Abstract
Marine invertebrate larvae are highly phototactic during early stages of larval period and greatly influenced by light, colour and other physio-chemical properties of the substrates. In the present study, the effects of light and substrate colour on recruitment of marine invertebrates were investigated. Four different colour panels (red, green, blue and yellow acrylic sheets) and colourless panel (clear transparent acrylic sheet) were suspended at 2 m depth in the central Red Sea for 4 weeks during two seasons (spring and summer). The effects of substrate colour on invertebrate recruitment were tested under light and shade conditions. The results revealed significant variations in the recruitment of invertebrates between different colour panels and the panels exposed to light and shade. Higher densities of invertebrates were observed on the panels exposed to shade but the bryozoans abundance was high on the panels exposed to light. Tube worms and bryozoans preferred blue colour panels and the abundance of barnacles and bivalves were high on red colour panels. Significant interaction between substrate colour and light was observed in the abundance of barnacles, tube worms, bivalves and bryozoans. In conclusion, this study indicated the ability of some marine invertebrate larvae to discriminate coloured substrates depending on the light intensity.
This is a preview of subscription content, log in via an institution to check access.
Similar content being viewed by others
Availability of data and materials
All data generated or analysed during this study are available from the corresponding author on reasonable request.
References
Al-Saafani, M. A., Al-Raddadi, T. M., & Al-Barakati, A. M. (2017). Seasonal variability of hydrographic structure in Sharm Obhur and water exchange with the Red Sea. Arabian Journal of Geosciences , 10, 315.
Baker, P., & Mann, R. L. (1998). Response of settling oyster larvae, Crassostrea virginica, to specific portions of the visible light spectrum. Journal of Shellfish Research, 17(4), 1081.
Balazy, P., Copeland, U., & Sokołowski, A. (2019). Shipwrecks and underwater objects of the southern Baltic—Hard substrata islands in the brackish, soft bottom marine environment. Estuarine, Coastal and Shelf Science, 225, 106240. https://doi.org/10.1016/j.ecss.2019.05.022.
Baxter, G. T., & Morse, D. E. (1992). Cilia from abalone larvae contain a receptor-dependent g protein transduction system similar to that in mammals. Biological Bulletin, 83, 147–154.
Bers, A. V., & Wahl, M. (2004). The influence of natural surface microtopographies on fouling. Biofouling, 20, 43–51.
Blockley, D. J., & Chapman, M. G. (2006). Recruitment determines differences between assemblages on shaded or unshaded seawalls. Marine Ecology Progress Series, 327, 27–36.
Burke, R. D. (1983). The induction of metamorphosis of marine invertebrate larvae: Stimulus and response. Canadian Journal of Zoology, 61, 1701–1719.
Cahill, A. E., & Koury, S. A. (2016). Larval settlement and metamorphosis in a marine gastropod in response to multiple conspecific cues. PeerJ, 4, 2295.
Carlson, R. L., Shulman, M. J., & Ellis, J. C. (2006). Factors contributing to spatial heterogeneity in the abundance of the common periwinkle Littorina littorea (L.). Journal of Molluscan Studies, 72, 149–156.
Coyer, J. A., Ambrose, R. F., Engle, J. M., & Carrol, J. C. (1993). Interactions between corals and algae on a temperate zone rocky reef: mediation by sea urchins. Journal of Experimental Marine Biology and Ecology, 167, 21–37.
Crisp, D. J. (1974). Factors influencing the settlement of marine invertebrate larvae. In P. T. Grant & A. M. Mackie (Eds.), Chemoreception in marine organisms (pp. 177–265). New York: Academic Press.
Davies, T. W., Duffy, J. P., Bennie, J., & Gaston, K. J. (2014). The nature, extent, and ecological implications of marine light pollution. Frontiers in Ecology and the Environment, 12, 347–355.
Dobretsov, S., Abed, R. M., & Voolstra, C. R. (2013). The effect of surface colour on the formation of marine micro and macrofouling communities. Biofouling, 29, 617–627.
Drake, P. T., Edwards, C. A., & Morgan, S. G. (2015). Relationship between larval settlement, alongshore wind stress and surface temperature in a numerical model of the central California coastal circulation. Marine Ecology Progress Series, 537, 71–87.
Ells, V., Filip, N., Bishop, C. D., DeMont, M. E., Smith-Palmer, T., & Wyeth, R. C. (2016). A true test of colour effects on marine invertebrate larval settlement. Journal of Experimental Marine Biology and Ecology, 483, 156–161.
El-rayis, O. A., & Eid, F. M. (1997). Hydrography and water budget of Obhur Creek, Red Sea. JKAU: Marine Sciences, 8, 29–45.
Freckelton, M. L., Nedved, B. T., & Hadfield, M. G. (2017). Induction of invertebrate larval settlement; different bacteria, different mechanisms? Scientific Reports, 7, 42557.
Gebauer, P., Freire, M., Barria, A., & Paschke, K. (2011). Effect of conspecifics density on the settlement of Petrolistheslaevigatus (Decapoda: Porcellanidae). Journal of the Marine Biological Association of the United Kingdom, 91, 1453–1458.
Glasby, T. M. (1999). Interactive effects of shading and proximity to the seafloor on the development of subtidal epibiotic assemblages. Marine Ecology Progress Series, 190, 113–124.
Glasby, T. M., & Connell, S. D. (2001). Orientation and position of substrata have large effects on epibiotic assemblages. Marine Ecology Progress Series, 214, 127–135.
Guenther, M., Gonzalez-Rodriguez, E., Carvalho, W., Rezende, C. E., Mugrabe, G., & Valentin, J. L. (2008). Plankton trophic structure and particulate organic carbon production during a coastal down welling-upwelling cycle. Marine Ecology Progress Series, 363, 109–119.
Hadfield, M. G. (2011). Biofilms and marine invertebrate larvae: What bacteria produce that larvae use to choose settlement sites. Annual Review of Marine Science, 3, 453–470.
Hadfield, M. G., & Paul, V. J. (2001). Natural chemical cues for settlement and metamorphosis of marine invertebrate larvae. In J. B. McClintock & B. J. Baker (Eds.), Marine chemical ecology (pp. 431–461). Florida: CRC Press.
Hibberd, T. Y., & Moore, K. (2009). Field Identification Guide to Heard Island and McDonald Islands Benthic Invertebrates: A Guide for Scientific Observers Aboard Fishing Vessels (1st ed.). Kingston: Australian Antarctic Division and Fisheries Research and Development Corporation.
Hills, J. M., & Thomason, J. C. (1996). A multi-scale analysis of settlement density and pattern dynamics of the barnacle Semibalanusbalanoides. Marine Ecology Progress Series, 138, 103–115.
Jessen, C., Voolstra, C. R., & Wild, C. (2014). Insitu effects of simulated overfishing and eutrophication on settlement of benthic coral reef invertebrates in the Central Red Sea. PeerJ, 2, 339.
Levy, O., Appelbaum, L., Leggat, W., Gothlif, Y., et al. (2007). Light-responsive cryptochromes from a simple multicellular animal, the coral Acropora millepora. Science, 318, 467–470.
Lillis, A., Eggleston, D. B., & Bohnenstiehl, D. R. (2013). Oyster larvae settle in response to habitat-associated underwater sounds. PLoS ONE, 8, 79337.
Lynch, W. F. (1952). Factors influencing metamorphosis of Bugula larvae. Biological Bulletin, 103, 369–383.
Maldonado, M., Durfort, M., McCarthy, D. A., & Young, C. M. (2003). The cellular basis of photobehavior in the tufted parenchymella larva of demosponges. Marine Biology, 143, 427–441.
Maldonado, M., & Young, C. M. (1996). Effects of physical factors on larval behaviour, settlement and recruitment of four tropical demosponges. Marine Ecology Progress Series, 138, 169–180.
Mason, B., Beard, M., & Miller, M. W. (2011). Coral larvae settle at a higher frequency on red surfaces. Coral Reefs, 30(3), 667–676.
Matsumura, K., & Qian, P. Y. (2014). Larval vision contributes to gregarious settlement in barnacles: Adult red fluorescence as a possible visual signal. Journal of Experimental Biology, 217, 743–750.
McCarthy, D. A., Forward, R. B., & Young, C. M. (2002). Ontogeny of phototaxis and geotaxis during larval development of the sabellariid polychaete Phragmatopomalapidosa. Marine Ecology Progress Series, 241, 215–220.
McKinney, F. K., & McKinney, M. J. (1993). Larval behaviour and choice of settlement site: Correlation with environmental distribution pattern in an erect bryozoan. Facies, 29, 119–131.
Miller, R. J., & Etter, R. J. (2008). Shading facilitates sessile invertebrate dominance in the rocky subtidal Gulf of Maine. Ecology, 89, 452–462.
Morello, S. L., & Yund, P. O. (2016). Response of competent blue mussel (Mytilus edulis) larvae to positive and negative settlement cues. Journal of Experimental Marine Biology and Ecology, 480, 8–16.
Mundy, C. N., & Babcock, R. C. (1998). Role of light intensity and spectral quality in coral settlement: Implications for depth-dependent settlement? Journal of Experimental Marine Biology and Ecology, 223, 235–255.
Pardo, L. M., Cardyn, C. S., & Garcés-Vargas, J. (2012). Spatial variation in the environmental control of crab larval settlement in a micro-tidal austral estuary. Helgoland Marine Research, 66, 253–263.
Pomerat, C. M., & Reiner, E. R. (1942). The influence of surface angle and of light on the attachment of barnacles and other sedentary organisms. Biological Bulletin, 82, 14–25.
Raimondi, P., & Morse, A. (2000). The consequences of complex larval behavior in a coral. Ecology, 81, 3193–3211.
Randel, N., & Jékely, G. (2016). Phototaxis and the origin of visual eyes. Philosophical Transactions of the Royal Society of London. Series B, 371, 20150042.
Ricardo, G. F., Jones, R. J., Nordborg, M., & Negri, A. P. (2017). Settlement patterns of the coral Acropora millepora on sediment-laden surfaces. Science of the Total Environment, 609, 277–288.
Ryland, J. S. (1977). Taxes and tropisms of bryozoans. In R. M. Woollacott & R. L. Zimmer (Eds.), Biology of bryozoans (pp. 411–436). New York: Academic press.
Satheesh, S., & Wesley, S. G. (2010). Influence of substratum colour on the recruitment of macrofouling communities. Journal of the Marine Biological Association of the United Kingtom, 90, 941–946.
Satheesh, S., & Wesley, S. G. (2011). Influence of submersion season on the development of test panel biofouling communities in tropical coast. Estuarine, Coastal and Shelf Science, 94, 155–163.
Saunders, R. J., & Connell, S. D. (2001). Interactive effects of shade and surface orientation on the recruitment of spirorbid polychaetes. Austral Ecology, 26, 109–115.
Shanks, A. L. (2009). Barnacle settlement versus recruitment as indicators of larval delivery. I. Effects of post settlement mortality and recruit density. Marine Ecology Progress Series, 385, 205–216.
Siddik, A. A., Al-Sofyani, A. A., Ba-Akdah, M. A., & Satheesh, S. (2019). Invertebrate recruitment on artificial substrates in the Red Sea: Role of substrate type and orientation. Journal of the Marine Biological Association United Kingdom, 99, 741–750.
Strader, M. E., Davies, S. W., & Matz, M. V. (2015). Differential responses of coral larvae to the colour of ambient light guide them to suitable settlement microhabitat. Royal Society Open Science, 2, 150358.
Su, Z., Huang, L., Yan, Y., & Li, H. (2007). The effect of different substrates on pearl oyster Pinctada martensii (Dunker) larvae settlement. Aquaculture, 271, 377–383.
Svane, I., & Dolmer, P. (1995). Perception of light at settlement: a comparative study of two invertebrate larvae, a scyphozoan planula and a simple ascidian tadpole. Journal of Experimental Marine Biology and Ecology, 187, 51–61.
Swain, G., Herpe, S., Ralston, E., & Tribou, M. (2006). Short-term testing of antifouling surfaces: The importance of colour. Biofouling, 22, 425–429.
Thorson, G. (1964). Light as an ecological factor in the dispersal and settlement of larvae of marine bottom invertebrates. Ophelia, 1, 167–208.
Underwood, A. J., & Keough, M. J. (1980). Supply-side ecology: the nature and consequences of variations in recruitment of intertidal organisms. In M. Hay, S. Gaines, & M. Bertness (Eds.), Marine community ecology (pp. 183–200). Sunderland: Sinauer Associates.
Verran, J., & Boyd, R. D. (2001). The relationship between substratum surface roughness and organic soiling: A review. Biofouling, 17, 59–71.
Wendt, D. E., & Woollacott, R. M. (1999). Ontogenies of phototactic behavior and metamorphic competence in larvae of three species of Bugula (Bryozoa). Invertebrate Biology, 118(1), 75–84.
Whalan, S., Ettinger-Epstein, P., & de Nys, R. (2008). The effect of temperature on larval pre-settlement duration and metamorphosis for the sponge, Rhopaloeidesodorabile. Coral Reefs, 27, 783–786.
Whalan, S., Wahab, M. A. A., Sprungala, S., Poole, A. J., et al. (2015). Larval settlement: the role of surface topography for sessile coral reef invertebrates. PLoS ONE, 10, 0117675.
Wisely, B. (1958). The settling and some experimental reactions of a bryozoan larva, watersiporacucullata (busk). Australian Journal of the Marine and Freshwater Research, 9, 362–371.
Young, C. M., & Chia, F. S. (1984). Microhabitat-associated variability in survival and growth of subtidal solitary ascidians during the first 21 days after settlement. Marine Biology, 81, 61–68.
Young, C. M., & Chia, F. S. (1987). Abundance and distribution of pelagic larvae as influenced by predation, behavior, and hydrographic factors. In A. C. Giese, J. S. Pearse, & V. B. Pearse (Eds.), Reproduction of marine invertebrates (pp. 385–463). Palo Alto: Blackwell Scientific Publications.
Zhao, B., & Qian, P. Y. (2002). Larval settlement and metamorphosis in the slipper limpet crepidula onyx (Sowerby) in response to conspecific cues and the cues from biofilm. Journal of Experimental Marine Biology and Ecology, 269, 39–51.
Acknowledgements
Not applicable
Funding
This project was funded by the Deanship of Scientific Research (DSR), King Abdulaziz University, Jeddah, under grant No. (D-011–150-1440). The authors, therefore, gratefully acknowledge the DSR for technical and financial support.
Author information
Authors and Affiliations
Contributions
AAS carried out the experiments and wrote the manuscript. SS conceptualized the study, designed the methodology, analysed the data set and edited the final draft. All authors read and approved the final manuscript.
Corresponding author
Ethics declarations
Conflict of interest
The authors declare that they have no competing interests.
Supplementary Information
Below is the link to the electronic supplementary material.
Rights and permissions
About this article
Cite this article
Siddik, A.A., Satheesh, S. Interactive effects of light and substrate colour on the recruitment of marine invertebrates on artificial materials. COMMUNITY ECOLOGY 22, 69–78 (2021). https://doi.org/10.1007/s42974-020-00037-0
Received:
Accepted:
Published:
Issue Date:
DOI: https://doi.org/10.1007/s42974-020-00037-0