Browsing by Author "Kothari, I L"
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Item Biotransformation of banana waste into protein by pleurotus sajor-caju.(2000-08-01) Reddy, G V; Kothari, I L; Mishra, A; Patel, C RPseudostems and leaves from banana waste were used for biotransformation into protein by using P. sajor-caju, an oyster mushroom. Treatment of formalin (500 ppm) + carbendazim (12.5 ppm) of these substrates was found to favour relatively high percentage biological efficiency (BE) of P. sajor-caju.. Steam sterilization also exhibited comparable yield performance by P. sajor-caju. Fruiting bodies harvested from all the treatments had relatively higher protein contents. The spent substrate (steam sterilized) was found to be suitable as an ideal animal feed because of its rich nutritive composition.Item Culture filtrate of Lasiodiplodia theobromae restricts the development of natural resistance in Brassica nigra plants.(2004-01-28) Thakkar, Vasudev R; Subramanian, R B; Kothari, I LCulture filtrate of Lasiodiplodia theobromae increased respiration rate, phenylalanine ammonia lyase activity, and levels of hydrogen peroxide, lipid peroxides and salicylic acid in B. nigra plants. Salicylic acid (SA) level increased for 1 hr of interaction and reduced later. Development of systemic acquired resistance (SAR) was found restricted in plants infected with L. theobromae due to deficiency of SA, which is a major signal for development of SAR. Exogenously supplied SA did develop resistance and plant death was delayed. It was hypothesized that deficiency of SA could be due to jasmonic acid produced by fungus that inhibits SA biosynthesis.Item Infra-red spectroscopic analyses of banana waste degraded by oyster mushroom.(2002-09-18) Reddy, G V; Shah, M P; Kothari, I L; Ray, ACarbon, hydrogen and nitrogen analyses of banana leaf and pseudostem biomass revealed their potentiality as substrates for microorganisms. Infra-red (IR) spectra of both biomass show presence of cellulose, xylan and lignin. IR spectra of leaf and pseudostem biomass degraded in solid state fermentation (SSF) by two Pleurotus species (P. sajor-caju and P. ostreatus) for 40 days showed the utilization of cellulose, xylan and lignin by these microbes. Dynamics of various lignocellulolytic enzymes of Pleurotus species and analyses of carbon, hydrogen and nitrogen contents of degraded biomass supported the same. Both the Pleurotus species exhibited lignin consumption ability on both the substrates.Item Plant defense induced in in vitro propagated banana (Musa paradisiaca) plantlets by Fusarium derived elicitors.(2004-07-02) Patel, Miral; Kothari, I L; Mohan, J S SPerception of microbial signal molecules is part of the strategy evolved by plants to survive attacks by potential pathogens. To gain a more complete understanding of the early signaling events involved in these responses, we used fungal components of Fusarium under in vitro condition and checked the rise in signal molecule, salicylic acid (SA), and marker enzymes in defense reactions against the pathogen. SA level increased by 21 folds in elicitor treated plantlets as compared to that of control plantlets and there was marked increase in phenylalanine ammonia-lyase(PAL), peroxidase(POX), polyphenol oxidase(PPO) along with higher total phenolic content. Present results indicated that use of fungal components had successfully induced systemic resistance in in vitro cultured banana plantlets.Item Plant immunization.(2004-03-06) Kothari, I L; Patel, MiralPlant immunization is the process of activating natural defense system present in plant induced by biotic or abiotic factors. Plants are pre-treated with inducing agents stimulate plant defense responses that form chemical or physical barriers that are used against the pathogen invasion. Inducers used usually give the signals to rouse the plant defense genes ultimately resulting into induced systemic resistance. In many plant-pathogen interactions, R-Avr gene interactions results in localized acquired resistance or hypersensitive response and at distal ends of plant, a broad spectrum resistance is induced known as systemic acquired resistance (SAR). Various biotic or abiotic factors induce systemic resistance in plants that is phenotypically similar to pathogen-induced systemic acquired resistance (SAR). Some of the biotic or abiotic determinants induce systemic resistance in plants through salicylic acid (SA) dependent SAR pathway, others require jasmonic acid (JA) or ethylene. Host plant remains in induced condition for a period of time, and upon challenge inoculation, resistance responses are accelerated and enhanced. Induced systemic resistance (ISR) is effective under field conditions and offers a natural mechanism for biological control of plant disease.