More Like this

1. Spectral scanning and fluorescence lifetime imaging microscopy (FLIM) enable separation and characterization of C. elegans autofluorescence in the cuticle and gut

   https://doi.org/10.1242/bio.060613  

   Hulsey-Vincent, Heino J; Cameron, Elizabeth A; Dahlberg, Caroline L; Galati, Domenico F (December 2024, Biology Open)

   ABSTRACT Caenorhabditis elegans gut and cuticle produce a disruptive amount of autofluorescence during imaging. Although C. elegans autofluorescence has been characterized, it has not been characterized at high resolution using both spectral and fluorescence lifetime-based approaches. We performed high resolution spectral scans of whole, living animals to characterize autofluorescence of adult C. elegans. By scanning animals at 405 nm, 473 nm, 561 nm, and 647 nm excitations, we produced spectral profiles that confirm the brightest autofluorescence has a clear spectral overlap with the emission of green fluorescent protein (GFP). We then used fluorescence lifetime imaging microscopy (FLIM) to further characterize autofluorescence in the cuticle and the gut. Using FLIM, we were able to isolate and quantify dim GFP signal within the sensory cilia of a single pair of neurons that is often obscured by cuticle autofluorescence. In the gut, we found distinct spectral populations of autofluorescence that could be excited by 405 nm and 473 nm lasers. Further, we found lifetime differences between subregions of this autofluorescence when stimulated at 473 nm. Our results suggest that FLIM can be used to differentiate biochemically unique populations of gut autofluorescence without labeling. Further studies involving C. elegans may benefit from combining high resolution spectral and lifetime imaging to isolate fluorescent protein signal that is mixed with background autofluorescence and to perform useful characterization of subcellular structures in a label-free manner. 

   more » « less
2. Comparative reconstruction of the predatory feeding structures of the polyphenic nematode Pristionchus pacificus

   https://doi.org/10.1111/ede.12397  

   Harry, Clayton J.; Messar, Sonia M.; Ragsdale, Erik J. (March 2022, Evolution & Development)

   Abstract Pristionchus pacificusis a nematode model for the developmental genetics of morphological polyphenism, especially at the level of individual cells. Morphological polyphenism in this species includes an evolutionary novelty, moveable teeth, which have enabled predatory feeding in this species and others in its family (Diplogastridae). From transmission electron micrographs of serial thin sections through an adult hermaphrodite ofP. pacificus, we three‐dimensionally reconstructed all epithelial and myoepithelial cells and syncytia, corresponding to 74 nuclei, of its face, mouth, and pharynx. We found that the epithelia that produce the predatory morphology ofP. pacificusare identical toCaenorhabditis elegansin the number of cell classes and nuclei. However, differences in cell form, spatial relationships, and nucleus position correlate with gross morphological differences fromC. elegansand outgroups. Moreover, we identified fine‐structural features, especially in the anteriormost pharyngeal muscles, that underlie the conspicuous, left‐right asymmetry that characterizes theP. pacificusfeeding apparatus. Our reconstruction provides an anatomical map for studying the genetics of polyphenism, feeding behavior, and the development of novel form in a satellite model toC. elegans. 

   more » « less
3. Orsay Virus Infection in Caenorhabditis elegans

   https://doi.org/10.1002/cpz1.1098  

   Batachari, Lakshmi E; Sarmiento, Mario Bardan; Wernet, Nicole; Troemel, Emily R (July 2024, Current Protocols)

   Abstract Orsay virus infection in the nematodeCaenorhabditis eleganspresents an opportunity to study host‐virus interactions in an easily culturable, whole‐animal host. Previously, a major limitation ofC. elegansas a model for studying antiviral immunity was the lack of viruses known to naturally infect the worm. With the 2011 discovery of the Orsay virus, a naturally occurring viral pathogen,C. eleganshas emerged as a compelling model for research on antiviral defense. From the perspective of the host, the genetic tractability ofC. elegansenables mechanistic studies of antiviral immunity while the transparency of this animal allows for the observation of subcellular processes in vivo. Preparing infective virus filtrate and performing infections can be achieved with relative ease in a laboratory setting. Moreover, several tools are available to measure the outcome of infection. Here, we describe workflows for generating infective virus filtrate, achieving reproducible infection ofC. elegans, and assessing the outcome of viral infection using molecular biology approaches and immunofluorescence. © 2024 The Authors. Current Protocols published by Wiley Periodicals LLC. Basic Protocol 1: Preparation of Orsay virus filtrate Support Protocol: SynchronizeC. elegansdevelopment by bleaching Basic Protocol 2: Orsay virus infection Basic Protocol 3: Quantification of Orsay virus RNA1/RNA2 transcript levels by qRT‐PCR Basic Protocol 4: Quantification of infection rate and fluorescence in situ hybridization (FISH) fluorescence intensity Basic Protocol 5: Immunofluorescent labeling of dsRNA in virus‐infected intestinal tissue 

   more » « less
4. Glial expression of a steroidogenic enzyme underlies natural variation in hitchhiking behavior

   https://doi.org/10.1073/pnas.2320796121  

   Yang, Heeseung; Lee, Daehan; Kim, Heekyeong; Cook, Daniel E; Paik, Young-Ki; Andersen, Erik C; Lee, Junho (July 2024, Proceedings of the National Academy of Sciences)

   Phoresy is an interspecies interaction that facilitates spatial dispersal by attaching to a more mobile species. Hitchhiking species have evolved specific traits for physical contact and successful phoresy, but the regulatory mechanisms involved in such traits and their evolution are largely unexplored. The nematodeCaenorhabditis elegansdisplays a hitchhiking behavior known as nictation during its stress-induced developmental stage. Dauer-specific nictation behavior has an important role in naturalC. eleganspopulations, which experience boom-and-bust population dynamics. In this study, we investigated the nictation behavior of 137 wildC. elegansstrains sampled throughout the world. We identified species-wide natural variation in nictation and performed a genome-wide association mapping. We show that the variants in the promoter ofnta-1, encoding a putative steroidogenic enzyme, underlie differences in nictation. This difference is due to the changes innta-1expression in glial cells, which implies that glial steroid metabolism regulates phoretic behavior. Population genetic analysis and geographic distribution patterns suggest that balancing selection maintained twonta-1haplotypes that existed in ancestralC. eleganspopulations. Our findings contribute to further understanding of the molecular mechanism of species interaction and the maintenance of genetic diversity within natural populations. 

   more » « less
5. The Vibrio type VI secretion system induces intestinal macrophage redistribution and enhanced intestinal motility

   https://doi.org/10.1128/mbio.02419-24  

   Ngo, Julia S; Amitabh, Piyush; Sokoloff, Jonah G; Trinh, Calvin; Wiles, Travis J; Guillemin, Karen; Parthasarathy, Raghuveer (January 2025, mBio)

   Graf, Joerg (Ed.)

   Intestinal microbes, whether resident or transient, influence the physiology of their hosts, altering both the chemical and the physical characteristics of the gut. An example of the latter is the human pathogenVibrio cholerae’sability to induce strong mechanical contractions, discovered in zebrafish. The underlying mechanism has remained unknown, but the phenomenon requires the actin crosslinking domain (ACD) ofVibrio’s type VI secretion system (T6SS), a multicomponent protein syringe that pierces adjacent cells and delivers toxins. By using a zebrafish-nativeVibrioand imaging-based assays of host intestinal mechanics and immune responses, we find evidence that macrophages mediate the connection between the T6SS ACD and intestinal activity. Inoculation withVibriogives rise to strong, ACD-dependent, gut contractions whose magnitude resembles those resulting from genetic depletion of macrophages.Vibrioalso induces tissue damage and macrophage activation, both ACD-dependent, recruiting macrophages to the site of tissue damage and away from their unperturbed positions near enteric neurons that line the midgut and regulate intestinal motility. Given known crosstalk between macrophages and enteric neurons, our observations suggest that macrophage redistribution forms a key link betweenVibrioactivity and intestinal motility. In addition to illuminating host-directed actions of the widespread T6SS protein apparatus, our findings highlight how localized bacteria-induced injury can reshape neuro-immune cellular dynamics to impact whole-organ physiology. IMPORTANCEGut microbes, whether beneficial, harmful, or neutral, can have dramatic effects on host activities. The human pathogenVibrio choleraecan induce strong intestinal contractions, though how this is achieved has remained a mystery. Using a zebrafish-nativeVibrioand live imaging of larval fish, we find evidence that immune cells mediate the connection between bacteria and host mechanics. A piece ofVibrio’s type VI secretion system, a syringe-like apparatus that stabs cellular targets, induces localized tissue damage, activating macrophages and drawing them from their normal residence near neurons, whose stimulation of gut contractions they dampen, to the damage site. Our observations reveal a mechanism in which cellular rearrangements, rather than bespoke biochemical signaling, drives a dynamic neuro-immune response to bacterial activity. 

   more » « less