Two models have been proposed to explain the interaction of cytochrome c with cardiolipin (CL) vesicles. In one case, an acyl chain of the phospholipid accommodates into a hydrophobic channel of the protein located close the Asn52 residue, whereas the alternative model considers the insertion of the acyl chain in the region of the Met80-containing loop. In an attempt to clarify which proposal offers a more appropriate explanation of cytochrome c-CL binding, we have undertaken a spectroscopic and kinetic study of the wild type and the Asn52Ile mutant of iso-1-cytochrome c from yeast to investigate the interaction of cytochrome c with CL vesicles, considered here a model for the CL-containing mitochondrial membrane. Replacement of Asn52, an invariant residue located in a small helix segment of the protein, may provide data useful to gain novel information on which region of cytochrome c is involved in the binding reaction with CL vesicles. In agreement with our recent results revealing that two distinct transitions take place in the cytochrome c-CL binding reaction, data obtained here support a model in which two (instead of one, as considered so far) adjacent acyl chains of the liposome are inserted, one at each of the hydrophobic sites, into the same cytochrome c molecule to form the cytochrome c-CL complex.
Cytochrome c undergoes structural variations during the apoptotic process; such changes have been related to modifications occurring in the protein when it forms a complex with cardiolipin, one of the phospholipids constituting the mitochondrial membrane. Although several studies have been performed to identify the site(s) of the protein involved in the cytochrome c−cardiolipin interaction, to date the location of this hosting region(s) remains unidentified and is a matter of debate. To gain deeper insight into the reaction mechanism, we investigate the role that the Lys72, Lys73, and Lys79 residues play in the cytochrome c−cardiolipin interaction, as these side chains appear to be critical for cytochrome c−cardiolipin recognition. The Lys72Asn, Lys73Asn, Lys79Asn, Lys72/73Asn, and Lys72/73/79Asn mutants of horse heart cytochrome c were produced and characterized by circular dichroism, ultraviolet−visible, and resonance Raman spectroscopies, and the effects of the mutations on the interaction of the variants with cardiolipin have been investigated. The mutants are characterized by a subpopulation with non-native axial coordination and are less stable than the wild-type protein. Furthermore, the mutants lacking Lys72 and/or Lys79 do not bind cardiolipin, and those lacking Lys73, although they form a complex with the phospholipid, do not show any peroxidase activity. These observations indicate that the Lys72, Lys73, and Lys79 residues stabilize the native axial Met80−Fe(III) coordination as well as the tertiary structure of cytochrome c. Moreover, while Lys72 and Lys79 are critical for cytochrome c−cardiolipin recognition, the simultaneous presence of Lys72, Lys73, and Lys79 is necessary for the peroxidase activity of cardiolipin-bound cytochrome c.
In plants, cysteine protease inhibitors are involved in the regulation of protein turnover and play an important role in resistance against insects and pathogens. AtCYS1 from Arabidopsis thaliana encodes a protein of 102 amino acids that contains the conserved motif of cysteine protease inhibitors belonging to the cystatin superfamily (GlnVal-Val-Ala-Gly). Recombinant A. thaliana cystatin-1 (AtCYS1) was expressed in Escherichia coli and purified. AtCYS1 inhibits the catalytic activity of papain (K d ¼ 4.0 · 10 )2 lM, at pH 7.0 and 25°C), generally taken as a molecular model of cysteine proteases. The molecular bases for papain inhibition by AtCYS1 have been analysed taking into account the three-dimensional structure of the papain-stefin B complex. AtCYS1 is constitutively expressed in roots and in developing siliques of A. thaliana. In leaves, AtCYS1 is strongly induced by wounding, by challenge with avirulent pathogens and by nitric oxide (NO). The overexpression of AtCYS1 blocks cell death activated by either avirulent pathogens or by oxidative and nitrosative stress in both A. thaliana suspension cultured cells and in transgenic tobacco plants. The suppression of the NO-mediated cell death in plants overexpressing AtCYS1 provides the evidence that NO is not cytotoxic for the plant, indicating that NO functions as cell death trigger through the stimulation of an active process, in which cysteine proteases and theirs proteinaceous inhibitors appear to play a crucial role.
A mutation in the rsaL gene of Pseudomonas aeruginosa produces dramatically higher amounts of N-acyl homoserine lactone with respect to the wild type, highlighting the key role of this negative regulator in controlling quorum sensing (QS) in this opportunistic pathogen. The DNA binding site of the RsaL protein on the rsaL-lasI bidirectional promoter partially overlaps the binding site of the LasR protein, consistent with the hypothesis that RsaL and LasR could be in binding competition on this promoter. This is the first direct demonstration that RsaL acts as a QS negative regulator by binding to the lasI promoter.Quorum sensing (QS) is a widespread bacterial intercellular communication system based on the production of signal molecules of which the extra cellular concentration is related to cell density. Individual cells sense the presence of the signal molecule, which allows the whole bacterial population to control gene expression in response to cell density. This form of regulation controls a diverse range of phenotypes, including various pathogenicity determinants, conjugation, biofilm formation, and production of antibiotics and secondary metabolites (16,27,31).Several gram-negative bacteria use acylated homoserine lactones (acyl-HSL) as signal molecules in quorum sensing. The Pseudomonas aeruginosa QS system is one of the most extensively studied within this group of bacteria, reflecting the importance of this microorganism as an opportunistic pathogen of humans, other animals, and plants (10, 15). P. aeruginosa possesses two homologous QS systems encoded by the lasR/lasI and rhlR/rhlI gene pairs. The lasI and rhlI genes encode acyl-HSL synthase enzymes (LasI and RhlI) responsible for the synthesis of the N-3-oxo-dodecanoyl homoserine lactone (3OC 12 -HSL) and N-butyryl homoserine lactone (C 4 -HSL) signal molecules, respectively. The lasR and rhlR genes encode the regulators (i.e., LasR and RhlR) that respond to their cognate signals (i.e., 3OC 12 -HSL and C 4 -HSL) and activate transcription of lasI and rhlI, respectively, thus creating a positive feedback loop. Moreover, the two P. aeruginosa quorumsensing systems are organized in a hierarchical manner, where the RhlR/RhlI system is subordinate to the LasR/LasI system, since expression of rhlR and rhlI is dependent upon LasR (18,24).In P. aeruginosa, QS is a major global regulatory system that has been estimated to control approximately 5% of the genes, including the most important virulence genes (21, 26). Indeed, P. aeruginosa quorum-sensing null mutants are severely impaired in virulence in all the infection model systems examined (reviewed in reference 24).The P. aeruginosa QS system is intricately connected with other cellular global regulatory networks, since it is regulated by a number of regulatory factors, including Vfr (1), GacA (20), the LuxR homologues QscR and VqsR (3, 11), MvaT (5), the alternative sigma factors RpoS and RpoN (8,29), PprB (6), RsmA (19), DksA (9), and RsaL (4). The additional regulation of QS by the above-mentioned factor...
Polyamine oxidase (PAO) is a flavin adenine dinucleotide-dependent enzyme involved in polyamine catabolism. Animal PAOs oxidize spermine (Spm), spermidine (Spd), and/or their acetyl derivatives to produce H 2 O 2 , an aminoaldehyde, and Spd or putrescine, respectively, thus being involved in a polyamine back-conversion pathway. On the contrary, plant PAOs that have been characterized to date oxidize Spm and Spd to produce 1,3-diaminopropane, H 2 O 2 , and an aminoaldehyde and are therefore involved in the terminal catabolism of polyamines. A database search within the Arabidopsis (Arabidopsis thaliana) genome sequence showed the presence of a gene (AtPAO1) encoding for a putative PAO with 45% amino acid sequence identity with maize (Zea mays) PAO. The AtPAO1 cDNA was isolated and cloned in a vector for heterologous expression in Escherichia coli. The recombinant protein was purified by affinity chromatography on guazatine-Sepharose 4B and was shown to be a flavoprotein able to oxidize Spm, norspermine, and N 1 -acetylspermine with a pH optimum at 8.0. Analysis of the reaction products showed that AtPAO1 produces Spd from Spm and norspermidine from norspermine, demonstrating a substrate oxidation mode similar to that of animal PAOs. To our knowledge, AtPAO1 is the first plant PAO reported to be involved in a polyamine back-conversion pathway.
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