A glial K+/Cl− cotransporter modifies temperature‐evoked dynamics in Caenorhabditis elegans sensory neurons

K⁺/Cl^? cotransporters (KCCs) are known to be crucial in the control of neuronal electrochemical Cl^? gradient. However, the role of these proteins in glial cells remains largely unexplored despite a number of studies showing expression of KCC proteins in glial cells of many species. Here, we show that the Caenorhabditis elegans K⁺/Cl^? cotransporter KCC‐3 is expressed in glial‐like cells and regulates the thermosensory behavior through modifying temperature‐evoked activity of a thermosensory neuron. Mutations in the kcc‐3 gene were isolated from a genetic screen for mutants defective in thermotaxis. KCC‐3 is expressed and functions in the amphid sheath glia that ensheathes the AFD neuron, a major thermosensory neuron known to be required for thermotaxis. A genetic analysis indicated that the regulation of the thermosensory behavior by KCC‐3 is mediated through AFD, and we further show that KCC‐3 in the amphid sheath glia regulates the dynamics of the AFD activity. Our results show a novel mechanism by which the glial KCC‐3 protein non‐cell autonomously modifies the stimulus‐evoked activity of a sensory neuron and highlights the functional importance of glial KCC proteins in modulating the dynamics of a neural circuitry to control an animal behavior.     

Cell Migration and Cell-Cell Interaction in the Presence of Mechano-Chemo-Thermotaxis

Although there are several computational models that explain the trajectory that cells take during migration, till now little attention has been paid to the integration of the cell migration in a multi-signaling system. With that aim, a generalized model of cell migration and cell-cell interaction under multisignal environments is presented herein. In this work we investigate the spatio-temporal cell-cell interaction problem induced by mechano-chemo-thermotactic cues. It is assumed that formation of a new focal adhesion generates traction forces proportional to the stresses transmitted by the cell to the extracellular matrix. The cell velocity and polarization direction are calculated based on the equilibrium of the effective forces associated to cell motility. It is also assumed that, in addition to mechanotaxis signals, chemotactic and thermotactic cues control the direction of the resultant traction force. This model enables predicting the trajectory of migrating cells as well as the spatial and temporal distributions of the net traction force and cell velocity. Results indicate that the tendency of the cells is firstly to reach each other and then migrate towards an imaginary equilibrium plane located near the source of the signal. The position of this plane is sensitive to the gradient slope and the corresponding efficient factors. The cells come into contact and separate several times during migration. Adding other cues to the substrate (such as chemotaxis and/or thermotaxis) delays that primary contact. Moreover, in all states, the average local velocity and the net traction force of the cells decrease while the cells approach the cues source. Our findings are qualitatively consistent with experimental observations reported in the related literature.     

Behavioural responses of freshwater phytoplanktonic flagellates to a temperature gradient

Photoresponses of motile phytoplanktonic flagellates have been widely studied, whereas the behavioural responses of these organisms to temperature, and their potential ecological consequences, have rarely been considered. This study investigated the population responses and individual swimming trajectories of five phylogenetically contrasting species of freshwater flagellates exposed to a gradient of temperature in micro-scale preference chambers. Population responses demonstrated a species-dependent diversity in thermoresponsive behaviour. Across a gradient of 9.8 to 15.1°;C which simulated the typical range of temperature across a thermocline in a temperate monomictic lake, Ceratium furcoides, Chlamydomonas moewusii, Dinobryon sertularia and Plagioselmis nannoplanctica all preferred the highest temperatures. In contrast, Euglena gracilis preferred the lowest temperature. Analysis of the swimming behaviour of individual cells confirmed preferences and demonstrated that, in all species, a combination of tactic and kinetic reactions was responsible for these accumulations. For the first time, controlled positive and negative thermotaxes towards a temperature preference were identified. This thermotactic orientation, in conjunction with a reduction in directionality of response in the preference zone and with ortho- and klino-thermokinesis, enabled cells to maintain position at preferred temperatures. Specifically, in all species apart from P. nannoplanctica, significant ortho-kinetic increases in swimming speed permitted rapid movement of cells away from unfavourable conditions, while a reduction in speed and a klino-kinetic increase in rate of turning (in all five species) maintained position within favoured temperatures. This ability to detect, orientate and accumulate within a temperature gradient may be triggered by physiological processes and presents ecological advantages. Behavioural response to temperature may optimize growth, influence the spatial and temporal distribution of flagellates, particularly the diel position of cells during migration, and contribute to the delineation of niche separation.     

Integration of Plasticity Mechanisms within a Single Sensory Neuron of C. elegans Actuates a Memory

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Human scent guides mosquito thermotaxis and host selection under naturalistic conditions

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Behavioral Responses of Meloidogyne incognita to Small Temperature Changes

Small, rapid temperature changes were generated by incandescent radiation, and behavioral responses of Meloidogyne incognita juveniles were recorded with high time resolution by computer tracking. Temperature changes away from the preferred temperature resulted in decreases in the rate of movement and increases in the rate of change of direction, whether the changes were toward warmer or cooler temperatures. These behavioral changes lasted about 30 seconds. Temperature changes toward the preferred temperature caused the response rates to change in the opposite directions, and the behavioral changes persisted for several minutes. These results demonstrate that nematodes can respond to a purely temporal thermal stimulus in a manner consistent with efficient indirect orientation or klinokinesis. The rate of temperature change was estimated to be of the order of 10⁻⁴ C/second, suggesting that the nematodes detected a change of about 0.001 C.     

Extremely Sensitive Thermotaxis of the Nematode Meloidogyne incognita

Eggs of the root-knot nematode Meloidogyne incognita were acclimated to 23 C. Newly hatched second-stage juveniles migrated toward higher temperatures when placed in shallow thermal gradients averaging 23 C. The threshold gradient for this response was below 0.001 C/cm, with a best estimate of 4 x 10⁻⁴ C/cm. Calculations of physical limitations on thermotaxis indicate that this sensitivity is well within the limits of what is physically possible.