Identification of the murine coronavirus MP1 cleavage site recognized by papain-like proteinase 2

The replicase polyprotein of murine coronavirus is extensively processed by three proteinases, two papain-like proteinases (PLPs), termed PLP1 and PLP2, and a picornavirus 3C-like proteinase (3CLpro). Previously, we established a trans-cleavage assay and showed that PLP2 cleaves the replicase polyprotein between p210 and membrane protein 1 (MP1) (A. Kanjanahaluethai and S. C. Baker, J. Virol. 74:7911-7921, 2000). Here, we report the results of our studies identifying and characterizing this cleavage site. To determine the approximate position of the cleavage site, we expressed constructs that extended various distances upstream from the previously defined C-terminal end of MP1. We found that the construct extending from the putative PLP2 cleavage site at glycine 2840-alanine 2841 was most similar in size to the processed MP1 replicase product generated in a trans-cleavage assay. To determine which amino acids are critical for PLP2 recognition and processing, we generated 14 constructs with amino acid substitutions upstream and downstream of the putative cleavage site and assessed the effects of the mutations in the PLP2 trans-cleavage assay. We found that substitutions at phenylalanine 2835, glycine 2839, or glycine 2840 resulted in a reduction in cleavage of MP1. Finally, to unequivocally identify this cleavage site, we isolated radiolabeled MP1 protein and determined the position of [(35)S]methionine residues released by Edman degradation reaction. We found that the amino-terminal residue of MP1 corresponds to alanine 2841. Therefore, murine coronavirus PLP2 cleaves the replicase polyprotein between glycine 2840 and alanine 2841, and the critical determinants for PLP2 recognition and processing occupy the P6, P2, and P1 positions of the cleavage site. This study is the first report of the identification and characterization of a cleavage site recognized by murine coronavirus PLP2 activity.     

Identification of a domain of ETA receptor required for ligand binding.

Various chimeric ETA and ETB receptors were produced in CHO cells for the elucidation of a specific domain which influences the affinity of the receptor toward BQ-123, a selective ETA antagonist. Replacement of the first extracellular loop domain (B-loop) of the ETA receptor with the corresponding domain of the ETB receptor, reduced the inhibition by BQ-123 drastically, while the replacements of other extracellular domains of ETA did not. By contrast, the introduction of the B-loop of ETA in place of the corresponding domain of the ETB receptor endowed the ETB-based chimeric receptor with a sensitivity to BQ-123. These observations suggest that the B-loop domain of the ETA receptor is involved in ligand binding.     

Identification of mouse chromosomes required for murine leukemia virus replication.

The replication patterns of five ecotropic and two amphotropic strains of murine leukemia virus (MuLV) were studied by infecting 41 Chinese hamster x mounse hybrid primary clones segregating mouse (Mus musculus) chromosomes. Ecotropic and amphotropic strains replicated in mouse and some hybrid cells, but not in hamster cells, indicating that replication of exogenous virus requires dominantly expressed mouse cellular genes. The patterns of replication of the five ecotropic strains in hybrid clones were similar; the patterns of replication of the two amphotropic strains were also similar. When compared to each other, however, the replication patterns of ecotropic and amphotropic viruses were dissimilar, indicating that these two classes of MuLV require different mouse chromosomes for replication. Chromosome and isozyme analyses assigned a gene, Rec-1 (replication of ecotropic virus), to mouse chromosome 5 that is necessary and may be sufficient for ecotropic virus replication. Because of preferential retention of mouse chromosomes 15 and 17 in the hybrid clones, however, the possibility that these chromosomes carry genes that are necessary but not sufficient for ecotropic virus replication cannot be excluded. Similarly, the data indicate that mouse chromosome 8 (or possibly 19) carried a gene we have designated Ram-1 (replication of amphotropic virus) which is necessary and may be sufficient for amphotropic virus replication. Because chromosomes 8 and 19 tended to segregate together and two of the three clones excluding 19 have chromosome reaggrangements, we cannot exclude 19 as being independent of amphotropic virus replication. In addition, because of preferential retention, chromosomes 7, 12, 15, 16 and 17 cannot be excluded as being necessary but not sufficient. Hybrid cell genetic studies confirm the assignment of the Fv-1 locus to chromosome 4 previously made by sexual genetics. In addition, our results demonstrate that hybrid cells which have segregated mouse chromosome 4 but have retained 5 become permissive for replication of both N and B tropic strains of MuLV.     

A complete domain structure of Drosophila tolloid is required for cleavage of short gastrulation

Drosophila tolloid (TLD) is a member of a family of proteinases that play important roles in development and includes mammalian tolloid (mTLD) and bone morphogenetic protein (BMP)-1. TLD accentuates the activity of decapentaplegic (DPP), a transforming growth factor beta superfamily growth factor, by cleaving its antagonist Short gastrulation (Sog). Similarly, the activity of BMP-2/4 (vertebrate homologues of DPP) is augmented by cleavage of chordin. However, whereas TLD is an effective Sogase, mTLD is a poor chordinase and is functionally replaced by its smaller splice variant BMP-1, which lacks the most C-terminal epidermal growth factor (EGF)-like and CUB domains of mTLD. Moreover, the minimal chordinase activity resides in the N-terminal half of BMP-1. This study showed that the proteolytic activity of TLD is considerably enhanced by Ca2+ and tested the hypothesis that the Sogase activity of TLD resides in the N-terminal half of the proteinase. Unexpectedly, it was found that TLD lacking the CUB4 and CUB5 domains and/or the EGF-like domains was unable to cleave Sog. Loss of function mutations have been reported in the tld gene that result in amino acid substitutions at E835K (in CUB4), S915L (in CUB5), and N760I (in EGF2) in TLD. The CUB mutants were found to be ineffective Sogases, but the activity of the EGF2 mutant was unchanged. The results show that substrate recognition and cleavage by Drosophila tolloid and mTLD are different despite their identical domain structure and homologous functions in patterning. The result that the N760I mutant has full Sogase activity suggests that novel substrates for TLD exist.     

Identification of the catalytic sites of a papain-like cysteine proteinase of murine coronavirus.

The murine coronavirus mouse hepatitis virus gene 1 is expressed as a polyprotein, which is cleaved into multiple proteins posttranslationally. One of the proteins is p28, which represents the amino-terminal portion of the polyprotein and is presumably generated by the activity of an autoproteinase domain of the polyprotein (S. C. Baker, C. K. Shieh, L. H. Soe, M.-F. Chang, D. M. Vannier, and M. M. C. Lai, J. Virol. 63:3693-3699, 1989). In this study, the boundaries and the critical amino acid residues of this putative proteinase domain were characterized by deletion analysis and site-directed mutagenesis. Proteinase activity was monitored by examining the generation of p28 during in vitro translation in rabbit reticulocyte lysates. Deletion analysis defined the proteinase domain to be within the sequences encoded from the 3.6- to 4.4-kb region from the 5' end of the genome. A 0.7-kb region between the substrate (p28) and proteinase domain could be deleted without affecting the proteolytic cleavage. However, a larger deletion (1.6 kb) resulted in the loss of proteinase activity, suggesting the importance of spacing sequences between proteinase and substrate. Computer-assisted analysis of the amino acid sequence of the proteinase domain identified potential catalytic cysteine and histidine residues in a stretch of sequence distantly related to papain-like cysteine proteinases. The role of these putative catalytic residues in the proteinase activity was studied by site-specific mutagenesis. Mutations of Cys-1137 or His-1288 led to a complete loss of proteinase activity, implicating these residues as essential for the catalytic activity. In contrast, most mutations of His-1317 or Cys-1172 had no or only minor effects on proteinase activity. This study establishes that mouse hepatitis virus gene 1 encodes a proteinase domain, in the region from 3.6 to 4.4 kb from the 5' end of the genome, which resembles members of the papain family of cysteine proteinases and that this proteinase domain is responsible for the cleavage of the N-terminal peptide.     

A functional c-myb gene is required for normal murine fetal hepatic hematopoiesis.

The c-myb proto-oncogene encodes a sequence-specific DNA-binding protein. To better understand its normal biological function, we have altered the c-myb gene by homologous recombination in mouse embryonic stem cells. Resulting homozygous c-myb mutant mice displayed an interesting phenotype. At day 13 of gestation these mice appeared normal, suggesting that c-myb is not essential for early development. By day 15, however, the mutant mice were severely anemic. Analysis indicated that embryonic erythropoiesis, which occurs in the yolk sac, was not impaired by the c-myb alteration. Adult-type erythropoiesis, which first takes place in the fetal liver, was greatly diminished in c-myb mutants, however. Additional hematopoietic lineages were similarly affected. These results are compatible with a role for c-myb in maintaining the proliferative state of hematopoietic progenitor cells.     

Maturation cleavage required for infectivity of a nodavirus.

Nodaviral morphogenesis involves formation of labile precursor particles, called provirions, which mature by autocatalytic cleavage of the 407-residue coat precursor protein between asparagine residue 363 and alanine residue 364. It has previously been demonstrated that maturation results in increased physicochemical stability of the virion. We show here that cleavage of coat protein in purified provirions of Flock House virus was accompanied by a five- to eightfold increase in specific infectivity. Cleavage-negative provirions, produced by site-directed mutagenesis of asparagine residue 363 to aspartate, threonine, or alanine, displayed no infectivity above revertant frequencies as measured by plaque assay. All viable revertants (nine of nine) restored asparagine to the mutated position, suggesting high specificity for asparagine at the cleavage site.     

A specific transmembrane domain of a coronavirus E1 glycoprotein is required for its retention in the Golgi region

The E1 glycoprotein of the avian coronavirus infectious bronchitis virus contains a short, glycosylated amino-terminal domain, three membrane-spanning domains, and a long carboxy-terminal cytoplasmic domain. We show that E1 expressed from cDNA is targeted to the Golgi region, as it is in infected cells. E1 proteins with precise deletions of the first and second or the second and third membrane-spanning domains were glycosylated, thus suggesting that either the first or third transmembrane domain can function as an internal signal sequence. The mutant protein with only the first transmembrane domain accumulated intracellularly like the wild-type protein, but the mutant protein with only the third transmembrane domain was transported to the cell surface. This result suggests that information specifying accumulation in the Golgi region resides in the first transmembrane domain, and provides the first example of an intracellular membrane protein that is transported to the plasma membrane after deletion of a specific domain.     

A new role for ns polyprotein cleavage in Sindbis virus replication

One of the distinguishing features of the alphaviruses is a sequential processing of the nonstructural polyproteins P1234 and P123. In the early stages of the infection, the complex of P123+nsP4 forms the primary replication complexes (RCs) that function in negative-strand RNA synthesis. The following processing steps make nsP1+P23+nsP4, and later nsP1+nsP2+nsP3+nsP4. The latter mature complex is active in positive-strand RNA synthesis but can no longer produce negative strands. However, the regulation of negative- and positive-strand RNA synthesis apparently is not the only function of ns polyprotein processing. In this study, we developed Sindbis virus mutants that were incapable of either P23 or P123 cleavage. Both mutants replicated in BHK-21 cells to levels comparable to those of the cleavage-competent virus. They continuously produced negative-strand RNA, but its synthesis was blocked by the translation inhibitor cycloheximide. Thus, after negative-strand synthesis, the ns proteins appeared to irreversibly change conformation and formed mature RCs, in spite of the lack of ns polyprotein cleavage. However, in the cells having no defects in alpha/beta interferon (IFN-alpha/beta) production and signaling, the cleavage-deficient viruses induced a high level of type I IFN and were incapable of causing the spread of infection. Moreover, the P123-cleavage-deficient virus was readily eliminated, even from the already infected cells. We speculate that this inability of the viruses with unprocessed polyprotein to productively replicate in the IFN-competent cells and in the cells of mosquito origin was an additional, important factor in ns polyprotein cleavage development. In the case of the Old World alphaviruses, it leads to the release of nsP2 protein, which plays a critical role in inhibiting the cellular antiviral response.     

Proteolytic processing of the coronavirus infectious bronchitis virus 1a polyprotein: identification of a 10-kilodalton polypeptide and determination of its cleavage sites.

Proteolytic processing of the polyprotein encoded by mRNA 1 is an essential step in coronavirus RNA replication and gene expression. We have previously reported that an open reading frame (ORF) 1a-specific proteinase of the picornavirus 3C proteinase group is involved in processing of the coronavirus infectious bronchitis virus (IBV) 1a/1b polyprotein, leading to the formation of a mature viral protein of 100 kDa. We report here the identification of a novel 10-kDa polypeptide and the involvement of the 3C-like proteinase in processing of the ORF 1a polyprotein to produce the 10-kDa protein species. By using a region-specific antiserum, V47, raised against a bacterial-viral fusion protein containing IBV sequence encoded between nucleotides 11488 and 12600, the 10-kDa polypeptide was detected in lysates from both IBV-infected and plasmid DNA-transfected Vero cells. Coexpression, deletion, and mutagenesis studies showed that this novel polypeptide was encoded by ORF 1a from nucleotide 11545 to 11878 and was cleaved from the 1a polyprotein by the 3C-like proteinase domain. Evidence presented suggested that a previously predicted Q-S (Q3783 S3784) dipeptide bond encoded by ORF 1a between nucleotides 11875 and 11880 was responsible for the release of the C terminus of the 10-kDa polypeptide and that a novel Q-N (Q3672 N3673) dipeptide bond encoded between nucleotides 11542 and 11547 was responsible for the release of the N terminus of the 10-kDa polypeptide.     

Identification of internal autoproteolytic cleavage sites within the prosegments of recombinant procathepsin B and procathepsin S. Contribution of a plausible unimolecular autoproteolytic event for the processing of zymogens belonging to the papain family

The steps involved in the maturation of proenzymes belonging to the papain family of cysteine proteases have been difficult to characterize. Intermolecular processing at or near the pro/mature junction, due either to the catalytic activity of active enzyme or to exogeneous proteases, has been well documented for this family of proenzymes. In addition, kinetic studies are suggestive of a slow unimolecular mechanism of autoactivation which is independent of proenzyme concentration. However, inspection of the recently determined x-ray crystal structures does not support this evidence. This is due primarily to the extensive distances between the catalytic thiolate-imidazolium ion pair and the putative site of proteolysis near the pro/mature junction required to form mature protein. Furthermore, the prosegments for this family of precursors have been shown to bind through the substrate binding clefts in a direction opposite to that expected for natural substrates. We report, using cystatin C- and N-terminal sequencing, the identification of autoproteolytic intermediates of processing in vitro for purified recombinant procathepsin B and procathepsin S. Inspection of the x-ray crystal structures reported to date indicates that these reactions occur within a segment of the proregion which binds through the substrate binding clefts of the enzymes, thus suggesting that these reactions are occurring as unimolecular processes.     

Sequence of the nucleocapsid gene from murine coronavirus MHV-A59.

The nucleotide sequence of the RNA encoding the nucleocapsid protein of coronavirus MHV-A59 has been determined. Copy DNA was prepared from mRNA isolated from virally infected cells, fragmented and cloned in the phage vector M13 mp8 for direct sequence determination. A sequence of 1817 nucleotides, adjacent to the viral poly-A tail, was obtained. It contains a single long open reading frame encoding a protein of mol. wt. 49660, which is enriched in basic residues.     

Identification of the erythropoietin receptor domain required for calcium channel activation.

Erythropoietin (Epo) activates a voltage-independent Ca2+ channel that is dependent on tyrosine phosphorylation. To identify the domain(s) of the Epo receptor (Epo-R) required for Epo-induced Ca2+ influx, Chinese hamster ovary (CHO) cells were transfected with wild-type or mutant Epo receptors subcloned into pTracer-cytomegalovirus vector. This vector contains an SV40 early promoter, which drives expression of the green fluorescent protein (GFP) gene, and a cytomegalovirus immediate-early promoter driving expression of the Epo-R. Successful transfection was verified in single cells by detection of GFP, and intracellular Ca2+ ([Ca]i) changes were simultaneously monitored with rhod-2. Transfection of CHO cells with pTracer encoding wild-type Epo-R, but not pTracer alone, resulted in an Epo-induced [Ca]i increase that was abolished in cells transfected with Epo-R F8 (all eight cytoplasmic tyrosines substituted). Transfection with carboxyl-terminal deletion mutants indicated that removal of the terminal four tyrosine phosphorylation sites, but not the tyrosine at position 479, abolished Epo-induced [Ca]i increase, suggesting that tyrosines at positions 443, 460, and/or 464 are important. In CHO cells transfected with mutant Epo-R in which phenylalanine was substituted for individual tyrosines, a significant increase in [Ca]i was observed with mutants Epo-R Y443F and Epo-R Y464F. The rise in [Ca]i was abolished in cells transfected with Epo-R Y460F. Results were confirmed with CHO cells transfected with plasmids expressing Epo-R mutants in which individual tyrosines were added back to Epo-R F8 and in stably transfected Ba/F3 cells. These results demonstrate a critical role for the Epo-R cytoplasmic tyrosine 460 in Epo-stimulated Ca2+ influx.     

Identification of a specific domain required for dimerization of activation-induced cytidine deaminase

Activation-induced cytidine deaminase (AID) is essential to all three genetic alterations required for generation of antigen-specific immunoglobulin: class switch recombination, somatic hypermutation, and gene conversion. Here we demonstrate that AID molecules form a homodimer autonomously in the absence of RNA, DNA, other cofactors, or post-translational modifications. Studies on serial deletion mutants revealed the minimum region between Thr27 and His56 responsible for dimerization. Analyses of point mutations within this region revealed that the residues between Gly47 and Gly54 are most important for the dimer formation. Functional analyses of these mutations indicate that all mutations impairing the dimer formation are inefficient for class switching, suggesting that dimer formation is required for class switching activity. Dimer formation and its requirement for the function of AID are features that AID shares with APOBEC-1, an RNA editing enzyme of apolipoprotein B100 mRNA.     

Identification of a CD4 domain required for interleukin-16 binding and lymphocyte activation.

Interleukin-16 (IL-16) activates CD4(+) cells, possibly by direct interaction with CD4. IL-16 structure and function are highly conserved across species, suggesting similar conservation of a putative IL-16 binding site on CD4. Comparison of the human CD4 amino acid sequence with that of several different species revealed that immunoglobulin-like domain 4 is the most conserved extracellular region. Potential interaction of this domain with IL-16 was studied by testing murine D4 sequence-based oligopeptides for inhibition of IL-16 chemoattractant activity and inhibition of IL-16 binding to CD4 in vitro. Three contiguous 12-residue D4 region peptides (designated A, B, and C) blocked IL-16 chemoattractant activity, with peptide B the most potent. Peptides A and B were synergistic for inhibition, but peptide C was not. Peptides A and B also blocked IL-16 binding to CD4 in vitro, whereas peptide C did not. CD4, in addition to its known function as a receptor for major histocompatibility complex class II, contains a binding site for IL-16 in the D4 domain. The D4 residues required for IL-16 binding overlap those previously shown to participate in CD4-CD4 dimerization following class II major histocompatibility complex binding, providing a mechanistic explanation for the known function of IL-16 to inhibit the mixed lymphocyte reaction.