Caseicin 80: purification and characterization of a new bacteriocin from Lactobacillus casei

When grown in complex or synthetic media, Lactobacillus casei B 80 synthesizes a mitomycin C-inducible polypeptide with very specific bactericidal activity against the sensitive strain Lactobacillus casei B 109. The amount of secreted bacteriocin in the culture solution was low, about 1 mg/l. The bacteriocin which we called caseicin 80, was also detectable in cell extracts, although only 2% of the total activity was retained intracellularly. Caseicin 80 was concentrated by ultrafiltration and purified by cation exchange chromatography with Cellulose SE-23 and Superose. The molecular weight was in the range of M _r=40,000–42,000 and the isoelectric point was pH 4.5.     

Antibacterial polypeptides of Lactobacillus species

Twelve of 79 strains of the genus Lactobacillus , mainly isolated from plants or fermenting material, were found to inhibit at least one of the nine indicator strains of the species Lact. brevis, Pediococcus damnosus and Leucanostoc oenos . The antimicrobial activities from Lact. brevis B 37 and Lact. casei B 80 were caused by polypeptides detectable in the culture liquids. They are bacteriocins with a narrow antimicrobial spectrum. Brevicin 37 from Lact. brevis B 37 was active against many lactic acid bacteria and Nocardia corallina , whereas caseicin 80 from Lact. casei B 80 inhibits only one other strain of Lact. casei . Brevicin 37 is stable at 121C, caseicin 80 is inactivated above 60C, and both are inactivated under alkaline conditions.     

A yeast mutant with glucose-resistant formation of mitochondrial enzymes

Summary Yeast mutants with glucose-insensitive formation of mitochondrial enzymes were isolated starting with a strain completely lacking alcohol dehydrogenase activity. The mutations could uniquely be attributed to a single nuclear gene, designated CCR80. They were largely dominant. Glucose-resistant enzyme formation was most prominent with regard to mitochondrial enzymes succinate dehydrogenase and NADH: cytochrome c oxidoreductase. The effect of CCR80 ^r mutations was rather small but significant on the gluconeogenetic enzymes isocitrate lyase, malate synthase and fructose-1,6-bisphosphatase and on invertase synthesis. The repressive effect of maltose in CCR80 ^r mutants was also reduced showing that glucose-resistance is not caused by a mere hexose uptake defect. This regulatory disorders were not accompanied by reduced levels of glycolytic enzymes or drastically altered levels of glycolytic intermediates.Aerobic fermentation of glucose was almost completely inhibited in the mutants; anaerobic glucose degradation was reduced but not completely abolished. Therefore, the mutants appear to be altered in the regulation of glycolysis. A largely glucose-resistant synthesis of respiratory enzymes is obviously a corollary of this alteration.     

Interaction of super-repressible and dominant constitutive mutations for the synthesis of galactose pathway enzymes in Saccharomyces cerevisiae

Summary Two dominant uninducible mutant alleles in the gal80 locus were identified. The GAL80 ^s-1 and GAL80 ^s-2 mutants showed novel phenotypes in response to the newly isolated GAL81-1 mutant allele, a dominant constitutive mutation linked to the gal4 locus; the GAL80 ^s-1 GAL81-1 strain was inducible and the GAL80 ^s-2 GAL81-1 strain was uninducible. Many galactose positive revertants from the GAL80 ^s-2 GAL81-1 strain were isolated. It was proved that each revertant was due to a secondary mutation either in the gal80 or GAL81 locus, whereas revertants due to mutation at the supposed controlling site for the structural gene cluster of the galactose-pathway enzymes have not been isolated.This study was supported in part by grant no. 048164 to Y. Oshima from the Scientific Research Fund of the Ministry of Eduction, Japan     

Karlotoxin mediates grazing by Oxyrrhis marina on strains of Karlodinium veneficum

Karlodinium veneficum is a common member of temperate, coastal phytoplankton assemblages that occasionally forms blooms associated with fish kills. Here, we tested the hypothesis that the cytotoxic and ichthyotoxic compounds produced by K. veneficum, karlotoxins, can have anti-grazing properties against the heterotrophic dinoflagellate, Oxyrrhis marina. The sterol composition of O. marina (>80% cholesterol) renders it sensitive to karlotoxin, and does not vary substantially when fed different algal diets even for prey that are resistant to karlotoxin. At in situ bloom concentrations (10⁴–10⁵ K. veneficum ml⁻¹), grazing rates (cells ingested per Oxyrrhis h⁻¹) on toxic K. veneficum strain CCMP 2064 were 55% that observed on the non-toxic K. veneficum strain MD5. At lower prey concentrations typical of in situ non-bloom levels (<10³ cells ml⁻¹), grazing rates (cells ingested per Oxyrrhis h⁻¹) on toxic K. veneficum strain CCMP 2064 were 70–80% of rates on non-toxic strain MD5. Growth of O. marina was significantly suppressed when fed the toxic strain of K. veneficum. Experiments with mixed prey cultures, where non-toxic strain MD5 was fluorescently stained, showed that the presence of toxic strain CCMP 2064 inhibited grazing of O. marina on the co-occurring non-toxic strain MD5. Exogenous addition of a sub-lethal dose (100 ng ml⁻¹) of purified karlotoxin inhibited grazing of O. marina by approximately 50% on the non-toxic K. veneficum strain MD5 or the cryptophyte S. major. These results identify karlotoxin as an anti-grazing compound for those grazers with appropriate sterol composition (i.e., desmethyl sterols). This strategy is likely to be an important mechanism whereby growth of K. veneficum is uncoupled from losses due to grazing, allowing it to form ichthyotoxic blooms in situ.     

Comparisons of Characteristics of Mercury-Tolerant Bacterium Pseudomonas oleovorans G-1 and Its Mercury-Sensitive Mutant Strain

An Hg²⁺-sensitive mutant strain was isolated from an Hg²⁺-tolerant bacterium Pseudomonas oleovorans G-1 strain by mutagenesis with N-methyl-N′-nitro-N-nitrosoguanidine. The Hg²⁺-sensitive mutant strain was about 10-times as sensitive to Hg²⁺ as the parent strain. Moreover, the mutant strain was considerably more sensitive to Cr⁶⁺ than the parent strain, but it did not show an appreciable change in sensitivity to Cd²⁺ and Cu²⁺. The mutant strain was considerably more sensitive to antibiotics achromycin, chloramphenicol and streptomycin than the parent strain. A more rigid structure was observed in the cell envelope of the mutant strain than the parent strain under transmission electron microscope. Higher amounts of DNA but less protein and RNA were found in the mutant strain compared to the parent strain. Disc electrophoretic patterns showed some differences in protein bands between the parent and mutant strain.     

Genetic control of basal level of alkaline phosphatase in Escherichia coli

Summary The basis for a difference in basal levels of alkaline phosphatase in two strains of E. coli has been examined. It was found that the enzyme level characteristic of a highlevel strain was not conferred upon a low level strain merely by the transfer of the pho ⁺, phoR⁺ or phoS ⁺ allele from the high-level strain to the low level strain. Such strains may have slightly altered basal levels of enzyme, but these changes are not quantitatively sufficient to account for the strain differences. Approximately 20% of the recombinants which receive the phoS ⁺ gene show a level of phosphatase intermediate between the high and low-level strains. The effect is specific for the basal level of phosphatase, since it does not affect the levels of three other enzymes, or the derepressed level of alkaline phosphatase itself. This latter fact is consistent with the view that the intermediate level strains have an intermediate level of repressor of alkaline phosphatase under repressed conditions. It is suggested that the basal level of enzyme is affected by several genes in addition to those previously described, and that the intermediate level strains have received the allele of one or more of these loci from the high level strain.     

Extensive manipulation of caseicins A and B highlights the tolerance of these antimicrobial peptides to change

Caseicins A and B are low-molecular-weight antimicrobial peptides which are released by proteolytic digestion of sodium caseinate. Caseicin A (IKHQGLPQE) is a nine-amino-acid cationic peptide, and caseicin B (VLNENLLR) is a neutral eight-amino-acid peptide; both have previously been shown to exhibit antibacterial activity against a number of pathogens, including Cronobacter sakazakii. Previously, four variants of each caseicin which differed subtly from their natural counterparts were generated by peptide synthesis. Antimicrobial activity assays revealed that the importance of a number of the residues within the peptides was dependent on the strain being targeted. In this study, this engineering-based approach was expanded through the creation of a larger collection of 26 peptides which are altered in a variety of ways. The investigation highlights the generally greater tolerance of caseicin B to change, the fact that changes have a more detrimental impact on anti-Gram-negative activity, and the surprising number of variants which exhibit enhanced activity against Staphylococcus aureus.     

In vitro synthesis and repression of argininosuccinase in Escherichia coli K12; partial purification of the arginine repressor

Summary 80dargECBH DNA has been used to direct cell-free synthesis of argininosuccinase, the argH gene product in Escherichia coli K12. In vitro enzyme synthesis is sensitive to repression by partially purified preparations from an argR ⁺ strain but not by corresponding preparations from an argR ^- strain. Using DNA-cellulose chromatography, approximately seventyfold purification of repressor has been obtained. The partially purified preparation represses argininosuccinase synthesis but has no effect on -galactosidase synthesis.     

Studies on hydrogenase activity and chlorobenzene respiration in <Emphasis Type="Italic">Dehalococcoides</Emphasis> sp. strain CBDB1

Hydrogen oxidation and electron transport were studied in the chlorobenzene-utilizing anaerobe Dehalococcoides sp. strain CBDB1. While Cu²⁺ and Hg²⁺ ions irreversibly inhibited hydrogenase activity in intact cells, Ni²⁺ ions inhibited reversibly. About 80% of the initial hydrogenase activity was inactivated within 30 s when the cells were exposed to air. In contrast, hydrogenase was active at a redox potential of +10 mV when this redox potential was established anoxically with a redox indicator. Viologen dyes served both as electron acceptor for hydrogenase and electron donor for the dehalogenase. A menaquinone analogue, 2,3-dimethyl 1,4-naphthoquinone, served neither as electron acceptor for the hydrogenase nor as electron donor for the dehalogenase. In addition, the menaquinone antagonist 2-n-heptyl-4-hydroxyquinoline-N-oxide had no effect on dechlorination catalyzed by cell suspensions or isolated membranes with hydrogen as electron donor, lending further support to the notion that menaquinone is not involved in electron transport. The ionophores tetrachlorosalicylanilide and carbonylcyanide m-chlorophenylhydrazone did not inhibit dechlorination by cell suspensions, indicating that strain CBDB1 does not require reverse electron transport. The ATP-synthase inhibitor N,N-dicyclohexylcarbodiimide inhibited the dechlorination reaction with cell suspensions; however, the latter effect was partially relieved by the addition of tetrachlorosalicylanilide. 1,2,3,4-Tetrachlorobenzene strongly inhibited dechlorination of other chlorobenzenes by cell suspensions with hydrogen as electron donor, but it did not interfere with either hydrogenase or dehalogenase activity.     

Inter-root movement of Azospirillum brasilense and subsequent root colonization of crop and weed seedlings growing in soil

Inter-root movement and dispersion of the beneficial bacterium Azospirillum brasilense were monitored in root systems of wheat seedlings growing in the field and in growth chamber soil trays. Two strains were used, a motile wild-type strain (Cd, mot⁺) and a motility deficient strain (mot^–), which was derived from the Cd strain. Root colonization by two wild-type strains (Cd and Sp-245) was studied in 64 plant species growing in pots in the greenhouse. The two wild-type strains of A. brasilense were capable of colonizing all tested plant species. In soil trays and in the field, mot⁺ cells moved from inoculated roots to non-inoculated roots of either wheat plants or weeds growing in the same field plot, but the mot^– strain did not move toward non-inoculated roots of either plant species. In the field, both mot⁺ and mot^– strains of A. brasilense survived well in the rhizosphere of wheat for 30 days, but only mot⁺ moved between different weeds, regardless of the species, botanical family, or whether they were annuals or perennials. In plant-free, water-saturated soils, either in columns or in the field, both strains remained at the inoculation site and did not move.It is proposed (a) that A. brasilense is not a plant-specific bacterium and that (b) colonization of the entire root system in soil is an active process determined by bacterial motility; it is not plant specific, but depends on the presence of plants. Correspondence to: Y. Bashan     

Observations on Nonconverting Phage,c-n71, Obtained from a Nontoxigenic Strain of Clostridium botulinum Type C

A nontoxigenic mutant (C-N71) obtained from a toxigenic strain of Clostridium botulinum type C, Stockholm, with nitrosoguanidine treatment was found to be lysogenic by the lysis test. Although the filtrate of a passaged lysate of this nontoxigenic but lysogenic strain, C-N71, lysed cells of the nontoxigenic strain C-AO2 equally as well as the converting phage c-st obtained from the strain C-Stockholm, it did not convert C-AO2 to the toxigenic state. The lysis spectrum of this filtrate was the same as that of the c-st phage. The ability of the filtrate to lyse the indicator cells, C-AO2, was destroyed neither by trypsin nor DNase but was inactivated by heat treatment at 80 C for 10 min. This suggested that the agent which caused lysis was not boticin but probably a phage. An electron micrograph of the complete phage, c-n71, which was similar in morphology to that of the c-st phage was obtained from the filtrate of strain C-N71. Anti-c-n71 phage rabbit serum neutralized both the lytic and the converting activities of the c-st phage. These findings strongly suggest that the c-n71 phage is a mutant of the c-st phage which lacks the gene controlling production of botulinum type C toxin.     

Production of the antimicrobial peptides Caseicin A and B by Bacillus isolates growing on sodium caseinate

Aims: The aim of this study was to identify Bacillus isolates capable of degrading sodium caseinate and subsequently to generate bioactive peptides with antimicrobial activity. Methods and results: Sodium caseinate (2·5% w/v) was inoculated separately with 16 Bacillus isolates and allowed to ferment overnight. Protein breakdown in the fermentates was analysed using gel permeation‐HPLC (GP‐HPLC) and screened for peptides (<3‐kDa) with MALDI‐TOF mass spectrometry. Caseicin A (IKHQGLPQE) and caseicin B (VLNENLLR), two previously characterized antimicrobial peptides, were identified in the fermentates of both Bacillus cereus and Bacillus thuringiensis isolates. The caseicin peptides were subsequently purified by RP‐HPLC and antimicrobial assays indicated that the peptides maintained the previously identified inhibitory activity against the infant formula pathogen Cronobacter sakazakii. Conclusions: We report a new method using Bacillus sp. to generate two previously characterized antimicrobial peptides from casein. Significance and impact of the study: This study highlights the potential to exploit Bacillus sp. or the enzymes they produce for the generation of bioactive antimicrobial peptides from bovine casein.     

Altering the composition of caseicins A and B as a means of determining the contribution of specific residues to antimicrobial activity

Caseicin A (IKHQGLPQE) and caseicin B (VLNENLLR) are antimicrobial peptides generated through the bacterial fermentation of sodium caseinate, and on the basis of this and previous studies, they are active against many Gram-negative pathogens (Cronobacter sakazakii, Cronobacter muytjensii, Salmonella enterica serovar Typhimurium, Escherichia coli, Klebsiella pneumoniae, and Pseudomonas fluorescens) as well as the Gram-positive organism Staphylococcus aureus. Here we describe further studies with the aim of establishing the importance of specific (charged and nonpolar aliphatic) residues within the caseicin peptides and the effects that they have on the bacteria listed above. In order to achieve our objective, we created four derivatives of each caseicin (A1 to A4 and B1 to B4) in which specific residues were altered, and results obtained with these derivatives were compared to wild-type caseicin activity. Although conversion of cationic residues to alanine in caseicins B1 (R8A change), A1 (K2A), A2 (H3A), and A3 (K2A-H3A) generally resulted in their activity against microbial targets being reduced or unaltered, C. sakazakii DPC6440 was unusual in that it displayed enhanced sensitivity to three peptides (caseicins A1, A3, and B2) in which positively charged residues had been eliminated. While the replacement of leucine with alanine in selected variants (B3 and B4) resulted in reduced activity against a number of strains of Cronobacter and, in some cases, S. Typhimurium, these changes enhanced the activities of these peptides against DPC6440 and a number of S. aureus strains. It is thus apparent that the importance of specific residues within the caseicin peptides is dependent on the strain being targeted.     

Characterization of Neurotoxigenic Clostridium butyricum Strain by DNA Hybridization Test and by in vivo and in vitro Germination Tests of Spores

The germination of spores of a neurotoxigenic Clostridium butyricum strain (BL 6340), which was isolated from infant botulism in Italy, and that of a non-toxigenic C. butyricum type strain (NCIB 7423) were studied. The spores of BL 6340 strain were killed at 80 C for 10 min, and required the mixture of L-alanine, L-lactate, glucose and bicarbonate for their optimal germination. These characteristics are the same as those of Clostridium botulinum type E strain, but different from those of NCIB 7423 strain. In a hybridization test, however, the labeled DNAs extracted from NCIB 7423 strain highly (98%) hybridized to the DNAs of the BL 6340 strain, but little (45%) to the DNAs of C. botulinum type E strain. The biochemical properties of the BL 6340 and NCIB 7423 strains were identical, but different from those of C. botulinum type E. These data confirmed that the BL 6340 strain belongs to C. butyricum species, but that only its characteristics of toxin production, its minimum requirements for germination, and the behavior of its spores to heat treatment are the same as those of C. botulinum type E. When conventionally raised suckling mice were injected with 5 × 10⁷ spores of BL 6340 strain intra- or orogastrically, botulism was not observed. However, 8- to 13-day-old mice had type E botulinum toxin in the large intestine 3 days after introduction of its spores.     

Resistance system of Mycobacterium bovis B.C.B. to aminoglycoside- and peptide-antibiotics. Comparison of resistant phenotypes between Mycobacterium tuberculosis and Mycobacterium bovis

The resistance system of Mycobacterium bovis (B.C.G.) to aminoglycoside-and peptide-antibiotics has been studied. The phenotype of mutants isolated from the parent B.C.G. strain by a single-step selection with an antibiotic were classified into the following three types: (1) resistant only to a low concentration (200 μg/ml) of kanamycin in Ogawa egg medium (k1R); (2) resistant to a low concentration (200 μg/ml) of viomycin and of capreomycin (2R); and (3) resistant to a high concentration (1,000 μg/ml or more) of kanamycin and low concentrations (100 to 200 μg/ml) of lividomycin and of paromomycin (KR). The mutants showing these phenotypes, k1R, 2R, and KR, were isolated from the parent strain by inoculating the strain into media containing 100 μg/ml of kanamycin, and 100 μ/g/ml of viomycin or capreomycin, and 1,000 μg/ml of kanamycin, respectively, at rates of 10^?5-10^?6, 10^?5-10^?6, and 10^?6-10^?7, respectively, in a total viable population of the parent strain. Unlike in the case of M. tuberculosis, no mutant could be isolated from the parent strain by use of enviomycin, lividomycin, and/or paromomycin. In contrast to the fact that quadruply resistant mutants were isolated directly from the parent H37Rv strain of M. tuberculosis, such mutants could be isolated only by two-step selections. Furthermore, the phenotypes of the quadruply resistant mutants were those showing a higher resistance or a broader spectrum than expected by the addition of phenotypes of individual mutations. In addition, it was shown that, in contrast to the fact that hextuply resistant mutants could be isolated directly from the parent strain of M. tuberculosis, such mutants were not isolated directly from the parent B.C.G. strain, but could be isolated only after pre-incubation of the strain on a medium containing Tween 80.     

The Saccharomyces cerevisiae Arr4p is involved in metal and heat tolerance*

Homologues of the bacterial ArsA ATPase are found in nearly every organism. While the enzyme is involved in arsenic detoxification in bacteria, the roles of eukaryotic homologues have not been identified. This article reports the function of the Saccharomyces cerevisiaehomologue encoded by ARR4 gene (YDL100c ORF). Disruption of ARR4 was not lethal, but the disrupted strain displayed increased sensitivity to As³⁺, As⁵⁺, Co²⁺, Cr³⁺, Cu²⁺ or VO ₄ ^3– salts and temperature. A plasmid-encoded copy of a wild-type ARR4 gene could complement the heat- or metal-related stress responses. Mutation of a codon within the consensus sequence for the nucleotide-binding site resulted in loss of complementation of the disrupted strain and produced a dominant negative phenotype in a wild type strain. Wild type and mutant Arr4p were purified from Escherichia coli. The wild type protein exhibited a low level of ATPase activity, and the mutant was inactive. The purified ATPase eluted as a dimer of 80-kDa species. A fusion of ARR4 and the GFP (green fluorescent protein) gene was constructed. The gene fusion was able to complement stress-related phenotype of the ARR4 disruption. Under non-stress conditions, GFP fluorescence was found diffusely in the cytosol. Under stress conditions GFP was localized in a few punctate bodies resembling late endosomes. It is proposed that under heat or metal stress, the soluble ATPase becomes membrane-associated, perhaps through interaction with a partner protein, and that this complex is involved in stress tolerance.     

Isolation of a novel bacterium, Blautia glucerasei sp. nov., hydrolyzing plant glucosylceramide to ceramide

A bacterial strain that is capable of hydrolyzing plant glucosylceramide (GluCer) was newly isolated from dog feces. The novel strain, designated as strain HFTH-1^T, hydrolyzed plant GluCer with a variety of chemical structures, but did not hydrolyze glucosylsphingosine, lactosylceramide, or monosialoganglioside GM₃, indicating that strain HFTH-1^T produces GluCer-specific glucosylceramidase. Strain HFTH-1^T was Gram-positive, anaerobic, oval-spore-forming, rod-shaped, lecithinase-negative, and lipase-negative. It fermented a wide variety of carbohydrates and produced mainly acetate, formate, and lactate from glucose. The G + C content of its DNA was 40.7 mol%. The phylogenetic analysis of 16S rRNA sequence revealed that strain HFTH-1^T is placed in the clostridial rRNA cluster XIVa, with Ruminococcus obeum as the nearest relative. Pairwise comparison revealed approximately 5.0% sequence divergence between strain HFTH-1^T and the type strain of R. obeum. On the basis of its phenotypic characteristics and phylogenetic divergence, it is proposed that the hitherto unknown rod-shaped bacterial strain HFTH-1^T (= DSM 22028^T = NBRC 104932^T) should be placed in the genus Blautia as a novel species, Blautia glucerasei sp. nov, the only currently known isolate of the species.     

ADP-dependent glucokinase from the hyperthermophilic sulfate-reducing archaeon<Emphasis Type="Italic"> Archaeoglobus fulgidus</Emphasis> strain 7324

The hyperthermophilic sulfate-reducing archaeon Archaeoglobus fulgidus strain 7324 has been shown to degrade starch via glucose using a modified Embden-Meyerhof pathway. The first enzyme of this pathway, ADP-dependent glucokinase, was purified 600-fold to homogeneity. The enzyme is a monomeric protein with an apparent molecular mass of 50 kDa. It had a temperature optimum at 83 °C and showed a significant thermostability up to 100 °C. The enzyme was highly specific for ADP and glucose as substrates; it did not use ATP, CDP, UDP, or GDP as phosphoryl donors, or mannose, fructose and fructose 6-phosphate as phosphoryl acceptors (at 80 °C). Only glucosamine was phosphorylated at significant rates. The apparent K_m values for ADP and glucose (at 50 °C) were 0.07 mM and 0.78 mM, respectively; the apparent V_max value was about 50 U/mg at 50 °C and 350 U/mg at 80 °C. Divalent cations were required for maximal activity; Mn²⁺, Mg²⁺ and Ca²⁺, which were most effective, could be replaced partially by Cu²⁺, Ni²⁺, Co²⁺ and Zn²⁺. The N-terminal amino acid sequence (42 amino acids) of ADP-dependent glucokinase was almost identical to that of ADP-dependent glucokinase from Thermococcus litoralis. In the genome of the closely related Archaeoglobus fulgidus strain VC16 a homologous gene for ADP-dependent glucokinase could not be identified.     

Construction and characterization of a clostripain-like protease-deficient mutant of <Emphasis Type="Italic">Clostridium perfringens</Emphasis> as a strain for clostridial gene expression

The inherent difficulty of expressing clostridial AT-rich genes in a heterologous host has limited their biotechnological application. We previously reported a plasmid for high-level expression of clostridial genes in Clostridium perfringens (Takamizawa et al., Protein Expr Purif 36:70–75, 2004). In this study, we examined the extracellular proteases of C. perfringens strain 13. Zymographic analysis and caseinase assaying of a culture supernatant showed that it contained a protease activated by dithiothreitol and Ca²⁺, suggesting that clostripain-like protease (Clp) is the most likely candidate for the major extracellular protease. Disruption of the clp gene by homologous recombination markedly decreased the level of caseinase activity in the culture supernatant. Analysis by sodium dodecyl sulfate–polyacrylamide gel electrophoresis (SDS-PAGE) revealed that the Clp⁻ mutant but not the wild type strain increased the levels of many polypeptides in the culture supernatant after the late exponential growth phase. Such polypeptides included both cytoplasmic and secretory proteins, suggesting proteins secreted or released into the medium were degraded by Clp. To assess the effects of Clp on the productivity and stability of recombinant proteins, 74-kDa NanI sialidase was expressed in the two strains. The mutant strain produced a higher level of NanI activity than the wild type strain. Furthermore, under the conditions where Clp was activated, NanI was degraded easily in the latter culture but not in the former one. These results indicate that the Clp⁻ mutant could serve as a useful strain for efficiently expressing and preparing protease-free clostridial proteins.