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Application Effect Of Exopolysaccharide ( Eps) Rich, Pgpr Coaggregates On The Enhancement Of Isr Mediated Biocontrol In Groundnut Sclerotium Rolfsii Pathosystem Under Rainfed Condition

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Abstract (Original Language): 
The bioinoculation effect of different bioformulations, viz.,vegetative cell application, co-inoculation and co-aggregates application, of efficient PGPR cells viz., Methylobacterium (MB-5) and Rhizobium sp. (RM-5), together with challenge inoculation of Sclerotium rolfsii on the induction of induced systemic resistance (ISR) in groundnut-Sclerotium rolfsii pathosystem was studied under pot culture condition with groundnut cv.JL-24. It was observed that the application of, Methylobacterium e and Rhizobium, as co-aggregates, positively altered the biochemical and physiological parameters viz., reducing and non-reducing sugars, total and OD phenol content and defense enzymes activities, such as, peroxidase (PO) and polyphenol oxidase (PPO), of groundnut plant to the highest level followed by co-inoculation and single strain inoculation treatment. The application of PGPR cells, as co-aggregates, was found to augment the total and OD phenol content and defense enzyme activities, such as, PO and PPO content of groundnut plant to a higher level whereas a reduction in reducing and non-reducing sugar level was recorded, which ultimately lead to a reduction in Sclerotium rolfsii incidence in rainfed groundnut. It has been postulated that the EPS biosynthesis of PGPR cells during coaggregation processes, might act as an elicitor for the enhancement of ISR in groundnut-Sclerotium rolfsii pathosystem whereas application the vegetative cell and co-inoculation formulations, without any involvement of EPS, responded poorly for the enhancement of ISR in the same pathosystem. This is the first comprehensive report on the positive role of bacterial EPS, as a determinant of ISR, in groundnut-Sclerotium rolfsii pathosytem.
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REFERENCES

References: 

I.Bhaskaran, R., and N.N. Prasad, 1971. Certain
biochemical changes in two cucumis spp. In response to
Fusarium infection. Phytopath. Medit, 10: 233 - 243.
II.Breil, B.T., Borneman, J., Triplett, E.W.,1996. A newly
discovered gene, tfuA , involved in the production of
ribosomally synthesized peptide antibiotic trifolitoxin.
Journal of Bacteriology 178, 4150–4156.
III.Breil, B.T., Ludden, P.W., Triplett, E.W., 1993. DNA
sequence and mutational analysis of genes involved in the
production and resistance of the antibiotic peptide
trifolitoxin. Journal of Bacteriology 175, 3693–3702
IV.Burdman S., Y. Okon and E. Jurkevitch. 2000. Surface
characteristics of Azospirillum brasilense in relation to cell
aggregation and1attachment to plant roots. Crit. Rev.
Microbiol., 26: 91-110. .
V.Chakraborty, U. and R.P. Purkayastha. 1984. Role of
Rhizobiotoxin in protecting soybean roots from
Macrophomina phaseolina infection. Can. J. Microbiol. 30:
285-289.
VI.Chaudhary, D.K., and B.N. Johri, 2008. Interactions of
Bacillus spp. And plants – with special reference to Induced
Systemic Resistance (ISR) Microbiol. Res., 164: 493-513.
VII.Deshwal, V.K., R.C. Dubey and D.K. Maheshwari.
2003. Isolation of plant growth promoting strains of
Bradyrhizobium sp. (Arachis) with biocontrol potential
against Macrophomina phaseolina causing charcoal rot of
peanut. Curr. Sci. 84: 443-448.
VIII.Duffy, B.k., Weller, D.M., 1985. Use of
Gaeumannomyces graminis var.graminis alone and in
combination with fluorescent Pseudomonas spp. To suppress
take-all of wheat. Plant dis. 79, 907-911.
IX.Ester-Bauer, H.E. Schwarzl and M. Hayn. 1977. Anal
Biochem., pp.477-486
X.Farkas, G.L., and Z. Kiraly, 1962. Role of Phenolic
compounds in the physiology of plant disease and disease
resistance. Phytopathol., Z., 44: 105 – 150.
XI.Ghewande, M. P., Pandey, R. N., Shukla, A. K. and
Misrad, .D. P., 1983, A new southern blight disease of
groundnut caused by Sclerortium rolfsii Sacc. Current
Science, 16: 845-847.
XII.Goodman, R.N., Z – Kiraly, and M. Zaitlin, 1967. The
Biochemistry and Physiology of Infectious plant Diseases,
D. Van, No strand Co. Inc., Princeton, New Jersey.
XIII.Grimaudo NJ, Nesbitt WE, “Coaggregation of Candida
albicans with Oral Fusobacterium sp.”, Oral Microbiol.
Immunol, 12: 168 – 173, (1997).
XIV.Guzzo, S.D., E.E. Bach, E.M.F. Martins and E.B.C.
Moraes. 1993. Crude exopolysaccharides from
Xanthomonas campestris pv. Manihotis, Xanthomonas
campestris pv. campestris, and commercial xanthan gum as
inducers of protection in coffee plants against Hemileia
vastatrix J. Phytopathol., 139: 119-128
XV.Hammerschmidt,R., Kuc, J.,1995. Induced resistance to
Disease in plants. Kluwer Academicn
XVI.Jabra-Rizk, M.A., A.A. M.A. Baqui, J.I. Kelley, W.A.
Falkler, Jr. W.G. Merz and T.F. Meiller. 1999. Identification
of Candida dubliniensis in prospective study of patients in
the United States. J. Clin. Microbiol., 37: 321-326.
XVII.Kannan, 2010. Intergeneric microbial co-aggregates –
a novel formulation technology for the enhancement of
rhizobiocoenosis and salt tolerance maize plants under
salinity stress in Cuddalore district, Tamilnadu, Ph.D.
Thesis, Annamalai University, India.
XVIII.Kloepper, J.W. and M.N. Schroth, 1981, Plant growth
promoting rhizobacteria on radish, Proc. 4th Int. Conf. Plant
Pathol. Bacteria., 2: 879-882.
XIX.Kyungseok, P., J.W. Kloepper, and C.M. Ryu, 2008.
Rhizobacterial exopolysaccharides elicit induced resistance
on cucumber. J. Microbiol. Biotechnol., 18 (6) : 1095-1100.
XX.Lee, H.J., K.H. Park, J.H. Shim, R.D. Park, Y.W. Kim
and J.Y. Cho. 2006. Quantitative changes of plant defense
enzymes in biocontrol of pepper (Capsicum annum) late
blight by antagonistic Bacillus subtilis HJ 1927. J.
Microbiol. Biotechnol., 15: 1073-1079.
XXI.Leeman, M., J.A. Van Pelt, F.M. Den Ouden, M.
Heinsbroek, P.A.H.M. Bakker and B. Schippers, 1996. Iron
availability affects induction of systemic resistance to
Fusarium wilt of radish by Pseudomonas fluorescens.
Phytopathology, 86: 149-155.
XXII.Li,D.M and M.Alexander,1986. Bacterial growth rates
and competition affect nodulation and root colonization
Rh i z o b i um me l i t o i . Ap p l i e d e n v i r o nme n t a l
microbial.,52;807-811.
XXIII.Liu, L., J.W. Kloepper and S. Tuzun. 1995. Induction
of systemic resistance in cucumber against Fusarium wilt by
plant growth promoting rhizobacteria. Phytopathol., 85:
695-698.
XXIV.Madhaiyan, M., B. V. Suresh Reddy, R. Anandham,
M. Senthilkumar, S. Poonguzhali, S.P. Sundaram, and T.M.
Sa. 2006. Plant growth-promoting Methylobacterium in
defenses responses in Groundnut (Arachis hypogaea L.)
compared with Rot Pathogens. Current Microbiology., 53:
270-276.
XXV.Madhaiyan, M., Poonguzhali, S., Senthilkumar, M.,
Seshadri, S., Chung, H.,Yang, J.,. Tongmin, S.A., 2004,
Growth promotion and induction of systemic resistance in
rice cultivar Co-47 (Oryza sativa L.) by Methylobacterium
spp. Botanical Bulletin Academy Sin, 45: 315-325.
XXVI.Mahadevan and R. Sridhar, 1986.methods in
physiological plant pathology, III. Edn. sivakami pub.,
madras, 82p.
XXVII.Malik, K.A., B. Rackshanda, s. Mehnaz, G. Rasul,
M.S. Misra and S. Ali. 1997. Association of nitrogen-fixing
plant growth promoting rhizobacteria (PGPR) with kallan
grass and rice. Plant and soil., 194:37-44.
XXVIII. Maurhofer, M., C. Reimmann, S.P. Sacherer, S.
Heeb, D. Haas, and G. Defago. 1998. Salicylic acid
biosynthetic genes expressed in Pseudomonas fluorescens
strain P3 to improve the induction of systemic resistance in
tobacco against tobacco necrosis virus. Phytopathol., 88:
678-684.
XXIX.Neyra, C.A., L.A., Atkison, O. Olubayi, L.
Sudasivam, D. Zaurov and R. Zappi. 1999. Novel microbial
Technologies for the enhancement of plant growth and
biocontrol of fungal diseases in crops. Cahiers Options
Mediterr., 31: 447-455.
XXX.Okon, Y. and C. Labandra-Gonzalez. 1994.
Agronomic application of Azospirillum an evaluation of 20
years worldwide field inoculation experiments. Soil. Boil.
Biochem., 26: 1591-160.
XXXI.Putter, J.1974. In: Methods of Enzymatic Analysis 2
Ed Bergmeyer Academic Press, New York, pp. 635.
XXXII. Rubiya, E., 2006. “Co-aggregated diazotrophic
cultures” – A novel delivery system of bioinocula for
lowland rice (Oryza sativa L.) M.Sc. (Ag.). Thesis
Annamalai University
XXXIII. Schwinghamer, E.A., and Belkengren, R.P (1968).
Inhibition of rhizobia by a strain of Rhizobium trifoli: Some
properties of the antibiotic and of the strain .
Arch.mikrobiol.,64, 130-145.
XXXIV. Siddaanagoudar R. Radder,2005. Effect of bio
agents and their metabolites on Sclerotium rolfsii on
groundnut. University of Agricultural sciences, Dharwad
XXXV.Subrahmanyam, P., Williams, J. H., Mcdonald, D.
and Gibbones, R. W., 1984, Studies on sclerotial root rot
disease of groundnut caused by Sclerotium rolfsii Sacc.
Annual Applied Biology, 40: 467-476.
XXXVI.Thangamani, G. and Sundaram, S.P., 2005, Effect
of facultative Methylobacterium isolates on the hybrid rice
(Co RH2) seed quality. Abstract of Poster Presented in 3rd
National Conference of Association of Applied
Microbiologists (IAAM), 5-7, January 2005, Department of
Microbiology, Adiprakasakthi College of Arts and Science,
Kalava, Tamil Nadu, India, pp.63-64.
XXXVII.Usharani, G. 2005. Studies on the development of
Pseudomonas fluorescens as plant growth promoting
rhizobacteria (PGPR) and biocontrol agent of rice (Oryza
sativa L.) in Cuddalore district, Tamilnadu, Ph.D. Thesis,
Annamalai University
XXXVIII.Vaidhei.K 2013, Studies On The Development
And Use Of Pink Pigmented Facultative Methylotrophs
(Ppfm) For The Maximization Of Plant Growth Stimulation
And Isr Mediated Biocontrol Against Pyricularia Oryzae In
Lowland Rice Ph.D. Thesis, Annamalai University, India.
XXXIX.Van – veen,A.J.,van L.S. overbeek and J.D. van
Elasas(1997). Response of pearl millet cultivars inoculation
with nitrogen fixing bacteria Exp. Agric.,21:175-182
XL.Van Loon, L.C., P.A.H.M. Baker and C.M.J. Pieterse.
1998. Systemic resistance induced by the rhizosphere
bacteria, Annu. Rev. Phytopathol., 36: 435-483.
XLI.Van Peer, R. and B. Schippers. 1992. Lipo
polysaccharides of plant growth promoting Pseudomonas sp.
strain WCS 417r induced resistance in carnation to Fusarium
wilt. Neth. J. Plant Pathol, 98: 129-139.
XLII.Virmani, S M and Shurapli, J N, 1999. Climate
Prediction for Sustainable Production of Rainfed
Groundnuts in semi arid trophics. ICRISAT
XLIII.Zehnder, G., J. Kloepper, C. Yao and G. Wei. 1997.
Induction of systemic resistance in cucumber against
cucumber beatles (Coleoptera: Chrysomelidae) by plant
growth promoting rhizobacteria. J. Econ. Entomol., 90:
391-396.
XLIV.Griesbach H. 1981. In the biochemistry of plants
(Conn,E>E., ed),Academic press, New York, USA.Vol.7 p-
475-478..
XLV.Hammerschmidt,R., Kuc, J.,and E.M. Nuckles.1995.
Liginification as a mechanism for induced systemic
resistance in cucumber. Physiol.Plant pathol.,20:485-493

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