The animal plasma membrane is a semi-fluid structural platform that maintains cellular homeostasis by regulating the passage of ions and small molecules in and out of the cell and modulating cell signaling activities. Disruption of its barrier function via mechanical damage or perforation by a pore-forming toxin is quickly followed by a sudden influx of extracellular Ca2+, which triggers efficient plasma membrane repair processes, the mechanisms of which are, to date, not fully elucidated. Efforts to understand cellular responses to plasma membrane damage have resulted in several non-mutually exclusive models of repair, each realized by the use of various cell types damaged using approaches that attempt to replicate normal physiological damage (mechanical, osmotic, and sheer stress) or damage that occurs under infectious conditions (bacterial pore-forming toxins). In the context of infection, evolutionarily distinct pathogens including the parasite Trypanosoma cruzi, the Gram-positive bacterium Listeria monocytogenes, and the non-enveloped Adenovirus have been shown to damage the plasma membrane of non-professional phagocytic cells in order to co-opt the subsequent cellular responses to facilitate their entry into target cells. It was concluded that T. cruzi and Adenovirus mechanically damage or perforate the host cell plasma membrane in order to co-opt a Ca2+ influx-dependent repair mechanism involving the exocytosis of lysosomes, release of acid sphingomyelinase, invagination of the host plasma membrane and endocytosis of the invading pathogen along with the damaged membrane. It was revealed that addition of the cholesterol-dependent cytolysin (CDC) pore-forming toxin Streptolysin O, which forms ~30 nm diameter proteinaceous pores in cholesterol-containing membranes, could further facilitate the efficient entry of these pathogens. Studies using the related CDC pore-forming toxin listeriolysin O (LLO) showed that L. monocytogenes entry into hepatocyte epithelial cells also requires Ca2+ influx subsequent to LLO-mediated perforation of the target cell suggesting that like T. cruzi and Adenovirus, L. monocytogenes could co-opt the repair machinery to gain entry. Using a combination of biochemical assays and live-cell fluorescence resonance energy transfer imaging, we found that LLO-mediated plasma membrane perforation and influx of extracellular Ca2+ activates a signal cascade involving the recruitment and activation of a conventional protein kinase C at the plasma membrane, activation of the central actin regulator, the Rho GTPase Rac1, and induction of Arp2/3-dependent F-actin polymerization leading to bacterial internalization. Inhibition of the cPKC/Rac1/Arp2/3 pathway prevents L. monocytogenes entry, but does not prevent membrane resealing, revealing that, in contract to the mechanism of entry of T. cruzi and Adenovirus, LLO-dependent L. monocytogenes endocytosis is distinct from the resealing machinery. An additional focus of this work has been on unifying the mutually non-exclusive models of plasma membrane repair, which include the Patch hypothesis, lysosomal exocytosis and subsequent endocytosis, exosome release, and ectocytosis/microvesicle shedding. Much of the pioneering work that led to these models required the use of morphologically unique cells (Xenopus laevis oocytes, sea urchin eggs, squid giant axons) damaged via microneedle puncture, laser ablation, or transection techniques. Further studies using various somatic mammalian cells including myocytes, neurons, epithelial and endothelial cells damaged via mechanical or sheer stress, or exposed to pore-forming toxins have also led to the identification of numerous proteins involved in the resealing process, many of which are cell type specific. The goal of this work was to provide a platform in which to study plasma membrane resealing in any cell type in a high-throughput manner in order to a) quantify the efficiency of resealing, b) identify new proteins involved in the resealing process, c) determine any overlap across different cell types, and d) unify the various models or resealing into a global system of repair mechanisms. Here we describe a high-throughput microplate-based assay to quantify the membrane resealing efficiency of cells exposed to the pore-forming toxin listeriolysin O using a spectrofluorometric plate reader. Additionally, image cytometry was incorporated to automatically enumerate target cells expressing nuclear localized histone 2B-GFP (HeLa H2B-GFP) before and after damage to account for differences in cell counts due to damage-induced cell detachment. Lastly, as a proof of concept, a siRNA library covering 287 gene targets involved in membrane trafficking, autophagy, lysosome biogenesis and function, ectocytosis, and cytoskeletal dynamics was used to identify proteins involved in the resealing of LLO-perforated HeLa cells. 26/287 knockdown conditions caused a defect in repair, which correspond to clathrin-mediated endocytosis (adaptor related proteins, dynamin), vesicular fusion and fission (Rab, SNARE, and exocyst proteins), plasma membrane stabilization (Annexins), and vesicle packaging (COP and ESCRT proteins). Surprisingly 19/287 knockdown conditions actually improved repair indicating that plasma membrane repair can potentially be negatively regulated. These preliminary findings confirmed the applicability of our high-throughput assay in identifying proteins involved in plasma membrane repair, but confirmation screens, pathway analyses, use of different cell types and damaging conditions are still required to meet the goals of this work.