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Imchen, Temjensangba
- Exposure of Eichhornia crassipes (Mart.) Solms to Salt Water and its Implications
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1 CSIR-National Institute of Oceanography, Dona Paula, Goa 403 004, IN
1 CSIR-National Institute of Oceanography, Dona Paula, Goa 403 004, IN
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Current Science, Vol 113, No 03 (2017), Pagination: 439-443Abstract
In this article, we discuss the effect of salinity on the viability and decomposition of Eichhornia crassipes plant under normal photoperiod, dark condition and physiological response. Highest concentration of total organic carbon (27.43 mg C l-1) was recorded in 15 psu salinity after 45 days. The TOC output was more in case of leaf (3.6 mg C l-1) than petiole (2.39 mg C l-1) under dark condition, after 21 days in freshwater. Salt stress was found to enhance the superoxide dismutase activity at 20 psu in both leaf and petiole. Enzyme activity declined when salt-stressed plants were transferred to nutrient enriched freshwater. This indicated that 20 psu could be a plant's salt tolerance limit. The potential transfer test conducted in this study showed that Eichorrnia introduction through shipping activities is less likely.Keywords
Eichhornia crassipes, Salinity Stress, Superoxide Dismutase, Total Organic Carbon.References
- Gopal, B., Water Hyacinth, Elsevier, Amsterdam, 1987, p. 471.
- Mehra, A., Farago, M. E. and Banerjee, D. K., The water hyacinth: an environmental friend or pest? A review. Resour. Environ. Biotechnol., 1999, 2, 255–281.
- Tag El Seed, M., Water hyacinth – The successful weed. In Aquatic Weeds in the Sudan (ed. Obeid, M.), University of Khartoum, Sudan, 1975, pp. 50–68.
- Reddy, K. R. and DeBusk, W. F., Decomposition of water hyacinth detritus in eutrophic lake water. Hydrobiologia, 1991, 211, 101–109.
- deBusk, T. A. and Dierberg, F. E., The effect of nitrogen and fibre content on the decomposition of the water hyacinth [Eichhornia crassipes (Mart.) Solms]. Hydrobiologia, 1984, 118, 199–204.
- Ogwada, R. A., Reddy, K. R. and Graets, D. A., Effects of aeration and temperature on nutrient regeneration from selected aquatic macrophytes. J. Environ. Qual., 1984, 13, 239–243.
- Sangiorgio, F. et al., Ecosystem processes: litter breakdown patterns in mediterranean and Black Sea transitional waters. Transit. Water Bull., 2007, 3, 51–55.
- Sangiorgio, F. et al., Environmental factors affecting Phragmites australis litter decomposition in Mediterranean and Black Sea transitional waters. Aquat. Conserv.: Mar. Freshwater Ecosyst., 2008, 18, S16–S26.
- Hunt, H. W., Ingham, E. R., Coleman, D. C., Elliott, E. T. and Reid, C. P. P., Nitrogen limitation of production and decomposition in prairies, mountain meadow, and pine forest. Ecology, 1988, 69, 1009–1016.
- McClaugherty, C. A., Aber, J. D. and Melillo, J. M., Forest litter decomposition in relation to soil nitrogen dynamics and litter quality. Ecology, 1984, 66, 266–275.
- Barik, S. K., Mishra, S. and Ayyappan, S., Decomposition patterns of unprocessed and processed lignocellulosic in a freshwater fish pond. Aquat. Ecol., 2000, 34, 185–204.
- Gaur, S., Singhal, P. K. and Hasija, S. K., Process of decomposition in Eichhornia crassipes(Mart.) Solms: 1. Early decomposition in different plant parts and effect of site variation. J. Environ. Biol., 1989, 10, 23–33.
- Singhal, P. K., Varghese, L. and Galegaonkar, L., Abiotic and microbial decomposition of pre- and post-bloom leaves of water hyacinth (Eichhornia crassipes (Mart.) Solms). Hydrobiologia, 1993, 259, 115–119.
- Bayo, M. M., Casa, J. J. and Cruz-Pizarro, Decomposition of submerged Phragmites australis leaf litter in two highly eutrophic Mediterranean coastal lagoons: relative contribution of microbial respiration and macroinvertebrate feeding. Arch. Hydrobiol., 2005, 163, 349–367.
- Mendelssohn, I. A., Sorrell, B. K., Brix, H., Schierup, H., Lorenzen, B. and Maltby, E., Controls on soil cellulose decomposition along a salinity gradient in a Phragmites australis wetland in Denmark. Aquat. Bot., 1999, 64, 381–398.
- Fonnesu, A., Pinna, M. and Basset, A., Spatial and temporal variations of detritus breakdown rates in the River Flumendosa basin (Sardinia, Italy). Int. Rev. Hydrobiol., 2004, 89, 443–452.
- Polunin, N. V. C., The decomposition of emergent macrophyte in freshwater. Adv. Environ. Res., 1984, 14, 115–166.
- Cunha-Santino, M. B., Bianchini Jr, I. and Okawa, M. H., The fate of Eichhornia azurea (Sw.) Kunth. detritus within a tropical reservoir. Acta Limnol. Bras., 2010, 22, 109–121; doi:10.4322/actalb.02202001.
- Godshalk, G. L. and Wetzel, R. G., Decomposition of aquatic angiosperms. II. Particulate components. Aquat. Bot., 1978, 5, 301–327.
- Reice, S. R. and Herbst, G., The role of salinity in decomposition of leaves of Phragmites australis in desert streams. J. Arid. Environ., 1982, 5, 361–368.
- Eisa, S., Hussin, S., Geissler, N., and Koyro, H. W., Effect of NaCl salinity on water relations, photosynthesis and chemical composition of quinoa (Chenopodium quinoa Willd.) as a potential cash crop halophyte. Aust. J. Crop Sci., 2012, 6, 357–368.
- Zagorchev, L., Kamenova, P. and Odjakova, M., The role of plant cell wall proteins in response to salt stress. Sci. World J., 2014; article ID 764089, 9 pages; http://dx.doi.org/10.1155/2014/764089.
- Wang, J. et al., Physiological and proteomic analyses of salt stress response in the halophyte Halogeton glomeratus. Plant Cell Environ., 2015, 38, 655–669.
- Fridovich, I., Superoxide dismutases. Adv. Enzymol. Relat. Areas Mol. Biol., 1986, 58, 61–79.
- Raychaudhuri, S. S. and Deng, X. W., The role of superoxide dismutase in combating oxidative stress in higher plants. Bot. Rev., 2000, 66, 89–98.
- DeCasabianca, M. and Laugier, T., Eichhornia crassipes Production on petroliferous wastewaters: effects of salinity. Bioresour. Technol., 1995, 54, 39–43.
- Bax, N., Williamsona, A., Aguero, M., Gonzalez, E. and Geeves, W., Marine invasive alien species: a threat to global biodiversity. Mar. Pollut., 2003, 23, 313–323.
- Vinita, J., Shivaprasad, A., Revichandran, C., Manoj, N. T., Muraleedharan, K. R. and Binzy, J., Salinity response to seasonal runoff in a complex estuarine system (Cochin Estuary, west coast of India). J. Coastal Res., 2015; doi:10.2112/JCOASTRES-D-13-00038.
- Kaladharan, P., Krishnakumar, P. K., Prema, D., Nandakumar, A., Khambadkar, L. R. and Valsala, K. K., Assimilative capacity of Cochin inshore waters with reference to contaminants received from the backwaters and the upstream areas. Indian J. Fish., 2011, 58(2), 75–83.
- Jayachandran, P. R., Nandan, S. B. and Sreedevi, O. K., Water quality variation and nutrient characteristics of Kodungallur–Azhikode estuary, Kerala, India. Indian J. Geo-Mar. Sci., 2012, 41(2), 180–187.
- Temporal Effect on the Abundance and Diversity of Intertidal Rocky Shore Macroalgae
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Authors
Affiliations
1 CSIR-National Institute of Oceanography, Dona Paula, Goa 403 004, IN
1 CSIR-National Institute of Oceanography, Dona Paula, Goa 403 004, IN
Source
Current Science, Vol 113, No 08 (2017), Pagination: 1593-1596Abstract
A study of the temporal effect on the abundance and diversity of intertidal rocky shore macroalgae revealed that there are ~70 species in the intertidal rocky shore of Anjuna (60 species) and Vagator (52 species) in Goa, India. Results showed that premonsoon (May) and post-monsoon (December) seasons favoured high species richness and abundance in both the study sites. In both cases, species diversity was low during the monsoon months (July and August). The study showed that low diversity might be a monsoonal effect and it coincides with the growth of Ulva and Porphyra species. The growth of opportunistic annuals brings about an ephemeral dominance of the macroalgal community by annual macroalgae. The driver is believed to be the nutrient influx from surface run-off, change in salinity and temperature due to high precipitation. The study showed that monsoon could have a role on the macroalgal community dynamics, and there was a strong correlation between diversity and biomass.Keywords
Biomass, Monsoon, Microalgal Abundance and Diversity, Nutrient Run-Off.References
- Worm, B. et al., Impacts of biodiversity loss on ocean ecosystem services. Science, 2006, 314, 787–790.
- Konar, B. et al., Current patterns of macroalgal diversity and biomass in Northern Hemisphere rocky shores. PLoS ONE, 2010, 5, e13195; doi:10.1371/journal.pone.0013195.
- Scrosati, R. and Heaven, C., Spatial trends in community richness, diversity, and evenness across rocky intertidal environmental stress gradients in eastern Canada. Mar. Ecol. Prog. Ser., 2007, 342, 1–14.
- Sangil, C., Sanson, M., Sabrina, C., Afonso-Carrillo, J. and Hernandez, J. C., Contrasting the species abundance, species density and diversity of seaweed assemblages in alternative states: urchin density as driver of biotic homogenization. J. Sea Res., 2013, 85, 92–103.
- Pinnegar, J. K. et al., Trophic cascades in benthic marine ecosystems: lessons for fisheries and protected-area management. Environ. Conserv., 2000, 27, 179–200.
- McCook, L. J., Macroalgae, nutrients and phase shifts on coral reefs: scientific issues and management consequences for the Great Barrier Reef. Coral Reefs, 1999, 18, 357–367.
- Thomsen, M. S. et al., A meta-analysis of seaweed impacts on seagrasses: generalities and knowledge gaps. PLoS ONE, 2012, 7, e28595; http:/dx.doi.org/10.1371/journal.pone.0028595.
- Díaz, R. J. and Rosenberg, R., Spreading dead zones and consequences for marine ecosystems. Science, 2008, 321, 926–929.
- Clemente, S., Hernández, J. C., Rodríguez, A. and Brito, A., Identifying keystone predators and importance of preserving functional diversity in sublittoral rocky bottom areas. Mar. Ecol. Prog. Ser., 2010, 413, 55–67.
- Mineur, F. et al., European seaweeds under pressure: consequences for communities and ecosystem functioning. J. Sea Res., 2014; http://dx.doi.org/10.1016/j.seares.2014.11.004.
- Huston, M. A., A general hypothesis of species diversity. Am. Nat., 1979, 113, 81–101.
- Jones, C. G., Lawton, J. H. and Shachak, M., Organisms as ecosystem engineers. Oikos, 1994, 69, 373–386.
- Dayton, P. K., Experimental evaluation of ecological dominance in a rocky intertidal algal community. Ecol. Monogr., 1975, 45, 137–159.
- Pergent, G. et al., Climate change and Mediterranean seagrass meadows: a synopsis for environmental managers. Mediterr. Mar. Sci., 2014, 15, 462–473.
- Graham, M. H., Effects of local deforestation on the diversity and structure of Southern California giant kelp forest food webs. Ecosystems, 2004, 7, 341–357.
- Tribollet, A. D. and Vroom. P. S., Temporal and spatial comparison of the relative abundance of macroalgae across the Mariana Archipelago between 2003 and 2005. Phycologia, 2007, 461, 87– 197.
- Gamfeldt, L. and Bracken, M. E. S., The role of biodiversity for the functioning of rocky reef communities. Marine Hard Bottom Communities, Ecol. Studies (ed. Wahl, M.), Springer-Verlag, Berlin, 2009, vol. 206, pp. 361–373; doi:10.1007/978-3-540-927044_26.
- Dhargalkar, V. K., Marine Biodiversity: A Comprehensive Catalogue of Seaweeds of the Central West Coast of India, National Institute of Oceanography, Dona Paula, Goa, 2008, pp. 1–152.
- Jha. B., Reddy, C. R. K., Thakur, M. C. and Rao, M. U., Seaweeds of India: The Diversity and Distribution of Seaweeds of Gujarat Coast, Springer, Dordrecht, The Netherlands, 2009, pp. 1–215.
- Krishnamurthy, V., Key to the taxonomic identification of green and brown algae of India. In Recent Advances on Applied Aspects of Indian Marine Algae (ed. Tewari, A.), 2006, pp. 1–45.
- Rao, M. U., Key to the identification of Indian red seaweeds. In Recent Advances on Applied Aspects of Indian Marine Algae (ed. Tewari, A.), CSMRI, Bhavnagar, 2006, pp. 46–140.
- Mathieson, A .C. and Penniman, C. A., A phytogeographic interpretation of the marine flora from the Isles of Shoals, USA. Bot. Mar., 1986, 29, 413–434.
- Pereira, N. and Almeida, M. R., A preliminary checklist of marine algae from the coast of Goa. Indian J. Geo-Mar. Sci., 2012, 43, 655–665.
- Mayakun, J. and Prathep, A., Seasonal variations in diversity and abundance of macroalgae at Samui Island, Surat Thani Province, Thailand. Songklanakarin J. Sci. Technol., 2005, 27, 653–663.
- Thakur, M. C., Reddy, C. R. K. and Jha, B., Seasonal variation in biomass and species composition of seaweeds stranded along Okha, northwest coast of India. J. Earth Syst. Sci., 2008, 117, 211–218.
- Jayachandran, P. R., Nandan, S. B. and Sreedevi, O. K., Water quality variation and nutrient characteristics of Kodungallur– Azhikode estuary, Kerala, India. Indian J. Geo-Mar. Sci., 2012, 41, 180–187.
- Anand, S. S., Sardessai, S., Muthukumar, C., Mangalaa, K. R., Sundar, D., Parab, S. G. and Kumar, M. D., Intra- and interseasonal variability of nutrients in a tropical monsoonal estuary (Zuari, India). Cont. Shelf Res., 2014, 82, 9–30.
- Poole, L. J. J. and Raven, A., The biology of Enteromorpha. Prog. Phycol. Res., 1997, 12, 1–148.
- Dhargalkar, V. K., Agadi, V. V. and Untawale, A. G., Occurrence of Porphyra vietnamensis (Bangiales, Rhodophyta) along the Goa coast. Mahasagar – Bull. Natl. Inst. Oceanogr., 1981, 14, 75–77.
- Taylor, R., Fletcher, R. L. and Raven, J. A., Preliminary studies on the growth of selected ‘green tide’ algae in laboratory culture: effects of irradiance, temperature, salinity and nutrients on growth rate. Bot. Mar., 2001, 44, 327–336.
- Kamermans, P., Malta, E., Verschuure, J. M., Lentz, L. F. and Schrijvers, L., Role of cold resistance and burial for winter survival and spring initiation of an Ulva sp. (Chlorophyta) bloom in a eutrophic lagoon (Veerse Meer lagoon, The Netherlands). Mar. Biol., 1998, 131, 45–51
- Santilices, B., Aedo, D. and Hoffmann, A., Bank of microscopic forms and survival of propagules and microscopic stages of macroalgae. Rev. Chil. Hist. Nat., 2002, 75, 547–555.
- Imchen, T., Recruitment potential of a green alga Ulva flexuosa Wolfen dark preserved zoospore and its development. PLoS ONE, 2012, 7, e32651, p. 5; doi.org/10.1371/journal.pone.0032651.
- Schories, D., Sporulation of Enteromorpha sp. (Chlorophyta) and overwintering of spores in sediments of the Wadden Sea, island Sylt, North Sea. J Aquat. Ecol., 1995, 29, 341–347.
- Filbee-Dexter, K. and Scheibling, R. E., Sea urchin barrens as alternative stable states of collapsed kelp ecosystems. Mar. Ecol. Prog. Ser., 2014, 495, 1–25.
- Petsut, N., Chirapart, A. and Keawnern, M., A stability assessment on seasonal variation of seaweed beds in the Trat peninsula of Thailand. Biodivers. J., 2012, 3, 229–236.
- Engelhardt, K. A. M. and Ritchie, M. E., Effects of macrophyte species richness on wetland ecosystem functioning and services. Nature, 2001, 411, 687–689.
- Emmerson, M. and Huxham, M., How can marine ecology contribute to the biodiversity–ecosystem functioning debate? In Biodiversity and Ecosystem Functioning: Synthesis and Perspectives (eds Loreau, M., Inchausti, P. and Naeem, S.), Oxford University Press, Oxford, UK, 2002, pp. 139–146.
- Krishnamurthy, V., Seaweed drift on the Indian coast. Proceedings of the Symposium ‘Indian Ocean’. Bull. Natl. Inst. Sci. India, 1967, 38, 657–666.
- Troumbis, A. Y. and Memtsas, D., Observational evidence that diversity may increase productivity in Mediterranean shrublands. Oecologia, 2000, 125, 101–108.