Molecular reconstruction of a genetic code alteration

The genetic code establishes the rules that govern gene translation into proteins. It was established more than 3.5 billion years ago and it is one of the most conserved features of life. Despite this, several alterations to the standard genetic code have been discovered in both prokaryotes and eukaryotes, namely in the fungal CTG clade where a unique seryl transfer RNA (tRNACAG Ser) decodes leucine CUG codons as serine. This tRNACAG Ser appeared 272±25 million years ago through insertion of an adenosine in the middle position of the anticodon of a tRNACGA Ser gene, which changed its anticodon from 5´-CGA-3´ to 5´-CAG-3´. This most dramatic genetic event restructured the proteome of the CTG clade species, but it is not yet clear how and why such deleterious genetic event was selected and became fixed in those fungal genomes. In this study we have attempted to shed new light on the evolution of this fungal genetic code alteration by reconstructing its evolutionary pathway in vivo in the yeast Saccharomyces cerevisiae. For this, we have expressed wild type and mutant versions of the C. albicans tRNACGA Ser gene into S. cerevisiae and evaluated the impact of the mutant tRNACGA Ser on fitness, tRNA stability, translation efficiency and aminoacylation kinetics. Our data demonstrate that these mutants are expressed and misincorporate Ser at CUGs, but their expression is repressed through an unknown molecular mechanism. We further demonstrate, using in vivo forced evolution methodologies, that the tRNACAG Ser can be easily inactivated through natural mutations that prevent its recognition by the seryl-tRNA synthetase. The overall data show that repression of expression of the mistranslating tRNACAG Ser played a critical role on the evolution of CUG reassignment from Leu to Ser. In order to better understand the evolution of natural genetic code alterations, we have also engineered partial reassignment of various codons in yeast. The data confirmed that genetic code ambiguity affects fitness, induces protein aggregation, interferes with the cell cycle and results in nuclear and morphologic alterations, genome instability and gene expression deregulation. Interestingly, it also generates phenotypic variability and phenotypes that confer growth advantages in certain environmental conditions. This study provides strong evidence for direct and critical roles of the environment on the evolution of genetic code alterations.

Compósitos de polímeros naturais e nanopartículas metálicas

Esta tese descreve diversas estratégias de preparação assim como a caracterização de nanocompósitos com base em distintos biopolímeros. Em particular foi estudada a incorporação de nanopartículas (NPs) metálicas, nomeadamente de Ag, Cu e Au. Estes nanomateriais apresentam um potencial prático enorme em diversas áreas, no entanto foi investigada especificamente a sua aplicação como materiais antimicrobianos. No primeiro capítulo apresenta-se uma revisão bibliográfica, onde são realçados os principais tópicos discutidos ao longo da tese. Inicialmente apresenta-se uma contextualização deste trabalho sendo seguidamente apresentadas algumas considerações sobre nanocompósitos e o seu impacto tecnológico atual. Em seguida, descrevem-se as vantagens do uso de NPs como cargas nos materiais compósitos especificamente no caso de bionanocompósitos. Foi focado o uso da celulose como matriz uma vez que foi o composto “base” usado neste trabalho. Fez-se a descrição exaustiva das metodologias existentes na literatura para a preparação dos nanocompósitos celulósicos com diferentes NPs metálicas assim como das respetivas aplicações. Dentro das aplicações, foi dado especial destaque às propriedades antimicrobianas dos materiais preparados seja a nível da sua atividade antibacteriana ou antifúngica. Esta introdução privilegia o trabalho relacionado diretamente com os sistemas descritos nos capítulos subsequentes. No segundo capítulo apresentam-se os resultados obtidos para nanocompósitos de prata em matriz celulósica. Através do uso de metodologias, tais como a síntese in situ e a pós-deposição, foram preparados diversos materiais usando dois substratos celulósicos distintos nomeadamente a celulose vegetal e bacteriana. Estes nanocompósitos foram caracterizados em termos da sua morfologia e composição química, verificando-se a importância destas características na sua atividade antibacteriana. Foi verificado que nanocompósitos com teores de Ag de 5 x 10-4 (% m/m) são suficientes para obter atividade antibacteriana. A libertação de Ag(I) foi estudada em alguns destes materiais de modo a tentar perceber o mecanismo subjacente a este tipo de nanocompósitos. No terceiro capítulo é apresentado o estudo de NPs coloidais de Ag e Au como cargas para a preparação de nanocompósitos à base de quitosano nãomodificado e modificado quimicamente (derivado solúvel em água e derivado anfifílico). Foram preparados filmes finos de espessura de 9-14 μm, caracterizando-se as suas propriedades óticas e antibacterianas. As propriedades óticas foram ajustadas, quer pela variação do teor de NPs de Ag (0,3-3,9% m/m) ou pela utilização de amostras de NPs com distribuição de tamanho de partícula distinta. Foi investigada a atividade antibacteriana tanto para bactérias Gram-negativas (Klebsiella pneumoniae e Escherichia coli) como para Gram-positivas (Staphylococcus aureus). Para nanocompósitos preparados com o quitosano não modificado verificou-se uma dependência em função do teor de Ag. No caso do uso de derivados modificados, os materiais preparados mostraram uma eficiência superior, mesmo sem NPs de Ag. No quarto capítulo é apresentada a síntese e caracterização de nanocompósitos de pululano e NPs de Ag. Neste estudo é avaliada a atividade antifúngica dos filmes compósitos preparados contra o Aspergillus niger usando protocolos padrão. Estes materiais foram preparados na forma de filmes (66-74 μm de espessura) por evaporação de solvente da mistura de pululano e coloides de Ag. Foi observado o aumento da inibição do fungo na presença dos nanocompósitos, tendo sido pela primeira vez mostrado o efeito disruptivo destes materiais sobre os esporos do A. niger através da análise das imagens de SEM. Este efeito ocorre na presença dos filmes devido à presença das cargas de NPs de Ag dispersas no pululano. O desenvolvimento de materiais de papel com NPs de Cu é um desafio devido à propensão destas espécies em oxidar sob condições ambiente. No quinto capítulo é descrita pela primeira vez o estudo comparativo do crescimento e estabilidade de NPs de Cu em celulose vegetal e bacteriana. Para além disso foi avaliado o uso de nanoestruturas com diferentes dimensionalidades como cargas, nomeadamente nanoesferas e nanofios. Foi observado que o uso de nanofios aumenta a resistência à oxidação destes nanocompósitos para tempos de exposição ao ar mais prolongados. As matrizes celulósicas apresentam comportamento distinto no crescimento e/ou adsorção das NPs de Cu. A celulose bacteriana foi o substrato mais eficiente para retardar a oxidação das NPs. A atividade antibacteriana destes nanocompósitos foi avaliada. Ao longo desta dissertação são apresentados métodos distintos para a obtenção de nanocompósitos com base em biopolímeros e NPs metálicas. Estes estudos permitiram não só a preparação de novos nanocompósitos mas também compreender e otimizar os mecanismos subjacentes à sua preparação. Ao mesmo tempo, este trabalho contribuiu para a transferência de tecnologia e conhecimento entre a área da Nanotecnologia e a área dos materiais derivados de fontes renováveis. As propriedades apresentadas por estes nanomateriais mostraram a sua possível aplicação como novos materiais antimicrobianos, no entanto é possível antecipar futuras aplicações em outras áreas tecnológicas.

Microbe-mediated recovery of salt marshes contaminated with oil hydrocarbons

Salt marshes are highly productive intertidal habitats that serve as nursery grounds for many commercially and economically important species. Because of their location and physical and biological characteristics, salt marshes are considered to be particularly vulnerable to anthropogenic inputs of oil hydrocarbons. Sediment contamination with oil is especially dangerous for salt marsh vegetation, since low molecular weight aromatic hydrocarbons can affect plants at all stages of development. However, the use of vegetation for bioremediation (phytoremediation), by removal or sequestration of contaminants, has been intensively studied. Phytoremediation is an efficient, inexpensive and environmental friendly approach for the removal of aromatic hydrocarbons, through direct incorporation by the plant and by the intervention of degrading microbial populations in the rhizosphere (microbe-assisted phytoremediation). Rhizosphere microbial communities are enriched in important catabolic genotypes for degradation of oil hydrocarbons (OH) which may have a potential for detoxification of the sediment surrounding the roots. In addition, since rhizosphere bacterial populations may also internalize into plant tissues (endophytes), rhizocompetent AH degrading populations may be important for in planta AH degradation and detoxification. The present study involved field work and microcosms experiments aiming the characterization of relevant plant-microbe interactions in oilimpacted salt marshes and the understanding of the effect of rhizosphere and endosphere bacteria in the role of salt marsh plants as potential phytoremediation agents. In the field approach, molecular tools were used to assess how plant species- and OH pollution affect sediment bacterial composition [bulk sediment and sediment surrounding the roots (rhizosphere) of Halimione portulacoides and Sarcocornia perennis subsp. perennis] in a temperate estuary (Ria de Aveiro, Portugal) chronically exposed to OH pollution. In addition, the 16S rRNA gene sequences retrieved in this study were used to generate in silico metagenomes and to evaluate the distribution of potential bacterial traits in different microhabitats. Moreover, a combination of culture-dependent and -independent approaches was used to investigate the effect of oil hydrocarbons contamination on the structure and function of endophytic bacterial communities of salt marsh plants.Root systems of H. portulacoides and S. perennis subsp. perennis appear to be able to exert a strong influence on bacterial composition and in silico metagenome analysis showed enrichment of genes involved in the process of polycyclic aromatic hydrocarbon (PAH) degradation in the rhizosphere of halophyte plants. The culturable fraction of endophytic degraders was essentially closely related to known OH-degrading Pseudomonas species and endophytic communities revealed sitespecific effects related to the level of OH contamination in the sediment. In order to determine the effects of oil contamination on plant condition and on the responses in terms of structure and function of the bacterial community associated with plant roots (rhizosphere, endosphere), a microcosms approach was set up. The salt marsh plant Halimione portulacoides was inoculated with a previous isolated Pseudomonas sp. endophytic degrader and the 2-methylnaphthalene was used as model PAH contaminant. The results showed that H. portulacoides health and growth were not affected by the contamination with the tested concentration. Moreover, the decrease of 2-methylnaphthalene at the end of experiment, can suggest that H. portulacoides can be considered as a potential plant for future uses in phytoremedition approaches of contaminated salt marsh. The acceleration of hydrocarbon degradation by inoculation of the plants with the hydrocarbon-degrading Pseudomonas sp. could not, however, be demonstrated, although the effects of inoculation on the structure of the endophytic community observed at the end of the experiment indicate that the strain may be an efficient colonizer of H. portulacoides roots. The results obtained in this work suggest that H. portulacoides tolerates moderate concentrations of 2-methylnaphthalene and can be regarded as a promising agent for phytoremedition approaches in salt marshes contaminated with oil hydrocarbons. Plant/microbe interactions may have an important role in the degradation process, as plants support a diverse endophytic bacterial community, enriched in genetic factors (genes and plasmids) for hydrocarbon degradation.

Infection mechanism of Diplodia corticola

Diplodia corticola is regarded as the most virulent fungus involved in cork oak decline, being able to infect not only Quercus species (mainly Q. suber and Q. ilex), but also grapevines (Vitis vinifera) and eucalypts (Eucalyptus sp.). This endophytic fungus is also a pathogen whose virulence usually manifests with the onset of plant stress. Considering that the infection normally culminates in host death, there is a growing ecologic and socio-economic concern about D. corticola propagation. The molecular mechanisms of infection are hitherto largely unknown. Accordingly, the aim of this study was to unveil potential virulence effectors implicated in D. corticola infection. This knowledge is fundamental to outline the molecular framework that permits the fungal invasion and proliferation in plant hosts, causing disease. Since the effectors deployed are mostly proteins, we adopted a proteomic approach. We performed in planta pathogenicity tests to select two D. corticola strains with distinct virulence degrees for our studies. Like other filamentous fungi D. corticola secretes protein at low concentrations in vitro in the presence of high levels of polysaccharides, two characteristics that hamper the fungal secretome analysis. Therefore, we first compared several methods of extracellular protein extraction to assess their performance and compatibility with 1D and 2D electrophoretic separation. TCA-Acetone and TCA-phenol protein precipitation were the most efficient methods and the former was adopted for further studies. The proteins were extracted and separated by 2D-PAGE, proteins were digested with trypsin and the resulting peptides were further analysed by MS/MS. Their identification was performed by de novo sequencing and/or MASCOT search. We were able to identify 80 extracellular and 162 intracellular proteins, a milestone for the Botryosphaeriaceae family that contains only one member with the proteome characterized. We also performed an extensive comparative 2D gel analysis to highlight the differentially expressed proteins during the host mimicry. Moreover, we compared the protein profiles of the two strains with different degrees of virulence. In short, we characterized for the first time the secretome and proteome of D. corticola. The obtained results contribute to the elucidation of some aspects of the biology of the fungus. The avirulent strain contains an assortment of proteins that facilitate the adaptation to diverse substrates and the identified proteins suggest that the fungus degrades the host tissues through Fenton reactions. On the other hand, the virulent strain seems to have adapted its secretome to the host characteristics. Furthermore, the results indicate that this strain metabolizes aminobutyric acid, a molecule that might be the triggering factor of the transition from a latent to a pathogenic state. Lastly, the secretome includes potential pathogenicity effectors, such as deuterolysin (peptidase M35) and cerato-platanin, proteins that might play an active role in the phytopathogenic lifestyle of the fungus. Overall, our results suggest that D. corticola has a hemibiotrophic lifestyle, switching from a biotrophic to a necrotrophic interaction after plant physiologic disturbances.This understanding is essential for further development of effective plant protection measures.

Identification of molecules and pathways regulating mistranslation in Candida albicans

Candida albicans is the major fungal pathogen in humans, causing diseases ranging from mild skin infections to severe systemic infections in immunocompromised individuals. The pathogenic nature of this organism is mostly due to its capacity to proliferate in numerous body sites and to its ability to adapt to drastic changes in the environment. Candida albicans exhibit a unique translational system, decoding the leucine-CUG codon ambiguously as leucine (3% of codons) and serine (97%) using a hybrid serine tRNA (tRNACAGSer). This tRNACAGSer is aminoacylated by two aminoacyl tRNA synthetases (aaRSs): leucyl-tRNA synthetase (LeuRS) and seryl-tRNA synthetase (SerRS). Previous studies showed that exposure of C. albicans to macrophages, oxidative, pH stress and antifungals increases Leu misincorporation levels from 3% to 15%, suggesting that C. albicans has the ability to regulate mistranslation levels in response to host defenses, antifungals and environmental stresses. Therefore, the hypothesis tested in this work is that Leu and Ser misincorporation at CUG codons is dependent upon competition between the LeuRS and SerRS for the tRNACAGSer. To test this hypothesis, levels of the SerRS and LeuRS were indirectly quantified under different physiological conditions, using a fluorescent reporter system that measures the activity of the respective promoters. Results suggest that an increase in Leu misincorporation at CUG codons is associated with an increase in LeuRS expression, with levels of SerRS being maintained. In the second part of the work, the objective was to identify putative regulators of SerRS and LeuRS expression. To accomplish this goal, C. albicans strains from a transcription factor knock-out collection were transformed with the fluorescent reporter system and expression of both aaRSs was quantified. Alterations in the LeuRS/SerRS expression of mutant strains compared to wild type strain allowed the identification of 5 transcription factors as possible regulators of expression of LeuRS and SerRS: ASH1, HAP2, HAP3, RTG3 and STB5. Globally, this work provides the first step to elucidate the molecular mechanism of regulation of mistranslation in C. albicans.