History of chromosome rearrangements reflects the spatial organization of yeast chromosomes

Three-dimensional (3D) organization of genomes affects critical cellular processes such as transcription, replication, and deoxyribo nucleic acid (DNA) repair. While previous studies have investigated the natural role, the 3D organization plays in limiting a possible set of genomic rearrangements following DNA repair, the influence of specific organizational principles on this process, particularly over longer evolutionary time scales, remains relatively unexplored. In budding yeast S.cerevisiae, chromosomes are organized into a Rabl-like configuration, with clustered centromeres and telomeres tethered to the nuclear periphery. Hi-C data for S.cerevisiae show that a consequence of this Rabl-like organization is that regions equally distant from centromeres are more frequently in contact with each other, between arms of both the same and different chromosomes. Here, we detect rearrangement events in Saccharomyces species using an automatic approach, and observe increased rearrangement frequency between regions with higher contact frequencies. Together, our results underscore how specific principles of 3D chromosomal organization can influence evolutionary events.National Institutes of Health (U.S.) (Grant GM114190

The role of chromosome-nuclear envelope attachments in 3D genome organization

Chromosomes are intricately folded and packaged in the cell nucleus and interact with the nuclear envelope. This complex nuclear architecture has a profound effect on how the genome works and how the cells function. The main goal of review is to highlight recent studies on the effect of chromosome–nuclear envelope interactions on chromatin folding and function in the nucleus. The data obtained suggest that chromosome–nuclear envelope attachments are important for the organization of nuclear architecture in various organisms. A combination of experimental cell biology methods with computational modeling offers a unique opportunity to explore the fundamental relationships between different aspects of 3D genome organization in greater details. This powerful interdisciplinary approach could reveal how the organization and function of the genome in the nuclear space is affected by the chromosome–nuclear envelope attachments and will enable the development of novel approaches to regulate gene expression

Population genomics of domestic and wild yeasts

The natural genetics of an organism is determined by the distribution of sequences of its genome. Here we present one- to four-fold, with some deeper, coverage of the genome sequences of over seventy isolates of the domesticated baker's yeast, _Saccharomyces cerevisiae_, and its closest relative, the wild _S. paradoxus_, which has never been associated with human activity. These were collected from numerous geographic locations and sources (including wild, clinical, baking, wine, laboratory and food spoilage). These sequences provide an unprecedented view of the population structure, natural (and artificial) selection and genome evolution in these species. Variation in gene content, SNPs, indels, copy numbers and transposable elements provide insights into the evolution of different lineages. Phenotypic variation broadly correlates with global genome-wide phylogenetic relationships however there is no correlation with source. _S. paradoxus_ populations are well delineated along geographic boundaries while the variation among worldwide _S. cerevisiae_ isolates show less differentiation and is comparable to a single _S. paradoxus_ population. Rather than one or two domestication events leading to the extant baker's yeasts, the population structure of _S. cerevisiae_ shows a few well defined geographically isolated lineages and many different mosaics of these lineages, supporting the notion that human influence provided the opportunity for outbreeding and production of new combinations of pre-existing variation

Consequences of local and global chromatin mechanics to adaption and genome stability in the budding yeast Saccharomyces cerevisiae

Le génome de la levure de boulanger Saccharomyces cerevisiae a évolué à partir d'un ancêtre chez lequel une profonde décompaction du génome s'est produite à la suite de la perte de la méthylation de la lysine 9 de l'histone H3, il y a environ 300 millions d'années. Il a été proposé que cette décompaction du génome a entraîné une capacité accrue des levures à évoluer par des mécanismes impliquant des taux de recombinaison méiotique et de mutation exceptionnellement élevés. La capacité à évoluer accrue qui en résulte pourrait avoir permis des adaptations uniques, qui en ont fait un eucaryote modèle idéal et un outil biotechnologique. Dans cette thèse, je présenterai deux exemples de la façon dont les adaptations locales et globales du génome se reflètent dans les changements des propriétés mécaniques de la chromatine qui, à leur tour, indiquent un phénomène de séparation de phase causée par les modifications post-traductionnelles des histones et des changements dans les taux d'échange des histones. Dans un premier manuscrit, je présente des preuves d'un mécanisme par lequel la relocalisation du locus INO1, gène actif répondant à la déplétion en inositol, du nucléoplasme vers l'enveloppe nucléaire, augmente la vitesse d'adaptation et la robustesse métabolique aux ressources fluctuantes, en augmentant le transport des ARNm vers le cytosol et leur traduction. La répartition d'INO1 vers l'enveloppe nucléaire est déterminée par une augmentation locale des taux d'échange d'histones, ce qui entraîne sa séparation de phase du nucléoplasme en une phase de faible densité plus proche de la périphérie nucléaire. J'ai quantifié les propriétés mécaniques de la chromatine du locus du gène dans les états réprimé et actif en analysant le déplacement de 128 sites LacO fusionnés au gène liant LacI-GFP en calculant diffèrent paramètres tel que la constante de ressort effective et le rayons de confinement du locus. De plus, j'ai mesuré l'amplitude et le taux d'expansion en fonction du temps du réseau LacO et j'ai observé une diminution significative du locus à l'état actif, ce qui est cohérent avec le comportement de ressort entropique de la chromatine décompactée. J'ai montré que les séquences d'éléments en cis dans le promoteur du locus, essentielles à la séparation de phase, sont des sites de liaison pour les complexes de remodelage de la chromatine effectuant l'acétylation des histones. Ces modifications de la chromatine entraînent une augmentation des taux d'échanges des sous-unités des complexes d'histones, et une séparation de phase locale de la chromatine. Enfin, je présente l’analyse de simulations in silico qui montrent que la séparation de phase locale de la chromatine peut être prédite à partir d'un modèle de formation/disruption des interactions multivalentes protéine-protéine et protéine-ADN qui entraîne une diminution de la dynamique de l'ADN. Ces résultats suggèrent un mécanisme général permettant de contrôler la formation rapide des domaines de la chromatine, bien que les processus spécifiques contribuant à la diminution de la dynamique de l'ADN restent à étudier. Dans un second manuscrit, je décris comment nous avons induit la « retro-évolution » de la levure en réintroduisant la méthylation de la lysine 9 de l'histone H3 par l'expression de deux gènes de la levure Schizosaccaromyces pombe Spswi6 et Spclr4. Le mutant résultant présente une augmentation de la compaction de la chromatine, ce qui entraîne une réduction remarquable des taux de mutation et de recombinaison. Ces résultats suggèrent que la perte de la méthylation de la lysine 9 de l'histone H3 pourrait avoir augmenté la capacité à l'évoluer. La stabilité inhabituelle du génome conférée par ces mutations pourrait être utile pour l'ingénierie métabolique de S. cerevisiae, dans laquelle il est difficile de maintenir des gènes exogènes intégrés pour les applications de nombreux processus biotechnologiques courants tels que la production de vin, de bière, de pain et de biocarburants. Ces résultats soulignent l'influence des propriétés physiques d'un génome sur son architecture et sa fonction globales.The genome of the budding yeast Saccharomyces cerevisiae evolved from an ancestor in which a profound genome decompaction occurred as the result of the loss of histone H3 lysine 9 methylation, approximately 300 million years ago. This decompaction may have resulted in an increased capacity of yeasts to evolve by mechanisms that include unusually high meiotic recombination and mutation rates. Resultant increased evolvability may have enabled unique adaptations, which have made it an ideal model eukaryote and biotechnological tool. In this thesis I will present two examples of how local and global genome adaptations are reflected in changes in the mechanical properties of chromatin. In a first manuscript, I present evidence for a mechanism by which partitioning of the active inositol depletion-responsive gene locus INO1 from nucleoplasm to the nuclear envelope increases the speed of adaptation and metabolic robustness to fluctuating resources, by increasing mRNA transport to the cytosol and their translation. Partitioning of INO1 to the nuclear envelope is driven by a local increase in histone exchange rates, resulting in its phase separation from the nucleoplasm into a low-density phase closer to the nuclear periphery. I quantified the mechanical properties of the gene locus chromatin in repressed and active states by monitoring mean-squared displacement of an array of 128 LacO sites fused to the gene binding LacI-GFP and calculating effective spring constants and radii of confinement of the array. Furthermore, I measured amplitude and rate of time-dependent expansion of the LacO array, and observed a significant decrease for the active-state locus which is consistent with entropic spring behavior of decompacted chromatin. I showed that cis element sequences in the promoter and upstream of the locus that are essential to phase separation are binding sites for chromatin remodeling complexes that perform histone acetylation among other modifications that result in increased histone complex exchange rates, and consequent local chromatin phase separation. Finally, I present analytical simulations that show that local phase separation of chromatin can be predicted from a model of formation/disruption of multivalent protein-protein and protein-DNA interactions that results in decreased DNA dynamics. These results suggest a general mechanism to control rapid formation of chromatin domains, although the specific processes contributing to the decreased DNA dynamics remain to be investigated. In a second manuscript, I describe how we retro-evolutionarily engineered yeast by reintroducing histone H3 lysine 9 methylation through the expression of two genes from the yeast Schizosaccaromyces pombe Spswi6 and Spclr4. This mutant shows an increase in compaction, resulting in remarkable reduced mutation and recombination rates. These results suggest that loss of histone H3 lysine 9 methylation may have increased evolvability. The unusual genome stability imparted by these mutations could be of value to metabolically engineering S. cerevisiae, in which it is difficult to maintain integrated exogenous genes for applications for many common biotechnological processes such as wine, beer, bread, and biofuels production. These results highlight the influence of the physical properties of a genome on its overall architecture and function

The Emerging Role of the Cytoskeleton in Chromosome Dynamics

Chromosomes underlie a dynamic organization that fulfills functional roles in processes like transcription, DNA repair, nuclear envelope stability, and cell division. Chromosome dynamics depend on chromosome structure and cannot freely diffuse. Furthermore, chromosomes interact closely with their surrounding nuclear environment, which further constrains chromosome dynamics. Recently, several studies enlighten that cytoskeletal proteins regulate dynamic chromosome organization. Cytoskeletal polymers that include actin filaments, microtubules and intermediate filaments can connect to the nuclear envelope via Linker of the Nucleoskeleton and Cytoskeleton (LINC) complexes and transfer forces onto chromosomes inside the nucleus. Monomers of these cytoplasmic polymers and related proteins can also enter the nucleus and play different roles in the interior of the nucleus than they do in the cytoplasm. Nuclear cytoskeletal proteins can act as chromatin remodelers alone or in complexes with other nuclear proteins. They can also act as transcription factors. Many of these mechanisms have been conserved during evolution, indicating that the cytoskeletal regulation of chromosome dynamics is an essential process. In this review, we discuss the different influences of cytoskeletal proteins on chromosome dynamics by focusing on the well-studied model organism budding yeast

A (3D-nuclear) space odyssey: making sense of Hi-C maps

Three-dimensional 3D)-chromatin organization is critical for proper enhancer-promoter communication and, therefore, for a precise execution of the transcriptional programs governing cellular processes. The emergence of Chromosome Conformation Capture (3C) methods, in particular Hi-C, has allowed the investigation of chromatin interactions on a genome-wide scale, revealing the existence of overlapping molecular mechanisms that we are just starting to decipher. Therefore, disentangling Hi-C signal into these individual components is essential to provide meaningful biological data interpretation. Here, we discuss emerging views on the molecular forces shaping the genome in 3D, with a focus on their respective contributions and interdependence. We discuss Hi-C data at both population and single-cell levels, thus providing criteria to interpret genomic function in the 3D-nuclear space