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ABSTRACT: Insects, like other animals, require sodium chloride (NaCl) as part of their normal diet and detect it with contact chemoreceptors on the body surface. By adjusting the responsiveness of the chemosensory neurons within these receptors insects can modify the intake of salt and other nutrients, and it has been hypothesized that the responsiveness of chemosensory neurons is regulated by nitric oxide (NO). To identify potential sources of NO in the periphery, the authors applied the NO-sensitive fluorescent probe 4,5-diaminofluorescein and the universal NO synthase antibody, and found that in locusts NO is synthesized within one particular class of cells of the epidermis, the glandular cells, from where it may diffuse to neighboring chemosensory neurons. The effects of NO on chemosensory neurons were investigated by recording from contact chemoreceptors on the leg while perfusing it with drugs that interfere with NO signaling. Results showed that both endogenous and exogenous NO decreased the frequency of action potentials in chemosensory neurons in response to stimulation with NaCl by acting via a cyclic guanosine monophosphate-independent pathway. Variation of the NaCl concentration in the perfusion solution demonstrated that the synthesis of NO in glandular cells depends on the NaCl concentration in the hemolymph. By contrast NO increased the frequency of action potentials in chemosensory neurons in response to sucrose stimulation. The authors suggest that NO released from glandular cells modulates the responsiveness of chemosensory neurons to regulate NaCl intake, and hypothesize that NO may play a key role in the signaling of salt and sugars.
Developmental Neurobiology 03/2007; 67(2):219-32. · 3.55 Impact Factor
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ABSTRACT: Insects, like other animals, require sodium chloride (NaCl) as part of their normal diet and detect it with contact chemoreceptors on the body surface. By adjusting the responsiveness of the chemosensory neurons within these receptors insects can modify the intake of salt and other nutrients, and it has been hypothesized that the responsiveness of chemosensory neurons is regulated by nitric oxide (NO). To identify potential sources of NO in the periphery, the authors applied the NO-sensitive fluorescent probe 4,5-diaminofluorescein and the universal NO synthase antibody, and found that in locusts NO is synthesized within one particular class of cells of the epidermis, the glandular cells, from where it may diffuse to neighboring chemosensory neurons. The effects of NO on chemosensory neurons were investigated by recording from contact chemoreceptors on the leg while perfusing it with drugs that interfere with NO signaling. Results showed that both endogenous and exogenous NO decreased the frequency of action potentials in chemosensory neurons in response to stimulation with NaCl by acting via a cyclic guanosine monophosphate-independent pathway. Variation of the NaCl concentration in the perfusion solution demonstrated that the synthesis of NO in glandular cells depends on the NaCl concentration in the hemolymph. By contrast NO increased the frequency of action potentials in chemosensory neurons in response to sucrose stimulation. The authors suggest that NO released from glandular cells modulates the responsiveness of chemosensory neurons to regulate NaCl intake, and hypothesize that NO may play a key role in the signaling of salt and sugars. © 2006 Wiley Periodicals, Inc. Develop Neurobiol 67: 219–232, 2007.
Developmental Neurobiology 01/2007; 67(2):219 - 232. · 3.55 Impact Factor
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ABSTRACT: Synaptic dysfunction is believed to be an early pathological change in neurodegenerative diseases and may cause the earliest clinical symptoms. We have used Drosophila to model a tauopathy in order to analyse the earliest neuronal and synaptic dysfunction. Our work has shown that overexpression of human tau (0N3R) in larval motor neurons causes a disruption of axonal transport and a morphological and functional disruption of NMJs (neuromuscular junctions). Tau-expressing NMJs are smaller with an abnormal structure. Despite abnormal morphology, tau-expressing NMJs retain synaptotagmin expression and can form active zones. Tau-expressing NMJs are functionally abnormal and exhibit disrupted vesicle cycling and synaptic transmission. At low-frequency stimulation (1 Hz), ESPs (evoked synaptic potentials) produced by tau-expressing motor neurons were indistinguishable from wild-type; however, following high-frequency stimulation (50 Hz), ESPs from tau-expressing NMJs were significantly decreased in amplitude. To investigate the mechanism underlying the change in ESPs, we analysed the relative numbers and distribution of mitochondria. This revealed that motor neurons expressing tau had a significant reduction in the number of detectable mitochondria in the pre-synaptic terminal. Our results demonstrate that tau overexpression results in synaptic dysfunction, associated with a reduced complement of functional mitochondria. These findings suggest that disruption of axonal transport and synaptic transmission may be key components of the pathogenic mechanism that underlie neuronal dysfunction in the early stages of tauopathies.
Biochemical Society Transactions 03/2006; 34(Pt 1):88-90. · 3.71 Impact Factor
