Genetic and genome-wide RNAi approaches available in C. elegans, combined with tools for visualizing subcellular events with high-resolution, have led to increasing adoption of the early C. elegans embryo as a model for mechanistic and functional genomic analysis of cellular processes. However, a limitation of this system has been the impermeability of the embryo eggshell, which has prevented the routine use of small molecule inhibitors. Here, we present a method to permeabilize and immobilize embryos for acute inhibitor treatment in conjunction with live imaging. To identify a means to permeabilize the eggshell, we used a dye uptake assay to screen a set of 310 candidate genes defined by a combination of bioinformatic criteria. This screen identified 20 genes whose inhibition resulted in >75% eggshell permeability, and 3 that permeabilized embryos with minimal deleterious effects on embryo production and early embryonic development. To mount permeabilized embryos for acute drug addition in conjunction with live imaging, we combined optimized inhibition of one of these genes with the use of a microfabricated chamber that we designed. We demonstrate that these two developments enable the temporally controlled introduction of inhibitors for mechanistic studies. This method should also open new avenues of investigation by allowing profiling and specificity-testing of inhibitors through comparison with genome-wide phenotypic datasets.
References
[1]
Hyman AA, White JG (1987) Determination of cell division axes in the early embryogenesis of Caenorhabditis elegans. J Cell Biol 105: 2123–2135.
[2]
Hill DP, Strome S (1990) Brief cytochalasin-induced disruption of microfilaments during a critical interval in 1-cell C. elegans embryos alters the partitioning of developmental instructions to the 2-cell embryo. Development 108: 159–172.
[3]
Edgar LG (1995) Blastomere culture and analysis. Methods Cell Biol 48: 303–321.
[4]
Rappleye CA, Tagawa A, Lyczak R, Bowerman B, Aroian RV (2002) The anaphase-promoting complex and separin are required for embryonic anterior-posterior axis formation. Dev Cell 2: 195–206.
[5]
Green RA, Kao HL, Audhya A, Arur S, Mayers JR, et al. (2011) A High-Resolution C. elegans Essential Gene Network Based on Phenotypic Profiling of a Complex Tissue. Cell 145: 470–482.
[6]
Benenati G, Penkov S, Muller-Reichert T, Entchev EV, Kurzchalia TV (2009) Two cytochrome P450s in Caenorhabditis elegans are essential for the organization of eggshell, correct execution of meiosis and the polarization of embryo. Mech Dev 126: 382–393.
[7]
Lee MH, Schedl T (2001) Identification of in vivo mRNA targets of GLD-1, a maxi-KH motif containing protein required for C. elegans germ cell development. Genes Dev 15: 2408–2420.
[8]
Oishi K, Okano H, Sawa H (2007) RMD-1, a novel microtubule-associated protein, functions in chromosome segregation in Caenorhabditis elegans. J Cell Biol 179: 1149–1162.
[9]
Olson SK, Bishop JR, Yates JR, Oegema K, Esko JD (2006) Identification of novel chondroitin proteoglycans in Caenorhabditis elegans: embryonic cell division depends on CPG-1 and CPG-2. J Cell Biol 173: 985–994.
[10]
Rappleye CA, Tagawa A, Le Bot N, Ahringer J, Aroian RV (2003) Involvement of fatty acid pathways and cortical interaction of the pronuclear complex in Caenorhabditis elegans embryonic polarity. BMC Dev Biol 3: 8.
[11]
Lee JY, Goldstein B (2003) Mechanisms of cell positioning during C. elegans gastrulation. Development 130: 307–320.
[12]
Schierenberg E, Junkersdorf B (1992) The role of eggshell and underlying vitelline membrane for normal pattern formation in the early C. elegans embryo. Roux's Arch Dev Biol 202: 10–16.
[13]
Reinke V, Gil IS, Ward S, Kazmer K (2004) Genome-wide germline-enriched and sex-biased expression profiles in Caenorhabditis elegans. Development 131: 311–323.
[14]
Reinke V, Smith HE, Nance J, Wang J, Van Doren C, et al. (2000) A global profile of germline gene expression in C. elegans. Mol Cell 6: 605–616.
[15]
Kamath RS, Fraser AG, Dong Y, Poulin G, Durbin R, et al. (2003) Systematic functional analysis of the Caenorhabditis elegans genome using RNAi. Nature 421: 231–237.
[16]
Kartalov EP, Walker C, Taylor CR, Anderson WF, Scherer A (2006) Microfluidic vias enable nested bioarrays and autoregulatory devices in Newtonian fluids. Proc Natl Acad Sci U S A 103: 12280–12284.
