Selection of the Bacillus thuringiensis Berliner strain to produce a parasporin with cytotoxic activity against MCF-7 breast cancer cells.

BACKGROUND: Bacillus thuringiensis (Bt) is a Gram-positive bacterium that is known worldwide for its entomopathogenic properties. Recent studies indicate that bacteria produces protein inclusions called parasporins (PSs) that have anti-cancer activity against several types of tumor cells. OBJECTIVE: The present work aimed to select a Bt strain that produces an active PS against MCF-7 breast cancer cells, and to provide an initial quantification of its toxicity and protein concentration. METHODS: Two batches of Bt strains were fermented, and the parasporins were produced and isolated. In vitro tests were performed in 96-well plates and analyzed by a spectrophotometer. RESULTS: Most peptides did not have any cytopathic effect, but the A14d2 strain produces a PS with high toxicity to cancer cells. In the MTT test, the A14d2 strain PS was efficient with an LD50 of 14.83 µg/mL and a protein concentration of 520 µg/mL. At the end of the experiments, this PS was added to bacterial cells that produce other biologically active bacterial toxins against MCF-7 cells, which allowed it to be produced by a safe and inert microorganism to humans. CONCLUSION: PSs represent a potential tool to treat this form of breast cancer by providing peptides that may be useful in therapy.

Glycan region of GPI anchored-protein is required for cytocidal oligomerization of an anticancer parasporin-2, Cry46Aa1 protein, from Bacillus thuringiensis strain A1547.

Parasporin-2 (PS2), alternatively named Cry46Aa1, an anticancer protein derived from Bacillus thuringiensis strain A1547, causes specific cell damage via PS2 oligomerization in the cell membrane. Although PS2 requires glycosylphosphatidylinositol (GPI)-anchored proteins for its cytocidal action, their precise role is unknown. Here, we report that the glycan of GPI induces PS2 oligomerization, which causes cell death. Cytotoxicity, cell-binding and oligomerization of the toxin were not observed in GPI-anchored protein-deficient Chinese hamster ovary cells. Expression and protease-treatment analyses showed that the actions of the toxin were dependent on the glycan core, not the polypeptide moiety, of GPI-anchored proteins. However, surface expression of some GPI-anchored proteins is observed in PS2-insensitive cells. These data suggest that GPI-anchored proteins do not determine the target specificity, but instead function as a kind of coreceptor, in the cytocidal action of PS2.

Parasporins as new natural anticancer agents: a review.

In 1999 Mizuki and co-authors studied for the first time the parasporal inclusion proteins extracted from B. thuringiensis strains (a Gram-positive, soil-dwelling bacterium) for cytotoxic activity against human leukaemia T-cells. Later some other proteins with this unusual property to recognize human leukemic cells were isolated from this strain of bacteria and named parasporins. At present 6 types of parasporins are identified and characterized. This review summarizes the properties of these new potentially useful antitumor agents of natural origin. Various types of parasporins possess unique cytotoxic mechanisms against cancer cells. The cytotoxic activity for cancer cells makes parasporins possible candidates for anticancer agents in clinical oncology. Recently, genetic engineering was applied for the production of parasporins and the gene responsible for the production of the proteins was expressed in E. coli. However, there are virtually no data regarding the cytotoxic (antitumor) activity of parasporins in vivo. These relatively new cytotoxic proteins warrant further investigation, especially in rodents, for possible application in clinical oncology.

Cloning and characterization of a unique cytotoxic protein parasporin-5 produced by Bacillus thuringiensis A1100 strain.

Parasporin is the cytocidal protein present in the parasporal inclusion of the non-insecticidal Bacillus thuringiensis strains, which has no hemolytic activity but has cytocidal activities, preferentially killing cancer cells. In this study, we characterized a cytocidal protein that belongs to this category, which was designated parasporin-5 (PS5). PS5 was purified from B. thuringiensis serovar tohokuensis strain A1100 based on its cytocidal activity against human leukemic T cells (MOLT-4). The 50% effective concentration (EC50) of PS5 to MOLT-4 cells was approximately 0.075 µg/mL. PS5 was expressed as a 33.8-kDa inactive precursor protein and exhibited cytocidal activity only when degraded by protease at the C-terminal into smaller molecules of 29.8 kDa. Although PS5 showed no significant homology with other known parasporins, a Position Specific Iterative-Basic Local Alignment Search Tool (PSI-BLAST) search revealed that the protein showed slight homology to, not only some B. thuringiensis Cry toxins, but also to aerolysin-type ß-pore-forming toxins (ß-PFTs). The recombinant PS5 protein could be obtained as an active protein only when it was expressed in a precursor followed by processing with proteinase K. The cytotoxic activities of the protein against various mammalian cell lines were evaluated. PS5 showed strong cytocidal activity to seven of 18 mammalian cell lines tested, and low to no cytotoxicity to the others.

FMP30 is required for the maintenance of a normal cardiolipin level and mitochondrial morphology in the absence of mitochondrial phosphatidylethanolamine synthesis.

Mitochondria of the yeast Saccharomyces cerevisiae contain enzymes Crd1p and Psd1p, which synthesize cardiolipin (CL) and phosphatidylethanolamine respectively. A previous study indicated that crd1Δ is synthetically lethal with psd1Δ. In this study, to identify novel genes involved in CL metabolism, we searched for genes that genetically interact with Psd1p, and found that deletion of FMP30 encoding a mitochondrial inner membrane protein results in a synthetic growth defect with psd1Δ. Although fmp30Δ cells grew normally and exhibited a slightly decreased CL level, fmp30Δpsd1Δ cells exhibited a severe growth defect and an about 20-fold reduction in the CL level, as compared with the wild-type control. We found also that deletion of FMP30 caused a defect in mitochondrial morphology. Furthermore, FMP30 genetically interacted with seven mitochondrial morphology genes. These results indicated that Fmp30p is involved in the maintenance of mitochondrial morphology and required for the accumulation of a normal level of CL in the absence of mitochondrial phosphatidylethanolamine synthesis.

Mega assemblages of oligomeric aerolysin-like toxins stabilized by toxin-associating membrane proteins.

Most ß pore-forming toxins need to be oligomerized via receptors in order to form membrane pores. Though oligomerizing toxins frequently form SDS-resistant oligomers, it was questionable whether SDS-resistant oligomers reflected native functional toxin complexes. In order to elucidate the essence of the cytocidal assemblages, oligomers of aerolysin-like toxins, aerolysin, parasporin-2 and epsilon toxin, were examined with or without SDS. On Blue Native PAGE, each toxin, which had been solubilized from target cells with mild detergent, was a much larger complex (nearly 1 MDa) than the typical SDS-resistant oligomers (∼200 kDa). Size exclusion chromatography confirmed the huge toxin complexes. While a portion of the huge complexes were sensitive to proteases, SDS-resistant oligomers resist the proteolysis. Presumably the core toxin complexes remained intact while the cellular proteins were degraded. Moreover, intermediate complexes, which included no SDS-resistant oligomers, could be detected at lower temperatures. This study provides evidence for huge functional complexes of ß pore-forming toxins and emphasizes their potential variance in composition.

Parasporin-2 requires GPI-anchored proteins for the efficient cytocidal action to human hepatoma cells.

Parasporin-2 (PS2) is a Bacillus thuringiensis inclusion protein that reacts intensively with human hepatoma cells. This antitumour toxin oligomerizes at the cell surface via binding to lipid rafts, leading to the cell lysis with typical blebs around peripheral cells. We find here that glycosylphosphatidylinositol (GPI)-anchored proteins are involved in the cytocidal actions. Depletion of the cellular cholesterol and loss of sphingolipid in lipid rafts slightly decreased cytolysis by PS2. Beyond those, the cells temporally resisted PS2 with reduction of the toxin binding after GPI-anchored proteins were cleaved off by phosphatidylinositol-specific phospholipase C. PS2 and aerolysin showed individual cytocidal specificity while aerolysin's receptor is GPI-anchored proteins. When we confirmed expression of GPI-anchored proteins on four cell lines, showing different cytotoxicity by PS2, GPI-anchored proteins were evenly expressed on the cells. Therefore, PS2 requires a kind of GPI-anchored proteins for the effective cytolysis.

Purification and characterization of human phosphatidylserine synthases 1 and 2.

PS (phosphatidylserine) in mammalian cells is synthesized by two distinct base-exchange enzymes, PSS1 (PS synthase 1) and PSS2, which are responsible for the conversion of PC (phosphatidylcholine) and PE (phosphatidylethanolamine) respectively into PS in intact cells. The PS synthesis in cultured mammalian cells is inhibited by exogenous PS, and this feedback control occurs through inhibition of PSSs by PS. In the present study, we purified epitope-tagged forms of human PSS1 and PSS2. The purified PSS2 was shown to catalyse the conversion of PE, but not PC, into PS, this being consistent with the substrate specificity observed in intact cells. On the other hand, the purified PSS1 was shown to catalyse the conversion of both PC and PE into PS, although PSS1 in intact cells had been shown not to contribute to the conversion of PE into PS to a significant extent. Furthermore, we found that the purified PSS2, but not the purified PSS1, was inhibited on the addition of PS to the enzyme assay mixture, raising the possibility that there was some difference between the mechanisms of the inhibitory actions of PS towards PSS1 and PSS2.

Crystal structure of the parasporin-2 Bacillus thuringiensis toxin that recognizes cancer cells.

Parasporin-2 is a protein toxin that is isolated from parasporal inclusions of the Gram-positive bacterium Bacillus thuringiensis. Although B. thuringiensis is generally known as a valuable source of insecticidal toxins, parasporin-2 is not insecticidal, but has a strong cytocidal activity in liver and colon cancer cells. The 37-kDa inactive nascent protein is proteolytically cleaved to the 30-kDa active form that loses both the N-terminal and the C-terminal segments. Accumulated cytological and biochemical observations on parasporin-2 imply that the protein is a pore-forming toxin. To confirm the hypothesis, we have determined the crystal structure of its active form at a resolution of 2.38 A. The protein is unusually elongated and mainly comprises long beta-strands aligned with its long axis. It is similar to aerolysin-type beta-pore-forming toxins, which strongly reinforce the pore-forming hypothesis. The molecule can be divided into three domains. Domain 1, comprising a small beta-sheet sandwiched by short alpha-helices, is probably the target-binding module. Two other domains are both beta-sandwiches and thought to be involved in oligomerization and pore formation. Domain 2 has a putative channel-forming beta-hairpin characteristic of aerolysin-type toxins. The surface of the protein has an extensive track of exposed side chains of serine and threonine residues. The track might orient the molecule on the cell membrane when domain 1 binds to the target until oligomerization and pore formation are initiated. The beta-hairpin has such a tight structure that it seems unlikely to reform as postulated in a recent model of pore formation developed for aerolysin-type toxins. A safety lock model is proposed as an inactivation mechanism by the N-terminal inhibitory segment.

Raft-targeting and oligomerization of Parasporin-2, a bacillus thuringiensis crystal protein with anti-tumour activity.

Parasporin-2 is a newly classified Bacillus thuringiensis crystal toxin with strong cytocidal activities toward human liver and colon cancer cells. Similar to other insecticidal B. thuringiensis crystal toxins, parasporin-2 shows target specificity and damages the cellular membrane. However, the mode of parasporin-2 actions toward the cell membrane remains unknown. Here, we show that this anti-tumour crystal toxin targets lipid rafts and assembles into oligomeric complexes in the membrane of human hepatocyte cancer (HepG2) cells. Upon incubation with HepG2 cells, peripheral membrane-bound toxins, which were recovered in a low-density detergent-resistant membrane fraction, i.e. with lipid rafts, were transformed into heat-stable SDS-resistant membrane-embedded oligomers (approximately 200 kDa). The toxin oligomerization was dependent on temperature and coupled with cell lysis. The toxin oligomerization also occurred in a cell-free membrane system and was required for binding to membrane proteins, the lipid bilayer and cholesterols. These results indicate that parasporin-2 is an oligomerizing and pore-forming toxin that accumulates in lipid rafts.

Spatial orientation of mitochondrial processing peptidase and a preprotein revealed by fluorescence resonance energy transfer.

Mitochondrial processing peptidase (MPP), which is composed of heterodimeric alpha-MPP and beta-MPP subunits. It specifically recognizes mitochondrial preproteins and removes their basic N-terminal signal prepeptides. In order to elucidate the spatial orientation of the preproteins toward MPP, which has been missed by crystal structures of a yeast MPP including a synthetic prepeptide in its acidic proteolytic chamber, we analysed the fluorescence resonance energy transfer (FRET) between EGFP fused to a yeast aconitase presequence (preEGFP) and regiospecific 7-dietylamino-3-(4'-maleimidyl phenyl)-4-methyl coumarin (CPM)-labelled yeast MPPs. FRET efficiencies of 65 and 55% were observed between the EGFP chromophore and CPM-Ser(84) and -Lys(156) of beta-MPP, respectively, leading to calculated distances between the molecules of 48 and 50 A, respectively. Considering the FRET results and the structural validity based on the crystal structure of the MPP-presequence complex, a plausible model of preEGFP associated with MPP was constructed in silico. The modelled structure indicated that amino acid residues on the C-terminal side of the cleavage site in the preprotein were orientated tail out from the large cavity of MPP and interacted with the glycine-rich loop of alpha-MPP. Thus, MPP orientates preproteins at the specific cleft between the catalytic domain and the flexible glycine-rich loop which seems to pinch the extended polypeptide.

A protein from a parasitic microorganism, Rickettsia prowazekii, can cleave the signal sequences of proteins targeting mitochondria.

The obligate intracellular parasitic bacteria rickettsiae are more closely related to mitochondria than any other microbes investigated to date. A rickettsial putative peptidase (RPP) was found to resemble the alpha and beta subunits of mitochondrial processing peptidase (MPP), which cleaves the transport signal sequences of mitochondrial preproteins. RPP showed completely conserved zinc-binding and catalytic residues compared with beta-MPP but barely contained any of the glycine-rich loop region characteristic of alpha-MPP. When the biochemical activity of RPP purified from a recombinant source was analyzed, RPP specifically hydrolyzed basic peptides and presequence peptides with frequent cleavage at their MPP-processing sites. Moreover, RPP appeared to activate yeast beta-MPP so that it processed preproteins with shorter presequences. Thus, RPP behaves as a bifunctional protein that could act as a basic peptide peptidase and a somewhat regulatory protein for other protein activities in rickettsiae. These are the first biological and enzymological studies to report that a protein from a parasitic microorganism can cleave the signal sequences of proteins targeted to mitochondria.

Cytocidal actions of parasporin-2, an anti-tumor crystal toxin from Bacillus thuringiensis.

Parasporin-2, a new crystal protein derived from noninsecticidal and nonhemolytic Bacillus thuringiensis, recognizes and kills human liver and colon cancer cells as well as some classes of human cultured cells. Here we report that a potent proteinase K-resistant parasporin-2 toxin shows specific binding to and a variety of cytocidal effects against human hepatocyte cancer cells. Cleavage of the N-terminal region of parasporin-2 was essential for the toxin activity, whereas C-terminal digestion was required for rapid cell injury. Protease-activated parasporin-2 induced remarkable morphological alterations, cell blebbing, cytoskeletal alterations, and mitochondrial and endoplasmic reticulum fragmentation. The plasma membrane permeability was increased immediately after the toxin treatment and most of the cytoplasmic proteins leaked from the cells, whereas mitochondrial and endoplasmic reticulum proteins remained in the intoxicated cells. Parasporin-2 selectively bound to cancer cells in slices of liver tumor tissues and susceptible human cultured cells and became localized in the plasma membrane until the cells were damaged. Thus, parasporin-2 acts as a cytolysin that permeabilizes the plasma membrane with target cell specificity and subsequently induces cell decay.

Recognition and processing of a nuclear-encoded polyprotein precursor by mitochondrial processing peptidase.

The nuclear-encoded protein RPS14 (ribosomal protein S14) of rice mitochondria is synthesized in the cytosol as a polyprotein consisting of a large N-terminal domain comprising preSDHB (succinate dehydrogenase B precursor) and the C-terminal RPS14. After the preSDHB-RPS14 polyprotein is transported into the mitochondrial matrix, the protein is processed into three peptides: the N-terminal prepeptide, the SDHB domain and the C-terminal mature RPS14. Here we report that the general MPP (mitochondrial processing peptidase) plays an essential role in processing of the polyprotein. Purified yeast MPP cleaved both the N-terminal presequence and the connector region between SDHB and RPS14. Moreover, the connector region was processed more rapidly than the presequence. When the site of cleavage between SDHB and RPS14 was determined, it was located in an MPP processing motif that has also been shown to be present in the N-terminal presequence. Mutational analyses around the cleavage site in the connector region suggested that MPP interacts with multiple sites in the region, possibly in a similar manner to the interaction with the N-terminal presequence. In addition, MPP preferentially recognized the unfolded structure of preSDHB-RPS14. In mitochondria, MPP may recognize the stretched polyprotein during passage of the precursor through the translocational apparatus in the inner membrane, and cleave the connecting region between the SDHB and RPS14 domains even before processing of the presequence.

Crystallization of parasporin-2, a Bacillus thuringiensis crystal protein with selective cytocidal activity against human cells.

Bacillus thuringiensis is a valuable source of protein toxins that are specifically effective against certain insects and worms but harmless to mammals. In contrast, a protein toxin obtained from B. thuringiensis strain A1547, designated parasporin-2, is not insecticidal but has a strong cytocidal activity against human cells with markedly divergent target specificity. The 37 kDa inactive protein is proteolytically activated to a 30 kDa active form. The active form of the recombinant protein toxin was crystallized in the presence of ethylene glycol and polyethylene glycol 8000 at neutral pH. The crystals belong to the hexagonal space group P6(1) or P6(5), with unit-cell parameters a = b = 134.37, c = 121.24 A. Diffraction data from a native crystal were collected to 2.75 A resolution using a synchrotron-radiation source.

A Bacillus thuringiensis crystal protein with selective cytocidal action to human cells.

Bacillus thuringiensis crystal proteins, well known to be toxic to certain insects but not pathogenic to mammals, are used as insecticidal proteins in agriculture and forest management. We here identified a crystal protein that is non-insecticidal and non-hemolytic but has strong cytocidal activity against various human cells with a markedly divergent target specificity, e.g. highly cytotoxic to HepG2 and Jurkat and less cytotoxic to the normal hepatocyte (HC) and HeLa. In slices of liver and colon cancer tissues, the toxin protein preferentially killed the cancer cells, leaving other cells unaffected. The cytocidal effect of the protein is non-apoptotic with swelling and fragmentation of the susceptible cells, although the apoptotic process does occur when the cell damage proceeded slowly. The amino acid sequence deduced from the nucleotide sequence of the cloned gene of the protein has little sequence homology with the insecticidal crystal proteins of B. thuringiensis. These observations raise the presence of a new group of the B. thuringiensis toxin and the possibility of new applications for the protein in the medical field.

Determination of the cleavage site of the presequence by mitochondrial processing peptidase on the substrate binding scaffold and the multiple subsites inside a molecular cavity.

Mitochondrial processing peptidase (MPP) recognizes a large variety of basic presequences of mitochondrial preproteins and cleaves the single site, often including arginine, at the -2 position (P(2)). To elucidate the recognition and specific processing of the preproteins by MPP, we mutated to alanines at acidic residues conserved in a large internal cavity formed by the MPP subunits, alpha-MPP and beta-MPP, and analyzed the processing efficiencies for various preproteins. We report here that alanine mutations at a subsite in rat beta-MPP interacting with the P(2) arginine cause a shift in the processing site to the C-terminal side of the preprotein. Because of reduced interactions with the P(2) arginine, the mutated enzymes recognize not only the N-terminal authentic cleavage site with P(2) arginine but also the potential C-terminal cleavage site without a P(2) arginine. In fact, it competitively cleaves the two sites of the preprotein. Moreover, the acidified site of alpha-MPP, which binds to the distal basic site in the long presequence, recognized the authentic P(2) arginine as the distal site in compensation for ionic interaction at the proximal site in the mutant MPP. Thus, MPP seems to scan the presequence from beta- to alpha-MPP on the substrate binding scaffold inside the MPP cavity and finds the distal and P(2) arginines on the multiple subsites on both MPP subunits. A possible mechanism for substrate recognition and cleavage is discussed here based on the notable character of a subsite-deficient mutant of MPP in which the substrate specificity is altered.