Type III metacaspases: calcium-dependent activity proposes new function for the p10 domain.

Metacaspases are a subgroup of caspase homologues represented in bacteria, algae and plants. Although type I and type II metacaspases are present in plants, recently discovered and uncharacterized type III metacaspases can only be found in algae which have undergone secondary endosymbiosis. We analysed the expression levels of all 13 caspase homologues in the cryptophyte Guillardia theta in vivo and biochemically characterized its only type III metacaspase, GtMC2, in vitro. Type III metacaspase GtMC2 was shown to be an endopeptidase with a preference for basic amino acids in the P1 position, which exhibited specific N-terminal proteolytic cleavage for full catalytic efficiency. Autolytic processing, as well as the activity of the mature enzyme, required the presence of calcium ions in low millimolar concentrations. In GtMC2, two calcium-binding sites were identified, one with a dissociation constant at low and the other at high micromolar concentrations. We show high functional relatedness of type III metacaspases to type I metacaspases. Moreover, our data suggest that the low-affinity calcium-binding site is located in the p10 domain, which contains a well-conserved N-terminal region. This region can only be found in type I/II/III metacaspases, but is absent in calcium-independent caspase homologues.

Dual Organellar Targeting of Aminoacyl-tRNA Synthetases in Diatoms and Cryptophytes.

The internal compartmentation of eukaryotic cells not only allows separation of biochemical processes but it also creates the requirement for systems that can selectively transport proteins across the membrane boundaries. Although most proteins function in a single subcellular compartment, many are able to enter two or more compartments, a phenomenon known as dual or multiple targeting. The aminoacyl-tRNA synthetases (aaRSs), which catalyze the ligation of tRNAs to their cognate amino acids, are particularly prone to functioning in multiple subcellular compartments. They are essential for translation, so they are required in every compartment where translation takes place. In diatoms, there are three such compartments, the plastid, the mitochondrion, and the cytosol. In cryptophytes, translation also takes place in the periplastid compartment (PPC), which is the reduced cytoplasm of the plastid's red algal ancestor and which retains a reduced red algal nucleus. We searched the organelle and nuclear genomes of the cryptophyte Guillardia theta and the diatoms Phaeodactylum tricornutum and Thalassiosira pseudonana for aaRS genes and found an insufficient number of genes to provide each compartment with a complete set of aaRSs. We therefore inferred, with support from localization predictions, that many aaRSs are dual targeted. We tested four of the predicted dual targeted aaRSs with green fluorescent protein fusion localizations in P. tricornutum and found evidence for dual targeting to the mitochondrion and plastid in P. tricornutum and G. theta, and indications for dual targeting to the PPC and cytosol in G. theta. This is the first report of dual targeting in diatoms or cryptophytes.

Non-photochemical quenching in cryptophyte alga Rhodomonas salina is located in chlorophyll a/c antennae.

Photosynthesis uses light as a source of energy but its excess can result in production of harmful oxygen radicals. To avoid any resulting damage, phototrophic organisms can employ a process known as non-photochemical quenching (NPQ), where excess light energy is safely dissipated as heat. The mechanism(s) of NPQ vary among different phototrophs. Here, we describe a new type of NPQ in the organism Rhodomonas salina, an alga belonging to the cryptophytes, part of the chromalveolate supergroup. Cryptophytes are exceptional among photosynthetic chromalveolates as they use both chlorophyll a/c proteins and phycobiliproteins for light harvesting. All our data demonstrates that NPQ in cryptophytes differs significantly from other chromalveolates - e.g. diatoms and it is also unique in comparison to NPQ in green algae and in higher plants: (1) there is no light induced xanthophyll cycle; (2) NPQ resembles the fast and flexible energetic quenching (qE) of higher plants, including its fast recovery; (3) a direct antennae protonation is involved in NPQ, similar to that found in higher plants. Further, fluorescence spectroscopy and biochemical characterization of isolated photosynthetic complexes suggest that NPQ in R. salina occurs in the chlorophyll a/c antennae but not in phycobiliproteins. All these results demonstrate that NPQ in cryptophytes represents a novel class of effective and flexible non-photochemical quenching.

Origin and evolution of ubiquitin-conjugating enzymes from Guillardia theta nucleomorph to hominoid.

The origin of eukaryotic ubiquitin-conjugating enzymes (E2s) can be traced back to the Guillardia theta nucleomorph about 2500 million years ago (Mya). E2s are largely vertically inherited over eukaryotic evolution [Lespinet, O., Wolf, Y.I., Koonin, E.V., Aravind, L., 2002. The role of lineage-specific gene family expansion in the evolution of eukaryotes. Genome Res. 1048-1059], while mammal E2s experienced evolution of multigene families by gene duplications which have been accompanied by the increase in the species complexity. Because of alternatively splicing, primate-specific expansions of E2s happened once again at a transcriptional level. Both of them resulted in increasing genomic complexity and diversity of primate E2 proteomic function. The evolutionary processes of human E2 gene structure during expansions were accompanied by exon duplication and exonization of intronic sequences. Exonizations of Transposable Elements (TEs) in UBE2D3, UBE2L3 and UBE2V1 genes from primates indicate that exaptation of TEs also plays important roles in the structural innovation of primate-specific E2s and may create alternative splicing isoforms at a transcriptional level. Estimates for the ratio of dN/dS suggest that a strong purifying selection had acted upon protein-coding sequences of their orthologous UBE2D2, UBE2A, UBE2N, UBE2I and Rbx1 genes from animals, plants and fungi. The similar rates of synonymous substitutions are in accordance with the neutral mutation-random drift hypothesis of molecular evolution. Systematic detection of the origin and evolution of E2s, analyzing the evolution of E2 multigene families by gene duplications and the evolutionary processes of E2s during expansions, and testing its evolutionary force using E2s from distant phylogenetic lineages may advance our distinguishing of ancestral E2s from created E2s, and reveal previously unknown relationships between E2s and metazoan complexity. Analysis of these conserved proteins provides strong support for a close relationship between social amoeba and eukaryote, choanoflagellate and metazoan, and for the central roles of social amoeba and choanoflagellate in the origin and evolution of eukaryote and metazoan. Retracing the different stages of primate E2 exonization by monitoring genomic events over 63 Myr of primate evolution will advance our understanding of how TEs dynamically modified primate transcriptome and proteome in the past, and continue to do so.

The RAB family GTPase Rab1A from Plasmodium falciparum defines a unique paralog shared by chromalveolates and rhizaria.

The RAB GTPases, which are involved in regulation of endomembrane trafficking, exhibit a complex but incompletely understood evolutionary history. We elucidated the evolution of the RAB1 subfamily ancestrally implicated in the endoplasmic reticulum-to-Golgi traffic. We found that RAB1 paralogs have been generated over the course of eukaryotic evolution, with some duplications coinciding with the advent of major eukaryotic lineages (e.g. Metazoa, haptophytes). We also identified a unique, derived RAB1 paralog, orthologous to the Plasmodium Rab1A, that occurs in stramenopiles, alveolates, and Rhizaria, represented by the chlorarachniophyte Gymnochlora stellata. This finding is consistent with the recently documented existence of a major eukaryotic clade ("SAR") comprising these three lineages. We further found a Rab1A-like protein in the cryptophyte Guillardia theta, but it exhibits unusual features among RAB proteins: absence of a C-terminal prenylation motif and an N-terminal extension with two MSP domains; and its phylogenetic relationships could not be established convincingly due to its divergent nature. Our results nevertheless point to a unique membrane trafficking pathway shared by at least some lineages of chromalveolates and Rhizaria, an insight that has implications towards interpreting the early evolution of eukaryotes and the endomembrane system.

Evolutionary dynamics of light-independent protochlorophyllide oxidoreductase genes in the secondary plastids of cryptophyte algae.

Plastid genes encoding light-independent protochlorophyllide oxidoreductase (LIPOR) subunits were isolated from cryptophyte algae, the first example of such genes in plastids of secondary endosymbiotic origin. The presence of functional and nonfunctional copies of LIPOR genes in cryptophytes suggests that light-independent chlorophyll biosynthesis is a nonessential pathway in these organisms.