Localization of the VirA domain involved in acetosyringone-mediatedvir gene induction inAgrobacterium tumefaciens

The VirA protein ofAgrobacterium tumefaciens is thought to be a receptor for plant phenolic compounds such as acetosyringone. Although it is not known whether the interaction between VirA and the phenolics is direct or requires other phenolic-binding proteins, it is shown in this study that the first 280 amino acids of the VirA protein are not essential for the acetosyringone mediatedvir gene induction response. Considering the fact that the cytoplasmic region between the amino acids 283 and 304 is highly conserved between the different VirA proteins, and that deletion of this region abolishes VirA activity, we suggest that the acetosyringone receptor domain is located in this cytoplasmic domain of the VirA protein.     

Molecular characterization of the virulence gene virA of the Agrobacterium tumefaciens octopine Ti plasmid

The virulence loci play an essential role in tumor formation by Agrobacterium tumefaciens. Induction of vir gene expression by plant signal molecules is solely dependent on the virulence loci virA and virG. This study focused on the virA locus of the octopine type Ti plasmid pTi15955. The nucleic acid sequence of a 5.7-kilobase fragment encompassing virA was determined. Genetic analysis of this region revealed that virA contains one open reading frame coding for a protein of 91 639 daltons. Immunodetection with antibodies raised against a 35-kDa VirA fusion protein produced in E. coli identified the VirA product in wild-type Agrobacterium cells. Moreover, it is shown that the VirA protein is located in the cytoplasmic membrane fraction of Agrobacterium. These data confirm the proposed regulatory function of VirA whereby VirA acts as a membrane sensor protein to identify plant signal molecules in the environment. The proposed sensory function of VirA strikingly resembles the function of the chemotaxis receptor proteins of E. coli.     

The sensing of plant signal molecules by Agrobacterium: genetic evidence for direct recognition of phenolic inducers by the VirA protein

The virulence (vir) genes of Agrobacterium tumefaciens are induced by low-molecular-weight phenolic compounds and monosaccharides through a two-component regulatory system consisting of the VirA and VirG proteins. Although it is clear that the monosaccharides require binding to a periplasmic binding protein before they can interact with the sensor VirA protein, it is not certain whether the phenolic compounds also interact with a binding protein or directly interact with the sensor protein. To shed light on this question, we tested the vir-inducing abilities of several different phenolic compounds using two wild-type strains of A. tumefaciens, KU12 and A6. We found that several compounds such as 4-hydroxyacetophone and p-coumaric acid induced the vir of KU12, but not A6. On the other hand, acetosyringone and several other phenolic compounds induced the vir of A6, but not KU12. By transferring different Ti plasmids into isogenic chromosomal backgrounds, we showed that the phenolic sensing determinant is associated with the Ti plasmid. Subcloning of the Ti plasmid indicated that the virA locus determines which phenolic compounds can function as vir inducers. These results suggest that VirA directly senses the phenolic compounds for vir activation.     

Molecular characterization of the virulence gene virA of the Agrobacterium tumefaciens octopine Ti plasmid

The virulence loci play an essential role in tumor formation by Agrobacterium tumefaciens. Induction of vir gene expression by plant signal molecules is solely dependent on the virulence loci virA and virG. This study focused on the virA locus of the octopine type Ti plasmid pTi15955. The nucleic acid sequence of a 5.7-kilobase fragment encompassing virA was determined. Genetic analysis of this region revealed that virA contains one open reading frame coding for a protein of 91 639 daltons. Immunodetection with antibodies raised against a 35-kDa VirA fusion protein produced in E. coli identified by the VirA product in wild-type Agrobacterium cells. Moreover, it is shown that the VirA protein is located in the cytoplasmic membrane fraction of Agrobacterium. These data confirm the proposed regulatory function of VirA whereby VirA acts as a membrane sensor protein to identify plant signal molecules in the environment. The proposed sensory function of VirA strikingly resembles the function of the chemotaxis receptor proteins of E. coli.     

Genetic analysis of the signal-sensing region of the histidine protein kinase VirA of Agrobacterium tumefaciens

The membrane-bound sensor protein kinase VirA of Agrobacterium tumefaciens detects plant phenolic substances, which induce expression of vir genes that are essential for the formation of the crown gall tumor. VirA also responds to specific monosaccharides, which enhance vir expression. These sugars are sensed by the periplasmic domain of VirA that includes the region homologous to the chemoreceptor Trg, and the phenolics are thought to be detected by a part of the cytoplasmic linker domain, while the second transmembrane domain (TM2) is reported to be nonessential. To define regions of VirA that are essential for signal sensing, we introduced base-substitution and deletion mutations into coding regions that are conserved among the respective domains of VirA proteins from various Agrobacterium strains, and examined the effects of these mutations on vir induction and tumorigenicity. The results show that the Trg-homologous region in the periplasmic domain is not essential for the enhancement of vir gene expression by sugars. Most mutations in the TM2 domain also failed to influence enhancement by sugars and reduced the level of vir induction, but a mutation in the TM2 region adjacent to the cytoplasmic linker abolished induction of the vir genes. In the linker domain, sites essential for vir induction by phenolics were scattered over the entire region. We propose that a topological feature formed by the linker domain and at least part of the TM2 may be crucial for activation of a membrane-anchored VirA protein. Complementation analysis with two different VirA mutants suggested that intermolecular phosphorylation between VirA molecules occurs in vivo, and that two intact periplasmic regions in a VirA dimer are required for the enhancement of vir induction by sugars. Received: 14 December 1999 / Accepted: 10 April 2000     

Nucleotide sequence, evolutionary origin and biological role of a rearranged cytokinin gene isolated from a wide host range biotype III Agrobacterium strain

Summary A DNA fragment with homology to the cytokinin (ipt) gene from biotype I Agrobacterium tumefaciens strain Ach5 was cloned from the Ti plasmid of the wide host range biotype III Agrobacterium strain Tm-4 and sequenced. The fragment contains an intact ipt coding sequence. However, the 3 non-coding region of this ipt gene is rearranged due to a 0.9 kb deletion fusing it to the 3 coding region of the neighbouring gene 6a, most of which was found to be deleted. The Tm-4 ipt gene is strongly related to the partially deleted ipt gene of the limited host range biotype III strain Ag162. To test its biological activity, the Tm-4 ipt gene was inserted into a specially constructed, disarmed Ti vector lacking tzs and tested on tobacco, where the rearranged ipt gene induced shoot formation. The cloned Tm-4 ipt gene was mutated with Tn5 and the intact gene on the wild-type Tm-4 Ti plasmid was replaced by the mutated gene. The resulting strain was avirulent on tobacco but normally virulent on the natural host of the wild-type strain Tm-4, grapevine. As the biotype 1 6b gene diminishes the effect of a corresponding ipt gene, a larger Tm-4 fragment carrying both the ipt gene and an adjacent 6b-like gene was also tested on tobacco and compared with the Tm-4 ipt fragment alone and with an ipt and 6b/ipt fragment derived from Ach5. The Tm-4 6b gene diminishes the effect of the Tm-4 ipt gene, showing the Tm-4 6b gene to be active as well. The Tm-4 6b/ipt combination is less effective than the Ach5 combination. These results provide further insight into the molecular basis of the host range differences between limited host range and wide host range biotype III Agrobacterium strains and show that the WHR cytokinin gene, although active, does not significantly contribute to tumour formation on the natural host of the WHR biotype III strains, grapevine.Abbreviations LHR limited host range - WHR wide host range - onc oncogenicity genes - iaaH indoleacetamide hydrolase gene - iaaM tryptophan monooxygenase gene - ipt isopentenyl transferase gene - tzs transzeatin secretion gene - NAA -naphthalene acetic acid - BAP 6-benzylaminopurine - Km kanamycin - Neo neomycin - Cm chloramphenicol     

Strategies in pathogenesis: mechanistic specificity in the detection of generic signals

The virulence genes of the plant pathogen Agrobacterium tumefaciens are induced by more than 40 low-molecular-weight phenolic compounds. The prevailing opinion is that (i) wound-derived phenols produced on breach of the integrity of the cell wall act as the initiating signal in a series of events which results in host cell transformation, and (ii) a classical membrane receptor, putatively VirA, is responsible for the recognition of all such phenolic inducers. Here, we argue that the discovery of the subset of inducers that are relatives of the dehydrodiconiferyl alcohol glucoside (DCG) growth factors redirects our attention to work on the plant wound as a site of cell division, and suggests that we further explore the implications of early work on the relationship between transformation efficiency and the status of the cell cycle of the host. In addition, we argue that the significant structural diversity allowed in the para position of the phenol ring of inducers suggests that a receptor–ligand interaction based solely on structural recognition is insufficient, but that recognition followed by a specific proton transfer event may be sufficient to explain vir induction activity. Hence, the specificity of the response of A. tumefaciens may be a consequence of the features required for a chemical reaction to occur on the receptor surface. Finally, we review affinity labelling studies which exploit this phenol detection mechanism and which provide evidence that the phenol receptor may be other than VirA, the sensory kinase of the two component regulatory system implicated in Agrobacterium virulence. Taken together, these hypotheses form a model which has predictive and therefore experimental value, and which may be of broader interest in that it calls attention to the possibility of an intricate co-evolution of signalling pathways of host and pathogen.     

Spatially Restricted G Protein-coupled Receptor Activity via Divergent Endocytic Compartments

Postendocytic sorting of G protein-coupled receptors (GPCRs) is driven by their interactions between highly diverse receptor sequence motifs with their interacting proteins, such as postsynaptic density protein (PSD95), Drosophila disc large tumor suppressor (Dlg1), zonula occludens-1 protein (zo-1) (PDZ) domain proteins. However, whether these diverse interactions provide an underlying functional specificity, in addition to driving sorting, is unknown. Here we identify GPCRs that recycle via distinct PDZ ligand/PDZ protein pairs that exploit their recycling machinery primarily for targeted endosomal localization and signaling specificity. The luteinizing hormone receptor (LHR) and β2-adrenergic receptor (B2AR), two GPCRs sorted to the regulated recycling pathway, underwent divergent trafficking to distinct endosomal compartments. Unlike B2AR, which traffics to early endosomes (EE), LHR internalizes to distinct pre-early endosomes (pre-EEs) for its recycling. Pre-EE localization required interactions of the LHR C-terminal tail with the PDZ protein GAIP-interacting protein C terminus, inhibiting its traffic to EEs. Rerouting the LHR to EEs, or EE-localized GPCRs to pre-EEs, spatially reprograms MAPK signaling. Furthermore, LHR-mediated activation of MAPK signaling requires internalization and is maintained upon loss of the EE compartment. We propose that combinatorial specificity between GPCR sorting sequences and interacting proteins dictates an unprecedented spatiotemporal control in GPCR signal activity.     

Limited host range Ti plasmids: recent origin from wide host range Ti plasmids and involvement of a novel IS element, IS868.

Agrobacterium tumefaciens biotype III octopine strains have been isolated from grapevine tumors worldwide. They comprise limited and wide host range (LHR and WHR) strains that carry related tumor-inducing (Ti) plasmids with two T-regions, TA and TB. The WHR TA-region resembles the biotype I octopine region, whereas the LHR TA-region is a recent deletion derivative of the WHR TA-region, which lacks the iaa genes and part of the ipt gene. Sequencing of the TA-region of the ubiquitous LHR strain AB3 showed that the deleted region is replaced by an insertion sequence (IS) element, IS868, which resembles the IS51 element of Pseudomonas syringae subsp. savastanoi. The Ti plasmid of LHR strain Ag57 carries essentially the same iaa gene deletion as pTiAB3, but lacks IS868. We propose that the LHR Ti plasmids arose by the recent insertion of an IS868 element into the TA-region of a WHR-type Ti plasmid, followed by transposition to a nearby site. The deletion was caused during the second transposition or by later recombination between the two IS868 copies. Biotype III octopine strains also carry an IS51-like sequence close to the TB iaa genes. Our results confirm and extend earlier observations indicating that IS51-like elements in Pseudomonas and Agrobacterium are associated with iaa genes and played a major role in Ti plasmid evolution.     

Role of large hydrophobic residues in proteins

Large Hydrophobic Residues (LHR) such as phenylalanine, isoleucine, leucine, methionine and valine play an important role in protein structure and activity. We describe the role of LHR in complete set of protein sequences in 15 different species. That is the distribution of LHR in different proteins of different species is reported. It is observed that the proteins prefer to have 27% of large hydrophobic residues in total and all along the sequence. It is also observed that proteins accumulate more LHR in its active sites. A window analysis on these protein sequences shows that the 27% of LHR is more frequent at window length of 45 amino acids. The influenza virus and P. falciparum show a random distribution of LHR in its proteins compared to other model organisms.     

Liquid holding recovery in a DEB-Inactivated rad3 strain of Saccharomyces cerevisiae carrying a thermosensitive prt mutation

Summary The mutation prt1-1 with a thermosensitive block in initiation of protein synthesis was introduced into a rad3 strain to study the effect of inhibition of protein synthesis on liquid holding recovery (LHR) from the lethal effects of diepoxybutane (DEB). Liquid holding of the prt1-1rad3 strain under restrictive conditions did not decrease the level of recovery as compared with the permissive temperature. Post-incubation of cells in growth medium under permissive conditions prior to LH resulted in the loss of capacity for LHR, while cells post-incubated under restrictive conditions were fully capable of LHR. The results are interpreted as indicating that protein synthesis during LH is not required for the increase in survival and that the occurrence of protein synthesis prior to liquid holding abolishes the capacity for LHR.     

Homology of the ligand-binding regions of Rhizobium symbiotic regulatory protein NodD and vertebrate nuclear receptors.

Summary The signal specificity and structure of sensor-activator proteins from different species (NodD of Rhizobium bacteria and vertebrate nuclear receptors) were compared. Several compounds (including flavonoids, coumestrol and estradiol) that bind to mammalian receptors also interact with NodD proteins. NodD-dependent synergism of the signal compounds luteolin and catechin was observed suggesting that these compounds bind directly to NodD. Two regions comprising 63 and 37 amino acids in NodD showed 45% and 36% homology, respectively, with the estrogen receptor. These regions, designated as modules M1 and M2, coincide with conserved parts of the ligand-binding domains of the nuclear receptors. A part of NodD overlapping with the M1 module was predicted to be membrane associated and was 46% homologous to a membrane-spanning sensory segment of the Agrobacterium VirA protein. We suggest that the homologous polypeptide modules detected in NodD and the nuclear receptors originate from a common ancestor protein and may be directly involved in ligand binding.     

Genetic analysis of the signal-sensing region of the histidine protein kinase VirA of <Emphasis Type="Italic">Agrobacterium tumefaciens</Emphasis>

The membrane-bound sensor protein kinase VirA of Agrobacterium tumefaciens detects plant phenolic substances, which induce expression of vir genes that are essential for the formation of the crown gall tumor. VirA also responds to specific monosaccharides, which enhance vir expression. These sugars are sensed by the periplasmic domain of VirA that includes the region homologous to the chemoreceptor Trg, and the phenolics are thought to be detected by a part of the cytoplasmic linker domain, while the second transmembrane domain (TM2) is reported to be nonessential. To define regions of VirA that are essential for signal sensing, we introduced base-substitution and deletion mutations into coding regions that are conserved among the respective domains of VirA proteins from various Agrobacterium strains, and examined the effects of these mutations on vir induction and tumorigenicity. The results show that the Trg-homologous region in the periplasmic domain is not essential for the enhancement of vir gene expression by sugars. Most mutations in the TM2 domain also failed to influence enhancement by sugars and reduced the level of vir induction, but a mutation in the TM2 region adjacent to the cytoplasmic linker abolished induction of the vir genes. In the linker domain, sites essential for vir induction by phenolics were scattered over the entire region. We propose that a topological feature formed by the linker domain and at least part of the TM2 may be crucial for activation of a membrane-anchored VirA protein. Complementation analysis with two different VirA mutants suggested that intermolecular phosphorylation between VirA molecules occurs in vivo, and that two intact periplasmic regions in a VirA dimer are required for the enhancement of vir induction by sugars.     

The Heme Transport Capacity of LHR1 Determines the Extent of Virulence in Leishmania amazonensis

Leishmania spp. are trypanosomatid parasites that replicate intracellularly in macrophages, causing serious human morbidity and mortality throughout the world. Trypanosomatid protozoa cannot synthesize heme, so must acquire this essential cofactor from their environment. Earlier studies identified LHR1 as a Leishmania amazonensis transmembrane protein that mediates heme uptake. Null mutants of LHR1 are not viable and single knockout strains have reduced virulence, but very little is known about the properties of LHR1 directly associated with heme transport. Here, we use functional assays in Saccharomyces cerevisiae to show that specific tyrosine residues within the first three predicted transmembrane domains of LHR1 are required for efficient heme uptake. These tyrosines are unique to LHR1, consistent with the low similarity between LHR1 and its corresponding homologs in C. elegans and human. Substitution of these tyrosines in LHR1 resulted in varying degrees of heme transport inhibition, phenotypes that closely mirrored the impaired ability of L. amazonensis to replicate as intracellular amastigotes in macrophages and generate cutaneous lesions in mice. Taken together, our results imply that the mechanism for heme transport by LHR1 is distinctive and may have adapted to secure heme, a limiting cofactor, inside the host. Since LHR1 is significantly divergent from the human heme transporter HRG1, our findings lay the groundwork for selective targeting of LHR1 by small molecule antagonists.