Project description:Neutrophils are responsible for the first line of defense against invading pathogens. Their nuclei are uniquely structured as multiple lobes that establish a highly constrained nuclear environment. Here we found that neutrophil genomes were depleted of local genomic interactions but enriched for long-range genomic interactions that spanned multiple topologically associating domains. Population-based simulation of spherical and torroid genomes revealed declining radii of gyration for neutrophil chromosomes. We found that neutrophil genomes were highly enriched for heterochromatic genomic interactions across vast genomic distances, a process named super-contraction. Super-contraction involved genomic regions located in the heterochromatic compartment in both progenitors and neutrophils or genomic regions that switched from the euchromatic to the heterochromatic compartment during neutrophil differentiation. Super-contraction was accompanied by the repositioning of centromeres, pericentromeres and Long-Interspersed Nuclear Elements to the neutrophil nuclear lamina. We found that Lamin-B Receptor expression was required to attach centromeric and pericentromeric repeats but not LINE-1 elements to the lamina. Differentiating neutrophils also repositioned rDNA and mini-nucleoli to the lamina: a process that was closely associated with sharply reduced rRNA expression. We propose that large-scale chromatin reorganization involving super-contraction and recruitment of heterochromatin and nucleoli to the nuclear lamina facilitate the folding of the neutrophil genome into a confined geometry imposed by a multi-lobed nuclear architecture.

Project description:In mammalian nuclei, transcriptionally active genomic regions tend to localize to the interior of the nucleus while inactive regions are often located at at the nuclear lamina. In this study we activated specific genes in lamina-associated domains by TALE-VP64 or CRISPRa-mediated activation. We also reduced transcription of individual genes by knockout of promoter/enhancer regions, or by insertion of a transcription termination sequence. In each case we generated genome-wide DamID maps to determine changes in nuclear lamina interactions, and in selected cases we also generated Repli-seq maps and/or RNAseq data.

Project description:In mammalian nuclei, transcriptionally active genomic regions tend to localize to the interior of the nucleus while inactive regions are often located at at the nuclear lamina. In this study we activated specific genes in lamina-associated domains by TALE-VP64 or CRISPRa-mediated activation. We also reduced transcription of individual genes by knockout of promoter/enhancer regions, or by insertion of a transcription termination sequence. In each case we generated genome-wide DamID maps to determine changes in nuclear lamina interactions, and in selected cases we also generated Repli-seq maps and/or RNAseq data.

Project description:In mammalian nuclei, transcriptionally active genomic regions tend to localize to the interior of the nucleus while inactive regions are often located at at the nuclear lamina. In this study we activated specific genes in lamina-associated domains by TALE-VP64 or CRISPRa-mediated activation. We also reduced transcription of individual genes by knockout of promoter/enhancer regions, or by insertion of a transcription termination sequence. In each case we generated genome-wide DamID maps to determine changes in nuclear lamina interactions, and in selected cases we also generated Repli-seq maps and/or RNAseq data.

Project description:CCCTC-binding factor (CTCF) regulates the 3D chromatin architecture by facilitating chromosomal loops. In addition to insulation of euchromatin from heterochromatin, CTCF is an important transcription factor and regulator of antigen receptor and T cell receptor recombination events. CTCF inactivating events have been found in human cancer, resulting in deregulation of global gene expression by altered methylated genomic states. In contrast to these studies, we here describe that inactivation of CTCF can drives subtle and local genomic effects that elevates oncogene expression levels from driving chromosomal rearrangements. For T cell acute lymphoblastic leukemia (T-ALL), heterozygous CTCF deletions or inactivating mutations are predominantly found in nearly 50 percent of t(5;14)(q35;q32.2) rearranged patients that couples the TLX3 oncogene in the vicinity of the BCL11B enhancer. This unique entity has been associated with γδ-lineage development. Functional CTCF loss results in diminished expression of the αβ-lineage commitment factor BCL11B from the non-rearranged allele, but unexpectedly drives higher levels of the TLX3 oncogene from the translocated allele. In line, Ctcf conditional knockout mice have reduced numbers of αβ T cells but increased numbers of γδ T cells, a phenotype identical to that of Bcl11b knockout mice and implying that CTCF is directly involved in the regulation of the BCL11B enhancer. We demonstrate that most TLX3-rearranged patients with heterozygous CTCF aberrations preserved single intervening CTCF bindings sites in the translocation breakpoint areas located in between the BCL11B enhancer and the TLX3 oncogene. These intervening CTCF sites insulate TLX3 from the enhancer by forming competitive loops with TLX3 regulatory sequences. Using reverse genetics, we provide evidence that heterozygous inactivation of CTCF diminishes competitive loop formation in favor of high-affinity TLX3 promoter loops to BCL11B enhancer sequences formed among multiple convergent CTCF binding sites. This boosts oncogene expression levels and leukemia burden in T-ALL patients.

Project description:CCCTC-binding factor (CTCF) regulates the 3D chromatin architecture by facilitating chromosomal loops. In addition to insulation of euchromatin from heterochromatin, CTCF is an important transcription factor and regulator of antigen receptor and T cell receptor recombination events. CTCF inactivating events have been found in human cancer, resulting in deregulation of global gene expression by altered methylated genomic states. In contrast to these studies, we here describe that inactivation of CTCF can drives subtle and local genomic effects that elevates oncogene expression levels from driving chromosomal rearrangements. For T cell acute lymphoblastic leukemia (T-ALL), heterozygous CTCF deletions or inactivating mutations are predominantly found in nearly 50 percent of t(5;14)(q35;q32.2) rearranged patients that couples the TLX3 oncogene in the vicinity of the BCL11B enhancer. This unique entity has been associated with γδ-lineage development. Functional CTCF loss results in diminished expression of the αβ-lineage commitment factor BCL11B from the non-rearranged allele, but unexpectedly drives higher levels of the TLX3 oncogene from the translocated allele. In line, Ctcf conditional knockout mice have reduced numbers of αβ T cells but increased numbers of γδ T cells, a phenotype identical to that of Bcl11b knockout mice and implying that CTCF is directly involved in the regulation of the BCL11B enhancer. We demonstrate that most TLX3-rearranged patients with heterozygous CTCF aberrations preserved single intervening CTCF bindings sites in the translocation breakpoint areas located in between the BCL11B enhancer and the TLX3 oncogene. These intervening CTCF sites insulate TLX3 from the enhancer by forming competitive loops with TLX3 regulatory sequences. Using reverse genetics, we provide evidence that heterozygous inactivation of CTCF diminishes competitive loop formation in favor of high-affinity TLX3 promoter loops to BCL11B enhancer sequences formed among multiple convergent CTCF binding sites. This boosts oncogene expression levels and leukemia burden in T-ALL patients.

Project description:CCCTC-binding factor (CTCF) regulates the 3D chromatin architecture by facilitating chromosomal loops. In addition to insulation of euchromatin from heterochromatin, CTCF is an important transcription factor and regulator of antigen receptor and T cell receptor recombination events. CTCF inactivating events have been found in human cancer, resulting in deregulation of global gene expression by altered methylated genomic states. In contrast to these studies, we here describe that inactivation of CTCF can drives subtle and local genomic effects that elevates oncogene expression levels from driving chromosomal rearrangements. For T cell acute lymphoblastic leukemia (T-ALL), heterozygous CTCF deletions or inactivating mutations are predominantly found in nearly 50 percent of t(5;14)(q35;q32.2) rearranged patients that couples the TLX3 oncogene in the vicinity of the BCL11B enhancer. This unique entity has been associated with γδ-lineage development. Functional CTCF loss results in diminished expression of the αβ-lineage commitment factor BCL11B from the non-rearranged allele, but unexpectedly drives higher levels of the TLX3 oncogene from the translocated allele. In line, Ctcf conditional knockout mice have reduced numbers of αβ T cells but increased numbers of γδ T cells, a phenotype identical to that of Bcl11b knockout mice and implying that CTCF is directly involved in the regulation of the BCL11B enhancer. We demonstrate that most TLX3-rearranged patients with heterozygous CTCF aberrations preserved single intervening CTCF bindings sites in the translocation breakpoint areas located in between the BCL11B enhancer and the TLX3 oncogene. These intervening CTCF sites insulate TLX3 from the enhancer by forming competitive loops with TLX3 regulatory sequences. Using reverse genetics, we provide evidence that heterozygous inactivation of CTCF diminishes competitive loop formation in favor of high-affinity TLX3 promoter loops to BCL11B enhancer sequences formed among multiple convergent CTCF binding sites. This boosts oncogene expression levels and leukemia burden in T-ALL patients.

Project description:CCCTC-binding factor (CTCF) regulates the 3D chromatin architecture by facilitating chromosomal loops. In addition to insulation of euchromatin from heterochromatin, CTCF is an important transcription factor and regulator of antigen receptor and T cell receptor recombination events. CTCF inactivating events have been found in human cancer, resulting in deregulation of global gene expression by altered methylated genomic states. In contrast to these studies, we here describe that inactivation of CTCF can drives subtle and local genomic effects that elevates oncogene expression levels from driving chromosomal rearrangements. For T cell acute lymphoblastic leukemia (T-ALL), heterozygous CTCF deletions or inactivating mutations are predominantly found in nearly 50 percent of t(5;14)(q35;q32.2) rearranged patients that couples the TLX3 oncogene in the vicinity of the BCL11B enhancer. This unique entity has been associated with γδ-lineage development. Functional CTCF loss results in diminished expression of the αβ-lineage commitment factor BCL11B from the non-rearranged allele, but unexpectedly drives higher levels of the TLX3 oncogene from the translocated allele. In line, Ctcf conditional knockout mice have reduced numbers of αβ T cells but increased numbers of γδ T cells, a phenotype identical to that of Bcl11b knockout mice and implying that CTCF is directly involved in the regulation of the BCL11B enhancer. We demonstrate that most TLX3-rearranged patients with heterozygous CTCF aberrations preserved single intervening CTCF bindings sites in the translocation breakpoint areas located in between the BCL11B enhancer and the TLX3 oncogene. These intervening CTCF sites insulate TLX3 from the enhancer by forming competitive loops with TLX3 regulatory sequences. Using reverse genetics, we provide evidence that heterozygous inactivation of CTCF diminishes competitive loop formation in favor of high-affinity TLX3 promoter loops to BCL11B enhancer sequences formed among multiple convergent CTCF binding sites. This boosts oncogene expression levels and leukemia burden in T-ALL patients.

Project description:CCCTC-binding factor (CTCF) regulates the 3D chromatin architecture by facilitating chromosomal loops. In addition to insulation of euchromatin from heterochromatin, CTCF is an important transcription factor and regulator of antigen receptor and T cell receptor recombination events. CTCF inactivating events have been found in human cancer, resulting in deregulation of global gene expression by altered methylated genomic states. In contrast to these studies, we here describe that inactivation of CTCF can drives subtle and local genomic effects that elevates oncogene expression levels from driving chromosomal rearrangements. For T cell acute lymphoblastic leukemia (T-ALL), heterozygous CTCF deletions or inactivating mutations are predominantly found in nearly 50 percent of t(5;14)(q35;q32.2) rearranged patients that couples the TLX3 oncogene in the vicinity of the BCL11B enhancer. This unique entity has been associated with γδ-lineage development. Functional CTCF loss results in diminished expression of the αβ-lineage commitment factor BCL11B from the non-rearranged allele, but unexpectedly drives higher levels of the TLX3 oncogene from the translocated allele. In line, Ctcf conditional knockout mice have reduced numbers of αβ T cells but increased numbers of γδ T cells, a phenotype identical to that of Bcl11b knockout mice and implying that CTCF is directly involved in the regulation of the BCL11B enhancer. We demonstrate that most TLX3-rearranged patients with heterozygous CTCF aberrations preserved single intervening CTCF bindings sites in the translocation breakpoint areas located in between the BCL11B enhancer and the TLX3 oncogene. These intervening CTCF sites insulate TLX3 from the enhancer by forming competitive loops with TLX3 regulatory sequences. Using reverse genetics, we provide evidence that heterozygous inactivation of CTCF diminishes competitive loop formation in favor of high-affinity TLX3 promoter loops to BCL11B enhancer sequences formed among multiple convergent CTCF binding sites. This boosts oncogene expression levels and leukemia burden in T-ALL patients.

Project description:The trans-luminal LINC (Linker of Nucleoskeleton and Cytoskeleton) complex plays a central role in nuclear mechanotransduction by coupling the nucleus with cytoskeleton. High spatial density and active dynamics of LINC complex have hindered its precise characterization for the understanding of underlying mechanisms how the linkages sense and respond to mechanical stimuli. In this study, we focus on SUN2, a core component of LINC complex interconnecting the nuclear lamina and actin cytoskeleton and apply single molecule super-resolution imaging to reveal how SUN2 responds to actomyosin contractility. Using stochastic optical reconstruction microscopy (STORM), we quantitated the distribution pattern and density of SUN2 on the basal nuclear membrane. We found that SUN2 undergoes bidirectional translocation between ER and nuclear membrane in response to actomyosin contractility, suggesting that dynamic constrained force on SUN2 is required for its proper distribution. Furthermore, single molecule imaging unveils interesting dynamics of SUN2 molecules that are regulated by both actomyosin contractility and laminA/C network, whereas SUN2 oligomeric states are not affected by actomyosin contractility. Lastly, the mechanical response of SUN2 to actomyosin contractility was found to regulate expression of mechano-sensitive genes located in lamina-associated domains (LADs) and perinuclear heterochromatin. Taken together, our results reveal how SUN2 responds to mechanical cues at the single-molecule level, providing new insights into the mechanism of nuclear mechanotransduction.