Effect of the alterations in the fusion protein of measles virus isolated from brains of patients with subacute sclerosing panencephalitis on syncytium formation

Measles virus (MV) is the causative agent of subacute sclerosing panencephalitis (SSPE) and viruses isolated from brains of the patients contain numerous mutations. We have previously demonstrated that the hemagglutinin (H) protein of MV SSPE strains can interact with the signaling lymphocyte activation molecule (SLAM) and an unidentified molecule on Vero cells, but not with CD46, as a receptor. The mechanism by which MV SSPE strains can induce cell–cell fusion in SLAM-negative Vero cells is not understood. We report here on the effect of mutations in the fusion (F) proteins of three MV SSPE strains on syncytium formation. The F proteins of the three SSPE strains were functional and co-expression with H protein from the MV wild-type or SSPE strains in this study induced formation of large syncytia in Vero cells as well as in cell lines expressing SLAM or CD46. Expression of chimeric F proteins of SSPE strains showed that amino acid substitutions in the F protein extracellular as well as cytoplasmic domain contributed to enhanced cell–cell fusion in Vero cells. These findings suggest a common molecular mechanism and a key role of the F protein for syncytium formation in cells expressing an unidentified third receptor for MV.     

Subacute sclerosing panencephalitis is typically characterized by alterations in the fusion protein cytoplasmic domain of the persisting measles virus.

Our recent extensive analysis of three cases of subacute sclerosing panencephalitis (SSPE) revealed intriguing genetic defects in the persisting measles virus (MV): the fusion (F) genes encoded truncated cytoplasmic F protein domains (Cattaneo et al., Virology 173, 415-425, 1989). Now this MV genomic region has been investigated in eight additional SSPE cases by PCR amplification, replacement cloning into a vector containing the F gene of a lytic MV, in vitro expression, and sequencing. In all cases at least part of the clones showed mutations leading to F protein truncations, elongation, or nonconservative amino acid replacements. It is proposed that alteration of the F protein cytoplasmic domain may play a critical role in the development of SSPE.     

Molecular analysis of structural protein genes of the Yamagata-1 strain of defective subacute sclerosing panencephalitis virus. IV. Nucleotide sequence of the fusion gene

The full-length cDNA corresponding to the mRNA of the fusion (F) protein of the Yamagata-1 strain of subacute sclerosing panencephalitis (SSPE) virus was cloned, and its complete nucleotide sequence was determined. The F gene was composed of 2369 nucleotides and contained a single large coding region, which is located between two noncoding regions. The 5-terminal noncoding region consisted of 584 nucleotides comprising 44.9% cytosine, and had several inverted repetitious sequences. The 3-terminal noncoding region had a relatively low homology of 91.7% with the MV. The coding region was expanded for nucleotides 585–2189, which encoded 534 amino acids with a molecular weight of 57,963. The homology of the amino acid sequence of the F protein between the MV and SSPE virus was 96.27%, and the positions of cysteine and proline were almost identical in the two viruses. The functional domains of SSPE-virus F protein closely resembled those of MV F protein, including the cleavage site, a signal sequence, the fusion-related stretch, the transmembrane region, and four potential glycosylation sites. Four antigenic epitopes on the MV F protein were also conserved on the SSPE-virus F protein.However, deletion of one nucleotide (position 2155) of the SSPE virus was found when compared with the MV, and shifted the coding frame, causing the substitutions of 27 C-terminal amino acids of the MV F protein with 11 different residues. The variations of the C-terminal region of the F protein were observed with two other SSPE viruses, suggesting that this may be a common property of SSPE virus that differs from MV.     

Molecular analysis of structural protein genes of the Yamagata-1 strain of defective subacute sclerosing panencephalitis virus. I. Nucleotide sequence of the nucleoprotein gene

The complete nucleotide sequence of cloned cDNAs corresponding to the fulllength mRNA encoding the NP protein of the Yamagata-1 strain of subacute sclerosing panencephalitis (SSPE) virus was determined. The gene is composed of 1683 nucleotides and contains a single large open reading frame, which is capable of encoding 525 amino acids with a molecular weight of 58,399. Comparison of the nucleotide and predicted amino acid sequences with those of the Edmonston strain of measles virus (MV) showed that the gene and the protein were highly conserved. However, the antigenic sites on the NP protein of the Yamagata-1 strain were found to be changed by an eiptope analysis using monoclonal antibodies against the NP protein of MV. Only 1 of 4 monoclonal antibodies reacted with the NP protein of SSPE virus, and the other three antibodies did not.Almost identical changes in nucleotides and amino acids were found to occur in the NP gene of the Yamagata-1 strain when compared with the IP-3-Ca strain of another SSPE virus. In addition, the deduced secondary structure of the NP protein of the IP-3-Ca strain was similar to that of the Yamagata-1 strain, but differed from the MV. These results suggest that the NP proteins of SSPE viruses have a common property that is different from MV.     

Expression and properties of the V protein in acute measles virus and subacute sclerosing panencephalitis virus strains.

Measles virus (MV) inserts one guanosine (G) residue at a specific site in a subpopulation of the mRNA transcribed from the phosphoprotein (P) gene to produce V mRNA. Using an antiserum against the unique carboxyl-terminal region of the predicted V protein, we found that a phosphorylated V protein was expressed in two acute MV strains (Edmonston and Nagahata) and three SSPE virus strains (Biken, Yamagata, and Niigata). The V protein of Biken strain SSPE virus was electrophoretically and antigenically indistinguishable from the V protein of Nagahata strain acute MV, the likely progenitor of the Biken strain. The V protein of these two viruses was not present in the intracellular viral nucleocapsids, but was found only in the cytosolic free protein pool. Pulse-chase experiments failed to show transport of the V protein to the plasma membrane. The V protein was also absent in the extracellular virions. The P protein synthesized from the cloned gene associated with the MV nucleocapsids in vitro, but the V protein had no affinity to the MV nucleocapsids. These results suggest that expression and properties of the V protein are conserved in chronic MV infection.     

Molecular analysis of structural protein genes of the Yamagata-1 strain of defective subacute sclerosing panencephalitis virus. III. Nucleotide sequence of the hemagglutinin gene

The full-length cDNA corresponding to the mRNA for the hemagglutinin (H) protein of the Yamagata-1 strain of the subacute sclerosing panencephalitis (SSPE) virus was cloned and the nucleotide sequence was determined. The mRNA corresponding to the H protein was composed of 1952 nucleotides and contained a single large open reading frame, which encoded 620 amino acids with a predicted molecular weight of 69,723. This cDNA clone expressed the H protein in Cos 7 cells, and the transfected cells showed hemadsorption. The nucleotide and amino-acid sequence homology with the Edmonston strain of MV were 98.0% and 96.6%, respectively. The deduced amino acid sequence had a single hydrophobic domain near the N-terminus that was long enough to serve as an anchor in the membrane. Five potential glycosylation sites were found on the H protein at identical positions as in the H protein of MV. Cysteine and proline were located at almost identical positions as those of the H protein of MV. In addition, monoclonal antibody study revealed that three epitopes, including the domains that were involved in the biological activities of the H protein of MV, were conserved on the Yamagata-1 strain. These results suggested that the H protein of the Yamagata-1 strain of defective SSPE virus is structurally and functionally similar to that of the Edmonston strain of MV.     

A novel amino acid position in hemagglutinin glycoprotein of measles virus is responsible for hemadsorption and CD46 binding

Summary.  Three recent isolates of measles virus Fu, IMA, and SMD obtained by using B95a cells did not exhibit hemadsorption with African green monkey red blood cells (AGM-RBC). After long-term passage in Vero cells, these Vero cell-adapted strains derived from three isolates obtained the activity to agglutinate AGM-RBC. The primary sequences of the hemagglutinin (H protein) and fusion glycoproteins (F protein) from these two types of viruses were compared and revealed that several important amino acid residues in the H protein do not converge. After adaptation, Fu strain has an Asn to Tyr substitution at position 481 and IMA strain has two substitutions – an Asp to Asn at position 14 and a Ser to Gly at position 546, SMD strain also has a Ser to Gly substitution at position 546. Since the sequences of the F protein were identical between both types of viruses, the hemadsorption alteration from negative to positive might be the result of these substitutions. Site-directed mutagenesis of the H genes were performed to confirm that the substitution of Ser Gly at position 546 and Asn → Tyr at position 481 in the H protein were responsible for hemadsorption alteration. Anti-CD46 monoclonal antibody (M75 and M160) study made clear that these two substitutions also governed the MV H protein’s interaction with CD46 receptor. Our results showed that two important amino acid residues in MV H protein govern the binding to CD46 receptor and hemadsorption. In this paper, we reported a novel amino acid residue at position 546 in MV H protein, which was critical for hemadsorption and CD46 binding. Received May 7, 2001 Accepted October 24, 2001     

A comparison of complete untranslated regions of measles virus genomes derived from wild-type viruses and SSPE brain tissues

We compared complete untranslated regions (UTRs) of two subacute sclerosing panencephalitis (SSPE) measles virus (MV) strains and two wild-type (wt) MV strains, all belonging to the same genotype (D6). In comparison to wt MVs of the same genotype, base changes were identified in the two SSPE measles virus strains at 27 and 33 noncoding positions, respectively. Majority of these residues are unique for each of the SSPE virus sequences in comparison to all other reported measles virus strain sequences. The location of some of these changes indicates that they may modify cis-acting regulatory sequences including gene-end signal of the P gene, H/L gene junction and Kozak consensus element of the L gene. Further, within the long UTR between M and F genes, deletions and insertions were identified. Thus, our study could be significant for additional investigation using reverse genetics and recombinant viruses, of possible influence of mutations in UTRs on establishment and maintenance of chronic progressive CNS disease caused by MV persistence.     

Molecular characterization of measles virus strains causing subacute sclerosing panencephalitis in France in 1977 and 2007

Measles virus strains from two subacute sclerosing panencephalitis (SSPE) cases diagnosed in 1977 (Laine strain) and in 2007 (Hoedts strain) were studied. Phylogenetic analysis based on C-terminal part of the nucleoprotein and the entire H gene showed that Hoedts strain, circulating in France presumably in the 1980s, belonged to genotype C2. However, Laine strain, suspected to have circulated between 1940s and 1960s, could not be assigned to any known measles virus genotypes. Sequences analysis of the Laine strain suggested that it originated from a measles virus that may have circulating at the same period as the Edmonston strain. The analysis of the whole genome of both SSPE strains revealed biased hypermutations in M, F, and H gene. Some of these mutations like the L165P found in the M protein sequence of the Laine strain, the amino acid position 94, where a mutation M94V was found in the F protein sequence of the Hoedts strain are known to play an important role in the glycoprotein interaction and to impair the ability of measles virus strain to produce cell-free infectious viral particles.This is the first study on molecular characterization of the entire coding region of measles virus isolated from SSPE cases in France.     

Glycoprotein evolution of vesicular stomatitis virus New Jersey

A T1 ribonuclease fingerprinting study of a large number of virus isolates had previously demonstrated that considerable genetic variability existed among natural isolates of the vesicular stomatitis virus (VSV) New Jersey (NJ) serotype [S.T. Nichol (1988) J. Virol. 62, 572-579]. Based on these results, 34 virus isolates were chosen as representing the extent of genetic diversity within the VSV NJ serotype. We report the entire glycoprotein (G) gene nucleotide sequence and the deduced amino acid sequence for each of these viruses. Up to 19.8% G gene sequence differences could be seen among NJ serotype isolates. Analysis of the distribution of nucleotide substitutions relative to nucleotide codon position revealed that third position changes were distributed randomly throughout the gene. Third base changes constituted 84% of the observed nucleotide substitutions and affected 89% of the third base positions located in the G gene. Only three short oligonucleotide stretches of complete sequence conservation were observed. The remaining nucleotide changes located in the first and second positions were not distributed randomly, indicating that most of the amino acids coded by the G gene cannot be altered without reducing the fitness of the VSV NJ serotype viruses. Despite these constraints, up to 8.5% amino acid differences were observed between virus isolates. These differences were located throughout the G protein including regions adjacent to defined major antibody neutralization epitopes. Apparent clusters of amino acid substitutions were present in the hydrophobic signal sequence, transmembrane domain, and within the cytoplasmic domain of the G protein. A maximum parsimony analysis of the G gene nucleotide sequences allowed construction of a phylogram indicating the evolutionary relationship of these viruses. The VSV NJ serotype appears to contain at least three distinct lineages or subtypes. All recent virus isolates from the United States and Mexico are within subtype I and appear to have evolved from an ancestor more closely related to the Hazelhurst historic strain than other older strains. The implications of these findings for the evolution, epizootiology, and classification of these viruses are discussed.     

Molecular analysis of structural protein genes of the yamagata-1 strain of defective subacute sclerosing panencephalitis virus. II. Nucleotide sequence of a cDNA corresponding to the P plus M dicistronic mRNA

The nucleotide sequence of a cloned cDNA corresponding to the P+M dicistronic mRNA of a subacute sclerosing panencephalitis (SSPE) virus was determined and compared with data of measles virus (MV). The dicistronic mRNA of the SSPE virus consisted of the 3 proximal 626 nucleotides of P mRNA, intercistronic trinucleotides, a full length of M mRNA, and 75 poly A nucleotides. The part encoding the P protein had a high homology to MV, except at the noncoding region. The terminating consensus sequence of the P gene and the intercistronic trinucleotides of the SSPE virus were CTAC(A)₆ and CCT; in MV they are TTAT(A)₆ and CTT, respectively. In the M gene, the starting consensus sequence was exactly the same as MV, but at the 5 proximal end, one third of this gene was different: The first ATG codon of the MV M gene signaling opening of the reading frame was changed to ACG in the SSPE virus and one long open reading frame started from the third ATG codon. The stop codon (TAG) of the MV M gene was also changed to CAG in the SSPE virus. Thus, the deduced SSPE-virus M protein lacked 50 amino acids at the amino terminal and had 15 extra amino acids at the carboxyl end when compared with the MV M protein.     

Molecular analysis of measles virus genome derived from SSPE and acute measles patients in Papua,New Guinea

A very high annual incidence of 56 per million population below the age of 20 years for subacute sclerosing panencephalitis (SSPE) has been reported from Papua New Guinea (PNG). In a more recent study, we have confirmed this unusual high incidence for Eastern Highlands Province (EHP) of PNG. In the study, it was observed that the vaccination rate among SSPE patients registered at Goroka Base General Hospital (GBGH) in EHP was higher than that of other infants in the province in recent years. To identify the measles virus (MV) responsible for SSPE in EHP, sequence analysis of hypervariable region of the N gene was performed from 13 MV genomes: 2 amplified from clinical specimens of SSPE patients and 11 from acute measles patients. In 2 cases among the 11 with acute measles, nucleotide sequence of the entire H gene derived from isolated viruses was determined. Both nucleotide sequence and phylogenetic tree analyses showed that the amplified MV cDNAs were closely related to one another and belonged to the D3 genotype though they were different from any previously reported MV sequences. No genome sequences of vaccine strains were detected. These findings suggest that the MV strains prevailing in the highlands of PNG belong to genotype D3 of the MV and this wild-type MV rather than the vaccine strains was likely to be responsible for SSPE in these patients.     

Adaptation of canine distemper virus to canine footpad keratinocytes modifies polymerase activity and fusogenicity through amino acid substitutions in the P/V/C and H proteins

The wild-type canine distemper virus (CDV) strain A75/17 induces a non-cytocidal infection in cultures of canine footpad keratinocytes (CFKs) but produces very little progeny virus. After only three passages in CFKs, the virus produced 100-fold more progeny and induced a limited cytopathic effect. Sequence analysis of the CFK-adapted virus revealed only three amino acid differences, of which one was located in each the P/V/C, M and H proteins. In order to assess which amino acid changes were responsible for the increase of infectious virus production and altered phenotype of infection, we generated a series of recombinant viruses. Their analysis showed that the altered P/V/C proteins were responsible for the higher levels of virus progeny formation and that the amino acid change in the cytoplasmic tail of the H protein was the major determinant of cytopathogenicity.     

F1 polypeptides of two canine distemper virus strains: variation in the conserved N-terminal hydrophobic region

The fusion protein of canine distemper virus was isolated by immunoadsorption from two virus strains, the rapidly growing Onderstepoort strain (forming large plaques) and the Convac vaccine strain (forming microplaques). The F1 subunits of the two fusion proteins were purified by preparative polyacrylamide gel electrophoresis. Direct amino acid sequence analysis revealed that 36-residue N-terminal regions of the proteins from the two strains are identical except at position 9, where Ala in the Convac strain is substituted by Val in the Onderstepoort strain. The two sequences show high homology with the previously determined N-terminal sequence of the F1 polypeptide of measles virus, and moderate homology with corresponding sequences of five paramyxoviruses, emphasizing the occurrence of an extensive conservation of these structures.     

Evidence that the hypermutated M protein of a subacute sclerosing panencephalitis measles virus actively contributes to the chronic progressive CNS disease

Subacute sclerosing panencephalitis (SSPE) is a progressive degenerative disease of the brain uniformly leading to death. Although caused by measles virus (MV), the virus recovered from patients with SSPE differs from wild-type MV; biologically SSPE virus is defective and its genome displays a variety of mutations among which biased replacements of many uridine by cytidine resides primarily in the matrix (M) gene. To address the question of whether the SSPE MVs with M mutations are passive in that they are not infectious, cannot spread within the CNS, and basically represent an end-stage result of a progressive infection or alternatively SSPE viruses are infectious, and their mutations enable them to persist and thereby cause a prolonged neurodegenerative disease, we utilized reverse genetics to generate an infectious virus in which the M gene of MV was replaced with the M gene of Biken strain SSPE MV and inoculated the recombinant virus into transgenic mice bearing the MV receptor. Our results indicate that despite biased hypermutations in the M gene, the virus is infectious in vivo and produces a protracted progressive infection with death occurring as long as 30 to 50 days after that caused by MV. In primary neuron cultures, the mutated M protein is not essential for MV replication, prevents colocalization of the viral N with membrane glycoproteins, and is associated with accumulation of nucleocapsids in cells' cytoplasm and nucleus.     

Comparison of morbillivirus proteins by limited proteolysis

Proteins of a number of measles and SSPE virus strains have been compared by limited proteolysis and they appear to be largely conserved amongst the various strains. Viruses derived from SSPE cannot be distinguished from other measles viruses by this technique. Small differences in the digest patterns of the M proteins have been observed between the Edmonston and other measles virus strains. Furthermore, in some strains where the M proteins migrate slower in SDS-PAGE the limited proteolysis patterns are slightly different from those in other MV and SSPE virus strains. The limited proteolysis pattern of some canine distemper virus (CDV) proteins have been determined and nucleocapsid breakdown products have been identified in infected cells. Comparisons of proteins of four strains of CDV have shown that these, too, are largely conserved, although the digest of proteins of CDV appear to show more pronounced differences than those present in the MV and SSPE virus group. Limited proteolysis can be used readily to distinguish MV from CDV isolates.     

Nucleotide sequences of the M gene of prevailing wild measles viruses and a comparison with subacute sclerosing panencephalitis virus

We determined the nucleotide sequences of the coding region for the M gene in seven strains of measles virus (MV) that were isolated in Japan between 1984 and 1993. The mutation found among the seven differed from those of laboratory strains. Many of these mutations were the same as those that are characteristic of SSPE viruses. Thus, we suggest that the mutations that have been considered specific to SSPE virus are in fact consensus among prevailing MV.     

Nucleotide sequence of the murine leukaemia virus amphotropicstrain 4070A integrase (IN) coding region and comparativestructural analysis of the inferred polypeptide

Summary.  The complete nucleotide sequence of the integrase (IN) protein coding region of the murine leukaemia virus (MLV) amphotropic strain 4070A is presented. The sequence comprises 1,224 nucleotides, encoding a 408-residue polypeptide of M_r 46,312. Alignment of the inferred 4070A IN amino acid sequence with the IN proteins of other MLV showed that substitutions are confined largely to segments within the N- and C-terminal domains. In the N-terminal domain the majority of substitutions occur as contiguous 2- to 6-residue blocks, whereas in the C-terminal domain they occur as isolated entities except within a short segment characterized by deletions/insertions. Selection appears to act on the C-terminal 19 residues of IN rather than on the N-terminal residues of ENV (encoded by overlapping reading frames), suggesting a functional role for this segment. Phylogenetic analyses grouped the sequences into two clusters, one comprising IN from the amphotropic strain 4070A and three ecotropic MLV (CAS-BR-E, Moloney and Friend), the other consisting of IN from three ecotropic MLV (two radiation-induced viruses and AKV) and a mink cell focus-forming (MCF) MLV virus. The same dichotomy and cluster composition was obtained from analysis of the long terminal repeat (LTR) regions from these viruses (consistent with the functional interrelationship of IN and LTR) but not from analysis of envelope protein sequences (consistent with the functional independence of ENV proteins from both IN and LTR). Secondary structure predictions supported features determined from the catalytic domain of human immunodeficiency virus and avian sarcoma virus IN, and identified probable structures within the relatively long N- and C-terminal domains of MLV IN proteins. Received February 25, 1997 Accepted May 2, 1997     

Genetic changes that affect the virulence of measles virus in a rhesus macaque model

To identify genetic changes that lead to the attenuation of measles virus (MV), a strain of MV that is pathogenic in rhesus macaques was adapted to grow in Vero cells, Vero/hSLAM cells and, to simulate the process used to derive live attenuated vaccines, in primary chicken embryo fibroblasts (CEF). Comparison of the complete genomic sequences of the pathogenic wild-type (Davis87-wt) and four cell culture-adapted strains derived from it showed complete conservation of sequence in the Vero/hSLAM-passaged virus. Viruses adapted to Vero cells and CEF had predicted amino acid changes in the nucleocapsid protein, phosphoprotein, V protein, C protein, matrix protein, and the cytoplasmic tail of the hemagglutinin protein. All four cell culture-adapted strains, including the Vero/hSLAM cell-passaged virus, were able to productively infect Vero cells, but the peak viral titers differed. The Vero cell-adapted strains were unable to replicate in Chinese Hamster Ovary cells expressing CD46, indicating that they had not adapted to use the CD46 receptor. The Vero/hSLAM cell-passaged virus retained pathogenicity in rhesus macaques as measured by the appearance of a skin rash while the Vero cell-adapted and CEF-adapted strains had lost the ability to cause a rash. There were no significant differences in viral titers in peripheral blood mononuclear cells among monkeys infected with any of the viral stocks tested. These results identify a limited number of genetic changes in the genome of MV that lead to attenuation in vivo.