Impact of the metabolic activity of Streptococcus thermophilus on the colon epithelium of gnotobiotic rats

The thermophilic lactic acid bacterium Streptococcus thermophilus is widely and traditionally used in the dairy industry. Despite the vast level of consumption of S. thermophilus through yogurt or probiotic functional food, very few data are available about its physiology in the gastrointestinal tract (GIT). The objective of the present work was to explore both the metabolic activity and host response of S. thermophilus in vivo. Our study profiles the protein expression of S. thermophilus after its adaptation to the GIT of gnotobiotic rats and describes the impact of S. thermophilus colonization on the colonic epithelium. S. thermophilus colonized progressively the GIT of germ-free rats to reach a stable population in 30 days (10(8) cfu/g of feces). This progressive colonization suggested that S. thermophilus undergoes an adaptation process within GIT. Indeed, we showed that the main response of S. thermophilus in the rat's GIT was the massive induction of the glycolysis pathway, leading to formation of lactate in the cecum. At the level of the colonic epithelium, the abundance of monocarboxylic acid transporter mRNAs (SLC16A1 and SLC5A8) and a protein involved in the cell cycle arrest (p27(kip1)) increased in the presence of S. thermophilus compared with germ-free rats. Based on different mono-associated rats harboring two different strains of S. thermophilus (LMD-9 or LMG18311) or weak lactate-producing commensal bacteria (Bacteroides thetaiotaomicron and Ruminococcus gnavus), we propose that lactate could be a signal produced by S. thermophilus and modulating the colon epithelium.     

The SecDFyajC domain of preprotein translocase controls preprotein movement by regulating SecA membrane cycling.

Escherichia coli preprotein translocase comprises a membrane-embedded hexameric complex of SecY, SecE, SecG, SecD, SecF and YajC (SecYEGDFyajC) and the peripheral ATPase SecA. The energy of ATP binding and hydrolysis promotes cycles of membrane insertion and deinsertion of SecA and catalyzes the movement of the preprotein across the membrane. The proton motive force (PMF), though not essential, greatly accelerates late stages of translocation. We now report that the SecDFyajC domain of translocase slows the movement of preprotein in transit against both reverse and forward translocation and exerts this control through stabilization of the inserted form of SecA. This mechanism allows the accumulation of specific translocation intermediates which can then complete translocation under the driving force of the PMF. These findings establish a functional relationship between SecA membrane insertion and preprotein translocation and show that SecDFyajC controls SecA membrane cycling to regulate the movement of the translocating preprotein.     

Identification of the preprotein binding domain of SecA

SecA, the preprotein translocase ATPase, has a helicase DEAD motor. To catalyze protein translocation, SecA possesses two additional flexible domains absent from other helicases. Here we demonstrate that one of these "specificity domains" is a preprotein binding domain (PBD). PBD is essential for viability and protein translocation. PBD mutations do not abrogate the basal enzymatic properties of SecA (nucleotide binding and hydrolysis), nor do they prevent SecA binding to the SecYEG protein conducting channel. However, SecA PBD mutants fail to load preproteins onto SecYEG, and their translocation ATPase activity does not become stimulated by preproteins. Bulb and Stem, the two sterically proximal PBD substructures, are physically separable and have distinct roles. Stem binds signal peptides, whereas the Bulb binds mature preprotein regions as short as 25 amino acids. Binding of signal or mature region peptides or full-length preproteins causes distinct conformational changes to PBD and to the DEAD motor. We propose that (a) PBD is a preprotein receptor and a physical bridge connecting bound preproteins to the DEAD motor, and (b) preproteins control the ATPase cycle via PBD.     

A dual role for mitochondrial heat shock protein 70 in membrane translocation of preproteins

The role of mitochondrial 70-kD heat shock protein (mt-hsp70) in protein translocation across both the outer and inner mitochondrial membranes was studied using two temperature-sensitive yeast mutants. The degree of polypeptide translocation into the matrix of mutant mitochondria was analyzed using a matrix-targeted preprotein that was cleaved twice by the processing peptidase. A short amino-terminal segment of the preprotein (40-60 amino acids) was driven into the matrix by the membrane potential, independent of hsp70 function, allowing a single cleavage of the presequence. Artificial unfolding of the preprotein allowed complete translocation into the matrix in the case where mutant mt-hsp70 had detectable binding activity. However, in the mutant mitochondria in which binding to mt-hsp70 could not be detected the mature part of the preprotein was only translocated to the intermembrane space. We propose that mt-hsp70 fulfills a dual role in membrane translocation of preproteins. (a) Mt-hsp70 facilitates unfolding of the polypeptide chain for translocation across the mitochondrial membranes. (b) Binding of mt-hsp70 to the polypeptide chain is essential for driving the completion of transport of a matrix- targeted preprotein across the inner membrane. This second role is independent of the folding state of the preprotein, thus identifying mt- hsp70 as a genuine component of the inner membrane translocation machinery. Furthermore we determined the sites of the mutations and show that both a functional ATPase domain and ATP are needed for mt- hsp70 to bind to the polypeptide chain and drive its translocation into the matrix.     

Membrane-embedded C-terminal segment of rat mitochondrial TOM40 constitutes protein-conducting pore with enriched beta-structure

TOM40 is the central component of the preprotein translocase of the mitochondrial outer membrane (TOM complex). We purified recombinant rat TOM40 (rTOM40), which was refolded in Brij35 after solubilization from inclusion bodies by guanidine HCl. rTOM40 (i) consisted of a 63% beta-sheet structure and (ii) bound a matrix-targeted preprotein with high affinity and partially translocated it into the rTOM40 pore. This partial translocation was inhibited by stabilization of the mature domain of the precursor. (iii) rTOM40 bound preprotein initially through ionic interactions, followed by salt-resistant non-ionic interactions, and (iv) exhibited presequence-sensitive, cation-specific channel activity in reconstituted liposomes. Based on the domain structure of rTOM40 deduced by protease treatment, we purified the elastase-resistant and membrane-embedded C-terminal segment (rTOM40(DeltaN165)) as a recombinant protein with 62% beta-structure that exhibited properties comparable with those of full-size rTOM40. We concluded that the membrane-embedded C-terminal half of rTOM40 constitutes the preprotein recognition domain with an enriched beta-structure, which forms the preprotein conducting pore containing a salt-sensitive cis-binding site and a salt-resistant trans-binding site.     

Protein import channel of the outer mitochondrial membrane: a highly stable Tom40-Tom22 core structure differentially interacts with preproteins, small tom proteins, and import receptors

The preprotein translocase of the yeast mitochondrial outer membrane (TOM) consists of the initial import receptors Tom70 and Tom20 and a approximately 400-kDa (400 K) general import pore (GIP) complex that includes the central receptor Tom22, the channel Tom40, and the three small Tom proteins Tom7, Tom6, and Tom5. We report that the GIP complex is a highly stable complex with an unusual resistance to urea and alkaline pH. Under mild conditions for mitochondrial lysis, the receptor Tom20, but not Tom70, is quantitatively associated with the GIP complex, forming a 500K to 600K TOM complex. A preprotein, stably arrested in the GIP complex, is released by urea but not high salt, indicating that ionic interactions are not essential for keeping the preprotein in the GIP complex. Under more stringent detergent conditions, however, Tom20 and all three small Tom proteins are released, while the preprotein remains in the GIP complex. Moreover, purified outer membrane vesicles devoid of translocase components of the intermembrane space and inner membrane efficiently accumulate the preprotein in the GIP complex. Together, Tom40 and Tom22 thus represent the functional core unit that stably holds accumulated preproteins. The GIP complex isolated from outer membranes exhibits characteristic TOM channel activity with two coupled conductance states, each corresponding to the activity of purified Tom40, suggesting that the complex contains two simultaneously active and coupled channel pores.     

A single copy of SecYEG is sufficient for preprotein translocation

The heterotrimeric SecYEG complex comprises a protein‐conducting channel in the bacterial cytoplasmic membrane. SecYEG functions together with the motor protein SecA in preprotein translocation. Here, we have addressed the functional oligomeric state of SecYEG when actively engaged in preprotein translocation. We reconstituted functional SecYEG complexes labelled with fluorescent markers into giant unilamellar vesicles at a natively low density. Förster's resonance energy transfer and fluorescence (cross‐) correlation spectroscopy with single‐molecule sensitivity allowed for independent observations of the SecYEG and preprotein dynamics, as well as complex formation. In the presence of ATP and SecA up to 80% of the SecYEG complexes were loaded with a preprotein translocation intermediate. Neither the interaction with SecA nor preprotein translocation resulted in the formation of SecYEG oligomers, whereas such oligomers can be detected when enforced by crosslinking. These data imply that the SecYEG monomer is sufficient to form a functional translocon in the lipid membrane.     

Distinct catalytic roles of the SecYE, SecG and SecDFyajC subunits of preprotein translocase holoenzyme.

Escherichia coli preprotein translocase contains a membrane-embedded trimeric complex of SecY, SecE and SecG (SecYEG) and the peripheral SecA protein. SecYE is the conserved functional 'core' of the SecYEG complex. Although sufficient to provide sites for high-affinity binding and membrane insertion of SecA, and for its activation as a preprotein-dependent ATPase, SecYE has only very low capacity to support translocation. The proteins encoded by the secD operon--SecD, SecF and YajC--also form an integral membrane heterotrimeric complex (SecDFyajC). Physical and functional studies show that these two trimeric complexes are associated to form SecYEGDFyajC, the hexameric integral membrane domain of the preprotein translocase 'holoenzyme'. Either SecG or SecDFyajC can support the translocation activity of SecYE by facilitating the ATP-driven cycle of SecA membrane insertion and de-insertion at different stages of the translocation reaction. Our findings show that each of the prokaryote-specific subunits (SecA, SecG and SecDFyajC) function together to promote preprotein movement at the SecYE core of the translocase.     

Tyr-326 plays a critical role in controlling SecA-preprotein interaction

SecA is an essential ATP-dependent motor protein that interacts with the preprotein and translocon to drive protein translocation across the eubacterial plasma membrane. A region containing residues 267-340 has been proposed to comprise the preprotein binding site of Escherichia coli SecA. To elucidate the function of this region further, we isolated mutants using a combination of region-specific polymerase chain reaction (PCR) mutagenesis and a genetic and biochemical screening procedure. Although this region displayed considerable plasticity based on phylogenetic and genetic analysis, Tyr-326 was found to be critical for SecA function. secA mutants with non-conservative substitutions at Tyr-326 showed strong protein secretion defects in vivo and were completely defective for SecA-dependent translocation ATPase activity in vitro. The SecA-Y326 mutant proteins were normal in their membrane, SecYE and nucleotide-binding properties. However, they exhibited a reduced affinity for preprotein and were defective in preprotein release, as assessed by several biochemical assays. Our results indicate that the region containing Tyr-326 functions as a conformational response element to regulate the preprotein binding and release cycle of SecA.     

Mitochondrial GrpE is present in a complex with hsp70 and preproteins in transit across membranes.

We characterized a 24-kDa protein associated with matrix hsp70 (mt-hsp70) of Neurospora crassa and Saccharomyces cerevisiae mitochondria. By using specific antibodies, the protein was identified as MGE, a mitochondrial homolog of the prokaryotic heat shock protein GrpE. MGE extracted from mitochondria was quantitatively bound to hsp70. It was efficiently released from hsp70 by the addition of Mg-ATP but not by nonhydrolyzable ATP analogs or high salt. A mutant mt-hsp70, which was impaired in release of bound precursor proteins, released MGE in an ATP-dependent manner, indicating that precursor proteins and MGE bind to different sites of hsp70. A preprotein accumulated in transit across the mitochondrial membranes was specifically coprecipitated by either antibodies directed against MGE or antibodies directed against mt-hsp70. The preprotein accumulated at the outer membrane was not coprecipitated by either antibody preparation. After being imported into the matrix, the preprotein could be coprecipitated only by antibodies against mt-hsp70. We propose that mt-hsp70 and MGE cooperate in membrane translocation of preproteins.     

Hsp90 functions in the targeting and outer membrane translocation steps of Tom70-mediated mitochondrial import

The Tom70 import receptor on the mitochondrial outer membrane specifically recognizes Hsp90 and Hsc70, a critical step for the import of mitochondrial preproteins, the targeting of which depends on these cytosolic chaperones. To analyze the role of Hsp90 in mitochondrial import, the effects of the Hsp90 inhibitors geldanamycin and novobiocin were compared. Geldanamycin occludes the N-terminal ATP-binding site of Hsp90, whereas novobiocin targets the C-terminal region of the chaperone. Here, novobiocin was found to inhibit preprotein import and, in particular, targeting to the purified cytosolic fragment of Tom70. Hsp90 cross-linking to preprotein and coprecipitation of Hsp90 with Tom70 were both impaired by novobiocin. Overall, novobiocin treatment increased preprotein aggregation, contributing to reduced import competence. In contrast, geldanamycin had no apparent effect on preprotein interactions with Hsp90, formation of preprotein-chaperone complexes, Hsp90 docking onto Tom70, or preprotein association with the outer membrane. Instead, geldanamycin impaired formation of preprotein import intermediates at the outer membrane. This suggests a novel active role for Hsp90 in import steps subsequent to Tom70 targeting. Our results outline the mechanisms of Hsp90 function in preprotein targeting and transport.     

SecA supports a constant rate of preprotein translocation

In Escherichia coli, secretory proteins (preproteins) are translocated across the cytoplasmic membrane by the Sec system composed of a protein-conducting channel, SecYEG, and an ATP-dependent motor protein, SecA. After binding of the preprotein to SecYEG-bound SecA, cycles of ATP binding and hydrolysis by SecA are thought to drive the stepwise translocation of the preprotein across the membrane. To address how the length of a preprotein substrate affects the SecA-driven translocation process, we constructed derivatives of the precursor of the outer membrane protein A (proOmpA) with 2, 4, 6, and 8 in-tandem repeats of the periplasmic domain. With increasing polypeptide length, an increasing delay in the time before full-length translocation was observed, but the translocation rate expressed as amino acid translocation per minute remained constant. These data indicate that in the ATP-dependent reaction, SecA drives a constant rate of preprotein translocation consistent with a stepping mechanism of translocation.     

Studies on polypeptide-chain-elongation factors from an extreme thermophile, Thermus thermophilus HB8. 2. Catalytic properties.

Catalytic properties of the elongation factors from Thermus thermophilus HB8 have been studied and compared with those of the factors from Escherichia coli. 1. The formation of a ternary guanine-nucleotide . EF-Tu . EF-Ts complex was demonstrated by gel filtration of the T. thermophilus EF-Tu . EF-Ts complex on a Sephadex G-150 column equilibrated with guanine nucleotide. The occurrence of this type of complex has not yet been proved with the factors from E. coli. 2. The dissociation constants for the complexes of T. thermophilus EF-Tu . EF-Ts with GDP and GTP were 6.1 x 10(-7) M and 1.9 x 10(-6) M respectively. On the other hand, T. thermophilus EF-Tu interacted with GDP and GTP with dissociation constants of 1.1 x 10(-9) M and 5.8 x 10(-8) M respectively. This suggests that the association of EF-Ts with EF-Tu lowered the affinity of EF-Tu for GDP by a factor of about 600 and facilitated the nucleotide exchange reaction. 3. Although the T. thermophilus EF-Tu . EF-Ts complex hardly dissociates into EF-Tu and EF-Ts, a rapid exchange was observed between free EF-Ts and the EF-Tu . EF-Ts complex using 3H-labelled EF-Ts. The exchange reaction was independent on the presence or absence of guanine nucleotides. 4. Based on the above findings, an improved reaction mechanism for the regeneration of EF-Tu . GTP from EF-Tu . GDP is proposed. 5. Studies on the functional interchangeability of EF-Tu and EF-Ts between T. thermophilus and E. coli has revealed that the factors function much more efficiently in the homologous than in the heterologous combination. 6. T. thermophilus EF-Ts could bind E. coli EF-Tu to form an EF-Tu (E. coli) . EF-Ts (T. thermophilus hybrid complex. The complex was found to exist in a dimeric form indicating that the property to form a dimer is attributable to T. thermophilus EF-Ts. On the other hand, no stable complex between E. coli EF-Ts and T. thermophilus EF-Tu has been isolated. 7. The uncoupled GTPase activity of T. thermophilus EF-G was much lower than that of E. coli EF-G. T. thermophilus EF-G formed a relatively stable binary EF-G . GDP complex, which could be isolated on a nitrocellulose membrane filter. The Kd values for EF-G . GDP and EF-G . GTP were 6.7 x 10(-7) M and 1.2 x 10(-5) M respectively. The ternary T. thermophilus EF-G . GDP . ribosome complex was again very stable and could be isolated in the absence of fusidic acid. The stability of the latter complex is probably the cause of the low uncoupled GTPase activity of T. thermophilus EF-G.     

Modifications at the A-domain of the chloroplast import receptor Toc159

Two families of GTPases, the Toc34 and Toc159 GTPase families, take on the task of preprotein recognition at the translocon at the outer membrane of chloroplasts (TOC translocon). The major Toc159 family members have highly acidic N-terminal domains (A-domains) that are non-essential and so far have escaped functional characterization. But recently, interest in the role of the A-domain has strongly increased. The new data of three independent studies provide evidence that the Toc159 A-domain (I) participates in preprotein selectivity, (II) has typical features of intrinsically unfolded proteins and (III) is highly phosphorylated and possibly released from the rest of the protein by a proteolytic event. This hints at a complex regulation of A-domain function that is important for the maintenance of the preprotein selectivity at the TOC translocons.Key words: chloroplast, import, Toc159, acidic domain, kinase, protease     

Electron microscopic visualization of asymmetric precursor translocation intermediates: SecA functions as a dimer

SecA, the ATPase of Sec translocase, mediates the post-translational translocation of preprotein through the protein-conducting channel SecYEG in the bacterial inner membrane. Here we report the structures of Escherichia coli Sec intermediates during preprotein translocation as visualized by electron microscopy to probe the oligomeric states of SecA during this process. We found that the translocase holoenzyme is symmetrically assembled by SecA and SecYEG on proteoliposomes, whereas the translocation intermediate 31 (I₃₁) becomes asymmetric because of the presence of preprotein. Moreover, SecA is a dimer in these two translocation complexes. This work also shows surface topological changes in the components of translocation intermediates by immunogold labeling. The channel entry for preprotein translocation was found at the center of the I₃₁ structures. Our results indicate that the presence of preprotein introduces asymmetry into translocation intermediates, while SecA remains dimeric during the translocation process.     

Membrane potential-driven protein import into mitochondria. The sorting sequence of cytochrome b(2) modulates the deltapsi-dependence of translocation of the matrix-targeting sequence

The transport of preproteins into or across the mitochondrial inner membrane requires the membrane potential Deltapsi across this membrane. Two roles of Deltapsi in the import of cleavable preproteins have been described: an electrophoretic effect on the positively charged matrix-targeting sequences and the activation of the translocase subunit Tim23. We report the unexpected finding that deletion of a segment within the sorting sequence of cytochrome b(2), which is located behind the matrix-targeting sequence, strongly influenced the Deltapsi-dependence of import. The differential Deltapsi-dependence was independent of the submitochondrial destination of the preprotein and was not attributable to the requirement for mitochondrial Hsp70 or Tim23. With a series of preprotein constructs, the net charge of the sorting sequence was altered, but the Deltapsi-dependence of import was not affected. These results suggested that the sorting sequence contributed to the import driving mechanism in a manner distinct from the two known roles of Deltapsi. Indeed, a charge-neutral amino acid exchange in the hydrophobic segment of the sorting sequence generated a preprotein with an even better import, i.e. one with lower Deltapsi-dependence than the wild-type preprotein. The sorting sequence functioned early in the import pathway since it strongly influenced the efficiency of translocation of the matrix-targeting sequence across the inner membrane. These results suggest a model whereby an electrophoretic effect of Deltapsi on the matrix-targeting sequence is complemented by an import-stimulating activity of the sorting sequence.     

The preprotein conducting channel at the inner envelope membrane of plastids

The preprotein translocation at the inner envelope membrane of chloroplasts so far involves five proteins: Tic110, Tic55, Tic40, Tic22 and Tic20. The molecular function of these proteins has not yet been established. Here, we demonstrate that Tic110 constitutes a central part of the preprotein translocation pore. Dependent on the presence of intact Tic110, radiolabelled preprotein specifically interacts with isolated inner envelope vesicles as well as with purified, recombinant Tic110 reconstituted into liposomes. Circular dichroism analysis reveals that Tic110 consists mainly of beta-sheets, a structure typically found in pore proteins. In planar lipid bilayers, recombinant Tic110 forms a cation-selective high-conductance channel with a calculated inner pore opening of 1.7 nm. Purified transit peptide causes strong flickering and a voltage-dependent block of the channel. Moreover, at the inner envelope membrane, a peptide-sensitive channel is described that shows properties basically identical to the channel formed by recombinant Tic110. We conclude that Tic110 has a distinct preprotein binding site and functions as a preprotein translocation pore at the inner envelope membrane.     

SecY and SecA interact to allow SecA insertion and protein translocation across the Escherichia coli plasma membrane.

SecA, the preprotein-driving ATPase in Escherichia coli, was shown previously to insert deeply into the plasma membrane in the presence of ATP and a preprotein; this movement of SecA was proposed to be mechanistically coupled with preprotein translocation. We now address the role played by SecY, the central subunit of the membrane-embedded heterotrimeric complex, in the SecA insertion reaction. We identified a secY mutation (secY205), affecting the most carboxyterminal cytoplasmic domain, that did not allow ATP and preprotein-dependent productive SecA insertion, while allowing idling insertion without the preprotein. Thus, the secY205 mutation might affect the SecYEG 'channel' structure in accepting the preprotein-SecA complex or its opening by the complex. We isolated secA mutations that allele-specifically suppressed the secY205 translocation defect in vivo. One mutant protein, SecA36, with an amino acid alteration near the high-affinity ATP-binding site, was purified and suppressed the in vitro translocation defect of the inverted membrane vesicles carrying the SecY205 protein. The SecA36 protein could also insert into the mutant membrane vesicles in vitro. These results provide genetic evidence that SecA and SecY specifically interact, and show that SecY plays an essential role in insertion of SecA in response to a preprotein and ATP and suggest that SecA drives protein translocation by inserting into the membrane in vivo.     

Cloning, sequencing, and expression of ruvB and characterization of RuvB proteins from two distantly related thermophilic eubacteria.

The ruvB genes of the highly divergent thermophilic eubacteria Thermus thermophilus and Thermotoga maritima were cloned, sequenced, and expressed in Escherichia coli. Both thermostable RuvB proteins were purified to homogeneity. Like E. coli RuvB protein, both purified thermostable RuvB proteins showed strong double-stranded DNA-dependent ATPase activity at their temperature optima (> or = 70 degrees C). In the absence of ATP, T. thermophilus RuvB protein bound to linear double-stranded DNA with a preference for the ends. Addition of ATP or gamma-S-ATP destabilized the T. thermophilus RuvB-DNA complexes. Both thermostable RuvB proteins displayed helicase activity on supercoiled DNA. Expression of thermostable T. thermophilus RuvB protein in the E. coli ruvB recG mutant strain N3395 partially complemented the UV-sensitive phenotype, suggesting that T. thermophilus RuvB protein has a function similar to that of E. coli RuvB in vivo.     

Characterization of rat TOM40, a central component of the preprotein translocase of the mitochondrial outer membrane

We cloned a 38-kDa rat mitochondrial outer membrane protein (OM38) with structural homology to the central component of preprotein translocase of the fungal mitochondrial outer membrane, Tom40. Although it has no predictable alpha-helical transmembrane segments, OM38 is resistant to alkaline carbonate extraction and is inaccessible to proteases and polyclonal antibodies added from outside the mitochondria, suggesting that it is embedded in the membrane, probably in a beta-barrel structure, as has been similarly speculated for fungal Tom40. Immunoprecipitation demonstrated that OM38 is associated with the major import receptors rTOM20 and rTOM22, and several other unidentified components with molecular masses of 5-10 kDa in digitonin-solubilized membrane: OM10, OM7.5, and OM5. Blue native polyacrylamide gel electrophoresis revealed that OM38 is a component of a approximately 400-kDa complex, firmly associating with rTOM22 and loosely associating with rTOM20. The preprotein in transit to the matrix interacted with the TOM complex containing OM38, and immunodepletion of OM38 resulted in the loss of preprotein import activity of the detergent-solubilized and reconstituted outer membrane vesicles. Taken together, these results indicate that OM38 is a structural and functional homolog of fungal Tom40 and functions as a component of the preprotein import machinery of the rat mitochondrial outer membrane.