Differentiation of neuroblastoma cells by chick gizzard extract

Cholinergic neuroblastoma NS20Y cells were differentiated by the chicken gizzard extract. They were first inoculated into a glass culture bottle and the aggregated cells which grew in the suspension culture were collected. The aggregated cells (round and immature neuroblastoma cells) were seeded on a polyornithinecoated plastic dish, and the effect of various agents on the differentiation of the neuroblastoma was investigated. When gizzard extract from chicken was added to the culture, many flat cells with neurites emerged around the cell aggregates within 24 h. The flat cells could evoke action potentials with high frequency (in 70% cells). Cyclic GMP levels in the treated cultures were much lower than that in the control culture, and remained continuously lower during 2 days culture. The factor responsible for the differentiation of neuroblastoma cells was rich in the chick gizzard among extracts or conditioned media from various tissues tested. A similar effect was observed by the addition of dibutyryl cyclic AMP or prostaglandin E₁ plus theophylline over a slower time course. The factor in gizzard extract was trypsin-sensitive and heat-labile. The molecular size was estimated to be about 12 s.     

Histological and immunohistochemical study on ontogeny of the endocrine cells in the quail gizzard

The pre- and post-hatching development and differentiation of the endocrine cells in quail gizzard were examined histologically and immunohistochemically. A total of 158 heads (from 5th d of incubation to adult) were used in this study. The formation of gizzard tubular glands began from 11th d of incubation. 8 kinds of endocrine cells, argyrophil cells, and gastrin releasing polypeptide (GRP)-, 5-hydroxytryptamine (5-HT)-, somatostatin-, glucagon-, avian pancreatic polypeptide (APP)-, neurotensin-, and gastrin-immunoreactive cells were detected in the gizzard. These endocrine cells began to appear from 10th d of incubation. Argyrophil cells and GRP-immunoreactive cells in the gizzard were increased with age. Other kinds of immunoreactive cells were found rarely and irregularly, and some of them were found transitory in the embryonic stage.     

Differentiation of smooth muscle cells in chicken gizzard

During development of the chicken gizzard, a thick layer of undifferentiated cells (mesenchymal cells) is constructed, and the cells differentiate into smooth muscle cells or connective tissues. We found that the differentiation of smooth muscle cells occurred first near the outer surface of the gizzard and the differentiated area spread to the inside of the gizzard. Therefore, we assumed that the differentiation of most of the smooth muscle cells in the gizzard is induced by differentiated smooth muscle itself. When undifferentiated cells from gizzard of 7-day-old embryo (Hamburger and Hamilton's stages 26-27) were cultured on a coverglass coated with extract of gizzard that contained differentiated smooth muscle cells, the cells attached to the coverglass and differentiated into smooth muscle cells. On the other hand, extract of gizzard from 7-day-old embryo did not induce the differentiation of smooth muscle cells, though it induced the attachment of cells. We found that activity for the differentiation of smooth muscle cells appeared when differentiated smooth muscle cells appeared in developing gizzard. Gizzard contained higher activity for the differentiation of smooth muscle cells than the other tissues. Transforming growth factor-beta (TGF-beta), which induces the differentiation of vascular smooth muscle cells, did not induce the differentiation of smooth muscle cells in gizzard, though extract of aorta induced the differentiation of smooth muscle cells in gizzard. The results obtained here support evidence that the differentiation of most of the smooth muscle cells in gizzard is induced by a self-catalytic mechanism in which differentiated smooth muscle itself induces the differentiation of smooth muscle cells.     

Analysis of mesenchymal influence on the pepsinogen gene expression in the epithelium of chicken embryonic digestive tract

We performed tissue recombination experiments to discover the mesenchymal influences on differentiation of epithelia in chicken digestive organs. Epithelia and mesenchymes were taken from the lung, esophagus, proventriculus, gizzard, small intestine and large intestine of 6-day chicken embryos and recombined in various associations and cultivated in vitro for 6 days. Rather unexpectedly, embryonic chicken pepsinogen (ECPg) gene, a marker of the proventricular epithelium, was induced in the gizzard epithelium, which does not express ECPg in normal development, by the proventricular and lung mesenchymes. In the second half of this study, we investigated the mode of action of mesenchymal cells on ECPg expression in gizzard epithelial cells more precisely using the cell aggregate culture system, in which gizzard epithelial cells were mixed with proventricular, gizzard or lung mesenchymal cells. We found that supporting action of lung mesenchymal cells on ECPg expression was even stronger than that of proventricular mesenchymal cells, and suggest that the action of lung mesenchyme may be due partly to the enhancement of epithelial cell proliferation. According to the results of this study, together with many facts obtained so far, we will discuss a new model for restricted expression of ECPg in the proventricular epithelium in normal development.     

An abundant chick gizzard integrin is the avian α1β1 integrin heterodimer and functions as a divalent cation-dependent collagen IV receptor

The α-subunit of an abundant chick gizzard integrin was isolated ([12.], J. Biol. Chem. 262, 17,189–17,199) and fragmented by proteolytic digestion. The N-terminal sequences of the intact polypeptide and of several internal peptides were determined and were found to be highly homologous to the mammalian integrin α₁-subunit. Monoclonal antibodies to the chick integrin β₁-chain react on immunoblots with the gizzard integrin β-subunit ([28.], J. Biol. Chem. 265, 14,561–14,565). The chain composition of the abundant chick gizzard integrin is therefore α₁β₁. Polyclonal antibodies to the avian integrin α₁-subunit block attachment of embryonic gizzard cells to human and chick collagen IV completely and inhibit attachment to mouse Engelbreth-Holm-Swarm (EHS) tumor laminin partially. In ELISA-style receptor assays, the isolated α₁β₁ integrin bound to human and chick collagen IV and to mouse EHS tumor and chick heart laminin. While the binding to collagen IV was abolished by removal of divalent cations, the binding to laminin was not sensitive to EDTA under the conditions used. Collagen I bound the isolated avian α₁β₁ integrin only weakly. As collagen IV was the only extracellular matrix protein for which a consistent, divalent cation-dependent, binding to the avian α₁β₁ integrin could be demonstrated in both cellular and molecular assays we suggest that it is a preferred ligand for this integrin.     

Extent and method of grinding of sorghum prior to inclusion in complete pelleted broiler chicken diets affects broiler gut development and performance

A broiler experiment was conducted to examine the effects of sorghum particle size and milling type on the performance, nitrogen corrected apparent metabolisable energy (AME_n), digestive tract development, digesta pH, duodenal digesta particle size and digesta passage rate. Complete pelleted diets with identical botanical and chemical composition containing 750 g/kg whole sorghum (WS), sorghum ground through hammer mill with 1 mm and 3 mm screen (HM1 and HM3) and sorghum ground on a roller mill with 0.15 mm spacing (RM0.15), were made. Sorghum for diets HM3 and RM0.15 were milled to approximately the same mean particle size. Diet WS resulted in poorer (P<0.05) weight gain and feed conversion ratio (FCR) than the other diets from 11 to 21 days of age, while diet RM0.15 resulted in improved FCR. Apparent ME_n determined between 25 and 28 days of age, however, was higher (P<0.05) for diet WS than for the other diets. This was possibly due to a longer adaptation time to a larger feed particle size, as indicated by a lower (P<0.05) pH in the gizzard and smaller duodenal digesta particle size for this diet. Diet HM1 gave similar performance as diet HM3, but resulted in a significantly smaller gizzard, a higher pH of the gizzard content, a lower pH of the duodenal content and larger particles in the duodenal contents, thus indicating that gizzard development and activity were compromised by this diet. Total tract passage rate of the liquid phase marker was slower (P<0.05) in the WS fed birds, but there were no differences in solid phase marker excretion rates.     

Identification of interstitial cells of Cajal in the digestive tract of turkeys (Meleagris gallopavo)

Interstitial cells of Cajal (ICCs) were identified in the digestive tract of turkeys by electron microscopy. ICCs have been implicated as sources of pacemaking slow wave potentials that initiate peristalsis in the stomach and intestines in mammals. The gastroduodenal contraction cycle in turkeys, however, is uniquely coordinated by a neurogenic pacemaker in the isthmus area between the glandular stomach and the gizzard, and this controls the coordinated phasic contractions of the muscles of the gizzard, duodenum and glandular stomach. Thus, it becomes important to look for the presence and distribution of ICCs in the avian digestive tract, especially in the gizzard and duodenum. This investigation has identified that cells are present which contain the typical characteristics of ICCs including: numerous mitochondria, caveolae, thin processes, basement membrane, filaments, rough ER, Golgi, and occasional gap junctions. They were mostly located in the region of the myenteric plexus between the longitudinal and circular muscle layers and occasionally within the longitudinal muscle layer. They were frequently near nerve axon bundles and were usually surrounded by collagen, elastin fibers, and occasional fibroblasts or blood vessels. ICCs were easily found in the ileum, but were also present in the duodenum, cecum, and rectum. None were found in the serosal region of the thick muscle of the gizzard. The presence of ICCs in the turkey duodenum, which like the gizzard is under neurogenic control, suggests that ICCs may play a role(s) in addition to initiating peristalsis.     

A 130K protein from chicken gizzard: Its localization at the termini of microfilament bundles in cultured chicken cells

A protein with a molecular weight of 130,000 (130K protein) was extracted from chicken gizzard and purified to homogeneity by ammonium sulfate fractionation and ion-exchange chromatography. Antibodies prepared against the pure protein were used for its immunochemical characterization and immunofluorescent visualization in cultured chicken cells. Both peptide mapping and immunochemical analysis indicated that the 130K protein is not related either structurally or antigenically to other mechanochemical proteins, including α-actinin, actin, myosin, tropomyosin, filamin and tubulin. Immunofluorescent labeling of different cultured embryonic chicken cells (from skin, heart and gizzard) indicated that the label was predominantly organized in intracellular plaques at the bottom of the cells and in some areas of cell-cell contact. Immunoprecipitation of the 130K protein from biosynthetically ³⁵S-methionine-labeled cultured cells, using the pure antibodies and Staphylococcus aureus, resulted in the specific isolation of a single labeled electrophoretic band indistinguishable from the chicken gizzard 130K protein. The 130K protein-rich plaques were found, by interference-reflection microscopy, to coincide with cell substrate adhesion plaques. Double immunofluorescent labeling for the 130K protein and other cytoskeletal proteins (actin, α-actinin and tropomyosin) indicated that the 130K protein-rich areas are localized at the termini of stress fibers. α-Actinin was found in close association with the 130K protein, while tropomyosin was usually excluded from those areas.     

Enhancement of Neurite Outgrowth and Aspartate-Glutamate Uptake Systems in Retinal Explants Cultured with Chick Gizzard Extract

Chicken gizzard extract promoted a long and radially directed neurite outgrowth from retinal explants of 8-day-old chick embryo in cultures of 2–3 days. The neurite outgrowth from retinal explants cultured in the absence of gizzard extract was short and restricted to the explant perimeter. The neurite outgrowth promoted by gizzard extract depended strictly on several factors. (a) Fetal calf serum and polycationic substratum were required in this culture system, (b) Pretreatment of the polyornithine-coated substratum with gizzard extract allowed the retinal explants to extend neurites even in the absence of gizzard extract in the medium. (c) Maximal neurite outgrowth was observed in retinal explants dissected from 8-day embryos, but thereafter the explants’response to gizzard extract rapidly declined and was almost lost at the 12th day. As a biochemical parameter of differentiation of cultured neuroretina, uptake systems for neurotransmitter candidates were examined in homogenates of retinal explants cultured in the absence or presence of gizzard extract. After 3 days in culture with gizzard extract, the uptake increased for aspartate and glutamate 1.6- to 1.8-fold and for γ-aminobutyric acid to a lesser degree when examined at a concentration for high-affinity uptake (10^-6M). In contrast, the uptake capacity for glycine, choline, and dopamine was not altered in explants cultured with or without gizzard extract. Kinetic analysis showed that the enhanced capacity to accumulate aspartate was not due to an alteration of K^m, but to an increase of V^max. The results suggest that one or several factors in chick gizzard muscle promote not only neurite outgrowth but also the aspartate-glutamate uptake systems in the developing neuroretina, probably related to ganglion cells.     

Intestinal mesenchyme provokes differentiation of intestinal endocrine cells in gizzard endoderm

The gizzard (muscular stomach) of chicks is deficient in endocrine cells at hatching. It has previously been shown that proventricular types and proportions of endocrine cells can be induced in gizzard endoderm under the influence of proventricular (glandular stomach) mesenchyme. In order to test its capacity to form nongastric endocrine cell types, gizzard endoderm of 3.75- to 5-day chick embryos was combined with mesenchyme from the small intestine of 3.5- to 4-day quail embryos. The combinations were grown as chorio-allantoic grafts until they attained an incubation age comparable to that of hatching chicks. Controls comprised reassociated endoderm and mesenchyme of chick gizzard and of quail intestine. In the experimental grafts, morphogenesis was predominantly intestinal but some grafts showed gizzard-like features, particularly if the endoderm had been provided by older donors. All intestinal endocrine cell types, including those also found in the normal proventriculus (serotonin-, glucagon-, pancreatic polypeptide-, neurotensin- and somatostatin-immunoreactive cells) differentiated in experimental grafts, some even where morphogenesis was gizzard-like. Hence progenitors of not only gastric, but also intestinal, endocrine cells are indeed present in gizzard endoderm. The possibility that gizzard mesenchyme is inhibitory to endocrine cell differentiation is mooted. Motilin- and secretin-immunoreactive cells, which are characteristic of the intestine but not of the proventriculus of chicks at hatching, were respectively sparse or absent when the endoderm was derived from older donors. Thus the ability of gizzard endoderm to differentiate into nongastric endocrine cell types declines before its capacity to form gastric types. The unexpected appearance of gastrin-releasing peptide (GRP)-immunoreactive cells, a proventricular type not found in normal chick intestine, suggests that the intestinal mesenchyme, at least in this instance, was exercising a permissive role.     

北京鸭消化道内分泌细胞的免疫组织化学研究

应用七种消化道激素抗血清，对北京鸭消化道内分泌细胞进行了免疫组织化学定位，促胃素释放肽细胞大量分布于腺胃和肌胃。生长抑素细胞在腺胃和肌胃数量很多，在幽门部密集，且偶见于十地二指肠，胃素细胞在幽门部非常密集，并较多分布于整个小肠，肌胃内亦有少量。５－羟色胺细胞大量见于肠管各段，并偶见于幽门，少量胰多肽细胞见于腺胃、十二指肠和空肠，未检出胃动素和抑胃肽细胞。     

红腹锦鸡胃肠道内分泌细胞的免疫组织化学定位

应用ABC免疫组织化学方法,对红腹锦鸡(Chrysolophus pictus)胃肠道5-羟色胺(5-hydroxtryptamine,5-HT)、胃泌素(gastfin,GAS)、生长抑素(somatostatin,ss)3种内分泌细胞的分布密度和形态进行了观察.结果显示,5-HT细胞在空肠和直肠分布密度最高,回肠和盲肠次之,十二指肠较少,腺胃和肌胃最少;GAS细胞在十二指肠和直肠分布密度最高,其次是空肠和盲肠,腺胃部最低,肌胃则呈免疫阴性;SS细胞数量较少,在直肠、盲肠处分布密度相对高,其次是十二指肠和空肠,腺胃部最低,肌胃则呈免疫阴性.3种内分泌细胞的形态多样,有圆形、椭圆形、锥体形、杆状和不规则形,其中以圆形、椭圆形为主.细胞分布于固有膜、黏膜上皮细胞基部、黏膜上皮细胞之间、腺泡上皮细胞基部或腺泡上皮细胞之间.红腹锦鸡胃肠道内分泌细胞的形态与其内、外分泌功能是相适应的.     

Developmental changes in the ability to express embryonic pepsinogen in the stomach epithelia of chick embryos

Summary The avian stomach is subdivided into two parts, the proventriculus and the gizzard. It has been shown that the gizzard epithelium can express embryonic chick pepsinogen (ECPg) antigen, a marker protein of the proventricular epithelium, as well as normal proventricular epithelium, under the appropriate experimental conditions. To study the possible mechanisms involved in the suppression of ECPg synthesis in the gizzard epithelium during normal development, we carried out heterotypic and heterochronic recombination experiments of the epithelium and mesenchyme of these two organ rudiments. When recombined and cultured with 6-day proventricular mesenchyme, gizzard epithelium of 3.5- to 12-day embryos expressed pepsinogen at all stages tested. However, the ratio of ECPg-positive cells to total epithelial cells in the gizzard epithelium decreased rapidly when epithelium older than 7 days was cultured with proventricular mesenchyme. In contrast to proventricular mesenchyme, 6-day gizzard mesenchyme did not allow ECPg expression in associated proventricular epithelium of 3.5- to 7-day embryos. These results indicate that gizzard epithelium does not express pepsinogen in normal development because of both a decrease in ability to express the enzyme in itself in the course of development and a repressive influence of gizzard mesenchyme.     

Characterization of chicken gizzard calcyclin and examination of its interaction with caldesmon

Using a procedure developed to purify calcyclin from mouse Ehrlich ascites tumor cells calcyclin was purified from smooth muscle of chicken gizzard. Chicken gizzard calcyclin bound to phenyl-Sepharose in a calcium dependent manner as did mouse EAT cells and rabbit lung calcyclin but appeared to be more acidic than its mammalian counterparts as revealed by ion exchange chromatography on Mono Q. Chicken gizzard calcyclin bound ⁴⁵Ca²⁺ on nitrocellulose filters and exhibited a shift in electrophoretic mobility on urea-PAGE depending on Ca²⁺ concentration. Crosslinking experiments with BS³ showed that chicken gizzard calcyclin was able to form noncovalent dimers. As indicated by a decrease in maximum tryptophan fluorescence emission of caldesmon (about 14% at 1:1 molar ratio) and displacement of calmodulin from its complex with caldesmon, chicken gizzard calcyclin binds caldesmon. This binding was, however, much weaker than that of calmodulin and could not influence the interaction of caldesmon with actin. In consequence, calcyclin was unable to reverse the inhibitory effect of caldesmon on actin-activated Mg²⁺-ATPase activity of myosin in the presence of Ca²⁺.     

Induction and Inhibition of Epithelial Differentiation by the Mixed Cell Aggregates of the Mesenchymes from the Chicken Embryonic Digestive Tract

Epithelial-mesenchymal interaction plays an important role in the differentiation of digestive tract. However, the factors of these mesenchymes involved in induction of the epithelial differentiation of each organs are still unknown. In the present study, we made reconstituted mesenchymal cell aggregates by mixing proventricular mesenchymal cells with other mesenchymal cells, recombined the reconstituted mesenchyme with gizzard epithelium, and observed the differentiation of the gizzard epithelium in the explants with special attention to the appearance of embryonic chicken pepsinogen, one of the molecular marker of the proventricular epithelial cells, in the gizzard epithelium. The results showed that the proventricular mesenchymal cells induce gland formation and pepsinogen in the gizzard epithelium and that the esophageal and gizzard mesenchymal cells have the inhibitory influence on the differentiation of epithelia toward proventricular epithelium. The cells from small-intestinal, lung and dorsal dermal mesenchyme have no such effect. Based on the results obtained so far, a hypothesis was presented to explain the mechanism regulating the differentiation of the epithelium in the digestive tract in the chicken embryo.     

Microheterogeneity of avian and mammalian vinculin: Distinctive subcellular distribution of different isovinculins

Vinculin from chicken gizzard and from pig heart may be separated by two-dimensional gel electrophoresis into several isoelectrophoretic forms. Peptide map analysis and immunochemical comparison of the different isovinculins indicated that all the isoforms are closely interrelated at the molecular level. Moreover, it was shown that avian and mammalian vinculins have similar molecular structures. Some differences were detected between the isovinculin pattern in intact chicken gizzard tissue and that found in cultured cells from the same organ. Various degrees of vinculin microheterogeneity were also detected in a variety of cultured cells, including primary cultures and several cell lines. Labelling of chicken gizzard cells with [³²P]orthophosphate resulted in the incorporation of ³²P in the minor acidic isoform of vinculin (α-vinculin) exclusively. Extraction of the cultured cells with detergent under conditions that remove the cytoplasmic “soluble” vinculin without significantly affecting focal contact-associated protein, indicated that specific vinculin isoforms may differ in their cellular distribution. The soluble fraction contained almost exclusively the basic form (β-vinculin), while the “organized” protein contained all three major isovinculins but was enriched with the acidic form (α) and the intermediate form (α′). The functional significance of isovinculin diversity and the involvement of phosphorylation events in vinculin interactions are discussed.     

Calcium sensitivity of contractile proteins from chicken gizzard muscle.

Actin, myosin, and "native" tropomyosin (NTM) were separately isolated from chicken gizzard muscle and rabbit skeletal muscle. With various combinations of the isolated contractile proteins, Mg-ATPase activity and superprecipitation activity were measured. It was thus found that gizzard myosin and gizzard NTM behaved differently from skeletal myosin and skeletal NTM, whereas gizzard actin functioned in the same wasy as skeletal actin. It was also found that gizzard myosin preparations were often Ca-sensitive, that is, that the two activities of gizzard myosin plus actin without NTM were activated by low concentrations of Ca2+. The Mg-ATPase activity of a Ca-insensitive preparation of gizzard myosin was not activated by actin even in the presence of Ca2+. When Ca-sensitive gizzard myosin was incubated with ATP (and Mg2+) in the presence of Ca2+, a light-chain component of gizzard myosin was phosphorylated. The light-chain phosphorylation also occurred when Ca-insensitive myosin was incubated with gizzard NTM and ATP (plus Mg2+) in the presence of Ca2+. In either case, the light-chain phosphorylation required Ca2+. Phosphorylated gizzard myosin in combination with actin was able to exhibit superprecipitation, and Mg-ATPase of the phosphorylated gizzard myosin was activated by actin; the actin activation and superprecipitation were found to occur even in the absence of Ca2+ and NTM or tropomyosin. The phosphorylated light-chain component was found to be dephosphorylated by a partially purified preparation of gizzard myosin light-chain phosphatase. Gizzard myosin thus dephosphorylated behaved exactly like untreated Ca-insensitive gizzard myosin; in combination with actin, it did not superprecipitate either in the presence of Ca2+ or in its absence, but did superprecipitated in the presence of NTM and Ca2+. Ca-activated hydrolysis of ATP catalyzed by gizzard myosin B proceeded at a reduced rate after removal of Ca2+ (by adding EGTA), whereas that catalyzed by a combination of actin, gizzard myosin, and gizzard NTM proceeded at the same rate even after removal of Ca2+. However, addition of a partially purified preparation of gizzard myosin light-chain phosphatase was found to make the recombined system behave like myosin B. Based on these findings, it appears that myosin light-chain kinase and myosin light-chain phosphatase can function as regulatory proteins for contraction and relaxation, respectively, of gizzard muscle.     

Polyclonal and monoclonal antibodies against chicken gizzard 5′-nucleotidase inhibit the spreading process of chicken embryonic fibroblasts on laminin substratum

Polyclonal and monoclonal antibodies raised against chicken gizzard 5'-nucleotidase were tested in adhesion assays of embryonic chicken fibroblasts (CEF) for their ability to interfere with the adhesion process of these cells on either laminin or fibronectin substrata. The initial attachment process of CEF on fibronectin and laminin substrata was not influenced by preincubating these cells with antibodies against chicken gizzard 5'-nucleotidase. However, the subsequent spreading process of these cells was found to be inhibited for at least 2 h on a laminin substratum. This effect was obtained with a polyclonal antibody as well as with one from 12 monoclonal antibodies raised against the native enzyme purified from chicken gizzard. In vitro assays demonstrated a competition of laminin and this monoclonal antibody for the binding site on purified 5'-nucleotidase. Spreading-arrested and rounded CEF do not develop prominent intracellular stress-fibers like control cells, instead they seem to concentrate their available actin in areas of presumptive initial contact with the laminin substratum.     

Gizzard epithelium of chick embryos can express embryonic pepsinogen antigen,a marker protein of proventriculus

Summary The avian stomach is composed of two distinct organs, the proventriculus and the gizzard. Pepsinogen expression in the proventricular and gizzard epithelia of chick embryos was investigated immunohistochemically with anti-embryonic chick pepsinogen (anti-ECPg) antiserum. In normal development, the ECPg antigen was expressed only in the glandular epithelial cells of the embryonic proventriculus from the 8th day of incubation onwards. However, both proventricular and gizzard epithelia of 6-day embryos expressed the ECPg antigen when recombined and cultured with the proventricular mesenchyme. Chronological studies revealed that the ECPg antigen was first detected in a few epithelial cells at 3 days of cultivation. The percentage of ECPg-positive cells among the total epithelial cells in each recombinant increased with the length of the culture period and all the glandular epithelial cells were positive at 9 days. During this process, the percentage of ECPg-positive cells in each cultured recombinant was similar in proventricular and gizzard epithelia. Moreover, both epithelia could express the ECPg antigen when recombined and cultured with the oesophageal or small-intestine mesenchyme for 9 days, though the percentage of ECPg-positive cells in each cultured recombinant was much lower than that in the cultured recombinant with the proventricular mesenchyme. These results indicate that the gizzard epithelium of 6-day chick embryos possesses a similar potential for pepsinogen expression as the proventricular epithelium of the same age.     

Nonmuscle and smooth muscle myosin light chain mRNAs are generated from a single gene by the tissue-specific alternative RNA splicing

We have isolated two cDNA clones for myosin alkali light chain (MLC) mRNA from two respective cDNA libraries of chick gizzard and fibroblast cells by cross-hybridization to the previously isolated cDNA of skeletal muscle MLC. Sequence analysis of the two cloned cDNAs revealed that both of them are homologous to but distinct from the cDNA sequence used as the probe so that they may be classified into members of the MLC family, that they are identical with each other in the 3' and 5' untranslated sequence as well as in the coding sequence with a notable exception of a 39-nucleotide insertion in the fibroblast cDNA, 26 nucleotides of which are used for encoding the C-terminal amino acid sequence, and, therefore, that they encode the identical 142-amino acid sequence with different C-terminals of nine amino acids, each specific for fibroblast and gizzard smooth muscle MLC. The position of the inserted block corresponds exactly to one of the exon-intron junctions in the other MLC genes whose structures have so far been elucidated. DNA blot analysis suggested that the two MLC mRNAs of gizzard (smooth muscle) and fibroblast cells (nonmuscle) are generated from a single gene, probably through alternative RNA splicing mechanisms. RNA blot analysis and S1 nuclease mapping analysis using RNA preparations from fibroblast and gizzard tissues showed that the fibroblast MLC mRNA is expressed predominantly in fibroblast cells, but not, or very scantily if at all, in the gizzard, whereas the reverse is true for the gizzard smooth muscle MLC mRNA.