Integrated method for single-cell DNA extraction, PCR amplification, and sequencing of ribosomal DNA from harmful dinoflagellates Cochlodinium polykrikoides and Alexandrium catenella

A simplified technique was developed for DNA sequence-based diagnosis of harmful dinoflagellate species. This protocol integrates procedures for DNA extraction and polymerase chain reaction (PCR) amplification into a single tube. DNA sequencing reactions were performed directly, using unpurified PCR products as the DNA template for subsequent sequencing reactions. PCR reactions using DNA extracted from single cells of Cocodinium polykrikoides and Alexandrium catenella successfully amplified the target ribosomal DNA regions. DNA sequencing of the unpurified PCR products showed that DNA sequences corresponded to the expected locus of ribosomal DNA regions of both A. catenella and C. polykrikoides (each zero genetic distance and 100% sequence similarity). Using the protocol described in this article, there was little DNA loss during the purification step, and the technique was found to be rapid and inexpensive. This protocol clearly resolves the taxonomic ambiguities of closely related algal species (such as Alexandrium and Cochlodinium), and it constitutes a significant breakthrough for the molecular analysis of nonculturable dinoflagellate species.     

Purification and cDNA cloning of a cecropin-like peptide from the great wax moth, Galleria mellonella

A cecropin-like antimicrobial peptide, Gm cecropin, was purified from hemolymph of larvae of the wax moth, Galleria mellonella, immunized against E. coli, and its antibacterial activity was examined in a radial diffusion assay. The molecular mass of Gm cecropin was 4,160.69 Da by matrix-assisted laser desorption ionization-time-of-flight mass spectrometry analysis. The full-length cDNA of the Gm cecropin precursor was cloned by a combination of RT-PCR, based on the N-terminal sequence obtained by Edman degradation, and 5'-RACE-PCR. Analysis of the cDNA showed that cecropin is synthesized as a prepropeptide, with a putative 22-residue signal peptide, a 4-residue propeptide and a 39-residue mature peptide with a calculated mass of 4,344.18 Da the difference between the calculated and measured masses suggests that Gm cecropin is a 37-residue peptide generated by removal of the C-terminal residue and amidation.     

A genotype-specific pollen gene associated with self-incompatibility in Lycopersicon peruvianum

Self-incompatibility is a genetically controlled process used to prevent self-pollination. We report here the characterization of pollen cDNA clones of Lycopersicon peruvianum, and the identification of a genotype-specific pollen factor involved in self-incompatibility. To identify the latter, differential mRNA display RT-PCR was performed on pollen cDNAs from S12Sa and S11Sa genotypes. We isolated four cDNA fragments expressed preferentially in S12Sa pollen, and screened a cDNA library from S12Sa pollen with the four cDNA fragments to isolate the corresponding full length cDNAs. One of the four isolated cDNAs encoded part of an actin depolymerizing factor protein that we named LpADF. LpADF is highly homologous to actin depolymerizing factors of Arabidopsis thaliana, Lilium longiflorum, and Zea mays. RNA blot analysis revealed that LpADF is only expressed in mature pollen of the S12Sa genotype, and is therefore a candidate pollen factor in the gametophyte self-incompatibility system of L. peruvianum.     

Cloning, expression, and complementation test of the RNA lariat debranching enzyme cDNA from mouse

The RNA lariat debranching enzyme of mouse (mDBR1) was cloned by screening a NIH/3T3 cDNA library. The sequence of full-length mDBR1 cDNA contained a single 515 amino acid open reading frame of 58 kDa protein. Comparison of the amino acid sequence of mDBR1 to other DBR proteins showed 40%, 44%, 43%, 42%, and 80% identity to Saccharomyces cerevisiae, Schizosaccharomyces pombe, Caenorhabditis elegans, Drosophila melanogaster, and human debranching enzymes, respectively. The mDBR1 cDNA was shown to be functional in an interspecies specific complementation experiment, and an in vitro debranching enzyme assay. Mouse DBR1 could complement the intron accumulation phenotype of a S. cerevisiae dbrl null mutant strain. However, the level of complementation depended on the copy number of the mDBR1 cDNA. The integration of the mDBR1 cDNA in the chromosome of S. pombe also complemented both intron accumulation and slow growth phenotypes of the S. pombe dbr1 knock-out mutant strain.