Project description:We transfected HEK-293T cells to express RfA1. The RNA-Seq results indicates that Genes evolved in biological processes such as “regulation of microtubule cytoskeleton organization”, “microtubule polymerization or depolymerization”, “microtubule nucleation” were found to respond to RfA1 expression. Correspondingly, these microtubule relevant genes were also sorted to cellular component items, including “spindle microtubule”, “spindle pole centrosome”, “mitotic spindle”, “spindle” , which indicates the tight relationship between RfA1 and microtubules.

Project description:To ensure an even segregation of chromosomes during somatic cell division, eukaryotes rely on specific microtubule structures called mitotic spindles. There are however striking differences in overall spindle organization among eukaryotic super groups, and in particular little is known about how spindle architecture is determined in plants. As a foundation for our work, we have measured prime characteristics of Arabidopsis mitotic spindles and built a three-dimensional dynamic model of the Arabidopsis mitotic spindle using Cytosim. Next, we identified the cell-cycle regulator CYCLIN-DEPENDENT KINASE B1 (CDKB1) together with its cyclin partner CYCB3;1 as key regulators of spindle shape and organization in Arabidopsis. Loss of CDKB1 function resulted in a high number of astral microtubules that are normally absent from plant spindles, as opposed to animal ones. We identified an augmin complex member, ENDOSPERM DEFECTIVE1 (EDE1), as a substrate of the CDKB1;1-CYCB3;1 complex. A non-phosphorylatable mutant of EDE1 displayed spindles with extended pole-to-pole distance, resembling the phenotypes of cycb3;1 and cdkb1 mutants, and the mutated EDE1 associated less efficiently with spindle microtubules. Consistently, reducing the level of augmin in Cytosim simulations largely recapitulated the spindle phenotypes observed in cycb3;1 and cdkb1 mutants. Our results emphasize the importance of cell cycle-dependent phospho-control of the mitotic spindle in plant cells. They also support the validity of our computational model as a framework for the exploration of mechanisms controlling the organization of plant spindles

Project description:Staufen1 (STAU1) is an RNA-binding protein involved in maturation, localization, translation and decay of mRNAs. STAU1 expression is modulated during the cell cycle and decreases during mitosis. In prometaphase, STAU155 binds specific classes of mRNAs that code for proteins implicated in transcription and cell cycle regulation. In this paper, we report that STAU155 co-localizes with microtubules on the mitotic spindle in human colorectal cancer cell line HCT116, and map the molecular determinant required for this association within the N-terminal 88 amino acids (aa 25-37). Interestingly, STAU1 co-purifies with ribosomal proteins and co-localizes with active sites of translation on the mitotic spindle. To characterize STAU1-dependent mRNA transport and localization on the spindle, we used RNAseq analysis to identify spindle-associated mRNAs on purified spindles of wild-type and STAU1-KO CRISPR cell lines. Our datasets identify 161 protein-coding transcripts that are less abundant on the mitotic spindle of STAU1-KO cells compared to WT, and 660 that are more abundant. Altogether, these data demonstrate that STAU1 controls the transport and the localization of specific sub-populations of mRNAs to the mitotic spindle of cancer cells and suggest that at least some spindle-localized mRNAs undergo local translation during mitosis.

Project description:The lack of a cure for metastatic prostate cancer (PCa) highlights the urgent need for more efficient drugs to fight this disease. Here, we report the molecular mechanism of action of the natural product 6-acetoxy-anopterine (6-AA) in malignant cells of the prostate. This potent cytotoxic alkaloid from the endemic Australian tree Anopterus macleayanus induced at low nanomolar doses a strong accumulation of LNCaP and PC3 PCa cells in mitosis, severe mitotic spindle defects and asymmetric cell divisions, ultimately leading to mitotic catastrophe accompanied by cell death through apoptosis. DNA microarray of 6-AA treated LNCaP cells combined with pathway analysis identified very similar transcriptional changes when compared to vinblastine, highlighting pathways involved in mitosis, microtubule spindle organisation and microtubule binding. Like vinblastine, 6-AA inhibited microtubule polymerization in a cell-free system and reduced microtubule polymer mass in vitro. Yet, microtubule alterations that are associated with resistance to microtubule-destabilizing drugs like vinca alkaloids or 2-methoxyestradiol did not confer cross-resistance to 6-AA, suggesting a different mechanism of microtubule interaction. Finally, 6-AA is the first-in-class microtubule inhibitor that features the unique anopterine scaffold. Altogether, this study provides a strong rationale to further develop this novel structure class of microtubule inhibitor for the treatment of malignant disease.

Project description:Kinetochores are macromolecular assemblies that connect chromosomes to spindle microtubules during mitosis. The metazoan-specific ≈800 kilodalton ROD-Zwilch-ZW10 (RZZ) complex builds a fibrous corona that assembles on mitotic kinetochores prior to microtubule attachment to promote chromosome alignment and robust spindle assembly checkpoint signaling. Here, we combine biochemical reconstitutions, single particle electron cryo microscopy, cross-linking mass spectrometry, and structural modeling to build a complete model of human RZZ

Project description:Mitosis is an important process in the cell cycle required for cells to divide. Never in mitosis (NIMA)-like kinases (NEKs) are regulators of mitotic functions in diverse organisms. Plasmodium spp, the causative agent of malaria is a divergent unicellular haploid eukaryote with some unusual features in terms of its mitotic and nuclear division cycle that presumably facilitate proliferation in varied environments. For example, during the sexual stage of male gametogenesis that occurs within the mosquito host, an atypical rapid closed endomitosis is observed. Three rounds of genome replication from 1N to 8N and successive cycles of multiple spindle formation and chromosome segregation occur within eight minutes followed by karyokinesis to generate haploid gametes. Our previous Plasmodium berghei kinome screen identified four Nek genes, of which two, NEK2 and NEK4, are required for meiosis. NEK1 is likely to be essential for mitosis in asexual blood stage schizogony in the vertebrate host, but its function during male gametogenesis is unknown. Here, we study NEK1 location and function, using live cell imaging, ultrastructure expansion microscopy (U-ExM) and electron microscopy, together with conditional gene knockdown and proteomic approaches. We report spatiotemporal NEK1 location in real-time, coordinated with microtubule organising centre (MTOC) dynamics during the unusual mitoses at various stages of the Plasmodium spp. life cycle. Knockdown studies reveal NEK1 to be an essential component of the MTOC in male cell differentiation, associated with rapid mitosis, spindle formation and kinetochore attachment. These data suggest that Plasmodium berghei NEK1 kinase is an important component of MTOC organisation and essential regulator of chromosome segregation during male gamete formation.

Project description:RNAseq analysis of suprabasal cells in the epidermis of control and K10rtTA;TRESpastin (which depolymerize microtubules) at E16.5 were performed. We observed the premature differentiation of the barrier and increased actomyosin contractility in suprabasal differentiated cells upon microtubule disruption compared to control, and proved the increased actomyosin contractility caused by microtubule depolymerization leads to basal stem cell hyperproliferation during epidermal development.

Project description:Muscle spindles are skeletal muscle stretch receptors that mediate axial and limb position sensation (proprioception) to the central nervous system. Defective proprioception, often characterized by gait ataxia and poor coordination, is present in a variety of human sensory and motor neuropathies having diverse etiologies. Spindles contain specialized intrafusal muscle fibers that are induced during development by sensory innervation. The molecular events mediating the morphogenetic induction process are poorly characterized but depend upon neuregulins and their cognate ErbB receptor signaling. Recently, we demonstrated that the transcription factor Egr3 is induced and regulated by intrafusal muscle fiber sensory innervation during spindle induction. Moreover, Egr3-deficient mice have impaired spindle morphogenesis and profound gait ataxia. Thus, Egr3 mediated transcription is critical for muscle stretch receptor development and potentially for myotube fate specification.,Egr3 may mediate spindle morphogenesis induced by Neuregulin/ErbB signaling after myotubes are contacted by sensory axons during development. As a starting point for understanding the specific role for Egr3 in this process, we will use a genome wide expression analysis to identify genes regulated (either directly or indirectly) by Egr3 in primary myotubes. It is not practical to examine Egr3 mediated gene expression directly within spindles since they comprise less than 0.1% of the muscle mass. Therefore, gene expression analysis will be examined in primary myotubes grown in vitro. Primary myoblasts isolated from mice and differentiated in vitro are biochemically most similar to extrafusal muscle fibers which do not express Egr3. To identify genes regulated by Egr3 in myotubes, gene expression in myotubes enforced to express full length Egr3 will be compared to gene expression in myotubes enforced to express truncated (transcriptionally inactive) Egr3.,Egr3-deficient mice lack muscle spindles and have profound proprioceptive deficits. Egr3 is specifically expressed in a subset of developing primary myotubes after innervation by sensory axons. Spindle induction is dependent upon sensory/myotube contact which involves sensory axon produced neuregulin and ErbB receptor signaling in the myotube. Shortly after or during induction, Egr3 expression is upregulated and maintained in the nascent myotube/spindle as one of the earliest molecular events know to occur during spindle morphogenesis. We hypothesize that Egr3 mediated transcription is critical for engaging gene programs specific to and essential for, muscle spindle formation. Moreover, Egr3 may be involved in fate specification of myotubes that develop into biochemically and physiologically distinct intrafusal muscle fibers within spindles. To date, the target genes regulated by Egr3 during spindle morphogenesis have not been characterized.,Myoblasts from wild type newborn mice will be isolated and purified. Myoblasts will be plated on collagen coated plates and differentiated in vitro for 7 days. During in vitro differentiation, myoblasts fuse to form multinucleated myotubes that exhibit contractile properties. Egr3 is not expressed in myotubes in vitro, which is consistent with their similarity to extrafusal muscle fibers that also do not express Egr3 in vivo. Only intrafusal fibers of muscle spindles express high levels of Egr3 in this muscle fiber context. Adenoviruses that express full length Egr3 (Egr3wt; transcriptionally active) and truncated Egr3 (Egr3tr; transcriptionally inactive) have been generated and characterized in our laboratory. After 7 days of in vitro differentiation, primary myotubes will be infected with either Egr3wt or Egr3tr adenoviruses. 100% infection is routinely obtained which is confirmed by coexpression of enhanced green fluorescent protein (EGFP). Care will be taken to minimize viral induced toxicity of the myotubes after infection. Myotubes are maintained after infection for 24 hours, after which total RNA is extracted from the cell lysates. The two RNA samples will be used for microarray analysis to identify genes that are upregulated and downregulated by Egr3 in the myotube cellular context. We will repeat the infection, RNA isolation and microarray analysis three times to minimize identifying false positive differentially expressed genes. Differentially expressed genes will be confirmed using real-time PCR. Interesting differentially expressed genes will be examined by in situ hybridization to determine if they are specifically expressed in wild type spindles. Since the identified differentially expressed genes will represent both indirect and direct target genes, we will perform Chromatin Immunoprecipitation (ChIP) from Egr3wt infected myotubes and screen the ChIP DNA library by PCR to determine which gene promoters are directly bound by Egr3.

Project description:Post-translational cycles of α-tubulin detyrosination/tyrosination generate microtubule diversity, with broad physiological and clinical implications. However, the mechanistic understanding of how this microtubule diversity is decoded into specific cellular functions remains largely unknown. Here we show that the core microtubule-binding site at kinetochores ‘reads’ and responds to the α-tubulin detyrosination/tyrosination code. By combining CRISPR-Cas9 gene editing of enzymatic ‘writers’ of α-tubulin detyrosination/tyrosination in human cells, with biochemical purifications, mass spectrometry and super-resolution microscopy, we identified over a hundred proteins that preferentially associate with either detyrosinated or tyrosinated microtubules during mitosis. Among these, the conserved KNL-1/MIS12 complex/NDC80 complex (KMN) network at kinetochores showed a preference for tyrosinated microtubules. In addition to established roles in error correction and polar chromosome alignment, live-cell imaging uncovered a previously overlooked link between the α-tubulin detyrosination/tyrosination code and the formation of functional kinetochore-microtubule attachments, necessary for normal metaphase chromosome oscillations and timely spindle assembly checkpoint satisfaction. In vitro reconstitution experiments revealed that α-tubulin detyrosination specifically promotes Ndc80 diffusion along the microtubule lattice. We propose that the gradual accumulation of detyrosinated α-tubulin after initial microtubule capture at kinetochores facilitates the biased diffusion of core-binding proteins along the microtubule lattice, establishing a positive feedback loop that sustains kinetochore-microtubule attachments.

Project description:In mitosis, the augmin complex binds to spindle microtubules to recruit the γ-tubulin ring complex (γ-TuRC), the principal microtubule nucleator, for the formation of branched microtubules. Our understanding of augmin-mediated microtubule branching is strongly hampered by the lack of structural information on the augmin complex. Here we elucidate the molecular architecture and define the conformational plasticity of the augmin complex using an integrative structural biology approach. The elongated structure of the augmin complex is characterised by extensive coiled-coil segments and comprises two structural elements with distinct but complementary functions in γ-TuRC and microtubule binding, linked by a flexible hinge. The augmin complex is recruited to microtubules via a composite microtubule binding site comprising a positively charged unordered extension and two Calponin homology domains. Our study provides the structural basis for augmin function in branched microtubule formation, decisively fostering our understanding of spindle formation in mitosis.