Neutrophils are the most abundant white blood cells in circulation, and patients with congenital neutrophil deficiencies suffer from severe infections that are often fatal, underscoring the importance of these cells in immune defense. In spite of neutrophils' relevance in immunity, research on these cells has been hampered by their experimentally intractable nature. Here, we present a survey of basic neutrophil biology, with an emphasis on examples that highlight the function of neutrophils not only as professional killers, but also as instructors of the immune system in the context of infection and inflammatory disease. We focus on emerging issues in the field of neutrophil biology, address questions in this area that remain unanswered, and critically examine the experimental basis for common assumptions found in neutrophil literature.
Neutrophil elastase escapes azurophilic granules, translocates to the nucleus, and degrades histones to promote chromatin decondensation necessary for NET formation.
IntroductionMyeloperoxidase (MPO) is one of the most abundant proteins in neutrophils, accounting for 5% of the dry weight of the cell. 1 Stored in the azurophilic granules and released when neutrophils are stimulated, MPO catalyzes the oxidation of chloride and other halide ions in the presence of hydrogen peroxide 2,3 to generate hypochlorous acid and other highly reactive products that mediate efficient antimicrobial action. 4,5 Several inherited mutations and deletions in the gene encoding MPO result in decreased enzyme production and activity. 6,7 Using automated hematological devices, clinicians can distinguish between partial and complete MPO deficiencies. 8 MPO deficiency is reported to have an incidence of 1 in 2000-4000 in the United States and Europe and 1 in 55 000 in Japan. 9-13 Candida infections are common in MPO-deficient patients, especially in those that also develop diabetes. 9,14-18 Occasionally, serious infectious or inflammatory complications have been observed in completely MPOdeficient patients as well. 8 Consistently, MPO knockout mice are susceptible to particular bacterial and fungal infections. 19 Neutrophil extracellular traps (NETs) are part of the neutrophil response to microbes. Activated neutrophils die and release these structures composed of decondensed chromatin and antimicrobial proteins 20,21 that trap and inhibit a broad range of microbes. 22 Little is known about the molecular mechanism that regulates NET formation, making the antimicrobial role of NETs in vivo difficult to assess.Interestingly, neutrophils from chronic granulomatous disease (CGD) patients fail to make NETs. 20 CGD is caused by mutations that disrupt the ability of the nicotinamide adenine dinucleotide phosphate (NADPH) oxidase to generate superoxide, which dismutates to hydrogen peroxide, the substrate of MPO. CGD patients are prone to recurrent and severe infections, as well as to persistent inflammation that can occur independently of infection. [23][24][25] NET formation by CGD neutrophils is restored by the addition of exogenous hydrogen peroxide, indicating that reactive oxygen species are required for NET formation. 20 Here we show that MPO is necessary for making NETs and suggest that defective NET formation may undermine host defense in patients lacking MPO. Methods Donor consentAll donors gave consent to blood drawing in accordance with the Declaration of Helsinki and to functional and genetic analysis. Samples were collected with approval from the ethical committees at each institution. Neutrophil isolationNeutrophils were isolated by centrifuging heparinized venous blood over Histopaque 1119 (Sigma-Aldrich) and subsequently over a discontinuous Percoll (Amersham Biosciences) gradient as described previously. 20 Cells were stored in Hank buffered salt solution (-) or Dulbecco phosphatebuffered saline (-), without calcium or magnesium, before experiments. NET formation and visualizationNeutrophils (5 ϫ 10 4 ) were seeded per well in 24-well tissue culture plates, in Hanks buffered salt solution (...
SummaryNeutrophils contain granules loaded with antimicrobial proteins and are regarded as impermeable organelles that deliver cargo via membrane fusion. However, during the formation of neutrophil extracellular traps (NETs), neutrophil elastase (NE) translocates from the granules to the nucleus via an unknown mechanism that does not involve membrane fusion and requires reactive oxygen species (ROS). Here, we show that the ROS triggers the dissociation of NE from a membrane-associated complex into the cytosol and activates its proteolytic activity in a myeloperoxidase (MPO)-dependent manner. In the cytosol, NE first binds and degrades F-actin to arrest actin dynamics and subsequently translocates to the nucleus. The complex is an example of an oxidative signaling scaffold that enables ROS and antimicrobial proteins to regulate neutrophil responses. Furthermore, granules contain protein machinery that transports and delivers cargo across membranes independently of membrane fusion.
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