A folded protein can be transported across the chloroplast envelope and thylakoid membranes

Toc, Tic, Tat et al.: structure and function of protein transport machineries in chloroplasts

The chloroplast is an organelle of prokaryotic origin that is situated in an eukaryotic cellular environment. As a result of this formerly endosymbiotic situation, the chloroplast houses a unique set of protein transport machineries. Among those are evolutionarily young transport pathways which are responsible for the import of the nuclear-encoded proteins into the organelle as well as ancient pathways operating in the 'export' of proteins from the stroma (the former cyanobacterial cytosol) across the thylakoid membrane into the thylakoid lumen. In this review, we have tried to address the main features of these various transport pathways.

Distinctive organization of genes for light-harvesting proteins in the cryptophyte alga Rhodomonas

Cryptophyte algae contain two kinds of light-harvesting protein, phycobiliproteins and chlorophyll a,c-binding proteins. The beta subunit of the phycobiliprotein phycoerythrin (PE) is encoded in the chloroplast. Genes for the other PE polypeptides are located in the nucleus but little is known of their organization. We cloned and sequenced six cpeA genes encoding the phycoerythrin alpha subunit from a genomic library of the cryptophyte Rhodomonas CS24. Derived peptide sequences of the cpeA genes show that alpha subunits occur in at least two forms, a longer alpha1 form and a shorter alpha2 form. Remarkably, all six cpeA genes occur in divergent pairs encoding one alpha1 and one alpha2 subunit. Four cac genes encoding chlorophyll a,c-binding proteins were cloned and sequenced and also found to occur in divergent pairs comprising one cac1 and one cac2 gene. Inspection of the predicted targeting sequences of the alpha1 and alpha2 phycoerythrin polypeptides shows that only the alpha1 polypeptides have a thylakoid lumen targeting sequence, corresponding to the TAT pathway. Given the previously reported lack of a lumen-targeting sequence on the beta subunit, we propose a novel import mechanism in which the entire alpha1alpha2 betabeta phycoerythrin complex is assembled in the stroma and transported into the thylakoid under the direction of the single targeting sequence on the alpha1 protein. The FAP motif implicated in plastid targeting in diatoms appears to be conserved in this cryptophyte.

Channel Properties of TpsB Transporter FhaC Point to Two Functional Domains with a C-terminal Protein-conducting Pore

Integral outer membrane transporters of the Omp85/TpsB superfamily mediate the translocation of proteins across, or their integration into, the outer membranes of Gram-negative bacteria, chloroplasts, and mitochondria. The Bordetella pertussis FhaC/FHA couple serves as a model for the two-partner secretion pathway in Gram-negative bacteria, with the TpsB protein, FhaC, being the specific transporter of its TpsA partner, FHA, across the outer membrane. In this work, we have investigated the structure/function relationship of FhaC by analyzing the ion channel properties of the wild type protein and a collection of mutants with varied FHA secretion activities. We demonstrated that the channel is formed by the C-terminal two-thirds of FhaC most likely folding into a beta-barrel domain predicted to be conserved throughout the family. A C-proximal motif that represents the family signature appears essential for pore function. The N-terminal 200 residues of FhaC constitute a functionally distinct domain that modulates the pore properties and may participate in FHA recognition.

The thylakoid delta pH/delta psi are not required for the initial stages of Tat-dependent protein transport in tobacco protoplasts

The twin-arginine translocation (Tat) system transports folded proteins across the chloroplast thylakoid membrane and bacterial plasma membrane. In vitro import assays have pointed to a key role for the thylakoid delta pH in the initial assembly of the full translocon from two subcomplexes; more generally, the delta pH is believed to provide the overall driving force for translocation. Here, we have studied the role of the delta pH in vivo by analyzing the translocation of Tat substrates in transfected tobacco protoplasts. We show that the complete maturation of the precursor of the 23-kDa lumenal protein (pre-23K) and of a fusion of the 23K presequence linked to green fluorescent protein (pre-GFP) are unaffected by dissipation of the delta pH. High level expression of Tat substrates in protoplasts has recently been shown to result in "translocation reversal" in that a large proportion of a given substrate is partially translocated across the thylakoid membrane, processed to the mature size, and returned to the stroma. However, the efficiency of translocation of pre-23K is undiminished in the absence of the delta pH and/or delta psi, and the rate and extent of maturation of both pre-23K and pre-GFP by the lumen-facing processing peptidase is similarly unaffected. These data demonstrate that the proton motive force is not required for the functional assembly of the Tat translocon and the initial stages of translocation in higher plant chloroplasts in vivo. We conclude that unknown factors play an influential role in both the mechanism and energetics of this system under in vivo conditions.

The complexity of pathways for protein import into thylakoids: it's not easy being green

Numerous proteins are transported into or across the chloroplast thylakoid membrane. To date, two major pathways have been identified for the transport of luminal proteins (the Sec- and Tat-dependent pathways) and it is now clear that these protein translocases use fundamentally different transport mechanisms. Integral membrane proteins are inserted by means of at least two further pathways. One involves the input of numerous targeting factors, including SRP (signal recognition particle), FtsY and Albino3. Surprisingly, the other pathway does not involve any of the known chloroplastic targeting factors, and insertion is energy-independent, raising the possibility of an unusual ‘spontaneous’ insertion mechanism.

Large-scale translocation reversal within the thylakoid Tat system in vivo

In vitro import assays have shown that the thylakoid twin-arginine translocase (Tat) system transports folded proteins in a unidirectional manner. Here, we expressed a natural substrate, pre-23K, and a 23K presequence-green fluorescent protein (GFP) chimera in vivo in tobacco protoplasts. Both are imported into chloroplasts, targeted to the thylakoids, and processed to the mature size by the lumen-facing processing peptidase. However, the vast majority of mature GFP and about half of the 23K are then returned to the stroma. Mutations in the twin-arginine motif block thylakoid targeting and maturation, confirming an involvement of the Tat apparatus. Mutation of the processing site yields membrane-associated intermediate-size protein in vivo, indicating a delayed reversal of translocation to the stroma and suggesting a longer lived interaction with the Tat machinery. We conclude that, in vivo, the Tat system can reject substrates at a late stage in translocation and on a very large scale, indicating the influence of factors that are absent in reconstitution assays.

Recognition and envelope translocation of chloroplast preproteins

Plastids are a diverse group of plant organelles that perform essential functions including important steps in many biosynthetic pathways. Chloroplasts are the best characterized type of plastid, and constitute the site of oxygenic photosynthesis in plants, a process essential to all higher life forms. It is well established that the majority (>90%) of chloroplast proteins are nucleus-encoded and must be post-translationally imported into these envelope-bound compartments. Most nucleus-encoded chloroplast proteins are translated in precursor form on cytosolic ribosomes, targeted to the chloroplast surface, and then imported across the double-membrane envelope by translocons in the outer and inner envelope membranes of the chloroplast, termed TOC and TIC, respectively. Recently, significant progress has been made in our understanding of how proteins are targeted to the chloroplast surface and translocated across the chloroplast envelope into the stroma. Evidence suggesting the existence of multiple import pathways at the outer envelope membrane for different classes of precursor proteins has been presented. These pathways appear to utilize similar TOC complexes equipped with different combinations of homologous GTPase receptors, providing preprotein recognition specificity.

Mechanisms of protein import and routing in chloroplasts

The vast majority of the approximately 3000 different proteins required to build a fully functional chloroplast are encoded by the nuclear genome and translated on cytosolic ribosomes. As chloroplasts are each surrounded by a double-membrane system, or envelope, sophisticated mechanisms are necessary to mediate the import of these nucleus-encoded proteins into chloroplasts. Once inside the organelle, many chloroplast proteins engage one of four additional protein sorting mechanisms that direct targeting to the internal thylakoid membrane system.

Evidence for interactions between domains of TatA and TatB from mutagenesis of the TatABC subunits of the twin-arginine translocase

The twin-arginine translocation (Tat) system transports folded proteins across the bacterial plasma membrane. Three subunits, TatA, B and C, are known to be involved but their modes of action are poorly understood, as are the inter-subunit interactions occurring within Tat complexes. We have generated mutations in the single transmembrane (TM) spans of TatA and TatB, with the aim of generating structural distortions. We show that substitution in TatB of three residues by glycine, or a single residue by proline, has no detectable effect on translocation, whereas the presence of three glycines in the TatA TM span completely blocks Tat translocation activity. The results show that the integrity of the TatA TM span is vital for Tat activity, whereas that of TatB can accommodate large-scale distortions. Near-complete restoration of activity in TatA mutants is achieved by the simultaneous presence of a V12P mutation in the TatB TM span, strongly implying a direct functional interaction between the TatA/B TM spans. We also analyzed the predicted amphipathic regions in TatA and TatB and again find evidence of direct interaction; benign mutations in either subunit completely blocked translocation of two Tat substrates when present in combination. Finally, we have re-examined the effects of previously analyzed TatABC mutations under conditions of high translocation activity. Among numerous TatA or TatB mutations tested, TatA F39A alone blocked translocation, and only substitutions of P48 and F94 in TatC blocked translocation activity.

Mutations in Subunits of the Escherichia coli Twin-arginine Translocase Block Function via Differing Effects on Translocation Activity or Tat Complex Structure

We have used a combination of blue-native (BN) gel electrophoresis and protein purification to analyze the effects of TatA or TatC mutations on the structures of the primary TatABC and multimeric TatA complexes in Escherichia coli. Expression of wild-type TatABC leads to the production of a single major TatABC complex of 370 kDa and a heterogeneous set of TatA complexes of <100 kDa to approximately 500 kDa. Two TatC mutations that block translocation have different effects on complex structures. P48A causes massive defects in TatABC assembly, including a marked separation of the TatBC subunits and the production of TatB and TatC aggregates. In contrast, TatABC complexes from the inactive TatC F94A mutant are structurally intact, suggesting that this mutation affects translocation activity rather than assembly. Neither TatC mutation affects the separate TatA complexes, showing that assembly of the TatA complexes is independent of TatABC assembly or activity. In contrast, three TatA mutations affect both the TatA and TatABC complexes. F39A assembles into smaller, incorrectly organized TatA complexes and the TatABC complexes contain an incorrect TatB:TatC ratio and unusually large amounts of TatA. A triple mutant in the amphipathic region forms slightly larger TatA complexes that are likewise disorganized, and a mutant containing three glycine substitutions in the transmembrane (TM) span assembles as grossly affected TatA complexes that are much larger than wild-type complexes. These mutants lead to a partial failure of TatB to assemble correctly. The data show that the amphipathic and TM regions play critical roles in TatA complex assembly. All of the TatA mutations lead to partial or substantial defects in TatABC complex formation, demonstrating that the properties of TatA can have a marked influence on the TatABC complex.

Location and mobility of twin arginine translocase subunits in the Escherichia coli plasma membrane

The twin arginine translocation (Tat) system transports folded proteins across the bacterial plasma membrane. Two primary Tat complexes have been identified, comprising TatABC or TatA multimers, which may interact at the point of translocation. We have analyzed green/cyan/yellow fluorescent protein (XFP) fusions to each of the Tat subunits. We show that the TatB and TatC fusions are active and incorporated into purified TatABC complexes. Proteolytic clipping of the TatA-XFP fusion precludes a definitive conclusion regarding activity, but we do find that the full fusion protein is preferentially incorporated into the TatABC complex. A previous study has proposed that TatB and possibly TatC are localized at the cell poles, whereas TatA is distributed more uniformly throughout the plasma membrane. Here, we likewise show that TatA-XFP is primarily distributed around the periphery of the cell. However, whereas much of the TatB-XFP is found at the poles, quantitative imaging studies show that approximately half of the protein is uniformly distributed in the plasma membrane. Moreover, we show that the bulk of TatC-XFP is detected as a halo around the cells, in some cases as punctate areas that are much smaller than those occupied by TatB-green fluorescent protein (GFP), indicating a uniform distribution. No evidence for a polar localization of TatC-GFP was obtained. Although TatC-GFP is found correctly complexed with TatB, a high proportion of TatB-GFP is not linked to TatC, and we propose that this "free" TatB forms unphysiological assemblies, possibly because it is synthesized in excess. Since TatC is invariably complexed with TatB in wild-type complexes, the combined data demonstrate that TatABC complexes are uniformly distributed throughout the plasma membrane. The significance of the punctate TatA/B/C-GFP is unclear; fluorescence recovery after photobleaching measurements show that these pools of proteins are immobile, whereas nonaggregated proteins are highly mobile in the plasma membrane.

Tat-dependent protein targeting in prokaryotes and chloroplasts

The twin-arginine translocation (Tat) system operates in the chloroplast thylakoid and the plasma membranes of a wide range of bacteria. It recognizes substrates bearing cleavable signal peptides in which a twin-arginine motif almost invariably plays a key role in recognition by the translocation machinery. These signal peptides are surprisingly similar to those used to specify transport by Sec-type systems, but the Tat pathway differs in fundamental respects from Sec-type and other protein translocases. Its key attribute is its ability to translocate large, fully folded (even oligomeric) proteins across tightly sealed membranes. To date, three key tat genes have been characterised and the first details of the Tat system are beginning to emerge. In this article we review the salient features of Tat systems, with an emphasis on the targeting signals involved, the substrate specificities of Tat systems, our current knowledge of Tat complex structures and the known mechanistic features. Although the article is focused primarily on bacterial systems, we incorporate relevant aspects of plant thylakoid Tat work and we discuss how the plant and bacterial systems may differ in some respects.

The Escherichia coli Twin-arginine Translocation Apparatus Incorporates a Distinct Form of TatABC Complex, Spectrum of Modular TatA Complexes and Minor TatAB Complex

The Tat system transports folded proteins across bacterial plasma and plant thylakoid membranes. To date, three key Tat subunits have been identified and mechanistic studies indicate the presence of two types of complex: a TatBC-containing substrate-binding unit and a separate TatA complex. Here, we used blue-native gel electrophoresis and affinity purification to study the nature of these complexes in Escherichia coli. Analysis of solubilized membrane shows that the bulk of TatB and essentially all of the TatC is found in a single 370kDa TatABC complex. TatABC was purified to homogeneity using an affinity tag on TatC and this complex runs apparently as an identical band. We conclude that this is the primary core complex, predicted to contain six or seven copies of TatBC together with a similar number of TatA subunits. However, the data indicate the presence of an additional form of Tat complex containing TatA and TatB, but not TatC; we speculate that this may be an assembly or disassembly intermediate of the translocator. The vast majority of TatA is found in separate complexes that migrate in blue-native gels as a striking ladder of bands with sizes ranging from under 100 kDa to over 500 kDa. Further analysis shows that the bands differ by an average of 34 kDa, indicating that TatA complexes are built largely, but possibly not exclusively, from modules of three or four TatA molecules. The range and nature of these complexes are similar in a TatC mutant that is totally inactive, indicating that the ladder of bands does not stem from ongoing translocation activity, and we show that purified TatA can self-assemble in vitro to form similar complexes. This spectrum of TatA complexes may provide the flexibility required to generate a translocon capable of transporting substrates of varying sizes across the plasma membrane in a folded state.

The Core TatABC Complex of the Twin-arginine Translocase in Escherichia coli: TatC Drives Assembly Whereas TatA is Essential for Stability

Current models for the action of the twin-arginine translocation (Tat) system propose that substrates bind initially to the TatBC subunits, after which a separate TatA complex is recruited to form an active translocon. Here, we have studied the roles of individual subunits in the assembly and stability of the core TatBC-containing substrate-binding complex. Previous studies have shown that TatB and TatC are active when fused together; we show here that deletion of the entire TatB transmembrane span from this Tat(BC) fusion inactivates the Tat system but does not affect assembly of the core complex. In this mutated complex, TatA is present but more loosely bound, indicating a role for TatB in the correct binding of TatA. In the absence of TatA, the truncated TatBC fusion protein still assembles into a complex of the correct magnitude, demonstrating that the transmembrane spans of TatC are the only determinants within the membrane bilayer that specify assembly of this complex. Further studies on both the Tat(BC) construct and the wild-type TatBC subunits show that the TatBC complex is unstable in the absence of TatA, and we show that TatA stabilises the TatB subunit specifically within this complex. The results demonstrate a dual role and location for TatA: in the functioning/maintenance of the core complex, and as a separate homo-oligomeric complex.

The Tat protein translocation pathway and its role in microbial physiology

The Tat (twin arginine translocation) protein transport system functions to export folded protein substrates across the bacterial cytoplasmic membrane and to insert certain integral membrane proteins into that membrane. It is entirely distinct from the Sec pathway. Here, we describe our current knowledge of the molecular features of the Tat transport system. In addition, we discuss the roles that the Tat pathway plays in the bacterial cell, paying particular attention to the involvement of the Tat pathway in the biogenesis of cofactor-containing proteins, in cell wall biosynthesis and in bacterial pathogenicity.

Consensus structural features of purified bacterial TatABC complexes

The twin-arginine translocation (Tat) system transports folded proteins across bacterial plasma membranes and the chloroplast thylakoid membrane. Here, we investigate the composition and structural organization of three different purified Tat complexes from Escherichia coli, Salmonella typhimurium and Agrobacterium tumefaciens. First, we demonstrate the functional activity of these Tat systems in vivo, since expression of the tatABC operons from S.typhimurium or A.tumefaciens in an E.coli tat null mutant strain resulted in efficient Tat-dependent export of an E.coli cofactor-containing substrate, TMAO reductase. The three isolated, affinity-tagged Tat complexes comprised TatA, TatB and TatC in each case, demonstrating a strong interaction between these three subunits. Single-particle electron microscopy studies of all three complexes revealed approximately oval-shaped, asymmetric particles with maximal dimensions up to 13 nm. A common feature is a number of stain-excluding densities surrounding more or less central pools of stain, suggesting protein-lined pores or cavities. The characteristics of size variation among the particles suggest a modular form of assembly and/or the recruitment of varying numbers of TatBC/TatA units. Despite low levels of sequence homology, the combined data indicate structural and functional conservation in the Tat systems of these three bacterial species.

Membrane-specific targeting of green fluorescent protein by the Tat pathway in the cyanobacterium Synechocystis PCC6803

The transport and sorting of extracytoplasmic proteins in cyanobacteria is made complex by the presence of a highly differentiated membrane system. Proteins destined for the periplasm and thylakoid lumen are initially transported by Sec- and Tat-type pathways but little is known of the mechanisms that ultimately direct them to the correct destinations. We have generated a Synechocystis PCC6803 transformant that expresses a fusion protein comprising the Tat-specific targeting signal of Escherichia coli TorA linked to green fluorescent protein (GFP). Immunoblotting indicates the presence of mature-size GFP but no precursor form, demonstrating that efficient translocation has taken place. Confocal microscopy and immunogold electron microscopy reveal GFP to be almost exclusively located in the periplasm, with almost no protein evident in the thylakoid network. These data point to the operation of highly effective sorting pathways for soluble proteins in this cyanobacterium. The observed sorting of the GFP suggests that either (a) the Tat apparatus is located only in the plasma membrane or (b) the TorA-GFP is targeted across either membrane but the GFP is subsequently directed to the periplasm, perhaps by a default sorting pathway to this compartment.

Targeting of EGFP chimeras within chloroplasts

We have tested the potential of EGFP, a derivative of the green fluorescent protein (GFP), as a passenger protein for the analysis of protein transport processes across the thylakoid membranes in chloroplasts. In contrast to the majority of fusion proteins commonly used in such studies, EGFP is not of plant origin and can therefore be assumed to behave like a "neutral" passenger protein that is unaffected by any internal plant regulatory circuits. Our in vitro transport experiments clearly demonstrate that EGFP is a suitable passenger protein that can be correctly targeted either to the stroma or to the thylakoid lumen if fused to the appropriate transit peptide. The transport of EGFP across the thylakoid membrane shows, however, a clear pathway preference. While the protein is efficiently targeted by the deltapH/TAT pathway, transport by the Sec pathway is barely detectable, either with isolated thylakoids or with intact chloroplasts. This pathway specificity suggests that EGFP is folded immediately after import into the chloroplast stroma, thus preventing further translocation across the thylakoid membrane by the Sec translocase. The data obtained provide a good basis for the development of molecular tools for transport studies using EGFP as a passenger protein. Furthermore, plant lines expressing corresponding EGFP chimeras are expected to allow in vivo studies on the transport and sorting mechanisms involved in the biogenesis of the chloroplast.

Folding quality control in the export of proteins by the bacterial twin-arginine translocation pathway

To examine the relationship between folding and export competence by the twin-arginine translocation (Tat) pathway we analyzed the subcellular localization of fusions between a set of eight putative Tat leader peptides and alkaline phosphatase in isogenic Escherichia coli strains that either allow or disfavor the formation of protein disulfide bonds in the cytoplasm. We show that export by the Tat translocator is observed only in strains that enable oxidative protein folding in the cytoplasm. Further, we show that other disulfide-containing proteins, namely single-chain Fv and heterodimeric F(AB) antibody fragments, are export-competent only in strains having an oxidizing cytoplasm. Functional, heterodimeric F(AB) protein was exported from the cytoplasm by means of a Tat leader peptide fused to the heavy chain alone, indicating that the formation of a disulfide-bonded dimer preceeds export. These results demonstrate that in vivo only proteins that have attained the native conformation are exported by the Tat translocator, indicating that a folding quality-control mechanism is intrinsic to the export process. The ability to export proteins with disulfide bonds and the folding proofing feature of the Tat pathway are of interest for biotechnology applications.

An alternative model of the twin arginine translocation system

The twin arginine translocation (Tat) system is a machinery which can translocate folded proteins across energy transducing membranes. Currently it is supposed that Tat substrates bind directly to Tat translocon components before a ApH-driven translocation occurs. In this review, an alternative model is presented which proposes that membrane integration could precede Tat-dependent translocation. This idea is mainly supported by the recent observations of Tat-independent membrane insertion of Tat substrates in vivo and in vitro. Membrane insertion may allow i) a quality control of the folded state by membrane bound proteases like FtsH, ii) the recognition of the membrane spanning signal peptide by Tat system components, and iii) a pulling mechanism of translocation. In some cases of folded Tat substrates, the membrane targeting process may require ATP-dependent N-terminal unfolding-steps.

Protein transport into secondary plastids and the evolution of primary and secondary plastids

Chloroplasts are key organelles in algae and plants due to their photosynthetic abilities. They are thought to have evolved from prokaryotic cyanobacteria taken up by a eukaryotic host cell in a process termed primary endocytobiosis. In addition, a variety of organisms have evolved by subsequent secondary endocytobioses, in which a heterotrophic host cell engulfed a eukaryotic alga. Both processes dramatically enhanced the complexity of the resulting cells. Since the first version of the endosymbiotic theory was proposed more than 100 years ago, morphological, physiological, biochemical, and molecular data have been collected substantiating the emerging picture about the origin and the relationship of individual organisms with different primary or secondary chloroplast types. Depending on their origin, plastids in different lineages may have two, three, or four envelope membranes. The evolutionary success of endocytobioses depends, among other factors, on the specific exchange of molecules between the host and endosymbiont. This raises questions concerning how targeting of nucleus-encoded proteins into the different plastid types occurs and how these processes may have developed. Most studies of protein translocation into plastids have been performed on primary plastids, but in recent years more complex protein-translocation systems of secondary plastids have been investigated. Analyses of transport systems in different algal lineages with secondary plastids reveal that during evolution existing translocation machineries were recycled or recombined rather than being developed de novo. This review deals with current knowledge about the evolution and function of primary and secondary plastids and the respective protein-targeting systems.

A GTP-driven motor moves proteins across the outer envelope of chloroplasts

The translocation of proteins across cellular membranes is a key mechanistic problem for every cell. The preprotein translocon at the chloroplast outer envelope is responsible for precursor protein recognition and translocation across the outer envelope. We have reconstituted the translocation process into proteoliposomes from single subunits or by using the purified translocon. Precursor proteins are recognized by the Toc34 receptor in an initial GTP-dependent process. Translocation across the plane of the membrane then occurs through the Toc75 channel in a GTP-dependent process. Correspondingly, GTP hydrolysis of Toc proteoliposomes is 100-fold enhanced in the presence of preprotein. Complete translocation is demonstrated by processing of the precursor form to the mature form by the stromal processing peptidase and by protease resistance of the imported protein. Molecular chaperones are not involved in this translocation event. We show that Toc159 acts as a GTP-driven motor in a sewing-machine-like mechanism.

Protein transport via the cpTat pathway displays cooperativity and is stimulated by transport-incompetent substrate

Kinetic analyses of cpTat-mediated protein transport across the thylakoid membrane were conducted, revealing three important characteristics of this translocation pathway. First, transport via the cpTAT system displays a non-Michaelis-Menten, sigmoidal rate-substrate relationship with an apparent Hill coefficient of 1.80, indicative of positive homotropic cooperativity. Second, the presence of transport-incompetent substrates was found not to competitively inhibit the translocation of transport-competent substrates. However, the presence of low concentrations of transport-incompetent protein enhances the transport of wild type substrate. Together, these findings suggest that interaction between Tat machinery components and both transport-competent and transport-incompetent protein may elicit a cooperative effect on the translocation rate.

Moving folded proteins across the bacterial cell membrane

The Tat protein export system is located in the bacterial cytoplasmic membrane and operates in parallel to the well-known Sec pathway. While the Sec system only transports unstructured substrates, the function of the Tat pathway is to translocate folded proteins. The Tat translocase thus faces the formidable challenge of moving structured macromolecular substrates across the bacterial cytoplasmic membrane without rendering the membrane freely permeable to protons and other ions. The substrates of the Tat pathway are often proteins that bind cofactor molecules in the cytoplasm, and are thus folded, prior to export. Such periplasmic cofactor-containing proteins are essential for most types of bacterial respiratory and photosynthetic energy metabolism. In addition, the Tat pathway is involved in outer membrane biosynthesis and in bacterial pathogenesis. Substrates are targeted to the Tat pathway by amino-terminal signal sequences harbouring consecutive, essentially invariant, arginine residues, and movement of proteins through the Tat system is energized by the transmembrane proton electrochemical gradient. The TatA protein probably forms the transport channel while the TatBC proteins act as a receptor complex that recognizes the signal peptide of the substrate protein.

Identification of key regions within the Escherichia coli TatAB subunits

The twin-arginine translocation (Tat) system catalyzes the transport of folded proteins across the bacterial plasma membrane or the chloroplast thylakoid membrane. In Escherichia coli and most other species, three important tat genes have been identified but the structure and mechanism of this system are poorly understood; the role and location of TatA are particularly unclear. In this report we have used site-specific mutagenesis to probe the significance of conserved features of the related TatA/B subunits. We find that an apparent 'hinge' region between the transmembrane (TM) span and an adjacent amphipathic region is important in both proteins, in that substitution of turn-inducing residues inhibits the export of a natural Tat substrate. Surprisingly, large-scale mutagenesis of the conserved amphipathic regions of TatA and TatB leads only to minor effects on Tat-dependent export suggesting that this particular feature is not central to the translocation mechanism. This domain is, however, critical for the translocation process and we identify Gly/Pro residues in these regions of TatA/B that are essential for efficient export.

Thylakoid targeting of Tat passenger proteins shows no delta pH dependence in vivo

The Tat pathway is a major route for protein export in prokaryotes and for protein targeting to thylakoids in chloroplasts. Based on in vitro studies, protein translocation through this pathway is thought to be strictly dependent on a transmembrane delta pH. In this paper, we assess the delta pH sensitivity of the Tat pathway in vivo. Using Chlamydomonas reinhardtii, we observed changes in the efficiency of thylakoid targeting in vivo by mutating the Tat signal of the Rieske protein. We then employed two endogenous pH probes located on the lumen side of the thylakoid membranes to estimate spectroscopically the delta pH in vivo. Using experimental conditions in which the trans-thylakoid delta pH was almost zero, we found no evidence for a delta pH dependence of the Tat pathway in vivo. We confirmed this observation in higher plants using attached barley leaves. We conclude that the Tat pathway does not require a delta pH under physiological conditions, but becomes delta pH sensitive when probed in vitro/in organello because of the loss of some critical intracellular factors.

Improvement of posttranslational bottlenecks in the production of penicillin amidase in recombinant Escherichia coli strains

Using periplasmic penicillin amidase (PA) from Escherichia coli ATCC 11105 as a model recombinant protein, we reviewed the posttranslational bottlenecks in its overexpression and undertook attempts to enhance its production in different recombinant E. coli expression hosts. Intracellular proteolytic degradation of the newly synthesized PA precursor and translocation through the plasma membrane were determined to be the main posttranslational processes limiting enzyme production. Rate constants for both intracellular proteolytic breakdown (k(d)) and transport (k(t)) were used as quantitative tools for selection of the appropriate host system and cultivation medium. The production of mature active PA was increased up to 10-fold when the protease-deficient strain E. coli BL21(DE3) was cultivated in medium without a proteinaceous substrate, as confirmed by a decrease in the sum of the constants k(d) and k(t). The original signal sequence of pre-pro-PA was exchanged with the OmpT signal peptide sequence in order to increase translocation efficiency; the effects of this change varied in the different E. coli host strains. Furthermore, we established that simultaneous coexpression of the OmpT pac gene with some proteins of the Sec export machinery of the cell resulted in up to threefold-enhanced PA production. In parallel, we made efforts to increase PA flux via coexpression with the kil gene (killing protein). The primary effects of the kil gene were the release of PA into the extracellular medium and an approximately threefold increase in the total amount of PA produced per liter of bacterial culture.

Protein structure and import into the peroxisomal matrix

Proteins destined for the peroxisomal matrix are synthesized in the cytosol, and imported post-translationally. It has been previously demonstrated that stably folded proteins are substrates for peroxisomal import. Mammalian peroxisomes do not contain endogenous chaperone molecules. Therefore, it is possible that proteins are required to fold into their stable, tertiary conformation in order to be imported into the peroxisome. These investigations were undertaken to determine whether proteins rendered incapable of folding were also substrates for import into peroxisomes. Reduction of albumin resulted in a less compact tertiary structure as measured by analytical centrifugation. Microinjection of unfolded albumin molecules bearing the PTS1 targeting signal resulted in their import into peroxisomes. Kinetic analysis indicated that native and unfolded molecules were imported into peroxisomes at comparable rates. While import was unaffected by treatment with cycloheximide, hsc70 molecules were observed to be imported along with the unfolded albumin molecules. These results indicate that proteins, which are incapable of assuming their native conformation, are substrates for peroxisomal import. When combined with previous observations demonstrating the import of stably folded proteins, these results support the model that tertiary structure has no effect on protein import into the peroxisomal matrix.

Protein unfolding--an important process in vivo?

Protein unfolding is an important step in several cellular processes, most interestingly protein degradation by ATP-dependent proteases and protein translocation across some membranes. Unfolding can be catalyzed when the unfoldases change the unfolding pathway of substrate proteins by pulling at their polypeptide chains. The resistance of a protein to unraveling during these processes is not determined by the protein's stability against global unfolding, as measured by temperature or solvent denaturation in vitro. Instead, resistance to unfolding is determined by the local structure that the unfoldase encounters first as it follows the substrate's polypeptide chain from the targeting signal. As unfolding is a necessary step in protein degradation and translocation, the susceptibility to unfolding of substrate proteins contributes to the specificity of these important cellular processes.

Energetics of protein transport across biological membranes. a study of the thylakoid DeltapH-dependent/cpTat pathway

Among the pathways for protein translocation across biological membranes, the DeltapH-dependent/Tat system is unusual in its sole reliance upon the transmembrane pH gradient to drive protein transport. The free energy cost of protein translocation via the chloro-plast DeltapH-dependent/Tat pathway was measured by conducting in vitro transport assays with isolated thylakoids while concurrently monitoring energetic parameters. These experiments revealed a substrate-specific energetic barrier to cpTat-mediated transport as well as direct utilization of protons from the gradient, consistent with a H+/protein antiporter mechanism. The magnitude of proton flux was assayed by four independent approaches and averaged 7.9 x 10(4) protons released from the gradient per transported protein. This corresponds to a DeltaG transport of 6.9 x 10(5) kJ.mol protein translocated(-1), representing the utilization of an energetic equivalent of 10(4) molecules of ATP. At this cost, we estimate that the DeltapH-dependent/cpTat pathway utilizes approximately 3% of the total energy output of the chloroplast.

DmsD is required for the biogenesis of DMSO reductase in Escherichia coli but not for the interaction of the DmsA signal peptide with the Tat apparatus

The DmsD protein is essential for the biogenesis of DMSO reductase in Escherichia coli, and binds the signal peptide of the DmsA subunit, a Tat substrate. This suggests a role as a guidance factor to target pre-DmsA to the translocase. Here, we have analysed the export of fusion proteins in which the DmsA and TorA signal peptides are fused to green fluorescent protein. Both chimeras are efficiently exported to the periplasm in wild-type E. coli cells and we show that their export efficiencies are essentially identical in a mutant lacking DmsD. An authentic Tat substrate, TMAO reductase, is also efficiently exported in the dmsD mutant. The data indicate that DmsD carries out a critical role in DMSO reductase biogenesis/assembly but is not required for the functioning of the DmsA signal peptide.

Transport of exogenous growth factors and cytokines to the cytosol and to the nucleus

In recent years a number of growth factors, cytokines, protein hormones, and other proteins have been found in the nucleus after having been added externally to cells. This review evaluates the evidence that translocation takes place and discusses possible mechanisms. As a demonstration of the principle that extracellular proteins can penetrate cellular membranes and reach the cytosol, a brief overview of the penetration mechanism of protein toxins with intracellular sites of action is given. Then problems and pitfalls in attempts to demonstrate the presence of proteins in the cytosol and in the nucleus as opposed to intracellular vesicular compartments are discussed, and some new approaches to study this are described. A detailed overview of the evidence for translocation of fibroblast growth factor, HIV-Tat, interferon-gamma, and other proteins where there is evidence for intracellular action is given, and translocation mechanisms are discussed. It is concluded that although there are many pitfalls, the bulk of the experiments indicate that certain proteins are indeed able to enter the cytosol and nucleus. Possible roles of the internalized proteins are discussed.

Functional genomic analysis of the Bacillus subtilis Tat pathway for protein secretion

Protein secretion from Bacillus species is a major industrial production tool with a market of over $1 billion per year. However, standard export technologies, based on the well-characterised general secretory (Sec) pathway, are frequently inapplicable for the production of proteins. The recently discovered twin-arginine translocation (Tat) pathway offers additional potential to transport proteins. Here we review the use of functional genomic and proteomic approaches to explore the Tat pathway of Bacillus subtilis. The properties of Tat pathway components and the twin-arginine signal peptides that direct proteins into this pathway are discussed. Where appropriate, a comparison is made with Tat systems from other organism, such as Escherichia coli. Recent findings with the latter organism in particular provide proof-of-principle that the Tat pathway can be exploited for the production of Sec-incompatible proteins.

The chloroplast protein import channel Toc75: pore properties and interaction with transit peptides

The channel properties of Toc75 (the protein import pore of the outer chloroplastic membrane) were further characterized by electrophysiological measurements in planar lipid bilayers. After improvement of the Toc75 reconstitution procedure the voltage dependence of the channel open probability resembled those observed for other beta-barrel pores. Studies concerning the pore size of the reconstituted Toc75 indicate the presence of a narrow restriction zone corresponding to the selectivity filter and a wider pore vestibule with diameters of approximately 14 A and 26 A, respectively. Interactions between Toc75 and different peptides (a genuine chloroplastic transit peptide, a synthetic peptide resembling a transit peptide, and a mitochondrial presequence) show that Toc75 itself is able to differentiate between these peptides and the recognition is based on both conformational and electrostatic interactions.

Toc, tic, and chloroplast protein import

The vast majority of chloroplast proteins are synthesized in precursor form on cytosolic ribosomes. Chloroplast precursor proteins have cleavable, N-terminal targeting signals called transit peptides. Transit peptides direct precursor proteins to the chloroplast in an organelle-specific way. They can be phosphorylated by a cytosolic protein kinase, and this leads to the formation of a cytosolic guidance complex. The guidance complex--comprising precursor, hsp70 and 14-3-3 proteins, as well as several unidentified components--docks at the outer envelope membrane. Translocation of precursor proteins across the envelope is achieved by the joint action of molecular machines called Toc (translocon at the outer envelope membrane of chloroplasts) and Tic (translocon at the inner envelope membrane of chloroplasts), respectively. The action of the Toc/Tic apparatus requires the hydrolysis of ATP and GTP at different levels, indicating energetic requirements and regulatory properties of the import process. The main subunits of the Toc and Tic complexes have been identified and characterized in vivo, in organello and in vitro. Phylogenetic evidence suggests that several translocon subunits are of cyanobacterial origin, indicating that today's import machinery was built around a prokaryotic core.

A twin arginine signal peptide and the pH gradient trigger reversible assembly of the thylakoid [Delta]pH/Tat translocase

The thylakoid DeltapH-dependent/Tat pathway is a novel system with the remarkable ability to transport tightly folded precursor proteins using a transmembrane DeltapH as the sole energy source. Three known components of the transport machinery exist in two distinct subcomplexes. A cpTatC-Hcf106 complex serves as precursor receptor and a Tha4 complex is required after precursor recognition. Here we report that Tha4 assembles with cpTatC-Hcf106 during the translocation step. Interactions among components were examined by chemical cross-linking of intact thylakoids followed by immunoprecipitation and immunoblotting. cpTatC and Hcf106 were consistently associated under all conditions tested. In contrast, Tha4 was only associated with cpTatC and Hcf106 in the presence of a functional precursor and the DeltapH. Interestingly, a synthetic signal peptide could replace intact precursor in triggering assembly. The association of all three components was transient and dissipated upon the completion of protein translocation. Such an assembly-disassembly cycle could explain how the DeltapH/Tat system can assemble translocases to accommodate folded proteins of varied size. It also explains in part how the system can exist in the membrane without compromising its ion and proton permeability barrier.

Essential cytoplasmic domains in the Escherichia coli TatC protein

The twin-arginine translocation (Tat) system mediates the transport of proteins across the bacterial plasma membrane and chloroplast thylakoid membrane. Operating in parallel with Sec-type systems in these membranes, the Tat system is completely different in both structural and mechanistic terms, and is uniquely able to catalyze the translocation of fully folded proteins across coupled membranes. TatC is an essential, multispanning component that has been proposed to form part of the binding site for substrate precursor proteins. In this study we have tested the importance of conserved residues on the periplasmic and cytoplasmic face of the Escherichia coli protein. We find that many of the mutations on the cytoplasmic face have little or no effect. However, substitution at several positions in the extreme N-terminal cytoplasmic region or the predicted first cytoplasmic loop lead to a significant or complete loss of Tat-dependent export. The mutated strains are unable to grow anaerobically on trimethylamine N-oxide minimal media and are unable to export trimethylamine-N-oxide reductase (TorA). The same mutants are completely unable to export a chimeric protein, comprising the TorA signal peptide linked to green fluorescent protein, indicating that translocation is blocked rather than cofactor insertion into the TorA mature protein. The data point to two essential cytoplasmic domains on the TatC protein that are essential for export.

Functional complexity of the twin-arginine translocase TatC component revealed by site-directed mutagenesis

The Escherichia coli Tat apparatus is a membrane-bound protein translocase that serves to export folded proteins synthesized with N-terminal twin-arginine signal peptides. The essential TatC component of the Tat translocase is an integral membrane protein probably containing six transmembrane helices. Sequence analysis identified conserved TatC amino acid residues, and the role of these side-chains was assessed by single alanine substitution. This approach identified three classes of TatC mutants. Class I mutants included F94A, E103A and D211A, which were completely devoid of Tat-dependent protein export activity and thus represented residues essential for TatC function. Cross-complementation experiments with class I mutants showed that co-expression of D211A with either F94A or E103A regenerated an active Tat apparatus. These data suggest that different class I mutants may be blocked at different steps in protein transport and point to the co-existence of at least two TatC molecules within each Tat translocon. Class II mutations identified residues important, but not essential, for Tat activity, the most severely affected being L99A and Y126A. Class III mutants showed no significant defects in protein export. All but three of the essential and important residues are predicted to cluster around the cytoplasmic N-tail and first cytoplasmic loop regions of the TatC protein.

Post-translational protein translocation into thylakoids by the Sec and DeltapH-dependent pathways

Two distinct protein translocation pathways that employ hydrophobic signal peptides function in the plant thylakoid membrane. These two systems are precursor specific and distinguished by their energy and component requirements. Recent studies have shown that one pathway is homologous to the bacterial general export system called Sec. The other one, called the DeltapH-dependent pathway, was originally considered to be unique to plant thylakoids. However, it is now known that homologous transport systems are widely present in prokaryotes and even present in archaea. Here we review these protein transport pathways and discuss their capabilities and mechanisms of operation.

Toc, Tic, and chloroplast protein import

The vast majority of chloroplast proteins are synthesized in precursor form on cytosolic ribosomes. Chloroplast precursor proteins have cleavable, N-terminal targeting signals called transit peptides. Transit peptides direct precursor proteins to the chloroplast in an organelle-specific way. They can be phosphorylated by a cytosolic protein kinase, and this leads to the formation of a cytosolic guidance complex. The guidance complex--comprising precursor, hsp70 and 14-3-3 proteins, as well as several unidentified components--docks at the outer envelope membrane. Translocation of precursor proteins across the envelope is achieved by the joint action of molecular machines called Toc (translocon at the outer envelope membrane of chloroplasts) and Tic (translocon at the inner envelope membrane of chloroplasts), respectively. The action of the Toc/Tic apparatus requires the hydrolysis of ATP and GTP at different levels, indicating energetic requirements and regulatory properties of the import process. The main subunits of the Toc and Tic complexes have been identified and characterized in vivo, in organello and in vitro. Phylogenetic evidence suggests that several translocon subunits are of cyanobacterial origin, indicating that today's import machinery was built around a prokaryotic core.

The Rieske Fe/S protein of the cytochrome b6/f complex in chloroplasts: missing link in the evolution of protein transport pathways in chloroplasts?

The Rieske Fe/S protein, a nuclear-encoded subunit of the cytochrome b(6)/f complex in chloroplasts, is retarded in the stromal space after import into the chloroplast and only slowly translocated further into the thylakoid membrane system. As shown by the sensitivity to nigericin and to specific competitor proteins, thylakoid transport takes place by the DeltapH-dependent TAT pathway. The Rieske protein is an untypical TAT substrate, however. It is only the second integral membrane protein shown to utilize this pathway, and it is the first authentic substrate without a cleavable signal peptide. Transport is instead mediated by the NH(2)-terminal membrane anchor, which lacks, however, the twin-arginine motif indicative of DeltapH/TAT-dependent transport signals. Furthermore, transport is affected by sodium azide as well as by competitor proteins for the Sec pathway in chloroplasts, demonstrating for the first time some cross-talk of the two pathways. This might take place in the stroma where the Rieske protein accumulates after import in several complexes of high molecular mass, among which the cpn60 complex is the most prominent. These untypical features suggest that the Rieske protein represents an intermediate or early state in the evolution of the thylakoidal protein transport pathways.

Thylakoid DeltapH-dependent precursor proteins bind to a cpTatC-Hcf106 complex before Tha4-dependent transport

The thylakoid DeltapH-dependent pathway transports folded proteins with twin arginine-containing signal peptides. Identified components of the machinery include cpTatC, Hcf106, and Tha4. The reaction occurs in two steps: precursor binding to the machinery, and transport across the membrane. Here, we show that a cpTatC-Hcf106 complex serves as receptor for specific binding of twin arginine-containing precursors. Antibodies to either Hcf106 or cpTatC, but not Tha4, inhibited precursor binding. Blue native gel electrophoresis and coimmunoprecipitation of digitonin-solubilized thylakoids showed that Hcf106 and cpTatC are members of an approximately 700-kD complex that lacks Tha4. Thylakoid-bound precursor proteins were also associated with an approximately 700-kD complex and were coimmunoprecipitated with antibodies to cpTatC or Hcf106. Chemical cross-linking revealed that precursors make direct contact with cpTatC and Hcf106 and confirmed that Tha4 is not associated with precursor, cpTatC, or Hcf106 in the membrane. Precursor binding to the cpTatC-Hcf106 complex required both the twin arginine and the hydrophobic core of the signal peptide. Precursors remained bound to the complex when Tha4 was sequestered by antibody, even in the presence of DeltapH. These results indicate that precursor binding to the cpTatC-Hcf106 complex constitutes the recognition event for this pathway and that subsequent participation by Tha4 leads to translocation.

A naturally occurring bacterial Tat signal peptide lacking one of the ‘invariant’ arginine residues of the consensus targeting motif

Currently described substrates of the bacterial Tat protein transport system are directed for export by signal peptides containing a pair of invariant arginine residues. The signal peptide of the TtrB subunit of Salmonella enterica tetrathionate reductase contains a single arginine residue but is nevertheless able to mediate Tat pathway transport. This naturally occurring example of a Tat signal peptide lacking a consensus arginine pair expands the range of sequences that can target a protein to the Tat pathway. The possible implications of this finding for the assembly of electron transfer complexes containing Rieske proteins in plant organelles are discussed.

Chloroplast TatC plays a direct role in thylakoid (Delta)pH-dependent protein transport

The thylakoid (Delta)pH-dependent pathway transports folded proteins. Identified components include Hcf106 and Tha4. Orthologs of these proteins plus a membrane protein called TatC are essential for the homologous bacterial Tat system. Here we report identification of a chloroplast TatC (cpTatC). cpTatC is an integral thylakoid membrane protein as determined by in vitro chloroplast import and immunoblotting. Antibody to cpTatC specifically inhibited the thylakoid (Delta)pH-dependent pathway in vitro. cpTatC is present in about the same quantity as estimated translocation sites, whereas Hcf106 and Tha4 are present in 5-8-fold excess. These results are relevant to mechanistic models for this system.

Protein targeting by the twin-arginine translocation pathway

The twin-arginine translocation pathway operates in the thylakoid membrane of chloroplasts and in the plasma membrane of most free-living bacteria. Its main function is to transport fully folded proteins across the membrane. Three important tat genes have been identified and the sequences of the encoded proteins, together with the unusual properties of the pathway, indicate that the Tat system is completely different from other protein translocases.

Multiple pathways used for the targeting of thylakoid proteins in chloroplasts

The assembly of the chloroplast thylakoid membrane requires the import of numerous proteins from the cytosol and their targeting into or across the thylakoid membrane. It is now clear that multiple pathways are involved in the thylakoid-targeting stages, depending on the type of protein substrate. Two very different pathways are used by thylakoid lumen proteins; one is the Sec pathway which has been well-characterised in bacteria, and which involves the threading of the substrate through a narrow channel. In contrast, the more recently characterised twin-arginine translocation (Tat) system is able to translocate fully folded proteins across this membrane. Recent advances on bacterial Tat systems shed further light on the structure and function of this system. Membrane proteins, on the other hand, use two further pathways. One is the signal recognition particle-dependent pathway, involving a complex interplay between many different factors, whereas other proteins insert without the assistance of any known apparatus. This article reviews advances in the study of these pathways and considers the rationale behind the surprising complexity.

Export of active green fluorescent protein to the periplasm by the twin-arginine translocase (Tat) pathway in Escherichia coli

The twin-arginine translocation (Tat) system targets cofactor-containing proteins across the Escherichia coli cytoplasmic membrane via distinct signal peptides bearing a twin-arginine motif. In this study, we have analysed the mechanism and capabilities of the E. coli Tat system using green fluorescent protein (GFP) fused to the twin-arginine signal peptide of TMAO reductase (TorA). Fractionation studies and fluorescence measurements demonstrate that GFP is exported to the periplasm where it is fully active. Export is almost totally blocked in tat deletion mutants, indicating that the observed export in wild-type cells occurs predominantly, if not exclusively, by the Tat pathway. Imaging studies reveal a halo of fluorescence in wild-type cells corresponding to the exported periplasmic form; the GFP is distributed uniformly throughout the cytoplasm in a tat mutant. Because previous work has shown GFP to be incapable of folding in the periplasm, we propose that GFP is exported in a fully folded, active state. These data also show for the first time that heterologous proteins can be exported in an active form by the Tat pathway.

A mammalian cytochrome fused to a chloroplast transit peptide is a functional haemoprotein and is imported into isolated chloroplasts

The small subunit of ribulose-1,5-bisphosphate carboxylase/oxygenase (Rubisco) is a major chloroplast stromal protein that is cytosolically synthesized as a precursor with an N-terminal extension, known as the transit sequence or transit peptide (Tp). The Tp is essential for the post-translational uptake of the precursor by the chloroplast. The Tp is thought to influence the conformation of the precursor protein and to facilitate polypeptide translocation across the chloroplast envelope barrier via a Tp-selective translocon. To address these issues we have devised a novel strategy to generate substrate amounts of a chloroplast targeting sequence as a fusion with the chromogenic globular domain of cytochrome b(5) (Cyt). The chimaeric protein is an ideal probe for investigating the conformation of a preprotein and events surrounding protein import into isolated chloroplasts. The Cyt of liver endoplasmic reticulum was fused at its N-terminus with the Tp of the small subunit of Rubisco of Pisum sativum (pea). To enhance its production by clearance from the cytoplasm of Escherichia coli, the chimaera was engineered by further N-terminal linkage of a prokaryotic secretory signal. Expression of this tripartite fusion resulted in mg quantities of the signal sequence-processed Tp-Cyt protein, which was eventually targeted to the membranes. The chromogenic nature of the chimaera and its localization to the bacterial membrane facilitated the biochemical isolation of the precursor in a soluble and functional form. The purified preprotein displayed spectral and enzymic properties that were indistinguishable from the native parental Cyt, implying an absence of observable influence of the Tp on the conformation of the haemoprotein. The chimaeric precursor was imported into the stroma of the isolated chloroplasts in a dose-dependent manner. Import was also strongly dependent upon exogenously supplied ATP. The stromally imported chimaeric precursor protein was processed to a size characteristic of Cyt.