Jean-Luc Boucher

Memory TH2 cells induce alternatively activated macrophages to mediate protection against nematode parasites

Although primary and memory responses against bacteria and viruses have been studied extensively, T helper type 2 (TH2) effector mechanisms leading to host protection against helminthic parasites remain elusive. Examination of the intestinal epithelial submucosa of mice after primary and secondary infections by a natural gastrointestinal parasite revealed a distinct immune-cell infiltrate after challenge, featuring interleukin-4–expressing memory CD4+ T cells that induced IL-4 receptorhi (IL-4Rhi) CD206+ alternatively activated macrophages. In turn, these alternatively activated macrophages (AAMacs) functioned as important effector cells of the protective memory response contributing to parasite elimination, demonstrating a previously unknown mechanism for host protection against intestinal helminths.

Dual Oxidase-2 Has an Intrinsic Ca2+-dependent H2O2-generating Activity

Duox2 (and probably Duox1) is a glycoflavoprotein involved in thyroid hormone biosynthesis, as the thyroid H2O2 generator functionally associated with Tpo (thyroperoxidase). So far, because of the impairment of maturation and of the targeting process, transfecting DUOX into nonthyroid cell lines has not led to the expression of a functional H2O2-generating system at the plasma membrane. For the first time, we investigated the H2O2-generating activity in the particulate fractions from DUOX2- and DUOX1-transfected HEK293 and Chinese hamster ovary cells. The particulate fractions of these cells stably or transiently transfected with human or porcine DUOX cDNA demonstrate a functional NADPH/Ca2+-dependent H2O2-generating activity. The immature Duox proteins had less activity than pig thyrocyte particulate fractions, and their activity depended on their primary structures. Human Duox2 seemed to be more active than human Duox1 but only half as active as its porcine counterpart. TPO co-transfection produced a slight increase in the enzymatic activity, whereas p22phox, the 22-kDa subunit of the leukocyte NADPH oxidase, had no effect. In previous studies on the mechanism of H2O2 formation, it was shown that mature thyroid NADPH oxidase does not release \batchmode \documentclass[fleqn,10pt,legalpaper]{article} \usepackage{amssymb} \usepackage{amsfonts} \usepackage{amsmath} \pagestyle{empty} \begin{document} \(\mathrm{O}_{2}^{{\bar{{\cdot}}}}\) \end{document} but H2O2. Using a spin-trapping technique combined with electron paramagnetic resonance spectroscopy, we confirmed this result but also demonstrated that the partially glycosylated form of Duox2, located in the endoplasmic reticulum, generates superoxide in a calcium-dependent manner. These results suggest that post-translational modifications during the maturation process of Duox2 could be implicated in the mechanism of H2O2 formation by favoring intramolecular superoxide dismutation.

Virus-helminth coinfection reveals a microbiota-independent mechanism of immunomodulation

Parasites make it hard to fight viruses Microbial co-infections challenge the immune system—different pathogens often require different flavors of immune responses for their elimination or containment (see the Perspective by Maizels and Gause). Two teams studied what happens when parasitic worms and viruses infect mice at the same time. Reese et al. found that parasite co-infection woke up a dormant virus. Osborne et al. found that mice already infected with parasitic worms were worse at fighting off viruses. In both cases, worms skewed the immune response so that the immune cells and the molecules they secreted created an environment favorable for the worm at the expense of antiviral immunity. Science, this issue p. 573 and p. 578; see also p. 517 Coinfection with intestinal parasites leads to altered antiviral immunity in mice. [Also see Perspective by Maizels and Gause] The mammalian intestine is colonized by beneficial commensal bacteria and is a site of infection by pathogens, including helminth parasites. Helminths induce potent immunomodulatory effects, but whether these effects are mediated by direct regulation of host immunity or indirectly through eliciting changes in the microbiota is unknown. We tested this in the context of virus-helminth coinfection. Helminth coinfection resulted in impaired antiviral immunity and was associated with changes in the microbiota and STAT6-dependent helminth-induced alternative activation of macrophages. Notably, helminth-induced impairment of antiviral immunity was evident in germ-free mice, but neutralization of Ym1, a chitinase-like molecule that is associated with alternatively activated macrophages, could partially restore antiviral immunity. These data indicate that helminth-induced immunomodulation occurs independently of changes in the microbiota but is dependent on Ym1.

Formation of nitrogen oxides and citrulline upon oxidation of Nω-hydroxy-L-arginine by hemeproteins

HRP catalyzes the oxidation of N omega-hydroxy-L-arginine (NOHA) by H2O2 with formation of citrulline and NO2- with initial rates of about 0.7 and 0.2 nmol per nmol HRP per min. In the same manner, cytochromes P450 from rat liver microsomes catalyze the oxidation of NOHA to citrulline and NO2- by cumylhydroperoxide. Inhibitors of these hemeproteins (N3- and CN- for HRP and miconazole for P450) strongly inhibit both citrulline and NO2- formation. Rates of NOHA oxidation by these hemeproteins markedly decrease with time presumably because of their denaturation by nitrogen oxides and of the formation of hemeprotein-iron-NO complexes. These results suggest that NO (and other nitrogen oxides) could be formed from oxidation of NOHA by other enzymes than NO-synthases.

Cytochrome P450 catalyzes the oxidation of Nω-hydroxy-L-arginine by NADPH and O2 to nitric oxide and citrulline

Rat liver microsomes catalyze the oxidative denitration of N omega-hydroxy-L-arginine (NOHA) by NADPH and O2 with formation of citrulline and nitrogen oxides like NO and NO2-. Besides NO2- and citrulline, whose simultaneous formation is linear for at least 20 min, the formation of NO could be detected under the form of its P450 and P420-Fe(II) complexes by UV-visible and EPR spectroscopy. Classical inhibitors of NO-synthases, like N omega-methyl-and N omega-nitro-arginine, fail to inhibit the microsomal oxidation of NOHA to citrulline and NO2-. On the contrary classical inhibitors of hepatic cytochromes P450 like CO, miconazole, dihydroergotamine and troleandomycin, strongly inhibit this monooxygenase reaction. These results show that the oxygenation of NOHA by NADPH and O2 with formation of citrulline and NO can be efficiently catalyzed by cytochromes P450 (with rates up to 1.5 turnovers per min for the cytochromes of the 3A subfamily).

Inhibition of arginase in rat and rabbit alveolar macrophages by Nω-hydroxy-D,L-indospicine, effects on L-arginine utilization by nitric oxide synthase

Alveolar macrophages (AMΦ) exhibit arginase activity and may, in addition, express an inducible form of nitric oxide (NO) synthase (iNOS). Both pathways may compete for the substrate, L‐arginine. The present study tested whether two recently described potent inhibitors of liver arginase (Nω‐hydroxy‐D,L‐indospicine and 4‐hydroxyamidino‐D,L‐phenylalanine) might also inhibit arginase in AMΦ and whether inhibition of arginase might affect L‐arginine utilization by iNOS. AMΦ obtained by broncho‐alveolar lavage of rat and rabbit isolated lungs were disseminated (2.5 or 3×106 cells per well) and allowed to adhere for 2 h. Thereafter, they were either used to study [*H]‐L‐arginine uptake (37 kBq, 0.1 μM, 2 min) or cultured for 20 h in the absence or presence of bacterial lipopolysaccharide (LPS). Cultured AMΦ were incubated for 1 h with [*H]‐L‐arginine (37 kBq, 0.1 μM) and the accumulation of [*H]‐L‐citrulline (NOS activity) and [*H]‐L‐ornithine (arginase activity) was determined. During 1 h incubation of rabbit AMΦ with [*H]‐L‐arginine, no [*H]‐L‐citrulline, but significant amounts of [*H]‐L‐ornithine (150 d.p.m.×1000) were formed. Nω‐hydroxy‐D,L‐indospicine and 4‐hydroxyamidino‐D,L‐phenylalanine, present during incubation, concentration‐dependently reduced [*H]‐L‐ornithine formation (IC50: 2 and 45 μM, respectively). Nω‐hydroxy‐D,L‐indospicine (up to 100 μM) had no effect on [*H]‐L‐arginine uptake into rabbit AMΦ, whereas 4‐hydroxyamidino‐D,L‐phenylalanine caused a concentration‐dependent inhibition (IC50: 300 μM). Rat AMΦ, cultured in the absence of LPS, formed significant amounts of [*H]‐L‐citrulline and [*H]‐L‐ornithine (133 and 212 d.p.m.×1000, respectively) when incubated for 1 h with [*H]‐L‐arginine. When AMΦ had been cultured in the presence of 0.1 or 1 μg ml−1 LPS, the formation of [*H]‐L‐citrulline was enhanced by 37±8.3 and 99±12% and that of [*H]‐L‐ornithine reduced by 21±8.7 and 70±2.5%, respectively. In rat AMΦ, cultured in the absence or presence of LPS, Nω‐hydroxy‐D,L‐indospicine (10 and 30 μM) greatly reduced formation of [*H]‐L‐ornithine (by 80–95%) and this was accompanied by increased formation of [*H]‐L‐citrulline. However, only 20–30% of the [*H]‐L‐arginine not metabolized to [*H]‐L‐ornithine after inhibition of arginase was metabolized to [*H]‐L‐citrulline, when the AMΦ had been cultured in the absence of LPS (i.e. low level of iNOS). On the other hand, when the AMΦ had been cultured in the presence of LPS (i.e. high level of iNOS), all the [*H]‐L‐arginine not metabolized by the inhibited arginase was metabolized to [*H]‐L‐citrulline. In conclusion, Nω‐hydroxy‐D,L‐indospicine is a potent and specific inhibitor of arginase in AMΦ. In cells in which, in addition to arginase, iNOS is expressed, inhibition of arginase can cause a shift of L‐arginine metabolism to the NOS pathway. However, the extent of this shift appears to depend in a complex manner on the level of iNOS.

Arginase inhibition protects against allergen-induced airway obstruction, hyperresponsiveness, and inflammation.

RATIONALE In a guinea pig model of allergic asthma, using perfused tracheal preparations ex vivo, we demonstrated that L-arginine limitation due to increased arginase activity underlies a deficiency of bronchodilating nitric oxide (NO) and airway hyperresponsiveness (AHR) after the allergen-induced early and late asthmatic reaction. OBJECTIVES Using the same animal model, we investigated the acute effects of the specific arginase inhibitor 2(S)-amino-6-boronohexanoic acid (ABH) and of L-arginine on AHR after the early and late reaction in vivo. In addition, we investigated the protection of allergen-induced asthmatic reactions, AHR, and airway inflammation by pretreatment with the drug. METHODS Airway responsiveness to inhaled histamine was measured in permanently instrumented, freely moving guinea pigs sensitized to ovalbumin at 24 hours before allergen challenge and after the allergen-induced early and late asthmatic reactions by assessing histamine PC(100) (provocative concentration causing a 100% increase of pleural pressure) values. MEASUREMENTS AND MAIN RESULTS Inhaled ABH acutely reversed AHR to histamine after the early reaction from 4.77 +/- 0.56-fold to 2.04 +/- 0.34-fold (P < 0.001), and a tendency to inhibition was observed after the late reaction (from 1.95 +/- 0.56-fold to 1.56 +/- 0.47-fold, P < 0.10). Quantitatively similar results were obtained with inhaled l-arginine. Remarkably, after pretreatment with ABH a 33-fold higher dose of allergen was needed to induce airway obstruction (P < 0.01). Consequently, ABH inhalation 0.5 hour before and 8 hours after allergen challenge protected against the allergen-induced early and late asthmatic reactions, AHR and inflammatory cell infiltration. CONCLUSIONS Inhalation of ABH or l-arginine acutely reverses allergen-induced AHR after the early and late asthmatic reaction, presumably by attenuating arginase-induced substrate deficiency to NO synthase in the airways. Moreover, ABH considerably reduces the airway sensitivity to inhaled allergen and protects against allergen-induced bronchial obstructive reactions, AHR, and airway inflammation. This is the first in vivo study indicating that arginase inhibitors may have therapeutic potential in allergic asthma.

Mitochondrial Arginase II Modulates Nitric-Oxide Synthesis through Nonfreely Exchangeable l-Arginine Pools in Human Endothelial Cells

Reduced synthesis of nitric oxide (NO) contributes to the endothelial dysfunction and may be related to limited availability of l-arginine, the common substrate of constitutive nitric-oxide synthase (NOS) and cytosolic arginase I and mitochondrial arginase II. To determine whether arginases modulate the endothelial NO synthesis, we investigated the effects of the competitive arginase inhibitor Nω-hydroxy-nor-l-arginine (Nor-NOHA) on the activity of NOS, arginases, and l-arginine transporter and on NO release at surface of human umbilical vein endothelial cells (HUVECs). In unstimulated cells, Nor-NOHA dose-dependently reduced the arginase activity with maximal inhibition at 20 μM. When HUVECs were stimulated by thrombin without extracellular l-arginine, Nor-NOHA dose-dependently increased the NOS activity and the NO release with maximal effects at 20 μM. Extracellular l-arginine also dose-dependently increased NO release and arginase activity. When HUVECs were stimulated by thrombin in the presence of 100 μM l-arginine, NOS activity and NO release were similar in untreated and Nor-NOHA-treated cells. However, despite activation of l-arginine uptake, the inhibition of arginase activity by Nor-NOHA was still significant. The depletion of freely exchangeable l-arginine pools with extracellular l-lysine did not prevent Nor-NOHA from increasing the NO release. This indicates the presence of pools, which are accessible to NOS and arginase, but not exchangeable. Interestingly, the mitochondrial arginase II was constitutively expressed, whereas the cytosolic arginase I was barely detectable in HUVECs. These data suggest that endothelial NO synthesis depends on the activity of arginase II in mitochondria and l-arginine carriers in cell membrane.

Modulation of cholinergic airway reactivity and nitric oxide production by endogenous arginase activity

Cholinergic airway constriction is functionally antagonized by agonist‐induced constitutive nitric oxide synthase (cNOS)‐derived nitric oxide (NO). Since cNOS and arginase, which hydrolyzes L‐arginine to L‐ornithine and urea, use L‐arginine as a common substrate, competition between both enzymes for the substrate could be involved in the regulation of cholinergic airway reactivity. Using a perfused guinea‐pig tracheal tube preparation, we investigated the modulation of methacholine‐induced airway constriction by the recently developed, potent and specific arginase inhibitor NΩ‐hydroxy‐nor‐L‐arginine (nor‐NOHA). Intraluminal (IL) administration of nor‐NOHA caused a concentration‐dependent inhibition of the maximal effect (Emax) in response to IL methacholine, which was maximal in the presence of 5 μM nor‐NOHA (Emax=31.2±1.6% of extraluminal (EL) 40 mM KCl‐induced constriction versus 51.6±2.1% in controls, P<0.001). In addition, the pEC50 (−log10 EC50) was slightly but significantly reduced in the presence of 5 μM nor‐NOHA. The inhibition of Emax by 5 μM nor‐NOHA was concentration‐dependently reversed by the NOS inhibitor NΩ‐nitro‐L‐arginine methyl ester (L‐NAME), reaching an Emax of 89.4±7.7% in the presence of 0.5 mM L‐NAME (P<0.01). A similar Emax in the presence of 0.5 mM L‐NAME was obtained in control preparations (85.2±9.7%, n.s.). In the presence of excess of exogenously applied L‐arginine (5 mM), 5 μM nor‐NOHA was ineffective (Emax=33.1±5.8 versus 31.1±7.5% in controls, n.s.). The results indicate that endogenous arginase activity potentiates methacholine‐induced airway constriction by inhibition of NO production, presumably by competition with cNOS for the common substrate, L‐arginine. This finding may represent an important novel regulation mechanism of airway reactivity.

Mouse Strain Susceptibility to Trypanosome Infection: An Arginase-Dependent Effect

We previously reported that macrophage arginase inhibits NO-dependent trypanosome killing in vitro and in vivo. BALB/c and C57BL/6 mice are known to be susceptible and resistant to trypanosome infection, respectively. Hence, we assessed the expression and the role of inducible NO synthase (iNOS) and arginase in these two mouse strains infected with Trypanosoma brucei brucei. Arginase I and arginase II mRNA expression was higher in macrophages from infected BALB/c compared with those from C57BL/6 mice, whereas iNOS mRNA was up-regulated at the same level in both phenotypes. Similarly, arginase activity was more important in macrophages from infected BALB/c vs infected C57BL/6 mice. Moreover, increase of arginase I and arginase II mRNA levels and of macrophage arginase activity was directly induced by trypanosomes, with a higher level in BALB/c compared with C57BL/6 mice. Neither iNOS expression nor NO production was stimulated by trypanosomes in vitro. The high level of arginase activity in T. brucei brucei-infected BALB/c macrophages strongly inhibited macrophage NO production, which in turn resulted in less trypanosome killing compared with C57BL/6 macrophages. NO generation and parasite killing were restored to the same level in BALB/c and C57BL/6 macrophages when arginase was specifically inhibited with Nω-hydroxy-nor-l-arginine. In conclusion, host arginase represents a marker of resistance/susceptibility to trypanosome infections.