Cytometry of apoptosis. Historical perspective and new advances

Characteristic changes in cell morphology paralleled by the appearance of a multitude of molecular and biochemical markers occur during apoptosis. These changes vary depending on the cell type, mechanism of induction of apoptosis, and the time-window at which the process of apoptosis is analyzed. By virtue of the capability of rapid measurement of individual cells the flow- and imaging-cytometry become preferred technologies to detect, identify and record incidence of apoptosis in large cell populations. It also provided a valuable tool to investigate molecular mechanisms in field of necrobiology. This review outlines the progress in development of the most commonly used cytometric methods probing cells death based on analysis of fragmentation of DNA, activation of caspases, analysis of mitochondrial potential, alterations in plasma membrane structure and other features that characterize programmed cell death. This article is part of a Special Issue entitled “Apoptosis: Four Decades Later

Cell Growth Measurement

The cell is the basic structural and functional unit of all living organisms. As the smallest unit and building blocks of life, cells differ in size, shape, metabolism, reproduction, and growth requirements. Cells reproduce through cell division involving a four-phase (G1, S, G2, M) cell cycle, which is tightly regulated at multiple checkpoints. The resulting growth curve demonstrates that cell population increases in three sequential steps: incubation, exponential hyperplasia, and stagnation/death phases. Cell growth is subject to changes in disease state and/or environmental conditions. This chapter will focus on methods for cell growth measurement, which are grouped into five sections: cell cycle, apoptosis, growth curve, drug-induced proliferation (DIP), and continuous assays. Among the continuous assays, the EZMTT dye allows for long-term tracking of cell growth under various conditions and shows promise in precision medicine by early detection of drug resistance

NAPO as a novel marker for apoptosis

Apoptosis or programmed cell death plays a pivotal role in embryonic development and maintenance of homeostasis. It is also involved in the etiology of pathophysiological conditions such as cancer, neurodegenerative, autoimmune, infectious, and heart diseases. Consequently, the study of apoptosis is now at center of both basic and clinical research applications. Therefore, sensitive and simple apoptosis detection techniques are required. Here we describe a monoclonal antibody–defined novel antigen, namely NAPO (negative in apoptosis), which is specifically lost during apoptosis. The anti-NAPO antibody recognizes two nuclear polypeptides of 60 and 70 kD. The antigen is maintained in quiescent and senescent cells, as well as in different phases of the cell cycle, including mitosis. Thus, immunodetection of NAPO antigen provides a specific, sensitive, and easy method for differential identification of apoptotic and nonapoptotic cells

Apoptosis and necrosis: Mechanisms of cell death induced by cyclosporine A in a renal proximal tubular cell line

Apoptosis and necrosis: Mechanisms of cell death induced by cyclosporine A in a renal proximal tubular cell line.BackgroundThe mechanisms of cyclosporine (CsA)-induced nephrotoxicity are not fully understood. While hemodynamic changes may be involved in vivo, there is also some evidence for tubular involvement. We previously showed direct toxicity of CsA in the LLC-PK1 renal tubular cell line. In the current study we examined mechanisms (apoptosis or necrosis) of cell death induced by CsA in the LLC-PK1 renal proximal tubular cell line. The possible role of the Fas (APO-1/CD95) antigen-Fas ligand system in the mediation of CsA-induced cell death was also investigated.MethodsCells were treated with CsA (0.42nm to 83 μm) for 24hours and alterations in DNA and protein synthesis and membrane integrity were examined. Flow cytometry was used to investigate: (i) alterations in the DNA content and cell cycle; (ii) the forward (FSC) and side (SSC) light scattering properties (indicators of cell size and granularity, respectively); (iii) the externalization of phosphatidylserine (PS) as a marker of early apoptosis using FITC-annexin V binding; and (iv) expression of the apoptotic Fas protein. DNA fragmentation in apoptotic cells was also determined by the TUNEL assay.ResultsCsA (all doses) caused a block in the G0/G1 phase of the cell cycle as indicated by a decrease in DNA synthesis and supported by an increase in the % of cells in the G0/G1 phase with concurrent decreases of those in the S and G2/M phases. The effect on protein synthesis appeared to be much less. Lower doses of CsA (4.2nm) caused the appearance of a “sub-G0/G1” peak, indicative of reduced DNA content, on the DNA histogram that was paralleled by a reduction in cell size and an increased cell granularity and an increase in FITC-annexin V binding. DNA fragmentation was evident in these cells as assessed using the TUNEL assay. Higher doses of CsA increased cell size and decreased cell granularity and reduced membrane integrity. Expression of Fas, the cell surface molecule that stimulates apoptosis, was increased following low dose CsA exposure.ConclusionsThese results indicate that CsA is directly toxic to LLC-PK1 cells with reduced DNA synthesis and cell cycle blockade. The mode of cell death, namely apoptosis or necrosis, is dose dependent. Fas may be an important mediator of CsA induced apoptosis in renal proximal tubular cells

Types, causes, detection and repair of DNA fragmentation in animal and human sperm cells

Concentration, motility and morphology are parameters commonly used to determine the fertilization potential of an ejaculate. These parameters give a general view on the quality of sperm but do not provide information about one of the most important components of the reproductive outcome: DNA. Either single or double DNA strand breaks can set the difference between fertile and infertile males. Sperm DNA fragmentation can be caused by intrinsic factors like abortive apoptosis, deficiencies in recombination, protamine imbalances or oxidative stress. Damage can also occur due to extrinsic factors such as storage temperatures, extenders, handling conditions, time after ejaculation, infections and reaction to medicines or post-testicular oxidative stress, among others. Two singular characteristics differentiate sperm from somatic cells: Protamination and absence of DNA repair. DNA repair in sperm is terminated as transcription and translation stops post-spermiogenesis, so these cells have no mechanism to repair the damage occurred during their transit through the epididymis and post-ejaculation. Oocytes and early embryos have been shown to repair sperm DNA damage, so the effect of sperm DNA fragmentation depends on the combined effects of sperm chromatin damage and the capacity of the oocyte to repair it. In this contribution we review some of these issuesThis review was supported by the project BFU2010-1673

Sequential events of apoptosis involving docetaxel, a microtubule-interfering agent: A cytometric study

BACKGROUND: Despite the great advances in the understanding of programmed cell death, little attention has been paid to the sequence of the events that characterise it. In particular, the course of apoptotic events induced by microtubule-interfering agents such as taxanes is poorly understood. In order to increase such knowledge, we studied a number of independent biochemical and cytological modifications using cytometric methods in a bladder cancer cell line treated with the second generation taxane, docetaxel. RESULTS: Within a few hours, drug treatment had induced mitochondrial membrane transition, cell shrinkage and a decrease in granularity. Cell cycle was almost completely blocked in G(2)/M phase within 24 hours. The hypodiploid peak started to become prominent 48 hours after the treatment. At the same time, the appearance of a DNA ladder demonstrated caspase-dependent chromatin fragmentation. Concurrently, specific cell surface modifications took place, involving at first glycoprotein syalilation and later phospholipid asymmetry. DNA fragmentation was subsequently detected by TUNEL assay. Over time, cell membranes became permeable to propidium iodide. A very similar time-course of apoptotic events was found after treatment of a myelomonocytic cell line with the same drug. CONCLUSION: After discussing some characteristics of the methods employed and their limitations, a succession of apoptotic events over time is suggested, in which the collapse of mitochondrial transmembrane potential (Δψm) is the earliest sign of apoptosis

Discriminating Between Apoptosis, Necrosis, Necroptosis, and Ferroptosis by Microscopy and Flow Cytometry

Funding Information: The Martin laboratory is supported by an ERC Advanced grant (101020534, DESTRESS) as well as an Irish Research Council Advanced Laureate Award (IRCLA/2019/133). The Hollville laboratory is supported by a Royal Society Research grant (RG16955).Peer reviewedPublisher PD