Modifications of the lipoamide-containing mitochondrial subproteome in a yeast mutant defective in cysteine desulfurase

Comparison and identification of mitochondrial matrix proteins from wild-type and cysteine desulfurase-defective (nfs1-14, carrying a hypomorphic allele of NFS1) yeast strains, using two-dimensional gel electrophoresis coupled to mass spectrometry analyses, revealed large changes in the amounts of various proteins. Protein spots that were specifically increased in the nfs1-14 mutant included subunits of lipoamide-containing enzyme complexes: Kgd2, Lat1, and Gcv3, subunits of the mitochondrial alpha-ketoglutarate dehydrogenase, pyruvate dehydrogenase, and glycine cleavage system complexes, respectively. Moreover the increased protein spots corresponded to lipoamide-deficient forms in the nfs1-14 mutant. The increased proteins migrated as separate, cathode-shifted spots, consistent with gain of a lysine charge due to lack of lipoamide addition. Lack of lipoylation of these proteins was further validated using an antibody specific for lipoamide-containing proteins. In addition, this antibody revealed a fourth lipoamide-containing protein, probably corresponding to the E2 component of the branched-chain keto acid dehydrogenase complex. Like the lipoamide-containing forms of Kgd2, Lat1, and Gcv3, this protein also showed decreased lipoic acid reactivity in the nfs1-14 mutant. Cysteine desulfurases, such as yeast NFS1, are required for sulfur addition to iron-sulfur clusters and other sulfur-requiring processes. The results demonstrate that Nfs1 protein is required for the proper post-translational modification of the lipoamide-containing mitochondrial subproteome in yeast and pave the road toward a thorough understanding of its precise role in lipoic acid synthesis.     

Proteotypic profiling of LHCI from Chlamydomonas reinhardtii provides new insights into structure and function of the complex

We used isotope dilution MS to measure the stoichiometry of light‐harvesting complex I (LHCI) proteins with the photosystem I (PSI) core complex in the green alga Chlamydomonas reinhardtii. Proteotypic peptides served as quantitative markers for each of the nine gene products (Lhca1–9) and for PSI subunits. The quantitative data revealed that the LHCI antenna of C. reinhardtii contains about 7.5 ± 1.4 subunits. It further demonstrated that the thylakoid LHCI population is heterogeneously composed and that several lhca gene products are not present in 1:1 stoichiometries with PSI. When compared with vascular plants, LHCI of C. reinhardtii possesses a lower proportion of proteins potentially contributing to far‐red fluorescence emission. In general, the strategy presented is universally applicable for exploring subunit stoichiometries within the C. reinhardtii proteome.     

The PsaC subunit of photosystem I provides an essential lysine residue for fast electron transfer to ferredoxin.

PsaC is the stromal subunit of photosystem I (PSI) which binds the two terminal electron acceptors FA and FB. This subunit resembles 2[4Fe-4S] bacterial ferredoxins but contains two additional sequences: an internal loop and a C-terminal extension. To gain new insights into the function of the internal loop, we used an in vivo degenerate oligonucleotide-directed mutagenesis approach for analysing this region in the green alga Chlamydomonas reinhardtii. Analysis of several psaC mutants affected in PSI function or assembly revealed that K35 is a main interaction site between PsaC and ferredoxin (Fd) and that it plays a key role in the electrostatic interaction between Fd and PSI. This is based upon the observation that the mutations K35T, K35D and K35E drastically affect electron transfer from PSI to Fd, as measured by flash-absorption spectroscopy, whereas the K35R change has no effect on Fd reduction. Chemical cross-linking experiments show that Fd interacts not only with PsaD and PsaE, but also with the PsaC subunit of PSI. Replacement of K35 by T, D, E or R abolishes Fd cross-linking to PsaC, and cross-linking to PsaD and PsaE is reduced in the K35T, K35D and K35E mutants. In contrast, replacement of any other lysine of PsaC does not alter the cross-linking pattern, thus indicating that K35 is an interaction site between PsaC and its redox partner Fd.     

The energy conserving methyltetrahydromethanopterin:coenzyme M methyltransferase complex from methanogenic archaea: function of the subunit MtrH.

In methanogenic archaea the transfer of the methyl group of N5-methyltetrahydromethanopterin to coenzyme M is coupled with energy conservation. The reaction is catalyzed by a membrane associated multienzyme complex composed of eight different subunits MtrA-H. The 23 kDa subunit MtrA harbors a corrinoid prosthetic group which is methylated and demethylated in the catalytic cycle. We report here that the 34 kDa subunit MtrH catalyzes the methylation reaction. MtrH was purified and shown to exhibit methyltetrahydromethanopterin:cob(I)alamin methyltransferase activity. Sequence comparison revealed similarity of MtrH with MetH from Escherichia coli and AcsE from Clostridium thermoaceticum: both enzymes exhibit methyltetrahydrofolate:cob(I)alamin methyltransferase activity.     

Photosystem I light-harvesting proteins regulate photosynthetic electron transfer and hydrogen production

Linear electron flow (LEF) and cyclic electron flow (CEF) compete for light-driven electrons transferred from the acceptor side of photosystem I (PSI). Under anoxic conditions, such highly reducing electrons also could be used for hydrogen (H₂) production via electron transfer between ferredoxin and hydrogenase in the green alga Chlamydomonas reinhardtii. Partitioning between LEF and CEF is regulated through PROTON-GRADIENT REGULATION5 (PGR5). There is evidence that partitioning of electrons also could be mediated via PSI remodeling processes. This plasticity is linked to the dynamics of PSI-associated light-harvesting proteins (LHCAs) LHCA2 and LHCA9. These two unique light-harvesting proteins are distinct from all other LHCAs because they are loosely bound at the PSAL pole. Here, we investigated photosynthetic electron transfer and H₂ production in single, double, and triple mutants deficient in PGR5, LHCA2, and LHCA9. Our data indicate that lhca2 and lhca9 mutants are efficient in photosynthetic electron transfer, that LHCA2 impacts the pgr5 phenotype, and that pgr5/lhca2 is a potent H₂ photo-producer. In addition, pgr5/lhca2 and pgr5/lhca9 mutants displayed substantially different H₂ photo-production kinetics. This indicates that the absence of LHCA2 or LHCA9 impacts H₂ photo-production independently, despite both being attached at the PSAL pole, pointing to distinct regulatory capacities.

Alteration of the light-harvesting composition of photosystem I impacts photosynthetic electron transfer and hydrogen production.     

PHOTOSYSTEM II SUBUNIT R Is Required for Efficient Binding of LIGHT-HARVESTING COMPLEX STRESS-RELATED PROTEIN3 to Photosystem II-Light-Harvesting Supercomplexes in Chlamydomonas reinhardtii

In Chlamydomonas reinhardtii, the LIGHT-HARVESTING COMPLEX STRESS-RELATED PROTEIN3 (LHCSR3) protein is crucial for efficient energy-dependent thermal dissipation of excess absorbed light energy and functionally associates with photosystem II-light-harvesting complex II (PSII-LHCII) supercomplexes. Currently, it is unknown how LHCSR3 binds to the PSII-LHCII supercomplex. In this study, we investigated the role of PHOTOSYSTEM II SUBUNIT R (PSBR) an intrinsic membrane-spanning PSII subunit, in the binding of LHCSR3 to PSII-LHCII supercomplexes. Down-regulation of PSBR expression diminished the efficiency of oxygen evolution and the extent of nonphotochemical quenching and had an impact on the stability of the oxygen-evolving complex as well as on PSII-LHCII-LHCSR3 supercomplex formation. Its down-regulation destabilized the PSII-LHCII supercomplex and strongly reduced the binding of LHCSR3 to PSII-LHCII supercomplexes, as revealed by quantitative proteomics. PHOTOSYSTEM II SUBUNIT P deletion, on the contrary, destabilized PHOTOSYSTEM II SUBUNIT Q binding but did not affect PSBR and LHCSR3 association with PSII-LHCII. In summary, these data provide clear evidence that PSBR is required for the stable binding of LHCSR3 to PSII-LHCII supercomplexes and is essential for efficient energy-dependent quenching and the integrity of the PSII-LHCII-LHCSR3 supercomplex under continuous high light.Plant photosynthetic electron transfer is conducted by a series of reactions at the chloroplast thylakoid membrane, resulting in light-dependent water oxidation, NADP reduction, and ATP formation (Whatley et al., 1963). Two separate photosystems (PSI and PSII) and an ATP synthase catalyze these reactions. PSI and PSII are multiprotein complexes that are mainly embedded in unstacked and stacked regions of the thylakoid membrane, respectively. PSI consists of more than 10 subunits and a number of cofactors such as chlorophyll a, β-carotene, phylloquinone, and three iron-sulfur (4Fe-4S) clusters (Busch and Hippler, 2011). PSI catalyzes light-driven electron transfer from luminal plastocyanin to stromal ferredoxin. The latter reduces the ferredoxin-NADP reductase that, in turn, leads to the formation of NADPH. PSII catalyzes light-induced electron transfer from water to the plastoquinone pool by using chlorophyll a, carotenoids, as well as redox-active cofactors, causing the release of oxygen and protons (Pagliano et al., 2013). The core complex is organized as a dimer. Monomers are composed of the reaction center subunits PSBA (D1) and PSBD (D2), the inner antenna proteins PSBB (CP47) and PSBC (CP43), the α- and β-subunits (PSBE and PSBF) of cytochrome b₅₅₉, as well as a number of intrinsic low-molecular-mass subunits. The core monomer is further associated with an inorganic Mn₄O₅Ca cluster and a few chloride ions (Rivalta et al., 2011; Umena et al., 2011) required for photosynthetic water oxidation. To optimize this process, the oxygen-evolving complex is formed at the luminal side by the extrinsic polypeptides PSBO, PSBP, PSBQ, and PSBR (for review, see Pagliano et al., 2013).To enhance the light-harvesting capacity of PSII, various light-harvesting proteins bind to dimeric PSII core complexes (Dekker and Boekema, 2005). A common structure found for vascular plants and green algae is the C₂S₂ supercomplex, where two copies of monomeric Lhcb4 and Lhcb5 and two LHCII trimers (S-trimer; Boekema et al., 1995) bind to the dimeric PSII core. In vascular plants, larger but less stable PSII supercomplexes, known as C₂S₂M₂, are composed of two extra copies of the monomeric Lhcb6 with two additional LHCII trimers (M-trimer) bound through Lhcb4 and Lhcb5 (Dekker and Boekema, 2005; Caffarri et al., 2009). Even larger complexes containing two additional LHCII trimers (L-trimer), bound via Lhcb6, are found and are known as C₂S₂M₂L_1–2 (Boekema et al., 1999). A recent study in Chlamydomonas reinhardtii identified PSII-LHCII supercomplexes with three LHCII trimers attached to each side of the core (C₂S₂M₂L₂; Tokutsu et al., 2012). Interestingly, such PSII-LHCII supercomplexes associate with LIGHT-HARVESTING COMPLEX STRESS-RELATED PROTEIN3 (LHCSR3; Tokutsu and Minagawa, 2013), an ancient light-harvesting protein required for efficient energy-dependent (qE) quenching in the alga (Peers et al., 2009). The qE component of nonphotochemical quenching (NPQ) is an energy-dependent constituent of NPQ and regulates the thermal dissipation of excess absorbed light energy (Li et al., 2000; Peers et al., 2009). The qE capacity in C. reinhardtii increases proportionally to the light-dependent accumulation of the LHCSR3 protein (Peers et al., 2009). In contrast, in vascular plants, qE is constitutively active and dependent on PSBS, a PSII polypeptide (Li et al., 2000). Mass spectrometric analyses of isolated C₂S₂M₂ PSII supercomplexes revealed the presence of extrinsic subunits PSBP, PSBQ, and PSBR, while PSBS was not identified, suggesting that PSBS does not influence the association of the PSII core with the outer light-harvesting complex system (Pagliano et al., 2014). In line with the proteomic findings, recent data suggest that subunits PSBP, PSBQ, and PSBR contribute to the stability of PSII-LHCII supercomplexes in vascular plants (Caffarri et al., 2009; Ifuku et al., 2011; Allahverdiyeva et al., 2013). A recent quantitative proteomic study performed with C. reinhardtii identified PSBR as the only PSII subunit to be induced upon the shift from photoheterotrophic to photoautotrophic growth conditions similar to LHCSR3 (Höhner et al., 2013).In vascular plants and green algae, PSBR is nucleus encoded and has a mass of about 10 kD. The mature protein has a predicted 70-amino acid luminal N-terminal part and a C-terminal transmembrane span (Ljungberg et al., 1986; Lautner et al., 1988; Webber et al., 1989). An association of PSBR with the oxygen-evolving complex has been suggested, as its presence is required for the stable assembly of PSBP with the PSII core and its absence also impacts the binding of PSBQ to the core (Suorsa et al., 2006; Liu et al., 2009). For stable association with the PSII core complex, PSBR needs the presence of PSBJ (Suorsa et al., 2006). Functionally, the depletion of PSBR protein expression decreased rates of oxygen evolution (Allahverdiyeva et al., 2007, 2013) and quinone reoxidation (Allahverdiyeva et al., 2007). PSBR phosphorylation is known for Arabidopsis (Arabidopsis thaliana; Reiland et al., 2009, 2011; Nakagami et al., 2010) and in the green alga C. reinhardtii (Turkina et al., 2006), although phosphorylation sites are not conserved between the alga and the vascular plant.In this work, we addressed the question of whether down-regulation of PSBR expression would affect LHCSR3 binding to the PSII-LHCII supercomplex in C. reinhardtii. To this end, we took advantage of artificial microRNA (amiRNA) technology to down-regulate PSBR expression and investigated the impact of PSBR down-regulation on photosynthetic performance as well as on PSII-LHCII-LHCSR3 supercomplex formation. Our data provide evidence that PSBR is required for the stable binding of LHCSR3 to PSII-LHCII supercomplexes.     

The composition and structure of photosystem I‐associated antenna from Cyanidioschyzon merolae

Red algae contain two types of light‐harvesting antenna systems, the phycobilisomes and chlorophyll a binding polypeptides (termed Lhcr), which expand the light‐harvesting capacity of the photosynthetic reaction centers. In this study, photosystem I (PSI) and its associated light‐harvesting proteins were isolated from the red alga Cyanidioschyzon merolae. The structural and functional properties of the largest PSI particles observed were investigated by biochemical characterization, mass spectrometry, fluorescence emission and excitation spectroscopy, and transmission electron microscopy. Our data provide strong evidence for a stable PSI complex in red algae that possesses two distinct types of functional peripheral light‐harvesting antenna complex, comprising both Lhcr and a PSI‐linked phycobilisome sub‐complex. We conclude that the PSI antennae system of red algae represents an evolutionary intermediate between the prokaryotic cyanobacteria and other eukaryotes, such as green algae and vascular plants.     

Parallel on-line detection of a methylbismuth species by hyphenated GC/EI-MS/ICP-MS technique as evidence for bismuth methylation by human hepatic cells

Methylation of metal(loid)s by bacteria or even mammals is a well known process that can lead to increased toxicity for humans. Nevertheless, reliable analytical techniques and tools are indispensable in speciation analysis of trace elements, especially since environmental or biological samples are usually characterised by complex matrices. Here the methylating capability of hepatic cells was observed in vitro. HepG2 cells were incubated with colloidal bismuth subcitrate, bismuth cysteine and bismuth glutathione, respectively for a period of 24 h. For identification the cell lysate was ethylated by sodium tetraethyl borate under neutral conditions. After cryo focussing by purge and trap, the bismuth speciation was carried out via GC/EI-MS/ICP-MS. Colloidal bismuth subcitrate and bismuth cysteine were methylated by HepG2 cells, while no methylated bismuth species was detected after incubation with bismuth glutathione.