Laboratory observations
showed that C. fecunda males only grazed on microscopic kelp gametophytes and small (<250 μm) sporophytes, rejecting larger sporophytes, whereas T. atra grazed on all the kelp stages. Recruitment to the C. fecunda treatments far exceeded that to bare rock in the absence of grazers but was not due to the physical presence of C. fecunda shells. We concluded that the key to M. pyrifera recruitment success in southern Chile this website is its capacity to colonize secondary substrates provided by the slipper limpet C. fecunda. “
“Group-II introns are selfish ribozymes that may have given rise to nuclear mRNA introns. Approximately 1,000 of these introns—derived from organelles, bacteria, and archaea—have been defined as either having no open reading frame (ORF) or encoding a single large protein, which is nearly always a variant of a reverse transcriptase-maturase-endonuclease (RT-Mat-En). While investigating intron ribozymes in cold-tolerant Chlamydomonas spp., we discovered an unusually large (3.9 kb) group-II intron in the psbA gene of Chlamydomonas subcaudata N. Wille, Csu.psbA. Reverse transcriptase-PCR (RT-PCR) analysis showed that Csu.psbA is efficiently spliced in vivo and
confirmed the predicted splice sites. The extreme HDAC inhibitor size of Csu.psbA is due to two large ORFs in domain IV of the predicted secondary structure. ORF1 encodes a typical RT-Mat-En protein (70 kDa), although it has an unusual start codon (ACG). ORF2, however, encodes a potentially novel protein (44 kDa)
that is predicted to have a transmembrane domain, immediately following an N-terminal thylakoid-targeting peptide, and to bind nucleic acids. BLAST analyses suggest that both ORFs are of bacterial origin and that ORF2 may have a TRKA domain. Csu.psbA is the first group-II intron reported to have two large, distinct ORFs and raises the possibility of identifying novel intron-encoded functions. “
“Although chlorophyll degradation pathways in higher plants have been well studied, little is known about the mechanisms of chlorophyll degradation in microalgae. In this article, we report the occurrence of a chlorophyll a derivative that has never been selleckchem discovered in photosynthetic organisms. This chlorophyll derivative emits no fluorescence and has a peculiar absorbance peak at 425, 451, 625, and 685 nm. From these features, it was identified as 132,173-cyclopheophorbide a enol (cPPB-aE), reported as a degradation product of chlorophyll a derived from prey algal cells in heterotrophic protists. We discovered cPPB-aE in six benthic photosynthetic dinoflagellates that are phylogenetically separated into four clades based on SSU rDNA molecular phylogeny. This is the first report of this chlorophyll derivative in photosynthetic organisms and we suggest that the derivative is used to quench excess light energy.