No evidence for binding between resistance gene product Cf-9 of tomato and avirulence gene product AVR9 of Cladosporium fulvum.

The gene-for-gene model postulates that for every gene determining resistance in the host plant, there is a corresponding gene conditioning avirulence in the pathogen. On the basis of this relationship, products of resistance (R) genes and matching avirulence (Avr) genes are predicted to interact. Here, we report on binding studies between the R gene product Cf-9 of tomato and the Avr gene product AVR9 of the pathogenic fungus Cladosporium fulvum. Because a high-affinity binding site (HABS) for AVR9 is present in tomato lines, with or without the Cf-9 resistance gene, as well as in other solanaceous plants, the Cf-9 protein was produced in COS and insect cells in order to perform binding studies in the absence of the HABS. Binding studies with radio-labeled AVR9 were performed with Cf-9-producing COS and insect cells and with membrane preparations of such cells. Furthermore, the Cf-9 gene was introduced in tobacco, which is known to be able to produce a functional Cf-9 protein. Binding of AVR9 to Cf-9 protein produced in tobacco was studied employing surface plasmon resonance and surface-enhanced laser desorption and ionization. Specific binding between Cf-9 and AVR9 was not detected with any of the procedures. The implications of this observation are discussed.

A highly conserved genomic region in baculoviruses: sequence analysis of an 11.3 kbp DNA fragment (46.5-55.1 m.u.) of the Spodoptera exigua multicapsid nucleopolyhedrovirus.

A DNA fragment of 11.3 kilobase pairs (kbp) in size of the baculovirus Spodoptera exigua multicapsid nucleopolyhedrovirus (SeMNPV) genome (46.5 to 55.1 m.u.) was completely sequenced. Analysis of the sequence revealed eleven potential open reading frames (ORF). Ten of these ORFs showed significant amino acid identity to Autographa californica MNPV (AcMNPV) and Orgyia pseudotsugata MNPV (OpMNPV) genes p6.9, lef5, 38K, p19, p143, p25, p18, vp33, lef4, and vp39. One ORF (XC12) has no homolog in other baculoviruses and may be unique to SeMNPV. All but three of these putative genes are preceded by the consensus baculovirus late promoter element (5'-ATAAG-3'). The genetic organization and the putative map of transcripts of this fragment suggested that this region is highly similar to a region in AcMNPV fragment EcoRI-D. Comparison of the genetic organization of this 11.3 kbp fragment with the genomes of AcMNPV, OpMNPV, Bombyx mori NPV (BmNPV) and SeMNPV revealed that this region is highly conserved among baculovirus genomes. This is in contrast to the genetic organization of the polyhedrin-p10 region, which is much more diverged, but has been taken as point of reference to orient baculovirus physical maps. Through its diversity the latter region, however, would be an excellent candidate to determine baculovirus relatedness and phylogeny. The presence of conserved and diverged regions in baculovirus genomes with respect to gene order is reminiscent to the situation in other large DNA viruses, such as herpes- and poxviruses, where conserved central and diverged terminal parts are common characteristics. The role of this feature in the genomic organization of large DNA viruses is discussed with particular emphasis on virus replication and evolution.

Genetic organization of the HindIII-I region of the single-nucleocapsid nucleopolyhedrovirus of Buzura suppressaria.

In order to investigate the genomic organization of the single-nucleocapsid nucleopolyhedrovirus (SNPV) of Buzura suppressaria (BusuNPV), the HindIII-I fragment located at map units (mu) 26.6-29.4 of the viral genome was sequenced. The fragment contained two partial and three complete open reading frames (ORFs) representing the 3' end of a polyhedron envelope protein gene (pep), a homologue of the AcMNPV ORF117, a conotoxin-like protein gene (ctl), an inhibitor of apoptosis gene (iap) and a superoxide dismutase gene (sod), respectively. These five genes were identified for the first time in a SNPV. Sequence analysis further revealed that these ORFs have the same conserved motifs and gene structure as those observed in their homologues from other baculoviruses. Between ctl and iap, an intergenic region of about 700 basepairs with structure similar to non-hr origins of DNA replication was observed. The genomic arrangement of the ORFs in the BusuNPV HindIII-I fragment is very different from the arrangement of their homologues in the genome of Autographa californica multiple nucleocapsid (M) NPV and other baculoviruses to date. Our data suggest that on the basis of gene arrangement, BusuNPV belongs to a distinct taxon within the Baculoviridae family, corroborating our previous conclusions derived from phylogeny analysis of several BusuNPV genes.

Generation of a p10-based baculovirus expression vector in yeast with infectivity for insect larvae and insect cells.

A new, versatile baculovirus vector was developed for the generation of recombinants in the yeast Saccharomyces cerevisiae and for the expression of foreign proteins in both insect larvae and in insect cells. This vector is based on Autographa californica multiple nucleocapsid nucleopolyhedrovirus (AcMNPV) and exploits the 10-kDa protein promoter (p10) for the expression of the foreign gene. The p10 locus was used for the insertion of a yeast-selectable marker system (ARS-URA-URA3) and of a gene for screening and titration of recombinants in insect cells (beta-galactosidase). The polyhedron-positive phenotype of this vector is maintained allowing its use in insect larvae, by feeding polyhedra, and in insect cells, by infecting with budded virus. The generation of this baculovirus vector requires a single recombination step in yeast prior to infection of insect cells, but has the advantage over the vector designed previously (Patel et al., A new method for the isolation of recombinant baculovirus, Nucleic Acids Research 20 (1992) 97-104) that these vectors can also be used in insects.

Comparative investigations on the coat protein binding sites of the genomic RNAs of alfalfa mosaic and tobacco streak viruses.

The genomic RNAs of alfalfa mosaic virus (AIMV) and tobacco streak virus (TSV) form complexes with viral coat protein. These complexes were subjected to digestion with ribonuclease T1 and filtered onto Millipore filters. It was shown that the major coat protein binding sites are located at the 3' ends of the genomic RNA species of AIMV and TSV in both heterologous and homologous RNA-coat protein combinations. Internal coat protein binding sites were found as well. Although there is homology between the 3'-terminal sequences, no structural features could be observed that are common to all coat protein binding sites. The fact that TSV and AIMV coat protein can mutually activate each others genome combined with the fact that the major target site of both coat protein preparations is located at the 3' ends of the genomic RNAs favors the assumption that binding of the coat protein to the 3' ends is an initiation event of the replication cycle.

Specificity of RNA and coat protein interaction in alfalfa mosaic virus and related viruses.

Well-defined coat protein binding sites were found to be present on the genomic RNAs of AlMV and TSV. In view of the regulatory importance of these sites in virus multiplication, the possibility that nonrelated proteins also were able to interact with these sites was investigated. The coat proteins of TSV, BMV, CMV, and SBMV recognize specific sites on AlMV RNA 1. The significance of these sites in virus multiplication is discussed. No specific binding sites were found with TMV coat protein or the nonviral proteins ovalbumin, myoglobin, and lysozyme. Moreover, the ability of AlMV coat protein to recognize specific sites on the heterologous RNAs of TSV, BMV, bacteriophage MS2, and Escherichia coli was tested. No specific sites were found with MS2-RNA. However, specific binding sites were found with BMV-RNA 3 and, unexpectedly, with E. coli 16 S ribosomal RNA. From these data it was concluded that binding of AlMV and TSV coat proteins to their genomic RNAs is a specific process. However, the binding of coat protein to BMV-RNAs and to ribosomal RNAs may result from secondary folding that may have been conserved for other purposes throughout evolution of the RNAs.

Structure of the M2 protein gene of sonchus yellow net virus.

The nucleotide sequence of the gene immediately following the nucleocapsid protein gene of sonchus yellow net virus (SYNV), a plant rhabdovirus, is presented. Serological reactions of SYNV proteins with antibodies elicited by a fusion protein constructed from the sequenced gene indicate that this gene encodes an SYNV structural protein designated M2. The 5' end of the M2 protein mRNA appears to correspond to position 1700 relative to the 3' end of SYNV RNA, because an extension product that maps to this position was synthesized by reverse transcription of polyadenylated [poly(A)+] RNA from infected tobacco that had been primed with an SYNV-specific oligodeoxyribonucleotide. The 3' end of the gene encoding the M2 protein is defined by a recombinant DNA plasmid derived from poly(A)+ RNA from SYNV-infected plants. This plasmid contains an insert with a 3'-terminal region corresponding to a uridylate-rich sequence present at positions 2832 to 2836 on SYNV genomic (g) RNA. These data thus suggest that the M2 protein mRNA is 1132 nucleotides (NT) long, excluding the poly(A) tail, and consists of a 50-NT untranslated 5' region, a 1035-NT open reading frame (ORF), and a 47-NT untranslated 3'region. The ORF is capable of encoding a 345-amino acid protein with a calculated molecular weight of 38,332. A small region of the M2 protein appears to have some similarity to the phosphoproteins of other rhabdoviruses. An identical 14-NT region occurs at the two sequenced gene junctions on SYNV gRNA and shares homology with regions separating the genes of some animal rhabdoviruses.

Structure of the nucleocapsid protein gene of sonchus yellow net virus.

The structure of the gene adjacent to the "leader RNA" gene of sonchus yellow net virus (SYNV), a plant rhabdovirus, was deduced by dideoxyribonucleotide sequence analysis of SYNV genomic (g) RNA and a series of plasmids constructed from SYNV gRNA or polyadenylated [poly(A)+] RNA from SYNV-infected plants. Evidence that this gene encodes the nucleocapsid (N) protein was obtained by reaction of SYNV N protein with polyclonal antibodies raised against recombinant proteins derived from the cloned gene. Experiments in which defined oligodeoxyribonucleotides were used to initiate reverse transcription of poly(A)+ RNA from SYNV-infected tobacco revealed that the N protein messenger (m) RNA gene begins at position 147 from the 3' end of the SYNV genome. Inspection of the sequence shows that this mRNA has a 56 nucleotide (NT) untranslated region followed by a 1425 NT open reading frame that is terminated by tandem UAA stop codons at positions 1628 to 1633 relative to the 3' end of SYNV gRNA. Little direct sequence homology is evident between the 475 amino acid polypeptide predicted from the SYNV sequence and the nucleocapsid (N) proteins deduced from nucleotide sequences of the Indiana and New Jersey serotypes of vesicular stomatitis virus (VSV) and rabies virus. However, a short region of possible importance contains a small group of chemically similar amino acids common to all four N proteins.

Minimum requirements for specific binding of RNA and coat protein of alfalfa mosaic virus.

Coat protein-protected fragments of alfalfa mosaic virus RNA (AlMV-RNA) and tobacco streak virus RNA (TSV-RNA), which were isolated as described [D. Zuidema, M. F. A. Bierhuizen, B. J. C. Cornelissen, J. F. Bol, and E. M. J. Jaspars (1983)Virology, 125, 361-369], were tested for their ability to rebind AlMV coat protein in the presence of an excess of Escherichia coli tRNA by means of a nitrocellulose filter retention assay. In order to obtain the minimum requirements for coat protein binding, a 3'-terminal binding site and several internal binding sites were isolated and fragmented by mild alkali treatment so that various lengths of a particular binding site were present in the mixture to be tested for rebinding capacity. All fragments which originated from the Wend of AlMV-RNA 1 and could bind AlMV coat protein have in common the sequence 5'-CUCAUGCUA-3'. However, this sequence alone is not sufficient to bind viral coat protein. Either an extension by at least 27 nucleotides of this oligomer to the right or an extension by 45 nucleotides (or possibly less) to the left is necessary for AlMV coat protein binding. Also, smaller extensions simultaneously occurring at both sides are sufficient. The smallest fragment which still has binding capacity for viral coat protein is 23 nucleotides long and originates from an internal site of RNA 1. All bound fragments have two common features: the occurrence of AUG(C) twice in the sequence and the potential ability to form a stable secondary structure. A striking observation was that 3'-terminal fragments of TSV-RNAs 1 and 2 rebind AlMV coat protein with low efficiency (about 27 and 37%, respectively), whereas a 3'-terminal fragment of TSV-RNA 3 rebinds AlMV coat protein with an efficiency of about 71%.

Removal of the N-terminal part of alfalfa mosaic virus coat protein interferes with the specific binding to RNA 1 and genome activation.

Trypsinized coat protein of alfalfa mosaic virus lacking 25 amino acids at its N terminus still has the capability to form complexes with RNA which are detectable by sedimentation in sucrose gradients. However, it does not protect specific sites on the RNA against degradation by ribonuclease, as the native coat protein does (D. Zuidema, M. F. A. Bierhuizen, B. J. C. Cornelissen, J. F. Bol, and E. M. J. Jaspars (1983) Virology 125, 361-369.). The trypsinized coat protein has lost the capacity of the native coat protein to make the genome RNAs of alfalfa mosaic virus infectious or to interfere with the infectivity brought about by the native coat protein. These findings suggest that genome activation occurs via binding of the N-terminal part of the coat protein to specific sites on the RNAs.