AGRICULTURE AND BIOLOGY JOURNAL OF NORTH AMERICA ISSN Print: 2151-7517, ISSN Online: 2151-7525, doi:10.5251/abjna.2011.2.6.897.901 © 2011, ScienceHuβ, http://www.scihub.org/ABJNA Food and feeding ecology of the MUDSKIPPER Periopthalmus koelreuteri (PALLAS) Gobiidae at Rumuolumeni Creek, Niger Delta, Nigeria F.G. Bob-Manuel Rivers State University of Education, Rumuolumeni, P. M. B. 5047, Port Harcourt, Nigeria ABSTRACT The food habits of the mudskipper Periophthalmus keolreuteri (Pallas) from the mudflats at Rumuolumeni Creek, Niger Delta, Nigeria were studied. The frequency of occurrence and ‘point’ methods was used for the gut content analysis. The results indicate that the juveniles were herbivorous feeding more on aquatic macrophytes, diatoms and algal filaments while the adults had a dietary shift towards crustaceans, aquatic and terrestrial insects and polychaetes. The amphibious lifestyle of the mudskipper confers on it the trophic position of a zoobenthivore and a predator. Keywords: diet composition, mudskippers, food web, trophic relations, Niger Delta. INTRODUCTION catch bigger fishes. The rich food supplies in the mangrove mud flat have been the impetus which led The mudskippers Periophthalmus koelreuteri the goby-like ancestors of modern mudskippers to (Gobiidae: Oxudercinae) live in the intertidal habitat leave the water from time to time. (Evans et al., 1999) of the mudflats and in mangrove ecosystem (Murdy, The mudskippers can move rapidly on the mud, 1989). These fishes are uniquely adapted to a which is inaccessible to people. completely amphibious lifestyle (Graham, 1997). They are quite active when out of water, feeding and The mudskipper, P. koelreuteri is a residential fish interacting with one another and defending their inhabiting the mudflats of the Niger Delta estuaries, territories. The mudskippers, Periophthalmus the waterways, and the mangrove forests in Nigeria. koelreuteri (Pallas) have a range of peculiar The objective of this work is to investigate the food behavioural and physiological adaptations to an and feeding ecology of the mudskipper P. koelreuteri amphibious lifestyle. These include anatomical and in the mudflat of the Rumuolumeni creek in the Niger behavioural adaptations that allow them to move Delta, Nigeria. effectively on land as well as in the water (Harris, MATERIALS AND METHODS 1960) the ability to breathe through their skin and the lining of their mouth (the mucosa) and throat (the Study Site: The study site was the mangrove swamp pharynx) by means of cutaneous air breathing and mudflat at the Western end of the Rivers State (Graham, 1997), digging of deeps burrows in soft University of Education Rumuolumeni, Port Harcourt. sediments that allow the fish to thermo-regulate The vegetation of the Rumuolumeni Mangrove Creek (Tytler and Vaughan, 1983); avoid marine predators consist of the red mangrove Rhizophora racemosa during high tide when the fish and burrow are and the white mangrove Avicennia Africana with submerged (Sasekumar et al 1994) heights ranging from 2.50 to 5.60m. The main river bifurcates into two smaller tributaries. The water is The mudskipper, P. Koelreuteri in widely fascinating brackish. At low tide stilt-like prop roots of the of all tropical fish. They can be seen jumping, mangrove were visible; the intertidal mudflats were climbing, and skipping about with great agility in the exposed and served as feeding ground for the mangrove creeks of the Niger Delta region of Nigeria. mudskippers. Burrows and small holes between 3.5- These fish have no legs but move with their arm-like 6cm in diameter abound around the prop-roots of the pectoral fins. The mudskippers are widely distributed Rhizophora trees. These areas served as in the brackish water rivers, creeks, and lagoons in Periophthalmus. species hide out. Traps were set the Niger-Delta area of Nigeria. This fish is around these areas. The substrate consisted of economically important and actively fished by the hydromorphic soil of the marine alluvium type heavily local inhabitants of this area to whom it serves as a impregnated with products of decayed organic special delicacy. The fish is also used as bait to Agric. Biol. J. N. Am., 2011, 2(6): 897-901 matter, usually mud. This gives the soil a black items over a slide, a little at a time. Two drops of coloration, water logged substratum and the smell of water was added to spread out the food contents. a rotten odour. Finally, the number of each taxonomic entity was recorded on data sheet for each stomach. Fish Trapping Method: About 405 mudskippers which consisted of 250 juveniles and 155 adults were Two methods were used for the stomach content collected with standard lengths ranging from 6.20 – analysis. The frequency of occurrence method and 6.30cm and 6.30- 15.0cm respectively. The fish were the ‘point’ method. The occurrence method (Hynes obtained between March 2009 to August 2009 on 1950 and Frost, 1943). The occurrence method is weekly basis. one in which the relative importance (to the fish) of different food items in each stomach were identified The fishing gear used were basket traps woven with and recorded. Here the number of fish in which each cane material with a single conical incurving opening. food item occurred was recorded and expressed as a Each basket trap is 30cm long and 35cm wide. percentage of the total number of stomach examined. These traps are non-selective and can catch both This method being qualitative portrays which adults and juveniles. The traps were set during the organisms were best being used as food. low-tide. Crushed crabs such as Cardiosoma armatum (land crab) and Uca tangeri (fiddler crab) The subjective or ‘points’ method was first employed were used as bait for the traps. As soon as catches by (Swynnerton and Worthinton 1940) and has since were made, the specimens were removed and put been used by other workers(Frost, 1943; Hynes, into specimen bottles containing 4% formalin. These 1950; Fagade, 1971). Here each food item is were later taken to the Biology laboratory of the awarded point proportional to its estimated Rivers State University of Education Port Harcourt for contribution to stomach volume. A total of 100 analysis. points is awarded to all the content of stomach and these points shared among the contents taking Laboratory Analysis: In the laboratory, the fish were cognizance of the relative volume of each food item. separated into adults and juveniles. The total and Fagade (1971) used only stomachs that are more standard lengths of the specimens were measured to than half filled. The points gained by each food from the nearest millimeter using a measuring board. The all the stomachs examined are summed up and stomach and some part of the oesophagus were expressed as a percentage of the total number of dissected out in each specimen and placed in a glass points. A combination of these two methods was petridish containing some freshwater to neutralize the used so that one method could nullify the effect of the formalin for a short while. Each disadvantage of the other. stomach was then slit open and the content removed by scrapping the inner mucosa with a spatula. The RESULT: The analysis of the gut-content for juvenile weight of the contents was now taken and food items Periophthalmus koelreuteri using the frequency of identified. This was done by spreading out the food occurrence method is shown in Table 1. Table I. Gut-content analysis of juvenile Periophthalmus koelreuteri in Rumuolumeni Creek Food Items Number of Species in which Frequency of occurrence (%) food items occurred Diatoms 213 85.00 Fragments of Higher Plants 227 90.60 Crustacean appendages 38 15 Fish Scales 26 10.30 Sand Grains 155 61.90 Unidentified Organic Matter/detritus 108 43.00 Algal Filament 201 80.60 Fish Gills 31 12.50 Polychaetes 63 25.00 Insect parts 75 30.00 No. of specimens 250 Stomach length range 4.60 – 6.20cm The gut-content analysis of juvenile P. koelreuteri using the ‘Point’ method is shown in Table 2. 898 Agric. Biol. J. N. Am., 2011, 2(6): 897-901 Table 2. Gut-content analysis of Juvenile P. Koelreuteri in Rumuolumeni creek using the ‘Point’ method Food Items Point gained (%) of total Diatoms 7,450 29.80 Fragments of Higher Plants 9,500 38.20 Crustacean Appendages - trace Fish Scales - trace Sand Grains 300 1.2 Unidentified Organic Matter (detritus) 1,100 4.4 Algal Filament 5,900 23.6 Fish Gills - Trace Polychaetes 350 1.4 Insect parts 275 1.1 Total Points 25,000 No. of Specimens 250 Standard Length range 4.60 - 6.20cm The analysis of gut-content using the frequency of occurrence method is shown in Table 3. for adult Periophthalmus koelreuteri. Table 3. Gut-content analysis of Adult P. Koelreuteri in Rumuolumeni creek using the frequency of occurrence method Food Items Point gained (%) of total Diatoms 23 15.3 Fragments of Higher Plants 31 20.2 Crustacean Appendages 148 95.5 Fish Scales 78 50 Sand Grains 71 45.5 Unidentified Organic Matter/detritus 78 50 Algal Filament 42 27.3 Fish Gills 78 50 Polychaetes 134 86.4 Insect parts 132 85 No. of Specimen 155 Standard length 6.30 – 15.0cm The gut-content analysis of adult P. koelrenteri using the ‘points’ method is shown in table 4. Table 4. Gut-content analysis of adult Periophthalmus koelreuteri at Rumuolumeni Creek using the ‘Point’ method. Food Items Points gained Percentage of total Diatoms - trace Fragments of Higher Plants - trace Crustacean appendages 5,642 36.40 Fish Scales 1,581 10.2 Sand Grains 171 1.10 Unidentified Organic Matter/detritus 233 1.50 Algal Filament 202 1.30 Fish Gills 1,008 6.50 Polychaetes 3,209 20.70 Insect parts 3,457 22.30 Total Points 15,000 No.
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