Molecular modeling studies of Fatty acyl-CoA synthetase (FadD13) from <Emphasis Type="Italic">Mycobacterium tuberculosis</Emphasis>—a potential target for the development of antitubercular drugs

Tuberculosis (TB) is a global health problem and the situation has become more precarious due to the advent of HIV infections and continuous rise in the number of multi-drug resistant strains of Mycobacterium tuberculosis (M. tb). Biochemical studies on Fatty Acyl-CoA Synthetases (FadD13), one of the gene products of mymA operon, have provided insights into the involvement of this protein in the activation of fatty acids. Due to non-availability of the crystal structure of FadD13, we have employed in silico approaches to resolve and characterize the structure of this important protein of M. tb. A three dimensional model of M. tb FadD13 was predicted by a de novo structure prediction server that integrates fragment assembly with SimFold energy function. With the aid of molecular mechanics and dynamics methods, the final model was obtained and assessed subsequently for global and local accuracy by various assessment programs. With this model, a flexible docking study with the substrates was performed. Results of ligand interactions with key amino acids in the binding site are also summarized. The molecular model for the M. tb FadD13 obtained sheds light on the topographical features of the binding pocket of the protein and provides atomic insight into the possible modes of substrate recognition. The three-dimensional model of FadD13 presented here would be helpful in guiding both enzymatic studies as well as design of specific inhibitors.     

The structure and orientation of the C-terminus of LRAP

Amelogenin is the predominant protein found during enamel development and is thought to be the biomineralization protein controlling the unique elongated hydroxyapatite crystals that constitute enamel. The secondary structure of biomineralization proteins is thought to be important in the interaction with hydroxyapatite. Unfortunately, very little data are available on the structure or the orientation of amelogenin, either in solution or bound to hydroxyapatite. The C-terminus contains the majority of the charged residues and is predicted to interact with hydroxyapatite; thus, we used solid-state NMR dipolar recoupling techniques to investigate the structure and orientation of the C-terminus of LRAP, a naturally occurring splice variant of full-length amelogenin. Using ¹³C{¹⁵N} Rotational Echo DOuble Resonance (REDOR), the structure of the C-terminus was found to be largely random coil, both on the surface of hydroxyapatite as well as lyophilized from solution. The orientation of the C-terminal region with respect to hydroxyapatite was investigated for two alanine residues (Ala⁴⁶ and Ala⁴⁹) using ¹³C{³¹P} REDOR and one lysine residue (Lys⁵²) using ¹⁵N{³¹P} REDOR. The residues examined were found to be 7.0, 5.7, and 5.8 Å from the surface of hydroxyapatite for Ala⁴⁶, Ala⁴⁹, and Lys⁵², respectively. This provides direct evidence that the charged C-terminus is interacting closely with hydroxyapatite, positioning the acidic amino acids to aid in controlling crystal growth. However, solid-state NMR dynamics measurements also revealed significant mobility in the C-terminal region of the protein, in both the side chains and the backbone, suggesting that this region alone is not responsible for binding.     

The N-terminus of Paenibacillus larvae C3larvinA modulates catalytic efficiency

C3larvinA was recently described as a mono-ADP-ribosyltransferase (mART) toxin from the enterobacterial repetitive intergenic consensus (ERIC) III genotype of the agricultural pathogen, Paenibacillus larvae. It was shown to be the full-length, functional version of the previously described C3larvin_trunc toxin, due to a 33-residue extension of the N-terminus of the protein. In the present study, a series of deletions and substitutions were made to the N-terminus of C3larvinA to assess the contribution of the α₁-helix to toxin structure and function. Catalytic characterization of these variants identified Asp²³ and Ala³¹ residues as supportive to enzymatic function. A third residue, Lys³⁶, was also found to contribute to the catalytic activity of the enzyme. Analysis of the C3larvinA homology model revealed that these three residues were participating in a series of interactions to properly orient both the Q-X-E and S-T-S motifs. Ala³¹ and Lys³⁶ were found to associate with a structural network of residues previously identified in silico, whereas Asp²³ forms novel interactions not previously described. At last, the membrane translocation activity into host target cells of each variant was assessed, highlighting a possible relationship between protein dipole and target cell entry.     

Charged surface area of maurocalcine determines its interaction with the skeletal ryanodine receptor

The 33 amino acid scorpion toxin maurocalcine (MCa) has been shown to modify the gating of the skeletal-type ryanodine receptor (RyR1). Here we explored the effects of MCa and its mutants ([Ala⁸]MCa, [Ala¹⁹]MCa, [Ala²⁰]MCa, [Ala²²]MCa, [Ala²³]MCa, and [Ala²⁴]MCa) on RyR1 incorporated into artificial lipid bilayers and on elementary calcium release events (ECRE) in rat and frog skeletal muscle fibers. The peptides induced long-lasting subconductance states (LLSS) on RyR1 that lasted for several seconds. However, their average length and frequency were decreased if the mutation was placed farther away in the 3D structure from the critical ²⁴Arg residue. The effect was strongly dependent on the direction of the current through the channel. If the direction was similar to that followed by calcium during release, the peptides were 8- to 10-fold less effective. In fibers long-lasting calcium release events were observed after the addition of the peptides. The average length of these events correlated well with the duration of LLSS. These data suggest that the effect of the peptide is governed by the large charged surface formed by residues Lys²⁰, Lys²², Arg²³, Arg²⁴, and Lys⁸. Our observations also indicate that the results from bilayer experiments mimic the in situ effects of MCa on RyR1.     

Molecular modeling and design of regioselectively addressable functionalized templates with rigidified three‐dimensional structures

Extensive conformational analysis of a series of β‐alkyl substituted cyclopeptides—cyclo(Pro¹–Xaa²–Nle³–Ala⁴–Nle⁵–Pro⁶–Xaa⁷–Nle⁸–Ala⁹–Nle¹⁰) and cyclo[Pro¹–Xaa²–Nle³–(Cys⁴– Nle⁵–Pro⁶–Xaa⁷–Nle⁸–Cys⁹)–Nle¹⁰] as well as their corresponding unsubstituted core structures cyclo(Pro¹–Xaa²–Ala³–Ala⁴–Ala⁵–Pro⁶–Xaa⁷–Ala⁸–Ala⁹–Ala¹⁰) and cyclo(Pro¹–Xaa²–Ala³–Cys⁴– Ala⁵–Pro⁶–Xaa⁷–Ala⁸–Cys⁹–Ala¹⁰) has been performed employing both the ECEPP/2 and the MAB force fields (Xaa = Gly, L ‐Ala, D ‐Ala, Aib, and D ‐Pro). Results show that (a) possible three‐dimensional structures of the cyclo(Pro¹–Gly²–Lys³–Ala⁴–Lys⁵–Pro⁶–Gly⁷–Lys⁸–Ala⁹–Lys¹⁰) molecule are not limited to a single extended “rectangular” conformation with all Lys side chains oriented at the same side of the molecule; (b) conformational equilibrium in monocyclic analogues obtained by replacements of conformationally flexible Gly residues for L ‐Ala, D ‐Ala, Aib, or D ‐Pro is not significantly shifted towards the target “rectangular” conformational type; and (c) introduction of disulfide bridges between positions 4 and 9 is a very powerful way to stabilize the target conformations in the resulting bicyclic molecules. These findings form the basis for further design of rigidified regioselectively addressable functionalized templates with many application areas ranging from biostructural to diagnostic purposes. © 1999 John Wiley & Sons, Inc. Biopoly 50: 361–372, 1999     

Biophysical Investigations of Complement Receptor 2 (CD21 and CR2)-Ligand Interactions Reveal Amino Acid Contacts Unique to Each Receptor-Ligand Pair

Human complement receptor type 2 (CR2 and CD21) is a cell membrane receptor, with 15 or 16 extracellular short consensus repeats (SCRs), that promotes B lymphocyte responses and bridges innate and acquired immunity. The most distally located SCRs, SCR1–2, mediate the interaction of CR2 with its four known ligands (C3d, EBV gp350, IFNα, and CD23). To ascertain specific interacting residues on CR2, we utilized NMR studies wherein gp350 and IFNα were titrated into ¹⁵N-labeled SCR1–2, and chemical shift changes indicative of specific inter-molecular interactions were identified. With backbone assignments made, the chemical shift changes were mapped onto the crystal structure of SCR1–2. With regard to gp350, the binding region of CR2 is primarily focused on SCR1 and the inter-SCR linker, specifically residues Asn¹¹, Arg¹³, Ala²², Arg²⁸, Ser³², Arg³⁶, Lys⁴¹, Lys⁵⁷, Tyr⁶⁴, Lys⁶⁷, Tyr⁶⁸, Arg⁸³, Gly⁸⁴, and Arg⁸⁹. With regard to IFNα, the binding is similar to the CR2-C3d interaction with specific residues being Arg¹³, Tyr¹⁶, Arg²⁸, Ser⁴², Lys⁴⁸, Lys⁵⁰, Tyr⁶⁸, Arg⁸³, Gly⁸⁴, and Arg⁸⁹. We also report thermodynamic properties of each ligand-receptor pair determined using isothermal titration calorimetry. The CR2-C3d interaction was characterized as a two-mode binding interaction with K_d values of 0.13 and 160 μm, whereas the CR2-gp350 and CR2-IFNα interactions were characterized as single site binding events with affinities of 0.014 and 0.035 μm, respectively. The compilation of chemical binding maps suggests specific residues on CR2 that are uniquely important in each of these three binding interactions.     

Crystal structure of a viral protease intramolecular acyl-enzyme complex: insights into cis-cleavage at the VP4/VP3 junction of Tellina birnavirus

Viruses of the Birnaviridae family are characterized by their bisegmented double-stranded RNA genome that resides within a single-shelled non-enveloped icosahedral particle. They infect birds, aquatic organisms, and insects. Tellina virus 1 (TV-1) is an Aquabirnavirus isolated from the mollusk Tellina tenuis. It encodes a polyprotein (NH₂-pVP2-X-VP4-VP3-COOH) that is cleaved by the self-encoded protease VP4 to yield capsid precursor protein pVP2, peptide X, and ribonucleoprotein VP3. Here we report the crystal structure of an intramolecular (cis) acyl-enzyme complex of TV-1 VP4 at 2.1-Å resolution. The structure reveals how the enzyme can recognize its own carboxyl terminus during the VP4/VP3 cleavage event. The methyl side chains of Ala⁸³⁰(P1) and Ala⁸²⁸(P3) at the VP4/VP3 junction point into complementary shallow and hydrophobic S1 and S3 binding pockets adjacent to the VP4 catalytic residues: nucleophile Ser⁷³⁸ and general base Lys⁷⁷⁷. The electron density clearly shows that the carbonyl carbon of Ala⁸³⁰ is covalently attached via an ester bond to the Oγ of Ser⁷³⁸. A highly ordered water molecule in the active site is coordinated in the proper position to act as the deacylating water. A comparative analysis of this intramolecular (cis) acyl-enzyme structure with the previously solved intermolecular (trans) acyl-enzyme structure of infectious pancreatic necrosis virus VP4 explains the narrower specificity observed in the cleavage sites of TV-1 VP4.     

Conformation of sequential and random copolypeptides of lysine and alanine in sodium dodecyl sulfate solution

A series of sequential polypeptides, (Lys_i-Ala_j)_n, and random copolypeptides, (Lys^x, Ala^y)_n, were synthesized. The competitive effect of Ala, a helix former, and Lys, whose homopolymer has a β-form in neutral NaDodSO₄ solution, was determined by CD and absorption spectroscopy. All the polypeptides studied were unordered in neutral solution without the surfactant. Of the six sequential polypeptides only (Lys-Ala)_n adopted a stable β-form in NaDodSO₄ solution. Most striking is the difference between this polypeptide, (Lys₂-Ala₂)_n and (Lys^x, Ala^y)_n, even though they all have equimolar Lys and Ala. (Lys₂-Ala₂)_n was partially helical in 2.5–5 mM NaDodSO₄ but approached the unordered form in 50 mM NaDodSO₄, whereas (Lys⁵⁰, Ala⁵⁰)_n was completely helical in all NaDodSO₄ concentrations. Even Lysrich (Lys₂-Ala)_n and (Lys₃-Ala)_n formed a partial helix and a trace of the β-form, respectively, in low NaDodSO₄ concentrations; both reverted to the unordered form in high NaDodSO₄ concentrations. These results can be explained by Pauling-Corey's model for β-pleated sheets. Only (Lys-Ala)_n has all DodSO-bound Lys⁺ residues on one side and Ala residues on the other side of the polypeptide chain. They can nestle quiet efficiently in a β-sheet and between neighboring β-sheets. Our results further imply that random copolypeptides are not completely random; they comprise varying segments of (Lys_k-Ala_m), where k and m could vary from zero to a small integer.     

Structural studies on epsilon-prototoxin of Clostridium perfringens type D. Localization of the site of tryptic scission necessary for activation to epsilon-toxin.

The mechanism of activation of ε-prototoxin to ε-toxin has been ascertained from partial amino acid sequences of both ε-prototoxin and ε-toxin. The activation of ε-prototoxin from $\text{Clostridium perfringens}$ type D by brief exposure to trypsin is caused by scission of a peptide bond between Lys₁₄ - Ala₁₅. A small peptide (14 amino acid residues) is split from the NH₂-terminus of the ε-prototoxin to give the active ε-toxin.     

Reductive methylation andpKa determination of the lysine side chains in calbindin D9k

The Lys residues in the 75-residue Ca²⁺-binding protein calbindin D_9k were reductively methylated with¹³C-enriched formaldehyde. The possible structural effects resulting from the chemical modification were critically investigated by comparing two-dimensional NMR spectra and the exchange rates of some of the amide protons of the native and the modified protein. Our results show that the protein retains its structure even though 10 Lys out of a total of 75 amino acid residues were modified. In the Ca²⁺- and apo-forms of the protein, the¹³C-methylated Lys residues can be detected with high sensitivity and resolution using two-dimensional (¹H,¹³C)-heteronuclear multiple quantum coherence (HMQC) NMR spectroscopy. ThepKa values of the individual Lys residues in Ca²⁺-calbindin D_9k and apo-calbindin D_9k were obtained by combiningpH titration experiments and (¹H,¹³C)-HMQC NMR spectroscopy. Each Lys residue in the Ca²⁺- and apo-forms of calbindin D_9k has a uniquepKa value. The LyspKa values in the calcium protein range from 9.3 to 10.9, while those in the apo-protein vary between 9.7 and 10.7. Although apo-calbindin D_9k has a very similar structure compared to Ca²⁺-calbindin D_9k, the removal of two Ca²⁺ ions from the protein leads to an increase of thepKa values of the Lys residues.     

Polypeptides. LVI. Effect of lithium bromide and of temperature on the conformation of a copolymer of glutamic acid and lysine

By using optical rotatory dispersion measurements, the helix content of poly Glu⁵⁰Lys⁵⁰ has been investigated and compared with that of poly Glu²⁰Lys²⁰Ala⁶⁰ in aqueous solutions. Measurements were made at pH 3 and at pH 8 in various concentrations of lithium bromide. Various factors affecting helix stabilization are considered and their perturbation by lithium bromide is related to the shape of the observed transition curves. A residual helix content of 12% in 8M LiBr, based upon a b₀ of +100 for a fully random conformation, was observed for poly Glu⁵⁰Lys⁵⁰ at pH 3 and 8. The loss of helix content of poly Glu⁵⁰Lys⁵⁰ as a function of temperature is also reported. ΔH is approximately ?6.9 kcal./mole for the overall transition, compared to ?6.5 kcal./mole for poly Glu²⁰Lys²⁰Ala⁶⁰. The midpoint of the broad transition is near 40°C. at pH 3, but much lower, at ?10 to 0°C., at pH 8. These results are discussed in terms of the stabilizing factors for the partial helix content of the polypeptides.     

Partial structure and properties of the ferredoxin from Rhodymenia palmata

A ferredoxin of MW 11 000 was isolated from the marine alga Rhodymenia palmata (Palmaria palmata). In its oxidised form the ferredoxin had absorption maxima at 276, sh 281, 328, 423 and 465 nm, and contained a single [2Fe-2S] cluster. The midpoint potential of the ferredoxin was ?400 mV and it effectively mediated electron transport in NADP⁺-photoreduction by higher plant chloroplasts, and pyruvate decarboxylation by the phosphoroclastic system of an anacrobic bacterium. The amino acid composition was Lys₃, His₁, Arg₁, Asx₁₂, Thr₉, Ser₈, Glx₁₃, Pro₄, Gly₈, Ala₇, Cys₅, Val₈, Ile₄, Leu₉, Tyr₄, Phe₂; tryptophan and methionine were absent from the molecule. The N-terminal amino acid region consisting of ca half the total amino acid sequence was determined using an automatic sequencer.     

Structure-function studies on gastrointestinal hormones: I. Synthesis of secretin analogs and their biological and immunological properties

Syntheses by conventional procedures of the three analogs corresponding to the porcine secretin sequence crossed at position 6 by the N-terminal hexapeptide sequences of VIP, GIP, and glucagon are described, viz., Ala⁴,Val⁵-, Tyr¹,Ala²,Glu³-, and Gln³-secretin (VIP-SN, GIP-SN, and GLU-SN). The analog Phe¹,Phe²,Trp³,Lys⁴-secretin (SOMA-SN), designed on the basis of the surprising homology of the sequence portions 10–13 of somatostatin and 5–8 of secretin, was also prepared. Finally, the synthesis of N^α-3-(4-hydroxyphenyl)propionyl-β-alanyl-secretin (DATA-SN), a tracer suitable for secretin radioimmunoassay and as an N-terminus modified secretin analog, is reported. The analogs are compared, in terms of their biological and immunological properties in different assay systems, with pure synthetic secretin.     

Cloning, Sequencing and Analysis of the 16S-23S rDNA Intergenic Spacers (IGSs) of Two Strains of Vibrio vulnificus

According to the conserved sequences flanking the 3′ end of the 16S and the 5′ end of the 23S rDNAs, PCR primers were designed, and the 16S-23S rDNA intergenic spacers (IGSs) of two strains of Vibrio vulnificus were amplified by PCR and cloned into pGEM-T vector. Different clones were selected to be sequenced and the sequences were analyzed with BLAST and the software DNAstar. Analyses of the IGS sequences suggested that the strain ZSU006 contains five types of polymorphic 16S-23S rDNA intergenic spacers, namely, IGS^GLAV, IGS^GLV, IGS^lA, IGS^G and IGS^A; while the strain CG021 has the same types of IGSs except lacking IGS^A. Among these five IGS types, IGS^GLAV is the biggest type, including the gene cluster of tRNA^Glu - tRNA^Lys - tRNA^Ala - tRNA^Val; IGS^GLV includes that of tRNA^Glu-tRNA^Lys-tRNA^Val; IGS^AG, tRNA^Ala-tRNA^Glu; IGS^IA, tRNA^Ile-tRNA^Ala; IGS^G, tRNA^Glu and IGS^A, tRNA^Ala. Intraspecies multiple alignment of all the IGS sequences of these two strains with those of V. vulnificus ATCC27562 available at GenBank revealed several highly conserved sequence blocks in the non-coding regions flanking the tRNA genes within all of strains, most notably the first 40 and last 200 nucleotides, which can be targeted to design species-specific PCR primers or detection probes. The structural variations of the 16S-23S rDNA intergenic spacers lay a foundation for developing diagnostic methods for V. vulnificus.     

A coupled assay measuring Mycobacterium tuberculosis antigen 85C enzymatic activity

The prevalence of drug-resistant strains of Mycobacterium tuberculosis (M. tb) emphasizes the need for new antitubercular drugs. An essential component of the drug discovery process is the development of tools to rapidly screen potential drug libraries against important biological targets. Similarly to well-documented M. tb targets, the antigen 85 (Ag85) enzymes are involved in the maintenance of the mycobacterial cell wall. The products synthesized by these mycolyltransferases are the cell wall components most responsible for the reduced permeability of drugs into the bacterial cell, thereby linking Ag85 activity directly with drug resistance. This article presents the development of a high-throughput colorimetric assay suitable for direct monitoring of the enzymatic activity. The assay uses a synthetic substrate containing three chemical moieties: an octanoyl fatty acid, β-d-glucose, and p-nitrophenyl. In the context of the assay, Ag85 catalyzes the removal of the fatty acid and releases p-nitrophenyl-β-d-glucoside. The glucoside is hydrolyzed by β-glucosidase to release the p-nitrophenolate chromophore. With this assay, the K_M and k_cat values of Ag85C were determined to be 0.047 ± 0.008 mM and 0.062 s⁻¹, respectively. In addition, the assay exhibits a Z′ value of 0.81 ± 0.06, indicating its suitability for high-throughput screening applications and drug development.     

Salt-induced conformational change of random copolymers (Lys50Tyr50)n and (Lys50Phe50)n studied by 1H- and 13C-nuclear magnetic resonances. Aggregation behavior of helical segments

¹H- and ¹³C-nmr studies of conformational transitions of random amino acid copolymers containing aromatic residues (Lys⁵⁰Tyr⁵⁰)_n and (Lys⁵⁰Phe⁵⁰)_n in the presence of neutral salts were performed to serve as models of the aggregation behavior of polypeptides of biological significance. The ¹H and ¹³C signal intensities of Tyr and Phe residues decreased preferentially with increasing concentration of neutral salts such as NaCl and NaClO₄. This behavior contrasts with that of (Lys)_n in the presence of similar neutral salts, where the displacement of the ¹³C signal is clearly seen on transition from the random-coil to the helical conformation. On the basis of the previous conformational studies, the loss of the peak areas is ascribed to the presence of immobilized helical segments by hydrophobic interaction between aromatic side chains. The remaining resonances are due to the residual random-coil regions, since the values of nuclear Overhauser enhancements and chemical shifts are unchanged in the presence and absence of the neutral salts.     

A Stationary-Phase Acyl-Coenzyme A Synthetase of Streptomyces coelicolor A3(2) Is Necessary for the Normal Onset of Antibiotic Production

The fadD1 and macs1 genes of Streptomyces coelicolor are part of a two-gene operon. Both genes encode putative acyl coenzyme A synthetases (ACSs). The amino acid sequence of FadD1 has high homology with those of several ACSs, while MACS1 has the closest homology with medium-chain ACSs, broadly known as SA proteins. Like FadD of Escherichia coli, FadD1 also has a broad substrate specificity, although saturated long-chain fatty acids appears to be the preferred substrate. fadD1 is a growth-phase-regulated gene, and its mRNA is detected only during the stationary phase of growth. Interestingly, a mutation in fadD1 alters the levels of another ACS or ACSs, both at the stationary phase and at the exponential phase of growth, at least when glucose is used as a main carbon source. The mutant also shows a severe deficiency in antibiotic production, and at least for Act biosynthesis, this deficiency seems to be related to delayed expression of the Act biosynthetic genes. Antibiotic production is restored by the introduction of a wt fadD1 allele into the cell, demonstrating a strict link between ACS activity and the biosynthesis of secondary metabolites. The results of this study indicate that the ACSs may be useful targets for the design of rational approaches to improving antibiotic production.     

Structures of Mycobacterium tuberculosis FadD10 Protein Reveal a New Type of Adenylate-forming Enzyme

Mycobacterium tuberculosis has a group of 34 FadD proteins that belong to the adenylate-forming superfamily. They are classified as either fatty acyl-AMP ligases (FAALs) or fatty acyl-CoA ligases based on sequence analysis. FadD10, involved in the synthesis of a virulence-related lipopeptide, was mis-annotated as a fatty acyl-CoA ligase; however, it is in fact a FAAL that transfers fatty acids to an acyl carrier protein (Rv0100). In this study, we have determined the structures of FadD10 in both the apo-form and the complexed form with dodecanoyl-AMP, where we see for the first time an adenylate-forming enzyme that does not adopt a closed conformation for catalysis. Indeed, this novel conformation of FadD10, facilitated by its unique inter-domain and intermolecular interactions, is critical for the enzyme to carry out the acyl transfer onto Rv0100 rather than coenzyme A. This contradicts the existing model of FAALs that rely on an insertion motif for the acyltransferase specificity and thus makes FadD10 a new type of FAAL. We have also characterized the fatty acid preference of FadD10 through biological and structural analyses, and the data indicate long chain saturated fatty acids as the biological substrates of the enzyme.     

Cloning, characterization and expression of a chloroplastic fructose-1,6-bisphosphatase from Porteresia coarctata conferring salt-tolerance in transgenic tobacco

A gene coding for the chloroplastic fructose 1,6-bisphosphatase (PcCFR) in Porteresia coarctata Tateoka (Roxb.), a halophytic wild rice, has been isolated along with its rice (Oryza sativa; var. indica) homologue (OsCFR), cloned and sequenced. Comparison between the nucleotide and deduced amino acid sequences of these two revealed a difference in five amino acid residues, namely Glu¹⁴, Thr²⁴, Ala⁴⁸, Ala¹⁶³ and Arg²⁹⁶ in OsCFR which have been found to be replaced by Ser¹⁴, Ile²⁴, Ser⁴⁸, Ser¹⁶³ and Lys²⁹⁶ in PcCFR respectively. The purified recombinant PcCFR is found to retain its enzymatic activity in presence of up to 500 mM NaCl in vitro as opposed to OsCFR, which is inactivated even at lower salt concentration. The six in vitro point mutant proteins of PcCFR showed varied degree of sensitivity towards high salt, with the maximum OsCFR-like effect in the triple mutant S¹⁴A-S⁴⁸A-S¹⁶³A suggesting a possible concerted role of all three serine residues in the in vitro salt tolerance property of PcCFR protein. Transgenic tobacco plants with chloroplast targeted PcCFR and OsCFR gene(s) have been developed under constitutive expression of CaMV 35S promoter and NOS terminator. The PcCFR transgenics showed better plant growth during exposure to salt stress in comparison to either the OsCFR or the empty vector transformed plants. The PcCFR transgenics also revealed enhanced photosynthetic efficiency coupled with protection to both photodamage of PSII and chlorophyll degradation through better reactive oxygen species scavenging at higher concentration of NaCl during late salt-stress growth.     

Analysis of the DNA binding site of Escherichia coli RecA protein

To investigate the DNA binding site of RecA protein, we constructed 15 recA mutants having alterations in the regions homologous to the other ssDNA binding proteins. The in vivo analyses showed that the mutational change at Arg²⁴³, Lys²⁴⁸, Tyr²⁶⁴, or simultaneously at Lys⁶ and Lys¹⁹, or Lys⁶ and Lys²³ caused severe defects in the recA functions, while other mutational changes did not. Purified RecA-K6A-K23A (Lys⁶ and Lys²³ changed to Ala and Ala, respectively) protein was indistinguishable from the wild-type RecA protein in its binding to DNA. However, the RecA-R243A (Arg²⁴³ changed to Ala) and RecA-Y264A (Tyr²⁶⁴ changed to Ala) proteins were defective in binding to both ss- and ds-DNA. In self-oligomerization property, RecA-R243A was proficient but RecA-Y264A was deficient, suggesting that the RecA-R243A protein had a defect in DNA binding site and the RecA-Y264A protein was defective in its interaction with the adjacent RecA molecule. The region of residues 243–257 including the Arg²⁴³ is highly homologous to the DNA binding motif in the ssDNA binding proteins, while the eukaryotic RecA homologues have a similar structure at the amino-terminal side proximal to the nucleotide binding core. The region of residues 243–257 would be a part of the DNA binding site. The other parts of this site would be the Tyr¹⁰³ and the region of residues 178–183, which were cross-linked to ssDNA. These three regions lie in a line in the crystal structure.