The C‐terminal regions of YidC from Rhodopirellula baltica and Oceanicaulis alexandrii bind to ribosomes and partially substitute for SRP receptor function in Escherichia coli

The marine Gram‐negative bacteria Rhodopirellula baltica and Oceanicaulis alexandrii have, in contrast to Escherichia coli, membrane insertases with extended positively charged C‐terminal regions similar to the YidC homologues in mitochondria and Gram‐positive bacteria. We have found that chimeric forms of E. coli YidC fused to the C‐terminal YidC regions from the marine bacteria mediate binding of YidC to ribosomes and therefore may have a functional role for targeting a nascent protein to the membrane. Here, we show in E. coli that an extended C‐terminal region of YidC can compensate for a loss of SRP‐receptor function in vivo. Furthermore, the enhanced affinity of the ribosome to the chimeric YidC allows the isolation of a ribosome nascent chain complex together with the C‐terminally elongated YidC chimera. This complex was visualized at 8.6 Å by cryo‐electron microscopy and shows a close contact of the ribosome and a YidC monomer.     

Interaction of Streptococcus mutans YidC1 and YidC2 with Translating and Nontranslating Ribosomes

The YidC/OxaI/Alb3 family of membrane proteins is involved in the biogenesis of integral membrane proteins in bacteria, mitochondria, and chloroplasts. Gram-positive bacteria often contain multiple YidC paralogs that can be subdivided into two major classes, namely, YidC1 and YidC2. The Streptococcus mutans YidC1 and YidC2 proteins possess C-terminal tails that differ in charges (+9 and + 14) and lengths (33 and 61 amino acids). The longer YidC2 C terminus bears a resemblance to the C-terminal ribosome-binding domain of the mitochondrial OxaI protein and, in contrast to the shorter YidC1 C terminus, can mediate the interaction with mitochondrial ribosomes. These observations have led to the suggestion that YidC1 and YidC2 differ in their abilities to interact with ribosomes. However, the interaction with bacterial translating ribosomes has never been addressed. Here we demonstrate that Escherichia coli ribosomes are able to interact with both YidC1 and YidC2. The interaction is stimulated by the presence of a nascent membrane protein substrate and abolished upon deletion of the C-terminal tail, which also abrogates the YidC-dependent membrane insertion of subunit c of the F₁F₀-ATPase into the membrane. It is concluded that both YidC1 and YidC2 interact with ribosomes, suggesting that the modes of membrane insertion by these membrane insertases are similar.     

A ribosome–nascent chain sensor of membrane protein biogenesis in Bacillus subtilis

Proteins in the YidC/Oxa1/Alb3 family have essential functions in membrane protein insertion and folding. Bacillus subtilis encodes two YidC homologs, one that is constitutively expressed (spoIIIJ/yidC1) and a second (yqjG/yidC2) that is induced in spoIIIJ mutants. Regulated induction of yidC2 allows B. subtilis to maintain capacity of the membrane protein insertion pathway. We here show that a gene located upstream of yidC2 (mifM/yqzJ) serves as a sensor of SpoIIIJ activity that regulates yidC2 translation. Decreased SpoIIIJ levels or deletion of the MifM transmembrane domain arrests mifM translation and unfolds an mRNA hairpin that otherwise blocks initiation of yidC2 translation. This regulated translational arrest and yidC2 induction require a specific interaction between the MifM C‐terminus and the ribosomal polypeptide exit tunnel. MifM therefore acts as a ribosome–nascent chain complex rather than as a fully synthesized protein. B. subtilis MifM and the previously described secretion monitor SecM in Escherichia coli thereby provide examples of the parallel evolution of two regulatory nascent chains that monitor different protein export pathways by a shared molecular mechanism.     

The Role of the Strictly Conserved Positively Charged Residue Differs among the Gram-positive,Gram-negative,and Chloroplast YidC Homologs

Recently, the structure of YidC2 from Bacillus halodurans revealed that the conserved positively charged residue within transmembrane segment one (at position 72) is located in a hydrophilic groove that is embedded in the inner leaflet of the lipid bilayer. The arginine residue was essential for the Bacillus subtilis SpoIIIJ (YidC1) to insert MifM and to complement a SpoIIIJ mutant strain. Here, we investigated the importance of the conserved positively charged residue for the function of the Escherichia coli YidC, Streptococcus mutans YidC2, and the chloroplast Arabidopsis thaliana Alb3. Like the Gram-positive B. subtilis SpoIIIJ, the conserved arginine was required for functioning of the Gram-positive S. mutans YidC2 and was necessary to complement the E. coli YidC depletion strain and to promote insertion of a YidC-dependent membrane protein synthesized with one but not two hydrophobic segments. In contrast, the conserved positively charged residue was not required for the E. coli YidC or the A. thaliana Alb3 to functionally complement the E. coli YidC depletion strain or to promote insertion of YidC-dependent membrane proteins. Our results also show that the C-terminal half of the helical hairpin structure in cytoplasmic loop C1 is important for the activity of YidC because various deletions in the region either eliminate or impair YidC function. The results here underscore the importance of the cytoplasmic hairpin region for YidC and show that the arginine is critical for the tested Gram-positive YidC homolog but is not essential for the tested Gram-negative and chloroplast YidC homologs.     

Reprogramming chaperone pathways to improve membrane protein expression in Escherichia coli

Because membrane proteins are difficult to express, our understanding of their structure and function is lagging. In Escherichia coli, α-helical membrane protein biogenesis usually involves binding of a nascent transmembrane segment (TMS) by the signal recognition particle (SRP), delivery of the SRP-ribosome nascent chain complexes (RNC) to FtsY, a protein that serves as SRP receptor and docks to the SecYEG translocon, cotranslational insertion of the growing chain into the translocon, and lateral transfer, packing and folding of TMS in the lipid bilayer in a process that may involve chaperone YidC. Here, we explored the feasibility of reprogramming this pathway to improve the production of recombinant membrane proteins in exponentially growing E. coli with a focus on: (i) eliminating competition between SRP and chaperone trigger factor (TF) at the ribosome through gene deletion; (ii) improving RNC delivery to the inner membrane via SRP overexpression; and (iii) promoting substrate insertion and folding in the lipid bilayer by increasing YidC levels. Using a bitopic histidine kinase and two heptahelical rhodopsins as model systems, we show that the use of TF-deficient cells improves the yields of membrane-integrated material threefold to sevenfold relative to the wild type, and that whereas YidC coexpression is beneficial to the production of polytopic proteins, higher levels of SRP have the opposite effect. The implications of our results on the interplay of TF, SRP, YidC, and SecYEG in membrane protein biogenesis are discussed.     

Isolation of cold-sensitive yidC mutants provides insights into the substrate profile of the YidC insertase and the importance of transmembrane 3 in YidC function

YidC, a 60-kDa integral membrane protein, plays an important role in membrane protein insertion in bacteria. YidC can function together with the SecYEG machinery or operate independently as a membrane protein insertase. In this paper, we describe two new yidC mutants that lead to a cold-sensitive phenotype in bacterial cell growth. Both alleles impart a cold-sensitive phenotype and result from point mutations localized to the third transmembrane (TM3) segment of YidC, indicating that this region is crucial for YidC function. We found that the yidC(C423R) mutant confers a weak phenotype on membrane protein insertion while a yidC(P431L) mutant leads to a stronger phenotype. In both cases, the affected substrates include the Pf3 coat protein and ATP synthase F₁F_o subunit c (F_oC), while CyoA (the quinol binding subunit of the cytochrome bo3 quinol oxidase complex) and wild-type procoat are slightly affected or not affected in either cold-sensitive mutant. To determine if the different substrates require various levels of YidC activity for membrane insertion, we performed studies where YidC was depleted using an arabinose-dependent expression system. We found that −3M-PC-Lep (a construct with three negatively charged residues inserted into the middle of the procoat-Lep [PC-Lep] protein) and Pf3 P2 (a construct with the Lep P2 domain added at the C terminus of Pf3 coat) required the highest amount of YidC and that CyoA-N-P2 (a construct with the amino-terminal part of CyoA fused to the Lep P2 soluble domain) and PC-Lep required the least, while F_oC required moderate YidC levels. Although the cold-sensitive mutations can preferentially affect one substrate over another, our results indicate that different substrates require different levels of YidC activity for membrane insertion. Finally, we obtained several intragenic suppressors that overcame the cold sensitivity of the C423R mutation. One pair of mutations suggests an interaction between TM2 and TM3 of YidC. The studies reveal the critical regions of the YidC protein and provide insight into the substrate profile of the YidC insertase.     

Versatility of Trigger Factor Interactions with Ribosome-Nascent Chain Complexes

Trigger factor (TF) is the first molecular chaperone that interacts with nascent chains emerging from bacterial ribosomes. TF is a modular protein, consisting of an N-terminal ribosome binding domain, a PPIase domain, and a C-terminal domain, all of which participate in polypeptide binding. To directly monitor the interactions of TF with nascent polypeptide chains, TF variants were site-specifically labeled with an environmentally sensitive NBD fluorophore. We found a marked increase in TF-NBD fluorescence during translation of firefly luciferase (Luc) chains, which expose substantial regions of hydrophobicity, but not with nascent chains lacking extensive hydrophobic segments. TF remained associated with Luc nascent chains for 111 ± 7 s, much longer than it remained bound to the ribosomes (t_½ ∼ 10–14 s). Thus, multiple TF molecules can bind per nascent chain during translation. The Escherichia coli cytosolic proteome was classified into predicted weak and strong interactors for TF, based on the occurrence of continuous hydrophobic segments in the primary sequence. The residence time of TF on the nascent chain generally correlated with the presence of hydrophobic regions and the capacity of nascent chains to bury hydrophobicity. Interestingly, TF bound the signal sequence of a secretory protein, pOmpA, but not the hydrophobic signal anchor sequence of the inner membrane protein FtsQ. On the other hand, proteins lacking linear hydrophobic segments also recruited TF, suggesting that TF can recognize hydrophobic surface features discontinuous in sequence. Moreover, TF retained significant affinity for the folded domain of the positively charged, ribosomal protein S7, indicative of an alternative mode of TF action. Thus, unlike other chaperones, TF appears to employ multiple mechanisms to interact with a wide range of substrate proteins.     

The charge distribution in the cytoplasmic loop of subunit C of the F1F0 ATPase is a determinant for YidC targeting

YidC is a member of the Oxa1 family of proteins that facilitates the membrane insertion of a subset of inner membrane proteins in Escherichia coli. YidC acts as an insertase for membrane insertion of subunit c of the F(1)F(0) ATP synthase (F(0)c), but the requirements for substrate recognition have remained unclear. Here, we have analyzed the role of the charged aminoacyl residues in F(0)c in YidC targeting and membrane insertion. Binding experiments demonstrate that F(0)c is targeted directly to YidC without the presence of a stable lipid surface-bound intermediate. Positive charges in the cytoplasmic loop of F(0)c are important determinants for YidC binding and subsequent membrane insertion. These data support a model in which F(0)c binds directly to YidC prior to its membrane insertion.     

MifM Monitors Total YidC Activities of Bacillus subtilis,Including That of YidC2, the Target of Regulation

The YidC/Oxa1/Alb3 family proteins are involved in membrane protein biogenesis in bacteria, mitochondria, and chloroplasts. Recent studies show that YidC uses a channel-independent mechanism to insert a class of membrane proteins into the membrane. Bacillus subtilis has two YidC homologs, SpoIIIJ (YidC1) and YidC2 (YqjG); the former is expressed constitutively, while the latter is induced when the SpoIIIJ activity is compromised. MifM is a substrate of SpoIIIJ, and its failure in membrane insertion is accompanied by stable ribosome stalling on the mifM-yidC2 mRNA, which ultimately facilitates yidC2 translation. While mutational inactivation of SpoIIIJ has been known to induce yidC2 expression, here, we show that the level of this induction is lower than that observed when the membrane insertion signal of MifM is defective. Moreover, this partial induction of YidC2 translation is lowered further when YidC2 is overexpressed in trans. These results suggest that YidC2 is able to insert MifM into the membrane and to release its translation arrest. Thus, under SpoIIIJ-deficient conditions, YidC2 expression is subject to MifM-mediated autogenous feedback repression. Our results show that YidC2 uses a mechanism that is virtually identical to that used by SpoIIIJ; Arg75 of YidC2 in its intramembrane yet hydrophilic cavity is functionally indispensable and requires negatively charged residues of MifM as an insertion substrate. From these results, we conclude that MifM monitors the total activities of the SpoIIIJ and the YidC2 pathways to control the synthesis of YidC2 and to maintain the cellular capability of the YidC mode of membrane protein biogenesis.     

The C Terminus of the Alb3 Membrane Insertase Recruits cpSRP43 to the Thylakoid Membrane

The YidC/Oxa1/Alb3 family of membrane proteins controls the insertion and assembly of membrane proteins in bacteria, mitochondria, and chloroplasts. Here we describe the molecular mechanisms underlying the interaction of Alb3 with the chloroplast signal recognition particle (cpSRP). The Alb3 C-terminal domain (A3CT) is intrinsically disordered and recruits cpSRP to the thylakoid membrane by a coupled binding and folding mechanism. Two conserved, positively charged motifs reminiscent of chromodomain interaction motifs in histone tails are identified in A3CT that are essential for the Alb3-cpSRP43 interaction. They are absent in the C-terminal domain of Alb4, which therefore does not interact with cpSRP43. Chromodomain 2 in cpSRP43 appears as a central binding platform that can interact simultaneously with A3CT and cpSRP54. The observed negative cooperativity of the two binding events provides the first insights into cargo release at the thylakoid membrane. Taken together, our data show how Alb3 participates in cpSRP-dependent membrane targeting, and our data provide a molecular explanation why Alb4 cannot compensate for the loss of Alb3. Oxa1 and YidC utilize their positively charged, C-terminal domains for ribosome interaction in co-translational targeting. Alb3 is adapted for the chloroplast-specific Alb3-cpSRP43 interaction in post-translational targeting by extending the spectrum of chromodomain interactions.     

YidC, an assembly site for polytopic Escherichia coli membrane proteins located in immediate proximity to the SecYE translocon and lipids

Like its mitochondrial homolog Oxa1p, the inner membrane protein YidC of Escherichia coli is involved in the integration of membrane proteins. We have analyzed individual insertion steps of the polytopic E. coli membrane protein MtlA targeted as ribosome-nascent chain complexes to inner membrane vesicles. YidC can accommodate at least the first two transmembrane segments of MtlA at the protein lipid interface and retain them even though the length of the nascent chain would amply allow insertion into membrane lipids. An even longer insertion intermediate of MtlA is described that still has the first transmembrane helix bound to YidC while the third contacts SecE and YidC during integration. Our findings suggest that YidC forms a contiguous integration unit with the SecYE translocon and functions as an assembly site for polytopic membrane proteins mediating the formation of helix bundles prior to their release into the membrane lipids.     

Membrane protein insertion of variant MscL proteins occurs at YidC and SecYEG of Escherichia coli

The mechanosensitive channel MscL in the inner membrane of Escherichia coli is a homopentameric complex involved in homeostasis when cells are exposed to hypoosmotic conditions. The E. coli MscL protein is synthesized as a polypeptide of 136 amino acid residues and uses the bacterial signal recognition particle for membrane targeting. The protein is inserted into the membrane independently of the Sec translocon but requires YidC. Depletion of YidC inhibits translocation of the protein across the membrane. Insertion of MscL occurs primarily in a proton motive force-independent manner. The hydrophilic loop region of MscL has 29 residues that include 5 charged residues. Altering the charges in the periplasmic loop of MscL affects the requirements for membrane insertion. The introduction of one, two or three negatively charged amino acids makes the insertion dependent on the electrochemical membrane potential and gradually dependent on the Sec translocon, whereas the addition of five negatively charged residues as well as the addition of three positively charged residues inhibits membrane insertion of MscL. However, we find that the mutant with three uncharged residues requires both the SecYEG complex and YidC but not SecA for membrane insertion. In vivo cross-linking data showed that the newly synthesized MscL interacts with YidC and with SecY. Therefore, the MscL mutants use a membrane insertion mechanism that involves SecYEG and YidC simultaneously.     

YidC Occupies the Lateral Gate of the SecYEG Translocon and Is Sequentially Displaced by a Nascent Membrane Protein

Most membrane proteins are co-translationally inserted into the lipid bilayer via the universally conserved SecY complex and they access the lipid phase presumably via a lateral gate in SecY. In bacteria, the lipid transfer of membrane proteins from the SecY channel is assisted by the SecY-associated protein YidC, but details on the SecY-YidC interaction are unknown. By employing an in vivo and in vitro site-directed cross-linking approach, we have mapped the SecY-YidC interface and found YidC in contact with all four transmembrane domains of the lateral gate. This interaction did not require the SecDFYajC complex and was not influenced by SecA binding to SecY. In contrast, ribosomes dissociated the YidC contacts to lateral gate helices 2b and 8. The major contact between YidC and the lateral gate was lost in the presence of ribosome nascent chains and new SecY-YidC contacts appeared. These data demonstrate that the SecY-YidC interaction is influenced by nascent-membrane-induced lateral gate movements.     

M13 procoat protein insertion into YidC and SecYEG proteoliposomes and liposomes

M13 procoat protein was one of the first model proteins used to study bacterial membrane protein insertion. It contains a signal peptide of 23 amino acid residues and is not membrane targeted by the signal recognition particle. The translocation of its periplasmic domain is independent of the preprotein translocase (SecAYEG) but requires electrochemical membrane potential and the membrane insertase YidC of Escherichia coli. We show here that YidC is sufficient for efficient membrane insertion of the purified M13 procoat protein into energized YidC proteoliposomes. When no membrane potential is applied, the insertion is substantially reduced. Only in the presence of YidC, membrane insertion occurs if bilayer integrity is preserved and membrane potential is stable for more than 20 min. A mutant of the M13 procoat protein, H5EE, with two additional negatively charged residues in the periplasmic domain inserted into YidC proteoliposomes and SecYEG proteoliposomes with equal efficiencies. We conclude that the protein can use both the YidC-only pathway and the Sec pathway. This poses the questions of how procoat H5EE is inserted in vivo and how insertion pathways are selected in the cell.     

Nascent polypeptide-associated complex stimulates protein import into yeast mitochondria

To identify yeast cytosolic proteins that mediate targeting of precursor proteins to mitochondria, we developed an in vitro import system consisting of purified yeast mitochondria and a radiolabeled mitochondrial precursor protein whose C terminus was still attached to the ribosome. In this system, the N terminus of the nascent chain was translocated across both mitochondrial membranes, generating a translocation intermediate spanning both membranes. The nascent chain could then be completely chased into the mitochondrial matrix after release from the ribosome. Generation of this import intermediate was dependent on a mitochondrial membrane potential, mitochondrial surface proteins, and was stimulated by proteins that could be released from the ribosomes by high salt. The major salt-released stimulatory factor was yeast nascent polypeptide-associated complex (NAC). Purified NAC fully restored import of salt-washed ribosome-bound nascent chains by enhancing productive binding of the chains to mitochondria. We propose that ribosome-associated NAC facilitates recognition of nascent precursor chains by the mitochondrial import machinery.     

Charge Composition Features of Model Single-span Membrane Proteins That Determine Selection of YidC and SecYEG Translocase Pathways in Escherichia coli

We have investigated the features of single-span model membrane proteins based upon leader peptidase that determines whether the proteins insert by a YidC/Sec-independent, YidC-only, or YidC/Sec mechanism. We find that a protein with a highly hydrophobic transmembrane segment that inserts into the membrane by a YidC/Sec-independent mechanism becomes YidC-dependent if negatively charged residues are inserted into the translocated periplasmic domain or if the hydrophobicity of the transmembrane segment is reduced by substituting polar residues for nonpolar ones. This suggests that charged residues in the translocated domain and the hydrophobicity within the transmembrane segment are important determinants of the insertion pathway. Strikingly, the addition of a positively charged residue to either the translocated region or the transmembrane region can switch the insertion requirements such that insertion requires both YidC and SecYEG. To test conclusions from the model protein studies, we confirmed that a positively charged residue is a SecYEG determinant for the endogenous proteins ATP synthase subunits a and b and the TatC subunit of the Tat translocase. These findings provide deeper insights into how pathways are selected for the insertion of proteins into the Escherichia coli inner membrane.     

Requirements for the membrane insertion of signal-anchor type proteins

Proteins which are inserted and anchored in the membrane of the ER by an uncleaved signal-anchor sequence can assume two final orientations. Type I signal-anchor proteins translocate the NH2 terminus across the membrane while type II signal-anchor proteins translocate the COOH terminus. We investigated the requirements for cytosolic protein components and nucleotides for the membrane targeting and insertion of single-spanning type I signal-anchor proteins. Besides the ribosome, signal recognition particle (SRP), GTP, and rough microsomes (RMs) no other components were found to be required. The GTP analogue GMPPNP could substitute for GTP in supporting the membrane insertion of IMC-CAT. By using a photocrosslinking assay we show that for secreted, type I and type II signal-anchor proteins the presence of both GTP and RMs is required for the release of the nascent chain from the 54-kD subunit of SRP. For two of the proteins studied the release of the nascent chain from SRP54 was accompanied by a new interaction with components of the ER. We conclude that the GTP-dependent release of the nascent chain from SRP54 occurs in an identical manner for each of the proteins studied.     

Role of the cytoplasmic segments of Sec61alpha in the ribosome-binding and translocation-promoting activities of the Sec61 complex

The Sec61 complex performs a dual function in protein translocation across the RER, serving as both the high affinity ribosome receptor and the translocation channel. To define regions of the Sec61 complex that are involved in ribosome binding and translocation promotion, ribosome-stripped microsomes were subjected to limited digestions using proteases with different cleavage specificities. Protein immunoblot analysis using antibodies specific for the NH(2) and COOH terminus of Sec61alpha was used to map the location of proteolysis cleavage sites. We observed a striking correlation between the loss of binding activity for nontranslating ribosomes and the digestion of the COOH- terminal tail or cytoplasmic loop 8 of Sec61alpha. The proteolyzed microsomes were assayed for SRP-independent translocation activity to determine whether high affinity binding of the ribosome to the Sec61 complex is a prerequisite for nascent chain transport. Microsomes that do not bind nontranslating ribosomes at physiological ionic strength remain active in SRP-independent translocation, indicating that the ribosome binding and translocation promotion activities of the Sec61 complex do not strictly correlate. Translocation-promoting activity was most severely inhibited by cleavage of cytosolic loop 6, indicating that this segment is a critical determinant for this function of the Sec61 complex.     

Elucidating the Native Architecture of the YidC: Ribosome Complex

Membrane protein biogenesis in bacteria occurs via dedicated molecular systems SecYEG and YidC that function independently and in cooperation. YidC belongs to the universally conserved Oxa1/Alb3/YidC family of membrane insertases and is believed to associate with translating ribosomes at the membrane surface. Here, we have examined the architecture of the YidC:ribosome complex formed upon YidC-mediated membrane protein insertion. Fluorescence correlation spectroscopy was employed to investigate the complex assembly under physiological conditions. A slightly acidic environment stimulates binding of detergent-solubilized YidC to ribosomes due to electrostatic interactions, while YidC acquires specificity for translating ribosomes at pH-neutral conditions. The nanodisc reconstitution of the YidC to embed it into a native phospholipid membrane environment strongly enhances the YidC:ribosome complex formation. A single copy of YidC suffices for the binding of translating ribosome both in detergent and at the lipid membrane interface, thus being the minimal functional unit. Data reveal molecular details on the insertase functioning and interactions and suggest a new structural model for the YidC:ribosome complex.     

Membrane topogenesis of a type I signal-anchor protein, mouse synaptotagmin II, on the endoplasmic reticulum

Synaptotagmin II is a type I signal-anchor protein, in which the NH(2)-terminal domain of 60 residues (N-domain) is located within the lumenal space of the membrane and the following hydrophobic region (H-region) shows transmembrane topology. We explored the early steps of cotranslational integration of this molecule on the endoplasmic reticulum membrane and demonstrated the following: (a) The translocation of the N-domain occurs immediately after the H-region and the successive positively charged residues emerge from the ribosome. (b) Positively charged residues that follow the H-region are essential for maintaining the correct topology. (c) It is possible to dissect the lengths of the nascent polypeptide chains which are required for ER targeting of the ribosome and for translocation of the N-domain, thereby demonstrating that different nascent polypeptide chain lengths are required for membrane targeting and N-domain translocation. (d) The H-region is sufficiently long for membrane integration. (e) Proline residues preceding H-region are critical for N-domain translocation, but not for ER targeting. The proline can be replaced with amino acid with low helical propensity.