Secretion of endogenous lectin by chicken intestinal goblet cells

The two lactose-binding lectins found in adult chicken intestine, chicken-lactose-lectin-1 (CLL-1) and chicken-lactose-lectin-11 (CLL- 11), were localized within the vesicles of the mucin-secreting goblet cells by indirect immunofluorescence and immunoperoxidase staining methods. Attention was concentrated on CLL-11 which is 200 time more abundant than CLL-1 in adult intestine. The localization of CLL-11 in secretory vesicles, combined with its demonstration on the intestinal epithelial surface by immune staining methods and by specific elution with lactose, suggested that at least a portion of the CLL-11 in the vesicles was secreted by the goblet cells and then became associated with the mucosal surface. In support of this, treatment of isolated intestinal strips with a cholinergic agent, bethanechol (10(-7 M) produced a small but significant increase in the amount of CLL-11 that could be eluted from their surface with lactose. Secretion of lectin may occur in conjunction with mucin because both are localized in the secretory vesicles and CLL-1 and CLL-11 apparently bind to purified chicken intestinal mucin, which is a potent inhibitor of their hemagglutination activities. The mucin is six orders of magnitude more potent than lactose as a hemagglutination inhibitor of CLL-1 or CLL-11 on a molar basis, and three orders of magnitude more potent when expressed per mole of hexose. These results suggest that CLL-11, and perhaps CLL-1, are secreted from the goblet cells along with mucin. They may function in the organization of mucin for secretion and/or in its association with the intestinal mucosal surface.     

Tyrosine phosphorylated proteins in different tissues during chick embryo development

A high affinity polyclonal antibody specific for phosphotyrosyl residues has been used in immunoblotting experiments to survey developing embryonic chicken tissues for the presence and characteristics of tyrosine phosphorylated proteins. Proteins phosphorylated on tyrosine were found to be present in all the embryonic tissues examined, including heart, thigh, gizzard, intestine, lung, liver, kidney, brain, and lens, from 7 to 21 d of development in ovo, but were greatly reduced or absent in the same tissues taken from adult chickens. A limited number of major tyrosine phosphorylated proteins were seen in all the tissues examined and they ranged in molecular mass from 35 to 220 kD. Most of the tissues contained proteins phosphorylated on tyrosine with apparent molecular masses of 120, 70, 60, and 35 kD, suggesting that the substrates of tyrosine protein kinases in different tissues may be related proteins. One-dimensional peptide mapping of the 120- and 70-kD protein bands indicated a close structural relationship among the phosphotyrosine-containing proteins of 120 kD, and similarly among those of 70 kD, from the different tissues.     

鸡胚凝集因子在发育过程中的活性变化

人们认为,细胞表面含碳水化合物的蛋白质可能在细胞相互作用中起着重要作用。从脊椎动物中分离出凝集因子以后(Teichberg et al., 1975;Nowak et al., 1977),许多研究表明这类凝集因子是与膜相结合的。这些发现支持了人们原先的设想。Beyer等人(1979;1980)从成体鸡肠中分离出一种结合乳糖的凝集因子,这种凝集因子似乎存在于粘液分泌小粒之中。1980年Pitts和Yang又从鸡胚肾脏中分离出一种结合乳糖的凝集因子,它可能是一种外周蛋白质。尽管他们的实验证明了成体鸡肾和肠这两种器官,同视网膜、肝脏、肌肉、心脏、脑和脊髓一样,存在着结合乳糖的凝集因子。但凝集因子在这两     

Localization of soluble endogenous lectins and their ligands at specific extracellular sites

Soluble lectins of chicken, rat, frog, and the cellular slime mold, Dictyostelium discoideum, were purified and specific antibodies raised against these proteins were used to immunohistochemically localize the lectins in and around the tissues in which they were synthesized. Within cells, some of these soluble lectins (chicken-lactose-lectin-II in intestinal goblet cells, discoidin II in prespore cells) appear to be concentrated within vesicles whereas others (e.g., rat beta-galactoside lectin in pulmonary alveolar and smooth muscle cells) appear to be free in the cytoplasm. All of these lectins are eventually secreted to extracellular sites in developing or adult tissues. The sites include mucin (chicken-lactose-lectin-II in intestine); developing extracellular matrix (chicken-lactose-lectin-I in muscle; Xenopus laevis lectin in blastula stage embryos); slime (discoidin I); developing spore coat (discoidin II); and a specialized extracellular matrix, elastic fibers (rat beta-galactoside lectin in lung). In cases where this has been studied in detail (discoidin I, discoidin II, and chicken-lactose-lectin-II), the lectin is associated with a complementary extracellular ligand, at least transiently. Lectin-ligand interactions presumably confer specialized properties in these particular extracellular domains.     

Chicken tissue binding sites for a purified chicken lectin

A lactose-binding lectin previously purified from embryonic chicken muscle and adult chicken liver, and here referred to as chicken-lactose-lectin-I (CLL-I), was added to sections of various adult chicken tissues to detect available binding sites. Both the sites of binding of added CLL-I as well as the tissue distribution of endogenous CLL-I were determined by indirect immunofluorescence using a rabbit antibody to CLL-I followed by fluorescent goat anti-rabbit IgG. Some tissues such as intestine and kidney showed abundant extracellular binding sites for the lectin, primarily between cells, in basement membrane, and in material on the luminal surface. In contrast, adult heart showed no significant binding sites for CLL-I. Adult pancreas showed considerable endogenous CLL-I in an extracellular site surrounding exocrine lobules, but added CLL-I did not bind substantially. The distribution of CLL-I binding sites in intestine were mimicked by those of purpurin, another lactose-binding lectin. CLL-I binding sites were also detected on the surface of cultured chick embryo skin fibroblasts. The factors controlling the specific distribution of occupied and unoccupied CLL-I binding sites are not known.     

Localization of an endogenous lectin in chicken liver, intestine, and pancreas

Extracts of adult chicken liver, pancreas, and intestine contain high levels of a lectin which appears to be identical to one previously purified from embryonic chick muscle. This lectin is virtually absent from adult muscle, but is highly concentrated in cells lining liver sinusoids, intestinal goblet cells, and the extracellular spaces surrounding pancreatic acini. These findings suggest that the lectin may play different roles in different tissues and at different times in the life of a chicken.     

Developmentally regulated lectins from chick muscle, brain, and liver have similar chemical and immunological properties

Developmentally regulated lectins in extracts from brain, liver and muscle of 16-day-old chick embryos and liver of 7-day-old chicks have been purified by affinity chromatography. The purified preparations from the different tissues were indistinguishable in molecular weight and isoelectric point. The lectins could also not be distinguished when tested as antigens with antiserum raised against highly purified muscle lectin. This apparent identity was indicated both in double gel diffusion tests and by determination of the antibody-mediated inhibition of hemagglutination activity of the various lectins. Thiodigalactoside and lactose were potent inhibitors of the lectins from all sources. Galactose was a less potent inhibitor, especially with preparations from embryonic liver. After isoelectric focusing of these purified preparations, they all showed reduced and equivalent galactose sensitivity. Since the lectins from the different tissues appear identical, there is presently no basis to infer that they impart qualitative uniqueness to these tissues during differentiation.     

Immunochemical analysis of myosin heavy chains in the developing chicken heart

Monoclonal antibodies (McAb) against myosin from the pectoralis muscle of the adult chicken have been generated and shown to react specifically with the myosin heavy chain (MHC). The reactivities of two such McAbs with myosin from adult chicken atrial and ventricular myocardium were further analysed by immunoautoradiography, radioimmunoassay, and immunofluorescence microscopy. Monoclonal antibody MF 20 was found to bind both atrial and ventricular MHC and stain all striated muscle cells of the adult chicken heart. In contrast, McAb B1 bound specifically to atrial myocytes in immunofluorescence studies, while immunoautoradiography and radioimmunoassay demonstrated the specificity of this antibody for the atrial MHC. Upon reacting these McAbs with myosin isolated from embryonic hearts where definitive atria and ventricles were present, the same specificity of antibody binding was observed. Immunofluorescence studies demonstrated that all striated muscle cells of the embryonic heart contained MHCs recognized by MF 20, while only atrial muscle cells were bound by B1. When extracts of presumptive atrial and ventricular tissue were reacted with MF 20 and B1, significant reactivity of MF 20 was first observed at stage 10 in the presumptive ventricle and thereafter this McAb reacted with all regions of the developing myocardium. Binding of B1 was detected approximately 1 day later at stage 15 and was confined to atrial-forming tissues. These data demonstrate antigenic similarity between adult and embryonic MHC isolated from atrial myocardium and suggest the expression of an atrial-specific MHC early in the regional differentiation of the heart.     

Endogenous lectins in chickens and slime molds: Transfer from intracellular to extracellular sites

Endogenous lectins in both cellular slime molds and chicken tissues have been localized primarily intracellularly, in contrast with the predominantly extracellular localization of the glycoproteins, glycolipids, and glycosaminoglycans with which they might interact. Here we present evidence that lectins in both of these organisms may be externalized and become associated with the cell surface and/or extracellular materials. In chicken intestine, chicken-lactose-lectin-II is shown to be localized in the secretory granules of the goblet cells, along with mucin, and to be secreted onto the intestinal surface. In embryonic muscle, chicken-lactose-lectin-I is shown to be externalized with differentiation, ultimately becoming localized on the surface of myotubes and in the extracellular spaces. In a cellular slime mold, Dictyostelium purpureum, externalization of lectin is elicited by either polyvalent glycoproteins that bind the small amount of endogenous cell surface lectin, or by slime mold or plant lectins that bind unoccupied complementary cell surface oligosaccharides. These results suggest that externalization of endogenous lectin may be a response to specific external signals. We conclude that lectins are frequently held in intracellular reserves awaiting release for specific external functions.     

Hamster uterine tissues accumulate corticosteroid-binding globulin during decidualization

Although corticosteroid-binding globulin (CBG) is known to be a serum steroid-binding protein, its function outside of the vascular space is not well understood. To prove an extravascular role for CBG, it must first be established that CBG occurs in steroid target tissues. We sought information on the occurrence of CBG in the cytosol, nuclear, and membrane fractions of 6 tissues during decidualization in the hamster. Our objectives were to determine if CBG is distributed in a tissue-specific manner, and to investigate the relationship between serum CBG and tissue CBG. Hamsters were given progesterone pellets s.c. on cycle Day 1 and decidualization was induced on Day 4. A 3H-cortisol-binding assay, which distinguished between CBG and glucocorticoid receptor, was used to determine CGB levels in the serum and in the cytosol, nuclear, and membrane fractions of deciduoma, myometrium, liver, kidney, muscle, and small intestine. Cytosol CBG accounted for greater than 97% of the total CBG detected in all tissues except liver, where nuclei contained 11% of the measurable CBG. For all cell fractions, CBG levels showed consistent tissue-specific differences. Cytosol CBG was highest in deciduoma and myometrium, 2-fold less in liver and kidney, and 5-fold less in muscle and small intestine. Nuclear CBG concentration was greatest in liver and approximately 10-fold less in other tissues, except for small intestine, where nuclear CBG was undetectable. Membrane CBG was highest in liver, 5-fold less in deciduoma, 10-fold less in myometrium, and about 20-fold less in other tissues. Serum CBG increased 7-fold from Day 4 to Day 9 in decidualized hamsters, but not in nondecidualized sham-operated hamsters. In all tissues, serum CBG was correlated with cytosol CBG. The high levels of CBG in uterine tissues were not the result of serum contamination because whole-body perfusion with buffered saline failed to remove the majority of cytosol CBG under conditions where over 70% of 51Cr-labeled red blood cells were removed. The identity of uterine cytosol CBG with serum CBG was established by ion-exchange chromatography (O-(diethylaminoethyl)-cellulose) and by immunoprecipitation with an antibody generated against serum CBG. These data demonstrate that uterine tissues accumulate substantial amounts of CBG during decidualization, thus raising the possibility of a functional role of CBG in uterine tissues during early pregnancy.     

Chicken lactose lectin: Cell-to-cell or cell-to-matrix adhesion molecule?

Summary Endogenous chicken muscle lectin isolated by lactose affinity chromatography inhibits myoblast fusion. Similar lectins isolated from embryonic brain, heart, and liver and from adult intestine exhibit the same ability. Elevated levels of any of these lectins canceled the inhibitory effect. Peanut agglutinin isolated by the same procedure had no effect at any concentration tested. Concanavalin A affected fusion only at high concentrations. Muscle lectin was shown to agglutinate myoblasts in microtiter plates, whereas exogenous addition in culture inhibited alignment as seen by time lapse microcinematography. Cell-to-cell communication between lectin-treated cells was shown by nucleotide exchange, and lectin-coated culture dishes did not affect cell attachment. Our evidence shows a lack of specificity to muscle, but suggests an aggregating capacity between cells, or possibly an interaction between the cell membrane and the extracellular matrix. This study was supported by National Institutes of Health grants AM 25202 and HD 07104, The Muscular Dystrophy Association, and the Cleveland chapter of Sigma Xi.     

Structure, evolution, and regulation of chicken apolipoprotein A-I

A full-length cDNA clone for the precursor form of chicken liver apolipoprotein A-I (apoA-I) was isolated by antibody screening of a chicken liver cDNA library in the expression vector lambda gt11. The complete nucleotide sequence and predicted amino acid sequence of this clone is presented. The identity of the clone was confirmed by comparison with partial amino acid sequences for chicken apolipoprotein A-I. Chicken preproapolipoprotein A-1 consists of an 18-amino acid prepeptide, a 6-amino acid propeptide, and 240 amino acids of mature protein. The sequence of the protein is homologous to mammalian apoA-I and is highly internally repetitive, consisting largely of 11-amino acid repeats predicted to have an amphipathic alpha-helical structure. The sequence of the propeptide (Arg-Ser-Phe-Trp-Gln-His) differs in two positions from that of mammalian apoA-I. The mRNA for chicken apoA-I is about 1 kilobase in length and is expressed in a variety of tissues including liver, intestine, brain, adrenals, kidneys, heart, and muscle. This quantitative tissue distribution has been determined and is similar to that observed for mammalian apoE and different from that of mammalian apoA-I mRNA. This reinforces the concept that avian apoA-I performs functions analogous to those of mammalian apoE. Moreover, comparisons revealed sequences of chicken apoA-I similar to the region of mammalian apoE responsible for interaction with cellular receptors. Previous studies have demonstrated striking changes in the rates of synthesis of apoA-I in breast muscle during development and in optic nerve after retinal ablation. We now demonstrate that these changes are paralleled by changes in mRNA levels. ApoA-I mRNA levels increase approximately 50-fold in breast muscle between 14 days postconception and hatching and then decrease about 15-fold to adult levels. The levels of apoA-I mRNA increase about 3-fold in optic nerve following retinal ablation. ApoA-I mRNA is also found in the brain in the absence of nerve injury. This may indicate that locally synthesized apoA-I has a routine or housekeeping function in lipid metabolism in the central nervous system.     

Pyruvate kinase isozymes in adult and fetal tissues of chicken.

Tissues of fetal and adult chickens were examined for pyruvate kinase activity. Two electrophoretically distinguishable and noninterconvertible isozymes were found. One of these, designated as type K (for kidney), is the sole pyruvate kinase in the early fetus and is found in appreciable quantities in all adult tissues except striated muscle. The second isozyme, type M, appears shortly before hatching in striated muscle and brain. These two isozymes correspond in their developmental pattern, tissue distribution, electrophoretic, immunological, and kinetic propertiesto similarly designated mammalian pyruvate kinases. However, no kinetic, immunological, or electrophoretic evidence could be found for a chicken isozyme corresponding to the mammalian type L pyruvate kinase. As the latter isozyme seems to be limited in its distribution mostly to highly differentiated gluconeogenic tissues (notable liver, kidney, and small intestine), our results support the proposition that the mammalian type L pyruvate kinase is a specilized isozyme that is present in mammals but not in birds.     

Structure and developmental expression of the chicken CDC2 kinase.

The cdc2 protein kinase plays a key role in controlling the eukaryotic cell cycle. We have isolated a cDNA clone for the chicken homolog of the cdc2 gene, raised antibodies against the corresponding protein, and studied the expression of cdc2 mRNA and protein during chicken embryonic development. The protein encoded by the chicken cdc2 cDNA shares extensive structural homology with cdc2 gene products from other species. Moreover, when expressed in fission yeast, the chicken cdc2 kinase is able to rescue a temperature-sensitive (ts) cdc2 mutant, demonstrating that it is functional as a cell cycle regulator. By Northern analysis and immunoblotting, we found that in total embryos both cdc2 mRNA and protein levels decreased substantially between day 3 and day 11 after egg laying, and no significant amounts of either cdc2 mRNA or protein were detected in adult liver, brain, heart or skeletal muscle. These data indicate the existence of a coarse correlation between the abundance of cdc2 mRNA and the proliferative state of a given tissue. Interestingly, however, when examining individual embryonic tissues, no correlation was observed between levels of cdc2 mRNA and protein, suggesting that cdc2 expression in developing chicken may be regulated at multiple levels.     

Detection of caldesmon in muscle and non-muscle tissues of the chicken using polyclonal antibodies

Polyclonal antibodies raised in rabbits against chicken gizzard caldesmon have been purified and used in immunoblotting experiments to study the distribution of this actin- and calmodulin-binding protein in diverse tissues of the chicken. Total homogenates and heat-treated homogenate supernatants derived from each tissue were subjected to sodium dodecyl sulfate-polyacrylamide gradient slab gel electrophoresis and immunoblotting using the horseradish peroxidase method. All chicken tissues examined contained caldesmon of Mr = 141,000. The amount of caldesmon found in the different tissues varied considerably and semi-quantitative comparison of stained immunoblots indicated the following relative caldesmon contents: gizzard greater than oesophagus greater than duodenum = small intestine greater than lung greater than aorta greater than heart = skeletal muscle greater than kidney = trachea greater than brain greater than liver. Each tissue revealed small amounts of lower Mr immunoreactive proteins, predominantly bands of Mr 94,000 and 70,000, which appear to be proteolytic fragments of caldesmon. Isolated caldesmon was found to be highly sensitive to proteolysis. The widespread distribution and similarity of caldesmon in different tissues of the chicken suggest its functional importance and structural conservation.     

Multiple forms of mutarotases from the kidney, liver, and small intestine of rats: purification, properties, subcellular localization and developmental changes

Comparative studies of mutarotase [aldose 1-epimerase, EC 5.1.3.3] from the kidney, liver and small intestine of rats were performed placing in the focus on the study of multiple forms. The findings obtained are as follows. Mutarotases from the kidney and liver of adult rats were both separated into four forms (types I-IV) by DEAE-cellulose column chromatography, whereas only two forms (types I and II) were detected in the small intestine. Liver mutarotase type I was further separated into types I1 and I2 by column chromatography on hydroxylapatite. Types I and II from the kidney and type II from the liver were purified to homogeneity as judged by isoelectric focusing on thin layer polyacrylamide gel. Of various physicochemical properties, only the Km for alpha-D-xylose and the isoelectric point were different among the multiple forms. Liver mutarotase was immunohistochemically localized in the nuclei of parenchymal cells and small intestine enzyme in the nuclei of mucosal cells, indicating similarity with the localization of kidney enzyme (in the nuclei of epithelial cells of renal tubules and glomeruli) which was reported in our previous paper [Experientia (1979) 35, 1094-1097]. The kidney mutarotase level increased gradually after birth and reached a maximum near adult level within 20 days. This developmental pattern was essentially the same as that in the liver but clearly different from that in the small intestine, in which the mutarotase activity of suckling rats was several times higher than that of adult rats. Distribution patterns of multiple forms (types I-IV) of the enzyme in the kidney and liver of 10-day-old rats were similar to those in respective tissues of adult rats. On the other hand, the small intestine of 10-day-old rats contained four forms (types I-IV), whereas there were only two forms (types I and II) in adult rats.     

Quantitation of mRNAs specific for the mixed-function oxidase system in rat liver and extrahepatic tissues during development

Evaluation of ontogenetic expression of the cytochrome P450PCN and cytochrome P450b gene families as well as the NADPH-cytochrome P450 oxidoreductase and epoxide hydrolase genes in Holtzmann rats showed that basal levels of mRNAs encoding these enzymes could be detected in most tissues. Distinct developmental patterns of mRNA expression are evident for these four proteins in liver and extrahepatic tissues. Levels of cytochrome P450b-like mRNA were comparable in adult lung and liver, while cytochrome P450PCN-homologous mRNA exhibited low levels in lung and approximately 100-fold higher levels in liver. Cytochrome P450PCN-homologous mRNA also reached substantial levels in adult intestine, and was also present in placenta, where it increased approximately 4-fold 24 h before birth. Epoxide hydrolase mRNA was demonstrated to be highest in liver followed by kidney, lung, and intestine but was extremely low in brain. NADPH-cytochrome P450 oxidoreductase mRNA in kidney, lung, prostate, adrenal, and intestine exhibited levels comparable to that found in liver; however, the pattern of expression for oxidoreductase mRNA was unique in that levels declined at maturity in liver, kidney, and intestine but not in lung and brain. Development of mixed-function oxidase and epoxide hydrolase activities in liver was distinct from that in other tissues in that mRNAs for all four proteins rose dramatically after parturition. Testis from immature males demonstrated low levels of all the mRNAs assayed, which ranged from 20% (oxidoreductase) to less than 1% (cytochrome P450PCN and epoxide hydrolase) of the levels found in liver.