RESUMEN
Essential amino acid, tryptophan which intake from food plays a critical role in numerous metabolic functions, exhibiting extensive biological functions and applications. Tryptophan is beneficial for the food sector by enhancing nutritional content and promoting the development of functional foods. A putative gene encoding tryptophan synthase was the first identified in Sphingobacterium soilsilvae Em02, a cellulosic bacterium making it inherently more environmentally friendly. The gene was cloned and expressed in exogenous host Escherichia coli, to elucidate its function. The recombinant tryptophan synthase with a molecular weight 42 KDa was expressed in soluble component. The enzymatic activity to tryptophan synthase in vivo was assessed using indole and L-serine and purified tryptophan synthase. The optimum enzymatic activity for tryptophan synthase was recorded at 50 ºC and pH 7.0, which was improved in the presence of metal ions Mg2+, Sr2+ and Mn2+, whereas Cu2+, Zn2+ and Co2+ proved to be inhibitory. Using site-directed mutagenesis, the consensus pattern HK-S-[GGGSN]-E-S in the tryptophan synthase was demonstrated with K100Q, S202A, G246A, E361A and S385A as the active sites. Tryptophan synthase has been demonstrated to possess the defining characteristics of the ß-subunits. The tryptophan synthase may eventually be useful for tryptophan production on a larger scale. Its diverse applications highlight the potential for improving both the quality and health benefits of food products, making it an essential component in advancing food science and technology.
Asunto(s)
Escherichia coli , Mutagénesis Sitio-Dirigida , Triptófano Sintasa , Triptófano , Triptófano Sintasa/metabolismo , Triptófano Sintasa/genética , Triptófano Sintasa/química , Triptófano/metabolismo , Escherichia coli/genética , Escherichia coli/metabolismo , Proteínas Bacterianas/genética , Proteínas Bacterianas/metabolismo , Proteínas Bacterianas/química , Sphingomonadaceae/enzimología , Sphingomonadaceae/genética , Sphingomonadaceae/metabolismo , Proteínas Recombinantes/metabolismo , Proteínas Recombinantes/genética , Proteínas Recombinantes/química , Dominio Catalítico , Clonación Molecular , Concentración de Iones de Hidrógeno , Indoles/metabolismo , Catálisis , Serina/metabolismoRESUMEN
Indigo, as a water-soluble non-azo colorant, is widely used in textile, food, pharmaceutical and other industrial fields. Currently, indigo is primarily synthesized by chemical methods, which causes environmental pollution, potential safety hazards, and other issues. Therefore, there is an urgent need to find a safer and greener synthetic method. In this study, a dual-enzyme cascade pathway was constructed with the tryptophan synthase (tryptophanase, EcTnaA) from Escherichia coli and flavin-dependent monooxygenase (flavin-dependent monooxygenase, MaFMO) from Methylophaga aminisulfidivorans to synthesize indigo with L-tryptophan as substrate. A recombinant strain EM-IND01 was obtained. The beneficial mutant MaFMOD197E was obtained by protein engineering of the rate-limiting enzyme MaFMO. MaFMOD197E showed the specific activity and kcat/Km value 2.36 times and 1.34 times higher than that of the wild type, respectively. Furthermore, MaFMOD197E was introduced into the strain EM-IND01 to construct the strain EM-IND02. After the fermentation conditions were optimized, the strain achieved the indigo titer of (1 288.59±7.50) mg/L, the yield of 0.86 mg/mg L-tryptophan, and the productivity of 26.85 mg/(L·h) in a 5 L fermenter. Protein engineering was used to obtain mutants with increased MaFMO activity in this study, which laid a foundation for industrial production of indigo.
Asunto(s)
Escherichia coli , Carmin de Índigo , Triptófano , Carmin de Índigo/metabolismo , Triptófano/metabolismo , Triptófano/biosíntesis , Escherichia coli/genética , Escherichia coli/metabolismo , Ingeniería de Proteínas , Triptofanasa/genética , Triptofanasa/metabolismo , Triptófano Sintasa/metabolismo , Triptófano Sintasa/genética , Fermentación , Oxigenasas/genética , Oxigenasas/metabolismoRESUMEN
Protein engineering often targets binding pockets or active sites which are enriched in epistasis-nonadditive interactions between amino acid substitutions-and where the combined effects of multiple single substitutions are difficult to predict. Few existing sequence-fitness datasets capture epistasis at large scale, especially for enzyme catalysis, limiting the development and assessment of model-guided enzyme engineering approaches. We present here a combinatorially complete, 160,000-variant fitness landscape across four residues in the active site of an enzyme. Assaying the native reaction of a thermostable ß-subunit of tryptophan synthase (TrpB) in a nonnative environment yielded a landscape characterized by significant epistasis and many local optima. These effects prevent simulated directed evolution approaches from efficiently reaching the global optimum. There is nonetheless wide variability in the effectiveness of different directed evolution approaches, which together provide experimental benchmarks for computational and machine learning workflows. The most-fit TrpB variants contain a substitution that is nearly absent in natural TrpB sequences-a result that conservation-based predictions would not capture. Thus, although fitness prediction using evolutionary data can enrich in more-active variants, these approaches struggle to identify and differentiate among the most-active variants, even for this near-native function. Overall, this work presents a large-scale testing ground for model-guided enzyme engineering and suggests that efficient navigation of epistatic fitness landscapes can be improved by advances in both machine learning and physical modeling.
Asunto(s)
Dominio Catalítico , Epistasis Genética , Triptófano Sintasa , Dominio Catalítico/genética , Triptófano Sintasa/genética , Triptófano Sintasa/metabolismo , Triptófano Sintasa/química , Ingeniería de Proteínas/métodos , Sustitución de Aminoácidos , Modelos MolecularesRESUMEN
Enzymes exhibit diverse conformations, as represented in the free energy landscape (FEL). Such conformational diversity provides enzymes with the ability to evolve towards novel functions. The challenge lies in identifying mutations that enhance specific conformational changes, especially if located in distal sites from the active site cavity. The shortest path map (SPM) method, which we developed to address this challenge, constructs a graph based on the distances and correlated motions of residues observed in nanosecond timescale molecular dynamics (MD) simulations. We recently introduced a template based AlphaFold2 (tAF2) approach coupled with 10 nanosecond MD simulations to quickly estimate the conformational landscape of enzymes and assess how the FEL is shifted after mutation. In this study, we evaluate the potential of SPM when coupled with tAF2-MD in estimating conformational heterogeneity and identifying key conformationally-relevant positions. The selected model system is the beta subunit of tryptophan synthase (TrpB). We compare how the SPM pathways differ when integrating tAF2 with different MD simulation lengths from as short as 10 ns until 50 ns and considering two distinct Amber forcefield and water models (ff14SB/TIP3P versus ff19SB/OPC). The new methodology can more effectively capture the distal mutations found in laboratory evolution, thus showcasing the efficacy of tAF2-MD-SPM in rapidly estimating enzyme dynamics and identifying the key conformationally relevant hotspots for computational enzyme engineering.
Asunto(s)
Biocatálisis , Simulación de Dinámica Molecular , Conformación Proteica , Triptófano Sintasa/química , Triptófano Sintasa/metabolismo , Dominio CatalíticoRESUMEN
Aromatic amino acids and their derivatives are diverse primary and secondary metabolites with critical roles in protein synthesis, cell structure and integrity, defense and signaling. All de novo aromatic amino acid production relies on a set of ancient and highly conserved chemistries. Here we introduce a new enzymatic transformation for L-tyrosine synthesis by demonstrating that the ß-subunit of tryptophan synthase-which natively couples indole and L-serine to form L-tryptophan-can act as a latent 'tyrosine synthase'. A single substitution of a near-universally conserved catalytic residue unlocks activity toward simple phenol analogs and yields exclusive para carbon-carbon bond formation to furnish L-tyrosines. Structural and mechanistic studies show how a new active-site water molecule orients phenols for a nonnative mechanism of alkylation, with additional directed evolution resulting in a net >30,000-fold rate enhancement. This new biocatalyst can be used to efficiently prepare valuable L-tyrosine analogs at gram scales and provides the missing chemistry for a conceptually different pathway to L-tyrosine.
Asunto(s)
Triptófano Sintasa , Tirosina , Triptófano Sintasa/metabolismo , Triptófano Sintasa/química , Tirosina/química , Tirosina/metabolismo , Dominio Catalítico , Modelos Moleculares , Tirosina Fenol-Liasa/metabolismo , Tirosina Fenol-Liasa/química , Tirosina Fenol-Liasa/genética , Subunidades de Proteína/química , Subunidades de Proteína/metabolismo , Biocatálisis , Triptófano/química , Triptófano/metabolismoRESUMEN
Indole in the gut is formed from dietary tryptophan by a bacterial tryptophan-indole lyase. Indole not only triggers biofilm formation and antibiotic resistance in gut microbes but also contributes to the progression of kidney dysfunction after absorption by the intestine and sulfation in the liver. As tryptophan is an essential amino acid for humans, these events seem inevitable. Despite this, we show in a proof-of-concept study that exogenous indole can be converted to an immunomodulatory tryptophan metabolite, indole-3-lactic acid (ILA), by a previously unknown microbial metabolic pathway that involves tryptophan synthase ß subunit and aromatic lactate dehydrogenase. Selected bifidobacterial strains converted exogenous indole to ILA via tryptophan (Trp), which was demonstrated by incubating the bacterial cells in the presence of (2-13C)-labeled indole and l-serine. Disruption of the responsible genes variedly affected the efficiency of indole bioconversion to Trp and ILA, depending on the strains. Database searches against 11,943 bacterial genomes representing 960 human-associated species revealed that the co-occurrence of tryptophan synthase ß subunit and aromatic lactate dehydrogenase is a specific feature of human gut-associated Bifidobacterium species, thus unveiling a new facet of bifidobacteria as probiotics. Indole, which has been assumed to be an end-product of tryptophan metabolism, may thus act as a precursor for the synthesis of a host-interacting metabolite with possible beneficial activities in the complex gut microbial ecosystem.
Asunto(s)
Bifidobacterium , Microbioma Gastrointestinal , Indoles , Triptófano , Triptófano/metabolismo , Humanos , Indoles/metabolismo , Bifidobacterium/metabolismo , Bifidobacterium/genética , Triptófano Sintasa/metabolismo , Triptófano Sintasa/genética , Tracto Gastrointestinal/microbiología , Tracto Gastrointestinal/metabolismoRESUMEN
Tryptophan synthase (TRPS) is a complex enzyme responsible for tryptophan biosynthesis. It occurs in bacteria, plants, and fungi as an αßßα heterotetramer. Although encoded by independent genes in bacteria and plants, in fungi, TRPS is generated by a single gene that concurrently expresses the α and ß entities, which are linked by an elongated peculiar segment. We conducted 1 µs all-atom molecular dynamics simulations on Hemileia vastatrix TRPS to address two questions: (i) the role of the linker segment and (ii) the comparative mode of action. Since there is not an experimental structure, we started our simulations with homology modeling. Based on the results, it seems that TRPS makes use of an already-existing tunnel that can spontaneously move the indole moiety from the α catalytic pocket to the ß one. Such behavior was completely disrupted in the simulation without the linker. In light of these results and the αß dimer's low stability, the full-working TRPS single genes might be the result of a particular evolution. Considering the significant losses that Hemileia vastatrix causes to coffee plantations, our next course of action will be to use the TRPS to look for substances that can block tryptophan production and therefore control the disease.
Asunto(s)
Basidiomycota , Simulación de Dinámica Molecular , Triptófano Sintasa , Triptófano Sintasa/química , Triptófano Sintasa/genética , Triptófano Sintasa/metabolismo , Triptófano , Hongos/metabolismoRESUMEN
L-tryptophan (l-Trp), a vital amino acid for the survival of various organisms, is synthesized by the enzyme tryptophan synthase (TS) in organisms such as eubacteria, archaebacteria, protista, fungi, and plantae. TS, a pyridoxal 5'-phosphate (PLP)-dependent enzyme, comprises α and ß subunits that typically form an α2ß2 tetramer. The enzyme's activity is regulated by the conformational switching of its α and ß subunits between the open (T state) and closed (R state) conformations. Many microorganisms rely on TS for growth and replication, making the enzyme and the l-Trp biosynthetic pathway potential drug targets. For instance, Mycobacterium tuberculosis, Chlamydiae bacteria, Streptococcus pneumoniae, Francisella tularensis, Salmonella bacteria, and Cryptosporidium parasitic protozoa depend on l-Trp synthesis. Antibiotic-resistant salmonella strains have emerged, underscoring the need for novel drugs targeting the l-Trp biosynthetic pathway, especially for salmonella-related infections. A single amino acid mutation can significantly impact enzyme function, affecting stability, conformational dynamics, and active or allosteric sites. These changes influence interactions, catalytic activity, and protein-ligand/protein-protein interactions. This study focuses on the impact of mutating the ßGln114 residue on the catalytic and allosteric sites of TS. Extensive molecular dynamics simulations were conducted on E(PLP), E(AEX1), E(A-A), and E(C3) forms of TS using the WT, ßQ114A, and ßQ114N versions. The results show that both the ßQ114A and ßQ114N mutations increase protein backbone root mean square deviation fluctuations, destabilizing all TS forms. Conformational and hydrogen bond analyses suggest the significance of ßGln114 drifting away from cofactor/intermediates and forming hydrogen bonds with water molecules necessary for l-Trp biosynthesis. The ßQ114A mutation creates a gap between ßAla114 and cofactor/intermediates, hindering hydrogen bond formation due to short side chains and disrupting ß-sites. Conversely, the ßQ114N mutation positions ßAsn114 closer to cofactor/intermediates, forming hydrogen bonds with O3 of cofactors/intermediates and nearby water molecules, potentially disrupting the l-Trp biosynthetic mechanism.
Asunto(s)
Criptosporidiosis , Cryptosporidium , Triptófano Sintasa , Humanos , Triptófano Sintasa/genética , Triptófano Sintasa/química , Triptófano Sintasa/metabolismo , Dominio Catalítico , Simulación de Dinámica Molecular , Salmonella typhimurium/genética , Cryptosporidium/metabolismo , Conformación Proteica , Aminoácidos , Mutación , Agua , CinéticaRESUMEN
Tryptophan synthetase (TSase), which functions as a tetramer, is a typical enzyme with a substrate channel effect, and shows excellent performance in the production of non-standard amino acids, histamine, and other biological derivatives. Based on previous work, we fused a mutant CE protein (colistin of E. coli, a polypeptide with antibacterial activity) sequence with the sequence of TSase to explore whether its catalytic activity could be enhanced, and we also analyzed whether the addition of a DNA scaffold was a feasible strategy. Here, dCE (CE protein without DNase activity) protein tags were constructed and fused to the TrapA and TrapB subunits of TSase, and the whole cell was used for the catalytic reaction. The results showed that after the dCE protein tag was fused to the TrapB subunit, its whole cell catalytic activity increased by 50%. Next, the two subunits were expressed separately, and the proteins were bound in vitro to ensure equimolar combination between the two subunits. After the dCE label was fused to TrapB, the activity of TSase assembled with TrapA also improved. A series of experiments revealed that the enzyme fused with dCE9 showed higher activity than the wild-type protein. In general, the activity of assembly TSase was optimal when the temperature was 50 °C and the pH was about 9.0. After a long temperature treatment, the enzyme maintained good activity. With the addition of exogenous nucleic acid, the activity of the enzyme increased. The maximum yield was 0.58 g/L, which was almost three times that of the wild-type TSase (0.21 g/L). The recombinant TSase constructed in this study with dCE fusion had the advantages of higher heat resistance and higher activity, and confirmed the feasibility of adding a nucleic acid scaffold, providing a new idea for the improvement of structurally similar enzymes.
Asunto(s)
Ácidos Nucleicos , Triptófano Sintasa , Triptófano Sintasa/química , Triptófano Sintasa/genética , Triptófano Sintasa/metabolismo , Escherichia coli/metabolismo , AminoácidosRESUMEN
The final two steps of tryptophan biosynthesis are catalyzed by the enzyme tryptophan synthase (TS), composed of alpha (αTS) and beta (ßTS) subunits. Recently, experimental and computational methods have mapped "allosteric networks" that connect the αTS and ßTS active sites. In αTS, allosteric networks change across the catalytic cycle, which might help drive the conformational changes associated with its function. Directed evolution studies to increase catalytic function and expand the substrate profile of stand-alone ßTS have also revealed the importance of αTS in modulating the conformational changes in ßTS. These studies also serve as a foundation for the development of TS inhibitors, which can find utility against Mycobacterium tuberculosis and other bacterial pathogens.
Asunto(s)
Triptófano Sintasa , Triptófano Sintasa/química , Triptófano Sintasa/metabolismo , Modelos Moleculares , Catálisis , Regulación AlostéricaRESUMEN
Pyridoxal-5'-phosphate (PLP) Schiff's bases of 2-aminoacrylate are intermediates in ß-elimination and ß-substitution reaction of PLP-dependent enzymes. These enzymes are found in two major families, the α-, or aminotransferase, superfamily, and the ß-family. While the α-family enzymes primarily catalyze ß-eliminations, the ß-family enzymes catalyze both ß-elimination and ß-substitution reactions. Tyrosine phenol-lyase (TPL), which catalyzes the reversible elimination of phenol from l-tyrosine, is an example of an α-family enzyme. Tryptophan synthase catalyzes the irreversible formation of l-tryptophan from l-serine and indole, and is an example of a ß-family enzyme. The identification and characterization of aminoacrylate intermediates in the reactions of both of these enzymes is discussed. The use of UV-visible absorption and fluorescence spectroscopy, X-ray and neutron crystallography, and NMR spectroscopy to identify aminoacrylate intermediates in these and other PLP enzymes is presented.
Asunto(s)
Triptófano Sintasa , Tirosina Fenol-Liasa , Humanos , Triptófano Sintasa/química , Triptófano Sintasa/metabolismo , Tirosina Fenol-Liasa/química , Tirosina Fenol-Liasa/metabolismo , Fosfato de Piridoxal/metabolismo , Catálisis , Fosfatos , CinéticaRESUMEN
Tryptophan synthase (TRPS) is a bifunctional enzyme consisting of α- and ß-subunits that catalyzes the last two steps of L-tryptophan (L-Trp) biosynthesis. The first stage of the reaction at the ß-subunit is called ß-reaction stage I, which converts the ß-ligand from an internal aldimine [E(Ain)] to an α-aminoacrylate [E(A-A)] intermediate. The activity is known to increase 3-10-fold upon the binding of 3-indole-D-glycerol-3'-phosphate (IGP) at the α-subunit. The effect of α-ligand binding on ß-reaction stage I at the distal ß-active site is not well understood despite the abundant structural information available for TRPS. Here, we investigate the ß-reaction stage I by carrying out minimum-energy pathway searches based on a hybrid quantum mechanics/molecular mechanics (QM/MM) model. The free-energy differences along the pathway are also examined using QM/MM umbrella sampling simulations with QM calculations at the B3LYP-D3/aug-cc-pVDZ level of theory. Our simulations suggest that the sidechain orientation of ßD305 near the ß-ligand likely plays an essential role in the allosteric regulation: a hydrogen bond is formed between ßD305 and the ß-ligand in the absence of the α-ligand, prohibiting a smooth rotation of the hydroxyl group in the quinonoid intermediate, whereas the dihedral angle rotates smoothly after the hydrogen bond is switched from ßD305-ß-ligand to ßD305-ßR141. This switch could occur upon the IGP-binding at the α-subunit, as evidenced by the existing TRPS crystal structures.
Asunto(s)
Triptófano Sintasa , Triptófano Sintasa/química , Triptófano Sintasa/metabolismo , Regulación Alostérica , Sitios de Unión , Ligandos , Conformación Proteica , CinéticaRESUMEN
The regiospecific prenylation of an aromatic amino acid catalyzed by a dimethylallyl-l-tryptophan synthase (DMATS) is a key step in the biosynthesis of many fungal and bacterial natural products. DMATS enzymes share a common "ABBA" fold with divergent active site contours that direct alternative C-C, C-N, and C-O bond-forming trajectories. DMATS1 from Fusarium fujikuroi catalyzes the reverse N-prenylation of l-Trp by generating an allylic carbocation from dimethylallyl diphosphate (DMAPP) that then alkylates the indole nitrogen of l-Trp. DMATS1 stands out among the greater DMATS family because it exhibits unusually broad substrate specificity: it can utilize geranyl diphosphate (GPP) or l-Tyr as an alternative prenyl donor or acceptor, respectively; it can catalyze both forward and reverse prenylation, i.e., at C1 or C3 of DMAPP; and it can catalyze C-N and C-O bond-forming reactions. Here, we report the crystal structures of DMATS1 and its complexes with l-Trp or l-Tyr and unreactive thiolodiphosphate analogues of the prenyl donors DMAPP and GPP. Structures of ternary complexes mimic Michaelis complexes with actual substrates and illuminate active site features that govern prenylation regiochemistry. Comparison with CymD, a bacterial enzyme that catalyzes the reverse N-prenylation of l-Trp with DMAPP, indicates that bacterial and fungal DMATS enzymes share a conserved reaction mechanism. However, the narrower active site contour of CymD enforces narrower substrate specificity. Structure-function relationships established for DMATS enzymes will ultimately inform protein engineering experiments that will broaden the utility of these enzymes as useful tools for synthetic biology.
Asunto(s)
Productos Biológicos , Dimetilaliltranstransferasa , Triptófano Sintasa , Catálisis , Dimetilaliltranstransferasa/química , Fusarium , Hemiterpenos , Indoles , Neopreno , Nitrógeno , Compuestos Organofosforados , Prenilación , Especificidad por Sustrato , Triptófano/química , Triptófano Sintasa/metabolismoRESUMEN
The reverse genetic approach has uncovered indole synthase (INS) as the first enzyme in the tryptophan (trp)-independent pathway of IAA synthesis. The importance of INS was reevaluated suggesting it may interact with tryptophan synthase B (TSB) and therefore involved in the trp-dependent pathway. Thus, the main aim of this study was to clarify the route of INS through the analysis of Arabidopsis genome. Analysis of the top 2000 co-expression gene lists in general and specific conditions shows that TSA is strongly positively co-expressed with TSB in general, hormone, and abiotic conditions with mutual ranks of 89, 38, and 180 respectively. Moreover, TSA is positively correlated with TSB (0.291). However, INS was not found in any of these coexpressed gene lists and negatively correlated with TSB (- 0.046) suggesting unambiguously that these two routes are separately and independently operated. So far, the remaining steps in the INS pathway have remained elusive. Among all enzymes reported to have a role in IAA synthesis, amidase was found to strongly positively co-expressed with INS in general and light conditions with mutual ranks of 116 and 141 respectively. Additionally, amidase1 was found to positively correlate with INS (0.297) and negatively coexpressed with TSB concluding that amidase may exclusively involve in the trp-independent pathway.
Asunto(s)
Arabidopsis , Triptófano Sintasa , Amidohidrolasas/genética , Amidohidrolasas/metabolismo , Arabidopsis/genética , Hormonas/metabolismo , Ácidos Indolacéticos/metabolismo , Indoles/metabolismo , Triptófano/metabolismo , Triptófano Sintasa/genética , Triptófano Sintasa/metabolismoRESUMEN
Indole is produced in nature by diverse organisms and exhibits a characteristic odor described as animal, fecal, and floral. In addition, it contributes to the flavor in foods, and it is applied in the fragrance and flavor industry. In nature, indole is synthesized either from tryptophan by bacterial tryptophanases (TNAs) or from indole-3-glycerol phosphate (IGP) by plant indole-3-glycerol phosphate lyases (IGLs). While it is widely accepted that the tryptophan synthase α-subunit (TSA) has intrinsically low IGL activity in the absence of the tryptophan synthase ß-subunit, in this study, we show that Corynebacterium glutamicum TSA functions as a bona fide IGL and can support fermentative indole production in strains providing IGP. By bioprospecting additional bacterial TSAs and plant IGLs that function as bona fide IGLs were identified. Capturing indole in an overlay enabled indole production to titers of about 0.7 g L-1 in fermentations using C. glutamicum strains expressing either the endogenous TSA gene or the IGL gene from wheat.
Asunto(s)
Liasas , Triptófano Sintasa , Animales , Fermentación , Glicerofosfatos , Indoles , Triptófano Sintasa/genética , Triptófano Sintasa/metabolismoRESUMEN
To adapt to changing environments, plants have evolved elaborate regulatory mechanisms balancing their growth with stress responses. It is currently unclear whether and how the tryptophan (Trp), the growth-related hormone auxin, and the stress hormone abscisic acid (ABA) are coordinated in this trade-off. Here, we show that tryptophan synthase ß subunit 1 (TSB1) is involved in the coordination of Trp and ABA, thereby affecting plant growth and abiotic stress responses. Plants experiencing high salinity or drought display reduced TSB1 expression, resulting in decreased Trp and auxin accumulation and thus reduced growth. In comparison with the wild type, amiR-TSB1 lines and TSB1 mutants exhibited repressed growth under non-stress conditions but had enhanced ABA accumulation and stress tolerance when subjected to salt or drought stress. Furthermore, we found that TSB1 interacts with and inhibits ß-glucosidase 1 (BG1), which hydrolyses glucose-conjugated ABA into active ABA. Mutation of BG1 in the amiR-TSB1 lines compromised their increased ABA accumulation and enhanced stress tolerance. Moreover, stress-induced H2O2 disrupted the interaction between TSB1 and BG1 by sulfenylating cysteine-308 of TSB1, relieving the TSB1-mediated inhibition of BG1 activity. Taken together, we revealed that TSB1 serves as a key coordinator of plant growth and stress responses by balancing Trp and ABA homeostasis.
Asunto(s)
Proteínas de Arabidopsis , Arabidopsis , Triptófano Sintasa , Ácido Abscísico/metabolismo , Arabidopsis/metabolismo , Proteínas de Arabidopsis/genética , Proteínas de Arabidopsis/metabolismo , Sequías , Regulación de la Expresión Génica de las Plantas , Homeostasis , Hormonas/metabolismo , Peróxido de Hidrógeno/metabolismo , Ácidos Indolacéticos/metabolismo , Plantas Modificadas Genéticamente/metabolismo , Estrés Fisiológico/genética , Triptófano/metabolismo , Triptófano Sintasa/genética , Triptófano Sintasa/metabolismoRESUMEN
Tryptophan synthase (TRPS) is a bifunctional enzyme consisting of α and ß-subunits and catalyzes the last two steps of l-tryptophan (L-Trp) biosynthesis, namely, cleavage of 3-indole-d-glycerol-3'-phosphate (IGP) into indole and glyceraldehyde-3-phosphate (G3P) in the α-subunit, and a pyridoxal phosphate (PLP)-dependent reaction of indole and l-serine (L-Ser) to produce L-Trp in the ß-subunit. Importantly, the IGP binding at the α-subunit affects the ß-subunit conformation and its ligand-binding affinity, which, in turn, enhances the enzymatic reaction at the α-subunit. The intersubunit communications in TRPS have been investigated extensively for decades because of the fundamental and pharmaceutical importance, while it is still difficult to answer how TRPS allostery is regulated at the atomic detail. Here, we investigate the allosteric regulation of TRPS by all-atom classical molecular dynamics (MD) simulations and analyze the potential of mean-force (PMF) along conformational changes of the α- and ß-subunits. The present simulation has revealed a widely opened conformation of the ß-subunit, which provides a pathway for L-Ser to enter into the ß-active site. The IGP binding closes the α-subunit and induces a wide opening of the ß-subunit, thereby enhancing the binding affinity of L-Ser to the ß-subunit. Structural analyses have identified critical hydrogen bonds (HBs) at the interface of the two subunits (αG181-ßS178, αP57-ßR175, etc.) and HBs between the ß-subunit (ßT110 - ßH115) and a complex of PLP and L-Ser (an α-aminoacrylate intermediate). The former HBs regulate the allosteric, ß-subunit opening, whereas the latter HBs are essential for closing the ß-subunit in a later step. The proposed mechanism for how the interdomain communication in TRPS is realized with ligand bindings is consistent with the previous experimental data, giving a general idea to interpret the allosteric regulations in multidomain proteins.
Asunto(s)
Triptófano Sintasa , Regulación Alostérica , Sitios de Unión , Indoles/metabolismo , Cinética , Ligandos , Fosfatos , Conformación Proteica , Triptófano Sintasa/química , Triptófano Sintasa/metabolismoRESUMEN
NMR-assisted crystallography-the integrated application of solid-state NMR, X-ray crystallography, and first-principles computational chemistry-holds significant promise for mechanistic enzymology: by providing atomic-resolution characterization of stable intermediates in enzyme active sites, including hydrogen atom locations and tautomeric equilibria, NMR crystallography offers insight into both structure and chemical dynamics. Here, this integrated approach is used to characterize the tryptophan synthase α-aminoacrylate intermediate, a defining species for pyridoxal-5'-phosphate-dependent enzymes that catalyze ß-elimination and replacement reactions. For this intermediate, NMR-assisted crystallography is able to identify the protonation states of the ionizable sites on the cofactor, substrate, and catalytic side chains as well as the location and orientation of crystallographic waters within the active site. Most notable is the water molecule immediately adjacent to the substrate ß-carbon, which serves as a hydrogen bond donor to the ε-amino group of the acid-base catalytic residue ßLys87. From this analysis, a detailed three-dimensional picture of structure and reactivity emerges, highlighting the fate of the L-serine hydroxyl leaving group and the reaction pathway back to the preceding transition state. Reaction of the α-aminoacrylate intermediate with benzimidazole, an isostere of the natural substrate indole, shows benzimidazole bound in the active site and poised for, but unable to initiate, the subsequent bond formation step. When modeled into the benzimidazole position, indole is positioned with C3 in contact with the α-aminoacrylate Cß and aligned for nucleophilic attack. Here, the chemically detailed, three-dimensional structure from NMR-assisted crystallography is key to understanding why benzimidazole does not react, while indole does.
Asunto(s)
Alanina/análogos & derivados , Dominio Catalítico , Cristalografía por Rayos X/métodos , Espectroscopía de Resonancia Magnética/métodos , Triptófano Sintasa/química , Catálisis , Indoles , Imagen por Resonancia Magnética , Resonancia Magnética Nuclear Biomolecular , Fosfato de Piridoxal/metabolismo , Triptófano Sintasa/metabolismoRESUMEN
The ß-subunit of tryptophan synthase (TrpB) catalyzes a PLP-mediated ß-substitution reaction between indole and serine to form L-Trp. A succession of TrpB protein engineering campaigns to expand the enzyme's nucleophile substrate range has enabled the biocatalytic production of diverse non-canonical amino acids (ncAAs). Here, we show that ketone-derived enolates can serve as nucleophiles in the TrpB reaction to achieve the asymmetric alkylation of ketones, an outstanding challenge in synthetic chemistry. We engineered TrpB by directed evolution to catalyze the asymmetric alkylation of propiophenone and 2-fluoroacetophenone with a high degree of selectivity. In reactions with propiophenone, preference for the opposite product diastereomer emerges over the course of evolution, demonstrating that full control over the stereochemistry at the new chiral center can be achieved. The addition of this new reaction to the TrpB platform is a crucial first step toward the development of efficient methods to synthesize non-canonical prolines and other chirally dense nitrogen heterocycles.
Asunto(s)
Cetonas/metabolismo , Ingeniería de Proteínas , Triptófano Sintasa/metabolismo , Alquilación , Biocatálisis , Cetonas/química , Estructura Molecular , Triptófano Sintasa/químicaRESUMEN
Intracellular growth and pathogenesis of Chlamydia species is controlled by the availability of tryptophan, yet the complete biosynthetic pathway for l-Trp is absent among members of the genus. Some representatives, however, preserve genes encoding tryptophan synthase, TrpAB - a bifunctional enzyme catalyzing the last two steps in l-Trp synthesis. TrpA (subunit α) converts indole-3-glycerol phosphate into indole and glyceraldehyde-3-phosphate (α reaction). The former compound is subsequently used by TrpB (subunit ß) to produce l-Trp in the presence of l-Ser and a pyridoxal 5'-phosphate cofactor (ß reaction). Previous studies have indicated that in Chlamydia, TrpA has lost its catalytic activity yet remains associated with TrpB to support the ß reaction. Here, we provide detailed analysis of the TrpAB from C. trachomatis D/UW-3/CX, confirming that accumulation of mutations in the active site of TrpA renders it enzymatically inactive, despite the conservation of the catalytic residues. We also show that TrpA remains a functional component of the TrpAB complex, increasing the activity of TrpB by four-fold. The side chain of non-conserved ßArg267 functions as cation effector, potentially rendering the enzyme less susceptible to the solvent ion composition. The observed structural and functional changes detected herein were placed in a broader evolutionary and genomic context, allowing identification of these mutations in relation to their trp gene contexts in which they occur. Moreover, in agreement with the in vitro data, partial relaxation of purifying selection for TrpA, but not for TrpB, was detected, reinforcing a partial loss of TrpA functions during the course of evolution.