Pheromone Transduction in Moths

Stengl, Monika

doi:10.3389/fncel.2010.00133

Cited by 89 publications

(138 citation statements)

References 157 publications

(275 reference statements)

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“…The MGC is marked in gray, while the various"ordinary glomeruli" are marked in different colors. trophysiological, and genetic investigations carried out in the last 20 years also suggest the existence of a G-protein-mediated metabotropic mechanism in pheromone signal transduction: in this context, studies on various moth species support a pheromone-activated IP 3 signal cascade in pheromone-sensitive OSNs [39,52]. A corresponding model which attempts to combine experimental findings obtained to date (.…”

Section: Olfactory Signal Transductionmentioning

confidence: 94%

“…Alternatively, it has been proposed that binding of the PBP-pheromone complex to SNMP reverses an inhibition of the pheromone receptor (PR x )-Orco complex, thus triggering an influx of cations into the cell [24]. D Several lines of evidence indicate a G-protein-mediated pathway in pheromone recognition [52]. Receptor activation could thus activate a phospholipase C (PLCβ) via a G q -protein, which converts phosphoinositol-(4,5)-biphosphate (PIP 2 ) into inositol trisphosphate (IP 3 ) and diacylglycerol (DAG).…”

Section: Olfactory Signal Transductionmentioning

confidence: 98%

“…3D) proposes that the binding of a pheromone molecule to a specific pheromone receptor mediates the activation of a G-protein and, subsequently, a phospholipase C (PLC); this enzyme catalyzes the hydrolysis of phosphatidyl-4,5-bisphosphate to yield inositol trisphosphate (IP 3 ) and diacylglycerol (DAG). IP 3 then opens a calcium (Ca 2+ )-selective ion channel, which in turn"gates" further non-selective cation channels via the calcium influx [52]. How the expression of the cAMP-activatable Orco channel in pheromone-responsive OSNs is reconcilable with this signal transduction cascade remains as yet unclear.…”

Section: Olfactory Signal Transductionmentioning

confidence: 99%

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Olfaction in insects

Sachse

Krieger

2011

E-Neuroforum

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SummaryOdorants provide insects with crucial information about their environment and trigger various insect behaviors. A remarkably sensitive and selective sense of smell allows the animals to detect extremely low amounts of relevant odorants and thereby recognize, e.g., food, conspecifics, and predators. In recent years, significant progress has been made towards understanding the molecular elements and cellular mechanisms of odorant detection in the antenna and the principles underlying the primary processing of olfactory signals in the brain. These findings show that olfactory hairs on the antenna are specifically equipped with chemosensory detector units. They contain several binding proteins, which transfer odorants to specific receptors residing in the dendritic membrane of olfactory sensory neurons (OSN). Binding of odorant to the receptor initiates ionotropic and/or metabotropic mechanisms, translating the chemical signal into potential changes, which alter the spontaneous action potential frequency in the axon of the sensory neurons. The odor-dependent action potentials propagate from the antennae along the axon to the brain leading to an input signal within the antennal lobe. In the antennal lobe, the first relay station for olfactory information, the input signals are extensively processed by a complex network of local interneurons before being relayed by projection neurons to higher brain centers, where olfactory perception takes place.

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Section: Olfactory Signal Transductionmentioning

confidence: 94%

Section: Olfactory Signal Transductionmentioning

confidence: 98%

Section: Olfactory Signal Transductionmentioning

confidence: 99%

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Olfaction in insects

Sachse

Krieger

2011

E-Neuroforum

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“…Decreases in sensitivity of the sensory system may be due to changes in the permeability of ion channels, mainly by increases in the intracellular Ca ++ concentration. Increase in intracellular Ca ++ is usually caused by the activation of CNG Ca ++ channels (Stengl, 2010). Broillet & Firestein (1997) describe a Ca ++ channel directly activated by NO in rats.…”

Section: Discussionmentioning

confidence: 99%

Deterrence of feeding in Rhodnius prolixus (Hemiptera: Reduviidae) after treatment of antennae with a nitric oxide donor

Sfara¹,

Zerba²,

Alzogaray³

2011

Eur. J. Entomol.

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Abstract. The blood-sucking bug Rhodnius prolixus is the main vector of Chagas Disease in Colombia, Venezuela and several countries in Central America. Nitric oxide (NO) is a ubiquitous gaseous molecule present in most types of cell and participates in the olfactory pathway of insects. In this work, nitroso-acetyl-cysteine (SNAC), a nitric oxide donor, was topically applied to the antennae of fifth instar nymphs of R. prolixus. After SNAC treatment, these insects showed a dose-dependent reluctance to feed when provided with a living pigeon as the food source (ED50 = 5.2 µg/insect). However, there was no reluctance to feed when dbcGMP was applied to the antennae of nymphs. In another experiment, insects that had their antennae treated with SNAC were less attracted than the control group to a CO2 source. A possible role of NO in the olfactory pathway of R. prolixus is discussed.

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“…There are marked similarities in the neural olfactory pathways in different phyla (reviewed by Hildebrand and Shepherd, 1997;Ache and Young, 2005;Wilson, 2008;Su et al, 2009), and temporal patterns of neuron activity play a role in olfactory coding in many types of animal (reviewed by Laurent et al, 2001;Stengl, 2010;Junek et al, 2010). Thus, the temporal patterns of active sampling (sniffing) of the odor environment by an olfactory organ can influence the brain's response to odors (reviewed by Ache and Young, 2005;Wilson, 2008), and temporal properties of the stimuli used in neurobiological experiments can affect olfactory coding (e.g.…”

Section: Features Of Odor Stimuli That Affect Neuron Firingmentioning

confidence: 99%