Roles of the N domain of the AAA+ Lon protease in substrate recognition,allosteric regulation and chaperone activity

Degron binding regulates the activities of the AAA+ Lon protease in addition to targeting proteins for degradation. The sul20 degron from the cell‐division inhibitor SulA is shown here to bind to the N domain of Escherichia coli Lon, and the recognition site is identified by cross‐linking and scanning for mutations that prevent sul20‐peptide binding. These N‐domain mutations limit the rates of proteolysis of model sul20‐tagged substrates and ATP hydrolysis by an allosteric mechanism. Lon inactivation of SulA in vivo requires binding to the N domain and robust ATP hydrolysis but does not require degradation or translocation into the proteolytic chamber. Lon‐mediated relief of proteotoxic stress and protein aggregation in vivo can also occur without degradation but is not dependent on robust ATP hydrolysis. In combination, these results demonstrate that Lon can function as a protease or a chaperone and reveal that some of its ATP‐dependent biological activities do not require translocation.     

Signal recognition particle (SRP) stabilizes the translocation-competent conformation of pre-secretory proteins.

When affinity-purified proOmpA was diluted out of 8 M urea into a sample of yeast microsomes, it was translocated and processed in the absence of any cytosolic factors; an intact membrane and ATP were the only requirements. The translocation competence of proOmpA was lost, however, during a 15-h incubation at 0 degrees C. The competence was retained when trigger factor and a yeast cytosolic extract were present during incubations at 0 degrees C. The same reactions were carried out with affinity-purified prepro-alpha-factor, and the same results were obtained with the exception that trigger factor was not required. When the various cytosolic factors were replaced with SRP, the addition of yeast microsomes after 15 h resulted in the translocation and processing (and glycosylation) of both proOmpA and prepro-alpha-factor. Pancreatic microsomes were also used in this type of assay, and it was found that proOmpA (but not prepro-alpha-factor) could be translocated when diluted out of urea. In this case, as with yeast microsomes, translocation competence was maintained by SRP. These results show that in addition to a recognition and targeting function, SRP can stabilize the translocation-competent conformation of pre-secretory proteins in vitro for translocation across eukaryotic membranes.     

In vivo kinetics of protein targeting to the endoplasmic reticulum determined by site-specific phosphorylation

We have developed a novel assay to detect the cytosolic localization of protein domains by inserting a short consensus sequence for phosphorylation by protein kinase A. In transfected COS-1 cells, this sequence was labeled efficiently with [(32)P]phosphate only when exposed to the cytosol and not when translocated into the lumen of the endoplasmic reticulum. The phosphorylation state of this sequence can therefore be used to determine the topology of membrane proteins. This assay is sufficiently sensitive to detect even the transient cytosolic exposure of the N-terminal domain of a membrane protein with a reverse signal-anchor sequence. The extent of phosphorylation per newly synthesized polypeptide was shown to reflect the time of exposure to the cytosol, which depends on translation, targeting and translocation of the N-terminus. By altering the length of the N-terminal domain or manipulating the translation rate, it was determined that protein targeting is rapid and requires only a few seconds. The rate of N-terminal translocation was estimated to be approximately 1.6 times the rate of translation.     

Secretory protein translocation in a yeast cell-free system can occur posttranslationally and requires ATP hydrolysis

We describe an in vitro system with all components derived from the yeast Saccharomyces cerevisiae that can translocate a yeast secretory protein across microsomal membranes. In vitro transcribed prepro-alpha-factor mRNA served to program a membrane-depleted yeast translation system. Translocation and core glycosylation of prepro-alpha-factor were observed when yeast microsomal membranes were added during or after translation. A membrane potential is not required for translocation. However, ATP is required for translocation and nonhydrolyzable analogues of ATP cannot serve as a substitute. These findings suggest that ATP hydrolysis may supply the energy required for translocation of proteins across the endoplasmic reticulum.     

Full-length prepro-alpha-factor can be translocated across the mammalian microsomal membrane only if translation has not terminated

We have previously shown that fully synthesized prepro-alpha-factor (pp alpha F), the precursor for the yeast pheromone alpha-factor, can be translocated posttranslationally across yeast rough microsomal (RM) membranes from a soluble, ribosome-free pool. We show here that this is not the case for translocation of pp alpha F across mammalian RM. Rather we found that a small amount of translocation of full-length pp alpha F is observed, but is solely due to polypeptide chains that were still ribosome bound and covalently attached to tRNA, i.e., not terminated. In addition, both signal recognition particle (SRP) and SRP receptor are required, i.e., the same targeting machinery that is normally responsible for the coupling between protein synthesis and translocation. Thus, the molecular requirements for targeting are distinct from posttranslational translocation across yeast RM. As termination is generally regarded as part of translation, the translocation of full-length pp alpha F across mammalian RM does not occur "posttranslationally," albeit independent of elongation. Most other proteins for which posttranslational translocation across mammalian RM was previously claimed fall into the same category in that ribosome attachment as peptidyl-tRNA is required. To clearly separate these two distinct processes, we suggest that the term posttranslational be reserved for those processes that occur in the complete absence of the translational machinery. We propose the term "ribosome-coupled translocation" for the events described here.     

Determinants of membrane-targeting and transmembrane translocation during bacterial protein export.

We have separately analyzed membrane-targeting and membrane translocation of an exported bacterial protein. The precursor of the outer membrane protein LamB of Escherichia coli was synthesized in vitro and translocated into inverted plasma membrane vesicles under co- and post-translational conditions. The translation/translocation products of LamB were subsequently resolved into soluble and membrane-associated material. Dissipation of the H(+)-motive force, depletion of ATP and treatment of membranes with N-ethylmaleimide each inhibited processing and translocation of preLamB without preventing its binding to the membranes. Hence, all three conditions block transmembrane passage rather than membrane-targeting. The latter was abolished by pretreatment of salt-extracted membrane vesicles with trypsin. It was also drastically reduced when preLamB was synthesized in cell extracts derived from either a secA amber or a secB null mutant. Membrane-targeting of preLamB therefore requires soluble SecA and SecB as well as a protease-sensitive membrane receptor. The finding that SecA is involved in targeting whereas ATP is required for the transmembrane passage suggests that SecA, which harbors an ATPase activity [Lill et al. (1989), EMBO J., 8, 961-966], might have a dual function in bacterial protein export.     

ATP-Induced Shape Change of Nuclear Pores Visualized with the Atomic Force Microscope

Bidirectional transport of molecules between nucleus and cytoplasm through the nuclear pore complexes (NPCs) spanning the nuclear envelope plays a fundamental role in cell function and metabolism. Nuclear import of macromolecules is a two-step process involving initial recognition of targeting signals, docking to the pore and energy-driven translocation. ATP depletion inhibits the translocation step. The mechanism of translocation itself and the conformational changes of the NPC components that occur during macromolecular transport, are still unclear. The present study investigates the effect of ATP on nuclear pore conformation in isolated nuclear envelopes from Xenopus laevis oocytes using the atomic force microscope. All experiments were conducted in a saline solution mimicking the cytosol using unfixed nuclear envelopes. ATP (1 mm) was added during the scanning procedure and the resultant conformational changes of the NPCs were directly monitored. Images of the same nuclear pores recorded before and during ATP exposure revealed dramatic conformational changes of NPCs subsequent to the addition of ATP. The height of the pores protruding from the cytoplasmic surface of the nuclear envelope visibly increased while the diameter of the pore opening decreased. The observed changes occurred within minutes and were transient. The slow-hydrolyzing ATP analogue, ATP-γ-S, in equimolar concentrations did not exert any effects. The ATP-induced shape change could represent a nuclear pore ``contraction.' Received: 10 February 1997/Revised: 10 February 1998     

Secretion in yeast: preprotein binding to a membrane receptor and ATP- dependent translocation are sequential and separable events in vitro

We have used a cytosol-free assay in which efficient translocation and signal peptide cleavage is achieved when the affinity-purified precursor of OmpA (proOmpA) is diluted out of 8 M urea into a suspension of yeast rough microsomes. This aspect of protein targeting and transport occurs in two discernible steps: (a) in the absence of ATP and cytosolic factors, the precursor binds to the membranes but is not translocated; (b) addition of ATP results in the translocation of the bound precursor and its processing to the mature form. The binding to microsomes of radiolabeled proOmpA is saturable and inhibited by the addition of unlabeled proOmpA but not by mature OmpA or other proteins. The binding of radiolabeled prepro-alpha-factor is also effectively competed by other preproteins, but not by mature ones. Scatchard analysis showed the Kd of proOmpA to be 7.5 X 10(-9) M. Binding is most likely protein mediated as treatment of the microsomes with the protease papain was found to be inhibitory. These results represent the first functional characterization of secretory protein precursor binding to membranes. Alkylation of the microsomes with NEM, washing the membranes with urea or using membranes from the (translocation) mutant ptll at the nonpermissive temperature, did not affect binding, but did eliminate the subsequent ATP-dependent translocation. The ability to subdivide translocation into individual reactions provides a more precise means of determining the membrane components involved in this process.     

Development of a minimal cell-free translation system for the synthesis of presecretory and integral membrane proteins

By combining translation and membrane integration/translocation systems, we have constructed a novel cell-free system for the production of presecretory and integral membrane proteins in vitro. A totally defined, cell-free system reconstituted from a minimal number of translation factors was supplemented with urea-washed inverted membrane vesicles (U-INVs) prepared from Escherichia coli, as well as with purified proteins mediating membrane targeting of presecretory and integral membrane proteins. Initially, efficient membrane translocation of a presecretory protein (pOmpA) was obtained simply by the addition of only SecA and SecB. Proteinase K digestion clearly showed the successful translocation of pOmpA inside the vesicles. Next, integration of an inner membrane protein (MtlA) into U-INVs was achieved in the presence of only SRP (Ffh) and SR (FtsY). Finally, a membrane protein possessing a large periplasmic region (FtsQ) and therefore requiring both factors (SRP/SR and SecA/SecB) for membrane integration/translocation was also shown to be integrated correctly in this cell-free system. Thus, our novel cell-free system provides not only an efficient strategy for the production of membrane-related proteins but also an improved platform for the biological study of protein translocation and integration mechanisms.     

In vitro analysis of the process of translocation of OmpA across the Escherichia coli cytoplasmic membrane. A translocation intermediate accumulates transiently in the absence of the proton motive force

The proton motive force (delta mu H+) plays an important role, although it is not absolutely essential, in the in vitro translocation of secretory proteins, such as OmpA, across the cytoplasmic membrane of Escherichia coli (Yamada, H., Tokuda, H., and Mizushima, S. (1989) J. Biol. Chem. 264, 1723-1728). The transient accumulation in membrane vesicles of a possible translocation intermediate of OmpA was observed in the absence of delta mu H+. The intermediate was detected on a polyacrylamide gel as a proteinase K-resistant band corresponding to a molecular weight of 26,000. The intermediate did not possess the signal peptide. The appearance of this band was inhibited in the absence of ATP or the presence of adenosine 5'-(beta,gamma-imino)triphosphate (AMP-PNP) and enhanced upon the addition of SecA. Upon the addition of NADH that energizes the membrane, the intermediate was converted to the translocated form of OmpA, even in the presence of AMP-PNP. These results suggest different requirements of ATP and delta mu H+ for the early and late stages of the translocation reaction. The SecA requirement for the early stage of the translocation has also been suggested. In addition to this band, two other bands were observed at higher positions on the gel, when the translocation reaction was performed in the absence of delta mu H+. Although these two bands also represented the mature form of OmpA, which was partly protected from the proteinase K treatment by the membrane vesicles, the accumulation was not transient. These bands did not appear when the translocation reaction was performed in the presence of dithiothreitol. Together with other evidence, the above observations suggest that OmpA, which has an intramolecular disulfide bridge, cannot undergo the translocation unless delta mu H+ is imposed.     

The amino terminus of opsin translocates "posttranslationally" as efficiently as cotranslationally

Opsin, a member of the G-protein-coupled receptor family, is a polytopic membrane protein that does not encode a cleaved amino-terminal signal sequence. The amino terminus of opsin precedes the first known targeting information, suggesting that it translocates across the endoplasmic reticulum (ER) membrane after synthesis, uncoupled from translation. However, translocation across the mammalian ER is believed to be coupled to protein synthesis. In this study we show that opsin, within a range of nascent peptide lengths, targets and translocates equally efficiently co- and posttranslationally. Longer nascent opsin peptides have a lower efficiency of cotranslational translocation but an even lower efficiency of posttranslational translocation. We also show that SRP is required for both co- and posttranslational targeting.     

Translation elongation regulates substrate selection by the signal recognition particle

The signal recognition particle (SRP) is a universally conserved cellular machinery responsible for delivering membrane and secretory proteins to the proper cellular destination. The precise mechanism by which fidelity is achieved by the SRP pathway within the in vivo environment is yet to be understood. Previous studies have focused on the SRP pathway in isolation. Here we describe another important factor that modulates substrate selection by the SRP pathway: the ongoing synthesis of the nascent polypeptide chain by the ribosome. A slower translation elongation rate rescues the targeting defect of substrate proteins bearing mutant, suboptimal signal sequences both in vitro and in vivo. Consistent with a kinetic origin of this effect, similar rescue of protein targeting was also observed with mutant SRP receptors or SRP RNAs that specifically compromise the kinetics of SRP-receptor interaction during protein targeting. These data are consistent with a model in which ongoing protein translation is in constant kinetic competition with the targeting of the nascent proteins by the SRP and provides an important factor to regulate the fidelity of substrate selection by the SRP.     

A functional interaction between the signal peptide and the translation apparatus is detected by the use of a single point mutation which blocks translocation across mammalian endoplasmic reticulum

A functional interaction between the signal sequence and the translation apparatus which may serve as a first step in chain targeting to the membrane is described. To this end, we exploited the powerful technique of molecular cloning in a procaryotic system and the well characterized translocation system of mammalian endoplasmic reticulum. The signal peptide of subunit B of the heat labile enterotoxin of Escherichia coli (EltB) was fused to several proteins. Single base substitutions were introduced in the signal peptide and their effect on protein synthesis and translocation was studied. We sought a single amino acid substitution which may define certain steps in the coordinated regulation of chain synthesis and targeting to the membrane. The substitution of proline for leucine at residue -8 in the signal peptide abolished all known functions of the signal peptide. In contrast to wild type signal peptide, the mutant signal peptide did not lead to arrest of nascent chain synthesis by signal recognition particle or translocation of the precursor protein across the membrane of the endoplasmic reticulum. Furthermore, the mutant signal peptide was not cleaved by purified E. coli signal peptidase. Interestingly, the mutation resulted in about a 2-fold increase in the rate of synthesis of the precursor protein, suggesting a role for the signal peptide in regulating the synthesis of the nascent secretory chain as a means of ensuring early and efficient targeting of this chain to the membrane. This role might involve interaction of the signal peptide with components of the translation apparatus and/or endogenous signal recognition particle. These results were obtained with three different fusion proteins carrying the signal peptide of EltB thus leading to the conclusion that the effect of the mutation on the structure and function of the signal peptide is independent of the succeeding sequence to which the signal peptide is attached.     

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.     

Evidence for a stromal GTP requirement for the integration of a chlorophyll a/b-binding polypeptide into thylakoid membranes.

The integration of chlorophyll a/b-binding (LHCP) polypeptides and the translocation of the 33-kD oxygen-evolving enhancer protein (OEE33) have been previously shown to occur in chloroplast extracts containing stroma, thylakoids, ATP, and MgCl2. We have re-examined the nucleotide requirement for these two reactions using stromal extract and translation products depleted of low molecular weight compounds. LHCP integration activity was up to 10-fold higher when assayed with GTP compared with ATP, CTP, or UTP. A combination of ATP and GTP supported less LHCP integration activity than GTP alone, suggesting that GTP meets the entire nucleotide requirement. Nonhydrolyzable analogs of GTP were inhibitory, consistent with the idea that GTP hydrolysis is required for integration activity. Periodate-oxidized GTP (GTPox) also inhibited the integration reaction when present during the assay. Pretreatment of stroma with GTPox followed by GTPox removal inhibited integration activity, whereas pretreatment of thylakoids had no effect. We interpret this to mean that a GTP-binding protein involved in integration is localized in the stroma. Translocation of OEE33 was more efficient with ATP than with GTP, and the combination of both nucleotides was not additive. Our data implicate the involvement of a GTPase in LHCP integration but not in the translocation of OEE33.     

ATP is required for the binding of precursor proteins to chloroplasts

One of the first steps in the transport of nuclear-encoded, cytoplasmically synthesized precursor proteins into chloroplasts is a specific binding interaction between precursor proteins and the surface of the organelle. Although protein translocation into chloroplasts requires ATP hydrolysis, binding is generally thought to be energy independent. A more detailed investigation of precursor binding to the surface of chloroplasts showed that ATP was required for efficient binding. Protein translocation is known to require relatively high levels (1 mM or more) of ATP. As little as 50-100 microM ATP caused significant stimulation of precursor binding over controls with no ATP. Several different precursors were tested and all showed increased binding upon addition of low levels of ATP. Nonhydrolyzable analogs of ATP did not substitute for ATP, indicating that ATP hydrolysis was required for binding. A protonmotive force was not involved in the energy requirement for binding. Other (hydrolyzable) nucleotides could substitute for ATP but were less effective at stimulating binding. Binding was stimulated by ATP generated inside chloroplasts even when an ATP trap was present to destroy external ATP. We conclude that internal ATP is required for stimulation of precursor binding to chloroplasts.     

The retinal rod Na(+)/Ca(2+),K(+) exchanger contains a noncleaved signal sequence required for translocation of the N terminus

The retinal rod Na(+)/Ca(2+),K(+) exchanger (RodX) is a polytopic membrane protein found in photoreceptor outer segments where it is the principal extruder of Ca(2+) ions during light adaptation. We have examined the role of the N-terminal 65 amino acids in targeting, translocation, and integration of the RodX using an in vitro translation/translocation system. cDNAs encoding human RodX and bovine RodX through the first transmembrane domain were correctly targeted and integrated into microsomal membranes; deletion of the N-terminal 65 amino acids (aa) resulted in a translation product that was not targeted or integrated. Deletion of the first 65 aa had no effect on membrane targeting of full-length RodX, but the N-terminal hydrophilic domain no longer translocated. Chimeric constructs encoding the first 65 aa of bovine RodX fused to globin were translocated across microsomal membranes, demonstrating that the sequence could function heterologously. Studies of fresh bovine retinal extracts demonstrated that the first 65 aa are present in the native protein. These data demonstrate that the first 65 aa of RodX constitute an uncleaved signal sequence required for the efficient membrane targeting and proper membrane integration of RodX.     

Mechanism of phosphorylation in the lumen of the Golgi apparatus. Translocation of adenosine 5'-triphosphate into Golgi vesicles from rat liver and mammary gland

The occurrence of phosphorylated secretory proteins such as caseins and vitellogenin and the recent characterization of phosphorylated proteoglycans, in the xylose and protein core, has raised the question of where in the cell and how this phosphorylation occurs. Previous studies have described a casein kinase activity in the lumen of the Golgi apparatus and this organelle as the site of xylose addition to the protein core of proteoglycans. We now report the translocation in vitro of ATP into the lumen of rat liver and mammary gland Golgi vesicles which are sealed and have the same membrane topographical orientation as in vivo. The entire ATP molecule was translocated into the lumen of the Golgi vesicles; this was established by using ATP radiolabeled with tritium in the adenine and gamma-32P. Translocation was temperature dependent and saturable, with an apparent Km of 0.9 microM and Vmax of 58 pmol/mg protein/min. Preliminary evidence suggests that translocation of ATP into the vesicles' lumen is coupled to exit of AMP from the lumen. Following translocation of ATP into the lumen of the vesicles, proteins were phosphorylated.     

A genomic integration method for the simultaneous visualization of endogenous mRNAs and their translation products in living yeast

Protein localization within cells can be achieved by the targeting and localized translation of mRNA. Yet, our understanding of the dynamics of mRNA targeting and protein localization, and of how general this phenomenon is, is not clear. Plasmid-based expression systems have been used to visualize exogenously expressed mRNAs and proteins; however, these methods typically produce them at levels greater than endogenous and can result in mislocalization. Hence, a method that allows for the simultaneous visualization of endogenous mRNAs and their translation products in living cells is needed. We previously developed a method (m-TAG) to localize endogenously expressed mRNAs in yeast by chromosomal insertion of the MS2 aptamer sequence between the open-reading frame (ORF) and 3' UTR of any gene. Upon coexpression with the MS2 RNA-binding coat protein (MS2-CP) fused with GFP, the aptamer-tagged mRNAs bearing their 3' UTRs are localized using fluorescence microscopy. Here we describe an advanced method (mp-TAG) that allows for the simultaneous visualization of both endogenously expressed mRNAs and their translation products in living yeast for the first time. Homologous recombination is used to insert the mCherry gene and MS2-CP binding sites downstream from any ORF, in order to localize protein and mRNA, respectively. As proof of the concept, we tagged ATP2 as a representative gene and demonstrated that endogenous ATP2 mRNA and protein localize to mitochondria, as shown previously. In addition, we demonstrate that tagged proteins like Hhf2, Vph1, and Yef3 localize to their expected subcellular location, while the localization of their mRNAs is revealed for the first time.