Showing 111 - 116 of 116 Items
The combinatorial effects of temperature and salinity on the nervous system of the American lobster, Homarus americanus
Date: 2024-01-01
Creator: Katrina Carrier
Access: Open access
- The ability of nervous systems to maintain function when exposed to global perturbations in temperature and salinity is a non-trivial task. The nervous system of the American lobster (H. americanus), a marine osmoconformer and poikilotherm, must be robust to these stressors, as they frequently experience fluctuations in both. I characterized the effects of temperature on the output of the pyloric circuit, a central pattern generator in the stomatogastric nervous system (STNS) that controls food filtration and established the maximum temperature that neurons in this circuit can withstand without “crashing” (ceasing to function but recovering when returned to normal conditions). I established a range of saline concentrations that did not cause the system to crash, and then determined whether combinatorial changes in temperature and salinity concentrations alter the maximum temperature the system tolerated. Even as burst frequency increased as temperature increased, phase constancy was observed. Interestingly, the system crashed at higher temperatures upon exposure to lower saline concentrations and lower temperatures in higher saline concentrations. I also established the range of saline concentrations that the lobster’s whole heart and cardiac ganglion (CG), the nervous system that controls the lobster’s heartbeat, can withstand. Then, I examined whether exposure to altered salinity and elevated temperature alters the crash temperature of the whole heart and CG. The CG crashed at higher temperatures than the whole heart in each saline concentration. Like the STNS, the whole heart and CG both crashed at higher temperatures in lower saline concentrations and higher temperatures in lower saline concentrations.
Peripheral modulation of cardiac contractions in the American lobster, Homarus americanus, by the peptide myosuppressin is mediated by effects on the cardiac muscle itself
Date: 2023-01-01
Creator: Isabel Stella Petropoulos
Access: Open access
- A substantial factor for behavioral flexibility is modulation — largely via neuropeptides — which occurs at multiple sites including neurons, muscles, and the neuromuscular junction (NMJ). Complex modulation distributed across multiple sites provides an interesting question: does modulation at multiple locations lead to greater dynamics than one receptor site alone? The cardiac neuromuscular system of the American lobster (Homarus americanus), driven by a central pattern generator called the cardiac ganglion (CG), is a model system for peptide modulation. The peptide myosuppressin (pQDLDHVFLRFamide) has been shown in the whole heart to decrease contraction frequency, largely due to its effects on the CG, as well as increase contraction amplitude by acting on periphery of the neuromuscular system, either at the cardiac muscle, the NMJ, or both. This set of experiments addresses the location(s) at which myosuppressin exerts its effects at the periphery. To elucidate myosuppressin’s effects on the cardiac muscle, the CG was removed, and muscle contractions were stimulated with L-glutamate while superfusing myosuppressin. Myosuppressin increased glutamate-evoked contraction amplitude in the isolated muscle, suggesting that myosuppressin exerts its peripheral effects directly on the cardiac muscle. To examine effects on the NMJ, excitatory junction potentials were evoked by stimulating of the motor nerve and intracellularly recording a single muscle fiber both in control saline and in the presence of myosuppressin. Myosuppressin did not modulate the amplitude of EJPs suggesting myosuppressin acts at the muscle and not at the NMJ, to cause an increase in contraction amplitude.
Modulation of the crustacean cardiac neuromuscular system by the SLY neuropeptide family
Date: 2024-01-01
Creator: Grant Griesman
Access: Open access
- Central pattern generators (CPGs) are neuronal networks that produce rhythmic motor output in the absence of sensory stimuli. Invertebrate CPGs are valuable models of neural circuit dynamics and neuromodulation because they continue to generate fictive activity in vitro. For example, the cardiac ganglion (CG) of the Jonah crab (Cancer borealis) and American lobster (Homarus americanus) contains nine electrochemically coupled neurons that fire bursts of action potentials to trigger a heartbeat. The CG is modulated by neuropeptides, amines, small molecule transmitters, gases, and mechanosensory feedback pathways that enable flexibility and constrain output. One such modulator, the SLY neuropeptide family, was previously shown to be expressed in hormonal release sites and within the CG itself and has unusual processing features. However, its physiological effect was unknown. Here, I performed dose-response experiments in the crab and lobster whole heart and isolated CG to determine the threshold concentration of SLY neuropeptides to which these systems respond. The crab isoform had strong, excitatory effects in the crab whole heart and weakly modulated the crab CG. The lobster isoform weakly modulated the lobster whole heart and CG. Surprisingly, the crab isoform exerted large, variable effects on the lobster system, which suggests that SLY neuropeptides, their receptors, and their signaling pathways may be evolutionarily conserved across these two species. This research contributes to our understanding of how neural circuits can generate flexible output in response to modulation. It may also offer insight into processes influenced by peptidergic neurotransmission in the nervous systems of other animals, including mammals.
Early life adversity-induced affective dysfunction and ketamine treatment: Exploring the role of parvalbumin and DNA methylation Access to this record is restricted to members of the Bowdoin community. Log in here to view.
Date: 2025-01-01
Creator: Yanevith A. Peña
Access: Access restricted to the Bowdoin Community
The Temperature Dependency of Myosuppressin’s Modulatory Activity on the Homarus Americanus Cardiac Neuromuscular system
Date: 2025-01-01
Creator: Yasemin Altug
Access: Open access
- In order to maintain circuit stability through environmental perturbations, such as increases in temperature, neural circuits are able to adjust their output via modulatory and ion channel regulation. For instance, peptide modulators enable the lobster cardiac neuromuscular system to sustain physiological function at temperatures that surpass the crash temperature of the organ in the absence of modulation. Crash temperature is defined as the temperature at which neural activity ceases. For a crash, this temperature induced loss of activity is recovered when temperature is returned within the permissible range. Thus, it is hypothesized that there are underlying physiological mechanisms employed by the nervous system that compensates for changes in temperature and provides stability within acute temperature fluctuations. Neuromodulatory mechanisms have been proposed as one hypothesis that provide this temperature compensation. In accordance with previously collected data (Lemus 2022), I hypothesized that myosuppressin, a crustacean neuropeptide, provides stability during acute temperature variations. Because myosuppressin acts on the cardiac neurons and muscles separately, we hypothesized that the myosuppressin-induced increase in heart contraction amplitude, and decrease in contraction period can offset each other to provide system stability as temperature is increased. To test whether or not myosuppressin stabilizes circuit output as temperature is increased, myosuppressin was applied to the lobster whole heart at 7ºC, 10ºC, 13ºC and 16ºC, for 20 minutes. Changes in cardiac output in response to temperature and modulation were assessed by measuring the contraction force, heart beat frequency, and minimum contraction force. Interestingly, and contrary to previous results, in this data set, the cardiac neuromuscular system was temperature compensated in saline alone (control), and was not temperature compensated when perfused with myosuppressin (10-6 M). These findings seemed to differ from Lemus’ data (2023), where the cardiac neuromuscular system was not temperature compensated in control conditions and became temperature compensated when perfused with myosuppressin. The seasons at which each data set was collected (June-August vs November-March) could underlie these observed discrepancies.
Age-dependent effects of capsaicin on the mammalian spinal CPG locomotor network Access to this record is restricted to members of the Bowdoin community. Log in here to view.
Date: 2025-01-01
Creator: Jasmine Jia
Access: Access restricted to the Bowdoin Community