Schwartz LM et al. (1994) Bioessays "Ced-3/ICE: evolutionarily conserved regulation of cell death."

Osborne BA, Schwartz LM

[Bioessays, 1994]

If treated harshly, any cell can be induced to die. These pathological deaths typically occur by necrosis, a passive process that involves membrane disruption, cellular swelling and ultimately, cellular lysis. Less well appreciated is the observation that many, if not most, of the cells that die during an organism's life, commit suicide. Instead of swelling, these cells become condensed and in most cases, undergo stereotypic changes in their surface and nuclear morphology that has been termed apoptosis . Another feature of most apoptotic deaths, is the double-stranded cleavage of genomic DNA by an endogenous DNAse . Interestingly, not all cells that undergo programmed cell death exhibit these apoptotic

Sivaranjani M et al. (2016) Int J Food Microbiol "Morin inhibits biofilm production and reduces the virulence of Listeria monocytogenes - An in vitro and in vivo approach."

Ravi AV, Balamurugan K, Kamaladevi A, Sivaranjani M, Pandian SK, Gowrishankar S

[Int J Food Microbiol, 2016]

The current study explores the in vitro and in vivo antibiofilm efficacy of morin against a leading foodborne pathogen-Listeria monocytogenes (LM). Minimum inhibitory concentration (MIC) of morin against LM strains was found to be 100g/ml. The non-antibacterial effect of morin at its sub-MICs (6.25, 12.5 and 25g/ml) was determined through growth curve and XTT assay. Morin at its sub-MICs demonstrated a significant dose dependent inhibitory efficacy against LM biofilm formation which was also evidenced through light, confocal and scanning electron microscopic analyses. However, morin failed to disperse the mature biofilm of LM even at its MIC. Our data also revealed the anti-virulence efficacy of morin, as it significantly inhibited the production of hemolysin and motility of LM. Concentration-dependent susceptibility of morin treated LM cells to normal human serum was observed. In vivo studies revealed that morin extended the lifespan of LM infected Caenorhabditis elegans by about 85%. Furthermore, the non-toxic nature and in vivo anti-adherence efficacy of morin were also ascertained through C. elegans-LM infection model. Overall, the data of the current study identifies morin as a promising antibiofilm agent and its suitability to formulate protective strategies against biofilm associated infections caused by LM.

Gowrishankar S et al. (2016) Pathog Dis "Cyclic dipeptide-cyclo(L-leucyl-L-prolyl) from marine Bacillus amyloliquefaciens mitigates biofilm formation and virulence in Listeria monocytogenes."

Pandian SK, Kamaladevi A, Ravi AV, Gowrishankar S, Balamurugan K, Sivaranjani M

[Pathog Dis, 2016]

The current study was intentionally focused on cyclo(L-leucyl- L-prolyl) (CLP)-a cyclic dipeptide with myriad pharmaceutical significance, to explore its antivirulence efficacy against the predominant food-borne pathogen-Listeria monocytogenes (LM). Minimum inhibitory concentration (MIC) of CLP against LM ATCC 19111 was found to be 512 g mL(-1). CLP at sub-MICs (64,128, 256 g mL(-1)) demonstrated a profound non-bactericidal dose-dependent antibiofilm efficacy (on polystyrene and glass) against LM, which was further confirmed through confocal and scanning electron microscopic analysis (on stainless steel surface). In vitro bioassays divulged the phenomenal inhibitory efficacy of CLP towards various virulence traits of LM, specifically its overwhelming suppression of swimming and swarming motility. Data of in vivo assay using Caenorhabditis elegans signified that the plausible mechanism of CLP could be by impeding the pathogen's initial adhesion and thereby attenuating the biofilm assemblage and its associated virulence. This was further confirmed by significant decrease in exopolymeric substance, auto-aggregation, hydrophobicity index and extracellular DNA (eDNA) of the CLP treated-LM cells. Collectively, the current study unveils the antivirulence efficacy of CLP against the Gram-positive food borne-pathogen and the strain Bacillus amyloliquifaciens augurs well to be a promising probiotic in controlling infections associated with LM.

Zhao P et al. (2023) Nat Methods "Femtosecond laser microdissection for isolation of regenerating C. elegans neurons for single-cell RNA sequencing."

Jiang N, Ma KY, Chizari S, Ben-Yakar A, DuPlissis A, Martin C, Mondal S, Messing RO, Maiya R, Zhao P

[Nat Methods, 2023]

Our understanding of nerve regeneration can be enhanced by delineating its underlying molecular activities at single-neuron resolution in model organisms such as Caenorhabditis elegans. Existing cell isolation techniques cannot isolate neurons with specific regeneration phenotypes from C. elegans. We present femtosecond laser microdissection (fs-LM), a single-cell isolation method that dissects specific cells directly from living tissue by leveraging the micrometer-scale precision of fs-laser ablation. We show that fs-LM facilitates sensitive and specific gene expression profiling by single-cell RNA sequencing (scRNA-seq), while mitigating the stress-related transcriptional artifacts induced by tissue dissociation. scRNA-seq of fs-LM isolated regenerating neurons revealed transcriptional programs that are correlated with either successful or failed regeneration in wild-type and dlk-1 (0) animals, respectively. This method also allowed studying heterogeneity displayed by the same type of neuron and found gene modules with expression patterns correlated with axon regrowth rate. Our results establish fs-LM as a spatially resolved single-cell isolation method for phenotype-to-genotype mapping.

Zhao, P. et al. (2019) International Worm Meeting "Femtosecond laser microdissection isolates single C. elegans neurons for nerve regeneration RNA-seq studies."

Kreeger, L., Arur, S., ZHAO, P., Ben-Yakar, A., Trimmer, K., Messing, R., Ma, K., Martin, C., Zemelman, B., Jiang, N., Maiya, R.

[International Worm Meeting, 2019]

C. elegans has become a versatile system for studying in vivo nerve regeneration since the advent of precise laser axotomy method for severing specific axons. Through mutant and RNAi screening, a number of regeneration regulator genes have been identified. Nevertheless, their downstream effectors remain elusive. As a complementary approach, we propose to perform single-cell RNA-sequencing on regrowing neurons to capture the genome-wide dynamics underlying nerve regeneration. However, it has been technically unfeasible to isolate regrowing neurons from living C. elegans. The prevalent isolation method uses FACS to sort neurons of interest from chemo-mechanically dissociated animals, thus requires thousands of animals with synchronized nerve injury, which cannot be obtained even with state-of-the-art automated microfluidic systems. We developed a new femtosecond laser microdissection (fs-LM) method to rapidly and precisely isolate single cells directly from living tissue or organisms by leveraging femtosecond laser ablation as a high-precision cutting tool. Compared to traditional laser capture microdissection, our method provides a few crucial advantages. 1) fs-LM yields intact single cells without sample sectioning, freezing, or fixing, thus preventing sample degradation or contamination. 2) compared to the dissociation and sorting method, fs-LM induces less stress response in isolated cells. 3) fs-LM preserves the spatial and phenotypic information of the collected neurons. In addition, by correlating gene expression to the context-dependent regeneration phenotypes, it is possible to further dissect the genetic activities encoding nerve regeneration. 4) fs-LM does can isolate unlabeled cells. We isolated regrowing posterior lateral microtubule (PLM) neurons from larval 4 stage animals. Single cell RNA-sequencing on the isolated neurons identified gene expression patterns underlying axon regeneration. To demonstrate the versatility of our method, we have also dissected and sequenced single C. elegans oocytes and mammalian brain neurons.

Schieber NL et al. (2017) Methods Cell Biol "Minimal resin embedding of multicellular specimens for targeted FIB-SEM imaging."

Markert SM, Schieber NL, Stigloher C, Schwab Y, Steyer AM, Machado P

[Methods Cell Biol, 2017]

Correlative light and electron microscopy (CLEM) is a powerful tool to perform ultrastructural analysis of targeted tissues or cells. The large field of view of the light microscope (LM) enables quick and efficient surveys of the whole specimen. It is also compatible with live imaging, giving access to functional assays. CLEM protocols take advantage of the features to efficiently retrace the position of targeted sites when switching from one modality to the other. They more often rely on anatomical cues that are visible both by light and electron microscopy. We present here a simple workflow where multicellular specimens are embedded in minimal amounts of resin, exposing their surface topology that can be imaged by scanning electron microscopy (SEM). LM and SEM both benefit from a large field of view that can cover whole model organisms. As a result, targeting specific anatomic locations by focused ion beam-SEM (FIB-SEM) tomography becomes straightforward. We illustrate this application on three different model organisms, used in our laboratory: the zebrafish embryo Danio rerio, the marine worm Platynereis dumerilii, and the dauer larva of the nematode Caenorhabditis elegans. Here we focus on the experimental steps to reduce the amount of resin covering the samples and to image the specimens inside an FIB-SEM. We expect this approach to have widespread applications for volume electron microscopy on multiple model organisms.

DeMott, Ella et al. (2021) MicroPubl Biol

Doonan, Ryan, DeMott, Ella, Dickinson, Daniel J

[MicroPubl Biol, 2021]

Plasmid-based CRISPR knock-in is a streamlined, scalable, and versatile approach for generating fluorescent protein tags in C. elegans (Dickinson et al. 2015; Schwartz and Jorgensen 2016). However, compared to more recent protocols that utilize commercially available Cas9/RNP products and linear DNA repair templates (Dokshin et al. 2018; Ghanta and Mello 2020), the cloning required for plasmid-based protocols has been cited as a drawback of this knock-in approach. Using thorough quantitative assessment, we have found that cloning efficiency can reproducibly reach 90% for the plasmids of the self-excising cassette (SEC) selection method, essentially resolving cloning as a burden for plasmid-based CRISPR knock-in.

Lucas MS et al. (2012) Methods Cell Biol "Bridging microscopes: 3D correlative light and scanning electron microscopy of complex biological structures."

Gasser P, Guenthert M, Lucas F, Lucas MS, Wepf R

[Methods Cell Biol, 2012]

The rationale of correlative light and electron microscopy (CLEM) is to collect data on different information levels--ideally from an identical area on the same sample--with the aim of combining datasets at different levels of resolution to achieve a more holistic view of the hierarchical structural organization of cells and tissues. Modern three-dimensional (3D) imaging techniques in light and electron microscopy opened up new possibilities to expand morphological studies into the third dimension at the nanometer scale and over various volume dimensions. Here, we present two alternative approaches to correlate 3D light microscopy (LM) data with scanning electron microscopy (SEM) volume data. An adapted sample preparation method based on high-pressure freezing for structure preservation, followed by freeze-substitution for multimodal en-bloc imaging or serial-section imaging is described. The advantages and potential applications are exemplarily shown on various biological samples, such as cells, individual organisms, human tissue, as well as plant tissue. The two CLEM approaches presented here are per se not mutually exclusive, but have their distinct advantages. Confocal laser scanning microscopy (CLSM) and focused ion beam-SEM (FIB-SEM) is most suitable for targeted 3D correlation of small volumes, whereas serial-section LM and SEM imaging has its strength in large-area or -volume screening and correlation. The second method can be combined with immunocytochemical methods. Both methods, however, have the potential to extract statistically relevant data of structural details for systems biology.

Carre-Pierrat M et al. (2010) Aging, Metabolism, Stress, Pathogenesis, and Small RNAs, Madison, WI "Caenorhabditis elegans as a screening tool to find active compounds and targets in rare neuromuscular diseases."

Carre-Pierrat M, Cisek J, Segalat L, Giacomotto J

[Aging, Metabolism, Stress, Pathogenesis, and Small RNAs, Madison, WI, 2010]

Current high-throughput screening methods for drug discovery rely upon the existence of targets and therefore on the understanding of the pathogenesis of a disease. In the case of diseases where the pathogenesis is not yet known, drug discovery is only feasible on model organisms mimicking the disease. The nematode Caenorhabditis elegans, which combines genetic amenability, low cost and easy culture conditions, is compatible with large-scale screens. Here, we report the results of screens of chemical libraries on Caenorhabditis elegans models of the Duchenne Muscular Dystrophy, the Spinal Muscular Amyotrophy and the Schwartz-Jampel syndrome. We present the methodology used for each model to screen up to 7,000 compounds and the results of these screening campaigns. We further present the validation of our best hits in mammalian models and try to understand their mechanism of action.

Dickinson DJ et al. (2018) MicroPubl Biol "SapTrap assembly of repair templates for Cas9-triggered homologous recombination with a self-excising cassette"

Goldstein B, Dickinson DJ, Chen AH, Slabodnick MM

[MicroPubl Biol, 2018]

The advent of CRISPR/Cas9 technology in C. elegans has enabled an unprecedented level of control over this organisms genome, which is facilitating research in a wide variety of fields. Several different experimental approaches exist for CRISPR in this organism (Dickinson and Goldstein 2016). One particularly powerful approach uses a drug selection with a Self-Excising Cassette (SEC) to isolate the desired genetically-modified animals following Cas9-triggered homologous recombination (Dickinson et al. 2015). The most labor-intensive step in this procedure is the construction of a plasmid-based repair template for homologous recombination. SapTrap (Schwartz and Jorgensen 2016) is a high-throughput cloning procedure that allows modular assembly of repair templates for CRISPR/Cas9-triggered homologous recombination. The original publication that described SapTrap cloning (Schwartz and Jorgensen 2016) used unc-119(+) as a positive selection marker for isolating recombinant strains. Compared to unc-119 selection, SEC selection is faster; can be used directly in a wild-type background; and eliminates an extra injection step followed by outcrossing to remove the selection markers after strain isolation (Dickinson et al. 2015). Because of these advantages of SEC selection over unc-119, we wished to incorporate the SEC into the SapTrap workflow. Here, we describe a toolkit of plasmids that allow building SEC-containing repair templates via SapTrap cloning.In brief, SapTrap links pieces of a repair template construct together by means of unique 3-bp overlaps generated by the type II restriction enzyme SapI. Constructs generated using SapTrap have the general form shown in Figure 1A. In a typical assembly reaction, the sgRNA target is provided as a pair of oligos, the homology arms are provided as PCR products, and a Fluorescent Protein (FP), SEC and linker fragments are provided by pre-existing donor vectors. These fragments are mixed together, along with the requisite enzymes, and are assembled in a single reaction. The linkers can be omitted from the final construct if desired, by designing the homology arms with 3-bp overlaps that anneal directly to the FP or SEC instead of to the linker.Using SapTrap to generate repair templates for SEC selection involves two modifications to the original approach described by Schwartz and Jorgensen. First, an AAG junction is added between the FP and SEC fragments (Figure 1A). Together, these two fragments replace the FP/unc-119(+) donors used by the Jorgensen lab. Second, it is important to ensure that a coding exon follows SEC in order to avoid nonsense-mediated decay. For this reason, we always include the NT-tag linker in our constructs, even for C-terminal tags. We generated and tested fluorescent protein donors covering the current best available fluorescent proteins for C. elegans imaging (Heppert et al. 2016 and our unpublished observations) along with SEC donors containing three different Lox sites that do not recombine with each other, for multiplex editing. These constructs have been deposited at Addgene and are listed in Table 1.Using various combinations of fluorescent protein, SEC and linker donors, we were routinely able to obtain the desired repair templates, although the cloning efficiency was lower compared to the ccdB/Gibson-based cloning approach described by Dickinson et al. (2015) (Figure 1B). Note that, for both the Gibson and SapTrap data reported in Figure 1B, we used PCR products 500-700 bp in length as the homology arms, enabling a direct comparison of the two cloning methods. We have not tested short homology arms formed from annealed oligonucleotides, which were used by Schwartz and Jorgensen (2016), with either cloning approach. Based on our extensive experience with both SapTrap and the ccdB/Gibson-based cloning procedure, we believe that each procedure has advantages. The advantages of SapTrap are:SapTrap is more modular: different fluorophores, epitope tags, and selection cassettes can be freely combined without the need to construct a new FPSEC vector each time.SapTrap does not require the use of ccdB-containing vectors, which are toxic to E. coli and therefore can be difficult to grow and maintain.