Binding Characteristics of a Potent AMPA Receptor Antagonist [3H]Ro 48-8587 in Rat Brain

Abstract: A new AMPA receptor antagonist, Ro 48-8587, was characterized pharmacologically in vitro. It is highly potent and selective for AMPA receptors as shown by its effects on [³H]AMPA, [³H]kainate, and [³H]MK-801 binding to rat brain membranes and on AMPA- or NMDA-induced depolarization in rat cortical wedges. [³H]Ro 48-8587 bound with a high affinity ( K _D = 3 n M ) to a single population of binding sites with a B _max of 1 pmol/mg of protein in rat whole brain membranes. [³H]Ro 48-8587 binding to rat whole brain membranes was inhibited by several compounds with the following rank order of potency: Ro 48-8587 > 6-nitro-7-sulphamoylbenzo[ f ]quinoxaline-2,3-dione (NBQX) > YM 90K > 6-cyano-7-nitroquinoxaline-2,3-dione (CNQX) > quisqualate > AMPA > glutamate > kainate > NMDA. The distribution and abundance of specific binding sites (∼95% of total) in sections of rat CNS, revealed by quantitative receptor radioautography and image analysis, indicated a very discrete localization. Highest binding values were observed in cortical layers (binding in layers 1 and 2 > binding in layers 3–6), hippocampal formation, striatum, dorsal septum, reticular thalamic nucleus, cerebellar molecular layer, and spinal cord dorsal horn. At 1 n M , the values for specific binding were highest in the cortical layers 1 and 2 and lowest in the brainstem (∼2.6 and 0.4 pmol/mg of protein, respectively). Ro 48-8587 is a potent and selective AMPA receptor antagonist with improved binding characteristics (higher affinity, selectivity, and specific binding) compared with those previously reported.     

Altered mechanisms of sympathetic activation during rhythmic forearm exercise in heart failure

In congestive heart failure (CHF), themechanisms of exercise-induced sympathoexcitation are poorly defined.We compared the responses of sympathetic nerve activity directed tomuscle (MSNA) and to skin (SSNA, peroneal microneurography) duringrhythmic handgrip (RHG) at 25% of maximal voluntary contraction andduring posthandgrip circulatory arrest (PHG-CA) in CHF patients with those of an age-matched control group. During RHG, the CHF patients fatigued prematurely. At end exercise, the increase in MSNA was similarin both groups (CHF patients, n = 12;controls, n = 10). However, duringPHG-CA, in the controls MSNA returned to baseline, whereas it remainedelevated in CHF patients (P < 0.05).Similarly, at end exercise, the increase in SSNA was comparable in bothgroups (CHF patients, n = 11;controls, n = 12), whereas SSNAremained elevated during PHG-CA in CHF patients but not in the controls (P < 0.05). In a separate controlgroup (n = 6), even high-intensity static handgrip was not accompanied by sustained elevation of SSNAduring PHG-CA. ³¹P-nuclear magneticresonance spectroscopy during RHG demonstrated significant muscleacidosis and accumulation of inorganic phosphate in CHF patients(n = 7) but not in controls(n = 9). We conclude that in CHFpatients rhythmic forearm exercise leads to premature fatigue andaccumulation of muscle metabolites. The prominent PHG-CA response ofMSNA and SSNA in CHF patients suggests activation of the musclemetaboreflex. Because, in contrast to controls, in CHF patients bothMSNA and SSNA appear to be under muscle metaboreflex control, themechanisms and distribution of sympathetic outflow during exerciseappear to be different from normal.

     

DNA-tumor virus entry—From plasma membrane to the nucleus

DNA-tumor viruses comprise enveloped and non-enveloped agents that cause malignancies in a large variety of cell types and tissues by interfering with cell cycle control and immortalization. Those DNA-tumor viruses that replicate in the nucleus use cellular mechanisms to transport their genome and newly synthesized viral proteins into the nucleus. This requires cytoplasmic transport and nuclear import of their genome. Agents that employ this strategy include adenoviruses, hepadnaviruses, herpesviruses, and likely also papillomaviruses, and polyomaviruses, but not poxviruses which replicate in the cytoplasm. Here, we discuss how DNA-tumor viruses enter cells, take advantage of cytoplasmic transport, and import their DNA genome through the nuclear pore complex into the nucleus. Remarkably, nuclear import of incoming genomes does not necessarily follow the same pathways used by the structural proteins of the viruses during the replication and assembly phases of the viral life cycle. Understanding the mechanisms of DNA nuclear import can identify new pathways of cell regulation and anti-viral therapies.     

Plaque2.0—A High-Throughput Analysis Framework to Score Virus-Cell Transmission and Clonal Cell Expansion

Classical plaque assay measures the propagation of infectious agents across a monolayer of cells. It is dependent on cell lysis, and limited by user-specific settings and low throughput. Here, we developed Plaque2.0, a broadly applicable, fluorescence microscopy-based high-throughput method to mine patho-biological clonal cell features. Plaque2.0 is an open source framework to extract information from chemically fixed cells by immuno-histochemistry or RNA in situ hybridization, or from live cells expressing GFP transgene. Multi-parametric measurements include infection density, intensity, area, shape or location information at single plaque or population levels. Plaque2.0 distinguishes lytic and non-lytic spread of a variety of DNA and RNA viruses, including vaccinia virus, adenovirus and rhinovirus, and can be used to visualize simultaneous plaque formation from co-infecting viruses. Plaque2.0 also analyzes clonal growth of cancer cells, which is relevant for cell migration and metastatic invasion studies. Plaque2.0 is suitable to quantitatively analyze virus infections, vector properties, or cancer cell phenotypes.     

The Diguanylate Cyclase SadC Is a Central Player in Gac/Rsm-Mediated Biofilm Formation in Pseudomonas aeruginosa

Pseudomonas aeruginosa is a Gram-negative opportunistic human pathogen and a threat for immunocompromised and cystic fibrosis patients. It is responsible for acute and chronic infections and can switch between these lifestyles upon taking an informed decision involving complex regulatory networks. The RetS/LadS/Gac/Rsm network and the cyclic-di-GMP (c-di-GMP) signaling pathways are both central to this phenomenon redirecting the P. aeruginosa population toward a biofilm mode of growth, which is associated with chronic infections. While these two pathways were traditionally studied independently from each other, we recently showed that cellular levels of c-di-GMP are increased in the hyperbiofilm retS mutant. Here, we have formally established the link between the two networks by showing that the SadC diguanylate cyclase is central to the Gac/Rsm-associated phenotypes, notably, biofilm formation. Importantly, SadC is involved in the signaling that converges onto the RsmA translational repressor either via RetS/LadS or via HptB/HsbR. Although the level of expression of the sadC gene does not seem to be impacted by the regulatory cascade, the production of the SadC protein is tightly repressed by RsmA. This adds to the growing complexity of the signaling network associated with c-di-GMP in P. aeruginosa. While this organism possesses more than 40 c-di-GMP-related enzymes, it remains unclear how signaling specificity is maintained within the c-di-GMP network. The finding that SadC but no other diguanylate cyclase is related to the formation of biofilm governed by the Gac/Rsm pathway further contributes to understanding of this insulation mechanism.     

Induced root-secreted phenolic compounds as a belowground plant defense

Rhizosphere is the complex place of numerous interactions between plant roots, microbes and soil fauna. Whereas plant interactions with aboveground organisms are largely described, unravelling plant belowground interactions remains challenging. Plant root chemical communication can lead to positive interactions with nodulating bacteria, mycorriza or biocontrol agents or to negative interactions with pathogens or root herbivores. A recent study¹ suggested that root exudates contribute to plant pathogen resistance via secretion of antimicrobial compounds. These findings point to the importance of plant root exudates as belowground signalling molecules, particularly in defense responses. In our report,² we showed that under Fusarium attack the barley root system launched secretion of phenolic compounds with antimicrobial activity. The secretion of de novo biosynthesized t-cinnamic acid induced within 2 days illustrates the dynamic of plant defense mechanisms at the root level. We discuss the costs and benefits of induced defense responses in the rhizosphere. We suggest that plant defense through root exudation may be cultivar dependent and higher in wild or less domesticated varieties.Key words: root exudates, plant defense, t-cinnamic acid, fusarium, induced defensePlants grow and live in very complex and changing ecosystems. Because plants lack the mobility to escape from attack by pathogens or herbivores, they have developed constitutive and in addition inducible defenses that are triggered by spatiotemporally dynamic signaling mechanisms. These defenses counteract the aggressor directly via toxins or defense plant structures or indirectly by recruitment of antagonists of aggressors. Whereas induced defenses are well described in aboveground interactions, evidence of the occurrence of such mechanisms in belowground interactions remains limited. The biosynthesis of a defensive molecule could be both constitutive and inducible with a low level of a preformed pool (Fig. 1). In addition, upon encounter of an attacking organism, those levels could be induced to rise locally to a high level of active compound that is able to disarm the pathogen.^2,3 Only a few examples show that root exudates play a role in induced plant defense. Hairy roots of Ocimum basilicum secrete rosmarinic acid only when challenged by the pathogenic fungus Pythium ultimum.⁴ Wurst et al.⁵ reported on the induction of irridoid glycosides in root exudates of Plantago lanceolata in presence of nematodes. In vivo labelling experiments² with ¹³CO₂ showed the induction of phenolic compounds secreted by barley roots after Fusarium graminearum infection and the de novo biosynthesis of root secreted t-cinnamic acid within 2 days. These results show that the pool of induced t-cinnamic acid originated from both pre-formed and newly formed carbon pools (Fig. 1), highlighting a case of belowground induced defense inside and outside the root system.Open in a separate windowFigure 1Suggested mechanisms for the induction of root defense exudates in barley in response to Fusarium attack. Upon pathogen attack by Fusarium, the initial preformed pool of phenolic compounds is increased by the addition of inducible, de novo biosynthesized t-cinnamic acid. Both, the preformed pool and the de novo biosynthesized pool fuel the exudation of defense compounds from infected roots.The concept of fitness costs is frequently presented to explain the coexistence of both constitutive and induced defense.⁶ In the case of induced defense, resources are invested in defenses only when the plant is under attack. In the absence of an infection, plants can optimize allocation of their resources to reproduction and growth to compete with neighbours.⁷ Constitutive defenses are thought to be more beneficial when the probability of attack is high, whereas adjustable, induced defenses are more valuable to fight against an unpredictable pathogen. Non disturbed soil is a heterogeneous matrix where biodiversity is very high and patchy^8,9 and organism motility is rather restricted.¹⁰ As a consequence of the patchiness, belowground environment is expected to be favourable to selection for induced responses.¹¹ The absence of defense root exudates between two infections may form an unpredictable environment for soil pathogens and reduce the chance for adaptation of root attackers. Plants may also use escape strategies to reduce the effect of belowground pathogens. Henkes et al. (unpublished) showed that Fusarium-infected barley plants reduced carbon allocation towards infected roots within a day and increased allocation carbon to uninfected roots. These results illustrate how reallocation of carbon toward non infected root parts represents a way to limit the negative impact of root infection.We have demonstrated the potential of barley plants to defend themselves against soil pathogen by root exudation.² Even the barley cultivar ‘Barke’ used in our study, a modern cultivated variety, was able to launch defense machinery via exudation of antimicrobial compounds when infected by F. graminearum. We suggest that plant defense through root exudation might be cultivar dependent and perhaps higher in wild or less domesticated varieties. Taddei et al.¹² reported that constitutivelyproduced root exudates from a resistant Gladiolus cultivar inhibit spore germination of Fusarium oxysporum whereas root exudates from a susceptible cultivar do not affect F. oxysporum germination. Root exudates from the resistant cultivar contained higher amounts of aromaticphenolic compounds compared to the susceptible cultivar and these compounds may be responsible for the inhibition of spore germination. Metabolic profiling of wheat cultivars, ‘Roblin’ and ‘Sumai3’, respectively, susceptible and resistant to Fusarium Head Blight, showed that t-cinnamic acid was a discriminating factor responsible for resistance/defense function.¹³ Therefore it is likely that wild barley varieties hold higher defense capacities compare to cultivated varieties selected for high yield. In the future, plant breeders in organic and low-input farming could use root-system defense ability as new trait in varietal variation.     

Mixed infections with <Emphasis Type="Italic">Chlamydia</Emphasis> and porcine epidemic diarrhea virus - a new <Emphasis Type="Italic">in vitro</Emphasis> model of chlamydial persistence

Background  

Chlamydiae induce persistent infections, which have been associated with a wide range of chronic diseases in humans and animals. Mixed infections with Chlamydia and porcine epidemic diarrhea virus (PEDV) may result in generation of persistent chlamydial infections. To test this hypothesis, an in vitro model of dual infection with cell culture-adapted PEDV and Chlamydia abortus or Chlamydia pecorum in Vero cells was established.