European Journal of Experimental Biology Open Access

Keywords

Synchronized correlation, rotifer, water parameters, Dynaneshwar dam

Introduction

Rotifers are economically and ecologically important group, they occupy a wide range of habitats existing in aquatic ecosystem [2,4,8]. They comprising integral link in aquatic food-webs, and contributing significantly to secondary productivity. These organisms have been studied in Indian freshwater habitats by various workers but yet there is limited information [14-16]. Recently it has shown that diversity & abundance of rotifer are sensitive to change in water variables [10,12,15]. In addition the influences of biotic on abiotic parameters are correlated in order to understand ecological relationship.

Several workers have studied diversity, density, variations, seasonality, correlation, indices, etc. in the rotifer community. But biotic and abiotic correlations are lacking. Correlation can provide a better insight for understanding adaptation & tolerance of organisms in aquatic ecosystem. However, the present study was assigned to evaluate individual and synchronize correlation of water, rotifer species and both from the Dynaneshwar dam water.

Materials and Methods

Study area: Dynaneshwar dam was a study area, a 26 TMC man made located at Rahuri, Ahmednagar District MS [19020’-35’ N latitude and 74025’-36’ E longitude]. It was built across the Mula River in 1971 and capacity being 840847 m³. It experiences an average rain fall 58 cm. The bottom is composed of detritus-mud layer in the littoral zone. The basin is semi-agricultural and semi-arid with cultivated top soil bank.

Collection & identification: The rotifers were collected from ten selected sites bimonthly early in the morning [7 to 9 am] during 2008-09. The samples were collected by filtering 50 liter of water through planktonic net (75μ) and concentrated in 5% formalin. The specimens were sorted and identified with the help of standard literature [5]. The enumeration of rotifer was done by drop method and analysis was carried out using Sedgwick-Rafter counting cell.

Physico-chemical analysis: The pH and temperature of water samples were recorded on the spot. The analysis of filtered water samples was carried out for the parameters, as Electrical Conductivity (EC), Total Dissolved Solids (TDS), Total Hardness (TH), Calcium (Ca), Magnesium (Mg), Sodium (Na), Potassium (K), Chloride (Cl), Total Alkalinity (TA), Sulphates (SO₄), Phosphate (PO₄), Nitrate (NO₃), Dissolved Oxygen (DO), Biological Oxygen Demand (BOD) and Chemical Oxygen Demand (COD. The samples were done according to standard methods [3].

Statistical analysis: The correlation analysis was performed using WindowTM/Excel/2007. The correlation of rotifer [Table 1], water [Table 2] and rotifer-water [Table 3] were presented.

Table 1. Correlation between rotifer species

Table 2. Correlation between water characteristics

Table 3. Synchronic correlation between water-rotifer species

Results and Discussion

The correlation is a relationship between two variables which can provide a better insight for understanding of adaptation and tolerance of organisms. In the study individual and synchronic correlation of water, rotifer and both were noticed. A total of twenty one individuals representing two orders as Ploimida and Gnesiotricha collected from sampling sites. Of these Ploimida was representing fourteen species from nine families & Gnesiotricha represent seven species belonging to four families.

The correlation noticed in between rotifer were 53.8% positive unions and 46.2% negative in which eighteen pairs were high related and three pairs were high negative. The pairs in between B. calyciflorus with T. longiseta, C. dossuarius and M. quadricornifera revealed r=0.70, 0.83 and 0.61 correlations respectively. The relation between species of K. tropica with S. spinosa and K. tropica with T. patina were r=0.60 and 0.61 respectively. The species L. pyriformis revealed correlation with P. dicipiens [r=0.70], L. flosculosa [=0.71], S. spinosa [r=0.74] and M. quadricornifera [=0.60]. The rotifer pair L. verecunda with R. rotatoria revealed r=0.60 correlations. The species P. dicipiens revealed r= 0.65 correlation with L. flosculosa and r=0.68 with S. spinosa. The genus S. longicaudatum showed negative relation with L. ceratophylli as r=-0.62. T. longiseta noticed positive correlation with C. dossuarius and M. quadricornifera as r= 0.63 and r=0.93 respectively, also A. brightwell with R. ratatoria was noticed r=0.82.

The correlation coefficient ‘r’ for various physico-chemical parameters of water is given in Table 2. Water parameter correlations were revealed 44.7% positive and 55.3% negative unions in which five pairs was high related [r=0.6]. Table 2 revealed that the high positive correlation was observed in between the pairs of pH-PO₄, ECSO₄, TH-DO, and TH-BOD and high negative between the pairs of pH-PO₄ and TH-BOD. It showed that pH bears negative relation with PO₄ [r=-0.66]. It indicates that the resulting pH of the water sample depends upon phosphate and TH on BOD. The analysis is very useful in the rapid study of water quality.

Regarding the correlation of water parameters more contribution was paid [19]. They reported highly positive correlation between EC-TDS, EC-Cl, EC-Mg TH-Mg TDS-Cl TDS-MG and Cl-Mg from Coimbatore. A high correlated parameters between EC-TDS, TDS-HCO, Mg-Cl and HCO-RSC from Sonai, Ahmednagar district [6] and also noticed high correlation between the parameters TA-TH, Cl-SO4 and Mg-Cl from Pravara area Ahmednagar district Maharashtra [7]. Shah [13] reported thirty five unions [64%] positive and twenty unions [36%] negative related from the fifteen rail stations in between Ahmedabad to Khedbrahma route. Patel [11] noticed positive correlation between forty two unions and rest was negative related from water of Surat district. So, it reveals that the correlation studies of the water quality parameters have a great significance in the study of water sources. The relation between water parameters varies water to water, season, location, time, agriculture, soil and rock conditions. In between water-rotifer synchronic correlation was noticed 52.4% and 47.8% positive and negative unions in which twelve pairs were positive and three pairs were negative relations. The species B. calyciflorus represented positive relationship in between calcium, chloride and sulphates as r=0.71, 0.65 and 0.67 respectively. A species L. pyriformis noticed positive correlation with total dissolve solids & phosphates such as r=0.78 and 0.60 respectively while negative correlation with pH and chromium as r=-0.61 and r=-0.63 respectively. A rotifer species L. verecunda reported negative [r=-0.63] with total dissolved solids. A species T. decipiens depicted positive relation with electric conductivity & total alkalinity as r=0.66 and 0.76 respectively. The unions of G. hyptopus with total dissolve solids, L. flosculosa with calcium, S. spinosa with total dissolved solids, C. dossuarius with calcium and R. ratatoria with cadmium noticed r=0.62, 0.74, 0.61, 0.74 and 0.66 respectively.

Sharma [16] reported Lacanida family was negatively correlated with magnesium and beside this family was correlated positively with specific conductivity, transparency, alkalinity, hardness, chloride, nitrate and dissolved organic matter. An earlier [9,17] were noticed correlation in Asplanchnidae and Brachionidae family which gave negative correlation with water temperature and positive with transparency, specific conductivity, alkalinity, total hardness, and chloride, also cumulative effects of ten abiotic factors.

To sum up, the individual and synchronic correlation from the aforesaid result, it could be made out that the availability of species, water parameters and food sources for rotifer in reservoir is important for the occurrence, abundance, tolerance and adaptations. Water chemistry is the important for the influences and distribution for specimens. The proper and regular study would further useful for the maintenance of population. The result is useful for the conservation of the organisms and water habitats.

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