Mohammed Akaaboune

Neurotransmitter Receptor Dynamics Studied In Vivo by Reversible Photo-Unbinding of Fluorescent Ligands

We show that fluorescently tagged ligands with high affinity for their targets can be reversibly unbound by focused laser excitation. By sequential unbinding and relabeling with different colors of alpha-bungarotoxin, we selectively labeled adjacent pools of acetylcholine receptors (AChRs) at neuromuscular junctions of adult mice. Timelapse imaging in vivo revealed that synaptic AChRs completely intermingle over approximately 4 days and many extrasynaptic AChRs are incorporated into the synapse each day. In mice that lacked alpha-dystrobrevin, a component of the dystrophin-glycoprotein complex, rates of AChR turnover, and intermingling were increased approximately 4- to 5-fold. These results demonstrate remarkable molecular dynamism underlying macroscopic stability of the postsynaptic membrane, and establish alpha-dystrobrevin as a key control point for regulation of mobility and turnover.

Identification of Nicotinic Acetylcholine Receptor Recycling and Its Role in Maintaining Receptor Density at the Neuromuscular Junction In Vivo

In the CNS, receptor recycling is critical for synaptic plasticity; however, the recycling of receptors has never been observed at peripheral synapses. Using a novel imaging technique, we show here that nicotinic acetylcholine receptors (AChRs) recycle into the postsynaptic membrane of the neuromuscular junction. By sequentially labeling AChRs with biotin-bungarotoxin and streptavidin-fluorophore conjugates, we were able to distinguish recycled, preexisting, and new receptor pools at synapses in living mice. Time-lapse imaging revealed that recycled AChRs were incorporated into the synapse within hours of initial labeling, and their numbers increased with time. At fully functional synapses, AChR recycling was robust and comparable in magnitude with the insertion of newly synthesized receptors, whereas chronic synaptic activity blockade nearly abolished receptor recycling. Finally, using the same sequential labeling method, we found that acetylcholinesterase, another synaptic component, does not recycle. These results identify an activity-dependent AChR-recycling mechanism that enables the regulation of receptor density, which could lead to rapid alterations in synaptic efficacy.

Tyrosine-phosphorylated and nonphosphorylated isoforms of α-dystrobrevin: Roles in skeletal muscle and its neuromuscular and myotendinous junctions

α-Dystrobrevin (DB), a cytoplasmic component of the dystrophin–glycoprotein complex, is found throughout the sarcolemma of muscle cells. Mice lacking αDB exhibit muscular dystrophy, defects in maturation of neuromuscular junctions (NMJs) and, as shown here, abnormal myotendinous junctions (MTJs). In normal muscle, alternative splicing produces two main αDB isoforms, αDB1 and αDB2, with common NH2-terminal but distinct COOH-terminal domains. αDB1, whose COOH-terminal extension can be tyrosine phosphorylated, is concentrated at the NMJs and MTJs. αDB2, which is not tyrosine phosphorylated, is the predominant isoform in extrajunctional regions, and is also present at NMJs and MTJs. Transgenic expression of either isoform in αDB−/− mice prevented muscle fiber degeneration; however, only αDB1 completely corrected defects at the NMJs (abnormal acetylcholine receptor patterning, rapid turnover, and low density) and MTJs (shortened junctional folds). Site-directed mutagenesis revealed that the effectiveness of αDB1 in stabilizing the NMJ depends in part on its ability to serve as a tyrosine kinase substrate. Thus, αDB1 phosphorylation may be a key regulatory point for synaptic remodeling. More generally, αDB may play multiple roles in muscle by means of differential distribution of isoforms with distinct signaling or structural properties.alpha-Dystrobrevin (DB), a cytoplasmic component of the dystrophin-glycoprotein complex, is found throughout the sarcolemma of muscle cells. Mice lacking alphaDB exhibit muscular dystrophy, defects in maturation of neuromuscular junctions (NMJs) and, as shown here, abnormal myotendinous junctions (MTJs). In normal muscle, alternative splicing produces two main alphaDB isoforms, alphaDB1 and alphaDB2, with common NH2-terminal but distinct COOH-terminal domains. alphaDB1, whose COOH-terminal extension can be tyrosine phosphorylated, is concentrated at the NMJs and MTJs. alphaDB2, which is not tyrosine phosphorylated, is the predominant isoform in extrajunctional regions, and is also present at NMJs and MTJs. Transgenic expression of either isoform in alphaDB-/- mice prevented muscle fiber degeneration; however, only alphaDB1 completely corrected defects at the NMJs (abnormal acetylcholine receptor patterning, rapid turnover, and low density) and MTJs (shortened junctional folds). Site-directed mutagenesis revealed that the effectiveness of alphaDB1 in stabilizing the NMJ depends in part on its ability to serve as a tyrosine kinase substrate. Thus, alphaDB1 phosphorylation may be a key regulatory point for synaptic remodeling. More generally, alphaDB may play multiple roles in muscle by means of differential distribution of isoforms with distinct signaling or structural properties.

Neuregulin/ErbB regulate neuromuscular junction development by phosphorylation of α-dystrobrevin

Neuregulin/ErbB signaling maintains high efficacy of synaptic transmission by stabilizing the postsynaptic apparatus via phosphorylation of α-dystrobrevin1.

Developmental regulation of amyloid precursor protein at the neuromuscular junction in mouse skeletal muscle.

Amyloid precursor protein (APP), associated with Alzheimers disease plaques, is known to be present in synapses of the brain and in the adult neuromuscular junction (NMJ). In the present study we examined protein and gene expression of APP during the development of mouse skeletal muscle. Using immunocytochemical approaches, we found that APP is first detected in myotube cytoplasm at embryonic day 16 and becomes progressively concentrated at the NMJ beginning at birth until adulthood. The colocalization between APP and acetylcholine receptors at the NMJ is only partial at birth, but becomes complete upon reaching adulthood. We observed that all APP isoforms, including the Kunitz-containing (protease inhibitor or KPI) forms, are up-regulated from birth to postnatal day 5 and then decreased to reach the low levels observed in the adult. This suggests the involvement of APP during the events which lead to a mature mono-innervated synapse. A 92-kDa band, characteristic of a cleaved APP695 isoform and not due to a new muscle-specific alternative spliced form, was observed from postnatal day 15 following completion of polyneuronal synapse elimination. Taken together, these data suggest that skeletal muscle APP may well play a role in the differentiation of skeletal muscle and in the formation and maturation of NMJs.

Neural Thrombin and Protease Nexin I Kinetics After Murine Peripheral Nerve Injury

Abstract: We addressed the balance between thrombin and its serpin protease nexin I (PNI) after sciatic nerve injury in the mouse. Prothrombin levels increased twofold 24 h after nerve crush, as measured by a specific chromogenic assay, and peaked at day 3. Thrombin activity also increased 2–4 days after injury in distal sciatic nerve segments. Nerve RNA analysis using reverse transcriptase‐polymerase chain reaction (RT‐PCR) assay confirmed that prothrombin was synthesized locally. We also monitored PNI levels in these injured nerve samples by complex formation with an 125I‐labeled target protease and found peak activity occurring later, 6–9 days after the thrombin induction. These data indicate that nerve injury first induces the synthesis of prothrombin, which is subsequently converted to active thrombin. Nerve crush‐induced thrombin is followed by the generation of functionally active PNI and may be directly responsible for its induction. By immunocytochemistry with anti‐PNI antibody, we found that activated Schwann cells were the source of induced PNI. These results support the concept that the balance between serine proteases and their serpins is dysregulated during nerve injury and suggests a role for its reestablishment in nerve damage repair.

Calcium/Calmodulin Kinase II-Dependent Acetylcholine Receptor Cycling at the Mammalian Neuromuscular Junction In Vivo

At the mammalian skeletal neuromuscular junction, cycling of nicotinic ACh receptors (nAChRs) is critical for the maintenance of a high postsynaptic receptor density. However, the mechanisms that regulate nAChRs recycling in living animals remain unknown. Using in vivo time-lapse imaging, fluorescence recovery after photobleaching, and biochemical pull down assays, we demonstrated that recycling of internalized nAChRs into fully functional and denervated synapses was promoted by both direct muscle stimulation and pharmacologically induced intracellular calcium elevations. Most of internalized nAChRs are recycled directly into synaptic sites. Chelating of intracellular calcium below resting level drastically decreased cycling of nAChRs. Furthermore we found that calcium-dependent AChR recycling is mediated by Ca2+/calmodulin-dependent kinase II (CaMKII). Inhibition of CaMKII selectively blocked recycling and caused intracellular accumulation of internalized nAChRs, whereas internalization of surface receptors remained unaffected. Electroporation of CaMKII-GFP isoforms into the sternomastoid muscle showed that muscle-specific CaMKIIβm isoform is highly expressed at the neuromuscular junction (NMJ) and precisely colocalized with nAChRs at crests of synaptic folds while the CaMKIIγ and δ isoforms are poorly expressed in synaptic sites. These results indicate that Ca2+ along with CaMKII activity are critical for receptor recycling and may provide a mechanism by which the postsynaptic AChR density is maintained at the NMJ in vivo.

Developmental regulation of the serpin, protease nexin I, localization during activity-dependent polyneuronal synapse elimination in mouse skeletal muscle

During vertebrate neuromuscular development, all muscle fibers are transiently innervated by more than one neuron. Among the numerous factors shown to potentially influence the passage from poly‐ to mononeuronal innervation, serine proteases and their inhibitors appear to play important roles. In this regard, protease nexin I (PNI), a potent inhibitor of the serine protease, thrombin, is highly localized to the neuromuscular junction (NMJ). In turn, thrombin is responsible for activity‐dependent synapse elimination both in an in vitro model, and in vivo. In the present study, we used a monospecific anti‐PNI polyclonal antibody to study the developmental kinetics of PNI expression in mouse leg skeletal muscle. By using immunoblotting, we detected PNI at embryonic day 16 (E16), as a 48‐kDa band. This 48‐kDa PNI band became prominent in leg muscle extracts at postnatal day 5 (P5) and remained so in extracts from adult muscle. In contrast, a higher molecular weight immunoreactive PNI band, which was sodium dodecyl sulfate– and β‐mercaptoethanol–resistant, was first detected at E16, increased at birth (P0), and then decreased at P15, i.e., after the wave of polyneuronal synapse elimination had occurred in these muscles. The results of an enzyme‐linked immunosorbent assay, measuring active, complexed, and truncated PNI, correlated with Western blot data. We used immunocytochemistry to probe the localization of PNI at the NMJ and found that PNI was present in the cytoplasm of myotubes at E16, but neither then nor at birth did it colocalize with acetylcholine receptors. PNI became localized at NMJs by P5 and increased by P15, after which it remained stably concentrated there in the adult. Finally, we studied the gene expression of PNI mRNA, by using Northern blotting, and showed that PNI mRNA was present in skeletal muscle and remained stable throughout the time‐course studies, suggesting that developmental regulation of muscle PNI occurs principally at the translational and/or post‐translational levels. These results suggest that the localization of PNI, through a binding site or “receptor” may play an important role in differentiation and maintenance of synapse. J. Comp. Neurol. 397:572–579, 1998.

Running to stand still: ionotropic receptor dynamics at central and peripheral synapses.

For synapses to form and function, neurotransmitter receptors must be recruited to a location on the postsynaptic cell in direct apposition to presynaptic neurotransmitter release. However, once receptors are inserted into the postsynaptic membrane, they are not fixed in place but are continually exchanged between synaptic and extrasynaptic regions, and they cycle between the surface and intracellular compartments. This article highlights and compares the current knowledge about the dynamics of acetylcholine receptors at the vertebrate peripheral neuromuscular junction and AMPA, N-methyl-d-aspartate, and γ-aminobutyric acid receptors in central synapses.

Receptor-associated proteins and synaptic plasticity.

Changes in synaptic strength are important for synaptic development and synaptic plasticity. Most directly responsible for these synaptic changes are alterations in synaptic receptor number and density. Although alterations in receptor density mediated by the insertion, lateral mobility, removal, and recycling of receptors have been extensively studied, the dynamics and regulators of intracellular scaffolding proteins have only recently begun to be illuminated. In particular, a closer look at the receptor‐associated proteins, which bind to receptors and are necessary for their synaptic localization and clustering, has revealed broader functions than previously thought and some rather unexpected thematic similarities. More than just “placeholders” or members of a passive protein “scaffold,” receptor‐associated proteins in every synapse studied have been shown to provide a number of signaling roles. In addition, the most recent state‐of‐the‐art imaging has revealed that receptor‐associated proteins are highly dynamic and are involved in regulating synaptic receptor density. Together, these results challenge the view that receptor‐associated proteins are members of a static and stable scaffold and argue that their dynamic mobility may be essential for regulating activity‐dependent changes in synaptic strength.— Bruneau, E. G., Esteban, J. A., Akaaboune, M. Receptor‐associated proteins and synaptic plasticity. FASEB J. 23, 679–688 (2009)