Where is APC going?

Adenomatous polyposis coli (APC) protein has been thought to function as a tumor suppressor through its involvement in the Wnt/β-catenin signaling pathway. However, its connections to the cytoskeleton and microtubules in particular are becoming apparent, and the discovery of these new functions for APC is leading to a reevaluation of its role not only in tumorigenesis, but also in normal physiology

The dynamic behavior of the APC-binding protein EB1 on the distal ends of microtubules

AbstractAdenomatous polyposis coli protein (APC) is a well-characterized tumor suppressor protein [1–3]. We previously showed that APC tagged with green fluorescent protein (GFP) in Xenopus A6 epithelial cells moves along a subset of microtubules and accumulates at their growing plus ends in cell extensions [4]. EB1, which was identified as an APC-binding protein by yeast two-hybrid analysis [5], was also reported to be associated with microtubules [6–8]. To examine the interaction between APC and EB1 within cells, we compared the dynamic behavior of EB1–GFP with that of APC–GFP in A6 transfectants. Time-lapse microscopy of live cells at interphase revealed that EB1–GFP was concentrated at all of the growing microtubule ends throughout the cytoplasm and abruptly disappeared from the ends when microtubules began to shorten. Therefore, EB1 appeared to be co-localized and interact with APC on the growing ends of a subset of microtubules. When APC–GFP was overexpressed, endogenous EB1 was recruited to APC–GFP, which accumulated in large amounts on microtubules. On the other hand, when microtubules were disassembled by nocodazole, EB1 was not co-localized with APC–GFP, which was concentrated along the basal plasma membrane. During mitosis, APC appeared to be dissociated from microtubules, whereas EB1–GFP continued to concentrate at microtubule growing ends. These findings showed that the APC–EB1 interaction is regulated within cells and is allowed near the ends of microtubules only under restricted conditions

Reconstituting regulation of the canonical Wnt pathway by engineering a minimal β-catenin destruction machine

Negatively regulating key signaling pathways is critical to development and altered in cancer. Wnt signaling is kept off by the destruction complex, which is assembled around the tumor suppressors APC and Axin and targets β-catenin for destruction. Axin and APC are large proteins with many domains and motifs that bind other partners. We hypothesized that if we identified the essential regions required for APC:Axin cooperative function and used these data to design a minimal β-catenin-destruction machine, we would gain new insights into the core mechanisms of destruction complex function. We identified five key domains/motifs in APC or Axin that are essential for their function in reconstituting Wnt regulation. Strikingly, however, certain APC and Axin mutants that are nonfunctional on their own can complement one another in reducing β-catenin, revealing that the APC:Axin complex is a highly robust machine. We used these insights to design a minimal β-catenin-destruction machine, revealing that a minimized chimeric protein covalently linking the five essential regions of APC and Axin reconstitutes destruction complex internal structure, size, and dynamics, restoring efficient β-catenin destruction in colorectal tumor cells. On the basis of our data, we propose a new model of the mechanistic function of the destruction complex as an integrated machine

Laminin-based cell adhesion anchors microtubule plus ends to the epithelial cell basal cortex through LL5α/β

A newly discovered interaction between LL5s, laminins, and integrins reveals how the extracellular matrix directs microtubule polarity in epithelial tissues

CLASP1 and CLASP2 bind to EB1 and regulate microtubule plus-end dynamics at the cell cortex

CLIP-associating protein (CLASP) 1 and CLASP2 are mammalian microtubule (MT) plus-end binding proteins, which associate with CLIP-170 and CLIP-115. Using RNA interference in HeLa cells, we show that the two CLASPs play redundant roles in regulating the density, length distribution and stability of interphase MTs. In HeLa cells, both CLASPs concentrate on the distal MT ends in a narrow region at the cell margin. CLASPs stabilize MTs by promoting pauses and restricting MT growth and shortening episodes to this peripheral cell region. We demonstrate that the middle part of CLASPs binds directly to EB1 and to MTs. Furthermore, we show that the association of CLASP2 with the cell cortex is MT independent and relies on its COOH-terminal domain. Both EB1- and cortex-binding domains of CLASP are required to promote MT stability. We propose that CLASPs can mediate interactions between MT plus ends and the cell cortex and act as local rescue factors, possibly through forming a complex with EB1 at MT tips

Regulation of interkinetic nuclear migration by cell cycle-coupled active and passive mechanisms in the developing brain

In proliferating neural epithelia, cells undergo interkinetic nuclear migration: stereotyped cell cycle-dependent movements in the apico-basal plane. The microtubule-binding protein Tpx2 is here shown to regulate the G2-phase basal-to-apical migration, while passive displacement effects are responsible for basally directed movements