Abstract
Abstract
Biologically rich rock-pools (RPs) are prominent component of rocky intertidal habitat and this study elucidates the factors affecting the phytoplankton distribution from high-tide (HT), mid-tide (MT) and low-tide (LT) RPs (Anjuna rocky shores, Goa, India), during the summer season. Results revealed that the RP location determines the nature of phytoplankton assemblage. MT-RPs and LT-RPs supported rich microalgal diversity (species number/morphological shapes) than HT-RPs. However, the cell abundance was higher in latter than former RPs. In frequently flushed MT-RPs and LT-RPs, pennate diatoms (Pseudonitzschia, Nitzschia, Thalasionema, Navicula, and Licmophora) representing elongated shapes dominated, whereas in stagnant HT-RPs spherical/combined shaped dinoflagellates (Amphidinium carterae sensu stricto and Bysmatrum gregarium) dominated. Interestingly, even though the taxonomic assemblages changed temporally the shape dominance remained consistent suggesting shape as a robust morphological trait. Additionally, the study also revealed the existence of species-specific allelopathy on other microalgae by Amphidinium (potential harmful algae) indicating a type of adaptive strategy, in addition to eurytolerant capabilities, for its predominance in HT-RPs, which experiences varying environmental (light, temperature, and salinity) conditions.
Research Highlights
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Investigated factors influencing distribution of phytoplankton (species and shape-wise) in intertidal rock pools (RPs) of Anjuna rocky shores, Goa.
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Location of RPs determined nature of phytoplankton community, i.e., less diversity and high abundance in high-tide RPs than mid/low-tide RPs.
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Spherical-shaped dinoflagellates and elongated shape diatoms dominated phytoplankton community of high and mid/low tide RPs, respectively.
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Even though the species composition changed temporally the shape dominance remained consistent suggesting the latter as a robust morphological trait.
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Dominant dinoflagellate, Amphidinium caterae sensu stricto, also showed species-specific allelopathy on other phytoplankton.
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Anusa A, Ndagurwa H G T and Magadza C H D 2012 The influence of pool size on species diversity and water chemistry in temporary rock pools on Domboshawa Mountain, northern Zimbabwe; Afr. J. Aqua. Sci. 37(1) 89–99.
Baig H S, Saifullah S M and Dar A 2006 Occurrence and toxicity of Amphidinium carterae Hulburt in the North Arabian Sea; Harmful Algae 5(2) 133–140.
Da Silva K D P, Simões N R, De Oliveira D L, Silva F S and Barbosa L G 2020 Phytoplankton communities in freshwater rock pools: Structural and spatial dynamics in Brazilian drylands; Limnetica 39(1) 487–498.
Fistarol G O, Legrand C, Rengefors K and Granéli E 2004 Temporary cyst formation in phytoplankton: A response to allelopathic competitors?; Environ. Microbiol. 6(8) 791–798.
Granéli E and Hansen P J 2006 Allelopathy in Harmful Algae: A mechanism to compete for resources?; In: Ecology of Harmful Algae. Ecological Studies Series (eds) Granéli E and Turner J T, vol. 189, Springer-Verlag, Berlin, pp. 189–201.
Grover J P 1989 Influence of cell shape and size on algal competitive ability; J. Phycol. 25 402–405.
Häggqvist K and Lindholm T 2015 Phytoplankton communities in rock pools on the Åland Islands, SW Finland – environmental variables, functional groups and strategies; Biodivers. 16(1) 15–26.
Häggqvist K and Lindholm T 2016 Phytoplankton, physical and chemical microscale variations in three brackish rock pools; Phycol. Res. 64 241–250.
Hillebrand H, Durselen C D, Kirschel D, Pollingher D and Zohary T 1999 Biovolume calculation for pelagic and benthic microalgae; J. Phycol. 35 403–424.
Huggett J and Griffiths C L 1986 Some relationships between elevation, physico-chemical variables and biota of intertidal rock pools; Mar. Ecol. Prog. Ser. 29 189–197.
Jeong H J, Kang H, Shim J H, Park J K, Kim J S, Song J Y and Choi H J 2001 Interactions among the toxic dinoflagellate Amphidinium carterae, the heterotrophic dinoflagellate Oxyrrhis marina, and the calanoid copepods Acartia spp; Mar. Ecol. Prog. Ser. 218 77–86.
Jeong H J, Jang S H, Kang N S, Yoo Y D, Kim M J, Lee K H, Yoon E Y, Potvin E, Hwang Y J, Kim J I and Seong K A 2012 Molecular characterization and morphology of the photosynthetic dinoflagellate Bysmatrum caponii from two solar Saltons in Western Korea; Ocean Sci. J. 47(1) 1–18.
Karp-Boss L and Boss E 2016 The elongated, the squat and the spherical: Selective pressures for phytoplankton shape; In: Aquatic microbial ecology and biogeochemistry: A dual perspective (eds) Glibert P and Kana T M, Springer, Berlin, pp. 25–34.
Kiorboe T 1993 Turbulence, phytoplankton cell size, and the structure of pelagic food webs; Adv. Mar. Biol. 29 1–72.
Legrand C, Rengefors K, Fistarol G O and Graneli E 2003 Allelopathy in phytoplankton–biochemical, ecological and evolutionary aspects; Phycologia 42(4) 406–419.
Lewis W M 1976 Surface/volume ratio: Implication for phytoplankton morphology; Science 192 885–887.
Litchman E and Klausmeier C A 2008 Trait-based community ecology of phytoplankton; Ann. Rev. Ecol. Evol. Syst. 39 615–639.
Mandal S K, Singh R P and Patel V 2011 Isolation and characterization of exopolysaccharide secreted by a toxic dinoflagellate, Amphidinium carterae Hulburt 1957 and its probable role in harmful algal blooms (HABs); Microb. Ecol. 62 518–527.
Margalef R 1978 Life-forms of phytoplankton as survival alternatives in an unstable environment; Oceanol. Acta 1 493–509.
Martins G M, Hawkins S J, Thompson R C and Jenkins S R 2007 Community structure and functioning in intertidal rock pools: Effects of pool size and shore height at different successional stages; Mar. Ecol. Prog. Ser. 329 43–55.
Metaxas A and Lewis A G 1992 Diatom communities in tidepools: The effect of Intertidal height; Botanica Marina 35 1–10.
Metaxas A and Scheibling R E 1993 Community structure and organization of tidepools; Mar. Ecol. Prog. Ser. 98 187–198.
Metaxas A and Scheibling R E 1994 Changes in phytoplankton abundance in tidepools over the period of tidal isolation; Botanica Marina 37 301–314.
Metaxas A and Scheibling R E 1996a Spatial heterogeneity of phytoplankton assemblages in tidepools: Effects of abiotic and biotic factors; Mar. Ecol. Prog. Ser. 130 179–199.
Metaxas A and Scheibling R E 1996b Top-down and bottom-up regulation of phytoplankton assemblages in tidepools; Mar. Ecol. Prog. Ser. 145 161–177.
Morabito G, Oggioni A, Caravati E and Panzani P 2007 Seasonal morphological plasticity of phytoplankton in Lago Maggiore (N. Italy); Hydrobiol. 578 47–57.
Murray S A, Kohli G S, Farrell H, Spiers Z B, Place A R, Dorantes-Aranda J J and Ruszczy K J 2015 A fish kill associated with a bloom of Amphidinium carterae in a coastal lagoon in Sydney, Australia; Harmful Algae 49 19–28.
Murray S A, Garby T, Hoppenrath M and Neilan B A 2012 Genetic diversity, morphological uniformity and polyketide production in Dinoflagellates (Amphidinium, Dinoflagellata); PLoS ONE 7(6) e38253, https://doi.org/10.1371/journal.pone.0038253.
Naselli-Flores L and Barone R 2007 Pluriannual morphological variability of phytoplankton in a highly productive Mediterranean reservoir (Lake Arancio, Southwestern Sicily); Hydrobiologia 578 87–95.
Naselli-Flores L, Padisak J and Albay M 2007 Shape and size in phytoplankton ecology: Do they matter?; Hydrobiologia 578 157–161.
Norberg J 1998 Effects of temperature and light on the composition of brackish-water rock pool ecosystem; Aqua. Ecol. 32 323–334.
Padisak J, Soroczki-Pinter E and Rezner Z 2003 Sinking properties of some phytoplankton shapes and the relation of form resistance to morphological diversity of plankton – an experimental study; Hydrobiologia 500 243–257.
Patil J S, Rodrigues R V, Paul P, Satish K, Rafi M and Anil A C 2017 Benthic dinoflagellate blooms in topical intertidal rock pools: Elucidation of photoprotection mechanisms; Mar. Biol. 164 89–91.
Pavaux A-S, Berdalet E and Lemée R 2020 Chemical Ecology of the Benthic Dinoflagellate Genus Ostreopsis: Review of Progress and Future Directions; Front. Mar. Sci. 7 498.
Poulson K L, Sieg R D, Prince E K and Kubanek J 2010 Allelopathic compounds of a red tide dinoflagellate have species-specific and context-dependent Impacts on phytoplankton; Mar. Ecol. Prog. Ser. 416 69–78.
Reynolds C S 2006 Ecology of Phytoplankton; Cambridge University Press, Cambridge.
Rice E L 1984 Allelopathy; Academic Press, Orlando.
Rishworth G M, Perissinotto R, Miranda N A F, Bornman T G and Steyn P P 2017 Phytoplankton community dynamics within peritidal pools associated with living Stromatolites at the freshwater–marine interface; Aquat. Sci. 79 357–370.
Salmaso N and Padisak J 2007 Morpho-Functional Groups and phytoplankton development in two deep lakes (Lake Garda, Italy and Lake Stechlin, Germany); Hydrobiologia 578 97–112.
Soininen J and Meier S 2014 Phytoplankton richness is related to nutrient availability, not to pool size, in a subarctic rock pool system; Hydrobiologia 70 137–145.
Sommer U 1998 Silicate and the functional geometry of marine phytoplankton; J. Plank. Res. 20 1853–1859.
Stanca E, Cellamare M and Basset A 2013 Geometric shape as a trait to study phytoplankton distributions in aquatic ecosystems; Hydrobiologia 701 99–116.
Suikkanen S, Fistaro G O and Granéli E 2005 Effects of cyanobacterial allelochemicals on a natural plankton community; Mar. Ecol. Prog. Ser. 287 1–9.
Sun J and Liu D 2003 Geometric models for calculating cell biovolume and surface area for phytoplankton; J. Plan. Res. 25 1331–1346.
Therriault T W and Kolasa J 2001 Desiccation frequency reduces species diversity and predictability of community structure in coastal rock pools; Israel J. Zoo. 47(4) 477–489.
Tomas C R 1997 Identifying marine phytoplankton; Academic Press, New York, 858p.
Underwood A J and Skilleter G A 1996 Effects of patch size on the structure of assemblages in rock pools; J. Exp. Mar. Biol. Ecol. 197 63–90.
Xiaoqing J I, Xiaotian H, Baijuan Y and Zhiming Y 2012 Analysis on allelochemicals in the cell-free Filtrates of Amphidinium carterae; Acta Ecologica Sinica 32(6) 1745–1754.
Acknowledgements
The authors are grateful to the Director of CSIR-National Institute of Oceanography for his support and encouragement. We thank Drs N L Thakur and D Desai for co-ordinating intertidal rock pool experiments under the Ocean Finder project (PSC0105) and the project staff, who were involved in the experiments, for their help during sampling. We are also thankful to the two anonymous reviewers for their suggestions in improving the manuscript. First author also acknowledges UGC for fellowship. This is an NIO Contribution No. 6695.
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Paul P: Performed field sampling, laboratory experiments, samples analysis, data analysis and interpretation; J S Patil: Original concept, field and experiment planning, field sampling, data interpretation and manuscript elaboration; A C Anil: Manuscript elaboration and also co-supervised all works.
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Communicated by N V Chalapathi Rao
This article is part of the topical collection: Advances in Coastal Research.
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Paul, P., Patil, J.S. & Anil, A.C. Phytoplankton communities in marine intertidal rock-pools: Effect of location, geometric shapes and allelopathy. J Earth Syst Sci 130, 128 (2021). https://doi.org/10.1007/s12040-021-01591-5
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DOI: https://doi.org/10.1007/s12040-021-01591-5