Nuclear envelope protein lamin B receptor protects the genome from chromosomal instability and tumorigenesis.

Lamin B Receptor (LBR) is an inner nuclear membrane protein that assembles the nuclear envelope post mitosis. Here we show that LBR depletion induces mitotic defects accompanied by recurrent chromosomal losses. In addition, LBR knockdown results in nuclear aberrations such as nuclear blebs and micronuclei, with chromosomes showing higher frequency of losses, being enriched within the micronucleus. Furthermore, doxycycline-induced conditional depletion of LBR significantly increased tumor volumes that form within the subcutaneous xenografts of mice. Of note, the tumor-derived primary cells recapitulated chromosomal losses and gains, revealing a novel role for LBR as a tumor suppressor. Co-immunoprecipitation of LBR uncovered an association of LBR with telomere-associated factors. Interestingly, qPCR array-based gene expression profiling showed a significant upregulation of telomere repeat-binding factor 1 (TRF1) upon LBR depletion. Remarkably, TRF1 knockdown in the background of LBR depletion maintains chromosomal stability, unraveling a novel mechanism involving LBR and TRF in the maintenance of chromosomal stability in colorectal cancer cells.

Nup93 and CTCF modulate spatiotemporal dynamics and function of the HOXA gene locus during differentiation.

Nucleoporins regulate nuclear transport and are also involved in DNA damage, repair, cell cycle, chromatin organization and gene expression. Here, we studied the role of nucleoporin Nup93 and the chromatin organizer CTCF in regulating expression of the HOXA gene locus during differentiation. ChIP sequencing revealed a significant overlap between Nup93 and CTCF peaks. Interestingly, Nup93 and CTCF are associated with the 3' and 5' HOXA genes, respectively. Depletions of Nup93 and CTCF antagonistically modulate expression levels of 3' and 5' HOXA genes in the undifferentiated human NT2/D1 cell line. Nup93 also regulates the localization of the HOXA gene locus, which disengages from the nuclear periphery upon Nup93 but not CTCF depletion, consistent with its upregulation. The dynamic association of Nup93 and CTCF with the HOXA locus during differentiation correlates with its spatial positioning and expression. Whereas Nup93 tethers the HOXA locus to the nuclear periphery, CTCF potentially regulates looping of the HOXA gene cluster in a temporal manner. In summary, Nup93 and CTCF complement one another in modulating the spatiotemporal dynamics and function of the HOXA gene locus during differentiation. This article has an associated First Person interview with the first authors of the paper.

Twist1 induces chromosomal instability (CIN) in colorectal cancer cells.

Twist1 is a basic helix-loop-helix transcription factor, essential during early development in mammals. While Twist1 induces epithelial-to-mesenchymal transition (EMT), here we show that Twist1 overexpression enhances nuclear and mitotic aberrations. This is accompanied by an increase in whole chromosomal copy number gains and losses, underscoring the role of Twist1 in inducing chromosomal instability (CIN) in colorectal cancer cells. Array comparative genomic hybridization (array CGH) analysis further shows sub-chromosomal deletions, consistent with an increased frequency of DNA double strand breaks (DSBs). Remarkably, Twist1 overexpression downmodulates key cell cycle checkpoint factors-Bub1, BubR1, Mad1 and Mad2-that regulate CIN. Mathematical simulations using the RACIPE tool show a negative correlation of Twist1 with E-cadherin and BubR1. Data analyses of gene expression profiles of patient samples from The Cancer Genome Atlas (TCGA) reveal a positive correlation between Twist1 and mesenchymal genes across cancers, whereas the correlation of TWIST1 with CIN and DSB genes is cancer subtype-specific. Taken together, these studies highlight the mechanistic involvement of Twist1 in the deregulation of factors that maintain genome stability during EMT in colorectal cancer cells. Twist1 overexpression enhances genome instability in the context of EMT that further contributes to cellular heterogeneity. In addition, these studies imply that Twist1 downmodulates nuclear lamins that further alter spatiotemporal organization of the cancer genome and epigenome. Notwithstanding their genetic background, colorectal cancer cells nevertheless maintain their overall ploidy, while the downstream effects of Twist1 enhance CIN and DNA damage enriching for sub-populations of aggressive cancer cells.

Lamin A/C modulates spatial organization and function of the Hsp70 gene locus via nuclear myosin I.

The structure-function relationship of the nucleus is tightly regulated, especially during heat shock. Typically, heat shock activates molecular chaperones that prevent protein misfolding and preserve genome integrity. However, the molecular mechanisms that regulate nuclear structure-function relationships during heat shock remain unclear. Here, we show that lamin A and C (hereafter lamin A/C; both lamin A and C are encoded by LMNA) are required for heat-shock-mediated transcriptional induction of the Hsp70 gene locus (HSPA genes). Interestingly, lamin A/C regulates redistribution of nuclear myosin I (NM1) into the nucleus upon heat shock, and depletion of either lamin A/C or NM1 abrogates heat-shock-induced repositioning of Hsp70 gene locus away from the nuclear envelope. Lamins and NM1 also regulate spatial positioning of the SC35 (also known as SRSF2) speckles - important nuclear landmarks that modulates Hsp70 gene locus expression upon heat shock. This suggests an intricate crosstalk between nuclear lamins, NM1 and SC35 organization in modulating transcriptional responses of the Hsp70 gene locus during heat shock. Taken together, this study unravels a novel role for lamin A/C in the regulation of the spatial dynamics and function of the Hsp70 gene locus upon heat shock, via the nuclear motor protein NM1.This article has an associated First Person interview with the first author of the paper.

Role of A- and B-type lamins in nuclear structure-function relationships.

Nuclear lamins are type V intermediate filament proteins that form a filamentous meshwork beneath the inner nuclear membrane. Additionally, a sub-population of A- and B-type lamins localizes in the nuclear interior. The nuclear lamina protects the nucleus from mechanical stress and mediates nucleo-cytoskeletal coupling. Lamins form a scaffold that partially tethers chromatin at the nuclear envelope. The nuclear lamina also stabilises protein-protein interactions involved in gene regulation and DNA repair. The lamin-based protein sub-complexes are implicated in both nuclear and cytoskeletal organisation, the mechanical stability of the nucleus, genome organisation, transcriptional regulation, genome stability and cellular differentiation. Here, we review recent research on nuclear lamins and unique roles of A- and B-type lamins in modulating various nuclear processes and their impact on cell function.

Emerin modulates spatial organization of chromosome territories in cells on softer matrices.

Cells perceive and relay external mechanical forces into the nucleus through the nuclear envelope. Here we examined the effect of lowering substrate stiffness as a paradigm to address the impact of altered mechanical forces on nuclear structure-function relationships. RNA sequencing of cells on softer matrices revealed significant transcriptional imbalances, predominantly in chromatin associated processes and transcriptional deregulation of human Chromosome 1. Furthermore, 3-Dimensional fluorescence in situ hybridization (3D-FISH) analyses showed a significant mislocalization of Chromosome 1 and 19 Territories (CT) into the nuclear interior, consistent with their transcriptional deregulation. However, CT18 with relatively lower transcriptional dysregulation, also mislocalized into the nuclear interior. Furthermore, nuclear Lamins that regulate chromosome positioning, were mislocalized into the nuclear interior in response to lowered matrix stiffness. Notably, Lamin B2 overexpression retained CT18 near the nuclear periphery in cells on softer matrices. While, cells on softer matrices also activated emerin phosphorylation at a novel Tyr99 residue, the inhibition of which in a phospho-deficient mutant (emerinY99F), selectively retained chromosome 18 and 19 but not chromosome 1 territories at their conserved nuclear locations. Taken together, emerin functions as a key mechanosensor, that modulates the spatial organization of chromosome territories in the interphase nucleus.

Chromosomal aneuploidies induced upon Lamin B2 depletion are mislocalized in the interphase nucleus.

Chromosome territories assume non-random positions in the interphase nucleus with gene-rich chromosomes localized toward the nuclear interior and gene-poor chromosome territories toward the nuclear periphery. Lamins are intermediate filament proteins of the inner nuclear membrane required for the maintenance of nuclear structure and function. Here, we show using whole-genome expression profiling that Lamin A/C or Lamin B2 depletion in an otherwise diploid colorectal cancer cell line (DLD1) deregulates transcript levels from specific chromosomes. Further, three-dimensional fluorescence in situ hybridization (3D-FISH) analyses of a subset of these transcriptionally deregulated chromosome territories revealed that the diploid chromosome territories in Lamin-depleted cells largely maintain conserved positions in the interphase nucleus in a gene-density-dependent manner. In addition, chromosomal aneuploidies were induced in ~25 % of Lamin A/C or Lamin B2-depleted cells. Sub-populations of these aneuploid cells consistently showed a mislocalization of the gene-rich aneuploid chromosome 19 territory toward the nuclear periphery, while gene-poor aneuploid chromosome 18 territory was mislocalized toward the nuclear interior predominantly upon Lamin B2 than Lamin A/C depletion. In addition, a candidate gene locus ZNF570 (Chr.19q13.12) significantly overexpressed upon Lamin B2 depletion was remarkably repositioned away from the nuclear lamina. Taken together, our studies strongly implicate an overarching role for Lamin B2 in the maintenance of nuclear architecture since loss of Lamin B2 relieves the spatial positional constraints required for maintaining conserved localization of aneuploid chromosome territories in the interphase nucleus.

Positional stability of single double-strand breaks in mammalian cells.

Formation of cancerous translocations requires the illegitimate joining of chromosomes containing double-strand breaks (DSBs). It is unknown how broken chromosome ends find their translocation partners within the cell nucleus. Here, we have visualized and quantitatively analysed the dynamics of single DSBs in living mammalian cells. We demonstrate that broken ends are positionally stable and unable to roam the cell nucleus. Immobilization of broken chromosome ends requires the DNA-end binding protein Ku80, but is independent of DNA repair factors, H2AX, the MRN complex and the cohesion complex. DSBs preferentially undergo translocations with neighbouring chromosomes and loss of local positional constraint correlates with elevated genomic instability. These results support a contact-first model in which chromosome translocations predominantly form among spatially proximal DSBs.

UBR7 in concert with EZH2 inhibits the TGF-ß signaling leading to extracellular matrix remodeling.

The intricate interplay between resident cells and the extracellular matrix (ECM) profoundly influences cancer progression. In triple-negative breast cancer (TNBC), ECM architecture evolves due to the enrichment of lysyl oxidase, fibronectin, and collagen, promoting distant metastasis. Here we uncover a pivotal transcription regulatory mechanism involving the epigenetic regulator UBR7 and histone methyltransferase EZH2 in regulating transforming growth factor (TGF)-ß/Smad signaling, affecting the expression of ECM genes. UBR7 loss leads to a dramatic reduction in facultative heterochromatin mark H3K27me3, activating ECM genes. UBR7 plays a crucial role in matrix deposition in adherent cancer cells and spheroids, altering collagen content and lysyl oxidase activity, directly affecting matrix stiffness and invasiveness. These findings are further validated in vivo in mice models and TNBC patients, where reduced UBR7 levels are accompanied by increased ECM component expression and activity, leading to fibrosis-mediated matrix stiffness. Thus, UBR7 is a master regulator of matrix stiffening, influencing the metastatic potential of TNBC.

Nitroreductase-activated nitric oxide (NO) prodrugs.

Due to the involvement of nitric oxide (NO) in numerous and diverse physiological processes, site-directed delivery of therapeutic NO in order to minimize unwanted side-effects is necessary. O(2)-(4-Nitrobenzyl) diazeniumdiolates are designed as substrates for Escherichia coli nitroreductase (NTR), an enzyme that is frequently used to facilitate directed delivery of cytotoxic species to cancers. O(2)-(4-Nitrobenzyl) diazeniumdiolates are found to be stable in aqueous buffer but are metabolized by NTR to produce NO. A cell viability assay revealed that cytotoxic effects of O(2)-(4-nitrobenzyl)1-(2-methylpiperidin-1-yl)diazen-1-ium-1,2-diolate (4b) towards two cancer cell lines is significantly enhanced in the presence of NTR suggesting the potential for use of this compound in nitric oxide-based directed prodrug therapy.

Studying the Role of Chromosomal Instability (CIN) in GI Cancers Using Patient-derived Organoids.

Chromosomal instability (CIN) is associated with the initiation and progression of gastrointestinal (GI) tract cancers. Cancers of the GI tract are typically characterized by altered chromosome numbers. While the dynamics of CIN have been extensively characterized in 2D monolayer cell cultures derived from GI tumors, the tumor microenvironment and 3D tumor architecture also contribute to the progression of CIN, which is not captured in 2D cell culture systems. To overcome these limitations, self-organizing cellular structures that retain organ-specific 3D architecture, namely organoids, have been derived from various tissues of the GI tract. Organoids derived from normal tissue and patient tumors serve as a useful paradigm to study the crosstalk between tumor cells in the context of a tissue microenvironment and its impact on chromosomal stability. Such a paradigm, therefore, has a considerable advantage over 2D cell culture systems in drug screening and personalized medicine. Here, we review the importance of patient-derived tumor organoids (PDTOs) as a model to study CIN in cancers of the GI tract.

Nuclear envelope, chromatin organizers, histones, and DNA: The many achilles heels exploited across cancers.

In eukaryotic cells, the genome is organized in the form of chromatin composed of DNA and histones that organize and regulate gene expression. The dysregulation of chromatin remodeling, including the aberrant incorporation of histone variants and their consequent post-translational modifications, is prevalent across cancers. Additionally, nuclear envelope proteins are often deregulated in cancers, which impacts the 3D organization of the genome. Altered nuclear morphology, genome organization, and gene expression are defining features of cancers. With advances in single-cell sequencing, imaging technologies, and high-end data mining approaches, we are now at the forefront of designing appropriate small molecules to selectively inhibit the growth and proliferation of cancer cells in a genome- and epigenome-specific manner. Here, we review recent advances and the emerging significance of aberrations in nuclear envelope proteins, histone variants, and oncohistones in deregulating chromatin organization and gene expression in oncogenesis.

Direct Demonstration of Seed Size-Dependent α-Synuclein Amyloid Amplification.

The size of amyloid seeds is known to modulate their autocatalytic amplification and cellular toxicity. However, the seed size-dependent secondary nucleation mechanism, toxicity, and disease-associated biological processes mediated by α-synuclein (α-Syn) fibrils are largely unknown. Using the cellular model and in vitro reconstitution, we showed that the size of α-Syn fibril seeds dictates not only their cellular internalization and associated cell death but also the distinct mechanisms of fibril amplification pathways involved in the pathological conformational change of α-Syn. Specifically, small fibril seeds showed elongation possibly through monomer addition at the fibril termini, whereas longer fibrils template the fibril amplification by surface-mediated nucleation as demonstrated by super-resolution microscopy. The distinct mechanism of fibril amplification and cellular uptake along with toxicity suggest that breakage of fibrils into seeds of different sizes determines the underlying pathological outcome of synucleinopathies.

A Novel cis Regulatory Element Regulates Human XIST in a CTCF-Dependent Manner.

The long noncoding RNA XIST is the master regulator for the process of X chromosome inactivation (XCI) in mammalian females. Here, we report the existence of a hitherto-uncharacterized cis regulatory element (cRE) within the first exon of human XIST, which determines the transcriptional status of XIST during the initiation and maintenance phases of XCI. In the initiation phase, pluripotency factors bind to this cRE and keep XIST repressed. In the maintenance phase of XCI, the cRE is enriched for CTCF, which activates XIST transcription. By employing a CRISPR-dCas9-KRAB-based interference strategy, we demonstrate that binding of CTCF to the newly identified cRE is critical for regulating XIST in a YY1-dependent manner. Collectively, our study uncovers the combinatorial effect of multiple transcriptional regulators influencing XIST expression during the initiation and maintenance phases of XCI.

Evaluating annotations of an Agilent expression chip suggests that many features cannot be interpreted.

BACKGROUND: While attempting to reanalyze published data from Agilent 4 x 44 human expression chips, we found that some of the 60-mer olignucleotide features could not be interpreted as representing single human genes. For example, some of the oligonucleotides align with the transcripts of more than one gene. We decided to check the annotations for all autosomes and the X chromosome systematically using bioinformatics methods. RESULTS: Out of 42683 reporters, we found that 25505 (60%) passed all our tests and are considered "fully valid". 9964 (23%) reporters did not have a meaningful identifier, mapped to the wrong chromosome, or did not pass basic alignment tests preventing us from correlating the expression values of these reporters with a unique annotated human gene. The remaining 7214 (17%) reporters could be associated with either a unique gene or a unique intergenic location, but could not be mapped to a transcript in RefSeq. The 7214 reporters are further partitioned into three different levels of validity. CONCLUSION: Expression array studies should evaluate the annotations of reporters and remove those reporters that have suspect annotations. This evaluation can be done systematically and semi-automatically, but one must recognize that data sources are frequently updated leading to slightly changing validation results over time.

Tumor formation via loss of a molecular motor protein.

Aneuploidy has long been suggested to be causal in tumor formation. Direct testing of this hypothesis has been difficult because of the absence of methods to specifically induce aneuploidy. The chromosome-associated kinesin motor KIF4 plays multiple roles in mitosis, and its loss leads to multiple mitotic defects including aneuploidy. Here, we have taken advantage of the direct formation of aneuploidy in the absence of KIF4 to determine whether loss of a molecular motor and generation of aneuploidy during mitosis can trigger tumorigenesis. We find that embryonic stem cells genetically depleted of KIF4 support anchorage-independent growth and form tumors in nude mice. In cells lacking KIF4, mitotic spindle checkpoints and DNA-damage response pathways are activated. Down regulation or loss of KIF4 is physiologically relevant because reduced KIF4 levels are present in 35% of human cancers from several tissues. Our results support the notion that loss of a molecular motor leads to tumor formation and that aneuploidy can act as a primary trigger of tumorigenesis.

Position of human chromosomes is conserved in mouse nuclei indicating a species-independent mechanism for maintaining genome organization.

The nonrandom positioning of chromosome territories in eukaryotic cells is largely correlated with gene density and is conserved throughout evolution. Gene-rich chromosomes are predominantly central, while gene-poor chromosomes are peripherally localized in interphase nuclei. We previously demonstrated that artificially introduced human chromosomes assume a position equivalent to their endogenous homologues in the diploid colon cancer cell line DLD-1. These chromosomal aneuploidies result in a significant increase in transcript levels, suggesting a relationship between genomic copy number, gene expression, and chromosome position. We previously proposed that each chromosome is marked by a "zip code" that determines its nonrandom position in the nucleus. In this paper, we investigated (1) whether mouse nuclei recognize such determinants of nuclear position on human chromosomes to facilitate their distinct partitioning and (2) if chromosome positioning and transcriptional activity remain coupled under these trans-species conditions. Using three-dimensional fluorescence in situ hybridization, confocal microscopy, and gene expression profiling, we show (1) that gene-poor and gene-rich human chromosomes maintain their divergent but conserved positions in mouse-human hybrid nuclei and (2) that a foreign human chromosome is actively transcribed in mouse nuclei. Our results suggest a species-independent conserved mechanism for the nonrandom positioning of chromosomes in the three-dimensional interphase nucleus.

Imaging Chromosome Territory and Gene Loci Positions in Cells Grown on Soft Matrices.

It is well established that the genome is non-randomly organized in the interphase nucleus with gene rich chromosome territories toward the nuclear interior, while gene poor chromosome territories are proximal to the nuclear periphery. In vivo tissue stiffness and architecture modulates cell type-specific genome organization and gene expression programs. However, the impact of external mechanical forces on the non-random organization of the genome is not completely understood. Here we describe a modified protocol for visualizing chromosome territories and gene loci positions in cells exposed to reduced matrix stiffness by employing soft polyacrylamide matrices. 3-Dimensional Fluorescence In Situ Hybridization (3D-FISH) protocol followed by image analyses performed on cells exposed to extracellular matrices of varying stiffness properties, enables the determination of the dynamics of chromosome territories as well as gene loci in the interphase nucleus. This will be useful in understanding how chromosome territories respond to changes in substrate stiffness and the potential correlation between the repositioning of chromosome territories and their respective transcriptional profiles.

Lamin A/C and Emerin depletion impacts chromatin organization and dynamics in the interphase nucleus.

BACKGROUND: Nuclear lamins are type V intermediate filament proteins that maintain nuclear structure and function. Furthermore, Emerin - an interactor of Lamin A/C, facilitates crosstalk between the cytoskeleton and the nucleus as it also interacts with actin and Nuclear Myosin 1 (NM1). RESULTS: Here we show that the depletion of Lamin A/C or Emerin, alters the localization of the nuclear motor protein - Nuclear Myosin 1 (NM1) that manifests as an increase in NM1 foci in the nucleus and are rescued to basal levels upon the combined knockdown of Lamin A/C and Emerin. Furthermore, Lamin A/C-Emerin co-depletion destabilizes cytoskeletal organization as it increases actin stress fibers. This further impinges on nuclear organization, as it enhances chromatin mobility more toward the nuclear interior in Lamin A/C-Emerin co-depleted cells. This enhanced chromatin mobility was restored to basal levels either upon inhibition of Nuclear Myosin 1 (NM1) activity or actin depolymerization. In addition, the combined loss of Lamin A/C and Emerin alters the otherwise highly conserved spatial positions of chromosome territories. Furthermore, knockdown of Lamin A/C or Lamin A/C-Emerin combined, deregulates expression levels of a candidate subset of genes. Amongst these genes, both KLK10 (Chr.19, Lamina Associated Domain (LAD+)) and MADH2 (Chr.18, LAD-) were significantly repressed, while BCL2L12 (Chr.19, LAD-) is de-repressed. These genes differentially reposition with respect to the nuclear envelope. CONCLUSIONS: Taken together, these studies underscore a remarkable interplay between Lamin A/C and Emerin in modulating cytoskeletal organization of actin and NM1 that impinges on chromatin dynamics and function in the interphase nucleus.

Genome 3D-architecture: Its plasticity in relation to function.

The genome of higher eukaryotes is non-randomly organized in the interphase nucleus. However, notwithstanding the absence of membrane bound sub-compartments, the nucleus coordinates a number of functions largely by organizing chromatin in a non-random but dynamic manner. The plasticity of chromatin structure and function relies on epigenetic modifications as well as its association with nuclear landmarks such as the nuclear envelope, nuclear lamina, nuclear pore complex and nuclear bodies such as the nucleolus among others. In the absence of membrane-bound compartments, cells and the nucleus, in particular, employ phase-separation, which unmixes phases that constrain biochemical reactions in complex non-membranous sub-compartments such as the nucleolus or even the heterochromatin. This review attempts to provide a glimpse into the microcosm of phase-separated nuclear sub-compartments, that regulate nuclear structure- function relationships.