The highly diverged trypanosomal MICOS complex is organized in a nonessential integral membrane and an essential peripheral module

The mitochondrial contact site and cristae organization system (MICOS) mediates the formation of cristae, invaginations in the mitochondrial inner membrane. The highly diverged MICOS complex of the parasitic protist Trypanosoma brucei consists of nine subunits. Except for two Mic10‐like and a Mic60‐like protein, all subunits are specific for kinetoplastids. Here, we determined on a proteome‐wide scale how ablation of individual MICOS subunits affects the levels of the other subunits. The results reveal co‐regulation of TbMic10‐1, TbMic10‐2, TbMic16 and TbMic60, suggesting that these nonessential, integral inner membrane proteins form an interdependent network. Moreover, the ablation of TbMic34 and TbMic32 reveals another network consisting of the essential, intermembrane space‐localized TbMic20, TbMic32, TbMic34 and TbMic40, all of which are peripherally associated with the inner membrane. The downregulation of TbMic20, TbMic32 and TbMic34 also interferes with mitochondrial protein import and reduces the size of the TbMic10‐containing complexes. Thus, the diverged MICOS of trypanosomes contains two subcomplexes: a nonessential membrane‐integrated one, organized around the conserved Mic10 and Mic60, that mediates cristae formation, and an essential membrane‐peripheral one consisting of four kinetoplastid‐specific subunits, that is required for import of intermembrane space proteins.     

Biosynthesis and properties of an extracellular thermostable serine alkaline protease from <Emphasis Type="Italic">Virgibacillus pantothenticus</Emphasis>

In this communication, we report the presence of a newly identified serine alkaline protease producing bacteria, Virgibacillus pantothenticus (MTCC 6729) in the fresh chicken meat samples and the factors affecting biosynthesis as well as characterization of protease. The strain produced only 14.3 U ml⁻¹ protease in the standard medium after 72 h of incubation, while in optimized culture conditions the production of protease was increased up to 18.2 U ml⁻¹. The strain was able to produce protease at 40°C at pH 9.0. The addition of dextrose and casein improved protease production. The protease was partially purified and characterized in terms of pH and temperature stability, effect of metal ions and inhibitors. The protease was found to be thermostable alkaline by retaining its 100% and 85% stability at pH 10.0 and at 50°C respectively. The protease was compatible with some of the commercial detergents tested, and was effective in removing protein stains from cotton fabrics. The V. pantothenticus, MTCC 6729 protease appears to be potentially useful as an additive in detergents as a stain remover and other bio-formulations.     

Fluorescence Resonance Energy Transfer Analysis of Merlin Conformational Changes

Neurofibromatosis type 2 is an inherited autosomal disorder caused by biallelic inactivation of the NF2 tumor suppressor gene. The NF2 gene encodes a 70-kDa protein, merlin, which is a member of the ezrin-radixin-moesin (ERM) family. ERM proteins are believed to be regulated by a transition between a closed conformation, formed by binding of their N-terminal FERM domain and C-terminal tail domain (CTD), and an open conformation, in which the two domains do not interact. Previous work suggests that the tumor suppressor function of merlin is similarly regulated and that only the closed form is active. Therefore, understanding the mechanisms that control its conformation is crucial. We have developed a series of probes that measures merlin conformation by fluorescence resonance energy transfer, both as purified protein and in live cells. Using these tools, we find that merlin exists predominately as a monomer in a stable, closed conformation that is mediated by the central α-helical domain. The contribution from the FERM-CTD interaction to the closed conformation appears to be less important. Upon phosphorylation or interaction with an effector protein, merlin undergoes a subtle conformational change, suggesting a novel mechanism that modulates the interaction between the FERM domain and the CTD.Neurofibromatosis type 2 is an inherited autosomal disorder that is characterized by bilateral schwannomas of the eighth cranial nerve. The tumor suppressor gene responsible for this disorder, NF2, was cloned in 1993 (45). Biallelic inactivation of the NF2 gene is also seen in spontaneous schwannoma, meningioma, and malignant mesothelioma (22). In mouse models, deletion of the Nf2 gene is embryonic lethal, indicating an essential role for NF2 in development (24). Heterozygous mice develop a variety of aggressive metastatic tumors that have lost the wild-type allele (23). Targeted deletion of the Nf2 gene in Schwann cells leads to schwannoma formation (7). In vitro, Nf2-null cells grow to significantly higher densities (31), suggesting that contact inhibition of growth is impaired in these cells and that mediation of growth arrest at high cell density may be the basis for the tumor suppressor function of the NF2 gene. In normal fibroblasts, merlin is inactive as a growth suppressor in subconfluent cells, becoming activated as they approach confluence, thereby effecting contact inhibition of growth (26).The NF2 gene encodes a 70-kDa protein called merlin (for moesin, ezrin, radixin-like protein), which shares significant homology with members of the ezrin-radixin-moesin (ERM) branch of the Band 4.1 superfamily (45). The domain structure of merlin, also shared with other ERM proteins, consists of an N-terminal FERM domain, followed by a central α-helical region (CH) and a C-terminal tail domain (CTD). The merlin FERM domain has relatively high sequence similarity with other ERM family members, a 60 to 70% identity over the first 300 amino acids. The CH domain and the CTD show much lower identity (28 to 36%); however, the α-helical character of the CH domain is preserved, as is the heptad repeat pattern typical of α-helices that form coiled coils (46).The critical point of regulation of all the ERM proteins is a high-affinity intramolecular interaction between the C-terminal domain and the FERM domain (4) (Fig. ​(Fig.1).1). The FERM domain folds into a three-lobed cloverleaf structure that acts as a multifaceted docking site for protein binding partners (16, 39). The CTD, consisting of four major and two minor helices and a beta sheet, binds to the FERM domain by extending across the face of the F2 and F3 lobes (32). This intramolecular head-to-tail binding results in a “closed” conformation, with the C-terminal domain covering much of the surface of the FERM domain (32, 44). For ezrin, radixin and moesin, the CTD functions as a mask, blocking access of effector molecules, such as the cell surface receptors CD44 and ICAM2 and adaptor molecules, like EBP50/NHERF, to sites on the surface of the FERM domain (11, 25, 44). The interaction between the CTD and FERM domain is regulated by phosphatidyl inositol-(4,5)-bisphosphate (PIP₂) binding to the FERM domain and by phosphorylation of a critical residue in the CTD (3, 6, 10, 49). This residue, threonine 567 in ezrin, is conserved throughout the ERM family (21). Phosphorylation introduces a negative charge and a bulky side group that effectively reduces the affinity of the interaction, releasing the CTD from the FERM domain and causing a transition to an open conformation. Low-angle rotary shadowing electron microscopy (13) and biochemical studies (12) of purified radixin suggest that in the open conformation it is an extended filamentous structure with globular N and C termini that is greater than 240 Å in length. Signal transduction systems, such as the epidermal growth factor and Rho A pathways, induce phosphorylation of ERM proteins at the conserved C-terminal threonine via a number of kinases, including Rho kinase and protein kinase Cα (21, 28). Thus, conformational regulation of ERM proteins can be a point of integration of ERM activity with signal transduction pathways. The overall concept of ERM regulation, then, is centered upon a transition between an inactive, closed conformation that is mediated by the FERM-CTD interaction and an active, open conformation that is regulated by phosphorylation. In these two states, ERM proteins likely interact with different sets of binding partners, resulting in distinct functional outcomes.Open in a separate windowFIG. 1.ERM tertiary structure as represented by the crystal structure of full-length Sf-moesin (20), but with the merlin amino acid sequence substituted for Sf-moesin. Approximate boundary amino acid residues for all domains appear at the top of the figure. Each domain is assigned a different color. The ERM structure consists of an N-terminal FERM domain folded into three lobes, F1, F2, and F3. This is followed by a central α-helical domain containing three subhelices (αA, αB, and αC) and a CTD with four short helices. An ERM protein is thought to have an open conformation, an extended structure with the FERM domain and the CTD separated by the α-helical domain, that is more than 240 Å long. In the closed conformation, the α-helical domain bends at the αA-αB junction and again at the αB-αC junction, causing the CTD to be positioned over F2 and F3 of the FERM domain. More than half of the surface of the FERM domain is masked by interaction with the CTD, αA, and parts of αB and αC.Like the classical ERMs, merlin is also thought to be regulated by changes in conformation. The FERM domain and the CTD of merlin interact with each other, albeit at a lower level of affinity than the ezrin FERM domain and the CTD (29). There are important differences, however, between merlin and the other ERM proteins. First, phosphorylation of the conserved C-tail threonine T576 has not been reported to occur in mammalian merlin, and nonphosphorylatable and phosphomimetic substitutions at this site have no effect on merlin activity (42). Instead, merlin is phosphorylated at serine 518 in the CTD, a target of the p21-activated kinase PAK and protein kinase A (1, 18, 47). The growth-suppressive function of merlin is activated by dephosphorylation of S518 by the phosphatase PP1δ in a density-dependent manner (14). Second, it was reported in a study using FERM domain and CTD truncates of merlin that only cotransfection of both the N-and C-terminal halves resulted in growth suppression (38). Together, these observations suggested a model of inactive, phosphorylated merlin in an open conformation that, upon cell-to-cell contact, is dephosphorylated and transitions to a closed, growth suppressive conformation.The existing model for conformational regulation described above is inferred from indirect data and assays that generally measure the interaction of isolated FERM and CTD truncates rather than full-length molecules (9, 29, 38). It has been impossible to test directly because tools have not been available to specifically assay for either the open or the closed form of merlin. Therefore, we have developed a series of probes that measures merlin conformation by fluorescence resonance energy transfer (FRET), both as purified protein and in live cells. Using these tools, we show that merlin exists predominately as a monomer in a stable, largely closed conformation. Additionally, we find that the closed conformation is largely mediated by the central α-helical domain; the contribution of the FERM-CTD interaction appears to be less significant than previously thought. Finally, we find that phosphorylation and protein interaction cause unexpectedly small changes in merlin conformation. We propose a new and more refined model for merlin regulation, in which merlin function is regulated by specific but subtle conformational changes that modulate the interaction between the FERM domain and the CTD.     

Mitochondrial Dysfunction in Rabies Virus-Infected Human and Canine Brains

Neurochemical Research - Rabies is a fatal encephalitis caused by the Rabies lyssavirus (RABV). The presence of minimal neuropathological changes observed in rabies indicates that neuronal...     

Verification of a virtual fields method to extract the mechanical properties of human optic nerve head tissues in vivo

We aimed to verify a custom virtual fields method (VFM) to estimate the patient-specific biomechanical properties of human optic nerve head (ONH) tissues, given their full-field deformations induced by intraocular pressure (IOP). To verify the accuracy of VFM, we first generated ‘artificial’ ONH displacements from predetermined (known) ONH tissue biomechanical properties using finite element analysis. Using such deformations, if we are able to match back the known biomechanical properties, it would indicate that our VFM technique is accurate. The peripapillary sclera was assumed anisotropic hyperelastic, while all other ONH tissues were considered isotropic. The simulated ONH displacements were fed into the VFM algorithm to extract back the biomechanical properties. The robustness of VFM was also tested against rigid body motions and noise added to the simulated displacements. Then, the computational speed of VFM was compared to that of a gold-standard stiffness measurement method (inverse finite element method or IFEM). Finally, as proof of principle, VFM was applied to IOP-induced ONH deformation data (obtained from one subject’s eye imaged with OCT), and the biomechanical properties of the prelamina and lamina cribrosa (LC) were extracted. From given ONH displacements, VFM successfully matched back the biomechanical properties of ONH tissues with high accuracy and efficiency. For all parameters, the percentage errors were less than 0.05%. Our method was insensitive to rigid body motions and was also able to recover the material parameters in the presence of noise. VFM was also found 125 times faster than the gold-standard IFEM. Finally, the estimated shear modulus for the prelamina and the LC of the studied subject’s eye were 33.7 and 63.5 kPa, respectively. VFM may be capable of measuring the biomechanical properties of ONH tissues with high speed and accuracy. It has potential in identifying patient-specific ONH biomechanical properties in the clinic if combined with optical coherence tomography.     

Synthesis and biology of bis-xylosylated dihydroxynaphthalenes

The 10 analogous bis-xylosylated dihydroxynaphthalenes have been synthesized and their chemical and biological properties investigated. The yield of the xylosylation reactions can be correlated to the electrostatic potential, and thus to the nucleophilicity, for the oxygen atoms of the dihydroxynaphthalenes. The bis-xylosylated compounds were more stable compared to the mono-xylosylated ones. They initiate priming of glycosaminoglycan chains to less extent but the priming proceeds in two directions. Contrary to the mono-xylosylated analogs, the tested compounds did not show any antiproliferative properties.     

Protein name tagging guidelines: lessons learned

Interest in information extraction from the biomedical literature is motivated by the need to speed up the creation of structured databases representing the latest scientific knowledge about specific objects, such as proteins and genes. This paper addresses the issue of a lack of standard definition of the problem of protein name tagging. We describe the lessons learned in developing a set of guidelines and present the first set of inter-coder results, viewed as an upper bound on system performance. Problems coders face include: (a) the ambiguity of names that can refer to either genes or proteins; (b) the difficulty of getting the exact extents of long protein names; and (c) the complexity of the guidelines. These problems have been addressed in two ways: (a) defining the tagging targets as protein named entities used in the literature to describe proteins or protein-associated or -related objects, such as domains, pathways, expression or genes, and (b) using two types of tags, protein tags and long-form tags, with the latter being used to optionally extend the boundaries of the protein tag when the name boundary is difficult to determine. Inter-coder consistency across three annotators on protein tags on 300 MEDLINE abstracts is 0.868 F-measure. The guidelines and annotated datasets, along with automatic tools, are available for research use.     

Advanced glycation end products enhance expression of pro-apoptotic genes and stimulate fibroblast apoptosis through cytoplasmic and mitochondrial pathways

Both aging and diabetes are characterized by the formation of advanced glycation end products (AGEs). Both exhibit other similarities including deficits in wound healing that are associated with higher rates of fibroblast apoptosis. In order to investigate a potential mechanism for enhanced fibroblast apoptosis in diabetes and aged individuals, experiments were carried out to determine whether the predominant advanced glycation end product in skin, N-epsilon-(carboxymethyl) lysine (CML)-collagen, could induce fibroblast apoptosis. In vivo experiments established that CML-collagen but not unmodified collagen induced fibroblast apoptosis and that apoptosis was dependent upon caspase-3, -8, and -9 activity. In vitro experiments demonstrated that CML-collagen but not control collagen induced a time- and dose-dependent increase in fibroblast apoptosis. By use of blocking antibodies, apoptosis was shown to be mediated through receptor for AGE signaling. AGE-induced apoptosis was largely dependent on the effector caspase, caspase-3, which was activated through both cytoplasmic (caspase-8-dependent) and mitochondrial (caspase-9) pathways. CML-collagen had a global effect of enhancing mRNA levels of pro-apoptotic genes that included several classes of molecules including ligands, receptors, adaptor molecules, mitochondrial proteins, and others. However, the pattern of expression was not identical to the pattern of apoptotic genes induced by tumor necrosis factor alpha.     

Spatial normalization of array-CGH data

Background  

Array-based comparative genomic hybridization (array-CGH) is a recently developed technique for analyzing changes in DNA copy number. As in all microarray analyses, normalization is required to correct for experimental artifacts while preserving the true biological signal. We investigated various sources of systematic variation in array-CGH data and identified two distinct types of spatial effect of no biological relevance as the predominant experimental artifacts: continuous spatial gradients and local spatial bias. Local spatial bias affects a large proportion of arrays, and has not previously been considered in array-CGH experiments.