Abstract
When diatoms undergo vegetative cell division the new siliceous wall components are slightly smaller than those of the parent because they are produced within the confines of the parent wall. Thus, with continued growth the mean size of cells in a population declines. Given this unique feature of diatom cell division, if the growth of a species in a lake increases (decreases) under more (less) favorable conditions, then the mean size of the resulting population will decline (increase). Numerous paleolimnological investigations rely on shifts in the relative abundances of diatom species over time to infer lake conditions. Although relative abundance data yield information about the dominance of species in the community, they do not necessarily provide evidence about growth of a given species. For instance, a species could have increased in growth, but simply to a lesser extent than other taxa, resulting in a decline in relative abundance. In a similar fashion, relative abundance values can be misleading when used to infer environmental change, such as trophic status change in lakes. We propose that including data on mean size of diatom valves can yield greater insight into changes in growth and improve observations and conclusions based on relative abundance data. To test this concept, we examined changes in the mean diameter of Aulacoseira ambigua (Grunow) Simonsen valves relative to known shifts in lake trophic status in a core from Bantam Lake, Connecticut, representing ~ 130 years of sediment accumulation. The mean valve diameter of A. ambigua declined from 9.7 to 7.6 µm, with the largest declines clearly tracking significant increases in trophic status. We conclude that changes in the mean size of diatom frustules over time can provide valuable information for understanding long-term environmental changes.
This is a preview of subscription content, log in via an institution to check access.
Similar content being viewed by others
References
Anderson MJ, Gorley RN, Clarke KR (2008) Permanova + for primer: guide to software and statistical methods. PRIMER-E, Plymouth, UK
Appleby PG, Oldfield F (1978) The calculation of lead-210 dates assuming a constant rate of supply of unsupported 210Pb to the sediment. Catena 5:1–8
Aquatic Ecosystem Research (AER) LLC (2020) Bantam lake: 2018–2019 water quality monitoring. Prepared for the Bantam Lake Protective Association, Morris, CT
Barber A, Siver PA, Karis W (2013) Euglyphid testate amoebae (Rhizaria: Euglyphida) from an arctic Eocene waterbody: evidence of evolutionary stasis in plate morphology for over 40 million years. Protist 164:541–555
Battarbee RW (1986) Diatom analysis. In: Berglund BE (ed) Handbook of holocene paleoecology and paleohydrology. John Wiley and Sons Ltd, Chichester, pp 527–570
Boeff KA, Strock KE, Saros JE (2016) Evaluating planktonic diatom response to climate change across three lakes with differing morphometry. J Paleolimnol 56:33–47
Brown RE, Nelson SJ, Saros JE (2017) Paleolimnological evidence of the consequences of recent increased dissolved organic carbon (DOC) in lakes of the northeastern USA. J Paleolimnol 57:19–35. https://doi.org/10.1007/s10933-016-9913-3
Canavan R, Siver PA (1995) Connecticut Lakes: A Study of the Chemical and Physical Properties of Fifty-six Connecticut Lakes. Connecticut College Arboretum
Chen G, Dalton C, Leira M, Taylor D (2008) Diatom-based total phosphorus (TP) and pH transfer functions for the Irish Ecoregion. J Paleolimnol 40:143–163
Clarke KR, Warwick RM (2001) Change in marine communities: an approach to statistical analysis and interpretation, 2nd edn. PRIMER-E, Plymouth, UK
Cornett RJ, Chant L, Link D (1984) Sedimentation of Pb-210 in Laurentian Shield Lakes. Wat Pollut Res J Can 19:97–109
Deevey ES Jr (1940) Limnological studies in Connecticut. V. A contribution to regional limnology. Am J Sci 238:717–741
Finkelstein SA, Bunbury J, Gajewski K, Wolfe AP, Adams JK, Devlin JE (2014) Evaluating diatom-derived Holocene pH reconstructions for Arctic lakes using an expanded 171 lake training set. J Quat Sci 29:249–260
Frink CR, Norvell WA (1984) Chemical and physical properties of Connecticut lakes. Conn Agric Exp Stat Bull p 817
Glew JR (1988) A new trigger mechanism for sediment samplers. J Paleolimnol 2:241–243
Glew JR (1989) A portable extruding device for close interval sectioning of unconsolidated core samples. J Paleolimnol 1:225–239
Hall RI, Smol JP (2010) Diatoms as indicators of lake eutrophication. In: Smol JP, Stoermer EF (eds) The diatoms: applications for the environmental and earth sciences. Cambridge University Press, Cambridge, pp 122–151
Houk V (2003) Atlas of freshwater centric diatoms with a brief key and descriptions. Part I. Melosiraceae, Orthoseiraceae, Paraliaceae and Aulacoseiraceae. Fottea, Olomouc 7:85–255
Houk V, Klee R (2007) Atlas of freshwater centric diatoms with a brief key and descriptions. Part II. Melosiraceae and Aulacoseiraceae (Supplement to Part I). Czech Phycol Suppl 1:1–112
Jewson DH (1992) Size reduction, reproductive strategy and the life cycle of a centric diatom. Philos T Roy Soc B 336:191–213
Kaland PE, Stabell B (1981) Methods for absolute diatom frequency analysis and combined diatom and pollen analysis in sediments. Nordic J Bot 1:697–700
Laws RA (1983) Preparing strewn slides for quantitative microfossil analysis: A test using calibrated microspheres. Micropaleont 29:60–65
Line JM, Birks HJB (1990) WACALIB version 2.1 – a computer program to reconstruct environmental variables from fossil assemblages by weighted averaging. J Paleolimnol 3:170–173
Marsicano LJ, Siver PA (1993) A paleolimnological assessment of lake acidification in five Connecticut lakes. J Paleolimnol 9:209–221
Reynolds CS (2006) The ecology of phytoplankton. Cambridge University Press, Cambridge
Riedinger-Whitmore MA, Whitmore TJ, Smoak JM, Brenner M, Moore A, Curtis J, Schelske CL (2005) Cyanobacterial proliferation is a recent response to eutrophication in many Florida lakes: A paleolimnological assessment. Lake Reserv Manag 21:423–435
Round FE, Crawford RM, Mann DG (1990) The diatoms - morphology and biology of the genera. Cambridge University Press, Cambridge
Saros JE, Stone JR, Pederson GT, Slemmons KEH, Spanbauer T, Schliep A, Cahl D, Williamson CE, Engstrom DR (2012) Climate-induced changes in lake ecosystem structure inferred from coupled neo- and paleoecological approaches. Ecology 93:2155–2164
Siver PA (1992) Assessing historical conditions of Bantam Lake, Connecticut, using a paleolimnological technique. Report to the Town of Morris, Connecticut
Siver PA (1999) Development of paleolimnological inference models for pH, total nitrogen and specific conductivity based on planktonic diatoms. J Paleolimnol 21:45–59
Siver PA, Hamilton PB (2011) Diatoms of North America: the freshwater flora of the Atlantic coastal plain. Iconographia Diatomologica 22:1–920
Siver PA, Kling H (1997) Morphological observations of Aulacoseira using scanning electron microscopy. Can J Bot 75:1807–1835
Siver PA, Marsicano LJ (1996) Inferring lake trophic status using scaled chrysophytes. In: Kristiansen J, Cronberg G (eds) Chrysophytes: progress and New Horizons. Beihefte zur Nova Hedwigia. vol 114, pp 233–246
Siver PA, Canavan RW IV, Field C, Marsicano LJ, Lott AM (1996) Historical changes in Connecticut lakes over a 55 year period. J Environ Qual 25:334–345
Siver PA, Lott AM, Cash E, Moss J, Marsicano LJ (1999) Century changes in Connecticut, U.S.A., lakes as inferred from siliceous algal remains and their relationship to land-use changes. Limnol Oceanogr 44:1928–1935
Siver PA, Wolfe AP, Edlund MB, Sibley J, Hausman J, Torres P, Lott AM (2019) Aulacoseira giraffensis (Bacillariophyceae), a new diatom species forming massive populations in an Eocene lake. Plant Ecol Evol 152:358–367
Smol JP, Stoermer EF (eds) (2010) The diatoms: applications for the environmental and earth sciences. Cambridge University Press, Cambridge
ter Braak CJF (1990) CANOCO – a Fortran program for canonical community ordination. Microcomputer Power, Ithaca, New York, USA
Whitmore TJ, Lauterman FM, Smithand KE, Riedinger-Whitmore MA (2015) Limnetic total phosphorus transfer functions for lake management: considerations about their design, use, and effectiveness. Front Ecol Evol 3:107
Yang JR, Pick FR, Hamilton PB (1996) Changes in the planktonic diatom flora of a large mountain lake in response to fertilization. J Phycol 32:232–243
Acknowledgements
This project was funded, in part, with grants to PAS from the National Science Foundation (EAR-1725265 and EAR-1940070). We thank David Jewson for helpful discussions, Josh Hausman for assistance in the laboratory, and special thanks to William Henley of AER for producing the map. Comments made by two external reviewers greatly improved the manuscript.
Author information
Authors and Affiliations
Corresponding author
Additional information
Publisher's Note
Springer Nature remains neutral with regard to jurisdictional claims in published maps and institutional affiliations.
Supplementary Information
Below is the link to the electronic supplementary material.
Rights and permissions
About this article
Cite this article
Siver, P.A., Sibley, J., Lott, AM. et al. Temporal changes in diatom valve diameter indicate shifts in lake trophic status. J Paleolimnol 66, 127–140 (2021). https://doi.org/10.1007/s10933-021-00192-y
Received:
Accepted:
Published:
Issue Date:
DOI: https://doi.org/10.1007/s10933-021-00192-y