Karin Kaelin scite author profile

A system has been established allowing the rescue of replicating measles viruses (MVs) from cloned DNA. On one hand, plasmids were constructed from which MV antigenomic RNAs with the correct termini are transcribed by phage T7 RNA polymerase. On the other hand, helper cells derived from the human embryonic kidney 293 cell line were generated constitutively expressing T7 RNA polymerase together with MV nucleocapsid protein and phosphoprotein. Simultaneous transfection of the helper cells with the MV antigenomic plasmid and with a plasmid encoding the MV polymerase under direction of a T7 promoter led to formation of syncytia from which MVs were easily recovered. A genetic tag comprising three nucleotide changes was present in the progeny virus. As a first application of reverse genetics, a segment of 504 nucleotides from the 5′ non‐coding region of the fusion gene was deleted, leading to an MV variant whose replication behaviour in Vero cells was indistinguishable from that of the laboratory Edmonston B strain. Since no helper virus is involved, this system, in principle, should be applicable to the rescue of any member of the large virus order Mononegavirales, i.e. viruses with a nonsegmented negative‐strand RNA genome.

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Measles virus editing provides an additional cysteine-rich protein

Cattaneo

Kaelin

Baczko

et al. 1989

Cell

336

215

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

et al. 1989

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Recombinant Measles Viruses Defective for RNA Editing and V Protein Synthesis Are Viable in Cultured Cells

1997

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The measles virus (MV) phosphoprotein (P) gene encodes three proteins, P, C, and V. The V protein is synthesized by pseudo-templated transcription, also designated as RNA editing: during P gene transcription one G residue is inserted at a defined position in about 50% of the mRNAs. To study the importance of sequence elements for the nontemplated G insertion, we generated recombinant MVs in which six different mutations were introduced within the region where editing occurs (3' UUUUUCCC, template strand). These viruses were then analyzed for their ability to edit their P mRNA and to produce V protein. Single U to C changes within the U stretch abolished editing. Extending the template by three C residues at the site of G insertion resulted in a less precise editing phenotype and overproduction of V. None of these mutants were impaired in their multiplication behavior when analyzed in cultured cells. However, the syncytia of a recombinant MV overproducing V protein were in general smaller and lysed 1 to 2 days later than usual.

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Rescue of Synthetic Measles Virus Minireplicons: Measles Genomic Termini Direct Efficient Expression and Propagation of a Reporter Gene

et al. 1995

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Measles virus (MV) mRNA transcription and replication are thought to be controlled by cis-acting sequence elements contained within the terminal MV genomic noncoding nucleotides. To validate these promoter and regulatory signal assignments, cDNAs were constructed allowing synthesis of RNAs corresponding to a MV genome in which all coding and intercistronic regions were replaced by the chloramphenicol acetyl transferase (CAT) coding sequence. Transcript production by T7 polymerase starting and ending precisely with the MV genome terminal residues was achieved by fusing the T7 polymerase promoter and the hepatitis delta virus genome ribozyme followed by tandem T7 polymerase termination sequences to the MV genomic 5' and 3' ends, respectively. Transfection of these negative polarity transcripts, mimicking natural defective interfering RNAs of the internal deletion type, into MV-infected 293 cells gave rise to CAT activity which could be serially transferred and massively amplified together with progeny helper virus in fresh cells. Transfer was blocked only by antibodies able to neutralize MV infectivity, indicating that the chimeric RNA not only was encapsidated, transcribed, and replicated, but also packaged into virions. Sequence analyses confirmed that both the expected chimeric antigenome and mRNA products were transcribed and replicated with fidelity during serial passage. Minor changes introduced in the transcription promoter markedly compromised function. This system now can be exploited to examine MV genomic cis-acting regulatory elements and extended to the development of full-length MV cDNAs.

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Karin Kaelin

Rescue of measles viruses from cloned DNA.

Measles virus editing provides an additional cysteine-rich protein

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

Recombinant Measles Viruses Defective for RNA Editing and V Protein Synthesis Are Viable in Cultured Cells

Rescue of Synthetic Measles Virus Minireplicons: Measles Genomic Termini Direct Efficient Expression and Propagation of a Reporter Gene

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