Nucleotide binding interactions modulate dNTP selectivity and facilitate 8-oxo-dGTP incorporation by DNA polymerase lambda

8-Oxo-7,8,-dihydro-2′-deoxyguanosine triphosphate (8-oxo-dGTP) is a major product of oxidative damage in the nucleotide pool. It is capable of mispairing with adenosine (dA), resulting in futile, mutagenic cycles of base excision repair. Therefore, it is critical that DNA polymerases discriminate against 8-oxo-dGTP at the insertion step. Because of its roles in oxidative DNA damage repair and non-homologous end joining, DNA polymerase lambda (Pol λ) may frequently encounter 8-oxo-dGTP. Here, we have studied the mechanisms of 8-oxo-dGMP incorporation and discrimination by Pol λ. We have solved high resolution crystal structures showing how Pol λ accommodates 8-oxo-dGTP in its active site. The structures indicate that when mispaired with dA, the oxidized nucleotide assumes the mutagenic syn-conformation, and is stabilized by multiple interactions. Steady-state kinetics reveal that two residues lining the dNTP binding pocket, Ala⁵¹⁰ and Asn⁵¹³, play differential roles in dNTP selectivity. Specifically, Ala⁵¹⁰ and Asn⁵¹³ facilitate incorporation of 8-oxo-dGMP opposite dA and dC, respectively. These residues also modulate the balance between purine and pyrimidine incorporation. Our results shed light on the mechanisms controlling 8-oxo-dGMP incorporation in Pol λ and on the importance of interactions with the incoming dNTP to determine selectivity in family X DNA polymerases.     

Structural and Dynamic Features of the MutT Protein in the Recognition of Nucleotides with the Mutagenic 8-Oxoguanine Base

Escherichia coli MutT hydrolyzes 8-oxo-dGTP to 8-oxo-dGMP, an event that can prevent the misincorporation of 8-oxoguanine opposite adenine in DNA. Of the several enzymes that recognize 8-oxoguanine, MutT exhibits high substrate specificity for 8-oxoguanine nucleotides; however, the structural basis for this specificity is unknown. The crystal structures of MutT in the apo and holo forms and in the binary and ternary forms complexed with the product 8-oxo-dGMP and 8-oxo-dGMP plus Mn²⁺, respectively, were determined. MutT strictly recognizes the overall conformation of 8-oxo-dGMP through a number of hydrogen bonds. This recognition mode revealed that 8-oxoguanine nucleotides are discriminated from guanine nucleotides by not only the hydrogen bond between the N7-H and Oδ (N119) atoms but also by the syn glycosidic conformation that 8-oxoguanine nucleotides prefer. Nevertheless, these discrimination factors cannot by themselves explain the roughly 34,000-fold difference between the affinity of MutT for 8-oxo-dGMP and dGMP. When the binary complex of MutT with 8-oxo-dGMP is compared with the ligand-free form, ordering and considerable movement of the flexible loops surrounding 8-oxo-dGMP in the binary complex are observed. These results indicate that MutT specifically recognizes 8-oxoguanine nucleotides by the ligand-induced conformational change.     

Structural and Biochemical Evidence That a TEM-1 ��-Lactamase N170G Active Site Mutant Acts via Substrate-assisted Catalysis

TEM-1 β-lactamase is the most common plasmid-encoded β-lactamase in Gram-negative bacteria and is a model class A enzyme. The active site of class A β-lactamases share several conserved residues including Ser⁷⁰, Glu¹⁶⁶, and Asn¹⁷⁰ that coordinate a hydrolytic water involved in deacylation. Unlike Ser⁷⁰ and Glu¹⁶⁶, the functional significance of residue Asn¹⁷⁰ is not well understood even though it forms hydrogen bonds with both Glu¹⁶⁶ and the hydrolytic water. The goal of this study was to examine the importance of Asn¹⁷⁰ for catalysis and substrate specificity of β-lactam antibiotic hydrolysis. The codon for position 170 was randomized to create a library containing all 20 possible amino acids. The random library was introduced into Escherichia coli, and functional clones were selected on agar plates containing ampicillin. DNA sequencing of the functional clones revealed that only asparagine (wild type) and glycine at this position are consistent with wild-type function. The determination of kinetic parameters for several substrates revealed that the N170G mutant is very efficient at hydrolyzing substrates that contain a primary amine in the antibiotic R-group that would be close to the Asn¹⁷⁰ side chain in the acyl-intermediate. In addition, the x-ray structure of the N170G enzyme indicated that the position of an active site water important for deacylation is altered compared with the wild-type enzyme. Taken together, the results suggest the N170G TEM-1 enzyme hydrolyzes ampicillin efficiently because of substrate-assisted catalysis where the primary amine of the ampicillin R-group positions the hydrolytic water and allows for efficient deacylation.     

Half molecules of serine-specific transfer ribonucleic acids from yeast

The preparation and analysis of half molecules from tRNA^Ser are described. Two pG-halves were isolated which differed only in the presence or absence of an acetyl group on the cytidylic acid residue at position 12. The CCA-half derived from tRNA₁^Ser was isolated pure, while the CCA-half derived from tRNA₂^Ser was isolated as a mixture with the CCA-half from tRNA₁^Ser from which the terminal CpCpA had been cleaved off.The acceptor activity of the combined complementary half molecules was 90% of the one of intact tRNA^Ser. The Michaelis constant and maximal velocity of amino-acylation were found to be identical for tRNA^Ser and the combined fragments.When half molecules were present at different ratios in aminoacylation studies it was found that one pG-half molecule can mediate the charging of several CCA-half molecules. There are indications that the CCA-half molecule alone can accept some serine. The CCA-half molecule alone can be aminoacylated to a rather high degree in the presence of an excess of tRNA_ox^Ser or tRNA^Ser-a and to a small degree in the presence of tRNA_ox^Ala (yeast) but not at all in the presence of tRNA_ox^Phe or tRNA_ox^Val (E. coli).Combinations of half molecules from tRNA^Ser with the opposite half molecules from tRNA^Phe could not be aminoacylated with Ser or Phe or 15 other amino acids although one of the combinations was well associated according to gel electrophoresis and differential melting curves.     

Ser422 phosphorylation blocks human Tau cleavage by caspase-3: Biochemical implications to Alzheimer’s Disease

Proteolytic truncation of microtubule associated human (h) Tau protein by caspase-3 at the carboxy (C) terminus has been linked to the pathogenesis of Alzheimer’s Disease (AD). This cleavage likely occurs between Asp⁴²¹↓Ser⁴²² leading to the formation of 421-mer truncated Tau protein which has been found to be present as aggregate in high level after phosphorylation in mortal AD brain tissue compared to normal. At least 50 phosphorylation sites involving Ser, Thr and Tyr residues have been identified or proposed in hTau and a selected number of them have been implicated in hTau aggregation following latter’s proteolytic truncation. Interestingly, it is further noted that Ser⁴²² residue present in the P1′ position of hTau caspase-3 cleavage region is a potential phosphorylation site. So we became interested to examine in vitro the effect of phospho-Ser⁴²² residue on hTau cleavage by caspase-3 which is a crucial upstream event associated with hTau self-assembly leading to AD pathogenesis. The goal of this project is to study in vitro the caspase-3 cleavage site of hTau protein and to examine the kinetics of this cleavage following Ser⁴²² phosphorylation and treatment with caspase-3 inhibitors. This is achieved by designing peptides from the sequence of hTau protein containing the proposed caspase-3 cleavage region. Peptides were designed from 441-mer major human Tau protein sequence that encompasses the proposed caspase-3 cleavage site [Asp⁴²¹↓Ser⁴²²]. Corresponding phospho-, dextro-Ser⁴²² and dextro-Asp⁴²¹ analogs were also designed. Peptides were synthesized by solid phase chemistry, purified and fully characterized by mass spectrometry. These were then incubated with recombinant caspase-3 enzyme under identical condition for digestion and analyzed for cleavage by mass spectrometry and RP-HPLC chromatograms. Our results indicated that while the control peptide is efficiently cleaved by caspase-3 at Asp⁴²¹↓Ser⁴²² site producing the expected N- and C-terminal fragment peptides, the corresponding phospho-Ser⁴²² peptide remained completely resistant to the cleavage. Substitution of Asp⁴²¹ by its dextro isoform also blocks peptide cleavage by caspase-3. However substitution of Ser⁴²² by its dextro isoform in the peptide did not affect the cleavage significantly. The above results were further confirmed by caspase-3 digestion experiment in the presence of varying amounts of caspase-3 inhibitor (Ac-DQVD-aldehyde) which was found to block this cleavage in a highly effective manner. Our results highlighted the crucial significance of Ser⁴²² phosphorylation and suggest that the kinase associated with this Ser-phosphorylation may protect Tau from aggregation. Thus specific promoters/activators of this kinase may find useful therapeutic benefits in arresting Tau truncation by caspase-3 and the progression of AD. In addition our data demonstrated that Tau-peptides where Ser⁴²² or Asp⁴²¹ are substituted by their respective dextro isomers, exhibit different cleavage kinetics by caspase-3 and this may have important implications in therapeutic intervention of Tau aggregation and associated AD.     

Improvements of rolling circle amplification (RCA) efficiency and accuracy using Thermus thermophilus SSB mutant protein

Rolling circle amplification (RCA) of plasmid or genomic DNA using random hexamers and bacteriophage phi29 DNA polymerase has become increasingly popular in the amplification of template DNA in DNA sequencing. We have found that the mutant protein of single-stranded DNA binding protein (SSB) from Thermus thermophilus (Tth) HB8 enhances the efficiency of amplification of DNA templates. In addition, the TthSSB mutant protein increased the specificity of phi29 DNA polymerase. We have overexpressed the native and mutant forms of TthSSB protein in Escherichia coli and purified them to homogeneity. In vitro, these proteins were found to bind specifically to single-stranded DNA. Addition of TthSSB mutant protein to RCA halved the elongation time required for phi29 DNA polymerase to synthesize DNA fragments in RCA. Furthermore, the presence of the TthSSB mutant protein essentially eliminates nonspecific DNA products in RCA reactions.     

Cloning and expression of a gene from Isochrysis galbana modifying fatty acid profiles in Escherichia coli

An ester hydrolase gene from the microalga Isochrysis galbana was cloned and expressed in Escherichia coli BL21 Rosetta 2?. The full-length putative gene has 1,146 base pairs and codes for a 381-amino acid polypeptide. The predicted molecular mass of the deduced protein is approximately 42.31 kDa, with a theoretical pI of 9.37. Slight similarity and identity were observed between the microalga sequence and various α/β-fold hydrolases found in diverse phyla. The catalytic triad corresponds to residues Ser²⁵⁴, Asp³⁰⁹, and His³⁴¹, with the nucleophilic catalytic residue Ser²⁵⁴ located in the pentapeptide consensus motif G-X-S²⁵⁴-X-G. The activity of the enzyme was established by fatty acid profile analysis of the membrane lipids. The expression of the protein in E. coli shifted the fatty acid composition predominantly towards C16:1 and C18:1 fatty acids. This enzyme is called I. galbana thioesterase/carboxylesterase (or IgTeCe). This novel gene is shown to have a potential for use in metabolic engineering to enhance the lipid yields of microalgae.     

Regulation of Human Cytidine Triphosphate Synthetase 2 by Phosphorylation

Cytidine triphosphate synthetase (CTPS) is the rate-limiting enzyme in de novo CTP synthesis and is required for the formation of RNA, DNA, and phospholipids. This study determined the kinetic properties of the individual human CTPS isozymes (hCTPS1 and hCTPS2) and regulation through substrate concentration, oligomerization, and phosphorylation. Kinetic analysis demonstrated that both hCTPS1 and hCTPS2 were maximally active at physiological concentrations of ATP, GTP, and glutamine, whereas the K_m and IC₅₀ values for the substrate UTP and the product CTP, respectively, were close to their physiological concentrations, indicating that the intracellular concentrations of UTP and CTP may precisely regulate hCTPS activity. Low serum treatment increased hCTPS2 phosphorylation, and five probable phosphorylation sites were identified in the hCTPS2 C-terminal domain. Metabolic labeling of hCTPS2 with [³²P]H₃PO₄ demonstrated that Ser⁵⁶⁸ and Ser⁵⁷¹ were two major phosphorylation sites, and additional studies demonstrated that Ser⁵⁶⁸ was phosphorylated by casein kinase 1 both in vitro and in vivo. Interestingly, mutation of Ser⁵⁶⁸ (S568A) but not Ser⁵⁷¹ significantly increased hCTPS2 activity, demonstrating that Ser⁵⁶⁸ is a major inhibitory phosphorylation site. The S568A mutation had a greater effect on the glutamine than ammonia-dependent activity, indicating that phosphorylation of this site may influence the glutaminase domain of hCTPS2. Deletion of the C-terminal regulatory domain of hCTPS1 also greatly increased the V_max of this enzyme. In summary, this is the first study to characterize the kinetic properties of hCTPS1 and hCTPS2 and to identify Ser⁵⁶⁸ as a major site of CTPS2 regulation by phosphorylation.     

Identification of a Polar Region in Transmembrane Domain 6 That Regulates the Function of the G Protein-Coupled α-Factor Receptor

The α-factor pheromone receptor (Ste2p) of the yeast Saccharomyces cerevisiae belongs to the family of G protein-coupled receptors that contain seven transmembrane domains (TMDs). Because polar residues can influence receptor structure by forming intramolecular contacts between TMDs, we tested the role of the five polar amino acids in TMD6 of the α-factor receptor by mutating these residues to nonpolar leucine. Interestingly, a subset of these mutants showed increased affinity for ligand and constitutive receptor activity. The mutation of the most polar residue, Q253L, resulted in 25-fold increased affinity and a 5-fold-higher basal level of signaling that was equal to about 19% of the α-factor induced maximum signal. Mutation of the adjacent residue, S254L, caused weaker constitutive activity and a 5-fold increase in affinity. Comparison of nine different mutations affecting Ser²⁵⁴ showed that an S254F mutation caused higher constitutive activity, suggesting that a large hydrophobic amino acid residue at position 254 alters transmembrane helix packing. Thus, these studies indicate that Gln²⁵³ and Ser²⁵⁴ are likely to be involved in intramolecular interactions with other TMDs. Furthermore, Gln²⁵³ and Ser²⁵⁴ fall on one side of the transmembrane helix that is on the opposite side from residues that do not cause constitutive activity when mutated. These results suggest that Gln²⁵³ and Ser²⁵⁴ face inward toward the other TMDs and thus provide the first experimental evidence to suggest the orientation of a TMD in this receptor. Consistent with this, we identified two residues in TMD7 (Ser²⁸⁸ and Ser²⁹²) that are potential contact residues for Gln²⁵³ because mutations affecting these residues also cause constitutive activity. Altogether, these results identify a new domain of the α-factor receptor that regulates its ability to enter the activated conformation.     

A role for DNA polymerase in the specificity of nucleotide incorporation opposite N-acetyl-2-aminofluorene adducts

Escherichia coli DNA polymerase I (Klenow fragment), DNA polymerase α from both calf thymus and human lymphoma cells and DNA polymerase β from calf thymus and Novikoff hepatoma cells can incorporate nucleotides opposite N-guanin-8-yl-acetyl-2-aminofluorene in DNA. The polymerases incorporate dCTP opposite some AAF-dG⁴ lesions when Mg²⁺ is the divalent cation. Substitution of Mn²⁺ for Mg²⁺ broadens the specificity of insertion: E. coli DNA polymerase I (Klenow fragment) also inserts A, and at specific sites G or T; DNA polymerase α inserts any of the four dNTPs with A and C incorporated preferentially to G and T. Polymerase β is specific, inserting mainly C even in the presence of Mn²⁺. The K_m for addition of dATP opposite a lesion by E. coli polymerase I (Klenow fragment) in the presence of Mn²⁺ is about 0.5 mm. dNMPs increase the insertion of nucleotides opposite AAF-dG in the presence of Mg²⁺ and increase both the rate and number of sites at which incorporation occurs in the presence of Mn²⁺. dNTPαS and recA protein increase only the insertion of C.We suppose that the incorporation of dCTP reflects normal base-pairing with the AAF-deoxyguanine in the anti conformation, whereas insertion of the other nucleotides (including some of the C) reflects insertion opposite the AAF adduct in its preferred syn conformation. The fact that the DNA polymerase plays a role in determining the specificity of insertion opposite a lesion terminating DNA synthesis suggests that the spectrum of base substitution mutagenesis seen in vivo may reflect the properties of the protein components, including the polymerase, involved in bypass synthesis.     

A comprehensive comparison of the metazoan tryptophan degrading enzymes

Tryptophan 2,3-dioxygenase (TDO) and indoleamine 2,3-dioxygenase (IDO) have an independent origin; however, they have distinctly evolved to catalyze the same reaction. In general, TDO is a single-copy gene in each metazoan species, and TDO enzymes demonstrate similar enzyme activity regardless of their biological origin. In contrast, multiple IDO paralogues are observed in many species, and they display various enzymatic properties. Similar to vertebrate IDO2, invertebrate IDOs generally show low affinity/catalytic efficiency for L-Trp. Meanwhile, two IDO isoforms from scallop (IDO-I and -III) and sponge IDOs show high L-Trp catalytic activity, which is comparable to vertebrate IDO1. Site-directed mutagenesis experiments have revealed that primarily two residues, Tyr located at the 2nd residue on the F-helix (F2^nd) and His located at the 9th residue on the G-helix (G9^th), are crucial for the high affinity/catalytic efficiency of these ‘high performance’ invertebrate IDOs. Conversely, those two amino acid substitutions (F2^nd/Tyr and G9^th/His) resulted in high affinity and catalytic activity in other molluscan ‘low performance’ IDOs. In human IDO1, G9^th is Ser¹⁶⁷, whereas the counterpart residue of G9^th in human TDO is His⁷⁶. Previous studies have shown that Ser¹⁶⁷ could not be substituted by His because the human IDO1 Ser¹⁶⁷His variant showed significantly low catalytic activity. However, this may be specific for human IDO1 because G9^th/His was demonstrated to be very effective in increasing the L-Trp affinity even in vertebrate IDOs. Therefore, these findings indicate that the active sites of TDO and IDO are more similar to each other than previously expected.     

DNA stabilization at the Bacillus subtilis PolX core��a binding model to coordinate polymerase, AP-endonuclease and 3��-5�� exonuclease activities

Family X DNA polymerases (PolXs) are involved in DNA repair. Their binding to gapped DNAs relies on two conserved helix-hairpin-helix motifs, one located at the 8-kDa domain and the other at the fingers subdomain. Bacterial/archaeal PolXs have a specifically conserved third helix-hairpin-helix motif (GFGxK) at the fingers subdomain whose putative role in DNA binding had not been established. Here, mutagenesis at the corresponding residues of Bacillus subtilis PolX (PolXBs), Gly130, Gly132 and Lys134 produced enzymes with altered DNA binding properties affecting the three enzymatic activities of the protein: polymerization, located at the PolX core, 3′-5′ exonucleolysis and apurinic/apyrimidinic (AP)-endonucleolysis, placed at the so-called polymerase and histidinol phosphatase domain. Furthermore, we have changed Lys192 of PolXBs, a residue moderately conserved in the palm subdomain of bacterial PolXs and immediately preceding two catalytic aspartates of the polymerization reaction. The results point to a function of residue Lys192 in guaranteeing the right orientation of the DNA substrates at the polymerization and histidinol phosphatase active sites. The results presented here and the recently solved structures of other bacterial PolX ternary complexes lead us to propose a structural model to account for the appropriate coordination of the different catalytic activities of bacterial PolXs.     

Asparagine and boric Acid cause allantoate accumulation in soybean leaves by inhibiting manganese-dependent allantoate amidohydrolase

Our previous work demonstrated substantial accumulation of allantoate in leaf tissue of nodulated soybeans (Glycine max L. Merr., cv Williams) in response to nitrogen fertilization. Research was continued to determine the effect of nitrate and asparagine on ureide assimilation in soybean leaves. Stem infusion of asparagine into ureide-transporting soybeans resulted in a significant increase in allantoate concentration in leaf tissue. Accumulation of allantoate was also observed when asparagine was supplied in the presence of allopurinol, an inhibitor of xanthine dehydrogenase in the pathway of ureide biosynthesis. In vitro, asparagine was found to have an inhibitory effect on the activity of allantoate amidohydrolase, a Mn²⁺-dependent enzyme catalyzing allantoate breakdown in soybean leaves. The inhibition was partially overcome by supplemental Mn²⁺ in enzyme assays. Another inhibitor of allantoate amidohydrolase, boric acid, applied foliarly on field-grown nodulated soybeans, caused up to a 10-fold increase in allantoate content of leaf tissue. Accumulation of allantoate in response to boric acid was either eliminated or greatly reduced in plants presprayed with Mn²⁺. We conclude that elevated levels of allantoate in leaves of ureide-transporting soybeans fertilized with ammonium nitrate result from inhibition of allantoate degradation by asparagine and that Mn²⁺ is a critical factor in this inhibition. Furthermore, our studies with asparagine and boric acid indicate that availability of Mn²⁺ has a direct effect on ureide catabolism in soybean.     

Novel properties of the Thermus thermophilus RuvB protein, which promotes branch migration of Holliday junctions

Branch migration of Holliday junctions, which are central DNA intermediates in homologous recombination, is promoted by the RuvA-RuvB protein complex, and the junctions are resolved by the action of the RuvC protein in Escherichia coli. We report here the cloning of the ruvB gene from a thermophilic eubacterium, Thermus thermophilus HB8 (Tth), and the biochemical characterization of the gene product expressed in E. coli. The Tth ruvB gene could not complement the UV sensitivity of an E. coli ruvB deletion mutant and made the wild-type strain more sensitive to UV. In contrast to E. coli RuvB, whose ATPase activity is strongly enhanced by supercoiled DNA but only weakly enhanced by linear duplex DNA, the ATPase activity of Tth RuvB was efficiently and equally enhanced by supercoiled and linear duplex DNA. Tth RuvB hydrolyzed a broader range of nucleoside triphosphates than E. coli RuvB. In addition, Tth RuvB, in the absence of RuvA protein, promoted branch migration of a synthetic Holliday junction at 60°?C in an ATP-dependent manner. The protein, as judged by its ATPase activity, required ATP for thermostability. Since a RuvA protein has not yet been identified in T. thermophilus, we used E. coli RuvA to examine the effects of RuvA on the activities of Tth RuvB. E. coli RuvA greatly enhanced the ability of Tth RuvB to hydrolyze ATP in the presence of DNA and to promote branch migration of a synthetic Holliday junction at 37°?C. These results indicate the conservation of the RuvA-RuvB interaction in different bacterial species, and suggest the existence of a ruvA homolog in T. thermophilus. Although GTP and dGTP were efficiently hydrolyzed by Tth RuvB, these nucleoside triphosphates could not be utilized for branch migration in vitro, implying that the conformational change in RuvB brought about by ATP hydrolysis, which is necessary for driving the Holliday junction branch migration, cannot be accomplished by the hydrolysis of these nucleoside triphosphates.     

Phosphoproteomic screening identifies Rab GTPases as novel downstream targets of PINK1

Mutations in the PTEN‐induced kinase 1 (PINK1) are causative of autosomal recessive Parkinson''s disease (PD). We have previously reported that PINK1 is activated by mitochondrial depolarisation and phosphorylates serine 65 (Ser⁶⁵) of the ubiquitin ligase Parkin and ubiquitin to stimulate Parkin E3 ligase activity. Here, we have employed quantitative phosphoproteomics to search for novel PINK1‐dependent phosphorylation targets in HEK (human embryonic kidney) 293 cells stimulated by mitochondrial depolarisation. This led to the identification of 14,213 phosphosites from 4,499 gene products. Whilst most phosphosites were unaffected, we strikingly observed three members of a sub‐family of Rab GTPases namely Rab8A, 8B and 13 that are all phosphorylated at the highly conserved residue of serine 111 (Ser¹¹¹) in response to PINK1 activation. Using phospho‐specific antibodies raised against Ser¹¹¹ of each of the Rabs, we demonstrate that Rab Ser¹¹¹ phosphorylation occurs specifically in response to PINK1 activation and is abolished in HeLa PINK1 knockout cells and mutant PINK1 PD patient‐derived fibroblasts stimulated by mitochondrial depolarisation. We provide evidence that Rab8A GTPase Ser¹¹¹ phosphorylation is not directly regulated by PINK1 in vitro and demonstrate in cells the time course of Ser¹¹¹ phosphorylation of Rab8A, 8B and 13 is markedly delayed compared to phosphorylation of Parkin at Ser⁶⁵. We further show mechanistically that phosphorylation at Ser¹¹¹ significantly impairs Rab8A activation by its cognate guanine nucleotide exchange factor (GEF), Rabin8 (by using the Ser111Glu phosphorylation mimic). These findings provide the first evidence that PINK1 is able to regulate the phosphorylation of Rab GTPases and indicate that monitoring phosphorylation of Rab8A/8B/13 at Ser¹¹¹ may represent novel biomarkers of PINK1 activity in vivo. Our findings also suggest that disruption of Rab GTPase‐mediated signalling may represent a major mechanism in the neurodegenerative cascade of Parkinson''s disease.     

Yeast protein kinase Ptk2 localizes at the plasma membrane and phosphorylates in vitro the C-terminal peptide of the H-ATPase

Glucose triggers posttranslational modifications that increase the activity of the Saccharomyces cerevisiae plasma membrane H⁺-ATPase (Pma1). Glucose activation of yeast H⁺-ATPase results from the change in two kinetic parameters: an increase in the affinity of the enzyme for ATP, depending on Ser⁸⁹⁹, and an increase in the V_max involving Thr⁹¹². Our previous studies suggested that Ptk2 mediates the Ser⁸⁹⁹-dependent part of the activation. In this study we find that Ptk2 localized to the plasma membrane in a Triton X-100 insoluble fraction. In vitro phosphorylation assays using a recombinant GST-fusion protein comprising 30 C-terminal amino acids of Pma1 suggest that Ser⁸⁹⁹ is phosphorylated by Ptk2. Furthermore, we show that the Ptk2 carboxyl terminus is essential for glucose-dependent Pma1 activation and for the phosphorylation of Ser⁸⁹⁹.     

Divergence of selenocysteine tRNA recognition by archaeal and eukaryotic O-phosphoseryl-tRNASec kinase

Selenocysteine (Sec) biosynthesis in archaea and eukaryotes requires three steps: serylation of tRNA^Sec by seryl-tRNA synthetase (SerRS), phosphorylation of Ser-tRNA^Sec by O-phosphoseryl-tRNA^Sec kinase (PSTK), and conversion of O-phosphoseryl-tRNA^Sec (Sep-tRNA^Sec) by Sep-tRNA:Sec-tRNA synthase (SepSecS) to Sec-tRNA^Sec. Although SerRS recognizes both tRNA^Sec and tRNA^Ser species, PSTK must discriminate Ser-tRNA^Sec from Ser-tRNA^Ser. Based on a comparison of the sequences and secondary structures of archaeal tRNA^Sec and tRNA^Ser, we introduced mutations into Methanococcus maripaludis tRNA^Sec to investigate how Methanocaldococcus jannaschii PSTK distinguishes tRNA^Sec from tRNA^Ser. Unlike eukaryotic PSTK, the archaeal enzyme was found to recognize the acceptor stem rather than the length and secondary structure of the D-stem. While the D-arm and T-loop provide minor identity elements, the acceptor stem base pairs G2-C71 and C3-G70 in tRNA^Sec were crucial for discrimination from tRNA^Ser. Furthermore, the A5-U68 base pair in tRNA^Ser has some antideterminant properties for PSTK. Transplantation of these identity elements into the tRNA^Ser_UGA scaffold resulted in phosphorylation of the chimeric Ser-tRNA. The chimera was able to stimulate the ATPase activity of PSTK albeit at a lower level than tRNA^Sec, whereas tRNA^Ser did not. Additionally, the seryl moiety of Ser-tRNA^Sec is not required for enzyme recognition, as PSTK efficiently phosphorylated Thr-tRNA^Sec.     

Identification of Multiple Phosphorylation Sites on Maize Endosperm Starch Branching Enzyme IIb,a Key Enzyme in Amylopectin Biosynthesis

Starch branching enzyme IIb (SBEIIb) plays a crucial role in amylopectin biosynthesis in maize endosperm by defining the structural and functional properties of storage starch and is regulated by protein phosphorylation. Native and recombinant maize SBEIIb were used as substrates for amyloplast protein kinases to identify phosphorylation sites on the protein. A multidisciplinary approach involving bioinformatics, site-directed mutagenesis, and mass spectrometry identified three phosphorylation sites at Ser residues: Ser⁶⁴⁹, Ser²⁸⁶, and Ser²⁹⁷. Two Ca²⁺-dependent protein kinase activities were partially purified from amyloplasts, termed K1, responsible for Ser⁶⁴⁹ and Ser²⁸⁶ phosphorylation, and K2, responsible for Ser⁶⁴⁹ and Ser²⁹⁷ phosphorylation. The Ser²⁸⁶ and Ser²⁹⁷ phosphorylation sites are conserved in all plant branching enzymes and are located at opposite openings of the 8-stranded parallel β-barrel of the active site, which is involved with substrate binding and catalysis. Molecular dynamics simulation analysis indicates that phospho-Ser²⁹⁷ forms a stable salt bridge with Arg⁶⁶⁵, part of a conserved Cys-containing domain in plant branching enzymes. Ser⁶⁴⁹ conservation appears confined to the enzyme in cereals and is not universal, and is presumably associated with functions specific to seed storage. The implications of SBEIIb phosphorylation are considered in terms of the role of the enzyme and the importance of starch biosynthesis for yield and biotechnological application.     

C-terminal Domain of Leucyl-tRNA Synthetase from Pathogenic Candida albicans Recognizes both tRNASer and tRNALeu

Leucyl-tRNA synthetase (LeuRS) is a multidomain enzyme that catalyzes Leu-tRNA^Leu formation and is classified into bacterial and archaeal/eukaryotic types with significant diversity in the C-terminal domain (CTD). CTDs of both bacterial and archaeal LeuRSs have been reported to recognize tRNA^Leu through different modes of interaction. In the human pathogen Candida albicans, the cytoplasmic LeuRS (CaLeuRS) is distinguished by its capacity to recognize a uniquely evolved chimeric tRNA^Ser (CatRNA^Ser(CAG)) in addition to its cognate CatRNA^Leu, leading to CUG codon reassignment. Our previous study showed that eukaryotic but not archaeal LeuRSs recognize this peculiar tRNA^Ser, suggesting the significance of their highly divergent CTDs in tRNA^Ser recognition. The results of this study provided the first evidence of the indispensable function of the CTD of eukaryotic LeuRS in recognizing non-cognate CatRNA^Ser and cognate CatRNA^Leu. Three lysine residues were identified as involved in mediating enzyme-tRNA interaction in the leucylation process: mutation of all three sites totally ablated the leucylation activity. The importance of the three lysine residues was further verified by gel mobility shift assays and complementation of a yeast leuS gene knock-out strain.