Evolution of Bacterial-Like Phosphoprotein Phosphatases in Photosynthetic Eukaryotes Features Ancestral Mitochondrial or Archaeal Origin and Possible Lateral Gene Transfer

Protein phosphorylation is a reversible regulatory process catalyzed by the opposing reactions of protein kinases and phosphatases, which are central to the proper functioning of the cell. Dysfunction of members in either the protein kinase or phosphatase family can have wide-ranging deleterious effects in both metazoans and plants alike. Previously, three bacterial-like phosphoprotein phosphatase classes were uncovered in eukaryotes and named according to the bacterial sequences with which they have the greatest similarity: Shewanella-like (SLP), Rhizobiales-like (RLPH), and ApaH-like (ALPH) phosphatases. Utilizing the wealth of data resulting from recently sequenced complete eukaryotic genomes, we conducted database searching by hidden Markov models, multiple sequence alignment, and phylogenetic tree inference with Bayesian and maximum likelihood methods to elucidate the pattern of evolution of eukaryotic bacterial-like phosphoprotein phosphatase sequences, which are predominantly distributed in photosynthetic eukaryotes. We uncovered a pattern of ancestral mitochondrial (SLP and RLPH) or archaeal (ALPH) gene entry into eukaryotes, supplemented by possible instances of lateral gene transfer between bacteria and eukaryotes. In addition to the previously known green algal and plant SLP1 and SLP2 protein forms, a more ancestral third form (SLP3) was found in green algae. Data from in silico subcellular localization predictions revealed class-specific differences in plants likely to result in distinct functions, and for SLP sequences, distinctive and possibly functionally significant differences between plants and nonphotosynthetic eukaryotes. Conserved carboxyl-terminal sequence motifs with class-specific patterns of residue substitutions, most prominent in photosynthetic organisms, raise the possibility of complex interactions with regulatory proteins.Reversible protein phosphorylation is a posttranslational mechanism central to the proper function of living organisms (Brautigan, 2013). Governed by two large groups of enzymes, protein kinases and protein phosphatases, this mechanism has been suggested to regulate upwards of 70% of all eukaryotic proteins (Olsen et al., 2010). Protein phosphatases represent one-half of this dynamic regulatory system and have been shown to be highly regulated proteins themselves (Roy and Cyert, 2009; Shi, 2009; Uhrig et al., 2013). Classically, protein phosphatases have been placed into four families defined by a combination of their catalytic mechanisms, metal ion requirements, and phosphorylated amino acid targets (Kerk et al., 2008). These four families are the phosphoprotein phosphatases (PPPs), metallo-dependent protein phosphatases, protein Tyr phosphatases, and Asp-based phosphatases. The PPP protein phosphatases, best known to include PP1, PP2A, PP2B, and PP4 to PP7 (Kerk et al., 2008; Shi, 2009), have been found to regulate a diverse number of biological processes in plants ranging from cell signaling (Ahn et al., 2011; Di Rubbo et al., 2011; Tran et al., 2012) to metabolism (Heidari et al., 2011; Leivar et al., 2011) and hormone biosynthesis (Skottke et al., 2011). The classical PPP protein phosphatase family has been expanded to include three novel classes that show greatest similarity to PPP-like protein phosphatases of prokaryotic origin (Andreeva and Kutuzov, 2004; Uhrig and Moorhead, 2011a; Uhrig et al., 2013). These bacterial-like phosphatase classes were annotated as Shewanella-like (SLP) phosphatases, Rhizobiales-like (RLPH) phosphatases, and ApaH-like (ALPH) phosphatases based on their similarity to prokaryotic sequences from these respective sources (Andreeva and Kutuzov, 2004). Recent characterization of the SLP phosphatases from Arabidopsis (Arabidopsis thaliana) provided biochemical evidence of insensitivity to the classic PPP protein phosphatase inhibitors okadaic acid and microcystin in addition to revealing a lack of genetic redundancy across sequenced plant genomes (Uhrig and Moorhead, 2011a).The characterization of eukaryotic protein evolution can provide insight into individual protein or protein class conservation across the domains of life for biotechnological applications in addition to furthering our understanding of how multicellular life evolved. In particular, investigation into the evolution of key signaling proteins, such as protein kinases and phosphatases from plants, can have wide-ranging agribiotechnological and medical potential. This can include the development of healthier, disease- or stress-resistant crops in addition to treatments for parasitic organisms such as Plasmodium spp. (malaria; Patzewitz et al., 2013) and other chromoalveolates (Kutuzov and Andreeva, 2008; Uhrig and Moorhead, 2011b) that are derived from photosynthetic eukaryotes and maintain a remnant chloroplast (apicoplast; Le Corguillé et al., 2009; Janouskovec et al., 2010; Kalanon and McFadden, 2010; Walker et al., 2011). The existence of proteins that are conserved across diverse eukaryotic phyla but absent in metazoa, such as the majority of bacterial-like PPP protein phosphatases described here, presents unique research opportunities.Conventional understanding of the acquisition by eukaryotes of prokaryotic genes and proteins largely involves ancient endosymbiotic gene transfer events stemming from primary endosymbiosis of α-Proteobacteria and Cyanobacteria to form eukaryotic mitochondria and chloroplasts, respectively (Keeling and Palmer, 2008; Dorrell and Smith, 2011; Tirichine and Bowler, 2011). Over time, however, it has become apparent that alternative modes of eukaryotic gene and protein acquisition exist, such as independent horizontal or lateral gene transfer (LGT) events (Keeling and Palmer, 2008; Keeling, 2009). Targeted studies of protein evolution have seen a steady rise in documented LGT events across a wide variety of eukaryotic organisms, including photosynthetic eukaryotes (Derelle et al., 2006; Raymond and Kim, 2012; Schönknecht et al., 2013), nematodes (Mayer et al., 2011), arthropods (Acuña et al., 2012), fungi (Wenzl et al., 2005), amoebozoa (Clarke et al., 2013), and oomycetes (Belbahri et al., 2008). Each instance documents the integration of a bacterial gene(s) into a eukaryotic organism, seemingly resulting in an adaptive advantage(s) important to organism survival.Utilizing a number of in silico bioinformatic techniques and available sequenced genomes, the molecular evolution of three bacterial-like PPP classes found in eukaryotes is revealed to involve ancient mitochondrial or archaeal origin plus additional possible LGT events. A third, more ancient group of SLP phosphatases (SLP3 phosphatases) is defined in green algae. Subcellular localization predictions reveal distinctive subsets of bacterial-like PPPs, which may correlate with altered functions. In addition, the large sequence collections compiled here have allowed the elucidation of two highly conserved C-terminal domain motifs, which are specific to each bacterial-like PPP class and whose differences are particularly pronounced in photosynthetic eukaryotes. Together, these findings substantially expand our knowledge of the molecular evolution of the bacterial-like PPPs and point the way toward attractive future research avenues.