Role of the mature protein sequence of maltose-binding protein in its secretion across the E. coli cytoplasmic membrane

Secretion of amber fragments of an E. coli periplasmic protein, the maltose-binding protein, was studied to determine if the mature portion of the protein is required for its export across the cytoplasmic membrane. A fragment lacking 25–35 amino acid residues at the C terminus is secreted at normal levels, suggesting that this sequence is not required for secretion. This is in contrast to the results obtained with the periplasmic protein β-lactamase. In studying another fragment of one-third the molecular weight of the intact protein, we found that the majority of the fragment is not recovered from the periplasmic fraction. However, a small amount of secretion of this polypeptide was observed. This fragment is synthesized as a larger molecular weight form when cells are induced for the synthesis of a maltose-binding protein-β-galactosidase hybrid protein, which was previously shown to block the proper localization and processing of envelope proteins. This result is consistent with the idea that the larger form is a precursor with an unprocessed signal sequence, whereas in the absence of the hybrid protein the fragment is a processed mature form. Thus secretion of the smaller fragment may be occurring up to the point where the signal sequence is removed. That this fragment has passed through the cytoplasmic membrane is further supported by its accessibility to externally added trypsin. We suggest that the fragment may be secreted to the periplasm, but cannot assume a water-soluble conformation; the majority of the polypeptide may be associated with the external surface of the cytoplasmic membrane. Thus the mature sequence of maltose-binding protein, at least its C-terminal two thirds, may not be required for its export across the cytoplasmic membrane.     

Sequences determining the cytoplasmic localization of a chemoreceptor domain.

The Escherichia coli serine chemoreceptor (Tsr) is a protein with a simple topology consisting of two membrane-spanning sequences (TM1 and TM2) separating a large periplasmic domain from N-terminal and C-terminal cytoplasmic regions. We analyzed the contributions of several sequence elements to the cytoplasmic localization of the C-terminal domain by using chemoreceptor-alkaline phosphatase gene fusions. The principal findings were as follows. (i) The cytoplasmic localization of the C-terminal domain depended on TM2 but was quite tolerant of mutations partially deleting or introducing charged residues into the sequence. (ii) The basal level of C-terminal domain export was significantly higher in proteins with the wild-type periplasmic domain than in derivatives with a shortened periplasmic domain, suggesting that the large size of the wild-type domain promotes partial membrane misinsertion. (iii) The membrane insertion of deletion derivatives with a single spanning segment (TM1 or TM2) could be controlled by either an adjacent positively charged sequence or an adjacent amphipathic sequence. The results provide evidence that the generation of the Tsr membrane topology is an overdetermined process directed by an interplay of sequences promoting and opposing establishment of the normal structure.     

Hemoglobin binds to the amino-terminal 23-residue fragment of human erythrocyte band 3 protein

Hemoglobin, aldolase and glyceraldehyde 3-phosphate dehydrogenase are known to bind to the cytoplasmic domain of band 3 protein. Binding of glycolytic enzymes to band 3 protein is inhibited by its amino-terminal fragments. To precisely localize the sequence portion of band 3 protein to which hemoglobin binds and to see whether the same region of amino-acid sequence binds both hemoglobin and glycolytic enzymes, a simple, direct solid-phase binding assay was developed. Peptides generated from the 23-kDa fragment by trypsin, cyanogen bromide and mild acid hydrolysis were used as inhibitors to determine the minimal sequence structure involved in the binding of the 23-kDa fragment to hemoglobin. The shortest peptide which inhibits the binding of the 23-kDa fragment is an acid cleavage peptide containing the sequence positions 1 to 23. This sequence is unusual as 14 of its residues are negatively charged, it contains no basic residues and has its amino terminus blocked. Using aldolase, glyceraldehyde-3-phosphate dehydrogenase and hemoglobin as competitive inhibitors in the binding of 23-kDa fragment, the affinity of hemoglobin to this fragment appears several-fold weaker than that of both the enzymes. These findings demonstrate that glycolytic enzymes and hemoglobin bind competitively to the same polyanionic sequence region of band 3 protein.     

Polarity and Charge of the Periplasmic Loop Determine the YidC and Sec Translocase Requirement for the M13 Procoat Lep Protein

During membrane biogenesis, the M13 procoat protein is inserted into the lipid bilayer in a strictly YidC-dependent manner with both the hydrophobic signal sequence and the membrane anchor sequence promoting translocation of the periplasmic loop via a hairpin mechanism. Here, we find that the translocase requirements can be altered for PClep in a predictable manner by changing the polarity and charge of the peptide region that is translocated across the membrane. When the polarity of the translocated peptide region is lowered and the charged residues in this region are removed, translocation of this loop region occurs largely by a YidC- and Sec-independent mechanism. When the polarity is increased to that of the wild-type procoat protein, the YidC insertase is essential for translocation. Further increasing the polarity, by adding charged residues, switches the insertion pathway to a YidC/Sec mechanism. Conversely, we find that increasing the hydrophobicity of the transmembrane segments of PClep can decrease the translocase requirement for translocation of the peptide chain. This study provides a framework to understand why the YidC and Sec machineries exist in parallel and demonstrates that the YidC insertase has a limited capacity to translocate a peptide chain on its own.     

Amino-Terminal Charge Affects the Periplasmic Accumulation of Recombinant Heregulin/EGF Hybrids Exported Using theEscherichia coliAlkaline Phosphatase Signal Sequence

AnEscherichia coliexpression system that exploits the bacterial alkaline phosphatase (PhoA) signal sequence to translocate recombinant human epidermal growth factor (hEGF) to the periplasm was used to evaluate how changes in the composition and sequence of amino acids near the PhoA–hEGF junction influence the periplasmic accumulation of recombinant protein. A series of chimeric structural genes was generated byin vitroreplacement of hEGF sequence with analogous segments from the EGF-like domain of human heregulin (HRG), significantly altering the electrostatic character of the amino-terminal region of the mature protein. Quantitation of HRG/EGF protein inE. coliperiplasmic extracts, by RP-HPLC, showed a fourfold decrease after one of two acidic residues located in the amino-terminal region of the mature hEGF, near the PhoA junction, was replaced. An additional threefold decrease was observed when the second acidic residue was replaced with a positively charged lysine. Further extension of the amino-terminal HRG sequence, beyond the first six residues, resulted in net neutralization of a more distant EGF acidic residue with no additional effect on protein yield. The importance of having a negatively charged group in the amino-terminal region of the mature protein was confirmed when insertion of an aspartic acid near the amino-terminus of two poorly expressed hybrid protein sequences resulted in a five- to eightfold increase in their recovery from the periplasm. This study demonstrates the importance of having negatively charged residues near the fusion junction of recombinant proteins expressed inE. coliusing the PhoA signal sequence for protein export.     

The DsbA signal sequence directs efficient, cotranslational export of passenger proteins to the Escherichia coli periplasm via the signal recognition particle pathway

The Escherichia coli cytoplasmic protein thioredoxin 1 can be efficiently exported to the periplasmic space by the signal sequence of the DsbA protein (DsbAss) but not by the signal sequence of alkaline phosphatase (PhoA) or maltose binding protein (MBP). Using mutations of the signal recognition particle (SRP) pathway, we found that DsbAss directs thioredoxin 1 to the SRP export pathway. When DsbAss is fused to MBP, MBP also is directed to the SRP pathway. We show directly that the DsbAss-promoted export of MBP is largely cotranslational, in contrast to the mode of MBP export when the native signal sequence is utilized. However, both the export of thioredoxin 1 by DsbAss and the export of DsbA itself are quite sensitive to even the slight inhibition of SecA. These results suggest that SecA may be essential for both the slow posttranslational pathway and the SRP-dependent cotranslational pathway. Finally, probably because of its rapid folding in the cytoplasm, thioredoxin provides, along with gene fusion approaches, a sensitive assay system for signal sequences that utilize the SRP pathway.     

Hepatitis B surface antigen: an unusual secreted protein initially synthesized as a transmembrane polypeptide.

Hepatitis B surface antigen (HBsAg), the major coat protein of hepatitis B virus, is also secreted from cells as a subviral particle, without concomitant cleavage of N-terminal amino acid sequences. We examined this unusual export process in a cell-free system and showed that the initial product of HBsAg biosynthesis is an integral transmembrane protein, with most or all of its C-terminal half on the lumenal side of the endoplasmic reticulum membrane. To study the nature of its topogenic signals, we synthesized fusion proteins between HBsAg and the nonsecreted protein alpha-globin. Fusion proteins in which approximately 100 amino acids of globin preceded all HBsAg sequences were successfully translocated in vitro; the same domain as in the wild-type HBsAg was transported into the vesicle lumen. Fusions in which the entire globin domain was C terminal were able to translocate both the C-terminal region of HBsAg and its attached globin domain. Thus, uncleaved signal sequences in p24s function to direct portions of the molecule across the membrane and are able to perform this function even when positioned in an internal protein domain.     

Membrane protein spanning segments as export signals.

Escherichia coli lac permease is a polytopic integral membrane protein with six translocated (periplasmic) domains. Individual N-terminal cytoplasmic regions and membrane-spanning segments adjacent to each of the periplasmic domains acted as export signals for an attached sensor protein (alkaline phosphatase). However, the export activity of one of the spanning segments was considerably lower than that of the others, and was limited by the presence of a positively charged residue (Arg302). These observations are compatible with models of membrane protein insertion in which hydrophilic domains are translocated independently. However, the results suggest that efficient translocation may sometimes require interaction between individual spanning segments.     

DNA sequence analysis of pglA and mechanism of export of its polygalacturonase product from Pseudomonas solanacearum.

The pglA gene encodes a 52-kilodalton extracellular polygalacturonase (PGA) which is associated with the phytopathogenic virulence of Pseudomonas solanacearum. The nucleotide sequence of pglA and the putative amino acid sequence of the PGA protein were determined. A computer search identified a 150-residue region of PGA which was similar (41%) to the amino acid sequence of a region of the PG-2A polygalacturonase from tomato. Comparison of the amino terminus of the pglA open reading frame with the actual amino-terminal sequence of purified extracellular PGA suggested that pglA is initially translated as a higher-molecular-mass precursor with a 21-residue amino-terminal signal sequence. Localization of various pglA-phoA fusion proteins in Escherichia coli and P. solanacearum indicated that the 21-residue leader sequence directs the export of PhoA only as far as the periplasm of both bacteria. Deletion of the last 13 residues of PGA eliminated its catalytic activity, as well as its ability to be exported outside of the P. solanacearum cell. Our results suggest that PGA excretion occurs in two steps. The first step involves a signal sequence cleavage mechanism similar to that used for periplasmic proteins and results in export of PGA across the inner membrane; the second step (transit of the outer membrane) occurs by an unknown mechanism requiring sequences from the mature PGA protein and biochemical factors absent from E. coli.     

Direct evidence that the proton motive force inhibits membrane translocation of positively charged residues within membrane proteins

The M13 phage procoat protein requires both its signal sequence and its membrane anchor sequence in the mature part of the protein for membrane insertion. Translocation of its short acidic periplasmic loop is stimulated by the proton motive force (pmf) and does not require the Sec components. We now find that the pmf becomes increasingly important for the translocation of negatively charged residues within procoat when the hydrophobicity of the signal or membrane anchor is incrementally reduced. In contrast, we find that the pmf inhibits translocation of the periplasmic loop when it contains one or two positively charged residues. This inhibitory effect of the pmf is stronger when the hydrophobicity of the inserting procoat protein is compromised. No pmf effect is observed for translocation of an uncharged periplasmic loop even when the hydrophobicity is reduced. We also show that the Delta Psi component of the pmf is necessary and sufficient for insertion of representative constructs and that the translocation effects of charged residues are primarily due to the DeltaPsi component of the pmf and not the pH component.     

Positive charges in the cytoplasmic domain of Escherichia coli leader peptidase prevent an apolar domain from functioning as a signal.

Leader peptidase, an integral transmembrane protein of Escherichia coli, requires two apolar topogenic elements for its membrane assembly: a 'hydrophobic helper' and an internal signal. The highly basic cytoplasmic region between these domains is a translocation poison sequence, which we have shown blocks the function of a preceding signal sequence. We have used oligonucleotide-directed mutagenesis to remove positively charged residues within this polar domain to determine if it is the basic character in this region that has the negative effect on translocation. Our results show that mutations that remove two or more of the positively charged residues within the polar region no longer block membrane assembly of leader peptidase. In addition, when the translocation poison domain (residues 30-52) is replaced with six lysine residues, the preceding apolar domain cannot function as an export signal, whereas it can with six glutamic acids. Thus, positively charged residues within membrane proteins may have a major role in determining the function of hydrophobic domains in membrane assembly.     

Export of Escherichia coli alkaline phosphatase attached to an integral membrane protein, SecY

The SecY protein is a membrane-bound factor required for bacterial protein export and embedded in the cytoplasmic membrane by its 10 transmembrane segments. We previously proposed a topology model for this protein by adapting the Manoil-Beckwith TnphoA approach, a genetic method to assign local disposition of a membrane protein from the enzymatic activity of the alkaline phosphatase (PhoA) mature sequence attached to the various regions. SecY-PhoA hybrid proteins with the PhoA domain exported to the periplasmic side of the membrane have been obtained at the five putative periplasmic domains of the SecY sequence. We now extended this method to apply it to follow export of the newly synthesized PhoA domain. Trypsin treatment of detergent-solubilized cell extracts digested the internalized (unfolded) PhoA domain but not those exported and correctly folded. One of the hybrid proteins was cleaved in vivo after export to the periplasm, providing a convenient indication for the export. Results of these analyses indicate that export of the PhoA domain attached to different periplasmic regions of SecY occurs rapidly and requires the normal functioning of the secY gene supplied in trans. Thus, this membrane protein with multiple transmembrane segments contains multiple export signals which can promote rapid and secY-dependent export of the PhoA mature sequence attached to the carboxyl-terminal sides.     

A universal system for the transport of redox proteins: early roots and latest developments

The transport of proteins binding redox cofactors across a biological membrane is complicated by the fact that insertion of the redox cofactor is often a cytoplasmic process. These cytoplasmically assembled redox proteins must thus be transported in partially or completely folded form. The need for a special transport system for redox proteins was first recognized for periplasmic hydrogenases in gram-negative bacteria. These enzymes, which catalyze the reaction H2 <--> 2H+ + 2e, are composed of a large and a small subunit. Only the small subunit has an unusually long signal sequence of 30-50 amino acid residues, characterized by a conserved motif (S/T)-R-R-x-F-L-K at the N-terminus. This sequence directs export of the large and small subunit complex to the periplasm. Sequencing of microbial genes and genomes has shown that signal sequences with this conserved motif, now referred to as twin-arginine leaders, occur ubiquitously and export different classes of redox proteins, containing iron sulfur clusters, molybdopterin cofactors, polynuclear copper sites or flavin adenine dinucleotide. Mutations in an Escherichia coli operon referred to as mtt (membrane targeting and translocation) or tat (twin arginine translocation) are pleiotropic, i.e. these prevent the expression of a variety of periplasmic oxido-reductases in functional form. The Mtt or Tat pathway is distinct from the well-known Sec pathway and occurs ubiquitously in prokaryotes. The fact that its component proteins share sequence homology with proteins of the delta pH pathway for protein transport associated with chloroplast thylakoid assembly, illustrates the universal nature of this novel protein translocation system.     

Complete amino acid sequence of theGlycera dibranchiata monomer hemoglobin Component IV: Structural implications

The globin derived from the monomer Component IV hemoglobin of the marine annelid,Glycera dibranchiata, has been completely sequenced, and the resulting information has been used to create a structural model of the protein. The most important result is that the consensus sequence of Component IV differs by 3 amino acids from a cDNA-predicted amino acid sequence thought earlier to encode the Component IV hemoglobin. This work reveals that the histidine (E7), typical of most heme-containing globins, is replaced by leucine in Component IV. Also significant is that this sequence is not identical to any of the previously reportedGlycera dibranchiata monomer hemoglobin sequences, including the sequence from a previously reported crystal structure, but has high identity to all. A three-dimensional structual model for monomer Component IV hemoglobin was constructed using the published 1.5 å crystal structure of a monomer hemoglobin fromGlycera dibranchiata as a template. The model shows several interesting features: (1) a Phe31 (B10) that is positioned in the active site; (2) a His39 occurs in an interhelical region occupied by Pro in 98.2% of reported globin sequences; and (3) a Met41 is found at a position that emerges from this work as a previously unrecognized heme contact.Abbreviations used GMHX the holo-protein (including b-type heme, Glycera dibranchiata monomer hemoglobin Component X (X=2, 3, or 4) - GMGX the apo-protein, or globin, Glycera dibranchiata monomer globin derived from Component X (X=2, 3, or 4) - rec-gmg the globin derived from a recombinant holoprotein of a Glycera dibranchiata monomer hemoglobin, rec-gmh, whose sequence has been inferred from an isolated cDNA insert - CB label refers to peptides generated from cyanogen bromide cleavage of GMG4 - HPLC high-performance liquid chromatography - T label refers to peptides generated from trypsin digests of GMG4 - Mb myoglobin - MCS monomer hemoglobin crystal structure from Glycera dibranchiata. H, N-terminal sequence of GMG4 - SWMb sperm whale myoglobin     

A nematode hemoglobin gene contains an intron previously thought to be unique to plants

Summary Hemoglobin genes from plants and animals both have a characteristic chromosomal organization. Plant hemoglobin genes contain a unique intron inserted into the heme-binding domain of exon 2. This intron has not been previously reported in animal globin genes, and its loss was hypothesized to have occurred early in the evolution of hemoglobins. We report here a unique six-intron, seven-exon internally duplicated nematode hemoglobin gene that contains an intron equivalent to the plant central intron in its first repeat. This nematode hemoglobin gene has lost both the central and the normal third intron in its second repeat. The nematode globin also contains a unique intron between its secretory peptide leader sequence and its coding sequence, which is absent in other extracellular invertebrate globin genes. Possible models to explain the head-to-tail duplication of this gene are discussed. Offprint requests to: B. Pohajdak     

Crystal structure of the major periplasmic domain of the bacterial membrane protein assembly facilitator YidC

The essential bacterial membrane protein YidC facilitates insertion and assembly of proteins destined for integration into the inner membrane. It has homologues in both mitochondria and chloroplasts. Here we report the crystal structure of the Escherichia coli YidC major periplasmic domain (YidCECP1) at 2.5A resolution. This domain is present in YidC from Gram-negative bacteria and is more than half the size of the full-length protein. The structure reveals that YidCECP1 is made up of a large twisted beta-sandwich protein fold with a C-terminal alpha-helix that packs against one face of the beta-sandwich. Our structure and sequence analysis reveals that the C-terminal alpha-helix and the beta-sheet that it lays against are the most conserved regions of the domain. The region corresponding to the C-terminal alpha-helix was previously shown to be important for the protein insertase function of YidC and is conserved in other YidC-like proteins. The structure reveals that a region of YidC that was previously shown to be involved in binding to SecF maps to one edge of the beta-sandwich. Electrostatic analysis of the molecular surface for this region of YidC reveals a predominantly charged surface and suggests that the SecF-YidC interaction may be electrostatic in nature. Interestingly, YidCECP1 has significant structural similarity to galactose mutarotase from Lactococcus lactis, suggesting that this domain may have another function besides its role in membrane protein assembly.     

The leader region of pre-maltose binding protein binds amphiphiles. A model for self-assembly in protein export

Maltose binding protein, like most periplasmic proteins, is resistant to a variety of proteinases. Treatment of pre-maltose binding protein with trypsin, chymotrypsin, or proteinase K removes an amino-terminal domain of the same approximate size as the leader sequence without degrading the mature portion of the protein. In addition, pre-maltose binding protein is as active as mature in binding maltose (Ferenci, T., and Randall, L.L. (1979) J. Biol. Chem. 254, 9979-9981). By these criteria, the precursor and mature proteins are in the same conformation except for the exposed leader sequence on the precursor. We have compared the ability of these proteins to interact with amphipaths, such as detergents. The precursor protein binds to Triton X-100, while the mature protein does not. We propose that the leader domain is responsible for detergent binding. Mutations in the leader region of the precursor which block export in vivo prevent detergent binding in vitro. A mutant with a mild export defect can still bind detergent. This correlation between detergent binding by precursors with related leaders and export efficiency of each precursor suggests that hydrophobic partition of the leader may initiate pre-protein transfer across the membrane.     

The photodestruction of hemoglobin]

It was shown that hemoglobin photodestruction occurs in the process of light absorption by protein globin, as well as by its hem. Quantum yields of photoreactions decreased with the increase of irradiation wave length. We observed two mechanisms of photodestruction: dependent and independent on the existence of the dissolved oxygen in solution. Hemoglobin photodestruction due to hem absorption did not exist in the absence of dissolved oxygen.