Nitric oxide regulates tissue transglutaminase localization and function in the vasculature.

The multifunctional enzyme tissue transglutaminase (TG2) contributes to the development and progression of several cardiovascular diseases. Extracellular rather than intracellular TG2 is enzymatically active, however, the mechanism by which it is exported out of the cell remains unknown. Nitric oxide (NO) is shown to constrain TG2 externalization in endothelial and fibroblast cells. Here, we examined the role of both exogenous and endogenous (endothelial cell-derived) NO in regulating TG2 localization in vascular cells and tissue. NO synthase inhibition in endothelial cells (ECs) using N-nitro L-arginine methyl ester (L-NAME) led to a time-dependent decrease in S-nitrosation and increase in externalization of TG2. Laminar shear stress led to decreased extracellular TG2 in ECs. S-nitrosoglutathione treatment led to decreased activity and externalization of TG2 in human aortic smooth muscle and fibroblast (IMR90) cells. Co-culture of these cells with ECs resulted in increased S-nitrosation and decreased externalization and activity of TG2, which was reversed by L-NAME. Aged Fischer 344 rats had higher tissue scaffold-associated TG2 compared to young. NO regulates intracellular versus extracellular TG2 localization in vascular cells and tissue, likely via S-nitrosation. This in part, explains increased TG2 externalization and activity in aging aorta.

S-nitrosation of arginase 1 requires direct interaction with inducible nitric oxide synthase.

Arginase constrains endothelial nitric oxide synthase activity by competing for the common substrate, L -Arginine. We have recently shown that inducible nitric oxide synthase (NOS2) S-nitrosates and activates arginase 1 (Arg1) leading to age-associated vascular dysfunction. Here, we demonstrate that a direct interaction of Arg1 with NOS2 is necessary for its S-nitrosation. The specific domain of NOS2 that mediates this interaction is identified. Disruption of this interaction in human aortic endothelial cells prevents Arg1 S-nitrosation and activation. Thus, disruption of NOS2-Arg1 interaction may represent a therapeutic strategy to attenuate age related vascular endothelial dysfunction.

Oral atorvastatin therapy restores cutaneous microvascular function by decreasing arginase activity in hypercholesterolaemic humans.

Elevated low-density lipoproteins (LDLs) are associated with vascular dysfunction evident in the cutaneous microvasculature. We hypothesized that uncoupled endothelial nitric oxide synthase (NOS3) through upregulated arginase contributes to cutaneous microvascular dysfunction in hyperocholesterolaemic (HC) humans and that a statin intervention would decrease arginase activity. Five microdialysis fibres were placed in the skin of nine normocholesterolaemic (NC: LDL level 95±4 mg dl⁻¹) and nine hypercholesterolaemic (HC: LDL: 177±6 mg dl⁻¹) men and women before and after 3 months of systemic atrovastatin. Sites served as control, NOS inhibited, arginase inhibited, L-arginine supplemented and arginase inhibited plus L-arginine supplemented. Skin blood flow was measured while local skin heating (42°C) induced NO-dependent vasodilatation. L-NAME was infused after the established plateau in all sites to quantify NO-dependent vasodilatation. Data were normalized to maximum cutaneous vascular conductance (CVC(max)). Skin samples were obtained to measure total arginase activity and arginase I and arginase II protein. Vasodilatation was reduced in hyperocholesterolaemic subjects (HC: 76±2 vs. NC: 94±3%CVC(max), P < 0.001) as was NO-dependent vasodilatation (HC: 43±5 vs. NC: 62±4%CVC(max), P < 0.001). The plateau and NO-dependent vasodilatation were augmented in HC with arginase inhibition (92±2, 67±2%CVC(max), P < 0.001), L-arginine (93±2, 71±5%CVC(max), P < 0.001) and combined treatments (94±4, 65±5%CVC(max), P < 0.001) but not in NC. After statin intervention (LDL: 98±5 mg dl⁻¹) there was no longer a difference between control sites (88±4, 61±5%CVC(max)) and localized microdialysis treatment sites (all P > 0.05). Arginase activity and protein were increased in HC skin (P < 0.05 vs. NC) and activity decreased with atrovastatin treatment (P < 0.05). Reduced NOS3 substrate availability through upregulated arginase contributes to cutaneous microvascular dysfunction in hyperocholesterolaemic humans, which is corrected with atorvastatin therapy.

Decreased S-nitrosylation of tissue transglutaminase contributes to age-related increases in vascular stiffness.

RATIONALE: Although an age-related decrease in NO bioavailability contributes to vascular stiffness, the underlying molecular mechanisms remain incompletely understood. We hypothesize that NO constrains the activity of the matrix crosslinking enzyme tissue transglutaminase (TG2) via S-nitrosylation in young vessels, a process that is reversed in aging. OBJECTIVE: We sought to determine whether endothelium-dependent NO regulates TG2 activity by S-nitrosylation and whether this contributes to age-related vascular stiffness. METHODS AND RESULTS: We first demonstrate that NO suppresses activity and increases S-nitrosylation of TG2 in cellular models. Next, we show that nitric oxide synthase (NOS) inhibition leads to increased surface and extracellular matrix-associated TG2. We then demonstrate that endothelium-derived bioactive NO primarily mediates its effects through TG2, using TG2(-/-) mice chronically treated with the NOS inhibitor l-N(G)-nitroarginine methyl ester (L-NAME). We confirm that TG2 activity is modulated by endothelium-derived bioactive NO in young rat aorta. In aging rat aorta, although TG2 expression remains unaltered, its activity increases and S-nitrosylation decreases. Furthermore, TG2 inhibition decreases vascular stiffness in aging rats. Finally, TG2 activity and matrix crosslinks are augmented with age in human aorta, whereas abundance remains unchanged. CONCLUSIONS: Decreased S-nitrosylation of TG2 and increased TG activity lead to enhanced matrix crosslinking and contribute to vascular stiffening in aging. TG2 appears to be the member of the transglutaminase family primarily contributing to this phenotype. Inhibition of TG2 could thus represent a therapeutic target for age-associated vascular stiffness and isolated systolic hypertension.

Arginase inhibition restores NOS coupling and reverses endothelial dysfunction and vascular stiffness in old rats.

There is increasing evidence that upregulation of arginase contributes to impaired endothelial function in aging. In this study, we demonstrate that arginase upregulation leads to endothelial nitric oxide synthase (eNOS) uncoupling and that in vivo chronic inhibition of arginase restores nitroso-redox balance, improves endothelial function, and increases vascular compliance in old rats. Arginase activity in old rats was significantly increased compared with that shown in young rats. Old rats had significantly lower nitric oxide (NO) and higher superoxide (O2(-)) production than young. Acute inhibition of both NOS, with N(G)-nitro-l-arginine methyl ester, and arginase, with 2S-amino- 6-boronohexanoic acid (ABH), significantly reduced O2(-) production in old rats but not in young. In addition, the ratio of eNOS dimer to monomer in old rats was significantly decreased compared with that shown in young rats. These results suggest that eNOS was uncoupled in old rats. Although the expression of arginase 1 and eNOS was similar in young and old rats, inducible NOS (iNOS) was significantly upregulated. Furthermore, S-nitrosylation of arginase 1 was significantly elevated in old rats. These findings support our previously published finding that iNOS nitrosylates and activates arginase 1 (Santhanam et al., Circ Res 101: 692-702, 2007). Chronic arginase inhibition in old rats preserved eNOS dimer-to-monomer ratio and significantly reduced O2(-) production and enhanced endothelial-dependent vasorelaxation to ACh. In addition, ABH significantly reduced vascular stiffness in old rats. These data indicate that iNOS-dependent S-nitrosylation of arginase 1 and the increase in arginase activity lead to eNOS uncoupling, contributing to the nitroso-redox imbalance, endothelial dysfunction, and vascular stiffness observed in vascular aging. We suggest that arginase is a viable target for therapy in age-dependent vascular stiffness.