Phospho‐Proteomic Analysis of Cardiac Dyssynchrony and Resynchronization Therapy

Cardiac dyssynchrony arises from conduction abnormalities during heart failure and worsens morbidity and mortality. Cardiac resynchronization therapy (CRT) re‐coordinates contraction using bi‐ventricular pacing, but the cellular and molecular mechanisms involved remain largely unknown. The aim is to determine how dyssynchronous heart failure (HF_dys) alters the phospho‐proteome and how CRT interacts with this unique phospho‐proteome by analyzing Ser/Thr and Tyr phosphorylation. Phospho‐enriched myocardium from dog models of Control, HF_dys, and CRT is analyzed via MS. There were 209 regulated phospho‐sites among 1761 identified sites. Compared to Con and CRT, HF_dys is hyper‐phosphorylated and tyrosine phosphorylation is more likely to be involved in signaling that increased with HF_dys and was exacerbated by CRT. For each regulated site, the most‐likely targeting‐kinase is predicted, and CK2 is highly specific for sites that are “fixed” by CRT, suggesting activation of CK2 signaling occurs in HF_dys that is reversed by CRT, which is supported by western blot analysis. These data elucidate signaling networks and kinases that may be involved and deserve further study. Importantly, a possible role for CK2 modulation in CRT has been identified. This may be harnessed in the future therapeutically to compliment CRT, improving its clinical effects.     

Molecular,genetic and evolutionary analysis of a paracentric inversion in Arabidopsis thaliana

Chromosomal inversions can provide windows onto the cytogenetic, molecular, evolutionary and demographic histories of a species. Here we investigate a paracentric 1.17‐Mb inversion on chromosome 4 of Arabidopsis thaliana with nucleotide precision of its borders. The inversion is created by Vandal transposon activity, splitting an F‐box and relocating a pericentric heterochromatin segment in juxtaposition with euchromatin without affecting the epigenetic landscape. Examination of the RegMap panel and the 1001 Arabidopsis genomes revealed more than 170 inversion accessions in Europe and North America. The SNP patterns revealed historical recombinations from which we infer diverse haplotype patterns, ancient introgression events and phylogenetic relationships. We find a robust association between the inversion and fecundity under drought. We also find linkage disequilibrium between the inverted region and the early flowering Col‐FRIGIDA allele. Finally, SNP analysis elucidates the origin of the inversion to South‐Eastern Europe approximately 5000 years ago and the FRI‐Col allele to North‐West Europe, and reveals the spreading of a single haplotype to North America during the 17th to 19th century. The ‘American haplotype’ was identified from several European localities, potentially due to return migration.     

Commuting (to) suicide: an update on nucleocytoplasmic transport in apoptosis

Commuting is the process of travelling between a place of residence and a place of work. In the context of biology, this expression evokes the continuous movement of macromolecules between different compartments of a eukaryotic cell. Transport in and out of the nucleus is a major example of intracellular commuting. This article discusses recent findings that substantiate the emerging link between nucleocytoplasmic transport and the signalling and execution of cell death.     

Maize Brittle Stalk2-Like3, encoding a COBRA protein,functions in cell wall formation and carbohydrate partitioning

Carbohydrate partitioning from leaves to sink tissues is essential for plant growth and development. The maize (Zea mays) recessive carbohydrate partitioning defective28 (cpd28) and cpd47 mutants exhibit leaf chlorosis and accumulation of starch and soluble sugars. Transport studies with ¹⁴C-sucrose (Suc) found drastically decreased export from mature leaves in cpd28 and cpd47 mutants relative to wild-type siblings. Consistent with decreased Suc export, cpd28 mutants exhibited decreased phloem pressure in mature leaves, and altered phloem cell wall ultrastructure in immature and mature leaves. We identified the causative mutations in the Brittle Stalk2-Like3 (Bk2L3) gene, a member of the COBRA family, which is involved in cell wall development across angiosperms. None of the previously characterized COBRA genes are reported to affect carbohydrate export. Consistent with other characterized COBRA members, the BK2L3 protein localized to the plasma membrane, and the mutants condition a dwarf phenotype in dark-grown shoots and primary roots, as well as the loss of anisotropic cell elongation in the root elongation zone. Likewise, both mutants exhibit a significant cellulose deficiency in mature leaves. Therefore, Bk2L3 functions in tissue growth and cell wall development, and this work elucidates a unique connection between cellulose deposition in the phloem and whole-plant carbohydrate partitioning.

Mutations in Bk2L3 result in dwarfed plants with decreased anisotropic cell growth, cellulose deposition, phloem pressure, sucrose export, and carbohydrate hyperaccumulation in mature maize leaves.     

Molecular, immunological, and structural characterization of Phl p 6, a major allergen and P-particle-associated protein from Timothy grass (Phleum pratense) pollen.

Due to the wide distribution and heavy pollen production of grasses, approximately 50% of allergic patients are sensitized against grass pollen allergens. cDNAs coding for two isoforms and four fragments of a major timothy grass (Phleum pratense) pollen allergen, Phl p 6, were isolated by IgE immunoscreening from a pollen expression cDNA library. Recombinant Phl p 6 (rPhl p 6), an acidic protein of 11.8 kDa, was purified to homogeneity as assessed by mass spectrometry and exhibited almost exclusive alpha-helical secondary structure as determined by circular dichroism spectroscopy. Phl p 6 reacted with serum IgE from 75% of grass pollen-allergic patients (n = 171). IgE binding experiments with rPhl p 6 fragments indicated that the N terminus of the allergen is required for IgE recognition. Purified rPhl p 6 elicited dose-dependent basophil histamine release and immediate type skin reactions in patients allergic to grass pollen. A rabbit antiserum raised against purified rPhl p 6 identified it as a pollen-specific protein that, by immunogold electron microscopy, was localized on the polysaccharide-containing wall-precursor bodies (P-particles). The association of Phl p 6 with P-particles may facilitate its intrusion into the deeper airways and thus be responsible for the high prevalence of IgE recognition of Phl p 6. Recombinant native-like Phl p 6 can be used for in vitro as well as in vivo diagnoses of grass pollen allergy, whereas N-terminal deletion mutants with reduced IgE binding capacity may represent candidates for immunotherapy of grass pollen allergy with a low risk of anaphylactic side effects.     

fdrtool: a versatile R package for estimating local and tail area-based false discovery rates

False discovery rate (FDR) methodologies are essential in the study of high-dimensional genomic and proteomic data. The R package 'fdrtool' facilitates such analyses by offering a comprehensive set of procedures for FDR estimation. Its distinctive features include: (i) many different types of test statistics are allowed as input data, such as P-values, z-scores, correlations and t-scores; (ii) simultaneously, both local FDR and tail area-based FDR values are estimated for all test statistics and (iii) empirical null models are fit where possible, thereby taking account of potential over- or underdispersion of the theoretical null. In addition, 'fdrtool' provides readily interpretable graphical output, and can be applied to very large scale (in the order of millions of hypotheses) multiple testing problems. Consequently, 'fdrtool' implements a flexible FDR estimation scheme that is unified across different test statistics and variants of FDR. AVAILABILITY: The program is freely available from the Comprehensive R Archive Network (http://cran.r-project.org/) under the terms of the GNU General Public License (version 3 or later). CONTACT: strimmer@uni-leipzig.de.     

Middle Permian Ostracods from Tak Fa Limestone, Phetchabun Province, Central Thailand

This paper presents the first Permian ostracod fauna discovered in Thailand. The ostracods are recovered from the Tak Fa Limestone (Middle Permian) in Phetchabun province, central Thailand. The ostracods belong to eight genera and 15 species. Four species are newly described: Sargentina phetchabunensis nov. sp., Geffenina bungsamphanensis nov. sp., Reviya subsompongensis nov. sp. and Bairdia takfaensis nov. sp. The ostracod assemblages characterize a shallow marine, near shore environment at the time of deposition. Except for one species, which shows palaeobiogeographical links between Central Thailand and South China, all the other species are endemic.     

N‐terminal residues of the yeast pheromone receptor,Ste2p,mediate mating events independently of G1‐arrest signaling

In Saccharomyces cerevisiae, mechanisms modulating the mating steps following cell cycle arrest are not well characterized. However, the N‐terminal domain of Ste2p, a G protein‐coupled pheromone receptor, was recently proposed to mediate events at this level. Toward deciphering receptor mechanisms associated with this mating functionality, scanning mutagenesis of targeted regions of the N‐terminal domain has been completed. Characterization of ste2 yeast overexpressing Ste2p variants indicated that residues Ile 24 and Ile 29 as well as Pro 15 are critical in mediating mating efficiency. This activity was shown to be independent of Ste2p mediated G1 arrest signaling. Further analysis of Ile 24 and Ile 29 highlight the residues' solvent accessibility, as well as the importance of the hydrophobic nature of the sites, and in the case of Ile 24 the specific size and shape of the side chain. Mutation of these Ile's led to arrest of mating after cell contact, but before completion of cell wall degradation. We speculate that these extracellular residues mediate novel receptor interactions with ligand or proteins, leading to stimulation of alternate signaling effector pathways. J. Cell. Biochem. 107: 630–638, 2009. © 2009 Crown in the right of Canada.     

The MalF P2 Loop of the ATP-Binding Cassette Transporter MalFGK2 from Escherichia coli and Salmonella enterica Serovar Typhimurium Interacts with Maltose Binding Protein (MalE) throughout the Catalytic Cycle

We have investigated the interaction of the uncommonly large periplasmic P2 loop of the MalF subunit of the maltose ATP-binding cassette transporter (MalFGK₂) from Escherichia coli and Salmonella enterica serovar Typhimurium with maltose binding protein (MalE) by site-specific chemical cross-linking in the assembled transport complex. We focused on possible distance changes between two pairs of residues of the P2 loop and MalE during the transport cycle. The distance between MalF(S205C) and MalE(T80C) (∼5 Å) remained unchanged under all conditions tested. Cross-linking did not affect the ATPase activity of the complex. The distance between MalF(T177C) and MalE(T31C) changed from ∼10 Å to ∼5 Å upon binding of ATP (or maltose, with a less pronounced result) and was reset to ∼10 Å after hydrolysis of one ATP. A cross-link (∼25 Å) between MalF(S205C) and MalE(T31C) was observed only when the transporter resided in a transition state-like conformation, as was the case after vanadate trapping or in a binding protein-independent mutant, both of which are characterized by tight binding of unliganded MalE to the transporter. Thus, we propose that the observed cross-link is indicative of catalytic intermediates of the transporter. Together, our results strengthen the notion that the MalF P2 loop plays an important role in intersubunit communication. In particular, this loop is involved in keeping MalE in close contact with the transporter. The data are discussed with respect to a crystal structure and current transport models.ATP-binding cassette (ABC) transporters utilize the free energy of ATP hydrolysis to translocate substrates across biological membranes and can function as import or export systems (17). ABC transporters are generally composed of two hydrophobic, pore-forming transmembrane subunits and transmembrane domains (TMDs) and two hydrophilic nucleotide-binding (or ABC) subunits and nucleotide-binding domains (NBDs) that hydrolyze ATP (9). The crystal structures of isolated NBDs (6, 23, 34, 43) revealed that NBDs can be divided into a RecA-like subdomain comprising both the Walker A and the Walker B motifs, which are involved in nucleotide binding, and a helical subdomain harboring the unique LSGGQ motif (35). Furthermore, in the physiologically relevant NBD dimer, the nucleotide is complexed between the Walker A and B sites of one monomer and the LSGGQ motif of the opposing monomer. Both subdomains are joined by the “Q loop” containing a conserved glutamine residue that binds to the Mg²⁺ ion and attacking water and is likely to be involved in communicating ATP binding to the TMDs (10, 20, 29). ATP-dependent closing of the NBD dimer is thought to provide one possibility of the power stroke of ABC transporters (38).ABC importers that are confined to prokaryotes mediate the uptake of a large variety of solutes, including inorganic ions, amino acids, sugars, vitamins, oligopeptides, and polyamines (5). They require an additional protein, the extracytoplasmic solute binding protein (SBP), in order to capture the substrate and to deliver it to the cognate ABC transporter (37). SBPs typically consist of two lobes that are connected by a linker region. The interface between the two lobes forms the substrate binding site. Upon binding of the ligand, the proteins undergo a conformational change from an open toward a closed state (33) which, by interaction with extracytoplasmic peptide regions of TMDs of the cognate ABC transporter, initiates the transport process (31). The molecular events by which binding of ATP to the NBDs and interaction of liganded binding proteins with the TMDs are communicated to eventually trigger substrate translocation are still poorly understood.The maltose ABC transporter of Escherichia coli and Salmonella enterica serovar Typhimurium is one of the best-characterized transporters and thus serves as a model system for studying the mechanism by which ABC transporters exert their functions in general (15). The transporter is composed of the extracytoplasmic (periplasmic) maltose binding protein (MalE), the membrane-spanning subunits MalF and MalG, and two copies of the ATP-hydrolyzing subunit (MalK) (Fig. ​(Fig.1A1A).Open in a separate windowFIG. 1.(A) Structure of the catalytic intermediate of the maltose transporter [MalFGK(E159Q)₂-E]. The complex is shown in a ribbon diagram. White horizontal bars mark the boundaries of the membrane. Color code: yellow, MalE; cyan, MalF; red, MalG; green and magenta, MalK dimer. (B) Close-up view of the contact site between MalF P2 and the N-terminal lobe of MalE. The color code is the same as that for panel A. Residues from regions I and II that were replaced by cysteines are indicated in pink (MalF) and green (MalE). Residue MalE-K179, which was used as a control, is shown in green. The figure was drawn with DS ViewerPro 6.0 (Accelrys, Cambridge, United Kingdom), using the coordinates from entry 2R6G in the Brookhaven Protein Data Bank.Recently, suppressor mutational analysis provided a first hint that substrate availability is communicated from MalE to the MalK dimer via periplasmic loop regions of MalFG (11). Moreover, by site-directed cross-linking based on previous genetic evidence (19, 40), we demonstrated a close proximity of MalE G13 to Pro-78 in the first periplasmic loop (P1) of MalG, independently of cofactors such as maltose or ATP. Interaction of both residues was also observed in intact cells (11). These findings led us to propose that a copy of MalE is permanently associated with the transporter throughout the catalytic cycle. Furthermore, we have found that a region of the large, periplasmic P2 loop of MalF around Ser-205 (Fig. ​(Fig.1)1) is in cross-linking distance from MalE in the presence of maltose and MgATP only or when the transporter resides in the vanadate-trapped transition state. These results were perfectly confirmed by the subsequently published crystal structure of the MalFGK(E159Q)₂-E complex, which represents a transport intermediate (32). Here, the MalK dimer is complexed with two ATP molecules, and MalE is tightly associated with MalFG, but maltose has already been released into a binding pocket formed by MalF only. In particular, the N-terminal lobe of MalE is in close contact with the P2 loop of MalF (Fig. ​(Fig.1A1A).In this communication, we have taken advantage of this structural information to gain further insight into the MalF P2-MalE interaction during the transport cycle. We demonstrate ATP- and maltose-dependent distance changes between selected pairs of residues of the loop and MalE in the assembled complex by site-specific cross-linking. Our data demonstrate for the first time that the MalF P2 loop is in close contact to MalE throughout the catalytic cycle.