Identification and functional analysis of a prokaryotic-type aspartate aminotransferase: implications for plant amino acid metabolism

In this paper, we report the identification of genes from pine (PpAAT), Arabidopsis (AtAAT) and rice (OsAAT) encoding a novel class of aspartate aminotransferase (AAT, EC 2.6.1.1) in plants. The enzyme is unrelated to other eukaryotic AATs from plants and animals but similar to bacterial enzymes. Phylogenetic analysis indicates that this prokaryotic-type AAT is closely related to cyanobacterial enzymes, suggesting it might have an endosymbiotic origin. Interestingly, most of the essential residues involved in the interaction with the substrate and the attachment of pyridoxal phosphate cofactor in the active site of the enzyme were conserved in the deduced polypeptide. The polypeptide is processed in planta to a mature subunit of 45 kDa that is immunologically distinct from the cytosolic, mitochondrial and chloroplastic isoforms of AAT previously characterized in plants. Functional expression of PpAAT sequences in Escherichia coli showed that the processed precursor is assembled into a catalytically active homodimeric holoenzyme that is strictly specific for aspartate. These atypical genes are predominantly expressed in green tissues of pine, Arabidopsis and rice, suggesting a key role of this AAT in nitrogen metabolism associated with photosynthetic activity. Moreover, immunological analyses revealed that the plant prokaryotic-type AAT is a nuclear-encoded chloroplast protein. This implies that two plastidic AAT co-exist in plants: a eukaryotic type previously characterized and the prokaryotic type described here. The respective roles of these two enzymes in plant amino acid metabolism are discussed.     

Unique substrate specificity of purine nucleoside phosphorylases from Thermus thermophilus

The degradation of purine nucleoside is the first step of purine nucleoside uptake. This degradation is catalyzed by purine nucleoside phosphorylase, which is categorized into two classes: hexameric purine nucleoside phosphorylase (6PNP) and trimeric purine nucleoside phosphorylase (3PNP). Generally, 6PNP and 3PNP degrade adenosine and guanosine, respectively. However, the substrate specificity of 6PNP and 3PNP of Thermus thermophilus (tt6PNP and tt3PNP, respectively) is the reverse of that anticipated based on comparison to other phosphorylases. Specifically, in this paper we reveal by gene disruption that tt6PNP and tt3PNP are discrete enzymes responsible for the degradation of guanosine and adenosine, respectively, in T. thermophilus HB8 cells. Sequence comparison combined with structural information suggested that Asn204 in tt6PNP and Ala196/Asp238 in tt3PNP are key residues for defining their substrate specificity. Replacement of Asn204 in tt6PNP with Asp changed the substrate specificity of tt6PNP to that of a general 6PNP. Similarly, substitution of Ala196 by Glu and Asp238 by Asn changed the substrate specificity of tt3PNP to that of a general 3PNP. Our results indicate that the residues at these positions determine substrate specificity of PNPs in general. Sequence analysis further suggested most 6PNP and 3PNP enzymes in thermophilic species belonging to the Deinococcus-Thermus phylum share the same critical residues as tt6PNP and tt3PNP, respectively.     

Identification and expression of a cDNA clone encoding aspartate aminotransferase in carrot

A full-length cDNA clone encoding aspartate aminotransferase (AAT) has been identified from a carrot root cDNA library. Degenerate oligo primers were synthesized from the known amino acid sequence of AAT form I from carrot (Daucus carota L. cv Danvers). These primers were utilized in a polymerase chain reaction to amplify a portion of a carrot AAT gene from first strand cDNA synthesized from poly(A)⁺ RNA isolated from 5-d-old cell suspension cultures. The resulting 750-bp fragment was cloned, mapped, and sequenced. The cloned fragment, mpAAT1, was used as a probe to identify a full-length cDNA clone in a library constructed from poly(A)⁺ RNA isolated from carrot roots. A 1.52-kb full-length clone, AAT7, was isolated and sequenced. AAT7 has 54% nucleotide identity with both the mouse cytoplasmic and mitochondrial AAT genes. The deduced amino acid sequence has 52 and 53% identity with the deduced amino acid sequences of mouse cytoplasmic and mitochondrial AAT genes, respectively. Further analysis of the sequence data suggests that AAT7 encodes a cytoplasmic form of carrot AAT; the evidence includes the (a) absence of a transit or signal sequence, (b) lack of “m-residues,” or invariant mitochondrial residues, in the carrot AAT sequence, and (c) high degree of sequence similarity with the amino acid sequence previously obtained for form I of carrot, a cytoplasmic isoenzyme. High- and low-stringency hybridizations to Southern blots of carrot nuclear DNA with AAT7 show that AAT is part of a small multigene family. Northern blot analysis of AAT7 suggests that AAT is expressed throughout cell culture up to 7 d and is highly expressed in roots but not in leaves.     

Functional divergence and catalytic properties of dehydroascorbate reductase family proteins from Populus tomentosa

Dehydroascorbate reductase (DHAR) is a key enzyme in the ascorbate–glutathione cycle that maintains reduced pools of ascorbic acid and serves as an important antioxidant. In this study, to investigate functional divergence of plant DHAR family and catalytic characteristics of the glutathione binding site (G-site) residues of DHAR proteins, we cloned three DHAR genes (PtoDHAR1/2/3) from Populus tomentosa and predicted the G-site residues. PtoDHAR1 protein was localized in chloroplast, while PtoDHAR2/3 proteins showed cytosolic localizations. Three DHAR proteins showed different enzymatic activities, apparent kinetic characteristics, optimum T _m and pH profiles, indicating their functional divergence. Cys20, Lys8, Pro61, Asp72 and Ser73 of PtoDHAR2 were predicted as G-site residues based on their N-terminal amino acid sequence identity and the available crystal structures of glutathione S-transferases. The biochemical functions of these residues are examined in this study through site-directed mutagenesis. The aforementioned five residues are critical components of active sites that contribute to the enzyme’s catalytic activity. Cys20, Pro61 and Asp72 of PtoDHAR2 are also responsible for maintaining proper protein structure. This study provides new insights into the functional divergence of the plant DHAR family and biochemical properties of the G-site residues in plant DHAR proteins.     

Comparative analyses of squalene synthase (SQS) proteins in poplar and pine by using bioinformatics tools

Squalene synthase (SQS, EC 2.5.1.21) is a major enzyme in biosynthesis of isoprenoid (farnesyl pyrophosphate (FPP) squalene). In the present study, we have analyzed SQS enzymes of black cottonwood (Populus trichocarpa, hereafter Pt) and Masson’s pine (Pinus massoniana, hereafter Pm) using bioinformatics tools. PtSQS and PmSQS sequences were found to have very similar physicochemical properties with “squalene/phytoene synthase” domain structure (PF00494). PtSQS sequence was 47.3 kDa weight and 413 amino acids long with a pI value of 6.86, while PmSQS was 46.6 kDa weight and 409 amino acids long with a pI of 7.92. Alignment of SQS protein sequences in 15 plant species showed a highly similar conserved pattern and included ⁷⁷DTVED⁸¹ and ²¹³DYLED²¹⁷ motifs, which are rich in aspartic acids, for FPP binding sites. In phylogenetic tree, monocots and polycot were clearly separated from dicots with high bootstrap value (99 %). A total of 10 interaction partners were predicted for PtSQS and PmSQS proteins. Nine of them were hypothetical proteins (related with phytosterol biosynthesis), while one was putative uncharacterized protein. Similar 3D structures and identical binding sites were predicted for pine and poplar. In docking, FPP-PtSQS was found to make 8 H bonds with Asp81, Asp217, Glu80, and Gln206 residues in poplar with highest affinity while FPP-PmSQS made 7 H bonds with Arg49, Arg74, Ser48, and Val47 residues in pine with highest affinity. The results of this study will provide valuable theoretical knowledge for future studies of identification and characterization of SQS genes and proteins in various tree species and will provide an insight for studies of biotechnological manipulation of sterol biosynthesis pathway to enhance the plant stress tolerance and productivity.     

Molecular interactions involved in proton-dependent gating in KcsA potassium channels

The bacterial potassium channel KcsA is gated open by the binding of protons to amino acids on the intracellular side of the channel. We have identified, via channel mutagenesis and x-ray crystallography, two pH-sensing amino acids and a set of nearby residues involved in molecular interactions that influence gating. We found that the minimal mutation of one histidine (H25) and one glutamate (E118) near the cytoplasmic gate completely abolished pH-dependent gating. Mutation of nearby residues either alone or in pairs altered the channel’s response to pH. In addition, mutations of certain pairs of residues dramatically increased the energy barriers between the closed and open states. We proposed a Monod–Wyman–Changeux model for proton binding and pH-dependent gating in KcsA, where H25 is a “strong” sensor displaying a large shift in pK_a between closed and open states, and E118 is a “weak” pH sensor. Modifying model parameters that are involved in either the intrinsic gating equilibrium or the pK_a values of the pH-sensing residues was sufficient to capture the effects of all mutations.     

Genetic evidence that Arabidopsis ALTERED ROOT ARCHITECTURE encodes a putative dehydrogenase involved in homoserine biosynthesis

Key message

Genetic and molecular analysis of an Arabidopsis root development mutant identified a putative dehydrogenase gene involved in homoserine biosynthesis.

Abstract

In higher plants, homoserine (Hse) is derived from aspartate (Asp) and is an important intermediate for production of methionine (Met), threonine (Thr), and isoleucine (Ile). In Arabidopsis, six enzymes involved in the biosynthesis of Hse from Asp have been well characterized. It is not known, however, whether there exist other enzymes involved in this process. In this work, we characterized an Arabidopsis mutant, ara (a ltered r oot a rchitecture), with a short primary root and an increased number of lateral roots. Genetic and molecular analysis indicated that the ARA gene encodes a protein with a D-isomer specific 2-hydroxyacid dehydrogenase domain. ARA is expressed in all plant organs and is localized in the cell periphery. The ara mutant phenotypes can be rescued by exogenously applied Hse, Met, Ile and 2-oxobutanoate. Based on the results presented here, we propose that the ARA protein may be a dehydrogenase involved in homoserine biosynthesis.     

Structural basis for substrate recognition and inhibition of prephenate aminotransferase from Arabidopsis

Aromatic amino acids are protein building blocks and precursors to a number of plant natural products, such as the structural polymer lignin and a variety of medicinally relevant compounds. Plants make tyrosine and phenylalanine by a different pathway from many microbes; this pathway requires prephenate aminotransferase (PAT) as the key enzyme. Prephenate aminotransferase produces arogenate, the unique and immediate precursor for both tyrosine and phenylalanine in plants, and also has aspartate aminotransferase (AAT) activity. The molecular mechanisms governing the substrate specificity and activation or inhibition of PAT are currently unknown. Here we present the X‐ray crystal structures of the wild‐type and various mutants of PAT from Arabidopsis thaliana (AtPAT). Steady‐state kinetic and ligand‐binding analyses identified key residues, such as Glu108, that are involved in both keto acid and amino acid substrate specificities and probably contributed to the evolution of PAT activity among class Ib AAT enzymes. Structures of AtPAT mutants co‐crystallized with either α‐ketoglutarate or pyridoxamine 5′‐phosphate and glutamate further define the molecular mechanisms underlying recognition of keto acid and amino acid substrates. Furthermore, cysteine was identified as an inhibitor of PAT from A. thaliana and Antirrhinum majus plants as well as the bacterium Chlorobium tepidum, uncovering a potential new effector of PAT.     

Structural basis of the strict specificity of a bacterial GH31 α-1,3-glucosidase for nigerooligosaccharides

Carbohydrate-active enzymes are involved in the degradation, biosynthesis, and modification of carbohydrates and vary with the diversity of carbohydrates. The glycoside hydrolase (GH) family 31 is one of the most diverse families of carbohydrate-active enzymes, containing various enzymes that act on α-glycosides. However, the function of some GH31 groups remains unknown, as their enzymatic activity is difficult to estimate due to the low amino acid sequence similarity between characterized and uncharacterized members. Here, we performed a phylogenetic analysis and discovered a protein cluster (GH31_u1) sharing low sequence similarity with the reported GH31 enzymes. Within this cluster, we showed that a GH31_u1 protein from Lactococcus lactis (LlGH31_u1) and its fungal homolog demonstrated hydrolytic activities against nigerose [α-D-Glcp-(1→3)-D-Glc]. The k_cat/K_m values of LlGH31_u1 against kojibiose and maltose were 13% and 2.1% of that against nigerose, indicating that LlGH31_u1 has a higher specificity to the α-1,3 linkage of nigerose than other characterized GH31 enzymes, including eukaryotic enzymes. Furthermore, the three-dimensional structures of LlGH31_u1 determined using X-ray crystallography and cryogenic electron microscopy revealed that LlGH31_u1 forms a hexamer and has a C-terminal domain comprising four α-helices, suggesting that it contributes to hexamerization. Finally, crystal structures in complex with nigerooligosaccharides and kojibiose along with mutational analysis revealed the active site residues involved in substrate recognition in this enzyme. This study reports the first structure of a bacterial GH31 α-1,3-glucosidase and provides new insight into the substrate specificity of GH31 enzymes and the physiological functions of bacterial and fungal GH31_u1 members.     

Structural basis of kinetic variations in Sucrose Phosphate Phosphatase (SPP) of rice and Anabaena unveiled through computational analysis

Sucrose is an important storage form of assimilated carbon in many plant species. Unlike other sucrose biosynthetic enzymes, Sucrose Phosphate Phosphatase (SPP), the terminal enzyme in sucrose biosynthetic pathway, is the least understood. SPPs from different organisms have different kinetic properties. The current study focuses on the structural differences among SPP homologues and unveils the probable structural basis of kinetic variations. We have employed computational methods of molecular modeling and structure comparisons and identified structural variations in some of the substrate binding residues, amino acid substitutions in regions that are lining the active site and minute structural differences that can enhance the nucleophilicity of a catalytic nucleophile (Asp 9 ). We report a structurally and hence functionally important amino acid substitution (Asp 159 by Alanine) in one of the rice SPP isoforms, which can result in the disruption of a H-bond that helps in binding of sucrose at the active site of the enzyme. In this paper we discuss the structural basis of enhanced catalytic efficiency of rice SPP in comparison with a cyanobacterium (Anabaena variabilis). The natural mutations identified in our analysis of the SPP catalytic domain would be useful in re-designing the enzyme for enhanced catalytic efficiency and higher sucrose production.     

Structure-function analysis of the kinase-CPD domain of yeast tRNA ligase (Trl1) and requirements for complementation of tRNA splicing by a plant Trl1 homolog

Trl1 is an essential 827 amino acid enzyme that executes the end-healing and end-sealing steps of tRNA splicing in Saccharomyces cerevisiae. Trl1 consists of two domains—an N-terminal ligase component and a C-terminal 5′-kinase/2′,3′-cyclic phosphodiesterase (CPD) component—that can function in tRNA splicing in vivo when expressed as separate polypeptides. To understand the structural requirements for the kinase-CPD domain, we performed an alanine scan of 30 amino acids that are conserved in Trl1 homologs from other fungi. We thereby identified four residues (Arg463, His515, Thr675 and Glu741) as essential for activity in vivo. Structure–function relationships at these positions, and at four essential or conditionally essential residues defined previously (Asp425, Arg511, His673 and His777), were clarified by introducing conservative substitutions. Biochemical analysis showed that lethal mutations of Asp425, Arg463, Arg511 and His515 in the kinase module abolished polynucleotide kinase activity in vitro. We report that a recently cloned 1104 amino acid Arabidopsis RNA ligase functions in lieu of yeast Trl1 in vivo and identify essential side chains in the ligase, kinase and CPD modules of the plant enzyme. The plant ligase, like yeast Trl1 but unlike T4 RNA ligase 1, requires a 2′-PO₄ end for tRNA splicing in vivo.     

Microarray and RNAi Analysis of P450s in Anopheles gambiae Male and Female Steroidogenic Tissues: CYP307A1 Is Required for Ecdysteroid Synthesis

In insects, the steroid hormone 20-hydroxyecdysone (20E) coordinates major developmental transitions. While the first and the final steps of 20E biosynthesis are characterized, the pathway from 7-dehydrocholesterol to 5β-ketodiol, commonly referred as the “black box”, remains hypothetical and whether there are still unidentified enzymes is unknown. The black box would include some oxidative steps, which are believed to be mediated by P450 enzymes. To identify new enzyme(s) involved in steroid synthesis, we analyzed by small-scale microarray the expression of all the genes encoding P450 enzymes of the malaria mosquito Anopheles gambiae in active steroidogenic organs of adults, ovaries from blood-fed females and male reproductive tracts, compared to inactive steroidogenic organs, ovaries from non-blood-fed females. Some genes encoding P450 enzymes were specifically overexpressed in female ovaries after a blood-meal or in male reproductive tracts but only three genes were found to be overexpressed in active steroidogenic organs of both females and males: cyp307a1, cyp4g16 and cyp6n1. Among these genes, only cyp307a1 has an expression pattern similar to other mosquito steroidogenic genes. Moreover, loss-of-function by transient RNAi targeting cyp307a1 disrupted ecdysteroid production demonstrating that this gene is required for ecdysteroid biosynthesis in Anopheles gambiae.     

Insights into the catalytic properties of bamboo vacuolar invertase through mutational analysis of active site residues

Plant acid invertases, which are either associated with the cell wall or present in vacuoles, belong to family 32 of glycoside hydrolases (GH32). Homology modeling of bamboo vacuolar invertase Boβfruct3 using Arabidopsis cell-wall invertase AtcwINV1 as a template showed that its overall structure is similar to GH32 enzymes, and that the three highly conserved motifs, NDPNG, RDP and EC, are located in the active site. This study also used site-directed mutagenesis to examine the roles of the conserved amino acid residues in these three motifs, which include Asp135, Arg259, Asp260, Glu316 and Cys317, and a conserved Trp residue (Trp159) that resides between the NDPNG and RDP motifs. The mutants W159F, W159L, E316Q and C317A retained acid invertase activity, but no invertase activity was observed for the mutant E316A or mutants with changes at Asp135, Arg259, or Asp260. The apparent K_m values of the four mutants with invertase activity were all higher than that of the wild-type enzyme. The mutants W159L and E316Q exhibited lower k_cat values than the wild-type enzyme, but an increase in the k_cat value was observed for the mutants W159F and C317A. The results of this study demonstrate that these residues have individual functions in catalyzing sucrose hydrolysis.     

Physico-chemical properties of the epoxide hydrolase from Rhodosporidium toruloides

Residue-specific chemical modification of amino acid residues of the microsomal epoxide hydrolase (mEH) from Rhodosporidium toruloides UOFS Y-0471 revealed that the enzyme is inactivated through modification of Asp/Glu and His residues, as well as through modification of Ser. Since Asp acts as the nucleophile, and Asp/Glu and His serve as charge relay partners in the catalytic triad of microsomal and soluble epoxide hydrolases during epoxide hydrolysis, inactivation of the enzyme by modification of the Asp/Glu and His residues agrees with the established reaction mechanism of these enzymes. However, the inactivation of the enzyme through modification of Ser residues is unexpected, suggesting that a Ser in the catalytic site is indispensable for substrate binding by analogy of the role of Ser residues in the related L-2-haloacid dehalogenases, as well as the ATPase and phosphatase enzymes. Co²⁺, Hg²⁺, Ag⁺, Mg²⁺ and Ca²⁺ inhibited enzyme activity and EDTA increased enzyme activity. The activation energy for inactivation of the enzyme was 167 kJ mol^–1. Kinetic constants for the enzyme could not be determined since unusual behaviour was displayed during hydrolysis of 1,2-epoxyoctane by the purified enzyme. Enantioselectivity w as strongly dependent on substrate concentration. When the substrate was added in concentrations ensuring two-phase conditions, the enantioselectivity was greatly enhanced. On the basis of these results, it is proposed that this enzyme acts at an interface, analogous to lipases.     

Long-range interaction between the enzyme active site and a distant allosteric site in the human mitochondrial NAD(P)-dependent malic enzyme

Our previous study has suggested that mutation of the amino acid residue Asp102 has a significant effect on the fumarate-mediated activation of human mitochondrial NAD(P)⁺-dependent malic enzyme (m-NAD(P)-ME). In this paper, we examine the cationic amino acid residue Arg98, which is adjacent to Asp102 and is highly conserved in most m-NAD(P)-MEs. A series of R98/D102 mutants were created to examine the possible interactions between Arg98 and Asp102 using the double-mutant cycle analysis. Kinetic analysis revealed that the catalytic efficiency of the enzyme was severely affected by mutating both Arg98 and Asp102 residues. However, the binding energy of these mutant enzymes to fumarate as determined by analysis of the K_A,Fum values, show insignificant differences, indicating that the mutation of Arg98 and Asp102 did not cause a significant decrease in the binding affinity of fumarate. The overall coupling energies for R98K/D102N as determined by analysis of the k_cat/K_m and K_A,Fum values were −2.95 and −0.32 kcal/mol, respectively. According to these results, we conclude that substitution of both Arg98 and Asp102 residues has a synergistic effect on the catalytic ability of the enzyme.     

Using continuous directed evolution to improve enzymes for plant applications

Continuous directed evolution of enzymes and other proteins in microbial hosts is capable of outperforming classical directed evolution by executing hypermutation and selection concurrently in vivo, at scale, with minimal manual input. Provided that a target enzyme’s activity can be coupled to growth of the host cells, the activity can be improved simply by selecting for growth. Like all directed evolution, the continuous version requires no prior mechanistic knowledge of the target. Continuous directed evolution is thus a powerful way to modify plant or non-plant enzymes for use in plant metabolic research and engineering. Here, we first describe the basic features of the yeast (Saccharomyces cerevisiae) OrthoRep system for continuous directed evolution and compare it briefly with other systems. We then give a step-by-step account of three ways in which OrthoRep can be deployed to evolve primary metabolic enzymes, using a THI4 thiazole synthase as an example and illustrating the mutational outcomes obtained. We close by outlining applications of OrthoRep that serve growing demands (i) to change the characteristics of plant enzymes destined for return to plants, and (ii) to adapt (“plantize”) enzymes from prokaryotes—especially exotic prokaryotes—to function well in mild, plant-like conditions.

Continuous directed evolution using the yeast OrthoRep system is a powerful way to improve enzymes for use in plant engineering as illustrated by “plantizing” a bacterial thiamin synthesis enzyme.     

Mutational Analysis of UMP Kinase from Escherichia coli

UMP kinase from Escherichia coli is one of the four regulatory enzymes involved in the de novo biosynthetic pathway of pyrimidine nucleotides. This homohexamer, with no counterpart in eukarya, might serve as a target for new antibacterial drugs. Although the bacterial enzyme does not show sequence similarity with any other known nucleoside monophosphate kinase, two segments between amino acids 35 to 78 and 145 to 194 exhibit 28% identity with phosphoglycerate kinase and 30% identity with aspartokinase, respectively. Based on these similarities, a number of residues of E. coli UMP kinase were selected for site-directed mutagenesis experiments. Biochemical, kinetic, and spectroscopic analysis of the modified proteins identified residues essential for catalysis (Asp146), binding of UMP (Asp174), and interaction with the allosteric effectors, GTP and UTP (Arg62 and Asp77).     

New developments in our understanding of the β-hydroxyacid dehydrogenases

The β-hydroxyacid dehydrogenases are a structurally conserved family of enzymes that catalyze the NAD⁺ or NADP⁺-dependent oxidation of specific β-hydroxyacid substrates like β-hydroxyisobutyrate. These enzymes share distinct domains of amino acid sequence homology, most of which now have assigned putative functions. 6-phosphogluconate dehydrogenase and β-hydroxyisobutyrate dehydrogenase, the most well-characterized members, both appear to be readily inactivated by chemical modifiers of lysine residues, such as 2,4,6-trinitrobenzene sulfonate (TNBS). Peptide mapping by ESI-LCMS showed that inactivation of β-hydroxyisobutyrate dehydrogenase with TNBS occurs with the labeling of a single lysine residue, K248. This lysine residue is completely conserved in all family members and may have structural importance relating to cofactor binding. The structural framework of the β-hydroxyacid dehydrogenase family is shared by many bacterial homologues. One such homologue from E. coli has been cloned and expressed as recombinant protein. This protein was found to have enzymatic activity characteristic of tartronate semialdehyde reductase, an enzyme required for bacterial biosynthesis of d-glycerate. A homologue from H. influenzae was also cloned and expressed as recombinant protein. This protein was active in the oxidation of d-glycerate, but showed approximately ten-fold higher activity with four carbon substrates like β-d-hydroxybutyrate and d-threonine. This enzyme might function in H. influenzae, and other species, in the utilization of polyhydroxybutyrates, an energy storage form specific to bacteria. Cloning and characterization of these bacterial β-hydroxyacid dehydrogenases extends our knowledge of this enzyme family.