This thesis pioneers diatom molecular identification and quantification through genome-scale methods, with four key aims: (i) reviewing DNA/RNA sequencing methods in aquatic biomonitoring to... Show moreThis thesis pioneers diatom molecular identification and quantification through genome-scale methods, with four key aims: (i) reviewing DNA/RNA sequencing methods in aquatic biomonitoring to highlight their strengths and limitations; (ii) unraveling the evolutionary history of Nitzschia palea and investigating species delimitation within the species complex; (iii) identifying silica genes in N. palea for insights into ecology and evolution; and (iv) assessing a genome-scale quantification method for diatom biomonitoring to improve accuracy and scalability in estimating abundances. The review (Chapter 2) emphasizes disparities between molecular and morphology-based approaches and introduces the challenges in accurately estimating species abundances. Chapter 3 explores N. palea's evolutionary history using transcriptome data and reveals reticulate evolutionary patterns resulting in a putative hybrid between populations with different morphological characteristics. Chapter 4 pinpoints silica genes in N. palea and reveals variations among different populations that may lead to differences in silica metabolism. Chapter 5 introduces a genome-scale quantification approach that provides a promising alternative for molecular diatom biomonitoring due to its improved taxonomic resolution and quantification accuracy. In summary, this thesis underscores that genome-scale methods' have a critical role in diatom identification and quantification, and in advancing our understanding of microalgal taxonomy, ecology, and evolution. Show less
DNA carries various forms of information. Out of these forms of information the most well-known is classical genetic information. Throughout this dissertation we discuss what is often referred to... Show moreDNA carries various forms of information. Out of these forms of information the most well-known is classical genetic information. Throughout this dissertation we discuss what is often referred to as the second layer of information on DNA: DNA mechanics. A sequence consisting of only A’s and T’s will bend differently from a sequence of G’s and C’s. An important consequence of this mechanical layer of information is the positioning of nucleosomes. Nucleosomes consist of 147 base pairs of DNA wrapped around a protein core, like a string around a spool. By either allowing or restricting access to a binding site, a nucleosome may serve as an on/off switch, of which the location is extremely important. A third layer of information on DNA is translation speed. Translation speed refers to the rate at which a protein is created, and it depends on the codons used in a genetic sequence. The research in this thesis investigates how these layers of information are multiplexed. It uses multiple novel approaches, one of them being the use of weighted graphs consisting of all possible DNA sequences to find the very best and very worst nucleosome-attracting sequences. Show less
In this thesis, I targeted the orchid genus Lepanthes, one of the six genera of angiosperms that surpasses 1,000 species in the Neotropics, as a study model to investigate the evolutionary... Show moreIn this thesis, I targeted the orchid genus Lepanthes, one of the six genera of angiosperms that surpasses 1,000 species in the Neotropics, as a study model to investigate the evolutionary processes that promoted species diversifications. To investigate this, we improved the taxonomy of the group integrating a solid phylogenetic framework with morphological evolution, assessing inter-specific relationships in species complexes with hundreds of DNA markers using anchored hybrid enrichment approach, and describing new species. In addition, we addressed the pollination of Trichosalpinx through the study of floral anatomy, pollinator behavior, and floral traits. Trichosalpinx flowers are pollinated exclusively by female biting midges that are attracted by the small quantities of proteins secreted on the flowers. Finally, we inferred the biogeographical history and diversification dynamics of the two largest Neotropical orchid groups (Cymbidieae and Pleurothallidinae), using densely sampled phylogenies coupled with geological datasets and discussed the impact of biogeographical events and orogeny on the species richness of Lepanthes. Species diversification is correlated with Andean orogeny, and multiple migrations and recolonizations across the Andes indicate that mountains do not constrain orchid dispersal over long timescales. This thesis provides new insights into the complex evolution of one of the most species-rich angiosperm. Show less
The four possible segments A, T, C and G that link together to form DNA molecules, and with their ordering encode genetic information, are not only different in name, but also in their physical and... Show moreThe four possible segments A, T, C and G that link together to form DNA molecules, and with their ordering encode genetic information, are not only different in name, but also in their physical and chemical properties. The result is that DNA molecules with different sequences have different physical behavior. For instance, one sequence may lead to a very flexible DNA molecule, another to a very stiff one. A DNA molecule with a given sequence may be straight, or intrinsically curved. This leads to an interplay between the information stored in a DNA molecule on one hand, and the physical properties of that molecule on the other. This is of great importance in our cells, where lengths of DNA far longer than the size of the cells that contain them need to be significantly folded up. The research presented in this thesis looks at how we can model this interplay, what its effects can be, and whether nature has made use of it to encode mechanical signals into real genomes. Show less
The explosive increase in infections by pathogens is a major problem in the clinic today. The theme of this thesis was to find novel antibiotics from actinomycetes. Next-generation... Show more The explosive increase in infections by pathogens is a major problem in the clinic today. The theme of this thesis was to find novel antibiotics from actinomycetes. Next-generation sequencing revealed that the biosynthetic potential of actinomycetes had been grossly underestimated. In this thesis, different antibiotics-eliciting strategies, including microbial cocultivation, streptomycin-resistant mutation, overexpression of pathway-specific activator, variation of culture conditions, were utilized to enforce fluctuations in the production of bioactive compounds in actinomycetes, after which, NMR-based metabolic profiling was used to facilitate uncovering those elicited molecules. This pipeline allowed the discovery of new antibiotics involving various chemical skeletons, such as 7-prenylisatin, methoxylated isocoumarins, endophenazines, and C-glycosylpyranonaphthoquinones. On the other hand, genome-mining methodology enabled the discovery of a group of endophenasides and leucanicidin in Kitasatospora sp. MBT66, whereby the rhamnosylation of both scaffold are executed by a same promiscuous glycosyltransferase. Last but not least, a novel antibiotic termed lugdunomycin with unprecedented chemical scaffold, as well as a number of new angucycline-type antibiotics, were characterized from Streptomyces sp. QL37. The biosynthetic pathway of lugdunomycin was deciphered by genetic knockout and OSMAC (One Strain MAny Compound) strategy. In summary, this thesis explores an interface of genomics and metabolomics to accelerate new antibiotics discovery. Show less