Octopamine regulates essential processes in nematodes; however, little is known about the physiological role of its precursor, tyramine. In the present study, we have characterized alternatively spliced Caenorhabditis elegans tyramine receptor isoforms (SER-2 and SER-2A) that differ by 23 amino acids within the mid-region of the third intracellular loop. Membranes prepared from cells expressing either SER-2 or SER-2A bind [3 H]lysergic acid diethylamide (LSD) in the low nanomolar range and exhibit highest affinity for tyramine. Similarly, both isoforms exhibit nearly identical K i values for a number of antagonists. In contrast, SER-2A exhibits a significantly lower affinity than SER-2 for other physiologically relevant biogenic amines, including octopamine. Pertussis toxin treatment reduces affinity for both tyramine and octopamine, especially for octopamine in membranes from cells expressing SER-2, suggesting that the conformation of the mid-region of the third intracellular loop is dictated by G-protein interactions and is responsible for the differential tyramine/octopamine affinities of the two isoforms. Tyramine reduces forskolin-stimulated cAMP levels in HEK293 cells expressing either isoform with nearly identical IC 50 values. Tyramine, but not octopamine, also elevates Ca 2+ levels in cells expressing SER-2 and to a lesser extent SER-2A. Most importantly, ser-2 null mutants (pk1357) fail to suppress head movements while reversing in response to nose-touch, suggesting a role for SER-2 in the regulation of foraging behavior, and fail to respond to tyramine in assays measuring serotonindependent pharyngeal pumping. These are the first reported functions for SER-2. These results suggest that C. elegans contains tyramine receptors, that individual SER-2 isoforms may differ significantly in their sensitivity to other physiologically relevant biogenic amines, such as octopamine (OA), and that tyraminergic signaling may be important in the regulation of key processes in nematodes.
Low-level exposure to 980 nm laser light can accelerate wound healing in vitro without measurable temperature increases. However, these results also demonstrate the need for appropriate supervision of laser therapy sessions to prevent overexposure to NIR laser light that may inhibit cell growth rates observed in response to lower intensity laser exposure.
Reproduction requires adequate energy stores for parents and offspring to survive. Kiss1 neurons, which are essential for fertility, have the potential to serve as the central sensors of metabolic factors that signal to the reproductive axis the presence of stored calories. Paradoxically, obesity is often accompanied by infertility. Despite excess circulating levels of insulin and leptin, obese individuals exhibit resistance to both metabolic factors in many neuron types. Thus, resistance to insulin or leptin in Kiss1 neurons could lead to infertility. Single deletion of the receptors for either insulin or the adipokine leptin from Kiss1 neurons does not impair adult reproductive dysfunction. However, insulin and leptin signaling pathways may interact in such a way as to obscure their individual functions. We hypothesized that in the presence of genetic or obesity-induced concurrent insulin and leptin resistance, Kiss1 neurons would be unable to maintain reproductive function. We therefore induced a chronic hyperinsulinemic and hyperleptinemic state in mice lacking insulin receptors in Kiss1 neurons through high fat feeding and examined the impact on fertility. In an additional, genetic model, we ablated both leptin and insulin signaling in Kiss1 neurons (IR/LepRKiss mice). Counter to our hypothesis, we found that the addition of leptin insensitivity did not alter the reproductive phenotype of IRKiss mice. We also found that weight gain, body composition, glucose and insulin tolerance were normal in mice of both genders. Nonetheless, leptin and insulin receptor deletion altered pubertal timing as well as LH and FSH levels in mid-puberty in a reciprocal manner. Our results confirm that Kiss1 neurons do not directly mediate the critical role that insulin and leptin play in reproduction. However, during puberty kisspeptin neurons may experience a critical window of susceptibility to the influence of metabolic factors that can modify the onset of fertility.
The physiology and circuitry associated with dorsal cochlear nucleus neurons (DCN) have been well described. The ability to remotely manipulate neuronal activity in these neurons would represent a step forward in the ability to understand the specific function of DCN neurons in hearing. Although, optogenetics has been used to study the function of pathways in other systems for several years, in the auditory system only neurons in the auditory cortex have been studied using this technique. Adeno-associated viral vectors with either channelrhodopsin-2 fused with GFP (ChR2-GFP) or halorhodopsin fused with mCherry (HaloR-mCherry), capable of expressing light sensitive cation channels or chloride pumps, respectively, were delivered into the dorsal cochlear nucleus (DCN). One to 18 months later, expression of ChR2 and HaloR was observed throughout the DCN. Rhodopsin distribution within the DCN was determined to be within several cell types identified based on morphology and location within the DCN. Expression of ChR2-GFP and HaloR-mCherry was found at both the injection site as well as in regions receiving projections from the site. Wavelength appropriate optical stimulation in vivo resulted in neuronal activity that was significantly increased over pre-stimulation levels with no return to baseline levels during the time of the light exposure. We also examined the effects of optically driven neuronal activity on subsequent tone driven responses in the DCN. In the DCN 75 % of the 16 electrode sites showed decreased neuronal activity in response to a tone immediately following light stimulation while six percent were decreased following tone stimulation and 19% of the electrode sites showed no change. This is in contrast to tone driven neuronal activity prior to the light exposure in which the majority of electrode sites showed increased neuronal activity. Our results indicate that expression and activation of rhodopsin within neurons involved in auditory processing does not appear to have deleterious effects on hearing even 18 months following expression. In addition, virally targeted rhodopsins may be useful as tract tracers to delineate as well as modulate the activity of pathways and specific neurons. In the future rhodopsins can be targeted to specific subpopulations auditory neurons. Ultimately, photostimulation may provide a physiologically relevant method for modulating the function of auditory neurons and affecting hearing outcomes.
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