Development of microsatellite markers in the marine phytoplankton Karenia mikimotoi (Dinophyceae)

Effects of ocean acidification and phosphate limitation on physiology and toxicity of the dinoflagellate Karenia mikimotoi

This work demonstrated a 10-day batch culture experiment to test the physiology and toxicity of harmful dinoflagellate Karenia mikimotoi in response to ocean acidification (OA) under two different phosphate concentrations. Cells were previously acclimated in OA (pH = 7.8 and CO₂ = 1100 μatm) condition for about three months before testing the responses of K. mikimotoi cells to a two-factorial combinations experimentation. This work measured the variation in physiological parameters (growth, rETR) and toxicity (hemolytic activity and its toxicity to zebrafish embryos) in four treatments, representing two factorial combinations of CO₂ (450 and 1100 μatm) and phosphate concentration (37.75 and 4.67 umol l^-1). Results: OA stimulated the faster growth, and the highest rETR_max in high phosphate (HP) treatment, low phosphate (LP) and a combination of high CO₂ and low phosphate (HC*LP) inhibited the growth and E_k in comparison to low CO₂*high phosphate (LCHP) treatment. The embryotoxicity of K. mikimotoi cells enhanced in all high CO₂ (HC) conditions irrespective of phosphate concentration, but the EC₅₀ of hemolytic activity increased in all high CO₂ (HC) and low phosphate (LP) treatments in comparison of LCHP. Ocean acidification (high CO₂ and lower pH) was probably the main factor that affected the rETR_max, hemolytic activity and embryotoxicity, but low phosphate was the main factor that affected the growth, α, and E_k. There were significant interactive effects of OA and low phosphate (LP) on growth, rETR_max, and hemolytic activity, but there were no significant effects on α, E_k, and embryotoxicity. If these results are extrapolated to the aquatic environment, it can be hypothesized that the K. mikimotoi cells were impacted significantly by future changing ocean (e.g., ocean acidification and nutrient stoichiometry).

Easy detection of multiple Alexandrium species using DNA chromatography chip

In this study, the Kaneka DNA chromatography chip (KDCC) for the Alexandrium species was successfully developed for simultaneous detection of five Alexandrium species. This method utilizes a DNA-DNA hybridization technology. In the PCR process, specifically designed tagged-primers are used, i.e. a forward primer consisting of a tag domain, which can conjugate with gold nanocolloids on the chip, and a primer domain, which can anneal/amplify the target sequence. However, the reverse primer consists of a tag domain, which can hybridize to the solid-phased capture probe on the chip, and a primer domain, which can anneal/amplify the target sequence. As a result, a red line that originates from gold nanocolloids appears as a positive signal on the chip, and the amplicon is detected visually by the naked eye. This technique is simple, because it is possible to visually detect the target species soon after (<5min) the application of 2μL of PCR amplicon and 65μL of development buffer to the sample pad of the chip. Further, this technique is relatively inexpensive and does not require expensive laboratory equipment, such as real-time Q-PCR machines or DNA microarray detectors, but a thermal cycler. Regarding the detection limit of KDCC for the five Alexandrium species, it varied among species and it was <0.1-10pg and equivalent to 5-500 copies of rRNA genes, indicating that the technique is sensitive enough for practical use to detect several cells of the target species from 1L of seawater. The detection sensitivity of KDCC was also evaluated with two different techniques, i.e. a multiplex-PCR and a digital DNA hybridization by digital DNA chip analyzer (DDCA), using natural plankton assemblages. There was no significant difference in the detection sensitivity among the three techniques, suggesting KDCC can be readily used to monitor the HAB species.

KARENIA: The biology and ecology of a toxic genus

Karenia is a genus containing at least 12 species of marine unarmored dinoflagellates. Species of the genus can be found throughout the world in both oceanic and coastal waters. They are usually sparse in abundance, but occasionally form large blooms in coastal waters. Most Karenia species produce a variety of toxins that can kill fish and other marine organisms when they bloom. In addition to toxicity, some Karenia blooms cause animal mortalities through the generation of anoxia. At least one species, K. brevis, produces brevetoxin that not only kills fish, marine mammals, and other animals, but also causes Neurotoxic Shellfish Poisoning and respiratory distress in humans. The lipid soluble brevetoxin can biomagnify up the food chain through fish to top carnivores like dolphins, killing them. Karenia dinoflagellates are slow growers, so physical concentrating mechanisms are probably important for the development of blooms. The blooms are highly sporadic in both time and space, although most tend to occur in summer or fall months in frontal regions. At the present time, our understanding of the causes of the blooms and ability to predict them is poor. Given the recent discovery of new species, it is likely that new Karenia species and toxins will be discovered in the future.

DEVELOPMENT OF A MULTIPLEX PCR ASSAY FOR SIMULTANEOUS DETECTION OF SIX ALEXANDRIUM SPECIES (DINOPHYCEAE)1

In Japan, the bloom seasons of two toxic species, namely, Alexandrium catenella (Whedon et Kof.) Balech and Alexandrium tamiyavanichii Balech, sometimes overlap with those of three nontoxic Alexandrium species, namely, Alexandrium affine (H. Inouye et Fukuyo) Balech, Alexandrium fraterculus (Balech) Balech, and Alexandrium pseudogoniaulax (Biecheler) T. Horig. ex Y. Kita et Fukuyo. In this study, a multiplex PCR assay has been developed that enables simultaneous detection of six Alexandrium species on the basis of differences in the lengths of the PCR products. The accuracy of the multiplex PCR system was assessed using 101 DNA templates of the six target Alexandrium species and 27 DNA templates of 11 nontarget species (128 DNA templates in total). All amplicons obtained from the 101 DNA templates of the target species were appropriately identified, whereas all 27 DNA templates of the nontarget species were not amplified. Species-specific identification by the multiplex PCR assay was certainly possible from single cells of the target species.

High genetic diversity and fine-scale spatial structure in the marine flagellate Oxyrrhis marina (Dinophyceae) uncovered by microsatellite loci

Free-living marine protists are often assumed to be broadly distributed and genetically homogeneous on large spatial scales. However, an increasing application of highly polymorphic genetic markers (e.g., microsatellites) has provided evidence for high genetic diversity and population structuring on small spatial scales in many free-living protists. Here we characterise a panel of new microsatellite markers for the common marine flagellate Oxyrrhis marina. Nine microsatellite loci were used to assess genotypic diversity at two spatial scales by genotyping 200 isolates of O. marina from 6 broad geographic regions around Great Britain and Ireland; in one region, a single 2 km shore line was sampled intensively to assess fine-scale genetic diversity. Microsatellite loci resolved between 1-6 and 7-23 distinct alleles per region in the least and most variable loci respectively, with corresponding variation in expected heterozygosities (H(e)) of 0.00-0.30 and 0.81-0.93. Across the dataset, genotypic diversity was high with 183 genotypes detected from 200 isolates. Bayesian analysis of population structure supported two model populations. One population was distributed across all sampled regions; the other was confined to the intensively sampled shore, and thus two distinct populations co-occurred at this site. Whilst model-based analysis inferred a single UK-wide population, pairwise regional F(ST) values indicated weak to moderate population sub-division (0.01-0.12), but no clear correlation between spatial and genetic distance was evident. Data presented in this study highlight extensive genetic diversity for O. marina; however, it remains a substantial challenge to uncover the mechanisms that drive genetic diversity in free-living microorganisms.