Inhibitors binding to L-aromatic amino acid decarboxylase

The effect of a number of inhibitors of L-aromatic amino acid decarboxylase activity on the absorption spectrum of the enzyme-bound coenzyme has been studied. It has been observed that the compounds tested, even if devoid of the amino function and therefore unable to form the Schiff base with the coenzyme, modify significantly the enzyme spectrum, indicating their binding to the coenzyme active site. Spectral modifications suggest that at least two kinds of binding of inhibitors to L-aromatic amino acid decarboxylase may occur, depending on their structural features. Moreover, from the spectra obtained at different concentrations of the inhibitors their affinity constants have been determined: data indicate that the cathecol ring gives the largest contribution to the binding, while the presence of the carboxyl group, the aminic group and the aliphatic chain are responsible for a decrease in the binding, which could be relevant for the efficiency of the catalysis.     

Recombinant agrobacterium AgaE-like protein with fructosyl amino acid oxidase activity

Agrobacterium tumefaciens AgaE-like protein had a similar sequence to that of a fructosyl amino acid oxidase from Corynebacterium sp. strain 2-4-1. To characterize the AgaE-like protein, we produced the enzyme in Escherichia coli, and purified it to homogeneity. The molecular mass of recombinant AgaE-like protein was 42 kDa on SDS-PAGE and 85 kDa on gel filtration. The protein acted on N-fructosyl valine and N-fructosyl glycine as substrates, but not on glycated protein or N(epsilon)-fructosyl lysine. Apparent Km for N-fructosyl valine and N-fructosyl glycine were 1.64 and 0.31 mM, respectively. The AgaE-like protein had maximum activity at pH 7.8 and 35 degrees C in 0.1 M potassium phosphate, but more than 80% of its activity was lost at 40 degrees C or more. In contrast to eukaryotic fructosyl amino acid oxidases, the AgaE-like protein contained noncovalently bound FAD as a cofactor and was inactive against N(epsilon)-fructosyl N(alpha)-Z(benzyloxycarbonyl)-lysine. These characteristics were similar to a fructosyl amino acid oxidase from Corynebacterium sp. strain 2-4-1, suggesting that these prokaryotic enzymes comprise a new family of fructosyl amino acid oxidases.     

Docking of tryptophanyl [corrected tryptophan] analogs to trytophanyl-tRNA synthetase: implications for non-canonical amino acid incorporations

Abstract Non-canonical amino acids (N(AA)), as building blocks for peptides and proteins during ribosomal translation, represent a nearly infinite supply of novel functions. The specific selection, activation and tRNA-charging of amino acids by aminoacyl-tRNA synthetases (AARS) in the aminoacylation reaction are essential steps. In most cases, aminoacylation of N(AA) is a good indication that the related amino acid will participate in ribosomal translation as well. However, testing the translational capacity of amino acid analogs has technical limitations. Therefore, a rapid and reliable in silico test for N(AA) recognition by AARS would be advantageous in experimental design. We chose tryptophanyl-tRNA synthetase from Escherichia coli as a model system for docking studies with various tryptophan analogs using the FlexX-Pharm strategy. We were able to calculate relative binding energies for Trp analogs in TrpRS that correlate well with their translational activities in E. coli. In particular, FlexX-Pharm predicted the binding sites of fluoro-, amino-, hydroxyl- and aza-containing Trp analogs within 1.5 A of Trp in the homology model of E. coli TrpRS. Therefore, the use of ligand docking prior to N(AA) incorporation experiments might provide a straightforward means for determining N(AA) that can be efficiently incorporated into a protein.     

Selective binding of amino acid residues to tRNAPhe

The interaction of amino acid amides with tRNAPhe was studied by measurements of the Wye base fluorescence. Binding of phenylalanine-, tyrosine- and tryptophan-amides leads to considerable quenching, whereas the amides of e.g. glycine and leucine do not induce quenching under the same conditions. Binding constants at 0.13 M salt - 100 M-1 for Phe-, 110 M-1 for Tyr- and 300 M-1 for Trp-amide - are about a factor of 6 higher than those evaluated from independent measurements for binding to simple single-stranded polynucleotides; the corresponding factor is 10 for double-stranded polynucleotides. Since the apparent enthalpy changes derived from measurements at different temperatures remains relatively low (-9 to -20 kJ/mol), the increased affinity appears to be mainly due to an increase of the entropy changes. Titration experiments performed in the presence of Mg2+ indicate cooperative interactions of the aromatic residues with the anticodon loop that are consistent with preferential binding to one of two loop conformations. Measurements of binding constants at different pH-values indicate the protonation of a tRNA residue in the tryptophanamide-tRNAPhe complex characterised by a pK value of about 7.0.     

Mutagenesis of rat acyl-CoA synthetase 4 indicates amino acids that contribute to fatty acid binding

Although each of the five mammalian long-chain acyl-CoA synthetases (ACSL) can bind saturated and unsaturated fatty acids ranging from 12 to 22 carbons, ACSL4 prefers longer chain polyunsaturated fatty acids. In order to gain a better understanding of ACSL4 fatty acid binding, we based a mutagenesis approach on sequence alignments related to ttLC-FACS crystallized from Thermus thermophilus HB8. Four residues selected for mutagenesis corresponded to residues in ttLC-FACS that comprise the fatty acid binding pocket; the fifth residue aligned with a region thought to be involved in fatty acid selectivity of the Escherichia coli acyl-CoA synthetase, FadD. Changing an amino acid at the entry of the putative fatty acid binding pocket, G401L, resulted in an inactive enzyme. Mutating a residue near the pocket entry, L399M, did not significantly alter enzyme activity, but mutating a residue at the hydrophobic terminus of the pocket, S291Y, altered ACSL4's preference for 20:5 and 22:6 and increased its apparent K(m) for ATP. Mutating a site in a region previously identified as important for fatty acid binding also altered activation of 20:4 and 20:5. These studies suggested that the preference of ACSL4 for long-chain polyunsaturated fatty acids can be modified by altering specific amino acid residues.     

Unraveling the amino acid sequence crucial for heparin binding to collagen V

We have previously shown that a recombinant 12-kDa fragment of the collagen alpha1(V) chain (Ile(824)-Pro(950)), referred to as HepV, binds to heparin and heparan sulfate (Delacoux, F., Fichard, A., Geourjon, C., Garrone, R., and Ruggiero, F. (1998) J. Biol. Chem. 273, 15069-15076). No consensus sequence was found in the alpha1(V) primary sequence, but a cluster of 7 basic amino acids (in the Arg(900)-Arg(924) region) was postulated to contain the heparin-binding site. The contribution of individual basic amino acids within this sequence was examined by site-directed mutagenesis. Further evidence for the precise localization of the heparin-binding site was provided by experiments based on the fact that heparin can protect the alpha1(V) chain heparin-binding site from trypsin digestion. The results parallel the alanine scanning mutagenesis data, i.e. heparin binding to the alpha1(V) chain involved Arg(912), Arg(918), and Arg(921) and two additional neighboring basic residues, Lys(905) and Arg(909). Our data suggest that this extended sequence functions as a heparin-binding site in both collagens V and XI, indicating that these collagens use a novel sequence motif to interact with heparin.     

Residues within a conserved amino acid motif of domains 1 and 4 of VCAM- 1 are required for binding to VLA-4

Vascular cell adhesion molecule 1 (VCAM-1), a member of the Ig superfamily originally identified on activated endothelium, binds to the integrin very late antigen-4 (VLA-4), also known as alpha 4 beta 1 or CD49d/CD29, to support cell-cell adhesion. Studies based on cell adhesion to two alternatively spliced forms of VCAM-1 or to chimeric molecules generated from them and intercellular adhesion molecule-1 (ICAM-1) have demonstrated two VLA-4 binding sites on the predominate form of VCAM-1. Here, we studied VLA-4-dependent adhesion of the lymphoid tumor cell line Ramos to cells expressing wild type and mutant forms of VCAM-1. Results based on domain deletion mutants demonstrated the existence and independence of two VLA-4-binding sites located in the first and fourth domains of VCAM-1. Results based on amino acid substitution mutants demonstrated that residues within a linear sequence of six amino acids found in both domain 1 and 4 were required for VLA-4 binding to either domain. Five of these amino acids represent a conserved motif also found in ICAM domains. We propose that integrin binding to these Ig-like domains depends on residues within this conserved motif. Specificity of integrin binding to Ig-like domains may be regulated by a set of nonconserved residues distinct from the conserved motif.     

Ligand binding characteristics of CXCR4 incorporated into paramagnetic proteoliposomes

The G protein-coupled receptor CXCR4 is a coreceptor, along with CD4, for the human immunodeficiency virus type 1 (HIV-1) and has been implicated in breast cancer metastasis. We studied the binding of the HIV-1 gp120 envelope glycoprotein (gp) to CXCR4 but found that the gp120s from CXCR4-using HIV-1 strains bound nonspecifically to several cell lines lacking human CXCR4 expression. Therefore, we constructed paramagnetic proteoliposomes (CXCR4-PMPLs) containing pure, native CXCR4. CXCR4-PMPLs specifically bound the natural ligand, SDF-1alpha, and the gp120s from CXCR4-using HIV-1 strains. Conformation-dependent anti-CXCR4 antibodies and the CXCR4 antagonist AMD3100 blocked HIV-1 gp120 binding to CXCR4-PMPLs. The gp120-CXCR4 interaction was blocked by anti-gp120 antibodies directed against the third variable (V3) loop and CD4-induced epitopes, structures that have also been implicated in the binding of gp120 to the other HIV-1 coreceptor, CCR5. Compared with the binding of R5 HIV-1 gp120s to CCR5, the gp120-CXCR4 interaction exhibited a lower affinity (K(d) = 200 nm) and was dependent upon prior CD4 binding, even at low temperature. Thus, although similar regions of X4 and R5 HIV-1 gp120s appear to be involved in binding CXCR4 and CCR5, respectively, differences exist in nonspecific binding to cell surfaces, affinity for the chemokine receptor, and CD4 dependence at low temperature.     

Crystallographic study of a site-specifically cross-linked protein complex with a genetically incorporated photoreactive amino acid

The benzophenone photophore is widely used to photo-cross-link macromolecules. Recent developments in genetic code expansion have allowed the biosynthesis of proteins with p-benzoyl-L-phenylalanine (pBpa) at defined sites, for covalent bonding with interacting proteins. However, the structure of a photo-cross-linked protein complex had not been revealed, and thus neither the actual structure of the "photobridge" in a complex nor the influence of this covalent bridge on the overall complex structure was known. In this study, we determine the crystal structure of the cross-linked complex of the liver oncoprotein gankyrin and the C-terminal domain of S6 proteasomal protein (S6C), at 2.05 ? resolution. First, the photoreactive amino acid was separately incorporated into gankyrin at 16 sites on the protein surface, and two variants that efficiently formed a covalent bond with S6C were found. The yield of one of the cross-linked products, with pBpa in place of Arg85 in gankyrin, was maximized for crystallization via optimization of the duration of complex exposure to 365 nm light. The structure revealed that the carbonyl group of the benzophenone of pBpa85 formed a covalent bond exclusively with the Cγ atom of Glu356 in S6C, showing the high selectivity of formation of cross-links by pBpa. In addition, the cross-linked structure exhibited little structural distortion from the native complex structure. Our results demonstrated that cross-linking with site-specifically incorporated pBpa preserves the native binding mode and is useful for probing protein-protein interactions.     

Site-specific modification of Candida antarctica lipase B via residue-specific incorporation of a non-canonical amino acid

In order to modify proteins in a controlled way, new functionalities need to be introduced in a defined manner. One way to accomplish this is by the incorporation of a non-natural amino acid of which the side chain can selectively be reacted to other molecules. We have investigated whether the relatively simple method of residue-specific replacement of methionine by azidohomoalanine can be used to achieve monofunctionalization of the model enzyme Candida antarctica lipase B. A protein variant was engineered with one additional methionine residue. Due to the high hydrophobicity and low abundance of methionine, this was the only residue out of five that was exposed to the solvent. The use of the Cu (I)-catalyzed [3 + 2] cycloaddition under native conditions resulted in a monofunctionalized enzyme which retained hydrolytic activity. The strategy can be considered a convenient tool to modify proteins at a single position as long as one solvent-exposed methionine is available.     

Dbf4 regulates the Cdc5 Polo-like kinase through a distinct non-canonical binding interaction

Cdc7-Dbf4 is a conserved, two-subunit kinase required for initiating eukaryotic DNA replication. Recent studies have shown that Cdc7-Dbf4 also regulates the mitotic exit network (MEN) and monopolar homolog orientation in meiosis I (Matos, J., Lipp, J. J., Bogdanova, A., Guillot, S., Okaz, E., Junqueira, M., Shevchenko, A., and Zachariae, W. (2008) Cell 135, 662-678 and Miller, C. T., Gabrielse, C., Chen, Y. C., and Weinreich, M. (2009) PLoS Genet. 5, e1000498). Both activities likely involve a Cdc7-Dbf4 interaction with Cdc5, the single Polo-like kinase in budding yeast. We previously showed that Dbf4 binds the Cdc5 polo-box domain (PBD) via an ～40-residue N-terminal sequence, which lacks a PBD consensus binding site (S(pS/pT)(P/X)), and that Dbf4 inhibits Cdc5 function during mitosis. Here we identify a non-consensus PBD binding site within Dbf4 and demonstrate that the PBD-Dbf4 interaction occurs via a distinct PBD surface from that used to bind phosphoproteins. Genetic and biochemical analysis of multiple dbf4 mutants indicate that Dbf4 inhibits Cdc5 function through direct binding. Surprisingly, mutation of invariant Cdc5 residues required for binding phosphorylated substrates has little effect on yeast viability or growth rate. Instead, cdc5 mutants defective for binding phosphoproteins exhibit enhanced resistance to microtubule disruption and an increased rate of spindle elongation. This study, therefore, details the molecular nature of a new type of PBD binding and reveals that Cdc5 targeting to phosphorylated substrates likely regulates spindle dynamics.     

Synthesis and analgesic activity of hydrochlorides and quaternary ammoniums of epibatidine incorporated with amino acid ester

Hydrochloride derivatives 5a–c and quaternary ammonium derivatives 6a–c of epibatidine incorporated with amino acid ester were synthesized and evaluated for their in vivo analgesic activity and toxicity. Among all tested compounds, compound 6c has the most potent analgesic activity. The quaternary ammonium salts 6a and 6c showed better analgesic activity than the corresponding hydrochlorides 5a and 5c. Both 5a–c and 6a–c showed significantly lower toxicity than epibatidine itself.     

SocA is a novel periplasmic binding protein for fructosyl amino acid

Bacterial periplasmic proteins (bPBPs) undergo drastic conformational changes upon binding substrate, making them appealing as novel molecular recognition tools for biosensing. A putative bPBP-encoding gene, socA, belongs to the soc operon responsible for santhopine (fructosyl glutamine, FQ) catabolism of Agrobacterium tumefaciens. The socA gene was isolated and expressed in Escherichia coli as a soluble 28.8kDa periplasmic protein to investigate its properties as a potential bPBP for fructosyl amino acid (FA). The autofluorescence of SocA was used to monitor the protein's conformational change resulting from substrate binding. The fluorescence intensity changed upon binding FQ in a concentration dependent manner with a calculated K(d) of 2.1muM, but was unaffected by the presence of sugars or amino acid. Our results demonstrate that SocA is a novel FA bPBP that can be utilized as a novel molecular recognition element for the monitoring of FA.     

Identification of amino acid residues of matrix metalloproteinase-7 essential for binding to cholesterol sulfate

Matrix metalloproteinase-7 (MMP-7; matrilysin) induces homotypic adhesion of colon cancer cells by cleaving cell surface protein(s) and enhances their metastatic potential. Our previous study (Yamamoto, K., Higashi, S., Kioi, M., Tsunezumi, J., Honke, K., and Miyazaki, K. (2006) J. Biol. Chem. 281, 9170-9180) demonstrated that binding of MMP-7 to cell surface cholesterol sulfate (CS) is essential for the cell membrane-associated proteolytic action of the protease. To determine the region of MMP-7 essential for binding to CS, we constructed chimeric proteases consisting of various parts of MMP-7 and those of the catalytic domain of MMP-2; the latter protease does not have an affinity for CS. Studies of these chimeric proteases and other mutants of MMP-7 revealed that Ile29, Arg33, Arg51, and Trp55, in the internal sequence, and the C-terminal three residues corresponding to residues 171-173 of MMP-7 are essential for binding to CS. An MMP-7 mutant, which had the internal 4 residues at positions 29, 33, 51, and 55 of MMP-7 replaced with the corresponding residues of MMP-2 and the C-terminal 3 residues deleted, had essentially no affinity for CS. This mutant and wild-type MMP-7 showed similar proteolytic activity toward fibronectin, whereas the mutant lacked the ability to induce the colon cancer cell aggregation. In the three-dimensional structure of MMP-7, the residues essential for binding to CS are located on the molecular surface in the opposite side of the catalytic cleft of the protease. Therefore, it is assumed that the active site of MMP-7 bound to cell surface is directed outside. We speculate that the direction of the cell-bound MMP-7 makes it feasible for the protease to cleave its substrates on cell surface.     

The binding of amino acids to the herbicide 2,4-dichlorophenoxy acetic acid

Summary. The interaction of amino acids with the herbicide 2,4-dichlorophenoxyacetic acid (2,4-D) was studied by charge-transfer chromatography carried out on diatomaceous layers covered with different amount of 2,4-D and the effect of salts on the strength of interaction was elucidated. It was established that Arg, His, Lys, Orn, Phe and Trp binds to 2,4-D, the binding process is of saturation character. Principal component analysis proved that the concentration of 2,4-D exerts the highest impact on the interaction and the effect of salts is of secondary importance. The results suggest that these amino acid residues may account for the binding of 2,4-D to proteins and can play a considerable role in the detoxification processes by forming conjugates with 2,4-D. Received April 10, 1998, Accepted September 15, 1998     

Haloperidol binding to monoclonal antibodies. Hypervariable region amino acid sequence determination

The primary sequences of five monoclonal antibodies (mAbs A-E) which bind with various affinities (Kd = 4-810 nM) to the D-2 dopaminergic antagonist, haloperidol, have been determined. Immunoglobulin light and heavy chain mRNA was isolated and gene sequence determined by primer extension in the presence of dideoxynucleotides. The pattern of insertions and deletions found within the hypervariable regions produce loops which differ in length from one antibody to another, and are directly responsible for establishing the gross architecture of the combining site. Two of the anti-haloperidol mAbs have long hypervariable loops which form a pocket-shaped combining site. Three other mAbs have deletions of 3 or 4 amino acids in the third heavy chain complementarity producing region which result in a groove-like combining site as determined by computer based molecular modeling. A discussion of the probable mechanism by which the given sequences were generated from various gene segments is also presented.     

Cellular retinoic acid binding protein I mediates rapid non-canonical activation of ERK1/2 by all-trans retinoic acid

All-trans retinoic acid (atRA), one of the active ingredients of vitamin A, exerts canonical activities to regulate gene expression mediated by nuclear RA receptors (RARs). AtRA could also elicit certain non-canonical activities including, mostly, rapid activation of extracellular signal regulated kinase 1/2 (ERK1/2); but the mechanism was unclear. In this study, we have found that cellular retinoic acid binding protein I (CRABPI) mediates the non-canonical, RAR- and membrane signal-independent activation of ERK1/2 by atRA in various cellular backgrounds. In the context of embryonic stem cells (ESCs), atRA/CRABPI-dependent ERK1/2 activation rapidly affects ESC cell cycle, specifically to expand the G1 phase. This is mediated by ERK stimulation resulting in dephosphorylation of nuclear p27, which elevates nuclear p27 protein levels to block G1 progression to S phase. This is the first study to identify CRABPI as the mediator for non-canonical activation of ERK1/2 by atRA, and demonstrate a new functional role for CRABPI in modulating ESC cell cycle progression.     

The RRM domain of human fused in sarcoma protein reveals a non-canonical nucleic acid binding site

Fused in sarcoma (FUS) is involved in many processes of RNA metabolism. FUS and another RNA binding protein, TDP-43, are implicated in amyotrophic lateral sclerosis (ALS). It is significant to characterize the RNA recognition motif (RRM) of FUS as its nucleic acid binding properties are unclear. More importantly, abolishing the RNA binding ability of the RRM domain of TDP43 was reported to suppress the neurotoxicity of TDP-43 in Drosophila. The sequence of FUS-RRM varies significantly from canonical RRMs, but the solution structure of FUS-RRM determined by NMR showed a similar overall folding as other RRMs. We found that FUS-RRM directly bound to RNA and DNA and the binding affinity was in the micromolar range as measured by surface plasmon resonance and NMR titration. The nucleic acid binding pocket in FUS-RRM is significantly distorted since several critical aromatic residues are missing. An exceptionally positively charged loop in FUS-RRM, which is not found in other RRMs, is directly involved in the RNA/DNA binding. Substituting the lysine residues in the unique KK loop impaired the nucleic acid binding and altered FUS subcellular localization. The results provide insights into the nucleic acid binding properties of FUS-RRM and its potential relevance to ALS.