OEP37 Is a New Member of the Chloroplast Outer Membrane Ion Channels

Goetze, Tom A.; Philippar, Katrin; Ilkavets, Irina; Soll, Jürgen; Wagner, Richard

doi:10.1074/jbc.m600700200

Cited by 59 publications

(57 citation statements)

References 43 publications

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“…Although both Toc75 and its paralog, outer envelope protein 80 kD (OEP80), are targeted with the assistance of some proteinaceous components on the chloroplast surface, the targeting of OEP80 is independent of the general import pathway, in agreement with the absence of an N-terminal cleavable cTP (Inoue and Potter, 2004;Huang et al, 2011). In fact, all other identified b-barrel proteins on the chloroplast outer membrane, including OEP21 (Bölter et al, 1999), OEP24 (Pohlmeyer et al, 1998), and OEP37 (Goetze et al, 2006), do not have a predicted cTP and are spontaneously integrated into the membrane. In addition to b-barrel proteins, chloroplasts have evolved a-helical integral proteins in the outer membrane, in spite of the endosymbiotic origin from a bacterial progenitor.…”

Section: Introductionmentioning

confidence: 67%

A Transit Peptide–Like Sorting Signal at the C Terminus Directs the Bienertia sinuspersici Preprotein Receptor Toc159 to the Chloroplast Outer Membrane

Lung

Chuong

2012

Plant Cell

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Although Toc159 is known to be one of the key GTPase receptors for selective recognition of chloroplast preproteins, the mechanism for its targeting to the chloroplast surface remains unclear. To compare the targeting of these GTPase receptors, we identified two Toc159 isoforms and a Toc34 from Bienertia sinuspersici, a single-cell C 4 species with dimorphic chloroplasts in individual chlorenchyma cells. Fluorescent protein tagging and immunogold studies revealed that the localization patterns of Toc159 were distinctive from those of Toc34, suggesting different targeting pathways. Bioinformatics analyses indicated that the C-terminal tails (CTs) of Toc159 possess physicochemical and structural properties of chloroplast transit peptides (cTPs). These results were further confirmed by fluorescent protein tagging, which showed the targeting of CT fusion proteins to the chloroplast surface. The CT of Bs Toc159 in reverse orientation functioned as a cleavable cTP that guided the fluorescent protein to the stroma. Moreover, a Bs Toc34 mutant protein was retargeted to the chloroplast envelope using the CTs of Toc159 or reverse sequences of other cTPs, suggesting their conserved functions. Together, our data show that the C terminus and the central GTPase domain represent a novel dual domain-mediated sorting mechanism that might account for the partitioning of Toc159 between the cytosol and the chloroplast envelope for preprotein recognition.

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Section: Introductionmentioning

confidence: 67%

A Transit Peptide–Like Sorting Signal at the C Terminus Directs the Bienertia sinuspersici Preprotein Receptor Toc159 to the Chloroplast Outer Membrane

Lung

Chuong

2012

Plant Cell

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“…With the exception of the capsule polysaccharide export machinery whose outer membrane translocon comprises a novel ␣-helical barrel (35), outer membrane translocator proteins or domains characterized to date appear to be ␤-barrel channel-like conduits, presumably used for the transport of unfolded, or in some cases folded, polypeptides (13, 36 -38). Only a very small number of them have been subjected to electrophysiological analysis (17, 39 -41), and, along with polypeptide-import machineries of chloroplasts and mitochondria (24,33,42,43), they display spontaneous kinetic transitions between open and closed states, and many of them have conductance properties typical of fairly large channels.…”

Section: Discussionmentioning

confidence: 99%

The TpsB Translocator HMW1B of Haemophilus influenzae Forms a Large Conductance Channel

Duret

Szymanski

Choi

et al. 2008

Journal of Biological Chemistry

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The Haemophilus influenzae HMW1 adhesin is secreted via the two-partner secretion pathway and requires HMW1B for translocation across the outer membrane. HMW1B belongs to the Omp85-TpsB superfamily of transporters and consists of two structural domains, a C-terminal transmembrane ␤-barrel and an N-terminal periplasmic domain. We investigated the electrophysiological properties of the purified full-length HMW1B and the C-terminal domain using planar lipid bilayers. Both the full-length and the truncated proteins formed conductive pores with a low open probability, two well defined conductance states, and other substates. The kinetic patterns of the two conductance states were distinct, with rapid and frequent transitions to the small conductance state and occasional and more prolonged openings to the large conductance state. The channel formed by the full-length HMW1B showed selectivity for cations, which decreased when measured at pH 5.2, suggesting the presence of acidic residues in the pore. The C-terminal domain of HMW1B was less stable and required reconstitution into liposomes prior to insertion in the bilayer. It formed a channel of smaller conductance but a similar gating pattern as the full-length protein, demonstrating the ability of the last 312 C-terminal amino acids to form a pore and suggesting that the periplasmic domain is not involved in occluding the pore, nor in controlling the inherent basal kinetics of the channel. The HMW1 pro-piece containing the secretion domain, although binding to the channel with high affinity, did not induce channel opening.Secretion of proteins in the external medium from the cytosol of a Gram-negative bacterium is a complex mechanism. Because of the compartmented structure of the cell envelope, a periplasm limited by the inner membrane and the outer membrane, secreted proteins may need to undergo two translocation processes. Seven main types of mechanisms exist to translocate proteins through the cell envelope (1-6). Some of these pathways export the protein directly from the cytosol to the extracellular milieu, whereas others include a periplasmic intermediate step. In this case, independent translocation pathways exist through the inner membrane and comprise the Sec pathway and the TAT pathway (7). The type V secretion pathway is one of those two-step processes, where proteins are first exported to the periplasm in a Sec-dependent manner (5). The second step involves the translocation through the outer membrane of a passenger peptide through a transporter. In many cases, the passenger and the transporter domains belong to the same polypeptide, thus defining an auto-transporter type of mechanism. The two-partner secretion pathway is distinct in that the secreted exoprotein (TpsA) and its cognate transporter protein (TpsB) are translated as two separate proteins but are coded on the same operon or the same locus. Each TpsB transporter is devoted to the translocation of one specific TpsA. For example, the Haemophilus influenzae HMW1/HMW1B pair represents a prototype t...

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“…Nonanoyl-N-methylglucamide was added up to a final concentration of 80 mM prior to the addition of an equal volume of protein-containing eluate (concentrated to approximately 1 mg of protein/ml). The mixture was incubated for 1.5 h at room temperature and subsequently dialyzed against 100 mM NaCl, 10 mM Mops/Tris, pH 7, for 22 h. The planar lipid bilayer measurements were performed as described previously (19). For a compilation of a representative current-voltage relationship of gating events, the difference of the respective current levels (open and more closed state) was taken from nine independent bilayers (approximately 1380 gating events).…”

Section: Methodsmentioning

confidence: 99%

Characterization of Tic110, a Channel-forming Protein at the Inner Envelope Membrane of Chloroplasts, Unveils a Response to Ca2+ and a Stromal Regulatory Disulfide Bridge

Balsera

Goetze

Kovács-Bogdán

et al. 2009

Journal of Biological Chemistry

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117

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Tic110 has been proposed to be a channel-forming protein at the inner envelope of chloroplasts whose function is essential for the import of proteins synthesized in the cytosol. Sequence features and topology determination experiments presently summarized suggest that Tic110 consists of six transmembrane helices. Its topology has been mapped by limited proteolysis experiments in combination with mass spectrometric determinations and cysteine modification analysis. Two hydrophobic transmembrane helices located in the N terminus serve as a signal for the localization of the protein to the membrane as shown previously. The other amphipathic transmembrane helices are located in the region composed of residues 92-959 in the pea sequence. This results in two regions in the intermembrane space localized to form supercomplexes with the TOC machinery and to receive the transit peptide of preproteins. A large region also resides in the stroma for interaction with proteins such as molecular chaperones. In addition to characterizing the topology of Tic110, we show that Ca 2؉ has a dramatic effect on channel activity in vitro and that the protein has a redox-active disulfide with the potential to interact with stromal thioredoxin.After the proposed endosymbiotic event that gave rise to chloroplasts and, as a consequence, to the massive transfer of genes from the endosymbiont to the host cell nucleus, two new machineries were developed at the outer and inner envelope of chloroplasts, the TOC and TIC complexes, respectively. The machineries transport plastid proteins, whose synthesis was moved to the cytosol, back to the plastid (for a review, see Refs. 1 and 2). Whereas the channel of the TOC complex is homologous to the Omp85 family of transporters in bacteria (3), the TIC complex shows no homology to known transport systems, since the plasma membrane-bacterial transport machineries were relocated to the thylakoid membrane. Moreover, there was an essential requirement for establishing new lines of communication between the organelle and other parts of the cell (4). In chloroplasts of land plants, redox regulation is linked to oxygen and/or light. The regulation of chloroplast-specific processes by redox in accord with the status of the organelle applies not only for transcription and translation but also for translocation. Redox regulation at the translocation level has been proposed for the TIC machinery on the basis of protein composition and dynamics (5-8) as well as specific in vitro import experiments (9). However, despite advances in our biochemical understanding of the import process, little is presently known regarding details of the role of redox or of the structure of the TIC complex, particularly with respect to its channel subunits.Tic110 is essential for protein import into plastids (10 -12). It has been proposed to be a pore-forming protein and one of the main components of the TIC complex (13). Previous studies have provided information about certain aspects of Tic110 structure-function. The region from residu...

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OEP37 Is a New Member of the Chloroplast Outer Membrane Ion Channels

Cited by 59 publications

References 43 publications

A Transit Peptide–Like Sorting Signal at the C Terminus Directs the Bienertia sinuspersici Preprotein Receptor Toc159 to the Chloroplast Outer Membrane

A Transit Peptide–Like Sorting Signal at the C Terminus Directs the Bienertia sinuspersici Preprotein Receptor Toc159 to the Chloroplast Outer Membrane

The TpsB Translocator HMW1B of Haemophilus influenzae Forms a Large Conductance Channel

Characterization of Tic110, a Channel-forming Protein at the Inner Envelope Membrane of Chloroplasts, Unveils a Response to Ca2+ and a Stromal Regulatory Disulfide Bridge

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