ABSTRACT
Co-polymers of tropomyosin and actin make up a major fraction of the actin cytoskeleton. Tropomyosin isoforms determine the function of an actin filament by selectively enhancing or inhibiting the association of other actin binding proteins, altering the stability of an actin filament and regulating myosin activity in an isoform-specific manner. Previous work has implicated specific roles for at least five different tropomyosin isoforms in stress fibres, as depletion of any of these five isoforms results in a loss of stress fibres. Despite this, most models of stress fibres continue to exclude tropomyosins. In this study, we investigate tropomyosin organisation in stress fibres by using super-resolution light microscopy and electron microscopy with genetically tagged, endogenous tropomyosin. We show that tropomyosin isoforms are organised in subdomains within the overall domain of stress fibres. The isoforms Tpm3.1 and 3.2 (hereafter Tpm3.1/3.2, encoded by TPM3) colocalise with non-muscle myosin IIa and IIb heads, and are in register, but do not overlap, with non-muscle myosin IIa and IIb tails. Furthermore, perturbation of Tpm3.1/3.2 results in decreased myosin IIa in stress fibres, which is consistent with a role for Tpm3.1 in maintaining myosin IIa localisation in stress fibres.
Subject(s)
Nonmuscle Myosin Type IIA/metabolism , Stress Fibers/metabolism , Tropomyosin/metabolism , Cell Line, Tumor , Humans , Nonmuscle Myosin Type IIA/genetics , Protein Isoforms/genetics , Protein Isoforms/metabolism , Stress Fibers/genetics , Tropomyosin/geneticsABSTRACT
The HIV capsid is a multifunctional protein capsule that mediates the delivery of the viral genetic material into the nucleus of the target cell. Host cell proteins bind to a number of repeating binding sites on the capsid to regulate steps in the replication cycle. Here, we develop a fluorescence fluctuation spectroscopy method using self-assembled capsid particles as the bait to screen for fluorescence-labeled capsid-binding analytes ("prey" molecules) in solution. The assay capitalizes on the property of the HIV capsid as a multivalent interaction platform, facilitating high sensitivity detection of multiple prey molecules that have accumulated onto capsids as spikes in fluorescence intensity traces. By using a scanning stage, we reduced the measurement time to 10 s without compromising on sensitivity, providing a rapid binding assay for screening libraries of potential capsid interactors. The assay can also identify interfaces for host molecule binding by using capsids with defects in known interaction interfaces. Two-color coincidence detection using the fluorescent capsid as the bait further allows the quantification of binding levels and determination of binding affinities. Overall, the assay provides new tools for the discovery and characterization of molecules used by the HIV capsid to orchestrate infection. The measurement principle can be extended for the development of sensitive interaction assays, utilizing natural or synthetic multivalent scaffolds as analyte-binding platforms.
Subject(s)
Capsid , HIV-1 , Binding Sites , Capsid Proteins , Spectrometry, FluorescenceABSTRACT
Centromeres form a chromosomal platform for the assembly of the kinetochores, which are required for orderly chromosome segregation. Assembly of both centromeres and kinetochores proceeds by a step-by-step mechanism that is regulated in time and space. It has been suggested that the regulated nuclear import of centromeric proteins is involved in this process. We show that the knockdown of nucleoporins NPP-10, NPP-13 and NPP-20 in Caenorhabditiselegans affects early steps in centromere formation and sister centromere resolution, and results in severe chromosomal defects in the early embryo. These phenotypes mirror the knockdown phenotype of HCP-4 (an ortholog of mammalian CENP-C), a key factor for centromere formation and inner kinetochore assembly. HCP-4 is present in the cytoplasm during interphase. It is imported into nuclei and assembled in centromeres during prophase. Following the knockdown of NPP-10, NPP-13 and NPP-20, HCP-4 remains in the cytosol throughout prophase due to stalled import. In prometaphase and later mitotic stages after breakdown of the nuclear envelope, HCP-4 is not incorporated into centromeres. These results indicate that correct timing of the availability of HCP-4 by nuclear import is essential.
Subject(s)
Caenorhabditis elegans Proteins/metabolism , Caenorhabditis elegans/metabolism , Cell Nucleus/metabolism , Centromere/metabolism , Nuclear Pore Complex Proteins/metabolism , Active Transport, Cell Nucleus , Animals , Caenorhabditis elegans/cytology , Caenorhabditis elegans/embryology , Embryo, Nonmammalian/cytology , Embryo, Nonmammalian/metabolism , Gene Knockdown Techniques , Metaphase , Mitosis , Models, Biological , Nuclear Envelope/metabolism , Prophase , RNA InterferenceABSTRACT
The replication of the genome is a spatio-temporally highly organized process. Yet, its flexibility throughout development suggests that this process is not genetically regulated. However, the mechanisms and chromatin modifications controlling replication timing are still unclear. We made use of the prominent structure and defined heterochromatic landscape of pericentric regions as an example of late replicating constitutive heterochromatin. We manipulated the major chromatin markers of these regions, namely histone acetylation, DNA and histone methylation, as well as chromatin condensation and determined the effects of these altered chromatin states on replication timing. Here, we show that manipulation of DNA and histone methylation as well as acetylation levels caused large-scale heterochromatin decondensation. Histone demethylation and the concomitant decondensation, however, did not affect replication timing. In contrast, immuno-FISH and time-lapse analyses showed that lowering DNA methylation, as well as increasing histone acetylation, advanced the onset of heterochromatin replication. While dnmt1(-)(/)(-) cells showed increased histone acetylation at chromocenters, histone hyperacetylation did not induce DNA demethylation. Hence, we propose that histone hypoacetylation is required to maintain normal heterochromatin duplication dynamics. We speculate that a high histone acetylation level might increase the firing efficiency of origins and, concomitantly, advances the replication timing of distinct genomic regions.
Subject(s)
DNA Replication Timing , Heterochromatin/physiology , Histones/metabolism , Acetylation , Animals , Cells, Cultured , DNA Methylation , Epistasis, Genetic , Heterochromatin/chemistry , Heterochromatin/metabolism , MiceABSTRACT
XMAP215/Dis1 family proteins positively regulate microtubule growth. Repeats at their N termini, called TOG domains, are important for this function. While TOG domains directly bind tubulin dimers, it is unclear how this interaction translates to polymerase activity. Understanding the functional roles of TOG domains is further complicated by the fact that the number of these domains present in the proteins of different species varies. Here, we take advantage of a recent crystal structure of the third TOG domain from Caenorhabditis elegans, Zyg9, and mutate key residues in each TOG domain of XMAP215 that are predicted to be important for interaction with the tubulin heterodimer. We determined the contributions of the individual TOG domains to microtubule growth. We show that the TOG domains are absolutely required to bind free tubulin and that the domains differentially contribute to XMAP215's overall affinity for free tubulin. The mutants' overall affinity for free tubulin correlates well with polymerase activity. Furthermore, we demonstrate that an additional basic region is important for targeting to the microtubule lattice and is critical for XMAP215 to function at physiological concentrations. Using this information, we have engineered a "bonsai" protein, with two TOG domains and a basic region, that has almost full polymerase activity.
Subject(s)
Caenorhabditis elegans Proteins/metabolism , Caenorhabditis elegans/enzymology , Microtubule-Associated Proteins/metabolism , Microtubules/physiology , Protein Engineering/methods , Protein Structure, Tertiary/physiology , Tubulin/metabolism , Animals , Base Sequence , Caenorhabditis elegans Proteins/genetics , Chromatography, Gel , Microscopy, Fluorescence , Microtubule-Associated Proteins/genetics , Microtubules/metabolism , Molecular Sequence Data , Mutagenesis , Polymers/metabolism , Protein Structure, Tertiary/geneticsABSTRACT
Chromatin has been shown to undergo diffusional motion, which is affected during gene transcription by RNA polymerase activity. However, the relationship between chromatin mobility and other genomic processes remains unclear. Hence, we set out to label the DNA directly in a sequence unbiased manner and followed labeled chromatin dynamics in interphase human cells expressing GFP-tagged proliferating cell nuclear antigen (PCNA), a cell cycle marker and core component of the DNA replication machinery. We detected decreased chromatin mobility during the S-phase compared to G1 and G2 phases in tumor as well as normal diploid cells using automated particle tracking. To gain insight into the dynamical organization of the genome during DNA replication, we determined labeled chromatin domain sizes and analyzed their motion in replicating cells. By correlating chromatin mobility proximal to the active sites of DNA synthesis, we showed that chromatin motion was locally constrained at the sites of DNA replication. Furthermore, inhibiting DNA synthesis led to increased loading of DNA polymerases. This was accompanied by accumulation of the single-stranded DNA binding protein on the chromatin and activation of DNA helicases further restricting local chromatin motion. We, therefore, propose that it is the loading of replisomes but not their catalytic activity that reduces the dynamics of replicating chromatin segments in the S-phase as well as their accessibility and probability of interactions with other genomic regions.
Subject(s)
Chromatin , DNA Replication , Humans , S Phase , Cell Cycle , DNA HelicasesABSTRACT
Human immunodeficiency virus (HIV) is the most extensively researched human pathogen. Despite this massive scientific endeavour, several fundamental viral processes remain enigmatic. One such critical process is uncoating-the event that releases the viral genome from the proteinaceous shell of the capsid during infection. While this process is conceptually simple, the molecular underpinnings, timing, regulation, and cellular location of uncoating remain contentious. This review describes the hurdles that have limited our understanding in this area and presents recently deployed in vitro and in cellulo techniques that have been developed expressly with the aim of directly visualising capsid uncoating at the single-particle level and understanding the mechanics behind this essential aspect of HIV infection.
ABSTRACT
Antimicrotubule vinca alkaloids are widely used in the clinic but their toxicity is often dose limiting. Strategies that enhance their effectiveness at lower doses are needed. We show that combining vinca alkaloids with compounds that target a specific population of actin filaments containing the cancer-associated tropomyosin Tpm3.1 result in synergy against a broad range of tumor cell types. We discovered that low concentrations of vincristine alone induce supernumerary microtubule asters that form transient multi-polar spindles in early mitosis. Over time these asters can be reconstructed into functional bipolar spindles resulting in cell division and survival. These microtubule asters are organized by the nuclear mitotic apparatus protein (NuMA)-dynein-dynactin complex without involvement of centrosomes. However, anti-Tpm3.1 compounds at nontoxic concentrations inhibit this rescue mechanism resulting in delayed onset of anaphase, formation of multi-polar spindles, and apoptosis during mitosis. These findings indicate that drug targeting actin filaments containing Tpm3.1 potentiates the anticancer activity of low-dose vincristine treatment. IMPLICATIONS: Simultaneously inhibiting Tpm3.1-containing actin filaments and microtubules is a promising strategy to potentiate the anticancer activity of low-dose vincristine.
Subject(s)
Actin Cytoskeleton/metabolism , Lung Neoplasms/drug therapy , Piperazines/administration & dosage , Tropomyosin/metabolism , Vincristine/administration & dosage , A549 Cells , Actin Cytoskeleton/drug effects , Animals , Cell Proliferation/drug effects , Cell Survival/drug effects , Dose-Response Relationship, Drug , Drug Synergism , Female , Gene Expression Regulation, Neoplastic/drug effects , HT29 Cells , HeLa Cells , Humans , Lung Neoplasms/metabolism , MCF-7 Cells , Mice , Piperazines/pharmacology , Tropomyosin/antagonists & inhibitors , Vincristine/pharmacologyABSTRACT
Mechanoelectrical transduction is a cellular signalling pathway where physical stimuli are converted into electro-chemical signals by mechanically activated ion channels. We describe here the presence of mechanically activated currents in melanoma cells that are dependent on TMEM87a, which we have renamed Elkin1. Heterologous expression of this protein in PIEZO1-deficient cells, that exhibit no baseline mechanosensitivity, is sufficient to reconstitute mechanically activated currents. Melanoma cells lacking functional Elkin1 exhibit defective mechanoelectrical transduction, decreased motility and increased dissociation from organotypic spheroids. By analysing cell adhesion properties, we demonstrate that Elkin1 deletion is associated with increased cell-substrate adhesion and decreased homotypic cell-cell adhesion strength. We therefore conclude that Elkin1 supports a PIEZO1-independent mechanoelectrical transduction pathway and modulates cellular adhesions and regulates melanoma cell migration and cell-cell interactions.
When cells receive signals about their surrounding environment, this initiates a chain of signals which generate a response. Some of these signalling pathways allow cells to sense physical and mechanical forces via a process called mechanotransduction. There are different types of mechanotransduction. In one pathway, mechanical forces open up specialized channels on the cell surface which allow charged particles to move across the membrane and create an electrical current. Mechanoelectrical transduction plays an important role in the spread of cancer: as cancer cells move away from a tumour they use these signalling pathways to find their way between cells and move into other parts of the body. Understanding these pathways could reveal ways to stop cancer from spreading, making it easier to treat. However, it remains unclear which molecules regulate mechanoelectrical transduction in cancer cells. Now, Patkunarajah, Stear et al. have studied whether mechanoelectrical transduction is involved in the migration of skin cancer cells. To study mechanoelectrical transduction, a fine mechanical input was applied to the skin cancer cells whilst measuring the flow of charged molecules moving across the membrane. This experiment revealed that a previously unknown protein named Elkin1 is required to convert mechanical forces into electrical currents. Deleting this newly found protein caused skin cancer cells to move more slowly and dissociate more easily from tumour-like clusters of cells. These findings suggest that Elkin1 is part of a newly identified mechanotransduction pathway that allows cells to sense mechanical forces from their surrounding environment. More work is needed to determine what role Elkin1 plays in mechanoelectrical transduction and whether other proteins are also involved. This could lead to new approaches that prevent cancer cells from dissociating from tumours and spreading to other body parts.
Subject(s)
Mechanotransduction, Cellular/physiology , Melanoma/pathology , Membrane Proteins/physiology , Cell Adhesion , Cell Communication , Cell Line, Tumor , Cell Movement , Humans , Ion Channels/physiology , Spheroids, CellularABSTRACT
Previous studies of the kinetochore in mammalian systems have demonstrated that this structure undergoes reorganizations after microtubule attachment or in response to activation of the spindle checkpoint. Here, we show that the Caenorhabditis elegans kinetochore displays analogous rearrangements at prometaphase, when microtubule/chromosome interactions are being established, and after exposure to checkpoint stimuli such as nocodazole or anoxia. These reorganizations are characterized by a dissociation of several kinetochore proteins, including HCP-1/CeCENP-F, HIM-10/CeNuf2, SAN-1/CeMad3, and CeBUB-1, from the centromere. We further demonstrate that at metaphase, despite having dissociated from the centromere, these reorganized kinetochore proteins maintain their associations with the metaphase plate. After checkpoint activation, these proteins are detectable as large "flares" that project out laterally from the metaphase plate. Disrupting these gene products via RNA interference results in sensitivity to checkpoint stimuli, as well as defects in the organization of chromosomes at metaphase. These phenotypes suggest that these proteins, and by extension their reorganization during mitosis, are important for mediating the checkpoint response as well as directing the assembly of the metaphase plate.
Subject(s)
Caenorhabditis elegans/ultrastructure , Cell Cycle , Kinetochores/metabolism , Metaphase , Prometaphase , Animals , Caenorhabditis elegans Proteins/metabolism , Cell Cycle Proteins/biosynthesis , Centromere/ultrastructure , Chromosomal Proteins, Non-Histone/biosynthesis , Chromosomal Proteins, Non-Histone/metabolism , Histones/metabolism , Hypoxia , Microfilament Proteins , Microscopy , Microtubules/ultrastructure , Mitosis , Nocodazole/pharmacology , Phenotype , Prophase , Protein Kinases/biosynthesis , Protein Serine-Threonine Kinases , RNA Interference , Spindle ApparatusABSTRACT
The actin cytoskeleton is a dynamic network of filaments that is involved in virtually every cellular process. Most actin filaments in metazoa exist as a co-polymer of actin and tropomyosin (Tpm) and the function of an actin filament is primarily defined by the specific Tpm isoform associated with it. However, there is little information on the interdependence of these co-polymers during filament assembly and disassembly. We addressed this by investigating the recovery kinetics of fluorescently tagged isoform Tpm3.1 into actin filament bundles using FRAP analysis in cell culture and in vivo in rats using intracellular intravital microscopy, in the presence or absence of the actin-targeting drug jasplakinolide. The mobile fraction of Tpm3.1 is between 50% and 70% depending on whether the tag is at the C- or N-terminus and whether the analysis is in vivo or in cultured cells. We find that the continuous dynamic exchange of Tpm3.1 is not significantly impacted by jasplakinolide, unlike tagged actin. We conclude that tagged Tpm3.1 may be able to undergo exchange in actin filament bundles largely independent of the assembly and turnover of actin.
Subject(s)
Actin Cytoskeleton/metabolism , Cytoskeleton/metabolism , Tropomyosin/metabolism , Actin Cytoskeleton/drug effects , Animals , Cytoskeleton/drug effects , Depsipeptides/pharmacology , Mice , Mice, KnockoutABSTRACT
The discovery of the DNA double helix structure half a century ago immediately suggested a mechanism for its duplication by semi-conservative copying of the nucleotide sequence into two DNA daughter strands. Shortly after, a second fundamental step toward the elucidation of the mechanism of DNA replication was taken with the isolation of the first enzyme able to polymerize DNA from a template. In the subsequent years, the basic mechanism of DNA replication and its enzymatic machinery components were elucidated, mostly through genetic approaches and in vitro biochemistry. Most recently, the spatial and temporal organization of the DNA replication process in vivo within the context of chromatin and inside the intact cell are finally beginning to be elucidated. On the one hand, recent advances in genome-wide high throughput techniques are providing a new wave of information on the progression of genome replication at high spatial resolution. On the other hand, novel super-resolution microscopy techniques are just starting to give us the first glimpses of how DNA replication is organized within the context of single intact cells with high spatial resolution. The integration of these data with time lapse microscopy analysis will give us the ability to film and dissect the replication of the genome in situ and in real time.
Subject(s)
DNA Replication/physiology , Genome , Animals , Cell Cycle/genetics , Epigenesis, Genetic , Humans , Microscopy, ConfocalABSTRACT
In vitro assays that reconstitute the dynamic behavior of microtubules provide insight into the roles of microtubule-associated proteins (MAPs) in regulating the growth, shrinkage, and catastrophe of microtubules. The use of total internal reflection fluorescence microscopy with fluorescently labeled tubulin and MAPs has allowed us to study microtubule dynamics at the resolution of single molecules. In this chapter we present a practical overview of how these assays are performed in our laboratory: fluorescent labeling methods, strategies to prolong the time to photo-bleaching, preparation of stabilized microtubules, flow-cells, microtubule immobilization, and finally an overview of the workflow that we follow when performing the experiments. At all stages, we focus on practical tips and highlight potential stumbling blocks.
Subject(s)
Image Processing, Computer-Assisted/methods , Microtubules/metabolism , Animals , Cell Culture Techniques/methods , Cells, Cultured , Color , Fluorescent Dyes/pharmacology , Humans , Microscopy, Fluorescence/instrumentation , Microscopy, Fluorescence/methods , Models, Biological , Staining and Labeling/methods , Tubulin/metabolismABSTRACT
Plus-end-tracking proteins (+TIPs) are localized at the fast-growing, or plus end, of microtubules, and link microtubule ends to cellular structures. One of the best studied +TIPs is EB1, which forms comet-like structures at the tips of growing microtubules. The molecular mechanisms by which EB1 recognizes and tracks growing microtubule ends are largely unknown. However, one clue is that EB1 can bind directly to a microtubule end in the absence of other proteins. Here we use an in vitro assay for dynamic microtubule growth with two-color total-internal-reflection-fluorescence imaging to investigate binding of mammalian EB1 to both stabilized and dynamic microtubules. We find that under conditions of microtubule growth, EB1 not only tip tracks, as previously shown, but also preferentially recognizes the GMPCPP microtubule lattice as opposed to the GDP lattice. The interaction of EB1 with the GMPCPP microtubule lattice depends on the E-hook of tubulin, as well as the amount of salt in solution. The ability to distinguish different nucleotide states of tubulin in microtubule lattice may contribute to the end-tracking mechanism of EB1.
Subject(s)
Microtubule-Associated Proteins/chemistry , Microtubules/metabolism , Tubulin/chemistry , Animals , Brain/metabolism , Cytoskeleton/metabolism , Green Fluorescent Proteins/metabolism , Humans , Microscopy, Fluorescence/methods , Microtubule-Associated Proteins/metabolism , Models, Biological , Nucleotides/chemistry , Protein Binding , Static Electricity , SwineABSTRACT
Fast growth of microtubules is essential for rapid assembly of the microtubule cytoskeleton during cell proliferation and differentiation. XMAP215 belongs to a conserved family of proteins that promote microtubule growth. To determine how XMAP215 accelerates growth, we developed a single-molecule assay to visualize directly XMAP215-GFP interacting with dynamic microtubules. XMAP215 binds free tubulin in a 1:1 complex that interacts with the microtubule lattice and targets the ends by a diffusion-facilitated mechanism. XMAP215 persists at the plus end for many rounds of tubulin subunit addition in a form of "tip tracking." These results show that XMAP215 is a processive polymerase that directly catalyzes the addition of up to 25 tubulin dimers to the growing plus end. Under some circumstances XMAP215 can also catalyze the reverse reaction, namely microtubule shrinkage. The similarities between XMAP215 and formins, actin polymerases, suggest that processive tip tracking is a common mechanism for stimulating the growth of cytoskeletal polymers.
Subject(s)
Microtubule-Associated Proteins/metabolism , Microtubules/metabolism , Tubulin/metabolism , Xenopus Proteins/metabolism , Animals , Binding Sites/physiology , Biological Assay/methods , Catalytic Domain/physiology , Cell Differentiation/physiology , Cell Enlargement , Cell Line , Cytoskeleton/metabolism , Cytoskeleton/ultrastructure , Diffusion , Dimerization , Fetal Proteins/metabolism , Formins , Green Fluorescent Proteins/metabolism , Microfilament Proteins/metabolism , Microscopy, Fluorescence , Microtubule-Associated Proteins/genetics , Microtubules/ultrastructure , Nuclear Proteins/metabolism , Polymers/metabolism , Protein Binding/physiology , Protein Structure, Tertiary/physiology , Protein Transport/physiology , Spodoptera , Sus scrofa , Xenopus Proteins/genetics , Xenopus laevisABSTRACT
The precise coordination of the different steps of DNA replication is critical for the maintenance of genome stability. We have probed the mechanisms coupling various components of the replication machinery and their response to polymerase stalling by inhibition of the DNA polymerases in living mammalian cells with aphidicolin. We observed little change in the behaviour of proteins involved in the initiation of DNA replication. In contrast, we detected a marked accumulation of the single stranded DNA binding factor RPA34 at sites of DNA replication. Finally, we demonstrate that proteins involved in the elongation step of DNA synthesis dissociate from replication foci in the presence of aphidicolin. Taken together, these data indicate that inhibition of processive DNA polymerases uncouples the initiation of DNA replication from subsequent elongation steps. We, therefore, propose that the replication machinery is made up of distinct functional sub-modules that allow a flexible and dynamic response to challenges during DNA replication.
Subject(s)
DNA Ligases/metabolism , DNA Replication , DNA-Binding Proteins/metabolism , DNA-Directed DNA Polymerase/metabolism , DNA/biosynthesis , Proliferating Cell Nuclear Antigen/metabolism , Repressor Proteins/metabolism , Animals , Aphidicolin/pharmacology , Cell Line , DNA Ligase ATP , Enzyme Inhibitors/pharmacology , HeLa Cells , Humans , Mice , Myoblasts/cytology , Myoblasts/metabolismABSTRACT
Previous studies of mitosis show that capture of single kinetochores by microtubules from both centrosomes (merotelic orientation) is a major cause of aneuploidy. We have characterized hcp-6, a temperature-sensitive chromosome segregation mutant in C. elegans that exhibits chromosomes attached to both poles via a single sister kinetochore. We demonstrate that the primary defect in this mutant is a failure to fully condense chromosomes during prophase. Although centromere formation and sister centromere resolution remain unaffected in hcp-6, the chromosomes lack the rigidity of wild-type chromosomes and twist around the long axis of the chromosome. As such, they are unable to establish a proper orientation at prometaphase, allowing individual kinetochores to be captured by microtubules from both poles. We therefore propose that chromosome rigidity plays an essential role in maintaining chromosome orientation to prevent merotelic capture.