Sebastian Mana‐Capelli scite author profile

SUMMARY Similar to the mammalian intestine, the Drosophila adult midgut has resident stem cells that support growth and regeneration. How the niche regulates intestinal stem cell activity in both mammals and flies is not well understood. Here we show that the conserved germinal center protein kinase Misshapen restricts intestinal stem cell division by repressing the expression of the JAK-STAT pathway ligand Upd3 in differentiating enteroblasts. Misshapen, a distant relative to the prototypic Warts activating kinase Hippo, interacts with and activates Warts to negatively regulate the activity of Yorkie and the expression of Upd3. The mammalian Misshapen homolog MAP4K4 similarly interacts with LATS (Warts homolog) and promotes inhibition of YAP (Yorkie homolog). Together, this work reveals that the Misshapen-Warts-Yorkie pathway acts in enteroblasts to control niche signaling to intestinal stem cells. These findings also provide a model in which to study requirements for MAP4K4-related kinases in MST1/2-independent regulation of LATS and YAP.

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Dictyostelium Sun‐1 Connects the Centrosome to Chromatin and Ensures Genome Stability

Xiong

Rivero

Euteneuer

et al. 2008

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The centrosome-nucleus attachment is a prerequisite for faithful chromosome segregation during mitosis. We addressed the function of the nuclear envelope (NE) protein Sun-1 in centrosome-nucleus connection and the maintenance of genome stability in Dictyostelium discoideum. We provide evidence that Sun-1 requires direct chromatin binding for its inner nuclear membrane targeting. Truncation of the cryptic N-terminal chromatinbinding domain of Sun-1 induces dramatic separation of the inner from the outer nuclear membrane and deformations in nuclear morphology, which are also observed using a Sun-1 RNAi construct. Thus, chromatin binding of Sun-1 defines the integrity of the nuclear architecture. In addition to its role as a NE scaffold, we find that abrogation of the chromatin binding of Sun-1 dissociates the centrosome-nucleus connection, demonstrating that Sun-1 provides an essential link between the chromatin and the centrosome. Moreover, loss of the centrosomenucleus connection causes severe centrosome hyperamplification and defective spindle formation, which enhances aneuploidy and cell death significantly. We highlight an important new aspect for Sun-1 in coupling the centrosome and nuclear division during mitosis to ensure faithful chromosome segregation.Key words: aneuploidy, centrosome hyperamplification, nuclear envelope architecture, spindle formation defects, Unc-84 The nuclear envelope (NE) separates the nuclear compartment from the cytoplasm. It is composed of two membranes: the outer nuclear membrane (ONM) and the inner nuclear membrane (INM). The lumen between the two membranes is the perinuclear space (PNS). The ONM is continuous with the endoplasmic reticulum (ER), whereas the INM harbors a unique set of proteins. INM and ONM proteins can interact within the PNS. Underneath the INM, the nuclear lamina is located, which is formed by intermediate filament (IF) proteins and associated proteins. The lamina forms the nucleoskeleton and associates with the INM, chromatin and nuclear pore complexes. Proteins of the NE have important roles. They are involved in nuclear migration and positioning and are essential for many processes such as mitosis, meiosis, differentiation and cell migration. Furthermore, several of the NE proteins have been associated with inherited diseases (1,2). Research in mammalian cells and in Caenorhabditis eleganshas identified conserved components of the NE that link the nucleoskeleton to the cytoskeleton. In C. elegans, two putative INM proteins, matefin/SUN-1 and UNC-84, bind to the nuclear lamina and extend their C-terminus into the PNS where they interact with the C-termini of KASH domain proteins (Klarsicht/Anc-1/Syne homology, designated KASH domain). Matefin/SUN-1 and UNC-84 belong to the SUN family of proteins based on the presence of the conserved SUN (Sad1/UNC-84 homology) domain at their C-terminus. KASH domain proteins are type II transmembrane proteins of the NE and have been identified as molecular linkers connecting the nucleus to actin filaments [filamentous acti...

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TRIP6 inhibits Hippo signaling in response to tension at adherens junctions

et al. 2017

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The transcriptional co-activator YAP controls cell proliferation, survival, and tissue regeneration in response to changes in the mechanical environment. It is not known how mechanical stimuli such as tension are sensed and how the signal is transduced to control YAP activity. Here, we show that the LIM domain protein TRIP6 acts as part of a mechanotransduction pathway at adherens junctions to promote YAP activity by inhibiting the LATS1/2 kinases. Previous studies showed that vinculin at adherens junctions becomes activated by mechanical tension. We show that vinculin inhibits Hippo signaling by recruiting TRIP6 to adherens junctions and stimulating its binding to and inhibition of LATS1/2 in response to tension. TRIP6 competes with MOB1 for binding to LATS1/2 thereby blocking MOB1 from recruiting the LATS1/2 activating kinases MST1/2. Together, these findings reveal a novel pathway that responds to tension at adherens junctions to control Hippo pathway signaling.

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Identification of SIN Pathway Targets Reveals Mechanisms of Crosstalk between NDR Kinase Pathways

et al. 2013

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Summary The Septum Initiation Network (SIN) regulates multiple functions during late mitosis to ensure successful completion of cytokinesis in S. pombe. One mechanism by which the SIN promotes cytokinesis is by inhibiting a competing polarity pathway called the MOR [1], which is required for initiation of polarized growth following completion of cytokinesis [2]. Mutual antagonism between the two NDR kinase pathways, SIN and MOR, is required to coordinate cytoskeletal rearrangements during the mitosis-interphase transition. To determine how the SIN regulates the MOR pathway, we developed a proteomics approach that allowed us to identify multiple substrates of the SIN effector kinase, Sid2, including the MOR pathway components Nak1 kinase and an associated protein Sog2. We show that Sid2 phosphorylation of Nak1 causes removal of Nak1 from the SPBs, which may both relieve Nak1 inhibition of the SIN, and block MOR signaling by preventing interaction of Nak1 with the scaffold protein Mor2. Because the SIN and MOR are conserved in mammalian cells (Hippo and Ndr1/2 pathways respectively), this work may provide important insight into how the activities of these essential pathways are coordinated.

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Archaeoglobus fulgidus CopB Is a Thermophilic Cu2+-ATPase

Mana‐Capelli

Mandal

Argüello

2003

Journal of Biological Chemistry

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Angiomotins stimulate LATS kinase autophosphorylation and act as scaffolds that promote Hippo signaling

Mana‐Capelli

McCollum

2018

Journal of Biological Chemistry

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The Hippo pathway controls cell proliferation, differentiation, and survival by regulating the Yes-associated protein (YAP) transcriptional coactivator in response to various stimuli, including the mechanical environment. The major YAP regulators are the LATS1/2 kinases, which phosphorylate and inhibit YAP. LATS1/2 are activated by phosphorylation on a hydrophobic motif (HM) outside of the kinase domain by MST1/2 and other kinases. Phosphorylation of the HM motif then triggers autophosphorylation of the kinase in the activation loop to fully activate the kinase, a process facilitated by MOB1. The angiomotin family of proteins (AMOT, AMOTL1, and AMOTL2) bind LATS1/2 and promote its kinase activity and YAP phosphorylation through an unknown mechanism. Here we show that angiomotins increase Hippo signaling through multiple mechanisms. We found that, by binding LATS1/2, SAV1, and YAP, angiomotins function as a scaffold that connects LATS1/2 to both its activator SAV1-MST1 and its target YAP. Deletion of all three angiomotins reduced the association of LATS1 with SAV1-MST1 and decreased MST1/2-mediated LATS1/2-HM phosphorylation. Angiomotin deletion also reduced LATS1/2's ability to associate with and phosphorylate YAP. In addition, we found that angiomotins have an unexpected function along with MOB1 to promote autophosphorylation of LATS1/2 on the activation loop motif independent of HM phosphorylation. These results indicate that angiomotins enhance Hippo signaling by stimulating LATS1/2 autophosphorylation and by connecting LATS1/2 with both its activator SAV1-MST1/2 and its substrate YAP.

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The kinesin-14 Klp2 is negatively regulated by the SIN for proper spindle elongation and telophase nuclear positioning

Mana‐Capelli

McLean

Chen

et al. 2012

MBoC

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