The IV instar larvae of A. sulcatus (Order: Coleoptera) were collected from shallow ponds and rice fields and Larvae of Cx. quinquefasciatus from drains of Burdwan, West Bengal, India and colony was maintained in the Mosquito Research Unit of the Department of Zoology, Burdwan University. Average length of A. sulcatus larvae taken for study was 1.7 cm (± 0.12 SE; n = 10). One and five A. sulcatus were provided with 200 and 1000 newly emerged IV instar Cx. quinquefasciatus larvae as prey for a period of 24 hr in glass jars (20 cm × 15 cm × 25 cm ; 5 L capacity) containing 1 L and 5 L of pond water respectively. The pond water of the habitat of A. sulcatus, was used in the experiments after sieving through a net (>500 mesh) to exclude any larvae of other predator species. The water temperature ranged from 23.8 to 27°C, pH from 6.67 to 6.84 and dissolved oxygen from 5.33 to 6.23 mg/l, during the experiment. Abrupt changes in the quality of holding water during rearing and experimentation were avoided. The predation experiment was conducted three times on three separate days, each with three replications. A control experiment was done every time. The number of Cx. quinquefasciatus larvae consumed by A. sulcatus larva during lights-on (0600 – 1800 h, IST-Indian Standard Time) and lights-off phase (1800 – 0600 h, IST) was noted through one day at an interval of 3 hrs. After counting the number of consumed larvae, after every 3 hr, the same numbers of larvae were replenished within the glass jars to maintain the same prey density. The experiment was commenced at 6 a.m. of a day and those were completed at 6 a.m. of the next day to observe the daily feeding rate. The length of the lights-on and lights-off phases were maintained by the application of artificial lights (Tube fluorescent lights), set on the walls of the laboratory (6 × 40 Watt). The lights-on phase in the laboratory synchronized manually with the natural outdoor sunlight photo phase and the lights-off phase with the dark phase of the night.

To evaluate the predation of the larval forms of A. sulcatus on the 4th instar larvae of Cx. quinquefasciatus, different combinations of prey, predator and volume of water were considered. In each case nine replicate for one combination were made. The combinations were as stated below:

a) 1 predator, 1 litre of water, 200 numbers of prey – combination A

b) 1 predator, 2 litres of water, 200 numbers of prey – combination B

c) 1 predator, 1 litre of water and 400 numbers of prey – combination C

d) 2 predators, 1 litre of water and 200 numbers of prey – combination D

e) 2 predators, 2 litre of water and 200 numbers of prey – combination E

f) 2 predators, 1 litre of water and 400 numbers of prey – combination F

The rate of predation for a period of 24 h was noted and the data was used to calculate the clearance rate (CR = number of prey/h/predator) an indicator of predatory efficiency. The CR values were obtained applying the following formula, following Gilbert and Burns 35, with certain modifications;

CR = V.(lnP)/T.N

Where, V = volume of water (in litre), ln = Natural log, P = number of prey killed/consumed, T = time, i.e. 24 h., N = number of predator.

To examine the efficacy of larvae of A. sulcatus in field condition, Sainthia in the district of Birbhum, West Bengal, India was selected. In the study area, ten cemented tanks (which were located in open air and contained about 250 L of water) were selected. These tanks are usually used in processing of paddy. The tanks remain unused for a long time i.e. from post rainy season to early spring (Sep to Feb), and played the role as natural breeding places of mosquitoes. The tanks were made free from any larvae or nymphs of larvivorous insects or fishes by a fine net having mesh size of >130, which allowed the passage of mosquito larvae. Those tanks contained mosquito larvae of different species namely Cx. quinquefasciatus (Say,1823), Cx. bitaeniorhynchus (Giles,1901), Cx. tritaeniorhynchus (Giles, 1901), Cx. vishnui (Theobald, 1901), Cx. gelidus (Theobald,1901), An. subpictus (Grassi, 1889), An. vagus (Doenitz, 1902), An. aconitus (Doenitz,1902), An. barbirostris (Van der Wulp, 1884), An. annularis (Van der Wulp, 1884) and Armigeres subalbatus (Coquillett,1898). Each time 5 dips were taken in each tank and the mean per dip (250 ml dipper) larval density of each of those 10 tanks was assessed according to WHO, 1975 36 for 15 times at an interval of 90 minutes on a specific day (total 5 × 15 dips in each tank). Then twenty larvae of A. sulcatus were introduced in each of first five tanks (No. 1 to 5). Five tanks no. 6 to 10 were kept as control to rule out the possibility of decreasing prey density by the activity of Zooplanktons like copepods. Larval densities in those tanks were assessed 30 days after introduction of Acilius larvae for 15 times in similar manner and on the next day all the predator larvae were removed. Densities were assessed again after 30 days from the withdrawal of A. sulcatus larvae from the tanks. The experiments (both in laboratory and in the field) were conducted in the months of June, July and August 2007. Re-colonization of tanks by larvae of other larvivorous insects was controlled by netting (>130 mesh) the tanks at an interval of 15 days during the study period. Methods of Ghosh et al. 373839 and Chatterjee et al. 18 were used to conduct laboratory and field experiments during the present study.

The data obtained on clearance rate for each combination was subjected to one-way ANOVA followed by Tukey's post hoc test 40 to justify the differences, if any, between the combinations. Besides, Students' t-tests and 'Z' tests 40 were performed to evaluate the difference in mosquito larval density in the field conditions before and after the presence of the A. sulcatus larvae in the mesocosms.

The larva of A. sulcatus was observed to capture the mosquito larva prey on its head, sucked its body fluid as a part of extra oral digestion 34 and discarded some portions of the prey body within a few minutes. The feeding of the larval dytiscid beetles involves mandibles for capturing prey and transfer of enzymes into the tissues and accumulating partially digested pieces of the tissue 34. The feeding posture of an A. sulcatus larva on a Culex larva has been presented in Plate [see Additional file 1]. Three hourly consumption rates of one and five A. sulcatus larvae on 200 and 1000 4^th instar Cx. quinquefasciatus larvae respectively have been presented in Fig 1. One A. sulcatus larva consumed 18 and 16 mosquito larvae during light on and light off phases respectively with a daily feeding rate of 34 larvae on an average. Five A. sulcatus larvae consumed 166 mosquito larvae during light on phase and 172 larvae during light off phase with a an average feeding rate of 33.8 larvae/predator in a 24 h period. The number of prey killed varied with the density of preys and predators available in a particular volume of water (Fig. 2). The clearance rate value ranged between 13.59 and 20.09 no. of prey L/h/predator. The maximum CR value was obtained when the predator larva was present in larger space (Fig. 3.). One way ANOVA revealed significant differences in the clearance rate at different combinations (Table 1). The result of the post hoc Tukey's test is presented in Fig 3. The results are suggestive of the fact that the larval stages of A. sulcatus exhibited varied predatory efficiency depending on the availability of space and the number of predators.