Your search keyword '"Karen A. Mesce"' showing total 56 results

1. Editorial: Naturalistic neuroscience — Towards a full cycle from lab to field

Author

Susanne Hoffmann, M. Jerome Beetz, Anna Stöckl, and Karen A. Mesce

Subjects

animal behavior, sensory system, motor control, brain, natural stimuli, Neurosciences. Biological psychiatry. Neuropsychiatry, RC321-571

Published

2023

2. A review of the bioeffects of low-intensity focused ultrasound and the benefits of a cellular approach

Author

Morgan N. Collins and Karen A. Mesce

Subjects

low-intensity focused ultrasound, non-invasive brain stimulation, neuromodulation, transcranial focused ultrasound, leech, thermal modulation, Physiology, QP1-981

Abstract

This review article highlights the historical developments and current state of knowledge of an important neuromodulation technology: low-intensity focused ultrasound. Because compelling studies have shown that focused ultrasound can modulate neuronal activity non-invasively, especially in deep brain structures with high spatial specificity, there has been a renewed interest in attempting to understand the specific bioeffects of focused ultrasound at the cellular level. Such information is needed to facilitate the safe and effective use of focused ultrasound to treat a number of brain and nervous system disorders in humans. Unfortunately, to date, there appears to be no singular biological mechanism to account for the actions of focused ultrasound, and it is becoming increasingly clear that different types of nerve cells will respond to focused ultrasound differentially based on the complement of their ion channels, other membrane biophysical properties, and arrangement of synaptic connections. Furthermore, neurons are apparently not equally susceptible to the mechanical, thermal and cavitation-related consequences of focused ultrasound application—to complicate matters further, many studies often use distinctly different focused ultrasound stimulus parameters to achieve a reliable response in neural activity. In this review, we consider the benefits of studying more experimentally tractable invertebrate preparations, with an emphasis on the medicinal leech, where neurons can be studied as unique individual cells and be synaptically isolated from the indirect effects of focused ultrasound stimulation on mechanosensitive afferents. In the leech, we have concluded that heat is the primary effector of focused ultrasound neuromodulation, especially on motoneurons in which we observed a focused ultrasound-mediated blockade of action potentials. We discuss that the mechanical bioeffects of focused ultrasound, which are frequently described in the literature, are less reliably achieved as compared to thermal ones, and that observations ascribed to mechanical responses may be confounded by activation of synaptically-coupled sensory structures or artifacts associated with electrode resonance. Ultimately, both the mechanical and thermal components of focused ultrasound have significant potential to contribute to the sculpting of specific neural outcomes. Because focused ultrasound can generate significant modulation at a temperature

Published

2022

3. A Tyrosine-Hydroxylase Characterization of Dopaminergic Neurons in the Honey Bee Brain

Author

Stevanus R. Tedjakumala, Jacques Rouquette, Marie-Laure Boizeau, Karen A. Mesce, Lucie Hotier, Isabelle Massou, and Martin Giurfa

Subjects

Apis mellifera, dopamine, dopaminergic signaling, neural circuits, neural clusters, Neurosciences. Biological psychiatry. Neuropsychiatry, RC321-571

Abstract

Dopamine (DA) plays a fundamental role in insect behavior as it acts both as a general modulator of behavior and as a value system in associative learning where it mediates the reinforcing properties of unconditioned stimuli (US). Here we aimed at characterizing the dopaminergic neurons in the central nervous system of the honey bee, an insect that serves as an established model for the study of learning and memory. We used tyrosine hydroxylase (TH) immunoreactivity (ir) to ensure that the neurons detected synthesize DA endogenously. We found three main dopaminergic clusters, C1–C3, which had been previously described; the C1 cluster is located in a small region adjacent to the esophagus (ES) and the antennal lobe (AL); the C2 cluster is situated above the C1 cluster, between the AL and the vertical lobe (VL) of the mushroom body (MB); the C3 cluster is located below the calyces (CA) of the MB. In addition, we found a novel dopaminergic cluster, C4, located above the dorsomedial border of the lobula, which innervates the visual neuropils of the bee brain. Additional smaller processes and clusters were found and are described. The profuse dopaminergic innervation of the entire bee brain and the specific connectivity of DA neurons, with visual, olfactory and gustatory circuits, provide a foundation for a deeper understanding of how these sensory modules are modulated by DA, and the DA-dependent value-based associations that occur during associative learning.

Published

2017

4. Tyrosine hydroxylase immunolabeling reveals the distribution of catecholaminergic neurons in the central nervous systems of the spidersHogna lenta(Araneae: Lycosidae) andPhidippus regius(Araneae: Salticidae)

Author

Anthony Auletta, Karen A. Mesce, Cynthia M. Harley, and Mara C. P. Rue

Subjects

Adrenergic Neurons, Central Nervous System, 0301 basic medicine, Hogna, Tyrosine 3-Monooxygenase, genetic structures, Wolf spider, Jumping spider, 03 medical and health sciences, Catecholamines, 0302 clinical medicine, Animals, Phidippus regius, Catecholaminergic, Spider, biology, Tyrosine hydroxylase, Dopaminergic Neurons, General Neuroscience, Spiders, biology.organism_classification, Immunohistochemistry, 030104 developmental biology, nervous system, Evolutionary biology, Catecholaminergic cell groups, 030217 neurology & neurosurgery

Abstract

With over 48,000 species currently described, spiders (Arthropoda: Chelicerata: Araneae) comprise one of the most diverse groups of animals on our planet, and exhibit an equally wide array of fascinating behaviors. Studies of central nervous systems (CNSs) in spiders, however, are relatively sparse, and no reports have yet characterized catecholaminergic (dopamine [DA]- or norepinephrine-synthesizing) neurons in any spider species. Because these neuromodulators are especially important for sensory and motor processing across animal taxa, we embarked on a study to identify catecholaminergic neurons in the CNS of the wolf spider Hogna lenta (Lycosidae) and the jumping spider Phidippus regius (Salticidae). These neurons were most effectively labeled with an antiserum raised against tyrosine hydroxylase (TH), the rate-limiting enzyme in catecholamine synthesis. We found extensive catecholamine-rich neuronal fibers in the first- and second-order optic neuropils of the supraesophageal mass (brain), as well as in the arcuate body, a region of the brain thought to receive visual input and which may be involved in higher order sensorimotor integration. This structure likely shares evolutionary origins with the DA-enriched central complex of the Mandibulata. In the subesophageal mass, we detected an extensive filigree of TH-immunoreactive (TH-ir) arborizations in the appendage neuromeres, as well as three prominent plurisegmental fiber tracts. A vast abundance of TH-ir somata were located in the opisthosomal neuromeres, the largest of which appeared to project to the brain and decorate the appendage neuromeres. Our study underscores the important roles that the catecholamines likely play in modulating spider vision, higher order sensorimotor processing, and motor patterning.

Published

2019

5. Contributors

Author

François Auclair, Francisco D. Benavides, Rune W. Berg, Frederic Bretzner, Ansgar Büschges, Stephano Chang, Denis Combes, Lan Deng, Réjean Dubuc, Adna S. Dumitrescu, Kevin Fidelin, Alain Frigon, Matthias Gruhn, James D. Guest, Maria Belen Harreguy, Gal Haspel, Maxime Lemieux, Wen-Chang Li, Karen A. Mesce, Morgan Newhoff, Brian R. Noga, Ioan Opris, Gregory E.P. Pearcey, R. Meldrum Robertson, Marie Roussel, Francisco J. Sanchez, Andrea J. Santamaria, Pedro M. Saraiva, Simon A. Sharples, Keith T. Sillar, John Simmers, Juan P. Solano, Zainab Tanvir, Louise Thiry, Luz M. Villamil, Peter A. Wenner, Patrick J. Whelan, Claire Wyart, and E. Paul Zehr

Published

2020

6. Small steps and larger strides in understanding the neural bases of crawling in the medicinal leech

Author

Morgan Newhoff and Karen A. Mesce

Subjects

animal structures, Computer science, Biological neural network, Leech, Crawling, Neuroscience, Neuromodulation (medicine)

Abstract

The nervous system of the medicinal leech (Hirudo species) has often provided elegant solutions to long-standing questions in the field of locomotor control. Such outcomes stem from its easily accessible and relatively large neurons, metameric organization, identified aminergic neuromodulation, and known role of action-selection neurons descending from the brain. Neural circuits underlying leech swimming were first revealed in the 1970s, but it has only been in the past two decades that crawling, the focus of this chapter, has shared the spotlight. In this review, we will discuss the functional architecture of crawling, its differences compared to swimming, and the inherent plasticity that enables the leech to recover its locomotion after injury. We will also underscore the full utility of the leech model while looking toward the future, focusing on the technological advances and expanded tool kits that will ensure that the leech persists as a valuable preparation for generations to come.

Published

2020

7. The Inhibitory Thermal Effects of Focused Ultrasound on an Identified, Single Motoneuron

Author

Wynn Legon, Morgan N. Collins, and Karen A. Mesce

Subjects

Action Potentials, Biology, Novel Tools and Methods, Inhibitory postsynaptic potential, Interneurons, Leeches, medicine, Animals, Humans, Tonic (music), Premovement neuronal activity, conduction block, Motor Neurons, Mechanism (biology), General Neuroscience, Depolarization, General Medicine, electrophysiology, invertebrates, thermal inhibition, Neuromodulation (medicine), Electrophysiology, medicine.anatomical_structure, nervous system, focused ultrasound, motoneurons, Neuron, Neuroscience, Research Article: New Research

Abstract

Focused ultrasound (US) is an emerging neuromodulation technology that has gained much attention because of its ability to modulate, noninvasively, neuronal activity in a variety of animals, including humans. However, there has been considerable debate about exactly which types of neurons can be influenced and what underlying mechanisms are in play. Are US-evoked motor changes driven indirectly by activated mechanosensory inputs, or more directly via central interneurons or motoneurons? Although it has been shown that US can mechanically depolarize mechanosensory neurons, there are no studies that have yet tested how identified motoneurons respond directly to US and what the underlying mechanism might be. Here, we examined the effects of US on a single, identified motoneuron within a well-studied and tractable invertebrate preparation, the medicinal leech,Hirudo verbana. Our approach aimed to clarify single neuronal responses to US, which may be obscured in other studies whereby US is applied across a diverse population of cells. We found that US has the ability to inhibit tonic spiking activity through a predominately thermal mechanism. US-evoked effects persisted after blocking synaptic inputs, indicating that its actions were direct. Experiments also revealed that US-comparable heating blocked the axonal conduction of spontaneous action potentials. Finally, we found no evidence that US had significant mechanical effects on the neurons tested, a finding counter to prevailing views. We conclude that a non-sensory neuron can be directly inhibited via a thermal mechanism, a finding that holds promise for clinical neuromodulatory applications.

Published

2021

8. Focused Ultrasound Neuromodulation and the Confounds of Intracellular Electrophysiological Investigation

Author

Morgan N. Collins and Karen A. Mesce

Subjects

leak currents, Sensory system, Biology, Novel Tools and Methods, Nervous System, Membrane Potentials, electrode resonance, cavitation, Leeches, Animals, Premovement neuronal activity, Neurons, Membrane potential, General Neuroscience, Depolarization, General Medicine, Hirudo verbana, intracellular recording, Neuromodulation (medicine), Electrophysiological Phenomena, Electrophysiology, ultrasound neuromodulation, Mechanosensitive channels, Neuroscience, Research Article: New Research, Intracellular

Abstract

Focused ultrasound (US) can modulate neuronal activity noninvasively with high spatial specificity. In intact nervous systems, however, efforts to determine its enigmatic mode of efficacy have been confounded by the indirect effects of US on mechanosensitive sensory cells and the inability to target equivalent populations of cells with precision across preparations. Single-cell approaches, either via cultured mammalian neurons or tractable invertebrate neural systems, hold great promise for elucidating the cellular mechanisms underlying the actions of US. Here, we present evidence from the medicinal leech,Hirudo verbana, that researchers should apply caution when using US in conjunction with single-cell electrophysiological recording techniques, including sharp-electrode intracellular recording. Although we found that US could elicit depolarization of the resting membrane potential of single neurons, a finding with precedent, we determined that this effect and others could be reliably mimicked via subtle manual displacement of the recording electrode. Because focused US is known to induce resonance of recording electrodes, we aimed to determine how similarly US-induced depolarizations matched those produced by micro movements of a sharp glass electrode, a phenomenon we believe can account for purported depolarizations measured in this manner. Furthermore, we show that when clonally related homologous neurons, which are essentially isopotential, are impaled before the application of focused US, they show a statistically significant change in their membrane potential as compared with the homologous cells that received US with no initial impalement. Future investigations into US’s cellular effects should attempt to control for potential electrode resonance or use alternative recording strategies.

Published

2020

9. Functional Recovery of a Locomotor Network after Injury: Plasticity beyond the Central Nervous System

Author

Anthony W. Bigelow, Karen A. Mesce, Joshua G. Puhl, and Mara C. P. Rue

Subjects

animal structures, Dopamine, Central nervous system, Biology, Hirudo medicinalis, homeostatic plasticity, Lesion, 03 medical and health sciences, Bursting, 0302 clinical medicine, Homeostatic plasticity, medicine, Animals, 030304 developmental biology, Motor Neurons, 0303 health sciences, Neuronal Plasticity, urogenital system, General Neuroscience, fungi, Central pattern generator, General Medicine, Recovery of Function, New Research, Proprioception, spinal cord injury, Ganglion, Ganglia, Invertebrate, locomotion, medicine.anatomical_structure, Peripheral nervous system, CPG, crawling, 8.1, Central Pattern Generators, Sensory and Motor Systems, Neuron, medicine.symptom, Neuroscience, 030217 neurology & neurosurgery

Abstract

Many animals depend on descending information from the brain for the initiation and proper execution of locomotion. Interestingly, after injury and the loss of such inputs, locomotor function can sometimes be regained without the regrowth of central connections. In the medicinal leech,Hirudo verbana, we have shown that crawling reemerges after removal of descending inputs. Here, we studied the mechanisms underlying this return of locomotion by asking if central pattern generators (CPGs) in crawl-recovered leeches are sufficient to produce crawl-specific intersegmental coordination. From recovered animals, we treated isolated chains of ganglia with dopamine to activate the crawl CPGs (one crawl CPG per ganglion) and observed fictive crawl-like bursting in the dorsal-longitudinal-excitor motoneuron (DE-3), an established crawl-monitor neuron. However, these preparations did not exhibit crawl-specific coordination across the CPGs. Although the crawl CPGs always generated bidirectional activation of adjacent CPGs, we never observed crawl-appropriate intersegmental phase delays. Because central circuits alone were unable to organize crawl-specific coordination, we tested the coordinating role of the peripheral nervous system. In transected leeches normally destined for recovery, we removed afferent information to the anterior-most (lead) ganglion located below the nerve-cord transection site. In these dually treated animals, overt crawling was greatly delayed or prevented. After filling the peripheral nerves with Neurobiotin tracer distal to the nerve-root lesion, we found a perfect correlation between regrowth of peripheral neuronal fibers and crawl recovery. Our study establishes that during recovery after injury, crawl-specific intersegmental coordination switches to a new dependence on afferent information.

Published

2018

10. An annotated CNS transcriptome of the medicinal leech, Hirudo verbana: De novo sequencing to characterize genes associated with nervous system activity

Author

Karen A. Mesce, Joshua G. Puhl, David J. Schulz, Adam J. Northcutt, and Eva K. Fischer

Subjects

0301 basic medicine, Nervous system, Central Nervous System, Potassium Channels, Physiology, De novo transcriptome assembly, lcsh:Medicine, Hirudo medicinalis, Nervous System, Biochemistry, Ion Channels, Transcriptome, Database and Informatics Methods, 0302 clinical medicine, Transient Receptor Potential Channels, RefSeq, Medicine and Health Sciences, Annelids, lcsh:Science, Multidisciplinary, Contig, Physics, Eukaryota, Genomics, Electrophysiology, medicine.anatomical_structure, Physical Sciences, Anatomy, Transcriptome Analysis, Sequence Analysis, Research Article, Bioinformatics, Biophysics, Leech, Neurophysiology, Sequence Databases, Computational biology, Biology, Research and Analysis Methods, 03 medical and health sciences, Leeches, medicine, Genetics, Animals, Sequence database, Gene Expression Profiling, lcsh:R, Organisms, Biology and Life Sciences, Computational Biology, Proteins, Ligand-Gated Ion Channels, biology.organism_classification, Genome Analysis, Invertebrates, 030104 developmental biology, Biological Databases, lcsh:Q, Hirudo verbana, 030217 neurology & neurosurgery, Neuroscience

Abstract

The medicinal leech is one of the most venerated model systems for the study of fundamental nervous system principles, ranging from single-cell excitability to complex sensorimotor integration. Yet, molecular analyses have yet to be extensively applied to complement the rich history of electrophysiological study that this animal has received. Here, we generated the first de novo transcriptome assembly from the entire central nervous system of Hirudo verbana, with the goal of providing a molecular resource, as well as to lay the foundation for a comprehensive discovery of genes fundamentally important for neural function. Our assembly generated 107,704 contigs from over 900 million raw reads. Of these 107,704 contigs, 39,047 (36%) were annotated using NCBI’s validated RefSeq sequence database. From this annotated central nervous system transcriptome, we began the process of curating genes related to nervous system function by identifying and characterizing 126 unique ion channel, receptor, transporter, and enzyme contigs. Additionally, we generated sequence counts to estimate the relative abundance of each identified ion channel and receptor contig in the transcriptome through Kallisto mapping. This transcriptome will serve as a valuable community resource for studies investigating the molecular underpinnings of neural function in leech and provide a reference for comparative analyses.

Published

2018

11. The stomatogastric nervous system of the medicinal leech: its anatomy, physiology and associated aminergic neurons

Author

Quentin Gaudry, Joshua G. Puhl, Karen A. Mesce, and Magda Alania

Subjects

0301 basic medicine, Nervous system, Physiology, Leech, Aquatic Science, Biology, Serotonergic, Hirudo medicinalis, Nervous System, 03 medical and health sciences, 0302 clinical medicine, Blood serum, Stomatogastric nervous system, Neuromodulation, medicine, Animals, Nervous System Physiological Phenomena, Molecular Biology, Ecology, Evolution, Behavior and Systematics, Neurons, Dopaminergic, Anatomy, Ganglia, Invertebrate, 030104 developmental biology, medicine.anatomical_structure, Insect Science, Animal Science and Zoology, Neuron, 030217 neurology & neurosurgery

Abstract

Blood feeding is an essential and signature activity of the medicinal leech species H irudo verbana . Despite keen interest in understanding the neuronal substrates of this behavior, a major component of the nervous system associated with feeding has remained overlooked. In this study, for the first time, we report on the presence and characteristics of five stomatogastric ganglia (STGs) comprising the visceral stomatogastric nervous system (STN) of the leech. Although a brief report was published by Ruth Hanke in 1948 indicating that a ring of three ganglia (not five) was associated with the cephalic ganglia, this information was never integrated into subsequent neurobiological studies of feeding. Here, the anatomical features of the STGs are described, as are the morphological and electrophysiological characteristics of neurons originating in them. We also determined that two of the five STGs (STG-1 and STG-3) each contained two relatively large (ca. 40 µm diameter) serotonergic neurons. The STN was also enriched with dopaminergic and serotonergic arborizations; however, no intrinsic dopaminergic somata were observed. The trajectory of the serotonergic large lateral (LL) neuron, a command-like cell for feeding, was documented to project directly to the STN and not to the jaw and pharyngeal musculature as previously reported, thus reopening the important question of how the LL cell activates and coordinates biting activity with pharyngeal swallowing. Additional studies revealed that the LL cell is excited by blood serum applied to the lip and is strongly inhibited by dopamine. These findings provide a new foundation for understanding the regulation and modulation of neural networks involved in feeding.

Published

2017

12. Morphology, ultrastructure and functional role of antennal sensilla in off-host aggregation by the bed bug, Cimex lectularius

Author

Karen A. Mesce, Roger D. Moon, Joelle F. Olson, and Stephen A. Kells

Subjects

Arthropod Antennae, Male, Olfactory system, Bedbugs, animal structures, media_common.quotation_subject, Olfaction, Bed bug, Animals, Metamorphosis, Ecology, Evolution, Behavior and Systematics, media_common, Behavior, Animal, biology, fungi, General Medicine, Anatomy, biology.organism_classification, Pedicel, Insect Science, Microscopy, Electron, Scanning, Ultrastructure, Instar, Female, sense organs, Cimex lectularius, Developmental Biology

Abstract

After blood feeding on a host, bed bugs, Cimex lectularius, assemble in aggregation sites away from the host. Off-host aggregation is mediated by a combination of mechanical and chemical stimuli associated with bug feces. Partial antennectomies indicated removal of flagellomeres did not affect aggregation, but removal of the whole pedicel or its distal half significantly reduced (P

Published

2014

13. Necessary, Sufficient and Permissive: A Single Locomotor Command Neuron Important for Intersegmental Coordination

Author

Karen A. Mesce, Mark A. Masino, and Joshua G. Puhl

Subjects

Central Nervous System, Nervous system, animal structures, Dopamine, Models, Neurological, Central nervous system, Action Potentials, Context (language use), Biology, Crawling, Article, Bursting, Leeches, medicine, Animals, Motor Neurons, Adaptive behavior, Communication, business.industry, General Neuroscience, fungi, medicine.anatomical_structure, Command neuron, Neuron, business, Neuroscience, Locomotion

Abstract

In this report we posed the overarching question: What multiple contributions can a single neuron have on controlling the behavior of an animal, especially within a given context? To address this timely question, we studied the neuron R3b-1 in the medicinal leech. This bilaterally paired neuron descends from the cephalic ganglion and projects uninterrupted through the segmental ganglia comprising the nerve cord; its terminal arbors invade each hemi-ganglion. We discovered that a single R3b-1 neuron functions as a command neuron in the strictest sense, as it was both necessary and sufficient for fictive crawling behavior. Aside from these command-related properties, we determined that R3b-1 modulates the cycle period of crawl motor activity. R3b-1 has previously been shown to activate swimming behavior, but when the CNS was exposed to dopamine (DA), crawling became the exclusive locomotor pattern produced by R3b-1. DA exposure also led to bursting in R3b-1 that matched periods observed during fictive crawling, even when potential ascending inputs from crawl oscillators were removed. Although the above attributes render R3b-1 an intriguing cell, it is its ability to permit the coordination of the segmentally distributed crawl oscillators that makes this multifunctional neuron so notable. To our knowledge, this cell provides the first biological example of a single command neuron that is also vital for the intersegmental coordination of a locomotor behavior. Furthermore, our study highlights the importance of DA as an internal contextual cue that can integrate functional layers of the nervous system for adaptive behavior.

Published

2012

14. Keeping It Together: Mechanisms of Intersegmental Coordination for a Flexible Locomotor Behavior

Author

Joshua G. Puhl and Karen A. Mesce

Subjects

animal structures, Flexibility (anatomy), Dopamine, General Neuroscience, Depolarization, Motor Activity, Crawling, Biology, Article, Ganglia, Invertebrate, Ganglion, Electrophysiology, Coupling (electronics), Bursting, medicine.anatomical_structure, Leeches, medicine, Excitatory postsynaptic potential, Animals, Neuroscience

Abstract

The coordination of multiple neural oscillators is key for the generation of productive locomotor movements. In the medicinal leech, we determined that activation and coordination of the segmental crawl oscillators, or unit burst generators, are dependent on signals descending from the cephalic ganglion. In nearly intact animals, removing descending input (reversibly with a sucrose block) prevented overt crawling, but not swimming. Cephalic depolarization was sufficient for coordination. To determine whether descending signals were necessary for the generation and maintenance of posterior-directed intersegmental phase delays, we induced fictive crawling in isolated whole nerve cords using dopamine (DA) and blocked descending inputs. After blockade, we observed a significant loss of intersegmental coordination. Appropriate phase delays were also absent in DA-treated chains of ganglia. In chains, when one ganglion was removed from its neighbors, crawling in that ganglion emerged robust and stable, underscoring that these oscillators operate best with either all or none of their intersegmental inputs. To study local oscillator coupling, we induced fictive crawling (with DA) in a single oscillator within a chain. Although appropriate intersegmental phase delays were always absent, when one ganglion was treated with DA, neighboring ganglia began to show crawl-like bursting, with motoneuron spikes/burst greatest in untreated posterior ganglia. We further determined that this local excitatory drive excluded the swim-gating cell, 204. In conclusion, both long-distance descending and local interoscillator coupling contribute to crawling. This dual contribution helps to explain the inherent flexibility of crawling, and provides a foundation for understanding other dynamic locomotor behaviors across animal groups.

Published

2010

15. Dopamine Activates the Motor Pattern for Crawling in the Medicinal Leech

Author

Karen A. Mesce and Joshua G. Puhl

Subjects

Motor Neurons, animal structures, biology, urogenital system, Dopamine, General Neuroscience, fungi, Central pattern generator, Leech, Motor Activity, Crawling, Hirudo medicinalis, biology.organism_classification, Spinal cord, Inhibitory postsynaptic potential, Article, Ganglion, Bursting, medicine.anatomical_structure, Hirudo, medicine, Animals, Neuroscience, Locomotion

Abstract

Locomotion in segmented animals is thought to be based on the coupling of "unit burst generators," but the biological nature of the unit burst generator has been revealed in only a few animal systems. We determined that dopamine (DA), a universal modulator of motor activity, is sufficient to activate fictive crawling in the medicinal leech, and can exert its actions within the smallest division of the animal's CNS, the segmental ganglion. In the entire isolated nerve cord or in the single ganglion, DA induced slow antiphasic bursting (approximately 15 s period) of motoneurons known to participate in the two-step elongation-contraction cycle underlying crawling behavior. During each cycle, the dorsal (DE-3) and ventral (VE-4) longitudinal excitor motoneurons fired approximately 180 degrees out of phase from the ventrolateral circular excitor motoneuron (CV), which marks the elongation phase. In many isolated whole nerve cords, DE-3 bursting progressed in an anterior to posterior direction with intersegmental phase delays appropriate for crawling. In the single ganglion, the dorsal (DI-1) and ventral (VI-2) inhibitory longitudinal motoneurons fired out of phase with each DE-3 burst, further confirming that the crawl unit burst generator exists in the single ganglion. All isolated ganglia of the CNS were competent to produce DA-induced robust fictive crawling, which typically lasted uninterrupted for 5-15 min. A quantitative analysis indicated that DA-induced crawling was not significantly different from electrically evoked or spontaneous crawling. We conclude that DA is sufficient to activate the full crawl motor program and that the kernel for crawling resides within each segmental ganglion.

Published

2008

16. Cellular substrates of action selection: a cluster of higher-order descending neurons shapes body posture and locomotion

Author

William B. Kristan, Teresa Esch, and Karen A. Mesce

Subjects

Neurons, animal structures, Sensory stimulation therapy, biology, Physiology, Posture, Action Potentials, Central pattern generator, Leech, Anatomy, Crawling, biology.organism_classification, Neuromere, Ganglia, Invertebrate, Electrophysiology, Behavioral Neuroscience, Hirudo, Leeches, Command neuron, Animals, Animal Science and Zoology, Brainstem, Neuroscience, Locomotion, Ecology, Evolution, Behavior and Systematics

Abstract

The selection of distinct movements involved in various body postures and locomotion is often dependent on higher-order descending neurons. To study how such cells select different actions, we used a nearly-intact leech preparation (Hirudo sp.) in which cephalic projection interneurons were recorded and stimulated while the leech generated overt behaviors. Two long-distance projecting neurons were identified in the sub-packet of the third neuromere (R3b) of the subesophageal ganglion. These interneurons, named R3b2 and R3b3, produced changes in whole-body posture, crawling and swimming. Cell R3b2 reliably caused the body to become turgid, to hyper-elongate, and to thrash cyclically. Such robust activity resembled struggling behavior exhibited by intact leeches when grasped. The neighboring cell R3b3 elicited body elongation accompanied by a static whole-body bend to the left or right. R3b3 activity was context-dependent, oscillated in phase with crawling, reset the crawl rhythm, and terminated swimming. Both neuronal types responded to multi-modal sensory stimulation delivered to various rostral and caudal regions of the body. Our study illustrates the need to study behavioral selection with a neuroethological approach, and provides a cellular substrate for the motor action-selection cluster proposed for the vertebrate brainstem.

Published

2008

17. Plasmon resonance and the imaging of metal-impregnated neurons with the laser scanning confocal microscope

Author

Grant M Barthel, Karen A. Mesce, Mark A. Sanders, Cynthia M. Harley, and Karen J. Thompson

Subjects

Microscope, Materials science, Mouse, QH301-705.5, Science, Confocal, Golgi stain, Nanoparticle, noble metals, Grasshoppers, General Biochemistry, Genetics and Molecular Biology, law.invention, Imaging, Three-Dimensional, law, Confocal microscopy, Manduca, Animals, Biology (General), Surface plasmon resonance, Neurons, Microscopy, Confocal, General Immunology and Microbiology, Staining and Labeling, business.industry, Super-resolution microscopy, Primate, General Neuroscience, Surface plasmon, General Medicine, Surface Plasmon Resonance, Laser, 3. Good health, Tools and Resources, super resolution microscopy, Metals, Medicine, Optoelectronics, nanoparticles, motoneurons, business, Insect, Neuroscience

Abstract

The staining of neurons with silver began in the 1800s, but until now the great resolving power of the laser scanning confocal microscope has not been utilized to capture the in-focus and three-dimensional cytoarchitecture of metal-impregnated cells. Here, we demonstrate how spectral confocal microscopy, typically reserved for fluorescent imaging, can be used to visualize metal-labeled tissues. This imaging does not involve the reflectance of metal particles, but rather the excitation of silver (or gold) nanoparticles and their putative surface plasmon resonance. To induce such resonance, silver or gold particles were excited with visible-wavelength laser lines (561 or 640 nm), and the maximal emission signal was collected at a shorter wavelength (i.e., higher energy state). Because the surface plasmon resonances of noble metal nanoparticles offer a superior optical signal and do not photobleach, our novel protocol holds enormous promise of a rebirth and further development of silver- and gold-based cell labeling protocols. DOI: http://dx.doi.org/10.7554/eLife.09388.001, eLife digest A fresh slice of brain tissue has a fairly uniform appearance, even when viewed under a microscope. To study the neurons and other cells in the brain, scientists must therefore first prepare tissue samples using methods that make it easier to see certain kinds of cells, or particular features of them. One method that has been available for over a century is to use metal particles to stain some of the cells. For example, when the Spanish anatomist Santiago Ramón y Cajal investigated how brain cells – or neurons – are organized in the brain in the late 1880s, he made the cells visible by staining them with silver. This silver staining technique, called the Golgi method, bears the name of Camillo Golgi who first discovered it. Both Golgi and Ramón y Cajal are considered to be the pioneers of neuroscience, and shared the Nobel Prize in Physiology or Medicine in 1906. Over the years, silver staining was superseded by the use of fluorescent probes. Light travels in the form of waves, and different colors of light have different wavelengths (the distance between the peaks of the wave). Shining light of one specific color onto a fluorescent probe causes it to emit light of a longer wavelength. By detecting this emitted light, it is possible to visualize structures that contain the probes. In the late 1980s, the invention of the laser-scanning confocal microscope allowed highly detailed three-dimensional reconstructions of individual neurons to be obtained using these fluorescent labels. Unfortunately, the lifespan of fluorescent probes is limited by the fact that their fluorescence decreases with repeated use, in a process called photobleaching. Traditional silver stains avoid this problem, but standard confocal microscopy cannot obtain good images from metal-stained cells. Now, Thompson, Harley et al. have overcome this problem by using the confocal microscope in a new way to detect emitted light with shorter wavelengths than the light that was initially absorbed (rather than the longer wavelength light normally detected). This protocol produced highly detailed three-dimensional images of individual metal-stained neurons that had been impregnated with silver or gold particles. The short wavelength light is thought to result from the activity of free electrons called plasmons that are present on the surface of small metal particles (nanoparticles) that are about one millionth of a centimeter in size. When plasmons absorb radiation of a specific wavelength, they vibrate rapidly and emit their excess energy in the form of light. Medieval craftsmen unknowingly exploited this same phenomenon when they added silver and gold particles to molten stained glass, producing windows with vivid red and yellow colors that are still vibrant today. A return to metal-based staining of brain tissue could produce similar longevity for today’s tissue samples. Equally, the procedure developed by Thompson, Harley et al. opens up the possibility of revisiting archived material with the tools of modern confocal microscopy. DOI: http://dx.doi.org/10.7554/eLife.09388.002

Published

2015

18. Author response: Plasmon resonance and the imaging of metal-impregnated neurons with the laser scanning confocal microscope

Author

Grant M Barthel, Karen J. Thompson, Mark A. Sanders, Karen A. Mesce, and Cynthia M. Harley

Subjects

Metal, Microscope, Materials science, Laser scanning, law, business.industry, Confocal, visual_art, visual_art.visual_art_medium, Optoelectronics, Surface plasmon resonance, business, law.invention

Published

2015

19. Compensatory plasticity restores locomotion after chronic removal of descending projections

Author

Christian Nagel, Emma Morley, Chantel Schlegel, Karen A. Mesce, Chris Stewart, Joshua G. Puhl, Melissa G. Reilly, Cynthia M. Harley, and Kevin M. Crisp

Subjects

animal structures, Time Factors, Physiology, Leech, Biology, Crawling, Litchi, Dopamine, Homeostatic plasticity, medicine, Animals, Neuro Forum, Spinal cord injury, Motor Neurons, Afferent Pathways, Neuronal Plasticity, urogenital system, General Neuroscience, fungi, Central pattern generator, Recovery of Function, medicine.disease, biology.organism_classification, Ganglion, Nerve Regeneration, medicine.anatomical_structure, Hirudo verbana, Neuroscience, Locomotion, Psychomotor Performance, medicine.drug

Abstract

Homeostatic plasticity is an important attribute of neurons and their networks, enabling functional recovery after perturbation. Furthermore, the directed nature of this plasticity may hold a key to the restoration of locomotion after spinal cord injury. Here we studied the recovery of crawling in the leech Hirudo verbana after descending cephalic fibers were surgically separated from crawl central pattern generators shown previously to be regulated by dopamine. We observed that immediately after nerve cord transection leeches were unable to crawl, but remarkably, after a day to weeks, animals began to show elements of crawling and intersegmental coordination. Over a similar time course, excessive swimming due to the loss of descending inhibition returned to control levels. Additionally, removal of the brain did not prevent crawl recovery, indicating that connectivity of severed descending neurons was not essential. After crawl recovery, a subset of animals received a second transection immediately below the anterior-most ganglion remaining. Similar to their initial transection, a loss of crawling with subsequent recovery was observed. These data, in recovered individuals, support the idea that compensatory plasticity directly below the site of injury is essential for the initiation and coordination of crawling. We maintain that the leech provides a valuable model to understand the neural mechanisms underlying locomotor recovery after injury because of its experimental accessibility, segmental organization, and dependence on higher-order control involved in the initiation, modulation, and coordination of locomotor behavior.

Published

2015

20. 'Neuroethoendocrinology': Integration of field and laboratory studies in insect neuroendocrinology

Author

Karen A. Mesce and Susan E. Fahrbach

Subjects

Cognitive science, Insecta, α adrenergic receptors, Endocrine and Autonomic Systems, media_common.quotation_subject, fungi, Neuroendocrinology, Behavioral state, Insect, Molting, Biology, Insect behavior, Neurosecretory Systems, Field (geography), Behavioral Neuroscience, Endocrinology, Insect Hormones, Animals, Octopamine, Neuroscience, media_common

Abstract

Progress in the field of insect neuroendocrinology has been rapid despite the relatively small number of investigators working on insect systems. This progress, in part, reflects the ease of studying insect behavior in the laboratory, and a historical perspective reveals that insect neuroendocrinology has been dominated since its inception by laboratory studies. Recent advances in methodology and a renewed interest in the concept of behavioral state in insects suggest that it might be useful for insect neuroendocrinologists to spend a little more time in the field.

Published

2005

21. Hygienic behavior in the honey bee (Apis mellifera L.) and the modulatory role of octopamine

Author

Rocco Ross, Karen A. Mesce, Rebecca Masterman, and Marla Spivak

Subjects

Foraging, Zoology, Olfaction, Biology, complex mixtures, Cellular and Molecular Neuroscience, Nest, Dibenzazepines, Image Processing, Computer-Assisted, medicine, Animals, Octopamine, Neurons, Microscopy, Confocal, Behavior, Animal, Ecology, General Neuroscience, fungi, Imidazoles, Brain, Hygiene, Honey bee, Bees, Immunohistochemistry, Brood, Electrophysiology, Smell, medicine.anatomical_structure, Odor, Histamine H1 Antagonists, behavior and behavior mechanisms, Antennal lobe, Octopamine (neurotransmitter), Adrenergic alpha-Agonists

Abstract

Honey bees, Apis mellifera, which perform hygienic behavior, quickly detect, uncap and remove diseased brood from the nest. This behavior, performed by bees 15-20 days old and prior to foraging, is likely mediated by olfactory cues. Because the neuromodulator octopamine (OA) plays a pivotal role in olfactory-based behaviors of honey bees, we examined whether bees bred for hygienic and nonhygienic behavior differed with regard to their OA expression and physiology. We compared the staining intensity of octopamine-immunoreactive (OA-ir) neurons in the deutocerebral region of the brain, medial to the antennal lobes, between hygienic and nonhygienic bees (based on genotype and phenotype). We also tested how the olfactory responses of the two lines, based on electroantennograms (EAGs), were affected by oral administration of OA and of epinastine, a highly specific OA antagonist. Our results revealed that bees expressing hygienic behavior (irrespective of genotype) possessed OA-ir neurons that exhibited more intense labeling than same-aged bees not performing the behavior. In bees bred for nonhygienic behavior, OA significantly increased the EAG response to low concentrations of diseased brood odor. Conversely, in bees bred for hygienic behavior, epinastine significantly reduced the magnitude of the EAG response, a reduction not observed in nonhygienic bees. Our results provide two lines of evidence that OA has the potential to facilitate the detection and response of honey bees to diseased brood. We discuss the contributions of OA for behavioral shaping and its ability to bias the nervous system to express one form of behavior over another.

Published

2003

22. Cellular localization of bursicon using antisera against partial peptide sequences of this insect cuticle-sclerotizing neurohormone

Author

Daniel Market, Kathleen A. Klukas, Melanie Wilson, Barbara Kostron, Dennis C. Choi, Elizabeth M. Dewey, Karen A. Mesce, Larry Pierce, and Hans-Willi Honegger

Subjects

Central Nervous System, medicine.medical_specialty, animal structures, Invertebrate Hormones, Neuropeptide, Molting cycle, Gryllidae, Species Specificity, Manduca, Internal medicine, medicine, Animals, Periplaneta, Electrophoresis, Gel, Two-Dimensional, Amino Acid Sequence, Chromatography, High Pressure Liquid, Cellular localization, Bursicon, biology, Immune Sera, General Neuroscience, Gryllus bimaculatus, Neuropeptides, fungi, biology.organism_classification, Immunohistochemistry, Ganglia, Invertebrate, Endocrinology, Biochemistry, Manduca sexta, Larva, Ecdysis, Drosophila

Abstract

Bursicon is the final neurohormone released at the end of the molting cycle. It triggers the sclerotization (tanning) of the insect cuticle. Until now, its existence has been verified only by bioassays. In an attempt to identify this important neurohormone, bursicon was purified from homogenates of 2,850 nerve cords of the cockroach Periplaneta americana by using high performance liquid chromatography technology and two-dimensional gel electrophoresis. Bursicon bioactivity was found in four distinct protein spots at approximately 30 kDa between pH 5.3 and 5.9. The protein of one of these spots at pH 5.7 was subsequently microsequenced, and five partial amino acid sequences were retrieved. Evidence is presented that two of these sequences are derived from bursicon. Antibodies raised against the two sequences labeled bursicon-containing neurons in the central nervous systems of P. americana. One of these antisera labeled bursicon-containing neurons in the crickets Teleogryllus commodus and Gryllus bimaculatus, and the moth Manduca sexta. A cluster of four bilaterally paired neurons in the brain of Drososphila melanogaster was also labeled. In addition, this antiserum detected three spots corresponding to bursicon in Western blots of two-dimensional gels. The 12-amino acid sequence detected by this antiserum, thus, seems to be conserved even among species that are distantly related.

Published

2002

23. Metamodulation of the Biogenic Amines: Second-Order Modulation by Steroid Hormones and Amine Cocktails

Author

Karen A. Mesce

Subjects

Central Nervous System, Nervous system, Biogenic Amines, Serotonin, Invertebrate Hormones, Dopamine, Leech, Biology, Behavioral Neuroscience, Species Specificity, Developmental Neuroscience, Leeches, Manduca, Biogenic amine, Biological neural network, medicine, Animals, Octopamine, Swimming, chemistry.chemical_classification, Neurotransmitter Agents, Neuronal Plasticity, Dopaminergic, Neural Inhibition, biology.organism_classification, Biological Evolution, Ganglia, Invertebrate, Hirudo medicinalis, Ecdysterone, medicine.anatomical_structure, chemistry, Manduca sexta, Larva, Nerve Net, Neuroscience, medicine.drug

Abstract

An evolutionarily conserved feature of neural systems is that they can be modified by neuromodulators. These modulatory chemical signals include the biogenic amines, octopamine (OA), serotonin (5-HT) and dopamine (DA). Such modulation effectively broadens the operational range in which specific neural circuits can function adaptively. This report discusses how these amines are themselves modulated; for example, by the steroid hormone 20-hydroxyecdysone (20-E) or by the addition of a second biogenic amine. Such second-order neuromodulation, termed metamodulation, is discussed in the context of two well-studied invertebrate systems: the tobacco hornworm moth Manduca sexta, a model of neurodevelopment and plasticity, and the medicinal leech Hirudo medicinalis, a long-favored preparation used to study neural circuits at the level of identified neurons. A portion of this article reviews our previous research of M. sexta that shows that the ‘preadult’ rise in 20-E is both necessary and sufficient for the increased levels of octopamine observed in the adult. Such elevated levels likely play an important role in the production and modulation of adult behaviors. The somatic growth of median octopaminergic neurons and the late expression of OA-immunoreactivity by novel lateral neurons are also demonstrated to be dependent on 20-E. New immunocytochemical results of stained dopaminergic neurons in the larval and adult moth brain are provided as well, and the potential influence of 20-E on the developmental expression of this neuromodulator is presented. Turning attention to the leech, data indicate that the actions of OA are dramatically altered when 5-HT is combined with OA in the bath surrounding the isolated nervous system. Although either OA or 5-HT alone induces fictive swimming behavior, a cocktail of these two amines strongly inhibits the generation of swimming. Subsequent removal of such a mixture induces nearly continuous swimming and constitutes the best swim-inducing stimulus encountered to date. To understand better how these nonadditive effects are achieved, new results are discussed that indicate that the leech brain is the target of metamodulation by the two amines. Both the arthropod and annelid systems presented here highlight the multiple levels of metamodulation that can exist in nervous systems, and the diverse ways that a modulator’s actions can become altered over short or long time periods.

Published

2002

24. Distribution and development of dopamine- and octopamine-synthesizing neurons in the medicinal leech

Author

Kevin M. Crisp, Adelrita J. Nartey, Kathleen A. Klukas, Karen A. Mesce, and Laura S. Gilchrist

Subjects

Central Nervous System, Aging, Embryo, Nonmammalian, Tyrosine 3-Monooxygenase, Dopamine, Central nervous system, Leech, Dopamine beta-Hydroxylase, Norepinephrine, Leeches, medicine, Animals, Octopamine, Body Patterning, Neurons, Microscopy, Confocal, biology, Tyrosine hydroxylase, General Neuroscience, Dopaminergic, biology.organism_classification, Immunohistochemistry, Ganglia, Invertebrate, Hirudo medicinalis, medicine.anatomical_structure, Octopamine (neurotransmitter), Digestive System, Neuroscience, medicine.drug

Abstract

Although the medicinal leech is a well-studied system in which many neurons and circuits have been identified with precision, descriptions of the distributions of some of the major biogenic amines, such as dopamine (DA) and octopamine (OA), have yet to be completed. In the European medicinal leech Hirudo medicinalis and the American medicinal leech Macrobdella decora,we have presented the first immunohistochemical study of DA neurons in the entire central nervous system, and of OA-immunoreactive (ir) neurons in the head and tail brains. Dopaminergic neurons were identified using the glyoxylic acid method and antisera to DA and its rate-limiting synthetic enzyme tyrosine hydroxylase (TH). Octopaminergic neurons were recognized using a highly specific antiserum raised against OA. An antibody raised against DA-β-hydroxylase (DβH), the mammalian enzyme that converts DA to norepinephrine (NE), was found to immunostain OA-ir neurons. This antibody appears to cross-react with the closely related invertebrate enzyme tyramine-β-hydroxylase, which converts tyramine to OA, suggesting that the OA-ir cells are indeed octopaminergic, capable of synthesizing OA. Because the DβH antiserum selectively immunostained the OA-ir neurons, but not the DA-synthesizing cells, our results also indicate that the DA-ir neurons synthesize DA and not NE as their end product. The expression of TH immunoreactivity was found to emerge relatively early in development, on embryonic day 9 (47–48% of development). In contrast, OA expression remained absent as late as embryonic day 20. Higher order processes of some of the dopaminergic and octopaminergic neurons in the adult brain were observed to project to a region previously described as a neurohemal complex. Several TH-ir processes were also seen in the stomatogastric nerve ring, suggesting that DA may play a role in the regulation of biting behavior. By mapping the distributions and developmental expression pattern of DA and OA neurons in the leech, we aim to gain a better understanding of the functional roles of aminergic neurons and how they influence behavior.J. Comp. Neurol. 442:115–129, 2002. © 2002 Wiley-Liss, Inc.

Published

2001

25. Olfactory and behavioral response thresholds to odors of diseased brood differ between hygienic and non-hygienic honey bees ( Apis mellifera L.)

Author

Karen A. Mesce, Marla Spivak, R. Ross, and R. Masterman

Subjects

Male, Physiology, Health Status, Zoology, Stimulus (physiology), Biology, complex mixtures, Animal Diseases, Behavioral Neuroscience, Honey Bees, Animals, Social Behavior, Ecology, Evolution, Behavior and Systematics, Behavior, Animal, Ecology, fungi, Honey bee, Bees, Adaptation, Physiological, Brood, Smell, Phenotype, Behavioral response, Proboscis extension reflex, Odor, Odorants, behavior and behavior mechanisms, Conditioning, Animal Science and Zoology

Abstract

Through the use of proboscis-extension reflex conditioning, we demonstrate that honey bees (Apis mellifera L.) bred for hygienic behavior (a behavioral mechanism of disease resistance) are able to discriminate between odors of healthy and diseased brood at a lower stimulus level than bees from a non-hygienic line. Electroantennogram recordings confirmed that hygienic bees exhibit increased olfactory sensitivity to low concentrations of the odor of chalkbrood infected pupae (a fungal disease caused by Ascosphaera apis). Three-week-old hygienic bees were able to discriminate between the brood odors significantly better than three-week old non-hygienic bees. However, the differential performance in brood odor discrimination was primarily genetically based, not a direct result of age, experience, or the temporary behavioral state of the bee. Lower stimulus thresholds for both the olfactory and behavioral responses of hygienic bees may facilitate their ability to detect, uncap and remove diseased brood rapidly from the nest. In contrast, non-hygienic bees, possessing higher response thresholds, may not be able to detect diseased brood as easily. Our results provide an example of how physiological and behavioral differences between the hygienic and non-hygienic honey bee lines, operating at the level of the individual, could produce colony-specific behavioral phenotypes.

Published

2001

26. Dopamine-synthesizing neurons include the putative H-cell homologue in the mothManduca sexta

Author

Andre W. DeLorme, Karen A. Mesce, T. Clark Brelje, and Kathleen A. Klukas

Subjects

Nervous system, biology, Tyrosine hydroxylase, General Neuroscience, Dopaminergic, biology.organism_classification, Ganglion, medicine.anatomical_structure, Manduca sexta, Ventral nerve cord, medicine, Neuron, Manduca, Neuroscience

Abstract

The catecholamine dopamine (DA) plays a fundamental role in the regulation of behavior and neurodevelopment across animal species. Uncovering the embryonic origins of neurons that express DA opens a path for a deeper understanding of how DA expression is regulated and, in turn, how DA regulates the activities of the nervous system. In a well-established insect model, Manduca sexta, we identified the putative homologue of the embryonic grasshopper "H-cell" using intracellular techniques, laser scanning confocal microscopy, and immunohistochemistry. In both species, this neuron possesses four axons and has central projections resembling the letter H. The H-cell in grasshoppers is known to be derived from the midline precursor 3 cell (MP3) and to pioneer the pathways of the longitudinal connectives; in Drosophila, the H-cell is also known to be derived from MP3. In the current study, we demonstrate that the Manduca H-cell is immunoreactive to antibodies raised against DA and its rate-limiting synthetic enzyme, tyrosine hydroxylase (TH). In larvae and adults, one DA/TH-immunoreactive (-ir) H-cell per ganglion is present. In embryos, individual ganglia contain a single midline TH-ir cell body positioned along side its putative sibling. Such observations are consistent with the known secondary transformation (in grasshoppers) of only one of the two MP3 progeny during early development. Although a hallmark feature of invertebrate neurons is the fairly stereotypical position of neuronal somata, we found that the H-cell somata can "flip-flop" by 180 degrees between an anterior and posterior position. This variability appears to be random and is not restricted to any particular ganglion. Curiously, what is segment-specific is the absence of the DA/TH-ir H-cell in the metathoracic (T3) ganglion as well as the unique structure of the H-cell in the subesophageal ganglion. Because this is the first immunohistochemical study of DA neurons in Manduca, we have provided the distribution pattern and morphologies of dopaminergic neurons, in addition to the H-cells, within the ventral nerve cord during development.

Published

2001

27. Programmed cell death of an identified motoneuron examinedin vivo: Electrophysiological and morphological correlates

Author

Andre W. DeLorme and Karen A. Mesce

Subjects

Programmed cell death, biology, General Neuroscience, Period (gene), medicine.medical_treatment, Cellular and Molecular Neuroscience, Electrophysiology, Steroid hormone, medicine.anatomical_structure, Apoptosis, medicine, biology.protein, Neuron, Cytoskeleton, Neuroscience, Caspase

Abstract

A paucity of information exists about the electrophysiological and anatomical correlates of neurons committed to die in vivo. Thus, we examined how an identified neuron, motoneuron MN-12, dies during development in the intact moth Manduca sexta. The developmental programmed cell death of this motoneuron was examined because of its defined commitment point of death. In addition, its ability to be unambiguously identified between animals and its accessibility to recording and dye injection facilitated our examination. MN-12 becomes committed to die approximately 28–30 h after adult emergence. At this time, MN-12 can no longer be saved by manipulations of steroid hormone levels, protein synthesis, or removal of descending inputs. Our initial prediction was that within a few hours after the commitment point, MN-12 would begin showing a gradual loss of central arbors and alterations in membrane properties. Contrary to our expectations, we found the MN-12 motoneuron to exhibit a stable central morphology and electrophysiological profile for ∼12 h, followed by a rapid dismantling that occurred within a 1- to 2-h period. Several hours prior to the commitment point, the target muscle of MN-12 was no longer viable; yet, this did not affect the death of MN-12 or cause retraction of its motor terminals. We conclude that the delayed (12-h) onset of rapid cell death is not preceded by a slow accumulation of damages to the neuronal membrane (e.g., ion channels or cytoskeletal components) as both the electrical activity and morphology of MN-12 remained measurably unaltered during this 12-h lag. © 1999 John Wiley & Sons, Inc. J Neurobiol 39: 307–322, 1999

Published

1999

28. Programmed cell death of identified peptidergic neurons involved in ecdysis behavior in the moth,Manduca sexta

Author

James W. Truman, Susan E. Fahrbach, Karen A. Mesce, Chiou Miin Wang, Kathleen A. Klukas, and John Ewer

Subjects

medicine.medical_specialty, Programmed cell death, education.field_of_study, animal structures, Crustacean cardioactive peptide, General Neuroscience, fungi, Central nervous system, Population, Regulator, Biology, biology.organism_classification, Cell biology, Cellular and Molecular Neuroscience, medicine.anatomical_structure, Endocrinology, nervous system, Manduca sexta, Apoptosis, Internal medicine, Ecdysis, medicine, education

Abstract

The eclosion of the adult Manduca sexta moth is followed by a wave of cell death that eliminates up to 50% of the neurons of the central nervous system within the first few days of imaginal life. While the identity of some of the dying motoneurons has been established, that of most doomed neurons is unknown. Here, we show that the dying cells include peptidergic neurons involved in the control of ecdysis behavior. These cells belong to a small population of 50 neurons that express crustacean cardioactive peptide (CCAP), a potent regulator of the ecdysis motor program, and show increases in cyclic 3',5'-guanosine monophosphate at each ecdysis. First, we describe new markers for these neurons and show that they are expressed in these CCAP-immunoreactive neurons in a complex temporal pattern during development. We then show that these neurons die within 36 h after adult eclosion, the last performance of ecdysis behavior in the life of the animal, via the active, genetically determined process of programmed cell death. The death of these neurons supports the hypothesis that outmoded or unused neurons are actively eliminated.

Published

1998

29. Novel mouse IgG-like immunoreactivity expressed by neurons in the mothManduca sexta: Developmental regulation and colocalization with crustacean cardioactive peptide

Author

Karen A. Mesce, Kathleen A. Klukas, and T. Clark Brelje

Subjects

Nervous system, education.field_of_study, medicine.medical_specialty, animal structures, Histology, biology, Crustacean cardioactive peptide, fungi, Population, Colocalization, Neuropeptide, biology.organism_classification, Neuromere, Cell biology, Medical Laboratory Technology, medicine.anatomical_structure, Endocrinology, Manduca sexta, Internal medicine, medicine, Anatomy, education, Instrumentation, Bursicon

Abstract

Immunoglobulin-related molecules have been shown to play important roles in cell-cell recognition events during the development of both vertebrate and invertebrate nervous systems. In the moth, Manduca sexta, we report the presence of novel, mouse, immunoglobulin G (mIgG)-like immunoreactivity in a discrete population of identified neurosecretory neurons (the NS-Ls also known as the cell 27s) and interneurons (the IN-704s). A number of polyclonal anti-mIgG antibodies were used to immunostain these cells in wholemount. The mIgG-like-immunoreactive (IR) neurons were present during embryogenesis through the developing adult stages, but disappeared in the postemerged adult. Biochemical analysis of M. sexta ventral nerve cords revealed that the mIgG-like antigen is a membrane-associated 27-kDa protein which is likely responsible for the mIgG-like immunostaining observed. Unambiguous identification of the mIgG-like-IR neurons was based on neuronal morphology and our ability to demonstrate conclusively that these neurons expressed immunoreactivity to an antiserum against crustacean cardioactive peptide (CCAP). The NS-Ls and IN-704s were both shown to colocalize the CCAP and mIgG-like immunoreactivities. The mIgG-like and CCAP-IR neurons were identical to a subset of CCAP-IR neurons recently described by Davis et al. [(1993) J. Comp. Neurol., 338:612-627] in pupae. We found these CCAP-IR neurons, however, also to be present in larvae. The mIgG-like- and CCAP-IR neurons included the NS-L pair of the subesophageal maxillary neuromere, which projected anteriorly to the corpora cardiaca, and the NS-L of the labial neuromere whose axons projected out the dorsal nerve of the next posterior ganglion. The mIgG-like and CCAP-IR NS-Ls were also observed throughout the three thoracic ganglia, and all shared strikingly similar structural features. These cells exited out the dorsal nerve of the next posterior ganglion and eventually projected to the neurohemal release sites of the perivisceral organs. These neurons appear to be the homologues of the abdominal CCAP-IR NS-Ls, neurons that in the adult switch their neurotransmitter and release the neuropeptide bursicon. Our description of the distribution and developmental expression of this novel mIgG-like immunoreactivity may provide new insights into the regulation of neurotransmitter plasticity and/or recognition-signaling events involved in the embryonic and postembryonic assembly of the nervous system.

Published

1996

30. A motoneuron spared from steroid-activated developmental death by removal of descending neural inputs exhibits stable electrophysiological properties and morphology

Author

Karen A. Mesce, Kathleen A. Klukas, Andre W. DeLorme, and Susan E. Fahrbach

Subjects

Nervous system, Cell Survival, media_common.quotation_subject, Cell, Degeneration (medical), Efferent Pathways, Membrane Potentials, Cellular and Molecular Neuroscience, Manduca, medicine, Animals, Endocrine system, Metamorphosis, media_common, Motor Neurons, Cell Death, biology, General Neuroscience, fungi, Metamorphosis, Biological, biology.organism_classification, Electrophysiology, medicine.anatomical_structure, nervous system, Manduca sexta, Steroids, Neuroscience, Hormone

Abstract

Neurons die during the development of nervous systems. The death of specific, idenified motoneuros during metamorphosis of the tobacco hornworm, Manduca sexta, provides an accessible model system in which to study the regulation of postembryonic neuronal death. Hormones and descending neural inputs have been shown toinfluence the survival of abdominal motoneurons during the first few days of adult life in this insect. Motoneurons prevented from undergoing the normal process of developmental degeneration by removal of neural inputs were examined at the physiological and structural levels using several cell imaging techniques. Although these neurons lost their muscle targets and experienced the endocrine cue that normally triggers death, they showed no overt electrophysiological or morphological signs of degeneration. Thus, by appropriate intervention, the MN-12 motoneuron can be spared from developmental neuronal death and remain as a functioning supernumerary element in the mature nervous system. © 1995 John Wiley & Sons, Inc.

Published

1995

31. Distribution and developmental expression of octopamine-immunoreactive neurons in the central nervous system of the leech

Author

Laura S. Gilchrist, Kathleen A. Klukas, Karen A. Mesce, Jürgen Rapus, John Jellies, and Manfred Eckert

Subjects

Central Nervous System, Central nervous system, Gene Expression, Leech, chemistry.chemical_compound, Norepinephrine, Leeches, medicine, Animals, Octopamine, Neurons, Microscopy, Confocal, biology, General Neuroscience, Octopamine (drug), biology.organism_classification, Immunohistochemistry, Cell biology, Hirudo medicinalis, medicine.anatomical_structure, chemistry, Serotonin, Neuron, Neuroscience, Immunostaining, medicine.drug

Abstract

Octopamine, a biogenic amine analogous to norepinephrine, plays an important role in the orchestration and modulation of invertebrate behavior. In the leech, the behavioral actions of octopamine have been demonstrated; however, identification of octopaminergic neurons had not been determined by using immunohistochemical techniques. Thus, we used an antibody highly specific to octopamine to examine the distribution of octopamine-immunoreactive neurons in the segmental ganglia of American and European medicinal leeches (Macrobdella decora and Hirudo medicinalis). One pair of octopamine-immunoreactive neurons was located in the dorsolateral ganglionic region of anterior ganglia 1–6 and posterior ganglia 15–21. No corresponding octopamine-immunoreactive neurons were found in midbody ganglia 7–14. Using Neutral Red staining in combination with intracellular Neurobiotin injections and octopamine immunostaining, we determined the identity of the dorsolateral octopamineimmunoreactive cells. The dorsolateral octopamine-immunoreactive neuron (the DLO) was not cell 21, the only previously reported Neutral Red staining neuron in the dorsolateral position. We also determined that the Leydig neuron was not octopamine immunoreactive in either of the two medicinal leech species. Octopamine immunostaining in the sex ganglia revealed hundreds of immunoreactive neurons in sexually mature leeches. Such neurons were not observed in juvenile leeches. The developmental time course of octopamine immunoreactivity in the dorsolateral octopamine-immunoreactive neurons was also investigated by staining embryonic Hirudo medicinalis, Octopamine expression occurred relatively late as compared with the detectable onset of serotonin expression. Octopamine expression in the dorsolateral octopamine-immunoreactive cells was not detectable at early to mid-embryonic stages, and must commence during late embryonic to early juvenile stages. The identification of octopamineimmunoreactive cells now sets the stage for further investigations into the functional role of octopamine in leech behavior and the development of behavior. © 1995 Wiley-Liss, Inc.

Published

1995

32. Mechanisms contributing to the dopamine induction of crawl-like bursting in leech motoneurons

Author

Kevin M. Crisp, Brian R. Gallagher, and Karen A. Mesce

Subjects

animal structures, Physiology, Phosphodiesterase Inhibitors, Dopamine, chemistry.chemical_element, Leech, Action Potentials, Aquatic Science, Calcium, Bursting, Theophylline, 1-Methyl-3-isobutylxanthine, Leeches, medicine, Cyclic AMP, Animals, Receptor, Molecular Biology, Ecology, Evolution, Behavior and Systematics, Swimming, Motor Neurons, urogenital system, fungi, Cell Membrane, Phosphodiesterase, Riluzole, Cell biology, chemistry, Insect Science, Animal Science and Zoology, Neuroscience, Intracellular, Locomotion, medicine.drug, Adenylyl Cyclases

Abstract

Summary Dopamine (DA) activates fictive crawling behavior in the medicinal leech. To identify the cellular mechanisms underlying this activation at the level of crawl-specific motoneuronal bursting, we targeted potential cAMP-dependent events that are often activated through DA1-like receptor signaling pathways. We found that isolated ganglia produced crawl-like motoneuron bursting after bath application of phosphodiesterase inhibitors (PDIs) that up-regulated cAMP. This bursting persisted in salines in which calcium ions were replaced with equimolar cobalt or nickel, but was blocked by riluzole, an inhibitor of a persistent sodium current. PDI-induced bursting contained a number of patterned elements that were statistically similar to those observed during DA-induced fictive crawling, except that one motoneuron (CV) exhibited bursting during the contraction rather than the elongation phase of crawling. Although DA and the PDI produced similar bursting profiles, intracellular recordings from motoneurons revealed differences in altered membrane properties. For example, DA lowered motoneuron excitability while the PDI increased resting discharge rates. We suggest that PDIs (and DA) activate a sodium-influx-dependent timing mechanism capable of setting the crawl rhythm and that multiple DA receptor sub-types are involved in shaping and modulating the phase relationships and membrane properties of cell-specific members of the crawl network to generate crawling.

Published

2012

33. Reorganization of the ventral nerve cord in the moth Manduca sexta (L.) (Lepidoptera : Sphingidae)

Author

Karen A. Mesce and Therese M. Amos

Subjects

biology, Interneuron, media_common.quotation_subject, Sphingidae, fungi, Central nervous system, Insect, Anatomy, biology.organism_classification, medicine.anatomical_structure, nervous system, Manduca sexta, Insect Science, Ecdysis, Ventral nerve cord, Neuropil, medicine, sense organs, Developmental Biology, media_common

Abstract

Morphology of the ventral nerve cord of the hawkmoth, Manduca sexta (Lepidoptera : Sphingidae), changes at the larval-pupal transition as several separate larval ganglia fuse to form single ganglia characteristic of the adult. We examined in detail the time course of ganglionic fusion. Changes in the relative positions of the ganglia were studied by staining the tissue with methylene or toluidine blue. Alterations in the positions and structure of individual neurons were studied by filling neurons with a cobalt-lysine complex. The first gross morphological change, anterior movement of the first abdominal ganglion, is visible within the first 24 hr after pupal ecdysis. Adult ventral nerve cord morphology is recognizable 6 days later, approximately 12 days before the adult will emerge. The sequence in which the individual ganglia fuse is invariant. During ganglionic fusion, the neuronal cell bodies and associated neuropil move out of their former ganglionic sheath and through the sheath covering the connectives. Axons between the fusing ganglia form loops in the shortening connectives. The presence of looping axons is a morphological feature that identifies the boundaries between ganglia during intermediate stages of fusion. Some individual adult neurons also show looped axons at the boundaries of fused ganglia. These axonal loops may be a valuable morphological marker by which neurons can be characterized as conserved neurons.

Published

1994

34. Dopamine Signaling in the Bee

Author

Kyle T. Beggs, H. James McQuillan, Karen A. Mesce, Vanina Vergoz, Alison R. Mercer, Lisa H. Geddes, Julie A. Mustard, and Kathleen A. Klukas

Subjects

Kenyon cell, Honey bee, Biology, chemistry.chemical_compound, chemistry, Dopamine, Mushroom bodies, medicine, Olfactory Learning, Tyrosine, Receptor, Neurotransmitter, Neuroscience, medicine.drug

Abstract

Dopamine (DA) is a signaling molecule derived from the amino acid tyrosine. It is an important neuromodulator, neurotransmitter and neurohormone in invertebrates as well as in vertebrates and numerous studies suggest roles for this amine in motor function, learning and memory, aggression, arousal and sleep, and in a number of other behaviors. A growing body of evidence suggests that DA plays a diversity of roles also in Apis mellifera. Three honey bee DA receptor genes have been cloned and characterized. In this chapter we focus on their likely involvement in the regulation of locomotor activity, ovary development, and olfactory learning and memory.

Published

2011

35. The shell selection behaviour of two closely related hermit crabs

Author

Karen A. Mesce

Subjects

Pagurus hirsutiusculus, Anomura, biology, Ecology, Decapoda, Pagurus samuelis, biology.organism_classification, Crustacean, Tegula funebralis, Animal Science and Zoology, Nucella canaliculata, Biological system, Sensory cue, Ecology, Evolution, Behavior and Systematics

Abstract

Abstract. Shell selection behaviour in response to shell features or stimuli that might contribute to shell detection, investigation and ultimately shell choice were examined in two inter-tidal hermit crabs, Pagurus samuelis and P. hirsutiusculus. Each species displayed a different preference for either Tegula funebralis shells ( P. samuelis ) or Nucella canaliculata shells ( P. hirsutiusculus ), shells that differ greatly in their external appearance and internal configuration. Visual and chemical shell stimuli were found to have a different effect on each of the two closely related species. Pagurus samuelis relied on visual cues for shell detection. It also displayed visually-mediated tracking of objects resembling T. funebralis shells in colour, shape and size. Pagurus hirsutiusculus did not display tracking behaviour. Both species responded to the chemical composition of shells, specifically their calcium content. Various coatings were applied to the shell surfaces to remove (cover) the calcium cue. For P. hirsutiusculus only, shell exploratory behaviour was not initiated if this one stimulus was absent. Both species were found to rely on the chemical cues alone to locate and uncover partially buried shells. Each species apparently relies on shell cues that are distinguishing features of their preferred shells. Thus, underlying differences in sensory and other neural mechanisms enable each species to detect quickly and respond to its preferred shell type. The stimulus value of the aperture and possible importance of the shell's internal configuration, for shell selection, were also examined. Lastly, the role of learning in shell selection is discussed.

Published

1993

36. A Light Insensitive Method for Contrast Enhancement of Insect Neurons Filled with a Cobalt-Lysine Complex

Author

Therese M. Amos, Karen A. Mesce, and Sheila M. Clough

Subjects

Nervous system, Silver Staining, Histology, Interneuron, media_common.quotation_subject, Lysine, chemistry.chemical_element, Insect, Moths, Interneurons, medicine, Animals, media_common, Neurons, Staining and Labeling, biology, fungi, Brain, Cobalt, General Medicine, Anatomy, biology.organism_classification, Retrograde tracing, Ganglia, Invertebrate, Staining, Medical Laboratory Technology, medicine.anatomical_structure, chemistry, Manduca sexta, Larva, Biophysics

Abstract

Modified protocols for cobalt-filling and silver intensification of neurons in the larval and adult stages of the moth, Manduca sexta, have led to improved neuronal visualization and minimal background staining. In particular, long distance projecting multisegmental interneurons, originating in the pterothoracic or terminal abdominal ganglion, were best visualized when a cobalt:lysine complex was used to fill hemi-connectives for several days at 4 C. Ganglia closest to the placement of tracer, which became flooded with cobalt:lysine during the filling period, were removed from the insect. This step eliminated the artifactual filling of neurons that may have taken up the tracer from such pooled regions. This led to a more accurate assessment of whether a multisegmental interneuron projected through the full length of nerve cord to the original site of tracer placement. The protocol for light insensitive silver intensification of cobalt-filled neurons was modified to include an important pH adjustment. NaOH was used to alter the pH of the protective colloid, sodium tungstate, to 10.4 or greater in solution. Especially in larvae, our techniques produced intensely stained cobalt-filled neurons within ganglia that remained transparent and relatively free of nonspecific silver deposition.

Published

1993

37. MORPHOLOGICAL AND PHYSIOLOGICAL IDENTIFICATION OF CHELAR SENSORY STRUCTURES IN THE HERMIT CRAB PAGURUS HIRSUTIUSCULUS (DECAPODA)

Author

Karen A. Mesce

Subjects

Pagurus hirsutiusculus, Chemoreceptor, biology, Decapoda, Ultrastructure, Zoology, Seta, Chela, Anatomy, Aquatic Science, biology.organism_classification, Hermit crab, Crustacean

Abstract

The hermit crab Pagurus hirsutiusculus uses its minor chela to examine gastropod shells that may be selected for habitation. Since tactile and chemical cues, especially calcium, are important for the recognition and selection of shells by this species, the minor chela was examined for the presence of mechano- and chemoreceptors. Chelar cuticular structures were examined with a scanning electron microscope, and electrophysiological methods were used to determine their sensory responses. Two structural types, simple setae and rows of teeth, function as mechanoreceptors. The simple setae also function as chemoreceptors, sensitive to calcium. A detailed description of the arrangement and external morphology of these bifunctional simple setae is provided and serves as background for further studies of their ultrastructural features. Other structures found on the chelar surface were pits and nonsensory tubercles. The function of the pits remains unknown. Behavioral adaptations for calcium detection in marine environments are discussed, as is the possible occurrence of calcium detection in other crustaceans.

Published

1993

38. Shared Strategies for Behavioral Switching: Understanding How Locomotor Patterns are Turned on and Off

Author

Jonathan T. Pierce-Shimomura and Karen A. Mesce

Subjects

animal structures, Nematode caenorhabditis elegans, Cognitive Neuroscience, Lophotrochozoa, Leech, Crawling, medicinal leech, lcsh:RC321-571, 03 medical and health sciences, Behavioral Neuroscience, 0302 clinical medicine, behavioral choice, Caenorhabditis elegans, lcsh:Neurosciences. Biological psychiatry. Neuropsychiatry, 030304 developmental biology, 0303 health sciences, biology, fungi, Behavioral choice, decision-making, biology.organism_classification, Neuropsychology and Physiological Psychology, Perspective Article, dopamine, Ecdysozoa, Neuroscience, Hirudo verbana, 030217 neurology & neurosurgery

Abstract

Animals frequently switch from one behavior to another, often to meet the demands of their changing environment or internal state. What factors control these behavioral switches and the selection of what to do or what not to do? To address these issues, we will focus on the locomotor behaviors of two distantly related ‘worms’, the medicinal leech Hirudo verbana (clade Lophotrochozoa) and the nematode Caenorhabditis elegans (clade Ecdysozoa). Although the neural architecture and body morphology of these organisms are quite distinct, they appear to switch between different forms of locomotion by using similar strategies of decision-making. For example, information that distinguishes between liquid and more solid environments dictates whether an animal swims or crawls. In the leech, dopamine biases locomotor neural networks so that crawling is turned on and swimming is turned off. In C. elegans, dopamine may also promote crawling, a form of locomotion that has gained new attention.

Published

2010

39. Hormone-dependent expression of fasciclin II during ganglionic migration and fusion in the ventral nerve cord of the moth Manduca sexta

Author

Susan E. Fahrbach, Karen A. Mesce, Kathleen A. Klukas, and Katherine E. Himes

Subjects

Gene isoform, biology, Cell adhesion molecule, General Neuroscience, Cell Adhesion Molecules, Neuronal, Neuropeptide, Gene Expression Regulation, Developmental, Cycloheximide, biology.organism_classification, Immunohistochemistry, Article, Cell biology, Ganglia, Invertebrate, chemistry.chemical_compound, chemistry, Manduca sexta, Cell Movement, Ventral nerve cord, Insect Hormones, Larva, Manduca, Animals, Cell adhesion, Receptor, Neuroscience

Abstract

The ventral nerve cord of holometabolous insects is reorganized during metamorphosis. A prominent feature of this reorganization is the migration of subsets of thoracic and abdominal larval ganglia to form fused compound ganglia. Studies in the hawkmoth Manduca sexta revealed that pulses of the steroid hormone 20-hydroxyecdysone (20E) regulate ganglionic fusion, but little is known about the cellular mechanisms that make migration and fusion possible. To test the hypothesis that modulation of cell adhesion molecules is an essential component of ventral nerve cord reorganization, we used antibodies selective for either the transmembrane isoform of the cell adhesion receptor fasciclin II (TM-MFas II) or the glycosyl phosphatidylinositol-linked isoform (GPI-MFas II) to study cell adhesion during ganglionic migration and fusion. Our observations show that expression of TM-MFas II is regulated temporally and spatially. GPI-MFas II was expressed on the surface of the segmental ganglia and the transverse nerve, but no evidence was obtained for regulation of GPI-MFas II expression during metamorphosis of the ventral nerve cord. Manipulation of 20E titers revealed that TM-MFas II expression on neurons in migrating ganglia is regulated by hormonal events previously shown to choreograph ganglionic migration and fusion. Injections of actinomycin D (an RNA synthesis inhibitor) or cycloheximide (a protein synthesis inhibitor) blocked ganglionic movement and the concomitant increase in TM-MFas II, suggesting that 20E regulates transcription of TM-MFas II. The few neurons that showed TM-MFas II immunoreactivity independent of endocrine milieu were immunoreactive to an antiserum specific for eclosion hormone (EH), a neuropeptide regulator of molting.

Published

2008

40. Beyond the central pattern generator: amine modulation of decision-making neural pathways descending from the brain of the medicinal leech

Author

Karen A. Mesce and Kevin M. Crisp

Subjects

Serotonin, Physiology, Decision Making, Aquatic Science, Biology, Serotonergic, Serotonin Agents, Neuromodulation, Leeches, Neural Pathways, Biological neural network, medicine, Animals, Amines, Molecular Biology, Octopamine, Ecology, Evolution, Behavior and Systematics, Swimming, Central pattern generator, Brain, biology.organism_classification, Hirudo medicinalis, medicine.anatomical_structure, Insect Science, Command neuron, Excitatory postsynaptic potential, Animal Science and Zoology, Ganglia, Neuron, human activities, Neuroscience, Adrenergic alpha-Agonists

Abstract

SUMMARY The biological mechanisms of behavioral selection, as it relates to locomotion, are far from understood, even in relatively simple invertebrate animals. In the medicinal leech, Hirudo medicinalis, the decision to swim is distributed across populations of swim-activating and swim-inactivating neurons descending from the subesophageal ganglion of the compound cephalic ganglion, i.e. the brain. In the present study, we demonstrate that the serotonergic LL and Retzius cells in the brain are excited by swim-initiating stimuli and during spontaneous swim episodes. This activity likely influences or resets the neuromodulatory state of neural circuits involved in the activation or subsequent termination of locomotion. When serotonin (5-HT) was perfused over the brain, multi-unit recordings from descending brain neurons revealed rapid and substantial alterations. Subsequent intracellular recordings from identified command-like brain interneurons demonstrated that 5-HT, especially in combination with octopamine, inhibited swim-triggering neuron Tr1, as well as swim-inactivating neurons Tr2 and SIN1. Although 5-HT inhibited elements of the swim-inactivation pathway, rather than promoting them, the indirect and net effect of the amine was a reliable and sustained reduction in the firing of the segmental swim-gating neuron 204. This modulation caused cell 204 to relinquish its excitatory drive to the swim central pattern generator. The activation pattern of serotonergic brain neurons that we observed during swimming and the 5-HT-immunoreactive staining pattern obtained, suggest that within the head brain 5-HT secretion is massive. Over time, 5-HT secretion may provide a homeostatic feedback mechanism to limit swimming activity at the level of the head brain.

Published

2006

41. Hygienic behavior of the honey bee (Apis mellifera) is independent of sucrose responsiveness and foraging ontogeny

Author

Karen A. Mesce, Marla Spivak, Katarzyna Goode, and Zachary J. Huber

Subjects

Sucrose, Forage (honey bee), Foraging, Conditioning, Classical, Zoology, complex mixtures, Discrimination Learning, Behavioral Neuroscience, Endocrinology, Animals, Octopamine, Appetitive Behavior, Apidae, biology, Behavior, Animal, Endocrine and Autonomic Systems, Ecology, fungi, Association Learning, Honey bee, Bees, biology.organism_classification, Brood, Apoidea, Associative learning, Smell, Aculeata, Phenotype, behavior and behavior mechanisms, Reinforcement, Psychology

Abstract

Hygienic behavior in honey bees is a behavioral mechanism of disease resistance. Bees bred for hygienic behavior exhibit an increased olfactory sensitivity to odors of diseased brood, which is most likely differentially enhanced in the hygienic line by the modulatory effects of octopamine (OA), a noradrenaline-like neuromodulator. Here, we addressed whether the hygienic behavioral state is linked to other behavioral activities known to be modulated by OA. We specifically asked if, during learning trials, bees from hygienic colonies discriminate better between odors of diseased and healthy brood because of differences in sucrose (reward) response thresholds. This determination had to be tested because sucrose response thresholds are susceptible to OA modulation and may have influenced the honey bee’s association of the conditioned stimulus (odor) with the unconditioned stimulus (i.e., the sucrose reward). Because the onset of first foraging is also modulated by OA, we also examined whether bees from hygienic colonies differentially forage at an earlier age compared to bees from non-hygienic colonies. Our study revealed that 1-day- and 15- to 20-day-old bees from the hygienic line do not have lower sucrose response thresholds compared to bees from the non-hygienic lines. In addition, hygienic bees did not forage at an earlier age or forage preferentially for pollen as compared to non-hygienic bees. These results support the idea that OA does not function in honey bees simply to enhance the detection of all chemical cues non-selectively or control related behaviors regardless of their environmental milieu. Our results indicate that the behavioral profile of the hygienic bee is sculpted by multiple factors including genetic, neural, social and environmental systems.

Published

2005

42. A cephalic projection neuron involved in locomotion is dye coupled to the dopaminergic neural network in the medicinal leech

Author

Karen A. Mesce and Kevin M. Crisp

Subjects

Nervous system, animal structures, Interneuron, Physiology, Dopamine, Action Potentials, Aquatic Science, Inhibitory postsynaptic potential, Neuromodulation, Leeches, medicine, Animals, Molecular Biology, Ecology, Evolution, Behavior and Systematics, Feedback, Physiological, Motor Neurons, biology, Central pattern generator, Brain, Motor neuron, biology.organism_classification, Electrophysiology, Hirudo medicinalis, medicine.anatomical_structure, Insect Science, Animal Science and Zoology, Neuron, Neuroscience, Locomotion

Abstract

SUMMARYIt is widely appreciated that the selection and modulation of locomotor circuits are dependent on the actions of higher-order projection neurons. In the leech, Hirudo medicinalis, locomotion is modulated by a number of cephalic projection neurons that descend from the subesophageal ganglion in the head. Specifically, descending brain interneuron Tr2 functions as a command-like neuron that can terminate or sometimes trigger fictive swimming. In this study, we demonstrate that Tr2 is dye coupled to the dopaminergic neural network distributed in the head brain. These findings represent the first anatomical evidence in support of dopamine (DA) playing a role in the modulation of locomotion in the leech. In addition, we have determined that bath application of DA to the brain and entire nerve cord reliably and rapidly terminates swimming in all preparations exhibiting fictive swimming. By contrast, DA application to nerve cords expressing ongoing fictive crawling does not inhibit this motor rhythm. Furthermore, we show that Tr2 receives rhythmic feedback from the crawl central pattern generator. For example, Tr2 receives inhibitory post-synaptic potentials during the elongation phase of each crawl cycle. When crawling is not expressed, spontaneous inhibitory post-synaptic potentials in Tr2 correlate in time with spontaneous excitatory post-synaptic potentials in the CV motor neuron, a circular muscle excitor that bursts during the elongation phase of crawling. Our data are consistent with the idea that DA biases the nervous system to produce locomotion in the form of crawling.

Published

2004

43. To swim or not to swim: regional effects of serotonin, octopamine and amine mixtures in the medicinal leech

Author

Karen A. Mesce and Kevin M. Crisp

Subjects

medicine.medical_specialty, Serotonin, Interneuron, Physiology, Leech, Biology, Behavioral Neuroscience, chemistry.chemical_compound, Internal medicine, Neuromodulation, Leeches, medicine, Animals, Amines, Octopamine, Ecology, Evolution, Behavior and Systematics, Swimming, Membrane potential, Central pattern generator, Brain, Octopamine (drug), biology.organism_classification, Solutions, Hirudo medicinalis, medicine.anatomical_structure, Endocrinology, chemistry, Animal Science and Zoology, human activities, Neuroscience

Abstract

Focally treating the head brain of the medicinal leech Hirudo medicinalis with various biogenic amines affected the initiation, termination and maintenance of fictive swimming (i.e., the neural correlate of swimming). Application of serotonin to saline surrounding only the head brain inhibited fictive swimming, whereas removing serotonin induced swimming. This contrasts sharply with previous observations that serotonin applied to the nerve cord induces swimming. Although application of octopamine to the brain activated swimming, a mixture of octopamine and serotonin inhibited swimming. Subsequent removal of this mixture from the brain activated robust swimming and was more potent for activating swimming than either the removal of serotonin or the application of octopamine. Swim episodes induced by brain-specific manipulations of octopamine had more swim bursts per episode than those induced by serotonin. These brain-specific effects of the amines on fictive swimming are probably due to the modulation of higher-order circuits that control locomotion in the leech. We observed that serotonin or a mixture of serotonin and octopamine hyperpolarized an identified descending brain interneuron known as Tr2. Removal of the mixture caused Tr2 to exhibit membrane potential depolarizations that correlated in time with the expression of swim episodes.

Published

2002

44. Integration of endocrine signals that regulate insect ecdysis

Author

Karen A. Mesce and Susan E. Fahrbach

Subjects

medicine.medical_specialty, Insecta, biology, Endocrine and Autonomic Systems, media_common.quotation_subject, fungi, Insect, Molting, biology.organism_classification, Neurosecretory Systems, Eclosion hormone, Endocrinology, Manduca sexta, Ecdysis, Internal medicine, medicine, Endocrine system, Animals, Drosophila melanogaster, Neuroscience, Moulting, media_common, Bursicon

Abstract

The extremely large number of insects and members of allied groups alive today suggests that molting--shedding of an old cuticle--may be one of the most commonly performed behaviors on our planet. Removal of an old cuticle in insects is associated with stereotyped, species-specific patterns of behavior referred to as ecdysis. It has been recognized for decades that the initiation of ecdysis is under hormonal control, but until recently many of the key peptides that regulate ecdysis were unknown. The report in 1996 of a new ecdysis-triggering hormone (ETH) sparked an era of significant advances in our understanding of the regulation of molting. This article summarizes the current model of peptide regulation of ecdysis, a model that is based on a positive feedback loop between ETH and a brain peptide, eclosion hormone. Then the relationship of these regulatory peptides to the neural circuitry that is the ultimate driver of the behavior are described. Because insects can undergo both status quo (larval-larval) and metamorphic (larval-pupal and pupal-adult) molts, differences in ecdysis behavior at different life stages are described and potential sources of these differences are identified. Most of the work described is based on studies of ecdysis in the hawkmoth, Manduca sexta, but results from studies of ecdysis in the fruit fly Drosophila melanogaster are also discussed.

Published

2002

45. Mixtures of octopamine and serotonin have nonadditive effects on the CNS of the medicinal leech

Author

Laura S. Gilchrist, Kevin M. Crisp, and Karen A. Mesce

Subjects

Central Nervous System, Serotonin, Physiology, Nerve net, Central nervous system, Leech, Biology, Drug synergism, chemistry.chemical_compound, Leeches, medicine, Animals, Neurotransmitter, Octopamine, Swimming, Neurons, Dose-Response Relationship, Drug, General Neuroscience, Drug Synergism, Octopamine (drug), Ganglia, Invertebrate, medicine.anatomical_structure, chemistry, Nerve Net, Neuroscience

Abstract

It is well established that neural networks respond to a wide variety of modulatory substances by which they can become reconfigured, yet few studies have examined the effects of neurotransmitter mixtures on such networks. In a previous study of the medicinal leech using triple intracellular recordings, we found that stimulation of identified mechanosensory neurons activated both the serotonergic cell 21 (a swimgating neuron) and the dorsal lateral octopamine (DLO) cell. Because these findings suggested that serotonin (5-HT) and octopamine (OA) may be released together, we investigated the effects of 5-HT and OA mixtures on isolated nerve cords of Hirudo medicinalis (which contained both head and tail brains). Fifty micromolar OA, 50 μM 5-HT, or a mixture of 50 μM OA and 50 μM 5-HT was bath applied to the nerve cord under constant perfusion conditions. Additional experiments were performed with combinations of either 25 or 100 μM OA and 5-HT. Neural activity was examined specifically in the segmentally repeated dorsal posterior (DP) nerve because it has been shown to contain identified swim motor units. Nonadditive effects of amine combinations were most apparent in their ability to decrease overall activity in the DP nerve and to alter patterned motor activity in the form of fictive swimming. Whereas swim burst activity has been previously shown to increase in nerve cords bathed in either 5-HT or OA solutions alone, we demonstrated that a mixture of the two amines resulted in a robust decrease in the number of swim bursts expressed and an inhibition of swim activity in preparations already swimming. Most compelling was the observation that when the amine mixture was replaced with normal saline, swim burst activity increased dramatically. We discuss that the effects of amine mixtures may be due to their interaction with descending interneurons known to trigger and inhibit swimming as the mixture-induced effects were not observed in nerve cords lacking the head and tail brains. Because the net effect of the two amines was not simply additive (i.e., 5-HT or OA is known to activate swimming, yet the mix inhibits swimming), this result reveals yet another layer of complexity inherent in “simpler” invertebrate nervous systems.

Published

2001

46. Coactivation of putative octopamine- and serotonin-containing interneurons in the medicinal leech

Author

Karen A. Mesce and Laura S. Gilchrist

Subjects

Membrane potential, Serotonin, Physiology, General Neuroscience, Leech, Depolarization, Biology, Serotonergic, Immunohistochemistry, Membrane Potentials, medicine.anatomical_structure, nervous system, Interneurons, Leeches, medicine, Excitatory postsynaptic potential, Animals, Octopamine (neurotransmitter), Neuron, Neurons, Afferent, Neuroscience, Octopamine

Abstract

Gilchrist, Laura S. and Karen A. Mesce. Coactivation of putative octopamine- and serotonin-containing interneurons in the medicinal leech. J. Neurophysiol. 78: 2108–2115, 1997. Possible interactions between octopamine-immunoreactive (IR) and serotonergic neurons in the CNS of the medicinal leech were investigated. Simultaneous intracellular recordings of serotonin-containing neurons (either the Retzius neuron or cell 21) and the dorsolateral octopamine-IR (DLO) neuron demonstrated that both sets of neurons are coactive at times. Depolarization of either serotonergic cell 21 or the Retzius neuron did not alter the membrane potential of the DLO. Similarly, depolarization of the DLO did not affect the serotonergic neurons examined. Because it was found that the DLO and either the serotonergic cell 21 or Retzius neuron were at times coactive, we looked for possible sources of common excitatory inputs. The centrally located pressure (P)- and touch (T)-sensitive mechanosensory neurons excited the DLOs through a polysynaptic pathway. Stimulation of nociceptive (N) mechanosensory neurons did not cause a measurable depolarization in the membrane potential of the DLO. Through simultaneous recordings of the DLO, cell 21, and a particular identified mechanosensory neuron, it was demonstrated that activity in the T or P cells can excite both serotonergic cell 21 and the octopamine-IR DLO. These findings indicate that, in many instances, both serotonin and octopamine, biogenic amines with neuromodulatory actions in many different invertebrates, may be released simultaneously in the leech.

Published

1997

47. Contents Vol. 60, 2002

Author

Michael P. Nusbaum, Barbara E. Musolf, Andrew B. Barron, Shelley A. Adamo, Franklin B. Krasne, Donald H. Edwards, Brian L. Antonsen, Shih-Rung Yeh, Gene E. Robinson, David J. Schulz, and Karen A. Mesce

Subjects

Behavioral Neuroscience, Developmental Neuroscience

Published

2002

48. Preface

Author

Karen A. Mesce

Subjects

Behavioral Neuroscience, Developmental Neuroscience, Chemistry, Brain behavior, Neuroscience

Published

2002

49. Improvements for the anatomical characterization of insect neurons in whole mount: the use of cyanine-derived fluorophores and laser scanning confocal microscopy

Author

Kathleen A. Klukas, Karen A. Mesce, and Brelje Tc

Subjects

Nervous system, Male, Serotonin, Histology, Fluorophore, Optical sectioning, Interneuron, Confocal, Immunocytochemistry, Fluorescent Antibody Technique, Biology, Moths, Pathology and Forensic Medicine, chemistry.chemical_compound, medicine, Animals, FMRFamide, Fluorescein, Fluorescent Dyes, Neurons, Lasers, fungi, Histological Techniques, Neuropeptides, Brain, Cell Biology, medicine.anatomical_structure, nervous system, chemistry, Microscopy, Fluorescence, Evaluation Studies as Topic, Biophysics, Ganglia, sense organs, Neuroscience

Abstract

The optical sectioning capability of the laser scanning confocal microscope was utilized to image dye-filled neurons within whole-mounted insect ganglia. Specific pterothoracic interneurons, in the moth Manduca sexta, were retrogradely filled with Neurobiotin and subsequently visualized with a monoclonal anti-biotin conjugated with one of the following fluorophores: fluorescein, and the newly developed cyanines, Cy3.18 (Cy3) and Cy5.18 (Cy5). Overall, the Cy5 fluorophore was best suited for imaging insect neurons within ganglia. This new methodology allowed us to identify and characterize morphologically a collection of descending multisegmental interneurons with large or small diameter somata. A variety of larger molecular weight (10,000 daltons) tracers was also used to examine the possibility of nonselective filling of neurons with Neurobiotin, possibly through gap junctions. We also investigated the usefulness of Cy3 and Cy5 as fluorophores for transmitter immunostaining of neurons in whole mount. Neurons immunoreactive for serotonin and the neuropeptides, FMRFamide and SCPB, were imaged in the brain and the pterothoracic ganglion. The central projections of some of these immunoreactive neurons were imaged in their entirety.

Published

1993

50. Metamorphosis of the ecdysis motor pattern in the hawkmoth,Manduca sexta

Author

Karen A. Mesce and James W. Truman

Subjects

Time Factors, Physiology, media_common.quotation_subject, In Vitro Techniques, Moths, Motor Activity, Behavioral Neuroscience, Neurons, Efferent, Abdomen, Animals, Premovement neuronal activity, Adult stage, Metamorphosis, Ecology, Evolution, Behavior and Systematics, Cuticle (hair), media_common, Denervation, Larva, biology, fungi, Metamorphosis, Biological, Nerve Block, Anatomy, biology.organism_classification, Cold Temperature, Lepidoptera, Manduca sexta, Ecdysis, Ganglia, Animal Science and Zoology

Abstract

The hawkmoth, Manduca sexta, undergoes periodic molts during its growth and metamorphosis. At the end of each molt, the old cuticle is shed by means of a hormonally-activated ecdysis behavior. The pharate adult, however, must not only shed its old cuticle but also dig itself out from its underground pupation chamber. To accomplish this, the adult performs a series of abdominal retractions and extensions; the extensions are coupled with movements of the wing bases. This ecdysis motor pattern is distinct from the slowly progressing, anteriorly-directed, abdominal peristalses expressed by ecdysing larvae and pupae. We have found that the ability to produce the larval-like ecdysis pattern is retained in the adult. Although this behavior is not normally expressed by the adult, larval-like ecdysis could be unmasked when descending neuronal inputs, originating in the pterothoracic ganglion, were removed from the unfused abdominal ganglia. Transformation of the adult-specific ecdysis pattern to the larval-like pattern was accomplished by transecting the connectives between the pterothorax and the abdomen, or by reversibly blocking neuronal activity with a cold-block. A comparative analysis of the ecdysis motor patterns expressed by larvae and by isolated adult abdomens indicates that the two motor patterns are indistinguishable, suggesting that the larval ecdysis motor pattern is retained through metamorphosis. We speculate that its underlying neural circuitry is conserved through development and later modulated to produce the novel ecdysis pattern expressed in the adult stage.

Published

1988