Transient reprogramming of crop plants for agronomic performance.

The development of a new crop variety is a time-consuming and costly process due to the reliance of plant breeding on gene shuffling to introduce desired genes into elite germplasm, followed by backcrossing. Here, we propose alternative technology that transiently targets various regulatory circuits within a plant, leading to operator-specified alterations of agronomic traits, such as time of flowering, vernalization requirement, plant height or drought tolerance. We redesigned techniques of gene delivery, amplification and expression around RNA viral transfection methods that can be implemented on an industrial scale and with many crop plants. The process does not involve genetic modification of the plant genome and is thus limited to a single plant generation, is broadly applicable, fast, tunable and versatile, and can be used throughout much of the crop cultivation cycle. The RNA-based reprogramming may be especially useful in plant pathogen pandemics but also for commercial seed production and for rapid adaptation of orphan crops.

C-terminal truncation of a Tat passenger protein affects its membrane translocation by interfering with receptor binding.

During thylakoid transport of the chimeric model twin-arginine translocation (Tat) substrate 16/23, two consecutive translocation intermediates with different membrane topology are observed. The early translocation intermediate Ti-1 is bound to the membrane such that almost half of the protein is protected against proteolysis and it was concluded that not only the signal peptide but also part of the passenger protein participates in membrane binding. However, topology studies using a membrane-impermeable thiol-reactive reagent show that most of the passenger remains accessible from the stromal side in Ti-1 conformation. Establishment of such Ti-1 topology at the membrane apparently requires the fully folded passenger protein, as it was not observed with 16/23 truncation derivatives lacking the C-terminal 20, 40, 60, or 88 residues. Thylakoid transport of these mutants, which depends on a fully functional Tat machinery, is progressively reduced with increasing size of the truncated passenger polypeptide. The same holds true also for the interaction with the thylakoidal TatBC complexes, suggesting that in this case receptor binding, which is apparently impaired by extended unfolded or malfolded passenger polypeptides, is the rate-limiting step of Tat-dependent membrane transport.

Tat transport of a Sec passenger leads to both completely translocated as well as membrane-arrested passenger proteins.

We have studied the membrane transport of the chimeric precursor protein 16/33, which is composed of the Tat(1)-specific transport signal of OEC16 and the Sec passenger protein OEC33, both subunits of the oxygen-evolving system associated with photosystem II. Protein transport experiments performed with isolated pea thylakoids show that the 16/33 chimera is transported in a strictly Tat-dependent manner into the thylakoid vesicles yielding mature OEC33 (mOEC33) in two different topologies. One fraction accumulates in the thylakoid lumen and is thus resistant to externally added protease. A second fraction is arrested during transport in an N-in/C-out topology within the membrane. Chase experiments demonstrate that this membrane-arrested mOEC33 moiety does not represent a translocation intermediate but instead an alternative end product of the transport process. Transport arrest of mOEC33, which is embedded in the membrane with a mildly hydrophobic protein segment, requires more than 26 additional and predominantly hydrophilic residues C-terminal of the membrane-embedded segment. Furthermore, it is stimulated by mutations which potentially affect the conformation of mOEC33 suggesting that at least partial folding of the passenger protein is required for complete membrane translocation.

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.

Twin arginine translocation (Tat)-dependent protein transport: the passenger protein participates in the initial membrane binding step.

The initial step in twin arginine translocation (Tat)-dependent thylakoid transport of the 16/23 chimera is the interaction of the protein with the lipid bilayer. It results in the formation of the early translocation intermediate Ti-1, which is represented by a protease-protected fragment of 14 kDa. Cys-scanning mutagenesis in combination with in thylakoido and liposome insertion assays was used to precisely map this membrane-interacting and protease-protected fragment within the 16/23 chimera. The fragment comprises 124 residues, which are provided both by the transit peptide (31 residues) and the mature protein (93 residues), demonstrating that the passenger protein directly participates in membrane binding. The implications of this finding on the mechanism of Tat-dependent protein transport are discussed.