Your search keyword '"Carausius morosus"' showing total 341 results

1. Pharmacological Characterization of the Stick Insect Carausius morosus Allatostatin-C Receptor with Its Endogenous Agonist

Author

Burcin Duan Sahbaz, Gunes Tuncgenc, Ali Işbilir, Moritz Bünemann, Martin J. Lohse, and Necla Birgül-Iyison

Subjects

Carausius morosus, G protein-coupled receptor kinase, biology, G protein, General Chemical Engineering, Gi alpha subunit, Allatostatin, General Chemistry, biology.organism_classification, Cell biology, Chemistry, Cardiovascular and Metabolic Diseases, Arrestin, Receptor, QD1-999, G protein-coupled receptor

Abstract

G protein-coupled receptors (GPCRs) play a pivotal role in regulating key physiological events in all animal species. Recent advances in collective analysis of genes and proteins revealed numerous potential neuro-peptides and GPCRs from insect species, allowing for the characterization of peptide-receptor pairs. In this work, we used fluorescence resonance energy transfer (FRET)-based genetically encoded biosensors in intact mammalian cells to study the pharmacological features of the cognate GPCR of the type-C allatostatin (AST-C) peptide from the stick insect, Carausius morosus. Analysis of multiple downstream pathways revealed that AST-C can activate the human Gi(2) protein, and not Gs or Gq, through AST-C receptor (AIstRC). Activated AlstRC recruits beta-arrestin2 independent of the Gi protein but stimulates ERK phosphorylation in a Gi protein-dependent manner. Identification of G alpha i-, arrestin-, and GRK-like transcripts from C. morosus revealed high evolutionary conservation at the G protein level, while beta-arrestins and GRKs displayed less conservation. In conclusion, our study provides experimental and homology-based evidence on the functionality of vertebrate G proteins and downstream signaling biosensors to characterize early signaling steps of an insect GPCR. These results may serve as a scaffold for developing assays to characterize pharmacological and structural aspects of other insect GPCRs and can be used in deorphanization and pesticide studies.

Published

2020

2. Prediction and expression analysis of G protein-coupled receptors in the laboratory stick insect, Carausius morosus

Author

Necla Birgül Iyison and Burcin Duan Sahbaz

Subjects

Carausius morosus, Physiology, media_common.quotation_subject, 0206 medical engineering, De novo transcriptome assembly, 02 engineering and technology, Insect, Biology, Microbiology, 03 medical and health sciences, 0302 clinical medicine, Genetics, Extracellular, Receptor, Molecular Biology, G protein-coupled receptor, media_common, RNA, Cell Biology, biology.organism_classification, 020601 biomedical engineering, Cell biology, 030220 oncology & carcinogenesis, General Agricultural and Biological Sciences, hormones, hormone substitutes, and hormone antagonists, Intracellular

Abstract

G protein-coupled receptors (GPCRs) are 7-transmembrane proteins that transduce various extracellular signals into intracellular pathways. They are the major target of neuropeptides, which regulate the development, feeding behavior, mating behavior, circadian rhythm, and many other physiological functions of insects. In the present study, we performed RNA sequencing and de novo transcriptome assembly to uncover the GPCRs expressed in the stick insect Carausius morosus. The transcript assemblies were predicted for the presence of 7-transmembrane GPCR domains. As a result, 430 putative GPCR transcripts were obtained and 43 of these revealed full-length sequences with highly significant similarity to known GPCR sequences in the databases. Thirteen different GPCRs were chosen for tissue expression analysis. Some of these receptors, such as calcitonin, inotocin, and tyramine receptors, showed specific expression in some of the tissues. Additionally, GPCR prediction yielded a novel uncharacterized GPCR sequence, which was specifically expressed in the central nervous system and ganglia. Previously, the only information about the anatomy of the stick insect was on its gastrointestinal system. This study provides complete anatomical information about the adult insect.

Published

2019

3. The tracheal system in the stick insect prothorax and prothoracic legs: Homologies to Orthoptera and relations to mechanosensory functions

Author

Johannes Strauß

Subjects

0106 biological sciences, 0301 basic medicine, Carausius morosus, Insecta, media_common.quotation_subject, Insect, Biology, 010603 evolutionary biology, 01 natural sciences, Neoptera, Vibration, 03 medical and health sciences, Animals, Respiratory function, Ecology, Evolution, Behavior and Systematics, media_common, Appendage, Sipyloidea sipylus, General Medicine, Anatomy, respiratory system, biology.organism_classification, Chordotonal organ, Trachea, 030104 developmental biology, Spiracle, Prothorax, Insect Science, Orthoptera, Developmental Biology

Abstract

Arthropod respiration depends on the tracheal system running from spiracles at the body surface through the body and appendages. Here, three species of stick insects (Carausius morosus, Ramulus artemis, Sipyloidea sipylus) are investigated for the tracheae in the prothorax and foreleg. The origin of the tracheae from the mesothoracic spiracle that enter the foreleg is identified: five tracheae originate from the mesothoracic spiracle, of which two enter the foreleg (supraventral trachea, trachea pedalis anterior). These two tracheae run separately through the leg to the femur-tibia joint where they fuse, but in the proximal tibia split again into two tracheae. The leg tracheae in stick insects are homologous to those in Tettigoniidae (bushcrickets). Stick insects have two chordotonal organs in the proximal tibia (subgenual organ and distal organ) which locate dorsally of the leg trachea. The tracheal system shows no adaptation specific to the propagation of airborne sound, like enlarged spiracles or tracheal volumes. Tracheal vesicles form in the tibia proximally to the mechanosensory organs, but no tracheal sacks or expansions occur at the level of the sensory organs that could mediate the detection of airborne sound or amplify substrate vibrations transmitted in the hemolymph fluid. Rather, the morphological characteristics indicate a respiratory function.

Published

2021

4. Proprioceptive input to a descending pathway conveying antennal postural information: Terminal organisation of antennal hair field afferents

Author

Jens Goldammer and Volker Dürr

Subjects

leg, 0301 basic medicine, INFORMATION, Arthropod, INSECTS, HAIRS, Mechanoreceptor, flagellum, 0302 clinical medicine, mechanoreceptors, MOVEMENT CONTROL, Tactile sensing, ganglion, biology, insect antenna, coordinate transformation, Collaterals, Spatial localisation, STICK-INSECT, General Medicine, FUNCTIONAL-ROLE, Motoneuron, Ganglion, medicine.anatomical_structure, localisation, Terminal (electronics), Cerebral ganglion, Female, Locomotion, Arthropod Antennae, Carausius morosus, Sensory Receptor Cells, Front Leg, Morphological similarity, Posture, TERMINALS, STICK INSECTS, Environment, lobe, Neoptera, tactile, AFFERENTS, MOVEMENT, 03 medical and health sciences, Carausius, mechanosensory, medicine, HAIR, Animals, PROJECTION PATTERNS, Stick Insect, Ecology, Evolution, Behavior and Systematics, Antennal motoneuron, Ganglion Cysts, proprioceptor, MOVEMENTS, PROJECTION, Proprioception, dorsal lobe, PROPRIOCEPTORS, TACTILE HAIRS, Antennae, tactile hair, biology.organism_classification, CARAUSIUS-MOROSUS, Lobe, pedicel, Neuroanatomy, PATTERN, 030104 developmental biology, ARBORIZATIONS, proprioceptive, Insect Science, antennal movement, afferent, PATTERNS, Hair field, insect, sense organs, control, Neuroscience, 030217 neurology & neurosurgery, Developmental Biology

Abstract

Like several other arthropod species, stick insects use their antennae for tactile exploration of the near-range environment and for spatial localisation of touched objects. More specifically, Carausius morosus continuously moves its antennae during locomotion and reliably responds to antennal contact events with directed movements of a front leg. Here we investigate the afferent projection patterns of antennal hair fields (aHF), proprioceptors known to encode antennal posture and movement, and to be involved in antennal movement control. We show that afferents of all seven aHF of C. morosus have terminal arborisations in the dorsal lobe (DL) of the cerebral (=supraoesophageal) ganglion, and descending collaterals that terminate in a characteristic part of the gnathal (=suboesophageal) ganglion. Despite differences of functional roles among aHF, terminal arborisation patterns show no topological arrangement according to segment specificity or direction of movement. In the DL, antennal motoneuron neurites show arborizations in proximity to aHF afferent terminals. Despite the morphological similarity of single mechanoreceptors of aHF and adjacent tactile hairs on the pedicel and flagellum, we find a clear separation of proprioceptive and exteroceptive mechanosensory neuropils in the cerebral ganglion. Moreover, we also find this functional separation in the gnathal ganglion.

Published

2018

5. Investigating the role of low level reinforcement reflex loops in insect locomotion

Author

Clarissa A. Goldsmith, Nicholas S. Szczecinski, and Roger D. Quinn

Subjects

Carausius morosus, Nervous system, Insecta, biology, Interneuron, Computer science, Biophysics, Sensory system, Feedback loop, biology.organism_classification, Biochemistry, Chordotonal organ, medicine.anatomical_structure, Feedback, Sensory, Interneurons, Reflex, medicine, Animals, Molecular Medicine, Engineering (miscellaneous), Neuroscience, Locomotion, Biotechnology, Positive feedback

Abstract

Insects are highly capable walkers, but many questions remain regarding how the insect nervous system controls locomotion. One particular question is how information is communicated between the ‘lower level’ ventral nerve cord (VNC) and the ‘higher level’ head ganglia to facilitate control. In this work, we seek to explore this question by investigating how systems traditionally described as ‘positive feedback’ may initiate and maintain stepping in the VNC with limited information exchanged between lower and higher level centers. We focus on the ‘reflex reversal’ of the stick insect femur-tibia joint between a resistance reflex (RR) and an active reaction in response to joint flexion, as well as the activation of populations of descending dorsal median unpaired (desDUM) neurons from limb strain as our primary reflex loops. We present the development of a neuromechanical model of the stick insect (Carausius morosus) femur-tibia (FTi) and coxa-trochanter joint control networks ‘in-the-loop’ with a physical robotic limb. The control network generates motor commands for the robotic limb, whose motion and forces generate sensory feedback for the network. We based our network architecture on the anatomy of the non-spiking interneuron joint control network that controls the FTi joint, extrapolated network connectivity based on known muscle responses, and previously developed mechanisms to produce ‘sideways stepping’. Previous studies hypothesized that RR is enacted by selective inhibition of sensory afferents from the femoral chordotonal organ, but no study has tested this hypothesis with a model of an intact limb. We found that inhibiting the network’s flexion position and velocity afferents generated a reflex reversal in the robot limb’s FTi joint. We also explored the intact network’s ability to sustain steady locomotion on our test limb. Our results suggested that the reflex reversal and limb strain reinforcement mechanisms are both necessary but individually insufficient to produce and maintain rhythmic stepping in the limb, which can be initiated or halted by brief, transient descending signals. Removing portions of this feedback loop or creating a large enough disruption can halt stepping independent of the higher-level centers. We conclude by discussing why the nervous system might control motor output in this manner, as well as how to apply these findings to generalized nervous system understanding and improved robotic control.

Published

2021

6. Differential effects of predator cues versus activation of fight-or-flight behaviour on reproduction in the cricket Gryllus texensis

Author

Shelley A. Adamo and R. McKee

Subjects

0106 biological sciences, 0301 basic medicine, Carausius morosus, Gryllus texensis, Walking stick, biology, Ecology, media_common.quotation_subject, Zoology, biology.organism_classification, 010603 evolutionary biology, 01 natural sciences, Predation, 03 medical and health sciences, 030104 developmental biology, Cricket, Animal Science and Zoology, Habituation, Reproduction, Predator, Ecology, Evolution, Behavior and Systematics, media_common

Abstract

How prey animals determine predation risk remains uncertain. We propose that one signal of high predation risk is repeated activation of fight-or-flight behaviour. We activated escape runs in the cricket Gryllus texensis by blowing air on the cerci. Escape runs were induced for 5 min, three times per day, three times per week for 4 weeks. Repeated fight-or-flight behaviour led to a loss in mass and decreased life span, suggesting a decline in somatic maintenance. However, there was an increase in egg laying, which we interpret as terminal reproductive investment. Stress responses remained robust. Octopamine (OA), a stress neurohormone in insects, increased in concentration in the haemolymph after running, and the magnitude of the increase was the same even after repeated activation (i.e. there was no habituation of the response). There was also no increase in basal OA haemolymph levels. In a second experiment, crickets were exposed to a mantid (predator, Tenodera sinensis), a walking stick (nonpredator, Carausius morosus), or an empty container. None of the crickets exhibited fight-or-flight behaviour. However, mantid-exposed crickets decreased egg laying. There was no decrease in life span or mass. There was no change in basal levels of OA, or in the magnitude of the OA increase after running. These results are consistent with the hypothesis that repeated fight-or-flight behaviour induces reproductive responses that would be adaptive for a shortened life span. These responses differ from those produced by predator cues alone. Even short-lived animals, such as crickets, appear to alter reproduction depending on the relative predation risk and their residual reproductive potential.

Published

2017

7. Fiber-type distribution in insect leg muscles parallels similarities and differences in the functional role of insect walking legs

Author

Matthias Gruhn, Ansgar Büschges, and Elzbieta Godlewska-Hammel

Subjects

030110 physiology, 0301 basic medicine, Carausius morosus, Insecta, Contraction (grammar), Physiology, media_common.quotation_subject, Muscle Fibers, Skeletal, Walking, Hindlimb, Insect, Biology, Leg muscle, 03 medical and health sciences, Behavioral Neuroscience, 0302 clinical medicine, Animals, Muscle, Skeletal, Ecology, Evolution, Behavior and Systematics, media_common, Adenosine Triphosphatases, Fiber type, Motor control, Anatomy, biology.organism_classification, Biomechanical Phenomena, Female, Animal Science and Zoology, Myofibril, 030217 neurology & neurosurgery

Abstract

Previous studies have demonstrated that myofibrillar ATPase (mATPase) enzyme activity in muscle fibers determines their contraction properties. We analyzed mATPase activities in muscles of the front, middle and hind legs of the orthopteran stick insect (Carausius morosus) to test the hypothesis that differences in muscle fiber types and distributions reflected differences in their behavioral functions. Our data show that all muscles are composed of at least three fiber types, fast, intermediate and slow, and demonstrate that: (1) in the femoral muscles (extensor and flexor tibiae) of all legs, the number of fast fibers decreases from proximal to distal, with a concomitant increase in the number of slow fibers. (2) The swing phase muscles protractor coxae and levator trochanteris, have smaller percentages of slow fibers compared to the antagonist stance muscles retractor coxae and depressor trochanteris. (3) The percentage of slow fibers in the retractor coxae and depressor trochanteris increases significantly from front to hind legs. These results suggest that fiber-type distribution in leg muscles of insects is not identical across leg muscles but tuned towards the specific function of a given muscle in the locomotor system.

Published

2017

8. Carausius morosus (Phasmatodea) Homologues of Human Genes with Elevated Expression in the Colon

Author

Matan Shelomi

Subjects

Carausius morosus, Malpighian tubule system, biology, ved/biology, business.industry, ved/biology.organism_classification_rank.species, General Medicine, biology.organism_classification, Transcriptome, Excretion, Biochemistry, Excretory system, Myosin, Medicine, Model organism, business, Gene

Abstract

Background: Preliminary testing of novel drugs for colorectal conditions must be performed on animal models, with invertebratemodels desirable for practical reasons. The insect excretory organs, the Malpighian tubules, have been cited as models for humanrenal disease research because they differentially express several genes homologous to those differentially expressed in humankidneys. Their role in excretion and homeostasis suggests that they could be models for human colorectal disease. The insect Carausiusmorosus (Phasmatodea) has been a model organism for decades. Regarding its potential use as a colorectal disease model,it has an advantage over other insects in that excretion in Phasmatodea is split between two organs: Malpighian tubules and thePhasmatodea-specific “appendices of the midgut”.Objectives: To find homologues of human colon genes expressed in the excretory tissues of C. morosus for potential use in drugtesting and other experiments requiring an animal model.Methods: Pre-existing transcriptomics data for the excretory system of the C. morosus were examined to find genes homologous tothose known to have elevated expression in the human colon. This was done with the goal of possibly determining the excretorytissues in which they are differentially expressed.Results: Exactly sixty transcripts from the excretory system transcriptome of C. morosus showed high sequence homology withhuman colon-specific genes, with a minimum e-value of 1e-50. Examples include solute carriers, myosin, bestrophin, carbonic anhydrase,and nitric oxide synthase. Several genes were identified with prognostic value for renal, pancreatic, endometrial, liver, skin,and urothelial cancers.Conclusions: C. morosus can be used as model insect for human medical research applications, including colorectal drug testing.

Published

2019

9. Motor control of an insect leg during level and incline walking

Author

Dallmann, Chris, Dürr, Volker, and Schmitz, Josef

Subjects

Carausius morosus, medicine.medical_specialty, Insecta, Physiology, Body height, Video Recording, Walking, Kinematics, Electromyography, Aquatic Science, 03 medical and health sciences, 0302 clinical medicine, Physical medicine and rehabilitation, Motor system, medicine, Animals, Ground reaction force, Muscle, Skeletal, Molecular Biology, Ecology, Evolution, Behavior and Systematics, 030304 developmental biology, Mathematics, 0303 health sciences, biology, medicine.diagnostic_test, Proprioception, Motor control, Extremities, biology.organism_classification, Biomechanical Phenomena, body regions, Torque, Insect Science, Animal Science and Zoology, 030217 neurology & neurosurgery

Abstract

During walking, the leg motor system must continually adjust to changes in mechanical conditions, such as the inclination of the ground. To understand the underlying control, it is important to know how changes in leg muscle activity relate to leg kinematics (movements) and leg dynamics (forces, torques). Here, we studied these parameters in hindlegs of stick insects (Carausius morosus) during level and uphill/downhill (±45deg) walking, using a combination of electromyography, 3D motion capture and ground reaction force measurements. We find that some kinematic parameters including leg joint angles and body height vary across walking conditions. However, kinematics vary little compared with dynamics: horizontal leg forces and torques at the thorax-coxa joint (leg protraction/retraction) and femur-tibia joint (leg flexion/extension) tend to be stronger during uphill walking and are reversed in sign during downhill walking. At the thorax-coxa joint, the different mechanical demands are met by adjustments in the timing and magnitude of antagonistic muscle activity. Adjustments occur primarily in the first half of stance after the touch-down of the leg. When insects transition from level to incline walking, the characteristic adjustments in muscle activity occur with the first step of the leg on the incline, but not in anticipation. Together, these findings indicate that stick insects adjust leg muscle activity on a step-by-step basis so as to maintain a similar kinematic pattern under different mechanical demands. The underlying control might rely primarily on feedback from leg proprioceptors signaling leg position and movement. © 2019. Published by The Company of Biologists Ltd.

Published

2019

10. Stubborn insects stick to regular walk when scaling slopes

Author

Kathryn Knight

Subjects

0106 biological sciences, Carausius morosus, 0303 health sciences, History, biology, Physiology, 030310 physiology, Art history, Aquatic Science, biology.organism_classification, 010603 evolutionary biology, 01 natural sciences, 03 medical and health sciences, Insect Science, Animal Science and Zoology, Molecular Biology, Ecology, Evolution, Behavior and Systematics

Abstract

[Figure][1] A stick insect ( Carausius morosus ). Photo credit: Department of Biological Cybernetics, Bielefeld University. Anyone who has ever visited the historic city of Cambridge, UK, will know that something is missing: hills. Residents rarely experience the challenge of negotiating

Published

2019

11. Identification of the origin of force-feedback signals influencing motor neurons of the thoraco-coxal joint in an insect

Author

Matthias Gruhn, Anna Haberkorn, Sasha N. Zill, and Ansgar Büschges

Subjects

Carausius morosus, Insecta, Physiology, 030310 physiology, media_common.quotation_subject, Campaniform sensilla, Movement, Insect, 03 medical and health sciences, Behavioral Neuroscience, 0302 clinical medicine, Feedback, Sensory, medicine, Animals, Sensilla, Ecology, Evolution, Behavior and Systematics, Haptic technology, media_common, Motor Neurons, 0303 health sciences, Mechanosensation, biology, Motor control, Extremities, Anatomy, Motor neuron, biology.organism_classification, medicine.anatomical_structure, Coxal joint, Animal Science and Zoology, 030217 neurology & neurosurgery

Abstract

Force feedback from Campaniform sensilla (CS) on insect limbs helps to adapt motor outputs to environmental conditions, but we are only beginning to reveal the neural control mechanisms that mediate these influences. We studied CS groups that affect control of the thoraco-coxal joint in the stick insect Carausius morosus by applying horizontal and vertical forces to the leg stump. Motor effects of ablation of CS groups were evaluated by recording extracellularly from protractor (ProCx) and retractor (RetCx) nerves. Extracellular recordings showed that the effects of stimulating the sensilla were consistent with their broad ranges of directional sensitivity: for example, RetCx firing in response to posterior bending could be reduced by ablating several groups of trochanteral CS, whereas ablation of tibial and femoral sensilla had little effect. In contrast, ProCx motor neuron activity upon anteriorly directed stimuli was affected mainly by ablating a single CS group (G2). Dye fills of trochanteral, femoral and tibial CS groups with fluorescent dyes revealed a common projection pattern with little group specificity. These findings support the idea that the influences of CS feedback are determined by the activities of pre-motor interneurons, facilitating fast and task-dependent adaptation to changing environmental conditions.

Published

2019

12. The plant hopperIssus coleoptratuscan detoxify phloem sap saponins including the degradation of the terpene core

Author

Markus Himmelsbach, Werner Baumgartner, Agnes Weth, Christine Böhme, Martin Schwarz, and Peter Bräunig

Subjects

0106 biological sciences, 0301 basic medicine, Carausius morosus, QH301-705.5, Science, media_common.quotation_subject, Ivy, Insect, complex mixtures, 01 natural sciences, General Biochemistry, Genetics and Molecular Biology, Fulgoromorpha, Terpene, 03 medical and health sciences, Mass spectroscopy, Triterpene, ddc:570, parasitic diseases, Botany, Biology (General), media_common, chemistry.chemical_classification, biology, Hedera, fungi, food and beverages, Midgut, biology.organism_classification, Issus coleoptratus, carbohydrates (lipids), 030104 developmental biology, chemistry, Phloem, Genine, General Agricultural and Biological Sciences, Research Article, 010606 plant biology & botany

Abstract

Issus coleoptratus is a small plant hopper which mainly feeds on the phloem sap from ivy. Although all parts of ivy are poisonous as the plant contains saponins, especially hederasaponins, I. coleoptratus can cope with the poison. In contrast to other animals like the stick insect Carausius morosus which accumulates saponins in its body, I. coleoptratus can degrade and disintegrate not only the saponins but even the genines, i.e. the triterpene core of the substances. This is perhaps made possible by a specialised midgut and/or the salivary glands. When the glands and the gut are dissected and added to saponins in solution, the saponins, including the genines, are degraded ex vivo., Summary: In contrast to other insects the plant hopper Issus coleoptratus does not accumulate toxic saponins from ivy. I. coleoptratus can degrade the saponines by its salivary glands and its gut as shown by HPLC-MS.

Published

2016

13. In silico characterization of adipokinetic hormone receptor and screening for pesticide candidates against stick insect, Carausius morosus

Author

Merve Gizem Sinmaz, Burcin Duan Sahbaz, Busecan Aksoydan, Serdar Durdagi, Aida Shahraki, and Necla Birgül Iyison

Subjects

0301 basic medicine, Carausius morosus, Insecta, In silico, 03 medical and health sciences, 0302 clinical medicine, Materials Chemistry, Animals, Homology modeling, Pesticides, Physical and Theoretical Chemistry, Adipokinetic hormone, Spectroscopy, G protein-coupled receptor, Virtual screening, biology, Chemistry, Ligand (biochemistry), biology.organism_classification, Computer Graphics and Computer-Aided Design, Pyrrolidonecarboxylic Acid, Molecular Docking Simulation, 030104 developmental biology, Biochemistry, Docking (molecular), Insect Hormones, Insect Proteins, Oligopeptides, 030217 neurology & neurosurgery

Abstract

Adipokinetic hormone (AKH) is an insect neuropeptide that plays crucial roles in a variety of physiological functions such as regulation of heartbeat frequency, blood hemolymph trehalose levels, and protein synthesis. It exerts its functions through binding to its cognate G protein-coupled receptor (GPCR), named adipokinetic hormone receptor (AKHR). The aim of this study is to characterize AKHR of stick insect, Carausius morosus, which becomes an agricultural and forest pest during its outbreaks, and to screen pesticide candidates that would act through inhibition of AKHR. To this aim, the sequence of the receptor and its ligand were obtained from previously published transcriptome data and homology modeling, molecular docking, and molecular dynamics (MD) simulations were combined to find the ligand-binding pocket of AKHR. As a result, crucial residues in ligand binding were identified. These residues were located at the 6th and 7th transmembrane (TM) domains and the 2nd extracellular loop (ECL) of AKHR model. In order to propose pesticide candidates, virtual screening was performed, and candidate ligands were obtained. Considering the binding energies and the stability of the interaction between the ligand and the receptor, four hit compounds were selected. In conclusion, this study revealed a possible ligand-binding pocket of AKHR and proposed some high-affinity small-molecules to block its function, which would further facilitate pesticide design studies against the same receptor of various pests.

Published

2020

14. Scaling of claw sharpness: mechanical constraints reduce attachment performance in larger insects

Author

David Labonte, Jonathan G. Pattrick, Walter Federle, Pattrick, Jonathan G [0000-0001-6587-5500], and Apollo - University of Cambridge Repository

Subjects

0106 biological sciences, 0301 basic medicine, Carausius morosus, Claw, animal structures, Insecta, Physiology, Cockroaches, Cephalotes, Aquatic Science, Body size, 010603 evolutionary biology, 01 natural sciences, Article, Scaling, 03 medical and health sciences, Animals, Body Size, Molecular Biology, Ecology, Evolution, Behavior and Systematics, Allometry, Gromphadorhina portentosa, biology, Ants, Attachment performance, Claw sharpness, Extremities, Atta cephalotes, 11 Medical And Health Sciences, 06 Biological Sciences, biology.organism_classification, Biomechanical Phenomena, body regions, 030104 developmental biology, Insect Science, Animal Science and Zoology, Biological system

Abstract

Claws are the most widespread attachment devices in animals, but comparatively little is known about the mechanics of claw attachment. A key morphological parameter in determining attachment ability is claw sharpness; however, there is a conflict between sharpness and fracture resistance. Sharper claws can interlock on more surfaces but are more likely to break. Body size interacts with this conflict such that larger animals should have much blunter claws and consequently poorer attachment ability than smaller animals. This expected size-induced reduction in attachment performance has not previously been investigated, and it is unclear how animals deal with this effect, and whether it indeed exists. We explored the scaling of claw sharpness with body size using four insect species (Nauphoeta cinerea, Gromphadorhina portentosa, Atta cephalotes and Carausius morosus) each covering a large size range. The scaling of claw sharpness varied significantly between species, suggesting that they face different pressures regarding claw function. Attachment forces were measured for A. cephalotes and G. portentosa (which had different scaling of claw sharpness) on several rough surfaces using a centrifuge setup. As expected, attachment performance was poorer in larger animals. Firstly, larger animals were more likely to slip, although this effect depended on the scaling of claw sharpness. Secondly, when they gripped, they attached with smaller forces relative to their weight. This size-induced reduction in attachment performance has significant implications for the attachment ability of larger animals on rough surfaces.

Published

2018

15. Fine structure of the abdominal neural fat-body sheath in the stick insect (Carausius morosus, Br.)

Author

K. Oates, H. Huddart, and M. Greenwood

Subjects

Carausius morosus, integumentary system, biology, Glycogen, media_common.quotation_subject, Central nervous system, Anatomy, Insect, biology.organism_classification, law.invention, chemistry.chemical_compound, medicine.anatomical_structure, chemistry, law, Ventral nerve cord, Lipid droplet, medicine, Animal Science and Zoology, Electron microscope, Developmental Biology, Lamella (cell biology), media_common

Abstract

The neural fat-body sheath surrounding the abdominal ventral nerve cord of Carausius morosus has been examined by light and electron microscopy. A perineural chamber between the ventral nerve cord and the sheath is present in the ganglionic regions, but in the interconnective regions the sheath directly covers the neural lamella. The sheath is differentiated into secretory cells with abundant granular endoplasmic reticulum and many mitochondria and storage cells with lipid droplets and granules presumed to be glycogen. The whole sheath is pervaded with tracheoblast cells and associated tracheal and tracheolar tubules. Recent evidence suggests that this sheath may have little power of ionic regulation. The function of the sheath, deduced from the fine structure described here, appears to be to serve the nutritional needs of the central nervous system. Why a sheath of this type appears to be confined to herbivorous insects with unusual haemolymph cationic balance is still unexplained.

Published

2018

16. Transcriptomic and Neuropeptidomic Analysis of the Stick Insect, Carausius morosus

Author

Ansgar Büschges, Lapo Ragionieri, Reinhard Predel, Susanne Neupert, and Sander Liessem

Subjects

0301 basic medicine, Nervous system, Carausius morosus, Central Nervous System, Insecta, media_common.quotation_subject, Neuropeptide, Insect, Biology, Biochemistry, Homology (biology), Transcriptome, 03 medical and health sciences, 0302 clinical medicine, medicine, Animals, Motor activity, Protein precursor, media_common, Gene Expression Profiling, Neuropeptides, General Chemistry, biology.organism_classification, Cell biology, 030104 developmental biology, medicine.anatomical_structure, Spectrometry, Mass, Matrix-Assisted Laser Desorption-Ionization, Insect Proteins, 030217 neurology & neurosurgery

Abstract

One of the most thoroughly studied insect species, with respect to locomotion behavior, is the stick insect Carausius morosus. Although detailed information exists on premotor networks controlling walking, surprisingly little is known about neuropeptides, which are certainly involved in motor activity generation and modulation. So far, only few neuropeptides were identified from C. morosus or related stick insects. We performed a transcriptome analysis of the central nervous system to assemble and identify 65 neuropeptide and protein hormone precursors of C. morosus, including five novel putative neuropeptide precursors without clear homology to known neuropeptide precursors of other insects ( Carausius neuropeptide-like precursor 1, HanSolin, PK-like1, PK-like2, RFLamide). Using Q Exactive Orbitrap and MALDI-TOF mass spectrometry, 277 peptides including 153 likely bioactive mature neuropeptides were confirmed. Peptidomics yielded a complete coverage for many of the neuropeptide propeptides and confirmed a surprisingly high number of heterozygous sequences. Few neuropeptide precursors commonly occurring in insects, including those of insect kinins and sulfakinins, could neither be found in the transcriptome data nor did peptidomics support their presence. The results of our study represent one of the most comprehensive peptidomic analyses on insects and provide the necessary input for subsequent experiments revealing neuropeptide function in greater detail.

Published

2018

17. Both stiff and compliant: morphological and biomechanical adaptations of stick insect antennae for tactile exploration

Author

Jan-Henning Dirks, Hamed Rajabi, Volker Dürr, A. Shafiei, Stanislav N. Gorb, and Abolfazl Darvizeh

Subjects

030110 physiology, 0301 basic medicine, Carausius morosus, Arthropod Antennae, media_common.quotation_subject, Biomedical Engineering, Biophysics, Bioengineering, Insect, Flagellum, Somatosensory system, Biochemistry, Models, Biological, Neoptera, Biomaterials, flagellum, 03 medical and health sciences, 0302 clinical medicine, Animals, biomimetics, Exploration behaviour, Cuticle (hair), media_common, damping, biology, Life Sciences–Physics interface, Anatomy, biology.organism_classification, Touch Perception, Touch, active exploration, cuticle, 030217 neurology & neurosurgery, Biotechnology

Abstract

Active tactile exploration behaviour is constrained to a large extent by the morphological and biomechanical properties of the animal's somatosensory system. In the model organismCarausius morosus, the main tactile sensory organs are long, thin, seemingly delicate, but very robust antennae. Previous studies have shown that these antennae are compliant under contact, yet stiff enough to maintain a straight shape during active exploration. Overcritical damping of the flagellum, on the other hand, allows for a rapid return to the straight shape after release of contact. Which roles do the morphological and biomechanical adaptations of the flagellum play in determining these special mechanical properties? To investigate this question, we used a combination of biomechanical experiments and numerical modelling. A set of four finite-element (FE) model variants was derived to investigate the effect of the distinct geometrical and material properties of the flagellum on its static (bending) and dynamic (damping) characteristics. The results of our numerical simulations show that the tapered shape of the flagellum had the strongest influence on its static biomechanical behaviour. The annulated structure and thickness gradient affected the deformability of the flagellum to a lesser degree. The inner endocuticle layer of the flagellum was confirmed to be essential for explaining the strongly damped return behaviour of the antenna. By highlighting the significance of two out of the four main structural features of the insect flagellum, our study provides a basis for mechanical design of biomimetic touch sensors tuned to become maximally flexible while quickly resuming a straight shape after contact.

Published

2018

18. Object Localisation with a Highly Compliant Tactile Sensory Probe via Distributed Strain Sensors

Author

Schultz, Marco, Dürr, Volker, and Vasiliki, Vouloutsi

Subjects

0209 industrial biotechnology, Computer science, INSECTS, 02 engineering and technology, Bending, sensory, Insect antennae, Walking, sensors, sensillum, law.invention, flagellum, 020901 industrial engineering & automation, 0302 clinical medicine, touch, law, sensor, climbing, neural, POSITION, biology, insect antenna, STICK-INSECT, Spatial localisation, Pointing, localisation, tactile sensor, robots, Carausius morosus, Artificial Neural Network, STRAIN, Acoustics, Curvature, compliance, contact location, CURVATURE, tactile, 03 medical and health sciences, Industrial robot, MOVEMENT, Carausius, Tactile localisation, DEFORMATION, Antennal movements, distance, Stick Insect, MOVEMENTS, robot, Antennae, biology.organism_classification, CARAUSIUS-MOROSUS, Neural network, Ambient space, Antenna, antennal movement, SENSILLA, network, Robot, insect, Polar coordinate system, tactile sensors, 030217 neurology & neurosurgery, Tactile sensor

Abstract

Insect antennae have been repeatedly proposed as paragons of active tactile sensors for biomimetic robots. A challenging aspect of using insect-like feelers for tactile localisation concerns the compliance of the long and slender structure of insect antennae. Other than in a rigid sensory probe, where the contact location in space may be estimated from the pointing direction and contact distance along the probe (polar coordinates), the strong compliance of insect antennae during contact events raises the question how insects can localise contact positions in space. Here we study the stick insect antenna to address this question. Our main objective was to test whether and how the bending properties of the insect antenna may allow reliable estimation of spatial contact locations through an array of bending sensors. During walking and climbing, the stick insect Carausius morosus executes cyclic antennal movements to explore the ambient space ahead. When the antenna touches an obstacle, it often bends strongly. Nevertheless, the insect can reliably reach for the contacted obstacle. Here, we systematically deflected insect antennae with an industrial robot to mimic an array of static contact locations. Then, we measured the resulting curvature of the flagellum, assuming that campanifom sensilla distributed along the flagellum could encode the corresponding bending profile. We found that we could train an artificial neural network to estimate the contact positions in 3D space with an accuracy of 0.5 mm or less from a given set of curvature data. This suggests that the bending characteristics of a tactile sensory probe could be tuned to aid spatial localisation by contact-site-dependent, compliant deformation.

Published

2018

19. A comparison of hemocytes in Phasmatodea and Blattodea species

Author

Maria Špoljar, Goran Kovačević, Ena Kolundžić, and Damir Sirovina

Subjects

0106 biological sciences, Carausius morosus, Phasmatidae, Cockroach, biology, media_common.quotation_subject, 010607 zoology, Zoology, Insect, biology.organism_classification, 01 natural sciences, Blaberidae, 010602 entomology, Blattodea, Phasmatodea, Insect Science, biology.animal, hemocytes, insects, Blaberus, Ecology, Evolution, Behavior and Systematics, media_common

Abstract

The aim of this study was to characterize and quantify hemocyte types in the Indian stick insect Carausius morosus (Phasmatidae) and in the tropical cockroaches Blaberus craniifer and Archimandrita tessellata (Blaberidae) cultivated in an insectary. Plasmatocytes, prohemocytes, granulocytes, coagulocytes and spherulocytes were found in the cockroaches. Of the mentioned cells, the Indian stick insect lacks spherulocytes. C. morosus had the lowest total hemocyte count (THC) and B. craniifer had the highest THC. However, the number of plasmatocytes was high in all the insects, but was more pronounced in C. morosus. In cockroaches, as expected, the differential hemocyte count (DHC) was similar, and contained a high number of spherulocytes. The number of coagulocytes was relatively low in all species. Our results contribute to insect hemocyte data and confirm the need for further intensive research into the function of hemocytes and into evolutionary ecology.

Published

2018

20. Avoiding death by feigning death

Author

John Skelhorn

Subjects

0106 biological sciences, 0301 basic medicine, Carausius morosus, Insecta, Zoology, Immobility Response, Tonic, Biology, biology.organism_classification, 010603 evolutionary biology, 01 natural sciences, General Biochemistry, Genetics and Molecular Biology, Predation, Birds, Death, 03 medical and health sciences, 030104 developmental biology, Predatory Behavior, Animals, Freezing Reaction, Cataleptic, General Agricultural and Biological Sciences, Chickens

Abstract

Thanatosis is a common phenomenon in which prey appear to feign death when attacked by predators. It was once widely believed that thanatosis exploited predators' tendencies to avoid dead prey. However, this hypothesis has never been tested, and its feasibility has been questioned to the point that it has been largely abandoned [1,2]. Here, I show that naive birds quickly learned that dead Indian stick insects Carausius morosus were unpalatable, and subsequently rejected live insects that displayed thanatosis, but not those that failed to show thanatosis. Thanatosis had no effect on the behavior of birds that had never experienced dead insects, or those that had experienced dead insects whose resemblance to thanatosic insects had been destroyed. Therefore, thanatosis clearly caused predators to avoid prey that they mistakenly perceived to be dead.

Published

2018

21. Sensory neuroanatomy of stick insects highlights the evolutionary diversity of the orthopteroid subgenual organ complex

Author

Reinhard Lakes-Harlan and Johannes Strauß

Subjects

Carausius morosus, Sense organ, Orthopteroid, General Neuroscience, media_common.quotation_subject, Anatomy, Insect, Biology, biology.organism_classification, Sensory Receptor Cells, Chordotonal organ, medicine.anatomical_structure, Phasmatodea, medicine, Neuroscience, media_common, Neuroanatomy

Abstract

The subgenual organ is a scolopidial sense organ located in the tibia of many insects. In this study the neuroanatomy of the subgenual organ complex of stick insects is clarified for two species, Carausius morosus and Siyploidea sipylus. Neuronal tracing shows a subgenual organ complex that consists of a subgenual organ and a distal organ. There are no differences in neuroanatomy between the three thoracic leg pairs, and the sensory structures are highly similar in both species. A comparison of the neuroanatomy with other orthopteroid insects highlights two features unique in Phasmatodea. The subgenual organ contains a set of densely arranged sensory neurons in the anterior-ventral part of the organ, and a distal organ with 16-17 scolopidial sensilla in C. morosus and 20-22 scolopidial sensilla in S. sipylus. The somata of sensory neurons in the distal organ are organized in a linear array extending distally into the tibia, with only a few exceptions of closely associated neurons. The stick insect sense organs show a case of an elaborate scolopidial sense organ that evolved in addition to the subgenual organ. The neuroanatomy of stick insects is compared to that studied in other orthopteroid taxa (cockroaches, locusts, crickets, tettigoniids). The comparison of sensory structures indicates that elaborate scolopidial organs have evolved repeatedly among orthopteroids. The distal organ in stick insects has the highest number of sensory neurons known for distal organs so far.

Published

2013

22. Ligand Binding Pocket Of A Novel Allatostatin Receptor Type C Of Stick Insect, Carausius Morosus

Author

Hamdi Torun, Osman Ugur Sezerman, Necla Birgül Iyison, Burcin Duan Sahbaz, and Acibadem University Dspace

Subjects

Models, Molecular, 0301 basic medicine, Agonist, Carausius morosus, Insecta, Time Factors, medicine.drug_class, Amino Acid Motifs, Receptors, Cell Surface, Peptide, Ligands, Protein Structure, Secondary, Article, 03 medical and health sciences, 0302 clinical medicine, medicine, Animals, Inverse agonist, Amino Acid Sequence, Receptor, Phylogeny, G protein-coupled receptor, chemistry.chemical_classification, Binding Sites, Multidisciplinary, biology, Neuropeptides, Allatostatin, C700, biology.organism_classification, Cell biology, 030104 developmental biology, chemistry, Insect Proteins, Peptides, 030217 neurology & neurosurgery, Function (biology), Protein Binding

Abstract

Allatostatins (AST) are neuropeptides with variable function ranging from regulation of developmental processes to the feeding behavior in insects. They exert their effects by binding to cognate GPCRs, called Allatostatin receptors (AlstR), which emerge as promising targets for pesticide design. However, AlstRs are rarely studied. This study is the first reported structural study on AlstR-AST interaction. In this work, the first C type AlstR from the stick insect Carausius morosus (CamAlstR-C) was identified and its interaction with type C AST peptide was shown to be physically consistent with the experimental results. The proposed structure of CamAlstR-C revealed a conserved motif within the third extracellular loop, which, together with the N-terminus is essential for ligand binding. In this work, computational studies were combined with molecular and nano-scale approaches in order to introduce an unknown GPCR-ligand system. Consequently, the data obtained provided a reliable target region for future agonist/inverse agonist studies on AlstRs.

Published

2017

23. How does a slender tibia resist buckling? The effect of material, structural and geometric characteristics on the buckling behaviour of the hindleg tibia in the postembryonic development of the stick insectCarausius morosus

Author

Hamed Rajabi, Maximilian Schmitt, Stanislav N. Gorb, and Thies H. Büscher

Subjects

musculoskeletal diseases, 0106 biological sciences, Carausius morosus, Materials science, Physiology, 02 engineering and technology, Aquatic Science, 010603 evolutionary biology, 01 natural sciences, medicine, Tibia, Composite material, Molecular Biology, Ecology, Evolution, Behavior and Systematics, Developmental stage, Mechanical load, biology, Biomechanics, Stiffness, musculoskeletal system, 021001 nanoscience & nanotechnology, Compression (physics), biology.organism_classification, Buckling, Insect Science, Animal Science and Zoology, medicine.symptom, 0210 nano-technology

Abstract

During their lifespan, the long and narrow tibiae of the stick insect Carausius morosus (Sinéty, 1901) experience substantial compressive loads. The mechanical load on the tibiae increases as the weight of the insect rises. The increase in the body weight is accompanied by a notable increase in the insect's body size and, accordingly, by an increase in the length of the tibiae. These changes can both raise the risk of buckling of the tibiae. In this study, we track changes in the material and geometric properties of the hindleg tibia of C. morosus during growth. The results show that although buckling (either by Euler buckling or local buckling) is the dominant failure mode under compression, the tibia is well capable of maintaining its buckling resistance in each postembryonic developmental stage. This is found to be essentially the result of a compromise between the increasing slenderness of the tibia and its increasing material stiffness. The use of an optimal radius to thickness ratio, a soft resilin-dominated core, and chitin fibres oriented in both longitudinal and circumferential directions are presumably additional strategies preventing buckling of the tibia. This study, providing the first quantitative data on changes in the biomechanical properties of cuticle during the entire life of an insect, is expected to shed more light on the structure-property-function relationship in this complex biological composite.

Published

2017

24. Postembryonic Developmental Changes in Photoreceptors of the Stick InsectCarausius morosus Enhance the Shift to an Adult Nocturnal Life-Style

Author

Roman V. Frolov, Mikko Vähäsöyrinki, Esa-Ville Immonen, and Matti Weckström

Subjects

Carausius morosus, Embryo, Nonmammalian, Insecta, Light, genetic structures, media_common.quotation_subject, Embryonic Development, Stimulation, Insect, Biology, Nocturnal, Ion Channels, Ommatidium, Animals, Metamorphosis, Nymph, Vision, Ocular, media_common, General Neuroscience, Articles, Anatomy, biology.organism_classification, eye diseases, Circadian Rhythm, Cell biology, Acoustic Stimulation, Data Interpretation, Statistical, Larva, Instar, Female, Photoreceptor Cells, Invertebrate, sense organs, Energy Metabolism, Noise, Photic Stimulation

Abstract

Optimization of sensory processing during development can be studied by using photoreceptors of hemimetabolous insects (with incomplete metamorphosis) as a research model. We have addressed this topic in the stick insectCarausius morosus, where retinal growth after hatching is accompanied by a diurnal-to-nocturnal shift in behavior, by recording from photoreceptors of first instar nymphs and adult animals using the patch-clamp method. In the nymphs, ommatidia were smaller and photoreceptors were on average 15-fold less sensitive to light than in adults. The magnitude of A-type K+current did not increase but the delayed rectifier doubled in adults compared with nymphs, the K+current densities being greater in the nymphs. By contrast, the density of light-induced current did not increase, although its magnitude increased 8.6-fold, probably due to the growth of microvilli. Nymph photoreceptors performed poorly, demonstrating a peak information rate (IR) of 2.9 ± 0.7 bits/s versus 34.1 ± 5.0 bits/s in adults in response to white-noise stimulation. Strong correlations were found between photoreceptor capacitance (a proxy for cell size) and IR, and between light sensitivity and IR, with larger and more sensitive photoreceptors performing better. In adults, IR peaked at light intensities matching irradiation from the evening sky. Our results indicate that biophysical properties of photoreceptors at each age stage and visual behavior are interdependent and that developmental improvement in photoreceptor performance may facilitate the switch from the diurnal to the safer nocturnal lifestyle. This also has implications for how photoreceptors achieve optimal performance.

Published

2012

25. Adhesive and frictional properties of tarsal attachment pads in two species of stick insects (Phasmatodea) with smooth and nubby euplantulae

Author

Harald Wolf, Philipp Busshardt, and Stanislav N. Gorb

Subjects

Carausius morosus, Insecta, Friction, biology, Surface Properties, Adhesiveness, Extremities, Anatomy, Adhesion, biology.organism_classification, Biomechanical Phenomena, Smooth surface, Phasmatodea, Rough surface, Animals, Animal Science and Zoology, Adhesive, Composite material, Locomotion

Abstract

In the present study, the tarsal attachment pads (euplantulae) of two stick insect species (Phasmatodea) were compared. While the euplantulae of Cuniculina impigra (syn. Medauroidea extradentata) are smooth, those of Carausius morosus bear small nubs on their surfaces. In order to characterize the adhesive and frictional properties of both types of euplantulae, adhesion and friction measurements on smooth (Ra=0.054 μm) and rough (Ra=1.399 μm) substrates were carried out. The smooth pads of C. impigra generated stronger adhesion on the smooth substrate than on the rough one. The adhesive forces of the structured pads of C. morosus did not differ between the two substrates. Friction experiments showed anisotropy for both species with higher values for proximal pulls than for distal pushes. In C. impigra, friction was stronger on the smooth than on the rough surface for both directions, whereas in C. morosus friction was stronger on the smooth surface only for pushes. This shows that smooth attachment pads are able to generate relatively stronger adhesion and friction on a flat smooth surface than on a rough one. In contrast, nubby pads have similar adhesion on both substrates, and also show no difference in friction in the pulling direction. This leads to the conclusion that smooth pads are specialized for rather smooth substrates, whereas nubby pads are better adapted to generate stronger forces on a broader range of surfaces.

Published

2012

26. Motoneurons, DUM cells, and sensory neurons in an insect thoracic ganglion: A tracing study in the stick insect Carausius morosus

Author

Ansgar Büschges, Jens Goldammer, and Joachim Schmidt

Subjects

Motor Neurons, Carausius morosus, Insecta, Sensory Receptor Cells, Staining and Labeling, General Neuroscience, fungi, Sensory system, Anatomy, Biology, musculoskeletal system, biology.organism_classification, Ganglia, Invertebrate, medicine.anatomical_structure, nervous system, Tubulin, Cortex (anatomy), Neuropil, medicine, Animals, Soma, Thoracic ganglia, Neuroscience, Neuroanatomy

Abstract

Anatomical features of leg motoneurons, dorsal unpaired median (DUM) cells, and sensory neurons in stick insect mesothoracic ganglia were examined using fluorescent dye backfills of lateral nerves. Structures were analyzed in whole-mounts of ganglia and transverse sections. Numbers of motoneurons and details of their structure by far exceed previously published data. The general neuroanatomical layout of motoneurons matches the general orthopteran pattern. Cell bodies of excitatory motoneurons form clusters in the lateral cortex, dendrites branch mainly in the dorsal neuropil. We identified nine DUM cells, six of which have axons in nerve nl5. Most sensory fibers terminate in the ventral association center (VAC). Twenty-three small cell bodies located close to the soma of the fast extensor tibiae motoneuron likely belong to strand receptors. Labeled structures are compared with previously published data from stick insects and other orthopterous insects.

Published

2011

27. Activity Patterns and Timing of Muscle Activity in the Forward Walking and Backward Walking Stick InsectCarausius morosus

Author

Anne Wosnitza, Matthias Gruhn, Philipp Rosenbaum, and Ansgar Büschges

Subjects

Carausius morosus, medicine.medical_specialty, Insecta, Time Factors, Physiology, media_common.quotation_subject, Walking, Insect, Kinematics, Motor Activity, Biology, Neural activity, Physical medicine and rehabilitation, Orientation, medicine, Animals, Muscle activity, Muscle, Skeletal, media_common, Adaptive behavior, Communication, Backward walking, Electromyography, business.industry, General Neuroscience, biology.organism_classification, body regions, Female, business

Abstract

Understanding how animals control locomotion in different behaviors requires understanding both the kinematics of leg movements and the neural activity underlying these movements. Stick insect leg kinematics differ in forward and backward walking. Describing leg muscle activity in these behaviors is a first step toward understanding the neuronal basis for these differences. We report here the phasing of EMG activities and latencies of first spikes relative to precise electrical measurements of middle leg tarsus touchdown and liftoff of three pairs ( protractor/retractor coxae, levator/depressor trochanteris, extensor/flexor tibiae) of stick insect middle leg antagonistic muscles that play central roles in generating leg movements during forward and backward straight walking. Forward walking stance phase muscle (depressor, flexor, and retractor) activities were tightly coupled to touchdown, beginning on average 93 ms prior to and 9 and 35 ms after touchdown, respectively. Forward walking swing phase muscle (levator, extensor, and protractor) activities were less tightly coupled to liftoff, beginning on average 100, 67, and 37 ms before liftoff, respectively. In backward walking the protractor/retractor muscles reversed their phasing compared with forward walking, with the retractor being active during swing and the protractor during stance. Comparison of intact animal and reduced two- and one-middle-leg preparations during forward straight walking showed only small alterations in overall EMG activity but changes in first spike latencies in most muscles. Changing body height, most likely due to changes in leg joint loading, altered the intensity, but not the timing, of depressor muscle activity.

Published

2010

28. Influence of aminergic and peptidergic substances on heart beat frequency in the stick insectCarausius morosus(Insecta, Phasmatodea)

Author

Ottilie K. H. Katali, Gerd Gäde, and Heather G. Marco

Subjects

0301 basic medicine, Carausius morosus, medicine.medical_specialty, Insecta, Physiology, Neuropeptide, Proctolin, Biochemistry, 03 medical and health sciences, 0302 clinical medicine, Internal medicine, Hemolymph, medicine, Animals, Octopamine, Dose-Response Relationship, Drug, Crustacean cardioactive peptide, Cardiac cycle, biology, Neuropeptides, fungi, Heart, General Medicine, biology.organism_classification, 030104 developmental biology, Endocrinology, Prothorax, Insect Hormones, Insect Science, Insect Proteins, Octopamine (neurotransmitter), Oligopeptides, 030217 neurology & neurosurgery

Abstract

The dorsal heart of the Indian stick insect, Carausius morosus, is responsible for the anterograde flow of hemolymph to the aorta and into the body cavity. The contraction frequency of the insect heart is known to be influenced by several substances of neural source. Here, a semi-exposed heart assay was employed to study the effect of an aminergic substance (octopamine) and three neuropeptides (C. morosus hypertrehalosemic hormone [Carmo-HrTH], crustacean cardioactive peptide [CCAP], and proctolin) on heart contraction. The contraction frequency was measured as beats per minute in adults ligated between the head and the prothorax. All three investigated neuropeptides had a stimulatory effect on heart contraction that lasted approximately 6 min, after which the normal heart beat rate was restored. Proctolin and CCAP stimulated the rate of heart beat also in unligated stick insects, whereas Carmo-HrTH was active only in ligated insects. The latter could suggest that when the stick insect is not ligated, a competing substance may be released from the head of C. morosus; the competing substance is, apparently, not physiologically active but it binds or blocks access to the receptor of Carmo-HrTH-II, thereby rendering the HrTH peptide "not active." In ligated stick insects, 6.7 × 10-8 M Carmo-HrTH-II significantly increased the heart beat rate; higher doses resulted in no further increase, suggesting the saturation of the HrTH receptor. Octopamine inhibited the rate at which the heart contracted in a dose-dependent manner; inhibition was achieved with 10-4 M of octopamine.

Published

2018

29. Degenerative and regenerative processes involved in midgut pseudotumor formation in the stick insect (Carausius morosus)

Author

August Dorn, Matthias Holtmann, and Paul Hoffmann

Subjects

Carausius morosus, Pathology, medicine.medical_specialty, Hemocytes, Insecta, Cellular differentiation, Columnar Cell, Granuloma, Plasma Cell, Digestive System Physiological Phenomena, Stomatogastric nervous system, medicine, Animals, Homeostasis, Regeneration, Progenitor cell, Tissue homeostasis, Cell Proliferation, biology, Stem Cells, fungi, Cell Differentiation, Midgut, biology.organism_classification, stomatognathic diseases, Animal Science and Zoology, Stem cell, Digestive System, Developmental Biology

Abstract

Spontaneous and experimentally induced pseudotumor formation in Carausius morosus impairs the midgut tissue homeostasis. Spontaneous pseudotumor formation begins by the break down of a single or a small group of columnar cells (CCs) and is followed by the degeneration of neighboring CCs. There are not only marked similarities but also decisive differences between normal dying CCs in healthy specimens and the degeneration of CCs leading to pseudotumors: in both cases, the apical cell parts with the nucleus are extruded into the midgut lumen, but only during of pseudotumor formation an "amorphous substance" originates from the basal parts of the CCs. Hemocytes are attracted to this substance and form a nodule-like aggregation, which is responsible for the phenotype of pseudotumors. Pseudotumor infestation has also an impact on the midgut nidi, which consist of an intestinal stem cell and several CC progenitor cells. In healthy specimens only one progenitor cell per nidus differentiates at a time, but, several to all progenitor cells differentiate simultaneously in pseudotumor-infested specimens. Extirpation of the ingluvial ganglion in healthy specimens results in an immediate onset of pseudotumor formation and a dramatic acceleration of pseudotumor growth. Importantly, the ultrastructural characteristics of spontaneous and experimentally induced pseudotumors are identical. This supports the idea that the stomatogastric nervous system plays an integral role in the maintenance of midgut tissue homeostasis.

Published

2009

30. Control of Stepping Velocity in the Stick InsectCarausius morosus

Author

Anne Wosnitza, Ansgar Büschges, Sandra Westmark, Géraldine von Uckermann, Matthias Gruhn, and Anke Borgmann

Subjects

Carausius morosus, medicine.medical_specialty, Insecta, Time Factors, Physiology, media_common.quotation_subject, Action Potentials, Walking, Insect, Stimulus (physiology), Physical medicine and rehabilitation, medicine, Animals, media_common, Motor Neurons, Physics, Communication, Nerve activity, biology, business.industry, General Neuroscience, Biomechanics, Articles, Swing, biology.organism_classification, Biomechanical Phenomena, Ganglia, Invertebrate, body regions, Preferred walking speed, Electrophysiology, Female, business, Microelectrodes

Abstract

We performed electrophysiological and behavioral experiments in single-leg preparations and intact animals of the stick insect Carausius morosus to understand mechanisms underlying the control of walking speed. At the level of the single leg, we found no significant correlation between stepping velocity and spike frequency of motor neurons (MNs) other than the previously shown modification in flexor (stance) MN activity. However, pauses between stance and swing motoneuron activity at the transition from stance to swing phase and stepping velocity are correlated. Pauses become shorter with increasing speed and completely disappear during fast stepping sequences. By means of extra- and intracellular recordings in single-leg stick insect preparations we found no systematic relationship between the velocity of a stepping front leg and the motoneuronal activity in the ipsi- or contralateral mesothoracic protractor and retractor, as well as flexor and extensor MNs. The observations on the lack of coordination of stepping velocity between legs in single-leg preparations were confirmed in behavioral experiments with intact stick insects tethered above a slippery surface, thereby effectively removing mechanical coupling through the ground. In this situation, there were again no systematic correlations between the stepping velocities of different legs, despite the finding that an increase in stepping velocity in a single front leg is correlated with a general increase in nerve activity in all connectives between the subesophageal and all thoracic ganglia. However, when the tethered animal increased walking speed due to a short tactile stimulus, provoking an escape-like response, stepping velocities of ipsilateral legs were found to be correlated for several steps. These results indicate that there is no permanent coordination of stepping velocities between legs, but that such coordination can be activated under certain circumstances.

Published

2009

31. XIX. Observations on the Growth and Habits of the Stick Insect, Carausius morosus, Br.; intended as a contribution towards a knowledge of variation in an organism which reproduces itself by the parthenogenetic method

Author

H. Ling Roth

Subjects

Carausius morosus, Variation (linguistics), Ecology, biology, Insect Science, media_common.quotation_subject, Zoology, Parthenogenesis, Insect, biology.organism_classification, Organism, media_common

Published

2009

32. XI. A Contribution to our knowledge of the Life-history of the Stick Insect, Carausius morosus Br

Author

Geoege Talbot

Subjects

Carausius morosus, Ecology, Insect Science, media_common.quotation_subject, Zoology, Insect, Life history, Biology, biology.organism_classification, media_common

Published

2009

33. Structural differentiation in the mid-gut epithelium of the phasmid Carausius morosus Brunner

Author

D. J. Beadle

Subjects

Carausius morosus, medicine.anatomical_structure, Physiology, Insect Science, medicine, Midgut, Anatomy, Biology, biology.organism_classification, Ecology, Evolution, Behavior and Systematics, Epithelium

Abstract

SYNOPSIS The epithelial cells of the anterior central and posterior regions of the midgut of Carausius morosus are described. Possible functions of the cells, indicated by structural differentiation, are discussed.

Published

2009

34. Neural Control of Unloaded Leg Posture and of Leg Swing in Stick Insect, Cockroach, and Mouse Differs from That in Larger Animals

Author

Christoph Guschlbauer, Turgay Akay, Scott L. Hooper, Marcus Blümel, Matthias Gruhn, Philipp Rosenbaum, and Ansgar Büschges

Subjects

Carausius morosus, Insecta, Movement, media_common.quotation_subject, Posture, Action Potentials, Motor nerve, Insect, In Vitro Techniques, Mice, biology.animal, Animals, Humans, Horses, Muscle, Skeletal, Motor skill, media_common, Motor Neurons, Cockroach, Behavior, Animal, biology, Proprioception, Electromyography, General Neuroscience, Motor control, Articles, Anatomy, Swing, biology.organism_classification, Biomechanical Phenomena, body regions, Lower Extremity, Female, Muscle Contraction

Abstract

Stick insect (Carausius morosus) leg muscles contract and relax slowly. Control of stick insect leg posture and movement could therefore differ from that in animals with faster muscles. Consistent with this possibility, stick insect legs maintained constant posture without leg motor nerve activity when the animals were rotated in air. That unloaded leg posture was an intrinsic property of the legs was confirmed by showing that isolated legs had constant, gravity-independent postures. Muscle ablation experiments, experiments showing that leg muscle passive forces were large compared with gravitational forces, and experiments showing that, at the rest postures, agonist and antagonist muscles generated equal forces indicated that these postures depended in part on leg muscles. Leg muscle recordings showed that stick insect swing motor neurons fired throughout the entirety of swing. To test whether these results were specific to stick insect, we repeated some of these experiments in cockroach (Periplaneta americana) and mouse. Isolated cockroach legs also had gravity-independent rest positions and mouse swing motor neurons also fired throughout the entirety of swing. These data differ from those in human and horse but not cat. These size-dependent variations in whether legs have constant, gravity-independent postures, in whether swing motor neurons fire throughout the entirety of swing, and calculations of how quickly passive muscle force would slow limb movement as limb size varies suggest that these differences may be caused by scaling. Limb size may thus be as great a determinant as phylogenetic position of unloaded limb motor control strategy.

Published

2009

35. Sensory Feedback Induced by Front-Leg Stepping Entrains the Activity of Central Pattern Generators in Caudal Segments of the Stick Insect Walking System

Author

Ansgar Büschges, Scott L. Hooper, and Anke Borgmann

Subjects

Central Nervous System, Carausius morosus, medicine.medical_specialty, Insecta, Nerve net, Movement, Sensory system, Walking, Muscarinic Agonists, Biology, Feedback, Physical medicine and rehabilitation, medicine, Animals, Motor Neurons, Sensory stimulation therapy, Extramural, General Neuroscience, digestive, oral, and skin physiology, Pilocarpine, Central pattern generator, Extremities, Articles, Anatomy, biology.organism_classification, body regions, medicine.anatomical_structure, Female, Nerve Net, Step cycle

Abstract

Legged locomotion results from a combination of central pattern generating network (CPG) activity and intralimb and interlimb sensory feedback. Data on the neural basis of interlimb coordination are very limited. We investigated here the influence of stepping in one leg on the activities of neighboring-leg thorax–coxa (TC) joint CPGs in the stick insect (Carausius morosus). We used a new approach combining single-leg stepping with pharmacological activation of segmental CPGs, sensory stimulation, and additional stepping legs. Stepping of a single front leg could activate the ipsilateral mesothoracic TC CPG. Activation of the metathoracic TC CPG required that both ipsilateral front and middle legs were present and that one of these legs was stepping. Unlike the situation in real walking, ipsilateral mesothoracic and metathoracic TC CPGs activated by front-leg stepping fired in phase with the front-leg stepping. Local (intralimb) sensory feedback from load sensors could override this intersegmental influence of front-leg stepping, shifting retractor motoneuron activity relative to the front-leg step cycle and thereby uncoupling them from front-leg stepping. These data suggest that front-leg stepping in isolation would result in in-phase activity of all ipsilateral legs, and functional stepping gaits (in which the three ipsilateral legs do not step in synchrony) emerge because of local load sensory feedback overriding this in-phase influence.

Published

2009

36. Tight turns in stick insects

Author

Sebastian Stübner, Ingo Ehmanns, Josef Schmitz, and Holk Cruse

Subjects

leg, Carausius morosus, life, Insecta, Front Leg, Physiology, Individuality, Spatial Behavior, Geometry, Walking, Models, Biological, hind leg, Behavioral Neuroscience, Carausius, Insect locomotion, Beam (nautical), Orientation, Turn (geometry), Animals, turning, POSITION, Stick Insect, Leg movement, Ecology, Evolution, Behavior and Systematics, MOVEMENTS, biology, Animal, Movement (music), Front (oceanography), Extremities, legs, Anatomy, body, small, Swing, biology.organism_classification, TIME, Biomechanical Phenomena, body regions, insect, Animal Science and Zoology, movement, Locomotion, Psychomotor Performance, Geology, Middle Leg, Curve walking

Abstract

We investigated insects Carausius morosus walking whilst hanging upside down along a narrow 3 mm horizontal beam. At the end of the beam, the animal takes a 180 degrees turn. This is a difficult situation because substrate area is small and moves relative to the body during the turn. We investigated how leg movements are organised during this turn. A non-contact of either front leg appears to indicate the end of the beam. However, a turn can only begin if the hind legs stand in an appropriate position relative to each other; the outer hind leg must not be placed posterior to the inner hind leg. When starting the turn, both front legs are lifted and usually held in a relatively stable position and then the inner middle leg performs a swing-and-search movement: The leg begins a swing, which is continued by a searching movement to the side and to the rear, and eventually grasps the beam. At the same time the body is turned usually being supported by the outer middle leg and both hind legs. Then front legs followed by the outer middle leg reach the beam. A scheme describing the turns based on a few simple behavioural elements is proposed.

Published

2009

37. C-mannosylation in the hypertrehalosaemic hormone from the stick insect Carausius morosus

Author

Gerd Gäde, Claudia Elisabeth Munte, Werner Kremer, Hans Robert Kalbitzer, Barbara Domogalla, and Roland Kellner

Subjects

chemistry.chemical_classification, Carausius morosus, Aqueous solution, Tryptophan, Peptide, Cell Biology, Nuclear magnetic resonance spectroscopy, Biology, biology.organism_classification, Biochemistry, Peptide Conformation, carbohydrates (lipids), chemistry, Mannosylation, Biophysics, Hexose, Molecular Biology

Abstract

The hypertrehalosaemic hormone from the stick insect Carausius morosus (Cam-HrTH) contains a hexose covalently bound to the ring of the tryptophan, which is in the eighth position in the molecule. We show by solution NMR spectroscopy that the tryptophan is modified at its Cδ1(C2) by an α-mannopyranose. It is the first insect hormone to exhibit C-glycosylation whose exact nature has been determined experimentally. Chemical shift analysis reveals that the unmodified as well as the mannosylated Cam-HrTH are not completely random-coil in aqueous solution. Most prominently, C-mannosylation strongly influences the average orientation of the tryptophan ring in solution and stabilizes it in a position clearly different from that found in the unmodified peptide. NMR diffusion measurements indicate that mannosylation reduces the effective hydrodynamic radius. It induces a change of the average peptide conformation that also diminishes the propensity for aggregation of the peptide.

Published

2008

38. Micromechanics of smooth adhesive organs in stick insects: pads are mechanically anisotropic and softer towards the adhesive surface

Author

Ingo Scholz, Werner Baumgartner, and Walter Federle

Subjects

Carausius morosus, Insecta, Materials science, Physiology, Modulus, Arthropod cuticle, Nanotechnology, Microscopy, Atomic Force, Models, Biological, Behavioral Neuroscience, Microscopy, Electron, Transmission, Indentation, Animals, Composite material, Ecology, Evolution, Behavior and Systematics, Cuticle (hair), biology, Adhesiveness, Micromechanics, Extremities, biology.organism_classification, Elasticity, Biomechanical Phenomena, Microscopy, Electron, Scanning, Female, Animal Science and Zoology, Adhesive, Layer (electronics)

Abstract

Animals have evolved adhesive structures on their legs to cling to the substrate during locomotion. Here we characterise the ultrastructure and mechanical properties of adhesive pads in Carausius morosus (Phasmatodea) using atomic force microscopy (AFM) as well as transmission and scanning electron microscopy (TEM, SEM). The smooth adhesive arolium has a soft cuticle consisting of principal rods, which branch into finer fibres near the surface. Indentation experiments showed that the pad material consists of distinct layers with different mechanical properties. The 100-300 nm thick outermost layer consisting of the cuticulin envelope and the epicuticle is extremely soft and resilient (mean effective Young's modulus 12 kPa), while the subjacent procuticle is a much stiffer material (mean effective Young's modulus 625 kPa). AFM contact mode imaging revealed that the cuticle is mechanically anisotropic, which can be explained by its fibrillar inner structure. We propose that the described layered structure of smooth adhesive pads, consisting of materials decreasing in stiffness towards the outer surface, represents a superior design to conform and adhere to substrates with roughnesses at different length scales. This design principle could be easily implemented in technical adhesives, and thus has a potential to inspire biomimetic applications.

Published

2008

39. Intersegmental Coordination: Influence of a Single Walking Leg on the Neighboring Segments in the Stick Insect Walking System

Author

Anke Borgmann, Hans Scharstein, and Ansgar Büschges

Subjects

Carausius morosus, Communication, medicine.medical_specialty, Physiology, business.industry, General Neuroscience, Extremities, Walking, Hindlimb, Motor Activity, Thorax, Biology, biology.organism_classification, body regions, Kinetics, Physical medicine and rehabilitation, Forelimb, medicine, Animals, Orthoptera, Treadmill, business, Psychomotor Performance

Abstract

A key element of walking is the coordinated interplay of multiple limbs to achieve a stable locomotor pattern that is adapted to the environment. We investigated intersegmental coordination of walking in the stick insect, Carausius morosus by examining the influence a single stepping leg has on the motoneural activity of the other hemiganglia, and whether this influence changes with the walking direction. We used a reduced single leg walking preparation with only one intact front, middle, or hind leg. The intact leg performed stepping movements on a treadmill, thus providing intersegmental signals about its stepping to the other hemiganglia. The activity of coxal motoneurons was simultaneously recorded extracellularly in all other segments. Stepping sequences of any given single leg in either walking direction were accompanied by an increase in coxal motoneuron (MN) activity of all other segments, which was mostly modulated and slightly in phase with stance of the walking leg. In addition, forward stepping of the front leg and, to a lesser extent, backward stepping of the hind leg elicited alternating activity in mesothoracic coxal MNs. Forward and backward stepping of the middle leg did not elicit alternating activity in coxal MNs in any other hemiganglia, indicating that the influence of middle leg stepping is qualitatively different from that of forward front and backward hind leg stepping. Our results indicate that in an insect walking system individual segments differ with respect to their intersegmental influences and thus cannot be treated as similar within the chain of segmental walking pattern generators. Consequences for the current concepts on intersegmental coordination are discussed.

Published

2007

40. A dynamic model of thoracic differentiation for the control of turning in the stick insect

Author

Hugo Rosano and Barbara Webb

Subjects

Carausius morosus, Insecta, General Computer Science, Movement, media_common.quotation_subject, Context (language use), Insect, Rotation, Models, Biological, Control theory, Orientation, Animals, Computer Simulation, Simulation, Mathematics, media_common, Behavior, Animal, biology, Extremities, Robotics, Thorax, biology.organism_classification, Biomechanical Phenomena, body regions, Turning behaviour, Algorithms, Locomotion, Psychomotor Performance, Biotechnology

Abstract

Leg movements of stick insects (Carausius morosus) making turns towards visual targets are examined in detail, and a dynamic model of this behaviour is proposed. Initial results suggest that front legs shape most of the body trajectory, while the middle and hind legs just follow external forces (Rosano H, Webb B, in The control of turning in real and simulated stick insects, vol. 4095, pp 145-156, 2006). However, some limitations of this explanation and dissimilarities in the turning behaviour of the insect and the model were found. A second set of behavioural experiments was made by blocking front tarsi to further investigate the active role of the other legs for the control of turning. The results indicate that it is necessary to have different roles for each pair of legs to replicate insect behaviour. We demonstrate that the rear legs actively rotate the body while the middle legs move sideways tangentially to the hind inner leg. Furthermore, we show that on average the middle inner and hind outer leg contribute to turning while the middle outer leg and hind inner leg oppose body rotation. These behavioural results are incorporated into a 3D dynamic robot simulation. We show that the simulation can now replicate more precisely the turns made by the stick insect.

Published

2007

41. Walking in Aretaon asperrimus

Author

Holk Cruse and Thorsten Jeck

Subjects

Male, Carausius morosus, Aretaon, biology, Power walking, Physiology, Movement, Biomechanics, Walking, Anatomy, Mechanics, Swing, biology.organism_classification, Biomechanical Phenomena, Gait (human), Amplitude, swing movement, Duration (music), Insect Science, leg coordination, Trajectory, Animals, Orthoptera, rearward walking, Locomotion

Abstract

This article describes basic parameters characterizing walking of the stick insect Aretaon asperrimus to allow a comparative approach with other insects studied. As in many other animals, geometrical parameters such as step amplitude and leg extreme positions do not vary with walking velocity. However, the relation between swing duration and stance duration is quite constant, in contrast to most insects studied. Therefore, velocity profiles during swing vary with walking velocity whereas time course of leg trajectories and leg angle trajectories are independent of walking velocity. Nevertheless, A. asperrimus does not show a classical tripod gait, but performs a metachronal, or tetrapod, gait, showing phase values differing from 0.5 between ipsilateral neighbouring legs. As in Carausius morosus, the detailed shape of the swing trajectory may depend on the form of the substrate. Effects describing coordinating influences between legs have been found that prevent the start of a swing as long as the posterior leg performs a swing. Further, the treading on tarsus reflex can be observed in Aretaon. No hint to the existence of a targeting influence has been found. Control of rearward walking is easiest interpreted by maintaining the basic rules but an anterior-posterior reversal of the information flow.

Published

2007

42. Slanted joint axes of the stick insect antenna: an adaptation to tactile acuity

Author

André Frank Krause, Samir Mujagic, and Volker Dürr

Subjects

Male, Carausius morosus, media_common.quotation_subject, Acuity, leaf insect, Walking, Insect, Kinematics, size, tactile, Carausius, Blattodea, antennal joint, Species Specificity, Cockroach, Orientation, axis, Orientation (geometry), Animals, Comparative Study, Antennal movements, Adaptation, Stick Insect, Ecology, Evolution, Behavior and Systematics, media_common, MOVEMENTS, Phasmatodea, biology, JOINT, WALKING INSECT, General Medicine, Terrestrial locomotion, Anatomy, biology.organism_classification, Locust, Euphasmatodea, Antenna, Touch, antennal movement, Orthoptera, insect, Female, Cricket, movement, Ensifera, Locomotion

Abstract

Like many flightless, obligatory walking insects, the stick insect Carausius morosus makes intensive use of active antennal movements for tactile near range explora- tion and orientation. The antennal joints of C. morosus have a peculiar oblique and non-orthogonal joint axis arrange- ment. Moreover, this arrangement is known to differ from that in crickets (Ensifera), locusts (Caelifera) and cock- roaches (Blattodea), all of which have an orthogonal joint axis arrangement. Our hypothesis was that the situation found in C. morosus represents an important evolutionary trait of the order of stick and leaf insects (Phasmatodea). If this was true, it should be common to other species of the Phasmatodea. The objective of this comparative study was to resolve this question. We have measured the joint axis orientation of the head-scape and scape-pedicel joints along with other parameters that affect the tactile efficiency of the antenna. The obtained result was a complete kinematic description of the antenna. This was used to determine the size and location of kinematic out-of-reach zones, which are indicators of tactile acuity. We show that the oblique and non-orthogonal arrangement is common to eight species from six sub-families indicating that it is a synapomorphic character of the Euphasmatodea. This character can improve tactile acuity compared to the situation in crickets, locusts and cockroaches. Finally, because molecular data of a recent study indicate that the Phasmatodea may have evolved as flightless, obligatory walkers, we argue that the antennal joint axis arrangement of the Euphasmatodea reflects an evolutionary adaptation to tactile near range exploration during terrestrial locomotion.

Published

2006

43. Natural Neural Output That Produces Highly Variable Locomotory Movements

Author

Ansgar Büschges, Géraldine von Uckermann, Scott L. Hooper, and Christoph Guschlbauer

Subjects

Carausius morosus, Insecta, Contraction (grammar), Physiology, Neural Conduction, High animal, Action Potentials, Motor nerve, Biology, medicine, Animals, Motor Neurons, Communication, business.industry, Muscles, General Neuroscience, Active sensing, Motor neuron, biology.organism_classification, Ganglia, Invertebrate, medicine.anatomical_structure, Aplysia, Female, medicine.symptom, business, Neuroscience, Locomotion, Muscle Contraction, Muscle contraction

Abstract

We recorded fast extensor tibiae motor neuron activity during single-legged treadmill walking in the stick insect, Carausius morosus. We used this activity to stimulate the extensor muscle motor nerve, observed the resulting extensor muscle contractions under isotonic conditions, and quantified these contractions with a variety of measures. Extensor contractions induced in this manner were highly variable, with contraction measures having SDs of 12 to 51%, and ranges of 82 to 275%, when expressed as percentages of the means, an unexpectedly wide range for a locomotory pattern. Searches for correlations among the contraction measures showed that, in general, this high variability is not reduced by contraction measure covariation. Comparing responses (to identical input) across animals showed that extensor muscles from different animals generally significantly differed from one another. However, correlation analyses on these data suggested that these differences do not indicate that multiple extensor muscle subtypes exist. Extensor muscles instead appear to belong to a single class, albeit one with high animal to animal variability. These data thus provide another well-quantified example (along with Aplysia feeding) of a repetitive but highly variable motor pattern (in contrast to the high rhythmicity and stereotypy present in most other well-quantified repetitive motor patterns). We suggest this high variability could be an adaptive combination of locomotion, active sensing, and crypsis arising from the relatively low demand for locomotion in Carausius behavior, the highly fragmented environment the animal inhabits, and its need to avoid predatory attention.

Published

2006

44. The behavioural transition from straight to curve walking: kinetics of leg movement parameters and the initiation of turning

Author

Volker Dürr and Wiebke Ebeling

Subjects

leg, Kinematics, Insecta, Time Factors, Physiology, Arthropod, Video Recording, Walking, Gait (human), Orientation (geometry), Gait, Mathematics, response, biology, JOINT, locomotor, Biomechanics, legs, TIME, Biomechanical Phenomena, Optomotor Response, Muscle, movement, Locomotion, Curve walking, Carausius morosus, Front Leg, direction, Context (language use), system, Aquatic Science, Carausius, Control theory, Orientation, distribution, Animals, Behaviour, turning, Leg movement, Stick Insect, Molecular Biology, Ecology, Evolution, Behavior and Systematics, Communication, Hexapod, SEQUENCES, Animal, business.industry, Time constant, movement sequence, Extremities, Antennae, biology.organism_classification, Kinetics, Insect Science, Optomotor response, insect, action, Animal Science and Zoology, business, control, Head

Abstract

SUMMARYThe control of locomotion requires the ability to adapt movement sequences to the behavioural context of the animal. In hexapod walking, adaptive behavioural transitions require orchestration of at least 18 leg joints and twice as many muscle groups. Although kinematics of locomotion has been studied in several arthropod species and in a range of different behaviours,almost nothing is known about the transition from one behavioural state to another. Implicitly, most studies on context-dependency assume that all parameters that undergo a change during a behavioural transition do so at the same rate. The present study tests this assumption by analysing the sequence of kinematic events during turning of the stick insect Carausius morosus, and by measuring how the time courses of the changing parameters differ between legs. Turning was triggered reliably at a known instant in time by means of the optomotor response to large-field visual motion. Thus, knowing the start point of the transition, the kinematic parameters that initiate turning could be ranked according to their time constants.Kinematics of stick insect walking vary considerably among trials and within trials. As a consequence, the behavioural states of straight walking and curve walking are described by the distributions of 13 kinematic parameters per leg and of orientation angles of head and antennae. The transitions between the behavioural states are then characterised by the fraction of the variance within states by which these distributions differ,and by the rate of change of the corresponding time courses. The antennal optomotor response leads that of the locomotor system. Visually elicited turning is shown to be initiated by stance direction changes of both front legs. The transition from straight to curve walking in stick insects follows different time courses for different legs, with time constants of kinematic parameters ranging from 1.7 s to more than 3 s. Therefore, turning is a behavioural transition that involves a characteristic orchestration of events rather than synchronous parallel actions with a single time constant.

Published

2005

45. Adaptive control for insect leg position: controller properties depend on substrate compliance

Author

Seung Park, Josef Schmitz, Holk Cruse, and Simone Kühn

Subjects

leg, Insecta, Adaptive control, Physiology, Computer science, Femur-Tibia Joint, Campaniform sensilla, Video Recording, Controller, Behavioral Neuroscience, Information, femoral chordotonal organ, POSITION, Behavior, Animal, biology, motor output, JOINT, Muscles, legs, Anatomy, Campaniform Sensillum, Denervation, leg position, Hindlimb, Sense organ, Electrophysiology, Chordotonal organ, Female, MOTOR, Compliance, Carausius morosus, Movement, system, Spring (mathematics), NO, AFFERENTS, Carausius, Chordotonal Organ, Control theory, Position (vector), Physical Stimulation, Reaction Time, Animals, Stick Insect, Ecology, Evolution, Behavior and Systematics, MOVEMENTS, Electromyography, ORGAN, Proprioception, biology.organism_classification, body regions, Compliance (physiology), afferent, insect, Joints, Animal Science and Zoology, control

Abstract

This paper concentrates on the system that controls the femur-tibia joint in the legs of the stick insect, Carausius morosus. Earlier investigations have shown that this joint is subject to a mixture of proportional and differential control whereby the differential part plays a prominent role. Experiments presented here suggest another interpretation: single legs of a stick insect were systematically perturbed using devices of different compliance and compensatory forces and movements monitored. When the compliance is high (soft spring), forces are generated that return the leg close to its original position. When the compliance is low (stiff spring), larger forces are generated but sustained changes in position occur that are proportional to the force that is applied. Selective ablation of leg sense organs showed that the leg did not maintain its position after elimination of afferents of the femoral chordotonal organ. Ablation of leg campaniform sensilla had no effect. These data support the idea that different control strategies are used, depending upon substrate compliance. In particular, what we and other authors have called a differential controller, is now considered as an integral controller that ldquointelligently gives uprdquo when the correlation between motor output and movement of the leg is low.

Published

2004

46. Post-embryonic photoreceptor development and dark/light adaptation in the stick insect Carausius morosus (Phasmida, Phasmatidae)

Author

Essi Keskinen and V. Benno Meyer-Rochow

Subjects

Carausius morosus, Phasmatidae, Arthropod eye, genetic structures, biology, media_common.quotation_subject, Insect, Compound eye, Anatomy, Nocturnal, biology.organism_classification, eye diseases, Insect Science, Instar, sense organs, Nymph, media_common

Abstract

The aims of this paper have been (a) to document postembryonic eye growth in the common laboratory stick insect Carausius morosus and (b) to examine whether the capacity of the eye to adapt to changing light intensities varied with age. We found that number of facets, corneal thickness, ommatidial diameter, widths of cone and retinal layers, and rhabdom volume increased linearly. Interommatidial angles, pigment grain sizes, and microvillar diameters, however, remained approximately the same. On the basis of the morphometric data we calculated that sensitivity in the adult stick insect eye was at least tenfold that of the eye of first instar nymphs and could show that adults would be able to perceive a similar amount of detail at considerably dimmer ambient light than the smaller individuals. In terms of resolving power this means that light- and dark-adapted first instar stick insects possess acceptance angles of 5.3° and 8°, respectively and that the corresponding figures for the adult eye are 4.7° and 7.3°. The bigger (and more light-sensitive) eye of fully grown C. morosus makes protection against radiation damage a more serious issue in the adult individual than the small first instar. The findings explain why smaller (=younger) stick insects are less nocturnal than mature, fully-grown individuals. It is, thus, not surprising to see that dark/light adaptational photomechanical changes affecting pigment position and rhabdom widths, are more pronounced in the eyes of the adults.

Published

2003

47. Stick Insect Antennae

Author

Dürr, Volker, Prescott, Tony, Ahissar, Ehud, and Izhikevich, Eugene

Subjects

0106 biological sciences, Carausius morosus, Organizational Behavior and Human Resource Management, Strategy and Management, media_common.quotation_subject, Pharmaceutical Science, Zoology, Insect, Biology, 01 natural sciences, Joint axis, 03 medical and health sciences, 0302 clinical medicine, Drug Discovery, Antenna (biology), media_common, Marketing, Pharmacology, Communication, business.industry, Sensory hair, biology.organism_classification, Chordotonal organ, 010602 entomology, Tactile sense, business, 030217 neurology & neurosurgery

Abstract

Insects have an elaborate sense of touch. Their most important source for tactile information is the pair of feelers on the head: the antennae (Figure 1; singular: antenna). The stick insect Carausius morosus is one of four major study organisms for the insect tactile sense. Open image in new window Figure 1 The stick insect Carausius morosus (de Sinety 1901) carries a pair of long and straight feelers, or antennae. They are the main sensory organs for touch and smell

Published

2015

48. Comparative whole-body kinematics of closely related insect species with different body morphology

Author

Volker Dürr, Holger Bekemeier, and Leslie Theunissen

Subjects

Carausius morosus, Arthropod Antennae, Aretaon, Insecta, Physiology, Range (biology), media_common.quotation_subject, Cuniculina, Zoology, Context (language use), Insect, Kinematics, Aquatic Science, Biology, Motor Activity, Carausius, motion capture, leg coordination, Thorax (insect anatomy), Animals, Molecular Biology, Ecology, Evolution, Behavior and Systematics, media_common, Body proportions, Behavior, Animal, Extremities, Anatomy, biology.organism_classification, stick insect, Biomechanical Phenomena, kinematics, Insect Science, Climbing, Animal Science and Zoology, insect, Medauroidea, Locomotion

Abstract

Legged locomotion through natural environments is very complex and variable. For example, leg kinematics may differ strongly among species, but even within the same species it is adaptive and context-dependent. Inter-species differences in locomotion are often difficult to interpret, because both morphological and ecological differences among species may be strong and, as a consequence, confound each other's effects. In order to understand better how body morphology affects legged locomotion, we compare unrestrained whole-body kinematics of three stick insect species with different body proportions, but similar feeding ecology: Carausius morosus, Aretaon asperrimus and Medauroidea extradentata (= Cuniculina impigra). In order to co-vary locomotory context, we introduced a gradually increasing demand for climbing by varying the height of stairs on the set-up. The species were similar in many aspects, for example in using distinct classes of steps, with minor differences concerning the spread of corrective short steps. Major differences were related to (1) antenna length, (2) segment lengths of thorax and head, and (3) the ratio of leg length over body length: (1) Whereas all species continuously moved their antennae, only Medauroidea executed high swing movements with its front legs to search for obstacles in the near-range environment. (2) Whereas all species adjusted their body inclination, the range in which body segments moved differed considerably, with longer thorax segments tending to be moved more. (3) Finally, leg posture, time courses of leg joint angles and intra-leg coordination differed most strongly in long-legged Medauroidea.

Published

2014

49. Identification, rearing, and distribution of stick insects of Madeira Island: an example of raising biodiversity awareness

Author

Ysabel M. Gonçalves, Dora Aguin Pombo, and António Miguel Franquinho Aguiar

Subjects

0106 biological sciences, Carausius morosus, Phasmatidae, Insecta, Bacillidae, Clonopsis gallica, Biodiversity, Captivity, 010603 evolutionary biology, 01 natural sciences, 03 medical and health sciences, Macaronesia, Animals, 14. Life underwater, 030304 developmental biology, Ovum, 0303 health sciences, geography, geography.geographical_feature_category, biology, Portugal, Ecology, General Medicine, biology.organism_classification, Phasmatodea, Insect Science, Archipelago, Papers, Female, Animal Distribution

Abstract

Two species of stick insects are currently known to be present in the Macaronesian archipelagos: Clonopsis gallica (Charpentier) (Phasmatodea: Bacillidae) on the Canary Islands and in the Azores and Carausius morosus (Sinéty) (Phasmatidae) in the Azores. Here, we provide the first reliable records of the presence and distribution of C. gallica and C. morosus on Madeira Island. Egg and adult stages are briefly described along with some notes on the life history of these species in captivity. Data on islandwide distribution are based on specimens donated by the public in response to an article published in a daily newspaper. This method of data collection raised great popular interest in stick insects. The role of newspapers as a means of communicating awareness in biodiversity issues is discussed.

Published

2014

50. Ecdysis behaviors and circadian rhythm of ecdysis in the stick insect, Carausius morosus

Author

Andrew Carriman, Christopher A. Moffatt, Alba A. Gutierrez, Megumi Fuse, and Tracy Wadsworth

Subjects

Carausius morosus, Nymph, medicine.medical_specialty, Insecta, Physiology, media_common.quotation_subject, Stimulation, Insect, Molting, Motor Activity, Article, Internal medicine, medicine, Animals, Circadian rhythm, Cyclic GMP, Preparatory phase, media_common, biology, biology.organism_classification, Cell biology, Circadian Rhythm, Eclosion hormone, Endocrinology, Insect Science, Ecdysis, Nerve Net, Moulting

Abstract

Successful ecdysis in insects depends on proper timing and sequential activation of an elaborate series of motor programs driven by a relatively conserved network of neuropeptides. The behaviors must be activated at the appropriate times to ensure successful loosening and shedding of the old cuticle, and can be influenced by environmental cues in the form of immediate sensory feedback and by circadian rhythms. We assessed the behaviors, components of the neural network and the circadian basis of ecdysis in the stick insect, Carausius morosus. C. morosus showed many of the characteristic pre-ecdysis and ecdysis behaviors previously described in crickets and locusts. Ecdysis was described in three phases, namely the (i) preparatory or pre-ecdysis phase, (ii) the ecdysial phase, and (iii) the post-ecdysis or exuvial phase. The frequencies of push-ups and sways during the preparatory phase were quantified as well as durations of all the phases. The regulation of ecdysis appeared to act via elevation of cGMP, as described in many other insects, although eclosion hormone-like immunoreactivity was not noted using a lepidopteran antiserum. Finally, C. morosus showed a circadian rhythm to the onset of ecdysis, with ecdysis occurring just prior to or at lights on. Ecdysis could be induced precociously with mechanical stimulation.

Published

2014