| Abstract: | The compatible solute mannosylglucosylglycerate (MGG), recently identified in Petrotoga miotherma, also accumulates in Petrotoga mobilis in response to hyperosmotic conditions and supraoptimal growth temperatures. Two functionally connected genes encoding a glucosyl-3-phosphoglycerate synthase (GpgS) and an unknown glycosyltransferase (gene Pmob_1143), which we functionally characterized as a mannosylglucosyl-3-phosphoglycerate synthase and designated MggA, were identified in the genome of Ptg. mobilis. This enzyme used the product of GpgS, glucosyl-3-phosphoglycerate (GPG), as well as GDP-mannose to produce mannosylglucosyl-3-phosphoglycerate (MGPG), the phosphorylated precursor of MGG. The MGPG dephosphorylation was determined in cell extracts, and the native enzyme was partially purified and characterized. Surprisingly, a gene encoding a putative glucosylglycerate synthase (Ggs) was also identified in the genome of Ptg. mobilis, and an active Ggs capable of producing glucosylglycerate (GG) from ADP-glucose and d-glycerate was detected in cell extracts and the recombinant enzyme was characterized, as well. Since GG has never been identified in this organism nor was it a substrate for the MggA, we anticipated the existence of a nonphosphorylating pathway for MGG synthesis. We putatively identified the corresponding gene, whose product had some sequence homology with MggA, but it was not possible to recombinantly express a functional enzyme from Ptg. mobilis, which we named mannosylglucosylglycerate synthase (MggS). In turn, a homologous gene from Thermotoga maritima was successfully expressed, and the synthesis of MGG was confirmed from GDP-mannose and GG. Based on the measurements of the relevant enzyme activities in cell extracts and on the functional characterization of the key enzymes, we propose two alternative pathways for the synthesis of the rare compatible solute MGG in Ptg. mobilis.Thermophilic and hyperthermophilic organisms, like the vast majority of other microorganisms, accumulate compatible solutes in response to water stress imposed by salt. In fact, many of the (hyper)thermophiles known were isolated from geothermal areas venting seawater (36). However, the compatible solutes of thermophilic and hyperthermophilic prokaryotes are generally different from those of their mesophilic counterparts and some, namely, di-myo-inositol-phosphate (DIP), mannosyl-di-myo-inositol-phosphate (MDIP), diglycerol phosphate, and mannosylglyceramide, are confined to organisms that grow at extremely high temperatures (19, 22, 34, 38). Mannosylglycerate (2-α-d-mannosylglycerate; MG), for example, is a common compatible solute of thermophiles and hyperhermophiles (23, 27, 38) but has also been found in mesophilic organisms, such as red algae, where it was first identified (6). It should also be noted that there is a growing awareness that compatible solutes are involved in other types of stress; trehalose, for example, plays a role in osmotic stress, heat stress, desiccation, and freezing (9). Some compatible solutes of thermophilic organisms are extremely rare and have been encountered in only one or two, generally closely related, species. Among them are mannosylglyceramide in Rhodothermus marinus, diglycerol phosphate in Archaeoglobus fulgidus, and, more recently, mannosylglucosylglycerate (α-d-1→2-mannopyranosyl-α-d-1→2-glucopyranosylglycerate; MGG) identified in Petrotoga miotherma (16, 19, 38).The species of the genus Petrotoga represent slightly thermophilic members of the generally hyperthermophilic and deep-branching bacteria of the order Thermotogales (2, 3, 31). Organisms of this genus have all been isolated from hot oilfield water (21, 25), and have an optimum temperature for growth of 55 to 60°C in medium containing NaCl in the range of 0.5 to 10% (16). In Ptg. miotherma, the levels of MGG increased during low-level osmotic adaptation, whereas glutamate and proline were used for protection against hyperosmotic stress (16). The hyperthermophilic Thermotoga spp. accumulate primarily di-myo-inositol-phosphate and mannosyl-di-myo-inositol-phosphate during osmotic adjustment or during growth at temperatures above the optimum for growth (37).The novel compatible solute MGG is a derivative of glucosylglycerate (2-α-d-glucosylglycerate; GG) identified in the free form in Erwinia chrysanthemi, in the marine cyanobacteria Prochlorococcus marinus and Synechococcus sp. PCC7002, and in the thermophilic bacterium Persephonella marina, the latter of which possesses two alternative pathways for its synthesis (8, 13, 14, 18, 37). Glucosylglycerate has also been detected in trace amounts in Mycobacterium smegmatis, where it probably is the precursor of a polysaccharide involved in the regulation of fatty acid synthesis, as well as in the polar head group of a glycolipid from Nocardia otitidiscaviarum (17, 30).Two alternative pathways for the synthesis of GG have been identified and characterized. In the two-step reaction scheme, the synthesis of GG involves the condensation of nucleoside diphosphate (NDP)-glucose and d-3-phosphoglycerate (3-PGA) into glucosyl-3-phosphoglycerate (GPG), which in turn is dephosphorylated to yield GG. Yet, in a single-step pathway, the synthesis of GG occurs via the condensation of ADP-glucose with d-glycerate (13). Similar routes to those described above also lead to the synthesis of mannosylglycerate in Rhodothermus marinus (4).Two functionally connected genes encoding an “actinobacterial”-type glucosyl-3-phosphoglycerate synthase (GpgS) and an unknown glycosyltransferase were detected in the genome of Petrotoga mobilis (12). In this study, we examine the synthesis of MGG through a phosphorylating pathway (with a phosphorylated intermediate) from 3-phosphoglycerate and UDP-glucose to the final compatible solute, in cell extracts and by functional characterization of recombinant enzymes. We also examine a second nonphosphorylating pathway (no phosphorylated intermediates) that could represent an alternative route for the synthesis of MGG in Ptg. mobilis that could lead to the direct conversion of GG and GDP-mannose to MGG. Pathway multiplicity likely reflects a crucial role for MGG in the physiology of Ptg. mobilis during stress adaptation. |
