NopB, a soybean cultivar-specificity protein from Sinorhizobium fredii USDA257, is a type III secreted protein

The type III secretion system (TTSS) of plant- and animal-pathogenic bacteria is involved in translocation of virulence factors into the host cell cytosol where they modulate cellular processes. Sinorhizobium fredii USDA257 is a gram-negative soil bacterium that forms nitrogen-fixing nodules on specific soybean cultivars (Glycine max (L.) Merr.). This microsymbiont is known to secrete at least five nodulation outer proteins (Nops) in response to flavonoid induction. Some of these Nops have been shown to be secreted by TTSS in this symbiotic bacterium. We have isolated and purified an 18-kDa extracellular protein from flavonoid-induced cultures of USDA257. The N-terminal amino acid sequence of this purified protein was identical to the published sequence of the soybean cultivar-specificity protein, NopB (formerly NoIB). Inactivation of rhcN, which encodes an ATPase, abolished secretion of NopB. Similarly, a nonpolar nopB deletion mutant was compromised in its ability to secrete several Nops. A construct containing the coding region of nopB under control of a T7 promoter was expressed successfully in Escherichia coli and, subsequently, the recombinant NopB was purified by nickel-affinity column chromatography. Polyclonal antibodies raised against purified recombinant NopB were used in Western blot analysis to demonstrate the association of NopB with pilus-like surface appendages. Deletion analysis indicated that the first 33 N-terminal residues of NopB were necessary and sufficient to mediate the secretion of a green fluorescent protein reporter. Introduction of plasmid-borne extra copies of nopB into USDA257 resulted in lower accumulation of native NopB. We also show that USDA257 and its nonpolar nopB deletion mutant exhibited discernible differences in their ability to nodulate legume hosts.     

Circular dichroism and conformational properties of modeccin,a toxic protein

According to its circular dichroism (CD) spectrum, modeccin, a toxic lectin from the roots of the South African plantModecca digitata, is structurally similar to the ricins and abrins. In nearly neutral and weakly alkaline solutions (pH 7.6–9.0) the CD spectra of modeccin displayed a positive CD band at 190–195 nm and a negative band at 210–220 nm, indicating the presence of some α-helix and β-sheet structures. In the near-ultraviolet zone, we observed positive CD bands at 232 and 245 nm and weak negative bands at 285 and 293 nm. In more strongly alkaline solutions of pH 9.5–10.2 the CD bands in the farultraviolet zone were not affected, but the CD band at 232 nm diminished and the CD band at 245 nm was enhanced. These transitions were reversible. At pH 11.2–11.5 the CD band at 232 nm disappeared completely, and the CD bands in the far-ultraviolet diminished. The CD bands at 285 and 293 nm were affected very little by the alkali, and these bands were assigned to buried tryptophan side chains. Sodium dodecyl sulfate and 2,2,2-trifluoroethanol disorganized the tertiary structure of modeccin and reconstructed the secondary structure into a new form with a higher helix content than in the native protein.     

Immunochemical properties of the aminopropeptide of procollagen type III

The precursor-specific aminopropeptide of bovine type III procollagen is a strong immunogen in rabbits, guinea pigs and mice and induces antibodies which do not cross-react with type I procollagen. The antibody response is regulated by immune response genes associated with the major histocompatibility complex. Major antigenic determinants were found in the compact, non-collagenous domain (fragment Col 1) located at the N terminus of the aminopropeptide and were destroyed by reduction of disulfide bonds. Minor antigenic determinants independent of disulfide bonds also exist in fragment Col 1 and could be localized on a distinct tryptic peptide. Fragment Col 1 showed a lower affinity for antibody when compared with the intact aminopropeptide which causes a non-parallel shift in radioimmuno-inhibition profiles. Monovalent antibody fragments showed an average tenfold reduction in affinity constant and failed to distinguish between aminopropeptide and fragment Col 1. This indicates that the stronger binding of bivalent antibody by the triple-stranded aminopropeptide is due to multiple interactions with both antibody binding sites which are lost for a single-stranded antigen (Col 1) or with monovalent antibody fragments.     

Gm-TX,a new toxic protein from soybean (Glycine max) seeds with potential for controlling insect pests

A novel toxic protein from Glycine max seeds, named Gm-TX, was purified by combination of differential precipitation with ammonium sulphate, DEAE-cellulose, anhydrotrypsin-sepharose 4B and Superdex 200 HR fast-protein liquid chromatography.Gm-TX is composed of one polypeptide chain of 28 kDa (SDS-PAGE), with pI 5.1–5.2, contains <0.5% neutral sugar, has N-terminal sequence comprised of KTISSEDSPFFNCREK, maximum absorption spectrum at 280 nm and molar extinction coefficient of 16.9. It exhibited ribonuclease activity (1821.42 ± 3.34 UA/h/mgP) toward yeast RNA and promoted rabbit erythrocyte agglutination (120.4 HU/mgP) mediated by anti-Gm-TX IgG, which was inhibited by mannose. It was devoid of trypsin inhibitory, urease and chitinase activities. Gm-TX was lethal to mice by intraperitoneal route with LD₅₀ of 4.5 mg/kg. Moreover, it showed dose-dependent insecticidal activity on the major economically important pests Callosobruchus maculatus and Dysdercus peruvianus, producing ca. 50% and 56% mortality when incorporated into artificial diets at a level of 1.16% and 0.25%, respectively. These data indicate that Gm-TX is a candidate protein that could be expressed in genetically transformed plants for improved resistance to insect pests.     

Cell-free Pseudomonas vaccine. III. Immunochemical analysis of purified Pseudomonas aeruginosa protein antigens and protective properties of antisera against these antigens

The immunochemical analysis of isolated and purified antigens A and B obtained from P. aeruginosa, strains 868 (serogroup O3 according to Lányi or immunotype 3/7 according to Fisher) and 170015 (serogroup O7 or immunotype 2), was carried out. Rabbit antisera to proteins A and B, as well as to the initial aqueous extracts and partially purified aqueous extracts, were obtained. Cross activity between the protein antigens of different strains was established by the methods of immunodiffusion and two-dimensional immunoelectrophoresis. Isolated proteins A and B contained both common and specific antigenic determinants detected by the method of two-dimensional immunoelectrophoresis. The immunization of rabbits with proteins A and B was found to stimulate the synthesis of protective, probably species-specific, antibodies.     

Bolevenine, a toxic protein from the Japanese toadstool Boletus venenatus

A toxic protein, called bolevenine, was isolated from the toxic mushroom Boletus venenatus based on its lethal effects on mice. On SDS-PAGE, in either the presence or absence of 2-mercaptoethanol, this protein showed a single band of approximately 12 kDa. In contrast, based on gel filtration and MALDI-TOFMS, its relative molecular mass was estimated to be approximately 30 kDa and approximately 33 kDa, respectively, indicating that the protein consists of three identical subunits. This toxin exhibited its lethal activity following injection at 10mg/kg into mice. The N-terminal amino acid sequence was determined up to 18, and found to be similar to the previously reported bolesatine, a toxic compound isolated from Boletus satanas.     

I-protein, a new regulatory protein from vertebrate skeletal muscle. III. Function.

I-protein inhibited theMg-activated ATPase [EC 3.6.1.3] activity of actinomyosin by approximately 50% at low ionic strength. Concomitantly, the onset of superprecipitation was retarded. I-protein was found to bind to myosin, but not to F-actin. The inhibitory action of I-protein occurred only in the absence of Ca ions in the troponintropomyosin-actin myosin system. Addition of Ca ions abolished the effect. Thus, it is very likely that I-protein prevents unnecessary hydrolysis of ATP in the relaxed state of muscle.     

Immunochemical properties of West Nile virus protein prM and protein M C-end

Complementary DNA fragments (nucleotides 466-966 and 878-1088) encoding prM protein and polypeptide M31-75-E1-30 of West Nile virus (WNV), strain LEIV-Vlg99-27889-human, were obtained and cloned. Recombinant polypeptides prM and M3175-E1-30 having amino acid sequences corresponding to the cloned cDNA fragments were purified by affinity chromatography. According to ELISA and Western blotting prM protein interacted with polyclonal antibodies against WNV. This is indicative the immunochemical similarity of WNV recombinant and native protein prM. 6 types of species-specific monoclonal antibodies (MAbs) raised against recombinant polypeptide prM recognized at least four epitopes within recombinant polypeptides prM and M31-75-E1-30. MAbs 7D11 were active in the virus - neutralization assay. Analysis of interaction of the MAbs with recombinant polypeptides prM, M31-75-EI-30, E1-180, E260-466 revealed cross-reactive epitopes within 260-466 amino acid residues (aa) of WNV protein E, 31-75 aa of polypeptide M31-75-E1-30 and protein prM. Proposed spatial model of proteins E and M C-end fragments shown similarity of their three-dimensional structures confirming results of immunochemical assay. Neutralization of viral infectivity by MAbs 7D11 raised against epitope within 31-75 aa t of protein M is evidence of important function of C-end region in the process of flaviviral penetration into host cell.     

SCB1, a BURP-domain protein gene,from developing soybean seed coats

We describe a gene, SCB1 (Seed Coat BURP-domain protein 1), that is expressed specifically within the soybean (Glycine max [L.] Merrill) seed coat early in its development. Northern blot analysis and mRNA in situ hybridization revealed novel patterns of gene expression during seed development. SCB1 mRNA accumulated first within the developing thick-walled parenchyma cells of the inner integument and later in the thick- and thin-walled parenchyma cells of the outer integument. This occurred prior to the period of seed coat maturation and seed filling and before either of the layers started to degrade. SCB1 may therefore play a role in the differentiation of the seed coat parenchyma cells. In addition, the protein product appears to be located within cell walls. The SCB1 gene codes for a new member of a class of modular proteins that possess a carboxy-terminal BURP domain and a variety of different repeated sequences. The sequence of the genomic clone revealed the insertion of a Tgm transposable element in the upstream promoter region but it is not certain whether it contributes to the tissue-specific pattern of SCB1 expression.