Chromosomal gene of hybrid multisensor histidine kinase is involved in motility regulation in the rhizobacterium Azospirillum baldaniorum Sp245 under mechanical and water stress.

Azospirillum alphaproteobacteria, which live in the rhizosphere of many crops, are used widely as biofertilizers. Two-component signal transduction systems (TCSs) mediate the bacterial perception of signals and the corresponding adjustment of behavior facilitating the adaptation of bacteria to their habitats. In this study, we obtained the A. baldaniorum Sp245 mutant for the AZOBR_150176 gene, which encodes the TCS of the hybrid histidine kinase/response sensory regulator (HSHK-RR). Inactivation of this gene affected bacterial morphology and motility. In mutant Sp245-HSHKΔRR-Km, the cells were still able to synthesize a functioning polar flagellum (Fla), were shorter than those of strain Sp245, and were impaired in aerotaxis, elaboration of inducible lateral flagella (Laf), and motility in semiliquid media. The mutant showed decreased transcription of the genes encoding the proteins of the secretion apparatus, which ensures the assembly of Laf, Laf flagellin, and the repressor protein of translation of the Laf flagellin's mRNA. The study examined the effects of polyethylene glycol 6000 (PEG 6000), an agent used to simulate osmotic stress and drought conditions. Under osmotic stress, the mutant was no longer able to use collective motility in semiliquid media but formed more biofilm biomass than did strain Sp245. Introduction into mutant cells of the AZOBR_150176 gene as part of an expression vector led to recovery of the lost traits, including those mediating bacterial motility under mechanical stress induced by increased medium density. The results suggest that the HSHK-RR under study modulates the response of A. baldaniorum Sp245 to mechanical and osmotic/water stress.

Gene Expression in Parthenogenic Maize Proembryos.

Angiosperm plants reproduce both sexually and asexually (by apomixis). In apomictic plants, the embryo and endosperm develop without fertilization. Modern maize seems to have a broken apomixis-triggering mechanism, which still works in Tripsacum and in Tripsacum-maize hybrids. For the first time, maize lines characterized by pronounced and inheritable high-frequency maternal parthenogenesis were generated 40 years ago, but there are no data on gene expression in parthenogenic maize proembryos. Here we examined for the first time gene expression in parthenogenic proembryos isolated from unpollinated embryo sacs (ESs) of a parthenogenic maize line (AT-4). The DNA-methylation genes (dmt103, dmt105) and the genes coding for the chromatin-modifying enzymes (chr106, hdt104, hon101) were expressed much higher in parthenogenic proembryos than in unpollinated ESs. The expression of the fertilization-independent endosperm (fie1) genes was found for the first time in parthenogenic proembryos and unpollinated ESs. In parthenogenic proembryos, the Zm_fie2 gene was expressed up to two times higher than it was expressed in unpollinated ESs.

Agrobacterial, Single-Stranded DNA-Binding Protein VirE2 and Its Complexes.

VirE2 from Agrobacterium tumefaciens is a single-stranded (ss) DNA-binding protein involved in delivery of ssT-DNA (single-stranded transfer DNA) from the agrobacterial Ti plasmid into the eukaryotic cell nucleus. The crystallized part of VirE2 was studied by X-ray diffraction, and the noncrystallized parts of the C- (40 amino acid residues [aars]) and N- (111 aars) termini of the protein, which are presumably disordered, were evaluated by computational methods. We did a molecular dynamics simulation of VirE2 without VirE1 and observed no large changes in domain orientation. The interaction of VirE2 with ssDNA and formation of ssDNA-VirE2 complexes in silico were studied. We also used computer-aided methods to design model complexes consisting from two- and four-subunit VirE2 proteins. We examined the implication of disordered sites in formation of two- and four-subunit VirE2 complexes. Formation of VirE2 dimers and tetramers within ssDNA-VirE2 complexes was demonstrated by computational methods. Using the Platinum program, we found that hydrophilic amino acids were predominant on the surface of the four-subunit VirE2 complex.

Computer evaluation of VirE2 protein complexes for ssDNA transfer ability.

The single-stranded transfer DNA from the Ti plasmid of the soil bacteria Agrobacterium nonspecifically integrates into the plant chromosome and is inherited at subsequent cell divisions. How it is transferred across host membranes is unknown, but it is believed that VirE2 proteins form a membrane-spanning pore or channel in a lipid bilayer and possibly mediate the delivery of the single-stranded transfer DNA-VirD2-VirE2 complex to the plant cell chromosomes. The aim of this work was to perform a computer simulation of VirE2's pore-forming capacity and an evaluation of constructed VirE2 complexes. The oscillating motions of complexes consisting of two and four VirE2 subunits were estimated by the molecular dynamics and normal modes methods. We did not predict any large changes in domain orientation for two and four-subunit VirE2 complexes within simulation times of 1ns. A possible gating mechanism similar to that seen in the ion channels of the complex formed from two VirE2 proteins was proposed, whereas no conformational changes were predicted inside the pore in the complex formed from four VirE2 proteins.

VirE2-dependent pores for ssDNA transfer across artificial and cell membranes.

The transfer of single-stranded (ss) T-DNA from soil bacteria of the genus Agrobacterium with the help of the VirE2 protein, which possibly mediates the delivery of ss-T-DNA across the cell membrane, was demonstrated earlier, but how VirE2 participates in ssDNA transfer across artificial and natural membranes is not known. Using computational methods, we reconstructed model structures composed of two and four VirE2 proteins and showed by the MOLE program the formation of pores with channel diameters of 1.2-1.6 and 1.4-4.6 nm in a model structure formed from two and four VirE2 molecules, respectively. Using light scattering, we recorded the size distribution for recombinant VirE2-dependent complexes in aqueous solutions and found that VirE2 in a buffer solution is present as a complex made up of two or more proteins. We revealed single, long-lived jumps in voltage-dependent membrane conductance during coincubation of planar black membranes with the VirE2 protein. On the addition of VirE2 and FAM-labeled oligonucleotides to HeLa cells, the fluorescence intensity for the cells increased by 56% as compared to that for cells incubated only with oligonucleotides.

Study of the VirE2-ssT-DNA complex formation by scanning probe microscopy and gel electrophoresis- T-complex visualization.

The recombinant virulence protein VirE2, capable of forming a complex with single-stranded T-DNA during transfer into plant cells, was isolated, purified, and used for interactions with ssT-DNA. The in vitro interaction of VirE2 and ss-binding protein from Escherichia coli with single-stranded DNA (phage lambda) was determined by agarose gel electrophoresis by the formation of high-molecular-weight complexes after preliminary coincubation of purified protein preparations with ssDNA. We show that VirE2 binds to single-stranded DNA and protects it against nuclease S1 degradation much better than does E. coli SSB protein. We for first time observed the VirE2-ssT-DNA complex by using atomic force microscopy. The complex observed by atomic force microscopy after ssT-DNA and VirE2 protein mixing has a length of about 800 nm and a 5-8 nm width in sites with attached VirE2 protein.

Isolation, purification, and identification of the virulence protein VirE2 from Agrobacterium tumefaciens.

Bacteria of the genus Agrobacterium can transfer a portion of their Ti plasmid (T-DNA) in complex with the VirE2 and VirD2 proteins into the plant-cell nucleus and cause it to be integrated in the host-cell chromosomes. The mechanism of T-DNA transfer across the plant-cell membrane and cytoplasm is unknown. The aim of this study was to isolate the virulence protein VirE2 in order to explore its role in T-DNA transfer across the eukaryotic-cell membrane and cytoplasm. To obtain VirE2, we cloned the virE2 gene into plasmid pQE31 in Escherichia coli cells. VirE2 protein was isolated from E. coli XL-1 blue cells containing a recombinant plasmid, pQE31-virE2. The cells were ultrasonically disrupted, and the protein containing six histidine residues at the N-terminal end was isolated by affinity chromatography on Ni-NTA agarose. The purified preparation was tested by immunodot, by using polyclonal rabbit antibodies and miniantibodies produced toward VirE2. The capacity of the recombinant protein VirE2 for interacting with single-stranded DNA was tested by the formation of complexes, recorded by agarose-gel electrophoresis. In summary, A. tumefaciens virulence protein VirE2, capable of forming a complex with single-stranded T-DNA during transfer into the plant cell, was isolated, purified, and partially characterized. Anti-VirE2 miniantibodies were obtained, and direct labeling of VirE2 with colloidal gold was done for the first time.