Evaluation of geranylazide and farnesylazide diphosphate for incorporation of prenylazides into a CAAX box-containing peptide using protein farnesyltransferase.

Protein farnesyltransferase (PFTase) catalyzes the attachment of a geranylazide (C10) or farnesylazide (C15) moiety from the corresponding prenyldiphosphates to a model peptide substrate, N-dansyl-Gly-Cys-Val-Ile-Ala-OH. The rates of incorporation for these two substrate analogs are comparable and approximately twofold lower than that using the natural substrate farnesyl diphosphate (FPP). Reaction of N-dansyl-Gly-Cys(S-farnesylazide)-Val-Ile-Ala-OH with 2-diphenylphosphanylbenzoic acid methyl ester then gives a stable alkoxy-imidate linked product. This result suggests future generations whereby azide groups introduced using this enzymatic approach are functionalized using a broad range of azide-reactive reagents. Thus, chemistry has been developed that could be used to achieve highly specific peptide and protein modification. The farnesylazide analog may be useful in certain biological studies, whereas the geranylazide group may be more useful for general protein modification and immobilization.     

Didehydrofarnesyl diphosphate: an intrinsically fluorescent inhibitor of protein farnesyltransferase

Didehydrofarnesyl diphosphate (delta delta FPP), a fluorescent pentaene analogue of farnesyl diphosphate (FPP), was synthesized using stereoselective Wittig reactions. Although delta delta FPP was not an alternative substrate for yeast protein farnesyltransferase (FTase), the fluorescent analogue was a potent competitive inhibitor with a K(i) value of 8.8 microM (K (m) (FPP) = 27 microM).     

Protease-catalyzed incorporation of non-protein amino acids into peptides via the kinetically controlled approach

Through the kinetically controlled approach, employing the methyl ester as an acyl donor, non-protein aliphatic amino acids were incorporated into peptides using papain in an aqueous buffer, while the incorporation of non-protein aromatic amino acids was achieved by exploiting -chymotrypsin in an aqueous buffer or acetonitrile with low water content. © Rapid Science Ltd. 1998     

Enzymatic activation of sulfur for incorporation into biomolecules in prokaryotes

Sulfur is a functionally important element of living matter. Incorporation into biomolecules occurs by two basic strategies. Sulfide is added to an activated acceptor in the biosynthesis of cysteine, from which methionine, coenzyme A and a number of biologically important thiols can be constructed. By contrast, the biosyntheses of iron sulfur clusters, cofactors such as thiamin, molybdopterin, biotin and lipoic acid, and the thio modification of tRNA require an activated sulfur species termed persulfidic sulfur (R-S-SH) instead of sulfide. Persulfidic sulfur is produced enzymatically with the IscS protein, the SufS protein and rhodanese being the most prominent biocatalysts. This review gives an overview of sulfur incorporation into biomolecules in prokaryotes with a special emphasis on the properties and the enzymatic generation of persulfidic sulfur as well as its use in biosynthetic pathways.     

Reversible fluorescence labeling of amino groups of protein using dansylaminomethylmaleic anhydride

The reversible fluorescence labeling of insulin, catalase and lysozyme has been demonstrated. As a derivatizing reagent, dansylaminomethylmaleic acid (DAM) has been used after investigating the precolumn and precapillary derivatization conditions. This reagent (DAM) reacts with the amino groups of proteins via its anhydride in the presence of a suitable dehydrating reagent, which then could be liberated under mild acidic conditions and the native proteins are regenerated. After the derivatization of insulin, catalase and lysozyme with DAM, no peaks of these native proteins were observed while several peaks of the derivatized proteins due to the multiple labeling were observed. However, after the regeneration, increasing amounts of the native proteins were observed as the regeneration period increased. For the lysozyme, the bacteriolytic activity of the enzyme decreased after the derivatization, and only 0.9% of the activity remained. The activity increases by the regeneration, and 95.6% of the bacteriolytic activity of the native enzyme was observed after a 48-h regeneration at pH 2.5 and 40 degrees C.     

Micro method for determination of reactive carbonyl groups in proteins and peptides, using 2,4-dinitrophenylhydrazine

A method is described for determining carbonyl groups that is especially suitable for use with proteins and peptides. It involves the determination of the extinction at 370nm of a sample solution after adding 2,4-dinitrophenylhydrazine. The reaction of 2,4-dinitrophenylhydrazine with pyruvoylglycine and with transaminated ribonuclease T(1) is presented; the isolation of protein hydrazones is discussed.     

Possible incorporation of phosphoserine into globin readthrough protein via bovine opal suppressor phosphoseryl-tRNA

Suppressor [32P]phosphoseryl-tRNA, prepared using bovine seryl-tRNA synthetase and ATP:seryl-tRNA phosphotransferase, was mixed with rabbit reticulocyte lysates containing endogenous hemoglobin mRNA having the termination codon UGA (opal). The chromatographic pattern of the lysate on Sephacryl S-200 showed that the radioactivity of [32P]phosphate in the hot trichloroacetic acid-precipitate (phosphoprotein) was eluted at the position between mature hemoglobin and globin subunits. The phosphoprotein, obtained by chromatography on S-200, moved to the position corresponding to that of globin readthrough protein on SDS-PAGE. The analyses of the hydrolyzate of the phosphoprotein showed the presence of phosphoserine in the protein. These results suggest that animal opal suppressor tRNA functions in vitro to transfer phosphoserine to the position of the termination codon UGA (opal) on mRNA.     

Selective labeling of functional groups on membrane proteins or glycoproteins using reactive biotin derivatives and 125I-streptavidin

Amino groups, sulfhydryl groups or oxidation-induced aldehydes on erythrocyte membrane proteins and/or glycoproteins, were reacted with biotinyl N-hydroxysuccinimide ester (BNHS), 3-(N-maleimido-propionyl) biocytin (MPB) or biocytin hydrazide (BCHZ), respectively. The detergent-lysed biotinylated samples were subjected to SDS-polyacrylamide gel electrophoresis, and the proteins were transferred onto nitrocellulose membranes. The blot was then incubated with a solution containing 125I-streptavidin, and processed for autoradiography. The advantages of this approach over previously reported procedures for labeling the three functional groups include the following: extremely high sensitivity; short exposure times of autoradiograms and relatively low levels of radioactivity; single-step radiolabeling procedures subsequent to processing and handling of gels and no background labeling in control samples.     

Modulation of adenovirus vector tropism via incorporation of polypeptide ligands into the fiber protein

The efficacy of adenovirus (Ad)-based gene therapy might be significantly improved if viral vectors capable of tissue-specific gene delivery could be developed. Previous attempts to genetically modify the tropism of Ad vectors have been only partially successful, largely due to the limited repertoire of ligands that can be incorporated into the Ad capsid. Early studies identified stringent size limitations imposed by the structure of the Ad fiber protein on ligands incorporated into its carboxy terminus and thus limited the range of potential ligand candidates to short peptides. We have previously identified the HI loop of the fiber knob domain as a preferred site for the incorporation of targeting ligands and hypothesized that the structural properties of this loop would allow for the insertion of a wide variety of ligands, including large polypeptide molecules. In the present study we have tested this hypothesis by deriving a family of Ad vectors whose fibers contain polypeptide inserts of incrementally increasing lengths. By assessing the levels of productivity and infectivity and the receptor specificities of the resultant viruses, we show that polypeptide sequences exceeding by 50% the size of the knob domain can be incorporated into the fiber with only marginal negative consequences on these key properties of the vectors. Our study has also revealed a negative correlation between the size of the ligand used for vector modification and the infectivity and yield of the resultant virus, thereby predicting the limits beyond which further enlargement of the fiber knob would not be compatible with the virion's integrity.     

Basis for selective incorporation of glycoproteins into the influenza virus envelope.

The ability of mutant or chimeric A/Japan hemagglutinins (HAs) to compete for space in the envelope of A/WSN influenza viruses was investigated with monkey kidney fibroblasts that were infected with recombinant simian virus 40 vectors expressing the Japan proteins and superinfected with A/WSN influenza virus. Wild-type Japan HA assembled into virions as well as WSN HA did. Japan HA lacking its cytoplasmic sequences, HAtail-, was incorporated into influenza virions at half the efficiency of wild-type Japan HA. Chimeric HAs containing the 11 cytoplasmic amino acids of the herpes simplex virus type 1gC glycoprotein or the 29 cytoplasmic amino acids of the vesicular stomatitis virus G protein were incorporated into virions at less than 1% the efficiency of HAtail-. Thus, the cytoplasmic domain of HA was not required for the selection process; however, foreign cytoplasmic sequences, even short ones, were excluded. A chimeric HA having the gC transmembrane domain and the HA cytoplasmic domain (HgCH) was incorporated at 4% the efficiency of HAtail-. When expressed from simian virus 40 recombinants in this system, vesicular stomatitis virus G protein with or without (Gtail-) its cytoplasmic domain was essentially excluded from influenza virions. Taken together, these data indicate that the HA transmembrane domain is required for incorporation of HA into influenza virions. The slightly more efficient incorporation of HgCH than G or Gtail- could indicate that the region important for assembling HA into virions extends into part of the cytoplasmic domain.     

Cleavable ester-linked magnetic nanoparticles for labeling of solvent-exposed primary amine groups of peptides/proteins

To study the solvent-exposed lysine residues of peptides/proteins, we previously reported disulfide-linked N-hydroxysuccinimide ester-modified silica-coated iron oxide magnetic nanoparticles (NHS–SS–SiO₂@Fe₃O₄ MNPs). The presence of a disulfide bond in the linker limits the use of disulfide reducing agent during protein digestion and allows unwanted disulfide formation between the MNPs and protein. In the current work, the disulfide bond was replaced with a cleavable ester group to synthesize NHS ester-modified SiO₂@Fe₃O₄ MNPs. Use of the cleavable ester group provides an improved method for protein labeling and allows the use of disulfide reducing agents during protein digestion.     

Fibrillar amyloid-beta peptides activate microglia via TLR2: implications for Alzheimer's disease

Microglial activation is an important pathological component in brains of patients with Alzheimer's disease (AD), and fibrillar amyloid-beta (Abeta) peptides play an important role in microglial activation in AD. However, mechanisms by which Abeta peptides induce the activation of microglia are poorly understood. The present study underlines the importance of TLR2 in mediating Abeta peptide-induced activation of microglia. Fibrillar Abeta1-42 peptides induced the expression of inducible NO synthase, proinflammatory cytokines (TNF-alpha, IL-1beta, and IL-6), and integrin markers (CD11b, CD11c, and CD68) in mouse primary microglia and BV-2 microglial cells. However, either antisense knockdown of TLR2 or functional blocking Abs against TLR2 suppressed Abeta1-42-induced expression of proinflammatory molecules and integrin markers in microglia. Abeta1-42 peptides were also unable to induce the expression of proinflammatory molecules and increase the expression of CD11b in microglia isolated from TLR2(-/-) mice. Finally, the inability of Abeta1-42 peptides to induce the expression of inducible NO synthase and to stimulate the expression of CD11b in vivo in the cortex of TLR2(-/-) mice highlights the importance of TLR2 in Abeta-induced microglial activation. In addition, ligation of TLR2 alone was also sufficient to induce microglial activation. Consistent to the importance of MyD88 in mediating the function of various TLRs, antisense knockdown of MyD88 also inhibited Abeta1-42 peptide-induced expression of proinflammatory molecules. Taken together, these studies delineate a novel role of TLR2 signaling pathway in mediating fibrillar Abeta peptide-induced activation of microglia.     

Effects of five-membered ring amino acid incorporation into peptides for coiled coil formation

A five-membered ring amino acid (Ac₅c), the peptides of which exhibit a preference for helical secondary structures, was introduced into peptides for the purpose of designing coiled coil peptides with high binding affinities. We prepared five types of peptides containing Ac₅c with different numbers or at different positions. The incorporation of Ac₅c into peptides enhanced their α-helicities; however, in contrast to our expectations, it did not result in stable coiled coil formation. The structures of side chains in hydrophobic amino acids, not α-helicities appeared to be important for stable hydrophobic interactions between peptides. Although we were unable to develop coiled coil peptides with high binding affinities, the present results will be useful for designing novel coiled coil peptides.     

Design of reactive-end DNA oligomers via incorporation of oxanine into oligonucleotides using terminal deoxynucleotidyl transferase

Oxanine (Oxa, O), a modified nucleobase, has a novel O-acylisourea structure. Oxa-incorporated oligodeoxynucleotides (ODNs) are reactive DNA oligomers that permit conjugation with various nucleophilic molecules in an activation-free manner. In this study, we developed a new procedure for enzymatic preparation of reactive-end DNA oligomers, using terminal deoxynucleotidyl transferase (TdT), in which a reactive Oxa base is incorporated into the 3′-end of ODNs. One limitation of TdT, an enzyme widely used for end labeling of DNA oligomers, is that it is difficult to control the number of incorporated labels, because it shows template-independent extension with random nucleotides. Notably, TdT showed a rate and efficiency of incorporation of the modified nucleobase, Oxa, different from that of natural bases. We investigated the conditions of TdT-mediated DNA incorporation of Oxa and achieved incorporation of Oxa at the 3′-end of ODNs by optimizing reaction parameters such as temperature and enzyme, cofactor, and substrate concentrations. We also confirmed the reactive functionality of Oxa after incorporation into ODNs by amide bonding conjugation with a polyamine (spermine) under physiological conditions, without need for an additional activation step.     

3-Azido-aspartic acid derivatives - orthogonally protected precursors for the stereoselective incorporation of 2,3-diaminosuccinic acid into peptide structures.

The stereoselective synthesis of orthogonally protected 3-azido aspartic acid derivatives is described. The convenience of their application as 2,3-diaminosuccinic acid in peptide chemistry was demonstrated by the incorporation of the nonproteinogenic diamino diacid as a cystine-substitute into the core structure of somatostatin.     

Crystal structure of Streptococcus suis Dps-like peroxide resistance protein Dpr: implications for iron incorporation

The Dps-like peroxide resistance protein (Dpr) is an aerotolerance and hydrogen peroxide resistance agent found in the meningitis-associated pathogen Streptococcus suis. Dpr is believed to act by binding free intracellular iron to prevent Fenton chemistry-catalysed formation of toxic hydroxyl radicals. The crystal structure of Dpr has been determined to 1.95 A resolution. The final model has an Rcyst value of 18.5% (Rfree = 22.4%) and consists of 12 identical monomers (each of them comprising a four alpha-helix bundle) that form a hollow sphere obeying 23 symmetry. Structural features show that Dpr belongs to the Dps family of bacterial proteins. Twelve putative ferroxidase centers, each formed at the interface of neighboring monomer pairs, were identified in the Dpr structure with structural similarities to those found in other Dps family members. Dpr was crystallized in the absence of iron, hence no bound iron was found in the structure in contrast to other Dps family members. A novel metal-binding site approximately 6A from the ferroxidase centre was identified and assigned to a bound calcium ion. Two residues from the ferroxidase centre (Asp63 and Asp74) were found to be involved in calcium binding. Structural comparison with other family members revealed that Asp63 and Asp74 adopt different conformation in the Dpr structure. The structure of Dpr presented here shows potential local conformational changes that may occur during iron incorporation. A role for the metal-binding site in iron uptake is proposed.     

Prosthetic groups for radioiodination and astatination of peptides and proteins: A comparative study of five potential bioorthogonal labeling strategies

¹²⁵I- and ²¹¹At-labeled azide and tetrazine based prosthetic groups for bioorthogonal conjugation were designed and tested in a comparative study of five bioorthogonal systems. All five bioconjugation reactions conducted on a model clickable peptide led to quantitative yields within less than a minute to several hours depending on the system used. Transferability to the labeling of an IgG was demonstrated with one of the bioorthogonal system. This study provides several new alternatives to the conventional and suboptimal approach currently in use for radioiodination and astatination of biomolecules and should accelerate the development of new probes with these radionuclides for applications in nuclear imaging and targeted alpha-therapy.     

Synthesis and enzymatic incorporation of photolabile dUTP analogues into DNA and their applications for DNA labeling

Two novel photolabile nucleotide triphosphate (NTP) analogues were synthesized through Sonogashira coupling and their enzymatic incorporation into DNA was evaluated with three different DNA polymerases (Taq, Vent exo- and T4) by polymerase chain reaction. Both nucleotide triphosphate analogues were recognized by these DNA polymerases as substrates for primer extension. Light irradiation of PCR products removed the photolabile group and released the amino and carboxyl moieties. Further site-specific dual-labeling for oligodeoxynucleotides (ODNs) and random labeling for a long DNA construct with fluorophores were successfully achieved with incorporation of the photolabile amine modified deoxyuridine triphosphate (dUnTP).