Project description:Osteoblast differentiation leading to bone formation requires a coordinated transcriptional program. We have recently demonstrated that microtubule actin crosslinking factor 1 (MACF1) promotes osteoblast differentiation, suggesting a key role in regulating early-phase osteoblast differentiation. Here, we showed that the early-phase osteoblast differentiation transcriptome dynamics was regulated by MACF1 and the transcription of TCF7/LEF1, key effectors of Wnt signaling that is important for osteoblast differentiation was suppressed by MACF1 knockdown. Co-IP and Protein mass spectrometry revealed that MACF1 interacted with a known and two previously unknown repressors of TCF7/LEF1, DKK1, CDK12 and MEAF6. ChIP-seq analysis of MACF1-associated promoters further revealed that MACF1 interacted with transcription factors TCF12 and E2F6, which also suppressed the transcription of TCF7/LEF1. Furthermore, all these four MACF-interacted proteins inhibited osteoblast differentiation. By studying the underlying mechanism, we found that cytoplasmic-nuclear localization of MACF1 was dependent on its level and the cytoplasmic-nuclear localization of TCF12 and E2F6 was regulated by MACF1 localization. In addition, MACF1 oppositely regulated the transcription activity of TCF12 and TCF7. Current study, for the first time to our knowledge, suggest that MACF1 acts as a sponge of osteoblast differentiation repressors to promote osteoblast differentiation, and indicate a novel mechanism for regulating the cellular location of transcription factors by a protein associated with microtubule and actin.

Project description:Microtubule actin crosslinking factor 1 (Macf1) plays a role in coordinated actions of actin and microtubules in multiple cellular processes. Here we show that Macf1 is also critical for ciliogenesis in multiple cell types. Ablation of Macf1 in the developing retina abolishes ciliogenesis and basal bodies fail to dock to ciliary vesicles or migrate apically. Photoreceptor polarity is randomized while inner retinal cells laminate correctly, suggesting that photoreceptor maturation is guided by polarity cues provided by cilia. Deletion of Macf1 in adult photoreceptors caused reversal of basal body docking and loss of outer segments, reflecting a continuous requirement for Macf1 function. Macf1 was also shown to interact with ciliary proteins Mkks and Talpid3. We propose that a disruption of trafficking across microtubles to actin filaments underlies the ciliogenesis defect in cells lacking Macf1, and that Mkks and Talpid3 are involved in the coordination of microtubule and actin interactions.

Project description:MACF1 promotes osteoblast differentiation by sequestering repressors in cytoplasm

Project description:MACF1 Promotes Osteoblast Differentiation by Sequestering Wnt Signaling Repressors in Cytoplasm [ChIP-seq]

Project description:MACF1 Promotes Osteoblast Differentiation by Sequestering Wnt Signaling Repressors in Cytoplasm [RNA-seq]

Project description:Canonical Wnt/B-catenin signaling is frequently dysregulated in myeloid leukemias and is implicated in leukemogenesis. Nuclear-localized β-catenin is indicative of active Wnt signaling and is frequently observed in acute myeloid leukemia (AML) patients; however, some patients exhibit little or no β-catenin nuclear-localization even where cytosolic B-catenin is abundant. Differential propensity for nuclear-localized β-catenin is also observed in cell lines. To investigate the factors mediating the nuclear-localization of B-catenin we carried out a nuclear/cytoplasmic proteomic analysis of the B-catenin interactome in myeloid leukemia cells. From this we identified hundreds of putative novel B-catenin-interactors. Comparison of interacting factors between Wnt-responsive cells (high nuclear B-catenin, K562/HEL) versus Wnt-unresponsive cells (low nuclear B-catenin, ML1) suggested the established interactor, LEF1, is a key factor mediating the nuclear-localization of B-catenin in myeloid leukemia. The relative levels of nuclear LEF1 and B-catenin were tightly correlated in both cell lines and in primary AML blasts. Furthermore, LEF1 knockdown inhibited B-catenin nuclear-localization and transcriptional activation in Wnt-responsive cells. Conversely, LEF1 overexpression was able to promote both nuclear-localization and B-catenin-dependent transcriptional responses in previously Wnt-unresponsive cells. This study is the first to present a B-catenin interactome in hematopoietic cells and reveals LEF1 as a critical regulator of canonical Wnt signaling in myeloid leukemia.

Project description:The transcriptome analysis of WT and Tcf7/Lef1 double knockout (dKO) Treg subset CD4+ Foxp3+ T regulatory (Treg) cells are key players in preventing lethal autoimmunity and deleterious tissue inflammation. To fulfill these roles, Treg cells undergo activation and differentiate processes to acquire diverse functional properties. However, how Treg’s functional specifications are regulated during their differentiation remains poorly understood. Here we show that two TCF/LEF family transcription factors (TFs), TCF1 and LEF1 act redundantly as checkpoint regulators in peripheral Treg homeostatic differentiation and functional subset specification. We find that gradient expression of TCF1 and LEF1 distinguishes Treg cells into three distinct subsets. Sustained expression of TCF1/LEF1 retains Treg at their resting stage. Conversely, conditional knockout of TCF1 and LEF1 promotes the effector-like phenotype in bulk Treg cells, but surprisingly renders the mice susceptible to early onset of systemic autoimmunity. This uncoupling between Treg effector phenotype and their function in suppressing autoimmunity is attributed by two TCF1/LEF1-centered mechanisms. First, the ablation of TCF1 and LEF1 in Treg cells abolishes the generation of T follicular regulatory (Tfr) cells, leading to unrestrained T follicular helper (Tfh) and germinal center B cell responses. Second, TCF1 and LEF1 are required for Treg survival under competitive conditions. Thus, TCF1 and LEF1 play critical roles in Treg homeostatic maintenance and Tfr generation.

Project description:T cell factor 1 (TCF1; encoded by Tcf7) plays a critical role in T cell development and functions as a tumor suppressor by repressing the expression of LEF1 in the thymus. Here we reported the stage-specific regulation of TCF1 in early T cell differentiation and T cell malignancy despite the broad understand on the functions of TCF1. To illustrate the stage-specific functions of Tcf7 in T cell development and tumorigenesis, we applied single-cell transcriptional analysis to identify the precise trajectory of gene expression changes between the surface receptor-defined stages of T cell development.

Project description:A critical problem in biology is understanding how cells choose between self-renewal and differentiation. To generate a comprehensive view of the mechanisms controlling early hematopoietic precursor self-renewal and differentiation, we used systems-based approaches and murine EML multipotential hematopoietic precursor cells as a primary model. EML cells give rise to a mixture of self-renewing Lin-SCA+CD34+ cells and partially differentiated non-renewing Lin-SCA-CD34- cells in a cell autonomous fashion. We identified and validated the HMG box protein TCF7 as a key regulator in this self-renewal/differentiation switch, and it operates in the absence of canonical Wnt signaling. We found that TCF7 is the most downregulated transcription factor when CD34+ cells switch into CD34- cells using RNA-Seq. We subsequently identified the target genes bound by TCF7 using ChIP-Seq. We show that TCF7 binds to Runx1 (Aml1) promoter region, and RUNX1 and TCF7 co-regulate. Gene Set Enrichment Analysis suggests that TCF7 primarily acts as a positive regulator of genes preferentially expressed in CD34+ cells. Consistent with this possibility, knocking-down TCF7 represses many up-regulated genes in Lin-CD34+ cells. Finally a network of up-regulated transcription factors of CD34+ cells which defines the self-renewing state was constructed. These studies in EML cells demonstrate fundamental cell-intrinsic properties of the switch between self-renewal and differentiation, and yield valuable insights for manipulating HSCs and other differentiating systems. Examining the transcription factor binding targets of TCF7 and RUNX1.

Project description:A critical problem in biology is understanding how cells choose between self-renewal and differentiation. To generate a comprehensive view of the mechanisms controlling early hematopoietic precursor self-renewal and differentiation, we used systems-based approaches and murine EML multipotential hematopoietic precursor cells as a primary model. EML cells give rise to a mixture of self-renewing Lin-SCA+CD34+ cells and partially differentiated non-renewing Lin-SCA-CD34- cells in a cell autonomous fashion. We identified and validated the HMG box protein TCF7 as a key regulator in this self-renewal/differentiation switch, and it operates in the absence of canonical Wnt signaling. We found that TCF7 is the most downregulated transcription factor when CD34+ cells switch into CD34- cells using RNA-Seq. We subsequently identified the target genes bound by TCF7 using ChIP-Seq. We show that TCF7 binds to Runx1 (Aml1) promoter region, and RUNX1 and TCF7 co-regulate. Gene Set Enrichment Analysis suggests that TCF7 primarily acts as a positive regulator of genes preferentially expressed in CD34+ cells. Consistent with this possibility, knocking-down TCF7 represses many up-regulated genes in Lin-CD34+ cells. Finally a network of up-regulated transcription factors of CD34+ cells which defines the self-renewing state was constructed. These studies in EML cells demonstrate fundamental cell-intrinsic properties of the switch between self-renewal and differentiation, and yield valuable insights for manipulating HSCs and other differentiating systems. The gene expression changes when TCF7 is knocked-down by shRNA in Lin-SCA+CD34+ cells were identified by microarray analysis of one control and two experimental samples.