James L. Wee

Production of the taste/odor-causing compound, trans-2, cis-6 nonadienal, within the Synurophyceae

Although several species of the Synurophyceae have been associated with taste and odor problems in potable water supplies, electron microscopic-based field studies linked problematic blooms only toSynura petersenii Korshikov. Eventually, the organic compoundtrans-2,cis-6-nonadienal was implicated to cause the associated ‘cucumberlike’ odors. The objective of this study was to survey unialgal cultures of various Synurophycean species for the occurrence oftrans-2,cis-6-nonadienal. The compound was detected throughout a 24-day growth assay with aS. petersenii isolate, but was not detected in an identical assay withSynura sphagnicola (Korshikov) Korshikov. In separate 24-day cultures,trans-2,cis-6-nonadienal was detected in two isolates from theS. petersenii species complex, but was not detected in isolates of twoMallomonas or fourSynura taxa not from theS. petersenii complex. These results support the hypothesis that production oftrans-2,cis-6-nonadienal is unique to taxa within theS. petersenii complex. When contrast-enhancing optics and specific specimen preparation techniques are employed, light microscopy can be used to distinguish taxa in theS. petersenii complex from all other Synurophycean taxa. These methods are suggested as an efficient way to monitortrans-2,cis-6-nonadienal-producing taxa in potable water supplies.

Scale biogenesis in Synurophycean protists: phylogenetic implications

Abstract The Synurophyceae is a class of golden-brown, freshwater, photosynthetic flagellates with a world-wide distribution. A well-developed taxonomy exists where genera and species are distinguished by colony or cell morphology or by the siliceous scales that cover the cells. However, phylogenetic relationships within the class are poorly understood, and incongruous taxonomic concepts occur. This study reviews scale morphology from field-collected samples and controlled culturing experiments as well as from studies of scale biogenesis. The information is used to identify homologous silicification surfaces among taxa and to document the diversity of the resulting scale structures. Thirty-two character states are coded into 11 characters in a cladistic analysis of 13 pivotal taxa. Colonial species are emphasized. One most-parsimonious phylogenetic tree is found (HI = 0, CI = 1). Synura lapponica is shown to be most closely related to Tessellaria volvocina. S. sphagnicola emerges at the base of the tree. ...

A STATISTICAL CHARACTERIZATION OF GROWTH AMONG CLONES OF SYNURA PETERSENII (SYNUROPHYCEAE)1

Each of four clones from the Synura petersenii complex was grown at different pHs (5.5, 6.5, 7.5, 8.5) in batch culture experiments. Growth response curves and exponential growth rates were compared among clones and pH treatments in order to examine growth trend variation among the clonal groups. The clones were isolated from geographically distant North American localities. The clonal groups represented distinct mating types, an isolate and its subisolate, and S. petersenii‐ and S. glabra‐like scale morphologies. No consistent relationship existed between growth response curve, and culture medium pH. Additionally, the trends across time differed according to clone and pH combination. Pairwise comparisons of linear trends from transformed growth response curves indicated two distinct clonal associations. Although the clonal associations corresponded with the final cell density of the cultures, growth response curves did not correspond with mating type, the parent‐isolate and subisolate, or scale morphology. Clones with glabra‐like scales had greater growth rates than the clone with petersenii‐like scales. The conflicting results generated from growth response curve and growth rate analyses support the concept that S. petersenii and S. glabra form a highly variable, homogeneous grouping.

Investigating the comparative biology of the heterokonts with nucleic acids

During the last decade investigations of heterokont protists utilizing molecular methods have challenged established biosystematic concepts. Most investigations emphasized the chloroplast genome or sequences from nuclear‐encoded, ribosomal genes. Refinement of DNA isolation protocols, advent of “universal primers” and the polymerase chain reaction, automated sequencing and increased accessibility of DNA sequence databases have expanded data‐gathering efficiency and increased dataset sizes. Because independent datasets have been easier to obtain, the testing of specific phylogenetic hypotheses has been facilitated, altering relationship concepts, primarily at phylum/class levels, and perceptions of cellular evolution. New approaches have emphasized ecological studies and extended studies to genus/species levels and poorly investigated genomes. This paper reviews studies documenting these impacts and identifies some current limitations. Additionally, new DNA sequence data from our laboratory on nuclear‐encoded rDNA internal transcribed spacers and the chloroplast‐encoded psb A gene suggest that these regions will provide taxonomic resolution for the Synu‐rophyceae, at the class/order level and subspecies level, respectively.

PARTIAL CHARACTERIZATION OF THE CHLOROPLAST GENOME FROM THE CHROMOPHYTIC ALGA SYNURA PETERSENII (SYNUROPHYCEAE)1

Hoechst dye 33258‐CsCl density gradients were used to isolate two satellite DNA species from Synura petersenii Korsh. sensu lato, a member of the Synurophyceae. One satellite DNA was identified as the chloroplast genome. The chloroplast genome is the smallest (91.5 kb) published for any chromophyte and approximates the size of the smallest functional chlorophyte chloroplast genome (Codium fragile, 89 kb). The second satellite DNA was small (34.5 kb), and its origin is undetermined. The potential of using the S. petersenii chloroplast genome in comparative studies for evaluating organellar evolution and algal systematics is discussed.

CCM8: the eighth international symposium on inorganic carbon uptake by aquatic photosynthetic organisms.

The articles in this special issue of Photosynthesis Research arose from the presentations given at the Eighth International Symposium on Inorganic Carbon Uptake by Aquatic Photosynthetic Organisms held from May 27 to June 1, 2013 in New Orleans, Louisiana USA. The meeting covered all the aspects of CO2 concentrating mechanisms (CCMs) present in photosynthetic bacteria, microalgae and macrophytes, and spanned disciplines from the molecular biology of CCMs to the importance of CCMs in aquatic ecosystems. The publications in this special issue represent our current understanding of CCMs and highlight recent advances in the field. The influences of CCMs on algal biofuel production as well as recent efforts to use the CCM to improve crop plants are also explored.