Abstract-Nitric oxide (NO) is an essential vasodilator. In vascular diseases, oxidative stress attenuates NO signaling by both chemical scavenging of free NO and oxidation and downregulation of its major intracellular receptor, the ␣ heterodimeric heme-containing soluble guanylate cyclase (sGC). Oxidation can also induce loss of the heme of sGC, as well as the responsiveness of sGC to NO. sGC activators such as BAY 58-2667 bind to oxidized/heme-free sGC and reactivate the enzyme to exert disease-specific vasodilation. Here, we show that oxidation-induced downregulation of sGC protein extends to isolated blood vessels. Mechanistically, degradation was triggered through sGC ubiquitination and proteasomal degradation. The heme-binding site ligand BAY 58-2667 prevented sGC ubiquitination and stabilized both ␣ and  subunits. Collectively, our data establish oxidation-ubiquitination of sGC as a modulator of NO/cGMP signaling and point to a new mechanism of action for sGC activating vasodilators by stabilizing their receptor, oxidized/heme-free sGC. O ne major risk factor for the development of cardiovascular diseases, such as coronary heart disease, stroke, and myocardial infarction, is an imbalance of the production and elimination of reactive oxygen species, also termed as oxidative stress. [1][2][3] As a consequence, the nitric oxide (NO)/ cGMP signaling cascade is impaired, eg, through the excessive production of superoxide, which reacts with NO in a diffusion-limited reaction, yielding peroxynitrite. 4 The biological impact of NO scavenging is further aggravated by the progressive inhibition and downregulation of the NO receptor soluble guanylate cyclase (sGC). [5][6][7][8][9] Circumstantial evidence has implicated proteasomal pathways in this downregulation of sGC. 10 -12 Conversely, a novel class of sGC activators, represented by BAY 58-2667, are potentiated under oxidative stress conditions and represent thus an entirely new diseasespecific vasodilator class. 13 sGC is a heterodimer consisting of an ␣ and a Fe 2ϩ /hemecontaining  subunit that complexes NO with high affinity and specificity. 14 Binding of NO to the Fe 2ϩ /heme results in allosteric activation of the enzyme and enhanced conversion of GTP into the vasorelaxant and antiproliferative second messenger cGMP. 14,15 In vitro experiments have demonstrated that oxidation of sGC heme to its ferric (Fe 3ϩ ) form by the sGC inhibitor 1H-[1,2,4]-oxadiazolo [3,4-a]quinoxalin-1-one (ODQ) attenuates NO-mediated cGMP production, suggesting that the ferro (Fe 2ϩ ) form of sGC is crucial for activation by NO. 16 -18 In addition, studies with primary endothelial and smooth muscle cells have revealed that, within 24 hours, ODQ causes a dramatic decrease in sGC protein levels. 13 Similar results were obtained with other oxidizing compounds such as methylene blue or the peroxynitrite donor 1,3-morpholino-sydnonimine hydrochloride (SIN-1), indicating that oxidative stress triggers downregulation of sGC protein levels. 13 At present, the molecular mechanisms under...
Highlights d The N-terminal region of SENP6 binds to SUMO chains d SENP6 controls SUMOylation of cohesin and regulates sister chromatid cohesion d SENP6 regulates the ATR-Chk1 DNA damage checkpoint d SENP6 orchestrates chromatin dynamics by balancing chromatin residency of proteins
Post-translational modification of proteins with ubiquitin-like SUMO modifiers is a tightly regulated and highly dynamic process. The SENP family of SUMO-specific isopeptidases comprises six cysteine proteases. They are instrumental in counterbalancing SUMO conjugation, but their regulation is not well understood. We demonstrate that in hypoxic cell extracts, the catalytic activity of SENP family members, in particular SENP1 and SENP3, is inhibited in a rapid and fully reversible process. Comparative mass spectrometry from normoxic and hypoxic cells defines a subset of hypoxia-induced SUMO1 targets, including SUMO ligases RanBP2 and PIAS2, glucose transporter 1, and transcriptional regulators. Among the most strongly induced targets, we identified the transcriptional co-repressor BHLHE40, which controls hypoxic gene expression programs. We provide evidence that SUMOylation of BHLHE40 is reversed by SENP1 and contributes to transcriptional repression of the metabolic master regulator gene PGC-1α. We propose a pathway that connects oxygen-controlled SENP activity to hypoxic reprogramming of metabolism.
Nitric oxide (NO)-sensitive soluble guanylyl cyclase (sGC) is the major cytosolic receptor for NO, catalyzing the conversion of GTP to cGMP. In a search for proteins specifically interacting with human sGC, we have identified the multidomain protein AGAP1, the prototype of an ArfGAP protein with a GTPase-like domain, Ankyrin repeats, and a pleckstrin homology domain. AGAP1 binds through its carboxyl terminal portion to both the ␣ 1 and  1 subunits of sGC. We demonstrate that AGAP1 mRNA and protein are co-expressed with sGC in human, murine, and rat cells and tissues and that the two proteins interact in vitro and in vivo. We also show that AGAP1 is prone to tyrosine phosphorylation by Src-like kinases and that tyrosine phosphorylation potently increases the interaction between AGAP1 and sGC, indicating that complex formation is modulated by reversible phosphorylation. Our findings may hint to a potential role of AGAP1 in integrating signals from Arf, NO/cGMP, and tyrosine kinase signaling pathways.
Awareness of drug‐drug interactions is critical in organ transplant recipient management. However, biologic agents interfering with monoclonal antibodies is not widely considered. We report the effect of high‐dose intravenous immunoglobulin (IVIg) on safety, tolerability, pharmacokinetics (PK), and pharmacodynamics (PD) of the human anti‐C5 monoclonal antibody tesidolumab (LFG316) in end‐stage renal disease patients awaiting kidney transplant. In this single‐center, phase 1, open‐label, parallel‐group study, 8 patients were assigned to receive either single‐dose tesidolumab + IVIg or tesidolumab alone, with 56‐day follow‐up. Within‐group PK parameters were consistent. Mean tesidolumab exposure decreased 34%, clearance increased 63%, and half‐life decreased 41% comparing tesidolumab + IVIg to tesidolumab alone. IVIg influence on tesidolumab elimination was most evident in the first 3 weeks. Complete suppression of both total and alternative complement activities was maintained for 4 weeks in the tesidolumab alone group and for 2 weeks in the tesidolumab + IVIg group. Tesidolumab was well tolerated. IVIg infused before tesidolumab affected tesidolumab PK and PD, resulting in a shortened period of full complement activity inhibition. These findings suggest a clinically relevant impact of IVIg on monoclonal antibody clearance and indirectly hint at an IVIg mechanism of action in treating autoimmune diseases and allosensitization by accelerating pathogenic IgG antibody degradation. Trial registration number: NCT02878616.
Post-translational modifications by ubiquitin-related SUMO modifiers regulate cellular signaling networks and protein homeostasis. While SUMO1 is mainly conjugated to proteins as a monomer, SUMO2/3 can form polymeric chains. Poly-SUMOylation is best understood in the SUMO-targeted ubiquitin ligase (StUbL) pathway, where chains prime proteins for subsequent ubiquitylation by StUbLs. SUMO chains typically form in response to genotoxic or proteotoxic stress and are preferentially linked via lysine 11 of SUMO2/3. Here, we report that K11 of SUMO2/3 undergoes reversible acetylation with SIRT1 being the K11 deacetylase. In a purified system, acetylation of SUMO2/3 impairs chain formation and restricts chain length. In a cellular context, however, K11 acetyl-mimicking SUMO2 does not affect the StUbL pathway, indicating that in cells non-canonical chains are more prevalent. MS-based SUMO proteomics indeed identified non-canonical chain types under basal and stress conditions. Importantly, mimicking K11 acetylation alters chain architecture by favoring K5- and K35-linked chains, while inhibiting K7 and K21 linkages. These data provide insight into SUMO chain signaling and point to a role of K11 acetylation as a modulator of SUMO2/3 chains.
Activated SUMOylation is a hallmark of cancer. Starting from a targeted screening for SUMO-regulated immune evasion mechanisms, we identified an evolutionarily conserved function of activated SUMOylation, which attenuated the immunogenicity of tumor cells. Activated SUMOylation allowed cancer cells to evade CD8 + T cell-mediated immunosurveillance by suppressing the MHC class I (MHC-I) antigen-processing and presentation machinery (APM). Loss of the MHC-I APM is a frequent cause of resistance to cancer immunotherapies, and the pharmacological inhibition of SUMOylation (SUMOi) resulted in reduced activity of the transcriptional repressor scaffold attachment factor B (SAFB) and induction of the MHC-I APM. Consequently, SUMOi enhanced the presentation of antigens and the susceptibility of tumor cells to CD8 + T cell-mediated killing. Importantly, SUMOi also triggered the activation of CD8 + T cells and thereby drove a feed-forward loop amplifying the specific antitumor immune response. In summary, we showed that activated SUMOylation allowed tumor cells to evade antitumor immunosurveillance, and we have expanded the understanding of SUMOi as a rational therapeutic strategy for enhancing the efficacy of cancer immunotherapies.
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