Effect of immobilization support, water activity, and enzyme ionization state on cutinase activity and enantioselectivity in organic media

We studied the reaction between vinyl butyrate and 2-phenyl-1-propanol in acetonitrile catalyzed by Fusarium solani pisi cutinase immobilized on zeolites NaA and NaY and on Accurel PA-6. The choice of 2-phenyl-1-propanol was based on modeling studies that suggested moderate cutinase enantioselectivity towards this substrate. With all the supports, initial rates of transesterification were higher at a water activity (a(w)) of 0.2 than at a(w) = 0.7, and the reverse was true for initial rates of hydrolysis. By providing acid-base control in the medium through the use of solid-state buffers that control the parameter pH-pNa, which we monitored using an organo-soluble chromoionophoric indicator, we were able, in some cases, to completely eliminate dissolved butyric acid. However, none of the buffers used were able to improve the rates of transesterification relative to the blanks (no added buffer) when the enzyme was immobilized at an optimum pH of 8.5. When the enzyme was immobilized at pH 5 and exhibited only marginal activity, however, even a relatively acidic buffer with a pK(a) of 4.3 was able to restore catalytic activity to about 20% of that displayed for a pH of immobilization of 8.5, at otherwise identical conditions. As a(w) was increased from 0.2 to 0.7, rates of transesterification first increased slightly and then decreased. Rates of hydrolysis showed a steady increase in that a(w) range, and so did total initial reaction rates. The presence or absence of the buffers did not impact on the competition between transesterification and hydrolysis, regardless of whether the butyric acid formed remained as such in the reaction medium or was eliminated from the microenvironment of the enzyme through conversion into an insoluble salt. Cutinase enantioselectivity towards 2-phenyl-1-propanol was indeed low and was not affected by differences in immobilization support, enzyme protonation state, or a(w).     

A gene from the mesophilic bacterium Dehalococcoides ethenogenes encodes a novel mannosylglycerate synthase

Mannosylglycerate (MG) is a common compatible solute found in thermophilic and hyperthermophilic prokaryotes. In this study we characterized a mesophilic and bifunctional mannosylglycerate synthase (MGSD) encoded in the genome of the bacterium Dehalococcoides ethenogenes. mgsD encodes two domains with extensive homology to mannosyl-3-phosphoglycerate synthase (MPGS, EC 2.4.1.217) and to mannosyl-3-phosphoglycerate phosphatase (MPGP, EC 3.1.3.70), which catalyze the consecutive synthesis and dephosphorylation of mannosyl-3-phosphoglycerate to yield MG in Pyrococcus horikoshii, Thermus thermophilus, and Rhodothermus marinus. The bifunctional MGSD was overproduced in Escherichia coli, and we confirmed the combined MPGS and MPGP activities of the recombinant enzyme. The optimum activity of the enzyme was at 50 degrees C. To examine the properties of each catalytic domain of MGSD, we expressed them separately in E. coli. The monofunctional MPGS was unstable, while the MPGP was stable and was characterized. Dehalococcoides ethenogenes cannot be grown sufficiently to identify intracellular compatible solutes, and E. coli harboring MGSD did not accumulate MG. However, Saccharomyces cerevisiae expressing mgsD accumulated MG, confirming that this gene product can synthesize this compatible solute and arguing for a role in osmotic adjustment in the natural host. We did not detect MGSD activity in cell extracts of S. cerevisiae. Here we describe the first gene and enzyme for the synthesis of MG from a mesophilic microorganism and discuss the possible evolution of this bifunctional MGSD by lateral gene transfer from thermophilic and hyperthermophilic organisms.     

Specialized roles of the two pathways for the synthesis of mannosylglycerate in osmoadaptation and thermoadaptation of Rhodothermus marinus

Rhodothermus marinus responds to fluctuations in the growth temperature and/or salinity by accumulating mannosylglycerate (MG). Two alternative pathways for the synthesis of MG have been identified in this bacterium: a single-step pathway and a two-step pathway. In this work, the genetic and biochemical characterization of the two-step pathway was carried out with the goal of understanding the function of the two pathways and their regulatory mechanisms. Mannosyl-3-phosphoglycerate synthase (MPGS) of the two-step pathway was purified from R. marinus. Sequence information led to the isolation of two contiguous genes, mpgs (encoding MPGS) and mpgp (encoding mannosyl-3-phosphoglycerate phosphatase). The recombinant MPGS had a low specific activity compared with other homologous MPGSs and contained approximately 30 additional residues at the C terminus. Truncation of this extension produced a protein with a 10-fold higher specific activity. Moreover, the activity of the complete MPGS was enhanced upon incubation with R. marinus cell extracts, and protease inhibitors abolished activation. Therefore, the C-terminal peptide of MPGS was identified as a regulatory site for short term control of MG synthesis in R. marinus. The control of gene expression by heat and osmotic stress was also studied; the level of mannosylglycerate synthase involved in the single-step pathway was selectively enhanced by heat stress, whereas MPGS was overproduced in response to osmotic stress. The concomitant changes in the level of MG were assessed as well. We conclude that the two alternative pathways for the synthesis of MG are differently regulated at the level of expression to play specific roles in the adaptation of R. marinus to two different types of aggression. This is the only example of pathway multiplicity being rationalized in terms of the need to respond efficiently to distinct environmental stresses.     

Diversity of human U2AF splicing factors

U2 snRNP auxiliary factor (U2AF) is an essential heterodimeric splicing factor composed of two subunits, U2AF(65) and U2AF(35). During the past few years, a number of proteins related to both U2AF(65) and U2AF(35) have been discovered. Here, we review the conserved structural features that characterize the U2AF protein families and their evolutionary emergence. We perform a comprehensive database search designed to identify U2AF protein isoforms produced by alternative splicing, and we discuss the potential implications of U2AF protein diversity for splicing regulation.     

Thermococcus kodakarensis Mutants Deficient in Di-myo-Inositol Phosphate Use Aspartate To Cope with Heat Stress

Many of the marine microorganisms which are adapted to grow at temperatures above 80°C accumulate di-myo-inositol phosphate (DIP) in response to heat stress. This led to the hypothesis that the solute plays a role in thermoprotection, but there is a lack of definitive experimental evidence. Mutant strains of Thermococcus kodakarensis (formerly Thermococcus kodakaraensis), manipulated in their ability to synthesize DIP, were constructed and used to investigate the involvement of DIP in thermoadaptation of this archaeon. The solute pool of the parental strain comprised DIP, aspartate, and α-glutamate. Under heat stress the level of DIP increased 20-fold compared to optimal conditions, whereas the pool of aspartate increased 4.3-fold in response to osmotic stress. Deleting the gene encoding the key enzyme in DIP synthesis, CTP:inositol-1-phosphate cytidylyltransferase/CDP-inositol:inositol-1-phosphate transferase, abolished DIP synthesis. Conversely, overexpression of the same gene resulted in a mutant with restored ability to synthesize DIP. Despite the absence of DIP in the deletion mutant, this strain exhibited growth parameters similar to those of the parental strain, both at optimal (85°C) and supraoptimal (93.7°C) temperatures for growth. Analysis of the respective solute pools showed that DIP was replaced by aspartate. We conclude that DIP is part of the strategy used by T. kodakarensis to cope with heat stress, and aspartate can be used as an alternative solute of similar efficacy. This is the first study using mutants to demonstrate the involvement of compatible solutes in the thermoadaptation of (hyper)thermophilic organisms.Hyperthermophilic bacteria and archaea isolated from saline environments accumulate unusual organic solutes in response to osmotic as well as heat stress. Mannosylglycerate, mannosylglyceramide, di-myo-inositol phosphate, mannosyl-di-myo-inositol phosphate (DIP), diglycerol phosphate, and glycero-phospho-myo-inositol are examples of compatible solutes highly restricted to thermophiles and hyperthermophiles (27, 31). Our team has, over several years, examined the compatible solute composition in a large number of hyperthermophiles and their accumulation under stressful conditions. The data reveal a trend toward specialization of roles in thermoadaptation and osmoadaptation. Indeed, mannosylglycerate and diglycerol phosphate typically accumulate in response to increased NaCl concentration in the growth medium, whereas the levels of DIP and derivatives consistently increase at supraoptimal growth temperatures (11, 16, 17, 27, 31).DIP is widespread among extreme archaeal hyperthermophiles, such as Methanotorris igneus, Aeropyrum pernix, Stetteria hydrogenophila, Pyrodictium occultum, Pyrolobus fumarii, Archaeoglobus spp., and all the members of the Thermococcales examined thus far, except Palaeococcus ferrophilus (5, 7, 11, 13, 16, 18, 31). This organic solute has also been found in representatives of the two hyperthermophilic bacterial genera, Aquifex and Thermotoga (14, 17, 22).The specific chemical nature of solutes encountered in hyperthermophiles, together with their accumulation in response to elevated temperatures, led to the hypothesis that they play a role in thermoprotection of cellular components in vivo. However, there is a lack of convincing experimental evidence, such as that obtained with suitable mutants. Progress toward understanding the physiological functions of these solutes critically depends on two conditions: the availability of genetic tools to manipulate hyperthermophilic organisms and knowledge about the genes and enzymes implicated in the synthesis of these unusual solutes.Thermococcus kodakarensis (formerly Thermococcus kodakaraensis) is a member of the order Thermococcales with an optimal growth temperature of 85°C and is able to grow at temperatures up to 94°C in batch cultures. The NaCl concentration for optimal growth matches that of seawater (1). T. kodakarensis is the only marine hyperthermophile for which a number of genetic tools have been developed, including Escherichia coli-T. kodakarensis shuttle vectors and a reliable gene disruption system (19, 29, 32, 34). The genome of T. kodakarensis possesses a gene encoding CTP:inositol-1-phosphate cytidylyltransferase/CDP-inositol:inositol-1-phosphate transferase (IPCT/DIPPS), a key enzyme in DIP synthesis (2, 25, 26). This enzyme catalyzes the synthesis of CDP-inositol from CTP and inositol-1-phosphate as well as the transfer of the inositol group from CDP-inositol to a second molecule of inositol-1-phosphate to yield a phosphorylated form of DIP (2). Therefore, we set out to investigate whether DIP was involved in thermoadaptation of T. kodakarensis. A DIP-deficient mutant was constructed by deleting the IPCT/DIPPS gene; subsequently, this strain was complemented in this activity by inserting the gene under the control of a constitutive promoter, resulting in a construct with restored ability to synthesize DIP. The effects of heat and osmotic stress on the pattern of solute accumulation and on the growth profiles of the two mutants provided evidence for the involvement of DIP in thermoprotection.     

Two Alternative Pathways for the Synthesis of the Rare Compatible Solute Mannosylglucosylglycerate in Petrotoga mobilis

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.     

Kinetics of double-chain reversals bridging contiguous quartets in tetramolecular quadruplexes

Repetitive 5'GGXGG DNA segments abound in, or near, regulatory regions of the genome and may form unusual structures called G-quadruplexes. Using NMR spectroscopy, we demonstrate that a family of 5'GCGGXGGY sequences adopts a folding topology containing double-chain reversals. The topology is composed of two bistranded quadruplex monomeric units linked by formation of G:C:G:C tetrads. We provide a complete thermodynamic and kinetic analysis of 13 different sequences using absorbance spectroscopy and DSC, and compare their kinetics with a canonical tetrameric parallel-stranded quadruplex formed by TG4T. We demonstrate large differences (up to 10(5)-fold) in the association constants of these quadruplexes depending on primary sequence; the fastest samples exhibiting association rate equal or higher than the canonical TG4T quadruplex. In contrast, all sequences studied here unfold at a lower temperature than this quadruplex. Some sequences have thermodynamic stability comparable to the canonical TG4T tetramolecular quadruplex, but with faster association and dissociation. Sequence effects on the dissociation processes are discussed in light of structural data.     

Dehydration of ribonucleotides catalyzed by ribonucleotide reductase: the role of the enzyme

This article focuses on the second step of the catalytic mechanism for the reduction of ribonucleotides catalyzed by the enzyme Ribonucleotide Reductase (RNR). This step corresponds to the protonation/elimination of the substrate's C-2' hydroxyl group. Protonation is accomplished by the neighbor Cys-225, leading to the formation of one water molecule. This is a very relevant step since most of the known inhibitors of this enzyme, which are already used in the fight against certain forms of cancer, are 2'-substituted substrate analogs. Even though some theoretical studies have been performed in the past, they have modeled the enzyme with minimal gas-phase models, basically represented by a part of the side chain of the relevant amino acids, disconnected from the protein backbone. This procedure resulted in a limited accuracy in the position and/or orientation of the participating residues, which can result in erroneous energetics and even mistakes in the choice of the correct mechanism for this step. To overcome these limitations we have used a very large model, including a whole R1 model with 733 residues plus the substrate and 10 A thick shell of water molecules, instead of the minimal gas-phase models used in previous works. The ONIOM method was employed to deal with such a large system. This model can efficiently account for the restrained mobility of the reactive residues, as well as the long-range enzyme-substrate interactions. The results gave additional information about this step, which previous small models could not provide, allowing a much clearer evaluation of the role of the enzyme. The interaction energy between the enzyme and the substrate along the reaction coordinate and the substrate steric strain energy have been obtained. The conclusion was that the barrier obtained with the present model was very similar to the one previously determined with minimal gas-phase models. Therefore, the role of the enzyme in this step was concluded to be mainly entropic, rather than energetic, by placing the substrate and the two reactive residues in a position that allows for the highly favorable concerted trimolecular reaction, and to protect the enzyme radical from the solvent.     

The Na+/H+ antiporter of the thermohalophilic bacterium Rhodothermus marinus

In the thermohalophilic bacterium Rhodothermus marinus, the NADH:quinone oxidoreductase (complex I) is encoded by two single genes and two operons, one of which contains the genes for five complex I subunits, nqo10-nqo14, a pterin carbinolamine dehydratase, and a putative single subunit Na+/H+ antiporter. Here we report that the latter encodes indeed a functional Na+/H+ antiporter, which is able to confer resistance to Na+, but not to Li+ to an Escherichia coli strain defective in Na+/H+ antiporters. In addition, an extensive amino acid sequence comparison with several single subunit Na+/H+ antiporters from different groups, namely NhaA, NhaB, NhaC, and NhaD, suggests that this might be the first member of a new type of Na+/H+ antiporters, which we propose to call NhaE.