Leader peptidase

The Escherichia coli leader peptidase has been vital for unravelling problems in membrane assembly and protein export. The role of this essential peptidase is to remove amino-terminal leader peptides from exported proteins after they have crossed the plasma membrane. Strikingly, almost all periplasmic proteins, many outer membrane proteins, and a few inner membrane proteins are made with cleavable leader peptides that are removed by this peptidase. This enzyme of 323 amino acid residues spans the membrane twice, with its large carboxyl-terminal domain protruding into the periplasm. Recent discoveries show that its membrane orientation is controlled by positively charged residues that border (on the cytosolic side) the transmembrane segments. Cleavable pre-proteins must have small residues at -1 and a small or aliphatic residue at -3 (with respect to the cleavage site). Leader peptidase does not require a histidine or cysteine amino acid for catalysis. Interestingly, serine 90 and aspartic acid 153 are essential for catalysis and are also conserved in a mitochondrial leader peptidase, which is 30.7% homologous with the bacterial enzyme over a 101-residue stretch.     

Synthesis of precursor maltose-binding protein with proline in the +1 position of the cleavage site interferes with the activity of Escherichia coli signal peptidase I in vivo.

The residues occupying the -3 and -1 positions relative to the cleavage site of secretory precursor proteins are usually amino acids with small, neutral side chains that are thought to constitute the recognition site for the processing enzyme, signal peptidase. No restrictions have been established for residues positioned +1 to the cleavage site, although there have been several indications that mutant precursor proteins with a proline at +1 cannot be processed by Escherichia coli signal peptidase I (also called leader peptidase). A maltose-binding protein (MBP) species with proline at +1, designated MBP27-P, was translocated efficiently but not processed when expressed in E. coli cells. Unexpectedly, induced expression of MBP27-P was found to have an adverse effect on the processing kinetics of five different nonlipoprotein precursors analyzed, but not precursor Lpp (the major outer membrane lipoprotein) processed by a different enzyme, signal peptidase II. Cell growth also was inhibited following induction of MBP27-P synthesis. Substitutions in the MBP27-P signal peptide that blocked MBP translocation across the cytoplasmic membrane and, hence, access to the processing enzyme or that altered the signal peptidase I recognition site at position -1 restored both normal growth and processing of other precursors. Since overproduction of signal peptidase I also restored normal growth and processing to cells expressing unaltered MBP27-P, it was concluded that precursor MBP27-P interferes with the activity of the processing enzyme, probably by competing as a noncleavable substrate for the enzyme's active site. Thus, although signal peptidase I, like many other proteases, is unable to cleave an X-Pro bond, a proline at +1 does not prevent the enzyme from recognizing the normal processing site. When the RBP signal peptide was substituted for the MBP signal peptide of MBP27-P, the resultant hybrid protein was processed somewhat inefficiently at an alternate cleavage site and elicited a much reduced effect on cell growth and signal peptidase I activity. Although the MBP signal peptide also has an alternate cleavage site, the different properties of the RBP and MBP signal peptides with regard to the substitution of proline at +1 may be related to their respective secondary structures in the processing site region.     

Both a short hydrophobic domain and a carboxyl-terminal hydrophilic region are important for signal function in the Escherichia coli leader peptidase

Leader peptidase, typical of inner membrane proteins of Escherichia coli, does not have an amino-terminal leader sequence. This protein contains an internal signal peptide, residues 51-83, which is essential for assembly and remains as a membrane anchor domain. We have employed site-directed mutagenesis techniques to either delete residues within this domain or substitute a charged amino acid for one of these residues to determine the important properties of the internal signal. The deletion analysis showed that a very small apolar domain, residues 70-76, is essential for assembly, whereas residues that flank it are dispensable for its function. However, point mutations with charged amino acid residues within the polar sequence (residues 77-82) slow or abolish leader peptidase membrane assembly. Thus, a polar region, Arg-Ser-Phe-Ile-Tyr-Glu, is important for the signal peptide function of leader peptidase, unlike other signals identified thus far.     

Conserved residues of the leader peptide are essential for cleavage by leader peptidase

Gene 8 of bacteriophage M13 codes for procoat, the precursor of its major coat protein. Gene 8 has been cloned into a plasmid and mutagenized. We have isolated mutants of this gene in which procoat is synthesized but is not processed to coat protein. We now describe mutants in the leader region of procoat, at positions -6, -3, and -1 with respect to the leader peptidase cleavage site. These positions are quite conserved among the leader peptides of various pre-proteins. Each of these mutant procoats is synthesized at a normal rate and inserts correctly into the plasma membrane, as judged by its accessibility to protease in intact spheroplasts. Procoat accumulates, largely in its transmembrane form, and is not cleaved to coat. In detergent extracts, the mutant procoats are very poor substrates for added leader peptidase. We conclude that these 3 residues are not conserved for insertion across the membrane but are part of an essential recognition site for the leader peptidase.     

A family of bacteriocin ABC transporters carry out proteolytic processing of their substrates concomitant with export

Lantibiotic and non-lantibiotic bacteriocins are synthesized as precursor peptides containing N-terminal extensions (leader peptides) which are cleaved off during maturation. Most non-lantibiotics and also some lantibiotics have leader peptides of the so- called double-glycine type. These leader peptides share consensus sequences and also a common processing site with two conserved glycine residues In positions -1 and 2. The double-glycine-type leader peptides are unrelated to the N-terminal signal sequences which direct proteins across the cytoplasmic membrane via the sec pathway. Their processing sites are also different from typical signal peptidase cleavage sites, suggesting that a different processing enzyme is involved. Peptide bacteriocins are exported across the cytoplasmic membrane by a dedicated ATP-binding cassette (ABC) transporter. Here we show that the ABC transporter is the maturation protease and that its proteolytic domain resides in the N-terminal part of the protein. This result demonstrates that the ABC transporter has a dual function: (i) removal of the leader peptide from its substrate, and (ii) translocation of its substrate across the cytoplasmic membrane. This represents a novel strategy for secretion of bacterial proteins.     

The reaction specificities of the thylakoidal processing peptidase and Escherichia coli leader peptidase are identical.

Proteins which are transported across the bacterial plasma membrane, endoplasmic reticulum and thylakoid membrane are usually synthesized as larger precursors containing amino-terminal targeting signals. Removal of the signals is carried out by specific, membrane-bound processing peptidases. In this report we show that the reaction specificities of these three peptidases are essentially identical. Precursors of two higher plant thylakoid lumen proteins are efficiently processed by purified Escherichia coli leader peptidase. Processing of one precursor, that of the 23 kd photosystem II protein, by both the thylakoidal and E. coli enzymes generates the correct mature amino terminus. Similarly, leader (signal) peptides of both eukaryotic and prokaryotic origin are cleaved by partially purified thylakoidal processing peptidase. No evidence of incorrect processing was obtained. Both leader peptidase and thylakoidal peptidase are inhibited by a synthetic leader peptide.     

Amino acid substitutions in pilin of Pseudomonas aeruginosa. Effect on leader peptide cleavage, amino-terminal methylation, and pilus assembly.

A total of 37 separate mutants containing single and multiple amino acid substitutions in the leader and amino-terminal conserved region of the Type IV pilin from Pseudomonas aeruginosa were generated by oligonucleotide-directed mutagenesis. The effect of these substitutions on the secretion, processing, and assembly of the pilin monomers into mature pili was examined. The majority of substitutions in the highly conserved amino-terminal region of the pilin monomer had no effect on piliation. Likewise, substitution of several of the residues within the six amino acid leader sequence did not affect secretion and leader cleavage (processing), including replacement of one or both of the positively charged lysine residues with uncharged or negatively charged amino acids. One characteristic of the Type IV pili is the presence of an amino-terminal phenylalanine after leader peptide cleavage which is N-methylated prior to assembly of pilin monomers into pili. Substitution of the amino-terminal phenylalanine with a number of other amino acids, including polar, hydrophobic, and charged residues, did not affect proper leader cleavage and subsequent assembly into pili. Amino-terminal sequencing showed that the majority of substitute residues were also methylated. Substitution of the glycine residue at the -1 position to the cleavage site resulted in the inability to cleave the prepilin monomers and blocked the subsequent assembly of monomers into pili. These results indicate that despite the high degree of conservation in the amino-terminal sequences of the Type IV pili, N-methylphenylalanine at the +1 position relative to the leader peptide cleavage site is not strictly required for pilin assembly. N-Methylation of the amino acids substituted for phenylalanine was shown to have taken place in four of the five mutants tested, but it remains unclear as to whether pilin assembly is dependent on this modification. Recognition and proper cleavage of the prepilin by the leader peptidase appears to be dependent only on the glycine residue at the -1 position. Cell fractionation experiments demonstrated that pilin isolated from mutants deficient in prepilin processing and/or assembly was found in both inner and outer membrane fractions, indistinguishable from the results seen with the wild type.     

Requirements for signal peptide peptidase-catalyzed intramembrane proteolysis

The presenilin-type aspartic protease signal peptide peptidase (SPP) can cleave signal peptides within their transmembrane region. SPP is essential for generation of signal peptide-derived HLA-E epitopes in humans and is exploited by Hepatitis C virus for processing of the viral polyprotein. Here we analyzed requirements of substrates for intramembrane cleavage by SPP. Comparing signal peptides that are substrates with those that are not revealed that helix-breaking residues within the transmembrane region are required for cleavage, and flanking regions can affect processing. Furthermore, signal peptides have to be liberated from the precursor protein by cleavage with signal peptidase in order to become substrates for SPP. We propose that signal peptides require flexibility in the lipid bilayer to exhibit an accessible peptide bond for intramembrane proteolysis.     

Use of site-directed mutagenesis to define the limits of sequence variation tolerated for processing of the M13 procoat protein by the Escherichia coli leader peptidase.

Leader peptidase cleaves the leader sequence from the amino terminus of newly made membrane and secreted proteins after they have translocated across the membrane. Analysis of a large number of leader sequences has shown that there is a characteristic pattern of small apolar residues at -1 and -3 (with respect to the cleavage site) and a helix-breaking residue adjacent to the central apolar core in the region -4 to -6. The conserved sequence pattern of small amino acids at -1 and -3 around the cleavage site most likely represents the substrate specificity of leader peptidase. We have tested this by generating 60 different mutations in the +1 to -6 domain of the M13 procoat protein. These mutants were analyzed for in vivo and in vitro processing, as well as for protein insertion into the cytoplasmic membrane. We find that in vivo leader peptidase was able to process procoat with an alanine, a serine, a glycine, or a proline residue at -1 and with a serine, a glycine, a threonine, a valine, or a leucine residue at -3. All other alterations at these sites were not processed, in accordance with predictions based on the conserved features of leader peptides. Except for proline and threonine at +1, all other residues at this position were processed by leader peptidase. None of the mutations at -2, -4, or -5 of procoat (apart from proline at -4) completely abolished leader peptidase cleavage in vivo although there were large effects on the kinetics of processing.(ABSTRACT TRUNCATED AT 250 WORDS)     

Leader peptidase catalyzes the release of exported proteins from the outer surface of the Escherichia coli plasma membrane

Leader peptidase cleaves the amino-terminal leader sequences of many secreted and membrane proteins. We have examined the function of leader peptidase by constructing an Escherichia coli strain where its synthesis is controlled by the arabinose B promoter. This strain requires arabinose for growth. When the synthesis of leader peptidase is repressed, protein precursors accumulate, including the precursors of M13 coat protein (an inner membrane protein), maltose binding protein (a periplasmic protein), and OmpA protein (an outer membrane protein). These precursors are translocated across the plasma membrane, as judged by their sensitivity to added proteinase K. However, pro-OmpA and pre-maltose binding protein are retained at the outer surface of the inner membrane. Thus, leader peptides anchor translocated pre-proteins to the outer surface of the plasma membrane and must be removed to allow their subsequent release into the periplasm or transit to the outer membrane.     

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.     

Maturation and secretion of the non-typable Haemophilus influenzae HMW1 adhesin: roles of the N-terminal and C-terminal domains

Non-typable Haemophilus influenzae is a common cause of human disease and initiates infection by colonizing the upper respiratory tract. The non-typable H. influenzae HMW1 and HMW2 adhesins mediate attachment to human epithelial cells, an essential step in the process of colonization. HMW1 and HMW2 have an unusual N-terminus and undergo cleavage of a 441-amino-acid N-terminal fragment during the course of their maturation. Following translocation across the outer membrane, they remain loosely associated with the bacterial surface, except for a small amount that is released extracellularly. In the present study, we localized the signal sequence to the first 68 amino acids, which are characterized by a highly charged region from amino acids 1-48, followed by a more typical signal peptide with a predicted leader peptidase cleavage site after the amino acid at position 68. Additional experiments established that the SecA ATPase and the SecE translocase are essential for normal export and demonstrated that maturation involves cleavage first between residues 68 and 69, via leader peptidase, and next between residues 441 and 442. Site-directed mutagenesis revealed that HMW1 processing, secretion and extracellular release are dependent on amino acids in the region between residues 150 and 166 and suggested that this region interacts with the HMW1B outer membrane translocator. Deletion of the C-terminal end of HMW1 resulted in augmented extracellular release and elimination of HMW1-mediated adherence, arguing that the C-terminus may serve to tether the adhesin to the bacterial surface. These observations suggest that the HMW proteins are secreted by a variant form of the general secretory pathway and provide insight into the mechanisms of secretion of a growing family of Gram-negative bacterial exoproteins.     

Alterations in the transport and processing of Rous sarcoma virus envelope glycoproteins mutated in the signal and anchor regions

The env gene of Rous sarcoma virus codes for two glycoproteins which are located on the surface of infectious virions. Subcloning of these coding sequences in the place of the late region of SV40 DNA has allowed the expression of a normally glycosylated, functionally active glycoprotein complex on the surface of monkey cells. Through the use of site-directed mutagenesis, the role of specific amino acids in the signal peptide, signal peptidase cleavage site, and membrane anchor region have been investigated. Amino-terminal mutations have shown that deletion of the signal peptidase cleavage site along with one or two amino acids of the hydrophobic signal peptide results in the synthesis of an unglycosylated, uncleaved, and presumably cytoplasmically located precursor. Nevertheless, changing the signal peptidase cleavage site from ala/asp to ala/asn does not block the translocation of the glycoprotein across the membrane or the action of the peptidase. At the other end of the molecule, carboxy-terminal mutations have shown that the deletion of the hydrophobic membrane anchor region is not sufficient for the secretion of the truncated glycoprotein. Interpretations of these results based on recent models for protein transport and secretion are discussed.     

Identification and solubilization of a signal peptidase from the phototrophic bacterium Rhodobacter capsulatus.

In Gram-negative bacteria, exported proteins are synthesized with an amino-terminal signal sequence which is cleaved off by the signal peptidase during, or shortly after the translocation process. Here, we report the identification and solubilization of a signal peptidase from the phototrophic bacterium Rhodobacter capsulatus which cleaves homologous and heterologous precursor proteins at the authentic cleavage site. This signal peptidase is the first identified component of the R. capsulatus protein export machinery.     

Mitochondrial protein import: identification of processing peptidase and of PEP, a processing enhancing protein

Transport of nuclear-encoded precursor proteins into mitochondria includes proteolytic cleavage of amino-terminal targeting sequences in the mitochondrial matrix. We have isolated the processing activity from Neurospora crassa. The final preparation (enriched ca. 10,000-fold over cell extracts) consists of two proteins, the matrix processing peptidase (MPP, 57 kd) and a processing enhancing protein (PEP, 52 kd). The two components were isolated as monomers. PEP is about 15-fold more abundant in mitochondria than MPP. It is partly associated with the inner membrane, while MPP is soluble in the matrix. MPP alone has a low processing activity whereas PEP alone has no apparent activity. Upon recombining both, full processing activity is restored. Our data indicate that MPP contains the catalytic site and that PEP has an enhancing function. The mitochondrial processing enzyme appears to represent a new type of "signal peptidase," different from the bacterial leader peptidase and the signal peptidase of the endoplasmic reticulum.     

Mutagenesis of nisin’s leader peptide proline strongly modulates export of precursor nisin

The lantibiotic nisin is produced by Lactococcus lactis as a precursor peptide comprising a 23 amino acid leader peptide and a 34 amino acid post-translationally modifiable core peptide. We previously demonstrated that the conserved FNLD part of the leader is essential for intracellular enzyme-catalyzed introduction of lanthionines in the core peptide and also for transporter-mediated export, whereas other positions are subject to large mutational freedom. We here demonstrate that, in the absence of the extracellular leader peptidase, NisP, export of precursor nisin via the modification and transporter enzymes, NisBTC, is strongly affected by multiple substitutions of the leader residue at position -2, but not by substitution of positions in the vicinity of this site. Export levels of precursor nisin increased by more than 70% for position -2 mutants Asp, Thr, Ser, Trp, Lys, Val and decreased more than 70% for Cys, His, Met. In a strain with leader peptidase, the Pro-2Lys and Pro-2Asp precursor nisins were less efficiently cleaved by NisP than wild type precursor nisin. Taken together, the wild type precursor nisin with a proline at position -2 allows balanced export and cleavage efficiencies by precursor nisin’s transporter and leader peptidase.     

Structural studies of a signal peptide in complex with signal peptidase I cytoplasmic domain: the stabilizing effect of membrane-mimetics on the acquired fold

A protein destined for export from the cell cytoplasm is synthesized as a preprotein with an amino-terminal signal peptide. In Escherichia coli, typically signal peptides that guide preproteins into the SecYEG protein conduction channel are subsequently removed by signal peptidase I. To understand the mechanism of this critical step, we have assessed the conformation of the signal peptide when bound to signal peptidase by solution nuclear magnetic resonance. We employed a soluble form of signal peptidase, which laks the two transmembrane domains (SPase I Δ2-75), and the E. coli alkaline phosphatase signal peptide. Using a transferred NOE approach, we found clear evidence of a weak peptide-enzyme complex formation. The peptide adopts a U-turn shape originating from the proline residues within the primary sequence that is stabilized by its interaction with the peptidase and leaves key residues of the cleavage region exposed for proteolysis. In dodecylphosphocholine (DPC) micelles the signal peptide also adopts a U-turn shape comparable with that observed in association with the enzyme. In both environments this conformation is stabilized by the signal peptide phenylalanine side chain-interaction with enzyme or lipid mimetic. Moreover, in the presence of DPC, the N-terminal core region residues of the peptide adopt a helical motif and based on PRE (paramagnetic relaxation enhancement) experiments are shown to be buried within the membrane. Taken together, this is consistent with proteolysis of the preprotein occurring while the signal peptide remains in the bilayer and the enzyme active site functioning at the membrane surface.     

Heterologous Processing and Export of the Bacteriocins Pediocin PA-1 and Lactococcin A in Lactococcus Lactis: A Study with Leader Exchange

The bacteriocins pediocin PA-1 and lactococcin A are synthesized as precursors carrying N-terminal extensions with a conserved cleavage site preceded by two glycine residues in positions -2 and -1. Each bacteriocin is translocated through the cytoplasmic membrane by an integral membrane protein of the ABC cassette superfamily which, in the case of pediocin PA-1, has been shown to possess peptidase activity responsible for proteolytic cleavage of the pre-bacteriocin. In each case, another integral membrane protein is essential for bacteriocin production. In this study, a two-step PCR approach was used to permutate the leaders of pediocin PA-1 and lactococcin A. Wild-type and chimeric pre-bacteriocins were assayed for maturation by the processing/export machinery of pediocin PA-1 and lactococcin A. The results show that pediocin PA-1 can be efficiently exported by the lactococcin machinery whether it carries the lactococcin or the pediocin leader. It can also compete with wild-type lactococcin A for the lactococcin machinery. Pediocin PA-1 carrying the lactococcin A leader or lactococcin A carrying that of pediocin PA-1 was poorly secreted when complemented with the pediocin PA-1 machinery, showing that the pediocin machinery is more specific for its bacteriocin substrate. Wild-type pre-pediocin and chimeric pre-pediocin were shown to be processed by the lactococcin machinery at or near the double-glycine cleavage site. These results show the potential of the lactococcin LcnC/LcnD machinery as a maturation system for peptides carrying double-glycine-type amino-terminal leaders.     

Prerequisites for terminal processing of thylakoidal Tat substrates

In bacteria and chloroplasts, the Tat (twin arginine translocation) system is capable of translocating folded passenger proteins across the cytoplasmic and thylakoidal membranes, respectively. Transport depends on signal peptides that are characterized by a twin pair of arginine residues. The signal peptides are generally removed after transport by specific processing peptidases, namely the leader peptidase and the thylakoidal processing peptidase. To gain insight into the prerequisites for such signal peptide removal, we mutagenized the vicinity of thylakoidal processing peptidase cleavage sites in several thylakoidal Tat substrates. Analysis of these mutants in thylakoid transport experiments showed that the amino acid composition of both the C-terminal segment of the signal peptide and the N-terminal part of the mature protein plays an important role in the maturation process. Efficient removal of the signal peptide requires the presence of charged or polar residues within at least one of those regions, whereas increased hydrophobicity impairs the process. The relative extent of this effect varies to some degree depending on the nature of the precursor protein. Unprocessed transport intermediates with fully translocated passenger proteins are found in membrane complexes of high molecular mass, which presumably represent Tat complexes, as well as free in the lipid bilayer. This seems to indicate that the Tat substrates can be laterally released from the complexes prior to processing and that membrane transport and terminal processing of Tat substrates are independent processes.     

Identification of Treponema pallidum subspecies pallidum genes encoding signal peptides and membrane-spanning sequences using a novel alkaline phosphatase expression vector

Treponema pallidum subspecies pallidum is a pathogenic spirochaete for which there are no systems of genetic exchange. In order to provide a system for the identification of T. pallidum surface proteins and potential virulence factors, we have developed a novel expression vector which confers the utility of TnphoA transposition. The relevant features of this plasmid vector, termed pMG, include an inducible tac promoter, a polylinker with multiple cloning sites in three reading frames, and an alkaline phosphatase (AP) gene lacking the signal sequence-encoding region. Library construction with Sau3A-digested T. pallidum genomic DNA resulted in the creation of functional T. pallidum-AP fusion proteins. Analysis of fusion proteins and their corresponding DNA and deduced amino acid sequences demonstrated that they could be grouped into three categories: (i) those with signal peptides containing leader peptidase I cleavage sites, (ii) those with signal peptides containing leader peptidase II cleavage sites, and (iii) those with non-cleavable hydrophobic membrane-spanning sequences. Triton X-114 detergent phase partitioning of individual T. pallidum-AP fusions revealed several clones whose AP activity partitioned preferentially into the hydrophobic detergent phase. Several of these fusion proteins were subsequently shown to be acylated by Escherichia coli following [3H]-palmitate labelling, indicating their lipoproteinaceous nature. DNA and amino acid sequence analysis of one acylated fusion protein, Tp75, confirmed the presence of a hydrophobic N-terminal signal sequence containing a consensus leader peptidase II recognition site. The DNA sequence of Tp75 also indicates that this is a previously unreported T. pallidum lipoprotein. T. pallidum-AP fusion proteins which partitioned into the hydrophobic detergent phase but did not incorporate palmitate were also identified. DNA and amino acid analysis of one such clone, Tp70, showed no cleavable signal but had a significant hydrophobic region of approximately 20 residues, consistent with a membrane-spanning domain. Immunoblot analysis of T. pallidum-AP fusions detected with a monoclonal antibody specific for AP identified several fusion proteins which migrated as doublets separated in apparent electrophoretic mobility by no more than 3 kDa. [35S]-methionine pulse-chase incorporation showed that the doublet AP fusions represented precursor and processed forms of the same protein. DNA and amino acid sequence analysis of clones expressing processed fusion proteins demonstrated hydrophobic N-terminal signal sequences containing consensus leader peptidase I recognition sites.