Rac1 Activation Controls Nuclear Localization of β-catenin during Canonical Wnt Signaling

Wu, Ximei; Tu, Xiaolin; Joeng, Kyu Sang; Hilton, Matthew J.; Williams, David A.; Long, Fanxin

doi:10.1016/j.cell.2008.01.052

Cited by 439 publications

(462 citation statements)

References 63 publications

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“…Similar observations could be achieved when the Ishikawa cells were transfected with a dominant negative Rac1 (N17Rac1) 26 (Figure 5f). Because Rac1 is a known target of Wnt5a signaling 35,36 that has been shown to be essential for cell polarity induction and epithelial function in various organs including the uterus, 9,11,37 we also analyzed the consequence of Rac1 deficiency on uterine Wnt5a expression.…”

Section: Resultssupporting

confidence: 81%

“…Because the systemic Rac1 null mice are embryonic lethal owing to gastrulation defects, 24 to analyze the pathophysiological significance of Rac1 in early pregnancy events, we next used a progesterone receptor (Pgr)-driven Cre (Pgr cre/+ ) mouse model crossed with Rac1 floxed (Rac1 f/f ) mice to achieve uterine-selective deletion of Rac1. [25][26][27] As shown in To ascertain the stage-specific causes accounting for this obvious infertility, we subsequently analyzed the implantation status in mice missing uterine Rac1. Although all Rac1 f/f mice tested showed normal embryo implantation on day 5 morning (Figure 2j).…”

Section: Resultsmentioning

confidence: 99%

“…Rac1 f/f mice were generated as previously described. 26,27 Uterine-specific mutant mice were generated by crossing Rac1 f/f mice with Pgr Cre/+ mice. 25 All mice were housed in the animal care facility of the Institute of Zoology, Chinese Academy of Sciences, according to the institutional guidelines for the care and use of laboratory animals.…”

Section: Discussionmentioning

confidence: 99%

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Uterine RAC1 via Pak1-ERM signaling directs normal luminal epithelial integrity conducive to on-time embryo implantation in mice

Wang

Cui

et al. 2015

Cell Death Differ

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Successful embryo implantation requires functional luminal epithelia to establish uterine receptivity and blastocyst-uterine adhesion. During the configuration of uterine receptivity from prereceptive phase, the luminal epithelium undergoes dynamic membrane reorganization and depolarization. This timely regulated epithelial membrane maturation and precisely maintained epithelial integrity are critical for embryo implantation in both humans and mice. However, it remained largely unexplored with respect to potential signaling cascades governing this functional epithelial transformation prior to implantation. Using multiple genetic and cellular approaches combined with uterine conditional Rac1 deletion mouse model, we demonstrated herein that Rac1, a small GTPase, is spatiotemporally expressed in the periimplantation uterus, and uterine depletion of Rac1 induces premature decrease of epithelial apical-basal polarity and defective junction remodeling, leading to disrupted uterine receptivity and implantation failure. Further investigations identified Pak1-ERM as a downstream signaling cascade upon Rac1 activation in the luminal epithelium necessary for uterine receptivity. In addition, we also demonstrated that Rac1 via P38 MAPK signaling ensures timely epithelial apoptotic death at postimplantation. Besides uncovering a potentially important molecule machinery governing uterine luminal integrity for embryo implantation, our finding has high clinical relevance, because Rac1 is essential for normal endometrial functions in women. The implantation of the blastocyst into the maternal uterus is a crucial step in establishing pregnancy and thus ensuring further embryonic development. 1-3 Similar to many developmental processes, implantation involves an intricate succession of molecular and cellular interactions which must be executed within an optimal time frame. During this period, the acquisition of blastocyst implantation competency is synchronized with the establishment of uterine receptivity. [4][5][6] On the basis of previous findings, uterine sensitivity to implantationcompetent blastocysts is classically divided into three stages: pre-receptive, receptive and refractory phases. 7 In mice, prior to day 4 of pregnancy, the uterus is conventionally considered as the pre-receptive phase. On day 4 and beyond, the uterus becomes fully receptive following the priming actions of ovarian progesterone and preimplantation estrogen; whereas by late day 5, the uterus becomes refractory to initiate the implantation. 2,4,8 Upon entering the receptive phase, uterine luminal epithelium undergoes dynamic transformation. For example, on day 4 morning in mice, luminal epithelial cells cease proliferation under the dominance of increasing levels of ovarian progesterone and preimplantation estrogen. Meanwhile, the epithelial cells undergo differentiation, accompanied with a dynamic junction complex remodeling and membrane maturation, leading to a decrease of epithelial polarity approaching implantation and a cell-shape transition from...

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Section: Resultssupporting

confidence: 81%

Section: Resultsmentioning

confidence: 99%

Section: Discussionmentioning

confidence: 99%

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Uterine RAC1 via Pak1-ERM signaling directs normal luminal epithelial integrity conducive to on-time embryo implantation in mice

Wang

Cui

et al. 2015

Cell Death Differ

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“…The results indicated that total b-catenin level was clearly reduced (Figures 5a and b). In comparison with the PAK1-knockdown cells, nuclear b-catenin staining was further reduced in Rac1-knockdown cells (compare Figures 5a and 2c) and this is consistent with the previous report that Rac1/JNK2 controls b-catenin nuclear localization (Wu et al, 2008;Phelps et al, 2009). In addition, NSC23766, a Rac1 inhibitor, was also able to reduce total b-catenin in SW480 cells (Figures 5c and d).…”

Section: Rac1 Controls B-catenin Level and Phosphorylation Through Pak1supporting

confidence: 92%

“…However, it was argued recently that APC mutation alone probably is not sufficient to promote full b-catenin signaling (Anderson et al, 2002;Phelps et al, 2009). Mutation of K-Ras was often observed in more advanced colon cancer samples and it was suggested that a K-Ras/Rac1/ JNK2 cascade may further enhance b-catenin nuclear accumulation by JNK2-mediated phosphorylation of b-catenin at Ser191 and Ser605 (Wu et al, 2008;Phelps et al, 2009). However, Rac1 was also found being able to elevate cytosolic, as well as nuclear levels of b-catenin (Esufali and Bapat, 2004).…”

Section: Introductionmentioning

confidence: 99%

A Rac1/PAK1 cascade controls β-catenin activation in colon cancer cells

et al. 2011

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P21-activated kinase 1 (PAK1) is associated with colon cancer progression and metastasis, whereas the molecular mechanism remains elusive. Here, we show that downregulation of PAK1 in colon cancer cells reduces total b-catenin level, as well as cell proliferation. Mechanistically, PAK1 directly phosphorylates b-catenin proteins at Ser675 site and this leads to more stable and transcriptional active b-catenin. Corroborating these results, PAK1 is required for full Wnt signaling, and superactivation of b-catenin is achieved by simultaneous knockdown of adenomatous polyposis coli protein and activation of PAK1. Moreover, we show that Rac1 functions upstream of PAK1 in colon cancer cells and contributes to b-catenin phosphorylation and accumulation. We conclude that a Rac1/PAK1 cascade controls b-catenin S675 phosphorylation and full activation in colon cancer cells. Supporting this conclusion, overexpression of PAK1 is observed in 70% of colon cancer samples and is correlated with massive b-catenin accumulation.

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CK1ε and p120‐catenin control Ror2 function in noncanonical Wnt signaling

et al. 2018

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Canonical and noncanonical Wnt pathways share some common elements but differ in the responses they evoke. Similar to Wnt ligands acting through the canonical pathway, Wnts that activate the noncanonical signaling, such as Wnt5a, promote Disheveled (Dvl) phosphorylation and its binding to the Frizzled (Fz) Wnt receptor complex. The protein kinase CK1ε is required for Dvl/Fz association in both canonical and noncanonical signaling. Here we show that differently to its binding to canonical Wnt receptor complex, CK1ε does not require p120‐catenin for the association with the Wnt5a co‐receptor Ror2. Wnt5a promotes the formation of the Ror2–Fz complex and enables the activation of Ror2‐bound CK1ε by Fz‐associated protein phosphatase 2A. Moreover, CK1ε also regulates Ror2 protein levels; CK1ε association stabilizes Ror2, which undergoes lysosomal‐dependent degradation in the absence of this kinase. Although p120‐catenin is not required for CK1ε association with Ror2, it also participates in this signaling pathway as p120‐catenin binds and maintains Ror2 at the plasma membrane; in p120‐depleted cells, Ror2 is rapidly internalized through a clathrin‐dependent mechanism. Accordingly, downregulation of p120‐catenin or CK1ε affects late responses to Wnt5a that are also sensitive to Ror2, such as SIAH2 transcription, cell invasion, or cortical actin polarization. Our results explain how CK1ε is activated by noncanonical Wnt and identify p120‐catenin and CK1ε as two critical factors controlling Ror2 function.

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Rac1 Activation Controls Nuclear Localization of β-catenin during Canonical Wnt Signaling

Cited by 439 publications

References 63 publications

Uterine RAC1 via Pak1-ERM signaling directs normal luminal epithelial integrity conducive to on-time embryo implantation in mice

Uterine RAC1 via Pak1-ERM signaling directs normal luminal epithelial integrity conducive to on-time embryo implantation in mice

A Rac1/PAK1 cascade controls β-catenin activation in colon cancer cells

CK1ε and p120‐catenin control Ror2 function in noncanonical Wnt signaling

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