Project description:Background: Stathmin (STMN1) protein functions to regulate assembly of the microtubule cytoskeleton by destabilizing microtubule polymers. Stathmin over-expression has been correlated with cancer stage progression, while stathmin depletion leads to death of some cancer cell lines in culture. In contrast, stathmin-null mice are viable with minor axonopathies and loss of innate fear response. Several stathmin binding partners, in addition to tubulin, have been shown to affect cell motility in culture. To expand our understanding of stathmin function in normal cells, we compared gene expression profiles, measured by microarray and qRT-PCR, of mouse embryo fibroblasts isolated from STMN1+/+ and STMN1-/- mice to determine the transcriptome level changes present in the genetic knock-out of stathmin. Results: Microarray analysis of STMN1 loss at a fold change threshold of 2.0 revealed expression changes for 437 genes, of which 269 were up-regulated and 168 were down-regulated. Microarray data and qRT-PCR analysis of mRNA expression demonstrated changes in the message levels for STMN4, encoding RB3, a protein related to stathmin, and in alterations to many tubulin isotype mRNAs. KEGG Pathway analysis of the microarray data indicated changes to cell motility-related genes, and qRT-PCR plates specific for focal adhesion and ECM proteins generally confirmed the microarray data. Several microtubule assembly regulators and motors were also differentially regulated in STMN1-/- cells, but these changes should not compensate for loss of stathmin. Conclusions: Approximately 50% of genes up or down regulated (at a fold change of ≥ 2) in STMN1-/- mouse embryo fibroblasts function broadly in cell adhesion and motility. These results support models indicating a role for stathmin in regulating cell locomotion, but also suggest that this functional activity may involve changes to the cohort of proteins expressed in the cell, rather than as a direct consequence of stathmin-dependent regulation of the microtubule cytoskeleton. Gene expression of mouse embryo fibroblasts lacking stathmin reveal changes in genes contributing to cell motility Two-color Agilent 4x44k chips with dye-swap on 2 of 4 arrays. Replicate data presented.

Project description:The CDK inhibitor p27Kip1 is a critical regulator of cell cycle progression, but the mechanisms by which p27Kip1 controls cell proliferation in vivo are still not fully elucidated. We recently demonstrated that the microtubule destabilizing protein stathmin is a relevant p27Kip1binding partner involved in the regulation of cell motility. To get more insights into the in vivo significance of this interaction, we generated p27Kip1 and stathmin double knock out (DKO) mice. Interestingly, thorough characterization of DKO mice demonstrated that most of the phenotypes of p27Kip1 null mice linked to the hyperproliferative behavior, such as the increased body and organ weights, the outgrowth of the retina basal layer and the development of pituitary adenomas, were reverted by co-ablation of stathmin. In vivo analyses showed a reduced proliferation rate in DKO compared to p27kip1 null mice, linked, at molecular level, to decreased kinase activity of CDK4/6, rather than of CDK1 and CDK2. Gene expression profile analyses of mouse thymuses confirmed the phenotypes observed in vivo, demonstrating that DKO clustered with WT and not with p27KO thymuses. Taken together, the results demonstrate that stathmin cooperates with p27Kip1 to control the early phase of G1 to S phase transition and strongly suggest that this function has particular relevance in the contest of tumor progression. Four-conditions experiment (four different mouse genotypes), 6 biological replicates of wild type mouse thymus, 6 biological replicates of p27 knock-out mouse thymus, 6 biological replicates of stathmin knock-out mouse thymus, 6 biological replicates of double knock-out (p27 and stathmin) mouse thymus. Reference design: pool of RNAs derived from mouse fibroblasts of all the genotypes.Reference design;

Project description:Glioblastoma multiforme (GBM) is an aggressive primary brain cancer that includes focal amplification of PDGFRα and for which there are no effective therapies. Herein, we report the development of a genetically engineered mouse model of GBM based on autocrine, chronic stimulation of PDGFRα and the analysis of GBM signaling pathways using proteomics. We discovered the tubulin-binding protein Stathmin1 (STMN1) as a PDGFRα phospho-regulated target and that this mis-regulation conferred selective sensitivity to vinblastine (VB) cytotoxicity. Treatment of PDGFRα GBMs with VB in mice drastically prolonged survival and was dependent on STMN1. Our work provides a rationale for evaluating genotype-specific anti-microtubule drugs as cancer treatment in select GBM patient populations.

Project description:Hereditary Spastic Paraplegia (HSP) leads to progressive gait disturbances with lower limb muscle weakness and spasticity. Mutations in SPG4 are a major cause of autosomal-dominant HSP. Spastin, the protein encoded by SPG4, is a microtubule-severing protein and is enriched in the distal axon of corticospinal motor neurons which degenerate in HSP patients. How SPG4 mutations cause axon degeneration in patients is not understood. Multipotent neural stem cells, accessible from patient olfactory mucosa biopsies, provided a new patient-derived cell models for HSP. Olfactory neurosphere-derived cells were obtained from cohorts of HSP patients with, and without, mutations in SPG4 and from healthy controls. Patient cells had extensive changes in expression of cell cycle-related genes and in genes associated with microtubule formation. Despite this, cell proliferation and metabolic functions of the patient cells were similar to controls. Cells with mutated SPG4 had significantly less spastin and acetylated tubulin but significantly more stathmin, a tubulin-depolymerising protein. These cells also significant deficits in the intracellular distribution of peroxisomes and mitochondria, compared to control cells. This model reveals that SPG4-HSP patient-derived neural stem/progenitors compensate for the cell cycle-related effects of reduced spastin levels in the nucleus, in part by large changes in gene expression, but failed to correct deficits in organelle trafficking. The results raise the question of whether these deficits arise directly from the loss of spastin or indirectly from the compensation. Patient-derived olfactory stem cells provide a new model for examining the neural consequences of human genetic mutations in their natural setting: at normal gene dosages against normal genetic backgrounds.

Project description:A proliferated and post-translationally modified microtubule network underlies cellular growth in cardiac hypertrophy and contributes to contractile dysfunction in heart failure. Yet how the heart achieves this modified network is poorly understood. Determining how the “tubulin code” – the permutations of tubulin isoforms and post-translational modifications - is rewritten upon cardiac stress may provide new targets to modulate cardiac remodeling. Further, while tubulin can autoregulate its own expression, it is unknown if autoregulation is operant in the heart or tuned in response to stress. Here we use heart failure patient samples and murine models of cardiac remodeling to interrogate transcriptional, autoregulatory, and post-translational mechanisms that contribute to microtubule network remodeling at different stages of heart disease. We find that autoregulation is operant across tubulin isoforms in the heart and leads to an apparent disconnect in tubulin mRNA and protein levels in heart failure. We also find that within 4 hours of a hypertrophic stimulus and prior to cardiac growth, microtubule detyrosination is rapidly induced to help stabilize the network. This occurs concomitant with rapid transcriptional and autoregulatory activation of specific tubulin isoforms and microtubule motors. Upon continued hypertrophic stimulation, there is an increase in post-translationally modified microtubule tracks and anterograde motors to support cardiac growth, while total tubulin content increases through progressive transcriptional and autoregulatory induction of tubulin isoforms. Our work provides a new model for how the tubulin code is rapidly rewritten to establish a proliferated, stable microtubule network that drives cardiac remodeling, and provides the first evidence of tunable tubulin autoregulation during pathological progression.

Project description:A proliferated and post-translationally modified microtubule network underlies cellular growth in cardiac hypertrophy and contributes to contractile dysfunction in heart failure. Yet how the heart achieves this modified network is poorly understood. Determining how the “tubulin code” – the permutations of tubulin isoforms and post-translational modifications - is rewritten upon cardiac stress may provide new targets to modulate cardiac remodeling. Further, while tubulin can autoregulate its own expression, it is unknown if autoregulation is operant in the heart or tuned in response to stress. Here we use heart failure patient samples and murine models of cardiac remodeling to interrogate transcriptional, autoregulatory, and post-translational mechanisms that contribute to microtubule network remodeling at different stages of heart disease. We find that autoregulation is operant across tubulin isoforms in the heart and leads to an apparent disconnect in tubulin mRNA and protein levels in heart failure. We also find that within 4 hours of a hypertrophic stimulus and prior to cardiac growth, microtubule detyrosination is rapidly induced to help stabilize the network. This occurs concomitant with rapid transcriptional and autoregulatory activation of specific tubulin isoforms and microtubule motors. Upon continued hypertrophic stimulation, there is an increase in post-translationally modified microtubule tracks and anterograde motors to support cardiac growth, while total tubulin content increases through progressive transcriptional and autoregulatory induction of tubulin isoforms. Our work provides a new model for how the tubulin code is rapidly rewritten to establish a proliferated, stable microtubule network that drives cardiac remodeling, and provides the first evidence of tunable tubulin autoregulation during pathological progression.

Project description:A proliferated and post-translationally modified microtubule network underlies cellular growth in cardiac hypertrophy and contributes to contractile dysfunction in heart failure. Yet how the heart achieves this modified network is poorly understood. Determining how the “tubulin code” – the permutations of tubulin isoforms and post-translational modifications - is rewritten upon cardiac stress may provide new targets to modulate cardiac remodeling. Further, while tubulin can autoregulate its own expression, it is unknown if autoregulation is operant in the heart or tuned in response to stress. Here we use heart failure patient samples and murine models of cardiac remodeling to interrogate transcriptional, autoregulatory, and post-translational mechanisms that contribute to microtubule network remodeling at different stages of heart disease. We find that autoregulation is operant across tubulin isoforms in the heart and leads to an apparent disconnect in tubulin mRNA and protein levels in heart failure. We also find that within 4 hours of a hypertrophic stimulus and prior to cardiac growth, microtubule detyrosination is rapidly induced to help stabilize the network. This occurs concomitant with rapid transcriptional and autoregulatory activation of specific tubulin isoforms and microtubule motors. Upon continued hypertrophic stimulation, there is an increase in post-translationally modified microtubule tracks and anterograde motors to support cardiac growth, while total tubulin content increases through progressive transcriptional and autoregulatory induction of tubulin isoforms. Our work provides a new model for how the tubulin code is rapidly rewritten to establish a proliferated, stable microtubule network that drives cardiac remodeling, and provides the first evidence of tunable tubulin autoregulation during pathological progression.

Project description:A proliferated and post-translationally modified microtubule network underlies cellular growth in cardiac hypertrophy and contributes to contractile dysfunction in heart failure. Yet how the heart achieves this modified network is poorly understood. Determining how the “tubulin code” – the permutations of tubulin isoforms and post-translational modifications - is rewritten upon cardiac stress may provide new targets to modulate cardiac remodeling. Further, while tubulin can autoregulate its own expression, it is unknown if autoregulation is operant in the heart or tuned in response to stress. Here we use heart failure patient samples and murine models of cardiac remodeling to interrogate transcriptional, autoregulatory, and post-translational mechanisms that contribute to microtubule network remodeling at different stages of heart disease. We find that autoregulation is operant across tubulin isoforms in the heart and leads to an apparent disconnect in tubulin mRNA and protein levels in heart failure. We also find that within 4 hours of a hypertrophic stimulus and prior to cardiac growth, microtubule detyrosination is rapidly induced to help stabilize the network. This occurs concomitant with rapid transcriptional and autoregulatory activation of specific tubulin isoforms and microtubule motors. Upon continued hypertrophic stimulation, there is an increase in post-translationally modified microtubule tracks and anterograde motors to support cardiac growth, while total tubulin content increases through progressive transcriptional and autoregulatory induction of tubulin isoforms. Our work provides a new model for how the tubulin code is rapidly rewritten to establish a proliferated, stable microtubule network that drives cardiac remodeling, and provides the first evidence of tunable tubulin autoregulation during pathological progression.

Project description:The CDK inhibitor p27Kip1 is a critical regulator of cell cycle progression, but the mechanisms by which p27Kip1 controls cell proliferation in vivo are still not fully elucidated. We recently demonstrated that the microtubule destabilizing protein stathmin is a relevant p27Kip1binding partner involved in the regulation of cell motility. To get more insights into the in vivo significance of this interaction, we generated p27Kip1 and stathmin double knock out (DKO) mice. Interestingly, thorough characterization of DKO mice demonstrated that most of the phenotypes of p27Kip1 null mice linked to the hyperproliferative behavior, such as the increased body and organ weights, the outgrowth of the retina basal layer and the development of pituitary adenomas, were reverted by co-ablation of stathmin. In vivo analyses showed a reduced proliferation rate in DKO compared to p27kip1 null mice, linked, at molecular level, to decreased kinase activity of CDK4/6, rather than of CDK1 and CDK2. Gene expression profile analyses of mouse thymuses confirmed the phenotypes observed in vivo, demonstrating that DKO clustered with WT and not with p27KO thymuses. Taken together, the results demonstrate that stathmin cooperates with p27Kip1 to control the early phase of G1 to S phase transition and strongly suggest that this function has particular relevance in the contest of tumor progression.

Project description:STMN1 is is a highly conserved 18 KDa cytosolic phosphoprotein, involved in the control of cell proliferation, differentiation, motility, clonogenicity and survival. Over-expression of STMN1 has been shown to be a marker of poor outcome in nasopharyngeal, ovarian, estrogen receptor positive tamoxifen treated early breast and oral squamous cell carcinomas. Limited studies have shown overexpression of STMN1 in higher grade localized prostate cancers; however its association with outcome and metastatic disease is unclear. Here, we investigate role and regulation of STMN1 during prostate cancer progression.