Your search keyword '"Bolam, Paul"' showing total 8 results

1. Gonadectomy but not biological sex affects burst-firing in dopamine neurons of the ventral tegmental area and in prefrontal cortical neurons projecting to the ventral tegmentum in adult rats.

Author

Locklear, Mallory N., Michaelos, Michalis, Collins, William F., Kritzer, Mary F., and Bolam, Paul

Subjects

CASTRATION, SEX (Biology), NEUROBEHAVIORAL disorders, DOPAMINERGIC neurons, PREFRONTAL cortex, LABORATORY rats, PHYSIOLOGY

Abstract

The mesocortical and mesolimbic dopamine systems regulate cognitive and motivational processes and are strongly implicated in neuropsychiatric disorders in which these processes are disturbed. Sex differences and sex hormone modulation are also known for these dopamine-sensitive behaviours in health and disease. One relevant mechanism of hormone impact appears to be regulation of cortical and subcortical dopamine levels. This study asked whether this regulation of dopamine tone is a consequence of sex or sex hormone impact on the firing modes of ventral midbrain dopamine neurons. To address this, single unit extracellular recordings made in the ventral tegmental area and substantia nigra were compared among urethane-anaesthetized adult male, female, gonadectomized male rats. These comparisons showed that gonadectomy had no effect on nigral cells and no effects on pacemaker, bursty, single-spiking or random modes of dopamine activity in the ventral tegmental area. However, it did significantly and selectively increase burst firing in these cells in a testosterone-sensitive, estradiol-insensitive manner. Given the roles of prefrontal cortex (PFC) in modulating midbrain dopamine cell firing, we next asked whether gonadectomy's effects on dopamine cell bursting had correlated effects on the activity of ventral tegmentally projecting prefrontal cortical neurons. We found that gonadectomy indeed significantly and selectively increased burst firing in ventral tegmentally projecting but not neighbouring prefrontal cells. These effects were also androgen-sensitive. Together, these findings suggest a working model wherein androgen influence over the activity of PFC neurons regulates its top-down modulation of mesocortical and mesolimbic dopamine systems and related dopamine-sensitive behaviours. [ABSTRACT FROM AUTHOR]

Published

2017

2. Optogenetic activation of melanin-concentrating hormone neurons increases non-rapid eye movement and rapid eye movement sleep during the night in rats.

Author

Blanco‐Centurion, Carlos, Liu, Meng, Konadhode, Roda P., Zhang, Xiaobing, Pelluru, Dheeraj, Pol, Anthony N., Shiromani, Priyattam J., and Bolam, Paul

Subjects

MELANIN-concentrating hormone, NON-REM sleep, SENSORY neurons, OPTOGENETICS, LABORATORY rats

Abstract

Neurons containing melanin-concentrating hormone ( MCH) are located in the hypothalamus. In mice, optogenetic activation of the MCH neurons induces both non-rapid eye movement (NREM) and rapid eye movement (REM) sleep at night, the normal wake-active period for nocturnal rodents [R. R. Konadhode et al. (2013) J. Neurosci., 33, 10257-10263]. Here we selectively activate these neurons in rats to test the validity of the sleep network hypothesis in another species. Channelrhodopsin-2 (ChR2) driven by the MCH promoter was selectively expressed by MCH neurons after injection of rAAV- MCHp-ChR2- EYFP into the hypothalamus of Long-Evans rats. An in vitro study confirmed that the optogenetic activation of MCH neurons faithfully triggered action potentials. In the second study, in Long-Evans rats, rAAV- MCH-ChR2, or the control vector, rAAV- MCH- EYFP, were delivered into the hypothalamus. Three weeks later, baseline sleep was recorded for 48 h without optogenetic stimulation (0 Hz). Subsequently, at the start of the lights-off cycle, the MCH neurons were stimulated at 5, 10, or 30 Hz (1 mW at tip; 1 min on - 4 min off) for 24 h. Sleep was recorded during the 24-h stimulation period. Optogenetic activation of MCH neurons increased both REM and NREM sleep at night, whereas during the day cycle, only REM sleep was increased. Delta power, an indicator of sleep intensity, was also increased. In control rats without ChR2, optogenetic stimulation did not increase sleep or delta power. These results lend further support to the view that sleep-active MCH neurons contribute to drive sleep in mammals. [ABSTRACT FROM AUTHOR]

Published

2016

3. Neuroprotective effect of propofol against excitotoxic injury to locomotor networks of the rat spinal cord in vitro.

Author

Kaur, Jaspreet, Flores Gutiérrez, Javier, Nistri, Andrea, and Bolam, Paul

Subjects

NEUROPROTECTIVE agents, PROPOFOL, MUSCULOSKELETAL system, SPINAL cord, LABORATORY rats, PSYCHOLOGY

Abstract

Although neuroprotection to contain the initial damage of spinal cord injury ( SCI) is difficult, multicentre studies show that early neurosurgery under general anaesthesia confers positive benefits. An interesting hypothesis is that the general anaesthetic itself might largely contribute to neuroprotection, although in vivo clinical settings hamper studying this possibility directly. To further test neuroprotective effects of a widely used general anaesthetic, we studied if propofol could change the outcome of a rat isolated spinal cord SCI model involving excitotoxicity evoked by 1 h application of kainate with delayed consequences on neurons and locomotor network activity. Propofol (5 μ m; 4-8 h) enhanced responses to GABA and depressed those to NMDA together with decrease in polysynaptic reflexes that partly recovered after 1 day washout. Fictive locomotion induced by dorsal root stimuli or NMDA and serotonin was weaker the day after propofol application. Kainate elicited a significant loss of spinal neurons, especially motoneurons, whose number was halved. When propofol was applied for 4-8 h after kainate washout, strong neuroprotection was observed in all spinal areas, including attenuation of motoneuron loss. Although propofol had minimal impact on recovery of electrophysiological characteristics 24 h later, it did not further depress network activity. A significant improvement in disinhibited burst periodicity suggested potential to ameliorate neuronal excitability in analogy to histological data. Functional recovery of locomotor networks perhaps required longer time due to the combined action of excitotoxicity and anaesthetic depression at 24 h. These results suggest propofol could confer good neuroprotection to spinal circuits during experimental SCI. [ABSTRACT FROM AUTHOR]

Published

2016

4. Orexin-A increases the activity of globus pallidus neurons in both normal and parkinsonian rats.

Author

Xue, Yan, Yang, Yu‐Ting, Liu, Hong‐Yun, Chen, Wen‐Fang, Chen, An‐Qi, Sheng, Qing, Chen, Xin‐Yi, Wang, Ying, Chen, Hua, Liu, Hong‐Xia, Pang, Ya‐Yan, Chen, Lei, and Bolam, Paul

Subjects

PARKINSONIAN disorders, OREXINS, GLOBUS pallidus, PROTEIN expression, ELECTROPHYSIOLOGY, STATISTICAL correlation, LABORATORY rats, THERAPEUTICS

Abstract

Orexin is a member of neuropeptides which was first identified in the hypothalamus. The globus pallidus is a key structure in the basal ganglia, which is involved in both normal motor function and movement disorders. Morphological studies have shown the expression of both OX1 and OX2 receptors in the globus pallidus. Employing single unit extracellular recordings and behavioural tests, the direct in vivo electrophysiological and behavioural effects of orexin-A in the globus pallidus were studied. Micro-pressure administration of orexin-A significantly increased the spontaneous firing rate of pallidal neurons. Correlation analysis revealed a negative correlation between orexin-A induced excitation and the basal firing rate. Furthermore, application of the specific OX1 receptor antagonist, SB-334867, decreased the firing rate of pallidal neurons, suggesting that endogenous orexinergic systems modulate the firing activity of pallidal neurons. Orexin-A increased the excitability of pallidal neurons through both OX1 and OX2 receptors. In 6-hydroxydopamine parkinsonian rats, orexin-A-induced increase in firing rate of pallidal neurons was stronger than that in normal rats. Immunostaining revealed positive OX1 receptor expression in the globus pallidus of both normal and parkinsonian rats. Finally, postural test showed that unilateral microinjection of orexin-A led to contralateral deflection in the presence of systemic haloperidol administration. Further elevated body swing test revealed that pallidal orexin-A and SB-334867 induced contralateral-biased swing and ipsilateral-biased swing respectively. Based on the electrophysiological and behavioural findings of orexin-A in the globus pallidus, the present findings may provide a rationale for the pathogenesis and treatment of Parkinson's disease. [ABSTRACT FROM AUTHOR]

Published

2016

5. Rizatriptan overuse promotes hyperalgesia induced by dural inflammatory stimulation in rats by modulation of the serotonin system.

Author

Su, Min, Ran, Ye, Han, Xun, Liu, Yufei, Zhang, Xu, Tan, Qingche, Li, Ruisheng, Yu, Shengyuan, and Bolam, Paul

Subjects

HYPERALGESIA, SEROTONIN receptors, DRUG overdose, HEADACHE, LABORATORY rats

Abstract

Clinical and preclinical studies have implicated serotonin (5- HT) and the 5- HT2A receptor (5- HT2 AR) in the pathogenesis of medication-overuse headache ( MOH). However, with no appropriate animal model to study this phenomenon it is difficult to differentiate the effects of chronic exposure to analgesics from the consequences of frequent headache attacks during the development of MOH. Therefore, this study used a novel animal model of MOH established by a combination of the overuse of rizatriptan ( RIZ) and stimulation with dural inflammatory soup ( IS) to investigate whether 5- HT and 5- HT2 AR are involved in central plasticity and hyperalgesia. Similar to an IS infusion, IS- RIZ treatment induced nociception-related behaviours in Sprague-Dawley rats and increased Fos expression in the cortex and trigeminal pathway, whereas the RIZ injection alone did not. In addition, overuse of RIZ, administration of an IS stimulus, and a combination of these treatments, decreased the periorbital withdrawal threshold, with IS- RIZ treatment having the most significant effects. Both chronic RIZ exposure and recurring nociception decreased 5- HT expression, whereas IS- RIZ treatment led to decreased expression of 5- HT and upregulation of 5- HT2 AR, which was positively correlated with Fos activation. These findings suggest that overuse of RIZ does not directly induce pain via the activation of nociceptive pathways but may increase hyperalgesia by influencing the pain modulation system. Furthermore, decreased 5- HT levels and upregulation of 5- HT2 AR may play important roles in this system. Taken together, these findings indicate that medication overuse and frequent headache attacks can promote the neural plasticity associated with MOH. [ABSTRACT FROM AUTHOR]

Published

2016

6. Upregulation and axonal transport of synaptotagmin- IV in the direct-pathway medium spiny neurons in hemi-parkinsonian rats induced by dopamine D1 receptor stimulation.

Author

Tratnjek, Larisa, Glavan, Gordana, Višnjar, Tanja, Živin, Marko, and Bolam, Paul

Subjects

AXONS, SYNAPTOTAGMINS, NEURAL physiology, PARKINSONIAN disorders, DOPAMINE receptors, BRAIN stimulation, NEURAL transmission, LABORATORY rats, MEDIUM spiny neurons

Abstract

Synaptotagmin- IV (Syt- IV) may function as a regulator of Ca2+-dependent synaptic transmission. In the hemi-parkinsonian rats with unilateral lesions of dopaminergic nigrostriatal neurons Syt- IV and substance-P ( SP) mRNAs could be upregulated within the dopaminergically hypersensitive striatum of the lesioned brain hemisphere via the stimulation of striatal dopamine D1 (D1-R), but not D2 receptors. The hypersensitive D1-R-mediated transmission may be the culprit for the undesired expression of levodopa-induced dyskinesia, implying the involvement of Syt- IV and SP in the process. First, striatal cellular phenotypes expressing Syt- IV were determined. It was found to be expressed in all striatal neurons and a small population of astrocytes. Then it was examined, if the D1-R-mediated upregulation of Syt- IV mRNA may result in the upregulation of the translated protein. It was found that, after acute stimulation with a selective D1 agonist, (±)-6-chloro-7,8-dihydroxy-3-allyl-1-phenyl-2,3,4,5-tetrahydro-1H-3-benzazepine hydrobromide ( SKF-82958), Syt- IV was elevated within the SP-expressing striatal neurons of the lesioned side. This was followed by the upregulation of Syt- IV, but not of its mRNA, within the ipsilateral target nuclei of the direct-pathway medium spiny neurons, indicating axonal transport of de novo synthesized protein to their SP-positive synaptic terminals. However, despite the striatal upregulation of SP and Syt- IV following a similar time-course, their subcellular co-localization within the axonal terminals was not found. It was therefore suggested that Syt- IV may regulate the hypersensitive striatal synaptic transmission, although via a SP-independent mechanism. [ABSTRACT FROM AUTHOR]

Published

2016

7. Substratum preferences of motor and sensory neurons in postnatal and adult rats.

Author

Gonzalez‐Perez, Francisco, Alé, Albert, Santos, Daniel, Barwig, Christina, Freier, Thomas, Navarro, Xavier, Udina, Esther, and Bolam, Paul

Subjects

SENSORY neurons, MOTOR neurons, PERIPHERAL nerve injuries, FIBRONECTINS, COLLAGEN, LABORATORY rats

Abstract

After peripheral nerve injuries, damaged axons can regenerate but functional recovery is limited by the specific reinnervation of targets. In this study we evaluated if motor and sensory neurites have a substrate preference for laminin and fibronectin in postnatal and adult stages. In postnatal dorsal root ganglia ( DRG) explants, sensory neurons extended longer neurites on collagen matrices enriched with laminin (~50%) or fibronectin (~35%), whereas motoneurons extended longer neurites (~100%) in organotypic spinal cord slices embedded in fibronectin-enriched matrix. An increased percentage of parvalbumin-positive neurites (presumptive proprioceptive) vs. neurofilament-positive neurites was also found in DRG in fibronectin-enriched matrix. To test if the different preference of neurons for extracellular matrix components was maintained in vivo, these matrices were used to fill a chitosan guide to repair a 6-mm gap in the sciatic nerve of adult rats. However, the number of regenerating motor and sensory neurons after 1 month was similar between groups. Moreover, none of the retrotraced sensory neurons in DRG was positive for parvalbumin, suggesting that presumptive proprioceptive neurons had poor regenerative capabilities compared with other peripheral neurons. Using real-time PCR we evaluated the expression of α5β1 (receptor for fibronectin) and α7β1 integrin (receptor for laminin) in spinal cord and DRG 2 days after injury. Postnatal animals showed a higher increase of α5β1 integrin, whereas both integrins were similarly expressed in adult neurons. Therefore, we conclude that motor and sensory axons have a different substrate preference at early postnatal stages but this difference is lost in the adult. [ABSTRACT FROM AUTHOR]

Published

2016

8. Copper enhances cellular and network excitabilities, and improves temporal processing in the rat hippocampus.

Author

Maureira, Carlos, Letelier, Juan Carlos, Alvarez, Osvaldo, Delgado, Ricardo, Vergara, Cecilia, and Bolam, Paul

Subjects

HIPPOCAMPUS physiology, NEURAL circuitry, NEUROTRANSMITTERS, PHYSIOLOGICAL effects of copper, LABORATORY rats

Abstract

Copper, an ion with many important metabolic functions, has also been proposed to have a role as modulator on neuronal function, mostly based on its effects on voltage- and neurotransmitter-gated conductance as well as on neurological symptoms of patients with altered copper homeostasis. Nevertheless, the mechanisms by which copper exerts its neuromodulatory effects have not been clearly established in a functional neuronal network. Using rat hippocampus slices as a neuronal network model, the effects of copper in the range of 10-100 nM were tested on the intrinsic, synaptic and network properties of the CA1 region. Most of the previously described effects of this cation were in the micromolar range of copper concentrations. The current results indicate that copper is a multifaceted neuromodulator, having effects that may be grouped into two categories: (i) activity enhancement, by modulating synaptic communication and action potential (AP) conductances; and (ii) temporal processing and correlation extraction, by improving reliability and depressing inhibition. Specifically it was found that copper hyperpolarizes AP firing threshold, enhances neuronal and network excitability, modifies CA3-CA1 pathway gain, enhances the frequency of spontaneous synaptic events, decreases inhibitory network activity, and improves AP timing reliability. Moreover, copper chelation by bathocuproine decreases spontaneous network spiking activity. These results allow the proposal that copper affects the network activity from cellular to circuit levels on a moment-by-moment basis, and should be considered a crucial functional component of hippocampal neuronal circuitry. [ABSTRACT FROM AUTHOR]

Published

2015