Organophotoredox-catalyzed cyanoalkylation of 1,4-quinones.

A visible-light-induced metal-free cyanoalkylation of 1,4-quinones under mild and redox-neutral conditions is described. This reaction proceeds at room temperature without the need of extra base or additive and is suitable for a variety of 1,4-quinones and differently substituted cyclobutanone oxime esters. Further transformation of cyano functionality to tetrazole and amine has also been demonstrated to showcase the advantage of this method to prepare drug-like molecules.

Probing functional conformation-state fluctuation dynamics in recognition binding between calmodulin and target peptide.

Conformational dynamics play a crucial role in protein functions. A molecular-level understanding of the conformational transition dynamics of proteins is fundamental for studying protein functions. Here, we report a study of real-time conformational dynamic interaction between calcium-activated calmodulin (CaM) and C28W peptide using single-molecule fluorescence resonance energy transfer (FRET) spectroscopy and imaging. Plasma membrane Ca-ATPase protein interacts with CaM by its peptide segment that contains 28 amino acids (C28W). The interaction between CaM and the Ca-ATPase is essential for cell signaling. However, details about its dynamic interaction are still not clear. In our current study, we used Cyanine3 labeled CaM (N-domain) and Dylight 649 labeled C28W peptide (N-domain) to study the conformational dynamics during their interaction. In this study, the FRET can be measured when the CaM-C28W complex is formed and only be observed when such a complex is formed. By using single-molecule FRET efficiency trajectory and unique statistical approaches, we were able to observe multiple binding steps with detailed dynamic features of loosely bound and tightly bound state fluctuations. The C-domain of CaM tends to bind with C28W first with a higher affinity, followed by the binding of the CaM N-domain. Due to the comparatively high flexibility and low affinity of the N-domain and the presence of multiple anchor hydrophobic residues on the peptide, the N-domain binding may switch between selective and non-selective binding states, while the C-domain remains strongly bound with C28W. The results provide a mechanistic understanding of the CaM signaling interaction and activation of the Ca-ATPase through multiple-state binding to the C28W. The new single-molecule spectroscopic analyses demonstrated in this work can be applied for broad studies of protein functional conformation fluctuation and protein-protein interaction dynamics.

Probing Protein-DNA Conformational Dynamics in DNA Damage Recognition: Xeroderma Pigmentosum Group A Stabilizes the Damaged DNA-RPA14 Complex by Controlling Conformational Fluctuation Dynamics.

DNA damage inside biological systems may result in diseases like cancer. One of the major repairing mechanisms is the nucleotide excision repair (NER) that recognizes and repairs the damage caused by several internal and external exposures, such as DNA double-strand distortion due to the chemical modifications. Recognition of lesions is the initial stage of the DNA damage repair, which occurs with the help of several proteins like Replication Protein A (RPA) and Xeroderma Pigmentosum group A (XPA). The recognition process involves complex conformational dynamics of the proteins. Studying the dynamics of damage recognition by these proteins helps us to understand the mechanism and to develop therapeutics to increase the efficiency of recognition. Here, we use single-molecule fluorescence fluctuation measurements of a dye, labeled at a damaged position on DNA, to understand the interaction of the damage site with RPA14 and XPA. Our results suggest that interactive conformational dynamics of RPA14 with damaged DNA is inhomogeneous due to its low affinity for DNA, whereas binding of XPA with the already formed DNA-RPA14 complex may increase the specificity of damage recognition by controlling the conformational fluctuation dynamics of the complex.

Compressive-force induced activation of apo-calmodulin in protein signalling.

Mechanical force plays a critical role in the relationship between protein structure and function. Force manipulation by Atomic Force Microscope can be significant and trigger chemical and biological activities of proteins. Previously we have reported that Apo-CaM undergoes through a spontaneous tertiary structural rupture under a piconewton compressive force. Here we have observed that the ruptured Apo-CaM molecules can be available to bind with C28W peptide, a typical protein signalling activity that only a Ca2+-activated CaM has. This behaviour is both unexpected and profound, as CaM in its Ca2+-non-activated form has a closed structure which does not presumably allow the molecule to bind to target peptides. In this experiment, we demonstrate that both chemical activation and force activation can play a vital role in biology, such as the cell-signalling protein dynamics and function.