Salvatore Carbonetto

Dystroglycan-α, a dystrophin-associated glycoprotein, is a functional agrin receptor

Aggregation of acetylcholine receptors (AChRs) on skeletal muscle fibers is thought to be mediated by the basal lamina protein agrin. Structural similarities shared by agrin and laminin suggested that the laminin receptor dystroglycan-alpha, part of a dystrophin-receptor complex, might also bind agrin. We show here that dystroglycan-alpha and dystrophin-related protein (DRP/utrophin) are concentrated within AChR aggregates in cultures of C2 myotubes and that agrin binds specifically to dystroglycan-alpha in in vitro assays. This binding is calcium dependent and is inhibited by monoclonal antibody (MAb) IIH6 against dystroglycan-alpha, heparin, and laminin, but not by fibronectin. In S27 cells, which do not aggregate AChRs spontaneously, agrin and laminin binding to dystroglycan-alpha are dramatically decreased. Moreover, MAb IIH6 significantly inhibits agrin-induced AChR aggregation on C2 cells. We conclude that dystroglycan-alpha is an agrin-binding protein and part of a dystrophin-receptor complex involved in AChR aggregation.

RNA cargoes associating with FMRP reveal deficits in cellular functioning in Fmr1 null mice

The Fragile X mental retardation-1 (Fmr1) gene encodes a multifunctional protein, FMRP, with intrinsic RNA binding activity. We have developed an approach, antibody-positioned RNA amplification (APRA), to identify the RNA cargoes associated with the in vivo configured FMRP messenger ribonucleoprotein (mRNP) complex. Using APRA as a primary screen, putative FMRP RNA cargoes were assayed for their ability to bind directly to FMRP using traditional methods of assessing RNA-protein interactions, including UV-crosslinking and filter binding assays. Approximately 60% of the APRA-defined mRNAs directly associate with FMRP. By examining a subset of these mRNAs and their encoded proteins in brain tissue from Fmr1 knockout mice, we have observed that some of these cargoes as well as the proteins they encode show discrete changes in abundance and/or differential subcellular distribution. These data are consistent with spatially selective regulation of multiple biological pathways by FMRP.

Matrix assembly, regulation, and survival functions of laminin and its receptors in embryonic stem cell differentiation

Laminin-1 is essential for early embryonic basement membrane assembly and differentiation. Several steps can be distinguished, i.e., the expression of laminin and companion matrix components, their accumulation on the cell surface and assembly into basement membrane between endoderm and inner cell mass, and the ensuing differentiation of epiblast. In this study, we used differentiating embryoid bodies derived from mouse embryonic stem cells null for γ1-laminin, β1-integrin and α/β-dystroglycan to dissect the contributions of laminin domains and interacting receptors to this process. We found that (a) laminin enables β1-integrin–null embryoid bodies to assemble basement membrane and achieve epiblast with β1-integrin enabling expression of the laminin α1 subunit; (b) basement membrane assembly and differentiation require laminin polymerization in conjunction with cell anchorage, the latter critically dependent upon a heparin-binding locus within LG module-4; (c) dystroglycan is not uniquely required for basement membrane assembly or initial differentiation; (d) dystroglycan and integrin cooperate to sustain survival of the epiblast and regulate laminin expression; and (e) laminin, acting via β1-integrin through LG1–3 and requiring polymerization, can regulate dystroglycan expression.

De novo mutations in the gene encoding the synaptic scaffolding protein SHANK3 in patients ascertained for schizophrenia

Schizophrenia likely results from poorly understood genetic and environmental factors. We studied the gene encoding the synaptic protein SHANK3 in 285 controls and 185 schizophrenia patients with unaffected parents. Two de novo mutations (R1117X and R536W) were identified in two families, one being found in three affected brothers, suggesting germline mosaicism. Zebrafish and rat hippocampal neuron assays revealed behavior and differentiation defects resulting from the R1117X mutant. As mutations in SHANK3 were previously reported in autism, the occurrence of SHANK3 mutations in subjects with a schizophrenia phenotype suggests a molecular genetic link between these two neurodevelopmental disorders.

Chimaeric mice deficient in dystroglycans develop muscular dystrophy and have disrupted myoneural synapses

Mutations in the dystrophin gene (DMD) and in genes encoding several dystrophin-associated proteins result in Duchenne and other forms of muscular dystrophy. α-Dystroglycan (Dg) binds to laminins in the basement membrane surrounding each myofibre and docks with β-Dg, a transmembrane protein, which in turn interacts with dystrophin or utrophin in the subplasmalemmal cytoskeleton. α- and β-Dgs are thought to form the functional core of a larger complex of proteins extending from the basement membrane to the intracellular cytoskeleton, which serves as a superstructure necessary for sarcolemmal integrity. Dgs have also been implicated in the formation of synaptic densities of acetylcholine receptors (AChRs) on skeletal muscle. Here we report that chimaeric mice generated with ES cells targeted for both Dg alleles have skeletal muscles essentially devoid of Dgs and develop a progressive muscle pathology with changes emblematic of muscular dystrophies in humans. In addition, many neuromuscular junctions are disrupted in these mice. The ultrastructure of basement membranes and the deposition of laminin within them, however, appears unaffected in Dg-deficient muscles. We conclude that Dgs are necessary for myofibre survival and synapse differentiation or stability, but not for the formation of the muscle basement membrane, and that Dgs may have more than a purely structural function in maintaining muscle integrity.

The extracellular matrix of the nervous system

Experiments by McMahan and co-workers indicate that the extracellular matrix of the nervous system controls synapse formation at myoneural junctions. This has prompted researchers in many laboratories to scrutinize the matrix for those molecular cues which signal proper regeneration and development of the nervous system. The functions of several molecules within the extracellular matrix are becoming clear. Moreover, the adhesion of neural cells to the extracellular matrix emerges as an event central to cell motility and to related processes such as nerve regeneration and myelination. An understanding of cell-matrix adhesion is essential to our understanding of neural regeneration and development.

A neuronal cell line (PC12) expresses two β1-class integrins—α1β1, and α3β1—that recognize different neurite outgrowth-promoting domains in laminin

Integrins mediate neuronal process outgrowth on components of the ECM. Integrin alpha subunit-specific antibodies have been used to examine the roles of individual beta 1 integrins in attachment and neurite outgrowth by the neuronal cell line, PC12, in response to laminin and collagen. alpha 1 beta 1 and alpha 3 beta 1 were identified as the major beta 1 integrins expressed by PC12 cells. In functional assays, both alpha 1 beta 1 and alpha 3 beta 1 mediated PC12 cell interactions with laminin, whereas alpha 1 beta 1 alone mediated responses to collagen types I and IV. alpha 1 beta 1 and alpha 3 beta 1 were shown to recognize two different neurite-promoting sites in laminin: alpha 1 beta 1 interacted with the cross-region of laminin present in proteolytic fragments E1-4 and E1; alpha 3 beta 1 recognized a site in the long arm contained in laminin fragment E8. Thus, PC12 cells express two beta 1 integrins, which together function in attachment and neurite outgrowth on laminin and collagen. These integrins are candidates for mediating neurite outgrowth of sympathetic and other neurons in response to these ECM components.

Mutations in the calcium-related gene IL1RAPL1 are associated with autism

In a systematic sequencing screen of synaptic genes on the X chromosome, we have identified an autistic female without mental retardation (MR) who carries a de novo frameshift Ile367SerfsX6 mutation in Interleukin-1 Receptor Accessory Protein-Like 1 (IL1RAPL1), a gene implicated in calcium-regulated vesicle release and dendrite differentiation. We showed that the function of the resulting truncated IL1RAPL1 protein is severely altered in hippocampal neurons, by measuring its effect on neurite outgrowth activity. We also sequenced the coding region of the close related member IL1RAPL2 and of NCS-1/FREQ, which physically interacts with IL1RAPL1, in a cohort of subjects with autism. The screening failed to identify non-synonymous variant in IL1RAPL2, whereas a rare missense (R102Q) in NCS-1/FREQ was identified in one autistic patient. Furthermore, we identified by comparative genomic hybridization a large intragenic deletion of exons 3-7 of IL1RAPL1 in three brothers with autism and/or MR. This deletion causes a frameshift and the introduction of a premature stop codon, Ala28GlufsX15, at the very beginning of the protein. All together, our results indicate that mutations in IL1RAPL1 cause a spectrum of neurological impairments ranging from MR to high functioning autism.

Dystroglycan in the Cerebellum is a Laminin α2‐chain Binding Protein at the Glial‐Vascular Interface and is Expressed in Purkinje cells

Dystroglycan is a core component of the dystrophin receptor complex in skeletal muscle which links the extracellular matrix to the muscle cytoskeleton. Dystrophin, dystrophin‐related protein (DRP, utrophin) and dystroglycan are present not only in muscles but also in the brain. Dystrophin is expressed in certain neuronal populations while DRP is associated with perivascular astrocytes. To gain insights into the function and molecular interactions of dystroglycan in the brain, we examined the localization of α‐and β‐dystroglycan at the cellular and subcellular levels in the rat cerebellum. In blood vessels, we find a‐dystroglycan associated with the laminin a2‐chain‐rich parenchymal vascular basement membrane and β‐dystroglycan associated with the endfeet of perivascular astrocytes. We also show that a‐dystroglycan purified from the brain binds a2‐chain‐containing laminin‐2. These observations suggest a dystroglycan‐mediated linkage between DRP in perivascular astrocytic endfeet and laminin‐2 in the parenchymal basement membrane similar to that described in skeletal muscle. This linkage of the astrocytic endfeet to the vascular basement membrane is likely to be important for blood vessel formation and stabilization and for maintaining the integrity of the blood‐brain barrier. In addition to blood vessel labelling, we show that β‐dystroglycan in the rat cerebellum is associated with the surface of Purkinje cell bodies, dendrites and dendritic spines. Dystrophin has previously been localized to the inner surface of the plasma membrane of Purkinje cells and is enriched at postsynaptic sites. Thus, the present results also support the hypothesis that dystrophin interacts with dystroglycan in cerebellar Purkinje neurons.

Magnesium-dependent attachment and neurite outgrowth by PC12 cells on collagen and laminin substrata

We report a study of the substratum and medium requirements for attachment and neurite outgrowth by cells of the pheochromocytoma-derived PC12 line. In attachment medium containing both Ca2+ and Mg2+, more than 50% of cells attached within 1 hr to petri dishes coated with native collagen Types I/III or II, native or denatured collagen Type IV, laminin, wheat germ agglutinin (WGA), or poly-L-lysine; attachment to dishes coated with nerve growth factor (NGF) was only about 20% and attachment to uncoated dishes or to dishes coated with fibronectin or gelatin was almost nil. Neither prior culturing in the presence of NGF nor addition of NGF to the attachment medium significantly affected the extent of attachment to collagen or laminin. With Ca2+ (1 mM) as the sole divalent cation, cells attached normally to WGA, polylysine, and NGF, but failed to attach to collagen or laminin. With Mg2+ (1 mM) as the only divalent cation, attachment to all substrata was about the same as in medium with both Ca2+ and Mg2+. Like the ionic requirements, the kinetics of attachment, insensitivity to protease treatment of the cells, and inhibition by low temperature and sodium azide were similar for PC12 attachment to collagen and laminin, suggesting that a common molecular mechanism may underlie attachment to these substrata. The only significant difference observed was that addition of WGA (30 micrograms/ml) to the attachment medium inhibited attachment to collagen but promoted attachment to laminin. Finally, PC12 cells extended neurites on laminin, on native collagens I/III, II, and IV, and on denatured collagen IV; they did not extend neurites on denatured collagens I/III or II, NGF, or WGA. Neurite outgrowth on collagen and laminin occurred with Mg2+ as the sole divalent cation. These results suggest that the same Mg2+-dependent adhesion mechanism operates at the cell body and at the growth cone.