Potyvirus terminal protein VPg, effector of host eukaryotic initiation factor eIF4E.

Potyvirus RNA contains at the 5' end a covalently linked virus-encoded protein VPg, which is required for virus infectivity. This role has been attributed to VPg interaction with the eukaryotic translation initiation factor eIF4E, a cap-binding protein. We characterized the dissociation constants for the interaction of the potato virus Y VPg with different plant eIF4Es and its isoforms and mapped the eIF(iso)4E attachment region on VPg. VPg/eIF4E interaction results in the inhibition of cell-free protein synthesis, and we show that it stems from the liberation of the cap moiety from the complex with eIF4E. Since VPg does not attach the cap, it appears that VPg induces changes in the eIF4E structure, diminishing its affinity to the cap. We show here that the initiation complex scaffold protein eIF(iso)4G increases VPg interaction with eIF(iso)4E. These data together suggest similar cap and VPg interactions with eIF4E and characterize VPg as a novel eIF4E-binding protein, which inhibits host protein synthesis at a very early stage of the initiation complex formation through the inhibition of cap attachment to the initiation factor eIF4E.

Complete primary structure of the chicken alpha1(V) collagen chain.

Chicken alpha1(V) collagen cDNAs have been cloned by a variety of methods and positively identified. We present here the entire translated sequence of the chick polypeptide and compare selected regions to other collagen chains in the type V/XI family.

Schmid's metaphyseal chondrodysplasia mutations interfere with folding of the C-terminal domain of human collagen X expressed in Escherichia coli.

Human collagen X contains a highly conserved 161-amino acid C-terminal non-triple helical domain that is homologous to the C-terminal domain of collagen VIII and to the C1q module of the human C1 enzyme. We have expressed this domain (residues 545-680) in Escherichia coli as a glutathione S-transferase fusion protein. The purified fusion protein trimerizes spontaneously in vitro, and after thrombin cleavage, the purified C-terminal domain trimer (46.2 kDa) is extremely stable and trypsin-resistant. Mutations within the C-terminal domain have been observed in patients with Schmid's metaphyseal chondrodysplasia (SMCD). Some of these mutations (Y598D, G618V, W651X, or H669X; X is the stop codon) were constructed by site-directed mutagenesis. Each mutation had identical consequences regarding the fusion protein: 1) absence of trimeric formation, 2) copurification of the approximately 60-kDa GroEL chaperone protein, and 3) sensitivity of the monomeric fusion protein to trypsin digestion. These results show that the C-terminal domain of collagen X is sufficient to produce a very stable and compact trimer in the absence of collagen Gly-X-Y repeats. Moreover, mutations causing SMCD interfere in this system with the correct folding of the C-terminal domain. The existence of a similar mechanism in chondrocytes might explain the relative homogeneity of phenotypes in SMCD despite the diversity of mutations.

Identification and characterization of a heparin binding site within the NC1 domain of chicken collagen XIV.

Collagen XIV is known to bind to the dermatan sulfate chain of decorin and to the heparan sulfate chain of perlecan. To study its possible interaction with glycosaminoglycans, the NC1 domain of chicken collagen XIV was overproduced in E. coli. Purified NC1*(6-119)* appears poorly organized (the asterisks indicate the presence of extension sequences), but V8-protease generated fragments containing the 84-108 basic sequence tend to fold into alpha-helix. These fragments interact specifically with heparin, which induces an alpha-helical fold with a maximum effect for equimolar heparin/peptide ratio. These data demonstrate the existence of a glycosaminoglycan binding site in NC1.

Degradation of the COL1 domain of type XIV collagen by 92-kDa gelatinase.

Type XIV collagen is a newly described member of the fibril-associated collagens with interrupted triple helices (FACITs). Expression of this collagen has been localized to various embryonic tissues, suggesting that it has a functional role in development. All FACITs thus far described (types IX, XII, XIV, and XVI) contain a highly homologous carboxyl-terminal triple helical domain designated COL1. We have studied the capacity of various matrix metalloproteinases (interstitial collagenase, stromelysin, matrilysin, and 92-kDa gelatinase) to degrade the COL1 domain of collagen XIV. We found that only 92-kDa gelatinase cleaves COL1. Furthermore, digestion of whole native collagen XIV by the 92-kDa gelatinase indicates that this enzyme specifically attacks the carboxyl-terminal triple helix-containing region of the molecule. COL1 is cleaved by 92-kDa gelatinase at 30 degrees C, a full 5-6 degrees C below the melting temperature (Tm) of this domain; native collagen XIV is also degraded at 30 degrees C. In comparison to interstitial collagenase degradation of its physiologic native type I collagen substrate, the 92-kDa enzyme cleaved COL1 (XIV) with comparable catalytic efficacy. Interestingly, following thermal denaturation of the COL1 fragment, its susceptibility to 92-kDa gelatinase increases, but only to a degree that leaves it several orders of magnitude less sensitive to degradation than denatured collagens I and III. These data indicate that native COL1 and collagen XIV are readily and specifically cleaved by 92-kDa gelatinase. They also suggest a role for 92-kDa gelatinase activity in the structural tissue remodeling of the developing embryo.

Type XIV collagen is encoded by alternative transcripts with distinct 5' regions and is a multidomain protein with homologies to von Willebrand's factor, fibronectin, and other matrix proteins.

The combined nucleotide sequences of several overlapping cDNAs provide the first complete amino acid sequence of type XIV collagen. Independent confirmation of the deduced sequence is provided by amino acid sequencing of several tryptic peptides isolated from purified chicken skin type XIV collagen. Comparative analyses show that the amino-terminal non-triple-helical region of alpha 1(XIV) chains contains sequence motifs that are similar to alpha 1(IX) collagen, fibronectin type III repeats, and von Willebrand's factor A-domains. The results also strongly suggest that the alpha 1(XIV) collagen gene is identical to the gene encoding the matrix component previously named undulin. cDNAs covering the 5' region of alpha 1(XIV) mRNA fall into two classes with distinct sequences in their 5'-untranslated regions. We believe the two alternative sequences result from differential splicing of the primary transcript. Interestingly, one of the untranslated sequences shows a high degree of identity with the cis-regulatory translational control sequence in the 5'-untranslated region of a Drosophila ribosomal protein mRNA. We hypothesize therefore that the sequence in alpha 1(XIV) collagen may play a role in the control of alpha 1(XIV) protein synthesis.

Tissue-specific expression of type XIV collagen--a member of the FACIT class of collagens.

The collagens represent a highly diverse superfamily of extracellular matrix proteins that can be divided into several distinct families. One of the families, called FACIT (fibril-associated collagens with interrupted triple-helices) family, contains molecules that appear to be associated with cross-striated fibrils composed of members of the fibrillar collagen family. We have determined a portion of the primary structure of a recently discovered member of the FACIT family, chicken alpha 1(XIV) collagen, based on cloning and sequencing cDNAs. A synthetic oligopeptide from within the carboxy-terminal non-triple-helical domain of the alpha 1(XIV) chain has been used for generating specific polyclonal antibodies. The antiserum, PS1, recognizes a 220 kDa polypeptide in immunoblots of extracts of chicken skin, tendons, and cartilage. Sequencing of a tryptic peptide generated from purified, immunoreactive material, gives a sequence identical to that derived from cDNA sequencing, providing strong support for the type XIV-specificity of PS1. We have examined the expression of type XIV collagen in developing chick embryos by immunostaining of sections from 12-day-old embryos with PS1 and by Northern blot analysis of RNA from several tissues from both 12- and 17-day-old embryos. The results show that type XIV collagen is prevalent within relatively dense connective tissues such as dermis, tendons, perichondrium, perimysium, the stroma of lungs and liver, and blood vessels.

Cloning of a cDNA for a new member of the class of fibril-associated collagens with interrupted triple helices.

cDNA from embryonic chick skin has been isolated and characterized which encodes a novel member of the FACIT (fibril-associated collagen with interrupted triple helices) group whose other known members are collagen types IX and XII. Nucleotide sequence analysis of the cDNA, combined with characterization of a pepsin-resistant fragment of the protein from embryonic chick skin, demonstrates that the collagen chain is more closely related to the chain of type XII collagen than to those of type IX. It is most similar to a collagen, type XIV, recently identified in bovine skin. It is possible, therefore, that the cDNA codes for a chain of chicken type XIV collagen. From the additional data on molecular structure obtained by sequencing the cDNA, the FACIT family appears to consist of at least two classes of molecules: one of which contains the three chains of type IX collagen, and a second which includes the chains of collagen types XII and XIV.

Type XIV collagen, a new homotrimeric molecule extracted from fetal bovine skin and tendon, with a triple helical disulfide-bonded domain homologous to type IX and type XII collagens.

Previously undescribed disulfide-bonded collagenous pepsin-derived fragments have been isolated from fetal calf tendon and skin. One fragment, 10.5 kDa after reduction, was shown to be similar but distinct to the COL1 domain of the recently characterized type XII collagen (64% primary structure identity). The similarity includes important features such as size, location of the cysteine residues, and nature and position of an imperfection of the triple helix. From fetal calf skin, two approximately 34-kDa disulfide-bonded trimeric fragments were isolated in the unreduced form. Amino acid sequencing showed that one fragment contained solely the COL1 domain of type XII collagen while the other one only contained the COL1 domain of the new chain. Like type XII collagen, the new chain is therefore part of a homotrimeric molecule and should thus be considered as a distinct collagen type. We propose to call the molecule from which this fragment is derived, type XIV collagen, with a chain composition (alpha 1 (XIV]3. The presence of a domain similar to the COL1 domain of collagens types IX and XII suggests that type XIV collagen belongs to the group of fibril-associated collagens with interrupted triple helices (FACIT). Two other fragments, 13.5 and 17 kDa after reduction, were also purified. They were shown to contain the same triple helical domain with different pepsin cleavage sites at the amino terminus. Several tryptic peptides were sequenced, and the derived sequences could be aligned with the COL2 domain of type XII collagen or with flanking sequences in the NC2 and NC3 domains (61% sequence identity). These fragments are very likely to be also derived from type XIV collagen.

Fibril-associated collagens.

Many collagen fibrils have been shown to be heterotypic, i.e. composed of more than one collagen type. Fibrils containing type I collagen as the major constituent do also contain, at least in some tissues, type III and type V collagens. Fibrils containing type II collagen have been shown to also contain type XI collagen. The type I, II, III, V and XI collagen molecules are very similar and are clearly derived from a single ancestral gene. However their processings are not identical. While collagen types I and II have a N-propeptide which is cleaved for their insertion in the fibrils, collagen types V and XI keep a N-terminal extension which must include, based on the cDNA derived structures, a short triple helix and a globular domain. They are thought to contribute to the control of fibril lateral growth and diameter. Other collagens are associated with fibrils without having the long triple uninterrupted triple helix characteristic of collagen types I, II, III, V and XI. Type IX collagen has been shown to be covalently cross-linked to type II collagen and to lay at or near the surface of fibrils, with a triple helical arm projecting in the extrafibrillar space a globular N-terminal domain. Type XII collagen is found in type I collagen containing matrices and contains a triple helical domain homologous to the type IX COL1 domain. This suggests a similar function.(ABSTRACT TRUNCATED AT 250 WORDS)

Type XII collagen. A large multidomain molecule with partial homology to type IX collagen.

Three overlapping cDNAs encoding alpha 1 (XII) collagen have been isolated and sequenced. The DNAs define five sequence domains within the chain. Three domains are nontriple-helical; two are relatively short triple-helical regions. The amino acid sequences of tryptic peptides derived from 16- and 10-kDa pepsin-resistant fragments isolated from tendon extracts are in full agreement with the deduced sequences of the triple-helical regions. Two of the five sequence domains in alpha 1 (XII), one triple-helical and one nontriple-helical, show a high degree of similarity to regions in type IX collagen chains. In addition, examination of seven exons in the alpha 1 (XII) gene shows that the gene is, in part, similar to the structure of type IX collagen genes. Therefore, collagen types IX and XII are partially homologous. The alpha 1 (XII) sequence data predict an asymmetric structure for type XII collagen molecules, fully consistent with the rotary shadowing images. These images show a triple-helical 75-nm tail attached through a central globule to three finger-like structures, each 60 nm long (Dublet, B., Oh, S., Sugrue, S. P., Gordon, M. K., Gerecke, D. R., Olsen, B. R., and van der Rest, M. (1989) J. Biol. Chem. 264, 13150-13156).

Immunoidentification of type XII collagen in embryonic tissues.

We have generated a monoclonal antibody against a synthetic peptide whose sequence was derived from the nucleotide sequence of a cDNA encoding alpha 1(XII) collagen. The antibody, 75d7, has been used to identify the alpha 1(XII) chain on immunoblots of SDS-PAGE tendon extracts as a 220-kD polypeptide, under reducing conditions. Amino-terminal amino acid sequence analysis of an immunopurified cyanogen bromide fragment of type XII collagen from embryonic chick tendons gave a single sequence identical to that predicted from the cDNA, thus confirming that the antibody recognizes the type XII protein. Immunofluorescence studies with the antibody demonstrate that type XII collagen is localized in type I-containing dense connective tissue structures such as tendons, ligaments, perichondrium, and periosteum. With these data, taken together with previous results showing that a portion of the sequence domains of type XII collagen is similar to domains of type IX, a nonfibrillar collagen associated with cross-striated fibrils in cartilage, we suggest that types IX and XII collagens are members of a distinct class of extracellular matrix proteins found in association with quarter-staggered collagen fibrils.

The structure of avian type XII collagen. Alpha 1 (XII) chains contain 190-kDa non-triple helical amino-terminal domains and form homotrimeric molecules.

The monoclonal antibody 75d7, specific for type XII collagen (Sugrue, S.P., Gordon, M.K., Seyer, J., Dublet, B., van der Rest, M., and Olsen, B. R. (1989) J. Cell Biol., in press), was used to characterize the intact form of type XII collagen from chick embryo leg tendons. On an immunoblot of a 6% polyacrylamide gel of tendon extracts, one sharp band is recognized by the antibody at Mr = 220,000, while two fuzzy and poorly resolved bands are seen at Mr = 270,000 and Mr = 290,000. By immunoprecipitation of radiolabeled tendon culture media and electrophoresis of the precipitated material, bands with the same mobilities are observed, indicating that type XII collagen is not proteolytically processed in the extracellular space. Type XII collagen was extracted from tendons with 1 M NaCl in a Tris-HCl buffer and partially purified by concanavalin A-Sepharose and gel permeation chromatographies, using dot immunoblots to monitor the purification. Fractions highly enriched in bacterial collagenase-sensitive proteins with the same electrophoretic properties as type XII collagen were obtained. These fractions did not stain with Alcian blue and neither they nor the immunostained type XII collagen were affected by chondroitinase ABC digestion, indicating that type XII collagen is not a proteoglycan. A disulfide-bonded trimeric CNBr peptide was isolated by affinity chromatography on an antibody column and further purified by gel electrophoresis. Its NH2-terminal amino acid sequence was shown to be unique, demonstrating that type XII collagen is a homotrimer [alpha 1 (XII)]3. After bacterial collagenase digestion, both the immunopurified radiolabeled preparation and the purified tendon extract fraction showed by gel electrophoresis the presence of a large disulfide-bonded, 3 x 190-kDa, collagenase-resistant domain. Rotary shadowing and electron microscopy of the purified type XII fraction demonstrated that the molecule has the structure of a cross consisting of a 75 nm collagenase-sensitive tail, a central globule, and three 60 nm arms each ending in a small globule. After heat denaturation and renaturation, only a very large globule can be seen, attached to the triple helical tail. These results show that type XII collagen has a unique structure and is different from the other matrix constituents described so far.

Translocation and proteolytic processing of nascent secretory polypeptide chains: two functions associated with the ribosomal domain of the endoplasmic reticulum.

Rat liver microsomes were subfractionated by isopycnic centrifugation in sucrose gradient. The subfractions were assayed for translocation and proteolytic processing of nascent polypeptides in a rabbit reticulocyte lysate programmed with total RNA from human term placenta. The distribution of the translocation and processing of prelactogen through the gradient correlated with that of the microsomal RNA (ribosomes). Microsomes became inactive upon incubation with elastase, but the proteolyzed membranes recovered their activity by recombination with the soluble and active fragment of the docking protein (SRP-receptor) from dog pancreas. When this fragment was combined with the gradient subfractions, or with the subfractions inactivated by incubation with elastase, the density profile of the translocation activity remained similar to that of RNA. Thus, its distribution cannot be accounted for merely by that of the docking protein; another membrane constituent, still unidentified, is both necessary for translocation of polypeptides and restricted to the rough portions of the endosplamic reticulum. Signal peptidase was assayed in the absence of protein synthesis, by use of preformed prelactogen and detergent-disrupted microsomes. Its density distribution was also similar to that of RNA. Several components of the endosplamic reticulum now appear to be segregated within restricted areas on either side of the membrane, and to make up a biochemically distinct domain. We propose to call it the ribosomal domain in consideration of its contribution to protein biosynthesis by bound ribosomes. This domain probably accounts for a greater part of the membrane area at the cytoplasmic than at the luminal surface, as postulated earlier to explain how enzymes of the cytoplasmic surface are relatively less abundant in the rough microsomes than those of the luminal surface [Amar-Costesec A. & Beaufay H. (1981) J. Theor. Biol. 89, 217-230].

Bovine type XII collagen: amino acid sequence of a 10 kDa pepsin fragment from periodontal ligament reveals a high degree of homology with the chicken alpha 1(XII) sequence.

A 10 kDa collagenous peptide, derived from a 30 kDa disulfide bonded fragment, was purified from bovine periodontal ligament. Amino acid sequence analysis of tryptic peptides demonstrated a 92.8% homology with the chicken alpha 1(XII) cDNA derived sequence, demonstrating for the first time the presence of type XII collagen in a mammalian species and in an adult tissue.

Type XII collagen is expressed in embryonic chick tendons. Isolation of pepsin-derived fragments.

Two new disulfide-bonded collagenous pepsin-derived fragments have been isolated from chick embryo tendons. These fragments represent less than 0.5% of the pepsin-extractable collagen. We purified 10- and 16-kDa reduced fragments derived, respectively, from 32- and 46-kDa disulfide-bonded fragments. Unique tryptic peptide maps were obtained for each fragment. Although these collagenous fragments differ from all the known collagens in their electrophoretic behaviors, tryptic peptides and amino acid compositions, they present some striking similarities with the pepsin-derived fragments from cartilage type IX collagen. Unique sequences from the amino terminus and from a tryptic peptide were obtained for the 10-kDa reduced fragment, demonstrating that this fragment is derived from type XII collagen, whose existence had only been inferred so far from a cDNA encoding it.

Immunological characteristics of human ferritins; consequences for human serum ferritin determination.

Standard curves established with human spleen, liver, placenta and heart ferritins for eight commercial radioimmunological procedures show that liver and spleen ferritins present almost identical responses, whereas three times as much placenta ferritin and six times as much heart ferritin were required to give the same response as liver and spleen ferritins. There are great variations between the kits in the estimation of the ferritin level of a control serum.