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http://dx.doi.org/10.5657/KFAS.2013.0176

Seasonal Variation in Species Composition and Biomass of Microphytobenthos at Jinsanri, Taean, Korea  

Park, Seo Kyoung (Faculty of Biological Science and Institute for Basic Science, Wonkwang University)
Kim, Bo Yeon (Faculty of Biological Science and Institute for Basic Science, Wonkwang University)
Choi, Han Gil (Faculty of Biological Science and Institute for Basic Science, Wonkwang University)
Oh, Joung-Soon (Institute of Eco and Environmental Incorporation)
Chung, Sang-Ok (Tidal Flat Research Institute, National Fisheries Research & Development Institute)
An, Kyoung-Ho (Tidal Flat Research Institute, National Fisheries Research & Development Institute)
Park, Kwang-Jae (Tidal Flat Research Institute, National Fisheries Research & Development Institute)
Publication Information
Korean Journal of Fisheries and Aquatic Sciences / v.46, no.2, 2013 , pp. 176-185 More about this Journal
Abstract
Seasonal species composition and biomass of microphytobenthos were examined at the intertidal flats of Jinsanri, Taean, Korea, from April to December 2011. In total, 121 species were identified, including 109 diatoms, 5 blue-green algae, and 5 dinoflagellates. Seasonal variation in species number ranged from 49 to 56 species (minimum in October and maximal in April), while vertical variation across three different shore levels ranged from 64 to 77 species with maximum at high and minimum at low shore. Species diversity ranged from 3.22 to 3.42 seasonally and from 3.50 to 3.17 across vertical shore levels. Seasonal average values of the normalized difference vegetation index and the vegetation index were 0.06 and 1.14, respectively. Chlorophyll a concentrations were $66.00-120.73mg/m^2$, with a seasonal minimum and maximum in July and October, respectively, and a vertical shore maximum of $137.35mg/m^2$ at mid shore. Phaeopigment concentrations peaked in October ($50.78mg/m^2$) and at high shore ($61.58mg/m^2$) and were lowest in December ($22.53mg/m^2$) and at low shore ($15.28mg/m^2$). The number of microphytobenthos ranged from 78,556 to 287,898 cells/$cm^2$, reaching a maximum in April and a minimum in July. The diatoms Paralia sulcata, Navicula sp., and Delphines surirella were dominant at all tidal levels over the study period. Dinoflagellates were dominant in July at low shore, and blue-green algae were abundant between July and October at mid shore. In conclusion, species composition and primary production of microphytobenthos exhibited clear seasonal and vertical patterns.
Keywords
Biomass; Chlorophyll a; Dominant species; Shore level; Species composition;
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1 Jordan CF. 1969. Derivationof leaf area index from quality of light on the forest floor. Ecology 50, 663-666.   DOI   ScienceOn
2 Kang CK, Kim JB, Lee KS, Kim JB, Lee PY and Hong JS. 2003. Trophic importance of benthic microalgae to macrozoobenthos in coastal bay systems in Korea: dual stable C and N isotope analyses. Mar Ecol Prog Ser 259, 79-92.   DOI
3 Kelly JA, Honeywill C and Paterson DM. 2001. Microscale analysis of chlorophyll-a in cohesive, intertidal sediments: the implications ofmicrophytobenthos distribution. J Mar Biol Ass UK 81, 151-162.   DOI   ScienceOn
4 Kendrick GA, Langtry LS, Fitzpatrick J, Griffiths R and Jacoby GA. 1998. Benthic microalgae and nutrient dynamics in wave-disturbed environments in Marmion Lagoon, Western Australia, compared with less disturbed mesocosms. Exp Mar Biol Ecol 228, 83-105.   DOI   ScienceOn
5 Kim JH and Cho KJ. 1985. The physico-chemical properties of sediment, the species composition and biomass of benthic diatoms in the intertidal zone of Keum River estuary. Korean J Ecol 8, 199-207.
6 Krumme U, Keuthen H, Barletta M, Saint-Paul U and Villwock W. 2008. Resuspended intertidal microphy to benthos as major diet component of planktivorousatlanticanchoveta Cetengraulis edentulus (Engraulidae) from equatorial mangrove creeks. Ecotropica 14, 121-128.
7 Lee HY. 2002. Comparison of the effects of physico-chemical factors on thezonation and vertical distribution of benthic microalgal communities in the tidal flats of south-west Korea. J Environ Sci 11, 529-535.
8 Lee HY. 2003. Studies on the distribution of the microalgae in the tidal flats of Gamami beach, Young-Gwang, Korea. J Environ Sci 12, 715-724.   과학기술학회마을   DOI   ScienceOn
9 Lee YW, Choi EJ, Kim YS, and Kang CK. 2009. Seasonal variations ofmicrophytobenthos in sediments of the estuarine muddy sandflat of Gwangyang Bay: HPLC pigment analysis. J Korean Fish Soc 14, 48-55
10 Lorenzen CJ. 1967. Determination of chlorophyll and phaeopigments: spectrophotometric equations. Limnol Oceanog 12, 343-346.   DOI   ScienceOn
11 Lucas DH, Widdows J and Wall L. 2003. Relating spatial and temporal variability in sediment chlorophyll a and carbohydrate distributionwitherodibility of a tidal flat. Estuaries 26, 885-893.   DOI   ScienceOn
12 MacIntyre HL, Geider RJ and Miller DG. 1996. Microphytobenthos: the ecological role of the "Secret Garden" of unvegetated, shallow-water marine habitats. I. Distribution, abundance and primary production. Estuaries 19, 186-201.   DOI   ScienceOn
13 Magni P and Montani S. 1997. Development of benthic microalgal assemblages on an intertidal flat in the Seto Inland Sea, Japan: effects of environmental variability. La Mer 35, 137- 148.
14 Meleder V, Barille L, Rince Y, Morancais M, Rosa P and Gaudin P. 2005. Spatio-temporal changes in microphytobenthosstructure analysed by pigment composition in a macrotidal flat (Bourgneuf Bay, France). Mar Ecol Prog Ser 297, 83-99.   DOI
15 Montagna PA, Blanchard GF and Dinet A. 1995. Effectof production and biomass of intertidal microphytobenthos on meiofaunal grazing rates. J Exp Mar Biol 185, 149-165.   DOI   ScienceOn
16 Montani S, Magni P and Abe N. 2003. Seasonal and interannual patterns of intertidal microphytobenthos in combination with laboratory and areal production estimates. Mar Ecol Prog Ser 249, 79-91.   DOI
17 Murphy RJ, Underwood AJ, Tolhurst TJ and Chapman MG. 2008. Field-based remote-sensing for experimental intertidal ecology: case studies usinghyperspatial and hyperspectral data for New South Wales (Australia). Remote Sens Environ 112, 3353-3365.   DOI   ScienceOn
18 Woelfel J, Schumann R, Adler S, Hubener T and Karsten U. 2007. Diatoms inhabiting a wind flat of the Baltic Sea: species diversity and seasonal succession. Estuar Coast Shelf Sci 75, 296-307.   DOI   ScienceOn
19 Underwood GJC. 1994. Seasonal and spatial variation in epipelic diatom assemblages in the severn estuary. Diatom Res 9, 451-472.   DOI
20 Underwood GJC and Kromkamp J. 1999. Primary production by phytoplankton and microphytobenthos in estuaries. Adv Ecol Res 29, 93-153.   DOI
21 Yoo MH and Choi JK. 2005. Seasonal distribution and primary production of microphytobenthos on an intertidal mud flat of the Janghwa in GanghwaIsland, Korea. J Korean Soc- Oceanogr 10, 8-18.
22 Oh SJ, Moon CH and Park MO. 2004. HPLC analysis of biomass and community composition of microphytobenthos in the Saemankeum tidal flat, west coast of Korea. J Kor Fish Soc 37, 215-225.   과학기술학회마을   DOI   ScienceOn
23 NFRDI. 2011. Technical report of national fisheries and development institute. 619-638.
24 Noh SM. 2008. Effect of tidal on microalgal distribution and primary production variation in Taean coastal environment.M.S. Thesis, Inha University, Incheon, Korea.
25 Oh SH and Koh CH. 1995. Distribution of diatoms in the surficial sediments of the Mangyung-Dongjintidal flat, west coast of Korea (Eastern Yellow Sea). Mar Biol 122, 487- 496.   DOI   ScienceOn
26 Park JS 2005.Taxonomic study of benthic diatoms in Nanauramudflat, Ariake Sea, Japan. M.S. Thesis, Seoul National University, Seoul, Korea.
27 Perkins RG, Lavaud J, Serodio J, Mouget JL, Cartaxana P, Rosa P, Barille L, Brotas V and Jesus BM. 2010. Vertical cell movement is a primary response of intertidal benthic biofilms to increasing light dose. Mar Ecol Prog Ser 416, 93-103.   DOI
28 Pitcher GC and Joyce LB. 2009. Dinoflagellate cystproduction on the southern Namaqua shelf of the Benguela upwelling system. J Plankton Res 31, 865-875.   DOI   ScienceOn
29 Rizzo WM. 1990. Nutrient exchanges between the water column and a subtidal benthic microalgal community. Estuaries 13, 219-226.
30 Rouse JW, Haas RH, Schell JA and Deering DW. 1973. Monitoring vegetation systems in the great plains with ERTS. Third ERTS Symposium. NASA SP-351, Washington, USA, 309-317.
31 Serodio J, Coelho H, Vieira S and Cruz S. 2006. Microphytobenthos vertical migratory photoresponse as characterised by light-response curves of surface biomass. Estuar Coast Shelf Sci 68, 547-556.   DOI   ScienceOn
32 Clarke KR and Gorley RN. 2006. PRIMER V6: User Manual/Tutorial. PRIMER-E Ltd, Plymouth, UK, 1-190.
33 Cariou-Le Gall V and Blanchard GF. 1995. Monthly HPLC measurements of pigment concentration from an intertidal muddy sediment of Marrennes-Oleron Bay, France. Mar Ecol Prog Ser 121, 171-179.   DOI
34 Cho KJ and Kim JH. 1988. Species composition and primary production of thebenthic algal assemblage along a channel in salt marsh, Kyonggi Bay, Korea. Korean J Ecol 11, 1-15.
35 Choi HS,1988. Afloristic study on benthic diatoms in Songdo tidal flat,Gyeonggi Bay.M.S. Thesis, Seoul National University, Seoul, Korea.
36 Coelho H, Vieira S and Serodio J. 2009. Effects of desiccation on the photosynthetic activity of Intertidalmicrophytobenthosbiofilms as studied by optical methods. J Exp Mar Bio Ecol 381, 98-104.   DOI   ScienceOn
37 Colijin F and Dijkema KS. 1981. Species composition of benthic diatoms and distribution of chlorophyll a on an intertidal flat in the Dutch Wadden Sea. Mar Ecol Prog Ser 4, 9-21.   DOI
38 Dandonneau Y. 1982. A method for the rapid determination of chlorophyll plus phaeopigments in samples collected by merchant ships. Deep Sea Research 29, 647-654.   DOI   ScienceOn
39 Consalvey M, Jesus B, Perkins R, Brotas V and Paterson DM. 2004. Monitoring migration and measuring biomass in benthic biofilms: the effects of dark/far red adaptation and vertical migration on fluorescence measurements. Photosynth Res 81, 91-101.   DOI
40 De Jonge VN and Colijn F. 1994.Dynamics of microphytobenthos biomass in the Ems estuary. Mar Ecol Prog Ser 104, 185-196.   DOI
41 Dodge JD. 1982. Marine dinoflagellates of the British Isles. Hobbs the Printers of Southhampton, London, U.K., 303.
42 Falasco E, Bona F, Ginepro M, Hlúbikova D, Hoffmann L and Ector L. 2009. Morphological abnormalities of diatom silica walls in relation to heavy metal contamination and artificial growth conditions. Water SA 35, 595-606.
43 Helling GR and Baars MA. 1985. Changes of the concentrations of chlorophylland phaeopigment in grazing experiments. Hydrobio Bull 19, 41-48.   DOI
44 Holm-Hansen O, Lorenzen CJ, Holmes RW and Strickland- JDH. 1965. Fluorimetric determination of chlorophyll. J Cons Perm Int Explor Mer 30, 3-15.   DOI
45 Jesus B, Mendes CR, Brotas V and Paterson DM. 2006. Effect of sediment type on microphytobenthos vertical distribution: Modelling the productive biomass and improving ground truth measurements. J Exp Mar Biol Ecol 332, 60-72   DOI   ScienceOn
46 Jesus B, Brotas V, Ribeiro L, Mendes CR, Cartaxana P and Paterson DM. 2009.Adaptations of microphytobenthos assemblages to sediment type and tidal position. Cont Shelf Res 29, 1624-1634.   DOI   ScienceOn
47 Jin DX, Chen ZD, Li JM, Junmin L and Li SC. 1985.The Marine Benthic Diatoms in China, Vol 1. China Ocean Press, Beijing, China, 314.