Lipid Rafts Are Physiologic Membrane Microdomains Necessary for the Morphogenic and Developmental Functions of Glial Cell Line-Derived Neurotrophic Factor In Vivo.

Glial cell line-derived neurotrophic factor (GDNF) promotes PNS development and kidney morphogenesis via a receptor complex consisting of the glycerophosphatidylinositol (GPI)-anchored, ligand binding receptor GDNF family receptor α1 (GFRα1) and the receptor tyrosine kinase Ret. Although Ret signal transduction in vitro is augmented by translocation into lipid rafts via GFRα1, the existence and importance of lipid rafts in GDNF-Ret signaling under physiologic conditions is unresolved. A knock-in mouse was produced that replaced GFRα1 with GFRα1-TM, which contains a transmembrane (TM) domain instead of the GPI anchor. GFRα1-TM still binds GDNF and promotes Ret activation but does not translocate into rafts. In Gfrα1(TM/TM) mice, GFRα1-TM is expressed, trafficked, and processed at levels identical to GFRα1. Although Gfrα1(+/TM) mice are viable, Gfrα1(TM/TM) mice display bilateral renal agenesis, lack enteric neurons in the intestines, and have motor axon guidance deficits, similar to Gfrα1(-/-) mice. Therefore, the recruitment of Ret into lipid rafts by GFRα1 is required for the physiologic functions of GDNF in vertebrates. Significance statement: Membrane microdomains known as lipid rafts have been proposed to be unique subdomains in the plasma membrane that are critical for the signaling functions of multiple receptor complexes. Their existence and physiologic relevance has been debated. Based on in vitro studies, lipid rafts have been reported to be necessary for the function of the Glial cell line-derived neurotrophic factor (GDNF) family of neurotrophic factors. The receptor for GDNF comprises the lipid raft-resident, glycerophosphatidylinositol-anchored receptor GDNF family receptor α1 (GFRα1) and the receptor tyrosine kinase Ret. Here we demonstrate, using a knock-in mouse model in which GFRα1 is no longer located in lipid rafts, that the developmental functions of GDNF in the periphery require the translocation of the GDNF receptor complex into lipid rafts.

Ret is critical for podocyte survival following glomerular injury in vivo.

Podocyte injury and loss directly cause proteinuria and the progression to glomerulosclerosis. Elucidation of the mechanisms of podocyte survival and recovery from injury is critical for designing strategies to prevent the progression of glomerular diseases. Glial cell line-derived neurotrophic factor (GDNF) and its receptor tyrosine kinase, Ret, are upregulated in both nonimmune and immune-mediated in vitro and in vivo models of glomerular diseases. We investigated whether Ret, a known receptor tyrosine kinase critical for kidney morphogenesis and neuronal growth and development, is necessary for glomerular and podocyte development and survival in vivo. Since deletions of both GDNF and Ret result in embryonic lethality due to kidney agenesis, we examined the role of Ret in vivo by generating mice with a conditional deletion of Ret in podocytes (Ret(flox/flox); Nphs2-Cre). In contrast to the lack of any developmental and maintenance deficits, Ret(flox/flox); Nphs2-Cre mice showed a significantly enhanced susceptibility to adriamycin nephropathy, a rodent model of focal segmental glomerulosclerosis. Thus, these findings demonstrated that the Ret signaling pathway is important for podocyte survival and recovery from glomerular injury in vivo.

CD2-associated protein (CD2AP) enhances casitas B lineage lymphoma-3/c (Cbl-3/c)-mediated Ret isoform-specific ubiquitination and degradation via its amino-terminal Src homology 3 domains.

Ret is the receptor tyrosine kinase for the glial cell line-derived neurotrophic factor (GDNF) family of neuronal growth factors. Upon activation by GDNF, Ret is rapidly polyubiquitinated and degraded. This degradation process is isoform-selective, with the longer Ret51 isoform exhibiting different degradation kinetics than the shorter isoform, Ret9. In sympathetic neurons, Ret degradation is induced, at least in part, by a complex consisting of the adaptor protein CD2AP and the E3-ligase Cbl-3/c. Knockdown of Cbl-3/c using siRNA reduced the GDNF-induced ubiquitination and degradation of Ret51 in neurons and podocytes, suggesting that Cbl-3/c was a predominant E3 ligase for Ret. Coexpression of CD2AP with Cbl-3/c augmented the ubiquitination of Ret51 as compared with the expression of Cbl-3/c alone. Ret51 ubiquitination by the CD2AP·Cbl-3/c complex required a functional ring finger and TKB domain in Cbl-3/c. The SH3 domains of CD2AP were sufficient to drive the Cbl-3/c-dependent ubiquitination of Ret51, whereas the carboxyl-terminal coiled-coil domain of CD2AP was dispensable. Interestingly, activated Ret induced the degradation of CD2AP, but not Cbl-3/c, suggesting a potential inhibitory feedback mechanism. There were only two major ubiquitination sites in Ret51, Lys(1060) and Lys(1107), and the combined mutation of these lysines almost completely eliminated both the ubiquitination and degradation of Ret51. Ret9 was not ubiquitinated by the CD2AP·Cbl-3/c complex, suggesting that Ret9 was down-regulated by a fundamentally different mechanism. Taken together, these results suggest that only the SH3 domains of CD2AP were necessary to enhance the E3 ligase activity of Cbl-3/c toward Ret51.

Proteomic analysis of the slit diaphragm complex: CLIC5 is a protein critical for podocyte morphology and function.

Podocytes are morphologically complex cells, the junctions of which form critical elements of the final filtration barrier. Disruption of their foot processes and slit diaphragms occur early in the development of many glomerular diseases. Here, we biochemically purified fractions enriched with slit diaphragm proteins and performed a proteomic analysis to identify new components of this important structure. Several known slit diaphragm proteins were found, such as podocin and nephrin, confirming the validity of the purification scheme. However, proteins on the apical membrane such as podocalyxin were neither enriched nor identified in our analysis. The chloride intracellular channel protein 5 (CLIC5), predominantly expressed in podocytes, was enriched in these fractions and localized in the foot process apical and basal membranes. CLIC5 colocalized and associated with the ezrin/radixin/moesin complex and with podocalyxin in podocytes in vivo. It is important to note that CLIC5(-/-) mice were found to have significantly decreased foot process length, widespread foot process abnormalities, and developed proteinuria. The ezrin/radixin/moesin complex and podocalyxin were significantly decreased in podocytes from CLIC5(-/-) mice. Thus, our study identifies CLIC5 as a new component that is enriched in and necessary for foot process integrity and podocyte function in vivo.

The differential axonal degradation of Ret accounts for cell-type-specific function of glial cell line-derived neurotrophic factor as a retrograde survival factor.

Glial cell line-derived neurotrophic factor (GDNF) is a neuronal growth factor critical for the development and maintenance of central and peripheral neurons. GDNF is expressed in targets of innervation and provides support to several populations of large, projection neurons. To determine whether GDNF promotes retrograde survival over long axonal distances to cell bodies, we used a compartmentalized culture system. GDNF supported only modest and transient survival of postnatal sympathetic neurons when applied to their distal axons, in contrast to dorsal root ganglion (DRG) sensory neurons in which GDNF promoted survival equally well from either distal axons or cell bodies. Ret, the receptor tyrosine kinase for GDNF, underwent rapid proteasomal degradation in the axons of sympathetic neurons. Interestingly, the level of activated Ret in DRG neurons was sustained in the axons and also appeared in the cell bodies, suggesting that Ret was not degraded in sensory axons and was retrogradely transported. Pharmacologic inhibition of proteasomes only in the distal axons of sympathetic neurons caused an accumulation of activated Ret in both the axons and cell bodies during GDNF stimulation. Furthermore, exposure of the distal axons of sympathetic neurons to both GDNF and proteasome inhibitors, but neither one alone, promoted robust survival, identical to GDNF applied directly to the cell bodies. This differential responsiveness of sympathetic and sensory neurons to target-derived GDNF was attributable to the differential expression and degradation of the Ret9 and Ret51 isoforms. Therefore, the local degradation of Ret in axons dictates whether GDNF family ligands act as retrograde survival factors.

CD2AP and Cbl-3/Cbl-c constitute a critical checkpoint in the regulation of ret signal transduction.

The glial cell line-derived neurotrophic factor (GDNF) family ligands (GFLs) are critical for nervous system development and maintenance. GFLs promote survival and growth via activation of the receptor tyrosine kinase (RTK) Ret. In sympathetic neurons, the duration of Ret signaling is governed by how rapidly Ret is degraded after its activation. In an effort to elucidate mechanisms that control the half-life of Ret, we have identified two novel Ret interactors, CD2-associated protein (CD2AP) and Cbl-3. CD2AP, an adaptor molecule involved in the internalization of ubiquitinated RTKs, is associated with Ret under basal, unstimulated conditions in neurons. After Ret activation by GDNF, CD2AP dissociates. Similarly, the E3-ligase Cbl-3 interacts with unphosphorylated Ret and dissociates from Ret after Ret activation. In contrast to their dissociation from autophosphorylated Ret, an interaction between CD2AP and Cbl-3 is induced by GDNF stimulation of sympathetic neurons, suggesting that CD2AP and Cbl-3 dissociate from Ret as a complex. In neurons, the overexpression of CD2AP enhances the degradation of Ret and inhibits GDNF-dependent survival, and gene silencing of CD2AP blocks Ret degradation and promotes GDNF-mediated survival. Surprisingly, Cbl-3 overexpression dramatically stabilizes activated Ret and enhances neuronal survival, even though Cbl-family E3 ligases normally function to trigger RTK downregulation. In combination with CD2AP, however, Cbl-3 promotes Ret degradation rapidly and almost completely blocks survival promotion by GDNF, suggesting that Cbl-3 acts as a switch that is triggered by CD2AP and oscillates between inhibition and promotion of Ret degradation. Consistent with the hypothesis, Cbl-3 silencing in neurons only inhibited Ret degradation and enhanced neuronal survival in combination with CD2AP silencing. CD2AP and Cbl-3, therefore, constitute a checkpoint that controls the extent of Ret downregulation and, thereby, the sensitivity of neurons to GFLs.

NGF augments the autophosphorylation of Ret via inhibition of ubiquitin-dependent degradation.

Nerve growth factor (NGF) is required for the trophic maintenance of postnatal sympathetic neurons. A significant portion of the growth-promoting activity of NGF is from NGF-dependent phosphorylation of the heterologous receptor tyrosine kinase, Ret. We found that NGF applied selectively to distal axons of sympathetic neurons maintained in compartmentalized cultures activated Ret located in these distal axons. Inhibition of either proteasomal or lysosomal degradation pathways mimicked the effect of NGF on Ret activation. Likewise, NGF inhibited the degradation of Ret induced by glial cell line-derived neurotrophic factor-dependent activation, a process that requires ubiquitination and proteasomal degradation. NGF induced the accumulation of autophosphorylated Ret predominantly in the plasma membrane, in contrast to GDNF, which promoted the internalization of activated Ret. An accretion of monoubiquitinated, but not polyubiquitinated, Ret occurred in NGF-treated neurons, in contrast to glial cell line-derived neurotrophic factor that promoted the robust polyubiquitination of Ret. Thus, NGF stimulates Ret activity in mature sympathetic neurons by inhibiting the ongoing ubiquitin-mediated degradation of Ret before its internalization and polyubiquitination.

Glial cell line-derived neurotrophic factor and its receptor ret is a novel ligand-receptor complex critical for survival response during podocyte injury.

Glomerulosclerosis correlates with a reduction in podocyte number that occurs through mechanisms that include apoptosis. Whether glial cell line-derived neurotrophic factor (GDNF), a growth factor that is critical for neural and renal development, is a survival factor for injured podocytes was investigated. Ret, the GDNF receptor tyrosine kinase, was upregulated in podocytes in the passive Heymann nephritis and puromycin aminonucleoside (PA) nephrosis rat models of podocyte injury. In addition, Ret mRNA and protein were upregulated in mouse podocytes in vitro after injury that was induced by sublytic C5b-9 and PA. GDNF, which also was induced during podocyte injury, inhibited significantly the apoptosis of podocytes that was induced by ultraviolet C irradiation. Knockdown of Ret expression by small interference RNA in podocytes exacerbated apoptosis that was induced by both ultraviolet C and PA. Ret knockdown, upon injury, decreased AKT phosphorylation, suggesting that the phosphoinositol-3 kinase/AKT pathway mediated the survival effect of GDNF on podocytes. Consistent with this hypothesis, the selective phosphoinositol-3 kinase inhibitor LY294002 blocked the survival-promoting effects of GDNF. In conclusion, GDNF is a novel podocyte survival factor. Furthermore, Ret is highly upregulated during podocyte injury in vitro and in vivo, suggesting that Ret activation is a critical adaptive response for podocyte remodeling and repair.