Soluble TatA forms oligomers that interact with membranes: Structure and insertion studies of a versatile protein transporter.

The twin-arginine translocase (Tat) mediates the transport of already-folded proteins across membranes in bacteria, plants and archaea. TatA is a small, dynamic subunit of the Tat-system that is believed to be the active component during target protein translocation. TatA is foremost characterized as a bitopic membrane protein, but has also been found to partition into a soluble, oligomeric structure of yet unknown function. To elucidate the interplay between the membrane-bound and soluble forms we have investigated the oligomers formed by Arabidopsis thaliana TatA. We used several biophysical techniques to study the oligomeric structure in solution, the conversion that takes place upon interaction with membrane models of different compositions, and the effect on bilayer integrity upon insertion. Our results demonstrate that in solution TatA oligomerizes into large objects with a high degree of ordered structure. Upon interaction with lipids, conformational changes take place and TatA disintegrates into lower order oligomers. The insertion of TatA into lipid bilayers causes a temporary leakage of small molecules across the bilayer. The disruptive effect on the membrane is dependent on the liposome's negative surface charge density, with more leakage observed for purely zwitterionic bilayers. Overall, our findings indicate that A. thaliana TatA forms oligomers in solution that insert into bilayers, a process that involves reorganization of the protein oligomer.

Functional reconstitution of TatB into the thylakoidal Tat translocase.

We have established an experimental system for the functional analysis of thylakoidal TatB, a component of the membrane-integral TatBC receptor complex of the thylakoidal Twin-arginine protein transport (Tat) machinery. For this purpose, the intrinsic TatB activity of isolated pea thylakoids was inhibited by affinity-purified antibodies and substituted by supplementing the assays with TatB protein either obtained by in vitro translation or purified after heterologous expression in E. coli. Tat transport activity of such reconstituted thylakoids, which was analysed with the authentic Tat substrate pOEC16, reached routinely 20-25% of the activity of mock-treated thylakoid vesicles analysed in parallel. In contrast, supplementation of the assays with the purified antigen comprising all but the N-terminal transmembrane helix of thylakoidal TatB did not result in Tat transport reconstitution which confirms that transport relies strictly on the activity of the TatB protein added and is not due to restoration of the intrinsic TatB activity by antibody release. Unexpectedly, even a mutated TatB protein (TatB,E10C) assumed to be incapable of assembling into the TatBC receptor complex showed low but considerable transport reconstitution underlining the sensitivity of the approach and its suitability for further functional analyses of protein variants. Finally, quantification of TatB demand suggests that TatA and TatB are required in approximately equimolar amounts to achieve Tat-dependent thylakoid transport.

Structure and dynamics of plant TatA in micelles and lipid bilayers studied by solution NMR.

The twin-arginine translocase (Tat) transports folded proteins across the cytoplasmic membrane of prokaryotes and the thylakoid membrane of plant chloroplasts. In Gram-negative bacteria and chloroplasts, the translocon consists of three subunits, TatA, TatB, and TatC, of which TatA is responsible for the actual membrane translocation of the substrate. Herein we report on the structure, dynamics, and lipid interactions of a fully functional C-terminally truncated 'core TatA' from Arabidopsis thaliana using solution-state NMR. Our results show that TatA consists of a short N-terminal transmembrane helix (TMH), a short connecting linker (hinge) and a long region with propensity to form an amphiphilic helix (APH). The dynamics of TatA were characterized using 15 N relaxation NMR in combination with model-free analysis. The TMH has order parameters characteristic of a well-structured helix, the hinge is somewhat less rigid, while the APH has lower order parameters indicating structural flexibility. The TMH is short with a surprisingly low protection from solvent, and only the first part of the APH is protected to some extent. In order to uncover possible differences in TatA's structure and dynamics in detergent compared to in a lipid bilayer, fast-tumbling bicelles and large unilamellar vesicles were used. Results indicate that the helicity of TatA increases in both the TMH and APH in the presence of lipids, and that the N-terminal part of the TMH is significantly more rigid. The results indicate that plant TatA has a significant structural plasticity and a capability to adapt to local environments.

Purification of rabbit serum histidine-proline-rich glycoprotein via preparative gel electrophoresis and characterization of its glycosylation patterns.

Histidine-Proline-rich Glycoprotein (HPRG) is a plasma protein of vertebrates and several marine bivalves. Due to its multidomain structure consisting of several regions HPRG can interact with a variety of ligands, however the exact physiological role has not been discovered yet. Past purification approaches out of plasma or serum often led to co-purification of other proteins so that for a profound understanding of the function it is important to obtain a protein of high purity. Recent purification strategies were based upon metale chelate affinity chromatography followed by anion exchange chromatography or size exclusion chromatography, respectively. A large amount of serum albumin, the major plasma protein, also elutes from metale chelate affinity chromatography columns. Separation of rabbit HPRG from rabbit serum albumin could not be achieved via the above named methods by us. We present a method of purification of rabbit serum HPRG by means of metal affinity chromatography and preparative gel electrophoresis, which makes it possible to obtain HPRG practically devoid of impurities as assessed by mass spectrometry analysis. Moreover, we characterize the amount of glycosylation of HPRG and-to the best of our knowledge for the first time-the glycosylation pattern of rabbit HPRG.

How to achieve Tat transport with alien TatA.

TatA is an essential and structurally conserved component of all known Twin-arginine transport (Tat) machineries which are able to catalyse membrane transport of fully folded proteins. Here we have investigated if bacterial TatA, or chimeric pea/E. coli TatA derivatives, are capable of replacing thylakoidal TatA in function. While authentic E. coli TatA does not show any transport activity in thylakoid transport experiments, TatA chimeras comprising the transmembrane helix (TMH) of pea TatA are fully active. For minimal catalytic activity it is even sufficient to replace three residues within TMH of E. coli TatA by the corresponding pea residues. Almost any further substitution within TMH gradually raises transport activity in the thylakoid system, while functional characterization of the same set of TatA derivatives in E. coli yields essentially inverse catalytic activities. Closer inspection of the substituted residues suggests that the two transport systems have deviating demands with regard to the hydrophobicity of the transmembrane helix.

Enough is enough: TatA demand during Tat-dependent protein transport.

The twin-arginine translocation (Tat(1)) pathway is unique with respect to its property to translocate proteins in a fully folded conformation across ion-tight membranes. In chloroplasts and Gram-negative bacteria, Tat translocase consists of the integral subunits TatB and TatC, which are assumed to constitute the membrane receptor, and TatA, a bitopic membrane protein being responsible in a yet unknown manner for the membrane translocation step. Antibody inhibition of intrinsic thylakoidal TatA activity and recovery of transport by heterologously expressed, purified TatA allowed to exactly quantify the amount of TatA required to catalyse membrane transport of the model Tat substrate 16/23. We can show that TatA concentrations in the 100nM range are sufficient to efficiently catalyse membrane transport of the protein, which corresponds well to the amount of TatA identified in thylakoids. Furthermore, TatA shows cooperativity in its catalytic activity suggesting that Tat translocase operates as an allosteric enzyme complex.

Interaction of a Tat substrate and a Tat signal peptide with thylakoid lipids at the air-water interface.

The Tat machinery enables folded proteins to be translocated across biological membranes. In vitro studies have shown that Tat substrates can interact with membranes prior to translocation. In this study we investigated the initial states of this interaction with thylakoid lipid monolayers at the air-water interface by using monolayer techniques combined with infrared reflection-absorption spectroscopy (IRRAS). We used enhanced green fluorescent protein (EGFP) as a model substrate and the signal peptide SP16 from the 16 kDa protein of the spinach oxygen-evolving complex (OEC16). We found that the signal peptide is essential for the interaction of the model substrate with lipid monolayers. IRRA spectroscopy showed an increased amount of α-helical secondary structure elements for the chimeric model substrate i16/EGFP (SP16 fused to EGFP) compared with EGFP; this can be attributed to the signal peptide.

One signal is enough: Stepwise transport of two distinct passenger proteins by the Tat pathway across the thylakoid membrane.

The twin-arginine translocation (Tat) pathway, one of four protein transport pathways operating at the thylakoid membrane of chloroplasts, shows remarkable substrate flexibility. Here, we have analyzed the thylakoid transport of chimeric tandem substrates that are composed of two different passenger proteins fused to a single Tat transport signal. The chimera 23/23-EGFP in which the reporter protein EGFP is connected to the C-terminus of the OEC23 precursor shows that a single Tat transport signal is sufficient to mediate transport of two distinct passenger proteins in a row. Replacing the transit peptide of OEC23 in 23/23-EGFP by its homolog from OEC16 yields the chimera 16/23-EGFP, which can likewise be fully translocated by the Tat pathway across the thylakoid membrane. However, transport of 16/23-EGFP is retarded at specific steps in the transport process leading to the temporary and consecutive accumulation of three translocation intermediates with distinct membrane topology. They are associated with two oligomeric membrane complexes presumably representing TatBC-receptor complexes. The composition of the translocation intermediates as determined by immunoprecipitation experiments suggests that the two passenger proteins are translocated in a stepwise manner across the membrane.

Tat subunit stoichiometry in Arabidopsis thaliana challenges the proposed function of TatA as the translocation pore.

The twin arginine translocation (Tat) machinery which is capable of transporting folded proteins across lipid bilayers operates in the thylakoid membrane of plant chloroplasts as well as in the cytoplasmic membrane of bacteria. It is composed of three integral membrane proteins (TatA, TatB, and TatC) which form heteromeric complexes of high molecular weight that accomplish binding and transport of substrates carrying Tat pathway-specific signal peptides. Western analyses using affinity purified antibodies showed in both, juvenile and adult tissue from Arabidopsis thaliana, an approximately equimolar ratio of the TatB and TatC components, whereas TatA was detectable only in minor amounts. Upon Blue Native-PAGE, TatB and TatC were found in four heteromeric TatB/C complexes possessing molecular weights of approximately 310, 370, 560 and 620 kDa, respectively, while TatA was detected only in a molecular weight range below 200 kDa. The implications of these findings on the currently existing models explaining the mechanism of Tat transport are discussed.

A stromal pool of TatA promotes Tat-dependent protein transport across the thylakoid membrane.

In chloroplasts and bacteria, the Tat (twin-arginine translocation) system is engaged in transporting folded passenger proteins across the thylakoid and cytoplasmic membranes, respectively. To date, three membrane proteins (TatA, TatB, and TatC) have been identified to be essential for Tat-dependent protein translocation in the plant system, whereas soluble factors seem not to be required. In contrast, in the bacterial system, several cytosolic chaperones were described to be involved in Tat transport processes. Therefore, we have examined whether stromal or peripherally associated membrane proteins also play a role in Tat transport across the thylakoid membrane. Analyzing both authentic precursors as well as the chimeric 16/23 protein, which allows us to study each step of the translocation process individually, we demonstrate that a soluble form of TatA is present in the chloroplast stroma, which significantly improves the efficiency of Tat-dependent protein transport. Furthermore, this soluble TatA is able to reconstitute the Tat transport properties of thylakoid membranes that are transport-incompetent due to extraction with solutions of chaotropic salts.

At least two Toc34 protein import receptors with different specificities are also present in spinach chloroplasts.

The receptor components of the chloroplast protein import machinery, Toc34 and Toc159, are both encoded by small gene families in Arabidopsis thaliana. Recent results suggest that each member of these families preferentially interacts with different groups of precursor proteins. Here we address the question, whether multiple homologous Toc receptors are unique to Arabidopsis or whether they are a general phenomenon in plants. Indeed, in spinach we could identify at least two Toc34 proteins with different substrate specificities as demonstrated by competition and antibody inhibition experiments. In addition, an analysis of the available genomic data revealed the presence of at least two Toc34 homologs in six other plant species.

Direct photomodulation of peptide backbone conformations.

Significant photoswitching ability is found for secondary thioxopeptide bonds and can be used for the photomodulation of the backbone conformation of peptides or proteins.