Automated and controlled mechanical stimulation and functional imaging in vivo in C. elegans

Correction for ‘Automated and controlled mechanical stimulation and functional imaging in vivo in C. elegans’ by Yongmin Cho et al., Lab Chip, 2017, 17, 2609–2618.

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High-Throughput Controlled Mechanical Stimulation and Functional Imaging In Vivo

10.1101/107318 ◽

2017 ◽

Cited By ~ 2

Author(s):

Yongmin Cho ◽

Daniel A. Porto ◽

Hyundoo Hwang ◽

Laura J. Grundy ◽

William R. Schafer ◽

...

Keyword(s):

Functional Imaging ◽

Sensory Integration ◽

Genetic Model ◽

Receptive Fields ◽

Model Systems ◽

Mechanical Stimuli ◽

C Elegans ◽

Fluid Delivery ◽

Chemical Stimuli

AbstractUnderstanding mechanosensation and other sensory behavior in genetic model systems such as C. elegans is relevant to many human diseases. These studies conventionally require immobilization by glue and manual delivery of stimuli, leading to low experimental throughput and high variability. Here we present a microfluidic platform that delivers precise mechanical stimuli robustly. The system can be easily used in conjunction with functional imaging and optical interrogation techniques, as well as other capabilities such as sorting or more sophisticated fluid delivery schemes. The platform is fully automated, thereby greatly enhancing the throughput and robustness of experiments. We show that behavior of the well-known gentle and harsh touch neurons and their receptive fields can be recapitulated in our system. Using calcium dynamics as a readout, we demonstrate the ability to perform a drug screen in vivo. Furthermore, using an integrated chip platform that can deliver both mechanical and chemical stimuli, we examine sensory integration in interneurons in response to multimodal sensory inputs. We envision that this system will be able to greatly accelerate the discovery of genes and molecules involved in mechanosensation and multimodal sensory behavior, as well as the discovery of therapeutics for related diseases.

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Caenorhabditis elegans PIEZO Channel Coordinates Multiple Reproductive Tissues to Govern Ovulation

10.1101/847392 ◽

2019 ◽

Cited By ~ 1

Author(s):

Xiaofei Bai ◽

Jeff Bouffard ◽

Avery Lord ◽

Katherine Brugman ◽

Paul W. Sternberg ◽

...

Keyword(s):

Caenorhabditis Elegans ◽

Ion Channels ◽

Calcium Signaling ◽

Brood Size ◽

Mechanical Stimuli ◽

C Elegans ◽

Reproductive Tissues ◽

Physiological Processes ◽

Wide Range

AbstractThe PIEZO proteins are involved in a wide range of developmental and physiological processes. Human PIEZO1 and PIEZO2 are newly identified excitatory mechano-sensitive proteins; they are non-selective ion channels that exhibit a preference for calcium in response to mechanical stimuli. To further understand the function of these proteins, we investigated the roles of pezo-1, the sole PIEZO ortholog in C. elegans. pezo-1 is expressed throughout development in C. elegans, with strong expression in reproductive tissues. A number of deletion alleles as well as a putative gain-of-function mutant caused severe defects in reproduction. A reduced brood size was observed in the strains depleted of PEZO-1. In vivo observations show that oocytes undergo a variety of transit defects as they enter and exit the spermatheca during ovulation. Post ovulation oocytes were frequently damaged during spermathecal contraction. Calcium signaling in the spermatheca is normal during ovulation in pezo-1 mutants, however, pezo-1 interacts genetically with known regulators of calcium signaling. Lastly, loss of PEZO-1 caused defective sperm navigation after being pushed out of the spermatheca during ovulation. Mating with males rescued these reproductive deficiencies in our pezo-1 mutants. These findings suggest that PEZO-1 may act in different reproductive tissues to promote proper ovulation and fertilization in C. elegans.

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Progressive recruitment of distal MEC-4 channels determines touch response strength in C. elegans

10.1101/587014 ◽

2019 ◽

Cited By ~ 1

Author(s):

S. Katta ◽

A. Sanzeni ◽

A. Das ◽

M. Vergassola ◽

M.B. Goodman

Keyword(s):

Temporal Dynamics ◽

Mechanical Strain ◽

Tissue Mechanics ◽

Mechanical Stimuli ◽

Patch Clamp Recording ◽

Open Probability ◽

C Elegans ◽

Somatosensory Neurons ◽

Touch Response

AbstractTouch deforms, or strains, the skin beyond the immediate point of contact. The spatiotemporal nature of the touch-induced strain fields depend on the mechanical properties of the skin and the tissues below. Somatosensory neurons that sense touch branch out within the skin and rely on a set of mechano-electrical transduction channels distributed within their dendrites to detect mechanical stimuli. Here, we sought to understand how tissue mechanics shape touch-induced mechanical strain across the skin over time and how individual channels located in different regions of the strain field contribute to the overall touch response. We leveraged C. elegans’ touch receptor neurons (TRNs) as a simple model amenable to in vivo whole-cell patch clamp recording and an integrated experimental-computational approach to dissect the mechanisms underlying the spatial and temporal dynamics that we observed. Consistent with the idea that strain is produced at a distance, we show that delivering strong stimuli outside the anatomical extent of the neuron is sufficient to evoke MRCs. The amplitude and kinetics of the MRCs depended on both stimulus displacement and speed. Finally, we found that the main factor responsible for touch sensitivity is the recruitment of progressively more distant channels by stronger stimuli, rather than modulation of channel open probability. This principle may generalize to somatosensory neurons with more complex morphologies.SummaryThrough experiment and simulation, Katta et al. reveal that pushing faster and deeper recruits more and more distant mechano-electrical transduction channels during touch. The net result is a dynamic receptive field whose size and shape depends on tissue mechanics, stimulus parameters, and channel distribution within sensory neurons.

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Characterization of the phototoxicity, chemigenetic profile, and mutational signatures of the chemotherapeutic CX-5461 in Caenorhabditis elegans

10.1101/2019.12.20.884981 ◽

2019 ◽

Author(s):

Frank B. Ye ◽

Akil Hamza ◽

Tejomayee Singh ◽

Stephane Flibotte ◽

Philip Hieter ◽

...

Keyword(s):

Caenorhabditis Elegans ◽

Cancer Therapeutics ◽

Copy Number Variations ◽

Factors Affecting ◽

C Elegans ◽

Dna Damaging Agents ◽

Wide Range ◽

Anti Cancer ◽

Exogenous Factors

ABSTRACTNew anti-cancer therapeutics require extensive in vivo characterization to identify endogenous and exogenous factors affecting efficacy, to measure toxicity and mutagenicity, and to determine genotypes resulting in therapeutic sensitivity or resistance. We used Caenorhabditis elegans as a platform with which to characterize properties of anti-cancer therapeutic agents in vivo. We generated a map of chemigenetic interactions between DNA damage response mutants and common DNA damaging agents. We used this map to investigate the properties of the new anti-cancer therapeutic CX-5461. We phenocopied the photoreactivity observed in CX-5461 clinical trials and found that CX-5461 generates reactive oxygen species when exposed to UVA radiation. We demonstrated that CX-5461 is a mutator, resulting in both large copy number variations and a high frequency of single nucleotide variations (SNVs). CX-5461-induced SNVs exhibited a distinct mutational signature. Consistent with the wide range of CX-5461-induced mutation types, we found that multiple repair pathways were needed for CX-5461 tolerance. Together, the data from C. elegans demonstrate that CX-5461 is a multimodal DNA damaging agent with strong similarity to ellipticines, a class of antineoplastic agents, and to anthracycline-based chemotherapeutics.

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Visualizing the metazoan proliferation-terminal differentiation decision in vivo

10.1101/2019.12.18.881888 ◽

2019 ◽

Cited By ~ 1

Author(s):

Rebecca C. Adikes ◽

Abraham Q. Kohrman ◽

Michael A. Q. Martinez ◽

Nicholas J. Palmisano ◽

Jayson J. Smith ◽

...

Keyword(s):

Cell Cycle ◽

Cell Cycle Control ◽

Cell Lineage ◽

Terminal Differentiation ◽

Cyclin Dependent Kinase ◽

C Elegans ◽

Differentiated Cells ◽

Imaging Tool ◽

Wide Range

SummaryCell proliferation and terminal differentiation are intimately coordinated during metazoan development. Here, we adapt a cyclin-dependent kinase (CDK) sensor to uncouple these cell cycle-associated events live in C. elegans and zebrafish. The CDK sensor consists of a fluorescently tagged CDK substrate that steadily translocates from the nucleus to the cytoplasm in response to increasing CDK activity and consequent sensor phosphorylation. We show that the CDK sensor can distinguish cycling cells in G1 from terminally differentiated cells in G0, revealing a commitment point and a cryptic stochasticity in an otherwise invariant C. elegans cell lineage. We also derive a predictive model of future proliferation behavior in C. elegans and zebrafish based on a snapshot of CDK activity in newly born cells. Thus, we introduce a live-cell imaging tool to facilitate in vivo studies of cell cycle control in a wide-range of developmental contexts.

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Sequence and transmembrane topology of MEC-4, an ion channel subunit required for mechanotransduction in Caenorhabditis elegans.

The Journal of Cell Biology ◽

10.1083/jcb.133.5.1071 ◽

1996 ◽

Vol 133 (5) ◽

pp. 1071-1081 ◽

Cited By ~ 78

Author(s):

C C Lai ◽

K Hong ◽

M Kinnell ◽

M Chalfie ◽

M Driscoll

Keyword(s):

Caenorhabditis Elegans ◽

Ion Channel ◽

Critical Role ◽

Comparative Sequence Analysis ◽

Mechanical Stimuli ◽

Transmembrane Topology ◽

C Elegans ◽

Carboxy Terminal

The process by which mechanical stimuli are converted into cellular responses is poorly understood, in part because key molecules in this mode of signal transduction, the mechanically gated ion channels, have eluded cloning efforts. The Caenorhabditis elegans mec-4 gene encodes a subunit of a candidate mechanosensitive ion channel that plays a critical role in touch reception. Comparative sequence analysis of C. elegans and Caenorhabditis briggsae mec-4 genes was used to initiate molecular studies that establish MEC-4 as a 768-amino acid protein that includes two hydrophobic domains theoretically capable of spanning a lipid bilayer. Immunoprecipitation of in vitro translated mec-4 protein with domain-specific anti-MEC-4 antibodies and in vivo characterization of a series of mec-4lacZ fusion proteins both support the hypothesis that MEC-4 crosses the membrane twice. The MEC-4 amino- and carboxy-terminal domains are situated in the cytoplasm and a large domain, which includes three Cys-rich regions, is extracellular. Definition of transmembrane topology defines regions that might interact with the extracellular matrix or cytoskeleton to mediate mechanical signaling.

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Hydrophobic analogues of rhodamine B and rhodamine 101: potent fluorescent probes of mitochondria in living C. elegans

Beilstein Journal of Organic Chemistry ◽

10.3762/bjoc.8.243 ◽

2012 ◽

Vol 8 ◽

pp. 2156-2165 ◽

Cited By ~ 40

Author(s):

Laurie F Mottram ◽

Safiyyah Forbes ◽

Brian D Ackley ◽

Blake R Peterson

Keyword(s):

Fluorescent Probes ◽

Rhodamine B ◽

Laser Scanning ◽

Fluorescent Dyes ◽

Laser Scanning Microscopy ◽

Confocal Laser ◽

C Elegans ◽

Wide Range ◽

Rhodamine 101

Mitochondria undergo dynamic fusion and fission events that affect the structure and function of these critical energy-producing cellular organelles. Defects in these dynamic processes have been implicated in a wide range of human diseases including ischemia, neurodegeneration, metabolic disease, and cancer. To provide new tools for imaging of mitochondria in vivo, we synthesized novel hydrophobic analogues of the red fluorescent dyes rhodamine B and rhodamine 101 that replace the carboxylate with a methyl group. Compared to the parent compounds, methyl analogues termed HRB and HR101 exhibit slightly red-shifted absorbance and emission spectra (5–9 nm), modest reductions in molar extinction coefficent and quantum yield, and enhanced partitioning into octanol compared with aqueous buffer of 10-fold or more. Comparison of living C. elegans (nematode roundworm) animals treated with the classic fluorescent mitochondrial stains rhodamine 123, rhodamine 6G, and rhodamine B, as well as the structurally related fluorophores rhodamine 101, and basic violet 11, revealed that HRB and HR101 are the most potent mitochondrial probes, enabling imaging of mitochondrial motility, fusion, and fission in the germline and other tissues by confocal laser scanning microscopy after treatment for 2 h at concentrations as low as 100 picomolar. Because transgenes are poorly expressed in the germline of these animals, these small molecules represent superior tools for labeling dynamic mitochondria in this tissue compared with the expression of mitochondria-targeted fluorescent proteins. The high bioavailabilty of these novel fluorescent probes may facilitate the identification of agents and factors that affect diverse aspects of mitochondrial biology in vivo.

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A programmable platform for sub-second multichemical dynamic stimulation and neuronal functional imaging inC. elegans

Lab on a Chip ◽

10.1039/c7lc01116d ◽

2018 ◽

Vol 18 (3) ◽

pp. 505-513 ◽

Cited By ~ 6

Author(s):

T. Rouse ◽

G. Aubry ◽

Y. Cho ◽

M. Zimmer ◽

H. Lu

Keyword(s):

Neuronal Activity ◽

Functional Imaging ◽

Microfluidic Platform ◽

C Elegans ◽

Dynamic Stimulation

This microfluidic platform enables monitoring neuronal activity ofC. elegansin response to dynamic multichemical cues.

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On-chip functional neuroimaging with mechanical stimulation inCaenorhabditis eleganslarvae for studying development and neural circuits

Lab on a Chip ◽

10.1039/c7lc01201b ◽

2018 ◽

Vol 18 (4) ◽

pp. 601-609 ◽

Cited By ~ 14

Author(s):

Yongmin Cho ◽

David N. Oakland ◽

Sol Ah Lee ◽

William R. Schafer ◽

Hang Lu

Keyword(s):

Mechanical Stimulation ◽

Neural Circuits ◽

Functional Neuroimaging ◽

Microfluidic Devices ◽

Mechanical Stimuli ◽

Neuronal Responses ◽

C Elegans ◽

Mechanosensory Neurons ◽

On Chip

New designs of microfluidic devices can facilitate recording ofC. eleganslarvae neuronal responses to precise mechanical stimuli, which reveal new understanding of development of mechanosensory neurons and circuits.

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