1 (approximately 200 kDa), ZP2 (approximately 120 kDa), and ZP3 (approximately 83 kDa). Overall, trout VE and mouse ZP proteins share approximately 25% sequence identity and have features in common; these include an N-terminal signal sequence, a ZP domain, a consensus furin cleavage-site, and a C-terminal tail. VEalpha, VEbeta, and ZP1 also have a trefoil or P-type domain upstream of the ZP domain. VEalpha and VEbeta are very similar in sequence (approximately 65% sequence identity) and are related to ZP1 and ZP2, whereas VEgamma is related to ZP3 (approximately 25% sequence identity). Mouse ZP proteins are synthesized and secreted exclusively by growing oocytes in the ovary. Trout VE proteins are synthesized by the liver under hormonal control and transported in the bloodstream to growing oocytes in the ovary. The trout VE is assembled from VEalpha/gamma and VEbeta/gamma heterodimers. The mouse ZP is assembled from ZP2/3 heterodimers and crosslinked by ZP1. Despite approximately 400 million years separating the appearance of trout and mice, and the change from external to internal fertilization and development, trout VE and mouse ZP proteins have many common structural features; as do avian and amphibian egg VE proteins. However, the site of synthesis of trout and mouse egg extracellular coat proteins has changed over time from the liver to the ovary, necessitating some changes in the C-terminal region of the polypeptides that regulates processing, secretion, and assembly of the proteins.     

A radioisotopic method for the determination of acetoacetyl Coenzyme A with 3-hydroxy-3-methylglutaryl Coenzyme A synthase

A simple and sensitive assay for the quantitative determination of acetoacetyl-CoA (AcAc-CoA) in liver and heart is described. The method is based on incorporation of [¹⁴C]acetyl-CoA into acid-stable nonvolatile material in the presence of avian HMG-CoA synthase. The specificity of this procedure for the measurement of AcAc-CoA was demonstrated by pretreating tissue extracts with 3-hydroxyacyl-CoA dehydrogenase or CoA transferase from Escherichia coli to deplete. AcAc-CoA prior to assay. Acid-stable nonvolatile ¹⁴C activity measured in the assay was proportional to the amount of tissue extract added. Satisfactory recovery of AcAc-CoA added at the initial extraction step further validated this procedure. This radioactive assay for acetoacetyl-CoA using a highly purified avian 3-hydroxy-3-methylglutaryl-CoA synthase has the advantages of both extreme specificity for AcAc-CoA as substrate and high sensitivity, facilitating the determination of this metabolite under a variety of physiological conditions.     

Mammalian mitochondrial nitric oxide synthase: characterization of a novel candidate

Recently a novel family of putative nitric oxide synthases, with AtNOS1, the plant member implicated in NO production, has been described. Here we present experimental evidence that a mammalian ortholog of AtNOS1 protein functions in the cellular context of mitochondria. The expression data suggest that a candidate for mammalian mitochondrial nitric oxide synthase contributes to multiple physiological processes during embryogenesis, which may include roles in liver haematopoesis and bone development.     

Inhibition of amylases from different origins by albumins from the wheat kernel.

The amylase activity of water extracts from 18 insect species, from 23 marine species and from 17 different species of birds and mammals was determined quantitatively. The inhibition of amylase in these extracts by three albumin fractions from the mature wheat kernel, which had been separated according to their molecular weights (60 000, 24 000 and 12 500 D), was determined as well. The inhibition activity of the three albumin fractions toward amylases extracted from a number of cereal species or from immature and germinating wheat kernel was also tested. The extracts from insects that are destructive of wheat grain and stored wheat products showed much higher amylase activities as compared to the other insect species that do not attack wheat and wheat products. On the basis of the effectiveness with which the three albumin fractions inhibit their activities, the amylase preparations tested were divided into susceptible, partially susceptible and resistent. Susceptible amylases, inhibited by any of the three albumin fractions, were found mainly in insects that attack wheat and in marine species. Partially susceptible amylases, inhibited by only one or two of the three albumin fractions, were present in a few avain and mammalian species including man. Resistent amylases were largely distributed in cereal, avian and mammalian species as well as in insect species that do not usually attack wheat grain or wheat flour products. At no stage of development, wheat alpha-amylase was inhibited by the albumin fractions from the mature kernel. The 12 500 dalton albumin fraction was the most effective in inhibiting insect amylases, but it was inactive toward avian and mammalian amylases. The 24 000 dalton albumin fraction was the most effective in inhibiting amylases from marine avian and mammalian species and inhibited as much as 33 amylases over 66 different amylases tested. It is suggested that protein inhibitors of amylase contributed to natural selection of polyploid wheats by giving some insect resistence to such wheats, even though some insect species were able to overcome this biochemical defense toa large degree by producing higher amylase activities.     

Cultivation of Cryptosporidium baileyi: studies with cell cultures, avian embryos, and pathogenicity of chicken embryo-passaged oocysts

Sporozoites of Cryptosporidium baileyi did not undergo development in primary cell cultures from either avian or mammalian hosts, or in mammalian cell lines. Oocysts of C. baileyi produced infections resulting in complete development to sporulated oocysts in chicken embryos and embryos of 8 other avian species examined. Inoculation of 4 X 10(5) oocysts was not pathogenic for avian embryos as evidenced by the lack of gross lesions or death. Oocysts obtained after C. baileyi had been passaged 10 times (first experiment) or 20 times (second experiment) in chicken embryos still caused clinical respiratory disease and gross airsacculitis when inoculated intratracheally into 2-day-old broiler chickens. Oocysts that had been passaged 10 times in chicken embryos were similarly pathogenic for 4-day-old turkeys after intratracheal inoculation.     

Avian alcohol dehydrogenase. Characterization of the quail enzyme, functional interpretations, and relationships to the different classes of mammalian alcohol dehydrogenase

The primary structure of the major quail liver alcohol dehydrogenase was determined. It is a long-chain, zinc-containing alcohol dehydrogenase of the type occurring also in mammals and hence allows judgement of the gene duplications giving rise to the classes of the human alcohol dehydrogenase system. The avian form is most closely related to the class I mammalian enzyme (72-75% residue identity), least related to class II (60% identity), and intermediately related to class III (64-65% identity). This pattern distinguishes the mammalian enzyme classes and separates classes I and II in particular. In addition to the generally larger similarities with class I, the avian enzyme exhibits certain residue patterns otherwise typical of the other classes, including an extra Trp residue, present in both class II and III but not in class I, with a corresponding increase in the UV absorbance. The avian enzyme further shows that a Gly residue at position 260 previously considered strictly conserved in alcohol dehydrogenases can be exchanged with Lys. However, zinc-binding residues, coenzyme-binding residues, and to a large extent substrate-binding residues are unchanged in the avian enzyme, suggesting its functional properties to be related to those of the class I mammalian alcohol dehydrogenases. In contrast, the areas of subunit interactions in the dimers differ substantially. These results show that (a) the vertebrate enzyme classes are of distant origin, (b) the submammalian enzyme exhibits partly mixed properties in relation to the classes, and (c) the three mammalian enzyme classes are not as equidistantly related as initially apparent but suggest origins from two sublevels.