Heterodimeric nitrate reductase (NapAB) from Cupriavidus necator H16: purification, crystallization and preliminary X-ray analysis

Acta Cryst. (2007). F63, 516–519

Electrochemical characterization of Dps, a DNA-protecting protein

Dissertação para obtenção do Grau de Mestre em Biotecnologia

Low-Spin Heme b3 in the Catalytic Center of Nitric Oxide Reductase from Pseudomonas nautica

Biochemistry, 2011, 50 (20), pp 4251–4262 DOI: 10.1021/bi101605p

A new CuZ active form in the catalytic reduction of N2O by nitrous oxide reductase from Pseudomonas nautica

J Biol Inorg Chem (2010) 15:967–976 DOI 10.1007/s00775-010-0658-6

Camelid nanobodies raised against an integral membrane enzyme, nitric oxide reductase

Protein Sci. 2009 Mar;18(3):619-28. doi: 10.1002/pro.69.

Enzymatic activity mastered by altering metal coordination spheres

J Biol Inorg Chem (2008) 13:1185–1195 DOI 10.1007/s00775-008-0414-3

Benefits of membrane electrodes in the electrochemistry of metalloproteins: mediated catalysis of Paracoccus pantotrophus cytochrome c peroxidase by horse cytochrome c: a case study

J Biol Inorg Chem. 2008 Jun;13(5):779-87. doi: 10.1007/s00775-008-0365-8

Correlating EPR and X-ray structural analysis of arsenite-inhibited forms of aldehyde oxidoreductase

J Biol Inorg Chem (2007) 12:353–366 DOI 10.1007/s00775-006-0191-9

Development of oxidoreductase based electrochemical biosensors

Dissertação para obtenção do Grau de Mestre em Biotecnologia

Supercomplexes of Prokaryotic Aerobic Respiratory Chains-Escherichia coli and Bacillus subtilis supramolecular assemblies

Dissertation presented to obtain the Ph.D degree in Biochemistry.

Study of novel energy metabolism pathways in anaerobic bacteria

Energy conservation in chemotrophic anaerobic bacteria is achieved by two possible processes, substrate level phosphorylation (SLP) and electron transfer phosphorylation (ETP). This second mechanism, also known as respiration, involves chemiosmotic coupling. However, a third mechanism for energy coupling was recently proposed: the flavin-based electron bifurcation (FBEB). (...)

Follow the red road of triheme cytochromes in Geobacter sulfurreducens

The bacterium Geobacter sulfurreducens (Gs) is capable of oxidizing a large variety of compounds relaying electrons out of the cytoplasm and across the membrane in a process designated as extracellular electron transfer. The Gs genome was fully sequenced and a family composed by five periplasmic triheme cytochromes c7 (designated PpcA-E) was identified. These cytochromes play an important role in the reduction of extracellular acceptors. They contain approximately 70 amino acids, three heme groups with bis-histidinyl axial coordination, and share between 57 and 77% sequence identity. The triheme cytochrome PpcA is highly abundant in Gs and is most likely the reservoir of electrons destined for outer surface. In addition to its role in electron transfer pathways this protein can perform e-/H+ energy transduction, a process that is disrupted when the strictly conserved aromatic residue phenylalanine 15 is replaced by a leucine (PpcAF15L). This Thesis focuses on the expression, purification and characterization of these proteins using Nuclear Magnetic Resonance and ultraviolet-visible spectroscopy. The orientations of the heme axial histidine ring planes and the orientation of the heme magnetic axis were determined for each Gs triheme cytochrome. The comparison of the orientations obtained in solution with the crystal structures available showed significant differences. The results obtained provide the paramagnetic constraints to include in the future refinement of the solution structure in the oxidized state. In this work was also determined the solution structure and the pH-dependent conformational changes of the PpcAF15L allowing infer the structural origin for e-/H+ energy transduction mechanism as shown by PpcA. Finally, the backbone and side chain NH signals of PpcA were used to map interactions between this protein and the putative redox partner 9,10-anthraquinone-2,6-disulfonate (AQDS). In this work a molecular interaction was identified for the first time between PpcA and AQDS, constituting the first step toward the rationalization of the Gs respiratory chain.

Fishing the key biological components of the bacterium Geobacter metallireducens for optimal biotechnological applications

Os resultados apresentados no capítulo 2 foram incluídos no artigo Dantas JM, Campelo LM, Duke NEC, Salgueiro CA, Pokkuluri PR (2015) "The structure of PccH from Geobacter sulfurreducens – a novel low reduction potential monoheme cytochrome essential for accepting electrons from an electrode", FEBS Journal, 282, 2215-2231.

Melanosome transfer between melanocytes and keratinocytes

RESUMO: A pele é o maior órgão do corpo humano e a sua pigmentação é essencial para a sua coloração e proteção contra os efeitos nocivos da radiação ultravioleta (UV). A pigmentação da pele resulta essencialmente de três processos: a síntese e o armazenamento de melanina pelos melanócitos, em organelos especializados denominados melanossomas; o transporte dos melanossomas dentro dos melanócitos; e finalmente, a transferência dos melanossomas para os queratinócitos adjacentes. Nos queratinócitos, a melanina migra para a região perinuclear apical da célula para formar um escudo protetor,responsável pela proteção do DNA dos danos causados pela radiação UV. Os melanócitos estão localizados na camada basal da epiderme e contactam com 30-40 queratinócitos. Em conjunto, estas células formam a “unidade melano-epidérmica”. Apesar dos processos de síntese e transporte de melanina nos melanócitos estarem bastante bem caracterizados, os mecanismos moleculares subjacentes à transferência inter-celular de melanina são menos conhecidos e ainda controversos. Dados preliminares obtidos pelo nosso grupo, que se basearam na observação de amostras de pele humana por microscopia electrónica, indicam que a forma predominante de transferência de melanina na epiderme consiste na exocitose dos melanossomas pelos melanócitos e subsequente endocitose da melanina por queratinócitos. Para além disso sabe-se que as proteínas Rab, que controlam o tráfego membranar, estão envolvidas em várias etapas de pigmentação da pele, nomeadamente na biogénese e no transporte de melanina. Assim, dado o seu papel fundamental nestes processos, questionámo-nos sobre o seu envolvimento na transferência de melanina. Com este trabalho, propomo-nos a expandir o conhecimento atual sobre a transferência de melanina na pele, através do estudo detalhado dos seus mecanismos moleculares, identificando as proteínas Rab que regulam o processo. Pretendemos também confirmar o modelo de exo/endocitose como sendo o mecanismo principal de transferência de melanina. Primeiro, explorámos a regulação da secreção de melanina pelos melanócitos e analisámos o papel de proteínas Rab neste processo. Os resultados foram obtidos recorrendo a um método in vitro, desenvolvido previamente no laboratório, que avalia a quantidade de melanina segregada para o meio de cultura por espectrofotometria, e ainda por microscopia, contando o número de melanossomas transferidos para os queratinócitos. Através de co-culturas de melanócitos e queratinócitos, verificou-se que os queratinócitos estimulam a libertação de melanina dos melanócitos para o meio extra-celular, bem como a sua transferência para os queratinócitos. Além disso, a proteína Rab11b foi identificada como um regulador da exocitose de melanina e da sua transferência para os queratinócitos. De facto, a diminuição da expressão de Rab11b em melanócitos provocou a redução da secreção de melanina estimulada por queratinócitos, bem como da transferência desta. Em segundo lugar, para complementar o nosso estudo, centrámos a nossa investigação na internalização de melanina por queratinócitos. Especificamente, usando uma biblioteca de siRNA, explorámos o envolvimento de proteínas Rab na captação de melanina por queratinócitos. Como primeira abordagem, usámos esferas fluorescentes como substituto de melanina, avaliando os resultados por citometria de fluxo. No entanto, este método revelou-se ineficaz uma vez que a internalização destas esferas é independente do recetor PAR-2 (recetor 2 ativado por protease), que foi previamente descrito como essencial na captação de melanina por queratinócitos Posteriormente, foi desenvolvido um novo protocolo de endocitose baseado em microscopia, usando melanossomas sem a membrana envolvente (melanocores) purificados do meio de cultura de melanócitos, incluindo um programa informático especialmente desenhado para realizar uma análise semi-automatizada. Após internalização, os melanocores acumulam-se na região perinuclear dos queratinócitos, em estruturas que se assemelham ao escudo supranuclear observado na pele humana. Seguidamente, o envolvimento do recetor PAR-2 na captação de melanocores por queratinócitos foi confirmado, utilizando o novo protocolo de endocitose desenvolvido. Para além disso, a necessidade de quatro proteínas Rab foi identificada na internalização de melanocores por queratinócitos. A redução da expressão de Rab1a ou Rab5b em queratinócitos diminuiu significativamente o nível de internalização de melanocores, enquanto o silenciamento da expressão de Rab2a ou Rab14 aumentou a quantidade de melanocores internalizados por estas células. Em conclusão, os resultados apresentados corroboram as observações anteriores, obtidas em amostras de pele humana, e sugerem que o mecanismo de transferência predominante é a exocitose de melanina pelos melanócitos, induzida por queratinócitos, seguida por endocitose pelos queratinócitos. A pigmentação da pele tem implicações tanto ao nível da cosmética, como ao nível médico, relacionadas com foto-envelhecimento e com doenças pigmentares. Assim sendo, ao esclarecer quais os mecanismos moleculares que regulam a transferência de melanina na pele, este trabalho pode conduzir ao desenvolvimento de novas estratégias para modular a pigmentação da pele.----------------ABSTRACT: Skin pigmentation is achieved through the highly regulated production of the pigment melanin in specialized organelles, termed melanosomes within melanocytes. These are transported from their site of synthesis to the melanocyte periphery before being transferred to keratinocytes where melanin forms a supra-nuclear cap to protect the DNA from UVinduced damage. Together, melanocytes and keratinocytes form a functional complex, termed “epidermal-melanin unit”, that confers color and photoprotective properties to the skin. Skin pigmentation requires three processes: the biogenesis of melanin; its intracelular transport within the melanocyte to the cell periphery; and the melanin transfer to keratinocytes. The first two processes have been extensively characterized. However, despite significant advances that have been made over the past few years, the mechanisms underlying inter-cellular transfer of pigment from melanocytes to keratinocytes remain controversial.Preliminary studies from our group using electron microscopy and human skin samples found evidence for a mechanism of coupled exocytosis-endocytosis. Rab GTPases are master regulators of intracellular trafficking and have already been implicated in several steps of skin pigmentation. Thus, we proposed to explore and characterize the molecular mechanisms of melanin transfer and the role of Rab GTPases in this process. Moreover, we investigated whether the exo/endocytosis model is the main mechanism of melanin transfer. We first focused on melanin exocytosis by melanocytes. Then, we started to investigate the key regulatory Rab proteins involved in this step by establishing an in vitro tissue culture model of melanin secretion. Using co-cultures of melanocytes and keratinocytes, we found that keratinocytes stimulate melanin release and transfer. Moreover, depletion of Rab11b decreases keratinocyte-induced melanin exocytosis by melanocytes. In order to determine whether melanin exocytosis is a predominant mechanism of melanin transfer, the amount of melanin transferred to keratinocytes was then assayed in conditions where melanin exocytosis was inhibited. Indeed, Rab11b depletion resulted in a significant decrease in melanin uptake by keratinocytes. Taken together, these observations suggest that Rab11b mediates melanosome exocytosis from melanocytes and transfer to keratinocytes. To complement and extend our study, we of melanin by keratinocytes. Thus, we aimed to explore the effect of depleting Rab GTPases on melanin uptake and trafficking within keratinocytes. As a first approach, we used fluorescent microspheres as a melanin surrogate. However, the uptake of microspheres was observed to be independent of PAR-2, a receptor that is required for melanin uptakecentred our attention in the internalization of melanin by keratinocytes. Thus, we aimed to explore the effect of depleting Rab GTPases on melanin uptake and trafficking within keratinocytes. As a first approach, we used fluorescent microspheres as a melanin surrogate. However, the uptake of microspheres was observed to be independent of PAR-2, a receptor that is required for melanin uptake.Therefore, we concluded that microspheres were uptaken by keratinocytes through a different pathway than melanin. Subsequently, we developed a microscopy-based endocytosis assay using purified melanocores (melanosomes lacking the limiting membrane) from melanocytes, including a program to perform a semi-automated analysis. Melanocores are taken up by keratinocytes and accumulate in structures in the perinuclear area that resemble the physiological supranuclear cap observed in human skin. We then confirmed the involvement of PAR-2 receptor in the uptake of melanocores by keratinocytes, using the newly developed assay. Furthermore, we identified the role of four Rab GTPases on the uptake of melanocores by keratinocytes. Depletion of Rab1a and Rab5b from keratinocytes significantly reduced the uptake of melanocores, whereas Rab2a, and Rab14 silencing increased the amount the melanocores internalized by XB2 keratinocytes. In conclusion, we present evidence supporting keratinocyte-inducedmelanosome exocytosis from melanocytes, followed by endocytosis of the melanin core by keratinocytes as the predominant mechanism of melanin transfer in skin. Although advances have been made, there is a need for more effective and safer therapies directed at pigmentation disorders and also treatments for cosmetic applications. Hence, the understanding of the above mechanisms of skin pigmentation will lead to a greater appreciation of the molecular machinery underlying human skin pigmentation and could interest the pharmaceutical and cosmetic industries.

Synthesis, characterization and reactivity of new cobalt, palladium and nickel complexes bearing α-diimines and P, O ligands

This work describes the synthesis and characterization of a series of new α-diimine and P,O, β-keto and acetamide phosphines ligands, and their complexation to Ni(II), Co(II),Co(III) and Pd(II) to obtain a series of new compounds aiming to study their structural characteristics and to test their catalytic activity. All the compounds synthesized were characterized by the usual spectroscopic and spectrometric techniques: Elemental Analysis, MALDI-TOF-MS spectrometry, IR, UV-vis, 1H, 13C and 31P NMR spectroscopies. Some of the paramagnetic compounds were also characterized by EPR. For the majority of the compounds it was possible to solve their solid state structure by single crystal X-ray diffraction. Tests for olefin polymerization were performed in order to determine the catalytic activity of the Co(II) complexes. Chapter I presents a brief introduction to homogenous catalysis, highlighting the reactions catalyzed by the type of compounds described in this thesis, namely olefin polymerization and oligomerization and reactions catalyzed by the complexes bearing α-diimines and P,O type ligands. Chapter II is dedicated to the description of the synthesis of new α-diimines cobalt (II) complexes, of general formula [CoX2(α-diimine)], where X = Cl or I and the α-diimines are bis(aryl)acenaphthenequinonediimine) (Ar-BIAN) and 1,4-diaryl-2,3-dimethyl-1,4-diaza-1,3-butadiene (Ar-DAB). Structures solved by single crystal X-ray diffraction were obtained for all the described complexes. For some of the compounds, X-band EPR measurements were performed on polycrystalline samples, showing a high-spin Co(II) (S = 3/2) ion, in a distorted axial environment. EPR single crystal experiments on two of the compounds allowed us to determine the g tensor orientation in the molecular structure. In Chapter III we continue with the synthesis and characterization of more cobalt (II)complexes bearing α-diimines of general formula [CoX2(α-diimine)], with X = Cl or I and α-diimines are bis(aryl)acenaphthenequinonediimine) (Ar-BIAN) and 1,4-diaryl-2,3-dimethyl- 1,4-diaza-1,3-butadiene (Ar-DAB). The structures of three of the new compounds synthesized were determined by single crystal X-ray diffraction. A NMR paramagnetic characterization of all the compounds described is presented. Ethylene polymerization tests were done to determine the catalytic activity of several of the Co(II) complexes described in Chapter II and III and their results are shown. In Chapter IV a new rigid bidentate ligand, bis(1-naphthylimino)acenaphthene, and its complexes with Zn(II) and Pd(II), were synthesized. Both the ligand and its complexes show syn and anti isomers. Structures of the ligand and the anti isomer of the Pd(II) complex were solved by single crystal X-ray diffraction. All the compounds were characterized by elemental analysis, MALDI-TOF-MS spectrometry, and by IR, UV-vis, 1H, 13C, 1H-1H COSY, 1H-13C HSQC, 1H-13C HSQC-TOCSY and 1H-1H NOESY NMR when necessary. DFT studies showed that both conformers of [PdCl2(BIAN)] are isoenergetics and can be obtain experimentally. However, we can predict that the isomerization process is not available in square-planar complex, but is possible for the free ligand. The molecular geometry is very similar in both isomers, and only different orientations for naphthyl groups can be expected. Chapter V describes the synthesis of new P, O type ligands, β-keto phosphine, R2PCH2C(O)Ph, and acetamide phosphine R2PNHC(O)Me, as well as a series of new cobalt(III) complexes namely [(η5-C5H5)CoI2{Ph2PCH2C(O)Ph}], and [(η5- C5H5)CoI2{Ph2PNHC(O)Me}]. Treating these Co(III) compounds with an excess of Et3N, resulted in complexes η2-phosphinoenolate [(η5-C5H5)CoI{Ph2PCH…C(…O)Ph}] and η2- acetamide phosphine [(η5-C5H5)CoI{Ph2PN…C(…O)Me}]. Nickel (II) complexes were also obtained: cis-[Ni(Ph2PN…C(…O)Me)2] and cis-[Ni((i-Pr)2PN…C(…O)Me)2]. Their geometry and isomerism were discussed. Seven structures of the compounds described in this chapter were determined by single crystal X-ray diffraction. The general conclusions of this work can be found in Chapter VI.