Identification and Differentiation of Tilletia indica and T. walkeri Using the Polymerase Chain Reaction.

ABSTRACT Karnal bunt of wheat, caused by Tilletia indica, was found in regions of the southwestern United States in 1996. Yield losses due to Karnal bunt are slight, and the greatest threat of Karnal bunt to the U.S. wheat industry is the loss of its export market. Many countries either prohibit or restrict wheat imports from countries with Karnal bunt. In 1997, teliospores morphologically resembling T. indica were isolated from bunted ryegrass seeds and wheat seed washes. Previously developed PCR assays failed to differentiate T. indica from the recently discovered ryegrass pathogen, T. walkeri. The nucleotide sequence of a 2.3 kb region of mitochondrial DNA, previously amplified by PCR only from T. indica, was determined for three isolates of T. indica and three isolates of T. walkeri. There was greater than 99% identity within either the T. indica group or the T. walkeri group of isolates, whereas there was =3% divergence between isolates of these two Tilletia species. Five sets of PCR primers were made specific to T. indica, and three sets were designed specifically for T. walkeri based upon nucleotide differences within the mitochondrial DNA region. In addition, a 212 bp amplicon was developed as a target sequence in a fluorogenic 5' nuclease PCR assay using the TaqMan system for the detection and discrimination of T. indica and T. walkeri.

De novo generation of defective interfering RNAs of tomato bushy stunt virus by high multiplicity passage.

Defective interfering (DI) RNAs were generated de novo in each of 12 independent isolates of tomato bushy stunt virus (TBSV) upon serial passage at high multiplicities of infection (m.o.i.) in plants, but not in any of 4 additional isolates after 11 serial passages at low m.o.i. The DI RNAs were detected in RNA isolated from virus particles and in 2.3 M LiCl-soluble RNA fractions isolated from inoculated leaves. Symptom attenuation leading to persistent infections was closely correlated with the passage in which DIs first developed. Comparisons of nucleotide sequences of 10 cDNA clones from 2 DI RNA populations and with a previously characterized TBSV DI RNA revealed the same four regions of sequence from the TBSV genome were strictly conserved in each of the DI RNAs: the virus 5' leader sequence of 168 bases; a region of approximately 200-250 bases from the viral polymerase gene; approximately 70 bases from the 3' terminus of the viral p19 and p22 genes; and approximately 130 bases from the 3' terminal noncoding region. Conservation of the sequence motif present in all of the DIs suggests that there might be a common mechanism of DI formation as well as selection pressure to maintain sequences essential for replication and encapsidation.

The complete genome structure and synthesis of infectious RNA from clones of tomato bushy stunt virus.

The complete sequence of the genome of the cherry strain of tomato bushy stunt virus (TBSV), a member of the tombusvirus group, was determined. A full-length clone of the genome containing a bacteriophage T7 RNA polymerase promoter was assembled from partial cDNA clones. In vitro transcripts of the genome, either with or without a 5' cap structure, were highly infectious. In addition, a genomic clone modified to contain an EcoRI restriction site as a signature mutation was infectious. Five genes are encoded by the TBSV genome. The first ORF from the 5' terminus encodes a p33 protein as well as a p92 product translated by read-through of the amber terminator for p33. The capsid protein gene resides internally, and two ORFs for proteins of 19 and 22 kDa reside at the 3' terminus. These last three genes are expressed from two subgenomic RNAs. The genomic organization of TBSV agrees with previous models for tombusviruses. Computer alignments of TBSV proteins with those of two other tombusviruses suggest greater relatedness among the members of this group than previously reported.

A point mutation in the tobacco mosaic virus capsid protein gene induces hypersensitivity in Nicotiana sylvestris.

In Nicotiana sylvestris, the N' gene confers hypersensitive resistance to some strains of tobacco mosaic virus (TMV) but not to the common strain. TMV sequences responsible for inducing local lesion formation in this host were identified by using cDNA clones to construct genomic recombinants between the common strain genome and a local-lesion-inducing mutant. To assay for sequences conferring the mutant phenotype, in vitro transcripts of recombinants were inoculated onto leaves of N. sylvestris and observed for the formation of either local lesions or a systemic infection. Sequences from the mutant that converted the hybrid genome to the mutant phenotype were located between nucleotides 5972 and 6206. Sequence analysis of this region revealed point mutations in the mutant at nucleotides 6157 (cytosine to uracil) and 6199 (adenine to guanine). The mutation at 6157 changes the capsid protein gene to specify phenylalanine rather than serine at position 148; nucleotide 6199 occurs in the 3' nontranslated region. When each point mutation was individually substituted into the wild-type background, transcripts containing only the alteration at 6157 produced local lesions on N. sylvestris, whereas transcripts containing only the alteration at 6199 produced systemic mosaic symptoms. The frequency of mutation was examined by partially sequencing virion RNA from six additional independent local-lesion mutants. Five mutants had the same alteration at 6157 as the original mutant and none had the alteration at 6199. This work demonstrates that the capsid protein gene of TMV is multifunctional, both encoding the virion structural protein and mediating the outcome of infection in N. sylvestris.

cDNA cloning of the complete genome of tobacco mosaic virus and production of infectious transcripts.

The entire genome of tobacco mosaic virus (TMV) was copied into a series of subgenomic cDNA clones. cDNA sequences of the 5' and 3' ends of TMV were cloned separately. A synthetic oligonucleotide primer was used to generate a Pst I site at the 5' terminus, whereas a different primer was used to generate an Nde I site at the 3' terminus. This strategy permitted removal of non-TMV sequences from cloned cDNA inserts by treatment with exonuclease VII following restriction endonuclease cleavage. Pst I linkers were added to TMV 3' terminal cDNAs. Subgenomic cDNA fragments were ligated together into several independent full-genomic constructions from which TMV cDNA sequences could be cleanly excised as a single fragment by Pst I digestion. Full-genomic TMV cDNA was ligated immediately downstream from the lambda phage promoter from pPM1 and transcribed in vitro with Escherichia coli RNA polymerase. RNA transcripts from three of four full-genomic cDNA constructions were infectious, even though they contained 6 non-TMV nucleotides at the 3' end. Transcripts from a construction with 6 extra nucleotides at the 5' end also were infectious. Progeny virus from plants infected with cDNA transcripts appeared identical to the parental virus. Restriction maps of independent cDNA clones of the same regions of the genome were identical to each other and as predicted from the reported nucleotide sequence of TMV. Also, sequences of the 200 nucleotides proximal to the 5' termini of four independent cDNA clones were identical to each other and to published sequences, suggesting that independent isolates of TMV may have remarkably similar sequences.