A linear relationship between crystal size and fragment binding time observed crystallographically: implications for fragment library screening using acoustic droplet ejection.

High throughput screening technologies such as acoustic droplet ejection (ADE) greatly increase the rate at which X-ray diffraction data can be acquired from crystals. One promising high throughput screening application of ADE is to rapidly combine protein crystals with fragment libraries. In this approach, each fragment soaks into a protein crystal either directly on data collection media or on a moving conveyor belt which then delivers the crystals to the X-ray beam. By simultaneously handling multiple crystals combined with fragment specimens, these techniques relax the automounter duty-cycle bottleneck that currently prevents optimal exploitation of third generation synchrotrons. Two factors limit the speed and scope of projects that are suitable for fragment screening using techniques such as ADE. Firstly, in applications where the high throughput screening apparatus is located inside the X-ray station (such as the conveyor belt system described above), the speed of data acquisition is limited by the time required for each fragment to soak into its protein crystal. Secondly, in applications where crystals are combined with fragments directly on data acquisition media (including both of the ADE methods described above), the maximum time that fragments have to soak into crystals is limited by evaporative dehydration of the protein crystals during the fragment soak. Here we demonstrate that both of these problems can be minimized by using small crystals, because the soak time required for a fragment hit to attain high occupancy depends approximately linearly on crystal size.

Pathogenic and nonpathogenic hantaviruses differentially regulate endothelial cell responses.

Hantaviruses cause two human diseases: hemorrhagic fever with renal syndrome (HFRS) and hantavirus pulmonary syndrome (HPS). Hantaviruses infect human endothelial cells but cause little or no damage to the infected endothelium. We analyzed with Affymetrix DNA Arrays (Santa Clara, CA) the endothelial cell transcriptional responses directed by hantaviruses associated with HPS [New York-1 virus (NY-1V)], HFRS [Hantaan virus (HTNV)], or by a hantavirus not associated with human disease [Prospect Hill virus (PHV)]. Hantavirus infections induced 117 cellular genes and repressed 25 genes by >3-fold, 4 days postinfection (p.i.). Although >80% of cells were infected by each virus 1 day p.i., PHV induced or repressed 67 genes at this early time compared with three genes altered by HTNV or NY-1V. The early high-level induction of 24 IFN-stimulated genes by PHV (4- to 229-fold) represents a fundamental difference in the temporal regulation of cellular responses by pathogenic and nonpathogenic hantaviruses. Because all hantaviruses induced >23 IFN-stimulated genes at late times p.i., pathogenic hantaviruses appear to suppress early cellular IFN responses that are activated by nonpathogenic hantaviruses. At late times p.i., 13 genes were commonly induced by HTNV and NY-1V that were not induced by PHV. In contrast to NY-1V, HTNV uniquely induced a variety of chemokines and cell adhesion molecules (i.e., IL-8, IL-6, GRO-beta, ICAM), as well as two complement cascade-associated factors that may contribute to immune components of HFRS disease. NY-1V failed to induce most cellular chemokines directed by HTNV (3/14) or genes primarily activated by NF-kappaB. However, NY-1V uniquely induced beta3 integrin-linked potassium channels, which could play a role in HPS-associated vascular permeability. These studies provide a basic understanding of hantavirus-directed cellular responses that are likely to differentiate pathogenic and nonpathogenic hantaviruses, contribute to HFRS and HPS pathogenesis, and provide insight into disease mechanisms and potential therapeutic interventions.