Análise in vitro da expressão de genes de resposta a estresse oxidativo e osmótico da bactéria fastidiosa Leifsonia xyli subsp. xyli

Atualmente, o Brasil é o maior produtor de cana-de-açúcar (Saccharum ssp.), no qual o estado de São Paulo é responsável por mais de 50% da produção. Esta cultura é hospedeira de diversos patógenos que podem limitar sua produção, dentre os quais se destaca a bactéria Leifsonia xyli subsp. xyli (Lxx), agente causal do raquitismo da soqueira (ratoon stunting disease - RSD). Pouco se sabe sobre a fisiologia deste organismo e quais as estratégias utilizadas por este para colonizar seu hospedeiro. No entanto, sabemos que para infectar e colonizar seus hospedeiros, é necessário que bactérias parasíticas superem estresses de diversas naturezas impostas durante estes processos, como os estresses oxidativo e o osmótico. Neste contexto, os objetivos deste trabalho foram identificar in silico e analisar a expressão in vitro, por qPCR, de genes relacionados a estes dois estresses. Uma análise da sequência do genoma de Lxx identificou 35 genes, sendo 8 relacionados ao estresse oxidativo, 9 relacionados ao estresse osmótico e 11 relacionados a estresse gerais, incluindo um cluster de 6 genes envolvidos na síntese de carotenoides. A expressão destes foi avaliada 60 minutos após exposição a 30mM de H2O2 ou 7% (p/v) de polietilenoglicol 6000 (PEG 6000). Sete genes foram avaliados como normalizadores das reações de qPCR. A quantificação do grau de peroxidação lipídica indicou que ambos os tratamentos resultaram em sensível peroxidação, muito embora o efeito do tratamento com PEG 6000 tenha sido maior do que o tratamento com H2O2. A exposição ao H2O2 aumentou a expressão dos genes katA (catalase), sodA (superóxido dismutase), msrA (Sulfóxido de metionina redutase) e msrB (Sulfóxido de metionina redutase) bem como de todos os genes responsáveis pela síntese de carotenoides. Por outro lado, todos os genes relacionados ao estresse osmótico foram menos expressos na presença deste composto. Já quando a bactéria foi exposta a PEG 6000, o oposto ocorreu, ou seja, os genes relacionados ao estresse osmótico, que são otsA (Trealose-6-fosfato sintase), otsB (Trealose fosfatase), treY (Malto-oligosil trealose sintase), treZ (Malto-oligosil trealose trealoidrolase), treS (Trealose sintase), proX (Proteína de ligamento em substrato, tipo ABC glicina betaína transportadora), proW (Proteína permease, tipo ABC glicina betaína transportadora), proZ (Proteína permease, tipo ABC glicina betaína transportadora) e Naggn (Amidotransferase), além dos genes do cluster carotenoide, foram mais expressos, ao passo que alguns dos genes ligados à resposta ao estresse oxidativo foram menos expressos. Verificou-se também, através de PCR convencional utilizando primers para amplificar as regiões entre os genes carotenoides, que estes são expressos como um RNA policistrônico, constituindo assim um operon. Estes resultados validam predições anteriores baseadas na análise in silico da sequência do genoma de Lxx, confirmando que Lxx possui mecanismos responsivos aos estresses osmótico e oxidativo aos quais é submetida durante o processo de infecção de seu hospedeiro.

Caracterização in vitro do metabolismo e da absorção intestinal da casearina X

As principais propriedades farmacológicas da Casearia sylvestris, uma espécie de árvore cujas folhas são utilizadas na medicina popular, já foram descritas na literatura. Recentemente foi demonstrada a potente atividade citotóxica in vitro da casearina X (CAS X), o diterpeno clerodânico majoritário isolado das folhas de C. sylvestris, contra linhagens de células tumorais humanas. Apesar dos resultados promissores, sua potente atividade citotóxica in vitro não pode ser extrapolada para uma potente atividade in vivo, a menos que possua boa biodisponibilidade e duração desejável do seu efeito. Tendo em vista que o avanço nas pesquisas de produtos naturais requer a avaliação pré-clínica de propriedades farmacocinéticas, no presente trabalho foi realizada a caracterização in vitro do metabolismo e da absorção intestinal da CAS X, com o objetivo de prever sua biodisponibilidade in vivo. Para os estudos de metabolismo in vitro, foi utilizado o modelo microssomal hepático de ratos e de humanos. Foi desenvolvido um método analítico para a quantificação da CAS X em microssomas, empregando a precipitação de proteínas com acetonitrila no preparo das amostras e a cromatografia líquida de alta eficiência para as análises. O método foi validado de acordo com os guias oficiais da Agência Nacional de Vigilância Sanitária e da European Medicine Agency (EMA). A CAS X demonstrou ser substrato para as reações de hidrólise mediada pelas carboxilesterases (CES) e apresentou um perfil cinético de Michaelis-Menten. Foram estimados os parâmetros de Vmax e KM, demonstrando que o clearance intrínseco em microssomas hepático de humanos foi 1,7 vezes maior que o de ratos. O clearance hepático foi estimado por extrapolação in vitro-in vivo, resultando em mais de 90% do fluxo sanguíneo hepático em ambas as espécies. Um estudo qualitativo para a pesquisa de metabólitos foi feito utilizando espectrometria de massas, pelo qual foi possível sugerir a formação da casearina X dialdeído como produto de metabolismo. Nos estudos de absorção intestinal in vitro foi utilizado o modelo de monocamadas de células Caco-2. Um método analítico por cromatografia líquida acoplada a espectrometria de massas foi desenvolvido e validado de acordo com o EMA, para as etapas de quantificação da CAS X no sistema de células. Os parâmetros cinéticos de permeabilidade aparente absortiva e secretória da CAS X foram estimados em um sistema celular, no qual a atividade hidrolítica da CES foi inibida. Assim, a CAS X foi capaz de permear a monocamada de células Caco-2, provavelmente por transporte ativo, sem a ocorrência de efluxo, mas com significativa retenção do composto dentro das células. Em conjunto, os ensaios in vitro realizados demonstraram a susceptibilidade da CAS X ao metabolismo de primeira passagem, como substrato para as CES específicas expressas no fígado e intestino.

The Phosphate Source Influences Gene Expression and Quality of Mineralization during In Vitro Osteogenic Differentiation of Human Mesenchymal Stem Cells

For in vitro differentiation of bone marrow-derived mesenchymal stem cells/mesenchymal stromal cells into osteoblasts by 2-dimensional cell culture a variety of protocols have been used and evaluated in the past. Especially the external phosphate source used to induce mineralization varies considerably both in respect to chemical composition and concentration. In light of the recent findings that inorganic phosphate directs gene expression of genes crucial for bone development, the need for a standardized phosphate source in in vitro differentiation becomes apparent. We show that chemical composition (inorganic versus organic phosphate origin) and concentration of phosphate supplementation exert a severe impact on the results of gene expression for the genes commonly used as markers for osteoblast formation as well as on the composition of the mineral formed. Specifically, the intensity of gene expression does not necessarily correlate with a high quality mineralized matrix. Our study demonstrates advantages of using inorganic phosphate instead of beta-glycerophosphate and propose colorimetric quantification methods for calcium and phosphate ions as cost-and time-effective alternatives to X-ray diffraction and Fourier-transform infrared spectroscopy for determination of the calcium phosphate ratio and concentration of mineral matrix formed under in vitro-conditions. We critically discuss the different assays used to assess in vitro bone formation in respect to specificity and provide a detailed in vitro protocol that could help to avoid contradictory results due to variances in experimental design.

The importance of EN ISO 15189 accreditation of allergen-specific IgE determination for reliable in vitro allergy diagnosis

International audience

Evaluation of polycaprolactone scaffold degradation for 6 months in vitro and in vivo

The use of polycaprolactone (PCL) as a biomaterial, especially in the fields of drug delivery and tissue engineering, has enjoyed significant growth. Understanding how such a device or scaffold eventually degrades in vivo is paramount as the defect site regenerates and remodels. Degradation studies of three-dimensional PCL and PCL-based composite scaffolds were conducted in vitro (in phosphate buffered saline) and in vivo (rabbit model). Results up to 6 months are reported. All samples recorded virtually no molecular weight changes after 6 months, with a maximum mass loss of only about 7% from the PCL-composite scaffolds degraded in vivo, and a minimum of 1% from PCL scaffolds. Overall, crystallinity increased slightly because of the effects of polymer recrystallization. This was also a contributory factor for the observed stiffness increment in some of the samples, while only the PCL-composite scaffold registered a decrease. Histological examination of the in vivo samples revealed good biocompatibility, with no adverse host tissue reactions up to 6 months. Preliminary results of medical-grade PCL scaffolds, which were implanted for 2 years in a critical-sized rabbit calvarial defect site, are also reported here and support our scaffold design goal for gradual and late molecular weight decreases combined with excellent long-term biocompatibility and bone regeneration. (C) 2008 Wiley Periodicals, Inc. J Biomed Mater Res 90A: 906-919, 2009

Evaluation of the in vitro bioactivity of bioceramics

Two common methods have been used to evaluate the in vitro bioactivity of bioceramics for the application of bone repair. One is to evaluate the ability of apatite formation by soaking ceramics in simulated body fluids (SBF); the other method is to evaluate the effect of ceramics on osteogenic differentiation using cell experiments. Both methods have their own drawbacks in evaluating the in vitro bioactivity of bioceramics. In this commentary paper we review the application of both methods in bioactivity of bioceramics and conclude that (i) SBF method is an efficient method to investigate the in vitro bioactivity of silicate-based bioceramics, (ii) cellular bioactivity of bioceramics should be investigated by evaluating their stimulatory ability using standard bioceramics as controls; and (iii) the combination of these two methods to evaluate the in vitro bioactivity of bioceramics can improve the screening efficiency for the selection of bioactive ceramics for bone regeneration.

Mathematical models for describing the shape of the in vitro unstretched human crystalline lens

We developed orthogonal least-squares techniques for fitting crystalline lens shapes, and used the bootstrap method to determine uncertainties associated with the estimated vertex radii of curvature and asphericities of five different models. Three existing models were investigated including one that uses two separate conics for the anterior and posterior surfaces, and two whole lens models based on a modulated hyperbolic cosine function and on a generalized conic function. Two new models were proposed including one that uses two interdependent conics and a polynomial based whole lens model. The models were used to describe the in vitro shape for a data set of twenty human lenses with ages 7–82 years. The two-conic-surface model (7 mm zone diameter) and the interdependent surfaces model had significantly lower merit functions than the other three models for the data set, indicating that most likely they can describe human lens shape over a wide age range better than the other models (although with the two-conic-surfaces model being unable to describe the lens equatorial region). Considerable differences were found between some models regarding estimates of radii of curvature and surface asphericities. The hyperbolic cosine model and the new polynomial based whole lens model had the best precision in determining the radii of curvature and surface asphericities across the five considered models. Most models found significant increase in anterior, but not posterior, radius of curvature with age. Most models found a wide scatter of asphericities, but with the asphericities usually being positive and not significantly related to age. As the interdependent surfaces model had lower merit function than three whole lens models, there is further scope to develop an accurate model of the complete shape of human lenses of all ages. The results highlight the continued difficulty in selecting an appropriate model for the crystalline lens shape.

In vitro and in vivo analysis of co-electrospun scaffolds made of medical grade poly(epsilon-caprolactone) and porcine collagen

In this study, a nanofiber mesh made by co-electrospinning medical grade poly(epsilon-caprolactone) and collagen (mPCL/Col) was fabricated and studied. Its mechanical properties and characteristics were analyzed and compared to mPCL meshes. mPCL/Col meshes showed a reduction in strength but an increase in ductility when compared to PCL meshes. In vitro assays revealed that mPCL/Col supported the attachment and proliferation of smooth muscle cells on both sides of the mesh. In vivo studies in the corpus cavernosa of rabbits revealed that the mPCL/Col scaffold used in conjunction with autologous smooth muscle cells resulted in better integration with host tissue when compared to cell free scaffolds. On a cellular level preseeded scaffolds showed a minimized foreign body reaction.

Elucidating the links between UV radiation and vitamin D synthesis : using an in vitro model

Ultraviolet radiation (UV) is the carcinogen that causes the most common malignancy in humans – skin cancer. However, moderate UV exposure is essential for producing vitaminDin our skin. VitaminDincreases the absorption of calcium from the diet, and adequate calcium is necessary for the building and maintenance of bones. Thus, low levels of vitamin D can cause osteomalacia and rickets and contribute to osteoporosis. Emerging evidence also suggests vitamin D may protect against falls, internal cancers, psychiatric conditions, autoimmune diseases and cardiovascular diseases. Since the dominant source of vitamin D is sunlight exposure, there is a need to understand what is a “balanced” level of sun exposure to maintain an adequate level of vitamin D but minimise the risks of eye damage, skin damage and skin cancer resulting from excessive UV exposure. There are many steps in the pathway from incoming solar UV to the eventual vitamin D status of humans (measured as 25-hydroxyvitamin D in the blood), and our knowledge about many of these steps is currently incomplete. This project begins by investigating the levels of UV available for synthesising vitamin D, and how these levels vary across seasons, latitudes and times of the day. The thesis then covers experiments conducted with an in vitro model, which was developed to study several aspects of vitamin D synthesis. Results from the model suggest the relationship between UV dose and vitamin D is not linear. This is an important input into public health messages regarding ‘safe’ UV exposure: larger doses of UV, beyond a certain limit, may not continue to produce vitamin D; however, they will increase the risk of skin cancers and eye damage. The model also showed that, when given identical doses of UV, the amount of vitamin D produced was impacted by temperature. In humans, a temperature-dependent reaction must occur in the top layers of human skin, prior to vitamin D entering the bloodstream. The hypothesis will be raised that cooler temperatures (occurring in winter and at high latitudes) may reduce vitamin D production in humans. Finally, the model has also been used to study the wavelengths of UV thought to be responsible for producing vitamin D. It appears that vitamin D production is limited to a small range of UV wavelengths, which may be narrower than previously thought. Together, these results suggest that further research is needed into the ability of humans to synthesise vitamin D from sunlight. In particular, more information is needed about the dose-response relationship in humans and to investigate the proposed impact of temperature. Having an accurate action spectrum will also be essential for measuring the available levels of vitamin D-effective UV. As this research continues, it will contribute to the scientific evidence-base needed for devising a public health message that will balance the risks of excessive UV exposure with maintaining adequate vitamin D.

Dynamics of in vitro polymer degradation of polycaprolactone-based scaffolds : accelerated versus simulated physiological conditions

The increasing use of biodegradable devices in tissue engineering and regenerative medicine means it is essential to study and understand their degradation behaviour. Accelerated degradation systems aim to achieve similar degradation profiles within a shorter period of time, compared with standard conditions. However, these conditions only partially mimic the actual situation, and subsequent analyses and derived mechanisms must be treated with caution and should always be supported by actual long-term degradation data obtained under physiological conditions. Our studies revealed that polycaprolactone (PCL) and PCL-composite scaffolds degrade very differently under these different degradation conditions, whilst still undergoing hydrolysis. Molecular weight and mass loss results differ due to the different degradation pathways followed (surface degradation pathway for accelerated conditions and bulk degradation pathway for simulated physiological conditions). Crystallinity studies revealed similar patterns of recrystallization dynamics, and mechanical data indicated that the scaffolds retained their functional stability, in both instances, over the course of degradation. Ultimately, polymer degradation was shown to be chiefly governed by molecular weight, crystallinity susceptibility to hydrolysis and device architecture considerations whilst maintaining its thermodynamic equilibrium.