Proton transfer limits protein translocation rate by the thylakoid DeltapH/Tat machinery

The thylakoid transmembrane DeltapH is the sole energy source driving translocation of precursor proteins by the DeltapH/Tat machinery. Consequently, proton translocation must be coupled to precursor translocation. For the precursor of the 17 kDa protein of the oxygen-evolving complex (pOE17), the protein translocation process is characterized by a steep drop in efficiency at an external pH below 7.0 and above 8.7. As the membrane DeltapH is virtually unaffected from pH 6.5 to 9.2, the loss in import efficiency is a consequence of the titration of multiple residues within the translocation machinery. Transport is retarded by a factor of 2-3 in deuterium oxide (D(2)O) relative to water, strongly suggesting that proton-transfer reactions limit translocation rate. The solvent isotope effect manifests itself after the precursor binds to the membrane, indicating that the rate-limiting step is a later event in the transport process.     

In vivo dissection of the Tat translocation pathway in Escherichia coli

The bacterial Tat pathway is capable of exporting folded proteins carrying a special twin arginine (RR) signal peptide. By using two in vivo reporter proteins, we assessed factors that affect Tat pathway transport. We observed that, like the intact RR signal peptide, those with a KR or RK substitution were still capable of mediating the translocation of the folded green fluorescent protein (GFP). However, the translocation efficiency decreased in the order of RR>KR>RK. The KK motif was unable to mediate GFP translocation. The translocation of the RR-GFP fusion required TatA, TatB and TatC proteins. By exploiting the periplasmic bactericidal property of colicin V (ColV), we constructed a translocation-suicide probe, RR-ColV. The translocation of RR-ColV fully inhibited the growth of wild-type Escherichia coli and those of the DeltatatD and DeltatatE mutants. In contrast, the deletion of the tatC gene blocked RR-ColV in the cytoplasm and this strain exhibited a normal growth phenotype. Interestingly, the growth of DeltatatA and tatB mutants was inhibited partially by RR-ColV. Moreover, KR, RK and KK motifs were capable of mediating the ColV translocation with a decreasing RR=KR>RK>KK efficiency. In addition to TatE and TatC proteins, either TatA or TatB was sufficient for the translocation of RR-ColV or KR-ColV. In contrast, TatA plus the conserved N-terminal domain of TatB were required to mediate the killing effect of ColV fused to the less-efficient RK signal peptide. Taken together, these results suggest that a fully efficient Tat pathway transport is determined by the sequence of the signal peptide, the composition of the Tat apparatus, and the intrinsic characteristics of exported proteins.     

A twin-arginine translocation (Tat)-mediated phage display system

The major limitation of conventional phage display is caused by its dependence on the Sec translocation pathway. All proteins displayed on filamentous phages must first be transported into the bacterial periplasm in an unfolded state via the Sec translocation machinery. Proteins that require a cytoplasmic environment and/or cytoplasmic components for folding, or that contain "stop transfer" signals, or reach their native state before they interact with the Sec proteins are not compatible with the Sec pathway. They can never be presented using conventional phage display. We have developed an alternative phage display system, termed the TPD system, which overcomes these limitations of conventional phage display by exploiting the properties of the twin-arginine translocation (Tat) pathway. The Tat pathway only exports folded proteins that have already attained their native conformation in the cytoplasm. We investigated the functional efficiency of the TPD system by displaying and panning for a mutant of the green fluorescent protein.     

Transport of cytochrome c derivatives by the bacterial Tat protein translocation system

An experimental system developed previously for the heterologous expression of c-type cytochromes in Escherichia coli Q1has been adapted to monitor protein transfer across the bacteria's cytoplasmic membrane. Apocytochrome, lacking the haem cofactor and probably in an unfolded state, was readily transferred across the cytoplasmic membrane when fused to a Sec-specific signal peptide. Furthermore, cytochrome fused to a signal peptide regarded as specific for the twin arginine transport (Tat) system was translocated in an unfolded state by the Sec apparatus. After maturation and folding in the cytoplasm, Tat-mediated transfer of holocytochrome to the periplasm occurred. We conclude that, in addition to the nature of the specific signal peptide, the folding state of a particular protein also governs its acceptance by a given transport system.     

The thylakoid proton gradient promotes an advanced stage of signal peptide binding deep within the Tat pathway receptor complex

Tat (twin arginine translocation) systems transport folded proteins across the thylakoid membrane of chloroplasts and the plasma membrane of most bacteria. Tat precursors are targeted by hydrophobic cleavable signal peptides with twin arginine (RR) motifs. Bacterial precursors possess an extended consensus, (S/T)RRXFLK, of which the two arginines and the phenylalanine are essential for efficient transport. Thylakoid Tat precursors possess twin arginines but lack the consensus phenylalanine. Here, we have characterized two stages of precursor binding to the thylakoid Tat signal peptide receptor, the 700-kDa cpTatC-Hcf106 complex. The OE17 precursor tOE17 binds to the receptor by RR-dependant electrostatic interactions and partially dissociates during blue native gel electrophoresis. In addition, the signal peptide of thylakoid-bound tOE17 is highly exposed to the membrane surface, as judged by accessibility to factor Xa of cleavage sites engineered into signal peptide flanking regions. By contrast, tOE17 containing a consensus phenylalanine in place of Val(-20) (V - 20F) binds the receptor more strongly and is completely stable during blue native gel electrophoresis. Thylakoid bound V - 20F is also completely protected from factor Xa at the identical sites. This suggests that the signal peptide is buried deeply in the cpTatC-Hcf106 binding site. We further provide evidence that the proton gradient, which is required for translocation, induces a tighter interaction between tOE17 and the cpTat machinery, similar to that exhibited by V - 20F. This implies that translocation involves a very intimate association of the signal peptide with the receptor complex binding site.     

Diffusion of a membrane protein, Tat subunit Hcf106, is highly restricted within the chloroplast thylakoid network

The thylakoid membrane forms stacked thylakoids interconnected by ‘stromal’ lamellae. Little is known about the mobility of proteins within this system. We studied a stromal lamellae protein, Hcf106, by targeting an Hcf106-GFP fusion protein to the thylakoids and photobleaching. We find that even small regions fail to recover Hcf106-GFP fluorescence over periods of up to 3 min after photobleaching. The protein is thus either immobile within the thylakoid membrane, or its diffusion is tightly restricted within distinct regions. Autofluorescence from the photosystem II light-harvesting complex in the granal stacks likewise fails to recover. Integral membrane proteins within both the stromal and granal membranes are therefore highly constrained, possibly forming ‘microdomains’ that are sharply separated.     

Transport and proofreading of proteins by the twin-arginine translocation (Tat) system in bacteria

The twin-arginine translocation (Tat) system operates in plant thylakoid membranes and the plasma membranes of most free-living bacteria. In bacteria, it is responsible for the export of a number of proteins to the periplasm, outer membrane or growth medium, selecting substrates by virtue of cleavable N-terminal signal peptides that contain a key twin-arginine motif together with other determinants. Its most notable attribute is its ability to transport large folded proteins (even oligomeric proteins) across the tightly sealed plasma membrane. In Gram-negative bacteria, TatABC subunits appear to carry out all of the essential translocation functions in the form of two distinct complexes at steady state: a TatABC substrate-binding complex and separate TatA complex. Several studies favour a model in which these complexes transiently coalesce to generate the full translocase. Most Gram-positive organisms possess an even simpler "minimalist" Tat system which lacks a TatB component and contains, instead, a bifunctional TatA component. These Tat systems may involve the operation of a TatAC complex together with a separate TatA complex, although a radically different model for TatAC-type systems has also been proposed. While bacterial Tat systems appear to require the presence of only a few proteins for the actual translocation event, there is increasing evidence for the operation of ancillary components that carry out sophisticated "proofreading" activities. These activities ensure that redox proteins are only exported after full assembly of the cofactor, thereby avoiding the futile export of apo-forms. This article is part of a Special Issue entitled Protein translocation across or insertion into membranes.     

The twin-arginine translocation (Tat) system is essential for Rhizobium-legume symbiosis

The Tat (twin-arginine translocation) system mediates export of periplasmic proteins in folded conformation. Proteins transported via Tat contain a characteristic twin-arginine motif in their signal peptide. Genetic determinants (tatABC genes) of the Tat system from Rhizobium leguminosarum bv. viciae were cloned and characterized, and a tatBC deletion mutant was constructed. The mutant lacked the ability for membrane targeting of hydrogenase, a known Tat substrate, and was impaired in hydrogenase activity. Interestingly, in the absence of a functional Tat system, only small, white nodules unable to fix nitrogen were induced in symbiosis with pea plants. Analysis of nodule structure and location of green fluorescent protein (GFP)-tagged bacteria within nodules indicated that the symbiotic process was blocked in the tat mutant at a stage previous to bacteria release into cortical cells. The R. leguminosarum Tat-deficient mutant lacked a functional cytochrome bc1 complex. This was consistent with the fact that R. leguminosarum Rieske protein, a key component of the symbiosis-essential cytochrome bc1 complex, contained a typical twin-arginine signal peptide. However, comparative analyses of nodule structure indicated that nodule development in the tat mutant was arrested at an earlier step than in a cytochrome bc1 mutant. These data indicate that the Tat pathway is also critical for proteins relevant to the initial stages of the symbiotic process.     

Functional reconstitution of bacterial Tat translocation in vitro

The Tat (twin-arginine translocation) pathway is a Sec-independent mechanism for translocating folded preproteins across or into the inner membrane of Escherichia coli. To study Tat translocation, we sought an in vitro translocation assay using purified inner membrane vesicles and in vitro synthesized substrate protein. While membrane vesicles derived from wild-type cells translocate the Sec-dependent substrate proOmpA, translocation of a Tat-dependent substrate, SufI, was not detected. We established that in vivo overexpression of SufI can saturate the Tat translocase, and that simultaneous overexpression of TatA, B and C relieves this SufI saturation. Using membrane vesicles derived from cells overexpressing TatABC, in vitro translocation of SufI was detected. Like translocation in vivo, translocation of SufI in vitro requires TatABC, an intact membrane potential and the twin-arginine targeting motif within the signal peptide of SUFI: In contrast to Sec translocase, we find that Tat translocase does not require ATP. The development of an in vitro translocation assay is a prerequisite for further biochemical investigations of the mechanism of translocation, substrate recognition and translocase structure.     

Protein transport towards the thylakoid lumen: post-translational translocation in tandem

Many proteins found in the chloroplast are synthesized in the cytoplasm as precursor molecules containing transit peptides. Proteins targeted to the stroma must pass through the two envelope membranes to reach their destination. Proteins located in the chloroplast lumen also have to be transferred across the thylakoid membrane. That is, lumen proteins must cross three biological membranes in order to reach their final location. Recent evidence shows that the routing of plastocyanin towards the lumen involves two post-translational transport processes mediated by two different regions of the transit peptide and two different processing proteases. It is postulated that the genetic information for the plastocyanin precursor, which already contained a signal peptide, was transferred from the endosymbiont to the nucleus. Then a chloroplast-specific targeting-peptide was added.     

Oligomers of Tha4 organize at the thylakoid Tat translocase during protein transport

The Tat (twin arginine translocation) systems of thylakoids and bacteria transport fully folded protein substrates without breaching the permeability barrier of the membrane. Two components of the thylakoid system, cpTatC and Hcf106, compose a precursor-bound receptor complex. The third component, Tha4, assembles with the precursor-bound receptor complex for the translocation step and is thought to compose at least part of the protein-conducting channel. Here, we used two different cross-linking approaches to explore the organization of Tha4 in the translocase. These cross-linking techniques showed that transition to an active protein transport state resulted in an alignment of the Tha4 amphipathic helix and C-terminal tail domains to form Tha4 oligomers. Oligomerization required functional Tha4, a twin arginine signal peptide, and an active cpTatC-Hcf106 receptor complex. The spectrum of oligomers obtained was independent of the mature folded domain of the precursor. We propose a trapdoor mechanism for translocation whereby aligned oligomers of Tha4 amphipathic helices fold into the membrane to allow formfitting passage of precursor proteins.     

Large-scale chromatin structural domains within mitotic and interphase chromosomes in vivo and in vitro

Higher-order chromatin structural domains approximately 130 nm in width are observed as prominent components of both Drosophila melanogaster and human mitotic chromosomes using buffer conditions which preserve chromosome morphology as determined by light microscopic comparison with chromosomes within living cells. Spatially discrete chromatin structural domains of similar size also exist as prominent components within interphase nuclei prepared under equivalent conditions. Examination of chromosomes during the anaphase-telophase transition suggests that chromosomes decondense largely through the progressive straightening or uncoiling of these large-scale chromatin domains. A quantitative analysis of the size distribution of these higher-order domains in telophase nuclei indicated a mean width of 126±36 nm. Three-dimensional views using stereopairs of chromosomes and interphase nuclei from 0.5 m thick sections suggest that these large-scale chromatin domains consist of 30 nm fibers packed by tight folding into larger, linear, fiber-like elements. Reduction in vitro of either polyamine or divalent cation concentrations within two different buffer systems results in a loss of these large-scale domains, with no higher-order chromatin organization evident above the 20–30 nm fiber. Under these conditions the DNA distribution within mitotic chromosomes and interphase nuclei appears significantly diffuse relative to the appearance by light microscopy within living cells, or, by electron microscopy, within cells fixed directly without permeabilization in buffer. These results suggest that these large-scale chromatin structural domains are fundamental elements of chromosome architecture in vivo.     

Role of the Tat ransport system in nitrous oxide reductase translocation and cytochrome cd1 biosynthesis in Pseudomonas stutzeri

By transforming N2O to N2, the multicopper enzyme nitrous oxide reductase provides a periplasmic electron sink for a respiratory chain that is part of denitrification. The signal sequence of the enzyme carries the heptameric twin-arginine consensus motif characteristic of the Tat pathway. We have identified tat genes of Pseudomonas stutzeri and functionally analyzed the unlinked tatC and tatE loci. A tatC mutant retained N2O reductase in the cytoplasm in the unprocessed form and lacking the metal cofactors. This is contrary to viewing the Tat system as specific only for fully assembled proteins. A C618V exchange in the electron transfer center CuA rendered the enzyme largely incompetent for transport. The location of the mutation in the C-terminal domain of N(2)O reductase implies that the Tat system acts on a completely synthesized protein and is sensitive to a late structural variation in folding. By generating a tatE mutant and a reductase-overproducing strain, we show a function for TatE in N2O reductase translocation. Further, we have found that the Tat and Sec pathways have to cooperate to produce a functional nitrite reductase system. The cytochrome cd1 nitrite reductase was found in the periplasm of the tatC mutant, suggesting export by the Sec pathway; however, the enzyme lacked the heme D1 macrocycle. The NirD protein as part of a complex required for heme D1 synthesis or processing carries a putative Tat signal peptide. Since NO reduction was also inhibited in the tatC mutant, the Tat protein translocation system is necessary in multiple ways for establishing anaerobic nitrite denitrification.     

Functional assembly of thylakoid deltapH-dependent/Tat protein transport pathway components in vitro.

Assembly of the components of the thylakoid deltapH-dependent/Tat protein transport machinery was analyzed in vitro. Upon incubation with intact chloroplasts, precursors to all three components, Hcf106, cpTatC and Tha4, were imported into the organelle and assembled into characteristic endogenous complexes. In particular, all of the imported cpTatC and approximately two-thirds of the imported Hcf106 functionally assembled into 700 kDa complexes capable of binding Tat pathway precursor proteins. The amounts assembled into thylakoids by this procedure were moderate. However, physiological quantities of mature forms of Tha4 and Hcf106 were integrated into isolated thylakoids and a significant percentage of the Hcf106 so integrated was assembled into the 700 kDa complex. Interestingly, a mutant form of Hcf106 in which an invariant transmembrane glutamate was changed to glutamine integrated into the membrane but did not assemble into the receptor complex. Analysis of energy and known pathway component requirements indicated that Hcf106 and Tha4 integrate by an unassisted or 'spontaneous' mechanism. The functionality of in vitro integrated Tha4 was verified by its ability to restore transport to thylakoid membranes from the maize tha4 mutant, which lacks the Tha4 protein. Development of this functional in vitro assembly assay will facilitate structure-function studies of the thylakoid Tat pathway translocation machinery.     

Protein targeting by the bacterial twin-arginine translocation (Tat) pathway

The Tat (twin-arginine translocation) protein export system is found in the cytoplasmic membrane of most prokaryotes and is dedicated to the transport of folded proteins. The Tat system is now known to be essential for many bacterial processes including energy metabolism, cell wall biosynthesis, the nitrogen-fixing symbiosis and bacterial pathogenesis. Recent studies demonstrate that substrate-specific accessory proteins prevent improperly assembled substrates from interacting with the Tat transporter. During the transport cycle itself substrate proteins bind to a receptor complex in the membrane which then recruits a protein-translocating channel to carry out the transport reaction.     

Sigmoidal stimulation by solutes of light-induced proton translocation in thylakoid membranes

A sigmoidal curve was obtained for the relationship betweenthe stimulation of light-induced proton uptake and the concentrationof salts in a suspending medium for thylakoid membranes. Substitutionof sucrose for the salts also resulted in a sigmoidal curve.It changed into a hyperbolic curve with salts when the mediumalready contained sucrose. The results are discussed in relationto the structural arrangement of the thylakoid membranes bythe osmotic effect of the solutes. (Received February 10, 1975; )     

Separate analysis of twin-arginine translocation (Tat)-specific membrane binding and translocation in Escherichia coli

The twin-arginine translocation (Tat) pathway exports those precursor proteins to the periplasmic space of bacteria that harbor a twin-arginine (RR) consensus motif in their signal sequences. We have reproduced translocation of several Tat substrates into inside-out plasma membrane vesicles from Escherichia coli. Translocation proceeding at an efficiency of up to 20% occurs specifically via the Tat pathway as indicated by (i) its requirement for elevated levels of the TatABC proteins in the membrane vesicles, (ii) competition by an intact twin-arginine signal peptide, and (iii) susceptibility toward dissipation of the transmembrane H(+) gradient. The latter treatment, while blocking translocation, still allows for functional membrane association of Tat precursors. This is shown by the finding that translocation of isolated membrane-bound Tat precursor is restored upon re-energization of the vesicles.     

Precursors bind to specific sites on thylakoid membranes prior to transport on the delta pH protein translocation system

The Delta pH pathway is one of two systems for protein transport to the thylakoid lumen. It is a novel transport system that requires only the thylakoidal DeltapH to power translocation. Several substrates of the Delta pH pathway, including the intermediate precursor form of OE17 (iOE17) and the truncated precursor form of OE17 (tOE17), were shown to bind to the membrane in the absence of the DeltapH and be transported into the lumen when the DeltapH was restored. Binding occurred without energy or soluble factors, and efficient transport from the bound state ( approximately 80-90%) required only the DeltapH. Binding is due to protein-protein interactions because protease pretreatment of thylakoids destroyed their binding capability. Precursors are bound to a specific site on the Delta pH pathway because binding was competed by saturating amounts of Delta pH pathway precursor proteins, but not by a Sec pathway precursor protein. These results suggested that precursor tOE17 binds to components of the Delta pathway translocation machinery. Hcf106 and Tha4 are two components of the Delta pH pathway machinery. Antibodies to Hcf106 or Tha4, when prebound to thylakoids, specifically inhibited precursor transport on the Delta pH pathway. However, only Hcf106 antibodies reduced the level of precursor binding. These results suggest that Hcf106 functions in early steps of the transport process.     

Cyclic flow of electrons within PSII in thylakoid membranes

In photosynthesis, the electrons released from PSII are considered to be shared mainly by carbon metabolism and the water-water cycle. We demonstrated previously that some electrons are utilized in a CO2- and O2-independent manner in leaves of wild watermelon [Miyake and Yokota (2000) Plant Cell Physiol: 41: 335]. In the present study, we examined the mechanism of this alternative flow of electrons in thylakoid membranes, isolated from fresh spinach leaves, by simultaneously measuring the quantum yield of PSII and the flux of the linear flow of electrons. In the presence of the protonophore nigericin, which eliminates the pH gradient across thylakoid membranes, the quantum yield and the flux of the linear flow of electrons were directly proportional to one another. The quantum yield at a given linear flux of electrons was much higher in the absence of nigericin than in its presence, indicating that an additional or alternative flow of electrons can occur independently of the linear flow in the absence of nigericin. In the presence of nigericin, the alternative flux of electrons increased with decreasing pH and with increasing reduction of the plastoquinone pool. Cyclic flow of electrons in PSII appears to be the most plausible candidate for the alternative flow of electrons. The flux reached 280 micromol x e(-) (mg Chl)(-1) x h(-1) and was similar to that of the CO2- and O2-independent alternative flow of electrons that we found in leaves of wild watermelon. The cyclic, alternative flow of electrons in PSII provides a possible explanation for the alternative flow of electrons observed in vivo.