Crystal structure of plant asparaginase

In plants, specialized enzymes are required to catalyze the release of ammonia from asparagine, which is the main nitrogen-relocation molecule in these organisms. In addition, K+-independent plant asparaginases are also active in splitting the aberrant isoaspartyl peptide bonds, which makes these proteins important for seed viability and germination. Here, we present the crystal structure of potassium-independent L-asparaginase from yellow lupine (LlA) and confirm the classification of this group of enzymes in the family of Ntn-hydrolases. The alpha- and beta-subunits that form the mature (alphabeta)2 enzyme arise from autoproteolytic cleavage of two copies of a precursor protein. In common with other Ntn-hydrolases, the (alphabeta) heterodimer has a sandwich-like fold with two beta-sheets flanked by two layers of alpha-helices (alphabetabetaalpha). The nucleophilic Thr193 residue, which is liberated in the autocatalytic event at the N terminus of subunit beta, is part of an active site that is similar to that observed in a homologous bacterial enzyme. An unusual sodium-binding loop of the bacterial protein, necessary for proper positioning of all components of the active site, shows strictly conserved conformation and metal coordination in the plant enzyme. A chloride anion complexed in the LlA structure marks the position of the alpha-carboxylate group of the L-aspartyl substrate/product moiety. Detailed analysis of the active site suggests why the plant enzyme hydrolyzes asparagine and its beta-peptides but is inactive towards substrates accepted by similar Ntn-hydrolases, such as taspase1, an enzyme implicated in some human leukemias. Structural comparisons of LlA and taspase1 provide interesting insights into the role of small inorganic ions in the latter enzyme.     

Structural comparison of Ntn-hydrolases

The Ntn-hydrolases (N-terminal nucleophile) are a superfamily of diverse enzymes that has recently been characterized. All of the proteins in this family are activated autocatalytically; they contain an N-terminally located catalytic nucleophile, and they cleave an amide bond. In the present study, the structures of four enzymes of this superfamily are compared in more detail. Although the amino acid sequence homology is almost completely absent, the enzymes share a similar alphabeta betaalpha-core structure. The central beta-sheets in the core were found to have different packing angles, ranging from 5 to 35 degrees. In the Ntn-hydrolases under study, eight totally conserved secondary structure units were found (region C). Five of them were observed to contain the greatest number of conserved and functionally important residues and are therefore crucial for the structure and function of Ntn-hydrolases. Two additional regions, consisting of secondary structure units (regions A and B), were found to be in structurally similar locations, but in different orders in the polypeptide chain. The catalytic machinery is located in the structures in a similar manner, and thus the catalytic mechanisms of all of the enzymes are probably similar. However, the substrate binding and the oxyanion hole differed partially.     

Identification and expression analysis of a gene encoding a bacterial-type phosphoenolpyruvate carboxylase from Arabidopsis and rice

Phosphoenolpyruvate carboxylase (PEPC) is distributed in plants and bacteria but is not found in fungi and animal cells. Important motifs for enzyme activity and structure are conserved in plant and bacterial PEPCs, with the exception of a phosphorylation domain present at the N terminus of all plant PEPCs reported so far, which is absent in the bacterial enzymes. Here, we describe a gene from Arabidopsis, stated as Atppc4, encoding a PEPC, which shows more similarity to Escherichia coli than to plant PEPCs. Interestingly, this enzyme lacks the phosphorylation domain, hence indicating that it is a bacterial-type PEPC. Three additional PEPC genes are present in Arabidopsis, stated as Atppc1, Atppc2, and Atppc3, encoding typical plant-type enzymes. As most plant PEPC genes, Atppc1, Atppc2, and Atppc3 are formed by 10 exons interrupted by nine introns. In contrast, Atppc4 gene has an unusual structure formed by 20 exons. A bacterial-type PEPC gene was also identified in rice (Oryza sativa), stated as Osppc-b, therefore showing the presence of this type of PEPC in monocots. The phylogenetic analysis suggests that both plant-type and bacterial-type PEPCs diverged early during the evolution of plants from a common ancestor, probably the PEPC from gamma-proteobacteria. The diversity of plant-type PEPCs in C3, C4, and Crassulacean acid metabolism plants is indicative of the evolutionary success of the regulation by phosphorylation of this enzyme. Although at a low level, the bacterial-type PEPC genes are expressed in Arabidopsis and rice.     

Plant-type and bacterial-type ferredoxins in a nitrogen-fixing cyanobacterium: Nostoc sp. strain PCC 73102

Abstract The cyanobacterium Nostoc sp. strain PCC 73102, cultured under nitrogen-fixing conditions, was investigated for the occurrence of ferrodoxins by SDS-PAGE/Western immunoblots using antisera directed against both a major plant-type and a bacterial-type ferredoxin purified from Anabaena variabilis . Immunocytological labelling and transmission electron microscopy were used to study the distribution of both types of ferredoxins in the Nostoc cells. SDS-PAGE/Western immunoblots revealed two proteins/polypeptides in the Nostoc strain, immunologically related to two soluble ferredoxins purified from Anabaena variabilis : the major plant-type ferredoxin (Fd I) and a bacterial-type ferredoxin (Fd III). Immunolocalization showed a uniform distribution of the plant-type and the bacterial-type ferredoxin in both the photosynthetic vegetative cells and in the nitrogen-fixing heterocysts, with no specific association with any subcellular inclusions. Using the particle analysis of an image processor, the labelling associated with the vegetative cells, expressed as number of gold particles per cell area, was found to be only slightly higher (1.2x) or almost twice as high (1.9x) compared to the heterocysts for the major plant-type and the bacterial-type ferredoxin, respectively.     

Crystal structure of isoaspartyl aminopeptidase in complex with L-aspartate

The crystal structure of Escherichia coli isoaspartyl aminopeptidase/asparaginase (EcAIII), an enzyme belonging to the N-terminal nucleophile (Ntn)-hydrolases family, has been determined at 1.9-A resolution for a complex obtained by cocrystallization with l-aspartate, which is a product of both enzymatic reactions catalyzed by EcAIII. The enzyme is a dimer of heterodimers, (alphabeta)(2). The (alphabeta) heterodimer, which arises by autoproteolytic cleavage of the immature protein, exhibits an alphabetabetaalpha-sandwich fold, typical for Ntn-hydrolases. The asymmetric unit contains one copy of the EcAIII.Asp complex, with clearly visible l-aspartate ligands, one bound in each of the two active sites of the enzyme. The l-aspartate ligand is located near Thr(179), the N-terminal residue of subunit beta liberated in the autoproteolytic event. Structural comparisons with the free form of EcAIII reveal that there are no major rearrangements of the active site upon aspartate binding. Although the ligand binding mode is similar to that observed in an l-aspartate complex of the related enzyme human aspartylglucosaminidase, the architecture of the EcAIII active site sheds light on the question of substrate specificity and explains why EcAIII is not able to hydrolyze glycosylated asparagine substrates.     

Gliap--a novel untypical L-asparaginase localized to rat brain astrocytes

L-asparaginases catalyse the formation of the neuroactive amino acid L-aspartate by deamination of asparagine. The major pathophysiological significance of L-asparaginase activity is in its clinical use for the treatment of acute lymphatic leukaemia and neoplasias that require asparagine and obtain it from circulating pools. Here we report the identification and characterization of Gliap, a cytosolic L-asparaginase, which is the founding member of a new group of L-asparaginases in mammalia. Structural modelling suggests that Gliap is an atypical mammalian type-I asparaginase inasmuch as it harbours the active centre of a type-I glycosylasparaginase but, like plant-type asparaginases, lacks their auto-proteolytic site and, in addition, exhibits significant type-II L-asparaginase enzymatic activity. Moreover, in contrast to glycosylasparaginases Gliap is enriched in the cytosolic fraction and not in lysosomes. The protein is particularly abundant in liver, testis and brain. In brain Gliap is exclusively expressed in astrocytes and prominently present in structures reminiscent of glial endfeet. These data suggest that Gliap is involved in astroglial production of the neuroactive amino acid L-aspartate.     

Only plant-type (GLYK) glycerate kinases produce d-glycerate 3-phosphate

d-Glycerate kinases (GK) occur in three phylogenetically distinct classes. Class II GKs produce glycerate 2-phosphate, while both class I GK and class III GK (GLYK) are thought to produce glycerate 3-phosphate. We report on the identification of a bacterial-type class I GK in the unicellular cyanobacterium Synechocystis sp. strain PCC 6803 and of a plant-type GLYK in the filamentous cyanobacterium Nostoc sp. strain PCC 7120. The comparison with other prokaryotic and eukaryotic GKs of both classes shows that glycerate 3-phosphate is produced only by the GLYKs, but, in contrast to current thinking, not by any of the examined class I enzymes.     

Specificity of molecular recognition in oligomerization of bacterial L-asparaginases

Bacterial L-asparaginases, which are widely used in the antitumor therapy, act only as homotetramers, because their active sites are located at the interface between the subunits of these enzymes. High stability of aspaginase tetramers is determined by ion pair formation between subunits, and this suggests high specificity of molecular recognition during oligomerization of bacterial L-asparaginases. In this study we have investigated specificity of molecular recognition in oligomerization of some bacterial asparaginases by a biosensor based on surface plasmon resonance. It was shown, that a stable tetrameric complex could be formed only by the subunits of the same L-asparaginase. Using two mutants of Helicobacter pylori L-asparaginase it was shown that even a single point mutation at the interface of highly homologous and closely related subunits significantly reduced specificity of molecular recognition.     

The cyanobacterium Gloeobacter violaceus PCC 7421 uses bacterial-type phytoene desaturase in carotenoid biosynthesis

Carotenoid composition and its biosynthetic pathway in the cyanobacterium Gloeobacter violaceus PCC 7421 were investigated. beta-Carotene and (2S,2'S)-oscillol 2,2'-di(alpha-L-fucoside), and echinenone were major and minor carotenoids, respectively. We identified two unique genes for carotenoid biosynthesis using in vivo functional complementation experiments. In Gloeobacter, a bacterial-type phytoene desaturase (CrtI), rather than plant-type desaturases (CrtP and CrtQ), produced lycopene. This is the first demonstration of an oxygenic photosynthetic organism utilizing bacterial-type phytoene desaturase. We also revealed that echinenone synthesis is catalyzed by CrtW rather than CrtO. These findings indicated that Gloeobacter retains ancestral properties of carotenoid biosynthesis.     

Expression, purification, and characterization of a new heterotetramer structure of leucyl-tRNA synthetase from Aquifex aeolicus in Escherichia coli

Aminoacyl-tRNA synthetases are key players in the interpretation of the genetic code. They constitute a textbook example of multi-domain proteins including insertion and terminal functional modules appended to one of the two class-specific active site domains. The non-catalytic domains usually have distinct roles in the aminoacylation reaction. Aquifex aeolicus leucyl-tRNA synthetase (LeuRS) is composed of a separated catalytic site and tRNA anticodon-binding site, which would represent one of the closest relics of the primordial aminoacyl-tRNA synthetase. Moreover, the essential catalytic site residues are split into the two different subunits. In all other class-I aminoacyl-tRNA synthetases, those two functional polypeptides are nowadays fused into a single protein chain. In this work, we report the isolation and the characterization, in Escherichia coli, of a novel oligomeric form (alphabeta)2 for A. aeolicus LeuRS, which is present in addition to the alphabeta heterodimer. A. aeolicus (alphabeta)2 LeuRS has been characterized by biochemical and biophysical methods. Native gel electrophoresis, mass spectrometry, analytical ultracentrifugation, and kinetic analysis confirmed that the (alphabeta)2 enzyme was a stable and active entity. By mass spectrometry we confirmed that the heterodimer alphabeta can bind one tRNALeu molecule whereas the heterotetramer (alphabeta)2 can bind two tRNALeu molecules. Active site titration and aminoacylation assays showed that two functional active sites are found per heterotetramer, suggesting that this molecular species might exist and be active in vivo. All those data suggest that the existence of the heterotetramer is certainly not an artifact of overexpression in E. coli.     

Determination of native oligomeric state and substrate specificity of rat NTPDase1 and NTPDase2 after heterologous expression in Xenopus oocytes.

NTPDase1 and NTPDase2 are two related plasma membrane-located enzymes involved in the extracellular degradation of nucleoside 5'-tri- and -diphosphates. They differ regarding their hydrolysis ratios for ATP and ADP. Both enzymes have a predicted transmembrane domain close to the N- and C-terminus, respectively, connected by an extensive extracellular domain that carries the active site. We expressed the rat-derived enzymes in Xenopus laevis oocytes and analyzed their quarternary structure. As revealed by application of blue native PAGE and a comparison of glutaraldehyde cross-linking, native NTPDase1 and NTPDase2 occur in oligomeric form. Oligomer formation of the cell surface-located pool of the enzymes was verified by surface iodination. The two enzymes differed in oligomeric structure and in oligomer complex stability. NTPDase1 preferentially occurred as a dimer that could be dissociated into monomeric forms in the presence of Coomassie Brilliant blue G-250 and dithiothreitol whereas NTPDase2 revealed higher oligomeric forms up to tetramers, largely resistant to dithiothreitol. Our results further suggest that the enzymes exist in varying oligomeric states. In contrast to NTPDase1, substrate specificity of NTPDase2 was altered with prolonged expression time, resulting in a decrease in the ATPase/ADPase activity ratio from 10 : 1 to 2.5 : 1. This was accompanied by a transition into a higher oligomeric state. Our results suggest that despite close sequence identity, NTPDase1 and NTPDase2 differ in oligomeric structure. Dynamic alterations in oligomeric state may induce changes in substrate preference and thus influence the pattern of extracellular nucleotide degradation in situ.     

Cysteine activation is an inherent in vitro property of prolyl-tRNA synthetases

Aminoacyl-tRNA synthetases are well known for their remarkable precision in substrate selection during aminoacyl-tRNA formation. Some synthetases enhance the accuracy of this process by editing mechanisms that lead to hydrolysis of incorrectly activated and/or charged amino acids. Prolyl-tRNA synthetases (ProRSs) can be divided into two structurally divergent groups, archaeal-type and bacterial-type enzymes. A striking difference between these groups is the presence of an insertion domain (approximately 180 amino acids) in the bacterial-type ProRS. Because the archaeal-type ProRS enzymes have been shown to recognize cysteine, we tested selected ProRSs from all three domains of life to determine whether cysteine activation is a general property of ProRS. Here we show that cysteine is activated by recombinant ProRS enzymes from the archaea Methanocaldococcus jannaschii and Methanothermobacter thermautotrophicus, from the eukaryote Saccharomyces cerevisiae, and from the bacteria Aquifex aeolicus, Borrelia burgdorferi, Clostridium sticklandii, Cytophaga hutchinsonii, Deinococcus radiodurans, Escherichia coli, Magnetospirillum magnetotacticum, Novosphingobium aromaticivorans, Rhodopseudomonas palustris, and Thermus thermophilus. This non-cognate amino acid was efficiently acylated in vitro onto tRNA(Pro), and the misacylated Cys-tRNA(Pro) was not edited by ProRS. Therefore, ProRS exhibits a natural level of mischarging that is to date unequalled among the aminoacyl-tRNA synthetases.     

Bioinformatic analysis of fold-type III PLP-dependent enzymes discovers multimeric racemases

Pyridoxal-5′-phosphate (PLP)-dependent enzymes are ubiquitous in nature and catalyze a variety of important metabolic reactions. The fold-type III PLP-dependent enzyme family is primarily comprised of decarboxylases and alanine racemases. In the development of a multiple structural alignment database (3DM) for the enzyme family, a large subset of 5666 uncharacterized proteins with high structural, but low sequence similarity to alanine racemase and decarboxylases was found. Compared to these two classes of enzymes, the protein sequences being the object of this study completely lack the C-terminal domain, which has been reported important for the formation of the dimer interface in other fold-type III enzymes. The 5666 sequences cluster around four protein templates, which also share little sequence identity to each other. In this work, these four template proteins were solubly expressed in Escherichia coli, purified, and their substrate profiles were evaluated by HPLC analysis for racemase activity using a broader range of amino acids. They were found active only against alanine or serine, where they exhibited Michaelis constants within the range of typical bacterial alanine racemases, but with significantly lower turnover numbers. As the already described racemases were proposed to be active and appeared to be monomers as judged from their crystal structures, we also investigated this aspect for the four new enzymes. Here, size exclusion chromatography indicated the presence of oligomeric states of the enzymes and a native-PAGE in-gel assay showed that the racemase activity was present only in an oligomeric state but not as monomer. This suggests the likelihood of a different behavior of these enzymes in solution compared to the one observed in crystalline form.

     

Structure and Function of Plant-Type Ferredoxins

The plant-type ferredoxins (Fds) are the [2Fe-2S] proteins that function primarily in photosynthesis; they transfer electrons from photoreduced Photosystem I to ferredoxin NADP(+) reductase in which NADPH is produced for CO(2) assimilation. In addition, Fds partition electrons to various ferredoxin-dependent enzymes not only for assimilations of inorganic nitrogen and sulfur and N(2) fixation but also for regulation of CO(2) assimilation cycle. Although Fds are small iron-sulfur proteins with molecular weight of 11 KDa, they are expected to interact with surprisingly many enzymes. Several Fd isoforms were found in non-photosynthetic cells as well as Fds in photosynthetic cells, leading to the recognition that they have differentiated physiological roles. In a quarter of century, X-ray crystallography and NMR spectroscopy provided wealth of structural data, which shed light on the structure-function relationship of the plant-type Fds and gave structural basis for the biochemical and spectroscopic properties so far accumulated. Thus the structural studies of Fds have come to a new era in which different roles of Fds and interactions with various enzymes are clarified on the basis of the tertiary and quaternary structures, although they are premature at present. This article reviews briefly the structures of the plant-type Fds together with their functions, properties, and interactions with Fd related enzymes. Lastly the folding motif of Fd, that has grown to be a large family by including many functionally unrelated proteins, is noted.     

Protein‐engineering of chitosanase from Bacillus sp. MN to alter its substrate specificity

Partially acetylated chitosan oligosaccharides (paCOS) have various potential applications in agriculture, biomedicine, and pharmaceutics due to their suitable bioactivities. One method to produce paCOS is partial chemical hydrolysis of chitosan polymers, but that leads to poorly defined mixtures of oligosaccharides. However, the effective production of defined paCOS is crucial for fundamental research and for developing applications. A more promising approach is enzymatic depolymerization of chitosan using chitinases or chitosanases, as the substrate specificity of the enzyme determines the composition of the oligomeric products. Protein‐engineering of these enzymes to alter their substrate specificity can overcome the limitations associated with naturally occurring enzymes and expand the spectrum of specific paCOS that can be produced. Here, engineering the substrate specificity of Bacillus sp. MN chitosanase is described for the first time. Two muteins with active site substitutions can accept N‐acetyl‐D‐glucosamine units at their subsite (?2), which is impossible for the wildtype enzyme.     

A catalytic mechanism for cysteine N-terminal nucleophile hydrolases, as revealed by free energy simulations

The N-terminal nucleophile (Ntn) hydrolases are a superfamily of enzymes specialized in the hydrolytic cleavage of amide bonds. Even though several members of this family are emerging as innovative drug targets for cancer, inflammation, and pain, the processes through which they catalyze amide hydrolysis remains poorly understood. In particular, the catalytic reactions of cysteine Ntn-hydrolases have never been investigated from a mechanistic point of view. In the present study, we used free energy simulations in the quantum mechanics/molecular mechanics framework to determine the reaction mechanism of amide hydrolysis catalyzed by the prototypical cysteine Ntn-hydrolase, conjugated bile acid hydrolase (CBAH). The computational analyses, which were confirmed in water and using different CBAH mutants, revealed the existence of a chair-like transition state, which might be one of the specific features of the catalytic cycle of Ntn-hydrolases. Our results offer new insights on Ntn-mediated hydrolysis and suggest possible strategies for the creation of therapeutically useful inhibitors.     

The BmChi-h gene, a bacterial-type chitinase gene of Bombyx mori, encodes a functional exochitinase that plays a role in the chitin degradation during the molting process

The silkworm, Bombyx mori, has been recently demonstrated to contain a bacterial-type chitinase gene (BmChi-h) in addition to a well-characterized endochitinase gene (BmChitinase). The deduced amino acid sequence of BmChi-h showed extensive structural similarities with chitinases from bacteria such as Serratia marcescens chiA and baculoviruses (v-CHIA). Bacterial-type chitinase genes have not been found from any eukaryotes and viruses except for lepidopteran insects and lepidopteran baculoviruses. Thus, it was suggested that BmChi-h may be derived from a bacterial or baculovirus chitinase gene via horizontal gene transfer. In this report, we investigated the biological function of BmChi-h. Our enzymological study indicated that a chitinase encoded by BmChi-h has exo-type substrate preference, which is the same as S. marcescens chiA and v-CHIA, and different from BmChitinase, which has endo-type substrate preference. An immunohistochemical study revealed that BmChi-h localizes in the chitin-containing tissues during the molting stages, indicating that it plays a role in chitin degradation during molting. These results suggest that BmChi-h (exochitinase) and BmChitinase (endochitinase) may catalyze a native chitin by a concerted mechanism. Cloning and comparison of BmChi-h orthologues revealed that bacterial-type chitinase genes are highly conserved among lepidopteran insects, suggesting that the utilization of a bacterial-type chitinase during the molting process may be a general feature of lepidopteran insects.     

Oligomerization of the Na,K-ATPase in cell membranes

The higher order oligomeric state of the Na,K-ATPase alphabeta heterodimer in cell membranes is the subject of controversy. We have utilized the baculovirus-infected insect cell system to express Na,K-ATPase with alpha-subunits bearing either His(6) or FLAG epitopes at the carboxyl terminus. Each of these constructs produced functional Na,K-ATPase alphabeta heterodimers that were delivered to the plasma membrane (PM). Cells were simultaneously co-infected with viruses encoding alpha-His/beta and alpha-FLAG/beta Na,K-ATPases. Co-immunoprecipitation of the His-tagged alpha-subunit in the endoplasmic reticulum (ER) and PM fractions of co-infected cells by the anti-FLAG antibody demonstrates that protein-protein associations exist between these heterodimers. This suggests the Na,K-ATPase is present in cell membranes in an oligomeric state of at least (alphabeta)(2) composition. Deletion of 256 amino acid residues from the central cytoplasmic loop of the alpha-subunit results in the deletion alpha-4,5-loop-less (alpha-4,5LL), which associates with beta but is confined to the ER. Co-immunoprecipitation demonstrates that when this inactive alpha-4,5LL/beta heterodimer is co-expressed with wild-type alphabeta, oligomers of wild-type alphabeta and alpha-4,5LL/beta form in the ER, but the alpha-4,5LL mutant remains retained in the ER, and the wild-type protein is still delivered to the PM. We conclude that the Na,K-ATPase is present as oligomers of the monomeric alphabeta heterodimer in native cell membranes.