The energetic contributions of hydrogen bonding to protein folding are still unclear, despite over 70 years of study. This is due partly to the difficulty of extracting thermodynamic information about specific interactions from protein mutagenesis data, and partly to the context dependence of hydrogen bond strengths. Herein, we test the hypothesis that hydrogen bond strengths depend on the polarity of their microenvironment, with stronger hydrogen bonds forming in non-polar surroundings. Double mutant thermodynamic cycle analysis using a combination of amide-to-ester backbone mutagenesis and traditional side chain mutagenesis revealed that hydrogen bonds can be stronger by up to 1.2 kcal mol−1 when they are sequestered in hydrophobic surroundings than when they are solvent exposed. Such large coupling energies between hydrogen bond strengths and local polarity suggest that the context dependence of hydrogen bond strengths must be accounted for in any comprehensive account of the forces responsible for protein folding.
We describe a new molecular class of genetic-pairing system that has a native DNA backbone but has all four base pairs replaced by new, larger pairs. The base pairs include size-expanded analogs of thymine and of adenine, both extended by the width of a benzene ring (2.4 A). The expanded-diameter double helices are more thermodynamically stable than the Watson-Crick helix, likely because of enhanced base stacking. Structural data confirm a right-handed, double-stranded, and base-paired helical form. Because of the larger base size, all the pairs of this helical system are fluorescent, which suggests practical applications in detection of natural DNA and RNA. Our findings establish that there is no apparent structural or thermodynamic prohibition against genetic systems having sizes different from the natural one.
Phosphorylation and dephosphorylation of the C-terminal domain (CTD) of RNA polymerase II (Pol II) represent a critical regulatory checkpoint for transcription. Transcription initiation requires Fcp1/Scp1-mediated dephosphorylation of phospho-CTD. Fcp1 and Scp1 belong to a family of Mg2+ -dependent phosphoserine (P.Ser)/phosphothreonine (P.Thr)-specific phosphatases. We recently showed that Scp1 is an evolutionarily conserved regulator of neuronal gene silencing. Here, we present the X-ray crystal structures of a dominant-negative form of human Scp1 (D96N mutant) bound to mono- and diphosphorylated peptides encompassing the CTD heptad repeat (Y1S2P3T4S5P6S7). Moreover, kinetic and thermodynamic analyses of Scp1-phospho-CTD peptide complexes support the structures determined. This combined structure-function analysis discloses the residues in Scp1 involved in CTD binding and its preferential dephosphorylation of P.Ser5 of the CTD heptad repeat. Moreover, these results provide a template for the design of specific inhibitors of Scp1 for the study of neuronal stem cell development.
We describe the design, preparation, and properties of two key building blocks of a size-expanded genetic system. Nucleoside analogues of the natural nucleosides dA and dT are reported in which the fusion of a benzo ring increases their size by ca. 2.4 A. The expanded dA analogue (dxA), having a tricyclic base, was first reported by Leonard nearly three decades ago. We describe a shortened and more efficient approach to this compound. The expanded dT analogue (dxT), a methylquinazolinedione C-glycoside, was previously unknown; we describe its preparation in eight steps from 5-methylanthranilic acid. The key glycoside bond formation employed Pd-mediated coupling of an aryl iodide precursor with a dihydrofuran derivative of deoxyribose. Both nucleosides are shown to be efficient fluorophores, emitting light in the blue-violet range. The base-protected phosphoramidite derivatives were prepared, and short oligonucleotides containing them were characterized. The two size-expanded nucleosides are key components of a new four-base genetic system designed to form helical paired structures having a diameter greater than that of natural DNA. Elements of the design of this expanded genetic molecule, termed xDNA, are discussed, including the possibility of up to eight base pairs of information storage capability.
We describe physicochemical properties in DNA of altered-size nucleobases that retain Watson-Crick analogous hydrogen-bonding ability. Size-expanded analogues of adenine and thymine (xA and xT, respectively, which are expanded by benzo-fusion) were incorporated into natural DNA oligonucleotides, and their effects on helix stability were measured. Base stacking studies revealed that the two stretched analogues stack much more strongly than do their naturally sized counterparts. In contrast to this, pairing studies showed that single substitutions of the new bases are destabilizing to the natural helix as compared to A or T in standard A-T pairs in the same context, unless multiple adjacent substitutions are used. Interestingly, the size-expanded bases displayed selective recognition of the hydrogen-bonding complementary partners, suggesting that Watson-Crick analogous pairs were still formed despite local backbone strain. In an attempt to compensate for the added size of the expanded adenine, we tested a formamide deoxynucleoside, which Leonard proposed as a shortened thymine analogue (F(o)). Data showed, however, that this compound adopts a conformation unfavorable for pairing. On the basis of the combined thermodynamic data, we estimate the energetic cost of the 2.4 A stretching of an isolated base pair in DNA at ca. +1 to 2 kcal/mol. Notably, during the pairing studies, the two size-expanded nucleobases were found to display significant changes in fluorescence on formation of stacked versus unstacked structures, suggesting possible applications in probing nucleic acid structures and biochemical mechanisms.
As a rich source of therapeutic agents, peptide natural products usually adopt a cyclic or multicyclic scaffold that minimizes structural flexibility to favor target binding. Inspired by nature, chemists have been interested in developing synthetic cyclic and multicyclic peptides that serve as biological probes and potential therapeutics. Herein we describe a novel strategy for peptide cyclization, in which intramolecular iminoboronate formation allows spontaneous cyclization under physiologic conditions to yield monocyclic and bicyclic peptides. Importantly the iminoboronate-based cyclization can be rapidly reversed in response to multiple stimuli, including pH, oxidation and small molecules. This highly versatile strategy for peptide cyclization should find applications in many areas of chemical biology.
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