The gut-brain axis mediates bacterial driven modulation of reward signaling.

OBJECTIVE: Our goal is to investigate if microbiota composition modulates reward signaling and assess the role of the vagus in mediating microbiota to brain communication. METHODS: Male germ-free Fisher rats were colonized with gastrointestinal contents from chow (low fat (LF) ConvLF) or HF (ConvHF) fed rats. RESULTS: Following colonization, ConvHF rats consumed significantly more food than ConvLF animals. ConvHF rats displayed lower feeding-induced extracellular DOPAC levels (a metabolite of dopamine) in the Nucleus Accumbens (NAc) as well as reduced motivation for HF foods compared to ConvLF rats. Dopamine receptor 2 (DDR2) expression levels in the NAc were also significantly lower in ConvHF animals. Similar deficits were observed in conventionally raised HF fed rats, showing that diet-driven alteration in reward can be initiated via microbiota. Selective gut to brain deafferentation restored DOPAC levels, DRD2 expression, and motivational drive in ConvHF rats. CONCLUSIONS: We concluded from these data that a HF-type microbiota is sufficient to alter appetitive feeding behavior and that bacteria to reward communication is mediated by the vagus nerve.

Non-neuronal crosstalk promotes an inflammatory response in nodose ganglia cultures after exposure to byproducts from gram positive, high-fat-diet-associated gut bacteria.

Vagal afferent neurons (VAN) projecting to the lamina propria of the digestive tract are the primary source of gut-originating signals to the central nervous system (CNS). VAN cell bodies are found in the nodose ganglia (NG). Responsiveness of VAN to gut-originating signals is altered by feeding status with sensitivity to satiety signals such as cholecystokinin (CCK) increasing in the fed state. Chronic high-fat (HF) feeding results in inflammation at the level of the NG associated with a loss of VAN ability to switch phenotype from the fasted to the fed state. HF feeding also leads to compositional changes in the gut microbiota. HF diet consumption notably drives increased Firmicutes to Bacteroidetes phyla ratio and increased members of the Actinobacteria phylum. Firmicutes and Actinobacteria are largely gram positive (GP). In this study, we aimed to determine if byproducts from GP bacteria can induce an inflammatory response in cultured NG and to characterize the mechanism and cell types involved in the response. NG were collected from male Wistar rats and cultured for a total of 72 hours. At 48-68 hours after plating, cultures were treated with neuronal culture media in which Serinicoccus chungangensis had been grown and removed (SUP), lipoteichoic acid (LTA), or meso-diaminopimelic acid (meso-DAP). Some treatments included the glial inhibitors minocycline (MINO) and/or fluorocitrate (FC). The responses were evaluated using immunocytochemistry, qPCR, and electrochemiluminescence. We found that SUP induced an inflammatory response characterized by increased interleukin (IL)-6 staining and increased expression of genes for IL-6, interferon (IFN)γ, and tumor necrosis factor (TNF)α along with genes associated with cell-to-cell communication such as C-C motif chemokine ligand-2 (CCL2). Inclusion of inhibitors attenuated some responses but failed to completely normalize all indications of response, highlighting the role of immunocompetent cellular crosstalk in regulating the inflammatory response. LTA and meso-DAP produced responses that shared characteristics with SUP but were not identical. Our results support a role for HF associated GP bacterial byproducts' ability to contribute to vagal inflammation and to engage signaling from nonneuronal cells.

Bax and caspases regulate increased production of mitochondria-derived reactive species in neuronal apoptosis: LACK of A role for depletion of cytochrome c from the mitochondrial electron transport chain.

A Bax-dependent increase of reactive oxygen species (ROS) and other reactive species (RS) occurs after withdrawing NGF from mouse sympathetic neurons in cell culture. Possible mechanisms underlying the increased ROS/RS are leakage of electrons from the mitochondrial electron transport chain secondary to caspase cleavage of respiratory complexes or leakage secondary to depletion of cytochrome c from the chain. We previously demonstrated that deletion of Bax or caspase 3 from these cells reduces ROS/RS production to near baseline levels indicating a central role for both Bax and caspase 3 in generating the ROS/RS. Here we depleted cytochrome c to a similar level in neurons from wild type and bax hemizygous or knockout mice by NGF withdrawal or treatment with H2O2. Death was prevented with a caspase inhibitor that caused a partial reduction of ROS/RS levels but did not completely prevent the ROS/RS increase. ROS/RS was highest in bax wild-type cells, lowest in bax knockout cells, and at an intermediate level in the bax hemizygous cells. These and our previous findings indicate that Bax and caspase 3 are necessary for the increased ROS/RS after withdrawing NGF from these cells and that little or none of the increased ROS/RS are secondary to a depletion of cytochrome c from the electron transport chain.

Bax regulates production of superoxide in both apoptotic and nonapoptotic neurons: role of caspases.

A Bax- and, apparently, mitochondria-dependent increase in superoxide (O(2)(·-)) and other reactive oxygen species (ROS) occurs in apoptotic superior cervical ganglion (SCG) and cerebellar granule (CG) neurons. Here we show that Bax also lies upstream of ROS produced in nonapoptotic neurons and present evidence that caspases partially mediate the pro-oxidant effect of Bax. We used the O(2)(·-)-sensitive dye MitoSOX to monitor O(2)(·-) in neurons expressing different levels of Bax and mitochondrial superoxide dismutase (SOD2). Basal and apoptotic O(2)(·-) levels in both SCG and CG neurons were reduced in SOD2 wild-type (WT) cells having lower Bax concentrations. Apoptotic and nonapoptotic neurons from Bax-WT/SOD2-null but not Bax-null/SOD2-null mice had increased O(2)(·-) levels. A caspase inhibitor inhibited O(2)(·-) in both apoptotic and nonapoptotic SCG neurons. O(2)(·-) production increased when WT, but not Bax-null, SCG neurons were permeabilized and treated with active caspase 3. There was no apoptosis and little increase in O(2)(·-) in SCG neurons from caspase 3-null mice exposed to an apoptotic stimulus. O(2)(·-) levels in nonapoptotic caspase 3-null SCG neurons were lower than in WT cells but not as low as in caspase inhibitor-treated cells. These data indicate that Bax lies upstream of most O(2)(·-) produced in neurons, that caspase 3 is required for increased O(2)(·-) production during neuronal apoptosis, that caspase 3 is partially involved in O(2)(·-) production in nonapoptotic neurons, and that other caspases may also be involved in Bax-dependent O(2)(·-) production in nonapoptotic cells.

Rapid activation of antioxidant defenses by nerve growth factor suppresses reactive oxygen species during neuronal apoptosis: evidence for a role in cytochrome c redistribution.

Depriving mouse sympathetic neurons of nerve growth factor (NGF) causes their apoptotic death. A Bax-dependent increase of mitochondrial-derived reactive oxygen species (ROS) begins in these cells soon after NGF withdrawal. We investigated the effects on these ROS of adding NGF to cultures of NGF-deprived neurons. ROS levels were monitored with the fluorescent, redox-sensitive dyes CM-H2DCFDA and MitoSOX Red. The intensity of the former dye increases when it is oxidized by H2O2 and free radicals downstream of H2O2. MitoSOX Red is relatively insensitive to oxidation by H2O2 but is sensitive to oxidation by superoxide (O2*-). Withdrawing NGF increased CM-H2DCFDA intensity, indicating elevated H2O2-associated ROS. Re-exposure of cells deprived of NGF to NGF resulted in rapid suppression of these ROS. Neurons deprived of NGF also had increased MitoSOX Red intensities. Readdition of NGF had no effect on MitoSOX Red fluorescence. The suppression of CM-H2DCFDA-detected ROS by NGF was caused by a rapid activation of glutathione redox cycling. The most likely explanation for these findings is that mitochondria increased O2*- production after NGF withdrawal. The O2*- was converted to H2O2 by dismutation, and the H2O2 was detoxified by accelerated glutathione redox cycling. Our previous work shows that H2O2 induces cytochrome c to be released from mitochondria in NGF-supported sympathetic neurons, whereas antioxidants that detoxify H2O2 block cytochrome c redistribution in NGF-deprived neurons. Readdition of NGF also immediately inhibits cytochrome c release. We present evidence that this inhibition is mediated by the rapid activation of glutathione redox cycling by NGF.

Rate of neurite outgrowth in sympathetic neurons is highly resistant to suppression of protein synthesis: role of protein degradation/synthesis coupling.

Neurites projecting to their target tissues during embryogenesis are subject to many perturbations that could influence their rate of growth. For example, environmental influences such as supply of neurotrophic factor or electrical activity profoundly influence the rate of neuronal protein synthesis. Because accumulation of protein is necessary for outgrowth to proceed normally, a perturbation in protein synthesis could cause a net change in the rate of accumulation of proteins with the result that neurite outgrowth rate increases or decreases. That neurite outgrowth does not normally seem to be subject to such perturbations suggests involvement of a homeostatic system controlling the rate of outgrowth. Consistent with this hypothesis, we show here that the rate of growth of neurites of sympathetic neurons is highly resistant to decreased rates of protein synthesis. Chronic suppression of protein synthesis by 60% had no significant effect on neurite outgrowth over a 2-day period while complete suppression halted it almost immediately. By the 3rd day of exposure, 60% suppression slowed outgrowth. Sustained suppression of protein synthesis rate by 33% had no effect on rate of outgrowth even after 7 days. We show that the ability of the growing neurites to resist protein synthesis suppression appears to be caused, at least in part, by a parallel decrease in the rate of protein degradation. The result of this coupling between degradation and synthesis is that proteins can continue to accumulate even when protein synthesis rate decreases, allowing normal rates of neurite outgrowth.

Bax affects production of reactive oxygen by the mitochondria of non-apoptotic neurons.

Depriving sympathetic neurons in cell culture of nerve growth factor (NGF) causes their apoptotic death. Bax-induced release of cytochrome c from mitochondria and the subsequent activation of cytosolic caspases are central to this death. A Bax-dependent increase of mitochondrial-derived reactive oxygen species (ROS) that is an important component of the apoptotic cascade in these cells begins soon after NGF withdrawal. Here we report that Bax can also influence mitochondrial production of ROS in non-apoptotic sympathetic neurons. We determined ROS levels by using confocal microscopy to monitor changes in the fluorescence intensity of a redox-sensitive dye loaded into single cells. ROS levels were similar in NGF-replete bax wild-type neurons and neurons from which bax had been deleted. To enhance any effects that Bax might have on ROS levels in NGF-replete cells we exposed cultures to the ATP synthase inhibitor, oligomycin. This treatment hyperpolarizes mitochondrial membrane potential (DeltaPsi(m)), an event that can favor increased ROS production. NGF-replete neurons from mice in which bax had been deleted had much higher levels of mitochondrial-derived ROS when treated with oligomycin than did bax wild-type cells. Oligomycin treatment also caused greater hyperpolarization of DeltaPsi(m) in bax-deleted cells than in wild-type cells. These findings indicate that Bax can affect mitochondrial ROS production in non-apoptotic neurons and may do so by altering DeltaPsi(m).

Bax, reactive oxygen, and cytochrome c release in neuronal apoptosis.

Half of all neurons produced during embryogenesis undergo apoptotic death shortly before birth or soon thereafter. Two cell culture models have been used extensively to investigate the cellular and molecular mechanisms underlying apoptosis during neuronal development: (a) sympathetic neurons deprived of their required neurotrophic factor, nerve growth factor, and (b) cerebellar granule neurons deprived of serum in low-potassium medium. A dramatic increase in mitochondrial-derived reactive oxygen species (ROS) occurs during the apoptotic death of both of these cell types. These ROS lie downstream from the proapoptotic protein, Bax. Bax normally resides in the cytoplasm, but translocates to the outer mitochondrial membrane during apoptosis. Once associated with mitochondria, Bax causes release of apoptogenic factors from the mitochondria into the cytoplasm, thus inducing or augmenting the apoptotic cascade. Although there is much controversy about the exact mechanism by which Bax causes release of these factors, recent evidence suggests that the Bax-induced ROS are critical for this release to occur in both sympathetic and cerebellar granule neurons. Because Bax is critical for the apoptotic death of many other types of neurons, it is likely that increased ROS is important for the death of these cells as well.

Prooxidant effects of NGF withdrawal and MEK inhibition in sympathetic neurons.

An increase of mitochondrial-derived reactive oxygen species (ROS) occurs in nerve growth factor (NGF)-deprived sympathetic neurons undergoing apoptotic death. It has been reported that NGF suppresses increased ROS production by the mitochondria in these cells through a mitogen-activated protein kinase kinase (MEK)/mitogen-activated protein (MAP) kinase pathway because NGF withdrawal inactivates this pathway and the MEK inhibitor, PD98059, increases ROS in the presence of NGF. We show here that treating rat sympathetic neurons in cell culture with PD98059 greatly decreased cellular concentrations of reduced glutathione (GSH), a major cellular antioxidant. Therefore, it is likely that this inhibitor induces a cellular prooxidant state in NGF-maintained sympathetic neurons primarily by decreasing GSH concentration rather than by causing increased mitochondrial ROS production. These data suggest that the MEK/MAP kinase signaling pathway regulates cellular GSH concentration.

Cytochrome c release precedes mitochondrial membrane potential loss in cerebellar granule neuron apoptosis: lack of mitochondrial swelling.

It has been suggested that release of cytochrome c (Cyt c) from mitochondria during apoptotic death is through opening of the mitochondrial permeability transition pore followed by swelling-induced rupture of the mitochondrial outer membrane. However, this remains controversial and may vary with cell type and model system. We determined that in mouse cerebellar granule neurons, Cyt c redistribution preceded the loss of mitochondrial membrane potential during the apoptotic process, suggesting that the pore did not open prior to release. Furthermore, when mitochondria were morphologically assessed by electron microscopy, they were not obviously swollen during the period of Cyt c release. This indicates that the pore mechanism of action, if any, is not through mitochondrial outer membrane rupture. While bongkrekic acid, an inhibitor of pore opening, modestly delayed apoptotic death, it also caused a significant (p < 0.05) suppression of protein synthesis. An equivalent suppression of protein synthesis by cycloheximide had a similar delaying effect, suggesting that bongkrekic acid was acting non-specifically. These findings suggest that mitochondrial permeability transition pore is not involved in Cyt c release from mitochondria during the apoptotic death of cerebellar granule neurons.

A Bax-induced pro-oxidant state is critical for cytochrome c release during programmed neuronal death.

Bax is required for the apoptotic death of sympathetic neurons deprived of nerve growth factor (NGF). After NGF withdrawal, Bax translocates from the cytoplasm to the mitochondria of these cells and induces release of the proapoptotic protein cytochrome c. Here, we report that withdrawing NGF from mouse sympathetic neurons caused an increase of mitochondria-derived reactive oxygen species (ROS). Suppressing these ROS inhibited apoptosis. Bax deletion blocked death and prevented the ROS burst. Inducing a pro-oxidant state similar to that in NGF-deprived, wild-type cells caused cytochrome c release even in neurons lacking Bax. A similar ROS burst in cerebellar granule neurons undergoing apoptosis was also blocked by Bax deletion. These findings indicate that Bax lies upstream from increased ROS in NGF-deprived neurons and suggest that the Bax-induced ROS burst is both necessary and sufficient for cytochrome c redistribution in these cells.