Factor h and properdin recognize different epitopes on renal tubular epithelial heparan sulfate

During proteinuria, renal tubular epithelial cells become exposed to ultrafiltrate-derived serum proteins, including complement factors. Recently, we showed that properdin binds to tubular heparan sulfates (HS). We now document that factor H also binds to tubular HS, although to a different epitope than properdin. Factor H was present on the urinary side of renal tubular cells in proteinuric, but not in normal renal tissues and colocalized with properdin in proteinuric kidneys. Factor H dose-dependently bound to proximal tubular epithelial cells (PTEC) in vitro. Preincubation of factor H with exogenous heparin and pretreatment of PTECs with heparitinase abolished the binding to PTECs. Surface plasmon resonance experiments showed high affinity of factor H for heparin and HS (K(D) values of 32 and 93 nm, respectively). Using a library of HS-like polysaccharides, we showed that chain length and high sulfation density are the most important determinants for glycosaminoglycan-factor H interaction and clearly differ from properdin-heparinoid interaction. Coincubation of properdin and factor H did not hamper HS/heparin binding of one another, indicating recognition of different nonoverlapping epitopes on HS/heparin by factor H and properdin. Finally we showed that certain low anticoagulant heparinoids can inhibit properdin binding to tubular HS, with a minor effect on factor H binding to tubular HS. As a result, these heparinoids can control the alternative complement pathway. In conclusion, factor H and properdin interact with different HS epitopes of PTECs. These interactions can be manipulated with some low anticoagulant heparinoids, which can be important for preventing complement-derived tubular injury in proteinuric renal diseases.     

Redescription of <Emphasis Type="Italic">Gaeolaelaps deinos</Emphasis> (Acari: Mesostigmata): an ant-associated laelapid mite

In this paper, we redescribe Gaeolaelaps deinos (Zeman 1982) based on morphological characters of female and male specimens collected from nests of Lasius sp. (Hymenoptera: Formicidae) Khuzestan and Chaharmahal va Bakhtiari Provinces, Iran, and based on its holotype photos. We also present an identification key for Gaeolaelaps aculeifer-like species group from Iran.     

Somatic mutations contribute to genotypic diversity in sterile and fertile populations of the threatened shrub, Grevillea rhizomatosa (Proteaceae)

Background and Aims

Grevillea rhizomatosa is a spreading shrub which exhibits multiple breeding strategies within a narrow area in the fire-prone heathlands of eastern Australia. Reproductive strategies include self-compatibility, self-incompatibility and clonality (with and without sterility). The close proximity of contrasting breeding systems provides an opportunity to explore the evolution of sterility and to compare and contrast the origins of genotypic diversity (recombinant or somatic) against degrees of sexual expression.

Methods

ISSR markers for 120 band positions (putative loci) were used to compare genetic diversity among five populations at a macro-scale of 5 m between samples (n = 244 shrubs), and at a micro-scale of nearest neighbours for all plants in five 25-m² quadrats with contrasting fertilities (n = 162 shrubs). Nearest-neighbour sampling included several clusters of connected ramets. Matrix incompatibility (MIC) analyses were used to evaluate the relative contribution of recombination and somatic mutation to genotype diversity.

Key Results

High levels of genotypic diversity were found in all populations regardless of fertilities (fertile populations, G/N ≥ 0·94; sterile populations, G/N ≥ 0·97) and most sterile populations had a unique genetic profile. Somatic mutations were detected along connected ramets in ten out of 42 ramet clusters. MIC analyses showed that somatic mutations have contributed to diversity in all populations and particularly so in sterile populations.

Conclusions

Somatic mutations contribute significantly to gene diversity in sterile populations of Grevillea rhizomatosa, the accumulation of which is the likely cause of male and female sterility. High levels of genetic diversity therefore may not always be synonymous with sexual fitness and genetic health. We hypothesize that frequent fires drive selection for clonal reproduction, at the cost of flowering such that sexual functions are not maintained through selection, and the build-up of somatic mutations in meristems results in high genotype diversity at the cost of pollen and ovule fertilities.     

Identifying Ca2+-Binding Sites in Proteins by Liquid Chromatography-Mass Spectrometry Using Ca2+-Directed Dissociations

Here we describe a new method to identify calcium-binding sites in proteins using high-resolution liquid chromatography-mass spectrometry in concert with calcium-directed collision-induced dissociations. Our method does not require any modifications to the liquid chromatography-mass spectrometry apparatus, uses standard digestion protocols, and can be applied to existing high-resolution MS data files. In contrast to NMR, our method is applicable to very small amounts of complex protein mixtures (femtomole level). Calcium-bound peptides can be identified using three criteria: (1) the calculated exact mass of the calcium containing peptide; (2) specific dissociations of the calcium-containing peptide from threonine and serine residues; and (3) the very similar retention times of the calcium-containing peptide and the free peptide.Calcium-dependent protein interactions mostly organized in protein networks are responsible for the regulation of cell cycle progression, cell growth, differentiation, secretion, and cytoskeletal organization (1–3). As many of these proteins are linked to various pathological conditions, they are clinically important. The speed at which calcium can have an interplay between various cellular components is impressive and comes notably detectable in neurological processes and in muscle contraction. Calcium binding sites in proteins can be determined by NMR spectroscopy (4, 5). For example, by such NMR measurements, the Ca²⁺-binding sites of the tellurite-resistance protein TerD from Klebsiella pneumoniae were found to be formed in part by a highly conserved motif of 13 residues specified by the sequence GDN(R/L)TG(E/A)GDGDDE (4).Although NMR is the gold standard to study calcium binding in proteins, this approach has several drawbacks. For instance, protein size is limited (< 30 kDa) and proteins should be pure and isotopically labeled. In addition, although the information content is high, NMR is relatively insensitive compared with other techniques such as MS and fluorescence spectroscopy, and relatively large quantities of material (typically 0.5 ml at 0.5–1.0 mm in biological samples) are needed, although efforts are devoted to improve sensitivity in NMR, such as stripline NMR (6).In bottom-up proteomics, proteolytic peptides, generated by enzymatic digestion of complex protein mixtures, are sequenced by MS-based methods (MS/MS (7, 8)) using collision-induced dissociations. Because of the even higher complexity of these peptide mixtures, liquid chromatography (LC)¹ is used to separate the peptides prior to sequencing. In such an LC-MS/MS procedure, many peptides can be identified belonging to the same protein. It has been stated (9) that by this procedure more peptides are analyzed than strictly necessary for identification purposes, but it can equally well be argued that such large coverages enable more reliable protein identifications; moreover, these larger coverages allow the detection of post-translational modifications, including specific calcium complexation as described here.Considering the need of identifying calcium-bound proteins in complex biological samples at low concentrations, we set out to develop a novel method for detecting Ca²⁺-binding sites in proteins based on LC-MS.     

Microbial imprinted polypyrrole/poly(3-methylthiophene) composite films for the detection of Bacillus endospores

The fabrication of Bacillus subtilis endospore imprinted conducting polymer films and subsequent electrochemical detection of bound spores is reported. Imprinted films were prepared by absorbing spores on the surface of glassy carbon electrodes upon which a polypyrrole, followed by a poly(3-methylthiophene), layer were electrochemically deposited. Spore template release was achieved through soaking the modified electrode in DMSO. Binding of endospores to imprinted films could be detected via impedance spectroscopy by monitoring changes in Y' (susceptance) using Mn(II)Cl2 (0.5M pH 3) as the supporting electrolyte. Here, the change in Y' could be correlated to spore densities between 10(4) and 10(7)cfu/ml. More sensitive detection of absorbed spores was achieved by following endospore germination via changes in film charge as measured using cyclic voltammetry. Here, imprinted films were submerged in spore suspensions to permit absorption, heat activated at 70 degrees C for 10 min prior to transferring to an electrochemical cell containing germination activators. By using the assay format it was possible to detect 10(2)cfu/ml. The observed changes in film charge could be attributed to the interaction of the supporting conducting polymer with dipicolinic acid (DPA) and other constituents released from the core in the course of germination. In all cases, it was not possible to regenerate the imprinted films without losing electrode response. In summary, the study has provided proof-of-concept for fabricating microbial imprinted films using conducting polymers.     

4-Oxalocrotonate tautomerase, an enzyme composed of 62 amino acid residues per monomer.

The xylH gene encoding 4-oxalocrotonate tautomerase (4-OT) has been located on a subclone of the Pseudomonas putida mt-2 TOL plasmid pWW0 and inserted into an Escherichia coli expression vector. Several of the genes of the metafission pathway encoded by pWW0 have been cloned in E. coli, but the overexpression of their gene products has met with limited success. By utilizing the E. coli alkaline phosphatase promoter (phoA) coupled with the proper positioning of a ribosome-binding region, we are able to express functional 4-OT in yields of at least 10 mg of pure enzyme/liter of culture. 4-OT has been previously characterized and shown to be an extremely efficient catalyst (Whitman, C. P., Aird, B. A., Gillespie, W. R., and Stolowich, N. J. (1991) J. Am. Chem. Soc. 113, 3154-3162). Kinetic and physical characterization of the E. coli-expressed protein show that it is identical with that of the 4-OT isolated from P. putida. The functional unit is apparently a pentamer of identical subunits, each consisting of only 62 amino acid residues. This is the smallest enzyme subunit reported to date. The amino acid sequence, determined in part from automated Edman degradation and also deduced from the primary sequence of xylH, did not show homology with any of the sequences in the current data bases nor with any of the sequences of enzymes that catalyze similar reactions. We propose that the active site of 4-OT may be established by an overlap of subunits and comprised of amino acid residues belonging to several, if not all, of the subunits.     

Genomic comparison between members of the Salinibacteraceae family,and description of a new species of Salinibacter (Salinibacter altiplanensis sp. nov.) isolated from high altitude hypersaline environments of the Argentinian Altiplano

The application of tandem MALDI-TOF MS screening with 16S rRNA gene sequencing of selected isolates has been demonstrated to be an excellent approach for retrieving novelty from large-scale culturing. The application of such methodologies in different hypersaline samples allowed the isolation of the culture-recalcitrant Salinibacter ruber second phylotype (EHB-2) for the first time, as well as a new species recently isolated from the Argentinian Altiplano hypersaline lakes. In this study, the genome sequences of the different species of the phylum Rhodothermaeota were compared and the genetic repertoire along the evolutionary gradient was analyzed together with each intraspecific variability. Altogether, the results indicated an open pan-genome for the family Salinibacteraceae, as well as the codification of relevant traits such as diverse rhodopsin genes, CRISPR-Cas systems and spacers, and one T6SS secretion system that could give ecological advantages to an EHB-2 isolate. For the new Salinibacter species, we propose the name Salinibacter altiplanensis sp. nov. (the designated type strain is AN15^T = CECT 9105^T = IBRC-M 11031^T).     

Kani: a QoS-aware hypervisor-level scheduler for cloud computing environments

Cloud computing environments (CCEs) are expected to deliver their services with qualities in service level agreements. On the other hand, they typically employ virtualization technology to consolidate multiple workloads on the same physical machine, thereby enhancing the overall utilization of physical resources. Most existing virtualization technologies are, however, unaware of their delivered quality of services (QoS). For example, the Xen hypervisor merely focuses on fair sharing of processor resources. We believe that CCEs have got married with traditional virtualization technologies without many traits in common. To bridge the gap between these two technologies, we have designed and implemented Kani, a QoS-aware hypervisor-level scheduler. Kani dynamically monitors the quality of delivered services to quantify the deviation between desired and delivered levels of QoS. Using this information, Kani determines how to allocate processor resources among running VMs so as to meet the expected QoS. Our evaluations of Kani scheduler prototype in Xen show that Kani outperforms the default Xen scheduler namely the Credit scheduler. For example, Kani reduces the average response time to requests to an Apache web server by up to \(93.6\,\%\); improves its throughput by up to \(97.9\,\%\); and mitigates the call setup time of an Asterisk media server by up to \(96.6\,\%\).