An autoinhibitory control element defines calcium-regulated isoforms of nitric oxide synthase

Nitric oxide synthases (NOSs) are classified functionally, based on whether calmodulin binding is Ca2+-dependent (cNOS) or Ca2+-independent (iNOS). This key dichotomy has not been defined at the molecular level. Here we show that cNOS isoforms contain a unique polypeptide insert in their FMN binding domains which is not shared with iNOS or other related flavoproteins. Previously identified autoinhibitory domains in calmodulin-regulated enzymes raise the possibility that the polypeptide insert is the autoinhibitory domain of cNOSs. Consistent with this possibility, three-dimensional molecular modeling suggested that the insert originates from a site immediately adjacent to the calmodulin binding sequence. Synthetic peptides derived from the 45-amino acid insert of endothelial NOS were found to potently inhibit binding of calmodulin and activation of cNOS isoforms. This inhibition was associated with peptide binding to NOS, rather than free calmodulin, and inhibition could be reversed by increasing calmodulin concentration. In contrast, insert-derived peptides did not interfere with the arginine site of cNOS, as assessed from [3H]NG-nitro-L-arginine binding, nor did they potently effect iNOS activity. Limited proteolysis studies showed that calmodulin's ability to gate electron flow through cNOSs is associated with displacement of the insert polypeptide; this is the first specific calmodulin-induced change in NOS conformation to be identified. Together, our findings strongly suggest that the insert is an autoinhibitory control element, docking with a site on cNOSs which impedes calmodulin binding and enzymatic activation. The autoinhibitory control element molecularly defines cNOSs and offers a unique target for developing novel NOS activators and inhibitors

De Novo Mutation Found in the Porphobilinogen Deaminase Gene in Slovak Acute Intermittent Porphyria Patient: Molecular Biochemical Study

Summary The porphyrias are group of mostly inherited disorders in which a specific spectrum of accumulated and excreted porphyrins and heme precursors are associated with characteristic clinical features. There are eight enzymes involved in the heme synthesis and defects in seven of them cause porphyria. Four of them are described as acute hepatic porphyrias, which share possible precipitation of acute attacks with symptoms engaging the nervous system. Acute intermittent porphyria (AIP), caused by partial deficiency of the porphobilinogen deaminase (PBGD), is the most frequent among hepatic porphyrias. Clinical expression is highly variable and ~ 90 % of AIP heterozygotes remain asymptomatic throughout life. During systematic genetic analysis of the AIP patients diagnosed in the Czech and Slovak Republics, we found a special case of AIP. In a 15-year-old boy with abdominal and subsequent neurological symptomatology, we identified de novo mutation 966insA within the PBGD gene leading to a stop codon after 36 completely different amino acids compared to the wt-sequence. To establish the effects of this mutation on the protein structure, we expressed mutant constructs with described mutation in E. coli and analyzed their biochemical and enzymatic properties. Moreover, computer-assisted protein structure prediction was performed

A new concept for the role of nitrite in the vasculature: eNOS as nitrite reductase

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European Porphyria Initiative (EPI): A platform to develop a common approach to the management of porphyrias and to promote research in the field

Porphyrias are uncommon inherited diseases of haem biosynthesis for which the diagnosis and treatment varies in individual countries. Despite the existence of guidelines recommended by porphyria experts concerning the diagnosis and management of the acute porphyrias, and of specialist centres in most European countries, many clinicians still do not apply these guidelines. The European Porphyia Initiative (EPI) network was formed in 2001 in order to compare experience among countries to attempt to develop a common approach to the management of the porphyrias, particularly concerning recommendation of safe and unsafe drugs, and to facilitate international collaborative clinical and biological research. The main achievements of EPI during this period have been: • Drafting and agreeing to consensus protocols for the diagnosis and management of acute hepatic porphyrias • Creation of a multilingual website, particularly focusing on guidelines for common prescribing problems in acute porphyria and on providing information for patients that is now available in 10 languages: www.porphyria-europe.org. EPI’s current objectives are to develop the EPI platform, expand to new countries, extend to non-acute porphyrias an

Dynamics of NO rebinding to the heme domain of NO synthase-like proteins from bacterial pathogens

International audienceSome Gram-positive bacterial pathogens harbor a gene that encodes a protein (HNS, Heme domain of NO Synthase-like proteins) with striking sequence identity to the oxygenase domain of mammalian NO synthases (NOS). However, they lack the N-terminal and the Zn-cysteine motif participating to the stability of an active dimer in the mammalian isoforms. The unique properties of HNS make it an excellent model system for probing how the heme environment tunes NO dynamics and for comparing it to the endothelial NO synthase heme domain (eNOSHD) using ultrafast transient spectroscopy. NO rebinding in HNS from Staphylococcus aureus (SA-HNS) is faster than that measured for either Bacillus anthracis (BA-HNS) or for eNOSHD in both oxidized and reduced forms in the presence of arginine. To test whether these distinct rates arise from different energy barriers for NO recombination, we measured rebinding kinetics at several temperatures. Our data are consistent with different barriers for NO recombination in SA-HNS and BA-HNS and the presence of a second NO-binding site. The hypothesis that an additional NO-binding cavity is present in BA-HNS is also consistent with the effect of the NO concentration on its rebinding. The lack of the effect of NO concentration on the geminate rebinding in SA-HNS could be due to an isolated second site. We confirm the existence of a second NO site in the oxygenase domain of the reduced eNOS as previously hypothesized [A. Slama-Schwok, M. Négrerie, V. Berka, J.C. Lambry, A.L. Tsai, M.H. Vos, J.L. Martin, Nitric oxide (NO) traffic in endothelial NO synthase. Evidence for a new NO binding site dependent on tetrahydrobiopterin? J. Biol. Chem. 277 (2002) 7581-7586]. This site requires the presence of arginine and BH4; and we propose that NO dynamic and escape from eNOS is regulated by the active site H-bonding network connecting between the heme, the substrate, and cofactor. Cop. 2006 Elsevier Inc. All rights reserved

Endothelial nitric oxide synthase reduces nitrite anions to NO under anoxia

International audienceIn this work, we demonstrate that endothelial nitric oxide synthase is capable of anoxic reduction of nitrite anions to nitric oxide at physiological pH by absorption and EPR spectroscopy and electrochemical measurements. The nitrite reduction is achieved at the oxygenase domain of the protein and proceeds even in the absence of the tetrahydrobiopterin cofactor. The nitrite pathway increases by sixfold the NO production with respect to the regular arginine pathway under hypoxia, which is largely blocked. Therefore, basal levels of NO release could be sustained by anoxic nitrite reduction. The reaction suggests a new pathway for fast NO delivery under hypoxia, precisely when the vasodilating properties of nitric oxide are most needed. (c) 2006 Elsevier Inc. All rights reserved

Folic acid reverts dysfunction of endothelial nitric oxide synthase.

International audience5-methyltetrahydrofolate (MTHF), the active form of folic acid, has been reported to restore NO status in hypercholesterolemic patients. The mechanism of this effect remains to be established. We assessed the effects of L- and D-MTHF on tetrahydrobiopterin (BH(4))-free and partially BH(4)-repleted endothelial NO synthase (eNOS). Superoxide production of eNOS and the rate constants for trapping of superoxide by MTHF were determined with electron paramagnetic resonance using 5-diethoxyphosphoryl-5-methyl-1-pyrroline-N-oxide (DEPMPO) as spin trap for superoxide. NO production was measured with [(3)H]arginine-citrulline conversion or nitrite assay. The rate constants for scavenging of superoxide by L- and D-MTHF were similar, 1.4 x 10(4) ms(-1). In BH(4)-free eNOS, L- and D-MTHF have no effect on enzymatic activity. In contrast, in partially BH(4)-repleted eNOS, we observe a 2-fold effect of MTHF on the enzymatic activity. First, superoxide production is reduced. Second, NO production is enhanced. In cultured endothelial cells, a similar enhancement of NO production is induced by MTHF. In the present study, we show direct effects of MTHF on the enzymatic activity of NO synthase both in recombinant eNOS as well as in cultured endothelial cells, which provides a plausible explanation for the previously reported positive effects of MTHF on NO status in vivo