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.     

SecY, a multispanning integral membrane protein, contains a potential leader peptidase cleavage site.

SecY is an Escherichia coli integral membrane protein required for efficient translocation of other proteins across the cytoplasmic membrane; it is embedded in this membrane by the 10 transmembrane segments. Among several SecY-alkaline phosphatase (PhoA) fusion proteins that we constructed previously, SecY-PhoA fusion 3-3, in which PhoA is fused to the third periplasmic region of SecY just after the fifth transmembrane segment, was found to be subject to rapid proteolytic processing in vivo. Both the SecY and PhoA products of this cleavage have been identified immunologically. In contrast, cleavage of SecY-PhoA 3-3 was barely observed in a lep mutant with a temperature-sensitive leader peptidase. The full-length fusion protein accumulated in this mutant was cleaved in vitro by the purified leader peptidase. A sequence Ala-202-Ile-Ala located near the proposed interface between transmembrane segment 5 and periplasmic domain 3 of SecY was found to be responsible for the recognition and cleavage by the leader peptidase, since a mutated fusion protein with Phe-Ile-Phe at this position was no longer cleaved even in the wild-type cells. These results indicate that SecY contains a potential leader peptidase cleavage site that undergoes cleavage if the PhoA sequence is attached carboxy terminally. Thus, transmembrane segment 5 of SecY can fulfill both of the two important functions of the signal peptide, translocation and cleavage, although the latter function is cryptic in the normal SecY protein.     

Yersinia spp. HMWP2, a cytosolic protein with a cryptic internal signal sequence which can promote alkaline phosphatase export.

The iron starvation-induced, 2,042-amino-acid protein HMWP2 of Yersinia enterocolitica has two internal hydrophobic segments which might promote its export and association with the cytoplasmic membrane. To determine whether part of HMWP2 could be exported beyond the periplasmic face of the cytoplasmic membrane, we used TnphoA mutagenesis to construct 10 hybrid proteins in which periplasmic alkaline phosphatase (PhoA) was fused to the end of C-terminally truncated HMWP1 (at amino acid positions 1751 and 1753 two independent isolates]) had high alkaline phosphate activity (close to that of the native enzyme), both in Escherichia coli and in Y. pseudotuberculosis, indicating that the PhoA segment of the hybrid reached the periplasm. Deletion studies showed that the export signal resides in the second hydrophobic segment of HMWP2. This result would be compatible with the topology of the protein in the cytoplasmic membrane predicted from the distribution of charged amino acids at either end of the two hydrophobic segments. However, two hybrids in which the junction was even further toward the C terminus of HMMWP2 (at positions 1793 and 1999) had only weak alkaline phosphatase activity, suggesting that the predicted topology is incorrect. The location of HMWP2 was therefore determined by subcellular fractionation. The results indicate that HMPW2 is mainly cytoplasmic, consistent with its presumed role in the ATP-dependent, nonribosomal synthesis of an unknown peptide. We propose that the high alkaline phosphatase activity associated with some of the HMWP-2-PhoA hybrids results from the unmasking of the cryptic export signal activity in the second hydrophobic segment of HMPW2.     

Requirements for translocation of periplasmic domains in polytopic membrane proteins.

Periplasmic domains of cytoplasmic membrane proteins require export signals for proper translocation. These signals were studied by using a MalF-alkaline phosphatase fusion in a genetic selection that allowed the isolation of mislocalization mutants. In the original construct, alkaline phosphatase is fused to the second periplasmic domain of the membrane protein, and its activity is thus confined exclusively to the periplasm. Mutants that no longer translocated alkaline phosphatase were selected by complementation of a serB mutation. A total of 11 deletions in the amino terminus were isolated, all of which spanned at least the third transmembrane segment. This domain immediately precedes the periplasmic domain to which alkaline phosphatase was fused. Our results obtained in vivo support the model that amino-terminal membrane-spanning segments are required for translocation of large periplasmic domains. In addition, we found that the inability to export the alkaline phosphatase domain could be suppressed by a mutation, prlA4, in the secretion apparatus.     

A topological model for the high-affinity nickel transporter of Alcaligenes eutrophus

The gene hoxN of Alcaligenes eutrophus encodes a membrane protein with a molecular mass of 33.1 kDa that mediates energy-dependent uptake of nickel ions. Based on the hydrophobicity of the HoxN protein five, six, or seven transmembrane segments were predicted, depending on the algorithm used for computer analysis. To distinguish between these possibilities varying segments of the amino-terminal end of the transporter were fused to the Escherichia coli enzymes aikaline phosphatase (PhoA) or β-galactosidase (LacZ). The enzymatic activity of 16 HoxN-PhoA and 15 HoxN-LacZ fusions was determined. On the assumption that PhoA fusions only exhibit high activity when fused to periplasmic domains of the target, while LacZ fusions are only active when oriented towards the cytoplasm, a two-dimensional model for the nickel transporter was developed. This model proposes that HoxN contains four periplasmic and four cytoplasmic regions, and seven transmembrane helices. The amino terminus is located in the cytoplasm, and the carboxyl terminus faces the periplasm.     

Dislocation of membrane proteins in FtsH-mediated proteolysis.

Escherichia coli FtsH degrades several integral membrane proteins, including YccA, having seven transmembrane segments, a cytosolic N-terminus and a periplasmic C-terminus. Evidence indicates that FtsH initiates proteolysis at the N-terminal cytosolic domain. SecY, having 10 transmembrane segments, is also a substrate of FtsH. We studied whether and how the FtsH-catalyzed proteolysis on the cytosolic side continues into the transmembrane and periplasmic regions using chimeric proteins, YccA-(P3)-PhoA-His6-Myc and SecY-(P5)-PhoA, with the alkaline phosphatase (PhoA) mature sequence in a periplasmic domain. The PhoA domain that was present within the fusion protein was rapidly degraded by FtsH when it lacked the DsbA-dependent folding. In contrast, both PhoA itself and the TM9-PhoA region of SecY-(P5)-PhoA were stable when expressed as independent polypeptides. In the presence of DsbA, the FtsH-dependent degradation stopped at a site near to the N-terminus of the PhoA moiety, leaving the PhoA domain (and its C-terminal region) undigested. The efficiency of this degradation stop correlated well with the rapidity of the folding of the PhoA domain. Thus, both transmembrane and periplasmic domains are degraded by the processive proteolysis by FtsH, provided they are not tightly folded. We propose that FtsH dislocates the extracytoplasmic domain of a substrate, probably using its ATPase activity.     

Identification and characterization of an Escherichia coli gene required for the formation of correctly folded alkaline phosphatase, a periplasmic enzyme.

Tn5 insertion mutations of Escherichia coli were isolated that impaired the formation of correctly folded alkaline phosphatase (PhoA) in the periplasm. The PhoA polypeptide synthesized in the mutants was translocated across the cytoplasmic membrane but not released into the periplasmic space. It was susceptible to degradation by proteases in vivo and in vitro. The wild-type counterpart of this gene (named ppfA) has been sequenced and shown to encode a periplasmic protein with a pair of potentially redox-active cysteine residues. PhoA synthesized in the mutants indeed lacked disulfide bridges. These results indicate that the folding of PhoA in vivo is not spontaneous but catalyzed at least at the disulfide bond formation step.     

Topology of the membrane-bound alkane hydroxylase of Pseudomonas oleovorans.

The Pseudomonas oleovorans alkane hydroxylase is an integral cytoplasmic membrane protein that is expressed and active in both Escherichia coli and P. oleovorans. Its primary sequence contains eight hydrophobic stretches that could span the membrane as alpha-helices. The topology of alkane hydroxylase was studied in E. coli using protein fusions linking different amino-terminal fragments of the alkane hydroxylase (AlkB) to alkaline phosphatase (PhoA) and to beta-galactosidase (LacZ). Four AlkB-PhoA fusions were constructed using transposon TnphoA. Site-directed mutagenesis was used to create PstI sites at 12 positions in AlkB. These sites were used to create AlkB-PhoA and AlkB-LacZ fusions. With respect to alkaline phosphatase and beta-galactosidase activity each set of AlkB-PhoA and AlkB-LacZ fusions revealed the expected complementary activities. At three positions, PhoA fusions were highly active, whereas the corresponding LacZ fusions were the least active. At all other positions the PhoA fusions were almost completely inactive, but the corresponding LacZ fusions were highly active. These data predict a model for alkane hydroxylase containing six transmembrane segments. In this model the amino terminus, two hydrophilic loops, and a large carboxyl-terminal domain are located in the cytoplasm. Only three very short loops near amino acid positions 52, 112, and 251 are exposed to the periplasm.     

The C-terminal domain of the Rhizobium leguminosarum chitin synthase NodC is important for function and determines the orientation of the N-terminal region in the inner membrane

The nod  C genes from rhizobia encode an N -acetylglucosaminyl transferase (chitin synthase) involved in the formation of lipo-chito-oligosaccharide Nod factors that initiate root nodule morphogenesis in legume plants. NodC proteins have two hydrophobic domains, one of about 21 residues at the N-terminus and a longer one, which could consist of two or three transmembrane spans, near the C-terminus. These two hydrophobic domains flank a large hydrophilic region that shows extensive homology with other β-glycosyl transferases. The topology of NodC in the inner membrane of Rhizobium leguminosarum biovar viciae was analysed using a series of gene fusions encoding proteins in which NodC was fused to alkaline phosphatase (PhoA) lacking an N-terminal transit sequence or to β-galactosidase (LacZ). Our data support a model in which the N-terminal hydrophobic domain spans the membrane in a N_out–C_in orientation, with the adjacent large hydrophilic domain being exposed to the cytoplasm. This orientation appears to depend upon the presence of the hydrophobic region near the C-terminus. We propose that this hydrophobic region contains three transmembrane spans, such that the C-terminus of NodC is located in the periplasm. A short region of about 40 amino acids, encompassing the last transmembrane span, is essential for the function of NodC. Our model for NodC topology suggests that most of NodC, including the region showing most similarity to other β-glycosyl transferases, is exposed to the cytoplasm, where it is likely that polymerization of N -acetyl glucoasamine occurs. Such a model is incompatible with previous reports suggesting that NodC spans both inner and outer membranes.     

Export of maltose-binding protein species with altered charge distribution surrounding the signal peptide hydrophobic core in Escherichia coli cells harboring prl suppressor mutations.

It is believed that one or more basic residues at the extreme amino terminus of precursor proteins and the lack of a net positive charge immediately following the signal peptide act as topological determinants that promote the insertion of the signal peptide hydrophobic core into the cytoplasmic membrane of Escherichia coli cells with the correct orientation required to initiate the protein export process. The export efficiency of precursor maltose-binding protein (pre-MBP) was found to decrease progressively as the net charge in the early mature region was increased systematically from 0 to +4. This inhibitory effect could be further exacerbated by reducing the net charge in the signal peptide to below 0. One such MBP species, designated MBP-3/+3 and having a net charge of -3 in the signal peptide and +3 in the early mature region, was totally export defective. Revertants in which MBP-3/+3 export was restored were found to harbor mutations in the prlA (secY) gene, encoding a key component of the E. coli protein export machinery. One such mutation, prlA666, was extensively characterized and shown to be a particularly strong suppressor of a variety of MBP export defects. Export of MBP-3/+3 and other MBP species with charge alterations in the early mature region also was substantially improved in E. coli cells harboring certain other prlA mutations originally selected as extragenic suppressors of signal sequence mutations altering the hydrophobic core of the LamB or MBP signal peptide. In addition, the enzymatic activity of alkaline phosphatase (PhoA) fused to a predicted cytoplasmic domain of an integral membrane protein (UhpT) increased significantly in cells harboring prlA666. These results suggest a role for PrlA/SecY in determining the orientation of signal peptides and possibly other membrane-spanning protein domains in the cytoplasmic membrane.     

Export of FepA::PhoA fusion proteins to the outer membrane of Escherichia coli K-12.

A library of fepA::phoA gene fusions was generated in order to study the structure and secretion of the Escherichia coli K-12 ferric enterobactin receptor, FepA. All of the fusion proteins contained various lengths of the amino-terminal portion of FepA fused in frame to the catalytic portion of bacterial alkaline phosphatase. Localization of FepA::PhoA fusion proteins in the cell envelope was dependent on the number of residues of mature FepA present at the amino terminus. Hybrids containing up to one-third of the amino-terminal portion of FepA fractionated with their periplasm, while those containing longer sequences of mature FepA were exported to the outer membrane. Outer membrane-localized fusion proteins expressed FepA sequences on the external face of the outer membrane and alkaline phosphatase moieties in the periplasmic space. From sequence determinations of the fepA::phoA fusion joints, residues within FepA which may be exposed on the periplasmic side of the outer membrane were identified.     

Analysis of Escherichia coli TonB membrane topology by use of PhoA fusions.

Alkaline phosphatase (PhoA) fusions to TonB amino acids 32, 60, 125, 207, and 239 (the carboxy terminus) all showed high PhoA activity; a PhoA fusion to TonB amino acid 12 was inactive. The full-length TonB-PhoA fusion protein was associated with the cytoplasmic membrane and retained partial TonB function. These results support a model in which TonB is anchored in the cytoplasmic membrane by its hydrophobic amino terminus, with the remainder of the protein, including its hydrophobic carboxy terminus, extending into the periplasm.     

Heterospecific cloning of Arabidopsis thaliana cDNAs by direct complementation of pyrimidine auxotrophic mutants of Saccharomyces cerevisiae. I. Cloning and sequence analysis of two cDNAs catalysing the second,fifth and sixth steps of the de novo pyrimidine biosynthesis pathway

A one-step mutant of Escherichia coli K-12 lacking both glucose-1-phosphatase (Agp) and pH 2.5 acid phosphatase (AppA) activities in the periplasmic space was isolated. The mutation which mapped close to ch1B, at 87 min on the E. coli linkage map, also caused the loss of alkaline phosphatase (PhoA) activity, even when this activity was expressed from TnphoA fusions to genes encoding periplasmic or membrane proteins. A DNA fragment that complements the mutation was cloned and shown to carry the dsbA gene, which encodes a periplasmic disulphide bond-forming factor. The mutant had an ochre triplet in dsbA, truncating the protein at amino acid 70. Introduction of TnphoA fusions into a plasmid-borne dsbA gene resulted in DsbA-PhoA hybrid proteins that were all exported to the periplasmic space in both dsbA ⁺ and dsbA strains. They belong to three different classes, depending on the length of the DsbA fragment fused to PhoA. When PhoA was fused to an amino-terminal DsbA heptapeptide, the protein was only seen in the periplasm of a dsbA ⁺ strain, as in the case of wild-type PhoA. Hybrid proteins missing up to 29 amino acids at the carboxy-terminus of DsbA were stable and retained both the DsbA and PhoA activities. Those with shorter DsbA fragments that still carried the -Cys-ProHis-Cys-motif were rapidly degraded (no DsbA activity). The presence is discussed of a structural domain lying around amino acid 170 of DsbA and which is probably essential for its folding into a proteolytic-resistant and enzymatically active form.     

The Tsr chemosensory transducer of Escherichia coli assembles into the cytoplasmic membrane via a SecA-dependent process

The Tsr protein of Escherichia coli is a chemosensory transducer that mediates taxis toward serine and away from certain repellents. Like other bacterial transducers, Tsr spans the cytoplasmic membrane twice, forming a periplasmic domain of about 150 amino acids and a cytoplasmic domain of about 300 amino acids. The 32 N-terminal amino acids of Tsr resemble the consensus signal sequence of secreted proteins, but they are not removed from the mature protein. To investigate the function of this N-terminal sequence in the assembly process, we isolated translational fusions between tsr and the phoA and lacZ genes, which code for the periplasmic enzyme alkaline phosphatase and the cytoplasmic enzyme beta-galactosidase, respectively. All tsr-phoA fusions isolated code for proteins whose fusion joints are within the periplasmic loop of Tsr, and all of these hybrid proteins have high alkaline phosphatase activity. The most N-terminal fusion joint is at amino acid 19 of Tsr. Tsr-lacZ fusions were found throughout the tsr gene. The beta-galactosidase activity of the LacZ-fusion proteins varies greatly, depending on the location of the fusion joint. Fusions with low activity have fusion joints within the periplasmic loop of Tsr. The expression of these fusions is most likely reduced at the level of translation. In addition, one of these fusions markedly reduces the export and processing of the periplasmic maltose-binding protein and the outer membrane protein OmpA, but not of intact PhoA or of the outer membrane protein LamB. A temperature-sensitive secA mutation, causing defective protein secretion, stops expression of new alkaline phosphatase activity coded by a tsr-phoA fusion upon shifting to the nonpermissive temperature. The same secA mutation, even at the permissive temperature, increases the activity and the level of expression of LacZ fused to the periplasmic loop of Tsr relative to a secA+ strain. We conclude that the assembly of Tsr into the cytoplasmic membrane is mediated by the machinery responsible for the secretion of a subset of periplasmic and outer membrane proteins. Moreover, assembly of the Tsr protein seems to be closely coupled to its synthesis.     

Anchoring proteins to Escherichia coli cell membranes using hydrophobic anchors derived from a Bacillus subtilis integral membrane protein

Anchored periplasmic expression (APEx) technology aims to express and localize proteins or peptides in the Escherichia coli periplasm. Some reports have suggested that transmembrane segments of integral membrane proteins can be used as membrane anchors in the APEx system. In this study, a series of hydrophobic anchors derived from the first putative transmembrane helix of a Bacillus subtilis integral membrane protein, MrpF, and its truncated forms were investigated for anchored periplasmic expression of alkaline phosphatase (PhoA) in E. coli. Anchoring efficiency of hydrophobic anchors was evaluated by monitoring the expression and activity of anchored PhoA. The length of hydrophobic anchors was found to be critical for anchoring proteins to cell membranes. This study may open new avenues for applying transmembrane segments derived from native membrane proteins as membrane anchors in the APEx system.     

Use of phoA fusions to study the topology of the Escherichia coli inner membrane protein leader peptidase.

A topology of the Escherichia coli leader peptidase has been previously proposed on the basis of proteolytic studies. Here, a collection of alkaline phosphatase fusions to leader peptidase is described. Fusions to the periplasmic domain of this protein exhibit high alkaline phosphatase activity, while fusions to the cytoplasmic domain exhibit low activity. Elements within the cytoplasmic domain are necessary to stably anchor alkaline phosphatase in the cytoplasm. The amino-terminal hydrophobic segment of leader peptidase acts as a weak export signal for alkaline phosphatase. However, when this segment is preceded by four lysines, it acts as a highly efficient export signal. The coherence of in vitro studies with alkaline phosphatase fusion analysis of the topology of leader peptidase further indicates the utility of this genetic approach to membrane protein structure and insertion.     

Characterization of Escherichia coli expressing an Lpp’OmpA(46-159)-PhoA fusion protein localized in the outer membrane

 The Lpp′OmpA(46–159) hybrid protein can serve as an efficient targeting vehicle for localizing a variety of procaryotic and eucaryotic soluble proteins onto the E. coli surface, thus providing a system for several possible biotechnology applications. Here we show that fusions between Lpp′OmpA(46–159) and bacterial alkaline phosphatase (PhoA), a normally periplasmic dimeric enzyme, are also targeted to the outer membrane. However, protease accessibility experiments and immunoelectron microscopy revealed that, unlike other periplasmic proteins, the PhoA domain of these fusions is not exposed on the cell surface in cells having an intact outer membrane. Conditions that affect the formation of disulfide bonds and the folding of the PhoA domain in the periplasm not only did not facilitate targeting to the cell surface but led to lethality when the fusion was expressed from a high-copy-number plasmid. Furthermore, E. coli expressing the Lpp′OmpA(46–159)-PhoA fusion exhibited strain- and temperature-dependent alterations in outer-membrane permeability. Our results are consistent with previous studies with other vehicles indicating that PhoA is not displayed on the surface when fused to cell-surface expression vectors. Presumably, the enzyme rapidly assumes a tightly folded dimeric conformation that cannot be transported across the outer membrane. The large size and quaternary structure of PhoA may define a limitation of the Lpp′OmpA(46– 159) fusion system for the display of periplasmic proteins on the cell surface. Alkaline phosphatase is a unique protein among a group of five periplasmic proteins (β-lactamase, alkaline phosphatase, Cex cellulase, Cex cellulose-binding domain, and a single-chain Fv antibody fragment), which have been tested as passengers for the Lpp′OmpA(46–159) expression system to date, since it was the only protein not displayed on the surface. Received: 23 March 1995/Received revision: 29 July 1995/Accepted: 22 August 1995     

Polypeptide binding of Escherichia coli FtsH (HflB)

The Escherichia coli FtsH protein is a membrane-bound and ATP-dependent protease. In this study, we describe ATP-dependent conformational changes in FtsH as well as a polypeptide binding ability of this protein. A 33 kDa segment of FtsH became trypsin resistant in the presence of ATP. ATP and ATPγS prevented self-aggregation of detergent-solubilized FtsH-His₆-Myc at 37°C, again suggesting that the binding of ATP induces a conformational change in FtsH. Affinity chromatography showed that FtsH-His₆-Myc can associate with denatured alkaline phosphatase (PhoA) but not with the native enzyme. Denatured PhoA also prevented the aggregation of FtsH, and these two proteins co-sedimented through a sucrose gradient. Binding between FtsH-His₆-Myc and detergent-solubilized SecY was also demonstrated. Although FtsH-bound SecY was processed further for ATP-dependent proteolysis, FtsH-bound PhoA was not. Thus, FtsH association with denatured PhoA is uncoupled from proteolysis. Overproduction of FtsH significantly increased the cytoplasmic localization of the PhoA moiety of a MalF–PhoA hybrid protein, in which a charged residue had been introduced into a transmembrane segment. Thus, denatured PhoA binding of FtsH may also occur in vivo .     

Topology and accessibility of the transmembrane helices and the sensory site in the bifunctional transporter DcuB of Escherichia coli

C(4)-Dicarboxylate uptake transporter B (DcuB) of Escherichia coli is a bifunctional transporter that catalyzes fumarate/succinate antiport and serves as a cosensor of the sensor kinase DcuS. Sites and domains of DcuB were analyzed for their topology relative to the cytoplasmic or periplasmic side of the membrane and their accessibility to the water space. For the topology studies, DcuB was fused at 33 sites to the reporter enzymes PhoA and LacZ that are only active when located in the periplasm or the cytoplasm, respectively. The ratios of the PhoA and LacZ activities suggested the presence of 10 or 11 hydrophilic loops, and 11 or 12 α-helical transmembrane domains (TMDs). The central part of DcuB allowed no clear topology prediction with LacZ/PhoA fusions. The sites of DcuB accessible to the hydrophilic thiol reagent 4-acetamido-4'-maleimidylstilbene-2,2'-disulfonate (AMS) were determined with variants of DcuB that carried single Cys residues. After intact cells were labeled with the membrane-impermeable AMS, denatured cells were differentially labeled with the thiol reagent polyethylene-glycol-maleimide (PEGmal) and analyzed for a mass shift. From 35 positions 17 were accessible to AMS in intact bacteria. The model derived from topology and accessibility suggests 12 TMDs for DcuB and a waterfilled cavity in its central part. The cavity ends with a cytoplasmic lid accessible to AMS from the periplasmic side. The sensory domain of DcuB is composed of cytoplasmic loop XI/XII and a membrane integral region with the regulatory residues Thr396/Asp398 and Lys353.     

Alkaline phosphatase which lacks its own signal sequence becomes enzymatically active when fused to N-terminal sequences of Escherichia coli haemolysin (HlyA)

Summary Fusion of the alkaline phosphatase gene (phoA) which lacks its own signal peptide sequence to the N-terminal region of hlyA, the structural gene for Escherichia coli haemolysin, leads to active alkaline phosphatase (AP). AP activity depends on the length of the N-terminal region of hlyA. An optimum is reached when 100–200 amino acids of HlyA are fused to PhoA but fusion of as little as 13 amino acids of HlyA to PhoA is sufficient to yield appreciable AP activity. When cells are treated with lysozyme most of the AP activity is found associated with the membrane fraction but a substantial amount is also found in the soluble fraction, most of which may represent, a periplasmic pool of AP. The soluble portion of AP activity is significantly increased when the cells are disrupted by ultrasonication, which indicates that the fusion proteins are only loosely associated with the membrane and that large parts are already located on the outside of the cytoplasmic membrane. The expected fusion proteins were identified in the soluble and the membrane fractions and their amounts in these fractions correlated well with AP activity.