Palaeolimnological records provide valuable information about how phytoplankton respond to long-term drivers of environmental change. Traditional palaeolimnological tools such as microfossils and pigments are restricted to taxa that leave sub-fossil remains, and a method that can be applied to the wider community is required. Sedimentary DNA (sedDNA), extracted from lake sediment cores, shows promise in palaeolimnology, but validation against data from long-term monitoring of lake water is necessary to enable its development as a reliable record of past phytoplankton communities. To address this need, 18S rRNA gene amplicon sequencing was carried out on lake sediments from a core collected from Esthwaite Water (English Lake District) spanning ~105 years. This sedDNA record was compared with concurrent long-term microscopy-based monitoring of phytoplankton in the surface water. Broadly comparable trends were observed between the datasets, with respect to the diversity and relative abundance and occurrence of chlorophytes, dinoflagellates, ochrophytes and bacillariophytes. Up to 20% of genera identified in the microscopy record were also detected using sedDNA, and sedDNA revealed a previously undetected community of phytoplankton. However, a substantial proportion of genera identified by microscopy were not detected using sedDNA, highlighting the current limitations of the technique that require further development such as reference database coverage. These results suggest that sedDNA can be used as an effective record of past phytoplankton communities, at least over timescales of less than 100 years, but the taphonomic processes which may affect its reliability, such as the extent and rate of deposition and DNA degradation, require further research.

Macrophyte productivity supports the littoral food web in fresh waters where widespread active CO2 concentrating mechanisms (CCMs) allow their productivity to be maintained despite potential inorganic carbon limitation. We studied HCO3- acquisition, the most common CCM in macrophytes, in the freshwater monocot Ottelia alismoides and showed that the external carbonic anhydrase (CA) inhibitor acetazolamide (AZ) decreases the affinity for CO2 uptake and prevents HCO3- use. The anion exchanger (AE)/solute carrier (SLC) type HCO3- transporters inhibitor 4,4’-diisothio-cyanatostilbene-2,2’-disulfonate (DIDS), has a smaller effect on CO2 uptake but also prevents HCO3- use. Analysis of transcripts showed that putative αCA-1 and SLC4 HCO3- transporters are unaffected by acclimation of leaves to different CO2, in agreement with physiological measurements showing a constitutive HCO3- use. Therefore, it is likely that αCA-1 and SLC4 HCO3- transporters are the targets of AZ and DIDS, respectively. Altogether, these results are consistent with acquisition of HCO3- based on co-diffusion of CO2 and HCO3- through the boundary layer, conversion of HCO3- to CO2 at the plasmalemma by αCA-1 and in addition, transport of HCO3- across the plasmalemma by SLC4 transporters. A model of these processes has been produced that can be used to test inorganic carbon uptake in future experiments.