Tomokazu Yamazaki

Starch and lipid accumulation in eight strains of six Chlorella species under comparatively high light intensity and aeration culture conditions.

The microalgae family Chlorella species are known to accumulate starch and lipids. Although nitrogen or phosphorous deficiencies promote starch and lipids formation in many microalgae, these deficiencies also limit their growth and productivity. Therefore, the Chlorellaceae strains were attempted to increase starch and lipids productivity under high-light-intensity conditions (600-μmol photons m(-2)s(-1)). The 12:12-h light-dark (LD) cycle conditions elicited more stable growth than the continuous light (LL) conditions, whereas the starch and lipids yields increased in LL conditions. The amount of starch and lipids per cell increased in Chlorella viscosa and Chlorella vulgaris in sulfur-deficient medium, and long-chain fatty acids with 20 or more carbon atoms accumulated in cells grown in sulfur-deficient medium. Accumulation of starch and lipids was investigated in eight strains. The accumulation was strain-dependent, and varied according to the medium and light conditions. Five of the eight Chlorella strains exhibited similar accumulation patterns.

Highly efficient lipid production in the green alga Parachlorella kessleri: draft genome and transcriptome endorsed by whole-cell 3D ultrastructure.

BackgroundAlgae have attracted attention as sustainable producers of lipid-containing biomass for food, animal feed, and for biofuels. Parachlorella kessleri, a unicellular green alga belonging to the class Trebouxiophyceae, achieves very high biomass, lipid, and starch productivity levels. However, further biotechnological exploitation has been hampered by a lack of genomic information.ResultsHere, we sequenced the whole genome and transcriptome, and analyzed the behavior of P. kessleri NIES-2152 under lipid production-inducing conditions. The assembly includes 13,057 protein-coding genes in a 62.5-Mbp nuclear genome. Under conditions of sulfur deprivation, lipid accumulation was correlated with the transcriptomic induction of enzymes involved in sulfur metabolism, triacylglycerol (TAG) synthesis, autophagy, and remodeling of light-harvesting complexes.ConclusionsThree-dimensional transmission electron microscopy (3D-TEM) revealed extensive alterations in cellular anatomy accompanying lipid hyperaccumulation. The present 3D-TEM results, together with transcriptomic data support the finding that upregulation of TAG synthesis and autophagy are potential key mediators of the hyperaccumulation of lipids under conditions of nutrient stress.

Molecular divergence and characterization of two chloroplast division genes, FtsZ1 and FtsZ2, in the unicellular green alga Nannochloris bacillaris (Chlorophyta)

Two FtsZ paralogues (NbFtsZ1 and NbFtsZ2) were isolated from the unicellular green alga Nannochloris bacillaris Naumann. These sequences encoded proteins of 435 and 439 amino acids with tubulin signature motifs (GGGTG[T/S]G), which are important for GTP binding activity. NbFtsZ1 and NbFtsZ2 had four and three introns, respectively, and two different putative core promoters; a TATA box (TATAAAA) and an initiator element (CCCAGG) were located 40 bp and 80 bp upstream of the coding regions of NbFtsZ1 and NbFtsZ2, respectively. Southern blot hybridization and contour‐clamped homogeneous electric field electrophoresis showed that N. bacillaris contained at least one copy of each gene and that NbFtsZ1 was located on chromosome 5 and NbFtsZ2 on chromosome 3 or 4. Phylogenetically, NbFtsZ1 and NbFtsZ2 belong to the vascular plant protein families FtsZ1 and FtsZ2, respectively. The FtsZ1 proteins do not contain carboxy‐terminal consensus sequences, whereas all FtsZ2 proteins possess the consensus sequence (I/V)PxFL(R/K)(K/R)(K/R). Our study has shown that NbFtsZ2 possesses a similar consensus sequence (VPDFLRRK), whereas NbFtsZ1 does not, further supporting their classification as FtsZ2 and FtsZ1. Escherichia coli ftsZ mutants transformed with cloned NbFtsZ1, and NbFtsZ2 cDNAs were restored for the capacity to divide by binary fission, suggesting that the proteins retained the ability to function in the bacterium. An anti‐NbFtsZ2 antibody specifically recognized a single protein band of approximately 51 kDa on an immunoblot of N. bacillaris cellular proteins. Immunostaining of the algal cells with this antibody produced an intense fluorescent signal as a ring near the middle of the cell, which corresponded to the chloroplast division site.

Phenotypic spectrum of Parachlorella kessleri (Chlorophyta) mutants produced by heavy-ion irradiation.

Heavy-ion mutagenesis is a technology used for effective production of genetic mutants. This study demonstrates that algal breeding using a unicellular alga, Parachlorella kessleri, by heavy-ion mutagenesis can improve lipid yield in laboratory experiments. The primary screening yielded 23 mutants among which a secondary screening yielded 7 strains, which were subjected to phenotypic assays. P. kessleri strains produced by heavy-ion radiation spanned a broad spectrum of phenotypes that differed in lipid content and fatty acid profiles. Starch grain morphology was distinctively altered in one of the mutants. The growth of strain PK4 was comparable to that of the wild type under stress-free culture conditions, and the mutant also produced large quantities of lipids, a combination of traits that may be of commercial interest. Thus, heavy-ion irradiation is an effective mutagenic agent for microalgae and may have potential in the production of strains with gain-of-function phenotypes.

Isolation of the plastid FtsZ gene from Cyanophora paradoxa (Glaucocystophyceae, Glaucocystophyta)

Plastids of glaucocystophytes are termed cyanelles and retain primitive features, such as a peptidoglycan wall. We isolated a full‐length prokaryotic plastid division gene, FtsZ, from the glaucocystophyte alga Cyanophora paradoxa Korshikov (CpFtsZ‐cy). CpftsZ‐cy has a chloroplast‐targeting signal at the N‐teminus. Immunofluorescence microscopy showed that CpFtsZ‐cy forms a ring‐like structure at the division plane of cyanelles.

Localization and evolution of septins in algae

Septins are a group of GTP-binding proteins that are multi-functional, with a well-known role in cytokinesis in animals and fungi. Although the functions of septins have been thoroughly studied in opisthokonts (fungi and animals), the function and evolution of plant/algal septins are not as well characterized. Here we describe septin localization and expression in the green algae Nannochloris bacillaris and Marvania geminata. The present data suggest that septins localize at the division site when cytokinesis occurs. In addition, we show that septin homologs may be found only in green algae, but not in other major plant lineages, such as land plants, red algae and glaucophytes. We also found other septin homolog-possessing organisms among the diatoms, Rhizaria and cryptomonad/haptophyte lineages. Our study reveals the potential role of algal septins in cytokinesis and/or cell elongation, and confirms that septin genes appear to have been lost in the Plantae lineage, except in some green algae.

Isolation and molecular characterization of rbcS in the unicellular green alga Nannochloris bacillaris (Chlorophyta, Trebouxiophyceae)

The small subunit of the chloroplast enzyme ribulose‐1,5‐bisphosphate carboxyase/oxygenase (Rubisco) is encoded by rbcS. We isolated and characterized three rbcS genes (NbrbcS1‐1, NbrbcS1‐2, and NbrbcS2) from the unicellular green alga Nannochloris bacillaris (Chlorophyta, Trebouxiophyceae). In the haploid N. bacillaris genome, each is a single‐copy gene located on different chromosomes. Each mature peptide contains 140 amino acid residues. NbrbcS1‐1 and NbrbcS1‐2 are identical and share 80% identity with NbrbcS2, while the respective transit sequences share only approximately 48% identity with that of NbrbcS2. NbrbcS1‐1 transcription was suppressed in the dark and recovered drastically after transfer to light. In contrast, NbrbcS1‐2 and NbrbcS2 expression were not reduced after transfer from light to dark. In chlorophyllic tobacco cells containing green fluorescent protein fusion proteins of the transit sequences of each peptide, green fluorescent protein signals were localized on particles matching chloroplasts. The first introns of NbrbcS1‐1 and NbrbcS1‐2 are identical to the corresponding introns of 37 rbcS genes in eight embryophyte species. While the second intron is conserved in the green algae, the NbrbcS2 intron appears to involve sliding by one base pair. The NbrbcS1‐1 and NbrbcS1‐2 intron conserved in green algae and embryophytes might be an ancestral intron from nuclear‐encoded rbcS.

Deciphering the relationship among phosphate dynamics, electron-dense body and lipid accumulation in the green alga Parachlorella kessleri

Phosphorus is an essential element for life on earth and is also important for modern agriculture, which is dependent on inorganic fertilizers from phosphate rock. Polyphosphate is a biological polymer of phosphate residues, which is accumulated in organisms during the biological wastewater treatment process to enhance biological phosphorus removal. Here, we investigated the relationship between polyphosphate accumulation and electron-dense bodies in the green alga Parachlorella kessleri. Under sulfur-depleted conditions, in which some symporter genes were upregulated, while others were downregulated, total phosphate accumulation increased in the early stage of culture compared to that under sulfur-replete conditions. The P signal was detected only in dense bodies by energy dispersive X-ray analysis. Transmission electron microscopy revealed marked ultrastructural variations in dense bodies with and without polyphosphate. Our findings suggest that the dense body is a site of polyphosphate accumulation, and P. kessleri has potential as a phosphate-accumulating organism.

Genomic structure and evolution of the mating type locus in the green seaweed Ulva partita.

The evolution of sex chromosomes and mating loci in organisms with UV systems of sex/mating type determination in haploid phases via genes on UV chromosomes is not well understood. We report the structure of the mating type (MT) locus and its evolutionary history in the green seaweed Ulva partita, which is a multicellular organism with an isomorphic haploid-diploid life cycle and mating type determination in the haploid phase. Comprehensive comparison of a total of 12.0 and 16.6 Gb of genomic next-generation sequencing data for mt− and mt+ strains identified highly rearranged MT loci of 1.0 and 1.5 Mb in size and containing 46 and 67 genes, respectively, including 23 gametologs. Molecular evolutionary analyses suggested that the MT loci diverged over a prolonged period in the individual mating types after their establishment in an ancestor. A gene encoding an RWP-RK domain-containing protein was found in the mt− MT locus but was not an ortholog of the chlorophycean mating type determination gene MID. Taken together, our results suggest that the genomic structure and its evolutionary history in the U. partita MT locus are similar to those on other UV chromosomes and that the MT locus genes are quite different from those of Chlorophyceae.

Morphological changes of giant mitochondria in the unicellular to multicellular phase during parthenogenesis of Ulva partita (Ulvophyceae) revealed by expression of mitochondrial targeting GFP and PEG transformation

A giant mitochondrion that branches and connects as a single mitochondrion in a cell has been observed during specific phases of the cell cycle of unicellular green algae, but has not been observed in multicellular algae. The genus Ulva is a green macroalga in which the haploid and diploid phases are isomorphic and its gametes develop parthenogenetically. The existence or absence of the giant mitochondrion, and its behavior in Ulva partita, were investigated using a parthenogenesis system. To observe the parthenogenesis of gametes and the dynamics of mitochondria by fluorescence microscopy, we developed an experimental system for culturing and observing U. partita on cover slips: gametes were suspended in 6‐well plates filled with artificial seawater, and cover slips were placed on the well bottoms. The gametes settled on the cover slips as spherical cells (1‐cell S phase). These cells grew into larger cells, losing their eyespot (1‐cell L phase), and developed into multicellular thalli. Gene introduction using the polyethylene glycol (PEG) method is available with transformation efficiencies of 9.0–15.1%. Transformation was performed using a plasmid encoding green fluorescent protein (GFP) fused to the mitochondrial targeting sequence, and mitochondria were labeled by GFP fluorescence. This revealed a string‐shaped giant mitochondrion in a cell of the 1‐cell S phase. In the 1‐cell L phase, a reticular mitochondrion was observed. After the initiation of cell division, the reticular mitochondrion was fragmented, and small oval mitochondria were observed in the 5‐cell phase.