BMI1 mediated heterochromatin compaction represses G-quadruplex formation in Alzheimer's disease

Hanna, Roy

09 1900

La maladie d'Alzheimer (MA) est la démence la plus importante dans le monde développé. Cette maladie neurodégénérative rend de plus en plus difficile la capacité d'accomplir les tâches quotidiennes de routine, elle peut également faire oublier les mots aux patients, les désorienter dans le temps et l'espace, et à des stades avancés entraîne une perte de mémoire. Malheureusement, la MA est considérée comme le prochain grand défi pour la santé publique de la plupart des pays, le nombre de cas devant doubler au cours des 20 prochaines années en raison du vieillissement de la population. Cette augmentation du nombre de patients s'accompagne d'une augmentation des besoins de financement et de personnel de santé afin de répondre aux demandes et aux besoins de ces patients. La MA peut être divisée en deux entités distinctes: une maladie héréditaire bien définie et bien comprise qui représente jusqu'à 5% de tous les cas de MA appelés maladie d'Alzheimer familiale, et une maladie moins définie appelée maladie d'Alzheimer sporadique. Le facteur de risque le plus défini pour la MA est l'âge, mais récemment, il a été démontré que le cerveau des patients atteints de MA avait un niveau réduit de BMI1 et que la suppression de BMI1 dans les neurones humains ou chez la souris déclenche les caractéristiques de cette maladie. Alors que BMI1 était connu pour être important dans les stades de développement, nous rapportons ici qu'il est crucial dans les cellules adultes pour maintenir la compaction de la chromatine et l’inhibition de la transcription des séquences répétitives. De plus, ces deux fonctions de BMI1 empêchent l'ADN d'acquérir une conformation G4. Cette conformation peut entraîner une instabilité du génome, une augmentation des dommages à l'ADN et une altération de l'expression des gènes, mais surtout, nous avons montré que dans les neurones corticaux, les structures G4 peuvent influencer l'épissage alternatif de divers gènes, notamment APP. Ces résultats apportent un éclairage nouveau sur l'origine de la maladie et l'importance de BMI1 et de la structure secondaire de l'ADN dans le cadre de la MA. / Alzheimer's disease is the most prominent dementia in the developed world. This neurodegenerative disease renders the ability to do the routine daily tasks more and more difficult; it can also cause patients to forget words, be disoriented in time and space, leading to a memory loss. Unfortunately, AD is considered the next big challenge for most country’s public health, with the number of cases thought to be doubling within the next 20 years due to the aging of the population. This increase in the number of patients comes with an increase in the need for funding and for healthcare personnel to meet the demands and the requirements of these patients. AD is divided into two separate entities: a well-defined and understood hereditary disease that makes up to 5% of all AD cases called familial Alzheimer disease, and a less defined one called sporadic Alzheimer disease. sAD most defined risk factor is age, but recently it was shown that brains of sAD patients had a reduced level of BMI1 and that the knockdown of BMI1 in human neurons or mice triggers the hallmarks of this disease. While BMI1 was known to be important in the developmental stages, we report here that it is crucial in adult cells to maintain the compaction of the chromatin and the silencing of the repetitive sequences. Furthermore, these two functions of BMI1 prevent the DNA from acquiring a G4 conformation. This conformation can lead to genome instability, increased DNA damage, and altered gene expression. However, most importantly, we showed that in cortical neurons, G4 structures could influence the alternative splicing of various genes, notably APP. These results shed new light on the origin of AD, and the importance of BMI1 and the secondary structure of the DNA in its context.

BMI1

G-Quadruplex

maladie d’Alzheimer

polycombes

séquences LINE

hétérochromatine

instabilité génomique

G4

Alzheimer’s disease

polycomb

LINE sequences

heterochromatin

genome instability

Chromatin Dynamics Regulate Transcriptional Homeostasis

Topal, Salih

26 December 2019

Eukaryotic promoters are inherently bidirectional and allow RNA Polymerase II to transcribe both coding and noncoding RNAs. Dynamic disassembly and reassembly is a prominent feature of nucleosomes around eukaryotic promoters. While H3K56 acetylation (H3K56Ac) enhances turnover events of these promoter-proximal nucleosomes, the chromatin remodeler INO80C ensures their proper positioning. In my dissertation, I explore how chromatin dynamics regulate transcriptional homeostasis. In the first part, I investigate the role of H3K56Ac on the nascent transcriptome throughout the eukaryotic cell cycle. I find that H3K56Ac is a global, positive regulator for coding and noncoding transcription by promoting both initiation and elongation/termination. On the contrary, I find that H3K56Ac represses promiscuous transcription following replication fork passage by ensuring efficient nucleosome assembly during S-phase. In addition, I show that there is a stepwise increase in transcription in the S-G2 transition, and this response to gene dosage imbalance does not require H3K56Ac. This study clearly shows that a single histone modification, H3K56Ac can exert both positive and negative effects on transcription at different cell cycle stages. In the second part, I investigate the role of the chromatin remodeler INO80C on the nascent transcription around replication origins. I show that INO80C, together with the transcription factor Mot1, prevents cryptic transcription around yeast replication origins, and the loss of these proteins lead to an increase in DNA double strand breaks. I hypothesize that recruitment of INO80C ensures proper positioning of nucleosomes around origins and the exclusion of RNA Pol II to prevent cryptic initiation. Together these findings indicate that H3K56Ac regulates transcription globally by enhancing nucleosome turnover, and it prevents cryptic transcription and reinforces transcriptional fidelity by promoting efficient nucleosome assembly in the S-phase. In addition, INO80C maintains genome stability by preventing cryptic transcription around the origins.

H3K56

histone acetylation

nucleosome turnover

nucleosome assembly

NET-seq

nascent RNA

INO80C

Break-seq

genome instability

Genomics

Molecular Biology

Molecular Genetics

Caracterização molecular do envolvimento das proteínas LmHus1 e LmRad9 em mecanismos de reconhecimento e reparo de DNA no parasito Leishmania major / Molecular characterization of the involvement of LmHus1 and LmRad9 in DNA damage sensing and repair in the parasite Leishmania major.

Damasceno, Jeziel Dener

06 February 2013

A estabilidade genômica é condição essencial à sobrevivência e ao funcionamento dos organismos vivos. No entanto, várias situações podem provocar danos no DNA. Por exemplo, cerca de 104 lesões podem ocorrer no material genético de uma célula de mamífero a cada dia. No intuito de preservar a integridade genômica e contornar os efeitos deletérios destas modificações, uma maquinaria constituída de proteínas especializadas em reconhecer e reparar estes danos foi selecionada ao longo do curso evolutivo. Defeitos em proteínas destas maquinarias causam instabilidade genômica e pode resultar em elevada taxa de mutações e quebras do DNA que resultam em eventos de amplificação gênica, como em células cancerosas. De uma maneira aparentemente contrária ao requerimento de estabilidade genômica como condição primordial para a perpetuação da vida, Leishmania apresenta um genoma notavelmente maleável e explora a amplificação gênica como recurso de sobrevivência. Ainda que a plasticidade genômica em Leishmania seja facilmente demonstrada, nós não conhecemos os mecanismos precisos pelos quais este parasita coordena a ação da maquinaria de detecção de danos no DNA e a consumação dos eventos de amplificação gênica. No intuito de contribuir para a compreensão deste processo, nós identificamos proteínas homólogas do complexo 9-1-1 (Rad9-Hus1-Rad1) em Leishmania major. As proteínas LmHus1 e LmRad9 apresentam marcada divergência estrutural em relação aos seus homólogos em outros eucariotos e nenhuma proteína obviamente homóloga a Rad1 foi identificada neste parasita. Análises filogenéticas indicam que LmHus1 e LmRad9 são relacionadas ao complexos heterotriméricos envolvidos na detecção de danos no DNA. Em acordo com isso, nossos experimentos demonstram que alteração nos níveis destas proteínas interfere na capacidade do parasita em lidar com estresse genotóxico. LmHus1 localiza-se no núcleo, é requerida para o crescimento normal deste parasita e a diminuição de sua expressão compromete mecanismos de controle de ciclo celular e manutenção de telômeros. LmRad9 também localiza-se no núcleo e sua superexpressão causa defeito de crescimento e de resposta ao estresse genotóxico em L. major. Nós observamos que LmHus1 e LmRad9 formam um complexo responsivo ao dano no DNA in vivo, uma forte indicação de que o complexo 9-1-1 tenha sido conservado em L. major. As peculiaridades estruturais destas proteínas sugerem que o complexo 9-1-1 de L. major possua uma arquitetura distinta em comparação aos eucariotos superiores. Em adição a isto, outras proteínas, tais como a LmRpa1, também apresentam uma marcante divergência estrutural. Isso sugere que a via de sinalização de danos no DNA envolvendo o complexo 9-1-1 e Rpa1 de L. major possua mecanismos peculiares de ação. Estas observações podem permitir entender como ocorreu o processo evolutivo da sinalização mediada pelo complexo 9-1-1 nos eucariotos, além de ajudar para o entendimento das bases moleculares de como este parasito conduz os eventos de amplificação gênica. / Genome stability is a essential condition for survival and proper functioning of living organisms. However, a broad range of elements may lead to DNA damage. For instance, about 104 DNA lesions may be inflicted upon any given mammalian cell everyday. In order to maintain the genome integrity and circumvent the deleterious effects of these lesions, a molecular machinery composed of proteins specialized in detecting and repairing DNA damage has been selected in evolution. Defects of the proteins that constitute such machineries may result not only in a high mutation rate, but also in breaks in the DNA structure that can mediate gene amplification as observed in cancer cells. In an apparent opposition to such requirement for stability as an essential condition to life, the protozoan Leishmania presents a highly malleable genome and explores genome amplification as a survival and adaptation tool. Despite of the fact that the Leishmania genome plasticity can be easily demonstrated, the precise mechanisms that coordinate the molecular machineries involved in the detection and signaling of DNA damage, and in the regulation of gene amplification is still largely unknown. In order to contribute to a better understanding of these processes, we identified and studied the Leishmania major proteins that are homologues of those proteins that compose the 9-1-1 complex (Rad9-Hus1-Rad1). The proteins LmHus1 and LmRad9 present a high structural divergence when compared to its homologues from other eukaryotes and no obvious homologue of Rad1 was identified in the parasite genome. Phylogeny analysis indicated that LmHus1 and LmRad9 are closely related to heterotrimeric complexes involved in the detection of DNA damage. In accordance to that, our experiments demonstrated that altered levels of these proteins interfere with the parasite ability to deal with genotoxic stress. Moreover, LmHus1 was localized to the parasite nucleus and is a required protein for normal parasite proliferation. Besides, we showed that decreased levels of LmHus1 compromise cell cycle regulation and the maintenance of telomeres. LmRad9 was also shown to be localized to the cell nucleus and its overexpression led to growth defects and affected the L. major response to genotoxic stress. We also observed that LmHus1 and LmRad9 interact with each other to for a protein complex that is responsive to DNA damage in vivo, which strongly suggested that the 9-1-1 complex was conserved in L. major. The structural peculiarities of these proteins indicate that the possible L. major 9-1-1 complex has a different architecture when compared to the complex found in higher eukaryotes. In addition to that, other proteins, such as LmRpa1, also present a marked structural divergence. Altogether, these findings suggest that the DNA damage signaling pathway involving the 9-1-1 complex and LmRpa1 in L. major, may present a peculiar mode of action. These observations may contribute to a better understanding not only of the evolution of the signaling pathway mediated by the 9-1-1 complex in eukaryotes, but also of the molecular basis of the genome plasticity and the gene amplification phenomenon.

Detecção de danos no DNA

DNA damage sensing

DNA repair

Estabilidade genômica

genome instability

genome plasticity

heterotrimeric 9-1-1 complex

Heterotrímero Complexo 9-1-1

Homotrímero PCNA.

Hus1

Hus1

Instabilidade genômica

Leishmania

Leishmania

PCNA homotrimer.

Plasticidade Genômica

Rad1

Rad1

Rad9

Rad9

Reparo de DNA

RPA

RPA

Tripanossomatídeos

trypanossomatids

Caracterização molecular do envolvimento das proteínas LmHus1 e LmRad9 em mecanismos de reconhecimento e reparo de DNA no parasito Leishmania major / Molecular characterization of the involvement of LmHus1 and LmRad9 in DNA damage sensing and repair in the parasite Leishmania major.

Jeziel Dener Damasceno

06 February 2013

A estabilidade genômica é condição essencial à sobrevivência e ao funcionamento dos organismos vivos. No entanto, várias situações podem provocar danos no DNA. Por exemplo, cerca de 104 lesões podem ocorrer no material genético de uma célula de mamífero a cada dia. No intuito de preservar a integridade genômica e contornar os efeitos deletérios destas modificações, uma maquinaria constituída de proteínas especializadas em reconhecer e reparar estes danos foi selecionada ao longo do curso evolutivo. Defeitos em proteínas destas maquinarias causam instabilidade genômica e pode resultar em elevada taxa de mutações e quebras do DNA que resultam em eventos de amplificação gênica, como em células cancerosas. De uma maneira aparentemente contrária ao requerimento de estabilidade genômica como condição primordial para a perpetuação da vida, Leishmania apresenta um genoma notavelmente maleável e explora a amplificação gênica como recurso de sobrevivência. Ainda que a plasticidade genômica em Leishmania seja facilmente demonstrada, nós não conhecemos os mecanismos precisos pelos quais este parasita coordena a ação da maquinaria de detecção de danos no DNA e a consumação dos eventos de amplificação gênica. No intuito de contribuir para a compreensão deste processo, nós identificamos proteínas homólogas do complexo 9-1-1 (Rad9-Hus1-Rad1) em Leishmania major. As proteínas LmHus1 e LmRad9 apresentam marcada divergência estrutural em relação aos seus homólogos em outros eucariotos e nenhuma proteína obviamente homóloga a Rad1 foi identificada neste parasita. Análises filogenéticas indicam que LmHus1 e LmRad9 são relacionadas ao complexos heterotriméricos envolvidos na detecção de danos no DNA. Em acordo com isso, nossos experimentos demonstram que alteração nos níveis destas proteínas interfere na capacidade do parasita em lidar com estresse genotóxico. LmHus1 localiza-se no núcleo, é requerida para o crescimento normal deste parasita e a diminuição de sua expressão compromete mecanismos de controle de ciclo celular e manutenção de telômeros. LmRad9 também localiza-se no núcleo e sua superexpressão causa defeito de crescimento e de resposta ao estresse genotóxico em L. major. Nós observamos que LmHus1 e LmRad9 formam um complexo responsivo ao dano no DNA in vivo, uma forte indicação de que o complexo 9-1-1 tenha sido conservado em L. major. As peculiaridades estruturais destas proteínas sugerem que o complexo 9-1-1 de L. major possua uma arquitetura distinta em comparação aos eucariotos superiores. Em adição a isto, outras proteínas, tais como a LmRpa1, também apresentam uma marcante divergência estrutural. Isso sugere que a via de sinalização de danos no DNA envolvendo o complexo 9-1-1 e Rpa1 de L. major possua mecanismos peculiares de ação. Estas observações podem permitir entender como ocorreu o processo evolutivo da sinalização mediada pelo complexo 9-1-1 nos eucariotos, além de ajudar para o entendimento das bases moleculares de como este parasito conduz os eventos de amplificação gênica. / Genome stability is a essential condition for survival and proper functioning of living organisms. However, a broad range of elements may lead to DNA damage. For instance, about 104 DNA lesions may be inflicted upon any given mammalian cell everyday. In order to maintain the genome integrity and circumvent the deleterious effects of these lesions, a molecular machinery composed of proteins specialized in detecting and repairing DNA damage has been selected in evolution. Defects of the proteins that constitute such machineries may result not only in a high mutation rate, but also in breaks in the DNA structure that can mediate gene amplification as observed in cancer cells. In an apparent opposition to such requirement for stability as an essential condition to life, the protozoan Leishmania presents a highly malleable genome and explores genome amplification as a survival and adaptation tool. Despite of the fact that the Leishmania genome plasticity can be easily demonstrated, the precise mechanisms that coordinate the molecular machineries involved in the detection and signaling of DNA damage, and in the regulation of gene amplification is still largely unknown. In order to contribute to a better understanding of these processes, we identified and studied the Leishmania major proteins that are homologues of those proteins that compose the 9-1-1 complex (Rad9-Hus1-Rad1). The proteins LmHus1 and LmRad9 present a high structural divergence when compared to its homologues from other eukaryotes and no obvious homologue of Rad1 was identified in the parasite genome. Phylogeny analysis indicated that LmHus1 and LmRad9 are closely related to heterotrimeric complexes involved in the detection of DNA damage. In accordance to that, our experiments demonstrated that altered levels of these proteins interfere with the parasite ability to deal with genotoxic stress. Moreover, LmHus1 was localized to the parasite nucleus and is a required protein for normal parasite proliferation. Besides, we showed that decreased levels of LmHus1 compromise cell cycle regulation and the maintenance of telomeres. LmRad9 was also shown to be localized to the cell nucleus and its overexpression led to growth defects and affected the L. major response to genotoxic stress. We also observed that LmHus1 and LmRad9 interact with each other to for a protein complex that is responsive to DNA damage in vivo, which strongly suggested that the 9-1-1 complex was conserved in L. major. The structural peculiarities of these proteins indicate that the possible L. major 9-1-1 complex has a different architecture when compared to the complex found in higher eukaryotes. In addition to that, other proteins, such as LmRpa1, also present a marked structural divergence. Altogether, these findings suggest that the DNA damage signaling pathway involving the 9-1-1 complex and LmRpa1 in L. major, may present a peculiar mode of action. These observations may contribute to a better understanding not only of the evolution of the signaling pathway mediated by the 9-1-1 complex in eukaryotes, but also of the molecular basis of the genome plasticity and the gene amplification phenomenon.

Detecção de danos no DNA

Estabilidade genômica

Heterotrímero Complexo 9-1-1

Homotrímero PCNA.

Hus1

Instabilidade genômica

Leishmania

Plasticidade Genômica

Rad1

Rad9

Reparo de DNA

RPA

Tripanossomatídeos

DNA damage sensing

DNA repair

genome instability

genome plasticity

heterotrimeric 9-1-1 complex

Hus1

Leishmania

PCNA homotrimer.

Rad1

Rad9

RPA

trypanossomatids