Biased Evolution : Causes and Consequences

Brandis, Gerrit

January 2016

In evolution alternative genetic trajectories can potentially lead to similar phenotypic outcomes. However, certain trajectories are preferred over others. These preferences bias the genomes of living organisms and the underlying processes can be observed in ongoing evolution. We have studied a variety of biases that can be found in bacterial chromosomes and determined the selective causes and functional consequences for the cell. We have quantified codon usage bias in highly expressed genes and shown that it is selected to optimise translational speed. We further demonstrated that the resulting differences in decoding speed can be used to regulate gene expression, and that the use of ‘non-optimal’ codons can be detrimental to reading frame maintenance. Biased gene location on the chromosome favours recombination between genes within gene families and leads to co-evolution. We have shown that such recombinational events can protect these gene families from inactivation by mobile genetic elements, and that chromosome organization can be selectively maintained because inversions can lead to the formation of unstable hybrid operons. We have used the development of antibiotic resistance to study how different bacterial lifestyles influence evolutionary trajectories. For this we used two distinct pairs of antibiotics and disease-causing bacteria, namely (i) Mycobacterium tuberculosis that is treated with rifampicin and (ii) Escherichia coli that is treated with ciprofloxacin. We have shown that in the slow-growing Mycobacterium tuberculosis, resistance mutations are selected for high-level resistance. Fitness is initially less important, and over time fitness costs can be ameliorated by compensatory mutations. The need for rapid growth causes the selection of ciprofloxacin resistance in Escherichia coli not only to be selected on the basis of high-level resistance but also on high fitness. Compensatory evolution is therefore not required and is not observed. Taken together, our results show that the evolution of a phenotype is the product of multiple steps and that many factors influence which trajectory is the most likely to occur and be most beneficial. Over time, selection will favour this particular trajectory and lead to biased evolution, affecting genome sequence and organization.

Evolution

Codon usage bias

Post-transcriptional regulation

Recombination

Inversion

EF-Tu

Frameshift suppression

Antibiotic resistance

Rifampicin

Ciprofloxacin

Compensatory evolution

Drug efflux

RNA polymerase

DNA gyrase

Investigating Molecular Evolution of Rhodopsin Using Likelihood/Bayesian Phylogenetic Methods

Du, Jingjing

22 July 2010

Rhodopsin, a visual pigment protein found in retinal photoreceptors, mediates vision at low-light levels. Recent studies focusing primarily in human and mouse have challenged the assumption of neutral evolution of synonymous substitutions in mammals. Using recently developed likelihood-based codon models accounting for mutational bias and selection, we find significant evidence for selective constraint on synonymous substitutions in mammalian rhodopsins, and a preference for cytosine at 3rd codon positions. A second project investigated adaptive evolution in rhodopsin, in view of theories of nocturnality in early mammals. We detected a significant acceleration of non-synonymous substitution rates at the origins of therian mammals, and a tendency of synonymous substitutions towards C-ending codons prior to that. These findings suggest an evolutionary scenario in which synonymous substitutions that increase mRNA stability and/or translation efficiency may have preceded adaptive non-synonymous evolution in early mammalian rhodopsins. These findings have important implications for theories of early mammalian nocturnality.

Molecular Evolution

Likelihood and Bayesian methods

Phylogenetics

Rhodopsin

Natural Selection

Codon Usage Bias

Nocturnality

Early mammals

Visual Pigment

Adaptive Evolution

Vision

GPCR

0715

0307

0369

Sekretované aspartátové proteázy kvasinky Candida parapsilosis. / The secreted aspartic proteases of Candida parapsilosis.

Marečková, Lucie

January 2012

Candida parapsilosis is an opportunistic fungal pathogen of humans causing a variety of infections. Immunocompromised individuals represent the most threatened group of patients. The increasing frequency of infections and occurrence of drug resistant strains are the main reasons for research focused on novel antimycotic compounds. Inhibition of secreted aspartic proteases (Sap) of pathogenic Candida spp. appears to be a potential target of therapeutic intervention. The genome of C. parapsilosis contains at least three genes coding for secreted aspartic proteases, denominated SAPP1-3. Protease Sapp1p has been well biochemically and structurally characterized, whereas Sapp2p and Sapp3p have been given less attention. The first part of the thesis is focused on structural analysis of Sapp1p complexes with selected peptidomimetic inhibitors binding to the active site of the enzyme. In addition, complex of the isoenzyme Sapp2p with the well-known secreted aspartate inhibitor Pepstatin A has been analyzed. The second part is related to the fact that C. parapsilosis belongs to the Candida spp. with the unique ability to translate standard leucine CUG codon mostly as serine. Even though it is a non-conservative substitution of hydrophobic amino acids for a hydrophilic one, this unique ability is maintained for more...

Evolution of symbiotic lineages and the origin of new traits

Tamarit, Daniel

January 2016

This thesis focuses on the genomic study of symbionts of two different groups of hymenopterans: bees and ants. Both groups of insects have major ecological impact, and investigating their microbiomes increases our understanding of their health, diversity and evolution. The study of the bee gut microbiome, including members of Lactobacillus and Bifidobacterium, revealed genomic processes related to the adaptation to the gut environment, such as the expansion of genes for carbohydrate metabolism and the acquisition of genes for interaction with the host. A broader genomic study of these genera demonstrated that some lineages evolve under strong and opposite substitution biases, leading to extreme GC content values. A comparison of codon usage patterns in these groups revealed ongoing shifts of optimal codons. In a separate study we analysed the genomes of several strains of Lactobacillus kunkeei, which inhabits the honey stomach of bees but is not found in their gut. We observed signatures of genome reduction and suggested candidate genes for host-interaction processes. We discovered a novel type of genome architecture where genes for metabolic functions are located in one half of the genome, whereas genes for information processes are located in the other half. This genome organization was also found in other Lactobacillus species, indicating that it was an ancestral feature that has since been retained. We suggest mechanisms and selective forces that may cause the observed organization, and describe processes leading to its loss in several lineages independently. We also studied the genome of a species of Rhizobiales bacteria found in ants. We discuss its metabolic capabilities and suggest scenarios for how it may affect the ants’ lifestyle. This genome contained a region with homology to the Bartonella gene transfer agent (GTA), which is a domesticated bacteriophage used to transfer bacterial DNA between cells. We propose that its unique behaviour as a specialist GTA, preferentially transferring host-interaction factors, originated from a generalist GTA that transferred random segments of chromosomal DNA. These bioinformatic analyses of previously uncharacterized bacterial lineages have increased our understanding of their physiology and evolution and provided answers to old and new questions in fundamental microbiology.

symbiosis

host-association

Lactobacillus

Bifidobacterium

Rhizobiales

Bartonella

honeybees

ants

codon usage bias

genome architecture

genome organization

gene transfer agent

evolutionary genomics

comparative genomics

Mechanisms of translational regulation in bacteria

Bentele, Kajetan

21 August 2013

Diese Arbeit untersucht den Zusammenhang zwischen Mechanismen der translationalen Regulation und der Genomorganisation in Bakterien. Der erste Teil der Arbeit analysiert die Beziehung zwischen der Translationseffizienz von Genen und der Häufigkeit bestimmter Codons am Genanfang. Es ist bekannt, dass die Häufigkeitsverteilung der Codons am Anfang der Gene bei einigen Organismen eine andere ist als sonst im Genom. Durch die systematische Analyse von ungefähr 400 bakteriellen Genomen, evolutionären Simulationen und experimentellen Untersuchungen sind wir zu dem Schluss gekommen, dass die beobachtete Abweichung der Codonhäufigkeiten wohl eine Konsequenz der Notwendigkeit ist, RNA Sekundärstruktur in der Nähe des Translationsstarts zu vermeiden und somit eine effiziente Initiation der Translation zu gewährleisten. Im zweiten Teil der Arbeit untersuchen wir den Einfluss der Genreihenfolge innerhalb eines Operons auf die Fitness von E. coli. In bakteriellen Genomen vereint ein Operon funktionell zusammengehörige Gene, die in einer mRNA zusammen transkribiert werden und somit in der Expression stark korreliert sind. Daneben kann die translationale Kopplung, d. h. die Interdependenz der Translationseffizienz zwischen benachbarten Genen innerhalb einer solchen mRNA, eine bestimmte Proteinstöchiometrie weiter stabilisieren. Mithilfe eines Modells für die translationale Kopplung sowie für den Chemotaxis Signalweg konnten wir zeigen, dass die native Genreihenfolge eine der Permutationen ist, die am meisten zur Robustheit der Chemotaxis beitragen. Die translationale Kopplung ist daher ein wichtiger Faktor, der die Anordnung der Gene innerhalb des Chemotaxis Operon bestimmt. Diese Arbeit zeigt, dass die Anforderungen einer effizienten Genexpression sowie die Robustheit wichtiger zellulärer Funktionen einen Einfluss auf die Organisation eines Genoms haben können: einerseits bei der Wahl der Codons am Anfang der Gene, andererseits auf die Ordnung der Gene innerhalb eines Operons. / This work investigates the relationship between mechanisms of translational regulation and genome organization in bacteria. The first part analyzes the connection between translational efficiency and codon usage at the beginning of genes. It is known for some organisms that usage of synonymous codons at the gene start deviates from the codon usage elsewhere in the genome. By analyzing about 400 bacterial genomes, evolutionary simulations and experimental investigations, we conclude that the observed deviation of codon usage at the beginning of genes is most likely a consequence of the need to suppress mRNA structure around the ribosome binding site, thereby allowing efficient initiation of translation. We investigate further driving forces for genome organization by studying the impact of gene order within an operon on the fitness of bacterial cells. Operons group functionally related genes which are transcribed together as single mRNAs in E. coli and other bacteria. Correlation of protein levels is thus to a large extent attributed to this coupling on the transcriptional level. In addition, translational coupling, i.e. the interdependence of translational efficiency between neighboring genes within such a mRNA, can stabilize a desired stoichiometry between proteins. Here, we study the role of translational coupling in robustness of E. coli chemotaxis. By employing a model of translational coupling and simulating the underlying signal transduction network we show that the native gene order ranks among the permutations contributing most to robustness of chemotaxis. We therefore conclude that translational coupling is an important determinant of the gene order within the chemotaxis operon. Both these findings show that requirements for efficient gene expression and robustness of cellular function have a pronounced impact on the genomic organization, influencing the local codon usage at the beginning of genes and the order of genes within operons.

Translationseffizienz

Bioinformatik

RNA-Faltung

translationale Kopplung

Chemotaxis

bioinformatics

codon usage

RNA folding

translation efficiency

translational coupling

chemotaxis

570 Biowissenschaften, Biologie

32 Biologie

WG 1870

ddc:570

The Role of Polyadenylation in Human Papillomavirus Type 16 Late Gene Expression

Öberg, Daniel

January 2005

<p>High-risk type human papillomaviruses (HPVs) are associated with cancer. HPVs are strictly epitheliotropic and infect basal cell layers, establishing a life cycle strongly linked to the differentiation stage of the infected cells. The viral capsid late genes, L2 and L1, are only expressed in terminally differentiated epithelium. Late gene expression involves regulation of most gene processing events including transcription, splicing, polyadenylation, mRNA stability and translation. </p><p>Both L2 and L1 have elements present in the open reading frames (ORFs) negatively affecting mRNA levels and translation. The negative elements in L1 were mapped to the first 514 nucleotides, with the strongest inhibitory effect located in the first 129 nucleotides. The negative elements in the L2 sequence were concentrated in two locations on the gene. Both genes were mutated by changing the nucleotide sequence while retaining the amino acid sequence. Mutating the first 514 nucleotides in L1 deactivated the negative elements while the entire L2 gene had to be mutated to achieve the same result. The L2 protein was found to localise the L1 protein into a punctuated pattern in the nucleus.</p><p>In the HPV-16 genome the negative elements reside in regions important for regulation of polyadenylation and splicing, critical for late gene expression. By exchanging parts of the L2 gene in subgenomic constructs with the corresponding mutant sequence we show that certain features of the L2 elements direct splicing to the L1 splice acceptor, and also regulate the efficiency of the early polyadenylation site. Cumulative binding of hnRNP H to the L2 mRNA gradually increased polyadenylation efficiency. Most interestingly, hnRNP H levels were downregulated in more differentiated epithelial cells. </p><p>Elucidation of how expression of the immunogenic late proteins is regulated would be greatly beneficial in prevention and treatment of HPV infection and thereby cancer.</p>

Molecular biology

HPV-16

polyadenylation

mRNA stability

codon usage

hnRNP H

DSE

splicing

negative element

RNA processing

Molekylärbiologi

Molecular biology

Molekylärbiologi

The Role of Polyadenylation in Human Papillomavirus Type 16 Late Gene Expression

Öberg, Daniel

January 2005

High-risk type human papillomaviruses (HPVs) are associated with cancer. HPVs are strictly epitheliotropic and infect basal cell layers, establishing a life cycle strongly linked to the differentiation stage of the infected cells. The viral capsid late genes, L2 and L1, are only expressed in terminally differentiated epithelium. Late gene expression involves regulation of most gene processing events including transcription, splicing, polyadenylation, mRNA stability and translation. Both L2 and L1 have elements present in the open reading frames (ORFs) negatively affecting mRNA levels and translation. The negative elements in L1 were mapped to the first 514 nucleotides, with the strongest inhibitory effect located in the first 129 nucleotides. The negative elements in the L2 sequence were concentrated in two locations on the gene. Both genes were mutated by changing the nucleotide sequence while retaining the amino acid sequence. Mutating the first 514 nucleotides in L1 deactivated the negative elements while the entire L2 gene had to be mutated to achieve the same result. The L2 protein was found to localise the L1 protein into a punctuated pattern in the nucleus. In the HPV-16 genome the negative elements reside in regions important for regulation of polyadenylation and splicing, critical for late gene expression. By exchanging parts of the L2 gene in subgenomic constructs with the corresponding mutant sequence we show that certain features of the L2 elements direct splicing to the L1 splice acceptor, and also regulate the efficiency of the early polyadenylation site. Cumulative binding of hnRNP H to the L2 mRNA gradually increased polyadenylation efficiency. Most interestingly, hnRNP H levels were downregulated in more differentiated epithelial cells. Elucidation of how expression of the immunogenic late proteins is regulated would be greatly beneficial in prevention and treatment of HPV infection and thereby cancer.

Molecular biology

HPV-16

polyadenylation

mRNA stability

codon usage

hnRNP H

DSE

splicing

negative element

RNA processing

Molekylärbiologi

Molecular biology

Molekylärbiologi

Investigating Molecular Evolution of Rhodopsin Using Likelihood/Bayesian Phylogenetic Methods

Du, Jingjing

22 July 2010

Rhodopsin, a visual pigment protein found in retinal photoreceptors, mediates vision at low-light levels. Recent studies focusing primarily in human and mouse have challenged the assumption of neutral evolution of synonymous substitutions in mammals. Using recently developed likelihood-based codon models accounting for mutational bias and selection, we find significant evidence for selective constraint on synonymous substitutions in mammalian rhodopsins, and a preference for cytosine at 3rd codon positions. A second project investigated adaptive evolution in rhodopsin, in view of theories of nocturnality in early mammals. We detected a significant acceleration of non-synonymous substitution rates at the origins of therian mammals, and a tendency of synonymous substitutions towards C-ending codons prior to that. These findings suggest an evolutionary scenario in which synonymous substitutions that increase mRNA stability and/or translation efficiency may have preceded adaptive non-synonymous evolution in early mammalian rhodopsins. These findings have important implications for theories of early mammalian nocturnality.

Molecular Evolution

Likelihood and Bayesian methods

Phylogenetics

Rhodopsin

Natural Selection

Codon Usage Bias

Nocturnality

Early mammals

Visual Pigment

Adaptive Evolution

Vision

GPCR

0715

0307

0369

PCR-based Synthesis of Codon Optimized cry2Aa Gene for Production of Shoot and Fruit Borer (Leucinodes orbonalis) Resistant Eggplant (Solanum melongena L.) Cultivars

Gupta, Rahul

20 January 2006

Brinjal shoot and fruit borer (Leucinodes orbonalis Guenee) is a major limiting factor in commercial cultivation of eggplant in southeast Asia. Extensive use of pesticides as well as the conventional breeding methods have been ineffective in controlling the borer so there is a need for Integrated Pest Management (IPM) strategies for its control. Bacillus thuringiensis (Bt) is known to produce a variety of insecticidal crystal proteins toxic to lepidopteran, dipteran and coleopteran pests. The Cry2Aa protein has been found to be more toxic to brinjal shoot and fruit borer than Cry1Ab. My objective was to develop eggplant cultivars that express a codon-optimized cry2Aa gene, the sequence of which is based on that of an Indian isolate of Bt, with the eventual goal of producing fully resistant cultivars. The cry2Aa gene was modified for optimal expression in eggplant using the codon usage frequencies based on solanaceous sequences (eggplant, tomato and pepper). The GC content was increased from 34.3% in the native gene to 41.3% in the optimized gene, thus removing the AT-rich regions that are typical for Bt cry genes. Also, other mRNA destabilizing and hairpin forming structure sequences were removed. The gene was synthesized in four different parts with complementary restriction sites. A total of 152 oligonucleotides (oligos) was used to assemble the 1.9 kb gene using dual asymmetric (DA) and overlap extension (OE) PCR techniques. The individual parts were subsequently ligated using the complementary restriction sites and inserted into vector pCAMBIA 1302. Also, the transformation efficiency of 12 different eggplant cultivars was tested using plasmid pHB2892 to predict utility for transformation with the synthetic cry2Aa. / Master of Science

genetic transformation

GFP

Bacillus thuringiensis

synthetic gene

Brinjal shoot and fruit borer

gene synthesis

codon usage

codon optimization

Solanum melongena

transgenic plants

Descoberta e caracterização de vírus emergentes e reergentes em áreas peri-florestais. / Discovering and characterizing emerging and re-emerging viruses in communities encroaching tropical hotspots.

Paola, Nicholas Di

21 March 2018

A fragmentação e a invasão de florestas tropicais e a crescente concentração de assentamentos humanos aumentaram exponencialmente as chances de exposição a vírus emergentes e emergentes. Dado o grande potencial de espalhamento de patógenos em população humanas, a identificação e caracterização de agentes patogênicos circulantes podem melhorar a atenção primária e as capacidades de diagnóstico para um agente emergente futuro. As abordagens moleculares e metagenômicas que utilizam as tecnologias de sequenciação da próxima geração levaram a descoberta e caracterização de muitos vírus emergentes na última década. Além disso, as abordagens in silico também podem ajudar a identificar vírus emergentes usando apenas dados de sequenciamento publicamente disponíveis. Além disso, estimar a ascendência filogenética e até mesmo analisar as mudanças no uso de codons são ferramentas adicionais que podem melhorar a nossa compreensão de vírus emergentes ou reemergentes. Este projeto visou aplicar essas ferramentas em ambos os vírus que poderiam estar circulando no Brasil: Parvovírus B19 e vírus da Febre Amarela. Também exploramos as aplicações de modelos ocultos de Markov e índice de adaptação de codons usando dados publicamente disponíveis. Esperamos que este trabalho forneça uma prova de conceito para futuros projetos metagenômicos e demonstre a utilidade das várias técnicas moleculares e bioinformáticas no estudo de vírus emergentes. / Fragmentation and encroachment of tropical rainforests and the growing concentration of human settlements have exponentially increased chances of exposure to re-emerging and emerging viruses. Given the large potential for pathogens to spillover and spread in a population, identifying and characterizing circulating human pathogens could improve the readiness and diagnostic capabilities for a future emergence. Molecular and metagenomic approaches using next-generation sequencing technologies have led to the discovery and characterization of many emerging viruses over the last decade. In complement, in silico approaches can also help identify emerging viruses using only publicly available sequencing data. Moreover, estimating the phylogenetic ancestry and even analyzing changes in codon usage are additional tools that can improve our understanding of an emerging or re-emerging virus. This project aimed to apply these tools to two viruses that could be circulating in Brazil: Parvovirus B19 and Yellow Fever virus. We also explored the applications of Hidden Markov models and codon adaptation index using publicly available data. We expect this work to provide a proof-of-concept for future metagenomic projects, and demonstrate the utility for several molecular and bioinformatics techniques in the study of emerging viruses.

Codon usage

Emerging virus

Evolução viral

Filogenia

Hidden Markov Models

Modelos Ocultos de Markov

Parvovirus B19

Parvovírus B19

Phylogeny

Uso do codão

Viral Evolution

Vírus da febre amarela

Vírus emergente

Yellow Fever virus