Virtual high throughput screening (vHTS) - A perspective

With the exponential rise in the number of viable novel drug targets, computational methods are being increasingly applied to accelerate the drug discovery process. Virtual High Throughput Screening (vHTS) is one such established methodology to identify drug candidates from large collection of compound libraries. Although it complements the expensive and time consuming High Throughput Screening (HTS) of compound libraries, vHTS possess inherent challenges. The successful vHTS requires the careful implementation of each phase of computational screening experiment right from target preparation to hit identification and lead optimization. This article discusses some of the important considerations that are imperative for designing a successful vHTS experiment.     

Bridging the imaging gap: visualizing subcellular architecture with electron tomography

Transmission electron microscopy is a powerful tool that is used to explore the internal structure of tissues, cells, organelles and macromolecular complexes. By integrating data from a series of images in which the orientation of the specimen is progressively varied relative to the incident electron beam it is also possible to extend electron microscopic imaging into the third dimension. This approach, commonly referred to as electron tomography, has been greatly aided in recent years by advances in technology for imaging specimens at cryogenic temperatures, as well as by substantial progress in procedures for automated data collection and image processing. The intense pace of developments in this field is inspired, in a large part, by the hope that the quality of the data will ultimately be good enough to allow interpretation of tomograms of cells, organelles, bacteria and viruses in terms of the three-dimensional spatial arrangements of the constituent molecules.     

Reactive carbonyls and polyunsaturated fatty acids produce a hydroxyl radical-like species: a potential pathway for oxidative damage of retinal proteins in diabetes

The pattern of oxidized amino acids in aortic proteins of nonhuman primates suggests that a species resembling hydroxyl radical damages proteins when blood glucose levels are high. However, recent studies argue strongly against a generalized increase in diabetic oxidative stress, which might instead be confined to the vascular wall. Here, we describe a pathway for glucose-stimulated protein oxidation and provide evidence of its complicity in diabetic microvascular disease. Low density lipoprotein incubated with pathophysiological concentrations of glucose became selectively enriched in ortho-tyrosine and meta-tyrosine, implicating a hydroxyl radical-like species in protein damage. Model system studies demonstrated that the reaction pathway requires both a reactive carbonyl group and a polyunsaturated fatty acid, involves lipid peroxidation, and is blocked by the carbonyl scavenger aminoguanidine. To explore the physiological relevance of the pathway, we used mass spectrometry and high pressure liquid chromatography to quantify oxidation products in control and hyperglycemic rats. Hyperglycemia raised levels of ortho-tyrosine, meta-tyrosine, and oxygenated lipids in the retina, a tissue rich in polyunsaturated fatty acids. Rats that received aminoguanidine did not show this increase in protein and lipid oxidation. In contrast, rats with diet-induced hyperlipidemia in the absence of hyperglycemia failed to exhibit increased protein and lipid oxidation products in the retina. Our observations suggest that generation of a hydroxyl radical-like species by a carbonyl/polyunsaturated fatty acid pathway might promote localized oxidative stress in tissues vulnerable to diabetic damage. This raises the possibility that antioxidant therapies that specifically inhibit the pathway might delay the vascular complications of diabetes.     

Lipid microdomains are required sites for the selective endocytosis and nuclear translocation of IFN-gamma,its receptor chain IFN-gamma receptor-1, and the phosphorylation and nuclear translocation of STAT1alpha

IFN-gamma contains a nuclear localization sequence that may play a role in the nuclear transport of activated STAT1alpha via a complex of IFN-gamma/IFN-gamma receptor (IFNGR)-1/STAT1alpha with the nuclear importer nucleoprotein interactor 1. In this study, we examine the mechanism of endocytosis of IFNGR-1 and the relationship of its nuclear translocation to that of STAT1alpha. In untreated WISH cells, both IFNGR-1 and IFNGR-2 were constitutively localized within caveolae-like microdomains isolated from plasma membrane. However, treatment of cells with IFN-gamma resulted in rapid migration of IFNGR-1, but not IFNGR-2, from these microdomains. Filipin pretreatment, which specifically inhibits endocytosis from caveolae-like microdomains, inhibited the nuclear translocation of IFN-gamma and IFNGR-1 as well as the tyrosine phosphorylation and nuclear translocation of STAT1alpha, but did not affect the binding of IFN-gamma to these cells. In the Jurkat T lymphocyte cell line, which does not express caveolin-1, nuclear translocation of IFNGR-1 and STAT1alpha were similarly inhibited by filipin pretreatment. Isolation of lipid microdomains from Jurkat cells showed that both IFNGR-1 and IFNGR-2 were associated with lipid microdomains only after stimulation with IFN-gamma, suggesting that the IFNGR subunits are recruited to lipid microdomains by IFN-gamma binding in lymphocytes (Jurkat) in contrast to their constitutive presence in epithelial (WISH) cells. In contrast, treatments that block clathrin-dependent endocytosis did not inhibit either activation or nuclear translocation of STAT1alpha or the nuclear translocation of IFN-gamma or IFNGR-1. Thus, membrane lipid microdomains play an important role in IFN-gamma-initiated endocytic events involving IFNGR-1, and the nuclear translocation of IFN-gamma, IFNGR-1, and STAT1alpha.     

Further characterization of human fetal osteoblastic hFOB 1.19 and hFOB/ER alpha cells: bone formation in vivo and karyotype analysis using multicolor fluorescent in situ hybridization

We have previously generated an immortalized human fetal osteoblastic cell line (hFOB) using stably transfected temperature sensitive SV40 T-antigen (Harris et al. [1995a] J. Bone. Miner. Res. 10:178-1860). To characterize these cells for phenotypic/genotypic attributes desired for a good cell model system, we performed karyotype analysis by multicolor fluorescent in situ hybridization (M-FISH), their ability to form bone in vivo without developing cell transformation, and finally their ability to form extracellular matrix formation in vitro. The karyotype analysis of hFOB cells revealed structural or numeric anomalies involving 1-2 chromosomes. In contrast, the human osteosarcoma MG63 cells displayed multiple, and often complex, numeric, and structural abnormalities. Subcutaneous injection of hFOB cells in the presence of Matrigel into nude mice resulted in bone formation after 2-3 weeks. Electron microscopic analysis of the extracellular matrix deposited by hFOB cells in culture revealed a parallel array of lightly banded fibrils typical of the fibrillar collagens such as type I and III. These results demonstrate that the hFOB cell line has minimal chromosome abnormalities, exhibit the matrix synthetic properties of differentiated osteoblasts, and are immortalized but non-transformed cell line. These hFOB cells thus appear to be an excellent model system for the study of osteoblast biology in vitro.     

Contents Volume 1

Volume Contents

Contents Volume 1     

Association of Chlamydia pneumoniae with central nervous system disease

Chlamydia pneumoniae is a common respiratory pathogen that is now being incriminated in a number of chronic diseases. The ability of C. pneumoniae to infect and persist in macrophages makes it a likely candidate to disseminate in a number of different tissues, including those of the central nervous system. This review addresses the potential and the underlying mechanisms by which C. pneumoniae infections can play a role in such diverse neurological diseases as multiple sclerosis and Alzheimer's disease.     

Three-dimensional structure of a bacterial oxalate transporter

The major facilitator superfamily (MFS) represents one of the largest classes of evolutionarily related membrane transporter proteins. Here we present the three-dimensional structure at 6.5 A resolution of a bacterial member of this superfamily, OxlT. The structure, derived from an electron crystallographic analysis of two-dimensional crystals, reveals that the 12 helices in the OxlT molecule are arranged around a central cavity, which is widest at the center of the membrane. The helices divide naturally into three groups: a peripheral set comprising helices 3, 6, 9 and 12; a second set comprising helices 2, 5, 8 and 11 that faces the central substrate transport pathway across most of the length of the membrane; and a third set comprising helices 1, 4, 7 and 10 that participate in the pathway either on the cytoplasmic side (4 and 10) or on the periplasmic side (1 and 7). Overall, the architecture of the protein is remarkably symmetric, providing a compelling molecular explanation for the ability of such transporters to carry out bi-directional substrate transport.     

Impact of the acidic C-terminal region comprising amino acids 109-140 on alpha-synuclein aggregation in vitro

The aggregation of alpha-synuclein, involved in the pathogenesis of several neurodegenerative disorders such as Parkinson's disease, is enhanced in vitro by biogenic polyamines binding to the highly charged C-terminal region aa109-140. In this study, we investigated the influence of this region on the aggregation kinetics, monitored by thioflavin T binding and static light scattering, and morphology, assessed by electron microscopy, fluorescence microscopy, and turbidity, by comparing the effect of various solution conditions on the wild-type protein, the disease related mutants A53T and A30P, and two truncated variants, syn(1-108) and syn(1-124), lacking the complete or the C-terminal half of the polyamine binding site. In the presence of the intact C-terminus, aggregation was strongly retarded in physiological buffer. This inhibition of aggregation was overridden by (i) addition of spermine or MgCl(2) or lowering of pH, leading to strong charge shielding in the C-terminus or (ii) by truncation of aa125-140 or aa109-140. Addition of MgCl(2) or spermine or acidification were not effective in promoting aggregation of syn(1-108). The impact of the disease-related mutations on the aggregation kinetics was dependent on the solution conditions, with the aggregation propensity order A53T approximately wt > A30P at low ionic strength, but A53T > wt approximately A30P at high ionic strength, with exceedingly potent promotion of aggregation by the A53T mutation in the presence of spermine. In contrast to full-length alpha-synuclein aggregates, those formed from syn(1-108) did not exhibit a pronounced polymorphism. The effects of the C-terminus on aggregation cannot be rationalized merely by a contribution to the protein net charge, but rather suggest a specific role of aa109-140 in the regulation of aggregation, presumably involving formation of intramolecular contacts.     

Nanofabricated biomimetic structures for smart targeting and drug delivery

We present a new approach to hybrid artificial cells (AC) designed for specific targeting and active drug delivery by combining an impermeable non-biological scaffold with an artificial bilayer lipid membrane (BLM) that supports the functioning bio-molecules required to provide AC functionality. We report on the fabrication of the scaffold using nanotechnology, as well as on loading of the scaffold and the functionalization of the AC. The results presented here are a first step towards the development of a biomimetic AC using nanotechnology.