Photochemistry Journey to Multielectron and Multiproton Chemical Transformation.

The odyssey of photochemistry is accompanied by the journey to manipulate "electrons" and "protons" in time, in space, and in energy. Over the past decades, single-electron (1e-) photochemical transformations have brought marvelous achievements. However, as each photon absorption typically generates only one exciton pair, it is exponentially challenging to accomplish multielectron and proton photochemical transformations. The multistep differences in thermodynamics and kinetics urgently require us to optimize light harvesting, expedite consecutive electron transfer, manipulate the interaction of catalysts with substrates, and coordinate proton transfer kinetics to furnish selective bond formations. Tandem catalysis enables orchestrating different photochemical events and catalytic transformations from subpicoseconds to seconds, which facilitates multielectron redox chemistries and brings consecutive, value-added reactivities. Joint efforts in molecular and material design, mechanistic understanding, and theoretical modeling will bring multielectron and proton synthetic opportunities for fuels, fertilizers, and chemicals with enhanced versatility, efficiency, selectivity, and scalability, thus taking better advantage of photons (i.e., sunlight) for our sustainable society.

Mechanistic Insights Into Iron(II) Bis(pyridyl)amine-Bipyridine Skeleton for Selective CO2 Photoreduction.

A bis(pyridyl)amine-bipyridine-iron(II) framework (Fe(BPAbipy)) of complexes 1-3 is reported to shed light on the multistep nature of CO2 reduction. Herein, photocatalytic conversion of CO2 to CO even at low CO2 concentration (1 %), together with detailed mechanistic study and DFT calculations, reveal that 1 first undergoes two sequential one-electron transfer affording an intermediate with electron density on both Fe and ligand for CO2 binding over proton. The following 2 H+ -assisted Fe-CO formation is rate-determining for selective CO2 -to-CO reduction. A pendant, proton-shuttling α-OH group (2) initiates PCET for predominant H2 evolution, while an α-OMe group (3) cancels the selectivity control for either CO or H2 . The near-unity selectivity of 1 and 2 enables self-sorting syngas production at flexible CO/H2 ratios. The unprecedented results from one kind of molecular catalyst skeleton encourage insight into the beauty of advanced multi-electron and multi-proton transfer processes for robust CO2 RR by photocatalysis.

Identifying a Real Catalyst of [NiFe]-Hydrogenase Mimic for Exceptional H2 Photogeneration.

Inspired by the natural [NiFe]-H2 ase, we designed mimic 1, (dppe)Ni(µ-pdt)(µ-Cl)Ru(CO)2 Cl to realize effective H2 evolution under photocatalytic conditions. However, a new species 2 was captured in the course of photo-, electro-, and chemo- one-electron reduction. Experimental studies of in situ IR spectroscopy, EPR, NMR, X-ray absorption spectroscopy, and DFT calculations corroborated a dimeric structure of 2 as a closed-shell, symmetric structure with a RuI center. The isolated dimer 2 showed the real catalytic role in photocatalysis with a benchmark turnover frequency (TOF) of 1936 h-1 for H2 evolution, while mimic 1 worked as a pre-catalyst and evolved H2 only after being reduced to 2. The remarkably catalytic activity and unique dimer structure of 2 operated in photocatalysis unveiled a broad research prospect in hydrogenases mimics for advanced H2 evolution.

Tetrahydrofolate Modulates Floral Transition through Epigenetic Silencing.

Folates, termed from tetrahydrofolate (THF) and its derivatives, function as coenzymes in one-carbon transfer reactions and play a central role in synthesis of nucleotides and amino acids. Dysfunction of cellular folate metabolism leads to serious defects in plant development; however, the molecular mechanisms of folate-mediated cellular modifications and physiological responses in plants are still largely unclear. Here, we reported that THF controls flowering time by adjusting DNA methylation-regulated gene expression in Arabidopsis (Arabidopsis thaliana). Wild-type seedlings supplied with THF as well as the high endogenous THF content mutant dihydrofolate synthetase folypoly-Glu synthetase homolog B exhibited significant up-regulation of the flowering repressor of Flowering Wageningen and thereby delaying floral transition in a dose-dependent manner. Genome-wide transcripts and DNA methylation profiling revealed that THF reduces DNA methylation so as to manipulate gene expression activity. Moreover, in accompaniment with elevated cellular ratios between monoglutamylated and polyglutamylated folates under increased THF levels, the content of S-adenosylhomo-Cys, a competitive inhibitor of methyltransferases, was obviously higher, indicating that enhanced THF accumulation may disturb cellular homeostasis of the concerted reactions between folate polyglutamylation and folate-dependent DNA methylation. In addition, we found that the loss-of-function mutant of CG DNA methyltransferase MET1 displayed much less responsiveness to THF-associated flowering time alteration. Taken together, our studies revealed a novel regulatory role of THF on epigenetic silencing, which will shed lights on the understanding of interrelations in folate homeostasis, epigenetic variation, and flowering control in plants.

Double hydrogen bonding-induced compact H-type π-π stacking enhancing rapid carrier transfer in perylene diimide supramolecules achieving high oxygen evolution performance.

Perylene diimides (PDI) are widely used in photocatalytic oxygen evolution due to their deep valence band potentials. Here, we report the synthesis of a unique supramolecular photocatalyst (designated s-PDI-P1) by introducing hydroxyl and carboxyl groups at the imide position of PDI. This modification allows the formation of intermolecular double hydrogen bond structures between the hydroxyl groups, oxygen atoms on the perylene cores and the carboxyl groups. The resulting double hydrogen bonding structures reduce lateral slip and promote the formation of supramolecular structures with H-type π-π stacking. In addition, the intermolecular hydrogen bonding interactions between the hydroxyl groups and the oxygen atoms on the perylene cores bring the PDI molecules closer together, enhancing the conjugation of the PDI supramolecules and facilitating the formation of ultrathin nanosheet-like structures. In this study, we successfully constructed ultrathin nanosheets of the supramolecular photocatalyst s-PDI-P1 with a compact H-type π-π stacking structure, which exhibited enhanced charge transfer capability, shorter charge migration distance, and achieved a high photocatalytic oxygen evolution rate of 3.23 mmolg-1h-1. These results highlight the potential of intermolecular double hydrogen bond structures to improve the separation and migration driving force of photogenerated charges, thus providing a novel design strategy for organic photocatalysts.

Concurrent Ammonia Synthesis and Alcohol Oxidation Boosted by Glutathione-Capped Quantum Dots under Visible Light.

Mother nature accomplishes efficient ammonia synthesis via cascade N2 oxidation by lightning strikes followed with enzyme-catalyzed nitrogen oxyanion (NOx -, x = 2,3) reduction. The protein environment of enzymatic centers for NOx --to-NH4 + process greatly inspires the design of glutathione-capped (GSH) quantum dots (QDs) for ammonia synthesis under visible light (440 nm) in tandem with plasma-enabled N2 oxidation. Mechanistic studies reveal that GSH induces positive shift of surface charge to strengthen the interaction between NOx - and QDs. Upon visible light irradiation of QDs, the balanced and rapid hole and electron transfer furnish GS·radicals for 2e-/2H+ alcohol oxidation and H·for 8e-/10H+ NO3 --to-NH4 + reduction simultaneously. For the first time, mmol-scale ammonia synthesis is realized with apparent quantum yields of 5.45% ± 0.64%, and gram-scale synthesis of value-added acetophenone and NH4Cl proceeds with 1:4 stoichiometry and stability, demonstrating promising multielectron and multiproton ammonia synthesis efficiency and sustainability with nature-inspired artificial photocatalysts.

Generation of induced pluripotent stem cell line (IPTi002-A) from an 87-year old sporadic Alzheimer's disease patient with APOE3 (ε3/ε3) genotype.

Here, we described the generation of human induced pluripotent stem cells (iPSC) from peripheral blood mononuclear cells (PBMCs) of a 87-year-old female patient with sporadic Alzheimer's disease (sAD) having APOE3 (ε3/ε3) genotype. iPSC line were generated from PBMCs with four factors of OCT4, SOX2, c-MYC and KLF4 using episomal system. The pluripotency of the iPSC line was assessed by embryoid body (EB) formation. Flow cytometry analyses revealed >97% cells positive for the pluripotency markers NANOG, OCT4 and SSEA4. Furthermore, the iPSC line displayed a normal karyotype (46, XX). The iPSC line may provide valuable tools for the study of sAD pathogenesis.

Human Induced Pluripotent Stem Cell-Derived Neural Cells from Alzheimer's Disease Patients Exhibited Different Susceptibility to Oxidative Stress.

The cell-type-specific response of neural cells to oxidative stress, a crucial mechanism for accelerating aging and cognitive dysfunction in Alzheimer's disease (AD), is still far from understood. Here, we employed human-induced pluripotent stem cells (hiPSCs)-derived neural stem cells (hiPSC-NSCs), neurons (hiPSC-Neurons), and microglia-like cells (hiPSC-MGLs) from sporadic AD (sAD) patients, age-matched cognitive normal controls (CNCs), and young subjects to observe human neural cell-type response to H2O2 stimulation. Without H2O2 exposure, reactive oxygen species (ROS) cannot be detected in hiPSC-NSCs from all three groups, but the viability of hiPSC-NSCs from AD patients was significantly lower than those of CNCs and young subjects. There were no significant differences in ROS, viabilities, neurite length, and neurite branch points in hiPSC-Neurons among three groups. No significant differences in viabilities, phagocytosis, and secretion of cytokines were observed in hiPSC-MGLs among three groups, but higher ROS levels in sAD hiPSC-MGLs. Under H2O2 exposure, the viability, neurite length, and neurite branch points of hiPSC-Neurons from AD patients reduced more significantly accompanied by more ROS release. H2O2 exposure caused hiPSC-MGLs from AD patients to release more ROS, cytokines, and stronger phagocytosis. Nevertheless, H2O2 exposure had no effect on viability of hiPSC-NSCs. Our results showed hiPSC-Neurons and hiPSC-MGLs were more sensitive to H2O2 than hiPSC-NSCs, which indicated the different response styles of hiPSC-NSCs, hiPSC-Neurons, and hiPSC-MGLs to oxidative stress. HiPSC-derived neural cells from AD patients suffered more severe injury from H2O2 than those of CNCs and young subjects, indicating that the vulnerability to oxidative stress of AD patients can be recapitulated in hiPSCs.

Establishment of two induced pluripotent stem cell line from healthy elderly (IPTi005-A and IPTi007-A).

Two healthy elderly donated their peripheral blood mononuclear cells (PBMCs). The induced pluripotent stem cell lines (IPTi005-A and IPTi007-A) were reprogrammed by episomal vector system with Yamanaka factors OCT4, SOX2, C-MYC and KLF4. Both the two iPSC lines can differentiate into three germ layers determined by embryoid bodies (EBs) differentiation. Flow cytometry analysis showed that more than 90% cells expressed NANOG, OCT4 and SSEA4. Besides, the iPSC lines of IPTi005-A and IPTi007-A were confirmed to exhibit a normal karyotype. In the studies of age-related disease, the iPSC lines can be used as controls.

Generation of induced pluripotent stem cell line (IPTi001-A) from a 62-year old sporadic Alzheimer's disease patient with APOE3 (ε3/ε3) genotype.

A 62-year old sporadic Alzheimer's disease (sAD) male patient with APOE3 (ε3/ε3) genotype donated his peripheral blood mononuclear cells (PBMCs). The induced pluripotent stem cell (iPSC) line was established by episomal vector system with the four factors OCT4, SOX2, C-MYC and KLF4. EB differentiation in vitro showed that iPSC line had a potential to differentiate into three germ layers. More than 90% cells expressed NANOG, OCT4 and SSEA4 detected by flow cytometry. In addition, the iPSC line was karyotypically normal. The iPSC line may provide new valuable tools for studying pathogenesis of sAD and screening candidate drugs for the disease.

Establishment of TUSMi003-A, an induced pluripotent stem cell (iPSC) line from a 62-year old Chinese Han patient with Alzheimer's disease with ApoE3/4 genetic background.

A 62-year old Chinese Han Alzheimer's disease (AD) female patient with ApoE3/4 genetic background donated her Peripheral blood mononuclear cells (PBMC). The non-integrating episomal vector system was used to reprogrammed PBMCs with the human OKSM transcription factors. The pluripotency of transgene-free iPSCs was confirmed by immunocytochemistry for pluripotency markers and by the ability of the iPSCs to differentiate spontaneously into 3 germ layers in vitro. In addition, the iPSC line displayed a normal karyotype. Our model might offer a good platform to further study the pathological mechanisms, to identify early biomarkers, and also for drug testing studies in AD.

Self-assembled inorganic clusters of semiconducting quantum dots for effective solar hydrogen evolution.

Owing to promoted electron-hole separation, the catalytic activity of semiconducting quantum dots (QDs) towards solar hydrogen (H2) production has been significantly enhanced by forming self-assembled clusters with ZnSe QDs made ex situ. Taking advantage of the favored interparticle hole transfer to ZnSe QDs, the rate of solar H2 evolution of CdSe QDs can be increased to ∼30 000 µmol h-1 g-1 with ascorbic acid as the sacrificial reagent, ∼150-fold higher than that of bare CdSe QDs clusters under the same conditions.

GP73-regulated oncolytic adenoviruses possess potent killing effect on human liver cancer stem-like cells.

Cancer stem cells (CSCs), also known as tumor-initiating cells, are highly metastatic, chemo-resistant and tumorigenic, and are critical for cancer development, maintenance and recurrence. Oncolytic adenovirus could targetedly kill CSCs and has been acted as a promising anticancer agent. Currently, a novel GP73-regulated oncolytic adenovirus GD55 was constructed to specifically treat liver cancer and exhibited obvious cytotoxicity effect. However, there remains to be confirmed that whether GD55 could effectively eliminate liver CSCs. We first utilized the suspension culture to enrich the liver CSCs-like cells, which acquires the properties of liver CSCs in self-renewal, differentiation, quiescence, chemo-resistance and tumorigenicity. The results indicated that GD55 elicited more significant cytotoxicity and stronger oncolytic effect in liver CSC-like cells compared to common oncolytic virus ZD55. Additionally, GD55 possessed the greater efficacy in suppressing the growth of implanted tumors derived from liver CSC-like cells than ZD55. Furthermore, GD55 induced remarkable apoptosis of liver CSC-like cells in vitro and in vivo, and inhibited the propogation of cells and angiogenesis in xenograft tumor tissues. Thus, GD55 may virtually represent an attractive therapeutic agent for targeting liver CSCs to achieve better clinical outcomes for HCC patients.