Molecular cloning and characterization of a tyrosine phosphatase from Monosiga brevicollis

Protein tyrosine phosphorylation is thought to be a unique feature of multicellular animals. Interestingly, the genome of the unicellular protist Monosiga brevicollis reveals a surprisingly high number and diversity of protein tyrosine kinases, protein tyrosine phosphatases (PTPs), and phosphotyrosine-binding domains. Our study focuses on a hypothetical SH2 domain-containing PTP (SHP), which interestingly has a predicted structure that is distinct from SHPs found in animals. In this study, we isolated cDNA of the enzyme and discovered that its actual sequence was different from the predicted sequence as a result of non-consensus RNA splicing. Contrary to the predicted structure with one SH2 domain and a disrupted phosphatase domain, Monosiga brevicollis SHP (MbSHP) contains two SH2 domains and an intact PTP domain, closely resembling SHP enzymes found in animals. We further expressed the full-length and SH2 domain-truncated forms of the enzyme in Escherichiacoli cells and characterized their enzymatic activities. The double-SH2 domain-truncated form of the enzyme effectively dephosphorylated a common PTP substrate with a specific activity among the highest in characterized PTPs, while the full-length and the N-terminal SH2 domain-truncated forms of the enzyme showed much lower activity with altered pH dependency and responses to ionic strength and common PTP inhibitors. This indicates that SH2 domains suppress the catalytic activity. SHP represents a highly conserved ancient PTP, and studying MbSHP should provide a better understanding about the evolution of tyrosine phosphorylation.     

Conserved Meiotic Genes Point to Sex in the Choanoflagellates

ABSTRACT. The choanoflagellates are a widespread group of heterotrophic aquatic nanoflagellates, which have recently been confirmed as the sister-group to Metazoa. Asexual reproduction is the only mode of cell division that has been observed within the group; at present the range of reproductive modes, as well as the ploidy level, within choanoflagellates are unknown. The recent discovery of long terminal repeat retrotransposons within the genome of Monosiga brevicollis suggests that this species also has sexual stages in its life cycle because asexual organisms cannot tolerate retrotransposons due to the rapid accumulation of deleterious mutations caused by their transposition. We screened the M. brevicollis genome for known eukaryotic meiotic genes, using a recently established "meiosis detection toolkit" of 19 genes. Eighteen of these genes were identified, none of which appears to be a pseudogene. Four of the genes were also identified in expressed sequence tag data from the distantly related Monosiga ovata . The presence of these meiosis-specific genes provides evidence for meiosis, and by implication sex, within this important group of protists.     

Horizontally acquired DAP pathway as a unit of self-regulation

In this study, we report the acquisition of the diaminopimelic acid (DAP) pathway of lysine biosynthesis in choanoflagellate Monosiga brevicollis and investigate how this pathway is incorporated and regulated in the established metabolic network. Our data show that all major genes related to the DAP pathway in Monosiga were acquired from bacteria and algae. Although an endogenous lysC exists in Monosiga, the newly acquired lysC is fused to lysA and used specifically for lysine biosynthesis. In addition, these acquired genes encode two key rate-limiting enzymes, thus conferring Monosiga a self-regulated unit with ability to generate lysine. Our data suggest that a newly acquired metabolic capability can be added to the recipient organism without disturbing the previously established metabolic network. This finding also implies that the biochemical system of the recipient organism may determine the type and function of genes to be acquired.     

Functional replacement of a primary metabolic pathway via multiple independent eukaryote‐to‐eukaryote gene transfers and selective retention

Although lateral gene transfer (LGT) is now recognized as a major force in the evolution of prokaryotes, the contribution of LGT to the evolution and diversification of eukaryotes is less understood. Notably, transfers of complete pathways are believed to be less likely between eukaryotes, because the successful transfer of a pathway requires the physical clustering of functionally related genes. Here, we report that in one of the closest unicellular relatives of animals, the choanoflagellate, Monosiga, three genes whose products work together in the glutamate synthase cycle are of algal origin. The concerted retention of these three independently acquired genes is best explained as the consequence of a series of adaptive replacement events. More generally, this study argues that (i) eukaryote‐to‐eukaryote transfers of entire metabolic pathways are possible, (ii) adaptive functional replacements of primary pathways can occur, and (iii) functional replacements involving eukaryotic genes are likely to have also contributed to the evolution of eukaryotes. Lastly, these data underscore the potential contribution of algal genes to the evolution of nonphotosynthetic lineages.     

Adaptive eukaryote-to-eukaryote lateral gene transfer: stress-related genes of algal origin in the closest unicellular relatives of animals

In addition to mutation, gene duplication and recombination, the transfer of genetic material between unrelated species is now regarded as a potentially significant player in the shaping of extant genomes and the evolution and diversification of life. Although this is probably true for prokaryotes, the extent of such genetic exchanges in eukaryotes (especially eukaryote-to-eukaryote transfers) is more controversial and the selective advantage and evolutionary impact of such events are less documented. A laterally transferred gene could either be added to the gene complement of the recipient or replace the recipient's homologue; whereas gene replacements can be either adaptive or stochastic, gene additions are most likely adaptive. Here, we report the finding of four stress-related genes (two ascorbate peroxidase and two metacaspase genes) of algal origin in the closest unicellular relatives of animals, the choanoflagellates. At least three of these sequences represent additions to the choanoflagellate gene complement, which is consistent with these transfers being adaptive. We suggest that these laterally acquired sequences could have provided the primitive choanoflagellates with additional or more efficient means to cope with stress, especially in relation to adapting to freshwater environments and/or sessile or colonial lifestyles.