Desarrollos de la Tabla de Bion / Developments on Bion´s grid

Después de una pequeña introducción a los elementos del psicoanálisis y los tres principios vitales de Bion: 1.º sentir; 2.º pensar (imaginar); 3.º sentir más pensar más Pensar, el autor desarrolla la Tabla de éste en seis anexos explicados en su texto: 1.º, la Tabla negativa; 2.º, la discriminación y la previsión en el trabajo psicoanalítico; 3.º, la diferenciación entre acción y actuación; 4.º, consideraciones acerca del sistema Superyó-Ideal; 5.º, el desarrollo de la personalidad y su uso desde la teoría del pensamiento de Bion; 6.º, la clínica en la Tabla. Este trabajo condensa, resume y añade alguna idea nueva al libro del autor: Del sinsentido a la abstracción (2003) (AU)

Following a small introduction on Bion´s elements of psycho-analysis and on his three vital principles: 1. To feel, 2. To think, 3. To feel plus to think plus to Think, the author develops Bion´s grid in six annexes explained in the text: 1. The negative grid. 2. Discrimination and foresight in psycho-analytic work. 3. The difference between acting and acting out. 5. The development of the personality according to Bion´s theory of thinking. 6 Clinical work in the grid (AU)

Peptide chemical ligation inside living cells: in vivo generation of a circular protein domain.

Here we describe the first example of a peptide chemical ligation reaction performed inside a living cell. A cell-based native chemical ligation approach was developed and used to generate a circular version of the N-terminal Src homology 3 (SH3) domain from the murine c-Crk adapter protein inside Escherichia coli cells. The in vivo cyclization reaction was extremely efficient and the resulting circular protein domain was fully biologically active and able to adopt the native SH3 folded structure. This work represents an important step towards the in vivo generation of small backbone cyclic peptides for use in basic biological research.

Rescuing a destabilized protein fold through backbone cyclization.

We describe the physicochemical characterization of various circular and linear forms of the approximately 60 residue N-terminal Src homology 3 (SH3) domain from the murine c-Crk adapter protein. Structural, dynamic, thermodynamic, kinetic and biochemical studies reveal that backbone circularization does not prevent the adoption of the natural folded structure in any of the circular proteins. Both the folding and unfolding rate of the protein increased slightly upon circularization. Circularization did not lead to a significant thermodynamic stabilization of the full-length protein, suggesting that destabilizing enthalpic effects (e.g. strain) negate the expected favorable entropic contribution to overall stability. In contrast, we find circularization results in a dramatic stabilization of a truncated version of the SH3 domain lacking a key glutamate residue. The ability to rescue the destabilized mutant indicates that circularization may be a useful tool in protein engineering programs geared towards generating minimized proteins.

Mapping the molecular interface between the sigma(70) subunit of E. coli RNA polymerase and T4 AsiA.

Bacteriophage T4 antisigma protein AsiA (10 kDa) orchestrates a switch from the host and early viral transcription to middle viral transcription by binding to the sigma(70) subunit of E. coli RNA polymerase. The molecular determinants of sigma(70)-AsiA complex formation are not known. Here, we used combinatorial peptide chemistry, protein-protein crosslinking, and mutational analysis to study the interaction between AsiA and its target, the 33 amino acid residues-long sigma(70) peptide containing conserved region 4.2. Many region 4.2 amino acid residues contact AsiA, which likely completely occludes the DNA-binding surface of region 4.2. Though none of region 4.2 amino acid residues is singularly responsible for the very tight interaction with AsiA, sigma(70) Lys593 and Arg596 which lie outside the putative DNA recognition element of region 4.2, contribute the most. In AsiA, the first 20 amino acid residues are both necessary and sufficient for interactions with sigma(70). Our results clarify details of sigma(70)-AsiA interaction and open the way for engineering AsiA derivatives with altered specificities.

Native chemical ligation of polypeptides.

The total synthesis and semisynthesis of proteins allows the site-specific incorporation of unnatural amino acids, post-translational modifications, and biophysical/biochemical probes into the target molecule. Among the various chemical and enzymatic approaches available for the synthesis/semisynthesis of proteins, the native chemical ligation technique has proven especially useful and is the exclusive focus of this unit. This unit first discusses how to choose the ligation site(s) in the target protein and then outlines how to obtain the necessary polypeptide building blocks using either chemical synthesis or recombinant DNA expression. Next, the synthesis of a protein by native chemical ligation of two polypeptide fragments is described. The synthesis of a protein from three polypeptide fragments using a sequential native chemical ligation strategy is also described. Support protocols describe how to obtain the necessary polypeptide fragments using either chemical synthesis or recombinant DNA expression.

Native-like cyclic peptide models of a viral antigenic site: finding a balance between rigidity and flexibility.

Antigenic site A of foot-and-mouth disease virus (serotype C) has been reproduced by means of cyclic versions of peptide A15, YTASARGDLAHLTTT, corresponding to residues 136-150 of envelope protein VP1. A structural basis for the design of the cyclic peptides is provided by crystallographic data from complexes between the Fab fragments of anti-site A monoclonal antibodies and A15, in which the bound peptide is folded into a quasi-cyclic pattern. Head-to-tail cyclizations of A15 do not provide peptides of superior antigenicity. Internal disulfide cyclization, however, leads to analogs which are recognized as one to two orders of magnitude better than linear A15 in both ELISA and biosensor experiments. CD and NMR studies show that the best antigen, CTASARGDLAHLTT-Ahx-C (disulfide), is very insensitive to environment-induced conformational change, suggesting that cyclization helps to stabilize a bioactive-like structure.

Introduction of unnatural amino acids into proteins using expressed protein ligation.

Here we describe the results of studies designed to explore the scope and limitations of expressed protein ligation (EPL), a protein semisynthesis approach that allows unnatural amino acids to be site specifically introduced into large proteins. Using Src homology 3 domains from the proteins c-Abl and c-Crk as model systems, we show here that EPL can be performed in the presence of moderate concentrations of the chemical denaturant, guanidine hydrochloride, and the organic solvent dimethylsulfoxide. Use of these solubilizing agents allowed the successful preparation of two semisynthetic proteins, 10 and 12, both of which could not be prepared using standard procedures due to the low solubility of the synthetic peptide reactants in aqueous buffers. We also report the results of thiolysis and kinetic studies which indicate that stable alkyl thioester derivatives of recombinant proteins can be generated for storage and purification purposes, and that 2-mercaptoethanesulfonic acid compares favorably with thiophenol as the thiol cofactor for EPL reactions, while having superior handling properties. Finally, we describe the semisynthesis of the fluorescein/rhodamine-containing construct (12) and the ketone-containing construct (14). The efficiency of these two syntheses indicates that EPL offers a facile way of incorporating these important types of biophysical and biochemical probes into proteins.

Studying receptor-ligand interactions using encoded amino acid scanning.

A novel technique is described that allows the synthesis, functional analysis, and quantitative readout of defined arrays of polypeptide analogues in aqueous solution. Key to this approach is the use of a simple encoding-decoding system in which a unique Fmoc-amino acid tag is covalently attached to the C terminus of each member of a molecular array through a selectively cleavable bond. These tags can be cleanly removed from the molecules they encode, allowing single-step characterization and quantification of the entire mixture by HPLC. The utility of this technique is illustrated through the preparation of an array of proline-rich sequences based on the exchange factor C3G, one of the natural ligands of the N-terminal SH3 domain from the proto-oncogene, c-Crk. The array was designed to systematically modify those residues within the C3G peptide ligand thought to make key interactions with the c-Crk SH3 domain. Using competition binding experiments, it was possible to determine the relative ED50 values for the entire array of molecules simultaneously. These studies revealed that in order to maintain optimal binding to the SH3 domain, the P-3 side chain of the ligand must be positively charged and the P-0 side chain must be hydrophobic and extend beyond the gamma-carbon. The excellent correlation between these relative ED50 values and a series of relative Kd values determined from individual peptides suggests that this approach may be useful in determining, in a parallel fashion, the relative biological activities of arrays of polypeptides.

Chemical ligation of unprotected peptides directly from a solid support.

In this article we describe a new, convenient procedure to carry out intramolecular (cyclization) and intermolecular native chemical ligations of unprotected peptides directly from a solid support. Our solid-phase ligation approach eliminates the need to manipulate peptide (alpha)thioacid and peptide (alpha)thioester intermediates in aqueous solution before the ligation step, thereby leading to a reduction in handling losses and significantly increasing the overall efficiency of the chemical ligation strategy. A key step in our ligation scheme is the ability to generate fully unprotected peptides tethered to a solid support through an (alpha)thioester linkage. This can be achieved efficiently using optimized Boc-solid-phase peptide synthesis on a 3-mercaptopropionamide-polyethylene glycol-poly-(N,N-dimethylacrylamide) copolymer support (HS-PEGA). Once the synthesis is complete, the fully protected peptide (alpha)thioester resin is treated with HF to give the corresponding fully unprotected peptide (alpha)thioester resin. Using this procedure several polypeptides ranging from 15 to 47 residues were synthesized successfully. These peptide-resins were then used to perform both intramolecular (head-to-tail cyclizations) and intermolecular solid-phase ligations. The intramolecular solid-phase ligations proceeded much faster than their intermolecular counterparts, but in both cases the reactions were observed to be remarkably clean. The presence of aromatic thiol cofactors significantly accelerated the relatively slow intermolecular ligations. This novel methodology was then extended to provide a general method for performing sequential intermolecular ligations, allowing easy access to much larger polypeptide and protein systems.

A cyclic disulfide peptide reproduces in solution the main structural features of a native antigenic site of foot-and-mouth disease virus.

A cyclic disulfide peptide corresponding to the G-H loop sequence 134-155 [replacement Tyr136 and Arg153 with Cys] of the capsid protein VP1 of foot-and-mouth disease virus (FMDV) isolate C-S8c1 was examined by proton 2D-NMR spectroscopy in water and in 25% HFIP/water. In water, NMR data supported the presence of a non-canonical turn in the central, conserved cell adhesion RGD motif and suggested the presence of a nascent helix in the C-terminal part, stabilized and slightly extended upon addition of 25% HFIP, a secondary structure stabilizing cosolvent. The formation of the C-terminal helix was evidenced by combined analysis of NOE connectivities, H alpha chemical shifts, 3JNH-H alpha coupling constants and amide temperature coefficients. Surprisingly, these global structural features of the cyclic peptide in solution show similarities to previous X-ray structure analysis of (a) a shortened linear peptide complexed with a antivirus antibody and (b) the G-H loop represented on the chemical reduced viral surface of a different serotype. Thus, even in entirely different biological environments the cyclic peptide reflect similar structural features, reinforcing the concept that this viral loop behaves as an independent structural and functional unit.

A large-scale evaluation of peptide vaccines against foot-and-mouth disease: lack of solid protection in cattle and isolation of escape mutants.

A large-scale vaccination experiment involving a total of 138 cattle was carried out to evaluate the potential of synthetic peptides as vaccines against foot-and-mouth disease. Four types of peptides representing sequences of foot-and-mouth disease virus (FMDV) C3 Argentina 85 were tested: A, which includes the G-H loop of capsid protein VP1 (site A); AT, in which a T-cell epitope has been added to site A; AC, composed of site A and the carboxy-terminal region of VP1 (site C); and ACT, in which the three previous capsid motifs are colinearly represented. Induction of neutralizing antibodies, lymphoproliferation in response to viral antigens, and protection against challenge with homologous infectious virus were examined. None of the tested peptides, at several doses and vaccination schedules, afforded protection above 40%. Protection showed limited correlation with serum neutralization activity and lymphoproliferation in response to whole virus. In 12 of 29 lesions from vaccinated cattle that were challenged with homologous virus, mutant FMDVs with amino acid substitutions at antigenic site A were identified. This finding suggests the rapid generation and selection of FMDV antigenic variants in vivo. In contrast with previous studies, this large-scale vaccination experiment with an important FMDV host reveals considerable difficulties for vaccines based on synthetic peptides to achieve the required levels of efficacy. Possible modifications of the vaccine formulations to increase protective activity are discussed.

Solution versus solid-phase cyclization strategies for large sidechain lactam-bridged peptides: a comparative study.

A 22-residue peptide with a sidechain lactam bridge involving 18 residues (60-atom cycle) has been synthesized. Three different protection schemes using Fmoc/tBu/cyclohexyl, Fmoc/tBu/allyl or Boc/Bzl/ fluorenylmethyl protecting group combinations have been explored for the solid phase of the linear precursors, which have been subsequently cyclized in solution or in the solid phase. Cyclization yields in solution have been consistently better than on solid phase; however, the solid-phase strategy requires fewer purification steps and therefore global yields are comparable.

Cyclic peptides as conformationally restricted models of viral antigens: application to foot-and-mouth disease virus.

Conformationally restricted cyclic peptide mimics of the antigenic site A of foot-and-mouth disease virus serotype C-S8c1 have been designed, first by comparison to the three-dimensional structure of the O1BFS serotype, later more accurately on the basis of X-ray diffraction data from a complex between a linear peptide reproducing site A and an FMDV-derived monoclonal antibody Fab fragment. A variety of cyclization strategies have been attempted, both in solution and in the solid phase, involving disulfide, side chain lactam and head-to-tail arrangements. Preliminary immunological results have shown one of the cyclic disulfide mimics to be a better immunogen than its linear counterpart.

Direct evaluation of the immunodominance of a major antigenic site of foot-and-mouth disease virus in a natural host.

The immunodominance of a major antigenic site of foot-to-mouth disease virus (FMDV) (serotype C; clone C-S8c1) in a natural host has been evaluated by serum immunoglobulin fractionation. Nineteen sera from either convalescent or vaccinated swine were fractionated by affinity chromatography using a synthetic peptide representing antigenic site A (the G-H loop of capsid protein VP1) coupled to a Sepharose matrix. Antigen-binding and neutralizing activities of serum fractions were quantitated. On average, about 57 or 27% of the virus-neutralizing activity (and about 35 or 12% of the virus-binding activity) from convalescent or vaccinated swine, respectively, corresponded to antibodies against site A. The results provide direct evidence of the important contribution of site A, and also of additional sites unrelated to site A, in the evoking of neutralizing antibodies by FMDV in a natural host. The proportion of antibodies directed to site A varied greatly among individual swine. Some animals evoked remarkably low levels of antibodies specific for site A although they were competent to raise antibodies against other antigenic sites of FMDV. Thus, the major antigenic site of FMDV shows heterogeneous dominance in a natural host. Possible implications for evolution of viral quasispecies are discussed.

A highly divergent antigenic site of foot-and-mouth disease virus retains its immunodominance.

The ability of a highly divergent antigenic site of foot-and-mouth disease virus (FMDV) of serotype C to elicit neutralizing antibodies has been evaluated in mice and rabbits. The viruses compared, FMDV C-S8c1 and HR, differ in a single amino acid replacement in their capsid proteins, but represent two extreme antigenic specificities of the major antigenic site A of FMDV type C. Both, studies of cross-neutralization of homologous and heterologous virus, and fractionation of site A-specific antibodies by immunoaffinity chromatography suggest a similar immunodominance of antigenic site A in FMDV C-S8c1 and variant HR. This information is relevant to the formulation of synthetic peptide vaccines that ideally should consist of mixtures of peptides representing several antigenic specificities. These cocktail formulations may be required to control diseases caused by FMDV and, generally, by highly variable RNA viruses, since single specificity peptides may trigger selection of vaccine-escape viral mutants.

Cyclic disulfide model of the major antigenic site of serotype-C foot-and-mouth disease virus. Synthetic, conformational and immunochemical studies.

A cyclic disulfide peptide representing antigenic site A of foot-and-mouth disease virus (FMDV) strain C-S8c1 (residues 134 to 155 of viral protein 1 (VP1) with Tyr136 and Arg153 replaced by cystine; TTCTASARGDLAHLTTTHACHL) was synthesized by solid phase methods. Formation of the cyclic disulfide was carried out by air oxidation of the fully deprotected and reduced bis-cysteine precursor, under high dilution conditions. The identity of the cyclic peptide was confirmed by both physical and enzymatic methods. A conformational study of the cyclic peptide and of its linear parent structure (YTASARGDLAHLTTTHARHLP, residues 136-156 of VP1 of FMDV C-S8c1) by circular dichroism in the presence of a structure-inducing solvent showed the cyclic disulfide analog to adopt lower levels of alpha-helix than its linear counterpart. In competitive ELISA assays both peptides reacted with similar affinity against a representative panel of neutralizing monoclonal antibodies directed towards antigenic site A. Thus, a high inherent flexibility of this loop may preclude a conformational restriction strong enough to alter recognition by anti-virus antibodies.

Non-additive effects of multiple amino acid substitutions on antigen-antibody recognition.

Synthetic peptides have been used to mimic the main antigenic site of foot-and-mouth disease virus (FMDV) of serotype C and of several variant isolates. This region includes multiple continuous B cell epitopes. The effect of single amino acid replacements, individually or in combination, on antigen specificity has been evaluated using monoclonal antibodies. Quantitative enzyme immunodot assays have shown that both additive and non-additive effects of multiple replacements occur in continuous B cell epitopes, with regard to antibody recognition. Antigenically critical single replacements may be compensated by other, non-critical replacements. Thus, the role of a single amino acid on antibody recognition depends on the sequence context in the antigenic domain. The non-additive effects of multiple replacements may modulate the extent of antigenic diversification of highly variable RNA viruses, and keep viruses confined within antigenic groups by precluding linear antigenic divergence.