The nature of the first genetic polymer is the subject of major debate in the origin of life field 1 . Although the common 'RNA world' theory suggests RNA as the first replicable information carrier at the dawn of life, other evidence implies that life may have started with a heterogeneous nucleic acid genetic system including both RNA and DNA 2 . Such a theory streamlines the eventual 'genetic takeover' of homogeneous DNA from RNA as the principal information storage molecule in the central dogma, but requires a selective abiotic synthesis of both RNA and DNA building blocks in the same local primordial geochemical scenario. Herein, we demonstrate a high-yielding, completely stereo-, regio-, and furanosyl-selective prebiotic synthesis of the purine deoxyribonucleosides, 2 deoxyadenosine and deoxyinosine. Our synthesis utilizes key intermediates in the prebiotic synthesis of the canonical pyrimidine ribonucleosides, and we show that, once generated, the pyrimidines persist throughout the synthesis of the purine deoxyribonucleosides, ultimately leading to a mixture of deoxyadenosine, deoxyinosine, cytidine, and uridine. These results support the notion that purine deoxyribonucleosides and pyrimidine ribonucleosides may have coexisted before the emergence of life 3 .
Layered hybrid metal-halide perovskites with non-centrosymmetric crystal structure are predicted to show spin-selective band splitting from Rashba effects. Thus, fabrication of metal-halide perovskites with defined crystal symmetry is desired to control the spin-splitting in their electronic states. Here, we report the influence of halogen parasubstituents on the crystal structure of benzylammonium lead iodide perovskites (4-XC 6 H 4 CH 2 NH 3 ) 2 PbI 4 (X = H, F, Cl, Br). Using X-ray diffraction and second-harmonic generation, we study structure and symmetry of single crystal and thin film samples. We report that introduction of a halogen atom lowers the crystal symmetry such that the chlorine-and bromine-substituted structures are non-centrosymmetric. The differences can be attributed to the nature of the intermolecular interactions between the organic molecules. We calculate electronic band structures and find good control of Rashba splittings. Our results present a facile approach to tailor hybrid layered metal halide perovskites with potential for spintronic and non-linear optical applications.
Although a multitude of studies have explored the coordination chemistry of classical tripodal ligands containing a range of main-group bridgehead atoms or groups, it is not clear how periodic trends affect ligand character and reactivity within a single ligand family. A case in point is the extensive family of neutral tris-2-pyridyl ligands E(2-py) (E=C-R, N, P), which are closely related to archetypal tris-pyrazolyl borates. With the 6-methyl substituted ligands E(6-Me-2-py) (E=As, Sb, Bi) in hand, the effects of bridgehead modification alone on descending a single group in the periodic table were assessed. The primary influence on coordination behaviour is the increasing Lewis acidity (electropositivity) of the bridgehead atom as Group 15 is descended, which not only modulates the electron density on the pyridyl donor groups but also introduces the potential for anion selective coordination behaviour.
Protein conjugates are valuable tools for studying biological processes or producing therapeutics, such as antibody− drug conjugates. Despite the development of several protein conjugation strategies in recent years, the ability to modify one specific amino acid residue on a protein in the presence of other reactive side chains remains a challenge. We show that monosubstituted cyclopropenone (CPO) reagents react selectively with the 1,2-aminothiol groups of N-terminal cysteine residues to give a stable 1,4-thiazepan-5-one linkage under mild, biocompatible conditions. The CPO-based reagents, all accessible from a common activated ester CPO-pentafluorophenol (CPO-PFP), allow selective modification of N-terminal cysteine-containing peptides and proteins even in the presence of internal, solvent-exposed cysteine residues. This approach enabled the preparation of a dual protein conjugate of 2×cys-GFP, containing both internal and N-terminal cysteine residues, by first modifying the N-terminal residue with a CPO-based reagent followed by modification of the internal cysteine with a traditional cysteine-modifying reagent. CPO-based reagents enabled a copper-free click reaction between two proteins, producing a dimer of a de novo protein mimic of IL2 that binds to the β-IL2 receptor with low nanomolar affinity. Importantly, the reagents are compatible with the common reducing agent dithiothreitol (DTT), a useful property for working with proteins prone to dimerization. Finally, quantum mechanical calculations uncover the origin of selectivity for CPO-based reagents for N-terminal cysteine residues. The ability to distinguish and specifically target N-terminal cysteine residues on proteins facilitates the construction of elaborate multilabeled bioconjugates with minimal protein engineering.
The binding and sensing of anions is an important cross-disciplinary field, which impacts broad areas such as biology, supramolecular chemistry and catalysis. To date, however, this area has been dominated by organic architectures which function as Hbonding, anion receptor molecules. Inorganic anion receptors have largely been based on Lewis acidic metals, with very few examples of H-bonding counterparts of organic systems having been systematically studied. This paper develops strategies for enhancing the anion binding properties of phosphazanes of the type [(RNH)(E)P(μ-N t Bu)] 2 (E = O, S, Se) which are bench-stable, H-bond receptors that can be regarded as inorganic analogues of squaramides (a key class of organic anion receptor). The distinct advantages of these inorganic receptors over organic counterparts is the ease by which their functionality and electronic character can be altered (by means of the R group, chalcogenide, or metal present). Se substitution at the P centers, the presence of electron-withdrawing R groups, and metal coordination to the soft donor centers can be used to modulate and enhance anion binding. The water stability and superior anion binding properties of the seleno-phosph(V)azanes give them applications as synthetic anion transporters through phospholipid layers.
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