P Pardha Saradhi

Publications (13)28.46 Total impact

• Article: Heavy metal induced physiological alterations in Salvinia natans.

  Bhupinder Dhir, P Sharmila, P Pardha Saradhi, S Sharma, R Kumar, Devinder Mehta
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  ABSTRACT: Salvinia possess inherent capacity to accumulate high levels of various heavy metals. Accumulation of Cr, Fe, Ni, Cu, Pb and Cd ranged between 6 and 9 mg g(-1)dry wt., while accumulation of Co, Zn and Mn was ∼4 mg g(-1)dry wt. Heavy metal accumulation affected the physiological status of plants. Photosystem II activity noted to decline in Ni, Co, Cd, Pb, Zn and Cu exposed plants, while Photosystem I activity showed enhancement under heavy metal stress in comparison to control. The increase in PS I activity supported build up of transthylakoidal proton gradient (ΔpH), which subsequently helped in maintaining the photophosphorylation potential. Ribulose 1,5 dicarboxylase/oxygenase (Rubisco) activity noted a decline. Alterations in photosynthetic potential of Salvinia result primarily from changes in carbon assimilation efficiency with slight variations in primary photochemical activities and photophosphorylation potential. Studies suggest that Salvinia possess efficient photosynthetic machinery to withstand heavy metal stress.
  Ecotoxicology and Environmental Safety 07/2011; 74(6):1678-84. · 2.29 Impact Factor
• Article: Heavy metal removal potential of dried Salvinia biomass.

  Bhupinder Dhir, Sekh A Nasim, P Sharmila, P Pardha Saradhi
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  ABSTRACT: Investigations were carried out to evaluate heavy metal adsorption capacity of Salvinia. Batch experiments showed that dry plant biomass possess good potential to adsorb heavy metals such as Ni, Co, Cr, Fe, and Cd. The metal adsorption increased with increase in initial metal concentration. The data obtained fitted well with Freundlich equilibrium isotherm. Further characterization of plant biomass showed presence of both acidic and basic surface functionalities that might facilitate binding of metal ions. Fourier transform infrared (FTIR) spectra of plant biomass suggested involvement of carbonyl (C=O), carboxyl (-COO), and hydroxyl (-OH) groups in binding heavy metals to plant biomass. The studies establish S. natans as an effective biosorbent for removing heavy metals from wastewater and further emphasize biomass utilization in wastewater treatment technologies.
  International Journal of Phytoremediation 02/2010; 12(2):133-41. · 1.30 Impact Factor
• Article: Physiological and antioxidant responses of Salvinia natans exposed to chromium-rich wastewater.

  Bhupinder Dhir, P Sharmila, P Pardha Saradhi, Sekh Abdul Nasim
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  ABSTRACT: Salvinia natans possess capacity to accumulate high concentrations of chromium (Cr). Studies were carried out to evaluate physiological efficiency and defensive potential of plant exposed to Cr-rich wastewater. Among photochemical reactions, photosystem I (PS I) and photosystem II (PS II) activity noted an increase in plants exposed to Cr-rich wastewater. Fluorescence ratio F(v)/F(m) depicted no alteration in plants exposed to Cr. The activity of ribulose-1,5-biphosphate carboxylase-oxygenase (Rubisco) noted a decline, while transthylakoidal pH gradient (DeltapH) (correlative of photophosphorylation) showed increase in plants exposed to Cr-rich wastewater. Plants lacked the ability to produce malondialdehyde, but possessed efficient enzymic and non-enzymic antioxidant defense mechanisms that played important role in curtailing oxidative stress. The activities of antioxidant enzymes showed alleviation in plants exposed to Cr-rich wastewater. The levels of cellular antioxidants noted decline suggesting a defensive role in protection against oxidative stress caused by Cr. The present findings suggest that Salvinia possess efficient antioxidant machinery that curtails oxidative stress caused by Cr-rich wastewater and protects photosynthetic machinery from damage.
  Ecotoxicology and Environmental Safety 05/2009; 72(6):1790-7. · 2.29 Impact Factor
• Article: Targeting prokaryotic choline oxidase into chloroplasts enhance the potential of photosynthetic machinery of plants to withstand oxidative damage.

  P Sharmila, M L V Phanindra, Firoz Anwar, Kavita Singh, Shipra Gupta, P Pardha Saradhi
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  ABSTRACT: Chloroplasts from plants of transgenic lines expressing prokaryotic choline oxidase gene (the codA(ps) gene; GenBank accession number-AY589052) and wild-type of chickpea and Indian mustard were evaluated for their efficacy to withstand photoinhibitory damage, by exposing them to high light intensity ( approximately 1200micromolm(-2)s(-1) photon flux density) at 10 and 25 degrees C. Western analysis confirmed presence of choline oxidase in chloroplasts of only transgenic lines. The loss in PS II activity in chloroplasts of wild-type exposed to high light intensity was significantly higher than that in chloroplasts of transgenic chickpea as well as Indian mustard. Although, chloroplasts of both wild-type and transgenic chickpea as well as Indian mustard were more sensitive to photoinhibitory damage at 10 than at 25 degrees C, the damage recorded in chloroplasts harboring choline oxidase was significantly lower than those of wild-type. High light promotes H(2)O(2) production in chloroplasts more significantly at low temperature (10 degrees C) than at 25 degrees C. We compared low temperature accelerated photoinhibition of chloroplasts with that caused due to exogenously applied H(2)O(2). Although exogenous H(2)O(2) accelerated high light intensity induced loss in PS II activity of chloroplasts of wild-type, it caused only a little alteration in PS II activity of chloroplasts from transgenic lines of both chickpea and Indian mustard, demonstrating that the chloroplasts harboring choline oxidase are better equipped to resist photoinhibition. We hypothesize that H(2)O(2) produced by choline oxidase as a byproduct during synthesis of glycinebetaine is responsible for building stronger antioxidant system in chloroplasts of transgenic lines compared to that of wild-type.
  Plant Physiology and Biochemistry 02/2009; 47(5):391-6. · 2.84 Impact Factor
• Article: An optimal protocol for in vitro regeneration, efficient rooting and stable transplantation of chickpea.

  Firoz Anwar, P Sharmila, P Pardha Saradhi
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  ABSTRACT: A rapid, reproducible and efficient regeneration method was developed for chickpea (Cicer arietinum L.) using single cotyledon with half embryonal axis as explants. MS medium supplemented with 4 ìM TDZ, 10 ìM 2-iP and 2 ìM kinetin induced 50-100 adventitious buds/shoots after 14 days of culture and elongated on MS medium supplemented with 5 ìM 2-iP and 2 ìM kinetin. Healthy, strong and 100 % rooting was achieved by exposing cut ends of the shoots to 10 sec pulse treatment with 100 ìmoles/ml IBA followed by their transfer to liquid MS basal medium within 10-14 d. 2-3 cm long shoots were most suitable for rooting. Potting-mixture with good aeration and lesser capacity to retain water was most suitable for achieving successful establishment of chickpea plantlets. Garden soil mixed with sand (gravel) and bio-manure in the ratio of 1:1:1 is most suitable for achieving cent percent transplantation success. Cent percent of plantlets got acclimatized, survived in the pots and showed normal growth, development, flowering followed by podding and seeds setting. Harvesting of seeds was done after the pods were fully matured and dry. In this communication, we have demonstrated for the first time that shoot length, pulse treatment of cut ends of shoots with 100 ìmoles/ml IBA and aeration of potting mixture are key factors for rapid micro-propagation and successful establishment of chickpea.
  Physiology and Molecular Biology of Plants 10/2008; 14(4):329-35.
• Article: Developing embryos of Sesbania sesban have unique potential to photosynthesize under high osmotic environment.

  Jos T Puthur, P Pardha Saradhi
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  ABSTRACT: This study has been carried out to investigate the photosynthetic activities in developing embryos of Sesbania sesban under a highly osmotic environment. In S. sesban, the embryo turns green/chlorophyllous at the early heart shape stage. Interestingly, despite being deeply embedded within the supporting tissues (several layers of pod wall, seed coat and endosperm) and developing in a highly osmotic environment, the growing embryo of the developing seed showed the presence of various components of photosynthetic machinery besides being chlorophyllous. The shade-adaptive nature of the photosynthetic machinery of the embryo is evident from (a) low chlorophyll a/b ratio, (b) photosystem (PS) II attaining maximal activity at low photon flux density and (c) lesser plastoquinone pool. The photosynthetic potential of the growing embryo seems to contribute towards seed filling as it has the potential not only to harvest light energy but also to fix CO2 as efficiently as other photosynthetic parts of S. sesban. In fact, ribulose-1,5 bisphosphate carboxylase purified from embryos manifested subunit composition similar to that of leaves. The PS II activity in leaves, cotyledonary leaves and pod wall declined sharply with increase in the level of NaCl and sucrose above 150 and 300 mmol, respectively. Amazingly, PS II activity in developing embryos was maximal in the presence of 250 mmol NaCl or 500 mmol sucrose and remained high even when NaCl and sucrose levels were increased to 500 and 1000 mmol, respectively. We hypothesize that the developing embryos have some factor(s) which protect(s) the photosynthetic machinery in an environment of high osmotic strength.
  Journal of Plant Physiology 11/2004; 161(10):1107-18. · 2.79 Impact Factor
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  Article: Hydrophytes lack potential to exhibit cadmium stress induced enhancement in lipid peroxidation and accumulation of proline.

  Bhupinder Dhir, P Sharmila, P Pardha Saradhi
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  ABSTRACT: Investigations were carried out to evaluate if hydrophytes (viz. Ceratophyllum, Wolffia, and Hydrilla) can be used as markers to assess the level of heavy metal pollution in aquatic bodies. The potential of these hydrophytes for lipid peroxidation and accumulation of proline in response to cadmium (Cd2+) pollution was studied. Hydrophytes were raised in artificial pond water (APW) supplemented with various levels of Cd2+. Interestingly, unlike mesophytes none of the hydrophytes showed ability to accumulate proline. Infact, in response to Cd2+ pollution hydrophytes exhibited a decline in proline levels in comparison to controls but mesophytes (viz. Brassica juncea, Vigna radiata and Triticum aestivum) showed progressive increase in the level of proline with increase in the extent of Cd2+ pollution. Mesophytes showed six to nine-fold increase in the level of proline in response to 1 mM Cd2+. The potential of the above hydrophytes for lipid peroxidation was also low under Cd2+ stress. In contrast, as expected a significant enhancement in the lipid peroxidation was observed in all three mesophytes in response to their exposure to Cd2+. About two-fold increase in production of malondialdehyde (a cytotoxic product of lipid peroxidation) was recorded in mesophytes exposed to 1 mM Cd2+. However, a decline in chlorophyll (Chl a and Chl b) levels was recorded in response to Cd2+pollution both in hydrophytes as well as mesophytes. In summary, hydrophytes neither have potential to accumulate proline nor have ability to accelerate lipid peroxidation under heavy metal stress. This suggests that the adaptive mechanism(s) existing in hydrophytes to tackle heavy metal stress is distinct from that in mesophytes.
  Aquatic Toxicology 03/2004; 66(2):141-7. · 3.76 Impact Factor
• Article: Sugars have potential to curtail oxygenase activity of Rubisco.

  P Sivakumar, P Sharmila, Vikas Jain, P Pardha Saradhi
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  ABSTRACT: Sugars play a critical role in regulating overall cellular metabolism and owing to their general compatibility with various cellular events plants invariably show enhanced levels of sugars for maintaining desired osmoticum under osmotic stress. Sugars (sucrose and trehalose) and sugar-alcohols (glycerol, mannitol, inositol, and sorbitol) with the exception of sorbitol lowered oxygenase activity of Rubisco (ribulose-1,5-bisphosphate carboxylase/oxygenase, EC 4.1.1.39) without altering carboxylase activity under unstressed conditions. Most interestingly, these solutes including sorbitol fully curtailed NaCl-induced enhancement in oxygenase activity, even at concentrations as low as 50mM. However, none of these solutes could alleviate NaCl-suppressed carboxylase activity. In summary, our findings demonstrate that one of the most important roles of sugars and sugar-alcohols in plants exposed to salt stress is to curtail oxygenase activity of Rubisco.
  Biochemical and Biophysical Research Communications 11/2002; 298(2):247-50. · 2.48 Impact Factor
• Article: Proline alleviates salt-stress-induced enhancement in ribulose-1, 5-bisphosphate oxygenase activity.

  P Sivakumar, P Sharmila, P Pardha Saradhi
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  ABSTRACT: Sodium chloride enhanced oxygenase activity while curtailing carboxylase activity of Rubisco (ribulose-1,5-bisphosphate carboxylase/oxygenase; EC 4.1.1.39) purified to electrophoretic homogeneity. Exposure to 200 mM NaCl brought about an increase in the potential of Rubisco to oxygenate RuBP by over 50%. On the other hand, proline suppressed both oxygenase as well as carboxylase activities of Rubisco. Interestingly, proline-induced suppression in oxygenase activity was significantly higher than that of carboxylase activity. Most amazingly, salt-stress-induced enhancement in oxygenase activity was fully alleviated by proline even when present at a concentration as low as 50 mM. The findings presented in this communication clearly demonstrate for the first time that stress-induced proline accumulation might have a critical role in lowering the loss in fixed carbon by curtailing salt-stress-promoted enhancement in oxygenase activity of Rubisco.
  Biochemical and Biophysical Research Communications 01/2001; 279(2):512-5. · 2.48 Impact Factor
• Article: Transformation of Brassica juncea (L.) Czern with bacterial codA gene enhances its tolerance to salt stress

  K.V.S.K. Prasad, P. Sharmila, P.A. Kumar, P. Pardha Saradhi
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  ABSTRACT: The codA gene for biosynthesis of glycinebetaine from Arthrobacter globiformis was used for transforming Brassica juncea cv. Pusa Jaikisan (which lack any means to synthesize glycinebetaine) through Agrobacterium mediated transformation. The stable insertion of the codA gene in the shoots obtained on medium with kanamycin and hygromycin was confirmed by PCR analysis of the nptII gene. Southern hybridization with a codA probe further demonstrated its successful integration. Immunoblot analysis revealed the presence of choline oxidase demonstrating that the bacterial codA gene had been successfully transcribed and translated. The seeds of transgenic lines showed enhanced capacity to germinate under salt stress as compared to that of the wild type. Further, the seedlings of transgenic plants that expressed codA gene showed significantly higher growth than that of the wild type under salt stress conditions. These results demonstrated that the introduction of a biosynthetic pathway for glycinebetaine into Brassica juncea significantly enhanced their salt tolerance. Hence, homozygous genotypes of selected transformed lines can be exploited for improving the salt tolerance of the desirable cultivars of Brassica juncea through breeding programmes.
  Molecular Breeding 01/2000; 6(5):489-499. · 2.85 Impact Factor
• Article: Vesicular arbuscular mycorrhizal fungi improves establishment of micropropagated Leucaena leucocephala plantlets

  Jos T. Puthur, K.V.S.K. Prasad, P. Sharmila, P. Pardha Saradhi
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  ABSTRACT: Investigations were carried out to achieve cent per cent transplantation success of micropropagated Leucaena leucocephala (a fast growing multipurpose leguminous tree species) plantlets using two vesicular arbuscular mycorrhizal fungi, Glomus fasciculatum and Glomus macrocarpum. Plantlets were obtained by rooting the shoots [obtained through; hypocotyl callus in presence of 10-5M BAP + 10-6M NAA; and axillary bud sprouting from cotyledonary and other nodes in presence of 10-5M BAP, on Gamborg's B5 medium], on half strength B5 medium supplemented with 5×10-6M IBA. Subsequent to the nodulation of their roots with Rhizobium (strain PRGL 001)in soilrite, these plantlets were tranferred to sterilized garden soil by laying inoculum of either Glomus fasciculatum or Glomus macrocarpum around their roots. Only 20% of the plantlets survived in soils lacking VAM fungus. In contrast, cent per cent of the plantlets of Leucaena leucocephala established very well and showed good growth in VAM inoculated soil. Roots of the later plantlets showed presence of both external and internal hyphae with well formed arbuscules and vesicles confirming the establishment of good mycorrhizal association. These studies convincingly demonstrate that the mycorrhizal association help in successful establishment of tissue culture raised plantlets of Leucaena leucocephala in the field conditions by alleviating the transplantation shock.
  Plant Cell Tissue and Organ Culture 04/1998; 53(1):41-47. · 3.09 Impact Factor
• Article: Glomus fasciculatum alleviates transplantation shock of micropropagated Sesbania sesban

  S. Subhan, P. Sharmila, P. Pardha Saradhi
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  ABSTRACT: Investigations were carried out using the vesicular arbuscular mycorrhizal fungus, Glomus fasciculatum, to improve the success in transplanting micropropagated plantlets of Sesbania sesban. Plantlets were developed from somatic embryos and/or adventitious buds (induced from various explants on Gamborg's medium supplemented with 6-benzylaminopurine), in the presence of 10–7 m α-naphthaleneacetic acid and 5×10–6 m gibberellic acid. Subsequent to nodulating the roots with Rhizobium, plantlets were transplanted into sterile garden soil and inoculated with or without G. fasciculatum. Only 30% of plantlets transferred to soil without G. fasciculatum survived. In contrast, all the plantlets inoculated with G. fasciculatum survived. Histochemical study revealed the presence of intracellular hyphae with well-developed arbuscules and intercellular hyphae with vesicles, suggesting that G. fasciculatum formed a good mycorrhizal association with S. sesban roots. These observations showed that mycorrhizal association helped to increase the potential of micropropagated plantlets to successfully withstand transplantation shock.
  Plant Cell Reports 01/1998; 17(4):268-272. · 2.27 Impact Factor
• Article: Targeting prokaryotic choline oxidase into chloroplasts enhance the potential of photosynthetic machinery of plants to withstand oxidative damage

  P. Sharmila, M.L.V. Phanindra, Firoz Anwar, Kavita Singh, Shipra Gupta, P. Pardha Saradhi
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  ABSTRACT: Chloroplasts from plants of transgenic lines expressing prokaryotic choline oxidase gene (the codAps gene; GenBank accession number-AY589052) and wild-type of chickpea and Indian mustard were evaluated for their efficacy to withstand photoinhibitory damage, by exposing them to high light intensity (∼1200 μmol m−2 s−1 photon flux density) at 10 and 25 °C. Western analysis confirmed presence of choline oxidase in chloroplasts of only transgenic lines. The loss in PS II activity in chloroplasts of wild-type exposed to high light intensity was significantly higher than that in chloroplasts of transgenic chickpea as well as Indian mustard. Although, chloroplasts of both wild-type and transgenic chickpea as well as Indian mustard were more sensitive to photoinhibitory damage at 10 than at 25 °C, the damage recorded in chloroplasts harboring choline oxidase was significantly lower than those of wild-type. High light promotes H2O2 production in chloroplasts more significantly at low temperature (10 °C) than at 25 °C. We compared low temperature accelerated photoinhibition of chloroplasts with that caused due to exogenously applied H2O2. Although exogenous H2O2 accelerated high light intensity induced loss in PS II activity of chloroplasts of wild-type, it caused only a little alteration in PS II activity of chloroplasts from transgenic lines of both chickpea and Indian mustard, demonstrating that the chloroplasts harboring choline oxidase are better equipped to resist photoinhibition. We hypothesize that H2O2 produced by choline oxidase as a byproduct during synthesis of glycinebetaine is responsible for building stronger antioxidant system in chloroplasts of transgenic lines compared to that of wild-type.
  Plant Physiology and Biochemistry.