Experimental and observational studies of radiolarian physiological ecology: 2. Trophic activity and symbiont primary productivity ofSpongaster tetras tetras with comparative data on predatory activity of some Nassellarida

The prey ofSpongaster tetras tetras, determined by transmission electron microscopic examination of ultrathin sections through food and digestive vacuoles, was predominantly picoplankton (1 to 3 μm, largely monerans) and only occasional vacuoles contained masses of larger digested organic matter. By contrast, Nassellarian specimens collected in the same location and fixed and examined identically contained nanoplankton prey (5–10 μm) including small phytoplankton cells. The differences in prey may reduce competition for nutritional resources and account for the co-existence of these two groups of radiolaria in the same water mass. The primary productivity of the symbionts in intactS. tetras tetras was assessed at varying light levels to more fully document potential sources of carbon compounds for nutrition. Thirty-five μg of carbon were fixed per radiolarian per hour at an intensity as low as 20 μE/m²/s which is approximately one-third the maximum productivity in the intensity range of 170 to 260 μE/m²/s. The mean abundance ofS. tetras tetras, density of potential prey, and physico-chemical characteristics of the water are presented for early spring (March–April), mid-summer (June and July), and late summer (August). The mean density ofS. tetras tetras varied from c. 12 individuals/m³ during the low productivity periods (spring and late summer) to 37.8 individuals/m³ in July. The concentration of cyanobacteria was at a peak during July while larger autotrophic plankton was at a minimun further suggesting that cyanobacteria can be a significant food source forS. tetras tetras.     

Dissociation between mature phenotype and impaired transmigration in dendritic cells from heparanase-deficient mice

To reach the lymphatics, migrating dendritic cells (DCs) need to interact with the extracellular matrix (ECM). Heparanase, a mammalian endo-β-D-glucuronidase, specifically degrades heparan sulfate proteoglycans ubiquitously associated with the cell surface and ECM. The role of heparanase in the physiology of bone marrow-derived DCs was studied in mutant heparanase knock-out (Hpse-KO) mice. Immature DCs from Hpse-KO mice exhibited a more mature phenotype; however their transmigration was significantly delayed, but not completely abolished, most probably due to the observed upregulation of MMP-14 and CCR7. Despite their mature phenotype, uptake of beads was comparable and uptake of apoptotic cells was more efficient in DCs from Hpse-KO mice. Heparanase is an important enzyme for DC transmigration. Together with CCR7 and its ligands, and probably MMP-14, heparanase controls DC trafficking.     

Oncogenic mutations counteract intrinsic disorder in the EGFR kinase and promote receptor dimerization

The mutation and overexpression of the epidermal growth factor receptor (EGFR) are associated with the development of a variety of cancers, making this prototypical dimerization-activated receptor tyrosine kinase a prominent target of cancer drugs. Using long-timescale molecular dynamics simulations, we find that the N lobe dimerization interface of the wild-type EGFR kinase domain is intrinsically disordered and that it becomes ordered only upon dimerization. Our simulations suggest, moreover, that some cancer-linked mutations distal to the dimerization interface, particularly the widespread L834R mutation (also referred to as L858R), facilitate EGFR dimerization by suppressing this local disorder. Corroborating these findings, our biophysical experiments and kinase enzymatic assays indicate that the L834R mutation causes abnormally high activity primarily by promoting EGFR dimerization rather than by allowing activation without dimerization. We also find that phosphorylation of EGFR kinase domain at Tyr845 may suppress the intrinsic disorder, suggesting a molecular mechanism for autonomous EGFR signaling.     

Composition and dynamics of the gill microbiota of an invasive Indo-Pacific oyster in the eastern Mediterranean Sea

Gill bacterial communities of Chama pacifica, an Indo-Pacific invasive oyster to the eastern Mediterranean Sea, were compared with those of Chama savignyi, its northern Red Sea congeneric species. Summer and winter bacterial populations were characterized and compared using 16S rDNA clone libraries, and seasonal population dynamics were monitored by automated ribosomal intergenic spacer analysis (ARISA). Clone libraries revealed a specific clade of bacteria, closely related to marine endosymbionts from the Indo-Pacific, found in both ecosystems, of which one taxon was conserved in oysters from both sites. This taxon was dominant in summer libraries and was weakly present in winter ones, where other members of this group were dominant. ARISA results revealed significant seasonal variation in bacterial populations of Mediterranean Sea oysters, as opposed to Red Sea ones that were stable throughout the year. We suggest that this conserved association between bacteria and oyster reflects either a symbiosis between the oyster host and some of its bacteria, a co-invasion of both parties, or both.     

Failure of the Tomato Trans-Acting Short Interfering RNA Program to Regulate AUXIN RESPONSE FACTOR3 and ARF4 Underlies the Wiry Leaf Syndrome

Interfering with small RNA production is a common strategy of plant viruses. A unique class of small RNAs that require microRNA and short interfering (siRNA) biogenesis for their production is termed trans-acting short interfering RNAs (ta-siRNAs). Tomato (Solanum lycopersicum) wiry mutants represent a class of phenotype that mimics viral infection symptoms, including shoestring leaves that lack leaf blade expansion. Here, we show that four WIRY genes are involved in siRNA biogenesis, and in their corresponding mutants, levels of ta-siRNAs that regulate AUXIN RESPONSE FACTOR3 (ARF3) and ARF4 are reduced, while levels of their target ARFs are elevated. Reducing activity of both ARF3 and ARF4 can rescue the wiry leaf lamina, and increased activity of either can phenocopy wiry leaves. Thus, a failure to negatively regulate these ARFs underlies tomato shoestring leaves. Overexpression of these ARFs in Arabidopsis thaliana, tobacco (Nicotiana tabacum), and potato (Solanum tuberosum) failed to produce wiry leaves, suggesting that the dramatic response in tomato is exceptional. As negative regulation of orthologs of these ARFs by ta-siRNA is common to land plants, we propose that ta-siRNA levels serve as universal sensors for interference with small RNA biogenesis, and changes in their levels direct species-specific responses.     

A Comparative Study of the Involvement of 17 Arabidopsis Myosin Family Members on the Motility of Golgi and Other Organelles

Gene families with multiple members are predicted to have individuals with overlapping functions. We examined all of the Arabidopsis (Arabidopsis thaliana) myosin family members for their involvement in Golgi and other organelle motility. Truncated fragments of all 17 annotated Arabidopsis myosins containing either the IQ tail or tail domains only were fused to fluorescent markers and coexpressed with a Golgi marker in two different plants. We tracked and calculated Golgi body displacement rate in the presence of all myosin truncations and found that tail fragments of myosins MYA1, MYA2, XI-C, XI-E, XI-I, and XI-K were the best inhibitors of Golgi body movement in the two plants. Tail fragments of myosins XI-B, XI-F, XI-H, and ATM1 had an inhibitory effect on Golgi bodies only in Nicotiana tabacum, while tail fragments of myosins XI-G and ATM2 had a slight effect on Golgi body motility only in Nicotiana benthamiana. The best myosin inhibitors of Golgi body motility were able to arrest mitochondrial movement too. No exclusive colocalization was found between these myosins and Golgi bodies in our system, although the excess of cytosolic signal observed could mask myosin molecules bound to the surface of the organelle. From the preserved actin filaments found in the presence of enhanced green fluorescent protein fusions of truncated myosins and the motility of myosin punctae, we conclude that global arrest of actomyosin-derived cytoplasmic streaming had not occurred. Taken together, our data suggest that the above myosins are involved, directly or indirectly, in the movement of Golgi and mitochondria in plant cells.The Arabidopsis (Arabidopsis thaliana) myosin gene family contains 17 members: myosin group XI, which includes 13 members (myosins XI-A, -B, -C, -D, -E, -F, -G, -H, -I, -J, and -K, MYA1, and MYA2), and myosin group VIII, which includes four members (ATM1, ATM2, myosin VIIIA, and myosin VIIIB). Both groups are related to unconventional myosin V (Berg et al., 2001; Foth et al., 2006). The Arabidopsis myosins contain a conserved motor domain with ATPase and actin-binding activities, a number of IQ domains that bind myosin light chains, a coiled-coil domain for dimerization, and a specific tail that binds different cargo (Kinkema and Schiefelbein, 1994; Tominaga et al., 2003). Using these functional domains, myosins convert chemical energy from ATP hydrolysis into physical movement along actin fibers, carrying with their tails membrane-bound organelles or RNA/protein complexes (Li and Nebenführ, 2008b).Plant myosins have been implicated in various cellular activities, such as cytoplasmic streaming (Shimmen and Yokota, 2004; Esseling-Ozdoba et al., 2008), plasmodesmata function (Baluska et al., 2001; Volkmann et al., 2003), organelle movement (Nebenführ et al., 1999; Jedd and Chua, 2002), cytokinesis (Molchan et al., 2002; Collings et al., 2003; Volkmann et al., 2003), endocytosis (Volkmann et al., 2003; Baluska et al., 2004; Samaj et al., 2005), and targeted RNA transport (Hamada et al., 2003). Actomyosin mediated cytoplasmic streaming found in various algae cells reach velocities of up to 100 μm s⁻¹, which is the fastest known myosin-mediated movement (Shimmen and Yokota, 1994).The information that exists regarding specific roles of each plant myosin is rather limited. Immunolocalization studies indicated that myosin XIs are associated with various particles in lily (Lilium longiflorum) and tobacco (Nicotiana tabacum) pollen tubes (Yokota et al., 1995), with mitochondria, plastids, and low-density membranes in maize (Zea mays) root cells (Liu et al., 2001; Wang and Pesacreta, 2004), and with endoplasmic reticulum (ER) in tobacco BY2 cells (Yokota et al., 2008). Specific antibodies against MYA2 showed that it is associated with peroxisomes in epidermal and guard cells of Arabidopsis leaves (Hashimoto et al., 2005). More recent studies using recombinant DNA fusions to fluorescent proteins showed localization of the tails of MYA2, MYA1, XI-K, and XI-I to peroxisomes (Li and Nebenführ, 2007; Reisen and Hanson, 2007) and MYA1 partially localized to Golgi (Li and Nebenführ, 2007). Furthermore, it was shown that peroxisomes, Golgi, and mitochondrial motility were arrested by dominant negative mutants of myosin XI-K and myosin XI-E (Avisar et al., 2008b; Sparkes et al., 2008). Arrest of organelle motility was also found in Arabidopsis knockout plants xi-k and mya2 (Peremyslov et al., 2008) and double mutants xi-k/mya1, xi-k/mya2, and mya2/xi-b (Prokhnevsky et al., 2008). In contrast, the association of the single globular tail domain of MYA1 or MYA2 with peroxisomes did not arrest their motility (Li and Nebenführ, 2007). Knockout plants for myosin xi-k and mya2 had root hair phenotypes (Ojangu et al., 2007; Peremyslov et al., 2008); however, all other 11 myosin XI single knockouts looked normal under regular growth conditions (Peremyslov et al., 2008). Reciprocal stimulation between dimerization via the coiled-coil domains of MYA1 and organelle binding was suggested (Li and Nebenführ, 2008a). As for myosin VIII, immunostaining studies showed that it localized to the cell periphery at plant-specific structures such as plasmodesmata and cytokinetic cell plates (Reichelt et al., 1999; Baluska et al., 2001). Recent data from our laboratory and from others confirmed the presence of myosin VIII in plasmodesmata (Golomb et al., 2008) and the cell plate (Van Damme et al., 2004) and further provided evidence for its involvement with endocytosis (Golomb et al., 2008; Sattarzadeh et al., 2008) and its colocalization with the ER (Golomb et al., 2008). In addition, it was shown that myosin VIII is involved in the plasmodesmata targeting of the beet yellows virus protein Hsp70h (Avisar et al., 2008a).We have determined the role of all 17 genes through transient overexpression of dominant negative forms in leaf epidermal cells. Fluorescent dominant negative fusions not only provide data on the subcellular location but also provide a relatively easy way of determining expression. Additionally, overexpression of dominant negative forms can expose a role of an individual member, which might be masked by redundant activity, if it was silenced. In order to undertake such a large-scale study, we needed to choose an efficient, fast, and reproducible expression system. Therefore, Agrobacterium tumefaciens-mediated transient expression in Nicotiana leaves was suitable.     

Comparison of Effects of Compost Amendment and of Single-Strain Inoculation on Root Bacterial Communities of Young Cucumber Seedlings

Compost amendment and inoculations with specific microorganisms are fundamentally different soil treatment methods, commonly used in agriculture for the improvement of plant growth and health. Although distinct, both methods affect the rhizosphere and the plant roots. In the present study we used a 16S rRNA gene approach to achieve an overview of early consequences of these treatments on the assemblage of plant root bacterial communities. For this purpose, cucumber seedlings were grown, under controlled conditions, in perlite potting mix amended with biosolid compost or straw compost, or inoculated with Streptomyces spp. A uniform trend of response of root bacterial communities for all treatments was observed. Root bacterial density, measured as bacterial targets per plant tef gene by real-time PCR, was reduced in 31 to 67%. In addition, increased taxonomic diversity accompanied shifts in composition (α-diversity). The magnitude of change in these parameters relative to the perlite control varied between the different treatments but not in relation to the treatment method (compost amendments versus inoculations). Similarity between the compositions of root and of potting mix bacterial communities (β-diversity) was relatively unchanged. The abundance of Oxalobacteraceae was >50% of the total root bacterial community in the untreated perlite. Root domination by this group subsided >10-fold (straw compost) to >600-fold (Streptomyces sp. strain S1) after treatment. Thus, loss of dominance appears to be the major phenomenon underlining the response trend of the root bacterial communities.Environmental concern over conventional agricultural fertilization and disease control measures has led to increased interest in finding environmentally friendly alternatives. The most explored ones include compost amendments (18, 36) and the application of different microbial preparations (11, 19, 37). These are widely distinct applications. The first approach adds to the amended medium not only a rich and diverse consortium of biological agents but also organic matter and nutrients. It was confirmed that the efficacy of such treatments involves the response of the soil, the plant, and the rhizosphere microbial communities (19, 56). The activities of rhizosphere microorganisms alter the rhizosphere and thus affect plant health and root growth and development (24). Therefore, one of the main objectives of compost amendment or of inoculation with specific microbial strains is manipulation of the plant rhizosphere conditions, particularly via manipulation of the microbial community composition (32).The response of rhizosphere bacterial communities to different anthropogenic and other disturbances has been discussed in terms of resilience (3, 32). Generally, the introduction of new microorganisms produces only restricted spatial and temporal effects on the soil, rhizosphere, and root microbial communities (4, 29, 35). Thus, the plant growth-promoting effect of such treatments may be related to microbial events occurring during the early stages of plant development. Such early effects were pointed out for inoculants of different bacterial species (14, 42) and for compost amendment (15, 21, 50).Consequences of compost amendment or of single species inoculation often include shifts in the plant roots hormonal balance or a plant systemic response, namely, induced systemic resistance (8, 38, 52). Thus, direct or indirect activities of the introduced microorganisms may result in similar modifications of the root habitat. If so, bacterial assemblages of treated roots may share qualitative and quantitative characteristics different from those exhibited by untreated roots.The objective of the present study was therefore to describe and compare responses of bacterial communities of young plant roots to the application of compost or bacterial inoculants. This was performed in a simple model comprised of cucumber seedlings grown in potting mixes amended with compost or inoculated with Streptomyces spp. isolated from the two different composts.     

An ancient autosomal haplotype bearing a rare achromatopsia-causing founder mutation is shared among Arab Muslims and Oriental Jews

Numerous cultural aspects, mainly based on historical records, suggest a common origin of the Middle-Eastern Arab Muslim and Jewish populations. This is supported, to some extent, by Y-chromosome haplogroup analysis of Middle-Eastern and European samples. Up to date, no genomic regions that are shared among Arab Muslim and Jewish chromosomes and are unique to these populations have been reported. Here, we report of a rare achromatopsia-causing CNGA3 mutation (c.1585G>A) presents in both Arab Muslim and Oriental Jewish patients. A haplotype analysis of c.1585G>A-bearing chromosomes from Middle Eastern and European origins revealed a shared Muslim–Jewish haplotype, which is different from those detected in European patients, indicating a recurrent mutation stratified by a Jewish–Muslim founder effect. Comprehensive whole-genome haplotype analysis using 250 K single nucleotide polymorphism arrays revealed a large homozygous region of ~11 Mbp shared by both Arab Muslim and Oriental Jewish chromosomes. A subsequent microsatellite analysis of a 21.5 cM interval including CNGA3 and the adjacent chromosome 2 centromere revealed a unique and extremely rare haplotype associated with the c.1585G>A mutation. The age of the shared c.1585G>A mutation was calculated using the microsatellite genotyping data to be about 200 generations ago. A similar analysis of mutation age based on the Arab Muslim data alone showed that the mutation was unlikely to be the product of a recent gene flow event. The data present here demonstrate a large (11 Mbp) genomic region that is likely to originate from an ancient common ancestor of Middle-Eastern Arab Muslims and Jews who lived approximately 5,000 years ago.     

Designing coarse grained-and atom based-potentials for protein-protein docking

Background  

Protein-protein docking is a challenging computational problem in functional genomics, particularly when one or both proteins undergo conformational change(s) upon binding. The major challenge is to define a scoring function soft enough to tolerate these changes and specific enough to distinguish between near-native and "misdocked" conformations.