Selective cysteines oxidation in soluble guanylyl cyclase catalytic domain is involved in NO activation.

Nitric oxide (NO) binds to soluble guanylyl cyclase (GC1) and stimulates its catalytic activity to produce cGMP. Despite the key role of the NO-cGMP signaling in cardiovascular physiology, the mechanisms of GC1 activation remain ill-defined. It is believed that conserved cysteines (Cys) in GC1 modulate the enzyme's activity through thiol-redox modifications. We previously showed that GC1 activity is modulated via mixed-disulfide bond by protein disulfide isomerase and thioredoxin 1. Herein we investigated the novel concept that NO-stimulated GC1 activity is mediated by thiol/disulfide switches and aimed to map the specific Cys that are involved. First, we showed that the dithiol reducing agent Tris (2-carboxyethyl)-phosphine reduces GC1 response to NO, indicating the significance of Cys oxidation in NO activation. Second, using dibromobimane, which fluoresces when crosslinking two vicinal Cys thiols, we demonstrated decreased fluorescence in NO-stimulated GC1 compared to unstimulated conditions. This suggested that NO-stimulated GC1 contained more bound Cys, potentially disulfide bonds. Third, to identify NO-regulated Cys oxidation using mass spectrometry, we compared the redox status of all Cys identified in tryptic peptides, among which, ten were oxidized and two were reduced in NO-stimulated GC1. Fourth, we resorted to computational modeling to narrow down the Cys candidates potentially involved in disulfide bond and identified Cys489 and Cys571. Fifth, our mutational studies showed that Cys489 and Cys571 were involved in GC1'response to NO, potentially as a thiol/disulfide switch. These findings imply that specific GC1 Cys sensitivity to redox environment is critical for NO signaling in cardiovascular physiology.

The ß1'-ß2' Motif of the RNase H Domain of Human Immunodeficiency Virus Type 1 Reverse Transcriptase Is Responsible for Conferring Open Conformation to the p66 Subunit by Displacing the Connection Domain from the Polymerase Cleft.

The heterodimeric human immunodeficiency virus type 1 reverse transcriptase is composed of p66 and p51 subunits. While in the p51 subunit, the connection domain is tucked in the polymerase cleft; it is effectively displaced from the cleft of the catalytically active p66 subunit. How is the connection domain relocated from the polymerase cleft of p66? Does the RNase H domain have any role in this process? To answer this question, we extended the C-terminal region of p51 by stepwise addition of N-terminal motifs of RNase H domain to generate p54, p57, p60, and p63 derivatives. We found all of the C-terminal extended derivatives of p51 assume open conformation, bind to the template-primer, and catalyze the polymerase reaction. Glycerol gradient ultracentrifugation analysis showed that only p54 sedimented as a monomer, while other derivatives were in a homodimeric conformation. We proposed a model to explain the monomeric conformation of catalytically active p54 derivative carrying additional 21-residues long ß1'-ß2' motif from the RNase H domain. Our results indicate that the ß1'-ß2' motif of the RNase H domain may be responsible for displacing the connection domain from the polymerase cleft of putative monomeric p66. The unstable elongated p66 molecule may then readily dimerize with p51 to assume a stable dimeric conformation.