Cripto localizes Nodal at the limiting membrane of early endosomes.

Cripto is a glycosylphosphatidylinositol (GPI)-anchored co-receptor of Nodal and several other transforming growth factor-beta (TGF-beta) family ligands. It contains an epidermal growth factor (EGF)-like motif and a Cripto-FRL1-Cryptic (CFC) domain, which are conserved in a family of EGF-CFC proteins. The EGF domain is thought to recruit Nodal, whereas the CFC domain mediates binding to activin receptor-like kinase 4 (ALK4). We found that the EGF-like motif of Cripto was not essential for its binding to Nodal. However, through residues phenylalanine 78 and glycine 71, Cripto enriched Nodal at the limiting membrane of early endosomes. Similarly, residues in the CFC domain that mediate binding of Cripto to ALK4 were required to attenuate sequestration of Nodal in the endosomal lumen. Thus, we propose that Cripto stimulates Nodal activity by localizing it at the interface of endosomes with cytoplasmic effectors. To our knowledge, Cripto is the first GPI-anchored protein shown to control intraendosomal sorting of its associated cargo.

Cripto recruits Furin and PACE4 and controls Nodal trafficking during proteolytic maturation.

The glycosylphosphatidylinositol (GPI)-anchored proteoglycan Cripto binds Nodal and its type I receptor Alk4 to activate Smad2,3 transcription factors, but a role during Nodal precursor processing has not been described. We show that Cripto also binds the proprotein convertases Furin and PACE4 and localizes Nodal processing at the cell surface. When coexpressed as in early embryonic cells, Cripto and uncleaved Nodal already associated during secretion, and a Cripto-interacting region in the Nodal propeptide potentiated the effect of proteolytic maturation on Nodal signalling. Disruption of the trans-Golgi network (TGN) by brefeldin A blocked secretion, but export of Cripto and Nodal to the cell surface was not inhibited, indicating that Nodal is exposed to extracellular convertases before entering the TGN/endosomal system. Density fractionation and antibody uptake experiments showed that Cripto guides the Nodal precursor in detergent-resistant membranes to endocytic microdomains marked by GFP-Flotillin. We conclude that Nodal processing and endocytosis are coupled in signal-receiving cells.

Cripto promotes A-P axis specification independently of its stimulatory effect on Nodal autoinduction.

The EGF-CFC gene cripto governs anterior-posterior (A-P) axis specification in the vertebrate embryo. Existing models suggest that Cripto facilitates binding of Nodal to an ActRII-activin-like kinase (ALK) 4 receptor complex. Cripto also has a crucial function in cellular transformation that is independent of Nodal and ALK4. However, how ALK4-independent Cripto pathways function in vivo has remained unclear. We have generated cripto mutants carrying the amino acid substitution F78A, which blocks the Nodal-ALK4-Smad2 signaling both in embryonic stem cells and cell-based assays. In cripto(F78A/F78A) mouse embryos, Nodal fails to expand its own expression domain and that of cripto, indicating that F78 is essential in vivo to stimulate Smad-dependent Nodal autoinduction. In sharp contrast to cripto-null mutants, cripto(F78A/F78A) embryos establish an A-P axis and initiate gastrulation movements. Our findings provide in vivo evidence that Cripto is required in the Nodal-Smad2 pathway to activate an autoinductive feedback loop, whereas it can promote A-P axis formation and initiate gastrulation movements independently of its stimulatory effect on the canonical Nodal-ALK4-Smad2 signaling pathway.

Nodal stability determines signaling range.

Secreted TGFbeta proteins of the Nodal family pattern the vertebrate body axes and induce mesoderm and endoderm . Nodal proteins can act as morphogens , but the mechanisms regulating their activity and signaling range are poorly understood. In particular, it has been unclear how inefficient processing or rapid turnover of the Nodal protein influences autocrine and paracrine signaling properties . Here, we evaluate the role of Nodal processing and stability in tissue culture and zebrafish embryos. Removal of the pro domain potentiates autocrine signaling but reduces Nodal stability and signaling range. Insertion of an N-glycosylation site present in several related TGFbeta proteins increases the stability of mature Nodal. The stabilized form of Nodal acts at a longer range than the wild-type form. These results suggest that increased proteolytic maturation of Nodal potentiates autocrine signaling, whereas increased Nodal stability extends paracrine signaling.

Asymmetric Nodal expression in the mouse is governed by the combinatorial activities of two distinct regulatory elements.

In all vertebrates, invariant left/right (L/R) positioning and organization of the internal viscera is controlled by a conserved pathway. Nodal, a member of the TGFbeta superfamily is a critical upstream component responsible for initiating L/R axis determination. Asymmetric Nodal expression in the node preceeds and foreshadows morphological L/R asymmetry. Here we address the mechanism of Nodal activation in the left LPM by studying the function of a novel enhancer element, the AIE. We show this element is exclusively active in cells of the left lateral plate mesoderm (LPM) and is not itself responding to Nodal asymmetry. To test the hypothesis that this element may initiate asymmetric Nodal expression in the LPM, we deleted it from the mouse germ line. Mice homozygous for the AIE deletion (Nodal(deltaaie/deltaaie)) show no defects. However, we find that the AIE contributes to regulating the level of asymmetric Nodal activity; analysis of transheterozygous embryos (Nodal(deltaaie/null)) shows reduced Nodal expression in the left LPM associated with a low penetrance of L/R defects. Our findings point to the existence of two independent pathways that control Nodal expression in the left LPM.

Molecular mechanisms regulating protein kinase Czeta turnover and cellular transformation.

The regulation of protein kinase C (PKC)zeta in relation to its turnover, cell growth and transformation was investigated in Rat2 fibroblasts by over-expressing wild-type or mutant forms of PKCzeta. Deletion of the pseudosubstrate site (PSS) produced the most active mutant (PKCzeta Delta PSS), but mutants designed to mimic phosphorylated PKCzeta had lower specific activities in an in vitro assay. The mutant lacking phosphorylation at the Thr-560 site (T560A) had similar specific activity to wild-type PKCzeta. The T560A mutant also protected PKCzeta against proteolysis, whereas phosphorylation at Thr-410 targeted it towards proteosomal degradation. Blocking proteosomal degradation with lactacystin caused the accumulation of full-length PKCzeta Delta PSS, T410E, PKCzeta Delta PSS T410/560E, PKCzeta and T560A. Expressed PKCzeta activity was paralleled by extracellular-regulated protein kinase activation, increased cell division, serum-independent growth and focus formation. These foci were seen for cells expressing higher PKCzeta activity (PKCzeta Delta PSS, PKCzeta Delta PSS T410/560E and T560A mutants), but these fibroblasts did not show significant anchorage-independent growth. This work provides novel information concerning the role of the PSS and phosphorylation sites in regulating the activity and turnover of an atypical PKC and shows how this activity can induce cell transformation with respect to focus formation.

Extraembryonic proteases regulate Nodal signalling during gastrulation.

During gastrulation, a cascade of inductive tissue interactions converts pre-existing polarity in the mammalian embryo into antero-posterior pattern. This process is triggered by Nodal, a protein related to transforming growth factor-beta (TFG-beta) that is expressed in the epiblast and visceral endoderm, and its co-receptor Cripto, which is induced downstream of Nodal. Here we show that the proprotein convertases Spc1 and Spc4 (also known as Furin and Pace4, respectively) are expressed in adjacent extraembryonic ectoderm. They stimulate Nodal maturation after its secretion and are required in vivo for Nodal signalling. Embryo explants deprived of extraembryonic ectoderm phenocopy Spc1(-/-); Spc4(-/-) double mutants in that endogenous Nodal fails to induce Cripto. But recombinant mature Nodal, unlike uncleaved precursor, can efficiently rescue Cripto expression. Cripto is also expressed in explants treated with bone morphogenetic protein 4 (BMP4). This indicates that Nodal may induce Cripto through both a signalling pathway in the embryo and induction of Bmp4 in the extraembryonic ectoderm. A lack of Spc1 and Spc4 affects both pathways because these proteases also stimulate induction of Bmp4.