Protein splicing is a posttranslational modification in which an intein domain excises itself out of a host protein. Here, we investigate how the steps in the splicing process are coordinated so as to maximize the production of the final splice products and minimize the generation of undesired cleavage products. Our approach has been to prepare a branched intermediate (and analogs thereof) of the Mxe GyrA intein using protein semi-synthesis. Kinetic analysis of these molecules indicates that the high fidelity of this protein splicing reaction results from the penultimate step in the process (intein-succinimide formation) being rate-limiting. NMR experiments indicate that formation of the branched intermediate affects the local structure around the amide bond cleaved during succinimide formation. We propose that this structural change reflects a re-organization of the catalytic apparatus to accelerate succinimide formation at the C-terminal splice junction.
The unfolding and folding of protein barnase has been extensively investigated in bulk conditions under the effect of denaturant and temperature. These experiments provided information about structural and kinetic features of both the native and the unfolded states of the protein, and debates about the possible existence of an intermediate state in the folding pathway have arisen. Here, we investigate the folding/unfolding reaction of protein barnase under the action of mechanical force at the single-molecule level using optical tweezers. We measure unfolding and folding force-dependent kinetic rates from pulling and passive experiments, respectively, and using Kramers-based theories (e.g., Bell-Evans and Dudko-Hummer-Szabo models), we extract the position of the transition state and the height of the kinetic barrier mediating unfolding and folding transitions, finding good agreement with previous bulk measurements. Measurements of the force-dependent kinetic barrier using the continuous effective barrier analysis show that protein barnase verifies the Leffler-Hammond postulate under applied force and allow us to extract its free energy of folding, ΔG0. The estimated value of ΔG0 is in agreement with our predictions obtained using fluctuation relations and previous bulk studies. To address the possible existence of an intermediate state on the folding pathway, we measure the power spectrum of force fluctuations at high temporal resolution (50 kHz) when the protein is either folded or unfolded and, additionally, we study the folding transition-path time at different forces. The finite bandwidth of our experimental setup sets the lifetime of potential intermediate states upon barnase folding/unfolding in the submillisecond timescale.
DNA bis-intercalators are widely used in molecular biology with applications ranging from DNA imaging to anticancer pharmacology. Two fundamental aspects of these ligands are the lifetime of the bis-intercalated complexes and their sequence selectivity. Here, we perform single-molecule optical tweezers experiments with the peptide Thiocoraline showing, for the first time, that bis-intercalation is driven by a very slow off-rate that steeply decreases with applied force. This feature reveals the existence of a long-lived (minutes) mono-intercalated intermediate that contributes to the extremely long lifetime of the complex (hours). We further exploit this particularly slow kinetics to determine the thermodynamics of binding and persistence length of bis-intercalated DNA for a given fraction of bound ligand, a measurement inaccessible in previous studies of faster intercalating agents. We also develop a novel single-molecule footprinting technique based on DNA unzipping and determine the preferred binding sites of Thiocoraline with one base-pair resolution. This fast and radiolabelling-free footprinting technique provides direct access to the binding sites of small ligands to nucleic acids without the need of cleavage agents. Overall, our results provide new insights into the binding pathway of bis-intercalators and the reported selectivity might be of relevance for this and other anticancer drugs interfering with DNA replication and transcription in carcinogenic cell lines.
Cell-cell interactions drive essential biological processes critical to cell and tissue development, function, pathology, and disease outcome. The growing appreciation of immune cell interactions within disease environments has led to significant efforts to develop protein-and cell-based therapeutic strategies. A better understanding of these cell-cell interactions will enable the development of effective immunotherapies. However, characterizing these complex cellular interactions at molecular resolution in their native biological contexts remains challenging. To address this, we introduce photocatalytic cell tagging (PhoTag), a modality agnostic platform for profiling cell-cell interactions. Using photoactivatable flavin-based cofactors, we generate phenoxy radical tags for targeted labeling at the cell surface. Through various targeting modalities (e.g. MHC-Multimer, antibody, single domain antibody (VHH)) we deliver a flavin photocatalyst for cell tagging within monoculture, co-culture, and peripheral blood mononuclear cells. PhoTag enables highly selective tagging of the immune synapse between an immune cell and an antigen-presenting cell through targeted labeling at the cell-cell junction. This allowed for the ability to profile gene expression-level differences between interacting and bystander cell populations. Given the modality agnostic and spatio-temporal nature of PhoTag, we envision its broad utilization to detect and profile intercellular interactions within an immune synapse and other confined cellular regions for any biological system..
Prolyl oligopeptidase is a cytosolic serine peptidase that hydrolyzes proline-containing peptides at the carboxy termini of the proline residues. This peptidase has been associated with schizophrenia, bipolar affective disorder, and related neuropsychiatric disorders and might therefore have important clinical implications. Traditional Chinese medicinal (TCM) plants provide a rich source of unexplored compounds for strategies to find novel POP inhibitors, but the traditional methodologies used to identify POP inhibitors could have some limitations when working with natural products: interference with the colorimetric or fluorimetric detection methods commonly used to screen for POP inhibitors can result in the generation of false positives or false negatives. Since NMR screening is less prone to such interference, we decided to explore the use of 19F NMR to screen for POP inhibitors. We synthesized a new 19F-labeled POP substrate--Z-Gly-Pro-Phe-4(CF3)-NH2--and used it to search for new POP inhibitors in TCM plant extracts. We identified several plants with high POP-inhibitory activity and show here that the combination of 19F NMR and TCM plant extracts is a useful tool for identifying new POP inhibitors.
Knowledge of the mechanisms of interaction between self-aggregating peptides and nucleic acids or other polyanions is key to the understanding of many aggregation processes underlying several human diseases (e.g. Alzheimer's and Parkinson's diseases). Determining the affinity and kinetic steps of such interactions is challenging due to the competition between hydrophobic self-aggregating forces and electrostatic binding forces. Kahalalide F (KF) is an anticancer hydrophobic peptide which contains a single positive charge that confers strong aggregative properties with polyanions. This makes KF an ideal model to elucidate the mechanisms by which self-aggregation competes with binding to a strongly charged polyelectrolyte such as DNA. We use optical tweezers to apply mechanical forces to single DNA molecules and show that KF and DNA interact in a two-step kinetic process promoted by the electrostatic binding of DNA to the aggregate surface followed by the stabilization of the complex due to hydrophobic interactions. From the measured pulling curves we determine the spectrum of binding affinities, kinetic barriers and lengths of DNA segments sequestered within the KF-DNA complex. We find there is a capture distance beyond which the complex collapses into compact aggregates stabilized by strong hydrophobic forces, and discuss how the bending rigidity of the nucleic acid affects such process. We hypothesize that within an in vivo context, the enhanced electrostatic interaction of KF due to its aggregation might mediate the binding to other polyanions. The proposed methodology should be useful to quantitatively characterize other compounds or proteins in which the formation of aggregates is relevant.
Inteins are autoprocessing domains that cut themselves out of host proteins in a traceless manner. This process, known as protein splicing, involves multiple chemical steps that must be coordinated to ensure fidelity in the process. The committed step in splicing involves attack of a conserved Asn side-chain amide on the adjacent backbone amide, leading to an intein-succinimide product and scission of that peptide bond. This cleavage reaction is stimulated by formation of a branched intermediate in the splicing process. The mechanism by which the Asn side-chain becomes activated as a nucleophile is not understood. Here we solve the crystal structure of an intein trapped in the branched intermediate step in protein splicing. Guided by this structure, we use proteinengineering approaches to show that intein-succinimide formation is critically dependent on a backbone-to-side-chain hydrogenbond. We propose that this interaction serves to both position the side-chain amide for attack and to activate its nitrogen as a nucleophile. Collectively, these data provide an unprecedented view of an intein poised to carry out the rate-limiting step in protein splicing, shedding light on how a nominally nonnucleophilic group, a primary amide, can become activated in a protein active site.expressed | protein semisynthesis P rotein splicing is a posttranslational modification in which an internal domain, termed an intein, excises itself from a host protein with concomitant ligation of the flanking sequences (termed the N-and C-exteins) (1, 2). Inteins are found in unicellular organisms from all domains of life (3) and belong to the HINT (Hedgehog INTein) superfamily of autoprocessing domains (4), which includes the cholesterol ligase domain found in the eponymous hedgehog family of developmental proteins present in all bilaterian animals (5, 6). High-resolution structures of inteins reveal a characteristic horseshoe-like β-sheet fold (7), common to all HINT family members (8), which positions catalytic residues from four conserved sequence blocks (A, B, F, G) in proximity to N-and C-terminal splice junctions (Fig. 1A). This structural information has aided mechanistic studies into the protein splicing process, which we know to be a multistep cascade involving a series of acyl-transfer reactions (Fig. 1B) (1, 2). Although a biological role for protein splicing remains elusive, an ever-deepening understanding of the splicing mechanism has led to the development of a wide range of biotechnology and chemical biology approaches based on engineered inteins (9).The most intriguing chemical step in protein splicing is inteinsuccinimide formation. This acts as the rate-limiting step in the process and leads to the resolution of the so-called branched (thio) ester intermediate species (Fig. 1B, step 3). This step involves nucleophilic attack of the side-chain primary amide group of a conserved Asn residue (the block G Asn) on the adjacent peptide bond (+1 scissile amide), leading to cleavage of the intein from the Cextein. This is an extre...
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