Understanding the specificity of serpin–protease complexes through interface analysis

Serpins such as antithrombin, heparin cofactor II, plasminogen activator inhibitor, antitrypsin, antichymotrypsin, and neuroserpin are involved in important biological processes by inhibiting specific serine proteases. Initially, the protease recognizes the mobile reactive loop of the serpin eliciting conformational changes, where the cleaved loop together with the protease inserts into β-sheet A, translocating the protease to the opposite side of inhibitor leading to its inactivation. Serpin interaction with proteases is governed mainly by the reactive center loop residues (RCL). However, in some inhibitory serpins, exosite residues apart from RCL have been shown to confer protease specificity. Further, this forms the basis of multi-specificity of some serpins, but the residues and their dimension at interface in serpin-protease complexes remain elusive. Here, we present a comprehensive structural analysis of the serpin-protease interfaces using bio COmplexes COntact MAPS (COCOMAPS), PRotein Interface Conservation and Energetics (PRICE), and ProFace programs. We have carried out interface, burial, and evolutionary analysis of different serpin-protease complexes. Among the studied complexes, non-inhibitory serpins exhibit larger interface region with greater number of residue involvement as compared to the inhibitory serpins. On comparing the multi-specific serpins (antithrombin and antitrypsin), a difference in the interface area and residue number was observed, suggestive of a differential mechanism of action of these serpins in regulating their different target proteases. Further, detailed study of these multi-specific serpins listed few essential residues (common in all the complexes) and certain specificity (unique to each complex) determining residues at their interfaces. Structural mapping of interface residues suggested that individual patches with evolutionary conserved residues in specific serpins determine their specificity towards a particular protease.     

Gibbs ensemble Monte Carlo simulations of binary vapour–liquid–liquid equilibrium: application to n-hexane–water and ethane–ethanol systems

Gibbs ensemble Monte Carlo (GEMC) simulations in the isochoric–isothermal (NVT) ensemble were used to simulate vapour–liquid–liquid equilibrium (VLLE) for binary n-hexane–water and ethane–ethanol mixtures. The GEMC simulation of binary VLLE data proved to be extremely difficult and that is probably the reason why the open literature is so sparse with simulations for these types of systems. The results presented in this paper are to our knowledge the first successful binary three-phase GEMC simulations of non-idealised fluid systems. This paper also shows that the isobaric–isothermal (NPT) ensemble is unsuitable for the simulation of phase equilibria of binary three-phase systems.     

Liquid-surface immobilization system and liquid–liquid interface bioreactor: Application to fungal hydrolysis

Novel fungal cultivation and bioconversion systems are proposed. Spores and mycelia of a fungus suspended in a liquid medium were effectively floated on a liquid surface by the aid of a ballooned microsphere (MS). Many fungi such as Aspergillus and Penicillium formed a thick and physically strong fungus-MS mat on the liquid surface followed by stationary cultivation (LSI). The fungus-MS mat of Absidia coerulea IFO 4423 was overlaid by a solution of 2-ethylhexyl acetate (1) in n-decane (liquid–liquid interface bioreactor, L-L IBR). The strain could efficiently catalyze the hydrolysis of 1 to 2-ethyl-1-hexanol (2). The accumulation of 2 in the L-L IBR was significantly higher than those in emulsion and organic-aqueous two-liquid-phase systems and a formerly reported interface bioreactor (solid–liquid interface bioreactor, S-L IBR). Furthermore, lipase production in the LSI system was also higher than that in a submerged cultivation system.     

Monte Carlo simulations of vapour–liquid phase equilibrium and microstructure for the system containing azeotropes

Abstract

Phase equilibrium data of the mixtures including alcohols, esters and organic acids are of first interest particularly to design and optimise biodiesel production and reactive distillation processes. In this work, vapour–liquid phase equilibrium of these systems was simulated at low pressure using Gibbs ensemble Monte Carlo method. All Lennard–Jones parameters of pseudo-atoms involved in the systems were derived from previous parametrisations of TraPPE-UA force field. The Fourier coefficients of dihedrals encountered in ethyl acetate molecule have been obtained from the quantum calculations. Using this force field, temperature-composition diagrams are well reproduced for ethyl acetate + ethanol, ethyl acetate + methanol at 70.00 kPa and ethyl acetate + acetic acid mixtures at 77.33 kPa. The transferability of this force field to mixtures in these systems is noticeable. Analysis of the microstructure for the ethyl acetate + ethanol and ethyl acetate + acetic acid mixtures was presented. We found that the hydrogen bond networks consist of autoassociation and cross-association and autoassociation occupies the main position as compared with cross association in the ethyl acetate + ethanol mixture. OC_HAc–H_HAc and OC_EtOAc–H_HAc hydrogen bond interactions play a significant role in the phase behaviours or structures of ethyl acetate + acetic acid mixture.     

Air–liquid and liquid–liquid interfaces influence the formation of the urothelial permeability barrier in vitro

Optimizing culture conditions is known to be crucial for the differentiation of urothelial cell cultures and the formation of the permeability barrier. However, so far, no data exist to confirm if air–liquid (AL) and liquid–liquid (LL) interfaces are physiologically relevant during urothelial differentiation and barrier formation. To reveal the influence of interfaces on the proliferation, differentiation, and barrier formation of the urothelial cells (UCs) in vitro, we cultured UCs under four different conditions, i.e., at the AL or LL interfaces with physiological calcium concentration and without serum or without physiological calcium concentration and with serum. For each of the four models, the urothelial integrity was tested by measuring the transepithelial resistance (TER), and the differentiation stage was examined by immunolabeling of differentiation-related markers and ultrastructural analysis. We found that the UCs at a LL interface, regardless of the presence or absence of calcium or serum, form the urothelium with more cell layers and achieve a higher TER than UCs at an AL interface. However, UCs grown at an AL interface with physiological concentration of calcium in medium form only one- to two-layered urothelium of UCs, which are larger and express more differentiation-related proteins uroplakins than UCs in other models. These results demonstrate that the interface itself can play a major, although so-far neglected, role in urothelial physiology, particularly in the formation of the urothelial permeability barrier in vitro and the regulatory mechanisms related with urothelial differentiation. In the study, the culturing of UCs in three successive steps is proposed.     

Probing the equilibrium unfolding of ketosteroid isomerase through xenon-perturbed 1H–15N multidimensional NMR spectroscopy

We used xenon-perturbed ¹H–¹⁵N multidimensional NMR to investigate the structural changes in the urea-induced equilibrium unfolding of the dimeric ketosteroid isomerase (KSI) from Pseudomonas putida biotype B. Three limited regions located on the β3-, β5- and β6-strands of dimeric interface were significantly perturbed by urea in the early stage of KSI unfolding, which could lead to dissociation of the dimer into structured monomers at higher denaturant concentration as the interactions in these regions are weakened. The results indicate that the use of xenon as an indirect probe for multidimensional NMR can be a useful method for the equilibrium unfolding study of protein at residue level.     

Amphisomes: out of the autophagosome shadow?

EMBO J (2013) 32: 3130–3144 doi: 10.1038/emboj.2013.233; published online November012013Amphisomes are intermediate organelles, formed during autophagy through the fusion between autophagosomes and endosomes. Complex multivesicular vacuoles that resemble amphisomes have been observed in various cell types, but whether they have cellular roles other than being a precursor structure is still enigmatic. While autophagy-related (ATG) proteins interact with the endocytic pathways in other processes different from autophagy, Patel and colleagues now report that these factors come together to generate amphisome-like compartments that regulate mucin secretion in goblet cells.ATG and endosomal proteins have been linked to secretion, and the specific loss of them impairs the function of different secretory cell types (Jung et al, 2008; DeSelm et al, 2011; Ushio et al, 2011; Sasidharan et al, 2012). ATG proteins have also been shown to interact with the endocytic pathway in few situations that do not involve autophagy. For example in phagocytic cells, the surface of bacteria-containing phagosomes acquires LC3/Atg8 through the concerted action of a subpopulation of ATG proteins. This process, which has been termed LC3-associated phagocytosis (LAP), promotes the fusion of phagosomes with lysosomes (Sanjuan et al, 2007). Something similar occurs during entotic cell death, an engulfment programme leading to the elimination of cells into lysosomes. The entotic vacuole membranes surrounding the internalized cells also recruit LC3 through a mechanism that depends on several ATG proteins, but not on autophagosome formation (Florey et al, 2011).In their work aimed to understand the function of ATG proteins in goblet cells, Patel et al (2013) show that the autophagy and endocytic machinery converge at the amphisomes to promote the secretion of mucins. In the gastrointestinal tract, secretory cells have a crucial role in providing the mucus barrier that protects against intestinal pathogens. Mucins, the main components of the mucus, are produced in goblet cells where large polymers of these highly glycosylated proteins are packed into secretory granules that accumulate at the apical surface. The release of these mucin granules relies on a series of cellular events that are tightly coordinated. Patel et al (2013) show that knockout mice lacking ATG5 in the intestinal epithelium, that is, Atg5VC mice, exhibit both a dramatic accumulation of mucin granules in goblet cells and a diminished mucus secretion. Taking advantage of a newly developed in vitro system to culture and differentiate intestinal epithelial stem cells into secretory goblet cells, the authors also demonstrate that the ablation of other ATG proteins causes the same phenotype showing that the autophagy machinery is required for mucin secretion in these specialized cells (Patel et al, 2013). Interestingly, ATG proteins affect the functionality of another gastrointestinal secretory lineage, the Paneth cells. Paneth cells homozygous for the atg16L1 risk allele, associated with Crohn disease, produce less secretory granules than in controls (Cadwell et al, 2008). This suggests that although ATG proteins regulate secretion in the two most abundant secretory lineages in the intestinal tract, two different mechanisms are probably involved.A microarray analysis of mRNA from Atg5VC mouse colonic epithelial cells revealed a possible alteration in the endocytic pathway. Indeed, blocking endocytosis also provoked an accumulation of mucin granules. While LC3B has been previously found on the surface of secretory granules (Ushio et al, 2011; Ishibashi et al, 2012), immuno-electron microscopy of wild-type mouse intestinal tissue revealed a distribution of LC3B not on mucin granules, but on multivesicular vacuoles positive for several endosomal proteins (Patel et al, 2013). Because of the morphological and molecular characteristics of these compartments, it appears that the ATG proteins together with the endocytic pathway regulate secretion in goblet cells by converging in what could be a new amphisome-like organelle (Figure 1).Open in a separate windowFigure 1Schematic representation for the regulated secretion of mucin granules by amphisome-like structures in goblet cells. ROS generated by NADPH oxidases promote the fusion of LC3-positive vesicles with endosomes marked by Rab5 and containing the NADPH oxidase subunit p22phox. The resulting amphisomes-like organelles are decorated with LC3, endosomal proteins (Rab5, Rab7 and EEA1) and p22phox and localize near the mucin granules. The formation of these copartments probably prolong and/or enhance the production of ROS by the NADPH oxidase, which in turn increases the levels of cytoplasmic calcium through an unknown mechanism leading to the release of the mucin granules.NADPH oxidases are known to be present in endosomes, and NADPH oxidase-generated reactive oxygen species (ROS) are necessary for LC3 recruitment to phagosomes.(Huang et al, 2009). Patel et al (2013) thus explored whether these enzymes played a role in mucin granule secretion in goblet cells. Indeed, expression of a mutant form of p22phox, a transmembrane subunit of several NADPH oxidase complexes, altered the exocytosis of these carriers. Moreover, p22phox was found to localize to Rab5-positive endosomes and also with the observed amphisome-like structures (Figure 1). Because a mutant form of p22phox also caused a misslocalization of both LC3 and the early-endosomal marker protein EEA1, the obvious conclusion was that ROS production by endosomes is necessary to trigger the formation of the amphisome-like organelles via the acquisition of the ATG machinery (Figure 1). Interestingly, addition of H₂O₂ that mimics ROS generation was able to induce mucin granule exocytosis in the p22phox mutant cells, showing that ROS was also required to regulate secretion in goblet cells (Patel et al, 2013). Furthermore, H₂O₂ bypassed as well the mucin granule secretion defect in autophagy and endocytosis-deficient goblet cells through an increase of cytosolic calcium levels (Patel et al, 2013). This, together with the observation that the loss of ATG5 and the block of the endocytic pathway impair the production of ROS has led Patel et al (2013) to propose that amphisome-like organelles are a signalling platform, where NADPH oxidase-driven ROS production promotes the release of the mucin granules.Amphisomes have been characterized and defined as autophagic vacuoles formed upon fusion between autophagosomes and endosomes. Given that ATG and endosomal proteins converge in multivesicular and/or vacuolar compartments resembling amphisomes in cellular processes independent of autophagy, one could consider to use the term amphisomes to describe a more heterogenous and ampler population of unnamed compartments where part of the autophagy and endosomal machineries co-localize. Based on this consideration, the study by Patel et al (2013) has identified an amphisome-like structure where molecular events interconnect to trigger granule secretion. While their work adds to the still limited number of non-degradative roles of the autophagic pathway, which include unconventional secretion (Subramani and Malhotra, 2013), it is one of the first reports highlighting that amphisomes (or any autophagosomal intermediate structure) could be more than just a transport intermediate, and at least in goblet cells, they could act as a platform where signals integrating some aspects of the cell physiology are elicited.Though it remains to be establish whether the organelles described by Patel et al (2013) are indeed amphisomes, especially as they are formed by fusion of endosomes with LC3-positive single-membrane vesicles rather than LC3-positive double-membrane autophagosomes, their study raises some intriguing questions. Are these compartments persistent or will they eventually fuse with lysosomes? Why has the cell opted to signal from amphisomes and not from endosomes, where the NADPH oxidases are normally present? Maybe the answer to these questions is hidden in the transient life of amphisomes. In the most classical signalling pathways, the transduction cascade amplifies the initial cue but it also turn it off subsequently through negative feedback loops. This permits to precisely modulate the signal output temporally (and locally). The amphisome-like structures observed in goblet cells could also act as the molecular switch for the signal-stimulating mucin granule secretion. The ROS generated initially from endosomes would trigger the recruitment of LC3 through vesicle fusion events, and the production of this second messenger will be prolonged and/or enhanced in the resulting amphisomes-like structure, leading to a stimulation of mucin granule exocytosis (Figure 1). The subsequent fusion of the amphisomes with lysosomes could lead to the termination of the signal. Other scenarios, however, cannot be excluded like, for example, the delivery of a protein enhancing the NADPH oxidase activity to the endosomes by the LC3-positive vesicles.While these are just hypotheses, it is clear that Patel et al (2013) have opened a window on a new and unexplored area of the autophagy field. Future investigations will tell us whether what observed in goblet cells is a unique situation or the intermediate organelles characterizing autophagy can carry out cellular functions different from the one delivering unwanted structures into the lysosome interior for degradation, including to serve as signalling platforms.     

Comparison of simple perturbation-theory estimates for the liquid–solid and the liquid–vapor interfacial free energies of Lennard-Jones systems

The most naive perturbation method to estimate interfacial free energies is based on the assumption that the interface between coexisting phases is infinitely sharp. Although this approximation does not yield particularly accurate estimates for the liquid–vapor surface tension, we find that it works surprisingly well for the interface between a dense liquid and a solid. As an illustration we estimate the liquid–solid interfacial free energy of a Lennard-Jones system with truncated and shifted interactions and compare the results with numerical data that have been reported in the literature. We find that the agreement between theory and simulation is excellent. In contrast, if we apply the same procedure to estimate the variation of the liquid–vapor surface tension, for different variants of the Lennard-Jones potential (truncated/shifted/force-shifted), we find that the agreement with the available simulation data is, at best, fair. The present method makes it possible to obtain quick and easy estimate of the effect on the surface free energy of different potential-truncation schemes used in computer simulations.     

Radial liquid distribution in gas–liquid concurrent downflow through packed beds

Radial liquid velocity profiles under concurrent air-water downflow through a packed bed containing cylinders were experimentally obtained at different flow rates of both the phases. The variation in liquid velocity with radial position of the column was estimated. A simple correlation for predicting the liquid phase velocity in terms of single phase velocities of gas and liquid, and dynamic liquid saturation was proposed.     

Fluid–structure interactions in micro-interlocked regions of the cement–bone interface

Experimental tests and computational modelling were used to explore the fluid dynamics at the trabeculae–cement interlock regions found in the tibial component of total knee replacements. A cement–bone construct of the proximal tibia was created to simulate the immediate post-operative condition. Gap distributions along nine trabeculae–cement regions ranged from 0 to 50.4 μm (mean = 12 μm). Micro-motions ranged from 0.56 to 4.7 μm with a 1 MPa compressive load to the cement. Fluid–structure analysis between the trabeculae and the cement used idealised models with parametric evaluation of loading direction, gap closing fraction (GCF), gap thickness, loading frequency and fluid viscosity. The highest fluid shear stresses (926 Pa) along the trabecular surface were found for conditions with very thin and large GCFs, much larger than reported physiological levels (～1–5 Pa). A second fluid–structure model was created with a provision for bone resorption using a constitutive model with resorption velocity proportional to fluid shear rate. A lower cut-off was used, below which bone resorption would not occur (50 s^? 1). Results showed that there was initially high shear rates (>1000 s^? 1) that diminished after initial trabecular resorption. Resorption continued in high shear rate regions, resulting in a final shape with bone left deep in the cement layer, and is consistent with morphology found in post-mortem retrievals. Small gaps between the trabecular surface and the cement in the immediate post-operative state produce fluid flow conditions that appear to be supra-physiologic; these may cause fluid-induced lysis of trabeculae in the micro-interlock regions.     

Liquid–vapour interface varying the softness and range of the interaction potential

Molecular dynamics simulations in a canonical ensemble were carried out for simple fluids. The inter-particles interaction law is described by the Morse function plus a repulsive term. This kind of combination allows to tune the repulsive term of the interaction function by fitting the range of the attractive well and vice versa. As a relevant result, we show that for an inhomogeneous system the particle softness affects the vapour pressure, the surface tension and also the equilibrium densities of a simple fluid. Lower numerical values for these same properties were obtained by using a more repulsive interaction potential. The differences among these same interfacial properties are bigger when the range of the attractive interaction is longer. The surface tension written in terms of the corresponding critical parameters, such as scaled surface tension, was plotted for different softness degrees. And from this comparison, a unique master curve was not found.     

Connecting the typology and semantics of nominal possession: alienability splits and the morphology–semantics interface

Approaching possession as a phenomenon of the morphology–semantics interface, this paper combines two major perspectives, namely the typological and the semantic perspective. It offers a comprehensive approach that bears on the contrast of semantic and pragmatic possession. After portraying the most essential morphosyntactic strategies of split possession, the lexical distinction of nominal concept types and the resulting representation of non-relational and relational nouns is presented, following the theory of Löbner (2011). This allows to explain the use of a certain construction for a given noun by the mapping of lexical semantics to morphosyntactic realisation.Semantic possession is understood as involving a relation that is inherent to the meaning of the possessed noun, in the sense that the referent of the noun can only be established if the possessor is specified. In contrast, pragmatic possession implies that the relation POSS is established by the context rather than by the lexical semantics. This opposition enables a fresh look at the morphology of nominal possession under which the notion of (in)alienability is reinterpreted. The morphology of alienable constructions is analysed as establishing pragmatic possession by denoting an operation that shifts the head noun from a sortal to a relational concept. Thus, the innovation of the approach lies in its typologically justified radically compositional nature. It is shown in detail how this general methodical strategy accounts for all essential morphosyntactic oppositions known from the typology of nominal possession.     

Emerging roles of low-molecular-weight thiols at the host–microbe interface

Low-molecular-weight (LMW) thiols are an abundant class of cysteine-derived small molecules found in all forms of life that maintain reducing conditions within cells. While their contributions to cellular redox homeostasis are well established, LMW thiols can also mediate other aspects of cellular physiology, including intercellular interactions between microbial and host cells. Here we discuss emerging roles for these redox-active metabolites at the host–microbe interface. We begin by providing an overview of chemical and computational approaches to LMW-thiol discovery. Next, we highlight mechanisms of virulence regulation by LMW thiols in infected cells. Finally, we describe how microbial metabolism of these compounds may influence host physiology.     

Reverse zoonosis of influenza to swine: new perspectives on the human–animal interface

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A nonlinear homogenized finite element analysis of the primary stability of the bone–implant interface

Stability of an implant is defined by its ability to undergo physiological loading–unloading cycles without showing excessive tissue damage and micromotions at the interface. Distinction is usually made between the immediate primary stability and the long-term, secondary stability resulting from the biological healing process. The aim of this research is to numerically investigate the effect of initial implantation press-fit, bone yielding, densification and friction at the interface on the primary stability of a simple bone–implant system subjected to loading–unloading cycles. In order to achieve this goal, human trabecular bone was modeled as a continuous, elasto-plastic tissue with damage and densification, which material constants depend on bone volume fraction and fabric. Implantation press-fit related damage in the bone was simulated by expanding the drilled hole to the outer contour of the implant. The bone–implant interface was then modeled with unilateral contact with friction. The implant was modeled as a rigid body and was subjected to increasing off-axis loading cycles. This modeling approach is able to capture the experimentally observed primary stability in terms of initial stiffness, ultimate force and progression of damage. In addition, it is able to quantify the micromotions around the implant relevant for bone healing and osseointegration. In conclusion, the computationally efficient modeling approach used in this study provides a realistic structural response of the bone–implant interface and represents a powerful tool to explore implant design, implantation press-fit and the resulting risk of implant failure under physiological loading.     

Review: transport of tRNA out of the nucleus-direct channeling to the ribosome?

Although tRNA was the first substrate whose export from the nuclei of eukaryotic cells had been shown to be carrier-mediated and active, it has only been in the last 2 years that the first mechanistic details of this nucleocytoplasmic transport pathway have begun to emerge. A member of the importin/karyopherin beta superfamily, Los1p in yeast and Xpo-t in vertebrates, has been shown to export tRNA in cooperation with the small GTPase Ran (Gsp1p) from the nucleus into the cytoplasm, where tRNA becomes available for translation. However, Los1p is not essential for viability in yeast cells, suggesting that alternative tRNA export pathways exist. Recent results show that aminoacylation and a translation factor are also required for efficient nuclear tRNA export. Thus, protein translation and nuclear export of tRNA appear to be coupled processes.     

Influence of polymer structure on adsorption behavior at solid–liquid interface by Monte Carlo simulation

Monte Carlo simulations for the adsorption of polymers including random copolymer, homopolymer, diblock copolymer and two kinds of triblock copolymers, respectively, in nonselective solvent at solid–liquid interface have been performed on a simple lattice model. The effect of polymer structure on adsorption properties was examined. In simulations, all polymeric molecules are modeled as self-avoiding linear chains composed of two segments A and B while A is attractive to the surface and B is non-attractive. It was found that for all polymers, the size distribution of various configurations is determined by the linked sequence of segments and the interaction energy between segment and surface. The results of simulation show that the adsorbed amount always increases with increasing bulk concentration but the adsorption layer thickness is mostly dependent on the adsorption energy at a fixed fraction of segments A. On the other hand, diblock copolymer has always the highest surface coverage and adsorbed amount, while random copolymers and homopolymers give generally the smallest surface coverage and adsorbed amount. It is shown that the sequence of polymer chains, i.e. molecular structure, is the most important factor in affecting adsorption properties at the same composition and interaction between segment and surface. The results also show that the adsorption behavior of random copolymers is remarkably different from that of block copolymers, but acting like homopolymer.