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Reaction times and force production during escape behavior of a calanoid copepod, Undinula vulgaris (1999)

Lenz, P. H. ; Hartline, D. K.

Springer

Marine biology 133 (1999), S. 249-258

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ISSN: 1432-1793

Source: Springer Online Journal Archives 1860-2000

Topics: Biology

Notes: Abstract Effective escape behavior contributes to the success of copepods in planktonic communities. The kinematics of escape were studied in tethered Undinulavulgaris (Calanoida) by analyzing the timing and magnitude of their power strokes to a precisely controlled, sudden mechanical perturbation in the surrounding water. Copepods responded with rapid swims to water velocities of 36 to 86 μm s−1. Reaction times were under 2.5 ms following stimulus onset. The time course of force exerted was complex, but reproducible from stimulus to stimulus. Multiple power strokes (“kicks”) were frequently observed in response to single stimuli. Time intervals of 5 ms were observed between the end of one escape kick and the beginning of the next. U. vulgaris developed maximum forces of 40 to over 100 dynes (dyn) during a rapid swim. The behavioral reaction times and intervals between multiple responses observed in this calanoid are among the shortest reported in aquatic invertebrates.

Type of Medium: Electronic Resource

URL: http://dx.doi.org/10.1007/s002270050464

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The need for speed. II. Myelin in calanoid copepods (2000)

Weatherby, T. M. ; Davis, A. D. ; Hartline, D. K. ; [et al.]

Springer

Journal of comparative physiology 186 (2000), S. 347-357

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ISSN: 1432-1351

Keywords: Key words Crustacean ; Sensorimotor ; Ultrastructure ; Multilamellar sheath ; Myelinated axons

Source: Springer Online Journal Archives 1860-2000

Topics: Biology , Medicine

Notes: Abstract Speed of nerve impulse conduction is greatly increased by myelin, a multi-layered membranous sheath surrounding axons. Myelinated axons are ubiquitous among the vertebrates, but relatively rare among invertebrates. Electron microscopy of calanoid copepods using rapid cryofixation techniques revealed the widespread presence of myelinated axons. Myelin sheaths of up to 60 layers were found around both sensory and motor axons of the first antenna and interneurons of the ventral nerve cord. Except at nodes, individual lamellae appeared to be continuous and circular, without seams, as opposed to the spiral structure of vertebrate and annelid myelin. The highly organized myelin was characterized by the complete exclusion of cytoplasm from the intracellular spaces of the cell generating it. In regions of compaction, extracytoplasmic space was also eliminated. Focal or fenestration nodes, rather than circumferential ones, were locally common. Myelin lamellae terminated in stepwise fashion at these nodes, appearing to fuse with the axolemma or adjacent myelin lamellae. As with vertebrate myelin, copepod sheaths are designed to minimize both resistive and capacitive current flow through the internodal membrane, greatly speeding nerve impulse conduction. Copepod myelin differs from that of any other group described, while sharing features of every group.

Type of Medium: Electronic Resource

URL: http://dx.doi.org/10.1007/s003590050435

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The need for speed. I. Fast reactions and myelinated axons in copepods (2000)

Lenz, P. H. ; Hartline, D. K. ; Davis, A. D.

Springer

Journal of comparative physiology 186 (2000), S. 337-345

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ISSN: 1432-1351

Keywords: Key words Crustacean ; Escape behavior ; Mechanosensitivity ; Phylogeny ; Myelination

Source: Springer Online Journal Archives 1860-2000

Topics: Biology , Medicine

Notes: Abstract A rapid and powerful escape response decreases predation risk in planktonic copepods. Calanoid copepods are sensitive to small and brief hydrodynamic disturbances: they respond with multiple nerve impulses to a vibrating sphere. Some species, such as Pleuromamma xiphias and Labidocera madurae, respond with very large spikes (1–4 mV), whereas maximum spike heights are an order of magnitude smaller in others, such as Undinula vulgaris and Neocalanus gracilis. A comparative study of the escape responses showed that all species reacted within 10 ms of the initiation of a hydrodynamic stimulus. However, U. vulgaris and N. gracilis had significantly shorter reaction times (minimum reaction times: 1.5 ms and 1.6 ms) than the other two, P. xiphias (6.6 ms) and L. madurae (3.1 ms). Examination of the first antenna and the central nervous system using transmission electron microscopy revealed extensive myelination of sensory and motor axons in the two species with the shorter reaction times. Axons of the other two species resembled typical crustacean unmyelinated fibers. A survey of 20 calanoids revealed that none of the species in two of the more ancient superfamilies possessed myelin, but myelination was present in the species from three more recently-evolved superfamilies.

Type of Medium: Electronic Resource

URL: http://dx.doi.org/10.1007/s003590050434

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The biogeography and ecology of myelin in marine copepods (2012)

Lenz, P. H.

Oxford University Press

In: Journal of Plankton Research

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Publication Date: 2012-05-29

Description: Calanoid copepods are ubiquitous in marine environments, where they are an abundant component of the plankton. Interestingly, this crustacean group is characterized by the co-existence of myelinate and amyelinate species. Myelin greatly enhances nervous system function, but requires the production and maintenance of large amounts of cell membranes. The role that myelin plays in the distribution and ecology of calanoids has not been investigated, yet should be significant given the costs and benefits of the adaptation. Surveying the available literature, habitats and ecological zones were identified, and calanoid species were categorized as either myelinate or amyelinate based on phylogeny. The diversity and abundance of the two types of calanoids were determined and compared to an expected ratio of 1:1. Myelinate taxa were predominant in oceanic epipelagic regions at all latitudes, while a majority of vertically migrating mesopelagic calanoids were amyelinate. Temperate and tropical estuaries were typically less diverse, with communities dominated by amyelinate calanoids. However, in many sub-tropical estuaries, myelinate species comprised 〉80% of the calanoid population. An enhanced escape response and savings in energy may promote the success of myelinate calanoids in habitats characterized by high predation risk and low standing stocks of phytoplankton. Environments with low food quality may favor amyelinate species, given the cost of producing large quantities of lipid-rich membranes.

Print ISSN: 0142-7873

Electronic ISSN: 1464-3774

Topics: Biology

Published by Oxford University Press

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Copepod diversity in a subtropical bay based on a fragment of the mitochondrial COI gene (2013)

Jungbluth, M. J., Lenz, P. H.

Oxford University Press

In: Journal of Plankton Research

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Publication Date: 2013-05-03

Description: Copepod communities in lagoons and embayments on subtropical islands in the Pacific Ocean are geographically isolated from other populations along continents and other islands. Nevertheless, taxonomic identifications suggest that many of these species are cosmopolitan. The genetic diversity of planktonic copepod species in a subtropical embayment, Kaneohe Bay, Hawaii, was investigated by pairing morphological identification of the species with sequencing a 710 bp fragment of the mitochondrial cytochrome oxidase c subunit I (mtCOI) gene. DNA sequences were obtained for six calanoid and three cyclopoid copepod species. The sequences of two oceanic species found in the bay, Undinula vulgaris and Paracalanus parvus , were ≤3.0% divergent from conspecifics in the coastal western Pacific Ocean. In contrast, sequences from the more estuarine, Parvocalanus crassirostris and Bestiolina similis specimens were ≥16.0% divergent from conspecifics of the western Pacific Ocean. The Labidocera sp. and Acartia sp. were ≥16.0% divergent from all congeners, while three Oithona species differed by ≥26.5% from congeners. These results suggest significant genetic isolation of the more estuarine species, although more sequence data for Hawaii and elsewhere will be needed to understand the population and genetic structure of coastal island copepod populations.

Print ISSN: 0142-7873

Electronic ISSN: 1464-3774

Topics: Biology

Published by Oxford University Press

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Swimming and escape behavior in two species of calanoid copepods from nauplius to adult (2012)

Bradley, C. J., Strickler, J. R., Buskey, E. J., Lenz, P. H.

Oxford University Press

In: Journal of Plankton Research

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Publication Date: 2012-12-28

Description: Subject to high predation risk, all developmental stages of copepods depend on evasive behaviors for survival in pelagic environments. Swim and escape behaviors were investigated in copepods from early nauplius to adult using 3D high-speed micro-cinematography. Parvocalanus crassirostris and Eurytemora affinis are two common estuarine species with broad geographic ranges. The early naupliar stages were mostly immobile, whereas the copepodids and adults spent most of the time actively swimming. Escapes and/or behavioral freezes were elicited by a predator mimic, an abrupt hydromechanical stimulus created by the rapid vertical movement of a 3-mm sphere, and video-recorded at 500 frames-per-second. All developmental stages of planktonic copepods responded with evasive behaviors and responses decreased with distance from the sphere. Maximum response distances were greater and response latencies were shorter in copepodids than in nauplii. Maximum escape speeds increased with copepod size, while the duration of the escape response decreased with the developmental stage. Maximum escape speeds scaled to body length as a power function from early nauplius to adult. Species-specific patterns in escape trajectories were apparent at the first nauplius (N1). These results start to differentiate between performance differences that result from size and design constraints, and those that are due to species-specific behavioral patterns.

Print ISSN: 0142-7873

Electronic ISSN: 1464-3774

Topics: Biology

Published by Oxford University Press

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