Upconversion nanophosphor: an efficient phosphopeptides-recognizing matrix and luminescence resonance energy transfer donor for robust detection of protein kinase activity.

Protein kinases play important regulatory roles in intracellular signal transduction pathways. The aberrant activities of protein kinases are closely associated with the development of various diseases, which necessitates the development of practical and sensitive assays for monitoring protein kinase activities as well as for screening of potential kinase-targeted drugs. We demonstrate here a robust luminescence resonance energy transfer (LRET)-based protein kinase assay by using NaYF4:Yb,Er, one of the most efficient upconversion nanophosphors (UCNPs), as an autofluorescence-free LRET donor and a tetramethylrhodamine (TAMRA)-labeled substrate peptide as the acceptor. Fascinatingly, besides acting as the LRET donor, NaYF4:Yb,Er UCNPs also serve as the phosphopeptide-recognizing matrix because the intrinsic rare earth ions of UCNPs can specifically capture the fluorescent phosphopeptides catalyzed by protein kinases over the unphosphorylated ones. Therefore, a sensitive and generic protein kinase assay is developed in an extremely simple mix-and-read format without any requirement of surface modification, substrate immobilization, separation, or washing steps, showing great potential in protein kinases-related clinical diagnosis and drug discovery. To the best of our knowledge, this is the first report by use of rare earth-doped UCNPs as both the phospho-recognizing and signal reporting elements for protein kinase analysis.

Space-Confined Growth of Cs2CuBr4 Perovskite Nanodots in Mesoporous CeO2 for Photocatalytic CO2 Reduction: Structure Regulation and Built-in Electric Field Construction.

Halide perovskites have shown great promise in photocatalytic CO2 conversion. However, their practical application is seriously hindered by severe charge recombination and inadequate adsorption/activation toward CO2 molecules. Herein, the space-confined growth of lead-free Cs2CuBr4 perovskite nanodots in mesoporous CeO2 was realized by a facile impregnation approach. An outstanding CO2 photoreduction performance is achieved by the optimum Cs2CuBr4/CeO2 heterojunction with CO and CH4 yields of 271.56 and 83.28 µmol g-1, respectively. Experimental characterizations and theoretical calculations cooperatively validate the S-scheme charge transfer mechanism in the Cs2CuBr4/CeO2 heterojunction. The CO2 photoreduction pathway is also revealed by combining in situ diffuse reflectance infrared Fourier transform spectra (DRIFTS) and density functional theory (DFT) calculations. This study provides useful guidance for the design of high-performance halide perovskite/mesoporous material heterostructure photocatalysts for artificial photosynthesis.

Chloroplastic photoprotective strategies differ between bundle sheath and mesophyll cells in maize (Zea mays L.) Under drought.

Bundle sheath cells play a crucial role in photosynthesis in C4 plants, but the structure and function of photosystem II (PSII) in these cells is still controversial. Photoprotective roles of bundle sheath chloroplasts at the occurrence of environmental stresses have not been investigated so far. Non-photochemical quenching (NPQ) of chlorophyll a fluorescence is the photoprotective mechanism that responds to a changing energy balance in chloroplasts. In the present study, we found a much higher NPQ in bundle sheath chloroplasts than in mesophyll chloroplasts under a drought stress. This change was accompanied by a more rapid dephosphorylation of light-harvesting complex II (LHCII) subunits and a greater increase in PSII subunit S (PsbS) protein abundance than in mesophyll cell chloroplasts. Histochemical staining of reactive oxygen species (ROS) suggested that the high NPQ may be one of the main reasons for the lower accumulation of ROS in bundle sheath chloroplasts. This may maintain the stable functioning of bundle sheath cells under drought condition. These results indicate that the superior capacity for dissipation of excitation energy in bundle sheath chloroplasts may be an environmental adaptation unique to C4 plants.

A conserved unusual posttranscriptional processing mediated by short, direct repeated (SDR) sequences in plants.

In several stress responsive gene loci of monocot cereal crops, we have previously identified an unusual posttranscriptional processing mediated by paired presence of short direct repeated (SDR) sequences at 5' and 3' splicing junctions that are distinct from conventional (U2/U12-type) splicing boundaries. By using the known SDR-containing sequences as probes, 24 plant candidate genes involved in diverse functional pathways from both monocots and dicots that potentially possess SDR-mediated posttranscriptional processing were predicted in the GenBank database. The SDRs-mediated posttranscriptional processing events including cis- and trans-actions were experimentally detected in majority of the predicted candidates. Extensive sequence analysis demonstrates several types of SDR-associated splicing peculiarities including partial exon deletion, exon fragment repetition, exon fragment scrambling and trans-splicing that result in either loss of partial exon or unusual exonic sequence rearrangements within or between RNA molecules. In addition, we show that the paired presence of SDR is necessary but not sufficient in SDR-mediated splicing in transient expression and stable transformation systems. We also show prokaryote is incapable of SDR-mediated premRNA splicing.

Functional defect at the rice choline monooxygenase locus from an unusual post-transcriptional processing is associated with the sequence elements of short-direct repeats.

Glycine betaine (GB), a quaternary ammonium solute, plays a crucial role in developing osmotic tolerance. Rice contains a choline monooxygenase (CMO) and two betaine aldehyde dehydrogenase homologues that are required for GB synthesis, but usually no GB is accumulated in rice (Oryza sativa). To elucidate the molecular processes that underlie the GB deficiency in rice, an experiment involving rice and spinach (Spinacia oleracea) was conducted to analyze the products transcribed from CMO genes. Reverse transcription-polymerase chain reaction (RT-PCR) was used to obtain CMO transcripts and a sequencing approach was employed to analyze the structural composition of various CMO transcripts. The results showed that most rice CMO transcripts were processed incorrectly, retaining introns or deleted of coding sequences; the unusual deletion events occurred at sequence elements of the short-direct repeats. In conclusion, the production of incorrect CMO transcripts results in a deficiency of the full-length CMO protein and probably reduces GB accumulation considerably in rice plants. Sequence comparison results also implied that the unusual deletion-site selection might be mediated by the short-direct repeats in response to stress conditions.