Prevalence of Hepatitis δ (Delta) Virus Infection A Seroepidemiologic Study

In assessing the prevalence of hepatitis δ (delta) virus (HDV) infection in 358 patients with acute hepatitis B seen in Los Angeles between 1983 and 1985 and in 196 patients with chronic hepatitis B followed between 1980 and 1985, we found that 23% of patients with chronic and 5% of patients with acute hepatitis B were infected with HDV. Among patients with chronic hepatitis B, the prevalence of HDV infection was 73% in intravenous drug users and 14% in homosexual men. Acute coinfection with the hepatitis B virus was also more frequent in drug users (8%) than in other groups. δ-Hepatitis is a common infection in hepatitis B virus carriers in Los Angeles, particularly in drug addicts, but also in homosexual men who do not abuse drugs intravenously.     

Green synthesis of ZnO nanoparticles for antimicrobial and vegetative growth applications: A novel approach for advancing efficient high quality health care to human wellbeing

The present work aims to synthesize zinc oxide (ZnO) nanoparticles via green approaches using leaf extract of Parthenium hysterophorus. UV–vis and FT-IR tests confirmed the existence of biomolecules, active materials, and metal oxides. The X-ray diffraction structural study exposes the ZnO nanoparticles formation with hexagonal phase structures. SEM and TEM analysis reveal surface morphologies of ZnO nanoparticles and most of them are spherical with a size range of 10 nm. ZnO nanoparticles were revealed strong antimicrobial activity against both bacterial and fungal strains. The germination of seeds and vegetative growth of Sesamum indicum has been greatly improved.     

Proteomic profiling and functional characterization of early and late shoulder osteoarthritis

Introduction

The development of effective treatments for osteoarthritis (OA) has been hampered by a poor understanding of OA at the cellular and molecular levels. Emerging as a disease of the ''whole joint’, the importance of the biochemical contribution of various tissues, including synovium, bone and articular cartilage, has become increasingly significant. Bathing the entire joint structure, the proteomic analysis of synovial fluid (SF) from osteoarthritic shoulders offers a valuable ''snapshot’ of the biologic environment throughout disease progression. The purpose of this study was to identify differentially expressed proteins in early and late shoulder osteoarthritic SF in comparison to healthy SF.

Methods

A quantitative ¹⁸O labeling proteomic approach was employed to identify the dysregulated SF proteins in early (n = 5) and late (n = 4) OA patients compared to control individuals (n = 5). In addition, ELISA was used to quantify six pro-inflammatory and two anti-inflammatory cytokines.

Results

Key results include a greater relative abundance of proteins related to the complement system and the extracellular matrix in SF from both early and late OA. Pathway analyses suggests dysregulation of the acute phase response, liver x receptor/retinoid x receptor (LXR/RXR), complement system and coagulation pathways in both early and late OA. The network related to lipid metabolism was down-regulated in both early and late OA. Inflammatory cytokines including interleukin (IL) 6, IL 8 and IL 18 were up-regulated in early and late OA.

Conclusions

The results suggest a dysregulation of wound repair pathways in shoulder OA contributing to the presence of a ''chronic wound’ that progresses irreversibly from early to later stages of OA. Protease inhibitors were downregulated in late OA suggesting uncontrolled proteolytic activity occurring in late OA. These results contribute to the theory that protease inhibitors represent promising therapeutic agents which could limit proteolytic activity that ultimately leads to cartilage destruction.     

Comparative analyses of quaternary arrangements in homo‐oligomeric proteins in superfamilies: Functional implications

A comprehensive analysis of the quaternary features of distantly related homo‐oligomeric proteins is the focus of the current study. This study has been performed at the levels of quaternary state, symmetry, and quaternary structure. Quaternary state and quaternary structure refers to the number of subunits and spatial arrangements of subunits, respectively. Using a large dataset of available 3D structures of biologically relevant assemblies, we show that only 53% of the distantly related homo‐oligomeric proteins have the same quaternary state. Considering these homologous homo‐oligomers with the same quaternary state, conservation of quaternary structures is observed only in 38% of the pairs. In 36% of the pairs of distantly related homo‐oligomers with different quaternary states the larger assembly in a pair shows high structural similarity with the entire quaternary structure of the related protein with lower quaternary state and it is referred as “Russian doll effect.” The differences in quaternary state and structure have been suggested to contribute to the functional diversity. Detailed investigations show that even though the gross functions of many distantly related homo‐oligomers are the same, finer level differences in molecular functions are manifested by differences in quaternary states and structures. Comparison of structures of biological assemblies in distantly and closely related homo‐oligomeric proteins throughout the study differentiates the effects of sequence divergence on the quaternary structures and function. Knowledge inferred from this study can provide insights for improved protein structure classification and function prediction of homo‐oligomers. Proteins 2016; 84:1190–1202. © 2016 Wiley Periodicals, Inc.     

Microfluidic and computational study of structural properties and resistance to flow of blood clots under arterial shear

The ability of a blood clot to modulate blood flow is determined by the clot’s resistance, which depends on its structural features. For a flow with arterial shear, we investigated the characteristic patterns relating to clot shape, size, and composition on the one hand, and its viscous resistance, intraclot axial flow velocity, and shear distributions on the other. We used microfluidic technology to measure the kinetics of platelet, thrombin, and fibrin accumulation at a thrombogenic surface coated with collagen and tissue factor (TF), the key clot-formation trigger. We subsequently utilized the obtained data to perform additional calibration and validation of a detailed computational fluid dynamics model of spatial clot growth under flow. We then ran model simulations to gain insights into the resistance of clots formed under our experimental conditions. We found that increased thrombogenic surface length and TF surface density enhanced the bulk thrombin and fibrin generation in a nonadditive, synergistic way. The height of the platelet deposition domain—and, therefore, clot occlusivity—was rather robust to thrombogenic surface length and TF density variations, but consistently increased with time. Clot viscous resistance was non-uniform and tended to be higher in the fibrin-rich, inner “core” region of the clot. Interestingly, despite intraclot structure and viscous resistance variations, intraclot flow velocity variations were minor compared to the abrupt decrease in flow velocity around the platelet deposition region. Our results shed new light on the connection between the structure of clots under arterial shear and spatiotemporal variations in their resistance to flow.

     

Sucrose Synthase: Expanding Protein Function

Sucrose synthase (SUS: EC 2.4.1.13), a key enzyme in plant sucrose catabolism, is uniquely able to mobilize sucrose into multiple pathways involved in metabolic, structural, and storage functions. Our research indicates that the biological function of SUS may extend beyond its catalytic activity. This inference is based on the following observations: (a) tissue-specific, isoform-dependent and metabolically-regulated association of SUS with mitochondria and (b) isoform-specific and anoxia-responsive interaction of SUS with the voltage-dependent anion channel (VDAC), the major outer mitochondrial membrane protein. More recent work shows that both VDAC and SUS are also localized to the nucleus in maize seedling tissues. Their intricate regulation under anoxia indicates that these two proteins may have a role in inter-compartmental signaling.Key Words: sucrose synthase, mitochondria, nucleus, localization, voltage-dependent anion channel (VDAC), non-catalytic rolesThe biochemical function of a protein is encoded within its primary sequence and can often be deciphered by simple in vitro assays. The cellular or organismal function of a protein is frequently the same as its biochemical activity. However, for many proteins, the biological function cannot be easily derived based on its biochemical function. This appears to be particularly true when the gene encoding the protein has a history of duplication and is represented by a family of paralogs. In maize and other species, sucrose synthase (SUS) isoforms are almost identical in their catalytic properties.^1,2 However, the characteristic phenotypes of mutants in specific isoforms suggest that the isoforms contribute to vastly different organismal functions.^2–4 Our interest is to identify the range of functions that maize SUS isoforms may have and elucidate the molecular basis of this functional diversity. Although expression divergence and consequent variation in their cellular abundance significantly contributes to this diversity,⁵ other factors such as intracellular distribution, post-translational modifications and interacting partners,^3,4,6,7 seem to be equally critical for the functional diversification of different SUS isoforms.Our study, spurred by a bioinformatics prediction, opened up a new facet of SUS biology, in that the protein may have organelle-based functions.⁸ Our analysis indicated that two of the three maize SUS isoforms (SH1 and SUS1) partly localize to mitochondria and nuclei, compartments not related to sucrose metabolism. In addition to this isoform-specificity, the compartmentation of SUS isoforms is influenced by developmental as well as environmental cues. Furthermore, its isoform-specific interaction with the voltage-dependent anion channel (VDAC) and an apparent conservation of SUS mitochondrial targeting across plant species suggest that SUS may have novel, noncatalytic biological functions. Our recent work shows that along with SUS, VDAC is also localized to the nucleus and these two proteins are inversely regulated in these two compartments under anoxic stress, indicating SUS-VDAC interaction may play a role in inter-compartmental signaling (Fig. 1).Open in a separate windowFigure 1Current working model of SUS-VDAC interactions in maize root tip cells. Prolonged anoxia leads to de-oligomerization of VDAC and the release of SUS from mitochondria, resulting in the migration of SUS to the nucleus. We hypothesize that the nuclear accumulation of SUS signals the induction of cell death pathway leading to the death of the root tip in anoxic maize seedlings. The insets show the primary root tip and a part of the axis from aerobic and anoxic seedlings. The root tip death is indicated by Evans Blue staining pattern of the anoxic root. ≠ = SUS. □ = VDAC.SUS mitochondrial localization also provided us an opportunity to reinterpret the phylogeny of sucrose metabolism. The proposed origin of sucrose metabolism is equivocal between the proteobacterial and cyanobacterial lineages.^9,10 Our discovery of SUS inside mitochondria, absence of plastid-bound SUS or plastid-targeting information in any of the plant SUS proteins and occurrence of mitochondrial targeting information in proteobacterial SUS orthologs strongly support a proteobacterial origin of plant sucrose synthases.⁸ Based on a genome-wide analysis of E. coli proteins, Lucattini et al.¹¹ proposed that mitochondrial targeting information may have been derived from the preexisting sequences of the endosymbiont proteins. We hypothesize that, in addition to the structural features needed for mitochondrial association, the functional basis of SUS-VDAC interaction may have been recruited by plants from the prokaryotic SUS genes. Based on striking similarities between bacterial and mitochondrial porins in their structure as well as regulation by purine nucleotides and their role in the host-cell death as modulated by cellular ATP levels, Frade and Michaelidis¹² speculated that the eukaryotic programmed cell death may have been a consequence of acquiring aerobic metabolism via the endosymbiotic process. Is organellar SUS a part of this acquisition?     

Camptothecin analogs with bulky, hydrophobic substituents at the 7-position via a Grignard reaction

By developing a new synthetic procedure for introduction of side chains onto the camptothecin ring system, we were able to achieve the preparation of a number of analogs bearing bulky, hydrophobic groups directly attached to the 7-position. These include 7-tert-butylcamptothecin, 7-benzylcamptothecin and the corresponding 10,11-methylenedioxycamptothecins. This method involves the reaction of an appropriate orthoaminobenzonitrile with various Grignard reagents to give the corresponding orthoaminoketones. Friedlander condensation of the latter with the key tricyclic ketone leads to 7-substituted camptothecin analogs. We report the activity of these compounds as topoisomerase I poisons and their ability to inhibit growth of selected tumor cell lines.     

Systematic variation of amino acid substitutions for stringent assessment of pairwise covariation

During protein evolution, amino acids change due to a combination of functional constraints and genetic drift. Proteins frequently contain pairs of amino acids that appear to change together (covariation). Analysis of covariation from naturally occurring sets of orthologs cannot distinguish between residue pairs retained by functional requirements of the protein and those pairs existing due to changes along a common evolutionary path. Here, we have separated the two types of covariation by independently recombining every naturally occurring amino acid variant within a set of 15 subtilisin orthologs. Our analysis shows that in this family of subtilisin orthologs, almost all possible pairwise combinations of amino acids can coexist. This suggests that amino acid covariation found in the subtilisin orthologs is almost entirely due to common ancestral origin of the changes rather than functional constraints. We conclude that naturally occurring sequence diversity can be used to identify positions that can vary independently without destroying protein function.