c-Type Cytochrome Assembly in Saccharomyces cerevisiae: A Key Residue for Apocytochrome c1/Lyase Interaction

The electron transport chains in the membranes of bacteria and organelles generate proton-motive force essential for ATP production. The c-type cytochromes, defined by the covalent attachment of heme to a CXXCH motif, are key electron carriers in these energy-transducing membranes. In mitochondria, cytochromes c and c₁ are assembled by the cytochrome c heme lyases (CCHL and CC₁HL) and by Cyc2p, a putative redox protein. A cytochrome c₁ mutant with a CAPCH heme-binding site instead of the wild-type CAACH is strictly dependent upon Cyc2p for assembly. In this context, we found that overexpression of CC₁HL, as well as mutations of the proline in the CAPCH site to H, L, S, or T residues, can bypass the absence of Cyc2p. The P mutation was postulated to shift the CXXCH motif to an oxidized form, which must be reduced in a Cyc2p-dependent reaction before heme ligation. However, measurement of the redox midpoint potential of apocytochrome c₁ indicates that neither the P nor the T residues impact the thermodynamic propensity of the CXXCH motif to occur in a disulfide vs. dithiol form. We show instead that the identity of the second intervening residue in the CXXCH motif is key in determining the CCHL-dependent vs. CC₁HL-dependent assembly of holocytochrome c₁. We also provide evidence that Cyc2p is dedicated to the CCHL pathway and is not required for the CC₁HL-dependent assembly of cytochrome c₁.THE c-type cytochromes, also referred to as cytochrome c, represent a universal class of heme-containing proteins that function as electron carriers in the energy-transducing pathways of bacteria, plastids, and mitochondria (Thöny-Meyer 1997; Nakamoto et al. 2000; Bonnard et al. 2010). Because cytochromes c carry a heme covalently attached to a CXXCH motif, they constitute an attractive object of study to address the question of cofactor protein assembly. The biochemical requirements for cytochrome c assembly were deduced from in vivo and in vitro studies, and the conclusion is that both apocytochromes c and heme are transported independently across at least one biological membrane and maintained as reduced prior to catalysis of the heme attachment reaction (Allen et al. 2003; Hamel et al. 2009; Kranz et al. 2009; Sanders et al. 2010). Bacterial cytochromes c are assembled in the periplasmic space, a compartment where cysteine pairs in proteins form disulfide bonds in reactions catalyzed by dedicated enzymes (Inaba 2009; Kadokura and Beckwith 2010). The current thinking holds that a c-type apocytochrome is a substrate of the disulfide bond-forming pathway, which introduces an intramolecular disulfide between the two cysteines of the CXXCH sequence (Allen et al. 2003; Sanders et al. 2010). This disulfide needs to be reduced to a dithiol to provide free sulfhydryls for the heme ligation. Consistent with this view is the fact that groups of specific oxido-reductases that constitute a transmembrane dithiol-disulfide relay from the cytosol to the periplasmic space have been shown to function as c-type cytochrome assembly factors (Allen et al. 2003; Kadokura et al. 2003; Mapller and Hederstedt 2006; Sanders et al. 2010). The proposal that the components of this pathway control the in vivo redox status of the CXXCH sulfhydryls has been inferred from the presence of motifs in their protein sequences that are consistent with a function in redox chemistry and also from the demonstration that their recombinant forms participate in dithiol–disulfide exchange reactions (Monika et al. 1997; Setterdahl et al. 2000). Moreover, the ability of exogenous thiol compounds to bypass the lack of these factors in vivo substantiates the view that the redox components have a disulfide-reducing activity in the pathway (e.g., Sambongi and Ferguson 1994; Fabianek et al. 1998; Beckett et al. 2000; Deshmukh et al. 2000; Bardischewsky and Friedrich 2001; Erlendsson and Hederstedt 2002; Erlendsson et al. 2003; Feissner et al. 2005; Turkarslan et al. 2008).While the role of these pathways is well established in bacteria, much less is known about the components that catalyze thiol/disulfide chemistry in the mitochondrial intermembrane space (IMS), which is topologically equivalent to the bacterial periplasm. By analogy with the bacterial pathways, the participation of redox-active factors that catalyze thiol formation is expected, as the mitochondrial IMS houses two c-type cytochromes, the soluble cytochrome c and the membrane-bound cytochrome c₁, both of which function in respiration. In fungi, heme attachment to apocytochromes c and c₁ is dependent upon the IMS resident cytochrome c and c₁ heme lyases, CCHL and CC₁HL, although the exact role of these lyases in the assembly process is still unclear (Dumont et al. 1987; Zollner et al. 1992). Conversion of apocytochrome to holocytochrome c depends only on CCHL, while apocytochrome c₁ can be acted upon by both CCHL and CC₁HL (Matner and Sherman 1982; Dumont et al. 1987; Stuart et al. 1990; Zollner et al. 1992; Bernard et al. 2003). In animals, apoforms of cytochromes c and c₁ are assembled by a unique heme lyase, HCCS, which carries both the CCHL and CC₁HL activities (Prakash et al. 2002; Schwarz and Cox 2002; Bernard et al. 2003).Cyc2p, a component first described as a mitochondrial biogenesis factor in yeast (Matner and Sherman 1982; Dumont et al. 1993; Pearce et al. 1998; Sanchez et al. 2001), was recently rediscovered in the context of cytochrome c₁ maturation (Bernard et al. 2003). Cyc2p is located at the mitochondrial inner membrane with its C-terminal domain containing a non-covalently bound FAD exposed to the IMS (Bernard et al. 2005). A redox function for Cyc2p is likely based on the finding that a recombinant form of the molecule exhibits a NAD(P)H-dependent reductase activity (Bernard et al. 2005). However, as Cyc2p activity is not essential for the maturation process, a functional redundancy was postulated based on the fact that a cyc2-null mutant still assembles holoforms of cytochromes c and c₁ (Bernard et al. 2005). The absolute requirement of Cyc2p was revealed via genetic analysis of the cyc2-null cyt1-34 combination that displays a synthetic respiratory-deficient phenotype with loss of holocytochrome c₁ assembly (Bernard et al. 2005). The cyt1-34 mutation maps to the gene encoding cytochrome c₁ and results in a CAPCH heme-binding site replacing the wild-type CAACH site (Bernard et al. 2005). The synthetic interaction is specific for the cyt1-34 allele carrying the A-to-P mutation and is not observed in a cyc2-null cyt1-48 strain carrying an A-to-D mutation at the heme-binding site of apocytochrome c₁ (Bernard et al. 2005). The fact that Cyc2p becomes essential when the cytochrome c₁ heme-binding site carries an A-to-P mutation suggests that the CXXCH motif could be the target of Cyc2p action in vivo. One possible interpretation for this observation is that the P residue alters the reactivity of the cysteinyl thiols to redox chemistry so that the apocytochrome c₁ CAPCH heme-binding site occurs in an oxidized (disulfide) form, which must be reduced in a Cyc2p-dependent reaction before heme attachment can occur.In this article, we have undertaken a genetic approach to elucidate this pathway and searched for suppressors that alleviate the respiratory deficiency of the cyc2-null cyt1-34 strain. Either overexpression of CC₁HL or replacement of the P mutation in the heme-binding site by H, L, S, or T residues restore the assembly of holocytochrome c₁. In vitro measurement of redox potential of apoforms of CA(A/P/T)CH cytochrome c₁ indicates that there is no change in the thermodynamic stability of the disulfide at the CXXCH motif that could account for the Cyc2p-dependent assembly of cytochrome c₁. Genetic studies reveal that the replacement of the second A residue at the CAACH motif by H, L, P, S, and T residues is key in determining the conversion of apocytochrome c₁ to its corresponding holoform via the CCHL and/or CC₁HL-dependent pathway. We also demonstrate that Cyc2p is a component dedicated to the CCHL pathway and is not required for the CC₁HL-dependent assembly of cytochrome c₁. We propose that the CAPCH cytochrome c₁ is strictly dependent upon CCHL and Cyc2p for its assembly but becomes a substrate of CC₁HL upon overexpression of CC₁HL or in the presence of H, L, S, or T mutations.     

First Biological Data on the Well Established Lessepsian Migrant <Emphasis Type="Italic">Fistularia commersonii</Emphasis> (Fistulariidae) in the Gulf of Tunis (Central Mediterranean)

The present note reports the first study of the Lessepsian migrant, bluespotted cornetfish Fistularia commersonii Rüppell, 1838 from the Gulf of Tunis based on 32 individuals. The male:female ratio was skewed towards females. The length-weight relationship exhibited an isometric growth. Morphometric and meristic characters, information on feeding habits and gonads were also provided. The eventual establishment of F. commersonii within the Mediterranean is then discussed according the available data on reproduction and growth.     

Optimization of transverse alternating field electrophoresis for strain identification of Leuconostoc oenos

Genomic DNA of several strains oof oenological lactic bacteria belonging to the species Lactobacillus plantarum, Leuconostoc oenos and Pediococcus pentosaceus was digested by the rare-cutting endonucleases ApaI and SmaI. The restriction products were separated by transverse alternating field electrophoresis (TAFE). The size of the genome of L. oenos estimated by adding the molecular size of the ApaI fragments was on average 1320 kb. A strong polymorphism was observed between the strains, which could be easily differentiated except for two industrial strains of L. oenos. A simple modification of the TAFE apparatus is proposed to improve the separation of the DNA fragments. Correspondence to: J.-N. Hallet     

Evaluation of a high-density oligonucleotide array for characterization of grlA, grlB, gyrA and gyrB mutations in fluoroquinolone resistant Staphylococcus aureus isolates

Using high-density oligonucleotide array technology, 30 Staphylococcus aureus strains were studied for the presence of mutations in genes involved in fluoroquinolone resistance: grlA, gyrA, grlB and gyrB. For the two most important genes, gyrA and grlA, correlation with sequencing reached 95.1%. If all genes were considered, correlation was 88.8%.     

Functions of Liver Natural Killer Cells Are Dependent on the Severity of Liver Inflammation and Fibrosis in Chronic Hepatitis C

During chronic hepatitis C virus (HCV) infection, the role of intra-hepatic (IH) natural killer (NK) cells is still controversial. To clarify their functions, we investigated anti-viral and cytotoxic activity of NK cells in human fresh liver biopsies. We compared the functions of IH-NK cells in HCV-infected and NASH patients in physiological conditions as well as after stimulation using flow cytometric and immunohistochemical analyses. Interestingly, few IH-NK cells produced anti-viral cytokine IFN-γ in HCV-infected patients similarly as in non-infected individuals. Spontaneous degranulation activity was extremely low in peripheral NK cells compared to IH-NK cells, and was significantly higher in IH-NK cells from HCV-infected patients compared to non-infected individuals. Immunohistochemical analysis revealed that perforin granules were polarized at the apical pole of IH-NK cells. The presence of CD107a and perforin in IH-NK cells demonstrated that NK cells exerted a cytolytic activity at the site of infection. Importantly, IH-NK cell functions from HCV-infected patients were inducible by specific exogenous stimulations. Upon ex vivo K562 target cell stimulations, the number of degranulating NK cells was significantly increased in the pool of IH-NK cells compared to circulating NK cells. Interestingly, after stimulation, the frequency of IFN-γ-producing IH-NK cells in HCV-infected patients was significantly higher at early stage of inflammation whereas the spontaneous IH-NK cell degranulation activity was significantly impaired in patients with highest inflammation and fibrosis Metavir scores. Our study highlights that some IH-NK cells in HCV-infected patients are able to produce INF-γ and degranulate and that those two activities depend on liver environment including the severity of liver injury. Thus, we conclude that critical roles of IH-NK cells have to be taken into account in the course of the liver pathogenesis associated to chronic HCV infection.     

The loss of metabolic control on alcohol drinking in heavy drinking alcohol-dependent subjects

Background

Most physiological studies interested in alcohol-dependence examined ethanol as a pharmacological agent rather than a nutrient. We conducted two studies, which assessed the metabolic and endocrine factors involved in the regulation of alcohol and nutrient intake in alcohol-dependent (AD) subjects. We also examined the potential role of a disruption in energy balance in alcohol-dependence.

Methods and Results

In Study-1, quantitative dietetic interviews of eating and drinking habits were conducted with 97 AD subjects. The population was split around a median alcohol intake value of 12.5 kcal/kg/day. The results showed that the “low alcohol” drinking AD subjects had high Body Mass Index (BMI) and Fat Mass (FM) and alcohol intake was compensated for by a decrease in non-alcoholic intakes. “High alcohol” drinking AD subjects, on the other hand, had low BMI and FM and the total caloric intakes were largely above norms. In Study-2, 24 AD inpatients were submitted to dietetic interviews, calorimetry and blood samplings for the measurement of biomarkers of the regulation of metabolism and satiety, on day 2, 5 and 16 of abstinence. These patients were compared with 20 controls matched for age and gender. We observed in AD patients an increase in cortisol, leptin and PYY plasma levels and a decrease in ghrelin, which might explain the observed decrease in non-alcoholic intakes. However, alcoholic and non-alcoholic intakes correlated positively with basal metabolism and negatively with leptin and leptin/BMI.

Conclusion

For individuals consuming below12.5 kcal/kg/day of alcohol, alcohol intake is compensated for by a decrease in non-alcoholic nutrient intakes, probably due to changes in metabolic and satiety factors. For individuals consuming above 12.5 kcal/kg/day of alcohol, alcohol accelerates metabolism and decreases fat mass and leptin levels, and the total caloric intake largely exceeds norms. A dual model for regulation of energy intake in AD subjects is proposed.     

Muscarinic M2 receptors in acetylcholine-isoproterenol functional antagonism in human isolated bronchus

The muscarinic functional antagonism of isoproterenol relaxation and the contribution of muscarinic M2 receptors were examined in human isolated bronchus. In intact tissues, acetylcholine (ACh) precontraction decreased isoproterenol potency and maximal relaxation (-log EC50 shift = -1.49 +/- 0.16 and E(max) inhibition for 100 microM ACh = 30%) more than the same levels of histamine contraction. The M2 receptor-selective antagonist methoctramine (1 microM) reduced this antagonism in ACh- but not histamine-contracted tissues. Similar results were obtained for forskolin-induced relaxation. After selective inactivation of M3 receptors with 4-diphenylacetoxy-N-(2-chloroethyl)piperadine hydrochloric acid (30 nM), demonstrated by abolition of contractile and inositol phosphate responses to ACh, muscarinic recontractile responses were obtained in U-46619-precontracted tissues fully relaxed with isoproterenol. Methoctramine antagonized recontraction, with pK(B) (6.9) higher than in intact tissues (5.4), suggesting participation of M2 receptors. In M3-inactivated tissues, methoctramine augmented the isoproterenol relaxant potency in U-46619-contracted bronchus and reversed the ACh-induced inhibition of isoproterenol cAMP accumulation. These results indicate that M2 receptors cause indirect contraction of human bronchus by reversing sympathetically mediated relaxation and contribute to cholinergic functional antagonism.     

Chronic Endocannabinoid System Stimulation Induces Muscle Macrophage and Lipid Accumulation in Type 2 Diabetic Mice Independently of Metabolic Endotoxaemia

Aims

Obesity and type 2 diabetes are characterised by low-grade inflammation, metabolic endotoxaemia (i.e., increased plasma lipopolysaccharides [LPS] levels) and altered endocannabinoid (eCB)-system tone. The aim of this study was to decipher the specific role of eCB-system stimulation or metabolic endotoxaemia in the onset of glucose intolerance, metabolic inflammation and altered lipid metabolism.

Methods

Mice were treated with either a cannabinoid (CB) receptor agonist (HU210) or low-dose LPS using subcutaneous mini-pumps for 6 weeks. After 3 weeks of the treatment under control (CT) diet, one-half of each group of mice were challenged with a high fat (HF) diet for the following 3-week period.

Results

Under basal conditions (control diet), chronic CB receptor agonist treatment (i.e., 6 weeks) induced glucose intolerance, stimulated metabolic endotoxaemia, and increased macrophage infiltration (CD11c and F4/80 expression) in the muscles; this phenomenon was associated with an altered lipid metabolism (increased PGC-1α expression and decreased CPT-1b expression) in this tissue. Chronic LPS treatment tended to increase the body weight and fat mass, with minor effects on the other metabolic parameters. Challenging mice with an HF diet following pre-treatment with the CB agonist exacerbated the HF diet-induced glucose intolerance, the muscle macrophage infiltration and the muscle''s lipid content without affecting the body weight or the fat mass.

Conclusion

Chronic CB receptor stimulation under basal conditions induces glucose intolerance, stimulates metabolic inflammation and alters lipid metabolism in the muscles. These effects worsen following the concomitant ingestion of an HF diet. Here, we highlight the central roles played by the eCB system and LPS in the pathophysiology of several hallmarks of obesity and type 2 diabetes.