Jos茅e Dostie
Professor, Department of Biochemistry
2000 - PhD, 缅北强奸
Role of 3D genome architecture in health and disease
The Dostie lab is interested in the role of spatial genome organization in human health and disease. Spatial genome organization refers to where chromosomes localize in the nuclear space and to how chromatin folds in three-dimensions (3D). We combine cell and molecular biology, genomics, and computational biology to understand how spatial genome organization impinges on the regulation of gene expression during normal cell differentiation and in the context of malignancies.
We use cells grown and manipulated in culture (gene inductions, RNA interference, CRISPR/Cas9) as our model systems. We use fluorescence microscopy (immunofluorescence, fluorescence in situ hybridization) to study chromatin localization. We apply classical molecular biology techniques such as cloning, real-time quantitative PCR, northern and western blotting, RNA and protein immunoprecipitation to identify and study underlying molecular mechanisms that regulate spatial chromatin organization and gene expression. We use both classical genomics (Chromatin immunoprecipitation, RNA-seq) and cutting-edge 3D genomics approaches (Hi-C, 5C) to map chromatin composition (epigenomics), activity, and folding. In collaboration with other groups, we integrate our findings computationally to uncover when, how, and why spatial genome organization affects the expression of genes.
I. Discovering underlying principles of chromatin organization.
We are working towards explaining why looping and chromatin domains form as they do and what makes them change. To this end, we are mapping 3D genome organization (Hi-C, 5C) under various conditions and relating this information to chromatin composition (ChIP-qPCR, 2C-ChIP, ChIP-seq) and activity (RT-qPCR, RNA-seq, CAGE). For example, as part of an ongoing collaboration we previously examined how chromatin folding varies during limb formation, and found that long-range contacts requiring the function of PRC2 (Polycomb repressive complex 2) also promote enhancer-promoter interactions [2]. In the past, we also tracked chromosome organization during cellular differentiation, and found that neighboring chromatin domains tend to naturally pair into progressively larger architectures (metaTADs) based on chromatin composition and activity [3]. Additionally, we previously compared data from microscopy-based approaches (FISH) to those from molecular biology-driven techniques (5C, Hi-C), and found that molecular-based techniques seem to capture more than the physical distance between chromatin segments [4].
II. Identifying novel 3D chromatin control mechanisms that regulate gene expression.
We are interested in identifying molecular mechanisms that control transcription through changes in 3D chromatin organization. We are currently studying how long non-coding RNAs (lncRNAs) alter the composition, 3D organization and activity of chromatin. LncRNAs belong to a large class of transcripts longer than 200 nucleotides that lack protein-coding sequence. Like mRNAs, they are transcribed by RNA polymerase II but tend to exist at lower levels and are more cell type-specific. Generally, lncRNAs are rapidly evolving genes with poorly conserved sequences. Unlike most lncRNAs, the mammalian HOTAIRM1 transcript can be identified by comparative genomic analysis and appears to have emerged prior to marsupial-eutherian divergence up to 160 Ma ago [5]. This lncRNA is thus expected to have evolutionarily conserved roles across all mammals, and interestingly, HOTAIRM1 has been linked to many cancer types.
We previously found that HOTAIRM1 is required to physically uncouple distal genes at the HOXA gene cluster so as to prevent premature transcription activating during neuronal differentiation induced with retinoic acid (RA) [6]. We also found that another lncRNA named HOXA-AS2 located downstream from HOTAIRM1, which is normally activated later during neuronal differentiation appears important to maintain high transcription activity at the HOXA cluster [7].
III. Genome organization in health and disease.
We aim to understand the role of 3D chromatin organization in cancer and determine whether it can be used as a molecular biomarker in the clinic. Proper genome organization is important for human health as demonstrated in cancers where SNPs (single nucleotide polymorphisms) creating novel enhancers activate distal genes long-range through DNA looping [8-10]. Accordingly, key developmental genes and those controlled by very strong enhancers often localize within stable TADs where regulation can occur independently from their neighbors [11]. Notably, the boundaries of neighborhoods wherein proto-oncogenes reside are sequences often mutated [12] or deleted in cancer cells, and their perturbation activates oncogene expression in non-cancerous cells [13]. In fact, actual TAD boundary disruptions can cause domain rearrangements, inappropriate gene activation, leading to carcinogenesis or other diseases [14].
We use both cell lines and patient-derived xenografts (PDXs) to map chromatin organization in normal and cancer cells with either Hi-C (genome-wide) or the 5C (genome-scale) technology. We then apply machine learning artificial intelligence (AI) programs to extract 3D chromatin signatures (3DCSs), integrate this information with other 鈥渙mics鈥 data, and identify potential molecular mechanisms and/or pathways deregulated in the corresponding cancer types. We previously examined the value of 3DCSs in disease classification, and demonstrated that it contains the necessary information to classify leukemia subtypes [15].
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