Detection of large COOH-terminal domains processed from the precursor of Serratia marcescens serine protease in the outer membrane of Escherichia coli.

The Serratia marcescens serine protease gene encoding a 1,045-amino-acid precursor protein of 112 kDa directs excretion of the mature protease of ca. 58 kDa through the outer membrane of Escherichia coli. A typical signal peptide of 27 amino acids and a large COOH-terminal domain of the precursor are both functionally essential for the excretion of the mature protease into the medium. Sequence analysis of the fragment peptides of the mature protease as well as site-directed mutagenesis indicated that the COOH-terminus of the mature enzyme was Asp645. By using the polyclonal antibody against the 112-kDa precursor protein, not only the intact precursor but also two proteins, C-1 (40 kDa) and C-2 (38 kDa), corresponding to the processed COOH-terminal domains were detected in the insoluble fraction of E. coli cells. Further fractionation by sucrose density gradient centrifugation showed that C-1 and C-2 were localized in the outer membrane. The NH2-terminal residues of C-1 and C-2 were determined to be Ala702 and Phe717, respectively. All these data suggest that the precursor is cleaved at three positions, between Asp645-Ser646, Glu701-Ala702, and Gly716-Phe717, probably by the self-processing activity in the normal excretion pathway through the outer membrane.     

Specific excretion of Serratia marcescens protease through the outer membrane of Escherichia coli.

A DNA fragment of Serratia marcescens directing an extracellular serine protease (Mr, 41,000) was cloned in Escherichia coli. The cloned fragment caused specific excretion of the protease into the extracellular medium through the outer membrane of E. coli host cells in parallel with their growth. No excretion of the periplasmic enzymes of host cells occurred. The cloned fragment contained a single open reading frame of 3,135 base pairs coding a protein of 1,045 amino acids (Mr 112,000). Comparison of the 5' nucleotide sequence with the N-terminal amino acid sequence of the protease indicated the presence of a typical signal sequence. The C-terminal amino acid of the enzyme was found at position 408, as deduced from the nucleotide sequence. Artificial frameshift mutations introduced into the coding sequence for the assumed distal polypeptide after the C terminus of the protease caused complete loss of the enzyme production. It was concluded that the Serratia serine protease is produced as a 112-kilodalton proenzyme and that its N-terminal signal peptide and a large C-terminal part are processed to cause excretion of the mature protease through the outer membrane of E. coli cells.     

Unique precursor structure of an extracellular protease, aqualysin I, with NH2- and COOH-terminal pro-sequences and its processing in Escherichia coli

Aqualysin I is a subtilisin-type serine protease which is secreted into the culture medium by Thermus aquaticus YT-1, an extremely thermophilic Gram-negative bacterium. The nucleotide sequence of the entire gene for aqualysin I was determined, and the deduced amino acid sequence suggests that aqualysin I is produced as a large precursor, consisting of at least three portions, an NH2-terminal pre-pro-sequence (127 amino acid residues), the protease (281 residues), and a COOH-terminal pro-sequence (105 residues). When the cloned gene was expressed in Escherichia coli cells, aqualysin I was not secreted. However, a precursor of aqualysin I lacking the NH2-terminal pre-pro-sequence (38-kDa protein) accumulated in the membrane fraction. On treatment of the membrane fraction at 65 degrees C, enzymatically active aqualysin I (28-kDa protein) was produced in the soluble fraction. When the active site Ser residue was replaced with Ala, cells expressing the mutant gene accumulated a 48-kDa protein in the outer membrane fraction. The 48-kDa protein lacked the NH2-terminal 14 amino acid residues of the precursor, and heat treatment did not cause any subsequent processing of this precursor. These results indicate that the NH2-terminal signal sequence is cleaved off by a signal peptidase of E. coli, and that the NH2- and COOH-terminal pro-sequences are removed through the proteolytic activity of aqualysin I itself, in that order. These findings indicate a unique four-domain structure for the aqualysin I precursor; the signal sequence, the NH2-terminal pro-sequence, mature aqualysin I, and the COOH-terminal pro-sequence, from the NH2 to the COOH terminus.     

Extracellular Production of a Serratia marcescens Serine Protease in Escherichia coli

The Serratia marcescens serine protease (SSP) is one of the extracellular enzymes secreted from this Gram-negative bacterium. When the ssp gene, which encodes a SSP precursor (preproSSP) composed of a typical NH₂-terminal signal peptide, a mature enzyme domain, and a large COOH-terminal pro-region, is expressed in Escherichia coli, the mature protease is excreted through the outer membrane into the medium. The COOH-terminal pro-region, which is integrated into the outer membrane, provides the essential function for the export of the mature protein across the outer membrane. This is a very simple pathway, in contrast to the general secretory pathway exemplified by the secretion of a pullulanase from Klebsiella oxytoca, in which many separately encoded accessory proteins are required for the transport through the outer membrane. Moreover, the NH₂-terminal region of 71 amino acid residues of the COOH-terminal pro-sequence plays an essential role, as an “intramolecular chaperone,” in the folding of the mature enzyme in the medium. In addition to ssp, the S. marcescens strain contains two ssp homologues encoding proteins similar to SSP in amino acid sequence and size, but with no protease activity. Characterization of the homologue proteins and chimeric proteins between the homologues and SSP, all of which are produced in E. coli, has shown that they are membrane proteins that are localized in the outer membrane in the same manner as for SSP. By use of the COOH-terminal domain of SSP, pseudoazurin was exported to the cell surface of E. coli, which proves the usefulness of the SSP secretory system in the export of foreign proteins across the outer membrane.     

Subcellular location and unique secretion of the hemolysin of Serratia marcescens

It is shown that Serratia marcescens exports a hemolysin to the cell surface and secretes it to the extracellular space. Escherichia coli containing the cloned hemolysin genes shlA and shlB exported and secreted the S. marcescens hemolysin. A nonhemolytic secretion-incompetent precursor of the hemolysin, designated ShlA*, was synthesized in a shlB deletion mutant and accumulated in the periplasmic space of E. coli. Immunogold-labeled ultrathin sections revealed ShlA* bound to the outer face of the cytoplasmic membrane and to the inner face of the outer membrane. A number of mutants carrying 3' deletions in the shlA gene secreted truncated polypeptides, the smallest of which contained only 261 of the 1578 amino acids of the mature ShlA hemolysin, showing that the information for export to the cell surface of E. coli and secretion into the culture medium is located in the NH2-terminal segment of the hemolysin. We propose a secretion pathway in which ShlA and ShlB are exported across the cytoplasmic membrane via a signal sequence-dependent mechanism. ShlB is integrated into the outer membrane. ShlA is translocated across the outer membrane with the help of ShlB. During the latter export process or at the cell surface, ShlA acquires the hemolytically active conformation and is released to the extracellular space. The hemolysin secretion pathway appears to be different from any other secretion system hitherto reported and involves only a single specific export protein.     

Mechanisms of activation and secretion of a cell-associated precursor of an exocellular protease of Pseudomonas aeruginosa 34362A

An inactive precursor to the active exocellular protease 1 of Pseudomonas aeruginosa is cell-associated and located primarily in the periplasmic space. We have studied factors that bring about activation of the precursor in vitro in order to shed some light on the process of its activation and secretion in vivo. A variety of diverse procedures were shown to effect irreversible activation. Several mild non-enzymatic procedures were effective, such as dialysis of an ammonium sulfate precipitate against neutral buffers, gel filtration (Sephadex G-100), and ion-exchange chromatography (DEAE-cellulose). Activation also resulted following treatment with anionic detergents (sodium dodecyl sulfate, N-lauroyl sarcosine) and deoxycholate. Limited exposure to any of several proteases with different specificities also resulted in activation. The kinetics of detergent-catalyzed activation reveals a long lag followed by rapid activation, suggesting at least a two-stage process. The precursor and the mature protease 1 have indistinguishable molecular masses (33 kDa), as measured by sodium dodecyl sulfate/polyacrylamide gel electrophoresis of these proteins purified by immunoabsorbance chromatography under denaturing conditions. Further, both precursor and protease have identical N-terminal alanine. Our results suggest that it is improbable that activation is the result of proteolytic processing of the precursor itself, but rather that it may involve the removal of a non-covalently associated inhibitor molecule. Hydrophobic interaction chromatography on octyl-Sepharose revealed that activation was accompanied by a significant change in the hydrophobicity, pointing to a significant change in the conformation of the precursor and the mature protease. A mutant has been studied which accumulates activatable precursor in the periplasm but releases no active enzyme into the culture medium, supporting the hypothesis that secretion through the inner and outer membranes proceed by different mechanisms. Comparison of outer membranes of protease-secreting strains (34362A and PAKS 1) and a protease-negative mutant (PAKS 18) which accumulates precursor has shown that there is a change in the outer membrane protein profile in the latter.     

Characterization of an Escherichia coli rotA mutant, affected in periplasmic peptidyl-prolyl cis/trans isomerase

The rotA gene of Escherichia coli encodes a peptidyl-prolyl cis/trans isomerase (PPlase), which is supposed to catalyse protein folding in the periplasm. To investigate the importance of the enzyme, the rotA gene was cloned and a chromosomal deletion mutant was created. The rotA mutant was normally viable. No residual PPlase activity could be detected in the periplasmic fraction of the mutant. Comparison of the patterns of periplasmic and outer membrane proteins by SDS-PAGE revealed no differences in protein composition between the rotA mutant and its parental strain. Similarly, the kinetics of periplasmic protein folding and outer membrane protein assembly appeared unaffected by the rotA mutation. Our results show that the periplasmic PPlase of E. coli is not essential and that the protein does not play an important role in protein folding.     

Secretion of periplasmic PhoA protein during its supersynthesis into the medium using outer membrane vesicles. Features of chemical composition of the vesicles and membranes of Escherichia coli secreting cells

E. coli K12802 cells transformed by multicopy plasmid with phoA gene acquire the ability to oversynthesize alkaline phosphatase, secrete it into the cultural medium, and accumulate the precursor of this enzyme. The dynamics of enzyme production and secretion as well as cytomorphological changes revealed the existence of a mechanism of selective enzyme secretion into the medium. It is characterized by a decrease of enzyme specific activity in periplasm and its increase in cultural medium, appearance of numerous local zones of adhesion of cytoplasmic and outer membranes, formation of large extracellular outer membrane vesicles containing PhoA protein on the cell poles, and their release into the medium. We isolated the vesicles and found that they contain PhoA (in dominating quantity), several other periplasmic proteins, and matrix proteins of outer membranes. By their phospholipid and protein composition, they correspond to the fraction of outer membranes which have the largest density and sedimentation rate and, apparently, contain no lipoprotein.     

Iron transport systems of Serratia marcescens.

Serratia marcescens W225 expresses an unconventional iron(III) transport system. Uptake of Fe3+ occurs in the absence of an iron(III)-solubilizing siderophore, of an outer membrane receptor protein, and of the TonB and ExbBD proteins involved in outer membrane transport. The three SfuABC proteins found to catalyze iron(III) transport exhibit the typical features of periplasmic binding-protein-dependent systems for transport across the cytoplasmic membrane. In support of these conclusions, the periplasmic SfuA protein bound iron chloride and iron citrate but not ferrichrome, as shown by protection experiments against degradation by added V8 protease. The cloned sfuABC genes conferred upon an Escherichia coli aroB mutant unable to synthesize its own enterochelin siderophore the ability to grow under iron-limiting conditions (in the presence of 0.2 mM 2.2'-dipyridyl). Under extreme iron deficiency (0.4 mM 2.2'-dipyridyl), however, the entry rate of iron across the outer membrane was no longer sufficient for growth. Citrate had to be added in order for iron(III) to be translocated as an iron citrate complex in a FecA- and TonB-dependent manner through the outer membrane and via SfuABC across the cytoplasmic membrane. FecA- and TonB-dependent iron transport across the outer membrane could be clearly correlated with a very low concentration of iron in the medium. Expression of the sfuABC genes in E. coli was controlled by the Fur iron repressor gene. S. marcescens W225 was able to synthesize enterochelin and take up iron(III) enterochelin. It contained an iron(III) aerobactin transport system but lacked aerobactin synthesis. This strain was able to utilize the hydroxamate siderophores ferrichrome, coprogen, ferrioxamine B, rhodotorulic acid, and schizokinen as sole iron sources and grew on iron citrate as well. In contrast to E. coli K-12, S. marcescens could utilize heme. DNA fragments of the E. coli fhuA, iut, exbB, and fur genes hybridized with chromosomal S. marcescens DNA fragments, whereas no hybridization was obtained between S. marcescens chromosomal DNA and E. coli fecA, fhuE, and tonB gene fragments. The presence of multiple iron transport systems was also indicated by the increased synthesis of at least five outer membrane proteins (in the molecular weight range of 72,000 to 87,000) after growth in low-iron media. Serratia liquefaciens and Serratia ficaria produced aerobactin, showing that this siderophore also occurs in the genus Serratia.     

Correct folding of alpha-lytic protease is required for its extracellular secretion from Escherichia coli

alpha-Lytic protease is a bacterial serine protease of the trypsin family that is synthesized as a 39-kD preproenzyme (Silen, J. L., C. N. McGrath, K. R. Smith, and D. A. Agard. 1988. Gene (Amst.). 69: 237-244). The 198-amino acid mature protease is secreted into the culture medium by the native host, Lysobacter enzymogenes (Whitaker, D. R. 1970. Methods Enzymol. 19:599-613). Expression experiments in Escherichia coli revealed that the 166-amino acid pro region is transiently required either in cis (Silen, J. L., D. Frank, A. Fujishige, R. Bone, and D. A. Agard. 1989. J. Bacteriol. 171:1320-1325) or in trans (Silen, J. L., and D. A. Agard. 1989. Nature (Lond.). 341:462-464) for the proper folding and extracellular accumulation of the enzyme. The maturation process is temperature sensitive in E. coli; unprocessed precursor accumulates in the cells at temperatures above 30 degrees C (Silen, J. L., D. Frank, A. Fujishige, R. Bone, and D. A. Agard. 1989. J. Bacteriol. 171:1320-1325). Here we show that full-length precursor produced at nonpermissive temperatures is tightly associated with the E. coli outer membrane. The active site mutant Ser 195----Ala (SA195), which is incapable of self-processing, also accumulates as a precursor in the outer membrane, even when expressed at permissive temperatures. When the protease domain is expressed in the absence of the pro region, the misfolded, inactive protease also cofractionates with the outer membrane. However, when the folding requirement for either wild-type or mutant protease domains is provided by expressing the pro region in trans, both are efficiently secreted into the extracellular medium. Attempts to separate folding and secretion functions by extensive deletion mutagenesis within the pro region were unsuccessful. Taken together, these results suggest that only properly folded and processed forms of alpha-lytic protease are efficiently transported to the medium.     

Activation of the proteinase B precursor of the yeast Saccharomyces cerevisiae by autocatalysis and by an internal sequence.

Proteinase B (PrB) is a subtilisin-like serine protease found in the vacuole of the yeast Saccharomyces cerevisiae. It is first made as a large precursor that consists of a putative signal sequence, a 260-amino acid pro region, the serine protease domain, and two small COOH-terminal post regions (Moehle, C. M., Dixon, C. K., and Jones, E. W. (1989) J. Cell Biol. 108, 309-324). This precursor is glycosylated and proteolytically processed at least three times before mature enzyme is formed. To determine whether an intact PrB catalytic site is required for proteolytic processing of the precursor, point mutations were generated at the codons for the active site serine or aspartate residues by site-directed mutagenesis. The effect of these mutations on PrB processing suggests that the large pro region may be cleaved by an intramolecular, autocatalytic mechanism. The properties of a prb1 mutant that accumulates a 37-kDa precursor in addition to mature sized mutant PrB antigen suggests that the final proteolytic cleavage step is also autocatalytic. A prb1 deletion that lacks codons for the large pro region was made to test whether this part of the precursor is required for formation of mature PrB. Analysis of this mutant revealed two functions for this region: it prevents N-linked glycosylation of the serine protease domain and it allows the PrB precursor to be processed by proteinase A. The pro region can fulfill this latter function if added as a separate molecule, so long as glycosylation of the catalytic domain is prevented by other means.     

A 38 kDa precursor protein of aqualysin I (a thermophilic subtilisin-type protease) with a C-terminal extended sequence: its purification and in vitro processing

The precursor of aqualysin I, an extracellular subtilisin-type protease produced by Thermus aquaticus, consists of four domains: an N-terminal signal peptide, an N-terminal pro-sequence, a protease domain, and a C-terminal extended sequence. In an Escherichia coli expression system for the aqualysin I gene, a 38 kDa precursor protein consisting of the protease domain and the C-terminal extended sequence is accumulated in the membrane fraction and processed to a 28 kDa mature enzyme upon heat treatment at 65°C. The 38 kDa precursor protein is separated as a soluble form from denatured E. coli proteins after heat treatment. Accordingly, purification of the 38 kDa proaqualysin I was performed using chromatography. The purified precursor protein gave a single band on SDS-polyacrylamide gels. The precursor protein exhibited proteolytic activity comparable to that of the mature enzyme. The purified precursor protein was processed to the mature enzyme upon heat treatment. The processing was inhibited by diisopropyl fluorophosphate. The processing rate increased upon either the addition of mature aqualysin I or upon an increase in the concentration of the precursor, suggesting that the cleavage of the C-terminal extended sequence occurs through an intermolecular self-processing mechanism.     

Thermosensitive omsA mutation of Escherichia coli that causes thermoregulated release of periplasmic proteins.

A mutant of Escherichia coli with a thermosensitive defect, possibly in the outer membrane (omsA mutant), was isolated from E. coli K-12 by mutagenization and selection for thermosensitivity and beta-lactam supersensitivity of growth. The mutant also showed very high sensitivity to other antibiotics, such as macarbomycin, midecamycin, rifampin, and bacitracin. The mutation was recessive to the wild type and was mapped at about 4 min on the E. coli chromosome between fhuA and metD. The mutation caused rapid release into the medium of periplasmic enzymes such as RTEM penicillinase but practically no cytoplasmic enzyme when cells grown at 30 degrees C were transferred to 37 or 42 degrees C. Electron microscopic observations showed many large double-layered vesicles attached to the surface of cells incubated at 42 degrees C. We conclude that the mutant had a mutation that caused a temperature-dependent defect in the outer membrane structure or its assembly (named an oms mutation). The omsA mutant may be useful for production of periplasmic proteins, which it releases into the culture medium on shift up of temperature.     

Excretion of the penicillinase of an alkalophilic Bacillus sp. through the Escherichia coli outer membrane is caused by insertional activation of the kil gene in plasmid pMB9.

Most of the cloned penicillinase from alkalophilic Bacillus sp. strain 170 and alkaline phosphatase were released into the culture medium by Escherichia coli strains bearing plasmid pEAP1 or pEAP2 (T. Kudo, C. Kato, and K. Horikoshi, J. Bacteriol. 156:949-951, 1983). We analyzed the basis for excretion of periplasmic enzymes in the cells bearing these plasmids. Several experiments such as subcloning, insertion of a chloramphenicol acetyltransferase cartridge, and DNA sequencing were done. A dormant kil gene in plasmid pMB9 was expressed by a promoter of the inserted DNA fragment of alkalophilic Bacillus sp. strain 170, and as a result, the outer membrane of E. coli became permeable, allowing the proteins to be excreted without cell lysis.     

Molecular and enzymatic properties of furin, a Kex2-like endoprotease involved in precursor cleavage at Arg-X-Lys/Arg-Arg sites.

We have recently shown that furin, a mammalian homologue of the yeast precursor-processing endoprotease Kex2, is involved in precursor cleavage at sites marked by the Arg-X-Lys/Arg-Arg motif within the constitutive secretory pathway. In this study, we analyzed molecular and enzymatic properties of furin expressed in Chinese hamster ovary cells using gene transfer techniques. COOH-terminal truncation analyses indicate that the polypeptide region significantly conserved among the Kex2 family members is required for the endoprotease activity of furin, while the COOH-terminal unconserved region containing the Cys-rich domain and the transmembrane domain is dispensable. A mutant of furin truncated up to the transmembrane domain from the COOH-terminus was secreted into the culture medium as an active form. The sequence requirements for precursor cleavage of this truncated furin determined in vitro were similar to those of wild-type furin determined by expression studies in cultured cells. It had a strong resemblance to the Kex2 protease in the inhibitor profile and pH dependency. These observations support the notion that furin is the endogenous endoprotease involved in precursor cleavage at Arg-X-Lys/Arg-Arg sites.     

Proteome-based identification of fusion partner for high-level extracellular production of recombinant proteins in Escherichia coli

Extracellular production of recombinant proteins in Escherichia coli has several advantages over cytoplasmic or periplasmic production. However, nonpathogenic laboratory strains of E. coli generally excrete only trace amounts of proteins into the culture medium under normal growth conditions. Here we report a systematic proteome-based approach for developing a system for high-level extracellular production of recombinant proteins in E. coli. First, we analyzed the extracellular proteome of an E. coli B strain, BL21(DE3), to identify naturally excreted proteins, assuming that these proteins may serve as potential fusion partners for the production of recombinant proteins in the medium. Next, overexpression and excretion studies were performed for the 20 selected fusion partners with molecular weights below 40 kDa. Twelve of them were found to allow fused proteins to excrete into the medium at considerable levels. The most efficient excreting fusion partner, OsmY, was used as a carrier protein to excrete heterologous proteins into the medium. E. coli alkaline phosphatase, Bacillus subtilis alpha-amylase, and human leptin used as model proteins could all be excreted into the medium at concentrations ranging from 5 to 64 mg/L during the flask cultivation. When only the signal peptide or the mature part of OsmY was used as a fusion partner, no such excretion was observed; this confirmed that these proteins were truly excreted rather than released by outer membrane leakage. The recombinant protein of interest could be recovered by cleaving off the fusion partner by enterokinase as demonstrated for alkaline phosphatase as an example. High cell density cultivation allowed production of these proteins to the levels of 250-700 mg/L in the culture medium, suggesting the good potential of this approach for the excretory production of recombinant proteins.     

Construction of an excretion vector and extracellular production of human growth hormone from Escherichia coli

A new excretion vector, pEAP8, was constructed to develop an excretion system for Escherichia coli. This plasmid, derived from pEAP37, carried the weakly activated kil gene of plasmid pMB9 [Kobayashi et al., J. Bacteriol. 166 (1986) 728-732] and the penicillinase promoter and signal region of an alkalophilic Bacillus sp. to excrete foreign gene products. A gene for human growth hormone (hGH) was joined to this signal sequence through the HindIII site. The recombinant plasmid p8hGH1 thus constructed, was introduced into E. coli. The hybrid protein which was produced in E. coli carrying p8hGH1 was processed during transport through the inner membrane, with the mature hGH being excreted into the medium through the outer membrane which was made permeable by the action of the kil gene. The N-terminal amino acid sequence and the biological activity of the extracellular hGH were consistent with those of the authentic hGH.     

Nucleotide sequences of the sfuA, sfuB, and sfuC genes of Serratia marcescens suggest a periplasmic-binding-protein-dependent iron transport mechanism.

The cloned sfu region of the Serratia marcescens chromosome confers the ability to grow on iron-limited media to an Escherichia coli K-12 strain that is unable to synthesize a siderophore. This DNA fragment was sequenced and found to contain three genes termed sfuA, sfuB, and sfuC, arranged and transcribed in that order. The sfuA gene encoded a periplasmic polypeptide with calculated molecular weights of 36,154 for the precursor and 33,490 for the mature protein. The sfuB gene product was a very hydrophobic protein with a molecular weight of 56,589. The sfuC gene was found to encode a rather polar but membrane-bound protein with a molecular weight of 36,671 which exhibited strong homology to consensus sequences of nucleotide-binding proteins. The number, structural characteristics, and locations of the SfuABC proteins were typical of a periplasmic-binding-protein-dependent transport mechanism. How Fe3+ is solubilized and taken up across the outer membrane remains an enigma.     

Molecular structure of Rarobacter faecitabidus protease I. A yeast-lytic serine protease having mannose-binding activity.

Rarobacter faecitabidus protease I (RPI) is a serine protease exhibiting lytic activity toward living yeast cells. RPI is similar to elastase in its substrate specificity and has a lectin-like affinity for mannose. The gene encoding RPI was cloned to elucidate its structure and function. And its nucleotide sequence revealed that it contains an open reading frame encoding a 525-amino acid protein. Homology comparison indicated that pre-pro-RPI consists of three domains: (1) an NH2-terminal prepro domain not found in the mature form of RPI, (2) a protease domain homologous to the trypsin family of serine proteases, and (3) a COOH-terminal domain homologous to the COOH-terminal part of Oerskovia xanthineolytica beta-1,3-glucanase and the NH2-terminal part of the ricin B chain, a lectin isolated from the part of the ricin B chain, a lectin isolated from the castor bean. The RPI gene and its mutant were subsequently expressed in Escherichia coli under its beta-galactosidase promoter to investigate the function of the COOH-terminal domain. The mutant RPI, whose COOH-terminal domain was truncated by site-directed mutagenesis, lost both its mannose-binding and yeast-lytic activity, although the protease activity was not affected. These findings suggest that the COOH-terminal domain actually participates in the mannose-binding activity and is required for yeast-lytic activity.