Johannes Nimpf

Reeler/Disabled-like Disruption of Neuronal Migration in Knockout Mice Lacking the VLDL Receptor and ApoE Receptor 2

Layering of neurons in the cerebral cortex and cerebellum requires Reelin, an extracellular matrix protein, and mammalian Disabled (mDab1), a cytosolic protein that activates tyrosine kinases. Here, we report the requirement for two other proteins, cell surface receptors termed very low density lipoprotein receptor (VLDLR) and apolipoprotein E receptor 2 (ApoER2). Both receptors can bind mDab1 on their cytoplasmic tails and are expressed in cortical and cerebellar layers adjacent to layers that express Reelin. mDab1 expression is upregulated in knockout mice that lack both VLDLR and ApoER2. Inversion of cortical layers and absence of cerebellar foliation in these animals precisely mimic the phenotype of mice lacking Reelin or mDab1. These findings suggest that VLDLR and ApoER2 participate in transmitting the extracellular Reelin signal to intracellular signaling processes initiated by mDab1.

Interactions of the Low Density Lipoprotein Receptor Gene Family with Cytosolic Adaptor and Scaffold Proteins Suggest Diverse Biological Functions in Cellular Communication and Signal Transduction

The members of the low density lipoprotein (LDL) receptor gene family bind a broad spectrum of extracellular ligands. Traditionally, they had been regarded as mere cargo receptors that promote the endocytosis and lysosomal delivery of these ligands. However, recent genetic experiments in mice have revealed critical functions for two LDL receptor family members, the very low density lipoprotein receptor and the apoE receptor-2, in the transmission of extracellular signals and the activation of intracellular tyrosine kinases. This process regulates neuronal migration and is crucial for brain development. Signaling through these receptors requires the interaction of their cytoplasmic tails with the intracellular adaptor protein Disabled-1 (DAB1). Here, we identify an extended set of cytoplasmic proteins that might also participate in signal transmission by the LDL receptor gene family. Most of these novel proteins are adaptor or scaffold proteins that contain PID or PDZ domains and function in the regulation of mitogen-activated protein kinases, cell adhesion, vesicle trafficking, or neurotransmission. We show that binding of DAB1 interferes with receptor internalization suggesting a mechanism by which signaling through this class of receptors might be regulated. Taken together, these findings imply much broader physiological functions for the LDL receptor family than had previously been appreciated. They form the basis for the elucidation of the molecular pathways by which cells respond to the diversity of ligands that bind to these multifunctional receptors on the cell surface.

The Reelin Receptor ApoER2 Recruits JNK-interacting Proteins-1 and -2

Correct positioning of neurons during embryonic development of the brain depends, among other processes, on the proper transmission of the reelin signal into the migrating cells via the interplay of its receptors with cytoplasmic signal transducers. Cellular components of this signaling pathway characterized to date are cell surface receptors for reelin like apolipoprotein E receptor 2 (ApoER2), very low density lipoprotein receptor (VLDLR), and cadherin-related neuronal receptors, and intracellular components like Disabled-1 and the nonreceptor tyrosine kinase Fyn, which bind to the intracellular domains of the ApoER2 and VLDL receptor or of cadherin-related neuronal receptors, respectively. Here we show that ApoER2, but not VLDLR, also binds the family of JNK-interacting proteins (JIPs), which act as molecular scaffolds for the JNK-signaling pathway. The ApoER2 binding domain on JIP-2 does not overlap with the binding sites for MLK3, MKK7, and JNK. These results suggest that ApoER2 is able to assemble a multiprotein complex containing Disabled-1 and JIPs, together with their binding partners, to the cell surface of neurons. This complex might participate in ApoER2-specific reelin signaling and thus would explain the different phenotype of mice lacking the ApoER2 from that of VLDLR-deficient mice.

Receptor Clustering Is Involved in Reelin Signaling

ABSTRACT The Reelin signaling cascade plays a crucial role in the correct positioning of neurons during embryonic brain development. Reelin binding to apolipoprotein E receptor 2 (ApoER2) and very-low-density-lipoprotein receptor (VLDLR) leads to phosphorylation of disabled 1 (Dab1), an adaptor protein which associates with the intracellular domains of both receptors. Coreceptors for Reelin have been postulated to be necessary for Dab1 phosphorylation. We show that bivalent agents specifically binding to ApoER2 or VLDLR are sufficient to mimic the Reelin signal. These agents induce Dab1 phosphorylation, activate members of the Src family of nonreceptor tyrosine kinases, modulate protein kinase B/Akt phosphorylation, and increase long-term potentiation in hippocampal slices. Induced dimerization of Dab1 in HEK293 cells leads to its phosphorylation even in the absence of Reelin receptors. The mechanism for and the sites of these phosphorylations are identical to those effected by Reelin in primary neurons. These results suggest that binding of Reelin, which exists as a homodimer in vivo, to ApoER2 and VLDLR induces clustering of ApoER2 and VLDLR. As a consequence, Dab1 becomes dimerized or oligomerized on the cytosolic side of the plasma membrane, constituting the active substrate for the kinase; this process seems to be sufficient to transmit the signal and does not appear to require any coreceptor.

Insulin-secreting β-Cell Dysfunction Induced by Human Lipoproteins

Diabetes is associated with significant changes in plasma concentrations of lipoproteins. We tested the hypothesis that lipoproteins modulate the function and survival of insulin-secreting cells. We first detected the presence of several receptors that participate in the binding and processing of plasma lipoproteins and confirmed the internalization of fluorescent low density lipoprotein (LDL) and high density lipoprotein (HDL) particles in insulin-secreting β-cells. Purified human very low density lipoprotein (VLDL) and LDL particles reduced insulin mRNA levels and β-cell proliferation and induced a dose-dependent increase in the rate of apoptosis. In mice lacking the LDL receptor, islets showed a dramatic decrease in LDL uptake and were partially resistant to apoptosis caused by LDL. VLDL-induced apoptosis of β-cells involved caspase-3 cleavage and reduction in the levels of the c-Jun N-terminal kinase-interacting protein-1. In contrast, the proapoptotic signaling of lipoproteins was antagonized by HDL particles or by a small peptide inhibitor of c-Jun N-terminal kinase. The protective effects of HDL were mediated, in part, by inhibition of caspase-3 cleavage and activation of Akt/protein kinase B. In conclusion, human lipoproteins are critical regulators of β-cell survival and may therefore contribute to the β-cell dysfunction observed during the development of type 2 diabetes.

Differential glycosylation regulates processing of lipoprotein receptors by γ-secretase

The low density lipoprotein (LDL) receptor-related protein 1 (LRP1) belongs to a growing number of cell surface proteins that undergo regulated proteolytic processing that culminates in the release of their intracellular domain (ICD) by the intramembranous protease γ-secretase. Here we show that LRP1 is differentially glycosylated in a tissue-specific manner and that carbohydrate addition reduces proteolytic cleavage of the extracellular domain and, concomitantly, ICD release. The apolipoprotein E (apoE) receptor-2 (apoER2), another member of the LDL receptor family with functions in cellular signal transmission, also undergoes sequential proteolytic processing, resulting in intracellular domain release into the cytoplasm. The penultimate processing step also involves cleavage of the apoER2 extracellular domain. The rate at which this cleavage step occurs is determined by the glycosylation state of the receptor, which in turn is regulated by the alternative splicing of an exon encoding several O-linked sugar attachment sites. These findings suggest a role for differential and tissue-specific glycosylation as a physiological switch that modulates the diverse biological functions of these receptors in a cell-type specific manner.

The PX-domain protein SNX17 interacts with members of the LDL receptor family and modulates endocytosis of the LDL receptor

Sorting nexins (SNXs) comprise a family of proteins characterized by the presence of a phox‐homology domain, which mediates the association of these proteins with phosphoinositides and recruits them to specific membranes or vesicular structures within cells. Although only limited information about SNXs and their functions is available, they seem to be involved in membrane trafficking and sorting processes by directly binding to target proteins such as certain growth factor receptors. We show that SNX17 binds to the intracellular domain of some members of the low‐density lipoprotein receptor (LDLR) family such as LDLR, VLDLR, ApoER2 and LDLR‐related protein. SNX17 resides on distinct vesicular structures partially overlapping with endosomal compartments characterized by the presence of EEA1 and rab4. Using rhodamine‐labeled LDL, it was possible to demonstrate that during endocytosis, LDL passes through SNX17‐positive compartments. Functional studies on the LDLR pathway showed that SNX17 enhances the endocytosis rate of this receptor. Our results identify SNX17 as a novel adaptor protein for LDLR family members and define a novel mechanism for modulation of their endocytic activity.

A New Low Density Lipoprotein Receptor Homologue with 8 Ligand Binding Repeats in Brain of Chicken and Mouse

The blood-brain barrier necessitates disparate macromolecular transport systems in the brain and central nervous system. We now report the discovery of a new member of the low density lipoprotein receptor (LDLR) family whose expression is highly restricted to the brain. The full-length cDNA specifying the chicken receptor (open reading frame, 2754 base pairs) as well as a cDNA for the major portion of its murine homologue have been obtained. The novel receptor shows the greatest similarity to the group of LDLR relatives with 8 ligand binding repeats, in chicken termed LR8 and in mammals, very low density lipoprotein receptors. Thus, in addition to 8 tandemly arranged ligand binding repeats, the five-domain receptor contains an O-linked sugar region and the internalization signal, Phe-Asp-Asn-Pro-Val-Tyr, typical for all LDLR gene family members. In chicken, the 6.5-kb receptor transcript is present at high levels in brain and at much lower levels in extraoocytic cells of the ovary; in mouse, the same transcript of 6.5 kb was detected in brain, but not in heart (the major site of very low density lipoprotein receptor expression), lung, liver, kidney, and ovary. An antibody directed against the predicted carboxyl terminus of the avian receptor detected a 130-kDa protein in brain extracts. The apparent size of the immunoreactive protein is compatible with extensive glycosylation of the 894-residue mature form of the receptor. The presence of this novel receptor in brain of a bird and a rodent suggests an important and evolutionary conserved function.

Chicken Oocytes and Somatic Cells Express Different Splice Variants of a Multifunctional Receptor

An abundant 95-kDa protein belonging to the low density lipoprotein receptor supergene family is essential for chicken oocyte growth by mediating the uptake of multiple plasma-borne yolk precursors. This receptor harbors at the amino terminus a cluster of eight tandemly arranged repeats typical of the ligand binding domains of members of this family and is designated low density lipoprotein receptor relative with 8 repeats (LR8). Here, we demonstrate by reverse transcriptase-polymerase chain reaction, Northern, and Western blot analyses that the chicken expresses two forms of LR8, which are generated by differential splicing of an exon encoding a serine- and threonine-rich region characteristic of LRs, termed O-linked sugar domain. The female germ cell of the chicken expresses extremely high levels of the short form of LR8 (LR8-), i.e. the 95-kDa protein; in contrast, somatic cells express lower but detectable levels of the form containing the O-linked sugar domain (LR8+). The main sites of LR8+ expression in the chicken are the heart and skeletal muscle, i.e. the same tissues where LR8 mRNAs predominate in mammals; in addition, in situ hybridization demonstrates that a significant amount of LR8+ is produced in the hens ovarian follicular granulosa cells. We found no apparent functional difference between the two receptor forms; however, cell type-specific targeting of the multiple ligands of these receptors possibly relates to their respective expression on the cell surface.

A secreted soluble form of ApoE receptor 2 acts as a dominant-negative receptor and inhibits Reelin signaling

Specialized neurons throughout the developing central nervous system secrete Reelin, which binds to ApoE receptor 2 (ApoER2) and very low density lipoprotein receptor (VLDLR), triggering a signal cascade that guides neurons to their correct position. Binding of Reelin to ApoER2 and VLDLR induces phosphorylation of Dab1, which binds to the intracellular domains of both receptors. Due to differential splicing, several isoforms of ApoER2 differing in their ligand‐binding and intracellular domains exist. One isoform harbors four binding repeats plus an adjacent short 13 amino acid insertion containing a furin cleavage site. It is not known whether furin processing of this ApoER2 variant actually takes place and, if so, whether the produced fragment is secreted. Here we demonstrate that cleavage of this ApoER2 variant does indeed take place, and that the resulting receptor fragment consisting of the entire ligand‐binding domain is secreted as soluble polypeptide. This receptor fragment inhibits Reelin signaling in primary neurons, indicating that it can act in a dominant‐negative fashion in the regulation of Reelin signaling during embryonic brain development.