SFE1, a constituent of the fertilization envelope in the sea urchin is made by oocytes and contains low-density lipoprotein-receptor-like repeats

At fertilization in most animals, cortical granules of the egg or oocyte secrete their contents, whose function it is to modify the extracellular matrix. This modified matrix then participates in the block to polyspermy and protection for early embryonic development. In the sea urchin, contents of the cortical granules are secreted within 30 sec of insemination. Several of these content proteins then bind to the nascent vitelline layer of the egg and lift off the cell surface to form a stable, impervious, fertilization envelope. At least six major proteins are present in the envelope, and recently we have identified cDNA clones of two, ovoperoxidase, and SFE9. Here we report on the identification and characterization of SFE1, a constituent of the fertilization envelope of the sea urchin Strongylocentrotus purpuratus, that has revealing characteristics of how the envelope might form and what protein interaction domains might predominate. We present the largest cDNA sequence we were able to identify representing approximately two thirds of the predicted protein coding region. The C-terminal half of the cognate SFE1 protein contains two different amino acid repeat motifs: a cysteine-rich (15%) motif of 40 amino acids that is tandemly repeated 22 times and is followed by a serine/threonine-rich (38%) repeat of 63 amino acids that is tandemly repeated 3.5 times. Surprisingly, just N-terminal to the cysteine-rich repeat region is a sequence of five repeats with similarity to repeats in another cortical granule protein, SFE9, and to the motif originally identified in the receptor of low-density lipoproteins, the LDLr motif. The amino acid composition deduced from the partial SFE1 cDNA is similar also to the composition of proteoliaisin, a protein thought to tether the ovoperoxidase to the vitelline layer of the egg and thereby sequester the crosslinking activity of the ovoperoxidase to a limited population of proteins in the fertilization envelope. However, by use of monoclonal and polyclonal antibodies to SFE1 and proteoliaisin, we show here that they are distinct gene products. We also show that SFE1 is packed selectively into the cortical granules and then is crosslinked into the fertilization envelope following fertilization. In situ RNA hybridization analysis shows that the mRNA of SFE1 (9 kilobases) is present in oocytes selectively and is turned over rapidly in the oocyte following germinal vesicle breakdown. Our findings suggest that the gene encoding this major product of the egg is activated concomitantly with the other cortical granule-specific products already identified, and that a common LDLr-like motif of the fertilization envelope may reveal a structural mechanism for protein interactions in its construction.     

Assembly of the sea urchin fertilization membrane: isolation of proteoliaisin, a calcium-dependent ovoperoxidase binding protein

Fertilization of the sea urchin egg is accompanied by the assembly of an extracellular glycoprotein coat, the fertilization membrane. Assembly of the fertilization membrane involves exocytosis of egg cortical granules, divalent cation-mediated association of exudate proteins with the egg glycocalyx (the vitelline layer), and cross- linking of the assembled structure by ovoperoxidase, a fertilization membrane component derived from the cortical granules. We have identified and isolated a new protein, which we call proteoliaisin, that appears to be responsible for inserting ovoperoxidase into the fertilization membrane. Proteoliaisin is a 250,000-Mr protein that binds ovoperoxidase in a Ca2+-dependent manner, with half-maximal binding at 50 microM Ca2+. Other divalent cations are less effective (Ba2+, Mn2+, and Sr2+) or ineffective (Mg2+ and Cd2+) in mediating the binding interaction. Binding is optimal over the physiological pH range of fertilization membrane assembly (pH 5.5-7.5). Both proteoliaisin and ovoperoxidase are found in isolated, uncross-linked fertilization membranes. We have identified several macromolecular aggregates that are released from uncross-linked fertilization membranes after dilution into divalent cation-free buffer. One of these is an ovoperoxidase- proteoliaisin complex that is further disrupted only upon the addition of EGTA. These results suggest that a Ca2+-stabilized complex of ovoperoxidase and proteoliaisin forms one structural subunit of the fertilization membrane.     

Regulation of extracellular matrix assembly: in vitro reconstitution of a partial fertilization envelope from isolated components

At fertilization, the glycocalyx (vitelline layer) of the sea urchin egg is transformed into an elevated fertilization envelope by the association of secreted peptides and the formation of intermolecular dityrosine bonds. Dityrosine cross-links are formed by a secreted ovoperoxidase that exists in a Ca2+-stabilized complex with proteoliaisin in the fertilization envelope. By using purified proteins, we now show that proteoliaisin is necessary and sufficient to link ovoperoxidase to the egg glycocalyx. Specifically, we have found that ovoperoxidase can associate with the vitelline layer only when complexed with proteoliaisin; proteoliaisin binds to the vitelline layer independently of its association with ovoperoxidase; proteolytic modification of the vitelline layer is not required for this interaction to occur; the binding of proteoliaisin to the vitelline layer is mediated by the synergistic action of the two major seawater divalent cations, Ca2+ and Mg2+; the number of proteoliaisin-binding sites on the vitelline layer of unfertilized eggs is equivalent to the amount of proteoliaisin secreted at fertilization; and the binding of ovoperoxidase to the vitelline layer, via proteoliaisin, permits the in vitro cross-linking of these two in vivo substrates. The association of purified ovoperoxidase and proteoliaisin with the vitelline layer of unfertilized eggs reconstitutes part of the morphogenesis of the fertilization envelope.     

Functional domains of proteoliaisin, the adhesive protein that orchestrates fertilization envelope assembly

Ovoperoxidase, the enzyme that hardens the sea urchin fertilization envelope, is inserted into the assembling extracellular matrix through the action of an intermediary protein, proteoliaisin (PLN). The domain structure of PLN, a large, rod-shaped protein that binds to ovoperoxidase and the vitelline layer, was examined by limited proteolytic cleavage. Purified proteolytic fragments of PLN were tested for their ability to bind ovoperoxidase, inhibit the binding of 125I-PLN to the vitelline layer, or act as substrates for the hardening reaction. Based on these results, the vitelline layer-binding domain can be placed near the amino terminus, followed by the binding site for ovoperoxidase; the distal two-thirds of the protein contain sites for ovoperoxidase-catalyzed dityrosine formation. The pentapeptide GRGDS (but not RGD) inhibited PLN-vitelline layer binding half-maximally at 0.2 mM. Moreover, PLN promoted adhesion of bovine aortic endothelial cells to plastic dishes, a process inhibited by GRGDS. Thus PLN is a new member of the adhesive protein family, the function of which is to coordinate the morphogenesis of a specific, rapidly assembled extracellular matrix.     

Localization and developmental fate of ovoperoxidase and proteoliaisin, two proteins involved in fertilization envelope assembly

Fertilization of the sea urchin egg leads to the assembly of an extracellular matrix, the fertilization envelope. Ovoperoxidase, the enzyme implicated in hardening the fertilization envelope, is inserted into the assembling structure via a Ca2+-dependent interaction with the protein proteoliasin (P. Weidman and B. M. Shapiro, 1987, J. Cell Biol. 105, 561-567). In the present report, polyclonal antisera were raised to ovoperoxidase and proteoliasin (purified from eggs of Strongylocentrotus purpuratus) and characterized by Western blot analysis and an enzyme-linked immunoabsorbent assay (ELISA). By indirect immunofluorescence microscopy all cortical granules of unfertilized eggs, as well as the fertilization envelope, contained both proteoliasin and ovoperoxidase. At the ultrastructural level both proteins are localized to the electron-dense spiral lamellae of the cortical granules. Western blot analysis revealed that ovoperoxidase and proteoliasin persist in early embryos until hatching, but are absent from later developmental stages. Homogenates of eggs of several other echinoderm species (Strongylocentrotus droebachiensis, Strongylocentrotus franciscanus, Pisaster ochraceus, Dendraster excentricus, and Lytechinus pictus) also contain proteins antigenically similar to ovoperoxidase and proteoliaisin, indicating that many echinoderms utilize a similar strategy for assembly of the fertilization envelope. The results underline the need for postsecretory controls in the extracellular matrix modifications that accompany the cortical reaction.     

Domains of the human immunodeficiency virus type 1 matrix and gp41 cytoplasmic tail required for envelope incorporation into virions.

We recently demonstrated that a single amino acid substitution in matrix residue 12 (12LE) or 30 (30LE) blocks the incorporation of human immunodeficiency virus type 1 (HIV-1) envelope glycoproteins into virions and that this block can be reversed by pseudotyping with heterologous retroviral envelope glycoproteins with short cytoplasmic tails or by truncating the cytoplasmic tail of HIV-1 transmembrane glycoprotein gp41 by 104 or 144 amino acids. In this study, we mapped the domain of the gp41 cytoplasmic tail responsible for the block to incorporation into virions by introducing a series of eight truncation mutations that eliminated 23 to 93 amino acids from the C terminus of gp41. We found that incorporation into virions of a HIV-1 envelope glycoprotein with a deletion of 23, 30, 51, or 56 residues from the C terminus of gp41 is specifically blocked by the 12LE matrix mutation, whereas truncations of greater than 93 amino acids reverse this defect. To elucidate the role of matrix residue 12 in this process, we introduced a number of additional single amino acid substitutions at matrix positions 12 and 13. Charged substitutions at residue 12 blocked envelope incorporation and virus infectivity, whereas more subtle amino acid substitutions resulted in a spectrum of envelope incorporation defects. To characterize further the role of matrix in envelope incorporation into virions, we obtained and analyzed second-site revertants to two different matrix residue 12 mutations. A Val-->Ile substition at matrix amino acid 34 compensated for the effects of both amino acid 12 mutations, suggesting that matrix residues 12 and 34 interact during the incorporation of HIV-1 envelope glycoproteins into nascent virions.     

Purification, physicochemical characterization, and immunohistochemical localization of a major 11.7 S glycoprotein from the jelly coats of the anuran Lepidobatrachus laevis

Embryos of the frog Lepidobatrachus laevis are encased by a fertilization envelope and two jelly layers, termed J1 (innermost) and J2 (outermost). From preparations of total jelly solubilized from cleavage-stage embryos by a solution of alkaline beta-mercaptoethanol we have purified one jelly coat glycoprotein to homogeneity via FPLC gel permeation chromatography on Superose 6H. The purified glycoprotein was 94% protein and 6% carbohydrate, had an s0(20),w of 11.7 S, with a molecular weight of 245,000 measured by sedimentation equilibrium and 263,000 by gel permeation chromatography. SDS-PAGE revealed that the glycoprotein is composed of a single subunit near 29,700 molecular weight; thus we propose that eight of these subunits comprise the native molecule. Amino acid analysis of the glycoprotein indicated a high content of Glx + Asx (32.4 mole%), a low content of basic amino acids (Arg + Lys = 12.2 mole%), and a single cysteine residue per subunit. The N-terminal amino acid was threonine and the sequence of the first twenty amino acids was determined. Monospecific antisera to the glycoprotein were prepared in rabbits and were used to immunohistochemically localize the glycoprotein throughout the matrix of both jelly layers. Antiserum against the glycoprotein had virtually no effect on the fertilizability of jellied eggs in vitro; thus we hypothesize that the glycoprotein fulfills a structural role in both jelly layers.     

The primary and higher order structures of sea urchin ovoperoxidase as determined by cDNA cloning and predicted by homology modeling.

At fertilization, sea urchin ovoperoxidase (OPO) is incorporated into a nascent fertilization envelope in association with proteoliaisin and plays an essential role in its hardening. By cDNA cloning based on the previously reported partial amino acid sequences of Hemicentrotus pulcherrimus OPO, the cDNA and deduced amino acid sequences of the enzyme precursor were determined. Its 814-residue sequence consists of 125-residue signal- plus pro-peptides and 689-residue mature enzyme and has 92.2 and 81.4% identity with the OPOs of Strongylocentrotus purpuratus and Lytechinus variegatus, respectively. Compared with human myeloperoxidase, it has 30.3% identity and 9.6% similarity and has an additional C-terminal sequence of about 100 residues, suggesting its possible role as the site for interaction with proteoliaisin, if not for the entire sequence. The linker peptide sequence between L- and H-chains (e.g., ASFVTG and FSFFTG) cleaved off upon activation in mammalian promyeloperoxidases is intrinsically lacking in OPO, uniquely rendering the single 70K polypeptide a basic unit. The positions of distal and proximal histidines, distal arginine, and six disulfide bridges are highly conserved among mammalian and sea urchin peroxidases. The secondary structure was predicted by EMBL-PHD on the Internet for the whole sequence of mature OPO, and both secondary and tertiary structures were predicted by Swiss-Model for the partial sequences residues 18-65 and 123-570 with canine myeloperoxidase as a template. The overall architecture of the OPO molecule is close to that of human myeloperoxidase but its secondary structure has some differences based on the sequence variation, as depicted by RasMol. Another software, Swiss-PdbViewer, produced a slightly but significantly different image of the OPO structure for the same predicted atomic coordinates. A discrepancy was also found between the secondary structures of human myeloperoxidase in the PDB file and in its Swiss-PdbViewer presentation.     

Incorporation of mouse zona pellucida proteins into the envelope of Xenopus laevis oocytes

 All vertebrate eggs have extracellular matrices, referred to as the zona pellucida in Mus musculus and the vitelline envelope in Xenopus laevis. The mouse zona, composed of three sulfated glycoproteins (ZP1, ZP2, ZP3), is critical for fertilization and early development, and mice lacking a zona pellucida produce no live offspring. The primary structures of mouse ZP1 (623 amino acids), ZP2 (713 amino acids) and ZP3 (424 amino acids) have been deduced from full-length cDNAs, but posttranslational modifications result in mature zona proteins with molecular masses of 200–180 kDa, 140–120 kDa, and 83 kDa, respectively. The vitelline envelope forms a similar structure around Xenopus eggs and contains three glycoproteins that are structurally related (39–48% amino acid similarity) to the three mouse zona proteins. To investigate whether the structural semblances are sufficient to allow incorporation of the mouse zona proteins into the Xenopus vitelline envelope, capped synthetic mRNAs encoding ZP1, ZP2, and ZP3 proteins were injected into the cytoplasm of stage VI Xenopus oocytes. After 20 h of incubation the oocytes were harvested, and posttranslationally modified zona proteins were detected with monoclonal antibodies specific to mouse ZP1, ZP2, and ZP3. The oocytes were imaged with confocal microscopy to detect individual zona proteins in the extracellular matrix of the oocytes, and this localization was confirmed biochemically. Thus the mouse zona proteins appear to have been sufficiently conserved through 350 million years of evolution to be incorporated into the extracellular envelope surrounding Xenopus eggs. Received: 5 January 1999 / Accepted: 12 February 1999     

The Xenopus laevis cortical granule lectin: cDNA cloning, developmental expression, and identification of the eglectin family of lectins

A Xenopus laevis egg cortical granule, calcium-dependent, galactosyl-specific lectin participates in forming the fertilization layer of the egg envelope and functions in establishing a block to polyspermy. We report the cDNA cloning of the lectin, expression of the cortical granule lectin gene during oogenesis and early development, and identification of a new family of lectins. The translated cDNA for the cortical granule lectin had a signal peptide, a structural sequence of 298 amino acids, a molecular weight of 32.7 K, contained consensus sequence sites for N-glycosylation and a fibrinogen domain. The lectin cDNA was expressed during early stages of oogenesis. Lectin glycoprotein levels were constant during development with 2/3 of the lectin associated with the extracellular perivitelline space and the egg/embryo fertilization envelope. Lectin mRNA levels were from 100- to 1000-fold greater in ovary than in other adult tissues. The lectin had no sequence homology to the previously identified lectin families. The lectin had 41-88% amino acid identity with nine translated cDNA sequences from an ascidian, lamprey, frog, mouse, and human. Based on the conserved carbohydrate binding and structural properties of these glycoproteins, we propose a new family of lectins, the eglectin family.     

Sequence of contactin, a 130-kD glycoprotein concentrated in areas of interneuronal contact, defines a new member of the immunoglobulin supergene family in the nervous system

The primary amino acid sequence of contactin, a neuronal cell surface glycoprotein of 130 kD that is isolated in association with components of the cytoskeleton (Ranscht, B., D. J. Moss, and C. Thomas. 1984. J. Cell Biol. 99:1803-1813), was deduced from the nucleotide sequence of cDNA clones and is reported here. The cDNA sequence contains an open reading frame for a 1,071-amino acid transmembrane protein with 962 extracellular and 89 cytoplasmic amino acids. In its extracellular portion, the polypeptide features six type 1 and two type 2 repeats. The six amino-terminal type 1 repeats (I-VI) each consist of 81-99 amino acids and contain two cysteine residues that are in the right context to form globular domains as described for molecules with immunoglobulin structure. Within the proposed globular region, contactin shares 31% identical amino acids with the neural cell adhesion molecule NCAM. The two type 2 repeats (I-II) are each composed of 100 amino acids and lack cysteine residues. They are 20-31% identical to fibronectin type III repeats. Both the structural similarity of contactin to molecules of the immunoglobulin supergene family, in particular the amino acid sequence resemblance to NCAM, and its relationship to fibronectin indicate that contactin could be involved in some aspect of cellular adhesion. This suggestion is further strengthened by its localization in neuropil containing axon fascicles and synapses.     

Gene encoding a novel extracellular metalloprotease in Bacillus subtilis.

The gene for a novel extracellular metalloprotease was cloned, and its nucleotide sequence was determined. The gene (mpr) encodes a primary product of 313 amino acids that has little similarity to other known Bacillus proteases. The amino acid sequence of the mature protease was preceded by a signal sequence of approximately 34 amino acids and a pro sequence of 58 amino acids. Four cysteine residues were found in the deduced amino acid sequence of the mature protein, indicating the possible presence of disulfide bonds. The mpr gene mapped in the cysA-aroI region of the chromosome and was not required for growth or sporulation.     

The structure and organization of the human heavy neurofilament subunit (NF-H) and the gene encoding it.

Genomic clones for the largest human neurofilament protein (NF-H) were isolated, the intron/exon boundaries mapped and the entire protein-coding regions (exons) sequenced. The predicted protein contains a central region that obeys the structural criteria identified for alpha-helical 'rod' domains typically present in all IF protein components: it is approximately 310 amino acids long, shares amino acid sequence homology with other IF protein rod domains and displays the characteristic heptad repeats of apolar amino acids which facilitate coiled-coil interaction. Nevertheless, anomalies are noted in the structure of the NF-H rod which could explain observations of its poor homopolymeric assembly in vitro. The protein segment on the carboxy-terminal side of the human NF-H rod is uniquely long (greater than 600 amino acids) compared to other IF proteins and is highly charged (greater than 24% Glu, greater than 25% Lys), rich in proline (greater than 12%) and impoverished in cysteine, methionine and aromatic amino acids. Its most remarkable feature is a repetitive sequence that covers more than half its length and includes the sequence motif, Lys-Ser-Pro (KSP) greater than 40 times. Together with the recent identification of the serine in KSP as the main target for NF-directed protein kinases in vivo, this repetitive character explains the massive phosphorylation of the NF-H subunit that can occur in axons. The human NF-H gene has three introns, two of which interrupt the protein-coding sequence at identical points to introns in the genes for the two smaller NF proteins, NF-M and NF-L.(ABSTRACT TRUNCATED AT 250 WORDS)     

Mutations within a putative cysteine loop of the transmembrane protein of an attenuated immunodeficiency-inducing feline leukemia virus variant inhibit envelope protein processing.

A replication-defective feline leukemia virus molecular clone, 61B, has been shown to cause immunodeficiency in cats and cytopathicity in T cells after a long latency period when coinfected with a minimally pathogenic helper virus (J. Overbaugh, E. A. Hoover, J. I. Mullins, D. P. W. Burns, L. Rudensey, S. L. Quackenbush, V. Stallard, and P. R. Donahue, Virology 188:558-569, 1992). The long-latency phenotype of 61B has been mapped to four mutations in the extracellular domain of the envelope transmembrane protein, and we report here that these mutations cause a defect in envelope protein processing. Immunoprecipitation analyses demonstrated that the 61B gp85 envelope precursor was produced but that further processing to generate the surface protein (SU/gp70) and the transmembrane protein (TM/p15E) did not occur. The 61B precursor was not expressed on the cell surface and appeared to be retained in the endoplasmic reticulum or Golgi apparatus. Two of the four 61B-specific amino acid changes are located within a putative cysteine loop in a region of TM that is conserved among retroviruses. Introduction of these two amino acid changes into a replication-competent highly cytopathic virus resulted in the production of noninfectious virus that exhibited an envelope-protein-processing defect. This analysis suggests that mutations in a conserved region within a putative cysteine loop affect retroviral envelope protein maturation and viral infectivity.     

The primary structure of the VLA-2/collagen receptor alpha 2 subunit (platelet GPIa): homology to other integrins and the presence of a possible collagen-binding domain

VLA-2 (also called gpIa/IIa on platelets) is a collagen receptor with a unique alpha subunit and a beta subunit common to other adhesion receptors in the VLA/integrin family. Multiple cDNA clones for the human VLA-2 alpha 2 subunit have been selected from a lambda gtll library by specific antibody screening. The 5,374-bp nucleotide sequence encoded for 1,181 amino acids, including a signal peptide of 29 amino acids followed by a long extracellular domain (1,103 amino acids), a transmembrane domain, and a short cytoplasmic segment (22 amino acids). Direct sequencing of purified alpha 2 protein confirmed the identity of the 15 NH2-terminal amino acids. Overall, the alpha 2 amino acid sequence was 18-25% similar to the sequences known for other integrin alpha subunits. In particular, the alpha 2 sequence matched other integrin alpha chains in (a) the positions of 17 of its 20 cysteine residues; (b) the presence of three metal-binding domains of the general structure DXDXDGXXD; and (c) the transmembrane domain sequence. In addition, the alpha 2 sequence has a 191-amino acid insert (called the I-domain), previously found only in leukocyte integrins of the beta 2 integrin family. The alpha 2 I-domain was 23-41% similar to domains in cartilage matrix protein and von Willebrand factor, which are perhaps associated with collagen binding. The NH2-terminal sequence reported here for alpha 2 does not match the previously reported alpha 2 NH2-terminal sequence (Takada, Y., J. L. Strominger, and M. E. Hemler. 1987. Proc. Natl. Acad. Sci. USA. 84:3239-3243). Resolution of this discrepancy suggests that there may be another VLA heterodimer that resembles VLA-2 in size but has a different amino acid sequence.