Processing of complementary sense RNAs of Digitaria streak virus in its host and in transgenic tobacco

We have used a polymerase chain reaction (PCR) procedure to analyse low abundance complementary sense RNAs of Digitaria streak virus (DSV) from infected leaves of Digitaria setigera. This study has confirmed that both spliced and unspliced RNAs are synthesised by the same transcription unit. The pos...

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Bibliographic Details
Published in:Nucleic acids research 1990-12, Vol.18 (24), p.7259-7265
Main Authors: Mullineaux, P.M, Guerineau, F, Accotto, G.P
Format: Article
Language:English
Subjects:
alternative splicing
Base Sequence
Biological and medical sciences
Blotting, Southern
Cloning, Molecular
complementary DNA
complementary rna
Consensus Sequence
Digitaria
Digitaria setigera
Digitaria streak virus
DNA - genetics
DNA Transposable Elements
Fundamental and applied biological sciences. Psychology
Geminiviridae
Geminivirus
Genetic Complementation Test
genetic transformation
Introns
Molecular and cellular biology
Molecular genetics
Molecular Sequence Data
Nicotiana - microbiology
Nicotiana tabacum
Plant Viruses - genetics
Plants, Toxic
Poly A
Polymerase Chain Reaction
Restriction Mapping
RNA
RNA editing
RNA Splicing
RNA, Viral - genetics
transcription (genetics)
Transcription, Genetic
Transcription. Transcription factor. Splicing. Rna processing
transgenic plants
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Summary:We have used a polymerase chain reaction (PCR) procedure to analyse low abundance complementary sense RNAs of Digitaria streak virus (DSV) from infected leaves of Digitaria setigera. This study has confirmed that both spliced and unspliced RNAs are synthesised by the same transcription unit. The position of the intron has been proven from sequencing cDNAs corresponding to the spliced RNA. Although the majority of cDNAs have 3' ends at coordinate 1063, downstream from a consensus polyadenylation sequence, a minor population of RNAs with heterogeneous 3' ends has also been identified. Two major RNA species with alternative splice sites or 3' ends, previously identified by nuclease S1 protection assays, could not be detected, but a cDNA species was observed with an apparent 90bp insertion at the 5' end of the intron. In transgenic tobacco containing integrated dimers of DSV DNA, the major unspliced RNA could readily be detected, but no spliced RNA was present. This may be a reason why DSV DNA did not replicate in tobacco. In addition, neither the minor population of heterogeneous RNAs nor the cDNA species with the insertion could be detected. The failure of the intron to be spliced in tobacco and its low activity in Digitaria is discussed in relation to recent studies on RNA splicing in plants and has led us to the conclusion that the geminivirus introns may be intrinsically inefficient.
ISSN:0305-1048
1362-4962
DOI:10.1093/nar/18.24.7259