SUMMARY
Salinity is an important factor of mangrove establishment, growth and development. Present study was conducted to evaluate the influence of salinity on seed germination of Heritiera fomes Buch.-Ham., Xylocarpus mekongensis Pierre, Xylocarpus granatum K.D. Koenig and Amoora cucullata Roxb from the Sundarbans, Bangladesh. This experiment was conducted with different salinity levels (0 to 40 ppt at 5 ppt interval) with Completely Randomized Design for 10 weeks. Moreover, influence of seed dipping at different salinity levels (0 to 40 ppt at 5 ppt interval) on germination was also examined in a Randomized Block Design. Significantly (p< 0.05) higher germination was observed at non saline to less saline (5 ppt) conditions for all the studied species. Seed germination of all the species was found to decrease at higher saline levels. About 57% and 21% of seeds of X. mekongensis and X. granatum were germinated respectively at 40 ppt salinity. While, germination of H. fomes and A. cucullata was ceased at salinity level of 35 ppt and 20 ppt respectively. The seeds of X. mekongensis found to viable even dipping for longer time with higher salinity level compared to other species. In the extreme situation, seed germination of H. fomes, X. mekongensis and X. granatum was ceased at 10 ppt salinity and no germination was observed for A. cucullatta after dipping of 4 weeks. In conclusion, seed germination and seed viability found to vary with the species, salinity and dipping duration.
Keywords: Amoora cucullata, Heritiera fomes, Salinity, Sundarbans, Xylocarpus granatum, Xylocarpus mekongensis
Mahmood HOSSAIN, Sanjoy SAHA, Serajis SALEKIN, Abdullah-AL-MAMUN, Mohammad Raqibul Hasan SIDDIQUE, S. M. Rubaiot ABDULLAH
UTICAJ SALINITETA NA KLIJANJE CETIRI ZNACAJNE VRSTE MANGROVE U SUNDARBANSU, BANGLADES
SAZETAK
Salinitet je vazan faktor u uspostavljanju, rastu i razvoju mangrove. Ovo ispitivanje je izvrseno sa ciljem da se procijeni uticaj saliniteta na klijanje sjemena Heritiera fomes Buch.-Ham., Xylocarpus mekongensis Pierre, Xylocarpus granatum K.D. Koenig i Amoora cucullata Roxb iz oblasti Sundarbans u Bangladesu. Ovaj ogled je postavljenj sa razlicitim nivoima saliniteta (0 do 40 ppt u intervalu od 5 ppt) po potpuno slucajnom sistemu tokom perioda od 10 sedmica. Uticaj potapanja sjemena na razlicitim nivoima saliniteta (0 do 40 ppt u intervalu od 5 ppt) na klijanje ispitivano je i na slucajnom blok sistemu. Znacajno (p < 0.05) vece klijanje zapazeno je pri neslanim i manje slanim uslovima (5 ppt) kod svih proucavanih vrsta. Klijavost sjemena svih vrsta opadala je pri visim nivoima saliniteta. Oko 57% sjemena X. mekongensis i 21% sjemena X. granatum klijalo je pri salinitetu od 40 ppt, dok je klijanje H. fomes i A. Cucullata prestalo pri nivou saliniteta od 35 ppt, odnosno 20 ppt. Sjeme X. mekongensis se odrzalo cak i nakon duzeg potapanja u visim nivoima saliniteta u odnosu na ostale vrste. U ekstremnim situacijama, klijanje sjemena H. fomes, X. mekongensis i X. granatum prestalo je pri salinitetu od 10 ppt, dok nikakvo klijanje nije zapazeno kod A. cucullatta nakon potapanja u trajanju od 4 sedmice. Zakljucak je da klijavost sjemena i odrzivost sjemena varira zavisno od vrste, saliniteta i duzine potapanja.
Kljucne rijeci: Amoora cucullata, Heritiera fomes, Salinitet, Sundarbans, Xylocarpus granatum, Xylocarpus mekongensis
INTRODUCTION
Mangroves are characterized by evergreen woody plant species with some physiological and structural adaptations to a habitat influenced by saline and tidal inundation in the tropical and subtropical sheltered coastline (Saenger et al., 1983; FAO, 1994; Field, 1995). They can tolerate saline and to some extent of waterlogged condition and play a vital role in supporting coastal food webs and nutrient cycles in the adjacent coastal ecosystems (Alongi, et al., 2000; Machiwa and Hallberg, 2002; Mumby et al., 2004; Mahmood et al., 2008). Mangroves distribution in the world and their floral diversity are believed to be influenced by temperature, rainfall, wind, tidal inundation, wave action, geomorphology, soil types, soil aeration, nutrients availability and salinity (Spalding et al., 1997).
Species composition and vegetation dynamics of the Sundarbans mangrove forest of Bangladesh are heterogeneous that seems to be controlled by hydrology, tidal inundation and salinity. The hydrodynamics of the Sundarbans is quite complex and it is dominated by the freshwater flows from the Ganga, Brahmaputra and Meghna rivers. The freshwater flows from the rivers and the tidal ingress result in a gradient of salinity that varies both spatially and temporally (Pethick, 2011). Heritiera fomes, Excoecaria agallocha, Xylocarpus mekongensis, X. granatum, Sonneratia apetala, Avicennia spp. are the dominant tree species of this forest (Hoque and Datta, 2005; Iftekhar and Saenger, 2008). Heritiera fomes and Amoora cucullata are found at the less saline areas while, Ceriops decandra, Avicennia spp., Sonneratia spp. Rhizophora spp., X. mekongensis, X. granatum and Bruguiera spp. are found at the moderate to high saline areas of the Sundarbans (Karim, 1994; Hoque et al., 2006; Giri et al., 2007). It is reported that H. fomes dominated areas are replaced by H. fomes -E. agallocha and H. fomes - X. mekongensis -B. gymnorrhiza community. The overall shiftis from H. fomes to E. agallocha and from E. agallocha to other more saline tolerant species (Das & Siddiqi 1985, Latif 2010).
This changes in species composition and vegetation pattern may be due to the changed scenario of salinity regime and tidal inundation (Mahmood et al. 1998, Hoque et al. 2006, Iftekhar & Saenger 2008). Salinity is one of the major parameters that influence the physiological parameters, productivity, growth, survival and regeneration of mangrove plants. Moreover, salinity is also a critical factor for the viability of mangrove seeds and propagules. Most of the mangrove species shed their fruits during the rainy season to increase the chances of survival at lower saline condition of the ecosystem (Bunt et al. 1982). The influence of salinity on seed germination, seedling growth and development of different species of the Sundarbans are not well known. On the contrary, global climate change, specifically changes in temperature, CO2 concentration, precipitation, intensive cyclonic storms and sea level rise, combined with anthropogenic threats will threaten the resilience of mangroves (McLeod & Salm 2000, Agrawala et al. 2003). It is reported that 25 cm increase in the sea level will inundate about 40 percent of the Sundarbans (World Bank 2000). So, sea level rise and lower flow of fresh water from upstream will lead to increase the salinity of the Sundarbans areas (Hoque et al. 2006). This combined effect may exert negative impact on seed germination, seed viability of different important species, which can be appeared as a threat on biodiversity of this pristine ecosystem (Gopal & Chouhan 2006) The knowledge on species specific range of salt tolerance will help to understand the changing pattern of vegetation dynamics of the Sundarbans. Different studies of salinity effect on germination were conducted at different mangroves areas of the world e.g. Aegiceras corniculatum, A. marina from Hong Kong (Ye et al. 2005); A. schaueriana and Laguncularia racemosa from Southeast Brazil (Cavalcanti et al. 2007); Ceriops tagal from India (Patel et al. 2010); C. roxburghina from India (Elumalai & Manikandan 2013). But, there are no studies on seed germination and seed viability of the important tree species like H. fomes, X. mekongensis, X. granatum and A. cucullata of the Sundarbans and somewhere else. Therefore, present study aims to examine the effect of salinity on seed germination and seed viability of H. fomes, X. mekongensis, X. granatum and A. cucullata of the Sundarbans, Bangladesh.
MATERIAL AND METHODS
Seed collection
The mature seeds of H. fomes, X. mekongensis, and A. cucullata were collected during the month of July 2011 and seeds of X. granatum were collected during the month of March 2012 from the Sundarbans mangrove forest of Bangladesh. The mature seeds of these species are buoyant and dispersed through water of cannels and rivers. Nets of 2 mm mesh were used to catch the floating seeds on the water course. Healthy seeds were sorted manually considering the visual appearance.
Seed germination
The effect of salinity on the germination of H. fomes, X. mekongensis, X. granatum and A. cucullata was studied under different saline conditions. In sea water and thus in mangrove environment NaCl represents the highest proportion of salts and others are present only in trace amount. In this study salt means NaCl and hydroponic method was followed for this germination study at the nursery of Forestry and Wood Technology Discipline, Khulna University. Nine treatments of salinity from 0 to 40 ppt at 5 ppt interval were applied in Completely Randomized Design. Each treatment was replicated three times with 30 seeds. Seeds were sown in plastic bowl with coarse sand layer of 2.5 cm. Salt solution of respective treatment was addes to the bowl in such way that a thin layer of solution can be seen on the layer of coarse sand. Frequently the solution layer and their salinity level were cheeked and maintained. Total number of germinated seeds were counted and recorded on daily basis for 10 weeks.
Seed viability
The effect of dipping of seeds in saline conditions was also tested. The collected seeds of individual species were dipped in nine treatments of salinity from 0 to 40 ppt at 5 ppt interval for 1 to 4 weeks with Randomized Block Design. Each treatment was replicated three times. Thirty seeds of individual species from each treatment were collected weekly for 4 weeks and sown in plastic bowl with 2.5 cm thick layer of coarse sand at non saline condition. Total number of germinated seeds were counted and recorded on daily basis for 10 weeks.
Statistical analysis
The germination percentages of seeds of the individual species at different salinity were calculated and transform to arcsine for statistical analysis. The seed germination of different species at different salinity treatments were compared by two-way analysis of variance followed by Duncan Multiple Range Test. Similarly, seed germination of different species at different dipping duration along with the salinity treatments were calculated and transform to arcsine. These germination values were compared by two-way analysis of variance followed by Duncan Multiple Range Test using SAS statistical software.
RESULTS AND DISCUSSION
Different levels of salinity showed significant (p<0.05) influence on seed germination and the germination values found to vary among the species (Table 1 and 2). Significantly (p<0.05) higher germination was observed at non saline to less saline (5 ppt) conditions for all the studied species. Among the species, A. cucullatta showed highest germination (85%) followed by X. mekongensis at non saline condition. The germination of the studied species was found to decrease at higher saline conditions. Xylocarpus mekongensis and X. granatum appeared as more salt tolerant at the germination stage. About 57% and 21% of germination was observed for X. mekongensis and X. granatum respectively at highest salinity of 40 ppt. While, A. cucullata and H. fomes appeared as less salt tolerant and their germination was ceased at salinity of 20 ppt and 35 ppt respectively (Fig. 1).
Salinity treatments along with dipping duration have shown significant (p<0.05) influence on seed germination of the studied species (Table 1 and 2). Comparatively (p<0.05) higher proportion of seed viability was observed for X. mekongensis compared to other species.
However, after 1 week of dipping, about 51% seeds of X. mekongensis were germinated at 40 ppt salinity. While, germination of H. fomes, X. granatum and A. cucullata was ceased at 25 ppt, 35 ppt and 15 ppt respectively. Similarly, seed germination of H. fomes, X. mekongensis and X. granatum found to cease at salinity of 10 ppt and no germination was observed for A. cucullatta after 4 weeks of dipping period (Fig. 2).
DISCUSSION
The germination and seed viability of the studied species were significantly (p<0.05) varied with species, salinity level and dipping duration (Table 1 and 2). Seed germination is a critical stage of plant's life cycle and salinity can adversely delay and can reduce the germination (Villagra 1997). Mangrove plants are well adapted to salinity for their germination, establishment, growth and development (Tomlinson 1986). But, they are also sensitive to higher salinity during the process of seed germination (Ungar 1996, Khan & Abdullah 2003, Debez et al. 2004). Seed viability and germination of mangrove species may depend on the critical level of salinity which is species and site specific (Yokoishi & Tanimoto 1994, Rubio Casal et al. 2003, Ye et al. 2005, Liu et al. 2006, Cavalcanti et al. 2007). Heritiera fomes and A. cucullata found to occur at the less saline areas and; X. mekongensis and X. granatum found to dominate at the moderate to high saline areas of the Sundarbans (Karim 1988, Siddiqi 2001). The dominance characteristics of a mangrove species at a particular site may be related to its salt tolerance at germination stage (Harradine 1982). Lower germination and less viability of H. fomes and A. cucullata seeds were observed at higher salinity levels compared to other species. This lower germination of H. fomes and A. cucullata at higher salinity (>15 ppt) may be due to the adverse effect of salinity (NaCl). Similar observation and opinion were also reported by Rehman et al. (1997) with different species of Acacia. Increased salinity reduces the germination of both mangrove and glycophyte seeds (Ungar 1982) through slowed down the water uptake by seeds, thereby inhabited their germination and root elongation (Werner & Finkelstein 1995, Begum et al. 2013). Salinity stress affects the seed germination (Sairam & Tyagi 2004) and this adverse effect may be attributed to ionic toxicity and decline in osmotic pressure under the saline condition (Greenway & Munns 1980, Levitt 1980). Internal osmotic and water potential generally increasingly negative with increases in salinity (Khan et al. 1998). Long time dipping in saline condition reduces the seed viability of the studied species may be attributed to negative osmotic potential at higher saline conditions and the toxic effect of NaCl (Bradford 1995, Katembe et al. 1998).
CONCLUSIONS
The result of this study allowed us to conclude that difference in germination and seed viability are species specific. The salt tolerance of the studied species in terms of germination showed a decreasing trend of X. mekongensis > X. granatum > H. fomes > A. cucullata. Therefore, with the increased salinity, less salt tolerant mangrove species of the Sundarbans may be eliminated by the more salt tolerant species and result in change in species composition and loss of biodiversity.
ACKNOWLEDGEMENTS
We are thankful to United States Department of Agriculture (USDA) for their financial support; Ministry of Education and University Grants Commission, Bangladesh for their monitoring and smoothing the project activities. We also acknowledge the Sundarbans East Forest Division, and Forestry and Wood Technology Discipline, Khulna University for the logistic support.
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Mahmood HOSSAIN, Sanjoy SAHA, Serajis SALEKIN, Abdullah-AL-MAMUN, Mohammad Raqibul Hasan SIDDIQUE, S. M. Rubaiot ABDULLAH
1 Mahmood Hossain, (corresponding author: [email protected]), Forestry and Wood Technology Discipline,Khulna University, Khulna - 9208, Bangladesh, Sanjoy Saha, Centre for Integrated Studies on the Sundarbans, Khulna University, Khulna - 9208, Bangladesh, Serajis Salekin, Abdullah-Al-Mamun, Mohammad Raqibul Hasan Siddique, S. M. Rubaiot Abdullah, Forestry and Wood Technology Discipline,Khulna University, Khulna -9208, Bangladesh
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Copyright University of Montenegro, Biotechnical Faculty 2014
Abstract
Salinity is an important factor of mangrove establishment, growth and development. This paper was conducted to evaluate the influence of salinity on seed germination of Heritiera fomes Buch.-Ham., Xylocarpus mekongensis Pierre, Xylocarpus granatum K.D. Koenig and Amoora cucullata Roxb from the Sundarbans, Bangladesh. This experiment was conducted with different salinity levels (0 to 40 ppt at 5 ppt interval) with Completely Randomized Design for 10 weeks. Significantly higher germination was observed at non saline to less saline (5 ppt) conditions for all the studied species. Seed germination of all the species was found to decrease at higher saline levels. About 57% and 21% of seeds of X. mekongensis and X. granatum were germinated respectively at 40 ppt salinity. While, germination of H. fomes and A. cucullata was ceased at salinity level of 35 ppt and 20 ppt, respectively. The seeds of X. mekongensis found to viable even dipping for longer time with higher salinity level compared to other species.
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