Signal recognition particle-dependent membrane insertion of mouse invariant chain: a membrane-spanning protein with a cytoplasmically exposed amino terminus

Invariant (Ii) chain is a membrane-spanning protein that is found associated intracellularly with class II histocompatibility antigens. In the endoplasmic reticulum Ii chain spans the membrane and exposes the NH2 terminus on the cytoplasmic and the COOH terminus on the lumenal side. This orientation across the membrane is demonstrated directly with the monoclonal antibody In-1, which exclusively recognizes the NH2 terminal cytoplasmically exposed part of Ii chain. Membrane insertion of Ii chain requires signal recognition particle and docking protein. When tested in a wheat germ cell free system, signal recognition particle arrests translation of Ii chain. No signal sequence is cleaved from Ii chain upon membrane insertion.     

Deletion analysis of the internal signal-anchor domain of the human asialoglycoprotein receptor H1.

The human asialoglycoprotein receptor H1 is a single-spanning membrane protein with the amino terminus facing the cytoplasm and the carboxy terminus exposed on the exoplasmic side of the plasma membrane. It has been shown earlier that the transmembrane segment, residues 38-65, functions as an internal signal directing protein synthesis to the endoplasmic reticulum and initiating membrane insertion. This process is co-translational and mediated by signal recognition particle (SRP). To identify subsegments within this region containing the signal information, we prepared deletion mutants at the level of the cDNA and analysed them in a wheat germ in vitro translation system with microsomes as the target membrane. Insertion and membrane anchoring were judged by the glycosylation of the protein, its resistance to exogenous protease and the extent to which it can be extracted from the microsomes by alkaline treatment. It was found that very small deletions already reduce the stability of membrane anchoring. However, nearly half of the transmembrane domain can be deleted, both from the amino-terminal and from the carboxy-terminal side, without completely abolishing membrane insertion. Several mutants, although not inserted, still interact with SRP. The results support the notion that the main feature of a signal sequence is a hydrophobic stretch of sufficient length (10-12 residues in our sequence), and indicate that recognition by SRP is not sufficient for membrane insertion.     

Signal recognition particle (SRP) does not mediate a translational arrest of nascent secretory proteins in mammalian cell-free systems.

The ability of the signal recognition particle (SRP) to induce translational arrests in wheat germ, reticulocyte and HeLa cell-free translation systems was examined. In accordance with published data, SRP caused a complete arrest of secretory protein (IgG light chain) translation in wheat germ. In contrast, SRP had no effect on translation in either reticulocyte or HeLa cell lysates, even at 5-fold higher SRP levels than needed for complete arrest in wheat germ. The existence of a "docking-protein-like" releasing activity was ruled out, in the case of reticulocyte lysate, by experiments in which reticulocyte subfractions were added to blocked translations in wheat germ. In the absence of additional evidence to the contrary, it seems as if the translational arrest is peculiar to the wheat germ cell-free system.     

Signal recognition particle mediates a transient elongation arrest of preprolactin in reticulocyte lysate

Signal recognition particle (SRP) is a ribonucleoprotein that functions in the targeting of ribosomes synthesizing presecretory proteins to the ER. SRP binds to the signal sequence as it emerges from the ribosome, and in wheat germ extracts, arrests further elongation. The translation arrest is released when SRP interacts with its receptor on the ER membrane. We show that the delay of elongation mediated by SRP is not unique to wheat germ translation extracts. Addition of mammalian SRP to reticulocyte lysates resulted in a delay of preprolactin synthesis due to increased ribosome pausing at specific sites on preprolactin mRNA. Addition of canine pancreatic microsomal membranes to reticulocyte lysates resulted in an acceleration of preprolactin synthesis, suggesting that the endogenous SRP present in the reticulocyte lysate also delays synthesis of secretory proteins.     

Protein translocation across wheat germ microsomal membranes requires an SRP-like component

Different wheat germ extracts were tested for the presence of membranes capable of translocating and processing nascent secretory proteins. One lysate was found in which nascent prehuman-placental lactogen (phPL) was translocated and processed to mature human placental lactogen (hPL). Processing was found to occur concomitant with translocation across membranes. Translocation across the wheat germ membrane required a component which is similar to the mammalian signal recognition particle (SRP). It bound to DEAE–Sepharose, had a sedimentation coefficient of 11S and contained a 7S RNA. In addition to hPL, the plant protein zein and the bacterial protein β-lactamase were translocated across and processed by wheat germ membranes. Transport was found to occur only co-translationally. Our results show that the wheat germ protein translocation system is similar to the mammalian one. Unlike the mammalian SRP, the particle purified from wheat germ did not arrest elongation of nascent secretory proteins.     

Translocation of nascent secretory proteins across membranes can occur late in translation.

Signal recognition particle (SRP) causes an arrest in the translation of nascent secretory proteins in a wheat germ cell-free system. In order to examine at what point during the synthesis of a secretory protein its translocation across the endoplasmic reticulum (ER) membrane can occur, SRP was used to arrest nascent chain elongation at various times during a synchronous translation, thus allowing the generation of nascent chains of increasing length. It was found that SRP can still bring about an arrest as late as when an average of two-thirds of nascent IgG light chain was completed. Rough microsomes were added to translations blocked with SRP to determine if such relatively long nascent chains could still be translocated across the membrane. It was found that nascent chains which had been arrested by SRP, regardless of their length, could be translocated into rough microsomes. In the case of IgG light chain, translocation levels of 50% were still observed with nascent chains corresponding to as much as 70-75% of the intact preprotein. Similar results were observed for the nascent bovine prolactin precursor. These results demonstrate that the synthesis of secretory proteins can be uncoupled from their translocation, and that fairly large nascent chains are capable of crossing the membrane of the ER post-translationally.     

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.     

Endoplasmic reticulum-bound ribosomes reside in stable association with the translocon following termination of protein synthesis

In current views, translation-coupled ribosome binding to the endoplasmic reticulum (ER) membrane is transient, with association occurring via the signal recognition particle pathway and dissociation occurring upon the termination of protein synthesis. Recent studies indicate, however, that ribosomal subunits remain membrane-bound following the termination of protein synthesis. To define the mechanism of post-termination ribosome association with the ER membrane, membrane-bound ribosomes were detergent-solubilized from tissue culture cells at different stages of the protein synthesis cycle, and the composition of the ribosome-associated membrane protein fraction was determined. We report that ribosomes reside in stable association with the Sec61alpha-translocon following the termination stage of protein synthesis. Additionally, in vitro experiments revealed that solubilized, gradient-purified ribosome-translocon complexes were able to initiate the translation of secretory and cytosolic proteins and were functional in assays of signal sequence recognition. Using this experimental system, synthesis of signal sequence-bearing polypeptides yielded a tight ribosome-translocon junction; synthesis of nascent polypeptides lacking a signal sequence resulted in a disruption of this junction. On the basis of these data, we propose that in situ, ribosomes reside in association with the translocon throughout the cycle of protein synthesis, with membrane release occurring upon translation of proteins lacking topogenic signals.     

Post-translational transport of proteins into microsomal membranes of Candida maltosa.

We have isolated from the yeast Candida maltosa microsomal membranes that are active in the translocation of proteins synthesized in cell-free systems derived from C. maltosa, Saccharomyces cerevisiae or wheat germ. Translocation and core glycosylation of prepro-alpha-factor, a secretory protein, were observed with yeast microsomes added during or after translation. The signal peptide is cleaved off. Cytochrome P-450 from C. maltosa, the first integral membrane protein studied in a yeast system, is also inserted both co- and post-translationally into Candida microsomal membranes. Its insertion into canine microsomes occurs efficiently only in a co-translational manner and is dependent on the function of the signal recognition particle.     

Signal recognition particle causes a transient arrest in the biosynthesis of prepromelittin and mediates its translocation across mammalian endoplasmic reticulum

The translocation of prepromelittin (pPM) across mammalian endoplasmic reticulum was studied in both wheat germ and reticulocyte lysate. In the wheat germ system, signal recognition particle (SRP) caused a transient arrest in the synthesis of pPM. This was indicated by a slowdown in the rate of synthesis of pPM in the presence of SRP. The arrest was specific, dependent on the concentration of SRP, and more effective at early incubation time. In a tightly synchronized translation system, SRP had no apparent effect on the elongation of pPM, indicating that the effect of SRP on pPM chain synthesis might be at the final stages of chain elongation and release from the ribosome. This was reflected in a transient accumulation of pPM as peptidyl tRNA. Because pPM is composed of only 70 amino acids, arrest by SRP may be very close to chain termination. Arrest at this stage of chain synthesis seems to be unstable and the nascent chain gets terminated and released from the ribosome after a transient delay. The translocation of pPM was shown to be dependent on both SRP and docking protein. The difference in the translocation efficiency of pPM in reticulocyte and wheat germ lysates may reflect a difference in the targeting process in the two systems.     

Role of signal recognition particle in the membrane assembly of Sindbis viral glycoproteins

We have investigated the role of signal recognition particle (SRP) in the biosynthesis of Sindbis glycoproteins by translating the viral 26S mRNA in a wheat-germ cell-free system. SRP was shown to have no effect on the synthesis or proteolytic processing of the cytoplasmic C protein. In contrast, the membrane integration and the proteolytic processing of the viral glycoproteins PE2 and E1 were demonstrated to be SRP-dependent. In the absence of microsomal membranes, SRP caused an arrest of the synthesis of the viral glycoproteins. This arrest could be released by the addition of salt-extracted microsomal membranes. Synchronization experiments indicated that the uncleaved signal sequence of PE2 was recognized by SRP after at most 130 amino acids of PE2 had been polymerized. No apparent interaction of SRP with a putative signal sequence of E1 and/or a 6-kDa peptide could be detected.     

Synthetic signal peptide and analogs display different activities in mammalian and plant in vitro secretion systems

The biological properties of four chemically synthesized signal peptides were compared in mammalian (rabbit reticulocyte) and plant (wheat germ) cell-free protein secretion systems. The precursor-specific region of bovine pre-proparathyroid hormone (preproPTH), [D-Tyr-(+1)]preproPTH-(-29-+1)amide, and a sulfur-free analog, [Nle-(-25), Nle-(-21), Nle-(-18), Ala-(-14), D-Tyr-(+1)]preproPTH-(-29-+1)amide, inhibit the processing of an unrelated precursor protein (pre-prolactin) to its mature secreted form (prolactin) in the mammalian system. In the plant system supplemented with signal recognition particle, the signal peptides arrest translation of both secretory (preprolactin) and cytoplasmic (globin) proteins. One analog, [Nle-(-25), Nle-(-21), Asp-(-18), Ala-(-14), D-Tyr-(+1)]preproPTH-(-29-+1)amide, inhibits preprotein processing in the mammalian system but fails to induce translation arrest in the plant system. A truncated peptide, [N alpha-AcLeu-(-17), Ala-(-14), D-Tyr-(+1)]preproPTH-(-17-+1)amide, lacking the N-terminal (positively charged) region and a portion of the hydrophobic core region, is inactive in both systems. These studies demonstrate that the chemically synthesized signal region of a precursor protein interacts directly with signal recognition particle and functionally mimics the proposed properties of a native signal sequence linked to a nascent protein as it emerges from the ribosome during biosynthesis, and an analog of the signal peptide reveals fundamental differences between the components involved in the protein secretion apparatus in mammals and plants.     

Translocation of proteins across the endoplasmic reticulum. I. Signal recognition protein (SRP) binds to in-vitro-assembled polysomes synthesizing secretory protein

An 11S protein composed of six polypeptide chains was previously purified from a salt extract of dog pancreas microsomal membranes and shown to be required for translocation of nascent secretory protein across the microsomal membrane (Wistar and Blobel 1980 Proc. Natl. Acad. Sci. U. S. A. 77:7112-7116). This 11S protein, termed signal recognition protein (SRP), has been shown here (a) to inhibit translation in the wheat germ cell-free system selectively of mRNA for secretory protein (bovine preprolactin) but not of mRNA for cytoplasmic protein (alpha and beta chain of rabbit globin); (b) to bind with relatively low affinity (apparent KD less than 5 x 10(-5)) to monomeric wheat germ ribosomes; and (c) to bind selectively and with 6,000-fold higher affinity (apparent KD less than 8 x 10(-9)) to wheat germ ribosomes engaged in the synthesis of secretory protein but not to those engaged in the synthesis of cytoplasmic protein. Low- and high- affinity binding as well as the selective translation-inhibitory effect were abolished after modification of SRP by N-ethyl maleimide. High- affinity binding and the selective translation-inhibitory effect of SRP were largely abolished when the leucine (Leu) analogue beta-hydroxy leucine was incorporated into the nascent secretory polypeptide.     

Import of honeybee prepromelittin into the endoplasmic reticulum. Requirements for membrane insertion, processing, and sequestration

Honeybee prepromelittin is correctly processed and imported by dog pancreas microsomes. Membrane insertion of prepromelittin, assayed as signal sequence removal by signal peptidase, is not dependent on signal recognition particle and docking protein. However, a previously uncharacterized proteinaceous component of the microsomal membrane is required for completion of membrane transfer of promelittin. Furthermore, membrane insertion of prepromelittin is not coupled to translation. These data suggest the signal sequence, in addition to its role in membrane recognition, has a more general function for membrane insertion, cotranslational import of proteins is not an intrinsic feature of microsomes, and at least in certain cases, proteinaceous membrane components are involved in membrane transfer.     

Cell-free processing and segregation of insulin precursors

The biosynthesis, segregation, and processing of preproinsulin (116 amino acids) was investigated to determine the mechanism(s) by which it is translocated across the endoplasmic reticulum membrane. Islet mRNA was translated in the wheat germ cell-free system, and at various times during preproinsulin synthesis, puromycin was added, followed by addition of microsomal membranes. Neither processing of preproinsulin nor translocation of proinsulin into microsomal membranes occurred in the presence of puromycin. Synchronization of preproinsulin translation by addition of 7-methylguanosine 5'-phosphate enabled the timing of preproinsulin synthesis and proinsulin (91 amino acids) segregation into microsomal membranes to be determined. Membrane binding occurs when about 60 amino acids have been polymerized, i.e. prior to the completion of the polypeptide chain. The binding of signal recognition particle to the nascent signal is demonstrated to be an absolute requirement for translocation and processing of preproinsulin. The results indicate that segregation and processing of preproinsulin are co-translational events; no evidence for a post-translational mechanism was found. Furthermore, this work, together with similar studies, suggests that presecretory polypeptides must be synthesized as part of a precursor with a minimum size of 60-80 amino acids in order to effect membrane binding and translocation of the polypeptide chain within the intracisternal space of the endoplasmic reticulum.     

Regulation of ribosome detachment from the mammalian endoplasmic reticulum membrane

In current models, protein translocation in the endoplasmic reticulum (ER) occurs in the context of two cycles, the signal recognition particle (SRP) cycle and the ribosome cycle. Both SRP and ribosomes bind to the ER membrane as a consequence of the targeting process of translocation. Whereas SRP release from the ER membrane is regulated by the GTPase activities of SRP and the SRP receptor, ribosome release from the ER membrane is thought to occur in response to the termination of protein synthesis. We report that ER-bound ribosomes remain membrane-bound following the termination of protein synthesis and in the bound state can initiate the translation of secretory and cytoplasmic proteins. Two principal observations are reported. 1) Membrane-bound ribosomes engaged in the synthesis of proteins lacking a signal sequence are released from the ER membrane as ribosome-nascent polypeptide complexes. 2) Membrane-bound ribosomes translating secretory proteins can access the translocon in an SRP receptor-independent manner. We propose that ribosome release from the ER membrane occurs in the context of protein translation, with release occurring by default in the absence of productive nascent polypeptide-membrane interactions.     

In vitro translation of chicken type X collagen in the presence of pancreas microsomes

Total RNA from epiphysis of 17-day-old chick embryo tibiae was used to direct protein synthesis in a wheat germ cell free system. The type X collagen chain, identified on the basis of its electrophoretic migration and of peptides obtained by S. aureus V8 protease digestion, was the major translation product. The newly synthesized chain included a signal sequence that was removed when dog pancreas membranes were added at the time of the protein synthesis.     

Incomplete polypeptides are formed in vitro by premature chain termination

The mechanism of incomplete polypeptides formation during protein synthesis was studied in the wheat germ cell-free system programmed with brome mosaic virus RNA 4. The synthesis of coat protein, the complete product of RNA 4 translation, was accompanied by the appearance of polypeptides of lower molecular mass. It was shown that incomplete products are formed by translation of different lengths of RNA 4, always from the first 5' AUG codon, and were due neither to proteolysis of coat protein nor to the translation of nucleolytic fragments of mRNA. The molecular masses of incomplete products were determined and the nucleotide sequence of RNA 4 was examined in the regions where wheat germ ribosomes stop translating. It was found that they contained, on average, a slightly higher guanosine content than the total coding part of RNA 4. Translation of RNA 4 in the reticulocyte lysate resulted in a marked diminution of incomplete polypeptides. Addition of high-speed supernatant from reticulocyte lysate prevented the formation of incomplete products during translation of RNA 4 in the wheat germ system. This suggests that reticulocyte lysate contains some factor(s) which facilitate the movement of ribosomes beyond the regions where the elongation is retarded.     

Bimodal targeting of microsomal CYP2E1 to mitochondria through activation of an N-terminal chimeric signal by cAMP-mediated phosphorylation

Cytochrome P450 2E1 (CYP2E1) plays an important role in alcohol-induced toxicity and oxidative stress. Recently, we showed that this predominantly microsomal protein is also localized in rat hepatic mitochondria. In this report, we show that the N-terminal 30 amino acids of CYP2E1 contain a chimeric signal for bimodal targeting of the apoprotein to endoplasmic reticulum (ER) and mitochondria. We demonstrate that the cryptic mitochondrial targeting signal at sequence 21-31 of the protein is activated by cAMP-dependent phosphorylation at Ser-129. S129A mutation resulted in lower affinity for binding to cytoplasmic Hsp70, mitochondrial translocases (TOM40 and TIM44) and reduced mitochondrial import. S129A mutation, however, did not affect the extent of binding to the signal recognition particle and association with ER membrane translocator protein Sec61. Addition of saturating levels of signal recognition particle caused only a partial inhibition of CYP2E1 translation under in vitro conditions, and saturating levels of ER resulted only in partial membrane integration. cAMP enhanced the mitochondrial CYP2E1 (referred to as P450MT5) level but did not affect its level in the ER. Our results provide new insights on the mechanism of cAMP-mediated activation of a cryptic mitochondrial targeting signal and regulation of P450MT5 targeting to mitochondria.