Potassium Iodide Doping for Vacancy Substitution and Dangling Bond Repair in InP Core-Shell Quantum Dots.

This work highlights the novel approach of incorporating potassium iodide (KI) doping during the synthesis of In0.53P0.47 core quantum dots (QDs) to significantly reduce the concentration of vacancies (i.e., In vacancies; VIn-) within the bulk of the core QD and inhibit the formation of InPOx at the core QD-Zn0.6Se0.4 shell interfaces. The photoluminescence quantum yield (PLQY) of ~97% and full width at half maximum (FWHM) of ~40 nm were achieved for In0.53P0.47/Zn0.6Se0.4/Zn0.6Se0.1S0.3/Zn0.5S0.5 core/multi-shell QDs emitting red light, which is essential for a quantum-dot organic light-emitting diode (QD-OLED) without red, green, and blue crosstalk. KI doping eliminated VIn- in the core QD bulk by forming K+-VIn- substitutes and effectively inhibited the formation of InPO4(H2O)2 at the core QD-Zn0.6Se0.4 shell interface through the passivation of phosphorus (P)-dangling bonds by P-I bonds. The elimination of vacancies in the core QD bulk was evidenced by the decreased relative intensity of non-radiative unpaired electrons, measured by electron spin resonance (ESR). Additionally, the inhibition of InPO4(H2O)2 formation at the core QD and shell interface was confirmed by the absence of the {210} X-ray diffraction (XRD) peak intensity for the core/multi-shell QDs. By finely tuning the doping concentration, the optimal level was achieved, ensuring maximum K-VIn- substitution, minimal K+ and I- interstitials, and maximum P-dangling bond passivation. This resulted in the smallest core QD diameter distribution and maximized optical properties. Consequently, the maximum PLQY (~97%) and minimum FWHM (~40 nm) were observed at 3% KI doping. Furthermore, the color gamut of a QD-OLED display using R-, G-, and B-QD functional color filters (i.e., ~131.1%@NTSC and ~98.2@Rec.2020) provided a nearly perfect color representation, where red-light-emitting KI-doped QDs were applied.

Porous Polyethylene Supports in Reinforcement of Multiblock Hydrocarbon Ionomers for Proton Exchange Membranes.

Hydrocarbon (HC)-based block copolymers have been recognized as promising candidates for proton exchange membranes (PEMs) due to their distinct hydrophilic-hydrophobic separation, which results in improved proton transport compared to that of random copolymers. However, most PEMs derived from HC-based ionomers, including block copolymers, encounter challenges related to durability in electrochemical cells due to their low mechanical and chemical properties. One method for reinforcing HC-based ionomers involves incorporating the ionomers into commercially available low surface tension PTFE porous substrates. Nevertheless, the high interfacial energy between the hydrocarbon-based ionomer solution and PTFE remains a challenge in this reinforcement process, which necessitates the application of surface energy treatment to PTFE. Here, multiblock sulfonated poly(arylene ether sulfone) (SPAES) ionomers are being reinforced using untreated PE on the surface, and this is compared to reinforcement using surface-treated porous PTFE. The PE support layer exhibits a lower surface energy barrier compared to the surface-treated PTFE layer for the infiltration of the multiblock SPAES solution. This is characterized by the absence of noticeable voids, high translucency, gas impermeability, and a physical and chemical stability. By utilizing a high surface tension PE support with a comparable value to the multiblock SPAES, effective reinforcement of the multiblock SPAES ionomers is achieved for a PEM, which is potentially applicable to various hydrogen energy-based electrochemical cells.

Profilin-1; a novel regulator of DNA damage response and repair machinery in keratinocytes.

Profilin-1 (PFN1) regulates actin polymerization and cytoskeletal growth. Despite the essential roles of PFN1 in cell integration, its subcellular function in keratinocyte has not been elucidated yet. Here we characterize the specific regulation of PFN1 in DNA damage response and repair machinery. PFN1 depletion accelerated DNA damage-mediated apoptosis exhibiting PTEN loss of function instigated by increased phosphorylated inactivation followed by high levels of AKT activation. PFN1 changed its predominant cytoplasmic localization to the nucleus upon DNA damage and subsequently restored the cytoplasmic compartment during the recovery time. Even though γH2AX was recruited at the sites of DNA double strand breaks in response to DNA damage, PFN1-deficient cells failed to recruit DNA repair factors, whereas control cells exhibited significant increases of these genes. Additionally, PFN1 depletion resulted in disruption of PTEN-AKT cascade upon DNA damage and CHK1-mediated cell cycle arrest was not recovered even after the recovery time exhibiting γH2AX accumulation. This might suggest PFN1 roles in regulating DNA damage response and repair machinery to protect cells from DNA damage. Future studies addressing the crosstalk and regulation of PTEN-related DNA damage sensing and repair pathway choice by PFN1 may further aid to identify new mechanistic insights for various DNA repair disorders.

Eupatilin treatment inhibits transforming growth factor beta-induced endometrial fibrosis in vitro.

OBJECTIVE: Endometrial fibrosis, the primary pathological feature of intrauterine adhesion, may lead to disruption of endometrial tissue structure, menstrual abnormalities, infertility, and recurrent pregnancy loss. At present, no ideal therapeutic strategy exists for this fibrotic disease. Eupatilin, a major pharmacologically active flavone from Artemisia, has been previously reported to act as a potent inducer of dedifferentiation of fibrotic tissue in the liver and lung. However, the effects of eupatilin on endometrial fibrosis have not yet been investigated. In this study, we present the first report on the impact of eupatilin treatment on transforming growth factor beta (TGF-ß)-induced endometrial fibrosis. METHODS: The efficacy of eupatilin on TGF-ß-induced endometrial fibrosis was assessed by examining changes in morphology and the expression levels of fibrosis markers using immunofluorescence staining and quantitative real-time reverse-transcription polymerase chain reaction. RESULTS: Eupatilin treatment significantly reduced the fibrotic activity of TGF-ß-induced endometrial fibrosis in Ishikawa cells, which displayed more circular shapes and formed more colonies. Additionally, the effects of eupatilin on fibrotic markers including alpha-smooth muscle actin, hypoxia-inducible factor 1 alpha, collagen type I alpha 1 chain, and matrix metalloproteinase-2, were evaluated in TGF-ß-induced endometrial fibrosis. The expression of these markers was highly upregulated by TGF-ß pretreatment and recovered to the levels of control cells in response to eupatilin treatment. CONCLUSION: Our findings suggest that suppression of TGF-ß-induced signaling by eupatilin might be an effective therapeutic strategy for the treatment of endometrial fibrosis.

Endometrial profilin 1: a key player in embryo-endometrial crosstalk.

OBJECTIVE: Despite extensive research on implantation failure, little is known about the molecular mechanisms underlying the crosstalk between the embryo and the maternal endometrium, which is critical for successful pregnancy. Profilin 1 (PFN1), which is expressed both in the embryo and in the endometrial epithelium, acts as a potent regulator of actin polymerization and the cytoskeletal network. In this study, we identified the specific role of endometrial PFN1 during embryo implantation. METHODS: Morphological alterations depending on the status of PFN1 expression were assessed in PFN1-depleted or control cells grown on Matrigel-coated cover glass. Day-5 mouse embryos were cocultured with Ishikawa cells. Comparisons of the rates of F-actin formation and embryo attachment were performed by measuring the stability of the attached embryo onto PFN1-depleted or control cells. RESULTS: Depletion of PFN1 in endometrial epithelial cells induced a significant reduction in cell-cell adhesion displaying less formation of colonies and a more circular cell shape. Mouse embryos co-cultured with PFN1-depleted cells failed to form actin cytoskeletal networks, whereas more F-actin formation in the direction of surrounding PFN1-intact endometrial epithelial cells was detected. Furthermore, significantly lower embryo attachment stability was observed in PFN1-depleted cells than in control cells. This may have been due to reduced endometrial receptivity caused by impaired actin cytoskeletal networks associated with PFN1 deficiency. CONCLUSION: These observations definitively demonstrate an important role of PFN1 in mediating cell-cell adhesion during the initial stage of embryo implantation and suggest a potential therapeutic target or novel biomarker for patients suffering from implantation failure.

Botulinum toxin type A enhances the inhibitory spontaneous postsynaptic currents on the substantia gelatinosa neurons of the subnucleus caudalis in immature mice.

Botulinum toxin type A (BoNT/A) has been used therapeutically for various conditions including dystonia, cerebral palsy, wrinkle, hyperhidrosis and pain control. The substantia gelatinosa (SG) neurons of the trigeminal subnucleus caudalis (Vc) receive orofacial nociceptive information from primary afferents and transmit the information to higher brain center. Although many studies have shown the analgesic effects of BoNT/A, the effects of BoNT/A at the central nervous system and the action mechanism are not well understood. Therefore, the effects of BoNT/A on the spontaneous postsynaptic currents (sPSCs) in the SG neurons were investigated. In whole cell voltage clamp mode, the frequency of sPSCs was increased in 18 (37.5%) neurons, decreased in 5 (10.4%) neurons and not affected in 25 (52.1%) of 48 neurons tested by BoNT/A (3 nM). Similar proportions of frequency variation of sPSCs were observed in 1 and 10 nM BoNT/A and no significant differences were observed in the relative mean frequencies of sPSCs among 1-10 nM BoNT/A. BoNT/A-induced frequency increase of sPSCs was not affected by pretreated tetrodotoxin (0.5 µM). In addition, the frequency of sIPSCs in the presence of CNQX (10 µM) and AP5 (20 µM) was increased in 10 (53%) neurons, decreased in 1 (5%) neuron and not affected in 8 (42%) of 19 neurons tested by BoNT/A (3 nM). These results demonstrate that BoNT/A increases the frequency of sIPSCs on SG neurons of the Vc at least partly and can provide an evidence for rapid action of BoNT/A at the central nervous system.

A novel dimeric inhibitor targeting Beta2GPI in Beta2GPI/antibody complexes implicated in antiphospholipid syndrome.

BACKGROUND: ß2GPI is a major antigen for autoantibodies associated with antiphospholipid syndrome (APS), an autoimmune disease characterized by thrombosis and recurrent pregnancy loss. Only the dimeric form of ß2GPI generated by anti-ß2GPI antibodies is pathologically important, in contrast to monomeric ß2GPI which is abundant in plasma. PRINCIPAL FINDINGS: We created a dimeric inhibitor, A1-A1, to selectively target ß2GPI in ß2GPI/antibody complexes. To make this inhibitor, we isolated the first ligand-binding module from ApoER2 (A1) and connected two A1 modules with a flexible linker. A1-A1 interferes with two pathologically important interactions in APS, the binding of ß2GPI/antibody complexes with anionic phospholipids and ApoER2. We compared the efficiency of A1-A1 to monomeric A1 for inhibition of the binding of ß2GPI/antibody complexes to anionic phospholipids. We tested the inhibition of ß2GPI present in human serum, ß2GPI purified from human plasma and the individual domain V of ß2GPI. We demonstrated that when ß2GPI/antibody complexes are formed, A1-A1 is much more effective than A1 in inhibition of the binding of ß2GPI to cardiolipin, regardless of the source of ß2GPI. Similarly, A1-A1 strongly inhibits the binding of dimerized domain V of ß2GPI to cardiolipin compared to the monomeric A1 inhibitor. In the absence of anti-ß2GPI antibodies, both A1-A1 and A1 only weakly inhibit the binding of pathologically inactive monomeric ß2GPI to cardiolipin. CONCLUSIONS: Our results suggest that the approach of using a dimeric inhibitor to block ß2GPI in the pathological multivalent ß2GPI/antibody complexes holds significant promise. The novel inhibitor A1-A1 may be a starting point in the development of an effective therapeutic for antiphospholipid syndrome.

Mode of interaction between beta2GPI and lipoprotein receptors suggests mutually exclusive binding of beta2GPI to the receptors and anionic phospholipids.

Lipoprotein receptors of the LDLR family serve as clearance receptors for beta2GPI and as signaling receptors for the beta2GPI/antibody complexes in antiphospholipid syndrome. We compared four ligand-binding LA modules from LDLR and ApoER2 for their ability to bind domain V of beta2GPI (beta2GPI-DV). We found that the LA modules capable of binding beta2GPI-DV interact with the same region on beta2GPI-DV using residues at their calcium-coordination site. The structure of a complex between beta2GPI-DV and LA4 of LDLR, solved by molecular docking guided by NMR-derived restraints and extensively validated, represents the general mode of interaction between beta2GPI and lipoprotein receptors. We have shown that beta2GPI-DV cannot simultaneously bind to lipoprotein receptors and anionic phospholipids, suggesting that the association of beta2GPI/anti-beta2GPI antibody complexes with anionic phospholipids will interfere with lipoprotein receptors' signaling in APS.

Structural insights into recognition of beta2-glycoprotein I by the lipoprotein receptors.

The interactions of beta2 glycoprotein I (B2GPI) with the receptors of the low-density lipoprotein receptor (LDLR) family are implicated in the clearance of negatively charged phospholipids and apoptotic cells and, in the presence of autoimmune anti-B2GPI antibodies, in cell activation, which might play a role in the pathology of antiphospholipid syndrome (APS). The ligand-binding domains of the lipoprotein receptors consist of multiple homologous LA modules connected by flexible linkers. In this study, we investigated at the atomic level the features of the LA modules required for binding to B2GPI. To compare the binding interface in B2GPI/LA complex to that observed in the high-resolution co-crystal structure of the receptor associated protein (RAP) with a pair of LA modules 3 and 4 from the LDLR, we used LA4 in our studies. Using solution NMR spectroscopy, we found that LA4 interacts with B2GPI and the binding site for B2GPI on the (15)N-labeled LA4 is formed by the calcium coordinating residues of the LA module. We built a model for the complex between domain V of B2GPI (B2GPI-DV) and LA4 without introducing any experimentally derived constraints into the docking procedure. Our model, which is in the agreement with the NMR data, suggests that the binding interface of B2GPI for the lipoprotein receptors is centered at three lysine residues of B2GPI-DV, Lys 308, Lys 282, and Lys317.

Molecular domain organization of BldD, an essential transcriptional regulator for developmental process of Streptomyces coelicolor A3(2).

A homodimeric protein, BldD is a key regulator for developmental process of Streptomyces coelicolor and the bldD mutant exhibits severely pleiotropic defects in the antibiotic production and morphological differentiation of the bacterium. In the present work, we approached domain organization of BldD, to structurally and functionally characterize the protein as a DNA-binding protein. We first observed a proteolytic cleavage of BldD by the cytoplasmic extracts of S. coelicolor, which was highly dependent on the developmental stage of the bacterium. The resulting fragment of BldD was identified by mass spectrometry as the N-terminal domain resistant to the proteolysis. Recombinant proteins corresponding to the intact BldD, the N-terminal domain (residues 1-79) and the rest part (C-terminal domain; residues 80-167) were used for comparative analyses by several spectroscopic, thermodynamic, and biochemical experiments, respectively. The results of circular dichroism and nuclear magnetic resonance spectroscopies certified each of the two determined domains could be regarded as an individual folding unit possessing an independent thermodynamic cooperativity. Structural interaction between the two domains was little observed in the DNA-free and DNA-bound states. Strikingly, it was revealed by gel permeation chromatography, chemical crosslink, gel mobility shift, and NMR-monitored DNA-binding experiments, that only the N-terminal domain is responsible for the dimerization as well as DNA-binding of BldD. Detailed inspection of the present results suggests that BldD function in a unique and complicated mode to totally regulate the diverse developmental stages of S. coelicolor.

Ligand-dependent particle size control of PbSe quantum dots.

Colloidal solutions of monodisperse PbSe quantum dots (QDs) were synthesized by a hot solution chemical method from a reaction mixture of lead oleate and TOPSe (TOP: tri-n-octylphosphine). The synthesis was carried out at a fixed temperature (170 degrees C) and time, while the particle sizes of the PbSe QDs were controlled by using two different kinds of organic ligands with varied chain length. It was seen that the tuning of PbSe QDs are possible by using the proper molar ratio of the co-ligands, such as acetic acid or hexanoic acid, at a fixed reaction temperature and time, verified by TEM and XRD as well as NIR absorption analysis. The effects of different organic acids were studied and the role of additional organic acids might be due to the extent of ligand exchange efficiency between the Pb oleate and acetic/hexanoic acid in the initial stage, which is caused by the steric hindrance effects of the acids.

Crystal structure of the DNA-binding domain of BldD, a central regulator of aerial mycelium formation in Streptomyces coelicolor A3(2).

BldD is a central regulator of the developmental process in Streptomyces coelicolor. The 1.8 angstroms resolution structure of the DNA-binding domain of BldD (BldDN) reveals that BldDN forms a compact globular domain composed of four helices (alpha1-alpha4) containing a helix-turn-helix motif (alpha2-alpha3) resembling that of the DNA-binding domain of lambda repressor. The BldDN/DNA complex model led us to design a series of mutants, which revealed the important role of alpha3 and the 'turn' region between alpha2 and alpha3 for DNA recognition. Based on the fact that BldD occupies two operator sites of bldN and whiG and shows significant disparity in the affinity toward the two operator sites when they are disconnected, we propose a model of cooperative binding, which means that the binding of one BldD dimer to the high affinity site facilitates that of the second BldD dimer to the low affinity site. In addition, structural and mutational investigation reveals that the Tyr62Cys mutation, found in the first-identified bldD mutant, can destabilize BldD structure by disrupting the hydrophobic core.

Crystallization and preliminary X-ray crystallographic analysis of the DNA-binding domain of BldD from Streptomyces coelicolor A3(2).

The N-terminal DNA-binding domain of BldD from Streptomyces coelicolor A3(2) was crystallized by the hanging-drop vapour-diffusion method at 296 K. A 1.8 angstroms data set has been collected using synchrotron radiation at Pohang Light Source, South Korea. The crystal belongs to the monoclinic space group C2, with unit-cell parameters a = 77.2, b = 31.8, c = 33.6 angstroms, beta = 105.1 degrees. Analysis of the packing density shows that the asymmetric unit probably contains one molecule, with a solvent content of 43.6%.

Biophysical and structural property of the putative DNA-binding protein, BldB, from Streptomyces lividans.

The bldB gene from Streptomyces lividans was cloned, and its product was overexpressed in Escherichia coli using a T7 expression system. Gel mobility shift assays showed that the BldB protein was functionally expressed in the E. coli system and may negatively regulate its own expression. The comparative analyses by mass spectrometry, Tris-Tricine sodium dodecyl sulfate-polyacrylamide gel electrophoresis (SDS-PAGE), and analytical ultracentrifuge established that BldB is a dimeric protein with 24 kDa molecular mass, of which monomers do not covalently interact with each other. Gel filtration result implied that the protein shape would not be globular. More detailed structural investigations by CD and NMR spectroscopy confirmed that the majority of the BldB structure is not only disordered but also highly flexible. The highly reversible, but hardly cooperative, property of the thermal denaturation also supported the idea that the protein structure is not compact. However, the existence of a structural nucleus, of which the ordered conformation remains stabilized even at more than 80 degrees C, was evidenced. The overall structure and the thermal stability of BldB were sensitive to pH, suggesting a proton-induced conformation change. Altogether, the results provide the first detailed characterization on the biophysical and structural property of the putative DNA-binding protein, BldB.