The structure of chordin: characteristics of protein and carbohydrate components and their role in antigenicity

Using immobilized monoclonal antibodies, a tissue-specific antigen, chordin, was isolated from cell extracts of giant sturgeon (beluga) notochord. The antigen was further purified by gel filtration through SP-Sephadex (pH 2.1) and gel chromatography on TSK Toyopearl HW-60. Purified chordin preparations contained 40% of protein and 60% of carbohydrates. The predominant polar amino acids were threonine, serine, glycine, asparagine and glutamine (or aspartic and glutamic amino acids). The carbohydrate moiety comprised mannose, fucose, galactose, galactosamine and glucosamine. Treatment of chordin with three enroglycosidases specifically hydrolyzing the carbohydrate chains of proteoglycans did not affect the antigenic properties of chordin or its behaviour on gel filtration. These findings and the fact that 75% of galactosamine was converted to galactosaminite after treatment with alkaline NaBH4 permitted to relate chordin to glycoproteins carrying O-glycosidic carbohydrate-peptide bonds between the N-acetyl-galactosamine and beta-hydroxyamino acid residues. Besides, chordin seems to contain a N-glycosylamide carbohydrate-peptide bond as can be judged from glucosaminite formation after treatment of the antigen with alkaline LiHB4. The changes in the antigenic properties of chordin after its treatment with neuraminidase, pronase, sodium periodate, alkali, alkaline NaBH4 or LiBH4 suggest that the polypeptide moiety of the chordin molecule and, perhaps, the N-acetylgalactosamine within the composition of the carbohydrate-peptide bond are involved in the construction of its most immunogenic determinants (P-determinants).     

Identification of proteolysis-resistant fragments carrying P-type antigenic determinants in chordin and immunologically related human brain antigen

An antigen immunologically related to chordin was identified in white and gray matter of large hemispheres of human brain as well as in one of glial tumours. It was shown that human and rabbit brain extract components cross-react with eight monoclonal antibodies directed against chordin-specific epitopes of P-group. Exhaustive proteolysis of giant sturgeon notochord and human brain extracts resulted in fragments interacting with anti-chordin antibodies and eluted in an equal volume during chromatography on TSK HW-40 gel. At the same time, gel electrophoresis performed under denaturing conditions revealed that the mobility of chordin subunits strikingly differs from that of brain antigen immunologically related to chordin. Thus, the cross-reactivity of antichordin antibodies with the human brain extract component is due to the presence in this antigen of a P-type determinant which, after exhaustive proteolysis of both antigens, is detected in structures (presumably, glycopeptides) having an identical molecular mass.     

P-epitope is characteristic for the neural tissue of vertebrates

In a search for antigens immunologically related to chordin, a notochord-specific glycoprotein of sturgeneous fishes, extracts from 55 samples of human and rabbit tissues were tested for inhibition of [125I]chordin binding to rabbit polyclonal antibodies. The strongest inhibition was observed with brain extracts of both species. Human, chicken, rabbit, and newt brain extracts also inhibited chordin binding in liquid phase to monoclonal antibodies (MAbs) against the P-epitope, the most immunogenic epitope of this glycoprotein. Immunohistochemical studies done on human and chicken embryos, newt, sterlet, and sturgeon embryos, larvae, and juveniles revealed a strong immunoreactivity of the brain, spinal cord, and tissue of the peripheral nervous system with an anti-P MAb. Other tissues, with several exceptions, showed a negative reaction in immunohistochemical experiments. The authors found that the P-epitope is ontogenetically expressed in the neural tissue of chicken, newt, and sterlet at the period of cytodifferentiation. Gel chromatography of human, chicken, and newt brain extracts showed that in each case the P-epitope was associated with a polydisperse macromolecular material of similar size. These antigens were designated as neurochordins. Prolonged pronase digestion of human and chicken brain extracts resulted in fragments with M about 3 kDa (presumably glycopeptides), which reacted with anti-P MAbs. These fragments were of the same size as corresponding glycopeptides of the pronase digest of chordin. Thus, in the present study, the P-epitope has been shown to be characteristic for the neural tissue of several vertebrate species; in the brain, it has been found in association with neurochordins, macromolecular antigens that are presumably protein conjugates with carbohydrates.     

VACUOLATION OF EXPLANTED AND IMPLANTED NOTOCHORDS OF AMPHIBIA

Processes of vacuolation were investigated with the explanted and implanted rudiments of amphibian notochord. Explanted notochords generally underwent vacuolation when they were surrounded by other differentiating tissues. In the absence of these tissues, they were not only unable to vacuolate but also unable to survive. When the notochords were implanted into the ventral mass of yolk granules of neurula, they showed no vacuolation and died within a few days if they were alone and not surrounded by other differentiating tissues. These facts suggest that the presence of other differentiating tissues surrounding the notochord is a requisite for the notochord to vacuolate. Further, the fact that in explanted notochords, vacuolation was frequently interrupted and was left unfinished when the surrounding tissues were scarce, suggests that the quantity of the surrounding tissues is important in promoting vacuolation. Interruption of the vacuolation occurs in the explanted notochord at any stage from the beginning to the end of the process. Therefore, almost all the stages of vacuolation were observed in these notochords. Very frequently, different parts of a single notochord presented different stages of vacuolation. All these stages were essentially the same as those found in the normal notochord. From these results, it emerges that although vacuolation of the explanted and implanted notochords is carried out with the same process as in the normal intact one, it is accomplished only when they are surrounded by a sufficient quantity of other differentiating tissues.     

Immunohistochemical distribution of the antigenic determinants detected by monoclonal antibodies to carcinoembryonic antigen

By using four distinct monoclonal antibodies to CEA, the molecular profile of which was clarified in our accompanying companion paper, immunohistochemical distribution of the antigenic determinants on both cancerous and noncancerous tissues as well as fetal tissues was studied with the use of the immunoperoxidase method. All of the monoclonal antibodies recognize different antigenic determinants on the tissue section. None of the antibodies stained granulocytes in the peripheral blood or in the normal liver tissues tested. Three of our monoclonal antibodies stained columnar epithelial cells in morphologically normal colonic mucosa; however, monoclonal antibody YK024 did not stain them. This antibody was also found to be unreactive with intestinal metaplasia lesions of the stomach, but reacted with a 16-wk-old fetal stomach as well as with cancerous parts of the colon and of the stomach. Moreover, it was found that this monoclonal antibody mainly reacted with moderately or poorly differentiated adenocarcinoma lesions of the colon and the stomach. Periodic acid treatment in this study, together with trypsin treatment on the antigen as described in our accompanying companion paper, may suggest that this antibody recognizes the carbohydrate antigenic determinant in nature.     

Biochemical specificity of Xenopus notochord

The biochemical composition and biosynthetic activity of Xenopus notochord were examined and compared with those of chick and mouse notochord. The notochords of all three species contain type-II collagen, and the notochords of Xenopus and chick synthesize a soluble glycoprotein with a molecular mass of 86 kilodaltons (kd). Mouse embryos were not tested for this molecule, because their notochords are too small to be dissected out. Most interestingly, Xenopus and chick notochords share a keratan-sulphate-containing proteoglycan which appears to be absent from mouse notochord. The presence or absence of keratan sulphate in the notochords of the different species reflects its presence or absence in cartilage. Since one role of the notochord in vivo is to stimulate chondrogenesis in the sclerotomes of the somites, this result provides support for the view that cells responding to the extracellular matrix produced by one tissue do so by increasing their production of the same matrix components.     

Immunohistochemical identification of the cytoskeletal elements in the notochord cells of bony fishes

The medulla of the unconstricted notochords of the shortnose sturgeon, Acipenser brevirostratus, and African lungfish, Protopterus annectens, and the cellular component of the intervertebral joint tissue of the teleost fish, Perca flavescens, are comprised of cells with a large central vacuole. Previous studies on the fine structure of this tissue revealed that the cytoplasm surrounding these vacuoles consists of 10-nm-diameter intermediate filaments. Since in mammals there are a large number of tissue-specific types of intermediate filaments, this study uses antibodies to mammalian intermediate filaments to determine the type of filaments present in the notochord cells of bony fishes. Positive labeling using a polyclonal antibody to human skin keratins is observed in the cytoplasm of the notochord cells in the intervertebral tissues of Perca. These tissues are also probed with the AE series antibodies that label keratins found in mammalian epithelial cells. In both Protopterus and Acipenser the peripheral cytoplasm of the notochord cells is labeled with all three AE antibodies. In Perca only the AE3 antibody probe produces positive staining. These staining patterns are consistent with previous studies on the localization of cytokeratins in fish tissues and indicate that the intermediate filaments in the notochord cells of bony fishes are immunologically similar to the mammalian keratins. J. Morphol. 236:105–116, 1998. © 1998 Wiley-Liss, Inc.     

Expression by human fetal organs of organ-specific cancer neoantigens as measured by leukocyte adherence inhibition

Summary Human cancers express organ-specific cancer neoantigens (OSN) as determined by in vitro leukocyte responses to extracts of cancers by the tumor host. In this study, we determined whether the OSNs were normal developmental proteins that were expressed by fetal organs and re-expressed with oncogenesis. Fetal extracts, principally of lung and colon but also of liver and kidney, were tested for their ability to induce leukocyte adherence inhibition (LAI) as compared to extracts from adult tissues of the same organ. Leukocytes from lung cancer patients showed positive LAI responses to 13- and 19-week fetal lung tissue. Likewise, leukocytes from colon cancer patients showed positive LAI responses to 14- and 19-week fetal colon tissue, whereas leukocytes from control subjects did not. Neither group responded positively to 21-week fetal organs. Criss-cross experiments showed that the fetal antigen was organ specific. Multiparous pregnant women showed positive LAI responses to cancer extracts but not to extracts from normal tissues of the same organ. The pattern of the LAI response was bell-shaped. Positive LAI responses to lung and breast cancer were detected at 4 to 7 months gestation and peaked at 5 months. To the fetal colon, LAI positive responses were detected at 5 to 8 months gestation, with the peak response at 6 months. The results indicate that OSN of cancers are also expressed by fetal organs and sufficient antigen is shed by fetal organs to sensitize pregnant women. Older fetal organs (21 weeks) and adult organs do not express an immunogenic or antigenic OSN.Supported by a grant from the National Cancer Institute of Canada     

The notochord proteins of true sturgeons carrying the At1 epitope]

Previously we reported the production of monoclonal antibodies against chordin, an acidic glycoprotein from true sturgeon notochord, carrying glycans terminating with 3-sulfoglucuronic acid. In addition, monoclonal antibodies At1, not reacting with chordin, were produced. Here we describe At1 epitope expression in sturgeon tissues and target proteins for At1 antibodies, and test interaction of these proteins with chordin and other molecules carrying glycan with 3-sulfoglucuronic acid. The expression of the antigens carrying At1 epitope during sturgeon development has also been studied.     

Absence of neural crest cells from the region surrounding implanted notochords in situ

Avian neural crest cells migrating along the trunk ventral pathway are distributed throughout the rostral half of the sclerotome with the exception of a neural crest cell-free space of approximately 85 microns width surrounding the notochord. To determine if this neural crest cell-free space results from the notochord inhibiting neural crest cell migration, a length of quail notochord was implanted lateral to the neural tube along the neural crest ventral migratory pathway of 2-day chicken embryos. The subsequent distribution of neural crest cells was analyzed in embryos fixed 2 days after grafting. When the donor notochord was isolated using collagenase, neural crest cells avoided the ectopic notochord and were absent from the area immediately surrounding the implant (mean distance of 43 microns). The neural crest cell-free space was significantly less when notochords were isolated using trypsin or chondroitinase digestion and was completely eliminated when notochords were fixed with paraformaldehyde or methanol prior to implantation. The implanted notochords did not appear to affect the overall number of neural crest cells, and therefore were unlikely to exert this effect by altering their viability. These results suggest that the notochord produces a substance that can inhibit neural crest cell migration and that this substance is trypsin and chondroitinase labile.     

Environmental factors modulate the size and the secretory activity of the notochord. A study of the Golgi apparatus in avian embryos

In this study we examined the Golgi apparatus of avian notochord transplants excised from 2-day-old (E2) chick embryos and grafted isochronically into a chick host either in a medial-ventral position, next to the host notochord, or in a superficial position under the ectoderm laterally or dorsally to the neural tube. The operated embryos were examined from E2 to E8. The diameters, the cytoplasmic vacuolization and the immunostained Golgi apparatus were identical between the endogenous and ventrally grafted notochords, as well as between host-and superficially transplanted notochords when observed at E2. In contrast, from E4 to E8, the size of the notochords grafted dorsally or laterally to the neural tube was significantly smaller than the host, while the cytoplasmic vacuolization and the degree of fragmentation of the Golgi apparatus were significantly less than in the host notochords. These results show that environmental and position-specific factors influence the developmental program and the secretory activity of the notochordal cells.     

Immunoenzyme determination of neurospecific antigen 10-40-4 in human and animal tissue and organ extracts

IEA of brain specific antigen 10-40-4 in human and animal organs and tissues was elaborated. The method permits measuring the concentration of the antigen within the range from 1 to 120 ng/ml. The use of the method made it possible to confirm brain specificity of protein 10-40-4, since its brain content is 1500 to 2000 times higher than in other organs, and to estimate the percentage of cross-reaction between antigenic determinants of brain specific antigen 10-40-4 from different species of animals.     

Interactions of antinicotinic acetylcholine receptor antibodies with rat brain and muscle antigenic determinants

Studies were performed to determine whether antibodies prepared against nicotinic acetylcholine receptors (nAcChoR) from electric tissue are reactive toward nAcChoR-like antigenic determinants in rat brain. Reference experiments involved the use of Torpedo electroplax and rat innervated muscle as tissue controls and an anti-alpha-bungarotoxin antiserum as a probe for curaremimetic neurotoxin binding sites. As evinced by their ability to inhibit immunoprecipitation of Torpedo nAcChoR, brain or muscle membranes specifically interact with polyclonal antisera raised against Electrophorus electroplax nAcChoR. When the extent of polyclonal anti-nAcChoR antibody binding to muscle membranes is measured by protein A binding protocols, receptor-like antigenic determinants and toxin binding sites are found to be present in approximately equal quantities. In contrast, nAcChoR-like antigenic determinants on rat brain membranes are present at concentrations in excess of those of toxin binding sites. The results are consistent with the earlier observation that some antibodies prepared against nAcChoR from peripheral tissues recognize rat brain high-affinity alpha-bungarotoxin binding sites. The results also suggest the existence of nAcChoR-like entities in brain that do not bind toxin with a high affinity.     

Morphogenesis of sclerotome and neural crest in avian embryos

Summary The distribution of sclerotome and neural crest cells of avian embryos was studied by light and electron microscopy. Sclerotome cells radiated from the somites towards the notochord, to occupy the perichordal space. Neural crest cells, at least initially, also entered cell-free spaces. At the cranial somitic levels they moved chiefly dorsal to the somites, favouring the rostral part of each somite. These cells did not approach the perichordal space. More caudally (i.e. trunk levels), neural crest cells initially moved ventrally between the somites and neural tube. Adjacent to the caudal half of each somite, these cells penetrated no further than the myosclerotomal border, but opposite the rostral somite half, they were found next to the sclerotome almost as far ventrally as the notochord. However, they did not appear to enter the perichordal space, in contrast to sclerotome cells.When tested in vitro, sclerotome cells migrated towards notochords co-cultured on fibronectin-rich extracellular material, and on collagen gels. In contrast, neural crest cells avoided co-cultured notochords. This avoidance was abolished by inclusion of testicular hyaluronidase and chondroitinase ABC in the culture medium, but not by hyaluronidase from Streptomyces hyalurolyticus. The results suggest that sclerotome and neural crest mesenchyme cells have a different distribution with respect to the notochord, and that differential responses to notochordal extracellular material, possibly chondroitin sulphate proteoglycan, may be responsible for this.     

Study of Cynops pyrrhogaster notochord differentiation using a novel monoclonal antibody

Two monoclonal antibodies which reacted specifically with the notochord of the early Cynops pyrrhogaster embryo were screened. The antigen molecules were detected within and around the notochord. They were first found mostly between the neural plate and the dorsal part of the notochord in the early neurula (stage 15). They were subsequently detected between the notochord and the somite in the advanced embryo, and they were last detected between the notochord and the underlying endoderm. Whole-mount labeling indicated that the antigen molecules were first detected in the anterior half of the notochord in the early neurula (stage 15). The signals gradually spread along the anterior-posterior axis, especially towards the posterior region. This fact suggests that notochord differentiation progresses from the anterior region which first receives the dorsal mesoderm-inducing signals released horizontally from the lower dorsal marginal zone during early gastrulation. The present study suggested that: (i) notochord differentiation proceeds from the anterior region; and (ii) secretion of the antigen molecules results in the drawing of a boundary between the adjacent tissues.     

IMMUNOCHEMICAL STUDIES ON THE BRAIN SPECIFIC PROTEIN

Abstract— In the soluble brain proteins of various species-man, ox, cat, rabbit, rat, mouse, hen, snake, frog and fish–there is a protein group which migrates more slowly than Moore's S-100 protein and faster than the albumin fraction on disc electrophoresis. The protein group is absent from any organs other than brain, and has a different pattern and number of fractions in different species. Immunochemically, the protein fraction group of the mammalian brains shows some common and identical distinctive antigenic determinants compared with the brain protein of the other animals-hen, snake, frog and fish. The protein group was designated the 'SPR' proteins, which were separated to 'P_II,', 'P_III', 'P_IV' and 'P_v' fractions. Common antigenic determinants are found in these fractions. The protein group is found in human brain in larger amounts in grey matter than in white matter and in small amounts in the cellular nuclei of human and bovine brain.     

Intermediate filament typing of the human embryonic and fetal notochord

In order to characterize human notochordal tissue we investigated notochords from 32 human embryos and fetuses ranging between the 5th and 13th gestational week, using immunohistochemistry to detect intermediate filament proteins cytokeratin, vimentin and desmin, the cytokeratin subtypes 7, 8, 18, 19 and 20, epithelial membrane antigen (EMA), and adhesion molecules pan-cadherin and E-cadherin. Strong immunoreactions could be demonstrated for pan-cytokeratin, but not for desmin or EMA. Staining for pan-cadherin and weak staining for E-cadherin was found on cell membranes of notochordal cells. Also it was demonstrated that notochordal cells of all developmental stages contain the cytokeratins 8, 18 and19, but not 7 or 20. Some cells in the embryonic notochord also contained some vimentin. Vimentin reactivity increased between the 8th and 13th gestational week parallel to morphological changes leading from an epithelial phenotype to the chorda reticulum which represents a mesenchymal tissue within the intervertebral disc anlagen. This coexpression reflects the epithelial-mesenchymal transformation of the notochord, which also loses E-cadherin expression during later stages. Our findings cannot elucidate a histogenetic germ layer origin of the human notochord but demonstrate its epithelial character. Thus, morphogenetic inductive processes between the human notochord and its surrounding vertebral column anlagen can be classified as epithelial-mesenchymal interactions.     

Indirect tissue electrophoresis: a new method for analyzing solid tissue protein

1. The eye lens core (nucleus) has been a valuable source of molecular biologic information. 2. In these studies, lens nuclei are usually homogenized so that any protein information related to anatomical subdivisions, or layers, of the nucleus is lost. 3. The present report is of a new method, indirect tissue electrophoresis (ITE), which, when applied to fish lens nuclei, permitted (a) automatic correlation of protein information with anatomic layer, (b) production of large, clear electrophoretic patterns even from small tissue samples and (c) detection of more proteins than in liquid extracts of homogenized tissues. 4. ITE seems potentially applicable to a variety of solid tissues.     

Comparison of two cell surface molecules involved in neural cell adhesion

Two cell surface molecules found in mouse brain, N-CAM and the L1 antigen, were compared in terms of their cell adhesion function, polypeptide structures, antigenic determinants and distribution in cerebellar tissue. Fab fragments of polyclonal antibodies to either N-CAM or L1 antigen only partially inhibited the rate of calcium-independent aggregation of neuroblastoma N2A cells, whereas complete and more efficient inhibition was obtained when they were used in combination. Despite the functional similarity, comparison of the electrophoretic behaviour of the purified molecules and of their proteolytic fragments shows that the L1 antigen polypeptide is distinct from that of N-CAM. In addition, no antigenic cross-reactivity was detected between the two molecules. In cryostat sections of cerebellum from young post-natal mice, N-CAM was found to be present in all cell and neurite layers, whereas L1 antigen was expressed only in regions containing post-mitotic cells. These results indicate that two chemically and histochemically distinct cell surface polypeptides can contribute to the calcium-independent adhesiveness of neural cells, and suggest that their differential expression might cause adhesive specificity among cells of developing neural tissues.