Nonresonant hyper-Raman and hyper-Rayleigh spectra excited at 1064 nm are reported for neat benzene and pyridine. The theory of Herzberg-Teller vibronic coupling in nonresonant and preresonant hyper-Raman scattering is developed. Nonresonant hyper-Raman scattering is shown to be vibronically induced by modes that efficiently couple strongly allowed onephoton and two-photon transitions. A weak and broad (55 cm -I) hyper-Rayleigh band was observed in benzene and attributed to collective scattering, while in pyridine, a much more intense and much narrower hyper-Rayleigh band was observed. Only the a 2u vibration (VII) was observed in the hyper-Raman spectrum of benzene, while several strong bands were observed in pyridine. Possible vibronic-coupling pathways are discussed for these modes. In addition, the observed hyper-Raman spectrum of pyridine is compared to a recent calculation.
As part of its pathogenic life cycle, Phytophthora capsici disperses to plants through a motile zoospore stage. Molecules on the zoospore surface are involved in reception of environmental signals that direct preinfection behavior. We developed a phage display protocol to identify peptides that bind to the surface molecules of P. capsici zoospores in vitro. The selected phage-displayed peptides contained an abundance of polar amino acids and proline but were otherwise not conserved. About half of the selected phage that were tested concomitantly induced zoospore encystment in the absence of other signaling agents. A display phage was shown to bind to the zoospore but not to the cyst form of P. capsici. Two free peptides corresponding to active phage were similarly able to induce encystment of zoospores, indicating that their ability to serve as signaling ligands did not depend on their exact molecular context. Isolation and subsequent expression of peptides that act on pathogens could allow the identification of receptor molecules on the zoospore surface, in addition to forming the basis for a novel plant disease resistance strategy.Phytophthora capsici is a soilborne pathogenic protist (phylum Oomycota) that infects aerial and subterranean structures of many solanaceous plants. Diseases caused by P. capsici are polycyclic in that multiple cycles of infection and inoculum production occur in a single growing season (20). The pathogen survives unfavorable conditions in soil by forming thickwalled oospores, while dissemination and infection are achieved through the production of motile biflagellate zoospores from oospores. The zoospores swim through water in the soil and are chemotactically attracted to the exudates released by the roots of potential host plants (11,14). After the zoospores have adhered to the root surface, they encyst and produce a precisely oriented germ tube that grows into adjacent host plant tissue (3). The progression from zoospores to germlings is triggered by environmental signals, some of which are produced by the plant root. Receptors on the surfaces of the zoospores, cysts, and germ tubes detect the environmental signals that trigger or orient each developmental event.Control of Phytophthora infection remains an ongoing agricultural problem and is most commonly accomplished by the application of biocides, such as methyl bromide or metalaxyl, to the soil. The ability of oospores to persist in soil for long periods obviates the use of crop rotation as an antipest strategy. Alternative, more environmentally benign methods of control will likely have to target host-specific stages of the infectious cycle, since the pathogen is so persistent.In the present study, we explore the possibility of using specific peptide ligands to interfere with the normal developmental progression of the pathogen. We reasoned that, since zoospores are chemotactic toward the plant surface and since the development of the pathogen involves interaction with the plant surface, surface receptor molecules on the zoosp...
We have developed a pump-probe picosecond spectrometer capable of time-resolved studies spanning nine decades in time, from the picosecond to the millisecond regimes. The system operates at repetition rates up to 2 kHz with ∼40-ps time resolution. Pump and probe beam average powers are ∼10 mW. The system is capable of studies of molecular dynamics in complex systems such as proteins, where internal motions span a wide range of time scales.
The ChAdOx1 nCoV‐19 vaccine has been associated with increased risk of thrombosis. Understanding of the management of these rare events is evolving, and currently recommended treatments include human normal immunoglobulin and nonheparin anticoagulation such as direct oral anticoagulants. Our report describes three consecutive patients presenting to a London teaching hospital with vaccine‐induced thrombotic thrombocytopenia (VITT), also referred to as vaccine‐induced prothrombotic immune thrombocytopenia. The patients ranged in age from 40 to 54 years and two had no known previous medical comorbidities. Two patients had cerebral venous sinus thrombosis and one had a deep vein thrombosis. Two were treated with anticoagulation, one with oral rivaroxaban and the other with an intravenous argotraban infusion that was later converted to oral apixaban. One patient received three doses of human normal immunoglobulin and 5 days of therapeutic plasma exchange. This case series may be used to improve understanding of the clinical course and management of VITT.
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