Estudio proteómico de las vesículas extracelulares y del secretoma de "Candida albicans" y análisis funcional de proteínas de superficie celular

Candida albicans es un importante patógeno oportunista en humanos, que puede causar distintos tipos de infecciones, desde micosis superficiales hasta sistémicas. La candidiasis invasiva es una enfermedad que puede causar mortalidad en pacientes inmunocomprometidos. Para causar daño en el hospedador, C. albicans cuenta con una serie de factores de virulencia. Entre ellos destaca la capacidad de cambiar su forma de crecimiento de levadura a hifa. La superficie celular es la estructura más externa de la célula y el punto de contacto entre el hongo y el hospedador. Las proteínas de superficie tienen un papel importante en la integridad estructural de la célula y en la adherencia e invasión de células del hospedador. Una de las proteínas localizadas en la superficie celular es Ecm33, una proteína de pared celular con anclaje glicosilfosfatidilinositol (GPI). La deleción de esta proteína afecta a la morfología tanto de levaduras como de hifas, dando como resultado células con la pared celular alterada y virulencia reducida tanto en condiciones in vitro como in vivo. El secretoma o las proteínas secretadas por C. albicans son también relevantes en la interacción patógeno-hospedador. C. albicans secreta muchas proteínas importantes relacionadas con diferentes procesos, entre los que se incluyen la formación de biofilms, la adquisición de nutrientes y el mantenimiento de la integridad de la pared celular. Muchas de estas proteínas secretadas, como las pertenecientes a las familias de aspartil proteasas (Sap) y la familia de fosfolipasas B (Plb), también han sido detectadas en la pared celular, ya que deben pasar a través de ella en su tránsito hacia el medio extracelular. Estas proteínas tienen un péptido señal en el extremo N-terminal que es el responsable de dirigirlas a la ruta clásica de secreción. Sin embargo, cerca de un tercio de las proteínas identificadas en el medio extracelular de C. albicans no poseen dicho péptido señal en su secuencia...

The Sinorhizobium meliloti EmrR Regulator Is Required for Efficient Colonization of Medicago sativa Root Nodules

The nitrogen-fixing bacterium Sinorhizobium meliloti must adapt to diverse conditions encountered during its symbiosis with leguminous plants. We characterized a new symbiotically relevant gene, emrR (SMc03169), whose product belongs to the TetR family of repressors and is divergently transcribed from emrAB genes encoding a putative major facilitator superfamily-type efflux pump. An emrR deletion mutant produced more succinoglycan, displayed increased cell-wall permeability, and exhibited higher tolerance to heat shock. It also showed lower tolerance to acidic conditions, a reduced production of siderophores, and lower motility and biofilm formation. The simultaneous deletion of emrA and emrR genes restored the mentioned traits to the wild-type phenotype, except for survival under heat shock, which was lower than that displayed by the wild-type strain. Furthermore, the ΔemrR mutant as well as the double ΔemrAR mutant was impaired in symbiosis with Medicago sativa; it formed fewer nodules and competed poorly with the wild-type strain for nodule colonization. Expression profiling of the ΔemrR mutant showed decreased expression of genes involved in Nod-factor and rhizobactin biosynthesis and in stress responses. Expression of genes directing the biosynthesis of succinoglycan and other polysaccharides were increased. EmrR may therefore be involved in a regulatory network targeting membrane and cell wall modifications in preparation for colonization of root hairs during symbiosis.

Harnessing bacterial signals for suppression of biofilm formation in the nosocomial fungal pathogen Aspergillus fumigatus

Faced with the continued emergence of antibiotic resistance to all known classes of antibiotics, a paradigm shift in approaches toward antifungal therapeutics is required. Well characterized in a broad spectrum of bacterial and fungal pathogens, biofilms are a key factor in limiting the effectiveness of conventional antibiotics. Therefore, therapeutics such as small molecules that prevent or disrupt biofilm formation would render pathogens susceptible to clearance by existing drugs. This is the first report describing the effect of the Pseudomonas aeruginosa alkylhydroxyquinolone interkingdom signal molecules 2-heptyl-3-hydroxy-4-quinolone and 2-heptyl-4-quinolone on biofilm formation in the important fungal pathogen Aspergillus fumigatus. Decoration of the anthranilate ring on the quinolone framework resulted in significant changes in the capacity of these chemical messages to suppress biofilm formation. Addition of methoxy or methyl groups at the C5–C7 positions led to retention of anti-biofilm activity, in some cases dependent on the alkyl chain length at position C2. In contrast, halogenation at either the C3 or C6 positions led to loss of activity, with one notable exception. Microscopic staining provided key insights into the structural impact of the parent and modified molecules, identifying lead compounds for further development.

Avaliação da eficácia de remoção do biofilme oral após a instrução da escovagem dentária em pacientes com necessidades educativas especiais

No âmbito da Medicina Dentária define como Paciente com Necessidades Especiais (PNE) todos o indivíduo que apresenta determinados desvios dos padrões de normalidade, identificáveis ou não e que por isso necessitam de atenção e abordagens especiais por um período da sua vida ou indefinidamente. De acordo com a Organização Mundial de Saúde (OMS), cerca de 10% da população mundial é constituída por pacientes especiais, sendo 50% portadores de deficiência mental, 20% de deficiência física, 15% de deficiência auditiva, 5% de deficiência visual e, 10% de alterações múltiplas. Indivíduos com necessidades especiais têm um risco elevado de ter doenças orais. Se, por um lado, um dos grandes objetivos deste trabalho é realçar a importância da higiene oral, não será menos importante, por outro lado, refletir sobre a eficácia da remoção do biofilme dentário através da técnica mais adequada para pacientes com necessidades educativas especiais. Assim, os principais objetivos deste estudo são: i. Perceber previamente ao estudo, quais as noções de higiene oral dos encarregados de educação dos alunos com necessidades educativas especiais e os hábitos de saúde oral que lhes estão associados; ii. Promover e melhorar a saúde oral desta população através de técnicas de motivação como jogos, apresentações de slides através do programa Microsoft powerpoint, filmes; iii. Levar os alunos com NEE a aprender a técnica mais adaptada às suas necessidades através do treino em macromodelos; iv. Comparar os valores do índice de placa no início e no final do estudo para perceber se houve ou não melhoria. Foi utilizada a base de dados do Pubmed, tendo sido pesquisados artigos com as palavras-chave “dental care in special children”, “especial needs”, “oral hygiene”, “oral health”; “deaf children and oral health”, “dental plaque” e “mechanic plaque control”. Foram incluídos os artigos escritos em Português e Inglês, aos quais houvesse acesso integral do artigo, dos últimos 10 anos. Foi realizada também uma consulta de livros relacionados com o tema. A população alvo foram os utentes da instituição CERCIPENICHE, portadores de dificuldade intelectual e desenvolvimental (DID) que compreendiam idades entre os 20 e os 57 anos. A amostra é constituída por 53 indivíduos. O estudo inclui todos aqueles alunos da instituição que conseguiam realizar a escovagem dentária sozinhos, sem qualquer ajuda. A investigação dividiu-se em 3 fases: na primeira fase foi avaliada a eficácia da escovagem dentária dos utentes sem qualquer instrução por parte do investigador, recorrendo a um revelador de placa bacteriana sem qualquer contraindicação para a saúde do indivíduo; numa segunda etapa foram dadas instruções de técnicas de escovagem com base nos resultados da fase anterior, auxiliando com atividades de motivação para a higiene da cavidade oral; por fim foi realizada uma nova avaliação do índice de placa bacteriana para verificar se houve ou não eficácia na remoção do biofilme dentário. Apesar das limitações físicas e mentais destes pacientes atuarem como um travão para uma boa higiene oral, os resultados são positivos, indicam que se verificou a existência de melhorias significativas no IHO-s após a intervenção. Do primeiro para o segundo momento houve uma diminuição dos valores médios deste índice, ou seja, houve uma melhoria na higiene oral desta população, após a instrução. Conclui-se que é importante para estes pacientes reforçar-se continuamente os hábitos de higiene oral, uma vez que reforça a interiorização do conhecimento, havendo não só melhorias na saúde oral destes indivíduos como melhoria na sua qualidade de vida e na saúde em geral.

Revêtement intelligent à base des silices mésoporeuses fonctionnalisées pour le relargage stimulé d’agents antimicrobiens

Les biofilms bactériens sont composés d’organismes unicellulaires vivants au sein d’une matrice protectrice, formée de macromolécules naturelles. Des biofilms non désirés peuvent avoir un certain nombre de conséquences néfastes, par exemple la diminution du transfert de chaleur dans les échangeurs de chaleurs, l’obstruction de membranes poreuses, la contamination des surfaces coques de navires, etc. Par ailleurs, les bactéries pathogènes qui prolifèrent dans un biofilm posent également un danger pour la santé s’ils croissent sur des surfaces médicales synthétiques comme des implants biomédicaux, cathéters ou des lentilles de vue. De plus, la croissance sur le tissu naturel par certaines souches des bactéries peut être fatale, comme Pseudomonas aeruginosa dans les poumons. Cependant, la présence de biofilms reste difficile à traiter, car les bactéries sont protégées par une matrice extracellulaire. Pour tenter de remédier à ces problèmes, nous proposons de développer une surface antisalissure (antifouling) qui libère sur demande des agents antimicrobiens. La proximité et la disposition du système de relargage placé sous le biofilm, assureront une utilisation plus efficace des molécules antimicrobiennes et minimiseront les effets secondaires de ces dernières. Pour ce faire, nous envisageons l’utilisation d’une couche de particules de silice mésoporeuses comme agents de livraison d’agents antimicrobiens. Les nanoparticules de silice mésoporeuses (MSNs) ont démontré un fort potentiel pour la livraison ciblée d’agents thérapeutiques et bioactifs. Leur utilisation en nano médecine découle de leurs propriétés de porosité intéressantes, de la taille et de la forme ajustable de ces particules, de la chimie de leur surface et leur biocompatibilité. Ces propriétés offrent une flexibilité pour diverses applications. De plus, il est possible de les charger avec différentes molécules ou biomolécules (de tailles variées, allant de l’ibuprofène à l’ARN) et d’exercer un contrôle précis des paramètres d’adsorption et des cinétiques de relargage (désorption). Mots Clés : biofilms, nanoparticules de silice mésoporeuses, microfluidique, surface antisalissure.

Caractérisation de l’effet antibiofilm et antibactérien du chitosane sur les souches de Staphylococcus aureus responsables des mammites bovines

La mammite bovine est l’inflammation des tissus internes de la glande mammaire des vaches laitières. Elle est la plupart du temps causée par l’intrusion d’agents pathogènes dans le canal du trayon de la glande mammaire causant ainsi une infection intramammaire (IIM). La mammite engendre des pertes économiques importantes pour l’industrie laitière en raison de la faible production du lait, des coûts de traitements élevés, la présence de résidus d’antibiotiques dans le lait suite à leur utilisation, le rejet de lait non destiné à la consommation et les faibles taux de rendement pendant la transformation du lait en divers produits laitiers. Le développement de l’inflammation est souvent associé au degré d’exposition des glandes mammaires aux pathogènes. Staphylococcus aureus est le pathogène le plus souvent responsable de la mammite bovine au Canada. Il est capable de causer des infections intramammaires persistantes sous-cliniques souvent réfractaires à l’antibiothérapie. En outre, le biofilm représente un facteur de virulence clé dans la persistance de S. aureus pendant la mammite, car il augmente la résistance des bactéries contre les antibiotiques grâce à la matrice extracellulaire qui recouvre et protège la communauté. Le biofilm représente donc, une problématique majeure de l’industrie laitière et le besoin de nouveaux outils thérapeutiques alternatifs adressant ce facteur de virulence est très urgent. Le chitosane est une molécule naturelle extraite de la carapace des crustacés. Elle est exploitée pour de multiples applications biologiques, y compris certaines activités antibiofilm. Dans cette étude, nous avons démontré que les formes de 2,6 kDa et 4 kDa empêchaient la production de biofilm des souches : S. aureus 2117 (forte productrice du biofilm) et le SARM bovin (S. aureus résistant à la méthicilline). Chez la souris, l’administration d’un chitosane de 2,6 kDa n’a démontré aucun effet inflammatoire comparativement au 4 kDa. Les tests de bactéricidie ont démontré que le 2,6 kDa était capable de tuer les bactéries incorporées dans les biofilms préformés d'une manière dose-réponse avec une réduction de > 3 log[indice inférieur 10] CFU / biofilm à la concentration de 4 mg / ml. En culture cellulaire, nous avons observé que le chitosane de 2,6 kDa pouvait empêcher la persistance du SARM bovin dans les cellules épithéliales bovines MAC-T. Les tests de combinaison sur plaque ont révélé que le 2,6 kDa produit une synergie avec les antibiotiques de la classe des macrolides (par exemple, la tilmicosine) contre S. aureus, en réduisant la CMI des deux molécules par 2-8 fois. Finalement, l'administration intramammaire de 2,6 kDa, seul (p <0,01) ou en combinaison avec la tilmicosine (p <0,0001), a réduit la colonisation de S. aureus dans les glandes mammaires de notre modèle de mammite aigu murin.

The impact of denture related disease on the oral microbiome of denture wearers

Advances in healthcare over the last 100 years has resulted in an ever increasing elderly population. This presents greater challenges for adequate systemic and oral healthcare delivery. With increasing age there is a natural decline in oral health, leading to the loss of teeth and ultimately for some having to wear denture prosthesis. It is currently estimated that approximately one fifth of the UK and US populations have some form of removable prosthesis. The microbiology of denture induced mucosal inflammation is a pivotal factor to consider in denture care management, similar to many other oral diseases of microbial influence, such as caries, gingivitis and periodontitis. Dentures support the growth of microbial biofilms, structures commonly known as denture plaque. Microbiologically, denture stomatitis (DS) is a disease primarily considered to be of yeast aetiology, with the literature disproportionately focussed on Candida spp. However, the denture surface is capable of carrying up to 1011 microbes per milligram, the majority of which are bacteria. Thus it is apparent that denture plaque is more diverse than we assume. There is a fundamental gap in our understanding of the bacterial composition of denture plaque and the role that they may play in denture related disease such as DS. This is categorised as inflammation of the oral mucosa, a disease affecting around half of all denture wearers. It has been proposed that bacteria and fungi interact on the denture surface and that these polymicrobial interactions lead to synergism and increased DS pathogenesis. Therefore, understanding the denture microbiome composition is the key step to beginning to understand disease pathogenesis, and ultimately help improve treatments and identify novel targets for therapeutic and preventative strategies. A group of 131 patients were included within this study in which they provided samples from their dentures, palatal mucosa, saliva and dental plaque. Microbes residing on the denture surface were quantified using standard Miles and Misra culture technique which investigated the presence of Candida, aerobes and anaerobes. These clinical samples also underwent next generation sequencing using the Miseq Illumina platform to give a more global representation of the microbes present at each of these sites in the oral cavity of these denture wearers. This data was then used to compare the composition and diversity of denture, mucosal and dental plaque between one another, as well as between healthy and diseased individuals. Additional comparisons included denture type and the presence or absence of natural teeth. Furthermore, microbiome data was used to assess differences between patients with varying levels of oral hygiene. The host response to the denture microbiome was investigated by screening the patients saliva for the presence and quantification of a range of antimicrobial peptides that are associated with the oral cavity. Based on the microbiome data an in vitro biofilm model was developed that reflected the composition of denture plaque. These biofilms were then used to assess quantitative and compositional changes over time and in response to denture cleansing treatments. Finally, the systemic implications of denture plaque were assessed by screening denture plaque samples for the presence of nine well known respiratory pathogens using quantitative PCR. The results from this study have shown that the bacterial microbiome composition of denture wearers is not consistent throughout the mouth and varies depending on sample site. Moreover, the presence of natural dentition has a significant impact on the microbiome composition. As for healthy and diseased patients the data suggests that compositional changes responsible for disease progression are occurring at the mucosa, and that dentures may in fact be a reservoir for these microbes. In terms of denture hygiene practices, sleeping with a denture in situ was found to be a common occurrence. Furthermore, significant shifts in denture microbiome composition were found in these individuals when compared to the denture microbiome of those that removed their denture at night. As for the host response, some antimicrobial peptides were found to be significantly reduced in the absence of natural dentition, indicating that the oral immune response is gradually impaired with the loss of teeth. This study also identified potentially serious systemic implications in terms of respiratory infection, as 64.6% of patients carried respiratory pathogens on their denture. In conclusion, this is the first study to provide a detailed understanding of the oral microbiome of denture wearers, and has provided evidence that DS development is more complex than simply a candidal infection. Both fungal and bacterial kingdoms clearly play a role in defining the progression of DS. The biofilm model created in this study demonstrated its potential as a platform to test novel actives. Future use of this model will aid in greater understanding of host: biofilm interactions. Such findings are applicable to oral health and beyond, and may help to identify novel therapeutic targets for the treatment of DS and other biofilm associated diseases.

Propolis components accountable for bactericidal accomplishment and antibiofilm activity

This study aimed at evaluating antimicrobial and antibiofilm activity of phenolic compounds present in propolis ethanol extracts (PEE). Seventy per cent ethanol extracts from seven types of propolis, one Green, two Red and four Brown collected in four Brazilian States were prepared and total phenolics, flavonoids, tannins and anthocyanins were assessed by high-performance liquid chromatography (HPLC). Minimum bactericidal concentration (MBC) and inhibitor effect on Staphylococcus aureus biofilm formation and capacity to disrupt established biofilms were assessed towards eight S. aureus isolates from milk of small ruminants with mastitis, one methicillin-resistant S. aureus (MRSA) and S. aureus ATCC 25923. To evaluate different propolis components accountability for bactericidal accomplishment and antibiofilm activity, the results were analysed by the non-parametric Spearman coefficient. Results of phenolic compounds were 216,21 to 312,08 gallic acid milligram equivalent per extract gram (mg EGA/g) of total phenolics, 55,08 to 140,6 quercetin milligram equivalent per extract gram (mg EQ/g) of flavonoids, 118,51 to 3766,16 catechin milligram equivalent per extract gram (mg EC/g) of tannins and 1,03 to 8,39 milligram per extract gram (mg/g) of anthocyanins. Red1 and Red2 showed higher tannin contents, while Red2 exhibited superior amount of anthocyanins and total phenolics. Brown3 presented higher flavonoid quantity. Green, Red1 and Red2 PEE showed the lowest levels of flavonoids, but the higher antimicrobial activity. Most PEE exhibit bactericidal activity at a concentration of 1.6 mg/mL. Brown4 PEE showed the worst capacity to inhibit S. aureus. Green PEE showed to be the most efficient in both preventing and disrupting biofilm. All PEE studied exhibited a better inhibitory activity prior-to than post-biofilm formation. According to non-parametric Spearman correlation analysis, there seems to be a significant negative correlation between the ability to disrupt biofilm and both tannins and anthocyanins contents.

A first insight on the biodegradation of limestone - the case of the World Heritage Convent of Christ

The present study is a multidisciplinary approach applied to architectural stone materials of the Convent of Christ in Tomar (Portugal) in order to understand and mitigate the active decay processes. The structure and appearance of the stonework from the Convent of Christ are strongly affected by stains, biofilms and structural degradation. To investigate these phenomena, a multianalytical approach comprising X-ray microdiffraction, scanning electron microscopy, microRaman and microinfrared spectroscopy was applied to the examination of altered outdoor stone areas being detected calcium oxalates, carotenoids and microbial proliferation. The presence of these alteration products seems to be correlated with the microbial activity of bacteria, microalgae, cyanobacteria and filamentous fungi. This work showed that the application of complementary methodologies is an efficient strategy to characterise the stone decay, and constitute a starting point for successful conservation intervention plans that are urgent to ensure the preservation and safeguard of this emblematic monument.

Biodeterioration of easel paintings: development of new mitigation strategies

Easel paintings have undergone biodeterioration processes due to microbiological agents proliferation, particularly by development of fungal strains that are associated to biofilms formation and microstructure disintegration of these artworks, due to a wide diversity of available nutrients. Thus, mitigation strategies, using green and non-toxic biocides, which eliminate and prevent the microbiological contamination of these cultural assets are in progress.