Differential expression of laminin genes in early chick embryo.

The expression patterns of laminin alpha1 and beta1 genes were examined by In situ hybridization of their mRNAs in the early chick embryo from the blastoderm at stage X (morula) to the 10-somite stage. The laminin alpha1 and beta1 transcripts were found in abundance in the chick blastoderm at stage X before initiation of synthesis of the protein. Laminin polypeptides were detected shortly thereafter in embryos at stage XIII (blastula). The expression of the laminin transcripts was intense in the epiblast and in the hypoblast of embryos at stage XIII. During gastrulation (stage HH3-4), the laminin (alpha1 and beta1 cRNAs gave strong signals in the cells ingressing through the primitive streak, in the migrating mesenchymal cells and the cells of the lower layer. The expression of laminin alpha1 and beta1 genes was restricted to specific cell populations later in development. At the neurula stage (stage HH5-6), the expression of laminin transcripts was low in epithelial ectoderm and strong in chordamesoderm neural ectoderm and may implicate important developmental roles for laminin in the morphogenetic movements of neural plate bending during primary neurulation. At the 10-somite stage (stage HH10-11), the (alpha1 and beta1 cRNAs gave no signals in the neural tube, notochord, and ectoderm. The alpha1 and beta1 cRNAs gave strong signals in neural crest cells and this may indicate that the neural crest cells can produce laminin. The alpha1 cRNAs gave strong signals in the dermamyotome and no signal in the sclerotome of somites, and intense signals in the pronephric tubules. The laminin expression pattern in somites may show transient expression of the alpha1 and/or expression of a distinct alpha1 isoform in the sclerotome. The selective expression of laminin alpha1 and beta1 subunits which shows a developmentally regulated, tissue specific distribution suggests potential roles for different members of the same subfamily of genes in the developing chick embryo.

Domain-specific interactions between entactin and neutrophil integrins. G2 domain ligation of integrin alpha3beta1 and E domain ligation of the leukocyte response integrin signal for different responses.

Extracellular matrix proteins activate neutrophils to up-regulate many physiologic functions that are necessary at sites of tissue injury. To elucidate the ligand-receptor interactions that mediate these functions, we examined neutrophil activation by the basement membrane protein, entactin. Entactin is structurally and functionally organized into distinct domains; therefore, we utilized glutathione S-transferase -fusion proteins encompassing its four major domains, G1, G2, E, and G3, to assess interactions between entactin and neutrophil integrin receptors. We show that the E domain, which contains the single RGD sequence of entactin, is sufficient for ligation of the beta3-like integrin, leukocyte response integrin, and signaling for chemotaxis. Moreover, the G2 domain signals for stimulation of Fc receptor-mediated phagocytosis via ligation of alpha3beta1. This receptor-ligand interaction was revealed only after stimulation of neutrophil by immune complexes or phorbol esters. Interestingly, the E domain does not enhance phagocytosis, and the G2 domain is not chemotactic. Furthermore, cleavage of entactin with the matrix metalloproteinase, matrilysin, liberates peptides that retain E domain-mediated chemotaxis and G2 domain-mediated enhancement of phagocytosis. These studies indicate that multiple domains of entactin have the ability to ligate individual integrins expressed by neutrophils and to activate distinct functions.

Human trophoblast cell adhesion to extracellular matrix protein, entactin.

PROBLEM: Trophoblast interaction with endometrial extracellular matrix (ECM) is crucial during human embryo implantation and placentation. Entactin, a ubiquitous basement membrane glycoprotein, plays a central role in ECM assembly, cell attachment, and chemotaxis. The present study was conducted to examine the possible role of entactin in promoting human trophoblast adhesion. METHODS: Using an extended life span first trimester trophoblast cell line HTR-8/SVneo (HTR) and a cell adhesion assay, we measured the adherence of human first trimester trophoblasts to recombinant entactin and its domains. Also, we used flow cytometry and indirect immunofluorescence to detect the presence of integrins that may be involved in human trophoblast-entactin interaction; these methods were used to analyze HTR cells, as well as tissue sections and freshly isolated human trophoblasts from first trimester and term placenta. RESULTS: We found that first trimester trophoblast cells were highly adherent to entactin and its E and G2 domains but not to G1 or G3 domains. Using indirect immunofluorescence and flow cytometry, we found that both beta 1 and beta 3 integrin subunits were expressed on the surface of HTR trophoblast cells adhering to entactin; in contrast, beta 2 and beta 4 integrin subunits were not detected. In addition, we found that alpha v beta 3 was expressed on freshly isolated villous cytotrophoblasts and cytotrophoblast and syncytiotrophoblasts in tissue sections from term placenta. The beta 3 integrin subunit was expressed in cytotrophoblasts and syncytiotrophoblasts in villi of first trimester placental tissue sections. CONCLUSION: Recombinant entactin promotes human trophoblast cell adhesion through both its E and G2 domains and these specific adhesive interactions may be mediated by beta 1 and/or beta 3 class integrins.

Two distinct cell attachment sites in entactin are revealed by amino acid substitutions and deletion of the RGD sequence in the cysteine-rich epidermal growth factor repeat 2.

The basement membrane glycoprotein, entactin, has previously been shown to promote cell attachment and chemotaxis. We have constructed a panel of glutathione S-transferase fusion proteins that encompasses the four major structural domains of entactin, G1, G2, E, and G3. These proteins have been synthesized in bacteria and purified by affinity chromatography. The connecting stalk of entactin, E, which contains four cysteine-rich EGF homology repeats and the integrin receptor RGD recognition sequence, has been modified by deletion of the RGD sequence and substituting glutamic acid for aspartic acid. Attachment assays reveal that the RGD sequence is one of the major cell attachment sites in entactin and that this sequence is recognized by the alpha v beta 3 integrin receptor. Analysis of cell attachment on mutant forms of full-length entactin expressed in the baculovirus expression system revealed a second attachment site that was independent of the RGD sequence. This second site was localized to a peptide of 39 amino acid residues in the second globular G2 domain of entactin. This peptide represents a cysteine-rich EGF repeat. Inhibition of cell attachment by anti-integrin receptor antibodies indicates that the second attachment site is recognized by a member of the beta 1 family of integrin receptors, possibly alpha 3 beta 1.

A novel role for alpha 3 beta 1 integrins in extracellular matrix assembly.

To study the biological role of alpha 3 beta 1 integrins in cell adhesion, migration, and in the deposition of extracellular matrix, we stably expressed the human alpha 3 integrin subunit in the alpha 4, alpha 5 integrin deficient CHO cell line B2. The expression of alpha 3 beta 1 integrins enhanced cell adhesion on entactin (also known as nidogen), but not on fibronectin. Using recombinant GST-fusion proteins that span the entire length of the entactin molecule, we located cell adhesive activity to the G2 domain of entactin. These results suggest that the alpha 3 beta 1 integrin functions as an adhesion receptor interacting with the G2 domain of entactin. On the other hand, the expression of alpha 3 beta 1 integrins did not confer the ability to migrate on entactin. Strikingly, the expression of alpha 3 beta 1 dramatically increased the deposition of entactin and fibronectin into the pericellular matrix. This was accompanied by increased binding activity of the 29 kDa amino-terminal domain of fibronectin. Thus, similar to alpha 5 beta 1 integrins, alpha 3 beta 1 integrins can play an important role in modulating the assembly of pericellular matrices. However, unlike fibronectin deposition supported by alpha 5 beta 1, alpha 3 beta 1 supported fibronectin deposition into pericellular matrix was not inhibited by antibodies binding to the RGD containing cell adhesion domain of fibronectin, demonstrating that the two processes are mechanistically distinct. The role of alpha 3 beta 1 in pericellular matrix assembly potentially implicates this receptor in the assembly and/or recognition of entactin-containing pericellular matrices, an observation consistent with its apparent role in the renal glomerulus of the mammalian kidney.

Exon organization of the mouse entactin gene corresponds to the structural domains of the polypeptide and has regional homology to the low-density lipoprotein receptor gene.

Entactin is a widespread basement membrane protein of 150 kDa that binds to type IV collagen and laminin. The complete exon-intron structure of the mouse entactin gene has been determined from lambda genomic DNA clones. The gene spans at least 65 kb and contains 20 exons. The exon organization of the mouse entactin gene closely corresponds to the organization of the polypeptide into distinct structural and functional domains. The two amino-terminal globular domains are encoded by three exons each. Single exons encode the two protease-sensitive, O-glycosylated linking regions. The six EGF-like repeats and the single thyroglobulin-type repeat are each encoded by separate exons. The carboxyl-terminal half of entactin displays sequence homology to the growth factor-like region of the low-density lipoprotein receptor, and in both genes this region is encoded by eight exons. The positions of four introns are also conserved in the homologous region of the two genes. These observations suggest that the entactin gene has evolved via exon shuffling. Finally, several sequence polymorphisms useful for gene linkage analysis were found in the 3' noncoding region of the last exon.

Entactin gene expression in normal and fibrotic rat liver and in rat liver cells.

BACKGROUND: Entactin, a constituent of basement membranes, is a sulfated glycoprotein with binding sites for laminin, collagen type IV, fibronectin, and cell surfaces. As it is known that excess matrix deposition and sinusoidal basement membrane formation is a central characteristic of liver fibrogenesis, we investigated whether the entactin gene is expressed in normal and in damaged rat liver and which cell types are able to express this gene. In addition, we were interested in the cellular origin and time course of laminin synthesis, a matrix protein closely associated with entactin. EXPERIMENTAL DESIGN: Entactin gene expression was analyzed in normal, acutely and chronically damaged rat livers (CCl4-model) by immunohistochemistry and in situ detection of specific transcripts. Rat fat-storing cells (FSC) (Ito), hepatocytes, Kupffer cells, liver endothelial cells, arterial smooth muscle cells (SMC), and skin fibroblasts (SF) were isolated according to standard techniques. Entactin gene expression in cultured cells was examined by sodium dodecyl sulfate-polyacrylamide gel electrophoresis analysis of immunoprecipitates, Northern blot analysis, and immunocytochemistry. RESULTS: In normal liver, entactin was detected in the vessel walls as continuous deposits and in a spot-like fashion along the sinusoids. Entactin was detectable among the cells of the inflammatory infiltrates of acutely damaged liver and in connective tissue septa, in the walls of newly formed vessels and bile ducts of fibrotic liver. Laminin distribution in the vessels was similar, but it was additionally present in the space of Dissé of damaged liver. By in situ hybridization, few entactin-positive cells were found in normal liver sections. Strongly positive cells were scattered over the injured parenchyma of acutely and chronically damaged livers. Northern blot analysis of total RNA extracted from normal and damaged liver tissue showed a distinct increase of entactin specific transcripts during development of fibrosis. Hybridization of total RNA from cultured FSC, hepatocytes, Kupffer cells, endothelial cells, SMC, and SF revealed entactin specific mRNA in FSC, SMC, SF, and endothelial cells; laminin mRNA was found in FSC and SF. Synthesis and secretion of both proteins were found in FSC, SMC and SF. Entactin and laminin gene expression increased in parallel to FSC during time in culture. CONCLUSIONS: Among the main liver cells, FSC show the highest entactin gene expression and might therefore play the dominant role in the synthesis of this protein in normal and fibrotic liver. However, endothelial cells and liver myofibroblasts could also contribute to entactin production.

The binding of fibronectin to entactin is mediated through the 29 kDa amino terminal fragment of fibronectin and the G2 domain of entactin.

Previous work has shown that fibronectin and entactin, an ubiquitous basement membrane glycoprotein, co-localize in the extracellular matrix of the embryonal carcinoma-derived 4CQ cell. Glutathione-S-transferase (GST) fusion proteins containing different domains of entactin have been obtained in the pGEX3X expression vector. These fusion proteins, GST-G1, GST-G2, GST-E and GST-G3, were purified with a glutathione affinity column. By using a solid phase binding assay, it was shown that the 125I-labeled 29 kDa amino terminal fragment of bovine fibronectin bound specifically to the immobilized GST-G2 fusion protein but not to GST-G1, GST-E, and GST-G3. Half saturation for binding of the 29 kDa fibronectin fragment to the immobilized GST-G2 fusion protein was obtained at a concentration of approximately 5 nM. It is suggested that the strong association between GST-G2, which contains the second globular domain of entactin, and the 29 kDa amino terminal fragment of fibronectin may be involved in the assembly of certain types of extracellular matrices.

Effects of laminin monoclonal antibodies on the development of cultured rat embryos.

Whole rat embryos (9.5 days of gestation) were exposed to six different monoclonal antibodies to laminin during 48 hr of culture. Four (LAM I, LAM V, 5A2, 9D2) of the six were teratogenic or lethal and two (LAM II, 5D3) were not toxic at comparable levels. Teratogenicity and lethality were not related to antibody level, subclass or affinity for whole laminin. Indirect immunofluorescence studies using mouse embryo sections revealed that the toxic antibodies bound in a diffuse manner, while the nontoxic antibodies showed distinct labeling of tissues. These observations suggest that previous varied responses seen in cultured rat embryos exposed to laminin antibodies obtained from humans, monkeys, and rats were the result of differences in the epitope specificity of those antibodies.

Migratory interaction of amphibian epidermal cells with components of the basement membrane.

In adult newts, basal epidermal cells adjacent to a fresh wound move toward the damaged area by migrating over the epidermal basement membrane. In an attempt to determine which basement membrane components mediate this migration, small pieces of glass coated with various natural matrices, purified proteins, or fragments of proteins were implanted into skin wounds such that epidermal cells attempting to form a wound epithelium would encounter the implants. Laminin derived from a cell line (M1536-B3) that produces no type IV collagen was inactive as a migration substrate. Migration on recombinant entactin was somewhat better than on laminin but was still only approximately 14% of that on type I collagen. M15 matrix, a laminin and entactin-containing product of M1536-B3 cells, was no better than entactin alone. Type IV collagen was an excellent substrate, producing slightly more migration than corresponding concentrations of type I collagen at nearly all concentrations tested. Migration on type IV lacking the NC1 domain was at least as good as on intact type IV. All the activity in type IV was present in a 95 kD fragment (alpha 1(IV)95) from the carboxy terminal two-thirds of the alpha 1 chain. Approximately 60% of the activity on alpha 1(IV)95 was obtained on implants coated with a 110 amino acid fragment of the alpha 1 chain derived from the carboxy terminal half of alpha 1(IV)95. Adding the synthetic peptide, arg-gly-asp-ser (RGDS) to the medium, blocked migration on fibronectin-coated implants but had no effect on implants coated with type IV, suggesting that migration on type IV involves different cell surface receptors than those mediating migration over fibronectin. Matrigel, a commercial product containing most basement membrane components, was a poor migration substrate. Thus if type IV mediates basal cell migration toward a wound in vivo, there may have to be some alterations in basement membrane structure to allow epidermal receptors to access type IV active site(s).

Characterization of the 5' end of the mouse Ent gene encoding the basement membrane protein, entactin.

Entactin (Ent) is a 150-kDa basement membrane glycoprotein that forms a complex with laminin and also binds to type-IV collagen. For the initial characterization of the 5' end of the mouse Ent gene, we isolated genomic clones that encompass the first three exons of the gene. A 3.5-kb EcoRI fragment at the 5' end of the gene was sequenced and shown to contain 1226 bp of the 5'-flanking DNA, the 260-bp first exon, and 2060 bp of the first intron. The second exon is separated from the first exon by an intron that spans greater than 18 kb. The major transcription start point (tsp) was mapped to 35 nucleotides upstream from the translation start codon. The 5'-flanking DNA contains a putative TATA box, two CAAT boxes and two GC boxes. Nine potential AP-2- and two potential AP-1-binding sites were found in the upstream region and the first intron. The first 248 bp of the promoter region are G+C rich, and they are 65% identical to the promoter of human Ent. Fragments of the 5'-flanking DNA linked to a reporter gene were shown to have promoter activity in transient transfection assays.

Appearance and distribution of entactin in the early chick embryo.

Entactin is a sulfated glycoprotein of basement membranes and recent data indicate that it may play a major role in extracellular matrix (ECM) assembly and in modulating the activities of the other molecular components. We investigated the time of appearance and subsequent distribution of entactin during the earliest stages of morphogenesis and its involvement in the first major cellular migrations and interactions in the chick embryo. Entactin is first detected in the epiblast and in the hypoblast at the blastula stage. The accumulating ECM displays intense presence of entactin in the space between the epiblast and the hypoblast at late blastula. Entactin is increasingly abundant in the neural plate and in the ECM and also at least transiently in many mesodermal tissues such as the notochord, the developing heart and somites in the early chick embryo. Immunogold labeling revealed a punctate pattern of entactin distribution in the ECM during the gastrula, neurula and at later stages and at all levels within the embryo. Because of its early appearance in more than one germ layer, entactin may be important in the formation of most embryonic structures. Entactin is detected at the same developmental time and co-localizes with laminin. Antibodies to entactin do not interfere with triggering of the first major cell movements but perturb directional migration of these cells. It would seem that entactin plays a functional role in the directed migration of cells and does not seem to affect cell adhesion during the period of the first morphogenetic events in the early chick embryo.

Recombinant entactin promotes mouse primary trophoblast cell adhesion and migration through the Arg-Gly-Asp (RGD) recognition sequence.

In vitro culture of mouse blastocysts during the period coinciding with implantation has revealed that primary trophoblast cells can adhere and migrate in serum-free medium when provided with certain extracellular matrix components, including fibronectin and laminin. Tightly associated with laminin is the glycoprotein, entactin, that may play an important role in basement membrane assembly and cell attachment. Mouse blastocysts were studied using this in vitro model to determine whether entactin was capable of mediating trophoblast invasive activity. Although entactin has never been shown to promote cell migration, we report here that recombinant entactin supported blastocyst outgrowth in a dose-dependent manner, with a maximal effect at 20-50 micrograms/ml. The ability of trophoblast cells to adhere and migrate on entactin was specifically inhibited by anti-entactin antibody, but not by antibodies raised against laminin. The synthetic peptide, Gly-Arg-Gly-Asp-Ser-Pro, that contains the Arg-Gly-Asp (RGD) integrin recognition site, reversibly inhibited entactin-mediated blastocyst outgrowth in a dose-dependent manner, but had no effect on laminin-mediated outgrowth. The synthetic peptide, Gly-Phe-Arg-Gly-Asp-Gly-Gln, that comprises the actual RGD-containing sequence within entactin, promoted trophoblast outgrowth when immobilized on the substratum. Furthermore, a mutated recombinant entactin, altered to contain a Glu in place of Asp at the RGD site, provided no trophoblast cell adhesive activity. We conclude that entactin promotes trophoblast outgrowth through a mechanism mediated by the RGD recognition site, and that it may play an important role during invasion of the endometrial basement membrane at implantation.

Embryonal carcinoma and the basement membrane glycoproteins laminin and entactin.

The mouse embryonal carcinoma lines PCC4-F and F9 have played important roles in the isolation and characterization of the two ubiquitous basement membrane proteins, laminin and entactin. The contributions of these cells to our work on extracellular matrices are briefly summarized. The in vitro differentiation of PCC4-F gives rise to a multiplicity of cell types. Two of these cell types have been propagated as cell lines. One of these, M1536-B3, synthesizes and deposits copious quantities of extracellular matrix glycoproteins, which led to the initial discovery and characterization of laminin and entactin. In addition, M1536-B3 provides a model system for analyzing the assembly of laminin and the laminin-entactin complex and for manipulating extracellular matrix structure and composition. The other cell line, 4CQ, synthesizes a matrix consisting of fibronectin and entactin. F9 cells differentiate to endodermal cells in response to retinoic acid and dibutyryl cyclic AMP (Strickland and Mahdavi, Cell 15: 393-402, 1978). The differentiated cells synthesize basement membrane components and provided the probes for the cDNA cloning of entactin and the three chains of laminin. The F9 cells have been widely employed to examine the regulation of expression of the laminin and entactin genes.

Degradation of entactin by matrix metalloproteinases. Susceptibility to matrilysin and identification of cleavage sites.

Entactin is the basement membrane protein which bridges laminin and type IV collagen. Entactin is known to be degraded by serine proteinases, but its susceptibility to matrix metalloproteinases has not been determined. We have studied the capacity of three matrix metalloproteinases (interstitial collagenase, 92-kDa gelatinase, and matrilysin) to degrade entactin. While all three metalloenzymes cleaved entactin, matrilysin was approximately 100-fold as effective as collagenase and 600-fold as effective as 92-kDa gelatinase. The Km of matrilysin for entactin was 8.9 x 10(-7) M. A Vmax of 21 molecules of entactin degraded/molecule of matrilysin/min at 37 degrees C was observed. An Arrhenius plot relating matrilysin's catalytic activity to temperature was linear from 15 to 37 degrees C and indicated an activation energy of 10,060 calories/mol. Matrilysin produced multiple, but distinct, cleavages in entactin resulting in peptide fragments ranging from 115 to 29 kDa. The precise sites of cleavage of six fragments were determined by Edman degradation. Cleavage sites consistently occurred amino-terminal to leucine or isoleucine. These data indicate that entactin is a substrate for matrix metalloproteinases. The effectiveness of matrilysin is noteworthy, however, particularly in relation to the minimal ability of other much more well described matrix metalloproteinases to attack this substrate. Our results suggest a potentially important role for matrilysin in disruption of basement membranes by tumor or inflammatory cells.

Biological functions of entactin.

Entactin is a sulfated multidomain glycoprotein component of basement membranes. The molecule consists of 1217 amino acids which are organized into two terminal globular domains linked by a rod-like structure largely composed of four EGF- and one thyroglobulin-like cysteine-rich homology repeats. Entactin binds to laminin, collagen IV, fibrinogen, and fibronectin. In the parietal endoderm M1536-B3 cell line, the laminin-entactin complex is formed intracellularly and transported in membrane enclosed vesicles to the extracellular compartment. Transfection of human choriocarcinoma JAR cells, which do not synthesize entactin, with entactin cDNA results in the synthesis and insertion of entactin into the extracellular matrix where it becomes associated with laminin and collagen IV. Indirect immunofluorescent staining also reveals that entactin co-localizes with fibronectin in the extracellular matrix of the embryonal carcinoma-derived 4CQ cell line. These observations suggest that entactin plays an important role in the assembly and properties of diverse extracellular matrices. In addition, entactin binds to immobilized fibrinogen, and more specifically, to the A alpha and B beta chains. The binding of radiolabeled entactin to immobilized fibrinogen is not dependent on metal ions, and is inhibited by antibodies against either fibrinogen or entactin, soluble fibrinogen, and unlabeled entactin. This interaction combined with the chemotactic and phagocytic promoting activities of entactin may be important in hemostasis and would healing.

Entactin stimulates neutrophil adhesion and chemotaxis through interactions between its Arg-Gly-Asp (RGD) domain and the leukocyte response integrin.

Entactin is an integral component of basement membranes that plays a major role in basement membrane assembly through its ability to bind avidly to both laminin and type IV collagen. Because neutrophil (PMN) interactions with entactin have not been examined, we investigated the ability of natural and recombinant entactin to mediate PMN adhesion and chemotaxis. With both forms of entactin, we observed that entactin-coated surfaces promoted PMN adhesion and that entactin stimulated PMN chemotaxis. The increase in adhesion to entactin over control was two to threefold whereas the chemotactic response to 15 ng/ml (1 x 10(-10) M) entactin was equivalent to the chemotactic response elicited with 1 x 10(-8) M formyl-methionyl-leucyl-phenylalanine (fMLP). HL-60 cells, after differentiation with dimethylsulfoxide, also demonstrated adhesion and chemotaxis to entactin. A synthetic peptide of the Arg-Gly-Asp (RGD) domain in entactin, SIGFRGDGQTC (S-RGD), mediated PMN adhesion and chemotaxis, and preexposure of PMN to S-RGD blocked PMN adhesion and chemotaxis induced by entactin without diminishing the adhesive and chemotactic activities of fMLP. In contrast, preexposure to peptides SIGFRGEGQTCA or SIGFKGDGQTCA had no effect. The findings with synthetic peptides were confirmed with a recombinant entactin mutant in which aspartic acid at residue 674 was replaced with glutamic acid, thus converting the RGD sequence of entactin to RGE. RGE-entactin was neither adhesive nor chemotactic for neutrophils. Monoclonal antibodies to the leukocyte response integrin (LRI) and the integrin-associated protein blocked entactin-mediated adhesion and chemotaxis whereas monoclonal antibodies to beta 1 and beta 2 integrins had no effect and PMN from an individual with leukocyte-adhesion deficiency adhered normally to entactin-coated surfaces. These data demonstrate that entactin mediates biologically and pathologically important functions of PMN through its RGD domain and that LRI, which has been shown previously to mediate RGD-stimulated phagocytosis, is also capable of mediating RGD-stimulated PMN adhesion and chemotaxis.

Laminin B1 expression is required for laminin deposition into the extracellular matrix of PC12 cells.

The extracellular matrix of rat pheochromocytoma PC12 cells was shown by indirect immunofluorescence to consist of a network of fibronectin. The matrix did not contain laminin. The cells synthesized messenger RNA for fibronectin, laminin B2, and s-laminin but not for entactin or the B1 and A chains of laminin. Laminin B2 but not laminin B1 was detectable in the culture medium and in cell lysates. A full-length cDNA clone for the B1 chain of laminin was constructed in the plasmid p-444, which contains the neomycin-resistance marker and human beta-actin promoter. PC12 cells were transfected with this recombinant plasmid, and stable neomycin-resistant clones were isolated and characterized. Clones that synthesized laminin B1 messenger RNA were found to deposit a laminin-containing matrix. In many of these clones the deposition of the fibronectin matrix was greatly diminished. The laminin matrix was predominantly localized in the intercellular spaces forming a honeycomb pattern. The morphology of the laminin-synthesizing transfected cells was markedly different from the parental cells. The cells grew in tight clusters that were resistant to dissociating agents. It is concluded that the B1 chain of laminin contains information that is required for the formation of a stable laminin-containing extracellular matrix network either by interaction with cell surface receptors or other extracellular matrix components. Furthermore, expression of the laminin B1 gene may be a central regulatory point in determining extracellular matrix composition during embryogenesis.

High-level production of human alpha- and beta-globins in insect cells.

High-level production of human alpha- and beta-globins in cultured Spodoptera frugiperda (Sf-9) cells infected with recombinant baculoviruses is described. The expressed globins are produced to 70-140 mg protein/liter of cell culture or 5-10% of the total cellular protein. Two recombinant baculoviruses for alpha-globin, H alpha and H beta alpha, differ in their construction in that the 5'-untranslated region of the beta-globin gene is inserted 5' to the alpha-globin mRNA coding region in H beta alpha. This insertion results in a 40% increase in yield of alpha-globin over that of H alpha. Consistent with previous observations of the processing of recombinant proteins in Sf-9 cells, both alpha- and beta-globins expressed in Sf-9 cells are correctly processed to remove the initiating methionine from the amino termini of the globins. Sequencing of the expressed globins in Sf-9 cells confirms their identity with globins purified from human normal adult hemoglobin.

The expression of the genes for entactin, laminin A, laminin B1 and laminin B2 in murine lens morphogenesis and eye development.

The temporal expression of the genes for the excellular matrix proteins entactin and the A, B1, and B2 chains of laminin was examined in the eye of the developing mouse embryo by in situ hybridization of their messenger RNAs. Entactin messenger RNA was found in abundance in specific cells. In the 25 somite embryo entactin message was synthesized by mesenchymal cells and, at later stages, by hyalocytes and lens cells in addition. The message was not detectable in corneal epithelium at embryonic stages E15 and E18.5 and at birth but was present in adjacent stromal cells. At the 28 and 38 somite stages, before pigment granules interfered with the detection of silver grains, no entactin message was detected in pigmented epithelial cells, in contrast to the messages for laminin B1 and B2. Entactin was not found in the neural epithelium at any time during development. The distribution of the laminin B1, B2 and A chain messenger RNAs was distinctly different from that of entactin. In particular, during the early stages of development B1 and B2 messages were synthesized by ectodermal, lens, corneal, pigment epithelial and hyaloid cells. In the older embryos cells in the ganglion layer of the retina synthesized B1 and B2 messages but undetectable amounts of entactin or the A chain messages. In general the A chain message was in lower abundance throughout development. The distribution of laminin and entactin messages suggested that the extracellular matrices, which contained both proteins, can be derived either from a single cell type or from the contributions of multiple cell types. The data demonstrate the complexity of extracellular matrix synthesis and assembly in the diverse structures of the developing eye where the temporal expression of specific molecules are tailored to the specific developmental requirements of particular structures.