Paraxial protocadherin mediates cell sorting and tissue morphogenesis by regulating C-cadherin adhesion activity

Little is known about how protocadherins function in cell adhesion and tissue development. Paraxial protocadherin (PAPC) controls cell sorting and morphogenetic movements in the Xenopus laevis embryo. We find that PAPC mediates these functions by down-regulating the adhesion activity of C-cadherin. Expression of exogenous C-cadherin reverses PAPC-induced cell sorting and gastrulation defects. Moreover, loss of endogenous PAPC results in elevated C-cadherin adhesion activity in the dorsal mesoderm and interferes with the normal blastopore closure, a defect that can be rescued by a dominant-negative C-cadherin mutant. Importantly, activin induces PAPC expression, and PAPC is required for activin-induced regulation of C-cadherin adhesion activity and explant morphogenesis. Signaling through Frizzled-7 is not required for PAPC regulation of C-cadherin, suggesting that C-cadherin regulation and Frizzled-7 signaling are two distinct branches of the PAPC pathway that induce morphogenetic movements. Thus, spatial regulation of classical cadherin adhesive function by local expression of a protocadherin is a novel mechanism for controlling cell sorting and tissue morphogenesis.     

Xenopus paraxial protocadherin inhibits Wnt/β-catenin signalling via casein kinase 2β

Xenopus paraxial protocadherin (PAPC) regulates cadherin-mediated cell adhesion and promotes the planar cell polarity (PCP) pathway. Here we report that PAPC functions in the Xenopus gastrula as an inhibitor of the Wnt/β-catenin pathway. The intracellular domain of PAPC interacts with casein kinase 2 beta (CK2β), which is part of the CK2 holoenzyme. The CK2α/β complex stimulates Wnt/β-catenin signalling, and the physical interaction of CK2β with PAPC antagonizes this activity. By this mechanism, PAPC restricts the expression of Wnt target genes during gastrulation. These experiments identify a novel function of protocadherins as regulators of the Wnt pathway.     

ANR5, an FGF target gene product, regulates gastrulation in Xenopus

Gastrulation is a morphogenetic process in which tightly coordinated cell and tissue movements establish the three germ layers (ectoderm, mesoderm, and endoderm) to define the anterior-to-posterior embryonic organization [1]. To elicit this movement, cells modulate membrane protrusions and undergo dynamic cell interactions. Here we report that ankyrin repeats domain protein 5 (xANR5), a novel FGF target gene product, regulates cell-protrusion formation and tissue separation, a process that develops the boundary between the ectoderm and mesoderm [2, 3], during Xenopus gastrulation. Loss of xANR5 function by antisense morpholino oligonucleotide (MO) caused a short trunk and spina bifida without affecting mesodermal gene expressions. xANR5-MO also blocked elongation of activin-treated animal caps (ACs) and tissue separation. The dorsal cells of xANR5-MO-injected embryos exhibited markedly reduced membrane protrusions, which could be restored by coinjecting active Rho. Active Rho also rescued the xANR5-MO-inhibited tissue separation. We further demonstrated that xANR5 interacted physically and functionally with paraxial protocadherin (PAPC), which has known functions in cell-sorting behavior, tissue separation, and gastrulation cell movements [4-6], to regulate early morphogenesis. Our findings reveal for the first time that xANR5 acts through Rho to regulate gastrulation and is an important cytoplasmic partner of PAPC, whose cytoplasmic partner was previously unknown.     

Structural elements necessary for oligomerization, trafficking, and cell sorting function of paraxial protocadherin

Protocadherins have been shown to regulate cell adhesion, cell migration, cell survival, and tissue morphogenesis in the embryo and the central nervous system, but little is known about the mechanism of protocadherin function. We previously showed that Xenopus paraxial protocadherin (PAPC) mediates cell sorting and morphogenesis by down-regulating the adhesion activity of a classical cadherin, C-cadherin. Classical cadherins function by forming lateral dimers that are necessary for their adhesive function. However, it is not known whether oligomerization also plays a role in protocadherin function. We show here that PAPC forms oligomers that are stabilized by disulfide bonds formed between conserved Cys residues in the extracellular domain. Disruption of these disulfide bonds by dithiothreitol or mutation of the conserved cysteines results in defects in oligomerization, post-translational modification, trafficking to the cell surface and cell sorting function of PAPC. Furthermore, none of the residues in the cytoplasmic domain of PAPC is required for its cell sorting activity, whereas both the transmembrane domain and the extracellular domain are necessary. Therefore, protein oligomerization and/or protein interactions via the extracellular and transmembrane domains of PAPC are required for its cell sorting function.     

The protocadherin PAPC establishes segmental boundaries during somitogenesis in xenopus embryos

BACKGROUND: One prominent example of segmentation in vertebrate embryos is the subdivision of the paraxial mesoderm into repeating, metameric structures called somites. During this process, cells in the presomitic mesoderm (PSM) are first patterned into segments leading secondarily to differences required for somite morphogenesis such as the formation of segmental boundaries. Recent studies have shown that a segmental pattern is generated in the PSM of Xenopus embryos by genes encoding a Mesp-like bHLH protein called Thylacine 1 and components of the Notch signaling pathway. These genes establish a repeating pattern of gene expression that subdivides cells in the PSM into anterior and posterior half segments, but how this pattern of gene expression leads to segmental boundaries is unknown. Recently, a member of the protocadherin family of cell adhesion molecules, called PAPC, has been shown to be expressed in the PSM of Xenopus embryos in a half segment pattern, suggesting that it could play a role in restricting cell mixing at the anterior segmental boundary. RESULTS: Here, we examine the expression and function of PAPC during segmentation of the paraxial mesoderm in Xenopus embryos. We show that Thylacine 1 and the Notch pathway establish segment identity one segment prior to the segmental expression of PAPC. Altering segmental identity in embryos by perturbing the activity of Thylacine 1 and the Notch pathway, or by treatment with a protein synthesis inhibitor, cycloheximide, leads to the predicted changes in the segmental expression of PAPC. By disrupting PAPC function in embryos using a putative dominant-negative or an activated form of PAPC, we show that segmental PAPC activity is required for proper somite formation as well as for maintaining segmental gene expression within the PSM. CONCLUSIONS: Segmental expression of PAPC is established in the PSM as a downstream consequence of segmental patterning by Thylacine 1 and the Notch pathway. We propose that PAPC is part of the mechanism that establishes the segmental boundaries between posterior and anterior cells in adjacent segments.     

Wnt-11 and Fz7 reduce cell adhesion in convergent extension by sequestration of PAPC and C-cadherin

Wnt-11/planar cell polarity signaling polarizes mesodermal cells undergoing convergent extension during Xenopus laevis gastrulation. These shape changes associated with lateral intercalation behavior require a dynamic modulation of cell adhesion. In this paper, we report that Wnt-11/frizzled-7 (Fz7) controls cell adhesion by forming separate adhesion-modulating complexes (AMCs) with the paraxial protocadherin (PAPC; denoted as AMCP) and C-cadherin (denoted as AMCC) via distinct Fz7 interaction domains. When PAPC was part of a Wnt-11-Fz7 complex, its Dynamin1- and clathrin-dependent internalization was blocked. This membrane stabilization of AMCP (Fz7/PAPC) by Wnt-11 prevented C-cadherin clustering, resulting in reduced cell adhesion and modified cell sorting activity. Importantly, Wnt-11 did not influence C-cadherin internalization; instead, it promoted the formation of AMCC (Fz7/Cadherin), which competed with cis-dimerization of C-cadherin. Because PAPC and C-cadherin did not directly interact and did not form a joint complex with Fz7, we suggest that Wnt-11 triggers the formation of two distinct complexes, AMCC and AMCP, that act in parallel to reduce cell adhesion by hampering lateral clustering of C-cadherin.     

A Protocadherin-Cadherin-FLRT3 Complex Controls Cell Adhesion and Morphogenesis

Background

Paraxial protocadherin (PAPC) and fibronectin leucine-rich domain transmembrane protein-3 (FLRT3) are induced by TGFβ signaling in Xenopus embryos and both regulate morphogenesis by inhibiting C-cadherin mediated cell adhesion.

Principal Findings

We have investigated the functional and physical relationships between PAPC, FLRT3, and C-cadherin. Although neither PAPC nor FLRT3 are required for each other to regulate C-cadherin adhesion, they do interact functionally and physically, and they form a complex with cadherins. By itself PAPC reduces cell adhesion physiologically to induce cell sorting, while FLRT3 disrupts adhesion excessively to cause cell dissociation. However, when expressed together PAPC limits the cell dissociating and tissue disrupting activity of FLRT3 to make it effective in physiological cell sorting. PAPC counteracts FLRT3 function by inhibiting the recruitment of the GTPase RND1 to the FLRT3 cytoplasmic domain.

Conclusions/Significance

PAPC and FLRT3 form a functional complex with cadherins and PAPC functions as a molecular “governor” to maintain FLRT3 activity at the optimal level for physiological regulation of C-cadherin adhesion, cell sorting, and morphogenesis.     

Regulation of Xenopus embryonic cell adhesion by the small GTPase,rac

TGF-beta family signalling pathways are important for germ layer formation and gastrulation in vertebrate embryos and have been studied extensively using embryos of Xenopus laevis. Activin causes changes in cell movements and cell adhesion in Xenopus animal caps and dispersed animal cap cells. Rho family GTPases, including rac, mediate growth factor-induced changes in the actin cytoskeleton, and consequently, in cell adhesion and motility, in a number of different cell types. Ectopic expression of mutant rac isoforms in Xenopus embryos was combined with animal cap adhesion assays and a biochemical assay for rac activity to investigate the role of rac in activin-induced changes in cell adhesion. The results indicate that (1) the perturbation of rac signalling disrupts embryonic cell-cell adhesion, (2) that rac activity is required for activin-induced changes in cell adhesive behavior on fibronectin, and (3) that activin increases endogenous rac activity in animal cap explants.     

Distinct functions of Rho and Rac are required for convergent extension during Xenopus gastrulation

We have undertaken the first detailed analysis of Rho GTPase function during vertebrate development by analyzing how RhoA and Rac1 control convergent extension of axial mesoderm during Xenopus gastrulation. Monitoring of a number of parameters in time-lapse recordings of mesoderm explants revealed that Rac and Rho have both distinct and overlapping roles in regulating the motility of axial mesoderm cells. The cell behaviors revealed by activated or inhibitory versions of these GTPases in native tissue were clearly distinct from those previously documented in cultured fibroblasts. The dynamic properties and polarity of protrusive activity, along with lamellipodia formation, were controlled by the two GTPases operating in a partially redundant manner, while Rho and Rac contributed separately to cell shape and filopodia formation. We propose that Rho and Rac operate in distinct signaling pathways that are integrated to control cell motility during convergent extension.     

The role of Paraxial Protocadherin in Xenopus otic placode development

Vertebrate inner ear develops from its rudiment, otic placode, which later forms otic vesicle and gives rise to tissues comprising the entire inner ear. Although several signaling molecules have been identified as candidates responsible for inner ear specification and patterning, many details remain elusive. Here, we report that Paraxial Protocadherin (PAPC) is required for otic vesicle formation in Xenopus embryos. PAPC is expressed strictly in presumptive otic placode and later in otic vesicle during inner ear morphogenesis. Knockdown of PAPC by dominant-negative PAPC results in the failure of otic vesicle formation and the loss of early inner ear markers Sox9 and Tbx2, suggesting the requirement of PAPC in the early stage of otic vesicle development. However, PAPC alone is not sufficient to induce otic placode formation.     

Mouse paraxial protocadherin is expressed in trunk mesoderm and is not essential for mouse development

Paraxial protocadherin (PAPC) is a cell adhesion molecule that marks cells undergoing convergence-extension cell movements in Xenopus and zebrafish gastrulating embryos. Here a mouse homologue (mpapc) was identified and characterized. During early- to mid-gastrulation, mpapc is expressed in the primitive streak as the trunk mesoderm undergoes morphogenetic cell movements. At head-fold stage mpapc expression becomes localized to paraxial regions in which somites are formed in the segmental plate. At later stages, mpapc displays a complex expression pattern in cerebral cortex, olfactory bulb, inferior colliculus, and in longitudinal stripes in hindbrain. To analyze the effect of the loss of PAPC function during mouse development, a null allele of the mouse papc gene was generated. Homozygous animals show no defects in their skeleton and are viable and fertile.     

EphA4 catalytic activity causes inhibition of RhoA GTPase in Xenopus laevis embryos

The Eph family of receptor tyrosine kinases is involved in limiting cell and tissue interactions via a repulsive mechanism. The mechanism of repulsion involves reorganizing the actin cytoskeleton, but little is known of the molecular components that connect the receptor to the actin cytoskeleton. Recent studies in retinal ganglion cells have demonstrated that EphA4 activates the small GTPase Rho. We have investigated the involvement of Rho in signaling downstream from EphA4. As a model system, we have used a chimeric receptor called EPP that we express and activate in early Xenopus embryos. Previous studies demonstrated that EPP activation leads to loss of cell-cell adhesion and change in cell shape, plus loss of aspects of cell polarity in epithelial cells, such as apical microvilli and the apical/basolateral boundary. In this study, we show that injecting inhibitors of Rho GTPases into early Xenopus embryos produces a phenotype very similar to that resulting from EPP activation. More importantly, expression of a constitutively active form of Xenopus RhoA (XRhoA) concurrent with activated EPP rescued embryos from the loss of cell-cell adhesion and change in cell shape associated with EPP. These data argue that, in contrast to the case in retinal ganglion cells, EphA4 in early Xenopus embryos acts to inhibit RhoA, suggesting that this receptor may regulate Rho differently (and therefore affect the cytoskeleton differently) in neuronal and non-neuronal cells. Furthermore, overexpression of ephexin, a novel guanine nucleotide exchange factor for Rho family GTPases, also blocks EPP-induced dissociation. This suggests that EphA4, which has been demonstrated to activate ephexin in cultured neuronal cells, may also target Rho GTPase via an ephexin-independent pathway.     

PKB mediates c-erbB2-induced epithelial beta1 integrin conformational inactivation through Rho-independent F-actin rearrangements

Signalling from the growth factor receptor subunit and proto-oncogene c-erbB2 has been shown to inhibit the adhesive function of the collagen receptor integrin alpha(2)beta(1) in human mammary epithelial cells. This anti-adhesive effect is mediated by the MAP ERK kinase 1/2 (MEK1/2) and protein kinase B (PKB) pathways. Here, we show that both pathways mediate suppression of matrix adhesion by causing the extracellular domain of the beta(1) integrin subunit to adopt an inactive conformation. The conformational switch was also dependent on rapid and extensive actin depolymerisation. While neither activation nor inhibition of the Rho GTPase affected this rearrangement, Rho was found to be activated by c-erbB2 and to be necessary for conformation-dependent integrin inactivation and, apparently by a different mechanism, a delayed re-formation of stress fibers which did not restore integrin function. Interestingly, the initial actin depolymerisation as well as its effects on integrin function was shown to be mediated by PKB. These results demonstrate how oncogenic growth factor signalling inhibits matrix adhesion by multiple pathways converging on integrin conformation and how Rho signalling can profoundly influence integrin activation in a cytoskeleton-independent manner.     

非洲爪蟾PAPC多克隆抗体的制备及其特异性鉴定

非洲爪蟾ParaxialProtocadherin(PAPC)是一个在爪蟾Spemann组织者特异表达的膜蛋白.它在爪蟾原肠运动阶段的汇聚延伸运动和体节发生阶段的体节边界形成,以及早期听泡的形态发生和细胞特化过程中都有重要的作用.为了研究PAPC基因在早期胚胎发育过程中的表达及其生物学功能,需要制备PAPC抗体.应用谷胱甘肽S-转移酶(glutathioneStransferase,GST)表达系统表达GST-PAPC融合蛋白,亲和纯化后用以免疫新西兰大白兔,获得PAPC多克隆抗体.免疫印迹分析发现,以1∶3000稀释的该多克隆抗体为一抗时,能够在转染了全长PAPC质粒的HEK293T细胞的蛋白质抽提物中,特异地识别出150ku的印迹条带.同时,GST-PAPC融合蛋白可以竞争性抑制该抗体对全长PAPC质粒转染细胞的蛋白质抽提物的特异性条带.用1∶500稀释的该抗体为一抗进行免疫荧光分析时,发现,PAPC多克隆抗体能够识别在HEK293T细胞中过表达以及爪蟾动物极细胞中过表达的PAPC蛋白,荧光信号定位在细胞膜上.免疫印迹分析证明,PAPC抗体能够识别爪蟾胚胎中内源表达的PAPC蛋白.