The function of calcium in protein C activation by thrombin and the thrombin-thrombomodulin complex can be distinguished by mutational analysis of protein C derivatives.

Protein C activation is catalyzed on endothelium by a complex between thrombin and thrombomodulin. Ca2+ stimulates protein C activation in the presence, and inhibits in the absence, of thrombomodulin. Protein C has Asp residues at the P3 and P3' positions relative to the scissile bond at Arg169-Leu. To determine the contribution of these residues to the Ca2+ effect on activation, we have expressed human 4-carboxyglutamic acid (Gla)-domainless protein C and 3 mutants with Asp-->Gly substitutions at P3, P3', and both positions. Ca2+ interaction with the protein C derivatives was monitored by changes in intrinsic fluorescence, and the Ca2+ dependence of activation by thrombin and a complex of thrombin-thrombomodulin with a soluble thrombomodulin derivative (the fourth through sixth epidermal growth factor domains). The affinity for Ca2+ of the mutants was reduced 3-6-fold, which was reflected by a comparable change in the Ca2+ concentration required for the half-maximal rate of activation by the thrombin-thrombomodulin complex. However, Ca2+ no longer effectively inhibited activation of the mutants by thrombin alone. We conclude that 1) the Asp residues play a specific role in the Ca(2+)-dependent inhibition of protein C activation by thrombin; 2) these mutations alter the affinity of Ca2+ for the high affinity binding site; and 3) the Asp residues in the P3 and P3' sites do not contribute in a positive fashion to rapid activation by the thrombin-thrombomodulin complex.     

MaxHiC: A robust background correction model to identify biologically relevant chromatin interactions in Hi-C and capture Hi-C experiments

Hi-C is a genome-wide chromosome conformation capture technology that detects interactions between pairs of genomic regions and exploits higher order chromatin structures. Conceptually Hi-C data counts interaction frequencies between every position in the genome and every other position. Biologically functional interactions are expected to occur more frequently than transient background and artefactual interactions. To identify biologically relevant interactions, several background models that take biases such as distance, GC content and mappability into account have been proposed. Here we introduce MaxHiC, a background correction tool that deals with these complex biases and robustly identifies statistically significant interactions in both Hi-C and capture Hi-C experiments. MaxHiC uses a negative binomial distribution model and a maximum likelihood technique to correct biases in both Hi-C and capture Hi-C libraries. We systematically benchmark MaxHiC against major Hi-C background correction tools including Hi-C significant interaction callers (SIC) and Hi-C loop callers using published Hi-C, capture Hi-C, and Micro-C datasets. Our results demonstrate that 1) Interacting regions identified by MaxHiC have significantly greater levels of overlap with known regulatory features (e.g. active chromatin histone marks, CTCF binding sites, DNase sensitivity) and also disease-associated genome-wide association SNPs than those identified by currently existing models, 2) the pairs of interacting regions are more likely to be linked by eQTL pairs and 3) more likely to link known regulatory features including known functional enhancer-promoter pairs validated by CRISPRi than any of the existing methods. We also demonstrate that interactions between different genomic region types have distinct distance distributions only revealed by MaxHiC. MaxHiC is publicly available as a python package for the analysis of Hi-C, capture Hi-C and Micro-C data.     

The comparative study of the effects of Fe2O3 and TiO2 micro- and nanoparticles on oxidative states of lung and bone marrow tissues and colony stimulating factor secretion

Nowadays, increased use of nanomaterials in industry and biomedicine poses potential risks to human health and the environment. Studying their possible toxicological effects is therefore of great significance. The present investigation was designed to examine the status of oxidative stress induced by nanoparticles (NPs) of ferric oxide (Fe₂O ₃) and titanium oxide (TiO ₂) with their micro-sized counterpart on mouse lung and bone marrow–derived normal tissue cells. We assessed the induction of oxidative stress by measuring its indicators such as antioxidant scavenging activity of superoxide dismutase and catalase as well as malondialdehyde concentration. Moreover, colony formation of bone marrow cells was assayed following induction with colony stimulating factor (CSF) from lung cells. NPs had a more potent stimulatory effect on the oxidative stress status than their micron-sized counterparts. In addition, the highest level of oxidative stress derived from TiO ₂ NPs was observed in both tissue types. Cotreatment with NPs and the antioxidant α-tocopherol reduced antioxidant activities and membrane lipid peroxidation (LPO) in the lung cells, but increased CSF-induced colony formation activity of bone marrow cells, suggesting that oxidative stress may be the cause of the cytotoxic effects of NPs. It is concluded that free radicals generated following exposure to NPs resulted in significant oxidative stress in mouse cells, indicated by increased LPO and antioxidant enzyme activity and decreased colony formation.     

The Comparative Study of Gelatin/CNT-contained Mg-Ca-P Bone Cement with the Plain and CNT-reinforced Ones

Mimicking compositional and constructional features of the extracellular matrix(ECM)is an effective parameter in improving the biological response of biomateria...     

Reactivities of the S2 and S3 subsite residues of thrombin with the native and heparin-induced conformers of antithrombin.

A pentasaccharide (PS) fragment of heparin capable of activating antithrombin (AT) markedly accelerates the inhibition of factor Xa by AT, but has insignificant effect on inhibition of thrombin. For inhibition of thrombin, the bridging function of a longer polysaccharide chain is required to accelerate the reaction. To study the basis for the similar reactivity of thrombin with the native or heparin-activated conformers of AT, several residues surrounding the active site pocket of thrombin were targeted for mutagenesis study. Leu99 and Glu192, the variant residues influencing the S2 and S3 subsite specificity of thrombin were replaced with Tyr and Gln. The Tyr60a, Pro60b, Pro60c, and Trp60d residues forming part of the S2 specificity pocket were deleted from the B-insertion loop of the wild-type and Leu99/Glu192 --> Tyr/Gln thrombins. Kinetic studies indicated that the reactivities of all mutants with AT were moderately or severely impaired. Although heparin largely corrected the defect in reactivities, it also markedly elevated the stoichiometries of inhibition with the mutants. Interestingly, PS also accelerated AT inhibition of the mutants 5-68-fold, suggesting that the mutants are able to discriminate between the native and activated conformers of AT. Based on these results and the recent crystal structure determination of AT in complex with PS, a model for thrombin-AT interaction is proposed in which the S2 and S3 subsite residues of thrombin are critical for recognition of the P2 and P3 residues of AT in the native conformation. In the activated conformation, other residues are made accessible for interaction with the protease, and the similar reactivity of thrombin with the native and heparin-activated conformers of AT may be coincidental. The results further suggest that the S2 and S3 subsite residues are crucial in controlling the partitioning of the thrombin-AT intermediate into the alternative inhibitory or substrate pathways of the reaction.     

Role of basic residues of the autolysis loop in the catalytic function of factor Xa

The autolysis loop of factor Xa (fXa) has four basic residues (Arg(143), Lys(147), Arg(150), and Arg(154)) whose contribution to protease specificity of fXa has not been examined. Here, we substituted these basic residues individually with Ala in the fX cDNA and expressed them in mammalian cells using a novel expression/purification vector system. Following purification to homogeneity and activation by the factor X activator from Russell viper venom, the mutants were characterized with respect to their ability to assemble into the prothrombinase complex to activate prothrombin and interact with target plasma fXa inhibitors, tissue factor pathway inhibitor (TFPI) and antithrombin. We show that all mutants interacted with factor Va with normal affinities and exhibited wild-type-like prothrombinase activities toward prothrombin. Lys(147) and Arg(154) mutants were inhibited by TFPI approximately 2-fold slower than wild type; however, both Arg(143) and Arg(150) mutants were inhibited normally by the inhibitor. The reactivities of Arg(143) and Lys(147) mutants were improved approximately 2-fold with antithrombin in the absence but not in the presence of heparin cofactors. On the other hand, the pentasaccharide-catalyzed reactivity of antithrombin with the Arg(150) mutant was impaired by an order of magnitude. These results suggest that Arg(150) of the autolysis loop may specifically interact with the activated conformation of antithrombin.     

Autolysis loop restricts the specificity of activated protein C: analysis by FRET and functional assays

We previously demonstrated that the substitution of the autolysis loop (residues 143-154 in chymotrypsin numbering) of APC with the corresponding loop of trypsin (APC-Tryp 143-154) has no influence on the proteolytic activity of the protease toward fVa, however, this substitution increases the reactivity of APC with plasma inhibitors so that the mutant exhibits no anticoagulant activity in plasma. To further investigate the role of the autolysis loop in APC and determine whether this loop is a target for modulation by protein S, we evaluated the activity of APC-Tryp 143-154 toward fVa and several plasma inhibitors both in the absence and presence of protein S. Furthermore, we evaluated the active-site topography of APC-Tryp 143-154 by determining the average distance of the closest approach (L) between a fluorescein dye tethered to a tripeptide inhibitor, attached to the active-site of APC-Tryp 143-154, and octadecylrhodamine dyes incorporated into PCPS vesicles both in the absence and presence of protein S. The activity of APC-Tryp 143-154 toward fVa was identical to that of wild-type APC both in the presence and absence of protein S. However, the reactivity of APC-Tryp 143-154 with plasma inhibitors was preferentially improved independent of protein S. The FRET analysis revealed a dramatic change in the active-site topography of APC both in the absence and presence of protein S. Anisotropy measurements revealed that the fluorescein dye has a remarkable degree of rotational freedom in the active-site of APC-Tryp 143-154. These results suggest that the autolysis loop of APC may not be a target for modulation by protein S. This loop, however, plays a critical role in restricting both the specificity and spatial environment of the active-site groove of APC.     

Expression and purification of a soluble tissue factor fusion protein with an epitope for an unusual calcium-dependent antibody.

The use of bacterial signal peptides to target recombinant mammalian proteins to the periplasmic space of Escherichia coli (to promote proper disulfide bond formation) has met with variable success. We report the design and use of a bacterial expression vector to direct recombinant fusion proteins to the periplasmic space of E. coli: it contains the signal peptide from the pelB gene of Erwinia carotovora linked to a small peptide epitope for an unusual calcium-dependent antibody (HPC4). HPC4 binds to the epitope in a Ca(2+)-dependent manner, but the epitope itself does not bind Ca2+. We have used this system to express a biologically active, soluble form of tissue factor, the protein responsible for triggering the blood clotting cascade. Soluble tissue factor was secreted into the culture medium at 1-2 mg/liter, from which it could be readily purified using immobilized HPC4 antibody. The HPC4 epitope could be removed by digestion with thrombin or factor Xa, although a free amino terminus was not required for function since soluble tissue factor was equally active with the epitope still in place. This vector/epitope system permits large-scale expression and purification of recombinant soluble tissue factor and should be generally applicable to the isolation of other recombinant proteins. Furthermore, the epitope confers Ca(2+)-dependent binding of the fusion protein to HPC4 antibody while avoiding the creation of a new metal binding site on the fusion protein itself. Tb3+ can bind in this Ca2+ site near Trp, allowing this site to serve as a means of attaching a fluorescent probe to tissue factor.     

Cardioprotective role of extracellular vesicles: A highlight on exosome beneficial effects in cardiovascular diseases

Extracellular vesicles (EVs) are nano-sized vesicles, released from many cell types including cardiac cells, have recently emerged as intercellular communication tools in cell dynamics. EVs are an important mediator of signaling within cells that influencing the functional behavior of the target cells. In heart complex, cardiac cells can easily use EVs to transport bioactive molecules such as proteins, lipids, and RNAs to the regulation of neighboring cell function. Cross-talk between intracardiac cells plays pivotal roles in the heart homeostasis and in adaptive responses of the heart to stress. EVs were released by cardiomyocytes under baseline conditions, but stress condition such as hypoxia intensifies secretome capacity. EVs secreted by cardiac progenitor cells and cardiosphere-derived cells could be pinpointed as important mediators of cardioprotection and cardiogenesis. Furthermore, EVs from many different types of stem cells could potentially exert a therapeutic effect on the damaged heart. Recent evidence shows that cardiac-derived EVs are rich in microRNAs, suggesting a key role in the controlling of cellular processes. EVs harboring exosomes may be clinically useful in cell-free therapy approaches and potentially act as prognosis and diagnosis biomarkers of cardiovascular diseases.     

Identification of a binding site for quaternary amines in factor Xa

In the process of characterizing the Na(+)-binding properties of factor Xa, a specific inhibition of this enzyme by quaternary amines was identified, consistent with previous observations. The binding occurs with K(i) in the low millimolar range, with trimethylphenylammonium (TMPA) showing the highest specificity. Binding of TMPA inhibits substrate hydrolysis in a competitive manner, does not inhibit the binding of p-aminobenzamidine to the S1 pocket, and is positively linked to Na(+) binding. Inhibition by TMPA is also seen in thrombin and tissue plasminogen activator (tPA), though to a lesser extent compared to factor Xa. Computer modeling using the crystal structure of factor Xa suggests that TMPA binds to the S2/S3 specificity sites, with its hydrophobic moiety making van der Waals interactions with the side chains of Y99, F174, and W215, and the charged amine coupling electrostatically with the carboxylates of E97. Site-directed mutagenesis of factor Xa, thrombin, and tPA confirms the predictions drawn by docking calculations and reveal a dominant role for residue Y99. Binding of TMPA to factor Xa is drastically (25-fold) reduced by the Y99T replacement. Likewise, the Y99L substitution compromises binding of TMPA to tPA. On the other hand, the affinity of TMPA is enhanced 4-fold in thrombin with the substitution L99Y. The identification of a binding site for quaternary amines in factor Xa has a bearing on the rational design of selective inhibitors of this clotting enzyme.