Quercetin can act either as an inhibitor or an inducer of the mitochondrial permeability transition pore: A demonstration of the ambivalent redox character of polyphenols

The Ca²⁺- and oxidative stress-induced mitochondrial permeability transition (MPT) plays an important role in phenomena ranging from tissue damage upon infarction to muscle wasting in some forms of dystrophy. The process is due to the activation of a large pore in the inner mitochondrial membrane. Anti-oxidants are considered a preventive and remedial tool, and mitochondria-targeted redox-active compounds have been developed. Plant polyphenols are generally considered as anti-oxidants, and thus candidates to the role of mitochondria-protecting agents. In patch-clamp experiments, easily oxidizable polyphenols induced closure of the MPT channel. In swelling experiments with suspensions of mitochondria, high (20–50 μM) concentrations of quercetin, the most efficient inhibitor, promoted instead the onset of the MPT. Chelators of Fe^2+/3+ and Cu^+/2+ ions counteracted this effect. Fluorescent indicators of superoxide production confirmed that quercetin potentiates O₂^? generation by isolated mitochondria and cultured cells. Since this was not affected by chelating Fe and Cu ions, the MPT-inducing effect can be ascribed to a “secondary”, metal ion-catalyzed production of ROS. These results are a direct demonstration of the ambivalent redox character of polyphenols. Their mode of action in vivo cannot be taken for granted, but needs to be experimentally verified.     

Molecular diversity and transferability of the tetracycline resistance gene <Emphasis Type="Italic">tet</Emphasis>(M), carried on Tn<Emphasis Type="Italic">916-1545</Emphasis> family transposons,in enterococci from a total food chain

In the present study, 20 enterococci belonging to the species Enterococcus faecalis (12 strains), Enterococcus faecium (4), Enterococcus durans (2), Enterococcus hirae (1) and Enterococcus mundtii (1) and originating from a total production chain of swine meat commodities were analysed to investigate the diversity of their tetracycline resistance gene tet(M). PCR–RFLP and sequence analysis showed that the tet(M) gene of most strains can be correlated with the Tn916 transposon. Conversely, tet(M) of six E. faecalis and the E. hirae strain, all isolated from pig faecal samples, may be associated with previously undescribed members of the Tn916-1545 transposon family. In vitro filter conjugation trials showed the ability of 50% of the enterococcal strains, including E. mundtii, to transfer the tet(M) gene (and the associated Tn916 and new transposons) to E. faecalis or Listeria innocua recipient strains. tet(M) gene transfer to L. innocua recipient was also directly observed in meat food products. Collectively, these sequence and conjugation data indicate that various transposons can be responsible of the spread of tetracycline resistance in enterococci and validate the opinion that Enterococcus species are important sources of antibiotic resistance genes for potentially pathogenic bacteria occurring in the food chain. Electronic supplementary material  The online version of this article (doi:) contains supplementary material, which is available to authorized users.     

The Tail Sheath of Bacteriophage N4 Interacts with the Escherichia coli Receptor

Unlike other characterized phages, the lytic coliphage N4 must inject the 360-kDa virion RNA polymerase (vRNAP), in addition to its 72-kbp genome, into the host for successful infection. The process of adsorption to the host sets up and elicits the necessary conformational changes in the virion to allow genome and vRNAP injection. Infection of suppressor and nonsuppressor strains, Escherichia coli W3350 supF and E. coli W3350, with a mutant N4 isolate (N4am229) harboring an amber mutation in Orf65 yielded virions containing (N4gp65⁺) and lacking (N4gp65⁻) gp65, respectively. N4gp65⁺ but not N4gp65⁻ phage was able to adsorb to the host. Recombinant gp65 with a hexahistidine tag at the N terminus or hexahistidine and c-myc tags at the C terminus was able to complement N4gp65⁻ virions in vivo and in vitro. Immunogold detection of gp65 in vivo complemented virions revealed its localization at the N4 tail. Finally, we show both in vitro and in vivo that gp65 interacts with the previously determined N4 outer membrane receptor, NfrA.     

BRCA1 Interaction of Centrosomal Protein Nlp Is Required for Successful Mitotic Progression

Breast cancer susceptibility gene BRCA1 is implicated in the control of mitotic progression, although the underlying mechanism(s) remains to be further defined. Deficiency of BRCA1 function leads to disrupted mitotic machinery and genomic instability. Here, we show that BRCA1 physically interacts and colocalizes with Nlp, an important molecule involved in centrosome maturation and spindle formation. Interestingly, Nlp centrosomal localization and its protein stability are regulated by normal cellular BRCA1 function because cells containing BRCA1 mutations or silenced for endogenous BRCA1 exhibit disrupted Nlp colocalization to centrosomes and enhanced Nlp degradation. Its is likely that the BRCA1 regulation of Nlp stability involves Plk1 suppression. Inhibition of endogenous Nlp via the small interfering RNA approach results in aberrant spindle formation, aborted chromosomal segregation, and aneuploidy, which mimic the phenotypes of disrupted BRCA1. Thus, BRCA1 interaction of Nlp might be required for the successful mitotic progression, and abnormalities of Nlp lead to genomic instability.The successful mitosis requires the assembly of a strictly bipolar mitotic apparatus that will ensure that chromosomes equally distribute to the daughter cells. This process is controlled by the centrosomes that are required for spindle formation and function (1). Abnormalities of centrosome have been demonstrated to cause chromosomal missegregation and generation of aneuploidy, consequently leading to cell malignant transformation and tumorigenesis (2, 3). The machinery that controls centrosome stability involves multiple important cellular proteins, including p53 (4), BRCA1 (5), Gadd45 (6, 7), p21 (8), and Cdk2/cyclin E (9). The precise coordination among those regulators maintains centrosome duplication and stability. Prior to mitosis, centrosomes undergo maturation (10), which is characterized by centrosome enlargement, recruitment of γ-tubulin, and an increased microtubule nucleation activity (11, 12). Centrosome maturation is regulated by several mitotic kinases (13), such as Plk1 (Polo-like kinase 1) (14), Aurora-A (15), and Nek2, a member of NIMA (never in mitosis gene A)-related kinase (16). Recently, a Plk1-regulated ninein-like protein, termed Nlp, has been characterized as an important molecule involved in centrosome maturation (17). Nlp interacts with γ-tubulin ring complex and stimulates microtubule nucleation in the interphase. Upon the G₂/M transition, Nlp is subjected to phosphorylation by Plk1 and Nek2 (17, 18) and departs from the centrosome. It is thus suggested that the delicate association of Nlp with the centrosome is required for proper centrosome maturation and spindle assembly (17).BRCA1, a breast cancer susceptibility gene that accounts for more than 70% of hereditary breast cancer cases, is a critical regulator in the control of cell cycle progression (19, 20). BRCA1 interacts with multiple important cellular proteins, including RAD51 (21), BRCA2 (22), p53 (23), c-Myc (24), and p300 proteins (25). It is speculated that the BRCA1 protein may exert its control over cellular functions by acting as a platform for these proteins to converge and interact and may, therefore, create interactive modes for regulating their respective functions. BRCA1 is linked to the control of centrosome stability (26). Mouse embryonic fibroblasts (MEFs)³ carrying targeted deletion of exon 11 of the Brca1 gene exhibit centrosome amplification and abnormalities of spindle formation (5). BRCA1 may regulate centrosome duplication, probably through its interacting proteins such as p53 (23), BRCA2 (27), Cdk2 (28), and γ-tubulin (29–31), or its downstream genes such as p21 (32) and Gadd45a (33, 34). Most recently, BRCA1 was reported to be required for mitotic spindle assembly through its interaction with three spindle pole proteins, TPX2, NuMA, nuclear mitotic apparatus protein; and XRHAMM, Xenopus homolog to human RHAXX (35). These findings strongly suggest that BRCA1 is involved in the mitotic machinery. However, the importance of BRCA1 in the control of mitotic progression still remains to be further defined.In this report, we demonstrate that BRCA1 physically interacts and colocalizes with Nlp. Nlp centrosomal localization and its protein stability are likely dependent on normal cellular BRCA1 function. Suppression of Nlp using the siRNA approach disturbs the process of chromosomal segregation and results in aberrant spindle formation, failure of chromosomal segregation, and aneuploidy.     

Multiplex PCR for Detection of Botulinum Neurotoxin-Producing Clostridia in Clinical,Food, and Environmental Samples

Botulinum neurotoxin (BoNT), the most toxic substance known, is produced by the spore-forming bacterium Clostridium botulinum and, in rare cases, also by some strains of Clostridium butyricum and Clostridium baratii. The standard procedure for definitive detection of BoNT-producing clostridia is a culture method combined with neurotoxin detection using a standard mouse bioassay (SMB). The SMB is highly sensitive and specific, but it is expensive and time-consuming and there are ethical concerns due to use of laboratory animals. PCR provides a rapid alternative for initial screening for BoNT-producing clostridia. In this study, a previously described multiplex PCR assay was modified to detect all type A, B, E, and F neurotoxin genes in isolated strains and in clinical, food, environmental samples. This assay includes an internal amplification control. The effectiveness of the multiplex PCR method for detecting clostridia possessing type A, B, E, and F neurotoxin genes was evaluated by direct comparison with the SMB. This method showed 100% inclusivity and 100% exclusivity when 182 BoNT-producing clostridia and 21 other bacterial strains were used. The relative accuracy of the multiplex PCR and SMB was evaluated using 532 clinical, food, and environmental samples and was estimated to be 99.2%. The multiplex PCR was also used to investigate 110 freshly collected food and environmental samples, and 4 of the 110 samples (3.6%) were positive for BoNT-encoding genes.Botulinum neurotoxins (BoNTs) are the most toxic agents known, and as little as 30 ng neurotoxin is potentially lethal to humans (36). These toxins are responsible for botulism, a disease characterized by flaccid paralysis. Seven antigenically distinct BoNTs are known (types A to G), and BoNT types A, B, E, and F are the principal types associated with human botulism (37). Significant sequence diversity and antigenically variable subtypes have recently been reported for the type A, B, and E neurotoxin genes (14, 22, 23, 42).Apart from the species Clostridium botulinum, which itself consists of four phylogenetically distinct groups of organisms, some strains of other clostridia, namely Clostridium butyricum and Clostridium baratii, are also known to produce BoNTs (2, 4, 7, 13, 20, 26, 34, 44). Also, strains that produce two toxins and strains carrying silent toxin genes have been reported (8, 22, 24, 39). Due to the great physiological variation of the BoNT-producing clostridia, their isolation and identification cannot depend solely on biochemical characteristics (32). Indeed, the standard culture methods take into consideration only C. botulinum and not C. baratii and C. butyricum, and identification and confirmation require detection of BoNT by a standard mouse bioassay (SMB) (12). The SMB is highly sensitive and specific but also expensive, time-consuming, and undesirable because of the use of experimental animals. Detection of neurotoxin gene fragments by PCR is a rapid alternative method for detection and typing of BoNT-producing clostridia (3). Different PCR methods have been described for detecting neurotoxin type A-, B-, E-, and F-producing clostridia (9, 15-18, 21, 40, 41).A previously described multiplex PCR method able to simultaneously detect type A, B, E, and F neurotoxin genes is a useful tool for rapid detection of the BoNT-producing clostridia (31). While this method generally has a high level of inclusivity for detection of type B, E, and F neurotoxin genes, limitations for detection of the recently described subtype A2, A3, and A4 strains have been identified (6, 28). To increase the efficiency of this multiplex PCR method, new primers were designed to detect genes for all identified type A neurotoxin subtypes (19). Additionally, an internal amplification control (IAC) was added according to ISO 22174/2005. The specificity and selectivity of this multiplex PCR method were evaluated in comparison with an SMB (12) using target and nontarget strains, and the robustness was assessed using clinical, food, and environmental samples. Moreover, to evaluate the applicability of this multiplex PCR method, a survey with food and environmental samples was performed in a German food control laboratory.     

GSH and analogs in antiviral therapy

Reduced glutathione (GSH) is the most prevalent non-protein thiol in animal cells. Its de novo and salvage synthesis serves to maintain a reduced cellular environment. GSH is the most powerful intracellular antioxidant and plays a role in the detoxification of a variety of electrophilic compounds and peroxides via catalysis by glutathione-S-transferases (GST) and glutathione peroxidases (GPx). As a consequence, the ratio of reduced and oxidized glutathione (GSH:GSSG) serves as a representative marker of the antioxidative capacity of the cell. A deficiency in GSH puts the cell at risk for oxidative damage. An imbalance in GSH is observed in a wide range of pathologies, such as cancer, neurodegenerative diseases, cystic fibrosis (CF), several viral infections including HIV-1, as well as in aging. Several reports have provided evidence for the use of GSH and molecules able to replenish intracellular GSH levels in antiviral therapy. This non-conventional role of GSH and its analogs as antiviral drugs is discussed in this chapter.     

Succinate is the controller of O<Stack><Subscript>2</Subscript><Superscript>−</Superscript></Stack>/H<Subscript>2</Subscript>O<Subscript>2</Subscript> release at mitochondrial complex I : negative modulation by malate,positive by cyanide

Mitochondrial production of H₂O₂ is low with NAD substrates (glutamate/pyruvate, 3 and 2 mM) (G/P) and increases over ten times upon further addition of succinate, with the formation of a sigmoidal curve (semimaximal value at 290 μM, maximal H₂O₂ production at 600 μM succinate). Malate counteracts rapidly the succinate induced increased H₂O₂ release and moves the succinate dependent H₂O₂ production curve to the right. Nitric oxide (NO) and carbon monoxide (CO) are cytochrome c oxidase inhibitors which increase mitochondrial ROS production. Cyanide (CN⁻) was used to mimic NO and CO. In the presence of G/P and succinate (300 μM), CN⁻ progressively increased the H₂O₂ release rate, starting at 1.5 μM. The succinate dependent H₂O₂ production curve was moved to the left by 30 μM CN⁻. The V_max was little modified. We conclude that succinate is the controller of mitochondrial H₂O₂ production, modulated by malate and CN⁻. We propose that succinate promotes an interaction between Complex II and Complex I, which activates O₂⁻ production.     

Dominance of Objects over Context in a Mediotemporal Lobe Model of Schizophrenia

Background

A large body of evidence suggests impaired context processing in schizophrenia. Here we propose that this impairment arises from defective integration of mediotemporal ‘what’ and ‘where’ routes, carrying object and spatial information to the hippocampus.

Methodology and Findings

We have previously shown, in a mediotemporal lobe (MTL) model, that the abnormal connectivity between MTL regions observed in schizophrenia can explain the episodic memory deficits associated with the disorder. Here we show that the same neuropathology leads to several context processing deficits observed in patients with schizophrenia: 1) failure to choose subordinate stimuli over dominant ones when the former fit the context, 2) decreased contextual constraints in memory retrieval, as reflected in increased false alarm rates and 3) impaired retrieval of contextual information in source monitoring. Model analyses show that these deficits occur because the ‘schizophrenic MTL’ forms fragmented episodic representations, in which objects are overrepresented at the expense of spatial contextual information.

Conclusions and Significance

These findings highlight the importance of MTL neuropathology in schizophrenia, demonstrating that it may underlie a broad spectrum of deficits, including context processing and memory impairments. It is argued that these processing deficits may contribute to central schizophrenia symptoms such as contextually inappropriate behavior, associative abnormalities, conversational drift, concreteness and delusions.     

GDNF Selectively Induces Microglial Activation and Neuronal Survival in CA1/CA3 Hippocampal Regions Exposed to NMDA Insult through Ret/ERK Signalling

The glial cell line-derived neurotrophic factor (GDNF) is a potent survival factor for several neuronal populations in different brain regions, including the hippocampus. However, no information is available on the: (1) hippocampal subregions involved in the GDNF-neuroprotective actions upon excitotoxicity, (2) identity of GDNF-responsive hippocampal cells, (3) transduction pathways involved in the GDNF-mediated neuroprotection in the hippocampus. We addressed these questions in organotypic hippocampal slices exposed to GDNF in presence of N-methyl-D-aspartate (NMDA) by immunoblotting, immunohistochemistry, and confocal analysis. In hippocampal slices GDNF acts through the activation of the tyrosine kinase receptor, Ret, without involving the NCAM-mediated pathway. Both Ret and ERK phosphorylation mainly occurred in the CA3 region where the two activated proteins co-localized. GDNF protected in a greater extent CA3 rather than CA1 following NMDA exposure. This neuroprotective effect targeted preferentially neurons, as assessed by NeuN staining. GDNF neuroprotection was associated with a significant increase of Ret phosphorylation in both CA3 and CA1. Interestingly, confocal images revealed that upon NMDA exposure, Ret activation occurred in microglial cells in the CA3 and CA1 following GDNF exposure. Collectively, this study shows that CA3 and CA1 hippocampal regions are highly responsive to GDNF-induced Ret activation and neuroprotection, and suggest that, upon excitotoxicity, such neuroprotection involves a GDNF modulation of microglial cell activity.     

Differential SELEX in Human Glioma Cell Lines

The hope of success of therapeutic interventions largely relies on the possibility to distinguish between even close tumor types with high accuracy. Indeed, in the last ten years a major challenge to predict the responsiveness to a given therapeutic plan has been the identification of tumor specific signatures, with the aim to reduce the frequency of unwanted side effects on oncologic patients not responding to therapy. Here, we developed an in vitro evolution-based approach, named differential whole cell SELEX, to generate a panel of high affinity nucleic acid ligands for cell surface epitopes. The ligands, named aptamers, were obtained through the iterative evolution of a random pool of sequences using as target human U87MG glioma cells. The selection was designed so as to distinguish U87MG from the less malignant cell line T98G. We isolated molecules that generate unique binding patterns sufficient to unequivocally identify any of the tested human glioma cell lines analyzed and to distinguish high from low or non-tumorigenic cell lines. Five of such aptamers act as inhibitors of specific intracellular pathways thus indicating that the putative target might be important surface signaling molecules. Differential whole cell SELEX reveals an exciting strategy widely applicable to cancer cells that permits generation of highly specific ligands for cancer biomarkers.