Next Article in Journal
Altered Sphingolipids, Glycerophospholipids, and Lysophospholipids Reflect Disease Status in Idiopathic Steroid-Sensitive Nephrotic Syndrome in Children: A Non-Targeted Metabolomic Study
Previous Article in Journal
Plant-Derived Antioxidants as Modulators of Redox Signaling and Epigenetic Reprogramming in Cancer
 
 
Search for Articles:
Title / Keyword
Author / Affiliation / Email
Journal
Article Type
 
 
Advanced Search
 
Section
Special Issue
Volume
Issue
Number
Page
 
Journals
Cells
Volume 14
Issue 24
10.3390/cells14241949
cells-logo
Submit to this Journal Review for this Journal Propose a Special Issue
Article Menu

Article Menu

share Share announcement Help format_quote Cite question_answer Discuss in SciProfiles
first_page
settings
Order Article Reprints
Font Type:
Arial Georgia Verdana
Font Size:
Aa Aa Aa
Line Spacing:
Column Width:
Background:
Article

Age-Dependent Regulation of Acetylcholine Release at the Neuromuscular Junction Mediated by GABA

by
Egor Nevsky
1,2,
Guzel Sibgatullina
1,
Dmitry Samigullin
1,3,
Artem Malomouzh
1,3,
Vladimir Parpura
4,* and
Konstantin Petrov
1,2,5,*
1
Kazan Institute of Biochemistry and Biophysics, FRC Kazan Scientific Center of RAS, 420111 Kazan, Russia
2
Department of Human and Animal Physiology, Institute of Fundamental Medicine and Biology, Kazan Federal University, 420008 Kazan, Russia
3
Department of Radiophotonics and Microwave Technologies, Kazan National Research Technical University Named After A.N. Tupolev-KAI, 420111 Kazan, Russia
4
International Translational Neuroscience Research Institute, Zhejiang Chinese Medical University, Hangzhou 310053, China
5
Arbuzov Institute of Organic and Physical Chemistry, FRC Kazan Scientific Center of RAS, 420111 Kazan, Russia
*
Authors to whom correspondence should be addressed.
Cells 2025, 14(24), 1949; https://doi.org/10.3390/cells14241949
Submission received: 18 September 2025 / Revised: 25 November 2025 / Accepted: 5 December 2025 / Published: 9 December 2025
(This article belongs to the Section Cellular Neuroscience)
Browse Figures
Versions Notes

Abstract

γ-Aminobutyric acid (GABA) is the main inhibitory neurotransmitter in the central nervous system. However, GABA receptors, notably at the neuromuscular junction (NMJ), have also been identified in the peripheral nervous system. Here, we studied GABAB receptor (GABAB–R)-mediated regulation of acetylcholine (ACh) release in mouse NMJs during early postnatal development. The results revealed that, depending on the age of the mice, the activation of GABAB–R had the opposite effect on ACh release. At the NMJ in mice on the second postnatal (P2) day, the GABAB–R blocker CGP 55845 (5 μM) significantly increased the level of ACh release, whereas the GABAB–R agonist baclofen (10 μM) decreased ACh release. In P14-aged mice, CGP 55845 decreased ACh release, while the application of baclofen significantly increased the release. At the NMJ of P14 mice, the mechanism of the ACh release-potentiating effect of GABAB–R activation involves N-type calcium ion channels and small-conductance calcium ion-activated potassium ion channels.

Graphical Abstract

1. Introduction

γ-Aminobutyric acid (GABA) is a key inhibitory neurotransmitter in the central nervous system. GABA acts via the activation of two types of receptors, GABAA (ionotropic) and GABAB (metabotropic). The activation of GABAA receptors, after the postnatal shift [1], results in an increase in an inward chloride ion current that induces hyperpolarization of the neuron and blocks action potential generation [2]. Metabotropic GABAB receptors (GABAB–Rs) are G protein–coupled receptors that trigger intracellular signal transduction mainly via interactions with Gi/o proteins [3]. The activation of GABAB–R can modulate the release of neurotransmitters through the inhibition of voltage-gated Ca2+ channels, inward-rectifying potassium channels (GIRKs) and two-pore-domain TREK-2 potassium channels [4,5].
There is some evidence that GABAB–Rs are involved in the regulation of neurotransmitter release not only in the central nervous system but also at neuromuscular junctions (NMJs) [6]. At vertebrate NMJs, the main neurotransmitter is acetylcholine (ACh), which is released from motor nerve terminals and activates postsynaptic nicotinic acetylcholine receptors (nAChRs) of the muscle type. The level of ACh released by motor neurons is not constant and can be dynamically regulated via different pathways [7,8,9,10,11,12,13,14,15,16].
The activation of the ACh release regulatory pathway, which includes GABA, has been previously described in the NMJs of adult mice with inhibited cholinesterase (ChE). After ChE inhibition, the activation of the α7 nAChRs, expressed on plasmalemmas of terminal Schwann cells (TSCs), by ACh spillover induced the secretion of GABA. GABA acts on GABAB–Rs on presynaptic terminals to reduce ACh release [17,18]. In adult mice with active ChE, activation of this α7/GABAB–R regulatory pathway was not detected. Recently, the application of the GABAB–R antagonist CGP 55845 was shown to increase the probability of ACh release in the diaphragm muscle of mice on the second postnatal (P2) day [18]. This effect of GABAB–R blockade in newborn mice was associated with intact ChE activity. Thus, endogenous GABA is released at newborn NMJs and affects cholinergic neurotransmission without ChE inhibition. However, the involvement of α7 nAChRs in the GABAB–R-mediated pathway in neonates has not been studied [18].
In the present study, we further investigated GABAB–R-mediated regulation of ACh release in mouse NMJs during early postnatal development. At P2, the α7/GABAB–R regulatory pathway decreases ACh release in the mouse levator auris longus (LAL) muscle. However, we also found that at P14, GABA increases ACh release in the NMJs of the LAL and that α7 nAChRs are not involved. Thus, in the first weeks of postnatal development, the effect of GABA on ACh release is reversed from depression to augmentation. Both effects of GABA on ACh release are mediated by the activation of GABAB–R.

2. Materials and Methods

2.1. Ethical Approval and Animals

Animal care and experiments were carried out in accordance with the NIH Guide for the Care and Use of Laboratory Animals and the EU Directive 2010/63/EU. The protocol for the experiments was approved by the Animal Care and Use Committee of the FRC Kazan Scientific Center of the Russian Academy of Sciences (protocol #23/7; 12 May 2023). All efforts were made to minimize animal suffering. BALB/c mice were kept in sawdust-lined plastic cages in a well-ventilated room at 20–22 °C under a 12 h light/dark cycle at 60–70% relative humidity and given ad libitum access to food and water.
The studies were performed on neuromuscular preparations of LAL [19] isolated from the animals at two (P2) and fourteen (P14) days after birth and from the animals at two months of age (P60). The animals were deeply anesthetized with isoflurane and then quickly decapitated. Animals of each age were not intentionally randomized, and the investigators were not blinded to the nature of the chemicals used.

2.2. Chemicals

The GABAB–R blocker CGP 55845 (Cat. #SML0594), the α7 nAChR blocker methyllycaconitine (MLA; Cat. #M168), and the phospholipase C inhibitor U-73122 (Cat. #U6756) were purchased from Sigma—Aldrich, St. Louis, MO, USA. The SK-type calcium-activated potassium channel blocker apamin (Cat. #1652), the inhibitor of adenylyl cyclase SQ 22536 (Cat. #1435/10), and the inhibitor of the N-type calcium channel ω-conotoxin GVIA (Cat. #1085/250U) were purchased from Tocris Cookson Inc., Bristol, UK. The GABAB–R agonist baclofen (Cat. #B3343) was purchased from Tokyo Chemical Industry, Tokyo, Japan. 3-(N-butylethanimidoyl)-4-hydroxy-2H-chromen-2-one was purchased from Syntrade-Kazan, Kazan, Russia. The recycling dye N-(3-triethylammoniumpropyl)-4- (4- (dibutylamino) styryl) pyridinium dibromide (FM1-43, Cat. #T-35356) was purchased from Thermo Fisher Scientific, Waltham, MA, USA.
The concentrations of agonists and antagonists reported in this study were obtained from the literature data that have shown a physiological response due to selective pharmacological action: CGP 55845 (5 μM) [20], baclofen (10 μM) [21], MLA (10 μM) [22], U-73122 (5 μM) [23], apamin (100 nM) [24], SQ 22536 (100 μM) [25] and ω-conotoxin GVIA (1 μM) [26].

2.3. Electrophysiological Recordings

Nerve–muscle preparations of LAL were pinned in translucent chambers and perfused at a rate of 2–3 mL min−1 with oxygenated (95% O2, 5% CO2) Krebs–Ringer solution containing 154 mM NaCl, 5 mM KCl, 2 mM CaCl2, 1 mM MgCl2, 5.0 mM HEPES buffer and 11 mM glucose (pH 7.4). End-plate potentials (EPPs) and miniature EPPs (mEPPs) were recorded at 20–22 °C via a standard glass microelectrode (resistance 10–15 MΩ) filled with 3 M KCl. Since µ-conotoxin GIIIB is not effective in newborns [27], to prevent the generation of action potentials and muscle contractions during EPP/mEPP recording, transverse cutting of muscle fibers was used [28]. The motor nerve was stimulated via a suction electrode with supramaximal current pulses (duration 0.1 ms) with a frequency of 0.5 Hz. Recordings were made in 5–10 end plates before treatment and in 5–10 other end plates after treatment. At each end plate, 50 EPPs and 50 mEPPs were recorded. The quantal content (QC) of the EPPs was calculated by dividing the mean EPP amplitude by the mean mEPP amplitude recorded in the same end plate. Only fibers with a stable resting membrane potential at −40 ± 2 mV were analyzed. To correct the QC value for the nonlinearity of the EPP/mEPP amplitude summation, Martin’s correction was used [29].
Synaptic responses were recorded via an Axoclamp 900A amplifier, digitized via Digidata 1440A (Molecular Devices, San Jose, CA, USA) and analyzed via pClamp v 10.4 software (Molecular Devices, San Jose, CA, USA).

2.4. Fluorescence Assays of Acetylcholine Release

Optical monitoring of changes in the process of synaptic vesicle exocytosis was carried out using the fluorescent dye FM1-43, which interacts with the external leaflet of the plasma membrane and is then taken up into synaptic vesicles by endocytosis. Motor nerve stimulation causes dye release from dye-preloaded synaptic vesicles [30].
FM1-43 was loaded into synaptic vesicles at 30 Hz (for 3 min), thereby inducing massive exocytosis-endocytosis. FM1-43 (7 μM) was present in the incubation solution 3 min before stimulation, during stimulation and 5 min after the end of stimulation. The preparations were then washed for 40 min with Ringer-Krebs solution. FM1-43-loaded nerve terminals were then stimulated at 30 Hz to induce massive synaptic exocytosis, resulting in the release of dye from vesicles (FM1-43 destaining). Muscle contractions were blocked by the skeletal muscle myosin inhibitor 50 μM 3-(N-butylethanimidoyl)-4-hydroxy-2H-chromen-2-one [31].
The fluorescence intensity of FM1-43 dye in nerve terminals was calculated via the following formula: (ΔF = FROI − Fback), where FROI is the average pixel intensity at a particular synapse and Fback is the fluorescence intensity of the background component defined in a 4 × 30 μm2 region outside the nerve terminals. The initial value of nerve terminal fluorescence, ΔFmax, was taken as 100%, and all other values were normalized to it as described previously [32].
The fluorescence signal was captured via an imaging system that included an Olympus BX-51 microscope equipped with a ×40 water-immersion objective (Olympus, Tokyo, Japan). The unloading of FM1-43-labeled synapses was recorded with a high-sensitivity RedShirtImaging NeuroCCD-smq camera (RedShirtImaging, Decatur, GA, USA). A Polychrome V light source (Till Photonics, Munich, Germany) was used at a wavelength of 488 nm. For data acquisition, we utilized Turbo-SM software (version 4.2.0.2, RedShirtImaging, Decatur, GA, USA).

2.5. Statistics

OriginLab 2021b software was used for statistical analysis. The data are presented as the means ± standard errors of the means (SEMs). The sample size (n) is the number of independent neuromuscular junctions obtained from 4 to 6 individual animals; ‘n’ is indicated in each figure legend.
The sample size required for an individual set of experiments was preassessed via power analysis (set at 80% and α = 0.05). There were no exclusions from outliers. Significance was assessed by the Mann–Whitney U test. * p < 0.05, ** p < 0.01 and *** p < 0.001 were considered statistically significant compared with control values, and # p < 0.05, ## p < 0.01 and ### p < 0.001 were considered statistically significant compared with prior treatment with inhibitor/blocker values.

3. Results

3.1. GABAB–Rs Mediate the Modulation of EPP Quantal Content in Newborn, Young and Adult Mice

We found that, e the application of the GABAB–R blocker CGP 55845 (5 μM) caused an increase in EPP QC of 33 ± 7% (p < 0.001) in the LAL of P2-aged mice, whereas the GABAB–R agonist baclofen (10 μM) caused a decrease in the QC of EPP of 50.9 ± 3.9% (p < 0.001; Figure 1). Hence, at the NMJs of P2-aged mice, stimulation of the motor nerve, in addition to ACh release, causes the secretion of GABA and the activation of GABAB–R, which triggers depression of ACh release.
Next, we studied the involvement of the α7 nAChR in the GABAB–R-mediated pathway of ACh release regulation in neonates. In the LAL muscle, the α7 nAChR blocker MLA (10 nM) had an effect similar to that of CGP 55845 (now on interchangeably used with the abbreviation CGP). Blockade of α7 nAChR significantly increased the QC of EPPs by 21.9 ± 6.9% (p < 0.05) in P2-aged mice (Figure 1). However, after the blockade of α7 nAChR, the blockade of GABAB–R with CGP 55845 had no effect on the QC of EPP (Figure 1). Thus, the pathway of ACh release regulation, mediated by α7/GABAB–R, is active in newborn animals at P2.
Unlike in neonates, in the LAL muscles of adult two-month-old (P60) mice, blockade of GABAB–R with CGP (5 μM) had no effect on the QC of the EPP. However, the application of the GABAB–R agonist baclofen (10 μM) significantly decreased the QC of EPP by 23.9 ± 3.4% (p < 0.001; Figure 1). The absence of the effect of CGP along with the decrease in the QC of the EPP upon application of baclofen were previously shown for the rat diaphragm muscle [6]. Thus, in adults, the GABAB–R-mediated pathway is less active than it is in neonates.
It can be assumed that the “silencing” of the pathway of ACh release regulation mediated by α7/GABAB–R already occurs in the neonatal period. Most likely, at the end of the process of remodeling, e.g., the transition of polyneuronal to mononeuronal innervation of the muscle fiber. Postnatal maturation of the NMJ occurs in several stages. However, it is generally accepted that by postnatal day 14 (P14), the morphology of the NMJ is mature [33].
Indeed, our experiments revealed that at P14, NMJs of LAL show no signs of downregulation of ACh release through the GABAB–R mediated pathway. We found the opposite effect of GABAB–R activation on ACh release. The application of the GABAB–R antagonist CGP 55845 (5 μM) decreased the EPP QC by 29.5 ± 3.9% (p < 0.001) in the LAL of P14 mice (Figure 1). The application of the GABAB–R agonist baclofen (10 μM) significantly increased the QC of EPP by 29.4 ± 6.3% (p < 0.001). Importantly, the blockade of α7 nAChR with MLA (10 nM) had no effect on EPP QC in P14 NMJs (Figure 1). Thus, α7 nAChR does not participate in the GABAB–R-mediated pathway of increasing ACh release.

3.2. GABAB-R-Mediated Potentiation of ACh Release at the NMJ of Young Mice Occurs via the Inhibition of N-Type Calcium Channels and Small-Conductance Calcium Ion-Activated Potassium Ion Channels

What could be the mechanism by which increasing ACh release is mediated by the activation of GABAB–R? In adult rats, GABA application reduces the QC of EPPs via the participation of phospholipase C (PLC) [6]. However, the activation of PLC can also lead to an increase in ACh release. It has been shown that the activation of PLC can decrease tetanic depression at the frog NMJ [34]. However, we have shown that application of the PLC inhibitor U-73122 (5 μM) did not lead to a significant decrease in the effect of baclofen (10 μM) on ACh release (Figure 2). After the inhibition of PLC, baclofen increased the EPP QC at the NMJ of P14 mice by 31.3 ± 5.4% (p < 0.001). Thus, PLC is not involved in the pathway of increased ACh release mediated by the activation of GABAB–R.
The activation of GABAB–R can increase neurotransmitter release through a decrease in adenylyl cyclase (AC) activity, which reduces the activity of small-conductance calcium ion-activated potassium ion (SK) channels [35]. Indeed, the blockade of SK channels by apamin (100 nM) did not significantly affect ACh release; however, it prevented the increase in the EPP QC caused by baclofen (Figure 2). Decreased potassium outflow through SK channels increases the duration of nerve action potentials, leading to increased neurotransmitter secretion [36]. To test the involvement of AC, its selective inhibitor SQ22536 (100 μM) was used. Pretreatment with SQ22536 did not prevent the increase in QC induced by baclofen, as the QC increased by 27.2 ± 4.6% (p < 0.001). Thus, SK channels but not ACs are involved in the pathway of increasing the EPP QC, which is mediated by the activation of GABAB–R.
The activation of G protein-coupled receptors causes the dissociation of Gα and Gβγ heterodimers [37]. Gβγ can directly bind to the Cav2 subunit of N-, P/Q- and R-type voltage-gated calcium ion channels. The interaction of Cav2 with Gβγ caused channel inhibition [38]. It can be speculated that the GABAB–R activation may decrease the activity of SK potassium channels if they are coupled to Cav2-containing calcium ion channels. A similar mechanism of GABA-mediated excitation of release involving GABAB–R, N-type calcium channels coupled to conductance potassium ion (BK) channels has been previously described in rat retinal ganglion cells [39].
To test the hypothesis of the involvement of N-type calcium channels, we studied the effect of baclofen on the QC of EPP after the blockade of these calcium channels with the ω-conotoxin GVIA. The application of ω-conotoxin GVIA (1 μM) alone significantly increased the EPP QC to 28.9 ± 9.3% (p < 0.01) in P14 mice. However, the application of baclofen after the blockade of N-type calcium ion channels did not increase but rather significantly decreased the QC at the NMJs of P14 mice (Figure 2). Importantly, the effect of ω-conotoxin GVIA on the QC of EPP was not observed after the blockade of SK channels with apamin (Figure 2). Thus, at P14, the activation of GABAB–R leads to the inhibition of N-type calcium ion channels, which is likely functionally coupled with SK channels. A decrease in potassium outflow prolongs the process of depolarization of nerve endings, which leads to an increase in the release of ACh. Notably, if N-type calcium channels are blocked with the ω-conotoxin GVIA, the “silencing” pathway of ACh release downregulation can be activated at the NMJs of P14-aged mice. Thus, it can be postulated that there is a mechanism for the occlusion of this pathway when the GABAB–R pathway of ACh release augmentation is active.

3.3. Fluorescence Assays of Acetylcholine Release/Regulated Exocytosis from Motor Nerves of Newborn (P2) or Young (P14) Mice After GABAB–R Inhibition

To confirm the bidirectional effects of GABAB–R blockade on ACh release at P2 and P14, we performed experiments to assess the extent regulated exocytosis and hence ACh release via the fluorescent marker of recycled synaptic vesicles FM 1-43.
In control experiments on the LAL of P2 mice, stimulation of the motor nerve led to a decrease in the fluorescence level to 79.7% of the initial level at 5 min (Figure 3). In the presence of a GABAB-R blocker (CGP 55845, 5 μM), the rate of FM 1-43 destaining of the nerve terminal accelerated (significantly from 90 s), thereby releasing 9.1 ± 2.5% (p < 0.01) more dye at 150 s than in the control and 8.5 ± 4.1% (p < 0.01) more dye at 300 s; after 5 min, the fluorescence level decreased to 69.1% (p < 0.01) (Figure 3). These data indicate an increase in the process of evoked/regulated exocytosis of synaptic vesicles after blockade of GABAB–R.
At the age of P14, the control value of FMs 1-43 destaining of the LAL nerve terminals by the end of 5 min was 49.1% (Figure 3). The application of CGP 55845 (5 μM) did not increase, but rather decreased the rate of destaining and released 10.2 ± 3.4% (p < 0.01) less dye at 150 s and 6.7 ± 3.5% (p < 0.01) less dye at 300 s than the control. A statistically significant difference in the dynamics of destaining was reliably detected from the 10th second of stimulation; after 5 min, the fluorescence level decreased to 56.4% (p < 0.01; Figure 3). These data may indicate a weakening of the process of evoked exocytosis of synaptic vesicles during blockade of GABAB–R.
Thus, the fluorescence microscopy data confirmed the data of electrophysiological experiments on the bidirectional effect of GABAB–R activation on ACh release at P2 and P14.

4. Discussion

GABA is an inhibitory neurotransmitter in the central and peripheral nervous systems. Therefore, pathways regulating neurotransmitter secretion that involve GABA receptors are aimed mainly at decreasing release. However, a number of studies have shown that the activation of GABAB–R can increase secretion through the inhibition of BK-type [39], SK-type [35], or both types of these potassium ion channels [40].
The initial goal of this study was to test the hypothesis that the α7/GABAB–R pathway downregulates ACh release at the NMJ during early ontogenesis. The effect of the α7/GABAB–R-mediated decrease in ACh release was detected at the NMJs of the mice on the second day after birth. However, unexpectedly, during postnatal development, another GABAB–R-mediated pathway that increases ACh release and does not involve the α7 nAChR is also active. On the 14th day after birth, activation of GABAB–R has been shown to decrease the activity of N-type voltage-gated calcium ion channels. The presence of this type of calcium ion channel in the neonatal NMJ has been previously described [41], but its role remains unknown. However, we have shown that N-type calcium ion channels are likely coupled with SK potassium ion channels. It is assumed that the inhibition of N-type calcium channels can decrease the activity of potassium ion channels, which can explain the increase in ACh release (Figure 4). The intracellular mechanisms of decreased ACh release at NMJs in P2 mice remain unknown and require further research. Thus, further studies employing genetic, molecular and cellular tools would help to unambiguously delineate the pathway underlying GABAB–R modulation of ACh release at the NMJ.
Muscarinic AChRs and adenosine receptors [42,43] are known to be involved in the regulation of ACh release at the newborn NMJ. In newborn animals, skeletal muscle fibers are innervated by several competing axons. During the first two weeks after birth, the NMJ remodeling process occurs, ending with the “victory” of one of the nerve endings and the elimination of others [44]. A high level of ACh release from a nerve terminal is one of the key factors determining the “winning” terminal [45]. The pathways of ACh release regulation activated by muscarinic AChRs or adenosine receptors provide competitive interactions between nerve endings. More active endings can directly “punish” less active endings by additionally suppressing ACh release or “rewarding” themselves [46].
The morphological effects of GABAB–R activation on early postnatal neuromuscular development have been previously described. The myelination of the motor nerve starts after the end of NMJ remodeling [47]. GABAB–Rs are expressed in premyelinating Schwann cells along the motor nerve and are downregulated from P0 to P15 [48]. Baclofen decreases the synthesis of myelin proteins in pure cultures of Schwann cells from neonatal rats [49]. Thus, activation of GABAB–R delays myelination of the motor nerve in the early postnatal period.
The origin of GABA is not fully understood. Sources can include nerve terminals, TSCs, muscle fibers, or blood plasma (Figure 4). There is immunohistochemical evidence of the presence of GABA, glutamate decarboxylase (the enzyme involved in the synthesis of GABA), GABAB–R, and GABA transporters (GAT-1, GAT-2) at NMJs in adult animals [18,50,51]. A comprehensive gene expression profile of TSCs and triceps brachii muscle in adult mice revealed that glutamate decarboxylases (Gad1 and Gad2) and GABA transporters (Best1, Slc6a1, Slc6a11 and Slc6a12) were enriched in TSCs [18]. Thus, GABA can be synthesized in the area of NMJs and released during neuromuscular synaptic transmission via GABA transporters and Bestrophin1, a Ca2+-activated anion channel [52].
The involvement of GABA in neuromuscular synaptic transmission in neonates has been described recently [18], and its physiological contribution is not fully understood. Petrov et al. reported that the GABAB–R blocker CGP 55845 significantly increases the decrease in the force of diaphragm muscle contraction in P1 mice ex vivo [18]. Thus, in the first days after birth, decreased ACh release can contribute to fatigue resistance.
Mouse muscle nAChRs undergo a developmental switch in subunit composition in the first two weeks after birth [33]. Fetal muscle receptors are designed to function at low ACh concentrations. Therefore, they have high sensitivity to ACh but are easily desensitized in the presence of high concentrations [53]. This contrasts with adult receptors, which are ideally tailored for robust and reproducible high-frequency neuromuscular transmission at mature synapses, where ACh reaches millimolar concentrations [54]. We hypothesize that a partial reduction in release via this GABA-mediated pathway can prevent ACh from overrun in the synaptic cleft during polyneuronal innervation (Figure 5A). In the first days after birth, before the competition between nerve endings begins, full rerelease of ACh from 3–4 nerve endings may be too excessive. A partial reduction in release via this GABA-mediated pathway can prevent excess ACh and desensitization. Moreover, for example, excessive recruitment of a readily releasable pool of synaptic vesicles can be prevented. This hypothesis is consistent with results previously obtained in adult mice [18]. As mentioned above, in adult mice, the effect of endogenous GABA was detected only when ChE was inhibited (Figure 5C). An excess of ACh in the synaptic cleft due to ChE inhibition triggered a decrease in ACh release, which was mediated by GABAB–R. Notably, GABAB–R blockade reduces fatigue in diaphragm muscles treated with a ChE inhibitor [18]. Thus, the effect of the GABAB–R blocker on muscle fatigue is similar in neonatal mice with intact ChE and in adults with inhibited ChE. However, the participation of this pathway in the process of communication between competing nerve endings cannot be excluded.
In the first two postnatal weeks, the NMJ of newborn animals undergoes cardinal structural and functional reorganizations. By the age of P14, the remodeling process is complete, and the morphology of all NMJ components generally corresponds to that of adult animals, but there are also differences [33,55]. During this period of postnatal development, the diameter and length of muscle fibers rapidly increase, which is accompanied by a change in their electrical properties. Intercalary growth of synaptic contacts is required to maintain the reliability of synaptic transmission. This process is crucial for NMJ enlargement during development and in response to increased neuromuscular activity [56]. This ensures that the pre-synaptic and post-synaptic specializations grow and maintain a precise correspondence as the muscle fiber itself grows. During this period, new postsynaptic folds and new sites of ACh release are intensively formed in NMJ synapses [57]. The activation of the GABA-mediated pathway of ACh release augmentation correlates with this “adolescent” period of postnatal development. It can be assumed that this pathway contributes to ensuring the safety of synaptic transmission during the period of intercalary growth of NMJs (Figure 5B).

5. Conclusions

GABA may be an important, previously unaccounted player in the process of postnatal maturation of the NMJ. In this study, we describe the bidirectional regulation of ACh release at the NMJ in newborn and young animals, which is mediated by metabotropic GABA receptors. During postnatal development, some GABA-mediated ACh release regulatory pathways are activated, whereas others are occluded. This may indicate that each process plays a significant physiological role.

Author Contributions

Conceptualization, K.P., A.M. and V.P.; investigation, E.N., G.S. and D.S.; writing—original draft preparation, V.P., A.M. and K.P. All authors have read and agreed to the published version of the manuscript.

Funding

This work was supported by the Russian Science Foundation (project No. 24-15-00249) for E.N., A.M. and K.P.

Institutional Review Board Statement

The study was conducted in accordance with the Declaration of Helsinki and was approved by the Animal Care and Use Committee of the FRC Kazan Scientific Center of RAS (protocol #23/7; 12 May 2023).

Informed Consent Statement

Not applicable.

Data Availability Statement

All data and materials are available in the article or upon request to the corresponding authors.

Acknowledgments

V.P. is a Cheung Kong (Yangtze River) Scholar, Ministry of Education, China; Kun Peng Action Expert, Zhejiang Province, China; Professor (voluntary) at The University of Alabama at Birmingham, USA; and an Honorary Professor (voluntary) at the University of Rijeka, Croatia. G.S. and D.S. are grateful for assignment for Kazan Institute of Biochemistry and Biophysics, FRC Kazan Scientific Center of Russian Academy of Sciences.

Conflicts of Interest

The authors declare that they have no conflicts of interest.

Abbreviations

The following abbreviations are used in this manuscript:
AChAcetylcholine
ACAdenylyl cyclase
BKBig conductance potassium ion channels
ChECholinesterase
CntrControl
EPPEnd-plate potential
FM1-43N- (3-triethylammoniumpropyl)-4- (4- (dibutylamino) styryl) pyridinium dibromide
GABAγ -aminobutyric acid
GABAB–RGABAB receptor
LALLevator auris longus
NMJNeuromuscular junction
MLAMethyllycaconitine
nAChRNicotinic acetylcholine receptor
PLCPhospholipase C
PPostnatal day
QCQuantal content
SKSmall-conductance calcium ion-activated potassium ion channels
mEPPMiniature end-plate potential
SDStandard deviation
SEStandard error
TSCTerminal Schwann cell

References

  1. Peerboom, C.; Wierenga, C.J. The postnatal GABA shift: A developmental perspective. Neurosci. Biobehav. Rev. 2021, 124, 179–192. [Google Scholar] [CrossRef]
  2. Siucinska, E. Γ-Aminobutyric acid in adult brain: An update. Behav. Brain Res. 2019, 376, 112224. [Google Scholar] [CrossRef] [PubMed]
  3. Shaye, H.; Stauch, B.; Gati, C.; Cherezov, V. Molecular mechanisms of metabotropic GABAB receptor function. Sci. Adv. 2021, 7, eabg3362. [Google Scholar] [CrossRef]
  4. Gassmann, M.; Bettler, B. Regulation of neuronal GABA(B) receptor functions by subunit composition. Nat. Rev. Neurosci. 2012, 13, 380–394. [Google Scholar] [CrossRef]
  5. Deng, P.Y.; Xiao, Z.; Yang, C.; Rojanathammanee, L.; Grisanti, L.; Watt, J.; Geiger, J.D.; Liu, R.; Porter, J.E.; Lei, S. GABA(B) receptor activation inhibits neuronal excitability and spatial learning in the entorhinal cortex by activating TREK-2 K+ channels. Neuron 2009, 63, 230–243. [Google Scholar] [CrossRef] [PubMed]
  6. Malomouzh, A.I.; Petrov, K.A.; Nurullin, L.F.; Nikolsky, E.E. Metabotropic GABAB receptors mediate GABA inhibition of acetylcholine release in the rat neuromuscular junction. J. Neurochem. 2015, 135, 1149–1160. [Google Scholar] [CrossRef]
  7. Tomàs, J.; Santafé, M.M.; Garcia, N.; Lanuza, M.A.; Tomàs, M.; Besalduch, N.; Obis, T.; Priego, M.; Hurtado, E. Presynaptic membrane receptors in acetylcholine release modulation in the neuromuscular synapse. J. Neurosci. Res. 2014, 92, 543–554. [Google Scholar] [CrossRef]
  8. Petrov, K.A.; Nikolsky, E.E.; Masson, P. Autoregulation of Acetylcholine Release and Micro-Pharmacodynamic Mechanisms at Neuromuscular Junction: Selective Acetylcholinesterase Inhibitors for Therapy of Myasthenic Syndromes. Front. Pharmacol. 2018, 9, 766. [Google Scholar] [CrossRef] [PubMed]
  9. Santafe, M.M.; Priego, M.; Obis, T.; Garcia, N.; Tomàs, M.; Lanuz, M.A.; Tomàs, J. Adenosine receptors and muscarinic receptors cooperate in acetylcholine release modulation in the neuromuscular synapse. Eur. J. Neurosci. 2015, 42, 1775–1787. [Google Scholar] [CrossRef]
  10. Ribeiro, J.A.; Cunha, R.A.; Correia-de-Sá, P.; Sebastião, A.M. Purinergic regulation of acetylcholine release. Prog. Brain Res. 1996, 109, 231–241. [Google Scholar]
  11. Sousa-Soares, C.; Noronha-Matos, J.B.; Correia-de-Sá, P. Purinergic Tuning of the Tripartite Neuromuscular Synapse. Mol. Neurobiol. 2023, 60, 4084–4104. [Google Scholar] [CrossRef] [PubMed]
  12. Giniatullin, A.R.; Mukhutdinova, K.A.; Petrov, A.M. Mechanism of Purinergic Regulation of Neurotransmission in Mouse Neuromuscular Junction: The Role of Redox Signaling and Lipid Rafts. Neurochem. Res. 2024, 49, 2021–2037. [Google Scholar] [CrossRef]
  13. Petrov, A.M.; Zakirjanova, G.F.; Kovyazina, I.V.; Tsentsevitsky, A.N.; Bukharaeva, E.A. Adrenergic receptors control frequency-dependent switching of the exocytosis mode between “full-collapse” and “kiss-and-run” in murine motor nerve terminal. Life Sci. 2022, 296, 120433. [Google Scholar] [CrossRef]
  14. Gaydukov, A.; Bogacheva, P.; Tarasova, E.; Molchanova, A.; Miteva, A.; Pravdivceva, E.; Balezina, O. Regulation of Acetylcholine Quantal Release by Coupled Thrombin/BDNF Signaling in Mouse Motor Synapses. Cells 2019, 8, 762. [Google Scholar] [CrossRef]
  15. Bogacheva, P.O.; Molchanova, A.I.; Pravdivceva, E.S.; Miteva, A.S.; Balezina, O.P.; Gaydukov, A.E. ProBDNF and Brain-Derived Neurotrophic Factor Prodomain Differently Modulate Acetylcholine Release in Regenerating and Mature Mouse Motor Synapses. Front. Cell. Neurosci. 2022, 16, 866802. [Google Scholar] [CrossRef]
  16. Tarasova, E.; Bogacheva, P.; Chernyshev, K.; Balezina, O. Quantal size increase induced by the endocannabinoid 2-arachidonoylglycerol requires activation of CGRP receptors in mouse motor synapses. Synapse 2024, 78, e22281. [Google Scholar] [CrossRef] [PubMed]
  17. Petrov, K.A.; Girard, E.; Nikitashina, A.D.; Colasante, C.; Bernard, V.; Nurullin, L.; Leroy, J.; Samigullin, D.; Colak, O.; Nikolsky, E.; et al. Schwann cells sense and control acetylcholine spillover at the neuromuscular junction by α7 nicotinic receptors and butyrylcholinesterase. J. Neurosci. 2014, 34, 11870–11883. [Google Scholar] [CrossRef]
  18. Petrov, K.; Lenina, O.; Leroy, J.; Bernard, V.; Germain, T.; Truong, C.; Nurullin, L.; Sibgatullina, G.; Ohno, K.; Samigullin, D.; et al. An α7 nicotinic and GABAB receptor-mediated pathway controls acetylcholine release in the tripartite neuromuscular junction. J. Physiol. 2025, 603, 507–527. [Google Scholar] [CrossRef] [PubMed]
  19. Angaut-Petit, D.; Molgo, J.; Connold, A.L.; Faille, L. The levator auris longus muscle of the mouse: A convenient preparation for studies of short- and long-term presynaptic effects of drugs or toxins. Neurosci. Lett. 1987, 82, 83–88. [Google Scholar] [CrossRef]
  20. Benedetti, B.; Matyash, V.; Kettenmann, H. Astrocytes control GABAergic inhibition of neurons in the mouse barrel cortex. J. Physiol. 2011, 589 Pt 5, 1159–1172. [Google Scholar] [CrossRef]
  21. Liu, Y.B.; Guo, J.Z.; Chiappinelli, V.A. Nicotinic receptor-mediated biphasic effect on neuronal excitability in chick lateral spiriform neurons. Neuroscience 2007, 148, 1004–1014. [Google Scholar] [CrossRef]
  22. Fucile, S.; Sucapane, A.; Eusebi, F. Ca2+ permeability of nicotinic acetylcholine receptors from rat dorsal root ganglion neurones. J. Physiol. 2005, 565 Pt 1, 219–228. [Google Scholar] [CrossRef]
  23. Liou, J.C.; Kang, K.H.; Chang, L.S.; Ho, S.Y. Mechanism of beta-bungarotoxin in facilitating spontaneous transmitter release at neuromuscular synapse. Neuropharmacology 2006, 51, 671–680. [Google Scholar] [CrossRef]
  24. Kato, M.; Tanaka, N.; Usui, S.; Sakuma, Y. The SK channel blocker apamin inhibits slow afterhyperpolarization currents in rat gonadotropin-releasing hormone neurones. J. Physiol. 2006, 574 Pt 2, 431–442. [Google Scholar] [CrossRef]
  25. Dibattista, M.; Mazzatenta, A.; Grassi, F.; Tirindelli, R.; Menini, A. Hyperpolarization-activated cyclic nucleotide-gated channels in mouse vomeronasal sensory neurons. J. Neurophysiol. 2008, 100, 576–586. [Google Scholar] [CrossRef] [PubMed]
  26. Massote, P.D.; Pinheiro, A.C.; Fonseca, C.G.; Prado, M.A.; Guimarães, A.L.; Massensini, A.R.; Gomez, M.V. Protective effect of retinal ischemia by blockers of voltage-dependent calcium channels and intracellular calcium stores. Cell Mol. Neurobiol. 2008, 28, 847–856. [Google Scholar] [CrossRef] [PubMed]
  27. Bazzy, A.R. Developmental changes in rat diaphragm endplate response to repetitive stimulation. Brain research. Dev. Brain Res. 1994, 81, 314–317. [Google Scholar] [CrossRef]
  28. Bogacheva, P.O.; Potapova, D.A.; Gaydukov, A.E. Sortilin and L-type Calcium Channels May be Involved in the Unusual Mechanism of proBDNF Signaling in Regenerating Mouse Neuromuscular Junctions. Neurochem. Res. 2025, 50, 104. [Google Scholar] [CrossRef] [PubMed]
  29. McLachlan, E.M.; Martin, A.R. Non-linear summation of end-plate potentials in the frog and mouse. J. Physiol. 1981, 311, 307–324. [Google Scholar] [CrossRef]
  30. Betz, W.J.; Bewick, G.S. Optical analysis of synaptic vesicle recycling at the frog neuromuscular junction. Science 1992, 255, 200–203. [Google Scholar] [CrossRef]
  31. Heredia, D.J.; Schubert, D.; Maligireddy, S.; Hennig, G.W.; Gould, T.W. A Novel Striated Muscle-Specific Myosin-Blocking Drug for the Study of Neuromuscular Physiology. Front. Cell. Neurosci. 2016, 10, 276. [Google Scholar] [CrossRef]
  32. Gafurova, C.R.; Tsentsevitsky, A.N.; Fedorov, N.S.; Khaziev, A.N.; Malomouzh, A.I.; Petrov, A.M. β2-Adrenergic Regulation of the Neuromuscular Transmission and Its Lipid-Dependent Switch. Mol. Neurobiol. 2024, 61, 6805–6821. [Google Scholar] [CrossRef] [PubMed]
  33. Sanes, J.R.; Lichtman, J.W. Development of the vertebrate neuromuscular junction. Annu. Rev. Neurosci. 1999, 22, 389–442. [Google Scholar] [CrossRef] [PubMed]
  34. Silveira, P.E.; Lima, R.F.; Guimarães, J.D.; Molgó, J.; Naves, L.A.; Kushmerick, C. Ryanodine and inositol triphosphate receptors modulate facilitation and tetanic depression at the frog neuromuscular junction. Muscle Nerve 2015, 52, 623–630. [Google Scholar] [CrossRef] [PubMed]
  35. Estep, C.M.; Galtieri, D.J.; Zampese, E.; Goldberg, J.A.; Brichta, L.; Greengard, P.; Surmeier, D.J. Transient Activation of GABAB Receptors Suppresses SK Channel Currents in Substantia Nigra Pars Compacta Dopaminergic Neurons. PLoS ONE 2016, 11, e0169044. [Google Scholar] [CrossRef]
  36. Stocker, M. Ca(2+)-activated K+ channels: Molecular determinants and function of the SK family. Nature reviews. Neuroscience 2004, 5, 758–770. [Google Scholar]
  37. Oldham, W.M.; Hamm, H.E. Heterotrimeric G protein activation by G-protein-coupled receptors. Nature reviews. Mol. Cell Biol. 2008, 9, 60–71. [Google Scholar]
  38. Zamponi, G.W.; Currie, K.P. Regulation of Ca(V)2 calcium channels by G protein coupled receptors. Biochim. Et Biophys. Acta 2013, 1828, 1629–1643. [Google Scholar] [CrossRef]
  39. Bogaj, K.; Urban-Ciecko, J. Inhibition of BK channels by GABAb receptors enhances intrinsic excitability of layer 2/3 vasoactive intestinal polypeptide-expressing interneurons in mouse neocortex. J. Physiol. 2025, 603, 1171–1196. [Google Scholar] [CrossRef]
  40. Ramakrishna, Y.; Sadeghi, S.G. Activation of GABAB receptors results in excitatory modulation of calyx terminals in rat semicircular canal cristae. J. Neurophysiol. 2020, 124, 962–972. [Google Scholar] [CrossRef]
  41. Rosato Siri, M.D.; Uchitel, O.D. Calcium channels coupled to neurotransmitter release at neonatal rat neuromuscular junctions. J. Physiol. 1999, 514 Pt 2, 533–540. [Google Scholar] [CrossRef]
  42. Nadal, L.; Garcia, N.; Hurtado, E.; Simó, A.; Tomàs, M.; Lanuza, M.A.; Cilleros, V.; Tomàs, J.M. Synergistic Action of Presynaptic Muscarinic Acetylcholine Receptors and Adenosine Receptors in Developmental Axonal Competition at the Neuromuscular Junction. Dev. Neurosci. 2016, 38, 407–419. [Google Scholar] [CrossRef] [PubMed]
  43. Darabid, H.; St-Pierre-See, A.; Robitaille, R. Purinergic-Dependent Glial Regulation of Synaptic Plasticity of Competing Terminals and Synapse Elimination at the Neuromuscular Junction. Cell Rep. 2018, 25, 2070–2082.e6. [Google Scholar] [CrossRef] [PubMed]
  44. Thompson, W.J. Activity and synapse elimination at the neuromuscular junction. Cell. Mol. Neurobiol. 1985, 5, 167–182. [Google Scholar] [CrossRef] [PubMed]
  45. Colman, H.; Nabekura, J.; Lichtman, J.W. Alterations in synaptic strength preceding axon withdrawal. Science 1997, 275, 356–361. [Google Scholar] [CrossRef]
  46. Tomàs, J.; Garcia, N.; Lanuza, M.A.; Santafé, M.M.; Tomàs, M.; Nadal, L.; Hurtado, E.; Simó, A.; Cilleros, V. Presynaptic Membrane Receptors Modulate ACh Release, Axonal Competition and Synapse Elimination during Neuromuscular Junction Development. Front. Mol. Neurosci. 2017, 10, 132. [Google Scholar] [CrossRef]
  47. Wang, M.; Kleele, T.; Xiao, Y.; Plucinska, G.; Avramopoulos, P.; Engelhardt, S.; Schwab, M.H.; Kneussel, M.; Czopka, T.; Sherman, D.L.; et al. Completion of neuronal remodeling prompts myelination along developing motor axon branches. J. Cell Biol. 2021, 220, e201911114. [Google Scholar] [CrossRef]
  48. Corell, M.; Wicher, G.; Radomska, K.J.; Dağlıkoca, E.D.; Godskesen, R.E.; Fredriksson, R.; Benedikz, E.; Magnaghi, V.; Fex Svenningsen, A. GABA and its B-receptor are present at the node of Ranvier in a small population of sensory fibers, implicating a role in myelination. J. Neurosci. Res. 2015, 93, 285–295. [Google Scholar] [CrossRef]
  49. Magnaghi, V.; Ballabio, M.; Camozzi, F.; Colleoni, M.; Consoli, A.; Gassmann, M.; Lauria, G.; Motta, M.; Procacci, P.; Trovato, A.E.; et al. Altered peripheral myelination in mice lacking GABAB receptors. Mol. Cell. Neurosci. 2008, 37, 599–609. [Google Scholar] [CrossRef]
  50. Malomuzh, A.I.; Nurullin, L.F.; Nikolsky, E.E. Immunohistochemical Evidence of the Presence of Metabotropic Receptors for γ-Aminobutyric Acid at the Rat Neuromuscular Junctions. Dokl. Biochem. Biophys. 2015, 463, 236–238. [Google Scholar] [CrossRef]
  51. Nurullin, L.F.; Nikolsky, E.E.; Malomouzh, A.I. Elements of Molecular Machinery of GABAergic Signaling in the Vertebrate Cholinergic Neuromuscular Junction. Acta Histochem. 2018, 120, 298–301. [Google Scholar] [CrossRef]
  52. Kilb, W.; Kirischuk, S. GABA Release from Astrocytes in Health and Disease. Int. J. Mol. Sci. 2022, 23, 15859. [Google Scholar] [CrossRef]
  53. Nayak, T.K.; Chakraborty, S.; Zheng, W.; Auerbach, A. Structural correlates of affinity in fetal versus adult endplate nicotinic receptors. Nat. Commun. 2016, 22, 11352. [Google Scholar] [CrossRef]
  54. Li, H.; Teng, J.; Hibbs, R.E. Structural switch in acetylcholine receptors in developing muscle. Nature 2024, 632, 1174–1180. [Google Scholar] [CrossRef] [PubMed]
  55. Brown, M.C.; Jansen, J.K.; Van Essen, D. Polyneuronal innervation of skeletal muscle in new-born rats and its elimination during maturation. J. Physiol. 1976, 261, 387–422. [Google Scholar] [CrossRef] [PubMed]
  56. Balice-Gordon, R.J.; Lichtman, J.W. In vivo visualization of the growth of pre- and postsynaptic elements of neuromuscular junctions in the mouse. J. Neurosci. 1990, 10, 894–908. [Google Scholar] [CrossRef]
  57. Marques, M.J.; Conchello, J.A.; Lichtman, J.W. From plaque to pretzel: Fold formation and acetylcholine receptor loss at the developing neuromuscular junction. J. Neurosci. 2000, 20, 3663–3675. [Google Scholar] [CrossRef] [PubMed]
Cells 14 01949 g001
Figure 1. Involvement of GABAB–R in the regulation of ACh at LAL NMJs in neonatal (P2), young (P14) and adult (P60) mice. (A)—Representative EPPs recorded at the NMJs in the control (Cntr) and after the application of the GABAB–R blocker CGP 55845 (CGP, 5 μM) or the GABAB–R agonist baclofen (10 μM) at different stages of ontogenesis. (B)—Effects of GABAB–R ligands (CGP 55845 or baclofen) and an α7 nAChR antagonist (MLA, 10 nM) on the QC of EPPs upon 0.5 Hz motor nerve stimulation. The value of the QC in the control was taken as 100%. The data are presented as box plots: gray diamonds, relative changes in individual experiments; horizontal lines, M; whiskers, SD; boxes, SEM for the entire series of experiments (n = 28–56). n.s.—not significant, * p < 0.05 and *** p < 0.001—Mann–Whitney U test between the control and individual chemical groups.
Figure 1. Involvement of GABAB–R in the regulation of ACh at LAL NMJs in neonatal (P2), young (P14) and adult (P60) mice. (A)—Representative EPPs recorded at the NMJs in the control (Cntr) and after the application of the GABAB–R blocker CGP 55845 (CGP, 5 μM) or the GABAB–R agonist baclofen (10 μM) at different stages of ontogenesis. (B)—Effects of GABAB–R ligands (CGP 55845 or baclofen) and an α7 nAChR antagonist (MLA, 10 nM) on the QC of EPPs upon 0.5 Hz motor nerve stimulation. The value of the QC in the control was taken as 100%. The data are presented as box plots: gray diamonds, relative changes in individual experiments; horizontal lines, M; whiskers, SD; boxes, SEM for the entire series of experiments (n = 28–56). n.s.—not significant, * p < 0.05 and *** p < 0.001—Mann–Whitney U test between the control and individual chemical groups.
Cells 14 01949 g001
Cells 14 01949 g002
Figure 2. The mechanism of the ACh release-potentiating effect of GABAB–R activation at NMJs of young (P14) mice. Effect of the GABAB–R agonist baclofen (Bacl, 10 μM) on the QC of EPPs against the background of the phospholipase C (PLC) inhibitor U-73122 (5 μM), the small-conductance calcium ion-activated potassium ion (SK) channel blocker apamin (100 nM), the adenylate cyclase (AC) inhibitor SQ 22536 (100 μM) and the N-type Ca2+ channel blocker ω-conotoxin GVIA (ω-Ctx, 1 μM). The values of the QC in the control were taken as 100%. In the experiments with Bacl, the values obtained in the presence of blockers were taken as 100%. In the Apamin + ω-Ctx experiments, the values obtained in the presence of blocker SK channels were taken as 100%. The data are presented as box plots: gray diamonds, relative changes in individual experiments; horizontal lines, M; whiskers, SD; boxes, SEM for the entire series of experiments (n = 38–43). n.s.—not significant and * p < 0.05 vs. control values; ## p < 0.01 and ### p < 0.001 vs. values for Bacl compared with the effect of preincubation with blockers or inhibitors (Mann–Whitney U test).
Figure 2. The mechanism of the ACh release-potentiating effect of GABAB–R activation at NMJs of young (P14) mice. Effect of the GABAB–R agonist baclofen (Bacl, 10 μM) on the QC of EPPs against the background of the phospholipase C (PLC) inhibitor U-73122 (5 μM), the small-conductance calcium ion-activated potassium ion (SK) channel blocker apamin (100 nM), the adenylate cyclase (AC) inhibitor SQ 22536 (100 μM) and the N-type Ca2+ channel blocker ω-conotoxin GVIA (ω-Ctx, 1 μM). The values of the QC in the control were taken as 100%. In the experiments with Bacl, the values obtained in the presence of blockers were taken as 100%. In the Apamin + ω-Ctx experiments, the values obtained in the presence of blocker SK channels were taken as 100%. The data are presented as box plots: gray diamonds, relative changes in individual experiments; horizontal lines, M; whiskers, SD; boxes, SEM for the entire series of experiments (n = 38–43). n.s.—not significant and * p < 0.05 vs. control values; ## p < 0.01 and ### p < 0.001 vs. values for Bacl compared with the effect of preincubation with blockers or inhibitors (Mann–Whitney U test).
Cells 14 01949 g002
Cells 14 01949 g003
Figure 3. Effect of the GABAB-R blocker CGP 55845 (5 μM) on exocytotic dye release from FM1-43-preloaded motor nerves of the LAL of newborn (P2, panel (A)) and young (P14, panel (B)) mice. (Top)—kinetics of exocytotic FM 1-43 dye release from motor nerve terminals in control (Cntr, black) and CGP-treated nerve-muscle preparations (CGP, blue). The inset shows typical fluorescence images of NMJs before the onset (0) and at 300 s of stimulation in the control and in the presence of CGP 55845. Scale bars, 15 µm. (Bottom)—the portion of dye fluorescence loss during 150 s and 300 s of stimulation at 30 Hz in control (Cntr; n = 12–17) and CGP-treated nerve terminals (n = 13–14). ** p < 0.01 vs. control values.
Figure 3. Effect of the GABAB-R blocker CGP 55845 (5 μM) on exocytotic dye release from FM1-43-preloaded motor nerves of the LAL of newborn (P2, panel (A)) and young (P14, panel (B)) mice. (Top)—kinetics of exocytotic FM 1-43 dye release from motor nerve terminals in control (Cntr, black) and CGP-treated nerve-muscle preparations (CGP, blue). The inset shows typical fluorescence images of NMJs before the onset (0) and at 300 s of stimulation in the control and in the presence of CGP 55845. Scale bars, 15 µm. (Bottom)—the portion of dye fluorescence loss during 150 s and 300 s of stimulation at 30 Hz in control (Cntr; n = 12–17) and CGP-treated nerve terminals (n = 13–14). ** p < 0.01 vs. control values.
Cells 14 01949 g003
Cells 14 01949 g004
Figure 4. Scheme of the GABAB–R-mediated ACh release augmentation pathway at NMJs in P14 mice. SK channels on the membrane at the motor nerve ending are activated by Ca2+ entering through N-type calcium channels. The activation of GABAB–R reduces the activity of N-type calcium channels and, consequently, the activity of SK channels. A decrease in potassium outflow prolongs the process of depolarization of the nerve ending, which leads to an increase in the release of ACh.
Figure 4. Scheme of the GABAB–R-mediated ACh release augmentation pathway at NMJs in P14 mice. SK channels on the membrane at the motor nerve ending are activated by Ca2+ entering through N-type calcium channels. The activation of GABAB–R reduces the activity of N-type calcium channels and, consequently, the activity of SK channels. A decrease in potassium outflow prolongs the process of depolarization of the nerve ending, which leads to an increase in the release of ACh.
Cells 14 01949 g004
Cells 14 01949 g005
Figure 5. Hypotheses about the physiological role of GABA-mediated ACh release at different stages of the NMJ ontogeny. (A) P2-aged mice. At this age, each muscle fiber is innervated by several motor neurons that release ACh equally. Over the next few days, competition between nerve endings begins, with a gradual decrease in release from the “losing” endings and their complete elimination. It can be assumed that at the age when competition has not yet begun (P2), ACh release is excessive. Therefore, mechanisms exist that prevent unnecessary ACh consumption or “flooding” of the NMJ by excess ACh. (B) P14-aged mice. At this age, the process of NMJ remodeling is complete, and muscle mass growth begins (shown by arrows). To maintain the reliability of synaptic transmission, an increase in muscle fiber diameter is accompanied by an increase in the NMJ area. However, morphological changes in the NMJ take time. It can be hypothesized that increased ACh release is used as an additional, rapid mechanism to maintain the reliability of synaptic transmission. (C) P60-aged mice. At this age, the effect of endogenous GABA is not detected if ChE is active. However, the application of GABA or GABAB–R agonists causes a decrease in the QC of EPP. Under conditions of inhibited ChE, an effect of endogenous GABA similar to that of a GABAB–R agonist is detected. It can be assumed that this pathway for regulating ACh release remains active in adult animals, for example, for fine tuning of synaptic transmission by ACh spillover. The possibility that this GABA-mediated regulatory pathway is activated by natural ChE inhibitors cannot be ruled out. Natural ChE inhibitors are found both in some plants (physostigmine, caffeine, etc.) and certain snake venoms (fasciculin).
Figure 5. Hypotheses about the physiological role of GABA-mediated ACh release at different stages of the NMJ ontogeny. (A) P2-aged mice. At this age, each muscle fiber is innervated by several motor neurons that release ACh equally. Over the next few days, competition between nerve endings begins, with a gradual decrease in release from the “losing” endings and their complete elimination. It can be assumed that at the age when competition has not yet begun (P2), ACh release is excessive. Therefore, mechanisms exist that prevent unnecessary ACh consumption or “flooding” of the NMJ by excess ACh. (B) P14-aged mice. At this age, the process of NMJ remodeling is complete, and muscle mass growth begins (shown by arrows). To maintain the reliability of synaptic transmission, an increase in muscle fiber diameter is accompanied by an increase in the NMJ area. However, morphological changes in the NMJ take time. It can be hypothesized that increased ACh release is used as an additional, rapid mechanism to maintain the reliability of synaptic transmission. (C) P60-aged mice. At this age, the effect of endogenous GABA is not detected if ChE is active. However, the application of GABA or GABAB–R agonists causes a decrease in the QC of EPP. Under conditions of inhibited ChE, an effect of endogenous GABA similar to that of a GABAB–R agonist is detected. It can be assumed that this pathway for regulating ACh release remains active in adult animals, for example, for fine tuning of synaptic transmission by ACh spillover. The possibility that this GABA-mediated regulatory pathway is activated by natural ChE inhibitors cannot be ruled out. Natural ChE inhibitors are found both in some plants (physostigmine, caffeine, etc.) and certain snake venoms (fasciculin).
Cells 14 01949 g005
Disclaimer/Publisher’s Note: The statements, opinions and data contained in all publications are solely those of the individual author(s) and contributor(s) and not of MDPI and/or the editor(s). MDPI and/or the editor(s) disclaim responsibility for any injury to people or property resulting from any ideas, methods, instructions or products referred to in the content.

Share and Cite

MDPI and ACS Style

Nevsky, E.; Sibgatullina, G.; Samigullin, D.; Malomouzh, A.; Parpura, V.; Petrov, K. Age-Dependent Regulation of Acetylcholine Release at the Neuromuscular Junction Mediated by GABA. Cells 2025, 14, 1949. https://doi.org/10.3390/cells14241949

AMA Style

Nevsky E, Sibgatullina G, Samigullin D, Malomouzh A, Parpura V, Petrov K. Age-Dependent Regulation of Acetylcholine Release at the Neuromuscular Junction Mediated by GABA. Cells. 2025; 14(24):1949. https://doi.org/10.3390/cells14241949

Chicago/Turabian Style

Nevsky, Egor, Guzel Sibgatullina, Dmitry Samigullin, Artem Malomouzh, Vladimir Parpura, and Konstantin Petrov. 2025. "Age-Dependent Regulation of Acetylcholine Release at the Neuromuscular Junction Mediated by GABA" Cells 14, no. 24: 1949. https://doi.org/10.3390/cells14241949

APA Style

Nevsky, E., Sibgatullina, G., Samigullin, D., Malomouzh, A., Parpura, V., & Petrov, K. (2025). Age-Dependent Regulation of Acetylcholine Release at the Neuromuscular Junction Mediated by GABA. Cells, 14(24), 1949. https://doi.org/10.3390/cells14241949

Note that from the first issue of 2016, this journal uses article numbers instead of page numbers. See further details here.

Article Metrics

Back to TopTop