A redox-based characterization of human immune cell subsets by polychromatic flow cytometry.

Cellular redox state determinants are traditionally studied using fluorescent microscopy and immunoblot analysis; however, no procedure has been developed for simultaneous measurement in various immune cell subsets. Here, we present a flow cytometry assay for measuring antioxidant defense systems and reactive oxygen species simultaneously in T, B, and natural killer lymphocytes. We describe steps for preparing and treating peripheral blood mononuclear cells, surface and dye staining, cell fixation/permeabilization, and intracellular staining. We then detail machine standardization, acquisition, and analysis.

AQP8 transports NOX2-generated H2O2 across the plasma membrane to promote signaling in B cells.

H2O2 acts as a second messenger in key signaling circuits, transiently modulating tyrosine phosphatases and kinases. We investigated its origin, membrane transport, and functional role during B cell activation and differentiation. Our data identified NADPH-oxidase 2 as the main source of H2O2 and aquaporin 8 as a transport facilitator across the plasma membrane. On aquaporin 8 silencing, inducible B lymphoma cells responded poorly to TLR and BCR stimulation. Their differentiation was severely impaired, as demonstrated by retarded onset of IgM polymerization, low amounts of IgM secretion, and prolonged BCR expression on the cell surface. A silencing-resistant aquaporin 8 rescued responsiveness, confirming that the import of H2O2 across the membrane is essential for B cell activation. The addition of exogenous catalase to primary B splenocytes severely impaired the tyrosine phosphorylation induced by BCR cross-linking, as did the absence of NOX2 in a murine model of chronic granulomatous disease. Importantly, re-expression of gp91phox through gene therapy restored the specific B cell signaling deficiency in NOX2-/- cells. Thus, efficient induction of B cell activation and differentiation requires intact H2O2 fluxes across the plasma membrane for signal amplification.

Stress Regulates Aquaporin-8 Permeability to Impact Cell Growth and Survival.

UNLABELLED: Aquaporin-8 (AQP8) allows the bidirectional transport of water and hydrogen peroxide across biological membranes. Depending on its concentration, H2O2 exerts opposite roles, amplifying growth factor signaling in physiological conditions, but causing severe cell damage when in excess. Thus, H2O2 permeability is likely to be tightly controlled in living cells. AIMS: In this study, we investigated whether and how the transport of H2O2 through plasma membrane AQP8 is regulated, particularly during cell stress. RESULTS: We show that diverse cellular stress conditions, including heat, hypoxia, and ER stress, reversibly inhibit the permeability of AQP8 to H2O2 and water. Preventing the accumulation of intracellular reactive oxygen species (ROS) during stress counteracts AQP8 blockade. Once inhibition is established, AQP8-dependent transport can be rescued by reducing agents. Neither H2O2 nor water transport is impaired in stressed cells expressing a mutant AQP8, in which cysteine 53 had been replaced by serine. Cells expressing this mutant are more resistant to stress-, drug-, and radiation-induced growth arrest and death. INNOVATION AND CONCLUSION: The control of AQP8-mediated H2O2 transport provides a novel mechanism to regulate cell signaling and survival during stress. Antioxid. Redox Signal. 24, 1031-1044.

Tyrosine kinase signal modulation: a matter of H2O2 membrane permeability?

Abstract H2O2 produced by extracellular NADPH oxidases regulates tyrosine kinase signaling inhibiting phosphatases. How does it cross the membrane to reach its cytosolic targets? Silencing aquaporin-8 (AQP8), but not AQP3 or AQP4, inhibited H2O2 entry into HeLa cells. Re-expression of AQP8 with silencing-resistant vectors rescued H2O2 transport, whereas a C173A-AQP8 mutant failed to do so. Lowering AQP8 levels affected H2O2 entry into the endoplasmic reticulum, but not into mitochondria. AQP8 silencing also inhibited the H2O2 spikes and phosphorylation of downstream proteins induced by epidermal growth factor. These observations lead to the hypothesis that H2O2 does not freely diffuse across the plasma membrane and AQP8 and other H2O2 transporters are potential targets for manipulating key signaling pathways in cancer and degenerative diseases.

On the redox control of B lymphocyte differentiation and function.

SIGNIFICANCE: On the one hand, redox emerges as a key mechanism in regulating intra- and intercellular signaling and homeostatic systems. On the other hand, cells of the B lineage provide powerful systems to unravel the intra- and intercellular mechanisms that coordinate the processes of development and terminal differentiation. RECENT ADVANCES: This essay summarizes a few paradigmatic examples of redox regulation and signal modulation that emerged from, or were confirmed by, studies on the development, differentiation and function of B cells. CRITICAL ISSUES: While a role for intra- and intercellular redox signaling has been firmly established for differentiating B cells, many fundamental questions remain open, including the cellular sources of reactive oxygen species (ROS), the spatial and temporal constraints of ROS signaling, and the functional role of the antioxidant response. FUTURE DIRECTIONS: Given their robustness and biotechnological and clinical interest, cells of the B lineage continue to be fruitful goldmines from which redox biologists can dig novel mechanistic knowledge of general relevance.

B- to plasma-cell terminal differentiation entails oxidative stress and profound reshaping of the antioxidant responses.

Limited amounts of reactive oxygen species are necessary for cell survival and signaling, but their excess causes oxidative stress. H(2)O(2) and other reactive oxygen species are formed as byproducts of several metabolic pathways, possibly including oxidative protein folding in the endoplasmic reticulum. B- to plasma-cell differentiation is characterized by a massive expansion of the endoplasmic reticulum, finalized to sustain abundant immunoglobulin (Ig) synthesis and secretion. The increased production of disulfide-rich Ig might cause oxidative stress that could serve signaling roles in the differentiation and lifespan control of antibody-secreting cells. Here we show that terminal B-cell differentiation entails redox stress, NF-E2-related factor-2 (Nrf2) activation, and reshaping of the antioxidant responses. However, plasma-cell differentiation was not dramatically impaired in peroxiredoxin (Prx)1-, 2-, 3-, and 4-, glutathione peroxidase 1-, and Nrf2-knockout splenocytes, suggesting redundancy and robustness in antioxidant systems. Endoplasmic reticulum (ER)-resident Prx4 increases dramatically during differentiation. In its absence, IgM secretion was not significantly affected, but more high-molecular-weight covalent complexes accumulated intracellularly. Our results suggest that the early intracellular production of H(2)O(2) facilitates B-cell proliferation and reveal a role for the Nrf2 pathway in the differentiation and function of IgM-secreting cells.

Redox remodeling allows and controls B-cell activation and differentiation.

During their differentiation to antibody-secreting plasma cells, B lymphocytes undergo dramatic changes in metabolism, structure, and function. Here we show that this transition entails extensive intra- and extracellular redox changes. Lipopolysaccharide (LPS)-driven activation and differentiation of naïve murine B splenocytes is paralleled by increased production of reactive oxygen species (ROS) from different sources, followed by a strong antioxidant response. This response includes upregulation of thioredoxin and of the cystine transporter xCT, and increased production and extracellular release of nonprotein thiols, mainly glutathione (GSH) and cysteine. Although ROS levels are higher in late-differentiating B cells, an early oxidative step is likely required to start the differentiation program, because inhibition of NADPH oxidase-dependent early ROS production impairs B-cell activation and differentiation. Addition of reducing agents such as 2-ME results in increased IgM secretion per cell, suggesting that the antioxidant response not only is aimed at restoring the redox homeostasis but also plays a functional role. A highly reduced environment coincident with the presence of large ROS-producing cells is observed in histologic sections of spleens from immunized mice, indicating that the redox modifications observed in LPS-induced B-cell differentiation in vitro occur also in vivo during physiologic immune responses.

CHOP-independent apoptosis and pathway-selective induction of the UPR in developing plasma cells.

Upon antigen stimulation, B lymphocytes differentiate into antibody secreting cells (ASC), most of which undergo apoptosis after a few days of intense Ig production. Differentiation entails expansion of the endoplasmic reticulum (ER) and requires XBP1 but not other elements of the unfolded protein response, like PERK. Moreover, normal and malignant ASC are exquisitely sensitive to proteasome inhibitors, but the underlying mechanisms are poorly understood. Here we analyze the role of C/EBP homologous protein (CHOP), a transcription factor mediating apoptosis in many cell types that experience high levels of ER stress. CHOP is transiently induced early upon B cell stimulation: covalent IgM aggregates form more readily and IgM secretion is slower in chop(-/-) cells. Despite these subtle changes, ASC differentiation and lifespan are normal in chop(-/-) mice. Unlike fibroblasts and other cell types, chop(-/-) ASC are equally or slightly more sensitive to proteasome inhibitors and ER stressors, implying tissue-specific roles for CHOP in differentiation and stress.