Your search keyword '"lateral line"' showing total 1,977 results

1. Sublethal effects of methylmercury on lateral line sensory and ion-regulatory functions in zebrafish embryos

Author

Hung, Giun-Yi, Pan, Yu-Chin, Horng, Jiun-Lin, and Lin, Li-Yih

Published

2023

2. Head Horn Enhances Hydrodynamic Perception in Eyeless Cavefish.

Author

Ma, Zhiqiang, Gong, Zheng, Jiang, Yonggang, Wu, Peng, You, Changxin, Dong, Zihao, Cao, Hongchao, Yang, Zhen, Zhao, Yahui, Chen, Huawei, and Zhang, Deyuan

Subjects

*PARTICLE image velocimetry, *COMPUTATIONAL fluid dynamics, *REMOTE submersibles, *SUBMERSIBLES, *MACHINE learning

Abstract

Fish can use hydrodynamic stimuli, decoded by lateral line systems, to explore the surroundings. Eyeless species of the genus Sinocyclocheilus have evolved conspicuous horns on their heads, whereas the specific function of which is still unknown. Meanwhile, the eyeless cavefish exhibits more sophisticated lateral line systems and enhanced behavioral capabilities (for instance rheotaxis), compared with their eyed counterparts. Here, the influence of head horn on the hydrodynamic perception capability is investigated through computational fluid dynamics, particle image velocimetry, and a bioinspired cavefish model integrated with an artificial lateral line system. The results show strong evidence that the head horn structure can enhance the hydrodynamic perception, from aspects of multiple hydrodynamic sensory indicators. It is uncovered as that the head horn renders eyeless cavefish with stronger hydrodynamic stimuli, induced by double‐stagnation points near the head, which are perceived by the strengthened lateral line systems. Furthermore, the eyeless cavefish model has ≈17% higher obstacle recognition accuracy and lower cost (time and sensor number) than eyed cavefish model is conceptually demonstrated, by incorporating with machine learning. This study provides novel insights into form‐function relationships in eyeless cavefish, in addition paves the way for optimizing sensor arrangement in fish robots and underwater vehicles. [ABSTRACT FROM AUTHOR]

Published

2024

3. Environmental and molecular control of tissue-specific ionocyte differentiation in zebrafish.

Author

Peloggia, Julia, Lush, Mark E., Ya-Yin Tsai, Wood, Christopher, and Piotrowski, Tatjana

Subjects

*HAIR cells, *CELL physiology, *PHYSIOLOGICAL adaptation, *PHENOTYPIC plasticity, *AQUATIC animals

Abstract

Organisms cope with environmental fluctuations and maintain fitness in part via reversible phenotypic changes (acclimation). Aquatic animals are subject to dramatic seasonal fluctuations in water salinity, which affect osmolarity of their cells and consequently cellular function. Mechanosensory lateral line hair cells detect water motion for swimming behavior and are especially susceptible to salinity changes due to their direct contact with the environment. To maintain hair cell function when salinity decreases, neuromast (Nm)-associated ionocytes differentiate and invade lateral line neuromasts. The signals that trigger the adaptive differentiation of Nm ionocytes are unknown. We demonstrate that new Nm ionocytes are rapidly specified and selectively triggered to proliferate by low Ca2+ and Na+/Cl- levels. We further show that Nm ionocyte recruitment and induction is affected by hair cell activity. Once specified, Nm ionocyte differentiation and survival are associated with sequential activation of different Notch pathway components, a process different from other tissue-specific ionocytes. In summary, we show how environmental changes activate a signaling cascade that leads to physiological adaptation. This may prove essential for survival not only in seasonal changing environments but also in changing climates. [ABSTRACT FROM AUTHOR]

Published

2024

4. Tadpoles rely on mechanosensory stimuli for communication when visual capabilities are poor.

Author

Butler, Julie M., McKinney, Jordan E., Ludington, Sarah C., Mabogunje, Moremi, Baker, Penelope, Singh, Devraj, Edwards, Scott V., and O'Connell, Lauren A.

Subjects

*TADPOLES, *DENDROBATIDAE, *PINEAL gland, *VISION, *SENSE organs, *FROGS, *PHOTOTAXIS

Abstract

The ways in which animals sense the world changes throughout development. For example, young of many species have limited visual capabilities, but still make social decisions, likely based on information gathered through other sensory modalities. Poison frog tadpoles display complex social behaviors that have been suggested to rely on vision despite a century of research indicating tadpoles have poorly-developed visual systems relative to adults. Alternatively, other sensory modalities, such as the lateral line system, are functional at hatching in frogs and may guide social decisions while other sensory systems mature. Here, we examined development of the mechanosensory lateral line and visual systems in tadpoles of the mimic poison frog (Ranitomeya imitator) that use vibrational begging displays to stimulate egg feeding from their mothers. We found that tadpoles hatch with a fully developed lateral line system. While begging behavior increases with development, ablating the lateral line system inhibited begging in pre-metamorphic tadpoles, but not in metamorphic tadpoles. We also found that the increase in begging and decrease in reliance on the lateral line co-occurs with increased retinal neural activity and gene expression associated with eye development. Using the neural tracer neurobiotin, we found that axonal innervations from the eye to the brain proliferate during metamorphosis, with few retinotectal connections in recently-hatched tadpoles. We then tested visual function in a phototaxis assay and found tadpoles prefer darker environments. The strength of this preference increased with developmental stage, but eyes were not required for this behavior, possibly indicating a role for the pineal gland. Together, these data suggest that tadpoles rely on different sensory modalities for social interactions across development and that the development of sensory systems in socially complex poison frog tadpoles is similar to that of other frog species. [Display omitted] • Ranitomeya imitator tadpoles hatch with fully developed lateral line systems. • Use of mechanosensory stimuli for begging is dependent on developmental stage. • The visual system of R. imitator tadpoles continues to develop through metamorphosis. • When visual capabilities are poor, tadpoles rely more on mechanosensory inputs. [ABSTRACT FROM AUTHOR]

Published

2024

5. Pharmacological reprogramming of zebrafish lateral line supporting cells to a migratory progenitor state.

Author

Brooks, Paige M., Lewis, Parker, Million-Perez, Sara, Yandulskaya, Anastasia S., Khalil, Mahmoud, Janes, Meredith, Porco, Joseph, Walker, Eleanor, and Meyers, Jason R.

Subjects

*SENSE organs, *HAIR cells, *PROGENITOR cells, *CELL cycle, *BRACHYDANIO, *CELL lines

Abstract

In the zebrafish lateral line, non-sensory supporting cells readily re-enter the cell cycle to generate new hair cells and supporting cells during homeostatic maintenance and following damage to hair cells. This contrasts with supporting cells from mammalian vestibular and auditory sensory epithelia which rarely re-enter the cell cycle, and hence loss of hair cells results in permanent sensory deficit. Lateral line supporting cells are derived from multipotent progenitor cells that migrate down the trunk midline as a primordium and are deposited to differentiate into a neuromast. We have found that we can revert zebrafish support cells back to a migratory progenitor state by pharmacologically altering the signaling environment to mimic that of the migratory primordium, with active Wnt signaling and repressed FGF signaling. The reverted supporting cells migrate anteriorly and posteriorly along the horizontal myoseptum and will re-epithelialize to form an increased number of neuromasts along the midline when the pharmacological agents are removed. These data demonstrate that supporting cells can be readily reprogrammed to a migratory multipotent progenitor state that can form new sensory neuromasts, which has important implications for our understanding of how the lateral line system matures and expands in fish and also suggest avenues for returning mammalian supporting cells back to a proliferative state. [Display omitted] • Zebrafish neuromasts can be pharmacologically reprogrammed to a migratory state. • Reprogrammed progenitors migrate along midline. • Migratory progenitors reaggregate into sensory organs following washout. • Reconstituted sensory organs form functional sensory cells and are innervated. [ABSTRACT FROM AUTHOR]

Published

2024

6. Head Horn Enhances Hydrodynamic Perception in Eyeless Cavefish

Author

Zhiqiang Ma, Zheng Gong, Yonggang Jiang, Peng Wu, Changxin You, Zihao Dong, Hongchao Cao, Zhen Yang, Yahui Zhao, Huawei Chen, and Deyuan Zhang

Subjects

Chinese cavefish, head horn, hydrodynamic perception, lateral line, sensor arrangement, Science

Abstract

Abstract Fish can use hydrodynamic stimuli, decoded by lateral line systems, to explore the surroundings. Eyeless species of the genus Sinocyclocheilus have evolved conspicuous horns on their heads, whereas the specific function of which is still unknown. Meanwhile, the eyeless cavefish exhibits more sophisticated lateral line systems and enhanced behavioral capabilities (for instance rheotaxis), compared with their eyed counterparts. Here, the influence of head horn on the hydrodynamic perception capability is investigated through computational fluid dynamics, particle image velocimetry, and a bioinspired cavefish model integrated with an artificial lateral line system. The results show strong evidence that the head horn structure can enhance the hydrodynamic perception, from aspects of multiple hydrodynamic sensory indicators. It is uncovered as that the head horn renders eyeless cavefish with stronger hydrodynamic stimuli, induced by double‐stagnation points near the head, which are perceived by the strengthened lateral line systems. Furthermore, the eyeless cavefish model has ≈17% higher obstacle recognition accuracy and lower cost (time and sensor number) than eyed cavefish model is conceptually demonstrated, by incorporating with machine learning. This study provides novel insights into form‐function relationships in eyeless cavefish, in addition paves the way for optimizing sensor arrangement in fish robots and underwater vehicles.

Published

2024

7. Contributions of mirror-image hair cell orientation to mouse otolith organ and zebrafish neuromast function

Author

Kazuya Ono, Amandine Jarysta, Natasha C Hughes, Alma Jukic, Hui Ho Vanessa Chang, Michael R Deans, Ruth Anne Eatock, Kathleen E Cullen, Katie S Kindt, and Basile Tarchini

Subjects

inner ear, lateral line, hair cells, cell polarity, mechano-electrical transduction, afferent innervation, Medicine, Science, Biology (General), QH301-705.5

Abstract

Otolith organs in the inner ear and neuromasts in the fish lateral-line harbor two populations of hair cells oriented to detect stimuli in opposing directions. The underlying mechanism is highly conserved: the transcription factor EMX2 is regionally expressed in just one hair cell population and acts through the receptor GPR156 to reverse cell orientation relative to the other population. In mouse and zebrafish, loss of Emx2 results in sensory organs that harbor only one hair cell orientation and are not innervated properly. In zebrafish, Emx2 also confers hair cells with reduced mechanosensory properties. Here, we leverage mouse and zebrafish models lacking GPR156 to determine how detecting stimuli of opposing directions serves vestibular function, and whether GPR156 has other roles besides orienting hair cells. We find that otolith organs in Gpr156 mouse mutants have normal zonal organization and normal type I-II hair cell distribution and mechano-electrical transduction properties. In contrast, gpr156 zebrafish mutants lack the smaller mechanically evoked signals that characterize Emx2-positive hair cells. Loss of GPR156 does not affect orientation-selectivity of afferents in mouse utricle or zebrafish neuromasts. Consistent with normal otolith organ anatomy and afferent selectivity, Gpr156 mutant mice do not show overt vestibular dysfunction. Instead, performance on two tests that engage otolith organs is significantly altered – swimming and off-vertical-axis rotation. We conclude that GPR156 relays hair cell orientation and transduction information downstream of EMX2, but not selectivity for direction-specific afferents. These results clarify how molecular mechanisms that confer bi-directionality to sensory organs contribute to function, from single hair cell physiology to animal behavior.

Published

2024

8. Effect of Aquaculture Sound on Fish Development, Physiology, and Behavior

Author

Sholes, Rikeem K., Coffin, Allison B., Popper, Arthur N., Section editor, Popper, Arthur N., editor, Sisneros, Joseph A., editor, Hawkins, Anthony D., editor, and Thomsen, Frank, editor

Published

2024

9. Representation of bulk water flow in the goldfish (Carassius auratus) midbrain

Author

Van Susteren, Grace E. and Mogdans, Joachim

Published

2024

10. Sensing in the dark: Constructive evolution of the lateral line system in blind populations of Astyanax mexicanus.

Author

Rodríguez‐Morales, Roberto

Subjects

*ASTYANAX, *BIOLOGICAL evolution, *NEUROPLASTICITY, *CAVE animals, *VISION disorders

Abstract

Cave‐adapted animals evolve a suite of regressive and constructive traits that allow survival in the dark. Most studies aiming at understanding cave animal evolution have focused on the genetics and environmental underpinnings of regressive traits, with special emphasis on vision loss. Possibly as a result of vision loss, other non‐visual sensory systems have expanded and compensated in cave species. For instance, in many cave‐dwelling fish species, including the blind cavefish of the Mexican tetra, Astyanax mexicanus, a major non‐visual mechanosensory system called the lateral line, compensated for vision loss through morphological expansions. While substantial work has shed light on constructive adaptation of this system, there are still many open questions regarding its developmental origin, synaptic plasticity, and overall adaptive value. This review provides a snapshot of the current state of knowledge of lateral line adaption in A. mexicanus, with an emphasis on anatomy, synaptic plasticity, and behavior. Multiple open avenues for future research in this system, and how these can be leveraged as tools for both evolutionary biology and evolutionary medicine, are discussed. [ABSTRACT FROM AUTHOR]

Published

2024

11. A Highly Sensitive Deep-Sea Hydrodynamic Pressure Sensor Inspired by Fish Lateral Line.

Author

Hu, Xiaohe, Ma, Zhiqiang, Gong, Zheng, Zhao, Fuqun, Guo, Sheng, Zhang, Deyuan, and Jiang, Yonggang

Subjects

*PRESSURE sensors, *FISHING lines, *REMOTE submersibles, *FISH morphology, *UNDERWATER exploration, *YOUNG'S modulus, *OCEAN mining

Abstract

Hydrodynamic pressure sensors offer an auxiliary approach for ocean exploration by unmanned underwater vehicles (UUVs). However, existing hydrodynamic pressure sensors often lack the ability to monitor subtle hydrodynamic stimuli in deep-sea environments. In this study, we present the development of a deep-sea hydrodynamic pressure sensor (DSHPS) capable of operating over a wide range of water depths while maintaining exceptional hydrodynamic sensing performance. The DSHPS device was systematically optimized by considering factors such as piezoelectric polyvinylidene fluoride–trifluoroethylene/barium titanate [P(VDF-TrFE)/BTO] nanofibers, electrode configurations, sensing element dimensions, integrated circuits, and packaging strategies. The optimized DSHPS exhibited a remarkable pressure gradient response, achieving a minimum pressure difference detection capability of approximately 0.11 Pa. Additionally, the DSHPS demonstrated outstanding performance in the spatial positioning of dipole sources, which was elucidated through theoretical charge modeling and fluid–structure interaction (FSI) simulations. Furthermore, the integration of a high Young's modulus packaging strategy inspired by fish skull morphology ensured reliable sensing capabilities of the DSHPS even at depths of 1000 m in the deep sea. The DSHPS also exhibited consistent and reproducible positioning performance for subtle hydrodynamic stimulus sources across this wide range of water depths. We envision that the development of the DSHPS not only enhances our understanding of the evolutionary aspects of deep-sea canal lateral lines but also paves the way for the advancement of artificial hydrodynamic pressure sensors. [ABSTRACT FROM AUTHOR]

Published

2024

12. The incomparable fascination of comparative physiology: 40 years with animals in the field and laboratory.

Author

Bleckmann, Horst

Subjects

*COMPARATIVE physiology, *LABORATORY animals, *POISONOUS snakes, *ELECTRIC fishes, *BIRDS of prey

Abstract

This paper is not meant to be a review article. Instead, it gives an overview of the major research projects that the author, together with his students, colleagues and collaborators, has worked on. Although the main focus of the author's work has always been the fish lateral line, this paper is mainly about all the other research projects he did or that were done in his laboratory. These include studies on fishing spiders, weakly electric fish, seals, water rats, bottom dwelling sharks, freshwater rays, venomous snakes, birds of prey, fire loving beetles and backswimmers. The reasons for this diversity of research projects? Simple. The authors's lifelong enthusiasm for animals, and nature's ingenuity in inventing new biological solutions. Indeed, this most certainly was a principal reason why Karl von Frisch and Alfred Kühn founded the Zeitschrift für vergleichende Physiologie (now Journal of Comparative Physiology A) 100 years ago. [ABSTRACT FROM AUTHOR]

Published

2024

13. Macrophages enhance regeneration of lateral line neuromast derived from interneuromast cells through TGF‐β in zebrafish.

Author

Hsu, Wei‐Lin, Lin, Yu‐Chi, Lin, Meng‐Ju, Wang, Yi‐Wen, and Lee, Shyh‐Jye

Subjects

*TUMOR necrosis factors, *NERVOUS system regeneration, *MACROPHAGES, *SCHWANN cells, *BRACHYDANIO

Abstract

Macrophages play a pivotal role in the response to injury, contributing significantly to the repair and regrowth of damaged tissues. The external lateral line system in aquatic organisms offers a practical model for studying regeneration, featuring interneuromast cells connecting sensory neuromasts. Under normal conditions, these cells remain dormant, but their transformation into neuromasts occurs when overcoming inhibitory signals from Schwann cells and posterior lateral line nerves. The mechanism enabling interneuromast cells to evade inhibition by Schwann cells remains unclear. Previous observations suggest that macrophages physically interact with neuromasts, nerves, and Schwann cells during regeneration. This interaction leads to the regeneration of neuromasts in a subset of zebrafish with ablated neuromasts. To explore whether macrophages achieve this effect through secreted cytokines, we conducted experiments involving tail amputation in zebrafish larvae and tested the impact of cytokine inhibitors on neuromast regeneration. Most injured larvae remarkably regenerated a neuromast within 4 days post‐amputation. Intriguingly, removal of macrophages and inhibition of the anti‐inflammatory cytokine transforming growth factor‐beta (TGF‐β) significantly delayed neuromast regeneration. Conversely, inhibition of the pro‐inflammatory cytokines interleukin‐6 (IL‐6) and tumor necrosis factor‐alpha (TNF‐α) had minor effects on the regeneration process. This study provides insights into how macrophages activate interneuromast cells, elucidating the pathways underlying neuromast regeneration. [ABSTRACT FROM AUTHOR]

Published

2024

14. Identifying novel molecular mechanisms underlying lateral line organ development in sterlet

Author

Campbell, Alexander and Baker, Clare

Subjects

Ampullary Organ, Bmp, CRISPR/Cas9, Development, Evolution, Lateral Line, Neuromast, Neuroscience, Notch, Signalling Pathway, Wnt

Abstract

In all fishes and aquatic-stage amphibians, lines of mechanosensory lateral line organs ('neuromasts' containing hair cells), distributed over the head and trunk, detect local water movement. Many species also have electrosensory lateral line organs that detect weak electric fields, such as those surrounding other animals. In electroreceptive non-teleost jawed fishes and amphibians, electroreceptor cells reside within 'ampullary organs' (AOs) distributed in fields flanking some or all neuromast lines on the head. Both AOs and neuromasts develop from lateral line placodes that elongate over the head to form sensory ridges. Their shared origin makes the system a useful model to investigate cell fate decisions during development. Electroreception was lost in the lineages leading to teleost ray-finned fishes and frogs, so the electrosensory (AO) vs. mechanosensory (neuromast) fate-choice cannot be studied in the standard anamniote models, zebrafish and Xenopus. To identify genes involved in AO vs. neuromast development, the lab previously used differential RNAseq in late-larval stages of a chondrostean ray-finned fish, the Mississippi paddlefish (Polyodon spathula), to generate a dataset of around 500 genes putatively enriched in lateral line organs. Candidate gene expression analysis suggested electroreceptors and hair cells are closely related cell types. To gain insight into signalling pathways potentially involved in AO and/or neuromast development, I cloned cDNA fragments of 50 signalling pathway-related genes from the paddlefish gene-set and 26 other signalling pathway-related genes selected via a candidate approach, in an experimentally tractable chondrostean, the sterlet (Acipenser ruthenus, a sturgeon). Overall, I cloned cDNA fragments of 33 genes encoding receptors, 27 encoding ligands and 16 encoding, for example, secreted inhibitors, scaffold proteins and co-receptors. In situ hybridisation identified 32 genes expressed in the developing lateral line system. Of these, five (Dner, Fgf10, Ngfr, Cbln18 and Kit) were expressed within developing neuromasts but not AOs, and four (Dll4, Axin2, Omg and Gpr52) within developing AOs but not neuromasts. (Other genes with specific expression patterns were expressed in non-lateral line structures such as gill filaments and taste buds.) I explored the Bmp signalling pathway in the most depth. I identified lateral line organ expression of genes encoding two ligands (Bmp5, Bmp4), an activin type II receptor (Acvr2a) that can complex with type I Bmp receptors, and two secreted dual-Bmp/Wnt inhibitors (Sostdc1, Apcdd1). CRISPR/Cas9-mediated mutagenesis targeting Bmp5 in F0-injected sterlet embryos led to fewer AOs forming, primarily in the posterior preopercular fields. Conversely, DMH1-mediated inhibition of Bmp signalling for 20 hours when AOs normally start to develop, led to precocious AO formation generally, plus ectopic AOs in the three dorsal-most fields. This suggested that Bmp signalling inhibits, while Bmp5 promotes, AO development.

Published

2022

15. A biologically-inspired artificial lateral line : observations of collective behaviour in fish lead to the development of a novel design of simple and low-cost artificial lateral line sensor

Author

Scott, Elliott J., Hauert, Sabine, Ioannou, Christos, and Genner, Martin

Subjects

bio-inspired, lateral line, collective behaviour, flow, sensors, fish

Abstract

Fish use their lateral line to extract information from the hydrodynamic world around them. The lateral line, comprised of velocity-sensitive superficial neuromasts and acceleration-sensitive canal neuromasts, plays a role in mediating many behaviours, from feeding to shoaling. However, even now, the precise functional mechanisms at work remain unclear. Given the complex, and often cluttered, underwater environment, if we were able to better understand the mechanisms behind this, and emulate such a sense, it could aid underwater vehicles as they traverse the deep. In this study, 96 cichlid hybrids were bred to generate a spectrum of lateral line characteristics. Cichlids have a relatively recent common ancestor, with species sharing many common traits. The well-developed 'widened' lateral line of the Aulonocara stuartgranti was chosen as one extreme of this spectrum and the underdeveloped 'narrow' lateral line of the Otopharynx lithobates as the other; the Aulonocara has been observed hunting benthic prey using these canals in dimly lit conditions, while the Otopharynx is a species that feeds visually in brightly lit environments. Individuals were placed into a shoal of companion fish and shoaling tendencies were observed in both laminar and turbulent flow. Neuromasts were stained in all individuals and their location and number recorded. Using Generalised Linear Mixed Models (GLMMs), we found individuals with greater numbers of head canal neuromasts or with larger head canal pores tended to swim closer to neighbours while those with greater numbers of head superficial neuromasts swam in looser shoals. A novel design of bio-inspired sensor that is able to detect a fish-like vortex wake was then created and optimised, both in simulation and experiment. This minimalist sensor is low-cost, low-power, and easy to manufacture, with a number of potential applications including flow monitoring in pipes, supplementary navigation systems in Autonomous Underwater Vehicles (AUVs) or simple flow sensing robots.

Published

2022

16. Sensing in the dark: Constructive evolution of the lateral line system in blind populations of Astyanax mexicanus

Author

Roberto Rodríguez‐Morales

Subjects

adaptation, cavefish, evolution, hair cells, lateral line, sensory systems, Ecology, QH540-549.5

Abstract

Abstract Cave‐adapted animals evolve a suite of regressive and constructive traits that allow survival in the dark. Most studies aiming at understanding cave animal evolution have focused on the genetics and environmental underpinnings of regressive traits, with special emphasis on vision loss. Possibly as a result of vision loss, other non‐visual sensory systems have expanded and compensated in cave species. For instance, in many cave‐dwelling fish species, including the blind cavefish of the Mexican tetra, Astyanax mexicanus, a major non‐visual mechanosensory system called the lateral line, compensated for vision loss through morphological expansions. While substantial work has shed light on constructive adaptation of this system, there are still many open questions regarding its developmental origin, synaptic plasticity, and overall adaptive value. This review provides a snapshot of the current state of knowledge of lateral line adaption in A. mexicanus, with an emphasis on anatomy, synaptic plasticity, and behavior. Multiple open avenues for future research in this system, and how these can be leveraged as tools for both evolutionary biology and evolutionary medicine, are discussed.

Published

2024

17. Spherical harmonics analysis reveals cell shape-fate relationships in zebrafish lateral line neuromasts.

Author

Hewitt, Madeleine N., Cruz, Iván A., and Raible, David W.

Subjects

*SPHERICAL harmonics, *CELL analysis, *CELL morphology, *HAIR cells, *BRACHYDANIO, *HARMONIC analysis (Mathematics)

Abstract

Cell shape is a powerful readout of cell state, fate and function. We describe a custom workflow to perform semi-automated, 3D cell and nucleus segmentation, and spherical harmonics and principal components analysis to distill cell and nuclear shape variation into discrete biologically meaningful parameters. We apply these methods to analyze shape in the neuromast cells of the zebrafish lateral line system, finding that shapes vary with cell location and identity. The distinction between hair cells and support cells accounted for much of the variation, which allowed us to train classifiers to predict cell identity from shape features. Using transgenic markers for support cell subpopulations, we found that subtypes had different shapes from each other. To investigate how loss of a neuromast cell type altered cell shape distributions, we examined atoh1a mutants that lack hair cells. We found that mutant neuromasts lacked the cell shape phenotype associated with hair cells, but did not exhibit a mutant-specific cell shape. Our results demonstrate the utility of using 3D cell shape features to characterize, compare and classify cells in a living developing organism. [ABSTRACT FROM AUTHOR]

Published

2024

18. Central Nervous System, Hormonal Regulation and Sensory Control of Schooling Behavior of Fish.

Author

Kasumyan, A. O. and Pavlov, D. S.

Abstract

Data on the role of brain regions (forebrain, midbrain and other structures) in the control of schooling behavior of fish has been systematized. Data have been presented on the influence of the presence in the food of certain substances (docosahexaenoic acid) accumulating in the brain on the rate of formation of schooling behavior in fish ontogeny. The neurohormonal system may be involved in the regulation of schooling behavior. The individual behavior of fish in a school depends on the lateralization of brain functions. Attention has been drawn to the extremely poor knowledge of the processes of central and hormonal regulation of schooling behavior of fish. Vision is the leading, and most often the only sensory system that enables fish to demonstare schooling behavior. Monomodality distinguishes schooling behavior from other complex forms of fish behavior. Visual deprivation or deterioration of the conditions for visual reception makes schooling reactions of fish difficult or completely impossible. Existing assumptions about the possible participation in schooling behavior of other sensory systems of fish—lateral line, hearing, olfaction, electroreception—have been critically analyzed. Strict evidence of the real involvement of these sensory systems in the mediation of schooling contacts in fish is still lacking. [ABSTRACT FROM AUTHOR]

Published

2023

19. Evolution of left–right asymmetry in the sensory system and foraging behavior during adaptation to food-sparse cave environments

Author

Vânia Filipa Lima Fernandes, Yannik Glaser, Motoko Iwashita, and Masato Yoshizawa

Subjects

Laterality, VAB, Foraging behavior, Lateral line, Evolution, Cavefish, Biology (General), QH301-705.5

Abstract

Abstract Background Laterality in relation to behavior and sensory systems is found commonly in a variety of animal taxa. Despite the advantages conferred by laterality (e.g., the startle response and complex motor activities), little is known about the evolution of laterality and its plasticity in response to ecological demands. In the present study, a comparative study model, the Mexican tetra (Astyanax mexicanus), composed of two morphotypes, i.e., riverine surface fish and cave-dwelling cavefish, was used to address the relationship between environment and laterality. Results The use of a machine learning-based fish posture detection system and sensory ablation revealed that the left cranial lateral line significantly supports one type of foraging behavior, i.e., vibration attraction behavior, in one cave population. Additionally, left–right asymmetric approaches toward a vibrating rod became symmetrical after fasting in one cave population but not in the other populations. Conclusion Based on these findings, we propose a model explaining how the observed sensory laterality and behavioral shift could help adaptation in terms of the tradeoff in energy gain and loss during foraging according to differences in food availability among caves.

Published

2022

20. Regionalized Protein Localization Domains in the Zebrafish Hair Cell Kinocilium.

Author

Erickson, Timothy, Biggers III, William Paul, Williams, Kevin, Butland, Shyanne E., and Venuto, Alexandra

Subjects

HAIR cells, BRACHYDANIO, PROTEIN domains, SENSE organs, SENSORINEURAL hearing loss, CELL receptors

Abstract

Sensory hair cells are the receptors for auditory, vestibular, and lateral line sensory organs in vertebrates. These cells are distinguished by "hair"-like projections from their apical surface collectively known as the hair bundle. Along with the staircase arrangement of the actin-filled stereocilia, the hair bundle features a single, non-motile, true cilium called the kinocilium. The kinocilium plays an important role in bundle development and the mechanics of sensory detection. To understand more about kinocilial development and structure, we performed a transcriptomic analysis of zebrafish hair cells to identify cilia-associated genes that have yet to be characterized in hair cells. In this study, we focused on three such genes—ankef1a, odf3l2a, and saxo2—because human or mouse orthologs are either associated with sensorineural hearing loss or are located near uncharacterized deafness loci. We made transgenic fish that express fluorescently tagged versions of their proteins, demonstrating their localization to the kinocilia of zebrafish hair cells. Furthermore, we found that Ankef1a, Odf3l2a, and Saxo2 exhibit distinct localization patterns along the length of the kinocilium and within the cell body. Lastly, we have reported a novel overexpression phenotype of Saxo2. Overall, these results suggest that the hair cell kinocilium in zebrafish is regionalized along its proximal-distal axis and set the groundwork to understand more about the roles of these kinocilial proteins in hair cells. [ABSTRACT FROM AUTHOR]

Published

2023

21. 小体鲟Ar-tnfsf10和Ar-tnfrsf10基因的克隆、表达和功能初步探究.

Author

展敏月, 王 建, and 范纯新

Subjects

*HAIR cells, *TUMOR necrosis factors, *TERTIARY structure, *IN situ hybridization, *MORPHOLOGY, *LARVAE

Abstract

Tumor Necrosis Factor Superfamily (TNFSF) and Tumor Factor Receptor Superfamily (TNFRSF) regulate cell apoptosis, metabolism and development. To explore the expression and function of TNFSF and TNFRSF in teleosts, we cloned tnfsf10 and tnfrsf10 of the sterlet, Acipenser ruthenus, and analyzed their structure and evolution. Results showed that, Tnfsf10 and Tnfrsf10 of the sterlet were located at the base of actinopterygii branch in phylogenetic tree and have low homology with Tnfsf10 and Tnfrsf10 of the tetrapod, however, their tertiary structure is similar to Tnfsf10 and Tnfrsf10 of the human. Whole-mount in situ hybridization analysis showed that tnfsf10 and tnfrsf10 were mainly expressed in the horizontal muscle septum of the trunk, infraorbital canal of the head, preopercular lateral line, and neuromast of the ventral rostral. After being treated with Tnfrsf10 specific activator Bioymifi, the morphology of sterlet larvae did not change significantly, but the number of hair cells in neuromast increased significantly. The findings suggest that the Tnfsf10 and Tnfrsf10 of the sterlet represent the original form of the teleost homologous protein, which may be specifically involved in the development of hair cells in the lateral line neuromast. [ABSTRACT FROM AUTHOR]

Published

2023

22. A Highly Sensitive Deep-Sea Hydrodynamic Pressure Sensor Inspired by Fish Lateral Line

Author

Xiaohe Hu, Zhiqiang Ma, Zheng Gong, Fuqun Zhao, Sheng Guo, Deyuan Zhang, and Yonggang Jiang

Subjects

lateral line, biomimetic, deep-sea, hydrodynamic pressure sensor, piezoelectric nanofiber mat, Technology

Abstract

Hydrodynamic pressure sensors offer an auxiliary approach for ocean exploration by unmanned underwater vehicles (UUVs). However, existing hydrodynamic pressure sensors often lack the ability to monitor subtle hydrodynamic stimuli in deep-sea environments. In this study, we present the development of a deep-sea hydrodynamic pressure sensor (DSHPS) capable of operating over a wide range of water depths while maintaining exceptional hydrodynamic sensing performance. The DSHPS device was systematically optimized by considering factors such as piezoelectric polyvinylidene fluoride–trifluoroethylene/barium titanate [P(VDF-TrFE)/BTO] nanofibers, electrode configurations, sensing element dimensions, integrated circuits, and packaging strategies. The optimized DSHPS exhibited a remarkable pressure gradient response, achieving a minimum pressure difference detection capability of approximately 0.11 Pa. Additionally, the DSHPS demonstrated outstanding performance in the spatial positioning of dipole sources, which was elucidated through theoretical charge modeling and fluid–structure interaction (FSI) simulations. Furthermore, the integration of a high Young’s modulus packaging strategy inspired by fish skull morphology ensured reliable sensing capabilities of the DSHPS even at depths of 1000 m in the deep sea. The DSHPS also exhibited consistent and reproducible positioning performance for subtle hydrodynamic stimulus sources across this wide range of water depths. We envision that the development of the DSHPS not only enhances our understanding of the evolutionary aspects of deep-sea canal lateral lines but also paves the way for the advancement of artificial hydrodynamic pressure sensors.

Published

2024

23. Morphological and Sensory Innovations for an Aquatic Lifestyle

Author

Marshall, Christopher D., Sarko, Diana K., Reep, Roger L., Würsig, Bernd, Series Editor, and Marsh, Helene, editor

Published

2022

24. Physiological responses of mechanosensory systems in the head of larval zebrafish (Danio rerio)

Author

Nils Brehm, Nils Wenke, Keshia Glessner, and Melanie Haehnel-Taguchi

Subjects

lateral line, mechanosensation, zebrafish, trigeminal, statoacoustic, Mechanical engineering and machinery, TJ1-1570, Electronic computers. Computer science, QA75.5-76.95

Abstract

The lateral line system of zebrafish consists of the anterior lateral line, with neuromasts distributed on the head, and the posterior lateral line, with neuromasts distributed on the trunk. The sensory afferent neurons are contained in the anterior and posterior lateral line ganglia, respectively. So far, the vast majority of physiological and developmental studies have focused on the posterior lateral line. However, studies that focus on the anterior lateral line, especially on its physiology, are very rare. The anterior lateral line involves different neuromast patterning processes, specific distribution of synapses, and a unique role in behavior. Here, we report our observations regarding the development of the lateral line and analyze the physiological responses of the anterior lateral line to mechanical and water jet stimuli. Sensing in the fish head may be crucial to avoid obstacles, catch prey, and orient in water current, especially in the absence of visual cues. Alongside the lateral line, the trigeminal system, with its fine nerve endings innervating the skin, could contribute to perceiving mechanosensory stimulation. Therefore, we compare the physiological responses of the lateral line afferent neurons to responses of trigeminal neurons and responsiveness of auditory neurons. We show that anterior lateral line neurons are tuned to the velocity of mechanosensory ramp stimulation, while trigeminal neurons either only respond to mechanical step stimuli or fast ramp and step stimuli. Auditory neurons did not respond to mechanical or water jet stimuli. These results may prove to be essential in designing underwater robots and artificial lateral lines, with respect to the spectra of stimuli that the different mechanosensory systems in the larval head are tuned to, and underline the importance and functionality of the anterior lateral line system in the larval fish head.

Published

2023

25. The monophyly of Crenuchinae and description of two new species of Poecilocharax (Teleostei: Crenuchidae) based on phenotypic and genotypic evidence.

Author

Ohara, Willian M, Pastana, Murilo, and Camelier, Priscila

Subjects

*GENOTYPES, *SPECIES, *PHENOTYPES, *SEXUAL dimorphism

Abstract

Crenuchinae is a subfamily of the fish family Crenuchidae distributed in the Amazon Basin with pronounced sexual dimorphism and exuberant colour patterns. Recent fieldwork in the tributaries of the Rio Aripuanã drainage, a large tributary of the Rio Madeira (Amazon Basin), resulted in the discovery of two distinctive, undescribed species of the crenuchin genus Poecilocharax , which are formally described herein, combining morphological and molecular data. These are the first representatives of Crenuchinae discovered after a gap of 57 years and the first records of Poecilocharax from the tributaries of the right bank of the Rio Amazonas draining the Brazilian crystalline shield. Based on a taxonomic review including all species of the subfamily, we provide an expanded morphological diagnosis for Crenuchinae. This now includes characteristics related to the lateral-line canals of head and body, the number of dorsal-fin rays and sexually dimorphic traits. In addition, we review previous characteristics used to diagnose Crenuchus and Poecilocharax , providing comments on their polarity and distribution across the subfamily. A dichotomous key is provided for the first time for species of Crenuchinae. [ABSTRACT FROM AUTHOR]

Published

2023

26. Effects of domestication and captive breeding on reaction to moving objects: implications for avoidance behaviours of masu salmon Oncorhynchus masou

Author

Koh Hasegawa, Masanori Nakae, and Kouta Miyamoto

Subjects

hatchery programme, lateral line, learning, salmonid, wild, Science

Abstract

Domestication and captive breeding can compromise the obstacle- and predator-avoidance capabilities of animals in the wild. Whereas previous studies only examined these effects in combination, here we examine them individually by comparing the abilities of wild, F1 (offspring of wild parents) and captive-bred (approx. F15) masu salmon Oncorhynchus masou to avoid a falling object under experimental conditions. Rates of avoidance failure were low (wild, 12.5%; F1, 10.7%; captive-bred, 8%) under light conditions, but increased under dark conditions (wild, 11.1%; F1, 32.1%; captive-bred, 60.0%). We attribute the elevated avoidance failure rate among F1 fish to the lack of learning opportunities in hatchery environments (i.e. domestication), and the further elevation of avoidance failure rate among captive-bred fish to the degradation of sensory organ function (i.e. captive breeding). These results imply reduced survival rates for F1 and captive-bred fish in the wild and are consistent with the low stocking efficiencies reported for captive-bred masu salmon.

Published

2023

27. Evolution of left–right asymmetry in the sensory system and foraging behavior during adaptation to food-sparse cave environments.

Author

Fernandes, Vânia Filipa Lima, Glaser, Yannik, Iwashita, Motoko, and Yoshizawa, Masato

Subjects

*FORAGING behavior, *CAVES, *STARTLE reaction, *POSTURE, *SYMMETRY (Biology), *LATERAL dominance, *ENERGY dissipation

Abstract

Background: Laterality in relation to behavior and sensory systems is found commonly in a variety of animal taxa. Despite the advantages conferred by laterality (e.g., the startle response and complex motor activities), little is known about the evolution of laterality and its plasticity in response to ecological demands. In the present study, a comparative study model, the Mexican tetra (Astyanax mexicanus), composed of two morphotypes, i.e., riverine surface fish and cave-dwelling cavefish, was used to address the relationship between environment and laterality. Results: The use of a machine learning-based fish posture detection system and sensory ablation revealed that the left cranial lateral line significantly supports one type of foraging behavior, i.e., vibration attraction behavior, in one cave population. Additionally, left–right asymmetric approaches toward a vibrating rod became symmetrical after fasting in one cave population but not in the other populations. Conclusion: Based on these findings, we propose a model explaining how the observed sensory laterality and behavioral shift could help adaptation in terms of the tradeoff in energy gain and loss during foraging according to differences in food availability among caves. [ABSTRACT FROM AUTHOR]

Published

2022

28. The Tapping Assay: A Simple Method to Induce Fear Responses in Zebrafish.

Author

Ro, Yoojin, Noronha, Marigrace, Mirza, Bashir, Ansari, Rida, and Gerlai, Robert

Subjects

*BRACHYDANIO, *BEHAVIORAL neuroscience, *FEAR, *CENTRAL nervous system, *ANXIETY disorders

Abstract

The zebrafish is increasingly employed in behavioral neuroscience as a translationally relevant model organism for human central nervous system disorders. One of the most prevalent CNS disorders representing an unmet medical need is the disorder cluster defined under the umbrella term anxiety disorders. Zebrafish have been shown to respond to a variety of anxiety and fear inducing stimuli and have been suggested for modeling human anxiety. Here, we describe a simple method with which we intend to induce fear/anxiety responses in this species. The method allows us to deliver a visual and lateral line stimulus (vibration or "tapping") to the fish with the use of a moving object, a ball colliding with the side glass of the experimental tank. We describe the hardware construction of the apparatus and the procedure of the behavioral paradigm. We also present data on how zebrafish respond to the tapping. Our results demonstrate that the method induces significant fear/anxiety responses. We argue that the simplicity of the method and the efficiency of the paradigm should make it popular among those who plan to use zebrafish as a tool in anxiety research. [ABSTRACT FROM AUTHOR]

Published

2022

29. Osteoclast activity sculpts craniofacial form to permit sensorineural patterning in the zebrafish skull.

Author

Miao, Kelly Z., Cozzone, Austin, Caetano-Lopes, Joana, Harris, Matthew P., and Fisher, Shannon

Subjects

BRACHYDANIO, FRONTAL bone, SKULL, CRANIAL nerves, BONE growth

Abstract

Efforts to understand the morphogenesis of complex craniofacial structures have largely focused on the role of chondrocytes and osteoblasts. Along with these bone-creating cells, bone-resorbing osteoclasts are critical in homeostasis of adult skeletal structures, but there is currently limited information on their role in the complex morphogenetic events of craniofacial development. Fundamental aspects of skull formation and general skeletal development are conserved from zebrafish to mammals. Using a cathepsinK reporter, we documented osteoclast location in the developing zebrafish skull over several weeks, from 5.18 mm to 9.6 mm standard length (approximately 15 to 34 days post fertilization). While broad distribution of osteoclasts is consistent across individuals, they are sparse and the exact locations vary among fish and across developmental time points. Interestingly, we observed osteoclasts concentrating at areas associated with neuromasts and their associated nerves, in particular the hyomandibular foramina and around the supraorbital lateral line. These are areas of active remodeling. In contrast, other areas of rapid bone growth, such as the osteogenic fronts of the frontal and parietal bones, show no particular concentration of osteoclasts, suggesting that they play a special role in shaping bone near neuromasts and nerves. In csf1ra mutants lacking functional osteoclasts, the morphology of the cranial bone was disrupted in both areas. The hyomandibular foramen is present in the initial cartilage template, but after the initiation of ossification, the diameter of the canal is significantly smaller in the absence of osteoclasts. The diameter of the supraorbital lateral line canals was also reduced in the mutants, as was the number of pores associated with neuromasts, which allow for the passage of associated nerves through the bone. Our findings define important and previously unappreciated roles for osteoclast activity in shaping craniofacial skeletal structures with a particular role in bone modeling around peripheral cranial nerves, providing a scaffold for wiring the sensioneural system during craniofacial development. This has important implications for the formation of the evolutionarily diverse lateral line system, as well understanding the mechanism of neurologic sequelae of congenital osteoclast dysfunction in human craniofacial development. [ABSTRACT FROM AUTHOR]

Published

2022

30. General Boundary Identification Through Surface Pressure Measurements on a 2-D Foil

Author

Clark, Jack H., Dahl, Jason M., Hirschel, Ernst Heinrich, Founding Editor, Schröder, Wolfgang, Series Editor, Boersma, Bendiks Jan, Editorial Board Member, Fujii, Kozo, Editorial Board Member, Haase, Werner, Editorial Board Member, Leschziner, Michael A., Editorial Board Member, Periaux, Jacques, Editorial Board Member, Pirozzoli, Sergio, Editorial Board Member, Rizzi, Arthur, Editorial Board Member, Roux, Bernard, Editorial Board Member, Shokin, Yurii I., Editorial Board Member, Mäteling, Esther, Managing Editor, Braza, Marianna, editor, Hourigan, Kerry, editor, and Triantafyllou, Michael, editor

Published

2021

31. Effect of pH on Development of the Zebrafish Inner Ear and Lateral Line: Comparisons between High School and University Settings.

Author

Soraire T, Thompson K, Wenzler T, Taibi J, and Coffin AB

Subjects

Animals, Hydrogen-Ion Concentration, Schools, Zebrafish growth & development, Ear, Inner growth & development, Ear, Inner embryology, Lateral Line System embryology

Abstract

Increasing carbon dioxide levels associated with climate change will likely have a devastating effect on aquatic ecosystems. Aquatic environments sequester carbon dioxide, resulting in acidic conditions that can negatively affect fish development. Increasing climate change impacts in the coming decades will have an outsized effect on younger generations. Therefore, our research had two interconnected goals: 1) understand how aquatic acidification affects the development of zebrafish, and 2) support a high school scientist's ability to address environmental questions of increasing importance to her generation. Working with teachers and other mentors, the first author designed and conducted the research, first in her high school, then in a university research laboratory. Zebrafish embryos were reared in varying pH conditions (6.7-8.2) for up to 7 days. We assessed fish length and development of the inner ear, including the otoliths; structures that depend on calcium carbonate for proper development. Although pH did not affect fish length, fish reared in pH 7.75 had smaller anterior otoliths, showing that pH can impact zebrafish ear development. Furthermore, we demonstrate how zebrafish may be used for high school students to pursue open-ended questions using different levels of available resources.

Published

2024

32. Contributions of mirror-image hair cell orientation to mouse otolith organ and zebrafish neuromast function.

Author

Ono K, Jarysta A, Hughes NC, Jukic A, Chang HHV, Deans MR, Eatock RA, Cullen KE, Kindt KS, and Tarchini B

Subjects

Animals, Mice, Transcription Factors metabolism, Transcription Factors genetics, Homeodomain Proteins metabolism, Homeodomain Proteins genetics, Mechanotransduction, Cellular, Lateral Line System physiology, Lateral Line System embryology, Zebrafish Proteins genetics, Zebrafish Proteins metabolism, Zebrafish physiology, Otolithic Membrane physiology, Hair Cells, Auditory physiology

Abstract

Otolith organs in the inner ear and neuromasts in the fish lateral-line harbor two populations of hair cells oriented to detect stimuli in opposing directions. The underlying mechanism is highly conserved: the transcription factor EMX2 is regionally expressed in just one hair cell population and acts through the receptor GPR156 to reverse cell orientation relative to the other population. In mouse and zebrafish, loss of Emx2 results in sensory organs that harbor only one hair cell orientation and are not innervated properly. In zebrafish, Emx2 also confers hair cells with reduced mechanosensory properties. Here, we leverage mouse and zebrafish models lacking GPR156 to determine how detecting stimuli of opposing directions serves vestibular function, and whether GPR156 has other roles besides orienting hair cells. We find that otolith organs in Gpr156 mouse mutants have normal zonal organization and normal type I-II hair cell distribution and mechano-electrical transduction properties. In contrast, gpr156 zebrafish mutants lack the smaller mechanically evoked signals that characterize Emx2-positive hair cells. Loss of GPR156 does not affect orientation-selectivity of afferents in mouse utricle or zebrafish neuromasts. Consistent with normal otolith organ anatomy and afferent selectivity, Gpr156 mutant mice do not show overt vestibular dysfunction. Instead, performance on two tests that engage otolith organs is significantly altered - swimming and off-vertical-axis rotation. We conclude that GPR156 relays hair cell orientation and transduction information downstream of EMX2, but not selectivity for direction-specific afferents. These results clarify how molecular mechanisms that confer bi-directionality to sensory organs contribute to function, from single hair cell physiology to animal behavior., Competing Interests: KO, AJ, NH, AJ, HC, MD, RE, KC, KK, BT No competing interests declared

Published

2024

33. Lateral line morphology, sensory perception and collective behaviour in African cichlid fish

Author

Elliott Scott, Duncan E. Edgley, Alan Smith, Domino A. Joyce, Martin J. Genner, Christos C. Ioannou, and Sabine Hauert

Subjects

lateral line, collective behaviour, bioinspiration, sensors, cichlids, Science

Abstract

The lateral line system of fishes provides cues for collective behaviour, such as shoaling, but it remains unclear how anatomical lateral line variation leads to behavioural differences among species. Here we studied associations between lateral line morphology and collective behaviour using two morphologically divergent species and their second-generation hybrids. We identify collective behaviours associated with variation in canal and superficial lateral line morphology, with closer proximities to neighbouring fish associated with larger canal pore sizes and fewer superficial neuromasts. A mechanistic understanding of the observed associations was provided by hydrodynamic modelling of an artificial lateral line sensor, which showed that simulated canal-based neuromasts were less susceptible to saturation during unidirectional movement than simulated superficial neuromasts, while increasing the canal pore size of the simulated lateral line sensor elevated sensitivity to vortices shed by neighbouring fish. Our results propose a mechanism behind lateral line flow sensing during collective behaviour in fishes.

Published

2023

34. Osteoclast activity sculpts craniofacial form to permit sensorineural patterning in the zebrafish skull

Author

Kelly Z. Miao, Austin Cozzone, Joana Caetano-Lopes, Matthew P. Harris, and Shannon Fisher

Subjects

osteoclast, neuromast, lateral line, foramen, live imaging, zebrafish, Diseases of the endocrine glands. Clinical endocrinology, RC648-665

Abstract

Efforts to understand the morphogenesis of complex craniofacial structures have largely focused on the role of chondrocytes and osteoblasts. Along with these bone–creating cells, bone–resorbing osteoclasts are critical in homeostasis of adult skeletal structures, but there is currently limited information on their role in the complex morphogenetic events of craniofacial development. Fundamental aspects of skull formation and general skeletal development are conserved from zebrafish to mammals. Using a cathepsinK reporter, we documented osteoclast location in the developing zebrafish skull over several weeks, from 5.18 mm to 9.6 mm standard length (approximately 15 to 34 days post fertilization). While broad distribution of osteoclasts is consistent across individuals, they are sparse and the exact locations vary among fish and across developmental time points. Interestingly, we observed osteoclasts concentrating at areas associated with neuromasts and their associated nerves, in particular the hyomandibular foramina and around the supraorbital lateral line. These are areas of active remodeling. In contrast, other areas of rapid bone growth, such as the osteogenic fronts of the frontal and parietal bones, show no particular concentration of osteoclasts, suggesting that they play a special role in shaping bone near neuromasts and nerves. In csf1ra mutants lacking functional osteoclasts, the morphology of the cranial bone was disrupted in both areas. The hyomandibular foramen is present in the initial cartilage template, but after the initiation of ossification, the diameter of the canal is significantly smaller in the absence of osteoclasts. The diameter of the supraorbital lateral line canals was also reduced in the mutants, as was the number of pores associated with neuromasts, which allow for the passage of associated nerves through the bone. Our findings define important and previously unappreciated roles for osteoclast activity in shaping craniofacial skeletal structures with a particular role in bone modeling around peripheral cranial nerves, providing a scaffold for wiring the sensioneural system during craniofacial development. This has important implications for the formation of the evolutionarily diverse lateral line system, as well understanding the mechanism of neurologic sequelae of congenital osteoclast dysfunction in human craniofacial development.

Published

2022

35. Putative COVID-19 therapies imatinib, lopinavir, ritonavir, and ivermectin cause hair cell damage: A targeted screen in the zebrafish lateral line.

Author

Coffin, Allison B., Dale, Emily, Doppenberg, Emilee, Fearington, Forrest, Hayward, Tamasen, Hill, Jordan, and Molano, Olivia

Subjects

BRACHYDANIO, HAIR cells, COVID-19 treatment, RITONAVIR, IVERMECTIN, AZITHROMYCIN, IMATINIB, MEDICAL screening

Abstract

The biomedical community is rapidly developing COVID-19 drugs to bring much-need therapies to market, with over 900 drugs and drug combinations currently in clinical trials. While this pace of drug development is necessary, the risk of producing therapies with significant side-effects is also increased. One likely side-effect of some COVID-19 drugs is hearing loss, yet hearing is not assessed during preclinical development or clinical trials. We used the zebrafish lateral line, an established model for drug-induced sensory hair cell damage, to assess the ototoxic potential of seven drugs in clinical trials for treatment of COVID-19. We found that ivermectin, lopinavir, imatinib, and ritonavir were significantly toxic to lateral line hair cells. By contrast, the approved COVID-19 therapies dexamethasone and remdesivir did not cause damage. We also did not observe damage from the antibiotic azithromycin. Neither lopinavir nor ritonavir altered the number of pre-synaptic ribbons per surviving hair cell, while there was an increase in ribbons following imatinib or ivermectin exposure. Damage from lopinavir, imatinib, and ivermectin was specific to hair cells, with no overall cytotoxicity noted following TUNEL labeling. Ritonavir may be generally cytotoxic, as determined by an increase in the number of TUNEL-positive non-hair cells following ritonavir exposure. Pharmacological inhibition of the mechanotransduction (MET) channel attenuated damage caused by lopinavir and ritonavir but did not alter imatinib or ivermectin toxicity. These results suggest that lopinavir and ritonavir may enter hair cells through the MET channel, similar to known ototoxins such as aminoglycoside antibiotics. Finally, we asked if ivermectin was ototoxic to rats in vivo. While ivermectin is not recommended by the FDA for treating COVID-19, many people have chosen to take ivermectin without a doctor’s guidance, often with serious side-effects. Rats received daily subcutaneous injections for 10 days with a clinically relevant ivermectin dose (0.2 mg/kg). In contrast to our zebrafish assays, ivermectin did not cause ototoxicity in rats. Our research suggests that some drugs in clinical trials for COVID-19 may be ototoxic. This work can help identify drugs with the fewest side-effects and determine which therapies warrant audiometric monitoring. [ABSTRACT FROM AUTHOR]

Published

2022

36. Alone in a crowd: effect of a nonfunctional lateral line on expression of the social hormone parathyroid hormone 2

Author

Alexandra Venuto, Cameron P. Smith, Marybelle Cameron-Pack, and Timothy Erickson

Subjects

hair cells, lateral line, neuropeptide, pth2, social brain, zebrafish, Science, Biology (General), QH301-705.5

Abstract

Parathyroid hormone 2 (Pth2) is a vertebrate-specific neuropeptide for which thalamic expression is upregulated by social contact with conspecifics. However, social interactions fail to stimulate pth2 expression in isolated zebrafish in which lateral line hair cells have been chemically ablated. These results suggest that modulation of pth2 by social context is acutely dependent on mechanosensory information from the lateral line. However, it is unclear how a congenital loss of lateral line function influences the ability of zebrafish to interpret their social environment. In this study, we measure pth2 levels in zebrafish mutants lacking hair cell function in either the lateral line only, or in both the inner ear and lateral line. Socially raised lateral line mutants express lower levels of pth2 relative to wild-type siblings, but there is no further reduction when all sensory hair cells are nonfunctional. However, social isolation of hair cell mutants causes a further reduction in pth2 expression, pointing to additional unidentified sensory cues that influence pth2 production. Lastly, we report that social context modulates fluorescent transgenes driven by the pth2 promoter. Altogether, these data suggest that lateral line mutants experience a form of isolation, even when raised in a social environment. This article has an associated First Person interview with the first author of the paper.

Published

2022

37. Chronic neurotransmission increases the susceptibility of lateral-line hair cells to ototoxic insults

Author

Daria Lukasz, Alisha Beirl, and Katie Kindt

Subjects

hair cell, neurotransmission, ototoxicity, lateral line, calcium, mitochondria, Medicine, Science, Biology (General), QH301-705.5

Abstract

Sensory hair cells receive near constant stimulation by omnipresent auditory and vestibular stimuli. To detect and encode these stimuli, hair cells require steady ATP production, which can be accompanied by a buildup of mitochondrial byproducts called reactive oxygen species (ROS). ROS buildup is thought to sensitize hair cells to ototoxic insults, including the antibiotic neomycin. Work in neurons has shown that neurotransmission is a major driver of ATP production and ROS buildup. Therefore, we tested whether neurotransmission is a significant contributor to ROS buildup in hair cells. Using genetics and pharmacology, we disrupted two key aspects of neurotransmission in zebrafish hair cells: presynaptic calcium influx and the fusion of synaptic vesicles. We find that chronic block of neurotransmission enhances hair-cell survival when challenged with the ototoxin neomycin. This reduction in ototoxin susceptibility is accompanied by reduced mitochondrial activity, likely due to a reduced ATP demand. In addition, we show that mitochondrial oxidation and ROS buildup are reduced when neurotransmission is blocked. Mechanistically, we find that it is the synaptic vesicle cycle rather than presynaptic- or mitochondrial-calcium influx that contributes most significantly to this metabolic stress. Our results comprehensively indicate that, over time, neurotransmission causes ROS buildup that increases the susceptibility of hair cells to ototoxins.

Published

2022

38. Putative COVID-19 therapies imatinib, lopinavir, ritonavir, and ivermectin cause hair cell damage: A targeted screen in the zebrafish lateral line

Author

Allison B. Coffin, Emily Dale, Emilee Doppenberg, Forrest Fearington, Tamasen Hayward, Jordan Hill, and Olivia Molano

Subjects

COVID-19 therapy, hair cell, zebrafish, lateral line, ototoxicity, ivermectin, Neurosciences. Biological psychiatry. Neuropsychiatry, RC321-571

Abstract

The biomedical community is rapidly developing COVID-19 drugs to bring much-need therapies to market, with over 900 drugs and drug combinations currently in clinical trials. While this pace of drug development is necessary, the risk of producing therapies with significant side-effects is also increased. One likely side-effect of some COVID-19 drugs is hearing loss, yet hearing is not assessed during preclinical development or clinical trials. We used the zebrafish lateral line, an established model for drug-induced sensory hair cell damage, to assess the ototoxic potential of seven drugs in clinical trials for treatment of COVID-19. We found that ivermectin, lopinavir, imatinib, and ritonavir were significantly toxic to lateral line hair cells. By contrast, the approved COVID-19 therapies dexamethasone and remdesivir did not cause damage. We also did not observe damage from the antibiotic azithromycin. Neither lopinavir nor ritonavir altered the number of pre-synaptic ribbons per surviving hair cell, while there was an increase in ribbons following imatinib or ivermectin exposure. Damage from lopinavir, imatinib, and ivermectin was specific to hair cells, with no overall cytotoxicity noted following TUNEL labeling. Ritonavir may be generally cytotoxic, as determined by an increase in the number of TUNEL-positive non-hair cells following ritonavir exposure. Pharmacological inhibition of the mechanotransduction (MET) channel attenuated damage caused by lopinavir and ritonavir but did not alter imatinib or ivermectin toxicity. These results suggest that lopinavir and ritonavir may enter hair cells through the MET channel, similar to known ototoxins such as aminoglycoside antibiotics. Finally, we asked if ivermectin was ototoxic to rats in vivo. While ivermectin is not recommended by the FDA for treating COVID-19, many people have chosen to take ivermectin without a doctor’s guidance, often with serious side-effects. Rats received daily subcutaneous injections for 10 days with a clinically relevant ivermectin dose (0.2 mg/kg). In contrast to our zebrafish assays, ivermectin did not cause ototoxicity in rats. Our research suggests that some drugs in clinical trials for COVID-19 may be ototoxic. This work can help identify drugs with the fewest side-effects and determine which therapies warrant audiometric monitoring.

Published

2022

39. Regionalized Protein Localization Domains in the Zebrafish Hair Cell Kinocilium

Author

Timothy Erickson, William Paul Biggers, Kevin Williams, Shyanne E. Butland, and Alexandra Venuto

Subjects

hair cells, kinocilium, cilia, deafness, hearing loss, lateral line, Biology (General), QH301-705.5

Abstract

Sensory hair cells are the receptors for auditory, vestibular, and lateral line sensory organs in vertebrates. These cells are distinguished by “hair”-like projections from their apical surface collectively known as the hair bundle. Along with the staircase arrangement of the actin-filled stereocilia, the hair bundle features a single, non-motile, true cilium called the kinocilium. The kinocilium plays an important role in bundle development and the mechanics of sensory detection. To understand more about kinocilial development and structure, we performed a transcriptomic analysis of zebrafish hair cells to identify cilia-associated genes that have yet to be characterized in hair cells. In this study, we focused on three such genes—ankef1a, odf3l2a, and saxo2—because human or mouse orthologs are either associated with sensorineural hearing loss or are located near uncharacterized deafness loci. We made transgenic fish that express fluorescently tagged versions of their proteins, demonstrating their localization to the kinocilia of zebrafish hair cells. Furthermore, we found that Ankef1a, Odf3l2a, and Saxo2 exhibit distinct localization patterns along the length of the kinocilium and within the cell body. Lastly, we have reported a novel overexpression phenotype of Saxo2. Overall, these results suggest that the hair cell kinocilium in zebrafish is regionalized along its proximal-distal axis and set the groundwork to understand more about the roles of these kinocilial proteins in hair cells.

Published

2023

40. Macrophages Break Interneuromast Cell Quiescence by Intervening in the Inhibition of Schwann Cells in the Zebrafish Lateral Line

Author

Meng-Ju Lin, Chia-Ming Lee, Wei-Lin Hsu, Bi-Chang Chen, and Shyh-Jye Lee

Subjects

regeneration, lateral line, interneuromast cell, Schwann cell, Wnt, macrophage, Biology (General), QH301-705.5

Abstract

In the zebrafish lateral line system, interneuromast cells (INCs) between neuromasts are kept quiescent by underlying Schwann cells (SWCs). Upon severe injuries that cause the complete loss of an entire neuromast, INCs can occasionally differentiate into neuromasts but how they escape from the inhibition by SWCs is still unclear. Using a genetic/chemical method to ablate a neuromast precisely, we found that a small portion of larvae can regenerate a new neuromast. However, the residual regeneration capacity was hindered by inhibiting macrophages. Using in toto imaging, we further discovered heterogeneities in macrophage behavior and distribution along the lateral line. We witnessed the crawling of macrophages between the injured lateral line and SWCs during regeneration and between the second primordium and the first mature lateral line during development. It implies that macrophages may physically alleviate the nerve inhibition to break the dormancy of INCs during regeneration and development in the zebrafish lateral line.

Published

2022

41. Evolutionary convergence of a neural mechanism in the cavefish lateral line system

Author

Elias T Lunsford, Alexandra Paz, Alex C Keene, and James C Liao

Subjects

cavefish, lateral line, corollary discharge, efference copy, afferent neuron, hair cell, Medicine, Science, Biology (General), QH301-705.5

Abstract

Animals can evolve dramatic sensory functions in response to environmental constraints, but little is known about the neural mechanisms underlying these changes. The Mexican tetra, Astyanax mexicanus, is a leading model to study genetic, behavioral, and physiological evolution by comparing eyed surface populations and blind cave populations. We compared neurophysiological responses of posterior lateral line afferent neurons and motor neurons across A. mexicanus populations to reveal how shifts in sensory function may shape behavioral diversity. These studies indicate differences in intrinsic afferent signaling and gain control across populations. Elevated endogenous afferent activity identified a lower response threshold in the lateral line of blind cavefish relative to surface fish leading to increased evoked potentials during hair cell deflection in cavefish. We next measured the effect of inhibitory corollary discharges from hindbrain efferent neurons onto afferents during locomotion. We discovered that three independently derived cavefish populations have evolved persistent afferent activity during locomotion, suggesting for the first time that partial loss of function in the efferent system can be an evolutionary mechanism for neural adaptation of a vertebrate sensory system.

Published

2022

42. Hydrodynamic model of fish orientation in a channel flow

Author

Maurizio Porfiri, Peng Zhang, and Sean D Peterson

Subjects

lateral line, rheotaxis, vortex dipole, organism: fish, Medicine, Science, Biology (General), QH301-705.5

Abstract

For over a century, scientists have sought to understand how fish orient against an incoming flow, even without visual and flow cues. Here, we elucidate a potential hydrodynamic mechanism of rheotaxis through the study of the bidirectional coupling between fish and the surrounding fluid. By modeling a fish as a vortex dipole in an infinite channel with an imposed background flow, we establish a planar dynamical system for the cross-stream coordinate and orientation. The system dynamics captures the existence of a critical flow speed for fish to successfully orient while performing cross-stream, periodic sweeping movements. Model predictions are examined in the context of experimental observations in the literature on the rheotactic behavior of fish deprived of visual and lateral line cues. The crucial role of bidirectional hydrodynamic interactions unveiled by this model points at an overlooked limitation of existing experimental paradigms to study rheotaxis in the laboratory.

Published

2022

43. Comparative Integumentary Morphology in Four Species of Pipa (Anura: Pipidae) from Colombia

Author

Sebastian Enrique Perez-Rojas and Adriana Jerez

Subjects

Dermal flap, Barbels, Fingertips, Lateral line, Ontogeny, Zoology, QL1-991

Abstract

Abstract As most neotropical pipids, the four species of Pipa present in Colombia are poorly understood despite their particular biology. The tegument of these New-World pipids presents particular structures which variations have been hardly analyzed. Therefore, we aim to describe the morphological variations of the dermal flap, barbels, fingertips, and the lateral line pattern among these four species, focusing on changes during the ontogeny. The results of the study show that the dermal flap was exclusively found in P. pipa, while barbels are usually present in P. pipa but seldom in P. snethlageae. The lateral line pattern in the dorsum is shared by the four species, but P. pipa present more neuromast lines along the snout than P. snethlageae. These species were different from P. parva and P. myersi, which cannot be distinguished based on external morphology, as they were more similar in all lateral line elements and exhibited the same fingertip morphology. On the other hand, the fingertips of young individuals of P. pipa and P. snethlageae presented four simple distal lobes which bifurcate twice during the ontogeny, so that adults present sixteen lobes. The difference between species is observed in the fingertip morphology: P. pipa has all four lobes distally placed, but P. snethlageae has one pair more proximal. The tegument structures analyzed here have a taxonomic utility using external morphology for P. pipa and P. snethlageae, but for P. parva and P. myersi additional studies are necessary. For future research, evaluating the function and anatomy of these structures is important to the understanding these integumentary structures in Pipa.

Published

2022

44. New small-sized species of Astyanax (Characiformes: Characidae) from the upper rio Paraguai basin, Brazil, with discussion on its generic allocation

Author

Fernando C. P. Dagosta and Manoela M. F. Marinho

Subjects

Lateral line, Nobres, Longitudinal stripe, Taxonomy, Tourist destination, Zoology, QL1-991

Abstract

Abstract A new species of Astyanax is described from the rio Salobra, tributary of rio Cuiabá, rio Paraguai basin. The new taxon can be distinguished from its congeners by having a well-defined dark midlateral stripe on body extending from the posterior margin of the opercle to the base of middle caudal-fin rays and a single vertical elongate humeral blotch. Although the new species is described in Astyanax, some specimens present an incomplete or a discontinuous series of perforated scales in the lateral line. Therefore, a discussion on its generic allocation is presented. Comments on different patterns of coloration among dark-striped species of Astyanax are also provided. The discovery of a new species in an underwater tourist point relatively near a large urban center underscores that even fish species daily observed by hundreds of people in limpid waters may lack a formal taxonomic identity. Such finding also highlights how the megadiverse Brazilian freshwater ichthyofauna still needs efforts and investments to identify and describe new taxa.

Published

2022

45. Fish communicate with water flow to enhance a school's social network.

Author

Peterson AN, Swanson N, and McHenry MJ

Subjects

Animals, Lateral Line System physiology, Biomechanical Phenomena, Social Behavior, Swimming physiology, Water Movements, Animal Communication

Abstract

Schooling fish rely on a social network created through signaling between its members to interact with their environment. Previous studies have established that vision is necessary for schooling and that flow sensing by the lateral line system may aid in a school's cohesion. However, it remains unclear to what extent flow provides a channel of communication between schooling fish. Based on kinematic measurements of the speed and heading of schooling tetras (Petitella rhodostoma), we found that compromising the lateral line by chemical treatment reduced the mutual information between individuals by ∼13%. This relatively small reduction in pairwise communication propagated through schools of varying size to reduce the degree and connectivity of the social network by more than half. Treated schools additionally showed more than twice the spatial heterogeneity of fish with unaltered flow sensing. These effects were much more substantial than the changes that we measured in the nearest-neighbor distance, speed and intermittency of individual fish by compromising flow sensing. Therefore, flow serves as a valuable supplement to visual communication in a manner that is revealed through a school's network properties., Competing Interests: Competing interests The authors declare no competing or financial interests., (© 2024. Published by The Company of Biologists Ltd.)

Published

2024

46. New small-sized species of Astyanax (Characiformes: Characidae) from the upper rio Paraguai basin, Brazil, with discussion on its generic allocation.

Author

Dagosta, Fernando C. P. and Marinho, Manoela M. F.

Subjects

*ASTYANAX, *CHARACIDAE, *CHARACIFORMES, *SPECIES, *INNER cities

Abstract

A new species of Astyanax is described from the rio Salobra, tributary of rio Cuiabá, rio Paraguai basin. The new taxon can be distinguished from its congeners by having a well-defined dark midlateral stripe on body extending from the posterior margin of the opercle to the base of middle caudal-fin rays and a single vertical elongate humeral blotch. Although the new species is described in Astyanax, some specimens present an incomplete or a discontinuous series of perforated scales in the lateral line. Therefore, a discussion on its generic allocation is presented. Comments on different patterns of coloration among dark-striped species of Astyanax are also provided. The discovery of a new species in an underwater tourist point relatively near a large urban center underscores that even fish species daily observed by hundreds of people in limpid waters may lack a formal taxonomic identity. Such finding also highlights how the megadiverse Brazilian freshwater ichthyofauna still needs efforts and investments to identify and describe new taxa. [ABSTRACT FROM AUTHOR]

Published

2022

47. Local tissue interactions govern pLL patterning in medaka.

Author

Seleit, Ali, Gross, Karen, Onistschenko, Jasmin, Hoang, Oi Pui, Theelke, Jonas, and Centanin, Lázaro

Subjects

*ORYZIAS latipes, *SENSE organs, *PERIPHERAL nervous system, *LASER ablation, *ORGANS (Anatomy), *TISSUES

Abstract

Vertebrate organs are arranged in a stereotypic, species-specific position along the animal body plan. Substantial morphological variation exists between related species, especially so in the vastly diversified teleost clade. It is still unclear how tissues, organs and systems can accommodate such diverse scaffolds. Here, we use the distinctive arrangement of neuromasts in the posterior lateral line (pLL) system of medaka fish to address the tissue-interactions defining a pattern. We show that patterning in this peripheral nervous system is established by autonomous organ precursors independent of neuronal wiring. In addition, we target the keratin 15 gene to generate stuck-in-the-midline (siml) mutants, which display epithelial lesions and a disrupted pLL patterning. By using siml/wt chimeras, we determine that the aberrant siml pLL pattern depends on the mutant epithelium, since a wild type epithelium can rescue the siml phenotype. Inducing epithelial lesions by 2-photon laser ablation during pLL morphogenesis phenocopies siml genetic mutants and reveals that epithelial integrity defines the final position of the embryonic pLL neuromasts. Our results using the medaka pLL disentangle intrinsic from extrinsic properties during the establishment of a sensory system. We speculate that intrinsic programs guarantee proper organ morphogenesis, while instructive interactions from surrounding tissues facilitates the accommodation of sensory organs to the diverse body plans found among teleosts. [Display omitted] • Epithelial integrity defines pLL patterning in medaka. • Patterning occurs regardless of nerve connectivity. • Primary organs' migration is independent of one another and depends on local cues. • Secondary organs' patterning is robust even on aberrant pLL initial conformation. • Hierarchical organization could be relevant for pLL adaption to diverse body plan. [ABSTRACT FROM AUTHOR]

Published

2022

48. The early development and physiology of Xenopus laevis tadpole lateral line system.

Author

Saccomanno, Valentina, Love, Heather, Sylvester, Amy, and Wen-Chang Li

Abstract

Xenopus laevis has a lateral line mechanosensory system throughout its full life cycle, and a previous study on prefeeding stage tadpoles revealed that it may play a role in motor responses to both water suction and water jets. Here, we investigated the physiology of the anterior lateral line system in newly hatched tadpoles and the motor outputs induced by its activation in response to brief suction stimuli. High-speed videoing showed tadpoles tended to turn and swim away when strong suction was applied close to the head. The lateral line neuromasts were revealed by using DASPEI staining, and their inactivation with neomycin eliminated tadpole motor responses to suction. In immobilized preparations, suction or electrically stimulating the anterior lateral line nerve reliably initiated swimming but the motor nerve discharges implicating turning was observed only occasionally. The same stimulation applied during ongoing fictive swimming produced a halting response. The anterior lateral line nerve showed spontaneous afferent discharges at rest and increased activity during stimulation. Efferent activities were only recorded during tadpole fictive swimming and were largely synchronous with the ipsilateral motor nerve discharges. Finally, calcium imaging identified neurons with fluorescence increase time-locked with suction stimulation in the hindbrain and midbrain. A cluster of neurons at the entry point of the anterior lateral line nerve in the dorsolateral hindbrain had the shortest latency in their responses, supporting their potential sensory interneuron identity. Future studies need to reveal how the lateral line sensory information is processed by the central circuit to determine tadpole motor behavior. NEW & NOTEWORTHY We studied Xenopus tadpole motor responses to anterior lateral line stimulation using high-speed videos, electrophysiology and calcium imaging. Activating the lateral line reliably started swimming. At high stimulation intensities, turning was observed behaviorally but suitable motor nerve discharges were seen only occasionally in immobilized tadpoles. Suction applied during swimming produced a halting response. We analyzed afferent and efferent activities of the tadpole anterior lateral line nerve and located sensory interneurons using calcium imaging. [ABSTRACT FROM AUTHOR]

Published

2021

49. Robust regeneration of adult zebrafish lateral line hair cells reflects continued precursor pool maintenance

Author

Cruz, Ivan A, Kappedal, Ryan, Mackenzie, Scott M, Hailey, Dale W, Hoffman, Trevor L, Schilling, Thomas F, and Raible, David W

Subjects

Regenerative Medicine, Neurosciences, Underpinning research, 1.1 Normal biological development and functioning, Animals, Bromodeoxyuridine, Fluorescence, Immunohistochemistry, Lateral Line System, Mechanoreceptors, Neomycin, Regeneration, Zebrafish, Adult zebrafish, Lateral line, Hair cells, Neuromasts, Biological Sciences, Medical and Health Sciences, Developmental Biology

Abstract

We have examined lateral line hair cell and support cell maintenance in adult zebrafish when growth is largely complete. We demonstrate that adult zebrafish not only replenish hair cells after a single instance of hair cell damage, but also maintain hair cells and support cells after multiple rounds of damage and regeneration. We find that hair cells undergo continuous turnover in adult zebrafish in the absence of damage. We identify mitotically-distinct support cell populations and show that hair cells regenerate from underlying support cells in a region-specific manner. Our results demonstrate that there are two distinct support cell populations in the lateral line, which may help explain why zebrafish hair cell regeneration is extremely robust, retained throughout life, and potentially unlimited in regenerative capacity.

Published

2015

50. The Cholinergic Lateral Line Efferent Synapse: Structural, Functional and Molecular Similarities With Those of the Cochlea

Author

Paola V. Plazas and Ana Belén Elgoyhen

Subjects

α9α10, efferent, cochlea, lateral line, nicotinic receptor, zebrafish, Neurosciences. Biological psychiatry. Neuropsychiatry, RC321-571

Abstract

Vertebrate hair cell (HC) systems are innervated by efferent fibers that modulate their response to external stimuli. In mammals, the best studied efferent-HC synapse, the cholinergic medial olivocochlear (MOC) efferent system, makes direct synaptic contacts with HCs. The net effect of MOC activity is to hyperpolarize HCs through the activation of α9α10 nicotinic cholinergic receptors (nAChRs) and the subsequent activation of Ca2+-dependent SK2 potassium channels. A serious obstacle in research on many mammalian sensory systems in their native context is that their constituent neurons are difficult to access even in newborn animals, hampering circuit observation, mapping, or controlled manipulation. By contrast, fishes and amphibians have a superficial and accessible mechanosensory system, the lateral line (LL), which circumvents many of these problems. LL responsiveness is modulated by efferent neurons which aid to distinguish between external and self-generated stimuli. One component of the LL efferent system is cholinergic and its activation inhibits LL afferent activity, similar to what has been described for MOC efferents. The zebrafish (Danio rerio) has emerged as a powerful model system for studying human hearing and balance disorders, since LL HC are structurally and functionally analogous to cochlear HCs, but are optically and pharmacologically accessible within an intact specimen. Complementing mammalian studies, zebrafish have been used to gain significant insights into many facets of HC biology, including mechanotransduction and synaptic physiology as well as mechanisms of both hereditary and acquired HC dysfunction. With the rise of the zebrafish LL as a model in which to study auditory system function and disease, there has been an increased interest in studying its efferent system and evaluate the similarity between mammalian and piscine efferent synapses. Advances derived from studies in zebrafish include understanding the effect of the LL efferent system on HC and afferent activity, and revealing that an α9-containing nAChR, functionally coupled to SK channels, operates at the LL efferent synapse. In this review, we discuss the tools and findings of these recent investigations into zebrafish efferent-HC synapse, their commonalities with the mammalian counterpart and discuss several emerging areas for future studies.

Published

2021