Ligand-Insertion Strategy for Constructing 2D Conjugated Metal-Organic Framework with Large Pore Size for Electrochemical Analytics.

Two-dimensional conjugated metal-organic frameworks (2D c-MOFs) have shown great promise in various electrochemical applications due to their intrinsic electrical conductivity. A large pore aperture is a favorable feature of this type of material because it facilitates the mass transport of chemical species and electrolytes. In this work, we propose a ligand insertion strategy in which a linear ligand is inserted into the linkage between multitopic ligands, extending the metal ion into a linear unit of -M-ligand-M-, for the construction of 2D c-MOFs with large pore apertures, utilizing only small ligands. As a proof-of-concept trial of this strategy, a 2D c-MOF with mesopores of 3.2 nm was synthesized using commercially available ligands hexahydrotriphenylene and 2,5-dihydroxybenzoquinone. The facilitation of the diffusion of redox species by the large pore size of this MOF was demonstrated through a series of probes. With this feature, it showed superior performance in the electrochemical analysis of a variety of biological species.

Sulfonated Azocalix[4]arene-Modified Metal-Organic Framework Nanosheets for Doxorubicin Removal from Serum.

Chemotherapy is one of the most commonly used methods for treating cancer, but its side effects severely limit its application and impair treatment effectiveness. Removing off-target chemotherapy drugs from the serum promptly through adsorption is the most direct approach to minimize their side effects. In this study, we synthesized a series of adsorption materials to remove the chemotherapy drug doxorubicin by modifying MOF nanosheets with sulfonated azocalix[4]arenes. The strong affinity of sulfonated azocalix[4]arenes for doxorubicin results in high adsorption strength (Langmuir adsorption constant = 2.45-5.73 L mg-1) and more complete removal of the drug. The extensive external surface area of the 2D nanosheets facilitates the exposure of a large number of accessible adsorption sites, which capture DOX molecules without internal diffusion, leading to a high adsorption rate (pseudo-second-order rate constant = 0.0058-0.0065 g mg-1 min-1). These adsorbents perform effectively in physiological environments and exhibit low cytotoxicity and good hemocompatibility. These features make them suitable for removing doxorubicin from serum during "drug capture" procedures. The optimal adsorbent can remove 91% of the clinical concentration of doxorubicin within 5 min.

In the human sperm nucleus, nucleosomes form spatially restricted domains consistent with programmed nucleosome positioning.

In human sperm, a fraction of its chromatin retains nucleosomes that are positioned on specific sequences containing genes and regulatory units essential for embryonic development. This nucleosome positioning (NP) feature provides an inherited epigenetic mark for sperm. However, it is not known whether there is a structural constraint for these nucleosomes and, if so, how they are localized in a three-dimensional (3D) context of the sperm nucleus. In this study, we examine the 3D organization of sperm chromatin and specifically determine its 3D localization of nucleosomes using structured illumination microscopy. A fraction of the sperm chromatin form nucleosome domains (NDs), visible as microscopic puncta ranging from 40 µm to 700 µm in diameter, and these NDs are precisely localized in the post acrosome region (PAR), outside the sperm's core chromatin. Further, NDs exist mainly in sperm from fertile men in a pilot survey with a small sample size. Together, this study uncovers a new spatially-restricted sub-nuclear structure containing NDs that are consistent with NPs of the sperm, which might represent a novel mark for healthy sperm in human.

Transplanted human neural precursor cells integrate into the host neural circuit and ameliorate neurological deficits in a mouse model of traumatic brain injury.

Traumatic brain injury (TBI) is to date one of the major critical conditions causing death and disability worldwide. Exogenous neural stem/precursor cells (NSCs/NPCs) hold great promise for improving neurological dysfunction, but their functional properties in vivo remain unknown. Human neural precursor cells (hNPCs) carrying one fluorescent reporter gene (DsRed) can be observed directly in vivo using two-photon laser-scanning microscope. Therefore, we evaluated the neural integration and potential therapeutic effect of hNPCs on mice with TBI. Behavioral tests were performed by rotarod task and Morris Water Maze task. Neural integration was detected by fluorometric Ca2+ imaging and nerve tracing. We found that motor and cognition functions were significantly improved in mice with hNPCs injection compared to mice with vehicle treatment, and hNPCs integrated into the host circuit and differentiated toward neuronal lineage. Our study provided reliable evidence for further hNPCs transplantation in clinical practice.

[Function of F10 gene, a novel hydatidiform mole-related gene: a preliminary study].

OBJECTIVE: To study the function of F10 gene, a novel hydaditiform mole-related gene. METHODS: A549 cell line was transfected with the F10 gene of forward or reverse sequence or with the empty vector, respectively. The cellular mRNA was extracted after 24 h of transfection to screen for the differentially expressed genes among the 3 transfected and the control cells using differential display-polymerase chain reaction (ddPCR). RESULTS: The bands representing differentially expressed genes were amplified from the cells, and the products were linked to T-Vector for sequence analysis. Several genes were screened by Blasting and their expressions were confirmed by fluorescent quantitative PCR. CONCLUSION: F10 gene is functionally related to cell proliferation and apoptosis.

[Construction and identification of a stable eukaryotic expression system for F10 gene].

OBJECTIVE: To detect the transcriptional level of a novel gene F10 associated with the pathogenesis of hydatidiform mole in human cell lines and screen the cell lines with low F10 expression to construct a stable eukaryotic expression system for F10 gene. METHODS: The expression level of F10 mRNA was detected with fluorescent quantitative PCR in A549, 16HBE, Bel7402, HIC, HepG2, 293, PC and MGC cell lines. A549 cell line was transfected with plasmid pRc-CMV2-F10 via electroporation to allow stable F10 expression, and the positive cell clones were selected by G418. The insertion and expression of F10 gene in the A549 cells was analyzed using fluorescent quantitative PCR. RESULTS: F10 mRNA was expressed differentially in these cells lines, and the Bel7402 cells, PC and MGC cells showed the highest F10 mRNA expression, followed by HepG2 and HIC cells and further by 293 cells, and 16HBE and A594 cells had the lowest expression. After transfection, A594 cells showed genomic integration of F10 gene and high expression level of F10 mRNA. CONCLUSION: The pulmonary carcinoma cell line A549 with stable expression of F10 gene has been established, which may facilitate further study of the biological functions of F10 gene.