Hostname: page-component-78c5997874-4rdpn Total loading time: 0 Render date: 2024-11-03T00:57:05.688Z Has data issue: false hasContentIssue false

On the benefits of being redundant: low compositional fidelity of diatom death assemblages does not hamper the preservation of environmental gradients in shallow lakes

Published online by Cambridge University Press:  10 March 2015

Gabriela S. Hassan*
Affiliation:
Instituto de Investigaciones Marinas y Costeras (IIMyC), Consejo Nacional de Investigaciones Científicas y Técnicas – Universidad Nacional de Mar del Plata, Juan B. Justo 2550, B7608FBY Mar del Plata, Argentina. E-mail: [email protected]

Abstract

Comparisons between death assemblages and their source living communities are among the most common actualistic methods of evaluating the preservation of compositional and environmental information in fossil assemblages. Although live-dead studies have commonly focused on marine mollusks, the potential of diatoms to preserve ecological information in continental settings has been overlooked. Thus, little is known about the nature and magnitude of the taphonomic biases affecting live-dead agreement of diatom assemblages, despite their extensive application as modern and fossil bioindicators in paleoecological and paleoenvironmental reconstructions. In this study, I analyzed three live-dead data sets in order to evaluate the compositional and environmental fidelity exhibited by diatom death assemblages in shallow lakes. I find that diatom death assemblages (DAs) do differ significantly in their taxonomic composition from living assemblages (LAs), mainly as a consequence of (1) differences in the temporal resolution between time-averaged DAs and non-averaged LAs, and (2) differential preservation of diatom taxa related to the intrinsic properties of their valves. Despite compositional dissimilarities, DAs were able to capture the same environmental gradients as LAs, with high significance. This decoupling between live-dead agreement in community composition and community response to gradients can be related to the existence of at least two mutually exclusive subsets of species that significantly captured compositional dissimilarities based on the full set of the species in the three lakes. This functional redundancy implies that the between-sample relationships of living assemblages can be significantly preserved by DAs even if some taxa are removed by taphonomic processes. The preservation of environmental gradients thus does not require good preservation of all living taxa. Structural redundancy compensates for the loss of compositional fidelity caused by postmortem processes in the diatom data set.

Type
Articles
Copyright
Copyright © 2015 The Paleontological Society. All rights reserved. 

Access options

Get access to the full version of this content by using one of the access options below. (Log in options will check for institutional or personal access. Content may require purchase if you do not have access.)

References

Literature Cited

Alin, S. R., and Cohen, A. S.. 2004. The live, the dead, and the very dead: taphonomic calibration of the recent record of paleoecological change in Lake Tanganyika, East Africa. Paleobiology 30:4481.2.0.CO;2>CrossRefGoogle Scholar
Anderson, M. J. 2006. Distance-based tests for homogeneity of multivariate dispersions. Biometrics 62:245253.Google Scholar
APHA. 1992. Standard methods for the examination of water and wastewater. American Public Health Association, Washington, D.C.Google Scholar
Austin, H. A., Austin, W. E. N., and Paterson, D. M.. 2005. Extracellular cracking and content removal of the benthic diatom Pleurosigma angulatum (Quekett) by the benthic foraminifera Haynesina germanica (Ehrenberg). Marine Micropaleontology 57:6873.Google Scholar
Baars, J. W. M. 1981. Autecological investigations on marine diatoms. 2. Generation times of 50 species. Hydrobiological Bulletin 15:137151.Google Scholar
Barker, P. 1992. Differential diatom dissolution in Late Quaternary sediments from Lake Manyara, Tanzania: an experimental approach. Journal of Paleolimnology 7:235251.Google Scholar
Behrensmeyer, A. K., Kidwell, S. M., and Gastaldo, R. A.. 2000. Taphonomy and paleobiology. Paleobiology 26:103147.Google Scholar
Bernhard, J. M. 2000. Distinguishing live from dead foraminifera: methods review and proper applications. Micropaleontology 46:3846.Google Scholar
Beyens, L., and Denys, L.. 1982. Problems in diatom analysis of deposits: allochthonous valves and fragmentation. Geologie en Mijnbouw 61:159162.Google Scholar
Carroll, M., Kowalewski, M., Simões, M. G., and Goodfriend, G. A.. 2003. Quantitative estimates of time-averaging in terebratulid brachiopod shell accumulations from a modern tropical shelf. Paleobiology 29:381402.Google Scholar
Clarke, K. R. 1993. Non-parametric multivariate analyses of changes in community structure. Australian Journal of Ecology 18:117143.Google Scholar
Clarke, K. R., and Warwick, R. M.. 1998. Quantifying structural redundancy in ecological communities. Oecologia 113:278289.CrossRefGoogle ScholarPubMed
Edinger, E. N., Pandolfi, J. M., and Kelley, R. A.. 2001. Community structure of Quaternary coral reefs compared with Recent life and death assemblages. Paleobiology 27:669694.Google Scholar
Fay, M. P., and Shaw, P. A.. 2010. Exact and asymptotic weighted log rank tests for interval censored data: the interval R Package. Journal of Statistical Software 36(2):134. http://www.jstatsoft.org/v36/i02/Google Scholar
Feijoó, C. S., and Lombardo, R. J.. 2007. Baseline water quality and macrophyte assemblages in Pampean streams: a regional approach. Water Research 41:13991410.Google Scholar
Flower, R. 1993. Diatom preservation: experiments and observations on dissolution and breakage in modern and fossil material. Hydrobiologia 269–270:473484.CrossRefGoogle Scholar
Flower, R. J., and Nicholson, A. J.. 1987. Relationships between bathymetry, water quality and diatoms in some Hebridean lochs. Freshwater Biology 18:7185.Google Scholar
Flower, R. J., and Ryves, D. B.. 2009. Diatom preservation: differential preservation of sedimentary diatoms in two saline lakes. Acta Botanica Croatica 68:381399.Google Scholar
Gavin, D. G., Oswald, W. W., Wahl, E. R., and Williams, J. W.. 2003. A statistical approach to evaluating distance metrics and analog assignments for pollen records. Quaternary Research 60:356367.Google Scholar
García-Rodríguez, F., Piovano, E., del Puerto, L., Inda, H., Stutz, S., Bracco, R., Panario, D., Córdoba, F., Sylvestre, F., and Ariztegui, D.. 2009. South American lake paleo-records across the Pampean Region. PAGES news 17:115118.CrossRefGoogle Scholar
Gillett, N., Pan, Y., and Parker, C.. 2009. Should only live diatoms be used in the bioassessment of small mountain streams? Hydrobiologia 620:135147.Google Scholar
Greenstein, B. J., and Pandolfi, J. M.. 1997. Preservation of community structure in modern reef coral life and death assemblages of the Florida Keys: implications for the Quaternary fossil record of coral reefs. Bulletin of Marine Science 61:431452.Google Scholar
Haberyan, K. 1985. The role of copepod fecal pellets in the deposition of diatoms in Lake Tanganyika. Limnology and Oceanography 30:10101023.Google Scholar
Hamm, C. E., Merkel, R., Springer, O., Jurkoic, P., Maier, C., Prechtel, K., and Smetacek, V.. 2003. Architecture and material properties of diatom shells provide effective mechanical protection. Nature 421:841843.Google Scholar
Hammer, Ø., Harper, D. A. T., and Ryan, P. D.. 2001. PAST: palaeontological statistics software package for education and data analysis. Paleontologia Electronica 41(1):9 pp.Google Scholar
Hassan, G. S. 2013. Diatom-based reconstruction of Middle to Late Holocene paleoenvironments in Lake Lonkoy, southern Pampas, Argentina. Diatom Research 28:473486.Google Scholar
Hassan, G. S., Espinosa, M. A., and Isla, F. I.. 2008. Fidelity of dead diatom assemblages in estuarine sediments: How much environmental information is preserved? Palaios 23:112120.CrossRefGoogle Scholar
Kidwell, S. M. 2001. Preservation of species abundance in marine death assemblages. Science 294:10911094.Google Scholar
Kidwell, S. M. 2002a. Time-averaged molluscan death assemblages: palimpsests of richness, snapshots of abundance. Geology 30:803806.Google Scholar
Kidwell, S. M. 2002b. Mesh-size effects on the ecological fidelity of death assemblages: a meta-analysis of molluscan live–dead studies. Geobios 35:107119.Google Scholar
Kidwell, S. M. 2013. Time-averaging and fidelity of modern death assemblages: building a taphonomic foundation for conservation palaeobiology. Palaeontology 56:487522.Google Scholar
Kidwell, S. M., and Bosence, D. W. J.. 1991. Taphonomy and time averaging of marine shelly faunas. Pp. 115209in P. A. Allison and D. E. G. Briggs, eds. Taphonomy: releasing the data locked in the fossil record (Topics in Geobiology, Vol. 9). Plenum, New York.Google Scholar
Kidwell, S. M., and Tomašových, A.. 2013. Implications of time-averaged death assemblages for ecology and conservation biology. Annual Review of Ecology, Evolution, and Systematics 44:539563.CrossRefGoogle Scholar
Krause, R. A. Jr., Barbour, S. L., Kowalewski, M., Kaufman, D. S., Romanek, C. S., Simões, M. G., and Wehmiller, J. F.. 2010. Quantitative comparisons and models of time-averaging in bivalve and brachiopod shell accumulations. Paleobiology 36:428452.Google Scholar
Lewin, J. C. 1961. The dissolution of silica from diatom walls. Geochimica et Cosmochimica Acta 21:182198.Google Scholar
Michelson, A. V., and Park, L. E.. 2013. Taphonomic dynamics of lacustrine ostracodes on San Salvador Island, Bahamas: high fidelity and evidence of anthropogenic modification. Palaios 28:129135.Google Scholar
Miller, A. I. 1988. Spatial resolution in subfossil molluscan remains: implications for paleobiological analyses. Paleobiology 14:91103.Google Scholar
Murray, J. W., and Pudsey, C. J.. 2004. Living (stained) and dead foraminifera from the newly ice-free Larsen Ice Shelf, Weddell Sea, Antarctica: ecology and taphonomy. Marine Micropaleontology 53:6781.Google Scholar
Oksanen, J. F., Blanchet, G., Kindt, R., Legendre, P., O’Hara, R. B., Simpson, G. L., Solymos, P., Stevens, M. H. H., and Wagner, H.. 2013. Vegan: community ecology package. R package, Version 2. 07. http://CRAN.R-project.org/package=veganGoogle Scholar
Oppenheim, D. 1987. Frequency distribution studies of epipelic diatoms along an intertidal shore. Helgoländer Meeresuntersuchungen 41:139148.Google Scholar
Overpeck, J. T., Webb, T. III, and Prentice, I. C.. 1985. Quantitative interpretation of fossil pollen spectra: dissimilarity coefficients and the method of modern analogs. Quaternary Research 23:87108.Google Scholar
Owen, B. B., Afzal, M., and Cody, W. R.. 1979. Distinguishing between live and dead diatoms in periphyton communities. In R. L. Wetzel, ed. Methods and measurements of periphyton communities: a review. American Society for Testing and Materials Special Technical Publication 690:70–76.Google Scholar
Pandolfi, J. M., and Minchin, P. R.. 1996. A comparison of taxonomic composition and diversity between reef coral life and death assemblages in Madang Lagoon, Papua New Guinea. Palaeogeography, Palaeoclimatology, Palaeoecology 119:321341.CrossRefGoogle Scholar
Park, L. E., Cohen, A. S., Martens, K., and Bralek, R.. 2003. The impact of taphonomic processes on interpreting paleoecologic changes in large lake ecosystems: ostracodes in Lakes Tanganyika and Malawi. Journal of Paleolimnology 30:127138.Google Scholar
Pryfogle, P. A., and Lowe, R. L.. 1979. Sampling and interpretation of epilithic lotic diatom communities. In R. L. Wetzel, ed. Methods and measurements of periphyton communities: a review. American Society for Testing and Materials Special Technical Publication 690:77–89.Google Scholar
R Development Core Team. 2013. R: a language and environment for statistical computing. R Foundation for Statistical Computing, Vienna. www.R-project.org.Google Scholar
Ryves, D. B., Jewson, D. H., Sturm, M., Battarbee, R. W., Flower, R. J., Mackay, A. W., and Granin, N. G.. 2003. Quantitative and qualitative relationships between planktonic diatom communities and diatom assemblages in sedimenting material and surface sediments in Lake Baikal, Siberia. Limnology and Oceanography 48:16431661.Google Scholar
Ryves, D. B., Battarbee, R., Juggins, S., Fritz, S. C., and Anderson, N. J.. 2006. Physical and chemical predictors of diatom dissolution in freshwater and saline lake sediments in North America and West Greenland. Limnology and Oceanography 51:13551368.Google Scholar
Ryves, D. B., Battarbee, R. W., and Fritz, S. C.. 2009. The dilemma of disappearing diatoms: incorporating diatom dissolution data into palaeoenvironmental modelling and reconstruction. Quaternary Science Reviews 28:120136.CrossRefGoogle Scholar
Ryves, D. B. R., Anderson, N. J., Flower, R., and Rippey, B.. 2013. Diatom taphonomy and silica cycling in two freshwater lakes and their implications for inferring past lake productivity. Journal of Paleolimnology 49:411430.Google Scholar
Sawai, Y. 2001. Distribution of living and dead diatoms in tidal wetlands of northern Japan: relations to taphonomy. Paleogeography, Paleoclimatology, Palaeoecology 173:125141.Google Scholar
Sawai, Y., Jankaew, K., Martin, M. E., Prendergast, A., Choowong, M., and Charoentitirat, T.. 2009. Diatom assemblages in tsunami deposits associated with the 2004 Indian Ocean tsunami at Phra Thong Island, Thailand. Marine Micropaleontology 73:7079.Google Scholar
Scott, D. B., and Medioli, F. S.. 1980. Living vs. total foraminiferal populations: their relative usefulness in paleoecology. Journal of Paleontology 54:814831.Google Scholar
Sims, H. J., and Cassara, J. A.. 2009. The taphonomic fidelity of seed size in fossil assemblages: a live-dead case study. Palaios 24:387393.Google Scholar
Smol, J. P., and Stoermer, E. F.. 2010. The diatoms: applications for the environmental and earth sciences, 2nd ed. Cambridge University Press, Cambridge.Google Scholar
Stanton, R. J. Jr. 1976. Relationship of fossil communities to original communities of living organisms. Pp. 107142in R. W. Scott and R. R. West, eds. Structure and classification of paleocommunities Dowden. Hutchinson and Ross, Stroudsburg, Penn.Google Scholar
Stockner, J. G., and Lund, J. W. G.. 1970. Live algae in postglacial lake deposits. Limnology and Oceanography 15:4158.Google Scholar
Sugita, S. 1994. Pollen representation of vegetation in Quaternary sediments: theory and method in patchy vegetation. Journal of Ecology 82:881897.Google Scholar
Tanimura, Y., Kato, M., Fukusawa, H., Mayama, S., and Yokoyama, K.. 2006. Cytoplasmic masses preserved in early Holocene diatoms: a possible taphonomic process and its paleo-ecological implications. Journal of Phycology 42:270279.Google Scholar
Terry, R. C. 2010a. On raptors and rodents: testing the ecological fidelity and spatiotemporal resolution of cave death assemblages. Paleobiology 36:137160.Google Scholar
Terry, R. C. 2010b. The dead do not lie: using skeletal remains for rapid assessment of historical small-mammal community baselines. Proceedings of the Royal Society of London B 277:11931201.Google Scholar
Tomašových, A. 2004. Postmortem durability and population dynamics affecting the fidelity of brachiopod size-frequency distributions. Palaios 19:477496.Google Scholar
Tomašových, A., and Kidwell, S. M.. 2009a. Fidelity of variation in species composition and diversity partitioning by death assemblages: time-averaging transfers diversity from beta to alpha levels. Paleobiology 35:94118.Google Scholar
Tomašových, A., and Kidwell, S. M.. 2009b. Preservation of spatial and environmental gradients by death assemblages. Paleobiology 35:119145.Google Scholar
Tomašových, A., and Kidwell, S. M.. 2011. Accounting for the effects of biological variability and temporal autocorrelation in assessing the preservation of species abundance. Paleobiology 37:332354.Google Scholar
Van Cappellen, P., Dixit, S., and van Beusekom, J.. 2002. Biogenic silica dissolution in the oceans: Reconciling experimental and field-based dissolution rates. Global Biogeochemical Cycles 16:1075.Google Scholar
Western, D., and Behrensmeyer, A. K.. 2009. Bone assemblages track animal community structure over 40 years in an African savanna ecosystem. Science 324:10611064.Google Scholar
Wetzel, R. G. 2001. Limnology: lake and river ecosystems, 3rd ed. Academic Press, San Diego.Google Scholar
Wilson, C. J., and Holmes, R. W.. 1981. The ecological importance of distinguishing between living and dead diatoms in estuarine sediments. British Phycological Journal 16:345349.Google Scholar
Wolfe, A. P., Edlund, M. B., Sweet, A. R., and Creighton, S. D.. 2006. A first account of organelle preservation in Eocene nonmarine diatoms: observations and paleobiological implications. Palaios 21:298304.Google Scholar
Zhao, Y., Sayer, C., Birks, H., Hughes, M., and Peglar, S.. 2006. Spatial representation of aquatic vegetation by macrofossils and pollen in a small and shallow lake. Journal of Paleolimnology 35:335350.Google Scholar