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The relevance of the acyl homoserine lactone (acyl-HSL) quorum signals N-3-oxododecanoyl-homoserine lactone (3OC12HSL) and N-butanoyl-homoserine lactone to the biology and virulence of Pseudomonas aeruginosa is well investigated. Previously, P. aeruginosa was shown to degrade long-chain, but not short-chain, acyl-HSLs as sole carbon and energy sources (J. J. Huang, J.-I. Han, L.-H. Zhang, and J. R. Leadbetter, Appl. Environ. Microbiol. 69:5941-5949, 2003). A gene encoding an enzyme with acyl-HSL acylase activity, pvdQ (PA2385), was identified, but it was not required for acyl-HSL utilization. This indicated that P. aeruginosa encodes another acyl-HSL acylase, which we identify here. A comparison of total cell proteins of cultures grown with long-acyl acyl-HSLs versus other substrates implicated the involvement of a homolog of PvdQ, the product of gene PA1032, for which we propose the name QuiP. Transposon mutants of quiP were defective for growth when P. aeruginosa was cultured in medium containing decanoyl-HSL as a sole carbon and energy source. Complementation with a functional copy of quiP rescued this growth defect. When P. aeruginosa was grown in buffered lysogeny broth, constitutive expression of QuiP in P. aeruginosa led to decreased accumulations of the quorum signal 3OC12HSL, relative to the wild type. Heterologous expression of QuiP was sufficient to confer long-chain acyl-HSL acylase activity upon Escherichia coli. Examination of gene expression patterns during acyl-HSL-dependent growth of P. aeruginosa further supported the involvement of quiP in signal decay and revealed other genes also possibly involved. It is not yet known under which “natural” conditions quiP is expressed or how P. aeruginosa balances the expression of its quorum-sensing systems with the expression of its acyl-HSL acylase activities.  相似文献   
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EMBO J 32: 2920–2937 10.1038/emboj.2013.207; published online September242013Microtubule loss from axons and dendrites is a key contributor to nervous system degeneration during Alzheimer disease. Previous evidence suggested a simple pathway by which tau dissociation from microtubules in the axon allows excess severing of microtubules by katanin. Now, new evidence has emerged for a more complex pathway by which abnormal tau invasion into dendrites, triggered by Aβ oligomers, results in excess severing of microtubules by spastin.Alzheimer disease (AD) is a member of a category of neurodegenerative disorders called tauopathies (Wang and Liu, 2008). These are diseases of the nervous system in which tau becomes abnormally phosphorylated, and thereby detaches from microtubules. As the microtubules lose tau, they diminish in number and density, and this loss of microtubule mass negatively impacts the capacity of the neuron to maintain axonal transport and synaptic connections. Terms such as disintegrate or ‘fall apart'' are often used to describe the effect on the microtubules as they lose tau, but to date there has been very little information on how this happens. There is no mechanistic evidence to support the view that the microtubules become less stable and simply disassemble by their normal dynamic properties.One possibility is that tau normally protects microtubules from being destroyed by various proteins in the axon that would otherwise cut them into pieces or in some other way break them down. This presumably reflects a physiological mechanism wherein the regulation of tau dissociation from the microtubule via signalling pathways controls when and where microtubule breakage normally occurs. When a pathological condition causes tau to detach from microtubules, they become extremely sensitive to such factors. In addition, there is strong evidence that the abnormal tau, whether soluble or filamentous, can elicit toxic gain-of-function effects on the axon (Wang and Liu, 2008).To make matters even more complex, AD is not a pure tauopathy. Beta amyloid (Aβ) accumulates abnormally in the brain during AD, and this prompts tau to become hyperphosphorylated and lose association with microtubules. However, the Aβ can also elicit microtubule loss, independent of tau dissociation from the microtubules. In AD, there is also a loss of microtubules from dendrites, and this introduces an additional degree of complexity. Tau is normally less enriched in dendrites than axons. In AD, tau invades dendrites abnormally through deregulation of its normal sorting mechanism, and this somehow leads to microtubule loss from dendrites (Zempel et al, 2010).Microtubule loss is a common end point of multiple pathways, some involving loss of tau function, others involving gain-of-function effects of abnormal tau, and still others working through tau-dependent Aβ toxicity. All of this is not to say that the effects on microtubules are the only reason or even the principal explanation for axonal degeneration in AD, but the loss of microtubules is an important contributor to nervous system degeneration. Preventing or reversing the effects on microtubules could help stave off degeneration and hence provide patients with additional years of cognitive health and better quality of life.Microtubule assembly and disassembly occur from the ends of a microtubule, mainly (and often exclusively) at the plus end of the microtubule in living cells. Proteins that regulate microtubule stability affect the rate of these dynamics at microtubule ends. In recent years, a great deal of attention has focused on a category of proteins, termed microtubule-severing proteins. These proteins are enzymes that yank at the microtubule anywhere along its length to pull out a tubulin subunit, and thereby ‘cut'' the microtubule by causing it to break into pieces (Roll-Mecak and Vale, 2008). If the microtubule is sufficiently stable in the region of the break, the parent microtubule is cut into two shorter microtubules that persist, with minimal disassembly of either of the two pieces. If a microtubule is severed in its more labile region, the breakage could cause a great deal of disassembly. If the tubulin being yanked is situated at one of the ends of a microtubule, the result would be a shortening of the microtubule from that end; that is, disassembly. Thus, microtubule severing in the axon can certainly lead to microtubule loss, either by cutting the polymer all the way to subunits, inducing disassembly directly from microtubule ends or promoting disassembly as a secondary effect to the cutting.To date, the AAA enzymes katanin and spastin are the best studied of the microtubule-severing proteins (Yu et al, 2008). Spastin was originally identified as the product of the gene whose mutations are the chief cause of hereditary spastic paraplegia. Curiously, neurons express levels of spastin and katanin that are theoretically high enough to completely sever all of the microtubules in the neuron to subunits (Solowska et al, 2008), and yet this does not happen. Various regulatory mechanisms presumably keep the activities of the severing proteins in check. One of these mechanisms, in the case of katanin, is microtubule-bound tau, which protects the microtubule from being accessed by katanin (Qiang et al, 2006).Could microtubule loss in AD be due, at least in part, to excess microtubule severing due to deregulation of microtubule-severing proteins? We have posited that heightened severing of the microtubules by katanin, as the microtubules lose association with tau, is a contributing factor to the degradation of microtubules in the axons of AD patients (Sudo and Baas, 2011). A role for spastin in this pathway is questionable, because tau does not appear to protect microtubules against spastin as effectively as it does against katanin (Qiang et al, 2006). However, we now know that spastin is far from irrelevant to AD, as an exciting new article from the Mandelkow and Dawson laboratories implicates spastin in an entirely different pathway for microtubule loss in AD (Zempel et al, 2013). Whereas the katanin pathway is more relevant to axons, this new spastin pathway is more relevant to dendrites.In this new work, Zempel et al (2013) exposed mature primary neurons to oligomers of Aβ and observed microtubule breakdown in dendrites that had been invaded by tau. They found that the missorting of tau leads to an elevation of TTLL6 (Tubulin-Tyrosine-Ligase-Like-6) in dendrites, and this results in a marked increase in the polyglutamylation status of the microtubules. Because spastin has a strong preference for polyglutamylated microtubules, the microtubules become more sensitive to spastin-induced severing. Exactly why katanin is not a factor remains unclear, as polyglutamylation renders microtubules more sensitive to both of the severing proteins, not just spastin (Lacroix et al, 2010). Perhaps some of the tau that invades the dendrite is able to bind to microtubules and protect them from katanin, or perhaps katanin is less potent in dendrites because their microtubules are poorly acetylated, as katanin prefers acetylated microtubules to unacetylated ones (Sudo and Baas, 2011). Whatever the case, these new studies suggest that spastin, a protein whose mutations cause an entirely different neurodegenerative disease, is also a major factor in AD.What are the implications of these findings for AD treatment? In recent years, there have been encouraging results on rodent models for AD, in which behavioural improvement and enhanced neuronal vitality were observed when the animals were treated with drugs that stabilize microtubules against disassembly (Zhang et al, 2012). Such drugs are currently in clinical trials for AD (Barten et al, 2012). This strategy is based on the presumption that the microtubule loss that occurs in AD is due to destabilization of the microtubules. However, the results discussed here suggest that the primary cause of the microtubule loss could be something quite different, namely excess severing of microtubules. In this regard, it is relevant that both katanin and spastin seem to have a preference for severing stable microtubules (Lacroix et al, 2010; Sudo and Baas, 2011). Therefore, while treatment with a microtubule-stabilizing drug would mitigate disassembly that occurs as an aftereffect of microtubule severing, the severing events themselves would likely be increased (Figure 1). Heightened microtubule severing in axons and dendrites, even if the total levels of microtubule mass are preserved, could result in a gradual shift from a normal distribution of long and short microtubules to a predominance of microtubules too short to support sustained excursions of organelle transport. Long microtubules are also necessary as compression-bearing struts that prevent axons and dendrites from collapsing on themselves. We suspect that appropriate treatment regimes can be devised to prevent such dire consequences from happening, but we would advocate for the development of new drugs that inhibit microtubule-severing proteins. Such drugs may prove to be a better approach (on their own or in combination with a stabilizing drug) for preserving the fidelity of axonal and dendritic microtubules in AD patients. Given that the structure of the severing proteins is known, it may be straightforward to develop inhibitors, especially to their ATPase domains.Open in a separate windowFigure 1Microtubules in axons and dendrites consist of a stable region towards the minus end of the microtubule and a labile region towards the plus end, as well as a pool of free tubulin subunits. Microtubule severing is a normal event in the neuron, when tightly regulated. Abnormal (deregulated) microtubule severing is posited to account for microtubule loss in AD. Severing in the stable region of the microtubule would create two new microtubules, with fairly minimal disassembly of either one. Severing in the labile region of the microtubule would result in notably more disassembly. Severing at the end of the microtubule would result in disassembly. Because known microtubule-severing proteins favour the stable region of the microtubule, treatment of AD with a microtubule-stabilizing drug may mitigate disassembly that occurs as an aftereffect of the severing, but the severing events themselves would likely increase.  相似文献   
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Akinetes are spore‐like nonmotile cells that differentiate from vegetative cells of filamentous cyanobacteria from the order Nostocales. They play a key role in the survival and distribution of these species and contribute to their perennial blooms. Various environmental factors were reported to trigger the differentiation of akinetes including light intensity and quality, temperature, and nutrient deficiency. Here, we report that deprivation of potassium ion (K+) triggers akinete development in the cyanobacterium Aphanizomenon ovalisporum. Akinetes formation is initiated 3 d–7 d after an induction by K+ depletion, followed by 2–3 weeks of a maturation process. Akinete formation occurs within a restricted matrix of environmental conditions such as temperature, light intensity or photon flux. Phosphate is essential for akinete maturation and P‐limitation restricts the number of mature akinetes. DNA replication is essential for akinete maturation and akinete development is limited in the presence of Nalidixic acid. While our results unequivocally demonstrated the effect of K+ deficiency on akinete formation in laboratory cultures of A. ovalisporum, this trigger did not cause Cylindrospermopsis raciborskii to produce akinetes. Anabaena crassa however, produced akinetes upon potassium deficiency, but the highest akinete concentration was achieved at conditions that supported vegetative growth. It is speculated that an unknown internal signal is associated with the cellular response to K+ deficiency to induce the differentiation of a certain vegetative cell in a trichome into an akinete. A universal stress protein that functions as mediator in K+ deficiency signal transduction cascade, may communicate between the lack of K+ and akinete induction.  相似文献   
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We previously reported that influenza A/swine/Korea/1204/2009(H1N2) virus was virulent and transmissible in ferrets in which the respiratory-droplet-transmissible virus (CT-Sw/1204) had acquired simultaneous hemagglutinin (HAD225G) and neuraminidase (NAS315N) mutations. Incorporating these mutations into the nonpathogenic A/swine/Korea/1130/2009(H1N2, Sw/1130) virus consequently altered pathogenicity and growth in animal models but could not establish efficient transmission or noticeable disease. We therefore exploited various reassortants of these two viruses to better understand and identify other viral factors responsible for pathogenicity, transmissibility, or both. We found that possession of the CT-Sw/1204 tripartite viral polymerase enhanced replicative ability and pathogenicity in mice more significantly than did expression of individual polymerase subunit proteins. In ferrets, homologous expression of viral RNA polymerase complex genes in the context of the mutant Sw/1130 carrying the HA225G and NA315N modifications induced optimal replication in the upper nasal and lower respiratory tracts and also promoted efficient aerosol transmission to respiratory droplet contact ferrets. These data show that the synergistic function of the tripartite polymerase gene complex of CT-Sw/1204 is critically important for virulence and transmission independent of the surface glycoproteins. Sequence comparison results reveal putative differences that are likely to be responsible for variation in disease. Our findings may help elucidate previously undefined viral factors that could expand the host range and disease severity induced by triple-reassortant swine viruses, including the A(H1N1)pdm09 virus, and therefore further justify the ongoing development of novel antiviral drugs targeting the viral polymerase complex subunits.  相似文献   
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The holotype of cf. Halticosaurus orbitoangulatus Huene, 1932, comprises an incomplete and macerated but associated skull of an archosaurian reptile from the middle (second) Stubensandstein (middle Löwenstein Formation; Upper Triassic: Norian) of Baden‐Württemberg, Germany. It was originally interpreted as a theropod dinosaur but more recently it has been suggested that this taxon has crocodylomorph affinities. Detailed preparation of the holotype of cf. H. orbitoangulatus has revealed much new anatomical information and permitted reassessment of its affinities. The maxilla lacks both a distinct antorbital fossa and a medial bony lamina bordering the antorbital fenestra. The lateral surface of the dentary bears a pronounced horizontal ridge. The squamosal differs from that of basal crocodylomorphs in being L‐shaped rather than arcuate in dorsal view, lacking a dorsolateral overhang, and lacking an interlocking contact with the paroccipital process as, for example, in the basal crocodylomorph Saltoposuchus connectens from the same horizon and locality. Phylogenetic analysis placed cf. H. orbitoangulatus amongst loricatan pseudosuchians (but not amongst Crocodylomorpha) rather than amongst theropod dinosaurs. The holotype of cf. H. orbitoangulatus represents a previously unrecognized taxon of loricatan pseudosuchian, which is here named Apatosuchus orbitoangulatus and set apart from other known Norian‐age non‐crocodylomorph loricatans by its apparently much smaller size. © 2013 The Linnean Society of London  相似文献   
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