Mg2+ mediates the cell-substratum interaction of Arg-Gly-Asp-dependent HeLa cell collagen receptors

Three HeLa cell surface collagen receptors of apparent molecular mass 102/58, 87, and 38/33 kDa were eluted from gelatin-Sepharose with salt gradients or Arg-Gly-Asp-containing peptides. To understand how the collagen receptors are involved in HeLa cell spreading on collagen we investigated the effects of divalent cations and Arg-Gly-Asp-containing peptides on adhesion to gelatin, since HeLa cells behave similarly on both native type I collagen and gelatin substrata and also whether Arg-Gly-Asp-containing substrata would substitute for gelatin in facilitating cell spreading. Gly-Arg-Gly-Asp-Ser-containing peptides in solution inhibited HeLa cell spreading onto gelatin and promoted only partial HeLa cell spreading when bound to tissue culture plastic. Both partial spreading of HeLa cells on the Gly-Arg-Gly-Asp-Ser substratum and full spreading on gelatin was dependent on Mg2+, but not on Ca2+. Binding of the 102/58-, 87-, and 38/33-kDa collagen receptors to gelatin-Sepharose was increased fourfold in the presence of Mg2+, and subsequent elution of the collagen receptors and a 45-kDa collagen-binding protein not thought to be involved in HeLa cell spreading was achieved with EDTA. In contrast, affinity chromatography on Gly-Arg-Gly-Asp-Ser-Sepharose eluted predominantly the 45-kDa collagen-binding protein and the 38/33-kDa collagen receptor. In summary, the Mg2(+)-dependent interaction of the collagen receptors with the Arg-Gly-Asp sequence in collagen appears to be essential for the initial events in HeLa cell spreading but is not sufficient for full cell spreading.     

Identification and distribution of a novel, collagen-binding protein in the developing subepicardium and endomysium.

A protein doublet (M(r) = 68,000) that copurifies with chicken cardiac collagen types I and III is purified and characterized in the present study. Peptide mapping and amino terminus sequencing for both 68-kDa polypeptides show they have similar structures. This is supported by amino terminus sequencing of a 39-kDa proteolytic fragment of each polypeptide. The 68-kDa polypeptides appear at pI 6.7-6.8 in two-dimensional gels. Under nonreducing, electrophoretic conditions, the doublet appears as a large multimer or aggregate. Amino acid sequencing of the protein shows that its amino terminus contains a heptapeptide (VCLXXGK) that appears in the heparin/fibrin-binding domain of fibronectin and the collagen-binding domain of laminin. Cardiac myocytes synthesize and secrete the protein in vitro onto cell surfaces and onto the substratum. Indirect immunofluorescence shows the protein first appears in the chicken subepicardium at approximately 10 days following fertilization. As collagen accumulates in the subepicardium and the volume of the subepicardial space increases, the 68-kDa protein is found predominantly at the interface between myocardial cells and the connective tissue and between epicardial cells and the connective tissue. In adult hearts, the protein is also present at lower concentrations in endomysial connective tissue. The 68-kDa protein is also present in the skeletal muscle endomysium of embryonic chickens. Electron microscopic immunocytochemistry shows the 68-kDa protein is located at the surface of subepicardial collagen fibers. In addition, a direct interaction between the 68-kDa protein and collagen are indicated by: 1) equilibrium gel filtration of the 68-kDa protein in the presence of gelatin, 2) gelatin affinity chromatography of the 68-kDa protein, and 3) comigration of type I collagen and the 68-kDa protein during gel filtration under reducing conditions. The 68-kDa protein exhibits no collagenase activity under native conditions or in zymograms. Together, the data indicate that the 68-kDa protein is a novel collagen-associated protein appearing in late epicardial development.     

Association between fibronectin receptor and the substratum: Spare receptors for cell adhesion

We have investigated the association of the recently described 140-kDa cell membrane receptor for fibronectin with the cytoskeleton or with substratum-bound fibronectin. Using a monospecific polyclonal antibody to the 140-kDa receptor, we have demonstrated that most of the receptor molecules are soluble in nonionic detergent either in suspension culture CHO cells or in CHO cells attached to and spread on a fibronectin-coated substratum. This may suggest that putative linkages of the receptor either to fibronectin or to detergent-insoluble cytoskeletal components are labile to nonionic detergent and thus are rather weak. Alternatively, it may mean that only a small fraction of the cell's receptors are needed to mediate adhesion. In order to explore this latter concept, we have coated substrata with various concentrations of PB1, a monoclonal antibody with a high affinity for fibronectin receptor. We demonstrate that coating the substratum with increasing concentrations of PB1 results in increasing amounts of 140-kDa receptor becoming bound to the substratum in detergent-insoluble form. However, the amount of receptor bound does not necessarily correlate with the degree of cell adhesion and spreading. Thus, coating the substratum with 5 μg/ml of PB1 results in essentially complete attachment and spreading of CHO cells, but only a small fraction of the 140-kDa receptor becomes substratum bound. Coating with 50 μg/ml of PB1 produces no further increase in cell adhesion and spreading, but results in the detergent-stable association of a large fraction of the total receptor pool with the substratum. These observations suggest the possibility of there being “spare” receptors for cell adhesion processes.     

Purification of a plant cell wall fibronectin-like adhesion protein involved in plant response to salt stress

The structural role of extracellular-matrix (ECM) has been recognized in both plants and animals as a support and anchorage-inducing cell behavior. Unlike the animal ECM proteins, the proteins that have been identified in plant ECM have not yet been purified from whole plants and cell wall. As several immunological data indicate the presence of animal ECM-like proteins in plants cell wall, especially under salt stress or water deficit, we propose a protocol to purify a fibronectin-like protein from the cell wall of epicotyls of young germinating peas. The process consists of a combination of gelatin and heparin affinity chromatography, close to the classical one used for human blood plasma fibronectin purification. Proteins with affinity for gelatin and heparin, immunologically related to human fibronectin, are found in the cell wall of epicotyls grown under salt stress or not. Total amount of purified proteins is 3-4 times more enriched in salt stressed epicotyls. SDS-PAGE and Western blot with antibodies directed against human blood plasma fibronectin give evidence that the cell wall proteins purified by gelatin/heparin affinity chromatography are closely related to human fibronectin. The present protocol leads us to purify 17 (control) or 65 (salt stress) micrograms of protein per g of fresh starting material. Our results suggest that plant cell wall proteins can provide better anchorage of the cell to its cell-wall during salt stress or water deficit and could be considered not only as cell adhesion but also as signaling molecules.     

Two cell surface proteins bind the sponge Microciona prolifera aggregation factor

Two extracellular matrix cell surface proteins which bind the proteoglycan-like aggregation factor from the marine sponge Microciona prolifera (MAF) and which may function as physiological receptors for MAF were identified and characterized for the first time. By probing nitrocellulose blots of nonreducing sodium dodecyl sulfate gels containing whole sponge cell protein with iodinated MAF, a 210- and a 68-kDa protein, which have native molecular masses of approximately 200-400 and 70 kDa, were identified. MAF binding to blots is species-specific. It is also sensitive to reduction and is completely abolished by pretreatment of live cells with proteases, as was cellular aggregation, indicating that the 210- and 68-kDa proteins may be located on the cell surface. The additional observations that the 68 kDa is an endoglycosidase F-sensitive glycoprotein and that antisera against whole sponge cells or membranes can immunoprecipitate the 210 kDa when prebound to intact cells are consistent with a cell surface location. Both proteins can be isolated from sponge cell membranes and from the sponge skeleton (insoluble extracellular matrix), but the 210-kDa MAF-binding protein can also be found in the soluble extracellular matrix (buffer washes of cells and skeleton) as well. A third MAF-binding protein of molecular mass 95 kDa was also found in the sponge extracellular matrix but rarely on cells. Both of the cell-associated 210- and 68-kDa proteins are nonintegral membrane proteins, based on Triton X-114 phase separation, flotation of liposomes containing sponge membrane lysates, and their extraction from membranes by buffer washes. Both proteins bind MAF affinity resins, indicating that they each exhibit a moderate affinity for MAF under native conditions. They can also be separated from each other and from the bulk of the protein in an octylpolyoxyethylene extract of membranes by fast protein liquid chromatography Mono Q anion exchange chromatography, as assessed by native dot blot and denaturing Western blot assays. Although neither protein bound to heparin, gelatin, hexosamine, or uronic acid-Sepharose resins, their affinity for an invertebrate proteoglycan, their roles in sponge cell adhesion, and their peripheral membrane protein natures suggest that they may represent early invertebrate analogs of cell-associated vertebrate extracellular matrix adhesion proteins, such as fibronectin or vitronectin, or else an entirely novel set of cell adhesion molecules.     

Developmental modulation of embryonic cardiac myocyte adhesion to cardiac collagens in vitro.

The goal of this investigation is to identify molecules that mediate embryonic cardiac myocyte adhesion during chick cardiac morphogenesis. The assay used employs culturing embryonic myocytes on substrata containing embryonic heart proteins separated by molecular weight. This assay shows that embryonic myocytes from 10- to 14-day-old embryos will bind to 140,000 and 128,000 Da proteins present in embryonic hearts and do not require Mg2+ or Ca2+ for adhesion. Myocytes from embryos younger than 10 days or older than 14 days display little or no binding. Embryonic heart fibroblasts collected at these same ages do not bind to these proteins. The 140- and 128-kDa proteins were found to copurify in extraction procedures for procollagens. Amino acid analysis shows that both proteins contain high glycine and hydroxyproline, indicating that they are collagens. However, glycine and imino acid levels are low relative to other known collagens, indicating a nonhelical domain present in each molecule and most closely resembled levels present in procollagens. Immunoblots show that antisera to chick collagen type I recognizes the 128-kDa protein while anti-collagen type III recognizes the 140-kDa protein. Monoclonal antibodies to the amino terminal propeptide of collagen type I recognize the 128-kDa protein in immunoblotting procedures. Embryonic chick myocytes bind to 140/128 kDa proteins present in extracts of sympathetic trunk, although they do not bind to 140/128 kDa proteins in embryonic tendon. The findings thereby indicate that forms of type III and type I collagens in embryonic heart support direct adhesion of embryonic myocytes for a restricted period of cardiac myogenesis and that these proteins differ from collagen types I and III present in other tissues and from fully processed collagen types I and III.     

Transforming growth factor beta 1-specific binding proteins on human vascular endothelial cells.

Transforming growth factor beta (TGF beta) regulates the growth of human umbilical vein endothelial cells (HUVEC) differently depending on the isoform of TGF beta and the culture conditions. The cells are resistant to growth inhibition by TGF beta when the cells are cultured on substratum coated with gelatin. However, the proliferation of HUVEC cultured on substratum without a gelatin coating is inhibited by TGF beta, depending on the isoform and concentration of TGF beta. Binding assays with 125I-TGF beta 1 reveal that HUVEC contain a single class of high-affinity (Kd = 4.4 pM) TGF beta 1 binding sites with 8500 sites per cell. Affinity cross-linking studies demonstrate that HUVEC express 180 and 80 kDa TGF beta 1 binding sites that do not bind TGF beta 2. The reduction and the removal of glycosaminoglycans does not affect the electrophoretic mobility of the 180-kDa binding protein cross-linked with 125I-TGF beta 1. Therefore, the 180-kDa TGF beta 1 binding protein is not related to the type III TGF beta receptor, but might be a novel TGF beta 1-specific receptor/binding protein expressed on vascular endothelial cells. The expression of TGF beta 1 binding sites is not affected by the presence or absence of the gelatin coating on the culture substratum. The data suggest that a gelatin coating does not regulate the susceptibility of HUVEC to TGF beta 1 at the level of the receptor/binding proteins, and that growth inhibition of HUVEC by TGF beta 1 is linked to the regulation of extracellular matrices required for the interaction between the cells and the substratum.     

Isolation of collagen binding proteins from embryonic chicken corneal epithelial cells

In the present paper, we report the isolation and characterization of embryonic corneal membrane glycoproteins that demonstrate specific affinity for collagen. Two collagen binding proteins have been isolated: a novel 70-kDa protein and a 47-kDa protein which is apparently similar to that reported by Kurkinen et al. (Kurkinen, M., Taylor, A., Garrels, J. I., and Hogan, B. (1984) J. Biol. Chem. 259, 5915-5922). Both proteins label metabolically with [35S]methionine and [3H] glucosamine. 125I iodination of cell surface proteins revealed that the two collagen binding proteins are expressed on the epithelial cell surface. The 70-kDa protein appears to be an integral membrane protein, whereas the 47-kDa protein can be removed from membranes by alkali treatment. The isolated proteins exhibit binding to native type IV collagen as well as heat-denatured type I collagen. It seems likely that we have isolated, at least in part, the cell surface receptor or receptor complex that binds collagen to the basal surface of epithelia.     

Two mRNAs exist for the Hs PROS-30 gene encoding a component of human prosomes.

Screening of a λgt11 cDNA expression library of the HeLa cell genome with a monoclonal antibody that specifically recognizes prosomal 30-33-kDa proteins, allowed isolation of a 1264-nucleotide (nt) recombinant cDNA containing a 327-nt untranslated 5'-end. The amino acid (aa) sequence deduced from this cDNA revealed a protein of 269 aa (M_r of 30 227) that includes a consensus box characteristic for Tyr phosphorylation, also observed in other prosomal proteins. Comparison with another prosomal 27-kDa protein, cloned in our laboratory, indicated the presence of three prosomespecific homology boxes observed in these proteins from archaebacteria to man. Interestingly, except for the untranslated 5'-end, as well as the sequence coding for the N-terminal six aa, this cDNA is identical to two recently published cDNAs encoding subunit C2 of human liver proteasome [Tamura et al., Biochim. Biophys. Acta 1089 (1991) 95–102] and subunit NU of human erythrocyte macropain [DeMartino et al., Biochim. Biophys. Acta 1079 (1991) 29–38]. Primer extension and Northern blot analysis using two specific 18-mer oligodeoxyribonucleotides indicated the presence of two mRNAs that have divergent 5'-ends. These results, as confirmed by the polymerase chain reaction, establish the existence of two distinct Hs PROS-30 mRNAs, differing in their 5'-noncoding regions and in the N-terminal six aa of their protein products.     

Isolation from adult human serum of four insulin-like growth factor (IGF) binding proteins and molecular cloning of one of them that is increased by IGF I administration and in extrapancreatic tumor hypoglycemia.

We have isolated four insulin-like growth factor binding proteins (IGFBPs) from adult human serum by insulin-like growth factor (IGF) I affinity chromatography and high performance liquid chromatography. A 36-kDa binding protein (BP), not digestible with N-glycanase, is increased in patients with extrapancreatic tumor hypoglycemia and during IGF I administration in healthy adults. Its 38 NH2-terminal amino acids are identical to those of an IGFBP sequence derived from a human cDNA that cross-hybridizes with the rat IGFBP-2 cDNA. With probes encoding a NH2-terminal, COOH-terminal, and a middle region of this protein we have obtained three cDNA clones from a Hep G2 cDNA library; one encodes human IGFBP-2, and the other two presumably represent unspliced heteronuclear and alternatively spliced mRNA, respectively. A 28-30-kDa IGFBP represents a novel BP species in human serum. Its 30 NH2-terminal amino acids are not homologous to IGFBP-1, -2, or -3. It is not digestible with N-glycanase and does not bind 125I-IGF I. The NH2-terminal sequences of a 42/45- and a 31-kDa IGFBP are identical to that of human IGFBP-3. The 42/45-kDa proteins are two glycosylation variants of BP-3. The 31-kDa protein presumably is a degradation product of BP-3 that lacks the COOH terminus. It is likely that the different IGFBPs modulate auto-/paracrine and endocrine effects of IGFs on growth and metabolism in a different and specific manner.     

Nucleolar proteins identified in human cells as antigens by sera from dogs with autoimmune disorders

In the course of a systematic screening of sera from dogs suffering from autoimmune disorders, three sera were shown by indirect immunofluorescence to characteristically label the nucleoli and nucleoplasm of human cell lines (Hep-2 and HeLa). This pattern of staining persisted throughout the cell cycle, except for mitosis when the fluorescence was localized in extrachromosomal areas. By immunoblotting nuclear and subnuclear fractions, three polypeptides of 110,000, 95,000, and 45,000 Da apparent molecular weight were identified, which reacted with all three sera. By means of affinity purification, it was shown that an antibody specific for any one of the three proteins also reacts with the two others. This antigenic cross-reactivity suggested regions of structural homology shared by the three proteins. Indeed, treatment of nucleoli with high concentrations of DNase I containing residual proteolytic activity resulted in the disappearance of the 110- and 95-kDa proteins and the concomitant appearance of a doublet of 45-kDa proteins. Subnuclear localization studies indicated that all three polypeptides were located in both nucleoli and nucleoplasm. Significantly, the 110-kDa protein differs from the major nucleolar protein, nucleolin, by its electrophoretic mobility in two-dimensional gels, its location in nucleoli and in nucleoplasm, its absence in nucleolar organizer regions of chromosomes, and its differential solubility of DNase I. Therefore, the three antigenically related species reported in this study constitute a new class of nucleolar proteins.     

Developmental modulation of embryonic cardiac myocyte adhesion to cardiac collagens in vitro

The goal of this investigation is to identify molecules that mediate embryonic cardiac myocyte adhesion during chick cardiac morphogenesis. The assay used employs culturing embryonic myocytes on substrata containing embryonic heart proteins separated by molecular weight. This assay shows that embryonic myocytes from 10- to 14-day-old embryos will bind to 140,000 and 128,000 Da proteins present in embryonic hearts and do not require Mg²⁺ or Ca²⁺ for adhesion. Myocytes from embryos younger than 10 days or older than 14 days display little or no binding. Embryonic heart flbroblasts collected at these same ages do not bind to these proteins. The 140- and 128-kDa proteins were found to copurify in extraction procedures for procollagens. Amino acid analysis shows that both proteins contain high glycine and hydroxyproline, indicating that they are collagens. However, glycine and imino acid levels are low relative to other known collagens, indicating a nonhelical domain present in each molecule and most closely resembled levels present in procollagens. Immunoblots show that antisera to chick collagen type I recognizes the 128-kDa protein while anti-collagen type III recognizes the 140-kDa protein. Monoclonal antibodies to the amino terminal propeptide of collagen type I recognize the 128-kDa protein in immunoblotting procedures. Embryonic chick myocytes bind to 140/128 kDa proteins present in extracts of sympathetic trunk, although they do not bind to 140/128 kDa proteins in embryonic tendon. The findings thereby indicate that forms of type III and type I collagens in embryonic heart support direct adhesion of embryonic myocytes for a restricted period of cardiac myogenesis and that these proteins differ from collagen types I and III present in other tissues and from fully processed collagen types I and III.     

Characterization of proteins from the matrix of spicules from the alcyonarian, Lobophytum crassum

The organic matrix of spicules of the alcyonarian coral, Lobophytum crassum, was studied to investigate its molecular characteristics and functional properties. The shape of the spicules was identified using scanning electron microscopy. The soluble organic matrix comprised 0.03% of the spicule weight. The SDS-PAGE analysis of the preparation showed four protein bands with apparent molecular weights of 37, 48, 67 and 102 kDa. The 67- and 102-kDa proteins appeared to be calcium binding proteins, detected as radioactive bands by ⁴⁵Ca autoradiography. The 67-kDa protein appears to be glycosylated. The N-terminal amino acid sequence of the 67 kDa was determined; 7 of 20 residues were acidic. A database search for homologous proteins did not give a clear indication of the function of the 67-kDa protein. The isolated organic matrix possesses carbonic anhydrase activity which functions in calcium carbonate crystal formation, indicating that organic matrix is not only structural protein but also a catalyst. An interpretation of these results is that the spicule of alcyonarian corals has a proteinaceous organic matrix related to the calcification process.     

Identification of multiple cell adhesion receptors for collagen and fibronectin in human fibrosarcoma cells possessing unique alpha and common beta subunits

Using monoclonal antibody technology and affinity chromatography we have identified four distinct classes of cell surface receptors for native collagen on a cultured human fibrosarcoma cell line, HT-1080. Two classes of monoclonal antibodies prepared against HT-1080 cells inhibited adhesion to extracellular matrix components. Class I antibodies inhibited cell adhesion to collagen, fibronectin, and laminin. These antibodies immunoprecipitated two noncovalently linked proteins (subunits) with molecular masses of 147 and 125 kD, termed alpha and beta, respectively. Class II antibodies inhibited cell adhesion to native collagen only and not fibronectin or laminin. Class II antibodies immunoprecipitated a single cell surface protein containing two noncovalently linked subunits with molecular masses of 145 and 125 kD, termed alpha and beta, respectively. The two classes of antibodies did not cross-react with the same cell surface protein and recognized epitopes present on the alpha subunits. Pulse-chase labeling studies with [35S]methionine indicated that neither class I nor II antigen was a metabolic precursor of the other. Comparison of the alpha and beta subunits of the class I and II antigens by peptide mapping indicated that the beta subunits were identical while the alpha subunits were distinct. In affinity chromatography experiments HT-1080 cells were extracted with Triton X-100 or octylglucoside detergents and chromatographed on insoluble fibronectin or native type I or VI collagens. A single membrane protein with the biochemical characteristics of the class I antigen was isolated on fibronectin-Sepharose and could be immunoprecipitated with the class I monoclonal antibody. The class I antigen also specifically bound to type I and VI collagens, consistent with the observation that the class I antibodies inhibit cell adhesion to types VI and I collagen and fibronectin. The class II antigen, however, did not bind to collagen (or fibronectin) even though class II monoclonal antibodies completely inhibited adhesion of HT-1080 cells to types I and III-VI collagen. The class I beta and II beta subunits were structurally related to the beta subunit of the fibronectin receptor described by others. However, none of these receptors shared the same alpha subunits. Additional membrane glycoprotein(s) with molecular mass ranges of 80-90 and 35-45 kD, termed the class III and IV receptors, respectively, bound to types I and VI collagen but not to fibronectin. Monoclonal antibodies prepared against the class III receptor had no consistent effect on cell attachment or spreading, suggesting that it is not directly involved in adhesion to collagen-coated substrates.(ABSTRACT TRUNCATED AT 400 WORDS)     

The RRM protein NonA from Drosophila forms a complex with the RRM proteins Hrb87F and S5 and the Zn finger protein PEP on hnRNA

The RRM protein NonA, an ubiquitous nuclear protein present in puffs on polytene chromosomes, has been immunopurified as a RNA-protein complex from Drosophila Kc cells. Three other proteins present in the complex have been identified: X4/PEP (protein on ecdysone puffs), a 100-kDa zinc finger RNA-binding protein; the 70-kDa S5 protein, an as yet uncharacterized RNA-binding protein; and P11/Hrb87F, a 38-kDa RRM protein homologous to hnRNP protein A1 from mammals. Monoclonal antibodies against any of the protein components coprecipitate all four proteins although at different ratios. NonA does not coprecipitate with the hrp40 hnRNP proteins and immunolocalizes in a pattern distinct of major hnRNP proteins. Like NonA, X4/PEP, S5, and P11/Hrb87F are present on active sites on polytene chromosomes. The precipitated NonA complex is enriched for certain protein encoding RNAs, notably, histone H3 and H4 RNA.     

Identification of a novel glycoprotein (AGp110) involved in interactions of rat liver parenchymal cells with fibronectin

We have identified an integral membrane glycoprotein in rat liver that mediates adhesion of cultured hepatocytes on fibronectin substrata. The protein was isolated by affinity chromatography of detergent extracts on wheat germ lectin-Agarose followed by chromatography of the WGA binding fraction on fibronectin-Sepharose. The glycoprotein (AGp110), eluted at high salt concentrations from the fibronectin column, has a molecular mass of 110 kD and a pI of 4.2. Binding of immobilized AGp110 to soluble rat plasma fibronectin required Ca2+ ions but was not inhibited by RGD peptides. Fab' fragments of immunoglobulins raised in rabbits against AGp110 reversed the spreading of primary hepatocytes attached onto fibronectin-coated substrata, but had no effect on cells spread on type IV collagen or laminin substrata. The effect of the antiserum on cell spreading was reversible. AGp110 was detected by immunofluorescence around the periphery of the ventral surface of substratum attached hepatocytes, and scattered on the dorsal surface. Immunohistochemical evidence and Western blotting of fractionated liver plasma membranes indicated a bile canalicular (apical) localization of AGp110 in the liver parenchyma. Expression of AGp110 is tissue specific: it was found mainly in liver, kidney, pancreas, and small intestine but was not detected in stomach, skeletal muscle, heart, and large intestine. AGp110 could be labeled by lactoperoxidase-catalyzed surface iodination of intact liver cells and, after phase partitioning of liver plasma membranes with the detergent Triton X-114, it was preferentially distributed in the hydrophobic phase. Treatment with glycosidases indicated extensive sialic acid substitution in at least 10 O-linked carbohydrate chains and 1-2 N-linked glycans. Immunological comparisons suggest that AGp110, the integrin fibronectin receptor and dipeptidyl peptidase IV, an enzyme involved in fibronectin-mediated adhesion of hepatocytes on collagen, are distinct proteins.     

Adhesion site composition of murine fibroblasts cultured on gelatin-coated substrata

Fibroblasts in vivo adhere to a collagenous extracellular matrix. We present here a combined morphological and biochemical analysis of the adhesion sites of fibroblast-like cells cultured in vitro on gelatin-coated plastic, for comparison with earlier model studies using serum (plasma-fibronectin [pFn])-coated plastic. Scanning electron microscopy shows that cell adhesion to the gelatin is quite similar to that on plastic, but with some morphological differences reminiscent of those caused by higher concentrations of fibronectin adsorbed to the substratum. Measurement using 125I-radiolabeled pFn shows the level of substratum-bound pFn adsorbed from serum in the growth medium is, however, comparable on gelatin or plastic; thus, differences due to pFn must be attributed to the quality of the adsorbed protein; not its absolute quantity. Gel electrophoretic analysis of cellular adhesion sites formed on the two substrata shows their compositions to be qualitatively similar, suggesting again that the same fundamental adhesion processes are involved. However, three protein bands do change; notably, cellular fibronectin is increased on gelatin. These three proteins are also the most resistant to saline extraction, suggesting their intrinsic importance in the adhesion sites. The nature of the growth substratum thus appears to modulate a fundamentally unvarying morphology and adhesion site composition of the cells that adhere to it.     

Analysis of heterogeneity of human keratinocytes interacting with immobilized fibronectin and collagenes I and IV types

The concept that stem cells form an independent subpopulations of somatic cells assumes the heterogeneity of cellular populations in adult tissues. As skin keratinocytes have natural affinity to extracellular matrix proteins, we made an attempt to reveal subpopulations of these cells depending on the time of their adhesion to substrates of collagen I and IV types and fibronectin. After selection for 10, 20 and 30 min the keratinocytes were cultivated for 24 h. The area of cell projection on a substrate and the spreading coefficient were measured (Kuzminykh, Petrov, 2004; Petrov et al., 2007). In 24 h statistically reliable morphological differences between the cells depending on the substratum were found. The size of the cells growing on collagen I type was twice as large as that of the cells cultivated on collagen IV type or in fibronectin. Irrespective of the substratum, up to 60-65% of the cells had a rounded form. The cultivation on collagens revealed the heterogeneity of keratinocytes both in the control cultures and under selection by adhesion time, while the cells grown on fibronectin behaved as a homogeneous population. These results suggest that, contrary to fibronectin, collagens stabilize some physiological states of keratinocytes corresponding to their interaction with extracellular matrix proteins in the organism.     

The RRM Protein NonA from Drosophila Forms a Complex with the RRM Proteins Hrb87F and S5 and the Zn Finger Protein PEP on hnRNA

The RRM protein NonA, an ubiquitous nuclear protein present in puffs on polytene chromosomes, has been immunopurified as a RNA–protein complex from Drosophila Kc cells. Three other proteins present in the complex have been identified: X4/PEP (protein on ecdysone puffs), a 100-kDa zinc finger RNA-binding protein; the 70-kDa S5 protein, an as yet uncharacterized RNA-binding protein; and P11/Hrb87F, a 38-kDa RRM protein homologous to hnRNP protein A1 from mammals. Monoclonal antibodies against any of the protein components coprecipitate all four proteins although at different ratios. NonA does not coprecipitate with the hrp40 hnRNP proteins and immunolocalizes in a pattern distinct of major hnRNP proteins. Like NonA, X4/PEP, S5, and P11/Hrb87F are present on active sites on polytene chromosomes. The precipitated NonA complex is enriched for certain protein encoding RNAs, notably, histone H3 and H4 RNA.