Optimization of the Hemolysis Assay for the Assessment of Cytotoxicity.

In vitro determination of hemolytic properties is a common and important method for preliminary evaluation of cytotoxicity of chemicals, drugs, or any blood-contacting medical device or material. The method itself is relatively straightforward, however, protocols used in the literature vary substantially. This leads to significant difficulties both in interpreting and in comparing the obtained values. Here, we examine how the different variables used under different experimental setups may affect the outcome of this assay. We find that certain key parameters affect the hemolysis measurements in a critical manner. The hemolytic effect of compounds tested here varied up to fourfold depending on the species of the blood source. The use of different types of detergents used for generating positive control samples (i.e., 100% hemolysis) produced up to 2.7-fold differences in the calculated hemolysis ratios. Furthermore, we find an expected, but substantial, increase in the number of hemolyzed erythrocytes with increasing erythrocyte concentration and with prolonged incubation time, which in turn affects the calculated hemolysis ratios. Based on our findings we propose an optimized protocol in an attempt to standardize future hemolysis studies.

Survival of Escherichia coli after high-antibiotic stress is dependent on both the pregrown physiological state and incubation conditions.

Introduction: The survival of bacterial cells exposed to antibiotics depends on the mode of action, the antibiotics concentration, and the duration of treatment. However, it also depends on the physiological state of the cells and the environmental conditions. In addition, bacterial cultures contain sub-populations that can survive high antibiotic concentrations, so-called persisters. Research on persisters is challenging due to multiple mechanisms for their formation and low fractions, down to and below one millionth of the total cell population. Here, we present an improved version of the persister assay used to enumerate the amount of persisters in a cell population. Methods: The persister assay with high antibiotic stress exposure was performed at both growth supporting and non-supporting conditions. Escherichia coli cells were pregrown to various growth stages in shake flasks and bench-top bioreactors. In addition, the physiological state of E. coli before antibiotic treatment was determined by quantitative mass spectrometry-based metabolite profiling. Results: Survival of E. coli strongly depended on whether the persister assay medium supported growth or not. The results were also highly dependent on the type of antibiotic and pregrown physiological state of the cells. Therefore, applying the same conditions is critical for consistent and comparable results. No direct connection was observed between antibiotic efficacy to the metabolic state. This also includes the energetic state (i.e., the intracellular concentration of ATP and the adenylate energy charge), which has earlier been hypothesized to be decisive for persister formation. Discussion: The study provides guides and suggestions for the design of future experimentation in the research fields of persisters and antibiotic tolerance.

Antimicrobial resistance: A challenge awaiting the post-COVID-19 era.

Microbe exposure to pharmaceutical and non-pharmaceutical agents plays a role in the development of antibiotic resistance. The risks and consequences associated with extensive disinfectant use during the COVID-19 pandemic remain unclear. Some disinfectants, like sanitizers, contain genotoxic chemicals that damage microbial DNA, like phenol and hydrogen peroxide. This damage activates error-prone DNA repair enzymes, which can lead to mutations that induce antimicrobial resistance. Public health priority programs that have faced drug-resistance challenges associated with diseases, such as tuberculosis, HIV, and malaria, have given less attention to risks attributable to the COVID-19 pandemic. Pathogen-specific programs, like the directly observed treatment strategy designed to fight resistance against anti-tuberculosis drugs, have become impractical because COVID-19 restrictions have limited in-person visits to health institutions. Here, we summarized the key findings of studies on the current state of antimicrobial resistance development from the perspective of current disinfectant use. Additionally, we provide a brief overview of the consequences of restricted access to health services due to COVID-19 precautions and their implications on drug resistance development.

Cellular responses to targeted genomic sequence modification using single-stranded oligonucleotides and zinc-finger nucleases.

Single-stranded oligonucleotides (ssODNs) and zinc-finger nucleases (ZFNs) are two approaches that are being pursued to achieve sequence specific genome modification. ZFNs induce high rates of homologous recombination (HR) between the target sequence and a given donor by introducing site-specific genomic double-strand breaks (DSBs). The mode of action that is used by ssODNs remains largely unknown, but may involve genomic integration of the ssODNs. In this work, cellular responses following ssODN and ZFN mediated correction of a genomic reporter gene have been investigated in human cells. Comparison of the cell cycle distribution of corrected cells following ssODN or ZFN exposure, established that ssODN corrected cells were arrested in the late S and G2/M cell cycle phases, while ZFN corrected cells displayed normal cell cycle profiles. We demonstrate that after ssODN mediated gene correction, phosphorylation of the damage sensor protein H2AX could be observed in 5.8% and 29% of the corrected cells, using a single copy and a multi copy reporter, respectively. When using the ZFN strategy in a single copy reporter only 1.5% of the corrected cells were positive for gamma-H2AX staining. By direct detection of genomic DSBs we establish that the observed cell cycle arrest following ssODN mediated gene correction could be associated with the presence of unrepaired genomic DSBs. Lastly, we establish that although a mutant cellular mismatch repair (MMR) system as expected enhanced ssODN mediated gene correction, the capacity of the ssODN corrected cells to proliferate was not influenced by the MMR system. In conclusion gene correction by means of the ssODN strategy leads to activation of DNA damage signalling and cell cycle arrest due to formation of unrepaired genomic DSBs in a high proportion of the corrected cells. On the contrary, cells corrected using ZFNs displayed normal cell cycle distribution and lower rates of DNA damage.

Antibiotic-induced DNA damage results in a controlled loss of pH homeostasis and genome instability.

Extracellular pH has been assumed to play little if any role in how bacteria respond to antibiotics and antibiotic resistance development. Here, we show that the intracellular pH of Escherichia coli equilibrates to the environmental pH following treatment with the DNA damaging antibiotic nalidixic acid. We demonstrate that this allows the environmental pH to influence the transcription of various DNA damage response genes and physiological processes such as filamentation. Using purified RecA and a known pH-sensitive mutant variant RecA K250R we show how pH can affect the biochemical activity of a protein central to control of the bacterial DNA damage response system. Finally, two different mutagenesis assays indicate that environmental pH affects antibiotic resistance development. Specifically, at environmental pH's greater than six we find that mutagenesis plays a significant role in producing antibiotic resistant mutants. At pH's less than or equal to 6 the genome appears more stable but extensive filamentation is observed, a phenomenon that has previously been linked to increased survival in the presence of macrophages.