Projects
PTDC/DTPFTO/2433/2014: MitoBOOST: A Next-Generation Therapeutics for Non-Alcoholic Fatty Liver Disease Based on Smart Antioxidant Delivery to Mitochondria
PTDC/AGR-TEC/2125/2014: Microbial Production of Bioactive Conjugated Linolenic Acid Isomers to Obtain Functional Ingredients.
Conjugated linolenic acid (CLnA) isomers are promising compounds due to their chemical similarities with the healthy omega 3 and Conjugated linoleic acid (CLA) and bioactivity at lower doses than this former compound. Moreover, some bacteria from foods transform linolenic acid (ALA) into CLnA and improved the in vivo fatty acid (FA) composition of liver, adipose tissue and brain in animals. It opens promising possibilities in the elaboration of new functional products. However, according to the existing bibliography and the experience of the research team of this proposal, some questions need to be addressed: a) The number of identified CLnA producing bacteria is too low b) Lack of knowledge about pathways involved in the microbial production of CLA/CLnA c) Are CLnA isomers only produced as FFA? d) Can microbial CLnA isomers exert positive health effects? e) Stability of High CLnA products The PRO-TECh-CLNA project aims to cover these topics to bring cutting-edge knowledge and result into social and economic benefits.
PTDC/AGR-TEC/2125/2014: Microbial Production of Bioactive Conjugated Linolenic Acid Isomers to Obtain Functional Ingredients.
PAEHP_CESPU_2017: Possible antiplatelet effect of Hypericum perforatum.
Antiplatelet therapy constitutes a mainstay therapy for patients with acute coronary syndromes and generally high-risk patients with thrombosis. However, the occurrence of drug-resistance or tolerance observed in some patients for antithrombotic agentes limits the efficacy and applicability of the therapy. Hypericum perforatum (HP) or St John´s wort is presently one of the most consumed medicinal plants in world because of its biological activities. In contrast to the significant number of reports on the antidepressive effects of HP, little is known about its antiplatelet or anti-inflammatory actions. Thus, the effects of Hypericum perforatum on haemostasis and inflammation need to be elucidated in order to contribute to assess its therapeutic potential. Thus, the main objective of the project is to investigate the possible functional relevance of Hypericum perforatum on platelet reactivity. To achieve this aim, this work will be focus on two aspects: 1) Characterize the profile of platelet activation in the presence of HP extracts and 2) Study the interactions involving platelets and leukocytes, reactions underlying to inflammation.
MetabRes_CESPU_2017: Unraveling the role of cell metabolism and tumor microenvironment in the molecular mechanisms of resistance in cancer.
Cancer is characterized by an uncontrolled cellular growth, implying a metabolic reprogramming, in which glycolysis is preferentially used, leading to microenvironment acidification. 3-bromopyruvate (3BP), dichloroacetate (DCA) and 2-deoxyglucose (2DG) inhibit cancer cell energy metabolism and modify the microenvironment, affecting the proteins involved in the resistance to chemotherapy. Therefore, we will elucidate the common mechanisms of resistance to 3BP, DCA and 2DG. First, we will assess the sensitivity of a lung cancer model to 3BP, DCA and 2DG and characterize their effect on viability, proliferation, migration, invasion and death. We will study the mechanism by which 3BP, DCA and 2DG can potentiate the action of conventional antitumor drugs and, thus, the possibility of being used in a combination therapy. Then, we will elucidate the molecular mechanisms involved in 3BP, DCA and 2DG action in tumor cells, by constructing cell lines resistant to these compounds.
MacrOral_CESPU_2017: Relating Monocarboxylate Transporters (MCTs) Expression to Macrophage Polarization in Oral Squamous Cell Carcinoma.
Recently, tumor-derived lactic acid (or lactate), a byproduct of aerobic and anaerobic glycolysis, was demonstrated to shift murine macrophage polarization towards M2 phenotype, the macrophage type that, in contrary to the tumoricidal M1 type, boosts tumor growth, angiogenesis, immunosuppression, and metastasis. Here, we propose to study whether such relationship also applies to human cancer, using oral squamous cell carcinoma (OSCC) as a model. Firstly, we will evaluate the expression of monocarboxylate transporters MCT1 and MCT4 (lactate transporters) in OSCC biopsies. As OSCC cases overexpressing MCT1/MCT4 are expected to transport lactate in the stroma, we predict M2 macrophages to be the prevalent phenotype in these tumors. Thus, OSCC will also be screened for M1 and M2 macrophages markers by immunohistochemistry, and correlation between macrophage polarization and MCT1,4 expression evaluated. Secondly, we propose to test the relationship between MCT1,4 expression and M2 macrophage differentiation in an in vitro model system using cancer cell lines.
FoodMicrobiome_CESPU_2017: Impact of different diets on microbiome: correlation with inflammation and metabolism.
The prevalence of obesity is increasing with a huge economic burden. At younger age, obesity can adversely affect almost every organ system and is often associated with hypertension, dyslipidemia, insulin resistance or diabetes. In addition, children are more susceptible to the interaction between genetic and environmental factors, which can substantially increase the risk of chronic diseases in adulthood. Attempts to explain this epidemic have focused on several contributors including calorie intake, changes in diet composition and in the microbiome. Gut “microbiome”, the collection of microorganisms living in our intestines, profoundly impacts many aspects of host physiology, such as metabolism, resistance to infection and regulation of the immune system. Moreover, several lines of investigation indicate that microbiome–host interactions may contribute to a broad range of extraintestinal inflammatory diseases and alteration of metabolic pathways. Here, we intend to study the impact of various diets on microbiome and their correlation with inflammation and metabolism. Thus, this study may help to develop new guidelines for feeding at younger ages and to improve health outcomes.
ComeTarget_CESPU_2017: The Mitotic Protein p31comet as a Cancer Therapeutic Target.
Interfering with mitosis in cancer cells leads to mitotic arrest and, very often, to cell death. This explains the proven success of the antimicrotubule drugs like paclitaxel in the treatment of many cancers. However, their clinical efficacy has been impaired by side effects and drug resistance, highlighting the need of search for new anticancer agents. Our research group is committed to discover mitotic components that could act as potential cancer therapeutic targets. In this context, as the protein p31comet is required for the completion of mitosis, its targeting is expected to affect tumor cell division. Thus, the present proposal has three goals: i) to test the antimitotic activity of p31comet inhibition human cancer, using as model non–small cell lung carcinoma (NSCLC) lines; ii) to determine if p31comet inhibition sensitizes NSCLC cells to paclitaxel in a combination therapy; and iii) to elucidate the mechanistic by which p31comet inhibition induces cancer cell death. It is expected that these results will be the basis of future in vivo experiments using functionalized p31comet-siRNA-loaded nanoparticles, in the context of a 4-year PhD fellowship recently approved by FCT.
BubOral_CESPU_2017: BubR1 as Predictive Biomarker of Malignant Transformation of Oral Potentially Malignant Disorders.
Oral potentially malignant disorders, such as oral leukoplakia, are clearly associated to oral cancer development. Mitotic checkpoint complex, including proteins such as BubR1, has an important role in preventing chromosomal instability. Our aim is to evaluate the expression of BubR1 in oral potentially malignant disorders and assess their potential predictive value of malignant transformation. Firstly, we will analyse the clinical and morphological characteristics of oral potentially malignant disorders and compare with the outcome of the lesions (recurrence and malignant transformation). Secondly, we will evaluate the expression of BubR1 by immunohistochemistry in these lesions analysing the significance of this expression on clinical, morphological and patient outcome. At last we will evaluate this protein as a biomarker of malignant transformation comparing with other classic markers such as dysplasia grade, or other classic proteins such as Ki-67 or PCNA. Our results could bring a useful biomarker for clinical use as a predictive diagnosis tool for oral potentially malignant disorders.
PTDC/MAR-BIO/4694/2014: Navigating through marine-derived fungi: bioprospection and synthesis of bioactive secondary metabolites and analogues as chemotherapic agents.
The need for a continued search for new anti-infective and anticancer drugs is universally considered of great importance since many of the current drugs are insufficiently effective, highly toxic, and resistances may be developed. Our group has isolated two alkaloids, eurochevalierine, a potent inhibitor of the growth of human tumor cell lines [1], from the soil fungus Neosartorya pseudofischeri, and neofiscalin A from the soil and marine fungus N. siamensis with potente antibacterial activity [2]. Neofiscalin A exhibited also antibiofilm activity in both reference and multidrugs-resistant isolates, and is currently in the patent filing process. On the other hands, marine fungi derived xanthones, particularly yicathins and isomers were considered promising as chemotherapic agents [3]. So, eurochevalierine, neofiscalin A and yicathins can be considered very interesting models to discover new anti-infective and anticancer drugs to overcome drug-resistance that could represent innovative drug candidates. However, their availability to proceed to further investigations and their complex structures could limit their future as drug candidates. Our group has multi- and transdisciplinary skills, with a large experience in isolation and structure elucidation of natural products, synthesis, cellular and molecular biology and nanotechnology. Moreover, the synthesis of anti-infective [4,5] and antitumor [6-10] xanthone derivatives, particularly in multidrugs-resistant models [5,10], is the strength of our group. Therefore, this expertise can drive these natural products and derivatives with enough potency and selectivity to become new potential anti-infective/antitumor clinical candidates. However, our goal is not only to continue with the search for innovative marine-derived compounds but also to obtain derivatives/formulations of the most promising compounds to obtain more efficient analogues. To achieve these goals, five approaches will be undertaken: i) isolate other bioactive compounds from the marine-derived N. pseudofischeri and N. siamensis and other related strains; ii) synthesize eurochevalierine, neofiscalin A and yicathins to obtain more quantity of these products for in vitro and in vivo tests, iii) carry out successive molecular modifications in order to achieve more eficiente analogues, iv) investigate their potential as anti-infective agents, v) perform in vitro studies in tumor cell lines; vi) incorporate in nanoparticles in order to improve permeability and selectivity of the most promising compounds. To carry out approach i) isolation of the bioactive metabolites, we will culture the fungi N. pseudofischeri and N. siamensis, isolated from the marine environment, such as sponge or coral to obtain eurochevalierine, neofiscalin A, and structurally related alkaloids. Moreover, we will also perform a co-culture of these two fungi with marine bacteria for the purpose of increasing the quantity of the alkaloids eurochevalierine and neofiscalin A as well as to verify if the fungi also accumulate other bioactive metabolites when compared to the pure cultures. To carry out approaches ii)-iii) these alcaloids and yicathins will be synthesized and the (semi)synthesized derivatives will be used to obtain a library of structurally-related analogues with improved efficacy. These results will allow us to establish structure activity relationships (SAR), to contribute to define the important molecular features of anti-infective and antitumor activities, and consequently, the design of more potent molecules. To carry out approach iv), the new compounds will be screened for antimicrobial activity using the agar disk diffusion assay and/or the broth microdilution method. These compounds will be also tested for their synergy with antibiotics, against isolates presenting resistance towards those antimicrobials, using the broth microdilution Checkerboard method. Compounds showing antimicrobial activity will be then tested for their ability to inhibit the biofilm formation. To screen for compounds with anti-parasitic activity their effect will be evaluated for Cryptosporidium inhibitory growth via human epithelial cells lines. To carry out approach v), the compounds will be screened for their in vitro growth inhibitory activity in human tumor cell lines. The elucidation of the molecular mechanism of antitumor activity of the most promising compounds will be performed, particularly alterations in cellular proliferation, cell cycle, mitosis, and apoptosis, analysis of the effect on tumor imune microenvironment, and identification of protein targets. To carry out approach vi), the compounds with promising anti-infective/antitumor activity will be incorporated into biodegradable and biocompatible LNP formulations by several methods, and technological parameters will be studied. This approach will allow us to verify if LNP formulations can improve the bioavailability and/or activity/selectivity of the bioactive compounds.