The phenotype in vitro and in infected cells of herpes simplex virus 1 alpha trans-inducing factor (VP16) carrying temperature-sensitive mutations introduced by substitution of cysteines.

alpha trans-inducing factor (alpha TIF, VP16, Vmw65) is an essential structural protein of herpes simplex virus, being required for virion assembly. The protein also forms complexes with host proteins and a response element and transactivates the alpha genes which carry this element. The protein contains an acidic carboxyl terminus required for transactivation and a much larger amino-terminal domain required for promoter recognition. We report the first set of temperature-sensitive (ts) mutations deliberately introduced into the protein by substitution of the cysteine codons with those specifying glycine at positions 78, 102, and 176, either singly or in combinations. We report the following results. (i) All mutated proteins synthesized in vitro formed complexes with the DNA response element at room temperature. However, the mutant with the triple substitution and two mutants with substitutions in two of the three cysteines exhibited a ts phenotype at 33 and 37 degrees C, and one exhibited a ts phenotype only at 37 degrees C. (ii) Replacement of wild-type alpha TIF with genes carrying substitutions in any two cysteines conferred a ts phenotype for replication at 39.5 degrees C. Shift-down experiments indicated that the 10(4)- to 10(5)-fold reduction in virus yield at the nonpermissive temperature was due to the disfunction of alpha TIF late in infection, presumably in virion maturation. (iii) The alpha TIF expressed in cells infected with mutant viruses exhibited the same ts phenotype in protein-DNA complex formation as those expressed in vitro from mutated plasmids. Although the virus carrying the alpha TIF substitutions at Cys-102 and Cys-176 failed to induce a reporter gene linked to the alpha 4 promoter at 39.5 degrees C, it replicated as well as the parent virus in cells maintained for the first 10 h of infection at 39.5 degrees C. We conclude the following. (i) Formation of DNA-protein complexes containing alpha TIF is a poor prognosticator of alpha TIF function. (ii) The data presented here and in the literature strongly support the hypothesis that the secondary structure of the alpha TIF is very sensitive to deletions or insertions which probably affect the interaction of alpha TIF with both viral proteins in the virion and cellular proteins during infection. As a consequence, deletion-insertion mutagenesis may not shed useful information on the role of transactivating function of alpha TIF in infection. (iii) Since cysteines may play a role in stabilizing the secondary structure of proteins, substitutions of cysteines may be a powerful technique for site-specific construction of ts mutants in essential viral proteins.     

Tritium planigraphy comparative structural study of tobacco mosaic virus and its mutant with altered host specificity.

Spatial organization of wild-type (strain U1) tobacco mosaic virus (TMV) and of the temperature-sensitive TMV ts21-66 mutant was compared by tritium planigraphy. The ts21-66 mutant contains two substitutions in the coat protein (Ile21-->Thr and Asp66-->Gly) and, in contrast with U1, induces a hypersensitive response (formation of necroses) on the leaves of plants bearing a host resistance gene N' (for example Nicotiana sylvestris); TMV U1 induces systemic infection (mosaic) on the leaves of such plants. Tritium distribution along the coat protein (CP) polypeptide chain was determined after labelling of both isolated CP preparations and intact virions. In the case of the isolated low-order (3-4S) CP aggregates no reliable differences in tritium distribution between U1 and ts21-66 were found. But in labelling of the intact virions a significant difference between the wild-type and mutant CPs was observed: the N-terminal region of ts21-66 CP incorporated half the amount of tritium than the corresponding region of U1 CP. This means that in U1 virions the CP N-terminal segment is more exposed on the virion surface than in ts21-66 virions. The possibility of direct participation of the N-terminal tail of U1 CP subunits in the process of the N' hypersensitive response suppression is discussed.     

Odontoglossum ringspot virus host range restriction in Nicotiana sylvestris maps to the replicase gene

The experimental host range of Odontoglossum ringspot virus (ORSV), a member of the tobamoviruses, includes several species of Nicotiana , but not N. sylvestris . However, ORSV was able to replicate in protoplasts from N. sylvestris leaves. By using the green fluorescent protein (GFP) as a marker inserted into ORSV, it was found that a small number of single epidermal cells became infected in mechanically inoculated leaves, but the virus did not move cell to cell. The ORSV movement protein (MP) and coat protein (CP) were examined for their ability to effect movement by substitution into Tobacco mosaic virus (TMV) hybrids. Both proteins and the 3' non-translated region (NTR) of ORSV allowed movement of TMV hybrids in N. sylvestris . These results suggested that the inability of ORSV to move in N. sylvestris was due to the replicase gene or the 5'NTR. One possibility was that the replicase gene could indirectly affect movement by failing to produce subgenomic (sg) RNAs for expression of MP or CP, but this appeared not to be the case as ORSV replicated and produced MP and CP sgRNAs, both of which were translated in N. sylvestris protoplasts. Additionally, genomic RNA was encapsidated into virions in N. sylvestris protoplasts. Because the 5'NTR permitted efficient replication and production of replicase proteins, these findings suggest that the replicase of ORSV is responsible for the defect in cell-to-cell movement of ORSV in N. sylvestris .     

Low sodium dodecyl sulfate concentrations inhibit tobacco mosaic virus coat protein amorphous aggregation and change the protein stability

Effects of low SDS concentrations on amorphous aggregation of tobacco mosaic virus (TMV) coat protein (CP) at 52 degrees C and on the protein structure were studied. It was found that SDS completely inhibits the TMV CP (11.5 microM) unordered aggregation at the detergent/CP molar ratio of 15 : 1 (0.005% SDS). As judged by fluorescence spectroscopy, these SDS concentrations did not prevent heating-induced disordering of the large-distance part of the TMV CP subunit, including the so-called "hydrophobic girdle". At somewhat higher SDS/protein ratio (40 : 1) the detergent completely disrupted the TMV CP hydrophobic girdle structure even at room temperature. At the same time, these low SDS concentrations (15 : 1, 40 : 1) strongly stabilized the structure of the small-distance part of the TMV CP molecule (the four alpha-helix bundle) against thermal disordering as judged by the far-UV (200-250 nm) CD spectra. Possible mechanisms of TMV CP heating-induced unordered aggregation initiation are discussed.     

A mechanism of macroscopic (amorphous) aggregation of the tobacco mosaic virus coat protein

To gain more insight into the mechanisms of heating-induced irreversible macroscopic aggregation of the tobacco mosaic virus (TMV) coat protein (CP), the effects of pH and ionic strength on this process were studied using turbidimetry, CD spectroscopy, and fluorescence spectroscopy. At 42 degrees C, the TMV CP passed very rapidly (in less than 15s) into a slightly unfolded conformation, presumably because heating disordered a segment of the subunit where the so-called hydrophobic girdle of the molecule resides. We suppose that the amino acid residues of this girdle are responsible for the aberrant hydrophobic interactions between subunits that initiate macroscopic protein aggregation. Its rate increased by several thousands of times as the phosphate buffer molarity was varied from 20 to 70 mM, suggesting that neutralization of strong repulsive electrostatic interactions of TMV CP molecules at high ionic strengths is a prerequisite for amorphous aggregation of this protein.     

Cymbidium ringspot tombusvirus coat protein coding sequence acts as an avirulent RNA

Avirulent genes either directly or indirectly produce elicitors that are recognized by specific receptors of plant resistance genes, leading to the induction of host defense responses such as hypersensitive reaction (HR). HR is characterized by the development of a necrotic lesion at the site of infection which results in confinement of the invader to this area. Artificial chimeras and mutants of cymbidium ringspot (CymRSV) and the pepper isolate of tomato bushy stunt (TBSV-P) tombusviruses were used to determine viral factors involved in the HR resistance phenotype of Datura stramonium upon infection with CymRSV. A series of constructs carrying deletions and frameshifts of the CymRSV coat protein (CP) undoubtedly clarified that an 860-nucleotide (nt)-long RNA sequence in the CymRSV CP coding region (between nt 2666 and 3526) is the elicitor of a very rapid HR-like response of D. stramonium which limits the virus spread. This finding provides the first evidence that an untranslatable RNA can trigger an HR-like resistance response in virus-infected plants. The effectiveness of the resistance response might indicate that other nonhost resistance could also be due to RNA-mediated HR. It is an appealing explanation that RNA-mediated HR has evolved as an alternative defense strategy against RNA viruses.     

Biophysical characterization of a designed TMV coat protein mutant, R46G, that elicits a moderate hypersensitivity response in Nicotiana sylvestris

The hypersensitivity resistance response directed by the N' gene in Nicotiana sylvestris is elicited by the tobacco mosaic virus (TMV) coat protein R46G, but not by the U1 wild-type TMV coat protein. In this study, the structural and hydrodynamic properties of R46G and wild-type coat proteins were compared for variations that may explain N' gene elicitation. Circular dichroism spectroscopy reveals no significant secondary or tertiary structural differences between the elicitor and nonelicitor coat proteins. Analytical ultracentrifugation studies, however, do show different concentration dependencies of the weight average sedimentation coefficients at 4 degrees C. Viral reconstitution kinetics at 20 degrees C were used to determine viral assembly rates and as an initial assay of the rate of 20S formation, the obligate species for viral reconstitution. These kinetic results reveal a decreased lag time for reconstitution performed with R46G that initially lack the 20S aggregate. However, experiments performed with 20S initially present reveal no detectable differences indicating that the mechanism of viral assembly is similar for the two coat protein species. Therefore, an increased rate of 20S formation from R46G subunits may explain the differences in the viral reconstitution lag times. The inferred increase in the rate of 20S formation is verified by direct measurement of the 20S boundary as a function of time at 20 degrees C using velocity sedimentation analysis. These results are consistent with the interpretation that there may be an altered size distribution and/or lifetime of the small coat protein aggregates in elicitors that allows N. sylvestris to recognize the invading virus.     

Properties of the Coat Protein of a New Tobacco Mosaic Virus Coat Protein ts-Mutant

Amino acid substitutions in a majority of tobacco mosaic virus (TMV) coat protein (CP) ts-mutants have previously been mapped to the same region of the CP molecule tertiary structure, located at a distance of about 70 Å from TMV virion axis. In the present work some properties of a new TMV CP ts-mutant ts21-66 (two substitutions I21 T and D66 G, both in the 70-Å region) were studied. Thermal inactivation characteristics, sedimentation properties, circular dichroism spectra, and modification by a lysine-specific reagent, trinitrobenzensulfonic acid, of ts21–66 CP were compared with those of wild-type (U1) TMV CP. It is concluded that the 70-Å region represents the most labile portion of the TMV CP molecule. Partial disordering of this region in the mutant CP at permissive temperatures leads to loss of the capacity to form two-layer aggregates of the cylindrical type, while further disordering induced by mild heating results also in the loss of the ability to form ordered helical aggregates.     

Mutants of tobacco mosaic virus with temperature-sensitive coat proteins induce heat shock response in tobacco leaves.

We analyzed, with respect to heat shock proteins (HSPs), systemically reacting tobacco leaves inoculated with Tobacco mosaic virus (TMV), wild-type vulgare, and temperature-sensitive coat protein (CP) mutants Ni 118 (P20L) and flavum (D19A), kept at 23 or 30 degrees C. HSP18 and HSP70 mRNAs and proteins were induced with temperature-sensitive CP mutants after 1 to 2 days at 30 degrees C. After 4 to 6 days, HSP70 was also induced at 23 degrees C. The induction of HSPs paralleled the amount of insoluble TMV CP in leaf extracts, indicating that denatured TMV CP by itself induces a heat-shock response.     

Structural elucidation and functional characterization of the Hyaloperonospora arabidopsidis effector protein ATR13

The oomycete Hyaloperonospora arabidopsidis (Hpa) is the causal agent of downy mildew on the model plant Arabidopsis thaliana and has been adapted as a model system to investigate pathogen virulence strategies and plant disease resistance mechanisms. Recognition of Hpa infection occurs when plant resistance proteins (R-genes) detect the presence or activity of pathogen-derived protein effectors delivered to the plant host. This study examines the Hpa effector ATR13 Emco5 and its recognition by RPP13-Nd, the cognate R-gene that triggers programmed cell death (HR) in the presence of recognized ATR13 variants. Herein, we use NMR to solve the backbone structure of ATR13 Emco5, revealing both a helical domain and a disordered internal loop. Additionally, we use site-directed and random mutagenesis to identify several amino acid residues involved in the recognition response conferred by RPP13-Nd. Using our structure as a scaffold, we map these residues to one of two surface-exposed patches of residues under diversifying selection. Exploring possible roles of the disordered region within the ATR13 structure, we perform domain swapping experiments and identify a peptide sequence involved in nucleolar localization. We conclude that ATR13 is a highly dynamic protein with no clear structural homologues that contains two surface-exposed patches of polymorphism, only one of which is involved in RPP13-Nd recognition specificity.     

Expression of the baculovirus p35 protein in tobacco affects cell death progression and compromises N gene-mediated disease resistance response to Tobacco mosaic virus

The p35 protein from baculovirus is a broad-range caspase inhibitor and suppresses programmed cell death in animals. We report here the effects of transgenic expression in tobacco of the p35 protein during the hypersensitive response (HR). Expression of p35 causes partial inhibition of nonhost HR triggered by bacteria and gene-for-gene HR triggered by virus. Infection of p35-expressing tobacco plants with Tobacco mosaic virus (TMV) disrupts N-mediated disease resistance, causing systemic spreading of the virus within a resistant background. Mutant variants altered in aspartate residues within the loop region of p35 are inefficient substrates for caspases in vitro, and they do not suppress caspase proteolytic activity in animal systems. Tobacco plants expressing these mutant variants of the p35 protein do not show inhibition of HR cell death or enhanced virus systemic movement. Thus, HR inhibition and TMV systemic spreading phenotype in p35-expressing plants correlate with the ability of the p35 protein to suppress caspase activity in animal systems. In addition, a C-terminal truncated variant of p35 is unable to suppress cell death in animals as well as HR cell death in transgenic tobacco. Our results provide evidence for the participation of caspase-like proteases during the HR. In addition, they suggest that timely activation of cell death is necessary for effective TMV containment within the primary infection site.     

Infra-red thermography revealed a role for mitochondria in pre-symptomatic cooling during harpin-induced hypersensitive response

The establishment of Erwinia amylovora harpin-induced hypersensitive response (HR) in Nicotiana sylvestris was followed by infra-red thermography (IRT). Three to four hours after elicitation, the temperature decreased in the harpin-infiltrated zone associated to stomatal opening. The marked drop in temperature which reached 2 degrees C and preceded necrosis symptoms for several hours, is thus likely caused by higher transpiration. Neither of these effects was observed in a respiratory mutant, affected in complex I structure and function and over-expressing alternative oxidase, indicating that they are directly or indirectly mediated by mitochondrial function. However, as the HR establishment was similar in both wild type and mutant, cell death was either uncorrelated with the observed epidermal changes or occurred by a different signalling pathway in the two genotypes. IRT revealed a novel aspect of plant-pathogen interactions and could be applied to screen for mutants affected in elicitor signalling and/or for respiratory mutants.     

Crystal Structure of a Four-Layer Aggregate of Engineered TMV CP Implies the Importance of Terminal Residues for Oligomer Assembly

Background

Crystal structures of the tobacco mosaic virus (TMV) coat protein (CP) in its helical and disk conformations have previously been determined at the atomic level. For the helical structure, interactions of proteins and nucleic acids in the main chains were clearly observed; however, the conformation of residues at the C-terminus was flexible and disordered. For the four-layer aggregate disk structure, interactions of the main chain residues could only be observed through water–mediated hydrogen bonding with protein residues. In this study, the effects of the C-terminal peptides on the interactions of TMV CP were investigated by crystal structure determination.

Methodology/Principal Findings

The crystal structure of a genetically engineered TMV CP was resolved at 3.06 Å. For the genetically engineered TMV CP, a six-histidine (His) tag was introduced at the N-terminus, and the C-terminal residues 155 to 158 were truncated (N-His-TMV CP¹⁹). Overall, N-His-TMV CP¹⁹ protein self-assembled into the four-layer aggregate form. The conformations of residues Gln36, Thr59, Asp115 and Arg134 were carefully analyzed in the high radius and low radius regions of N-His-TMV CP¹⁹, which were found to be significantly different from those observed previously for the helical and four-layer aggregate forms. In addition, the aggregation of the N-His-TMV CP¹⁹ layers was found to primarily be mediated through direct hydrogen-bonding. Notably, this engineered protein also can package RNA effectively and assemble into an infectious virus particle.

Conclusion

The terminal sequence of amino acids influences the conformation and interactions of the four-layer aggregate. Direct protein–protein interactions are observed in the major overlap region when residues Gly155 to Thr158 at the C-terminus are truncated. This engineered TMV CP is reassembled by direct protein–protein interaction and maintains the normal function of the four-layer aggregate of TMV CP in the presence of RNA.     

Induction of a hypersensitive response by chimeric helicase sequences of tobamoviruses U1 and Ob in N-carrying tobacco

Recently, the helicase domain of the Tobacco mosaic virus (TMV)-U1 replicase proteins (designated MOREHEL:U1) was identified as the elicitor of the N gene-mediated hypersensitive response (HR) in tobacco. In this study, we used agroinfiltration to express the equivalent MOREHEL domain of the non-HR-inducing tobamovirus strain TMV-Ob. It appeared that this MOREHEL:Ob sequence did not elicit a HR in N gene-carrying tobacco. Both MOREHEL sequences were divided into eight subdomains, and chimeras of MOREHEL sequences from U1 and Ob were constructed. Expression of these chimeric MOREHEL sequences revealed that, in the TMV-U1 MOREHEL sequence, at least four domains involved in full HR induction were present. The presence of at least three of these four domains seems a minimal requirement for HR induction. Two additional domains may play a minor role in HR induction. To study the elicitor function of the chimeras during the TMV life cycle, chimeric MOREHEL domains were introduced into full-length TMV cDNA clones. These constructs, however, were unable to establish an infection in Nicotiana benthamiana or Nicotiana tabacum plants.     

Local and systemic spread of tobacco mosaic virus in transgenic tobacco.

Expression of a chimeric gene encoding the coat protein (CP) of tobacco mosaic virus (TMV) in transgenic tobacco plants confers resistance to infection by TMV. We investigated the spread of TMV within the inoculated leaf and throughout the plant following inoculation. Plants that expressed the CP gene [CP(+)] and those that did not [CP(-)] accumulated equivalent amounts of virus in the inoculated leaves after inoculation with TMV-RNA, but the CP(+) plants showed a delay in the development of systemic symptoms and reduced virus accumulation in the upper leaves. Tissue printing experiments demonstrated that if TMV infection became systemic, spread of virus occurred in the CP(+) plants essentially as it occurred in the CP(-) plants although at a reduced rate. Through a series of grafting experiments, we showed that stem tissue with a leaf attached taken from CP(+) plants prevented the systemic spread of virus. Stem tissue without a leaf had no effect on TMV spread. All of these findings indicate that protection against systemic spread in CP(+) plants is caused by one or more mechanisms that, in correlation with the protection against initial infection upon inoculation, result in a phenotype of resistance to TMV.     

Regulation of plasmodesmal transport by phosphorylation of tobacco mosaic virus cell-to-cell movement protein

Cell-to-cell spread of tobacco mosaic virus (TMV) through plant intercellular connections, the plasmodesmata, is mediated by a specialized viral movement protein (MP). In vivo studies using transgenic tobacco plants showed that MP is phosphorylated at its C-terminus at amino acid residues Ser258, Thr261 and Ser265. When MP phosphorylation was mimicked by negatively charged amino acid substitutions, MP lost its ability to gate plasmodesmata. This effect on MP-plasmodesmata interactions was specific because other activities of MP, such as RNA binding and interaction with pectin methylesterases, were not affected. Furthermore, TMV encoding the MP mutant mimicking phosphorylation was unable to spread from cell to cell in inoculated tobacco plants. The regulatory effect of MP phosphorylation on plasmodesmal permeability was host dependent, occurring in tobacco but not in a more promiscuous Nicotiana benthamiana host. Thus, phosphorylation may represent a regulatory mechanism for controlling the TMV MP-plasmodesmata interactions in a host-dependent fashion.     

Structural basis of Kbm8 alloreactivity. Amino acid substitutions on the beta-pleated floor of the antigen recognition site

We have analyzed the functional significance of the four amino acid differences between the parental H-2Kb and mutant H-2Kbm8 glycoproteins. Six bm8 variants including single substitutions at residues 22, 23, 24, and 30 as well as paired substitutions at residues 23, 30 and 22, 24 were generated and transfected into L cells. Surface expression of these H-2Kb variants was analyzed using monoclonal antibodies which bind to well-defined H-2Kb epitopes. No alterations introduced into the conformational structure of H-2Kb by the amino acid substitutions were detected. The effect of these substitutions on CTL recognition was initially analyzed using the following bulk CTL: either H-2Kb anti-H-2Kbm8, H-2Kbm8 anti-H-2Kb, or third party anti-H-2Kb. The alloreactivity between H-2Kb and H-2Kbm8 is dominated by the amino acid substitution at residue 24 (Glu----Ser). The complete bm8 phenotype, however, also requires the additional substitution at residue 22 (Tyr----Phe). The H-2Kbm8 anti-Kb bulk CTL reacted with both variant H-2Kbm8 molecules containing single substitutions at amino acid positions 22 or 24 but not the variant molecule containing both substitutions. Further analysis using three individual H-2Kbm8 anti-Kb CTL clones indicated the complexity of the self Kbm8 phenotype. Clone 8B1.20 did not react to changes in residues 22 or 24. The 8B1.32 clone reacted with the change at residue 22 but not with the change at residue 24, although the 8B1.54 clone reacted with the change at residue 24 but not with the change at residue 22. The changes in residues 23 (Met----Ile) and/or 30 (Asp----Asn) did not impact significantly on the alloantigenic properties of Kbm8 as determined by both the bulk and cloned CTL populations. According to the three-dimensional class I structure the substitution at amino acid 24 is inaccessible to the TCR. The location of this substitution within the Ag recognition site implies that altered peptide binding, and not a disruption of MHC residues that interact with the TCR, is responsible for the alloreactivity between H-2Kb and H-2Kbm8.     

Internal point mutations of the capsid modify the serotype of Rice yellow mottle virus

Rice yellow mottle virus is classified in five major serotypes; the molecular diversity of the coat protein (CP) is well established, but the amino acids involved in the recognition by discriminant monoclonal antibodies (MAbs) remain unknown. Reconstruction of a phylogenetic tree and sequence alignment of the CP gene of a sample representative of the continental-large diversity were used to identify 10 serospecific amino acids (i.e., conserved in all isolates belonging to the same serotype and distinct in other serotypes). Positions occupied by serospecific residues were localized on the crystal structure of the CP monomer and on modeled capsomers. Structural, molecular, and serological properties of each serotype were analyzed, and subsequently, hypotheses on the potential role of amino acids in discriminating reactions with antibodies were formulated. The residues 114 and 115 (serospecific of Sr1) and 190 (serospecific of Sr2) were localized on the outer surface of the capsid and might be directly involved in the immunoreactivity with MAb D and MAb A, respectively. In contrast, residues 180 (Sr3) and 178 (Sr5) lay within the inner surface of the capsid. To understand the role of these internal positions in the recognition with the antibodies, two substitutions (T180K and G178D) were introduced in the CP of an infectious clone. These mutations modified the antigenicity with MAb G and MAb E discriminating Sr3 and Sr5, respectively, while the reaction with MAb D remained unaffected. This result suggests an indirect effect of these two internal mutations on local immunostructure while the global structure was maintained.     

Concerted effects of amino acid substitutions in conserved charged residues and other residues in the cytoplasmic domain of PomA, a stator component of Na+-driven flagella

PomA is a membrane protein that is one of the essential components of the sodium-driven flagellar motor in Vibrio species. The cytoplasmic charged residues of Escherichia coli MotA, which is a PomA homolog, are believed to be required for the interaction of MotA with the C-terminal region of FliG. It was previously shown that a PomA variant with neutral substitutions in the conserved charged residues (R88A, K89A, E96Q, E97Q, and E99Q; AAQQQ) was functional. In the present study, five other conserved charged residues were replaced with neutral amino acids in the AAQQQ PomA protein. These additional substitutions did not affect the function of PomA. However, strains expressing the AAQQQ PomA variant with either an L131F or a T132M substitution, neither of which affected motor function alone, exhibited a temperature-sensitive (TS) motility phenotype. The double substitutions R88A or E96Q together with L131F were sufficient for the TS phenotype. The motility of the PomA TS mutants immediately ceased upon a temperature shift from 20 to 42 degrees C and was restored to the original level approximately 10 min after the temperature was returned to 20 degrees C. It is believed that PomA forms a channel complex with PomB. The complex formation of TS PomA and PomB did not seem to be affected by temperature. Suppressor mutations of the TS phenotype were mapped in the cytoplasmic boundaries of the transmembrane segments of PomA. We suggest that the cytoplasmic surface of PomA is changed by the amino acid substitutions and that the interaction of this surface with the FliG C-terminal region is temperature sensitive.     

Mutational analysis of Xanthomonas harpin HpaG identifies a key functional region that elicits the hypersensitive response in nonhost plants

HpaG is a type III-secreted elicitor protein of Xanthomonas axonopodis pv. glycines. We have determined the critical amino acid residues important for hypersensitive response (HR) elicitation by random and site-directed mutagenesis of HpaG and its homolog XopA. A plasmid clone carrying hpaG was mutagenized by site-directed mutagenesis, hydroxylamine mutagenesis, and error-prone PCR. A total of 52 mutants were obtained, including 51 single missense mutants and 1 double missense mutant. The HR elicitation activity was abolished in the two missense mutants [HpaG(L50P) and HpaG(L43P/L50P)]. Seven single missense mutants showed reduced activity, and the HR elicitation activity of the rest of the mutants was similar to that of wild-type HpaG. Mutational and deletion analyses narrowed the region essential for elicitor activity to the 23-amino-acid peptide (H2N-NQGISEKQLDQLLTQLIMALLQQ-COOH). A synthetic peptide of this sequence possessed HR elicitor activity at the same concentration as the HpaG protein. This region has 78 and 74% homology with 23- and 27-amino-acid regions of the HrpW harpin domains, respectively, from Pseudomonas and Erwinia spp. The secondary structure of the peptide is predicted to be an alpha-helix, as is the HrpW region that is homologous to HpaG. The predicted alpha-helix of HpaG is probably critical for the elicitation of the HR in tobacco plants. In addition, mutagenesis of a xopA gene yielded two gain-of-function mutants: XopA(F48L) and XopA(F48L/M52L). These results indicate that the 12 amino acid residues between L39 and L50 of HpaG have critical roles in HR elicitation in tobacco plants.