Quantitative studies on biological water oxidation: a novel mechanism of T cells and antibodies.

Prior studies show that purified T cell receptors (TCRs) and antibodies catalyze the oxidation of water to H2O2 in the presence of singlet oxygen, but the comparative efficiencies of TCRs and antibodies in this process have not been reported. Since H2O2 has been shown to activate TCRs and selectively regulate redox sensitive TCR signaling pathways, it is important to understand the physiological significance of these recently uncovered processes. This new information might be used to develop new therapeutic tools for immune and inflammatory diseases. In this paper, we present data showing that under equivalent conditions Jurkat T cell membranes produce H2O2 at a rate of 457 pM/min/mg protein/muW/cm2 while IgG antibodies produce H2O2 at a rate of 192 pM/min/mg protein/muW/cm2. Taking into account the number of catalytic sites in a milligram of T cell membranes and IgGs, we calculate that TCRs catalyze H2O2 production at a specific rate that is about 10(6) times greater than the rate of IgGs. Based on these observations and calculations, we conclude that the comparatively high rate of H2O2 production by TCRs makes it more likely that this is a physiologically relevant process than the H2O2 production by IgGs. In addition, the catalytic rate for H2O2 production by TCRs is comparable to the rates of other physiologically important processes, such as catalysis by enzymes. This suggests that singlet oxygen-dependent, TCR mediated, H2O2 production is likely to be physiologically important, perhaps as H2O2 being a small molecule regulator of TCR signal transduction or a modulator of T cell gene transcription.

Biophotonic hydrogen peroxide production by antibodies, T cells, and T-cell membranes.

Rapidly accumulating evidence indicates that inflammatory T cells sensitively respond to their redox environment by activating signal transduction pathways. The hypothesis that T-cell receptors have the potential to catalytically transform singlet oxygen into H(2)O(2) attracted our attention since the biophysical regulation of this process would provide a new tool for therapeutically directing T cells down a preferred signaling pathway. Light-dependent production of H(2)O(2) was first described in antibodies, and we reproduced these findings. Using a real-time H(2)O(2) sensor we extended them by showing that the reaction proceeds in a biphasic way with a short-lived phase that is fast compared to the slow second phase of the reaction. We then showed that Jurkat T cells biophotonically produce about 30nM H(2)O(2)/min/mg protein when pretreated with NaN(3). This activity was concentrated 4 to 5 times in T-cell membrane preparations. The implications of these observations for the development of new therapeutic tools for inflammatory diseases are discussed.

A photochemical microreactor used to analyze hydrogen peroxide (H2O2) production of T lymphocytes.

In this report we describe a new photochemical reactor and its use in the study of ultraviolet-B light (UVB) dependent H2O2 production by T lymphocytes. In the reactor multiple biological samples rotate around a luminescent tube and thus simultaneously absorb a uniform light-flux. The reactor was developed to expand our earlier studies where we showed that UVB activates T lymphocytes so that 10(7) cells produce about 60 nmol H2O2 per minute. H2O2 has increasingly become recognized as a cell signaling molecule regulating immune reactions mediated by T lymphocytes. Our laboratory is researching the potential of such immune regulators as potential future therapeutic agents. To study photochemical H2O2 production in small samples such as suspensions of T lymphocyte cultures or cell extracts, we designed a reactor in which 12 samples (each 50 - 500 microliters) can be exposed to light under temperature-controlled conditions. The samples are mounted on a rotating platform equidistant from the axis of rotation, where the light source of the photoreactor is located. Rotating the samples helps assure that all samples receive a uniform amount of light energy over time. A cooling fan is integrated in the base of the reactor to help minimize convective heat transfer between the lamp and the samples. We simultaneously operate two identical systems to be able to compare data that are obtained from light exposed samples under control and experimental conditions. Data on the influence of therapeutically relevant electromagnetic fields on H2O2 production of T lymphocytes are presented. H2O2 was quantified using the Amplex Red dye.

Use of proteomics methodology to evaluate inflammatory protein expression in tendinitis.

In previous studies we established a rat model of acute tendinitis including functional and mechanical measures of healing. Achilles' tendinitis was induced by injection of collagenase, an enzyme that produces localized fiber digestion and edema formation. As quantitative measures of tissue inflammation, hypercellularity and edema were evaluated in injured tendons in comparison with controls. Using the rat tendinitis model, we have applied isotope-coded affinity tag analysis (ICAT) methodology to indicate localized tendon healing by quantitating protein expression. This novel proteomics method allows detection of subtle differences in protein levels that provide a detailed picture of tendinitis healing. The method involves a new class of chemical linkers used to differentially label cysteine residues from similar peptides in control and treated protein samples with heavy (deuterium off of backbone) and light (hydrogen off of backbone) ICAT reagents that are otherwise chemically identical. Proteins were extracted under liquid nitrogen from control untreated or injured Achilles' tendons 72 hours after collagenase-injection. These proteins were digested with endoproteinase Glu-C and trypsin and the resulting peptide mixtures were evaluated using reverse-phase C18 HPLC and Tristricine SDS-polyacrylamide gel electrophoresis. The two ICAT-modified peptide populations were mixed, affinity-purified and analyzed using microcapillary liquid chromatography and electrospray ionization tandem mass-spectroscopy. The process resulted in relative abundance and charge-to-mass ratio data used in conjunction with database searching to identify proteins expressed differentially in the two treatment groups. By analyzing different time periods in the healing process, an accurate model of the healing rat tendon can be made.

Characterization of a real time H2O2 monitor for use in studies on H2O2 production by antibodies and cells.

It was recently shown that antibodies catalyze a reaction between water and ultraviolet light (UV) creating singlet oxygen and ultimately H2O2. Although the in vivo relevance of these antibody reactions is unclear, it is interesting that among a wide variety of non-antibody proteins tested, the T cell receptor is the only protein with similar capabilities. In clinical settings UV is believed to exert therapeutic effects by eliminating inflammatory epidermal T cells and we hypothesized that UV-triggered H2O2 production is involved in this process. To test the hypothesis we developed tools to study production of H2O2 by T cell receptors with the long-term goal of understanding, and improving, UV phototherapy. Here, we report the development of an inexpensive, real time H2O2 monitoring system having broad applicability. The detector is a Clark oxygen electrode (Pt, Ag/AgCl) modified to detect UV-driven H2O2 production. Modifications include painting the electrode black to minimize UV effects on the Ag/AgCl electrode and the use of hydrophilic, large pore Gelnots electrode membranes. Electrode current was converted to voltage and then amplified and recorded using a digital multimeter coupled to a PC. A reaction vessel with a quartz window was developed to maintain constant temperature while permitting UV irradiation of the samples. The sensitivity and specificity of the system and its use in cell-free and cell-based assays will be presented. In a cellfree system, production of H2O2 by CD3 antibodies was confirmed using our real time H2O2 monitoring method. Additionally we report the finding that splenocytes and Jurkat T cells also produce H2O2 when exposed to UV light.

Effect of short duration electromagnetic field exposures on rat mass.

Daily preexposure and postexposure mass measurements of 65 rats (young males and females, old males) a proprietary pulsed wound healing field, pulsed electromagnetic field, (PEMF), or their control fields for 4 h/day for 21 days. Statistical analysis of mass changes over time showed that young rats exposed to PEMF lost more mass and recovered it more slowly compared to controls (2-4% more loss) than did older PEMF exposed rats or any 60 Hz exposed rats. We conclude that daily preexposure and postexposure mass measurements are needed to adequately assess the effects of electromagnetic fields on body mass.