Mirror-Image 5S Ribonucleoprotein Complexes.

After realizing mirror-image genetic replication, transcription, and reverse transcription, the biggest challenge in establishing a mirror-image version of the central dogma is to build a mirror-image ribosome-based translation machine. Here, we chemically synthesized the natural and mirror-image versions of three ribosomal proteins (L5, L18, and L25) in the large subunit of the Escherichia coli ribosome with post-translational modifications. We show that the synthetic mirror-image proteins can fold in vitro despite limited efficiency and assemble with enzymatically transcribed mirror-image 5S ribosomal RNA into ribonucleoprotein complexes. In addition, the RNA-protein interactions are chiral-specific in that the mirror-image ribosomal proteins do not bind with natural 5S ribosomal RNA and vice versa. The synthesis and assembly of mirror-image 5S ribonucleoprotein complexes are important steps towards building a functional mirror-image ribosome.

Landornamides: Antiviral Ornithine-Containing Ribosomal Peptides Discovered through Genome Mining.

Proteusins are a family of bacterial ribosomal peptides that largely remain hypothetical genome-predicted metabolites. The only known members are the polytheonamide-type cytotoxins, which have complex structures due to numerous unusual posttranslational modifications (PTMs). Cyanobacteria contain large numbers of putative proteusin loci. To investigate their chemical and pharmacological potential beyond polytheonamide-type compounds, we characterized landornamide A, the product of the silent osp gene cluster from Kamptonema sp. PCC 6506. Pathway reconstruction in E. coli revealed a peptide combining lanthionines, d-residues, and, unusually, two ornithines introduced by the arginase-like enzyme OspR. Landornamide A inhibited lymphocytic choriomeningitis virus infection in mouse cells, thus making it one of the few known anti-arenaviral compounds. These data support proteusins as a rich resource of chemical scaffolds, new maturation enzymes, and bioactivities.

Aligator: A computational tool for optimizing total chemical synthesis of large proteins.

The scope of chemical protein synthesis (CPS) continues to expand, driven primarily by advances in chemical ligation tools (e.g., reversible solubilizing groups and novel ligation chemistries). However, the design of an optimal synthesis route can be an arduous and fickle task due to the large number of theoretically possible, and in many cases problematic, synthetic strategies. In this perspective, we highlight recent CPS tool advances and then introduce a new and easy-to-use program, Aligator (Automated Ligator), for analyzing and designing the most efficient strategies for constructing large targets using CPS. As a model set, we selected the E. coli ribosomal proteins and associated factors for computational analysis. Aligator systematically scores and ranks all feasible synthetic strategies for a particular CPS target. The Aligator script methodically evaluates potential peptide segments for a target using a scoring function that includes solubility, ligation site quality, segment lengths, and number of ligations to provide a ranked list of potential synthetic strategies. We demonstrate the utility of Aligator by analyzing three recent CPS projects from our lab: TNFα (157 aa), GroES (97 aa), and DapA (312 aa). As the limits of CPS are extended, we expect that computational tools will play an increasingly important role in the efficient execution of ambitious CPS projects such as production of a mirror-image ribosome.

A Helping Hand to Overcome Solubility Challenges in Chemical Protein Synthesis.

Although native chemical ligation (NCL) and related chemoselective ligation approaches provide an elegant method to stitch together unprotected peptides, the handling and purification of insoluble and aggregation-prone peptides and assembly intermediates create a bottleneck to routinely preparing large proteins by completely synthetic means. In this work, we introduce a new general tool, Fmoc-Ddae-OH, N-Fmoc-1-(4,4-dimethyl-2,6-dioxocyclo-hexylidene)-3-[2-(2-aminoethoxy)ethoxy]-propan-1-ol, a heterobifunctional traceless linker for temporarily attaching highly solubilizing peptide sequences ("helping hands") onto insoluble peptides. This tool is implemented in three simple and nearly quantitative steps: (i) on-resin incorporation of the linker at a Lys residue ε-amine, (ii) Fmoc-SPPS elongation of a desired solubilizing sequence, and (iii) in-solution removal of the solubilizing sequence using mild aqueous hydrazine to cleave the Ddae linker after NCL-based assembly. Successful introduction and removal of a Lys6 helping hand is first demonstrated in two model systems (Ebola virus C20 peptide and the 70-residue ribosomal protein L31). It is then applied to the challenging chemical synthesis of the 97-residue co-chaperonin GroES, which contains a highly insoluble C-terminal segment that is rescued by a helping hand. Importantly, the Ddae linker can be cleaved in one pot following NCL or desulfurization. The purity, structure, and chaperone activity of synthetic l-GroES were validated with respect to a recombinant control. Additionally, the helping hand enabled synthesis of d-GroES, which was inactive in a heterochiral mixture with recombinant GroEL, providing additional insight into chaperone specificity. Ultimately, this simple, robust, and easy-to-use tool is expected to be broadly applicable for the synthesis of challenging peptides and proteins.

Novel chimeric peptide with enhanced cell specificity and anti-inflammatory activity.

An antimicrobial peptide (AMP), Hn-Mc, was designed by combining the N-terminus of HPA3NT3 and the C-terminus of melittin. This chimeric AMP exhibited potent antibacterial activity with low minimal inhibitory concentrations (MICs), ranging from 1 to 2 µM against four drug-susceptible bacteria and ten drug-resistant bacteria. Moreover, the hemolysis and cytotoxicity was reduced significantly compared to those of the parent peptides, highlighting its high cell selectivity. The morphological changes in the giant unilamellar vesicles and bacterial cell surfaces caused by the Hn-Mc peptide suggested that it killed the microbial cells by damaging the membrane envelope. An in vivo study also demonstrated the antibacterial activity of the Hn-Mc peptide in a mouse model infected with drug-resistant bacteria. In addition, the chimeric peptide inhibited the expression of lipopolysaccharide (LPS)-induced cytokines in RAW 264.7 cells by preventing the interaction between LPS and Toll-like receptors. These results suggest that this chimeric peptide is an antimicrobial and anti-inflammatory candidate as a pharmaceutic agent.

Synthesis and evaluation of fluorine-18 labelled compounds for imaging of bacterial infections with pet.

Syntheses of no carrier added (n.c.a.) 6-fluoro-1,4-dihydro-1-cyclopropyl-4-oxo-7-[4-[18F]fluoro-phenacyl-1-piperacinyl]-chinolincarboxylic acid ([18F]COPCA) and n.c.a. 4-[18F]fluoro-benzoyl-ubiquicidin 29-41 ([18F]UBI 29-41) are described. [18F]COPCA was synthesised within 120 min with a radiochemical yield of 9-12%. [18F]UBI 29-41 was synthesised within 150 min with a radiochemical yield of 15-20%. Both compounds had a specific activity of more than 35 GBq/micromol. The biological activity was verified by measuring its binding to Staphylococcus aureus bacteria. Specific binding was found for [18F]UBI 29-41 (12-17%), whereas no specific binding for [18F]COPCA was found.

Identification and chemical synthesis of a ribosomal protein antigenic determinant in systemic lupus erythematosus.

The characteristics of eukaryotic ribosomal proteins P0, P1, and P2 (P proteins) and their antigenic determinants were studied using the sera of patients with systemic lupus erythematosus (SLE). P0, P1, and P2 were isolated as a macromolecular complex by preparative isoelectric focusing and anion-exchange chromatography in the presence of 6 M urea. The apparent molecular size of the complex was 140 kDa as determined by gel filtration on a Sephadex G-200 column. P0 may, therefore, be the eukaryotic equivalent of Escherichia coli ribosomal protein L10. In addition, all three P proteins were detected in the postribosomal supernatant of HeLa cells, and P0 and P1 were found to be more acidic than their ribosome-bound counterparts. Partial proteolysis experiments revealed that SLE anti-P sera recognized one or both ends of the P2 equivalent protein from Artemia salina (eL12). Sixteen SLE sera containing antibodies to P0, P1, and P2 reacted with a carboxyl-terminal peptide 22 amino acids in length of eL12 and not with an amino-terminal peptide of 20 amino acids. Even though the carboxyl-terminal peptide completely inhibited the ability of the antiserum to react with all three proteins on an immunological blot, the same peptide produced only small decreases in binding of the SLE antibody to the native, nondenatured P proteins. These findings indicate that SLE anti-P antibodies react with a single sequential (linear) antigenic determinant on all three P proteins, but that additional antibodies recognize a conformational determinant(s).

Quantum chemical study of ester aminolysis catalyzed by a single adenine: a reference reaction for the ribosomal peptide synthesis.

Herein we report the results of a HF/6-31+G** and B3LYP/6-31+G** computational investigation of the title reaction for the peptide bond synthesis catalyzed by a single adenine. This system constitutes a reference reaction to study the basic chemical events that have been proposed to occur at the peptidyl transferase active site of ribosomes on the basis of structural determinations (Science 2000, 239, 920--931). Thus, the analysis of the geometry, charge distribution, and energetics of the critical structures involved in this title reaction yields insight into the catalytic mode of action of RNA molecules. Our computational results give further support to the hypotheses that the activated nucleotide A2451 in the ribosome acts as a base catalyst and that this role is similar to that of the His residue in the catalytic triad of serine proteases.

Heterogeneity of anti-dsDNA antibodies in their cross-reaction with ribosomal P protein.

We have investigated the possible cross-reaction of anti-dsDNA antibodies with ribosomal P peptide for several reasons. First, the antibodies frequently occur together, and secondly, they vary similarly with disease activity. Human polyclonal anti-dsDNA antibodies were affinity purified from eight patients and anti-ribosomal P antibodies from two patients with systemic Lupus erythematosus (SLE) who had high titers of anti-dsDNA as well as anti-ribosomal P antibodies. Nine of the 10 sera were totally specific in their reactivity with their cognate antigens. In only one patient did we find a subpopulation of antibodies which cross-reacted with both dsDNA and the carboxyl terminal 22 amino acid peptide. Our results indicate that anti-dsDNA antibodies are heterogeneous and usually do not cross-react with the carboxyl terminal P peptide, but on occasion (1/10) a patient will produce anti-dsDNA antibodies cross-reactive with the carboxyl terminal P peptide.

Characterization of large peptide fragments derived from the N-terminal domain of the ribosomal protein L9: definition of the minimum folding motif and characterization of local electrostatic interactions.

A set of peptides derived from the N-terminal domain of the ribosomal protein L9 (NTL9) have been characterized in an effort to define the minimum unit of this domain required to fold and to provide model peptides for the analysis of electrostatic interactions in the unfolded state. NTL9 is a 56-residue alpha-beta protein with a beta1-loop-beta2-alpha1-beta3-alpha2 topology. The beta-sheet together with the first helix comprise a simple example of a common supersecondary motif called the split beta-alpha-beta fold. Peptides corresponding to the beta1-loop-beta2 unit are unstructured even when constrained by an introduced disulfide. The pK(a)s of Asp-8 and Glu-17 in these peptides are slightly lower than the values found for shorter peptides but are considerably higher than the values in NTL9. A 34-residue peptide, which represents the beta1-loop-beta2-alpha1 portion of NTL9, is also unstructured. In contrast, a 39-residue peptide corresponding to the entire split beta-alpha-beta motif is folded and monomeric as judged by near- and far-UV CD, two-dimensional NMR, ANS binding experiments, pK(a) measurements, and analytical ultracentrifugation. The fold is very similar to the structure of this region in the intact protein. Thermal and urea unfolding experiments show that it is cooperatively folded with a DeltaG degrees of unfolding of 1.8-2.0 kcal/mol and a T(m) of 58 degrees C. This peptide represents the first demonstration of the independent folding of an isolated split beta-alpha-beta motif, and is one of only four naturally occurring sequences of fewer than 40 residues that has been shown to fold cooperatively in the absence of disulfides or ligand binding.

Structure and expression of the nuclear gene coding for the plastid CS1 ribosomal protein from spinach.

The chloroplast ribosomal protein CS1 is an essential component of the plastids translational machinery involved in translation initiation. Southern analysis suggests that the corresponding nuclear gene is present in one copy in the spinach genome. We have isolated and sequenced the gene (rps1) to study its expression at the transcriptional level. The gene consists of 7 exons and 6 introns including an unusually large intron in the 5' coding region. No canonical TATA-box is found in the 5' upstream region of the gene. rps1 transcripts are detected early during germination and a significant accumulation is observed after the protrusion of the radicle. CS1 mRNAs are present in all organs of young seedlings although there are dramatic differences in the steady state level of the mRNAs between leaves and roots tissues. Transcripts accumulate independently of the presence or absence of light. Band shift analysis shows that the +1, -400 bp region of the gene can bind different sets of proteins isolated from roots and leaves nuclei. We suggest that the expression of the housekeeping plastid-related rps1 gene is regulated in a tissue-specific manner by transcriptional trans-acting factors.

Multisite phosphorylation of a synthetic peptide derived from the carboxyl terminus of the ribosomal protein S6.

The synthetic peptide AKRRRLSSLRASTSKSESSQK (S6-21) which corresponds to the carboxyl-terminal 21 amino acids of human ribosomal protein S6 was synthesized and tested as a substrate for S6/H4 kinase purified from human placenta. The specific activity of the enzyme with the synthetic peptide and 40 S ribosomes was 45 and 23 nmol/min/mg, respectively. The S6/H4 kinase activity with S6-21 was greater than the enzyme activity with any other substrate tested, including histones, protamine, and casein and several other synthetic peptides. The phosphorylation of the peptide was not inhibited by inhibitors of several other proteins kinases. S6/H4 kinase catalyzed the phosphorylation of three major sites in the synthetic peptide and the 40 S ribosomes. A fourth site in S6-21 was phosphorylated more slowly. The principal phosphorylation sites were serines in the acidic carboxyl-terminal domain of the peptide. A serine (Ser-7 or -8) in the amino-terminal domain was phosphorylated at approximately 25% the rate of the carboxyl-terminal domain serines. The data suggest that multiple S6 kinases may be required to phosphorylate S6 at all five sites which are modified in vivo.

Design of novel analogues with potent antibiotic activity based on the antimicrobial peptide, HP(2-9)-ME(1-12).

To develop novel antibiotic peptides useful as therapeutic drugs, a number of analogues were designed to increase the hydrophobic helix region either by Trp-substitution or net positive charge increase by Lys-substitution, from HP(2-9)-ME(1-12). The antibiotic activities of these peptides were evaluated using bacterial (Salmonella tryphimurium, Proteus vulgaris, Bacillus subtilis and Staphylococcus aureus), fungi (Saccharomyces cerevisiae, Trichosporon beigelii and Candida albicans), tumor and human erythrocyte cells. The substitution of Lys for Thr at position 18 and 19 of HP(2-9)-ME(1-12) (HM5) increased activity against Proteus vulgaris and fungal strains without hemolysis. In contrast, substitution of Trp for Lys and Thr at positions 2, 15 and 19 of HP(2-9)-ME(1-12), respectively (HM3 and HM4), decreased activity but increased hemolysis against human erythrocytes. This suggests that an increase in positive charge increases antimicrobial activity whereas an increase in hydrophobicity by introducing Trp residues at C-terminus of HP(2-9)-ME(1-12) causes a hemolytic effect. Circular dichroism spectra suggested that the alpha-helical structure of these peptides plays an important role in their antibiotic effect but that the alpha-helical property is not connected with the enhanced antibiotic activity.

Chemically synthesized ubiquitin extension proteins detect distinct catalytic capacities of deubiquitinating enzymes.

We have used solid-phase chemistry to synthesize proteins equivalent to a human ubiquitin precursor (ubiquitin-52-amino-acid ribosomal protein fusion; UBICEP52) and representative of isopeptide-linked ubiquitin-protein conjugates [ubiquitin-(epsilonN)-lysine]; these proteins were precisely cleaved by a purified recombinant Drosophila deubiquitinating enzyme (DUB), UCH-D. Along with the previously synthesized ubiquitin-(alphaN)-valine, these synthetic proteins were used as substrates to assess the catalytic capacities of a number of diverse DUBs expressed in Escherichia coli: human HAUSP; mouse Unp; and yeast Ubps 1p, 2p, 3p, 6p, 11p, and 15p and Yuh1p. Distinct specificities of these enzymes were detected; notably, in addition to UCH-D, isopeptidase activity [ubiquitin-(epsilonN)-lysine cleavage] was only associated with Yuh1p, Unp, Ubp1p, and Ubp2p. Additionally, human placental 26S proteasomes were only able to cleave UBICEP52 and ubiquitin-(epsilonN)-lysine, suggesting that 26S proteasome-associated DUBs are class II-like. This work demonstrates that the synthetic approach offers an alternative to recombinant methods for the production of small proteins in vitro.

Ribosome modulation factor: stationary growth phase-specific inhibitor of ribosome functions from Escherichia coli.

Ribosome modulation factor (RMF) is an Escherichia coli protein associated with 100S ribosome dimers, which are formed at stationary growth phase or in slowly growing cells. RMF either purified from stationary-phase ribosomes or synthesized by a chemical method was examined for its functions. By adding either natural or synthetic RMF to 70S ribosomes prepared from both exponentially growing and stationary phase cells, 100S ribosome dimers were generated in a concentration-dependent manner. Protein synthesis in vitro was inhibited concomittantly with the formation of 100S ribosomes. The binding of aminoacyl-tRNA to ribosomes was inhibited in parallel. Taken together we propose that RMF is a stationary phase-specific inhibitor of ribosome functions and 100S dimers are stored forms of ribosomes.

Nobel de Química 2009: estructura atómica de la maquinaria celular para sintetizar proteínas / Nobel Prize in Chemistry 2009: atomic structure of the cellular machinery for protein synthesis

El Premio Nobel de Química de 2009 ha sido otorgado a VenkatramanRamakrishnan (MRC Laboratory of Molecular Biology, ReinoUnido), Thomas Steitz (Yale University, Estados Unidos) y Ada Yonath(Weizmann Institute of Science, Israel) por sus estudios sobre laestructura y función del ribosoma, la máquina macromolecular quelleva a cabo la síntesis de proteínas dentro de la célula. Los científicos,en un extraordinario esfuerzo de más de veinte años, aplicaron lacristalografía de rayos X para determinar la estructura atómica de esteenorme complejo macromolecular, de forma aislada y en asociacióncon los principales componentes que intervienen en el proceso de síntesisproteica. Los modelos resultantes han sido esenciales para entenderlos mecanismos que subyacen a dicho proceso, en particular cómoel ribosoma es capaz de descifrar el ARN de mensajero (que porta lainformación genética contenida en el ADN), cómo procede la catálisisdel enlace peptídico, y el modo en que varios antibióticos nos defiendende las infecciones bacterianas(AU)

Nobel Prize in Chemistry 2009: atomic structure of thecellular machinery for protein synthesisThe 2009 Nobel Prize in Chemistry has been awarded toVenkatraman Ramakrishnan (MRC Laboratory of Molecular Biology,United Kingdom), Thomas Steitz (Yale University, United States)and Ada Yonath (Weizmann Institute of Science, Israel) for theirstudies in the structure and function of the ribosome, a macromolecularmachine that carries out protein synthesis within the cell.The scientists, in an incredible tour de force that took over twentyyears, applied X-ray crystallography in order to determine the atomicstructure of this large macromolecular complex, alone and inassociation with the major components in the protein synthesisprocess. The resulting models have been essential to understand themechanisms underlying this process, in particular how the ribosomeis able to decode messenger RNA (which carries the geneticinformation stored in DNA), how peptide bond catalysis proceeds,and the way in which several antibiotics protect us from bacterialinfections(AU)