The BAD-BAX-Caspase-3 Cascade Modulates Synaptic Vesicle Pools via Autophagy.

The BAD-BAX-caspase-3 cascade is a canonical apoptosis pathway. Macroautophagy ("autophagy" hereinafter) is a process by which organelles and aggregated proteins are delivered to lysosomes for degradation. Here, we report a new function of the BAD-BAX-caspase-3 cascade and autophagy in the control of synaptic vesicle pools. We found that, in hippocampal neurons of male mice, the BAD-BAX-caspase-3 pathway regulates autophagy, which in turn limits the size of synaptic vesicle pools and influences the kinetics of activity-induced depletion and recovery of synaptic vesicle pools. Moreover, the caspase-autophagy pathway is engaged by fear conditioning to facilitate associative fear learning and memory. This work identifies a new mechanism for controlling synaptic vesicle pools, and a novel, nonapoptotic, presynaptic function of the BAD-BAX-caspase-3 cascade.SIGNIFICANCE STATEMENT Despite the importance of synaptic vesicles for neurons, little is known about how the size of synaptic vesicle pools is maintained under basal conditions and regulated by neural activity. This study identifies a new mechanism for the control of synaptic vesicle pools, and a new, nonapoptotic function of the BAD-BAX-caspase-3 pathway in presynaptic terminals. Additionally, it indicates that autophagy is not only a homeostatic mechanism to maintain the integrity of cells and tissues, but also a process engaged by neural activity to regulate synaptic vesicle pools for optimal synaptic responses, learning, and memory.

Dysbindin-1 regulates mitochondrial fission and gamma oscillations.

Mitochondria are cellular ATP generators. They are dynamic structures undergoing fission and fusion. While much is known about the mitochondrial fission machinery, the mechanism of initiating fission and the significance of fission to neurophysiology are largely unclear. Gamma oscillations are synchronized neural activities that impose a great energy challenge to synapses. The cellular mechanism of fueling gamma oscillations has yet to be defined. Here, we show that dysbindin-1, a protein decreased in the brain of individuals with schizophrenia, is required for neural activity-induced fission by promoting Drp1 oligomerization. This process is engaged by gamma-frequency activities and in turn, supports gamma oscillations. Gamma oscillations and novel object recognition are impaired in dysbindin-1 null mice. These defects can be ameliorated by increasing mitochondrial fission. These findings identify a molecular mechanism for activity-induced mitochondrial fission, a role of mitochondrial fission in gamma oscillations, and mitochondrial fission as a potential target for improving cognitive functions.

NMDA receptor-dependent LTD is required for consolidation but not acquisition of fear memory.

NMDA receptor-dependent long-term depression (NMDAR-LTD) is a form of synaptic plasticity leading to long-lasting decreases in synaptic strength. NMDAR-LTD is essential for spatial and working memory, but its role in hippocampus-dependent fear memory has yet to be determined. Induction of NMDAR-LTD requires the activation of caspase-3 by cytochrome c. Cytochrome c normally resides in mitochondria and during NMDAR-LTD is released from mitochondria, a process promoted by Bax (Bcl-2-associated X protein). Bax induces cell death in apoptosis, but it plays a nonapoptotic role in NMDAR-LTD. Here, we investigated the role of NMDAR-LTD in fear memory in CA1-specific Bax knock-out mice. In hippocampal slices from these knock-out mice, while long-term potentiation of synaptic transmission, basal synaptic transmission, and paired-pulse ratio are intact, LTD in both young and fear-conditioned adult mice is obliterated. Interestingly, in CA1-specific Bax knock-out mice, long-term contextual fear memory is impaired, but the acquisition of fear memory and innate fear are normal. Moreover, these conditional Bax knock-out mice exhibit less behavioral despair. These findings indicate that NMDAR-LTD is required for consolidation, but not the acquisition of fear memory. Our study also shows that Bax plays an important role in depressive behavior.

Peripheral TGF-ß1 signaling is a critical event in bone cancer-induced hyperalgesia in rodents.

Pain is the most common symptom of bone cancer. TGF-ß, a major bone-derived growth factor, is largely released by osteoclast bone resorption during the progression of bone cancer and contributes to proliferation, angiogenesis, immunosuppression, invasion, and metastasis. Here, we further show that TGF-ß1 is critical for bone cancer-induced pain sensitization. We found that, after the progression of bone cancer, TGF-ß1 was highly expressed in tumor-bearing bone, and the expression of its receptors, TGFßRI and TGFßRII, was significantly increased in the DRG in a rat model of bone cancer pain that is based on intratibia inoculation of Walker 256 mammary gland carcinoma cells. The blockade of TGF-ß receptors by the TGFßRI antagonist SD-208 robustly suppressed bone cancer-induced thermal hyperalgesia on post-tumor day 14 (PTD 14). Peripheral injection of TGF-ß1 directly induced thermal hyperalgesia in intact rats and wide-type mice, but not in Trpv1(-/-) mice. Whole-cell patch-clamp recordings from DRG neurons showed that transient receptor potential vanilloid (TRPV1) sensitivity was significantly enhanced on PTD 14. Extracellular application of TGF-ß1 significantly potentiated TRPV1 currents and increased [Ca(2+)]i in DRG neurons. Pharmacological studies revealed that the TGF-ß1 sensitization of TRPV1 and the induction of thermal hyperalgesia required the TGF-ßR-mediated Smad-independent PKCε and TGF-ß activating kinase 1-p38 pathways. These findings suggest that TGF-ß1 signaling contributes to bone cancer pain via the upregulation and sensitization of TRPV1 in primary sensory neurons and that therapeutic targeting of TGF-ß1 may ameliorate the bone cancer pain in advanced cancer.

Simultaneous Knockouts of the Oxytocin and Vasopressin 1b Receptors in Hippocampal CA2 Impair Social Memory.

Oxytocin (Oxt) and vasopressin (Avp) are two neuropeptides with many central actions related to social cognition. The oxytocin (Oxtr) and vasopressin 1b (Avpr1b) receptors are co-expressed in the pyramidal neurons of the hippocampal subfield CA2 and are known to play a critical role in social memory formation. How the neuropeptides perform this function in this region is not fully understood. Here, we report the behavioral effects of a life-long conditional removal (knockout, KO) of either the Oxtr alone or both Avpr1b and Oxtr from the pyramidal neurons of CA2 as well as the resultant changes in synaptic transmission within the different fields of the hippocampus. Surprisingly, the removal of both receptors results in mice that are unable to habituate to a familiar female presented for short duration over short intervals but are able to recognize and discriminate females when presented for a longer duration over a longer interval. Importantly, these double KO mice were unable to discriminate between a male littermate and a novel male. Synaptic transmission between CA3 and CA2 is enhanced in these mice, suggesting a compensatory mechanism is activated to make up for the loss of the receptors. Overall, our results demonstrate that co-expression of the receptors in CA2 is necessary to allow intact social memory processing.

TGF-ß1 enhances Kv2.1 potassium channel protein expression and promotes maturation of cerebellar granule neurons.

Members of the transforming growth factor-ß (TGF-ß) family of cytokines are involved in diverse physiological processes. Although TGF-ß is known to play multiple roles in the mammalian central nervous system (CNS), its role in neuronal development has not been explored. We have studied the effects of TGF-ß1 on the electrophysiological properties and maturation of rat primary cerebellar granule neurons (CGNs). We report that incubation with TGF-ß1 increased delayed rectifier potassium current (I(K) ) amplitudes in a dose- and time-dependent manner, but did not affect the kinetic properties of the channel. Exposure to TGF-ß1 (20 ng/ml) for 36 h led to a 37.2% increase in I(K) amplitudes. There was no significant change in mRNA levels for the key Kv2.1 channel protein, but translation blockade abolished the increase in protein levels and channel activity, arguing that TGF-ß1 increases I(K) amplitudes by upregulating translation of the Kv2.1 channel protein. Although TGF-ß1 treatment did not affect the activity of protein kinase A (PKA), and constitutive activation of PKA with forskolin failed to increase I(K) amplitudes, inhibition of PKA prevented channel upregulation, demonstrating that basal PKA activity is required for TGF-ß1 stimulation of I(K) channel activity. TGF-ß1 also promoted the expression of the γ-aminobutyric acid (GABA(A) ) receptor α6 subunit, a marker of mature CGNs, and calcium influx during depolarizing stimuli was reduced by TGF-ß1. The effects of TGF-ß1 were only observed during a narrow developmental time-window, and were lost as CGNs matured. These findings suggest that TGF-ß1 upregulates K(+) channel expression and I(K) currents and thereby promotes CGN maturation.

Analyzing autophagosomes and mitophagosomes in the mouse brain using electron microscopy.

Electron microscopy (EM) is considered the gold standard for studying macroautophagy and mitophagy, essential cellular processes for brain health. Here, we present a protocol using EM to analyze autophagosomes and mitophagosomes in the mouse amygdala. We describe the preparation of brain sections, followed by staining and EM imaging. We then detail the steps to identify and analyze autophagosome-like and mitophagosome-like structures. This protocol can be easily adapted to analyze autophagosomes and mitophagosomes in other mouse brain regions. For complete details on the use and execution of this protocol, please refer to Duan et al. (2021).

BAX regulates dendritic spine development via mitochondrial fusion.

BAX is a Bcl-2 family protein acting on apoptosis. It also promotes mitochondrial fusion by interacting with the mitochondrial fusion protein Mitofusin (Mfn1 and Mfn2). Neuronal mitochondria are important for the development and modification of dendritic spines, which are subcellular compartments accommodating excitatory synapses in postsynaptic neurons. The abundance of dendritic mitochondria influences dendritic spine development. Mitochondrial fusion is essential for mitochondrial homeostasis. Here, we show that in the hippocampal neuron of BAX knockout mice, mitochondrial fusion is impaired, leading to decreases in mitochondrial length and total mitochondrial mass in dendrites. Notably, BAX knockout mice also have fewer dendritic spines and less cellular Adenosine 5'triphosphate (ATP) in dendrites. The spine and ATP changes are abolished by restoring mitochondria fusion via overexpressing Mfn1 and Mfn2. These findings indicate that BAX-mediated mitochondrial fusion in neurons is crucial for the development of dendritic spines and the maintenance of cellular ATP levels.

Mitophagy in the basolateral amygdala mediates increased anxiety induced by aversive social experience.

Psychosocial stress is a common risk factor for anxiety disorders. The cellular mechanism for the anxiogenic effect of psychosocial stress is largely unclear. Here, we show that chronic social defeat (CSD) stress in mice causes mitochondrial impairment, which triggers the PINK1-Parkin mitophagy pathway selectively in the amygdala. This mitophagy elevation causes excessive mitochondrial elimination and consequent mitochondrial deficiency. Mitochondrial deficiency in the basolateral amygdalae (BLA) causes weakening of synaptic transmission in the BLA-BNST (bed nucleus of the stria terminalis) anxiolytic pathway and increased anxiety. The CSD-induced increase in anxiety-like behaviors is abolished in Pink1-/- and Park2-/- mice and alleviated by optogenetic activation of the BLA-BNST synapse. This study identifies an unsuspected role of mitophagy in psychogenetic-stress-induced anxiety elevation and reveals that mitochondrial deficiency is sufficient to increase anxiety and underlies the psychosocial-stress-induced anxiety increase. Mitochondria and mitophagy, therefore, can be potentially targeted to ameliorate anxiety.

Activation of extracellular signal-regulated kinase in the anterior cingulate cortex contributes to the induction and expression of affective pain.

The anterior cingulate cortex (ACC) is implicated in the affective response to noxious stimuli. However, little is known about the molecular mechanisms involved. The present study demonstrated that extracellular signal-regulated kinase (ERK) activation in the ACC plays a crucial role in pain-related negative emotion. Intraplantar formalin injection produced a transient ERK activation in laminae V-VI and a persistent ERK activation in laminae II-III of the rostral ACC (rACC) bilaterally. Using formalin-induced conditioned place avoidance (F-CPA) in rats, which is believed to reflect the pain-related negative emotion, we found that blockade of ERK activation in the rACC with MEK inhibitors prevented the induction of F-CPA. Interestingly, this blockade did not affect formalin-induced two-phase spontaneous nociceptive responses and CPA acquisition induced by electric foot-shock or U69,593, an innocuous aversive agent. Upstream, NMDA receptor, adenylyl cyclase (AC) and phosphokinase A (PKA) activators activated ERK in rACC slices. Consistently, intra-rACC microinjection of AC or PKA inhibitors prevented F-CPA induction. Downstream, phosphorylation of cAMP response element binding protein (CREB) was induced in the rACC by formalin injection and by NMDA, AC and PKA activators in brain slices, which was suppressed by MEK inhibitors. Furthermore, ERK also contributed to the expression of pain-related negative emotion. Thus, when rats were re-exposed to the conditioning context for retrieval of pain experience, ERK and CREB were reactivated in the rACC, and inhibiting ERK activation blocked the expression of F-CPA. All together, our results demonstrate that ERK activation in the rACC is required for the induction and expression of pain-related negative affect.

The expression and functionality of transient receptor potential vanilloid 1 in ovarian endometriomas.

Pains of various kinds--dysmenorrhea, chronic pelvic pain, and dyspareunia--are the major complaints from women with endometriosis, representing the most debilitating nature of the disease. Despite extensive research, our understanding as how endometriosis causes pain is still fragmentary. In this study, we examined transient receptor potential vanilloid 1 (TRPV1)-positive nerve fibers in ectopic endometrium from women with ovarian endometriomas and in endometrium from women without endometriosis and correlated the density with the severity of dysmenorrhea in cases. We also performed an immunohistochemistry analysis of TRPV1 in ectopic and control endometrium. After finding TRPV1 immunoreactivity in ectopic endometrial cells, we further examined whether TRPV1 is functional in ectopic endometrial stromal cells (EESCs). We found that the density of TRPV1-positive nerve fibers in ectopic endometrial implants is higher than that in control endometrium and correlates positively with the severity of dysmenorrhea in women with endometriosis. In addition, TRPV1 expression was also found to be elevated significantly in EESCs when stimulated with inflammatory mediators such as prostaglandin E2 (PGE(2) ) and tumor necrosis factor-α (TNF-α). Finally, we found that TRPV1 activation can induce the release of nitric oxide (NO) and interleukin 1ß (IL-1ß) in EESCs. The latter finding appears to be consistent with the reports of increased TRPV1 protein expression following peripheral inflammation. Our results suggest that the increased TRPV1-positive nerve fibers may integrate various stimuli on peripheral terminals or primary sensory neurons and generate hyperalgesia in endometriosis. The expression and functionality of TRPV1 in EESCs also suggest that TRPV1 may have neurosecretory functions that are yet to be elucidated.

Targeting A-type K(+) channels in primary sensory neurons for bone cancer pain in a rat model.

Cancer pain is one of the most severe types of chronic pain, and the most common cancer pain is bone cancer pain. The treatment of bone cancer pain remains a clinical challenge. Here, we report firstly that A-type K(+) channels in dorsal root ganglion (DRG) are involved in the neuropathy of rat bone cancer pain and are a new target for diclofenac, a nonsteroidal anti-inflammatory drug that can be used for therapy for this distinct pain. There are dynamically functional changes of the A-type K(+) channels in DRG neurons during bone cancer pain. The A-type K(+) currents that mainly express in isolectin B4-positive small DRG neurons are increased on post-tumor day 14 (PTD 14), then faded but still remained at a higher level on PTD 21. Correspondingly, the expression levels of A-type K(+) channel Kv1.4, Kv3.4, and Kv4.3 showed time-dependent changes during bone cancer pain. Diclofenac enhances A-type K(+) currents in the DRG neurons and attenuates bone cancer pain in a dose-dependent manner. The analgesic effect of diclofenac can be reversed or prevented by A-type K(+) channel blocker 4-AP or pandinotoxin-Kα, also by siRNA targeted against rat Kv1.4 or Kv4.3. Repeated diclofenac administration decreased soft tissue swelling adjacent to the tumor and attenuated bone destruction. These results indicate that peripheral A-type K(+) channels were involved in the neuropathy of rat bone cancer pain. Targeting A-type K(+) channels in primary sensory neurons may provide a novel mechanism-based therapeutic strategy for bone cancer pain.