Anita Schmid

Biased hypermutation and other genetic changes in defective measles viruses in human brain infections.

Abstract We assessed the alterations of viral gene expression occurring during persistent infections by cloning full-length transcripts of measles virus (MV) genes from brain autopsies of two subacute sclerosing panencephalitis patients and one measles inclusion body encephalitis (MIBE) patient. The suquence of these MV genes revealed that, most likely, almost 2% of the nucleotides were mutated during persistence, and 35% of these differences resulted in amino acid changes. One of these nucleotide substitutions and one deletion resulted in alteration of the reading frames of two fusion genes, as confirmed by in vitro translation of synthetic mRNAs. One cluster of mutations was exceptional; in the matrix gene of the MIBE case, 50% of the U residues were changed to C, which might result from a highly biased copying event exclusively affecting this gene. We propose that the cluster of mutations in the MIBE case, and other combinations of mutations in other cases, favored propagation of MV infections in brain cells by conferring a selective advantage to the mutated genomes.

Altered transcription of a defective measles virus genome derived from a diseased human brain.

Measles virus (MV) is a negative strand RNA virus which usually causes acute disease, but in rare cases its persistence in the human brain induces the lethal disease subacute sclerosing panencephalitis (SSPE). The transcription of MV and of a defective MV derived from autopsy material of a SSPE case was studied in cultured cells. In the lytic infection the levels of the MV mRNAs decreased progressively with the distance of the six cognate genes from the 3′ end of the genome, reflecting transcriptional attenuation at every gene junction. Transcripts covering two or three adjacent genes accounted for up to 20% of single gene transcripts; incidentally the MV intergenic transcription signals were found to be less conserved than the analogous signals of other negative strand RNA viruses. Although the analysed SSPE‐derived defective MV showed a localized transcription defect at the phosphoprotein‐‐matrix gene junction (substitution of the mRNAs by readthrough transcripts), the corresponding intergenic ‘consensus’ sequence and the surrounding nucleotides were not altered. This implies that factor(s) involved in the transcription of this defective SSPE virus fail to recognize this particular signal sequence, a constellation which in this and other cases might be causally related to the development of MV persistence.

Mutated and hypermutated genes of persistent measles viruses which caused lethal human brain diseases

Persistent measles viruses (MVs) causing lethal human brain diseases are defective, and the structure of several mutated matrix genes has been elucidated previously. The present study of four persistent MVs revealed a high number of differences from a consensus sequence also in other genes. Amino acid changes accumulated in the carboxyl terminus of the nucleocapsid protein and in the amino terminus of the phosphoprotein, but did not significantly alter these products, which are implicated in viral replication and transcription. The contrary is true for the envelope glycoproteins: In three of four cases, mutations caused partial deletion of the short intracellular domain of the fusion protein, most likely compromising efficient viral budding. Moreover, in the hemagglutinin gene of a strain showing strongly reduced hemadsorption, 20 clustered A to G mutations, resulting in 16 amino acid changes, were detected. This hypermutation might be due to unwinding modification of a part of the MV RNA genome accidentally present in a double-stranded form. Finally, we classified four lytic and seven persistent MV strains on the basis of their sequences. Surprisingly, the four lytic viruses considered belong to the same class. The persistent viruses form more loosely defined groups, which all differ from the vaccine strain Edmonston.

Accumulated measles virus mutations in a case of subacute sclerosing panencephalitis: interrupted matrix protein reading frame and transcription alteration

Subacute sclerosing panencephalitis (SSPE) is a fatal disease affecting the human central nervous system several years after acute measles infection. Measles virus (MV) genomes replicating in SSPE brains do not give rise to budding particles and present various defects in gene expression, mostly concerning the matrix (M) protein. For one SSPE case (K), shown previously to be devoid of M protein expression, we examined here in detail the features involved in this defect. In the brain of patient K the normal, monocistronic MV M mRNA was completely substituted by a bicistronic RNA containing the coding sequence of the preceding phosphoprotein (P) gene in addition to the M coding sequence. Analysis of the P-M intercistronic region by direct cDNA sequencing showed that the consensus sequence at this RNA processing site was unaltered but revealed several distant point mutations. cDNA cloning and sequencing of the entire M coding region established that one of the point mutations leads to a stop codon at triplet 12 of the M reading frame. It is unknown whether this defect, explaining by itself the lack of M protein, is related also to the block of M mRNA formation. In addition we note that as much as 1% of the nucleotides differed between two overlapping clones from the same brain. This high sequence variability could possibly account for the diversity of defects observed in MV gene expression in SSPE brains and may be a general phenomenon associated with RNA virus persistence.

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.

Generation and Properties of Measles Virus Mutations Typically Associated with Subacute Sclerosing Panencephalitis

Subacute sclerosing panencephalitis (SSPE), a very rare but lethal disease caused by measles viruses (MV) persisting in the human central nervous system (CNS) is characterized by lack of viral budding, reduced expression of the viral envelope proteins and spread of MV genomes through the CNS despite massive immune responses. The five major MV genes from several SSPE cases were cloned and sequenced, the two transmembrane envelope glycoproteins hemagglutinin (H) and fusion protein (F) were expressed and their maturation, cellular localization and functionality analyzed. We conclude that 1) mutations in the MV genes arise not only individually, by errors of the MV polymerase, but also in clusters as hypermutations, presumably due to RNA unwinding/modifying activity altering accidentally formed double-stranded RNA regions, 2) MVs spread in SSPE brains after clonal selection, 3) the MV matrix (M) gene is most heavily mutated and dispensable, 4) the two genes encoding envelope transmembrane proteins give rise to functional but altered proteins (typically F is heavily altered in its cytoplasmic domain), 5) H protein is transported poorly to the cell surface, 6) F and H proteins maintain tightly interdepending fusion functions, presumably to allow local cell fusion and MV ribonucleoprotein (RNP) spread through the CNS.

Infectious measles virus from cloned cDNA.

The study of measles virus (MV) and of negative strand RNA viruses in general has been hampered by the lack of an experimental system for genetic manipulation. Here we describe a procedure for generating infectious MV from cloned MV cDNA. First we assembled a genetically marked DNA copy of the MV genome in plasmids, under the control of phage T3 or T7 promoters, allowing production of transcripts almost identical to the MV genome or antigenome. Incubation of these linearized plasmid DNAs with the appropriate phage polymerase and only two ribonucleoside triphosphates yielded committed transcription complexes. Microinjection of these complexes into the cytoplasm of helper cells which provide the proteins necessary for MV genome encapsidation and transcription/replication, reproducibly give rise to lytic MVs. The transcripts of one of these viruses were analysed by sequencing after reverse transcription followed by DNA amplification, and found to contain the genetic tags. The described procedure permits the analysis of a negative strand RNA virus with the same genetic tools previously applicable only to positive strand RNA viruses and retroviruses.