Identification of Replication Specificity Determinants in Two Strains of Tomato Leaf Curl Virus from New Delhi

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Journal of Virology, July 1999, p. 5481-5489, Vol. 73, No. 7
0022-538X/99/$04.00+0
Copyright © 1999, American Society for Microbiology. All rights reserved.

Identification of Replication Specificity Determinants in Two Strains of Tomato Leaf Curl Virus from New Delhi

Anju Chatterji, Malla Padidam, Roger N. Beachy, and Claude M. Fauquet^*

International Laboratory for Tropical Agricultural Biotechnology, Division of Plant Biology, The Scripps Research Institute, La Jolla, California 92037

Received 2 November 1998/Accepted 29 March 1999

	ABSTRACT

Top Abstract Introduction Materials and Methods Results Discussion References

We used two strains of tomato leaf curl virus from New Delhi to investigate specificity in replication of their cognate genomes.The strains share 94% sequence identity and are referred to assevere and mild on the basis of symptoms on tomato and tobacco.Replication assays in tobacco protoplasts and plants showed thata single amino acid change, Asn10 to Asp in the N terminus ofRep protein, determines specificity for replication of the twostrains based upon its interaction with the origin of replication(ori) sequences. The change of Asp10 to Asn in Rep protein ofthe mild strain coupled with point mutations at the 3rd and 10thnucleotides of the 13-mer binding site altered its replicationability, resulting in increased levels of virus accumulation.Similarly, changing Asn10 to Asp in Rep protein of the severestrain impaired replication of the virus and altered its severephenotype in plants. Site-directed mutations made in ori and Asn10of Rep protein suggested that Asn10 recognizes the third basepair of the putative binding site sequence GGTGTCGGAGTC in theseverestrain.

	INTRODUCTION

Top Abstract Introduction Materials and Methods Results Discussion References

Geminiviruses are characterized by having small circular single-stranded DNA genomes encapsidated in twinned icosahedral particles(21, 30) that replicate via double-stranded replicative intermediatesby using a rolling circle mechanism (29, 31). They are transmittedby leafhoppers or whitefly vectors and have monopartite or bipartitegenomes. Geminiviruses with a bipartite genome have their essentialviral functions divided on two DNA components referred to as DNA-Aand DNA-B. DNA-A encodes the replication-associated protein (Rep),the replication enhancer (REn), the transcriptional activatorprotein (TrAP), and the coat protein, while the movement functionsare located on DNA-B. Genetic studies have shown that both themovement protein and the nuclear shuttle protein encoded by DNA-Bare necessary for systemic infection (3, 9). In DNA-A andDNA-B, the open reading frames (ORFs) are arranged in two divergentclusters separated by an intergenic region. The intergenic regioncontains sequences that are conserved between the two DNA componentsand are referred to as the common region (CR). The CR containsthe origin of replication (ori) sequences that are crucial toinitiate replication and consists of a conserved hairpin structureand a binding site for the Rep protein located upstream of thehairpin (11, 12). The ori for squash leaf curl virus has beenmapped to a 90-nucleotide DNA segment within the CR (22) andwithin a 100-bp fragment in tomato golden mosaic virus (TGMV)(10).

The only geminivirus protein that is indispensable for virus multiplication is the Rep protein. Rep protein possesses a nicking-closingactivity and initiates rolling circle replication by a site-specificcleavage within the loop of the conserved nonamer sequence, TAATATTAC(14, 19, 20, 24). The Rep protein binding site is locatedbetween the TATA box and the transcription start site for theRep gene and acts as the origin recognition sequence and as anegatively regulatory element for Rep gene transcription (7,8, 12).

Rep proteins of different geminiviruses show specificity for replication of their cognate genome despite the strong sequencehomology and functional conservation between them (5, 11,17, 22). This specificity is determined in part by the high-affinitybinding site of the Rep protein located within the origin anda replication specificity domain localized in the N-terminal regionof the Rep protein. In tomato yellow leaf curl virus (TYLCV),the virus-specific origin recognition is mapped to first 116 aminoacids of the Rep protein (17). A similar function was mappedto the first 211 amino acids of the TGMV Rep protein (13). Recently,the functional domains of TGMV Rep protein responsible for Repoligomerization (amino acids 121 to 181), DNA binding (amino acids1 to 181), and DNA cleavage (amino acids 1 to 120) have been identified(25).

We previously characterized two strains of tomato leaf curl virus from New Delhi (ToLCV-Nde) that share 94% sequence identitybetween them but cause significantly different symptoms on tomatoand Nicotiana benthamiana plants (27). The severe strain causessevere puckering and downward leaf curling in plants with markedreduction in leaf size and internodal length. The mild strainproduces minor leaf curl and no puckering of leaves. We used thesetwo strains to study specificity in replication of viral genomes.Our results show that two strains specifically replicate theircognate DNAs and that specificity is determined in part by theamino acid at position 10 of the Rep protein and the correspondingbinding site sequence in the ori. In addition, we present evidencethat the amino acid at position 10 may interact with the thirdnucleotide of the 13-mer Rep protein binding site in the ori.

	MATERIALS AND METHODS

Top Abstract Introduction Materials and Methods Results Discussion References

Construction of mutants. The cloning of DNA-A (pMPA1; accession no. U15015) and DNA-B (pMPB; accession no. U15017) of the severe strain and DNA-A(pMPA2; accession no. U15016) of the mild strain have beendescribed previously (27). The genome organization of the severestrain is shown in Fig. 1A. DNA-A of the mild strain has the samegenome organization as DNA-A of the severe strain. The mutationsanalyzed in this study were targeted in the Rep gene and the CRof the viral genome. A brief description of each mutant used inthis study and the method of construction is provided in Table1. Full-length Rep gene or its fragments were exchanged betweenthe mild and severe strains by utilizing the available restrictionenzyme sites. In cases where convenient restriction sites werenot present, oligonucleotide-directed mutagenesis (16) was usedto substitute the fragments. For creating amino acid substitutionsin the Rep protein, mutagenic oligonucleotides were designed tosubstitute codons. All mutants were confirmed by DNA sequencing.In case of substitutions made by oligonucleotide-directed mutagenesis,a small restriction fragment containing the mutation was reclonedinto the unmutagenized A component at the respective site to avoidincorporation of second-site mutations. Partial tandem dimersof the mutants were used to infect Nicotiana tabacum protoplastsand N. benthamiana plants.

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FIG. 1. Genome organization of ToLCV-Nde showing mutations made in the Rep gene and in the CR. (A) Genome maps of DNA-A and DNA-B of the severe strain. The genes encoding conserved proteins in geminiviruses are shown as solid arrows. Rep (AC1), TrAP (AC2), REn (AC3), and coat protein (AV1) on DNA-A are shown. BC1 and BV1 on DNA-B represent the movement protein and the nuclear shuttle protein, respectively. The genome organizations of DNA-A of the severe and the mild strain are identical. Relevant restriction sites used for mutagenesis are indicated. (B) Schematic representation of mutants made in the Rep gene of mild and severe strain DNA-A. Fragments were exchanged at the N (NcoI to XbaI) or C (ClaI to ClaI) terminus of the Rep gene between the strains. The ToLCV severe strain is indicated by white hatched lines, whereas the mild strain is shown by black lines. (C) Schematic showing the organization of oris in geminiviruses (not to scale). The mutations made in the putative binding site of Rep protein and the N-terminal region of the Rep gene are shown. The hairpin, TATA box, and major ORFs in virus sense and complementary sense are indicated. The repeat sequence forming the binding site is shown as two solid arrows near the TATA box. The putative binding sites identified for the severe strain DNA-A and DNA-B and the mild strain DNA-A are indicated. Substitution mutations made in the N-terminus of the Rep gene of the mild and the severe strain together with point mutations made in the Rep protein binding sites are presented. The panel on the left shows the sequence of the first 10 amino acids on the Rep protein of A1 and A2 starting with the initiation codon, methionine (M), while the middle panel indicates the putative binding site sequence on the corresponding mutants (indicated on the right).

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TABLE 1. Description of mutants used in this study

Protoplast and plant inoculations. Protoplasts derived from N. tabacum BY-2 suspension cultures were used for transfection with viral DNA (33). One millionprotoplasts were inoculated by electroporation (250 V, 500 µF)with 2 µg each of DNA-A and DNA-B and 40 µg of sheared herringsperm DNA. Protoplasts were collected from cultures 48 h postinoculationfor DNA isolation andanalysis.

Two-week-old seedlings of N. benthamiana grown in magenta boxes were inoculated with partial tandem dimers of viral DNA byusing a Bio-Rad helium-driven particle gun (27). Ten plantswere inoculated for each mutant, using 0.5 µg each of DNA-A andDNA-B per plant. Plants were observed for symptom development,and the newly emerging leaves were harvested for Southern blotanalysis 21 days afterinoculation.

Southern blot analysis. DNA extractions from systemically infected leaf samples were carried out as described in reference 6 and from protoplastsby the procedure of Mettler (23). Total DNA (4 µg) was electrophoresedon 1% agarose gels without ethidium bromide and transferred tonylon membranes. Viral DNA was detected by using a DNA-A-specificradiolabeled probe (a 900-bp AflII-PstI fragment containing theRep, REn, and TrAP genes) or a probe specific for the DNA-B (878-bpPCR-amplified movement protein gene). The amount of viral DNAwas quantified as previously described (28) by exposing theSouthern blots to phosphor screens and counting the radioactivityon a PhosphorImager (MolecularDynamics).

	RESULTS

Top Abstract Introduction Materials and Methods Results Discussion References

The mild strain does not replicate efficiently. The two strains of ToLCV-Nde used in this study have been described previously (27). The DNA-A (pMPA1) and DNA-B (pMPB)of the severe strain have been cloned and characterized, but onlythe DNA-A (pMPA2) of the mild strain has been cloned; the DNA-Bof the mild strain has not been isolated to date. All the threeclones were obtained from the same DNA sample prepared from collectionof several diseased plants in the same field. Inoculation of N.benthamiana plants with DNA-A and DNA-B of the severe strain producedsevere symptoms with characteristic leaf curl, but plants inoculatedwith DNA-A of the mild strain and DNA-B of the severe strain developedmild infection with minor leaf curl symptoms. For the sake ofbrevity, hereafter, the severe strain DNA-A and DNA-B will bereferred to as A1 and B1 and the mild strain DNA-A will be designatedA2. A1 and A2 DNAs have the same length (2,739 nucleotides) and94% sequence identity. Their CRs are 81% identical (27). Theamino acid sequence identity between individual genes in A1 andA2 ranged from 91 to 99%, with the greatest similarity in thecoat protein gene. The nucleotide sequence identity between theCRs of A1 and B1 is 97%, compared to 79% between the CRs of A2andB1.

It was not known whether the mild phenotype in plants inoculated with A2 and B1 is due to inefficient replication of the virusor because of its inability to spread in the plant. To comparethe replication levels of the two strains, BY-2 protoplasts weretransfected with A1 or A2 DNA and viral DNA replication was quantitated48 h aftertransfection.

We observed that A2 does not accumulate to the same level as the A1 in protoplasts. The replication efficiency of A2 DNA variedbetween 45 and 58% compared to the A1 DNA levels (Table 2). Nextwe tested the ability of A2 to replicate B1 in tobacco protoplasts.In transient assays, A2 replicated B1 to barely detectable levels(<1%) (Fig. 2B, lanes 1 and 10; Table 2). In N. benthamiana plantsinoculated with A2 and B1 DNAs, very mild symptoms mostly limitedto mild chlorosis and slight curling were observed 3 weeks postinoculation.Southern analysis of total DNA isolated from infected plants showedvery low levels (5 to 10% compared to the A1 DNA) of DNA-B accumulation(Fig. 3A, lanes 1 and 8; Fig. 3B, lanes 1 and 10; Table 2). Inplants, replication of DNA-B is required to cause a systemic infection(27), and these data suggested that low levels of DNA-B replicationcoupled with less efficient replication of A2 may account formild symptoms observed in inoculated plants. The apparent inabilityof A2 to replicate B1 of the severe strain provided the firstevidence that the two strains may have different replication requirements.Therefore, we focused on the incompatibility of A2 and B1 by makingsequence comparisons between the Rep genes of A1 and A2 and theCRs of A2 and B1.

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TABLE 2. Replication and infectivity of ToLCV mutants in N. tabacum protoplasts and N. benthamiana plants

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FIG. 2. Southern blot analysis of viral DNA in N. tabacum protoplasts inoculated with different mutants of ToLCV. Total DNA was extracted from protoplasts 48 h after transfection, electrophoresed through 1% agarose gel without ethidium bromide, transferred to a nylon membrane, and hybridized with ³²P-labeled DNA-A- and DNA-B-specific probes. (A) Replication of mutants made in severe strain DNA-A and probed with A-component (lanes 1 to 9)- and B-component (lanes 10 to 18)-specific probes; (B) replication of mutants made in the mild strain DNA-A probed with A-component (lanes 1 to 9)- and B-component (lanes 10 to 18)-specific probes. The positions of single-stranded (ss) and supercoiled (sc) viral DNAs are indicated. Each lane contains 4 µg of DNA obtained from protoplasts in a single transfection.

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FIG. 3. Southern blot analysis of viral DNA in N. benthamiana plants inoculated with ToLCV mutants. Total DNA was extracted from newly emerging leaves 3 weeks after bombardment and electrophoresed in 1% agarose gels without ethidium bromide, transferred to a nylon membrane, and hybridized with ³²P-labeled DNA-A- and DNA-B-specific probes. (A) Replication of severe strain mutants probed with A-component (lanes 1 to 7)- and B-component (lanes 8 to 14)-specific probes; B replication of mutants made in the mild strain DNA-A and probed with A-component (lanes 1 to 9)- and B-component (lanes 10 to 18)-specific probes. The positions of single-stranded (ss) and supercoiled (sc) viral DNAs are indicated.

N-terminal domains of Rep protein are not interchangeable between the strains. The low levels of DNA-B accumulation in protoplasts and plants inoculated with A2 and B1 indicated that the mild strain Repprotein replicated B1 DNA inefficiently. To test if replicationlevels of DNA-B can be increased by replacing the mild strainRep protein with its equivalent from A1, a full-length Rep gene(from NcoI to BclI) was exchanged between the two strains (Fig.1B; Table 1). The mild strain DNA-A containing a full-lengthRep gene of the severe strain (A2-RepA1) did not replicate efficientlyin tobacco protoplasts (Fig. 2B, lanes 2 and 11; Table 2). Similarly,the severe strain DNA-A containing the Rep gene from the mildstrain (A1-RepA2) failed to accumulate to high levels in protoplasts(Fig. 2A, lanes 2 and 11; Table 2), suggesting that the Rep proteinsare not interchangeable. Similar results were obtained in N. benthamianaplants inoculated with these mutants (Fig. 3A, lanes 2 and 9;Fig. 3B, lanes 2 and 11; Table 2).

To determine whether the specificity of the Rep protein for the DNA templates was associated with C- or N-terminal regionof the Rep protein, we exchanged both the 5' and 3' parts of theRep gene between the strains. The 3' region of the Rep gene codingfor 256 amino acids (containing 18 of the 22 amino acid differencesbetween the two Rep proteins) from the carboxyl-terminal end ofRep (ClaI-ClaI fragment) was exchanged between the strains (A2-cRepA1and A1-cRepA2 [Fig. 1B; Table 1]) and determined the abilityof the Rep chimera to replicate in tobacco protoplasts. Unlikethe exchange of full-length Rep genes, the hybrid Rep proteinswere functional in both strains but did not change the phenotypeof the two strains. The severe strain mutant, A1-cRepA2, accumulatedboth DNA-A and DNA-B at levels similar to the wild-type (A1) virus(Fig. 2A, lanes 3 and 12; Table 2). In contrast, the mild strainmutant A2-cRepA1 replicated DNA-A at moderate levels and DNA-Bat very low levels (Fig. 2B, lanes 3 and 12; Table 2). Inoculationof N. benthamiana seedlings with these hybrid Rep gene constructsshowed that the plants infected with A2-cRepA1 produced mild symptomswhereas plants inoculated with A1-cRepA2 developed typical leafcurl symptoms within 10 days (Table 2; Fig. 3A, lanes 3 and 10;Fig. 3B, lanes 3 and12).

It should be noted that by exchanging the full-length Rep gene between the strains, the overlapping TrAP gene was also transferred;however, the results described above eliminated the possibilitythat differences in the TrAP gene had an effect on replicationof the chimericviruses.

We then exchanged sequences from the 5' region of the Rep gene encoding amino acids 1 to 110 (NcoI-XbaI fragment) betweenthe strains and assayed for replication of viral DNA. The severestrain mutant A1-nRepA2 contains the N-terminal sequences fromthe mild strain and led to accumulation of very low levels ofviral DNA (Fig. 2A, lanes 4 and 13; Table 2). Similarly, themutant A2-cRepA1 resulted in negligible levels of virus replication(Fig. 2B, lanes 4 and 13; Table 2). None of the N. benthamianaplants inoculated with either the A1-nRepA2 or A2-nRepA1 mutantdeveloped symptoms and accumulated very low levels of viral DNA(Table 2; Fig. 3A, lanes 4 and 11; Fig. 3B, lanes 4 and 13),indicating that the region spanning amino acids 1 to 110 in theRep gene may contain residues that determine specificity of replicationbetween the two strains and are notinterchangeable.

Rep proteins display specificity in recognizing replication origins. Geminivirus replication requires a functional interaction of Rep protein with specific sequences in the ori (11, 12).Studies described above identified the N-terminal region of Repprotein as being important in determining replication of the twostrains. We compared the CRs of the three DNA components, A1,A2, and B1, to look for differences that may contribute to templatespecificity. The CRs of A1 and A2 are 81% identical, while theCRs of A2 and B1 share only 79% sequence homology; by comparison,A1 and B1 are 97% identical. To determine whether sequence differencesin the CR of the mild strain restricts its replication, the CRof A2 was replaced with that of B1 (mutant A2-CRB1 [Table 1])and tested for its ability to replicate in BY-2 protoplasts andN. benthamiana plants. As shown in Table 2, exchange of the commonregion of A2 with B1 did not increase the replication levels ofDNA-B in protoplasts. Rather, the replication levels of both DNA-Aand DNA-B were drastically reduced (Fig. 2B, lanes 5 and 14; Table2). Similarly, this mutant did not replicate in N. benthamiana(Fig. 3B, lanes 5 and 14; Table 2). These results demonstratedthat the Rep protein of A2 does not recognize the CR sequencesof B1, suggesting that the two strains specifically recognizeunique sequences in their oris.

The experiments done thus far helped to delimit two essential features that influence replication specificity of two strains,the CR sequences and the N-terminal residues in Rep protein. Wenext introduced mutations in the N-terminal region (amino acids1 to 110) of A1 and A2 Rep proteins with concomitant changes intheir viral oris to analyze the precise determinants of a functional,replication-competentinteraction.

The Rep protein in geminiviruses show sequence similarities with other initiator proteins that follow a rolling circle modeof replication. Based on comparison of sequences of these proteins,Koonin and Ilyina (18) identified a domain among geminivirusesin the N-terminal region of Rep protein that may be involved ininitiating rolling circle replication. In this region, at leastthree motifs have been identified: motif III, xxYxxK, which isinvolved in DNA nicking and closing activities (15, 19); motifII, HIHxUUQ (U is a bulky hydrophobic residue), which has structuralfeatures similar to those of the Mg² binding sites of metalloenzymes (18); and motif I, FLTYPqC(q is a basic or a polar amino acid), whose function has not beenestablished yet. The three motifs described are present withinthe region spanning amino acids 1 to 110 and are identical betweenthe Rep proteins of A1 andA2.

To define the amino acids involved in recognition of the ori, the region between amino acids 1 and 110 was examined for sequencevariation between Rep proteins of A1 and A2. Four amino acid differenceswere identified between the two proteins in this region. The A1strain contains amino acids Ile, Asn, Lys, and Glu at positions9, 10, 40, and 52, respectively, while the A2 strain has Val,Asp, Ala, and Asp at these positions. Two amino acids, Ile9 andAsn10, are immediately adjacent to motif I. To determine if Ile9and Asn10 had a role in replication, Val9 and Asp10 in Rep proteinof A2 were changed to Ile9 and Asn10. Simultaneously, the CR ofthe A2 DNA was replaced with either A1 (A2-RepM1/CRA1) or B1 (A2-RepM1/CRB1)sequence (Fig. 1C). In protoplasts, both mutants A2-RepM1/CRA1(Fig. 2B, lanes 6 and 15) and A2-RepM1/CRB1 (Fig. 2B, lanes 7and 16) accumulated viral DNA to similar levels as the severeA1 strain. N. benthamiana plants inoculated with both of thesemutants developed severe infection 10 days after inoculation andaccumulated high levels of viral DNA as determined by Southernhybridization (Fig. 3B, lanes 6, 7, 15, and 16; Table 2). Thesedata suggested that Ile9 and Asn10 are involved in determininginteraction of Rep protein with specific sequences in theCR.

Putative Rep binding sites are different between the two strains. Rep protein in geminiviruses is known to bind with high affinity to its binding site in the ori. Based on comparison of manyori sequences in geminiviruses (1, 2, 11), we looked forputative Rep binding sites in the CRs of A1, A2, and B1 DNAs.A 13-bp sequence was identified in ori close to the TATA box inthe CRs of the three DNAs. In A1 and B1, the repeat sequence GGTGTCTGGAGTCwas identified, while A2 DNA had the repeat sequenceGGCGTCTGGCGTC.

To determine if these sequences represent potential binding sites for Rep proteins, we introduced mutations in the 13-bp sequence.Deletions were made at the 3rd or the 10th nucleotide of the 13-nucleotidesequence since they are different between the two strains. Bothmutants A1-CRM1 (deletion at the 3rd nucleotide) and A1-CRM2 (deletionat the 10th nucleotide) showed dramatically reduced levels ofviral DNA replication in infected protoplasts (Fig. 2A, lanes6, 7, 15, and 16; Table 2). Inoculated N. benthamiana plantsdid not show any symptoms 3 weeks postinoculation, and replicationof both viruses was reduced to minimal levels (Fig. 3A, lanes6, 7, 13, and 14; Table 2). These results demonstrated that the13-bp sequence in A1 is essential for virus replication and mayrepresent the Rep protein bindingsite.

Asn10 may determine specific interaction with the viral origin. Earlier experiments showed that amino acids Ile9 and Asn10 in Rep protein of A1 may be involved in specific interaction withthe CR. To determine if these amino acids are involved in recognitionof the potential binding site in the ori, mutations were madein A2 Rep gene to change Val9 to Ile and Asp10 to Asn. Simultaneously,the 3rd and 10th nucleotides on the potential binding site inA2 (GGCGTCTGGCGTC) were mutated to T and A, respectively (GGTGTCGGAGTC)to make the repeat sequence identical to that of A1 (mutant A2-RepM1/CRM3[Fig. 1C]). As expected, the mutant A2-RepM1/CRM3 was functionalin protoplasts and replicated DNA-A and DNA-B to wild-type levels(Fig. 2B, lanes 8 and 17; Table 2). Also, plants inoculated withmutant A2-RepM1/CRM3 and B1 produced severe symptoms within 2weeks after inoculation, accumulating high levels of viral DNA(Fig. 3B, lanes 8 and 17; Table 2). These results implied thatthe 13-mer sequence identified in the ori of A2 is the putativebinding site and plays a significant role in replication and thatIle9 and Asn10 may be involved in specific interaction betweenRep and ori.

Of the two amino acid changes made, Asp10 to Asn is expected to be more significant than Val9 to Ile9; we therefore made anothermutant, A2-RepM2/CRM3, where only the Asp10 to Asn of Rep proteinin A2 is changed together with 3rd (C to T) and the 10th (C toA) nucleotides of the ori to make it identical to A1 (Fig. 1C).In an analogous experiment, the Asn10-to-Asp change was made inRep protein of A1 (A1-RepM3) without any changes in its ori (Fig.1C). Protoplasts transfected with A2-RepM2/CRM3 accumulated highlevels of viral DNA (Fig. 2B, lanes 9 and 18; Table 2) comparableto the wild-type severe strain. The corresponding mutant, A1-RepM3with the Asn10-to-Asp change in the Rep protein of A1, replicatedto very low levels in protoplasts (Fig. 2A, lanes 5 and 14; Table2). N. benthamiana plants inoculated with the mutant A2-RepM2/CRm3developed severe symptoms and accumulated increased levels ofviral DNA (Fig. 3B, lanes 9 and 18; Table 2), showing that Asn10alone is sufficient to facilitate specific replication of thevirus. In contrast, plants inoculated with A1-RepM3, which containsa substitution in the 10th residue of its Rep protein, did notreplicate viral DNA with high efficiency (Fig. 3A, lanes 5 and12; Table 2).

Asn10 may interact with the third nucleotide of the 5' iteron, GGTGTC. While the above experiment showed that Asn10 in Rep protein may be involved in specific recognition of the ori, it was essentialto determine if both the 3' and 5' repeats in the 13-mer bindingsite contributed to the specificity of recognition. To addressthis question, the A1 DNA was mutated at the third nucleotidein this sequence, substituting C for T (A1-CRM4) so that the altered5' iteron is GGCGTCTGGAGGTC. The mutant A1-CRM4 did not replicateefficiently in protoplasts and very low levels of viral DNA accumulated(Fig. 2A, lanes 8 and 17; Table 2), suggesting that Rep proteinmay be unable to recognize the modified binding site. This mutantwas further modified by changing Asn10 to Asp (A1-RepM4/CRM4 [Fig.1C]). The mutant A1-RepM4/CRM4 accumulated wild-type levels ofDNA-A in protoplasts (Fig. 2A, lanes 9 and 18; Table 2), indicatingthat Asp10 may indeed interact with the third base of the iteronGGCGTCsequence.

	DISCUSSION

Top Abstract Introduction Materials and Methods Results Discussion References

We investigated the specificity of interactions between Rep proteins and ori sequences in two related strains of ToLCV-Nde.The studies showed that the amino acid at position 10 in Rep proteincoupled with a change in the binding site sequence may determinewhether the viral DNA is replicated. Change of Asp10 to Asn inRep protein of the mild strain accompanied by exchange of the13-mer binding site (making it identical to the severe strain)altered its replication, leading to increased accumulation ofviral DNA. In addition, the mild strain thus modified could replicateheterologous strain DNA-B, indicating that the interaction ofRep protein with its binding site may be essential for replicationof viral DNA. Based on site-directed mutations, we propose thatAsn10 specifically recognizes the third base pair of the 5' iteronGGTGTC in the severestrain.

Even though the DNA-A component of the severe (A1) and mild (A2) strains share 94% sequence identity, A2 did not replicateefficiently in protoplasts or plants, nor did it support the replicationof DNA-B1. These results support the hypothesis that the mildsymptoms in plants inoculated with A2 and B1 are caused by lowlevels of replication of DNA-A combined with very low levels ofDNA-B. Comparison of amino acid sequences in Rep proteins of thetwo strains revealed 22 amino acid differences, 18 of which arelocated in the C-terminal region of Rep protein. The results ofexperiments in which sequences of Rep proteins were exchangedindicated that the region encoding 256 amino acid residues fromthe C-terminal end did not affect viral replication. On the contrary,exchange of amino acids 1 to 110 of Rep was deleterious to virusaccumulation, suggesting that this region may contain sequencescrucial for virus replication. However, N-terminal sequences inRep protein alone may not account for the replication specificity,as shown by the mild strain mutant A2-CRB1, which contained theexchanged CR but failed to replicate viral DNA. These resultsimply that Rep proteins exhibit specificity in their interactionwith their template and are not interchangeable. Similar resultshave been obtained with strains of TYLCV (17), TGMV (13, 25),and beet curly top virus (BCTV) (4, 5, 32).

Of the four amino acid differences in the N-terminal region (amino acids 1 to 110) between the Rep genes of A1 and A2, wechose to mutate Ile9 and Asn10 because of their proximity to motifI (FLTYPKC), a conserved element found in all the initiator proteinsthat replicate via a rolling circle mechanism (18). Replicationassays in protoplasts and in plants obtained with the mild strainmutants A2RepM1/CRA1 and A2-RepM1/CRB1 provided evidence thatthese amino acids may be involved in specificity because of theirinteraction with the sequences in theCR.

The binding site of Rep protein of ToLCV-Nde has not been biochemically determined. We used site-directed mutagenesis to determinewhether the 13-nucleotide sequence identified in the ori interactsin a functional way with the Rep protein. The severe strain mutantsA1-CRM1 and A1-CRM2, which contain single nucleotide deletionsin the 13-mer sequence, failed to accumulate viral DNA, demonstratingthat the CR sequence is essential for virus replication. Sincethese deletions also affected spacing of the putative bindingsite, these results indicate that both sequence and spacing maycontribute to specificity. Mutational analysis of the Rep bindingsite in TGMV showed that both spacing and sequence of the bindingsite are important for replication (26).

The mutant A2-RepM2/CRM3, which contains an Asp10-to-Asn mutation in the Rep protein and corresponding changes in the potentialbinding site sequence, GGCGTCTGGCGTC to GGTGTCTGGAGTC (identicalto the severe strain), restored the replication efficiency ofA2 DNA. These results indicated that Asn10 may differentiate betweenA1 and A2 strains and determine the specificity in recognizingori sequences. In addition, the fact that replication of B1 wasrestored by changing the putative binding site sequence of A2coupled with mutation of the Rep protein support the conclusionthat both components are key factors that determine which DNAtemplate is to undergo replication. We did not study the roleof the other two amino acids, Lys40 and Glu54, that are differentbetween the two Rep proteins and therefore do not conclude thatAsn10 is solely responsible for strainspecificity.

Since the iteron sequences in the binding sites of A1 and A2 are different with respect to the 3rd and 10th nucleotides, weexamined the significance of these differences in context of Asn10in Rep protein. These studies led to the conclusion that a GGCGTCiteron in the putative binding site may be correlated with thepresence of Asp in Rep protein at position 10 of A2. Likewise,in related experiments we showed that Asn10 may recognize thethird base pair in the 5' iteron GGTGTC. It is possible that Asn10is a part of the DNA binding domain of Rep protein which allowsappropriate structural presentation of the Rep protein that potentiatesrecognition with the iteron sequences by Rep protein and facilitatesreplication. In TGMV, the deletion of the first 29 amino acidsabolished DNA binding and DNA cleavage, demonstrating that anintact N terminus is required for both activities (25). Theinability of the Cal/Logan strain to replicate the Worland orthe CFH strain of BCTV (32) was correlated to the differencesin the third base pair of the 5' iteron sequence, supporting ourobservations that variation in this region of the sequence maybe crucial in determining the replication ability between thestrains. Similar reports of incongruity have been shown for differentstrains of TYLCV (17) whose Rep proteins share more than 76%amino acid identity but are not interchangeable and between TGMVand BGMV (12), probably because of differences in their iteronsequences, supporting the importance of specific interaction betweenthe Rep protein and its recognitionsequence.

The iteron sequences of A1 and B1 are not identical. Point mutations introduced in the 5' iteron of the severe strain (mutantA1-CRM4) to make it identical to its 3' homolog (A1-CRM4) resultedin drastic reduction in virus replication, indicating that thetwo iterons do not contribute equally to the recognition process.Yet, a deletion of the 10th nucleotide of the repeat motif (A1-CRM2)reduced the replication levels in A1, suggesting that both iteronsare required for replication. Similarly, differential contributionsof the two iterons have been reported for TGMV (11) and BCTV(5). Unlike the reports of Fontes et al. (11) and Choi andStenger (5), our studies indicated that the 5' iteron contributesto replication more than the 3' iteron, for example, in mutantA1-CRM4. It is possible that in the case of ToLCV, the Rep proteinhas a stronger affinity for the 5' than the 3' iteron, but detailedin vitro binding assays that examine the interaction of Rep proteinwith each of the iterons are required to confirm thissuggestion.

Our studies showed a correlation between the amino acid at the 10th position in Rep protein and the 3rd nucleotide of the5' iteron in the binding site and specificity of replication betweenthe strains. This suggestion was supported by several observations:A2 DNA mutated at position 10 (Asp to Asn) in the Rep proteinwith a concomitant change in the third nucleotide of the putativebinding site (A2-RepM2/CRM3) resulted in increased levels of virusaccumulation. Similarly, the mutant, A1-RepM4, containing a changeof Asn10 to Asp in Rep protein without any change in its bindingsite accumulated very low levels of virus DNA. Further, the changeof Asn10 to Asp accompanied by a change in the 5' iteron of thebinding site (mutant A1-RepM4/CRM4) restored virus replication,suggesting that the correlation between the amino acid at position10 and the third nucleotide of the iteron may indeed be relatedto specificity ofreplication.

The observed specificity of the Rep protein with sequences in the ori accounts for selective replication of A1 and A2 strains.While earlier work (4, 5, 17, 22) has shown that specificityof replication may reside within the N-terminal sequences of theRep, our work delimits the specificity determinants to amino acidAsn10 of Rep protein in case of the two strains of ToLCV-Nde.Since Asn10 is very closely associated with the conserved motifI sequence, FLTYPKC (18), in Rep protein, we suggest that itmay function as a part of motif I to mediate specific replicationof the cognate genomes. Experiments are in progress to determineif changes at Asn10 in Rep protein affects its capacity to bindDNA.

	ACKNOWLEDGMENTS

This work was supported by financial assistance from the Department of Science and Technology, New Delhi, India (as a BOYSCASTfellowship to A.C.) and ORSTOM, Paris,France.

We thank Hal Padgett, Mohammed Bendahmane, and Gerardo Arguello-Astorga (CINVESTAV, Irapuato, Mexico) for discussions andcritical reading of themanuscript.

	FOOTNOTES

^* Corresponding author. Mailing address: International Laboratory for Tropical Agricultural Biotechnology (ILTAB/ORSTOM-TSRI),Division of Plant Biology, BCC 206, The Scripps Research Institute,10550 N. Torrey Pines Rd., La Jolla, CA 92037. Phone: (619) 784-2909.Fax: (619) 784-2994. E-mail: iltab{at}scripps.edu.

Present address: Donald Danforth Plant Center, St. Louis, MO63105.

REFERENCES

Top
Abstract
Introduction
Materials and Methods
Results
Discussion
References

1. Arguello-Astorga, G. R., R. G. Guevara-Gonzalez, L. R. Herrera-Estrella, and R. F. Rivera-Bustamante. 1994. Geminivirus replication origins have a group specific organization of iterative elements: a model for replication. Virology 203:90-100[Medline].

2. Behjatnia, S. A., I. B. Dry, and M. Ali Rezaian. 1998. Identification of the replication associated protein binding domain within the intergenic region of tomato leaf curl geminivirus. Nucleic Acids Res. 26:925-931[Abstract/Free Full Text].

3. Brough, C. L., R. J. Hayes, A. J. Morgan, R. H. A. Coutts, and K. W. Buck. 1988. Effects of mutagenesis in vitro on the ability of cloned tomato golden mosaic geminivirus DNA to infect Nicotiana benthamiana plants. J. Gen. Virol. 69:503-514.

4. Choi, I.-R., and D. C. Stenger. 1995. Strain-specific determinants of beet curly top geminivirus DNA. Virology 206:904-912[Medline].

5. Choi, I.-R., and D. C. Stenger. 1996. The strain-specific cis acting element of beet curly top geminivirus DNA replication maps to the directly repeated motif of the ori. Virology 226:122-126[Medline].

6. Dellaporta, S. L., J. Wood, and J. B. Hicks. 1983. A plant DNA minipreparation: version II. Plant Mol. Biol. 1:19-21.

7. Eagle, P. A., B. M. Orozco, and L. Hanley-Bowdoin. 1994. A DNA sequence required for geminivirus replication also mediates transcriptional regulation. Plant Cell 6:1157-1170[Abstract].

8. Eagle, P. A., and L. Hanley-Bowdoin. 1997. cis elements that contribute to geminivirus transcriptional regulation and the efficiency of DNA replication. J. Virol. 71:6947-6955[Abstract].

9. Etessami, E., K. Saunders, J. Watts, and J. Stanley. 1991. Mutational analysis of complementary sense genes of African cassava mosaic virus DNA-A. J. Gen. Virol. 72:1005-1012[Abstract/Free Full Text].

10. Fontes, E. P. B., V. A. Luckow, and L. Hanley-Bowdoin. 1992. A geminivirus replication protein is a sequence specific DNA binding protein. Plant Cell 4:597-608[Abstract/Free Full Text].

11. Fontes, E. P. B., P. A. Eagle, P. S. Sipe, V. A. Luckow, and L. Hanley-Bowdoin. 1994. Interaction between a geminivirus replication protein and origin DNA is essential for viral replication. J. Biol. Chem. 269:8459-8465[Abstract/Free Full Text].

12. Fontes, E. P. B., H. J. Gladfelter, R. L. Schaffer, I. T. D. Petty, and L. Hanley-Bowdoin. 1994. Geminivirus replication origins have a modular organization. Plant Cell 6:405-416[Abstract].

13. Gladfelter, H. J., P. A. Eagle, E. P. B. Fontes, L. Batts, and L. Hanley-Bowdoin. 1997. Two domains of the AL1 protein mediate geminivirus origin recognition. Virology 239:186-197[Medline].

14. Heyraud-Nitschke, F., S. Schumacher, J. Laufs, S. Schaefer, J. Schell, and B. Gronenborn. 1995. Determination of the origin cleavage and joining domain of geminivirus Rep proteins. Nucleic Acids Res. 23:910-916[Abstract/Free Full Text].

15. Hoogstraten, R. A., S. F. Hanson, and D. P. Maxwell. 1996. Mutational analysis of the putative nicking motif in the replication associated protein (AC1) of bean golden mosaic virus. Mol. Plant Microbe Interact. 9:594-599[Medline].

16. Horton, R. M. 1994. In vitro recombination and mutagenesis of DNA. Methods Mol. Biol. 67:141-150.

17. Jupin, I., F. Hericourt, B. Benz, and B. Gronenborn. 1995. DNA replication specificity of TYLCV geminivirus is mediated by the amino terminal 116 amino acids of the rep protein. FEBS Lett. 262:116-120.

18. Koonin, E. V., and J. V. Ilyina. 1992. Geminivirus replication proteins are related to prokaryotic plasmid rolling circle DNA replication initiator proteins. J. Gen. Virol. 73:2763-2766[Abstract/Free Full Text].

19. Laufs, J., S. Schumacher, N. Geisler, I. Jupin, and B. Gronenborn. 1995. Identification of the nicking tyrosine of the geminivirus Rep protein. FEBS Lett. 377:258-262[Medline].

20. Laufs, J., W. Traut, F. Heyraud, V. Matzeit, S. G. Rogers, J. Schell, and B. Gronenborn. 1995. In vitro cleavage and joining at the viral origin of replication by the replication initiator protein of tomato leaf curl virus. Proc. Natl. Acad. Sci. USA 92:3879-3883[Abstract/Free Full Text].

21. Lazarowitz, S. 1992. Geminiviruses: genomes structure and gene function. Crit. Rev. Plant Sci. 11:327-349.

22. Lazarowitz, S. G., L. C. Wu, S. G. Rogers, and J. S. Elmer. 1992. Sequence-specific interaction with the viral AL-1 protein identifies a geminivirus DNA replication origin. Plant Cell 4:799-809[Abstract/Free Full Text].

23. Mettler, L. J. 1987. A simple and rapid method for minipreparation of DNA from tissue cultured plant cells. Plant Mol. Biol. Rep. 5:346-349.

24. Orozco, B. M., and L. Hanley-Bowdoin. 1996. A DNA structure is required for geminivirus origin function. J. Virol. 270:148-158.

25. Orozco, B. M., A.B. Miller, S. B. Settlage, and L. Hanley-Bowdoin. 1997. Functional domains of a geminivirus replication protein. J. Biol. Chem. 272:9840-9846[Abstract/Free Full Text].

26. Orozco, B. M., H. F. Gladfelter, S. B. Settlage, P. A. Eagle, R. N. Gentry, and L. Hanley-Bowdoin. 1998. Multiple cis acting elements contribute to geminivirus origin function. Virology 242:346-356[Medline].

27. Padidam, M., R. N. Beachy, and C. M. Fauquet. 1995. Tomato leaf curl geminivirus from India has a bipartite genome and coat protein is not essential for infectivity. J. Gen. Virol. 76:25-35[Abstract/Free Full Text].

28. Padidam, M., R. N. Beachy, and C. M. Fauquet. 1996. Role of AV2 ("precoat") and coat protein in viral replication and movement in tomato leaf curl geminivirus. Virology 224:390-404[Medline].

29. Saunders, K., A. Lucy, and J. Stanley. 1991. DNA forms of geminivirus African cassava mosaic geminivirus consistent with a rolling circle mechanism of replication. Nucleic Acids Res. 19:2325-2330[Abstract/Free Full Text].

30. Stanley, J. 1991. The molecular determinants of geminivirus pathogenesis. Semin. Virol. 2:139-150.

31. Stenger, D. C., G. N. Revington, M. C. Stevenson, and D. M. Bisaro. 1991. Replicational release of geminiviral genomes from tandemly repeated copies: evidence for rolling circle replication of a plant viral DNA. Proc. Natl. Acad. Sci. USA 88:8029-8033[Abstract/Free Full Text].

32. Stenger, D. C. 1998. Replication specificity elements of the Worland strain of beet curly top virus are compatible with those of the CFH strain but not those of the Cal/Logan strain. Phytopathology 88:1174-1178[Medline].

33. Watanabe, B., T. Meshi, and Y. Okada. 1987. Infection of tobacco protoplasts with in vitro transcribed tobacco mosaic virus RNA using an improved electroporation method. FEBS Lett. 219:65-69.

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1.	Arguello-Astorga, G. R., R. G. Guevara-Gonzalez, L. R. Herrera-Estrella, and R. F. Rivera-Bustamante. 1994. Geminivirus replication origins have a group specific organization of iterative elements: a model for replication. Virology 203:90-100[Medline].
2.	Behjatnia, S. A., I. B. Dry, and M. Ali Rezaian. 1998. Identification of the replication associated protein binding domain within the intergenic region of tomato leaf curl geminivirus. Nucleic Acids Res. 26:925-931[Abstract/Free Full Text].
3.	Brough, C. L., R. J. Hayes, A. J. Morgan, R. H. A. Coutts, and K. W. Buck. 1988. Effects of mutagenesis in vitro on the ability of cloned tomato golden mosaic geminivirus DNA to infect Nicotiana benthamiana plants. J. Gen. Virol. 69:503-514.
4.	Choi, I.-R., and D. C. Stenger. 1995. Strain-specific determinants of beet curly top geminivirus DNA. Virology 206:904-912[Medline].
5.	Choi, I.-R., and D. C. Stenger. 1996. The strain-specific cis acting element of beet curly top geminivirus DNA replication maps to the directly repeated motif of the ori. Virology 226:122-126[Medline].
6.	Dellaporta, S. L., J. Wood, and J. B. Hicks. 1983. A plant DNA minipreparation: version II. Plant Mol. Biol. 1:19-21.
7.	Eagle, P. A., B. M. Orozco, and L. Hanley-Bowdoin. 1994. A DNA sequence required for geminivirus replication also mediates transcriptional regulation. Plant Cell 6:1157-1170[Abstract].
8.	Eagle, P. A., and L. Hanley-Bowdoin. 1997. cis elements that contribute to geminivirus transcriptional regulation and the efficiency of DNA replication. J. Virol. 71:6947-6955[Abstract].
9.	Etessami, E., K. Saunders, J. Watts, and J. Stanley. 1991. Mutational analysis of complementary sense genes of African cassava mosaic virus DNA-A. J. Gen. Virol. 72:1005-1012[Abstract/Free Full Text].
10.	Fontes, E. P. B., V. A. Luckow, and L. Hanley-Bowdoin. 1992. A geminivirus replication protein is a sequence specific DNA binding protein. Plant Cell 4:597-608[Abstract/Free Full Text].
11.	Fontes, E. P. B., P. A. Eagle, P. S. Sipe, V. A. Luckow, and L. Hanley-Bowdoin. 1994. Interaction between a geminivirus replication protein and origin DNA is essential for viral replication. J. Biol. Chem. 269:8459-8465[Abstract/Free Full Text].
12.	Fontes, E. P. B., H. J. Gladfelter, R. L. Schaffer, I. T. D. Petty, and L. Hanley-Bowdoin. 1994. Geminivirus replication origins have a modular organization. Plant Cell 6:405-416[Abstract].
13.	Gladfelter, H. J., P. A. Eagle, E. P. B. Fontes, L. Batts, and L. Hanley-Bowdoin. 1997. Two domains of the AL1 protein mediate geminivirus origin recognition. Virology 239:186-197[Medline].
14.	Heyraud-Nitschke, F., S. Schumacher, J. Laufs, S. Schaefer, J. Schell, and B. Gronenborn. 1995. Determination of the origin cleavage and joining domain of geminivirus Rep proteins. Nucleic Acids Res. 23:910-916[Abstract/Free Full Text].
15.	Hoogstraten, R. A., S. F. Hanson, and D. P. Maxwell. 1996. Mutational analysis of the putative nicking motif in the replication associated protein (AC1) of bean golden mosaic virus. Mol. Plant Microbe Interact. 9:594-599[Medline].
16.	Horton, R. M. 1994. In vitro recombination and mutagenesis of DNA. Methods Mol. Biol. 67:141-150.
17.	Jupin, I., F. Hericourt, B. Benz, and B. Gronenborn. 1995. DNA replication specificity of TYLCV geminivirus is mediated by the amino terminal 116 amino acids of the rep protein. FEBS Lett. 262:116-120.
18.	Koonin, E. V., and J. V. Ilyina. 1992. Geminivirus replication proteins are related to prokaryotic plasmid rolling circle DNA replication initiator proteins. J. Gen. Virol. 73:2763-2766[Abstract/Free Full Text].
19.	Laufs, J., S. Schumacher, N. Geisler, I. Jupin, and B. Gronenborn. 1995. Identification of the nicking tyrosine of the geminivirus Rep protein. FEBS Lett. 377:258-262[Medline].
20.	Laufs, J., W. Traut, F. Heyraud, V. Matzeit, S. G. Rogers, J. Schell, and B. Gronenborn. 1995. In vitro cleavage and joining at the viral origin of replication by the replication initiator protein of tomato leaf curl virus. Proc. Natl. Acad. Sci. USA 92:3879-3883[Abstract/Free Full Text].
21.	Lazarowitz, S. 1992. Geminiviruses: genomes structure and gene function. Crit. Rev. Plant Sci. 11:327-349.
22.	Lazarowitz, S. G., L. C. Wu, S. G. Rogers, and J. S. Elmer. 1992. Sequence-specific interaction with the viral AL-1 protein identifies a geminivirus DNA replication origin. Plant Cell 4:799-809[Abstract/Free Full Text].
23.	Mettler, L. J. 1987. A simple and rapid method for minipreparation of DNA from tissue cultured plant cells. Plant Mol. Biol. Rep. 5:346-349.
24.	Orozco, B. M., and L. Hanley-Bowdoin. 1996. A DNA structure is required for geminivirus origin function. J. Virol. 270:148-158.
25.	Orozco, B. M., A.B. Miller, S. B. Settlage, and L. Hanley-Bowdoin. 1997. Functional domains of a geminivirus replication protein. J. Biol. Chem. 272:9840-9846[Abstract/Free Full Text].
26.	Orozco, B. M., H. F. Gladfelter, S. B. Settlage, P. A. Eagle, R. N. Gentry, and L. Hanley-Bowdoin. 1998. Multiple cis acting elements contribute to geminivirus origin function. Virology 242:346-356[Medline].
27.	Padidam, M., R. N. Beachy, and C. M. Fauquet. 1995. Tomato leaf curl geminivirus from India has a bipartite genome and coat protein is not essential for infectivity. J. Gen. Virol. 76:25-35[Abstract/Free Full Text].
28.	Padidam, M., R. N. Beachy, and C. M. Fauquet. 1996. Role of AV2 ("precoat") and coat protein in viral replication and movement in tomato leaf curl geminivirus. Virology 224:390-404[Medline].
29.	Saunders, K., A. Lucy, and J. Stanley. 1991. DNA forms of geminivirus African cassava mosaic geminivirus consistent with a rolling circle mechanism of replication. Nucleic Acids Res. 19:2325-2330[Abstract/Free Full Text].
30.	Stanley, J. 1991. The molecular determinants of geminivirus pathogenesis. Semin. Virol. 2:139-150.
31.	Stenger, D. C., G. N. Revington, M. C. Stevenson, and D. M. Bisaro. 1991. Replicational release of geminiviral genomes from tandemly repeated copies: evidence for rolling circle replication of a plant viral DNA. Proc. Natl. Acad. Sci. USA 88:8029-8033[Abstract/Free Full Text].
32.	Stenger, D. C. 1998. Replication specificity elements of the Worland strain of beet curly top virus are compatible with those of the CFH strain but not those of the Cal/Logan strain. Phytopathology 88:1174-1178[Medline].
33.	Watanabe, B., T. Meshi, and Y. Okada. 1987. Infection of tobacco protoplasts with in vitro transcribed tobacco mosaic virus RNA using an improved electroporation method. FEBS Lett. 219:65-69.