Simultaneous detection of harmful algae by multiple polymerase chain reaction coupled with reverse dot blot hybridization

• Taxonomic probes of six harmful algae were designed and their specificity was confirmed by dot blot hybridization.
• The established multiple PCR coupled with reverse dot blot hybridization (MPCRDBH) demonstrated a detection limit of 0.6 cell.
• MPCRDBH could recover all target species and was not affected by background DNA.
• MPCRDBH also demonstrated a stable detection performance for fixative (acidic Lugol's solution)-preserved samples over 30 d.
• MPCRDBH applicability was assessed and proven effective for parallel detection of target microalgae in the field samples.

Harmful algal blooms (HABs) caused by microscopic algae present a threat to human health, ecosystem, fishery, tourism, and aquaculture worldwide. HAB warning and monitoring projects require a simple and rapid method for accurate parallel identification of causative algae. This study presents a useful method for simultaneous detection of harmful algae by multiple PCR coupled with reverse dot blot hybridization (MPCRDBH). A variety of probes, including positive, negative, and specific, were first developed by sequencing and consequent sequence analysis of large subunit rDNA D1–D2 from target species and used for specificity test by blot hybridization. The MPCRDBH assay mainly included five steps: (1) microalgal DNA isolation; (2) amplification and labeling of target DNA by multiple PCR; (3) probe tailing and fixation onto positively charged nylon membrane; (4) reverse dot blot hybridization; and (5) hybridization signal recognition by naked eyes. The reverse dot blot hybridization conditions were optimized, and the appropriate parameters were as follows: ultraviolet cross-linking time, 0.5 min; probe density, 2 μM; Dig-labeled PCR product density, 200 ng; hybridization time and temperature, 2 h and 42 °C; and washing time and temperature, 2 × 5 min and 47 °C. Sensitivity tests showed that MPCRDBH demonstrated a detection limit of 0.6 cell. MPCRDBH recovered all target species and was not affected by background DNA. MPCRDBH also demonstrated a stable detection performance for fixative (acidic Lugol's solution)-preserved samples over 30 d using simulated field samples. MPCRDBH applicability was assessed and proven effective for parallel detection of target microalgae in the field samples. The developed MPCRDBH exhibited a simple membrane-based DNA array preparation and hybridization signal recognition compared with other current DNA arrays. The assay presented in this study is specific and sensitive for parallel detection of microalgae, with stable performance. Therefore, this assay is promising for field monitoring of natural samples.