Epitope-preserving magnified analysis of proteome (eMAP).

Synthetic tissue-hydrogel methods have enabled superresolution investigation of biological systems using diffraction-limited microscopy. However, chemical modification by fixatives can cause loss of antigenicity, limiting molecular interrogation of the tissue gel. Here, we present epitope-preserving magnified analysis of proteome (eMAP) that uses purely physical tissue-gel hybridization to minimize the loss of antigenicity while allowing permanent anchoring of biomolecules. We achieved success rates of 96% and 94% with synaptic antibodies for mouse and marmoset brains, respectively. Maximal preservation of antigenicity allows imaging of nanoscopic architectures in 1000-fold expanded tissues without additional signal amplification. eMAP-processed tissue gel can endure repeated staining and destaining without epitope loss or structural damage, enabling highly multiplexed proteomic analysis. We demonstrated the utility of eMAP as a nanoscopic proteomic interrogation tool by investigating molecular heterogeneity in inhibitory synapses in the mouse brain neocortex and characterizing the spatial distributions of synaptic proteins within synapses in mouse and marmoset brains.

Glutamate Receptors: Not Just for Excitation.

In this issue of Neuron, Fossati et al. (2019) report a new constellation of players regulating inhibitory synaptogenesis. They show that GluD1, through a non-canonical ionotropic-independent mechanism, controls GABAergic synapse formation via trans-synaptic interactions mediated by extracellular cerebellin-4. They identify ARHGEF12 and PPP1R12A as GluD1 intracellular interactors and downstream effectors.

Inhibitory Synapses Are Repeatedly Assembled and Removed at Persistent Sites In Vivo.

Older concepts of a hard-wired adult brain have been overturned in recent years by in vivo imaging studies revealing synaptic remodeling, now thought to mediate rearrangements in microcircuit connectivity. Using three-color labeling and spectrally resolved two-photon microscopy, we monitor in parallel the daily structural dynamics (assembly or removal) of excitatory and inhibitory postsynaptic sites on the same neurons in mouse visual cortex in vivo. We find that dynamic inhibitory synapses often disappear and reappear again in the same location. The starkest contrast between excitatory and inhibitory synapse dynamics is on dually innervated spines, where inhibitory synapses frequently recur while excitatory synapses are stable. Monocular deprivation, a model of sensory input-dependent plasticity, shortens inhibitory synapse lifetimes and lengthens intervals to recurrence, resulting in a new dynamic state with reduced inhibitory synaptic presence. Reversible structural dynamics indicate a fundamentally new role for inhibitory synaptic remodeling--flexible, input-specific modulation of stable excitatory connections.

Clustered dynamics of inhibitory synapses and dendritic spines in the adult neocortex.

A key feature of the mammalian brain is its capacity to adapt in response to experience, in part by remodeling of synaptic connections between neurons. Excitatory synapse rearrangements have been monitored in vivo by observation of dendritic spine dynamics, but lack of a vital marker for inhibitory synapses has precluded their observation. Here, we simultaneously monitor in vivo inhibitory synapse and dendritic spine dynamics across the entire dendritic arbor of pyramidal neurons in the adult mammalian cortex using large-volume, high-resolution dual-color two-photon microscopy. We find that inhibitory synapses on dendritic shafts and spines differ in their distribution across the arbor and in their remodeling kinetics during normal and altered sensory experience. Further, we find inhibitory synapse and dendritic spine remodeling to be spatially clustered and that clustering is influenced by sensory input. Our findings provide in vivo evidence for local coordination of inhibitory and excitatory synaptic rearrangements.

Comparative analysis of the effects of antimuscarinic agents on bladder functions in both nonhuman primates and rodents.

Both the physiological role of muscarinic receptors for bladder function and the therapeutic efficacy of antimuscarinic agents for overactive bladder syndrome are well documented. We investigated the effect of antimuscarinic agents with different subtype selectivity on urodynamic parameters in nonhuman primates and rodents and compared plasma levels of these agents between species. Anesthetized rhesus monkeys were transurethrally catheterized, and the bladder was infused with saline. Urodynamic parameters were measured before and after intravenous drug administration. Tolterodine (nonselective) and oxybutynin (moderately M(3)-selective) increased bladder capacity at lower doses than those required to decrease micturition pressure. However, higher doses of darifenacin (M(3)-selective) were needed to increase the bladder capacity than those needed to decrease the micturition pressure. In rats, tolterodine had no effect on the bladder capacity but decreased the micturition pressure at all of the doses administered. Oxybutynin also decreased micturition pressure and increased bladder capacity at the highest dose. Plasma levels of these drugs overlap in both species. These results suggest that, in addition to the M(3) receptor, other muscarinic receptor subtypes contribute to regulate bladder storage function in nonhuman primates, since less subtype-selective tolterodine and oxybutynin showed higher specificity to the bladder capacity effect than the effect on micturition pressure compared with M(3)-selective darifenacin. In addition, the role of muscarinic receptors in bladder storage function varies between primates and rodents. Compared with rodents, muscarinic receptors may play a more active role during the storage phase to regulate the functional bladder capacity in primates.

Correlation between pharmacologically-induced changes in cystometric parameters and spinal c-Fos expression in rats.

The inhibition of bladder sensory transmission is critical for the pharmacotherapy of urine storage symptoms. The purpose of this study is to examine the correlation between pharmacologically-induced changes in cystometric parameters and spinal c-Fos expression in anesthetized rats with bladder hyperactivity induced by the intravesical infusion of acetic acid. Animals were intravenously infused with either oxybutynin (OXY), a muscarinic receptor antagonist, tamsulosin (TAM), an alpha1-adrenoceptor antagonist, CL316243 (CL), a beta3-adrenoceptor agonist, or saline. Morphine (MOR) treatment served as a positive control to inhibit bladder afferent activity. Intermicturition intervals, micturition pressure and pressure threshold were measured after intravesical acetic acid infusion. Animals were then perfused and spinal cords were removed. Sections from the L6 spinal cord were immunostained with an anti-c-Fos antibody, and c-Fos positive cells in the dorsal region were counted. CL and MOR significantly increased intermicturition intervals, whereas OXY and TAM had no significant effect on intermicturition intervals. While TAM and MOR did not affect the micturition pressure, OXY and CL caused a significant decrease. Pressure threshold was significantly decreased by CL and increased by MOR. All drugs significantly decreased the number of c-Fos positive cells with the following order of efficacy: MOR>CL>OXT>TAM. The number of c-Fos positive cells in each animal from all treatment groups was negatively correlated with its average intermicturition interval and pressure threshold, but not with its micturition pressure. Bladder afferent activity is suppressed by several clinically proven mechanisms as measured by c-Fos expression, despite the varied effects on cystometric parameters of each pharmacological treatment.