Design of Functional Globular β‐Sheet Miniproteins

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Design of Functional Globular β-Sheet Miniproteins

Not just the beta versions. Miniprotein design has long been dominated by the well-understood α-helical coiled coil scaffolds. With increasing understanding, globular β-sheet scaffolds, which are generally considered to be prone to aggregation, are also becoming accessible. We review the design of β-hairpins and WW domains and discuss strategies for engineering these scaffolds into receptors, molecular switches and catalysts.


Abstract

The design of discrete β-sheet peptides is far less advanced than e. g. the design of α-helical peptides. The reputation of β-sheet peptides as being poorly soluble and aggregation-prone often hinders active design efforts. Here, we show that this reputation is unfounded. We demonstrate this by looking at the β-hairpin and WW domain. Their structure and folding have been extensively studied and they have long served as model systems to investigate protein folding and folding kinetics. The resulting fundamental understanding has led to the development of hyperstable β-sheet scaffolds that fold at temperatures of 100 °C or high concentrations of denaturants. These have been used to design functional miniproteins with protein or nucleic acid binding properties, in some cases with such success that medical applications are conceivable. The β-sheet scaffolds are not always completely rigid, but can be specifically designed to respond to changes in pH, redox potential or presence of metal ions. Some engineered β-sheet peptides also exhibit catalytic properties, although not comparable to those of natural proteins. Previous reviews have focused on the design of stably folded and non-aggregating β-sheet sequences. In our review, we now also address design strategies to obtain functional miniproteins from β-sheet folding motifs.

The Impact of Activating Agents on Non‐Enzymatic Nucleic Acid Extension Reactions

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The Impact of Activating Agents on Non-Enzymatic Nucleic Acid Extension Reactions

Non-enzymatic template-directed primer extension of RNA and DNA reveals an intrinsic battle between fidelity and rate. This review highlights pathways towards the optimization of these reactions to enable rapid, sequence-specific and scalable RNA and DNA synthesis.


Abstract

Non-enzymatic template-directed primer extension is increasingly being studied for the production of RNA and DNA. These reactions benefit from producing RNA or DNA in an aqueous, protecting group free system, without the need for expensive enzymes. However, these primer extension reactions suffer from a lack of fidelity, low reaction rates, low overall yields, and short primer extension lengths. This review outlines a detailed mechanistic pathway for non-enzymatic template-directed primer extension and presents a review of the thermodynamic driving forces involved in entropic templating. Through the lens of entropic templating, the rate and fidelity of a reaction are shown to be intrinsically linked to the reactivity of the activating agent used. Thus, a strategy is discussed for the optimization of non-enzymatic template-directed primer extension, providing a path towards cost-effective in vitro synthesis of RNA and DNA.

Immobilizing Triphenylamine with Photoredox Inert Sr2+ Forming Sr‐MOF with Controlled Electron Migration for Photocatalytic Oxidation of Thiols to Disulfides

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Immobilizing Triphenylamine with Photoredox Inert Sr2+ Forming Sr-MOF with Controlled Electron Migration for Photocatalytic Oxidation of Thiols to Disulfides

The immobilization of triphenylamine into MOF with photoredox inert Sr nodes can successfully control the photo-generated electrons transfer from the excited triphenylamine to O2 and realize the heterogeneous catalytic oxidation of thiols to disulfides.


Comprehensive Summary

The photocatalytic oxidative coupling of thiols is one of the most popular methods to synthesize the disulfides. Triphenylamine and its derivatives (TPAs) are promising for the above reaction, but suffer from the easy polymerization and difficult separation. To overcome these obstacles while controlling the photogenerated electrons transfer directly to target substrates, herein, we constructed one TPA-based metal-organic framework (MOF), (Me2NH2)[Sr(TCBPA)]·DMA·3H2O (1), by direct self-assembly of tris(4′-carboxybiphenyl)amine (H3TCBPA) and photoredox inert strontium ion (Sr2+). DFT calculations revealed that the valence band maximum (VBM) and the conduction band minimum (CBM) are mainly located on TCBPA3–, successfully inhibiting the undesirable electron migration to metal nodes. Experimental results indicated that 1 displays superior performance than homogeneous H3TCBPA, which may result from the abundant π···π and C—H···π interactions between the well-arranged TCBPA3– and the build-in electric field between the anionic framework and the Me2NH2 +. This work highlights that immobilizing TPAs into MOFs is one promising approach to designing heterogeneous photocatalysts for the synthesis of disulfides by oxidative coupling of thiols.

Synthesis of Diverse Oxetane Amino Acids via Visible‐Light‐Induced Photocatalytic Decarboxylative Giese‐Type Reaction

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Synthesis of Diverse Oxetane Amino Acids via Visible-Light-Induced Photocatalytic Decarboxylative Giese-Type Reaction

The divergent synthesis of versatile 3,3’-disubstituted oxetane amino acids by utilizing visible-light-induced photocatalytic decarboxylative Giese-type reaction has been demonstrated.


Comprehensive Summary

The divergent synthesis of versatile 3,3′-disubstituted oxetane amino acids by utilizing visible-light-induced photocatalytic decarboxylative Giese-type reaction has been demonstrated. 3-Methyleneoxetane-derived substrates are readily available in a single-step and highly reactive as radical acceptors, allowing the production of versatile oxetane γ- and α-amino acids in high yields. A distinct ring strain release-driven radical addition mechanism was preliminarily revealed. The preparative power was further highlighted by the application in the synthesis of oxetane-containing dipeptides and azetidine amino acids, as well as the transformation of the product into novel oxetane-containing spiro-heterocycle pharmacophore.

Nickel/α‐diimine catalysts in C (sp2)–C (sp2) homocoupling: An underestimated and versatile ligand family

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Nickel/α-diimine catalysts in C (sp2)–C (sp2) homocoupling: An underestimated and versatile ligand family

This paper reports the use of variously substituted easily available α-diimine ligands in Ni-catalyzed reductive homocoupling of aryl halides and demonstrates broad scope of thus prepared biaryls, including practically important cyclization and polycondensation products.


Application of α-diimine ligands in Ni-catalyzed reductive homocoupling of haloarenes is reported. The Ni/α-diimine catalysts are shown to be highly active and allow for preparation of a broad scope of biaryls, including practically important cyclization and polycondensation products. The synthetic availability and versatility of α-diimines allows for easy tuning of their structure aimed at achieving higher yields of each specific homocoupling product.

Improving the proton conductivity of HKUST‐1 by hole expansion and ionic liquid introduction

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Improving the proton conductivity of HKUST-1 by hole expansion and ionic liquid introduction

MIM-CF3SO3@LP-HKUST-1-100%, a conductive material with excellent proton conductivity at both high and low temperature, is proposed for the first time.


As a new type of proton conductor, metal–organic frameworks (MOFs) have attracted much attention because of their superior properties over conventional materials, such as the modifiability of framework, reversibility of coordination bond, high specific surface area, and porosity. It is predicted that the proton conductivities of MOFs can be improved by hole expansion and ionic liquid introduction. In this work, HKUST-1 and LP-HKUST-1 were prepared, which were filled with different proportions of N-methylimidazole triflate (MIM-CF3SO3) to prepare composite materials MIM-CF3SO3@HKUST-1-100% and MIM-CF3SO3@LP-HKUST-1-x (x = 25%, 50%, 75% and 100%). A total of seven kinds of materials were synthesized. The proton conductivities of all the materials at 75% RH were tested from 303 to 353 K. In this environment, MIM-CF3SO3@LP-HKUST-1-100% shows excellent proton conductivity (σ = 0.341 S·cm−1 at 353 K, 75% relatively humidity [RH]), being 7060 times that of HKUST-1, and reaches the peak value of MOF family in recent years. Then, the conductivities of parts of the materials were tested in extreme environments, such as in high-humidity environment (303–353 K, 100% RH), high-temperature environment (373–423 K, N2 atmosphere), and low-temperature environment (253–283 K, 75% RH). The results show that under all conditions above, the proton conductivity of MIM-CF3SO3@LP-HKUST-1-100% is the best, up to 0.341 S·cm−1 at 353 K and 75% RH, 0.179 S·cm−1 at 353 K and 100% RH, 1.31 × 10−3 S·cm−1 at 283 K and 75% RH, and 2.31 × 10−4 S·cm−1 at 423 K and N2 atmosphere, indicating that proton conductivity of HKUST-1 is improved by hole expansion and ionic liquid introduction. Finally, the stability test showed that MIM-CF3SO3@LP-HKUST-1-100% was stable in all environments above. Moreover, the conductive mechanism of HKUST-1 before and after introduction of ionic liquids was also discussed, providing a theoretical basis for the enhancement of proton conductivities of MOFs using ionic liquid introduction and hole expansion.

A Thermoresponsive Lead‐Free Organic‐Inorganic Hybrid Perovskite as a Dielectric Switch

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A Thermoresponsive Lead-Free Organic-Inorganic Hybrid Perovskite as a Dielectric Switch

This manuscript reports two-dimensional lead-free organic-inorganic hybrid perovskite [Cyclobutylammonium]2CuCl4. It demonstrates compelling features, including distinct phase transitions, thermochromic properties, and stable dielectric switching behavior. Its combination of non-toxicity and functional attributes makes it a promising candidate for further exploration and application in the fields of thermoresponsive and dielectric switching materials.


Abstract

Thermochromic perovskites, renowned for their tunable bandgap, high absorption coefficient, and reversible color changes, emerge as promising candidates for applications in smart windows. These advancements not only have the potential to enhance occupant comfort but also contribute significantly to reducing energy consumption in buildings. Here, we present a two-dimensional lead-free organic-inorganic hybrid perovskite [Cyclobutylammonium]2CuCl4 which shows phase transitions from C2/c to P21/c to P21/c space group at 319.5 K and 348.8 K, respectively. Accompanying these transitions is a fascinating, reversible thermochromic behavior that is dependent on the phase structure. This behavior manifests as a vibrant sequence transitioning from yellow to brown and finally to a slightly dark brown. Most importantly, the demonstrated ability to switch stably between high and low dielectric states indicates the enormous potential of this material as a dielectric switch. This non-toxic thermoresponsive perovskite, characterized by its appropriate transition temperatures, reversible phase structure-dependent thermochromism, and stable dielectric switching behavior, is expected to generate significant interest within the fields of thermoresponsive and dielectric switching materials. The integration of these features not only positions this perovskite as a noteworthy subject of scientific inquiry but also opens avenues for practical applications in diverse fields.

Induced Absolute Configuration of Achiral Tetradentate Ligands in Metal–Organic Frameworks for Circularly Polarized Luminescence

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Induced Absolute Configuration of Achiral Tetradentate Ligands in Metal–Organic Frameworks for Circularly Polarized Luminescence

Chiral induction agent can control the formation of the absolute configuration of racemate ligands. Two pairs of homochiral metal-organic frameworks (MOFs) were synthesized with the presence of enantiopure camphoric acid (D/L-cam). Importantly, DCF-17 and LCF-17 exhibit the efficient circularly polarized luminescent (CPL) activity with a luminescence dissymmetry factor (g lum) value of –1.0 × 10–2 and +9.2 ×10–3, respectively.


Comprehensive Summary

The crystallization of chiral molecules is of great significance to understand the origin and evolution of hierarchical chirality and reveal the relationships between structural chirality and circularly polarized luminescence (CPL) activity. Here, we report two pairs of chiral metal–organic frameworks (MOFs) (DCF-17/LCF-17, DCF-18/LCF-18) by utilizing tetradentate ligands tetra(3-imidazoylphenyl)ethylene (TIPE) and 4,4'-[4',5'-bis[4-(4-pyridinyl)phenyl][1,1':2',1”-terphenyl]-4,4”-diyl]bis[pyridine] (TPPP) as linkers. It can be observed that the spontaneous resolution of the achiral ligands is converted into the induced resolution, and the ligands form the absolute configuration by using enantiopure camphoric acid (cam) as chiral induced reagent (CIR). As a result, the racemate MOFs can be driven to generate absolute homochiral crystallization. Another two achiral MOFs [Cd(D-cam)(TPPP)0.5] (AF-1, AF = achiral framework) and [Cd(L-cam)(TPPP)0.5] (AF-2) were prepared. The position disorder of D/L-cam skeleton causes the generation of nonchiralization, further leading to disappearance of symmetry breaking of TPPP. For the perspective of structure, this is the first report which reveals the chiral transfer and nonchiralization between chiral induced agents and tetradentate ligands. Besides, DCF-17 and LCF-17 show CPL with luminescence dissymmetry factor (g lum) of –1.0 × 10-2 and +9.2 × 10–3, respectively. This work provides the useful evidences to reveal the induced chiral crystallization and the construction of CPL-active crystalline materials.