Chitin-supplemented foliar application of chitinolytic Bacillus cereus reduces severity of Botrytis gray mold disease in chickpea under controlled conditions

AIM

To identify and evaluate chitinolytic bacteria for control of Botrytis gray mold (BGM), a devastating disease in chickpea.

METHODS AND RESULTS

Two antifungal bacterial isolates, chitinolytic Bacillus cereus CRS 7 and nonchitinolytic Pseudomonas fluorescens CRS 31, from the rhizosphere of chickpea, were applied as a prophylactic foliar spray and evaluated for control of BGM. In a controlled environment, the two isolates reduced the severity of BGM on the susceptible cv. JG 62 to 6.0 and 5.6, respectively, compared with 9.0 in the control, measured on a 1-9 rating scale. Supplementation of the foliar application of CRS 7 with 0.5% and 1.0% colloidal chitin reduced BGM severity to 4.4 and 4.1 respectively, while chitin-supplemented application of CRS 31 was similar to CRS 31 applied alone. Partially purified 47-kDa chitinase from the cell-free culture filtrate of CRS 7 at 20 and 40 mug protein ml(-1) (enzyme activity 3.1 units ml(-1)) inhibited the germination and lysed the conidia of Botrytis cinerea, and as a prophylactic foliar spray reduced BGM severity to 5.4 and 4.8, respectively.

CONCLUSION

Chitin supplementation improved the biocontrol of the foliar disease BGM by chitinolytic bacterium. Disease control with partially purified chitinase of CRS 7 supported the major role of chitinolysis in improved control of BGM.

SIGNIFICANCE AND IMPACT OF THE STUDY

Enhanced control of BGM by chitin-supplemented application of CRS 7 is of significant in view of the frequent inconsistency in biocontrol of foliar diseases. This study supports further attempts on chitinolysis-based biocontrol methods for foliar disease biocontrol.

Phylloplane bacteria increase seedling emergence, growth and yield of field-grown groundnut (Arachis hypogaea L.)

AIM

To isolate and characterize groundnut-associated bacterial isolates for growth promotion of groundnut in field.

METHODS AND RESULTS

Three hundred and ninety-three groundnut-associated bacteria, representing the geocarposphere, phylloplane and rhizosphere, and endophytes were applied as seed treatment in greenhouse. Maximum increase in plant biomass (up to 26%) was observed following treatment with a rhizosphere isolate identified as Bacillus firmis GRS 123, and two phylloplane isolates Bacillus megaterium GPS 55 and Pseudomonas aeruginosa GPS 21. There was no correlation between the production of L-tryptophan-derived auxins and growth promotion by the test isolates. Actively growing cells and peat formulations of GRS 123 and GPS 55, and actively growing cells of GPS 21, significantly increased the plant growth and pod yield (up to 19%) in field. Rifampicin-resistant mutants of GRS 123 and GPS 21 colonized the ecto- and endorhizospheres of groundnut, respectively, up to 100 days after sowing (DAS), whereas GPS 55 was recovered from both the habitats at 100 DAS.

CONCLUSION

Seed bacterization with phylloplane isolates promoted groundnut growth indicating the possibility of isolating rhizosphere beneficial bacteria from different habitats.

SIGNIFICANCE AND IMPACT OF THE STUDY

Identification of phylloplane bacteria as effective plant growth-promoting rhizobacteria (PGPR) broadens the spectrum of PGPR available for field application.

Ascochyta blight of chickpea (Cicer arietinum L.): a review of biology, pathogenicity, and disease management

Ascochyta blight (AB), caused by Ascochyta rabiei is a major disease of chickpea (Cicer arietinum L.), especially in areas where cool, cloudy, and humid weather persists during the crop season. Several epidemics of AB causing complete yield loss have been reported. The fungus mainly survives between seasons through infected seed and in infected crop debris. Despite extensive pathological and molecular studies, the nature and extent of pathogenic variability in A. rabiei have not been clearly established. Accumulation of phenols, phytoalexins (medicarpin and maackiain), and hydrolytic enzymes has been associated with host-plant resistance (HPR). Seed treatment and foliar application of fungicides are commonly recommended for AB management, but further information on biology and survival of A. rabiei is needed to devise more effective management strategies. Recent studies on inheritance of AB resistance indicate that several quantitative trait loci (QTLs) control resistance. In this paper we review the biology of A. rabiei, HPR, and management options, with an emphasis on future research priorities.