(]Ji6Uograpli -...
Transcript of (]Ji6Uograpli -...
Bibliography
Aaronson, S. (1970). Experimental microbial ecology. Academic Press,
New York: 231.
Adyalkar, P.G. (1969) . Palaeogeograpily, nature and pattern of sedimentation
and ground water potentiality of the Puma basin of Maharashtra.
Proceeding of National Institution of Science, India, 29-A (1), 25-45.
Adyalkar, P.G. (1971 ). Palaeography, sedimentation of framework and
groundwater potentiality of the arid zones of western India. Proceeding
of Symposium on Problem& of Indian Arid Zones, CAZRI, 4-17.
Agnihotri , V.P. (1970). Solubilization of insoluble phosphate by some soil fungi
isolated from nursery seed beds. Can. J. Microbiology, 16: 877-880.
Ahmad, N. and K.K. Jha (1968). Solubilization of rock phosphate by
microorganisms isolated from Bihar soil. J . Can. Appl. Microbiol.,
14:89-95.
Alagwadi, A.R. (2003). Mechanism of microbial mineral phosphate
solubilization-a review. 44th Annual Conference of Association of
Microbiologists of India, Kaina!, Nov. 12-14.
Amann, R.I. , W. Ludwig. K.H. Sehleiyer., V.L. Torsvik and J. Goksoyr (1995).
Phylogenetic identification and in situ detection of individual microbial
cells without cultivation. Microbinl. Rev, 59: 143-169.
Ananthanarayan, R. and C.K.J. Paniker (1999). Bacteriology of water, milk
and air; in Paniker, C.K.J. (eds). Chapter 64, Textbook of Microbiology.
61h ed . 558-563.0rient Longman Ltd.
Asea, P.E.A., R.M.N. Kucey and J.W.8. Stewart (1988). Inorganic phosphate
solubilization by two Penicillium spp. in solution culture and soil.
Soil. Biol. Biochem, 20: 459-464.
Axelrood, P.E. , M.L. Chow., S. Clarke., A, Karen. L.U. Joseph., M. Dermott
and J . Davies (2002). Cultivation-dependent characterization of
bacterial diversity from British Columbia forest soils subjected to
disturbance. Can. J. Microbiai, 48: 643-656.
161
Bajpai, P.O. and W.V.B. SundaraR<10 (1971). Phosphate solubilizing bacteria
II, Extracellular production of organic acids by selected bacteria
solubilizing insoluble phosphate. Soil Science and Plant Nutrition, 17:
44-45.
Bajwa, M.S. (1999). Soil Salinity and alkalinity in Fundamentals of Soil
Science., 291-307. Published by Central Soil Salinity Research
Institute, Kamal.
Banik, S. and B.K. Dey (1981). Solubilization of inorganic phosphates and
production of organic acids by microorganisms isolated in sucrose
tricalcium phosphate aga; plates. Zentralblat. Bakteriol. II,
136: 4 78-486.
Banik, S. c.o1d 8 K. Dey (1982). Available phosphate content of an alluvial soil
as influenced by inoculation of some isolated phosphate solubilizing
microorganisms. Pl. Soil, 69: 353.
Baradiya, M.C. and AC. Gaur (1972). Rock phosphate dissolution by
bacteria. Indian Journal of Microbiology, 12: 269-271 .
Baradiya, M.C. and A.C. Gaur (1974). Isolation and screening of
microorganism dissolving low-grade rock phosphatic compounds by
native microflora of rock phosphate. Ind. J. Expt. Biol, 11: 427-429.
Barea, J. M., E. Navarro and E. Montoya (1976). Production of plant growth
regulators by rhizosphere phosphate solubilizing bacteria.
J. Appl. Bacterial., 40: 129-134.
Bhattacharya, P., T.K. Ghosh and R.K. Jain (1997). Evaluation of native
phosphate solubilizing mir.roorganisms from Vidarbha soils.
J. Maharashtra agric. Univ. , 22(2): 252-253.
Bilolikar, M.N., F<.S. Raut. , G.U. Malewar., S.N. Rachewad and
B.T. Lawand (1996). Occurrence of phosphate solubilizing bacteria in
soils of Marathwada region PKV Res. J, 20 (1): 18-20.
Citation - Hintz~. J. (2004). NCSS and Pass. Number Cruncher Statistical
System. Kaysville, Utah. Internet: http//www. NCSS. Com.
162
Collee, J.G., A.G. Frasier. , B.P. Marmion and A. Simmons {1996). Practical
Medical Microbiology, in Mackie and McCartney (eds), 141h ed.
978. Churchill Livingstone, New York.
Cornard, R. (1996). Soil microorganisms as controllers of atmospheric trace
gases. Microbial. Rev, 60: 609-640.
Dave, A., v. Narsian and H.H. Patel (2002). Halotolerant Pseudomonas
fluorescens as tricalcium phosphate solubilizer. Proceeding of national
symposium on Mineral Phosphate Solubilization,
U.A.S. Dharwad, Nov.
Dave, S.R. and H.B. Desai (2003). Microbial diversity at salterns near
Bhavnagar. Gujarat, India. Current Science, 90 (4): 497-500.
Dave. S.R., K.T. Chejava and K.G. Gongala (2003). Diversity among bacteria
growing on high salt concentration. 45th Annual Conference of
Association of Microbiologist of India, Hyderabad, Nov., 12-14.
Deepa, R. (2003). Mineral phosphate solubilization by fluorescent
Pseudomonas. M. Sc. (Agri .) thesis, University of Agricultural
Scienc;es, Dharwad.
Dey, B.K. , S. Banik and S. Nath (1976). Residual effect of organic manure on
the population and phosphate solubilizing power of wheat rhizosphere
soils. Indian Agric., 20: 235-249.
Dickinson, C.H., B Austin and M Goodfellow (1977). Antagonistic
interactions of phylloplane bactetia with Drechslera dictoroides.
Can. J . M:crobiol, 23: 710-715.
Dubey, R.C. and D.K. Maheshwari (2002). Practical Microbiology, 61h ed. 352.
S. Chand and Company Ltd., New Delhi.
Dubey, S.K. (1996). Response of soybean to rock phosphate applied with
Pseudomonas striala 1n a typical chromustert. J . Indian Soc.Soil Sci,
44(2): 252-255.
163
Dudhagara, P., M. Choudhary., R. Patel and S. Bhatt (2005). Screening of
diazotropic phosphate solub11izing isolates from the saline soil of
Gujarat. Western India 4c3'- ~.nnual Conference of Associailon of
Microbiologists of India, Hyderabad, Dec., 8-10.
Duff, R.B., D.M. Webley and R.O. Scott (1963). Solubilization of minerals and
related materials by 2-Ketogluco!'lic acid producing bacteria.
Soil. Sci, ~5: 105-114.
Erwin, T .L. (1991). An evolutionary basis for conservation strategies. Science,
253: 750-752.
Gadagi, A. and A.R. Alagawadi (2003). Effect of phosphate solubilizing
biofertilizers on growth and nutrient uptake of Sunflower. Proceeding of
National Symposium ori Mineral Phosphate Solubilization, U.A.S.
Dharwad, Nov.
Gaind, S. and A.C. Gaur (1991 ). Thermo tolerant phosphate solubilizing
microorGanisms and t~eir interaction with moongbean.
Pl. Soil, 133: 141-143.
Gaind, s. and A.G. Gaur (1999). Microbial phosphate solubilization as
influenced by sodium chloride. Ind. J. Exp!. Biol, 37: 209-210.
Gour, A. C., M. Madan and K. P. Ostwal (1973). Solubilization of phosphate
compounds by native miroflora of rock phosphate. Indian J . Exptl.
Biol. . 11 : 427-429.
Gaur, A. C. (1987). Organic manures and Biofertilizer. Division of
Microbiology, Indian Agriculture Research Institute, New Delhi, India.
46 and 124.
Gaur, A.G. (1990). Phosphate solubilizing microorganism as Biofertilizer.
Omega scientific publisher, New Delhi, India. 26-29.
Gaur, AC. and S. Gaind (1983). Microbial solubilization of phosphate with
particular reference to iron and aluminium phosphate.
Curr. Sci, 49: 110-112.
164
Gaur, A.C. and S. Sachar. (1980). Effect of rock phosphate and glucose
concentration on phosphste solubilization by Aspergillus awamori.
Curr Sci., 49: 553-554.
Gerretson, F.C. (1948). The influence of microorganism on the phosphate
uptake by the plant. Pl. Soil, 1: 51-58.
Girraffa, G., M. Gatti., L. Rossetti. , I. Senini and E. Neviani (2000). Molecular
diversity within Lactobaci/lus l1elveticus as revealed by genotypic
characterization. Appl. Environ. Microbiol, 66: 1259-1265.
Glick. B.R. (1995). The enhancement of plant growth by free-living bacteria.
Canadian J . Microbiol., 32: 145-148.
Goldstein, A.H . (1 g95). Bacterial solubilization of mineral phosphates:
Historical Perspective and Future Prospects. Amer. J . Alternat. Agric.,
1: 51-57.
Gordon, R.E. , W.C Haynes and C. Hov-Nay Pang (1973). "The genus
Bacillus". Agricultural Handbook. No. 427, USDA, Washington. DC.
Goswami, K.P. and A. Sen (1982). Solubilization of calcium phosphate by
three strains of phosphobacteria. Indian J . Agric. Sci., 32: 96-101 .
Greenwood, D .M . (1975). Anthrax bacillus; in Greenwood, D .M . (eds) .
Medical Microbiology. 2"d ed. 449-453. Churchill-Livingston, Edinberg,
London.
Ground Water Survey and Development Agency (1991). Government of
Maharashtra.
Ground Water Survey and Development Agency (2003). Government of
Maharashtra.
Gyaneshwar, P., G. Naresh Kumar and L.J. Parekh (1998). Effect of buffering
on the phosphate solubili;:.ing ability of microorganisms. World J .
Microbiol. Biotechnol., 14: 669-673.
Halder, A.K.. A.K. Mishra and P.K. Chakraborty (1992). Microbial
solubilization of phosphate. Everyman Science, 27: 38-41 .
165
Hallikeri, S.S., H.L. H:ilemani., R.P .. Nandagavi and M.B. Antaravalli (2003).
Response of cotton to Azospirillum and phosphate solubilizing bacteria
under rainfed condition. Proceeding of National Symposium on Mineral
Phosphate Solubilization. UAS. Dharwad, Nov.
Haque, N.A. and 3 .R. Dave (2006). Diversity of phosphate solubilizers in
semi-arid agricultural soils. Indian Journal of Microbiology,
15(1): 27-32.
Haque, NA and S.R. Dave (2002). Influence of nutrients on phosphate
solubilization by a non-sporulating gram-positive rod. Proceeding of
National Symposium on rv'!ineral Phosphate Solubilization, U.A.S.
Dharwad, Nov.
Holt, J.G., P.A. Sneath and A. Keren (1984-1989). "Bergey's Manual of
Systematic Bacteriology. 1: 2709. Williams and Wilkins, Baltimore.
Hooda, S. and K. Sumanjeet (1999). Laboratory Manual for Environmental
Chemistry. S. Chand and Company Ltd. New Delhi., 15.
Hutchinson, G.E. (1959). Homage to Santa Rosalia, or why are there so many
kinds of animals? Am. Nat .. 93: 145-159.
lllmer, P. and F. Shinner (1992). Solubilization of inorganic phosphate by
microorganisms isolated from forests soil. Biol. Biochem .. 24: 389-395.
lllmer, P., A. Barbato and F. Shinne.- (1995). Solubilization of inorganic
calcium phosphate solubilization mechanisms. Soil. Biol. Biochem.,
27: 257-263.
lntroy, M.C. and J.A., Kloepper (1994). Molecular Ecology of Rhizosphere
Micro-organisms; in O'Gera, F., D.N. Dowling and B. Boeten (eds).
Biotechnology and the Reliese of GMOs 19-2, VCH Verlagsgesllscheft,
wihein.
Isherwood, K.F. (2000). Mineral fertilizer use and the environment.
International fertilizer industry association/ United Nations environment
programme, Paris.
166
Jarn, R.K., M. l\apoor., S. Labar.a. , B. Lal .. P.M. Sharma., D. Bhattacharya
and l.S. Thakur (2005). Microbial diversity: Application of
microorganisms for the biodegradation of xenobiotics. Current Science.
89 (1): 101-112.
Jeffrien, P. and J.N. Barea (1994) Impact of arbuscular mycorrhizae on
sustainable agriculture and natural ecosystems.
in Gianinazzi, S. and H. Shuepp (eds). Birkhauser-Verlag, Basel.
101-115.
Johari, B.N .• RN. Ganguly., S.K. Goel., J.S. Virdi., A.K. Tripathi. , R.K. Jain.,
D.N. Karma and A. Bhatnagar. (2005). Microorganism diversity.
Strategy and action plan. Curr. Sci., 89: 151-154.
Johari, J.K., S. Surange and C.S. Nautiyal (1ggg). Occurrence of some pH
and temperature tolerant phosphate solubilizing bacteria from alkaline
soils. Current Microbial. , 39(2): 9g_93_
Kapoor, K.K. and M.M. Mishra (1939). Phosphate solubilization by soil
microorganisms. A review. Indian J. Microbial, 29: 119-127.
Kapoor, K.K., M.M. Mishra and K. Kukreja (1989). Phosphate solubilization
by soil microorganisms. Indian Journal of Microbiology. 29:119-127.
Kate, T.K. and S.A. Laird. (1999). The commercial use of biodiversity; in
Staley, J.T and A.L. Reysenbach (eds). Chapter 5, Access to genetic
resources and benefit-sharing, 477-519. Wiley-Liss, Inc.
Katznelson, H. and B. Bose (195g). Metabolic activity and phosphate
dissolving ability of bacterial isolates from wheat roots rhizosphere and
non- rhizosphere soil. Can. J. Microbiol., 5. 79-85.
Kennedy, A.G. and K.L. Smith (1995). Soil microbial diversity and
sustainability of agricultural soil. Plant and Soil, 170: 75-86.
Kessler, B.K. (1958). Soil microorganisms and salt avoidance: in Singh, J. S.
(eds). Restoration of degratled land; Concept and strategies 56-75.
Rastogi Publication, Meerut, India.
Kim, K.Y., D. Jordon and H.B. Krishnan (1997). Rahnella aquaticus a
bacterium isolated from Soyabean rhizosphere, can solubilized
hydroxyapatite. Can. J. Microbiology, 153: 273 -277.
167
Kloepper, J.W. , F.M. Scher., E.M. l.alibent and B. Tipping (1986). Iron,
siderophore and plant diseases; in Swinburne, T.R. (eds). 155-164.
Plenum Press, New York.
Knight, B.C.J. and H. Proom (1950). A comparative survey of the nutrition and
physiology of the mesophilic species in th!'! gMus aacillus.
J. Gen. Microbial. , 4: 508-538.
Kole, S.C. and J.N. Hajra (1997). Occurrence and acidity of tricalcium
phosphate solubilizing microorganism in mechanical plant compost of
Calcutta and non-alluvial soil of West Bengal.
Environment and Ecology, 16 (2): 344-349.
Kovda, V.A., C. Berg., D. Van and H.M. Robert (1973). Irrigation, drainage
and salinity, an international source book, 273-276., FAQ/UNESCO.
Kucey, R.M.N., H.H. Janzen and M.E. Leggett (1989). Microbially mediated
increases in plant avf'lilable phosphorus. Adv. Agron. , 42: 199-221 .
Kundu, B.S. and A.C. Gaur (1980). Effect of nitrogen fixing and phosphate
solubilizing microorganisms as single and composite inoculants on
cotton. Indian Journal of Microbiology, 20: 225-229.
Kundu , S.S., M. Tomar and K. Nandal (2002). Biochemical characterization
of phosphate solubilizing bacteria isolated from the rhizosphere of
chickepea, wheat and mustard grown at dlfterent location of Haryana.
43rd Annual Conference of Association of Microbiologists of India,
Hisar, Dec., 11-13
Kundu, B. S., M.Tomar and K. Nandal (2004). Mineral phosphate solubilizing
bacteria from the rhizosphere of chickepea, wheat and mustard grown
at different location of Haryana. 45th Annual Conference of Association
of Microbiologists of India, Kamal, Nov., 23-25.
Lakshmanaperumalsamy, P. (2001 ). Microbial biodiversity as bioresource.
44th Annual Conference of Association of Microbiologists of India,
Dharwad, Nov., 12-1 4
168
Liu, S.T., L.Y Lee., C.Y Tai. , C.H Hung ., Y.S Chang., J.H Wolfram.,
R. Rogers and A.H. Goldstsin (1992). Description of two new
thermophillic spp. from a hot spring. International Journal of Systematic
Bacteriology, 174: 5814-5819.
Logan, NA and R.C.W. Berkeley (1984). Identification of Bacillus strains
using the API system. J. Gen. Microbiol., 130: 1871-1882.
Lauw, HA and D.M. Webley (1959). The bacteriology of root region of the oat
plant gr'.lwn under controlled pot-culture conditions.
J. Appl. Bacterial , 22: 216-226.
Lynch, J.M. (1990). Introduction: some consequences of microbial
competence for plant and soil in the rhizosphere in Lynch, J.M. (eds).
1-10. John Willey and sons, Chichester, UK, 1990.
Mac arthur, R.H. (1957). On the relative abundance of bird species.
Proceeding of National Academic Science., USA, 43: 293-295.
Magurran, A.E. (1988). Ecolog1ca: diversity and its measurement.
in Staley, J.T and A.L. Reysenbach (eds). Chapter 5, Access to genetic
resources and benefit-sharing, 477-519. Wiley-Liss, Inc.
Mehta, S. and C.S. Nautiyal (2001 ). An efficient method for qualitative
:u;reening ur µllosphate SOIUOlllZlng bacteria. Current Microbial.,
43 (1 ) : 89-93.
Morris, S.A., J.E. Curotto., D.L. Zink .. S. Dreikorn., R. Jenkins., G.F. Bills. ,
J.R. Thompson., F. Vicente., A. Basilio., J.M. Liesch and R.E. Schwartz
(2002). Sonomolide-A and Sonomolide-B, new broad-spectrum
antifungal agents isolated from a coprophilous Fungus. Tetrahedron
Lett., 36: 9101-9104.
Motsara, M.R. (2002). Available nitrogen, phosphorus and potassium: status
of Indian soils as depicted in soil fertility maps. Fertilizers news.
47(8): 15-21 .
Myskow, W. (1960). The dissolving of calcium phosphate by some soil
bacteria. Acta Microbial. Polan. 9: 367-383.
169
Nahas, E. (1996). Factors determining rock phosphate solubilization by
microorganisms isolated from soil. World. J. Microbial. Biotechnol,
12: 567-572.
Nair, S.K. and N.S.S. Rao (1977). Distribution and activity of phosphate
solubilizing microorganisms in the rhizosphere of coconut and cacao
under mixed cropping. J. Plantation Crops, 5: 67-70.
Naresh Kumar, G. (2002). Genetic modification of rhizobacteria for enhanced
organic acid secretion and phosphate solubilization, in: First
international meeting on 'Microbial Phosphate Solubilization' held at
Salamanca, Spain during July 16-19.
Narsian, V., J. Thakkar and H.H. Patel (1993). Solubilization of natural rock
phosphate and pure insol;.ible inorganic phosphate by Aspergil/us
awar.1orii Ind. J . Expt. Biol., 31: 747-749.
Narsian V., J. Thakkar and H.H. Patel (1994). Isolation and screening of
phosphate solubilizing fungi. Indian Journal of Microbiology,
34 (2): 113-118.
Narsian, V., J. Tnakkar and H.H. Patel (1995). Mineral phosphate
solubilization by Aspergillus acuteatus. Ind. J. Expt. Biol., 33: 91-93.
Narsian, V. and H.H Patel (1997). Salt tolerance and phosphate solubilizing
activity of Aspergillus aculeatus. Ind. J. of Microbial., 37: 43-44.
Narsian, V. and H.H. Patel (2006). Biodiversity of phosphate solubilizing
microorganisms in various rhizosptiere soils of Bhavnagar district.
Asian. J. Microbial. Biotech. Env. Sci., 8 (2): 201-204.
Natarajan, T., K. lllamuruguk and K. Govindrajan (2002). Importance of
phosphate solubilizing mic~oorganisms on crop growth. Biofertilizer
News Letter, 15-16.
National Environmental and Engineering Research Institute, Nagpur (2001).
Environmental Impact Assessment of Jeagaon Project.
Nautiyal, C. S., S. Bhadauria., P. Kumar., H. Lal., R. Monda! and D. Verma
(2002). Stress induced phosphate solubilization in bacteria isolated
from alkaline soils. FEMS. Microbial. Lett., 182: 291-296.
1'10
Nimkar, A.M., SB. Deshpande and P.G. Babrekar (1992). Evaluation of
salinity problem in sweep, shrinks soils of a part of the Puma valley,
Maharashtra. Agropedology, 2: 59 - 65.
Nubel, U., F. Garcia-Piche!., M. Kuhl and G. Muyzer (1999). Quantifying
microbial diversity: Morphopypes, 163 rRNA genes and carotenoids of
oxygenic phototrophs in microbial mats. Appl. Environ. Microbial.,
65: 422-430.
O'Donnell, A.G., M. Goodfellow, and D.L. Hawksworth (1995). Theoretical and
practical aspects of the quantification of biodiversity among
microorganisms; in Hawksworth D.L. (eds). 65-73. Biodiversity
measurement and estimation. Chapman and Hall, London,
United Kingdom.
Ogunseitan, O.A., S. Yang and J.E. Erickson (2000). Microbial delta
ano-levulinate dehydratase as a biosensor of lead (Pb) bioavailability in
contaminated environments Soil Biology and Biochemistry,
32: 1899-1906.
Oren, A. (2002). Diversity of halophilic microorganisms: environment.
phylogeny, physiology and applications. Ind. J . Microbiol Biotechnol.
28 (1): 56-63.
Ostwal, K.P. and V.P. Bhide (1972). Solubilization of tricalcium phosphate by
soil Pseudomonas. Ind. J. Exptl. Biol., 10: 153-154.
Pace, N.R. (1997). A molecular view of microbial diversity and the biosphere.
Science, 276: 734-740.
Pandhi, N.D., H.B. Monpara., J.N. Patel., R.J. Shukla and V.B. Vyas (2005).
Study of phosphate solub11izing microbes of rhizosphere.
461h Annual Conference of Association of Microbiologists of India,
Hyderabad, Dec., 8-10.
Patil. S.G., M.B. Doddaniiani and K . s. Jagadish (2003). Phosphorus dynamic
in agro-ecosystem. Proceeding of National Symposium on Mineral
Phosphate Solubilization, U.A.S. Dharwad, Nov.
171
Paul. N.B and A. Sen. (1971) Phosphate dissolving bacteria in rhizosphere
of some cultivated legumes. Plant and Soil, 25 (1): 127-132.
Pendhan. R. A. and S. G. Dalhathreya (1998). Application of geophysical
investigation in groundwater zones within saline dominance. National
Seminar on Groundwater Salinity, Water Resource Development and
Management of Puma Alluvial Basin, (M.S.)
Jan. 28-29. G.C.O.E., Amravati.
Pikovskaya, R.I. (1984). Mobilization of phosphorus in soil in connection with
activity of some microbial species. Microbiologiya, 17: 362-370.
Priest, F.G (1981). DNA homology in the genus Baciilus: in Berkeley R.C.W.
and M. Goodfellow (eds). Aerobic endospore forming bacteria:
classification c.nd identification. 33-57. Academic Press, London.
Rai, M. (2004). Inaugural address note. 45th Annual Conference of
Association of M1crobio:ogists of India. Kamal. Nov. 23-25.
Ramachandran, K., V. Shrinivasan and S. Hamza (2001). Phosphate
solubilizlng bacteria isolated from the rhlzosphere soil and root cuttings
of bush black pepper (Piper nigrum. L). Current Microbial.,
43 (1 ): 89-93.
Ramanl, V. ar.d H.H. Patel (2001). Phosphate solubilizing halotolerant
bacteria as seed inoculants for saline area crop. Proceeding of
National Symposium on Mineral Phosphate Solubilization, U.A.S.
Dharwad, Nov.
Rodrigue.!, H. and R. Fraga (1999). Phosphate solubillzlng bacteria and their
role in plant growth promotion. Biotechnol. Adv., 17 (4-5): 319-339.
Sagare, B.N., S.K. Thakare and B.A. Sonune (2000). Vidarbhatil Purnechya
khoryatil ksharyukta Jamin. National Seminar on Groundwater Salinity,
Water Resource Development and Management of Puma Alluvial
Basin, M.S. Jan. 28-29. G.C 0 .E, Amravati.
Sahani, B. M. (1972). Water resource development strategy for saline ground
water zone of PRB (1999). National Seminar on Groundwater Salinity,
Water Resource Developme:nt and Management of Puma Alluvial
Basin, M.S. Jan. 28-29. G.C.O.E, Amravati.
172
Saraf, M. and N. D. Tank (2001). Evaluation of PGPR's as Phosphate
solubilizers and Ammonia excreting Rhizobacteria. Proceeding of
National Symposium on Mineral Phosphate Solubilization, U.A.S.
Dharwad, Nov.
Sattar, M.A. and Gaur, A.C (1885). Characterization of Phosphate dissolving
microorganisms isolated from some Bangladesh soil sample.
Bangladesh J. Microbiology, 2: 22-28.
Sen, A. and N.B. Paul (1957). Solubilization of Phosphates by some common
soil bacteria. Current Science, 26: 222-223.
Seshikala, D., J.V.S. Goud and M.A. Singaracharya (2005). Biodiversity of
macrofungi in Andhra Pradesh. 461h Annual Conference of Association
of Microbiologists of India. Dec .. 8-10.
Sharma, R.C. (1998) Nature, extent and classification; in Bajwa, M.S.(eds)
Fundamentals of Soil Science., 291-307. Published by Central Soil
Salinity Research Institute, 1121. ESSRI, Kamal.
Sharma, R. R. Ranjan., R.K. Kapardcir and A. Grover (2005). Uncultivable
bacterial diversity: An untapped resource in special section: Microbial
diversity. Current Science. 89(1): 72-75.
Singer, S. (1975). Use of bacteria for control of aquatic insect pest;
in Impact of the Use Microorganisms on Aquatic Environment, 5-22
and 239. National Ecological Research Series E.P.A. 660-3-75-001.
Singer, S. (1988). Clonal populations with special reference to Bacillus
sphasricus. Adv. Appl. Microbial. 33, 47-74.
Singh, J.S. and K.C. Jha (1993). Restoration of degraded land; Concept and
Strategies in Singh, J.S. (eds). Rastogi Publication. Meerut, India.
Singh, S. and K.K. Kapoor (1984). Solubilization of insoluble phosphate by
bacteria isolated from different sources. Environment and Ecology,
12(1 ): 51-55.
Singh, S. and K.K. Kapoor (1958). Solubilization of insoluble phosphate by
microorganisms under the influence of carbon sources isolated from
different sources. Bangladesh J. Microbiology, 1: 13-15.
173
---
Smith, R.D. (1995). Veterinary Clinical Epidemiology, 2nd ed ..
130-131.CRC Press. Ann Arbor, Mich.
Sneath, P.H.A. (1984). Bergey's Manual of Systematic Bacteriology.
8 1hed. 2: 1104-1108.
Sneath, P.H.A. and R.R. Sokal (1973). "Numerical Taxonomy." freeman,
San Francisco.
Somani. L.L.. H.N Gaur and SC Bhandari (1998) Microbiology of salt
affected soils: In soil microorganisms and crop growth. S.K.N. College
of Agriculture. Jobner-303 3291 , India.
Sonule, B.B. and A.K. Srivastav (1993). Morphometric analysis of Puma river
basin, Maharashtra. Groundwc:ter Recharging and with Management of
Wardha basin. Organised by Maharashtra water and irrigation
Amravati. 51 - 61.
Sperber, J .I. (1958). Solubilization of Mineral Phosphate by Soil Bacteria.
Nature, 181-934.
Subbarao, N.S. (1993). Phosphate solubilizing microorganisms.
in: Biofertilizers in Agriculture and Forestry, 129-136. Oxford and IBH
publishing Co. Pvt. ltd, New Dalhi.
Surange, S. and N. Kumar (1993) . Phosphate solubilization under varying pH
by rhizobium from tree legurne. Indian J . Experimental Biology,
31 : 855-857.
Tambekar, D.H. (1998). Phosphate solubilizing microorganisms as
bio'ertilizer. Selected topics In Biotechnology, 43-53. Edited PAMA
Publication, Karad.
Tambekar, O.H. and 0 .0. Bhokare (2003). Isolation and identification of
phosphate solub1izing microorganisms isolated from saline belt of
Akola district. J. Microb. World, 5(2): 67-68.
Tambekar, D.H. and M.V . Khodke (2003). Studies on production of liquid
phosphate solubilizing bacterial biofertilizer. 44th Annual Conference of
Association of Microbiologists of India, Dharwad, Nov. 12-14.
174
Tambekar, D.H. and U.A Bidwai (2003). Studies on biodiversity of phosphate
solubilizing Bacillus subtilis isolated from salinity affected villages in
Puma allJvial soil of Vidarbha. 44th Annual Conference of Association
of Microbiologists or India, Dharwad, Nov. 12-14.
Tambekar, D.H. and U.A. Bidwai (2004). Biodiversity of phosphate solubilizing
Bacillus subtilis in salinity affected soil of Vidarbha. 45lh Annual
Conference of Association of Microbiologists of India. Karnal.
NOV. 23-25.
Tambekar, D.H. a:id D.D. Bhokare (2005). Studies on effect of various carbon
and nitrogen sources on phosphate solubilization by bacteria isolated
from saline soil. J. Microb. Wor:d, 7(1): 67-68.
Tambekar, D.H. and U.A. Bidwai (2005). Effect of temperature on the
phosphate solubilizing activity of Bacillus subtilis. National Conference
on Microbial Technology for Sustainable Agriculture, Solapur,
Jan. 23-24.
Tombel\ar, D.H. and U.A. Bidwai (2005). Studies on biodiversity of phosphate
solubilizing Bacillus subtilis isolated from salinity affected villages in
Purna alluvial soil of Vidarbha. 45th Annual Conference of Association
of Microbiologists of India, Hyderabad, Dec. 8-10.
Tambekar, D.H .. U.A. Bidwai, D.D. Bhokare, R.R. Jane and S.D. Tambekar
(2006). Biodiversity of phosphate solubilizing Bacillus subtilis isolated
from saline tract of Vidarbha. PKV. Res. J., 30(2): 181-165.
Tambekar. D.H. and o o . Bhokare (2006). Effect of temperature on
phosphate solubilization by microorganisms isolated from saline soil.
J. Microb. World, 8(1): 140-142.
Tardieux-Roche, A. (1966). Contnbut1on an l'etude des interaction entre
phosphates naturals et micro flora du sol. Ann. Agron., Paris,
17: 403-407.
175
Tathe, J.M. and S.V. Borkar (1999). Desalination of Puma river water by
recharging and pumping. National Seminar on Groundwater Salinity,
Water Resource Development and Management of Puma Alluvial
Basin, M.S. Jan. 28-29. G.C.O.E, Amravati.
rna1111ar, J. (1993). Solubilization of natural rock phosphate and pure insoluble
inorganic phosphate by Aspergillus ewamori. Ind. J. Expt. Biol.,
31: 747-749.
Tham1zh V.R. and M. ThangaraJU (2005). Developing suitable strains of
phosphobacteria for acid and alkali soils. J. Microb. World, 7(2):
289-293.
Tisdale, S.L., W.L. Nelson., J.D. Beaton and J.L. Havin (1 997). Soil fertility
and fertilizers. 5'h ed., 176-205. Prentice Hall of the India, New Delhi.
Tomar. M., I<. Nandal and B. S. Kundl! (2004) Mineral phosphate solubilizing
bacteria from the rhlzosphere or Chickpea, Wheat and Mustard grown
at different location of Haryana. 451h Annual Conference of Association
of Microbiologists of India, Kamal, Nov. 23-25.
Torsvik, V., J. G0ksoyr and F.L. Daae (1990). High diversity in DNA of soil
bacteria. Appl. Environ. Microbial. 56: 782-787.
Upaddhaya, R.S., R. Raghuwanshi and A. Kumar (2004). Microbial Diversity
in Saline-alkali soils of India In Relation to its Reclamation, in: Microbial
Diversity: Opportunities and Challenges. 350-360.
Vaishya, U.K., P.N. 8apat and AV. Dubey (1996). Phosphate solubilizmg
efficiency ur microorganisms on gram grown on vertisol.
J. Indian Soc. Soil. Sci., 44(3): 524-526.
Veena, S.C., A.R. Alagwadi and P.U. Krishnaraj (2002). Phosphate
solubilization and other beneficial traits of the native micro flora of
sorghum rhizosphere. Proceeding of National Symposium on Mineral
Phosphate Solubilization, U.A.S. Dharwad, Nov.
vendan and Thangaraju (2005). Phosphorus cycling in wheat-pasture
rotation, II The role of the microbial biomass in phosphorus cycling.
Australian Journal of Soil Research, 26: 333-342.
176
Venkateshwarlu, 8., AV Rao and P. Raina (1984). Evaluation of phosphorus
solubilization by microorgcinisms isolated from arid soils.
J. Indian. Soc. Soil. Sci., 32 273-277.
Vivekanandhan G .. K. Sav1thamani and P. Lakshmanaperumalsamy (2005)
Influence of pH, salt concentration and temperature on the growth of
Aeromonas hydrophila. J. Environ. Biol., 24 (4): 373-379.
Waisel, Y (1972). Biology of Halophytes, Academic press. New York, 30.
Wani, P.V., 8.8. More and P.L. Patil (1979). Physiological studies on the
activity of phosphorus solubilizing microorganism. Ind. J. of Microbial.
19: 23-25.
Wani. SP (1992). Role of Bioferti!izer in Upland Crop Production
Semi Arid Tropics (ICRISAI), 91-112.
Ward, D.M., M. J. Ferris., S.C. Nold and M. M. Bateson (1998). A natural view
of microbial biodiversity within hot spring cyanobacterial mat
communities. Microbial. Mol. Biol. Rev., 62: 1353-1370.
Watanbe, K., H. Futamata and S Harayama (2002). Understanding the
d1vers1ty in catabolic potential of microorganisms for the development
of bioremediation strategies Anton Van Leeuwen., 81. 655-663.
Woese, C.R. (1998). The univers;il ancestor. Proceeding of National
Academic Science, 95: 6854-6859, U.S.A.
Woitke M., H. Junge and W.H. Schnitzler (2001) Bacillus subtifis as growth
promotor in hydroponically grown tomatoes under saline conditions.
{Abstract) ISHS Acta Horticulture, 659: 7..,, International Symposium on
Protected Cultivation In Mild Winter Climates: Production, Pest
Management and Global Competition.
Wyane, W. B. (1969). "Valley of rurna river water" Record on Geological
Survey, India. 1-5.
Yadav, R., M. Tomar and 8.S. Kundu (2004). improvement of phosphate
solubilizing bacterial strains for efficient phosphate solubilization. 45111
Annual Confere::nce of Association of Microbiologists or India, Karnal,
Nov 23-25.
177