Narendra K. Singh

Antifungal activity of tobacco osmotin has specificity and involves plasma membrane permeabilization

Osmotin protein is able to inhibit in vitro the growth of a number of unrelated pathogens. A survey of 31 isolates representing 18 fungal genera indicated that sensitivity may be determined at the genus level. Hyphal growth of Aspergillus flavus, Aspergillus parasitica, Rhizoctonia solani and Macrophomina phaseolina was highly resistant to osmotin whereas the growth of Bipolaris, Fusarium and Phytophthora species was very sensitive. Of all fungi tested Trichoderma longibrachiatum hyphal growth was most inhibited by osmotin treatment. Osmotin either induced spore lysis, inhibited spore germination or reduced germling viability in seven fungal species that exhibited some degree of sensitivity in hyphal growth inhibition tests. The species-specific growth inhibition was correlated with the ability of osmotin to dissipate the fungal membrane pH gradient. Both growth inhibition and pH gradient dissipation by osmotin were sensitive to NaCl and other inorganic cations. Cells of T. longibrachiatum were insensitive to osmotin after plasmolysis, suggesting that the cell wall may be a component of the mechanism by which osmotin permeabilizes the plasma membrane and kills fungal cells.

Regulation of the Osmotin Gene Promoter.

By introducing a chimeric gene fusion of the osmotin promoter and [beta]-glucuronidase into tobacco by Agrobacterium-mediated transformation, we have demonstrated a very specific pattern of temporal and spatial regulation of the osmotin promoter during normal plant development and after adaptation to NaCl. We have found that the osmotin promoter has a very high natural level of activity in mature pollen grains during anther dehiscence and in pericarp tissue at the final, desiccating stages of fruit development. GUS activity was rapidly lost after pollen germination. The osmotin promoter thus appears to be unique among active pollen promoters described to date in that it is active only in dehydrated pollen. The osmotin promoter was also active in corolla tissue at the onset of senescence. Adaptation of plants to NaCl highly stimulated osmotin promoter activity in epidermal and cortex parenchyma cells in the root elongation zone; in epidermis and xylem parenchyma cells in stem internodes; and in epidermis, mesophyll, and xylem parenchyma cells in developed leaves. The spatial and temporal expression pattern of the osmotin gene appears consistent with both osmotic and pathogen defense functions of the gene.

Analysis of structure and transcriptional activation of an osmotin gene.

A Nicotiana tabacum gene encoding the basic PR-like protein osmotin was isolated and characterized. The gene is derived from the N. sylvestris parent of N. tabacum. In cell suspension cultures of tobacco, the osmotin gene was shown to be transcriptionally activated by treatment with ABA.Transcriptional activation of the osmotin promoter was further investigated in transformed plants carrying copies of a fusion of the cloned promoter to the β-glucuronidase reporter gene. In these plants, the osmotin promoter is transcriptionally activated by the hormones ABA and ethylene. The sensitivity of the osmotin promoter to ABA applied exogenously decreased with age in both roots and shoots of young seedlings. NaCl shock also activated the promoter in plant tissues. The osmotin promoter is much more active in root tissues than in shoot tissues.

ADSORPTION AND DESORPTION OF SELENITE AND SELENATE SELENIUM ON DIFFERENT SOILS

In the laboratory, we studied the adsorption of selenite and selenate selenium and desorption by sulfate and phosphate in normal, calcareous, high organic carbon saline, and alkali soils. Initial selenium solutions contained 5 to 150 μmole Se/g soil, and desorbing solutions contained 500 μmole P or S/g soil. All soils sorbed variable amounts of selenite and selenate in the order: high organic carbon soil > calcareous soil > normal soil > saline soil > alkali soil. Adsorption of both selenite and selenate forms of selenium was influenced positively by organic carbon, clay content, CaCO3, and CEC and negatively influenced by high salt content, alkalinity, and pH. Conventional and rearranged Langmuir equations were tested. Langmuir curve analysis of Eadie-Hofstee was valid in normal and calcareous soils for selenite and in calcareous and saline soils for selenate. The analysis of Syers et al. did not fit well in any case. The adsorption of selenite and selenate showed differential behavior and indicated that a part of both selenite and selenate is adsorbed on differential qualitative sites. Selenate was always sorbed in higher amounts than selenite. The desorption of selenite selenium showed no preference for sulfate or phosphate, but selenate was more effectively desorbed by phosphate than sulfate in all soils.

Purification and characterization of a Bacillus cereus exochitinase

Five extracellular chitinases of Bacillus cereus 6E1 were detected by a novel in-gel chitinase assay using carboxymethyl-chitin-remazol brilliant violet 5R (CM-chitin-RBV) as a substrate. The major chitinase activity was associated with a 36-kDa (Chi36) gel band. Chi36 was purified by a one-step, native gel purification procedure derived from the new in-gel chitinase assay. The purified Chi36 has optimal activity at pH 5.8 and retains some enzymatic activity between pH 2.5-8. The temperature optimum for Chi36 was 35 degrees C, but the enzyme was active between 4-70 degrees C. Based on its ability to hydrolyze mainly p-nitrophenyl-(N-acetyl-beta-D-glucosaminide)(2), Chi36 is characterized as a chitobiosidase, a type of exochitinase. The N-terminal amino acid sequence of mature Chi36 was determined (25 amino acids). Alanine is the first N-terminal amino acid residue indicating the cleavage of a signal peptide from a Chi36 precursor to form the mature extracellular Chi36. The N-terminal sequence of Chi36 demonstrated highest similarity with Bacillus circulans WL-12 chitinase D and significant similarity with several other bacterial chitinases.

Photosynthesis in Salt-Adapted Heterotrophic Tobacco Cells and Regenerated Plants.

Tobacco (Nicotiana tabacum L.) cells growing heterotrophically in the light on supplied sucrose (S0) have previously been adapted to grow in 428 mM NaCl (S25). Among the changes occurring in salinity-adapted cell cultures are (a) elevated levels of chlorophyll compared to unadapted cells; (b) decreased levels of starch; (c) alterations in chloroplast ultrastructure, including loss of starch grains, increased thylakoid membrane structure, and the presence of plastoglobules; and (d) increased rates of O2 evolution, CO2 fixation, and photophosphorylation relative to S0 cells. These latter changes apparently derive from the fact that thylakoid membranes in S25 cells contain higher levels of photosystem I- and II-associated proteins as well as thylakoid ATPase components. S25 chloroplasts contain immunologically detectable levels of ribulose-1,5-bisphosphate carboxylase/oxygenase, whereas S0 completely lack the enzyme. These changes taken together suggest that even in the presence of sucrose, S25 cells have acquired a significant degree of salt-tolerant photosynthetic competence. This salt-tolerant photoysynthetic capability manifests itself in plants backcrossed with normal plants for three generations. These plants contain chloroplasts that demonstrate in vitro more salt-tolerant CO2 fixation, O2 evolution, and photophosphorylation than do backcross progeny of plants regenerated from S0 cultures.

Recovery of recombinant plasmids from Pleurotus ostreatus transformants

SummaryA transformation system employing selectable resistance to hygromycin B has been developed for the mushroom-forming fungus, Pleurotus ostreatus. Vector pAN7-1, a commonly used non-replicative vector for integrative transformation in fungi, yielded 5–46 resistant colonies per μg of DNA per 107 viable protoplasts. Southern blot analysis of certain transformants revealed unexpected replicative plasmids containing pAN7-1 sequences, but modified for size, methylation and restriction enzyme pattern when compared to the initial transforming vector. Two such replicative derivatives of pAN7-1 have been rescued from P. ostreatus by cloning into Escherichia coli. Rescued plasmids have been used to probe DNA from untransformed P. ostreatus in an effort to identify fungal sequences that recombined in vivo with pAN7-1 to form replicative plasmids. Such replicative sequences have been localized in high molecular weight (chromosomal) DNA of wild-type P. ostreatus. Transformation has been obtained for P. ostreatus using a rescued plasmid, thereby confirming the role of this recombinant plasmid as a shuttle vector.

Nitrate uptake and utilization is modulated by exogenous γ-aminobutyric acid in Arabidopsis thaliana seedlings

Exogenously applied GABA modulates root growth by inhibition of root elongation when seedlings were grown in vitro on full-strength Murashige and Skoog (MS) salts, but root elongation was stimulated when seedlings were grown on 1/8 strength MS salts. When the concentration of single ions in MS salts was individually varied, the control of growth between inhibition and stimulation was found to be related to the level of nitrate (NO(3)(-)) in the growth medium. At NO(3)(-) concentrations below 40 mM (full-strength MS salts level), root growth was stimulated by the addition of GABA to the growth medium; whereas at concentrations above 40 mM NO(3)(-), the addition of GABA to the growth medium inhibited root elongation. GABA promoted NO(3)(-) uptake at low NO(3)(-), while GABA inhibited NO(3)(-) uptake at high NO(3)(-). Activities of several enzymes involved in nitrogen and carbon metabolism including nitrate reductase (NR), glutamine synthetase (GS), glutamate synthase (NADH-GOGAT), NADP-dependent isocitrate dehydrogenase (NADP-ICDH), and phosphoenol pyruvate carboxylase (PEPCase) were regulated by GABA in the growth medium. Supplementing 1/8 strength MS medium with 50 mM GABA enhanced the activities of all of the above enzymes except ICDH activities in root tissues. However, at full-strength MS, GABA showed no inhibitory effect on the activities of these enzymes, except on GS in both root and shoot tissues, and PEPCase activity in shoot tissues. Exogenous GABA increased the amount of NR protein rather than its activation status in the tissues. This study shows that GABA affects the growth of Arabidopsis, possibly by acting as a signaling molecule, modulating the activity of enzymes involved in primary nitrogen metabolism and nitrate uptake.

Expression of apoplastically secreted tobacco osmotin in cotton confers drought tolerance

Osmotin or osmotin-like proteins have been shown to be induced in several plant species in response to various types of biotic and abiotic challenges. The protein is generally believed to be involved in protecting the plant against these stresses. Although some understanding of the possible mechanism underlying the defense function of osmotin against biotic stresses is beginning to emerge, its role in abiotic stress response is far from clear. We have transformed cotton plants with a tobacco-osmotin gene, lacking the sequence encoding its 20 amino acid-long, C-terminal vacuolar-sorting motif, under the control of CaMV 35S promoter. Apoplastic secretion of the recombinant protein was confirmed and the plants were evaluated for their ability to tolerate drought conditions. Under polyethylene glycol-mediated water stress, the osmotin-expressing seedlings showed better growth performance. The transformants showed a slower rate of wilting during drought and faster recovery following the termination of dry conditions in a greenhouse setting. During drought, the leaves from transgenic plants had higher relative water content and proline levels, while showing reduced H2O2 levels, lipid peroxidation and electrolyte leakage. Importantly, following a series of dry periods, the osmotin transformants performed better in terms of most growth and developmental parameters tested. Most relevant, the fiber yield of transgenic plants did not suffer as much as that of their non-transgenic counterparts under drought conditions. The results provide direct support for a protective role of osmotin in cotton plants experiencing water stress and suggest a possible way to achieve tolerance to drought conditions by means of genetic engineering.

Identification of a pyridoxine (pyridoxamine) 5′-phosphate oxidase from Arabidopsis thaliana

Pyridoxine (pyridoxamine) 5′‐phosphate oxidase (PPOX) catalyzes the oxidative conversion of pyridoxamine 5′‐phosphate (PMP) or pyridoxine 5′‐phosphate (PNP) to pyridoxal 5′‐phosphate (PLP). The At5g49970 gene of Arabidopsis thaliana shows homology to PPOXs from a number of organisms including the Saccharomyces cerevisiae PDX3 gene. A cDNA corresponding to putative A. thaliana PPOX (AtPPOX) was obtained using reverse transcriptase‐polymerase chain reaction and primers landing at the start and stop codons of At5g49970. The putative AtPPOX is 530 amino acid long and predicted to contain three distinct parts: a 64 amino acid long N‐terminal putative chloroplast transit peptide, followed by a long Yjef_N domain of unknown function and a C‐terminal Pyridox_oxidase domain. Recombinant proteins representing the C‐terminal domain of AtPPOX and AtPPOX without transit peptide were expressed in E. coli and showed PPOX enzyme activity. The PDX3 knockout yeast deficient in PPOX activity exhibited sensitivity to oxidative stress. Constructs of AtPPOX cDNA of different lengths complemented the PDX3 knockout yeast for oxidative stress. The role of the Yjef_N domain of AtPPOX was not determined, but it shows homology with a number of conserved hypothetical proteins of unknown function.