Cysteine protease activity is up-regulated in inflamed ankle joints of rats with adjuvant-induced arthritis and decreases with in vivo administration of a vinyl sulfone cysteine protease inhibitor.

OBJECTIVE: Cysteine proteases are postulated to play a role in tissue destruction in the joints of animals with arthritis. The purpose of the present study was to confirm the concept that cysteine proteases are enzymes involved in the pathology of rheumatoid arthritis (RA). METHODS: Arthritis was induced in Lewis rats by adjuvant injection (adjuvant-induced arthritis [AIA] model) and scored for inflammation. At necropsy, the rear paws were either fixed in formalin and assigned a histologic score (based on synovial cell proliferation, cartilage erosion, bone erosion, and fibroproliferative pannus) or frozen, cryosectioned, and assayed for enzyme activity either by in situ cytochemical staining with a post-azo-coupling method using a chromogenic substrate (Z-arg-arg-MNA) or by a novel assay placing the tissue section directly in a cuvette using the fluorogenic substrate Z-arg-arg-AMC. RESULTS: Enzymatic activity, measured either in frozen sections in situ or in the cuvette assay, was positively correlated with joint destruction (r = 0.7) and inflammation (r = 0.8). Activity was not inhibited significantly by Pefabloc (a serine protease inhibitor), EDTA (a metalloprotease inhibitor), or pepstatin A (an aspartyl protease inhibitor) but was inhibited by E-64 and vinyl sulfone irreversible inhibitors of cysteine proteases. The effect of one of the vinyl sulfone cysteine protease inhibitors, Mu-Leu-HomoPhe-vinylsulfone, was tested in vivo by dietary administration at 2.2 mg/kg/day in the AIA model; this resulted in a significant decrease in inflammation and in the amount of cysteine protease activity measured in the joint tissue. CONCLUSION: Cysteine protease activity levels increase in the diseased state and may be an important target for designing small molecule inhibitors to reduce the inflammation and tissue destruction associated with RA.

Aneuploidy, the somatic mutation that makes cancer a species of its own.

The many complex phenotypes of cancer have all been attributed to "somatic mutation." These phenotypes include anaplasia, autonomous growth, metastasis, abnormal cell morphology, DNA indices ranging from 0.5 to over 2, clonal origin but unstable and non-clonal karyotypes and phenotypes, abnormal centrosome numbers, immortality in vitro and in transplantation, spontaneous progression of malignancy, as well as the exceedingly slow kinetics from carcinogen to carcinogenesis of many months to decades. However, it has yet to be determined whether this mutation is aneuploidy, an abnormal number of chromosomes, or gene mutation. A century ago, Boveri proposed cancer is caused by aneuploidy, because it correlates with cancer and because it generates "pathological" phenotypes in sea urchins. But half a century later, when cancers were found to be non-clonal for aneuploidy, but clonal for somatic gene mutations, this hypothesis was abandoned. As a result aneuploidy is now generally viewed as a consequence, and mutated genes as a cause of cancer although, (1) many carcinogens do not mutate genes, (2) there is no functional proof that mutant genes cause cancer, and (3) mutation is fast but carcinogenesis is exceedingly slow. Intrigued by the enormous mutagenic potential of aneuploidy, we undertook biochemical and biological analyses of aneuploidy and gene mutation, which show that aneuploidy is probably the only mutation that can explain all aspects of carcinogenesis. On this basis we can now offer a coherent two-stage mechanism of carcinogenesis. In stage one, carcinogens cause aneuploidy, either by fragmenting chromosomes or by damaging the spindle apparatus. In stage two, ever new and eventually tumorigenic karyotypes evolve autocatalytically because aneuploidy destabilizes the karyotype, ie. causes genetic instability. Thus, cancer cells derive their unique and complex phenotypes from random chromosome number mutation, a process that is similar to regrouping assembly lines of a car factory and is analogous to speciation. The slow kinetics of carcinogenesis reflects the low probability of generating by random chromosome reassortments a karyotype that surpasses the viability of a normal cell, similar again to natural speciation. There is correlative and functional proof of principle: (1) solid cancers are aneuploid; (2) genotoxic and non-genotoxic carcinogens cause aneuploidy; (3) the biochemical phenotypes of cells are severely altered by aneuploidy affecting the dosage of thousands of genes, but are virtually un-altered by mutations of known hypothetical oncogenes and tumor suppressor genes; (4) aneuploidy immortalizes cells; (5) non-cancerous aneuploidy generates abnormal phenotypes in all species tested, e.g., Down syndrome; (6) the degrees of aneuploidies are proportional to the degrees of abnormalities in non-cancerous and cancerous cells; (7) polyploidy also varies biological phenotypes; (8) variation of the numbers of chromosomes is the basis of speciation. Thus, aneuploidy falls within the definition of speciation, and cancer is a species of its own. The aneuploidy hypothesis offers new prospects of cancer prevention and therapy.

Aneuploidy precedes and segregates with chemical carcinogenesis.

A century ago, Boveri proposed that cancer is caused by aneuploidy, an abnormal balance of chromosomes, because aneuploidy correlates with cancer and because experimental aneuploidy generates "pathological" phenotypes. Half a century later, when cancers were found to be nonclonal for aneuploidy, but clonal for somatic gene mutations, this hypothesis was abandoned. As a result, aneuploidy is now generally viewed as a consequence, and mutated genes as a cause of cancer. However, we have recently proposed a two-stage mechanism of carcinogenesis that resolves the discrepancy between clonal mutation and nonclonal karyotypes. The proposal is as follows: in stage 1, a carcinogen "initiates" carcinogenesis by generating a preneoplastic aneuploidy; in stage 2, aneuploidy causes asymmetric mitosis because it biases balance-sensitive spindle and chromosomal proteins and alters centrosomes both numerically and structurally (in proportion to the degree of aneuploidy). Therefore, the karyotype of an initiated cell evolves autocatalytically, generating ever-new chromosome combinations, including neoplastic ones. Accordingly, the heterogeneous karyotypes of "clonal" cancers are an inevitable consequence of the karyotypic instability of aneuploid cells. The notorious long latent periods, of months to decades, from carcinogen to carcinogenesis, would reflect the low probability of evolving by chance karyotypes that compete favorably with normal cells, in principle analagous to natural evolution. Here, we have confirmed experimentally five predictions of the aneuploidy hypothesis: (1) the carcinogens dimethylbenzanthracene and cytosine arabinoside induced aneuploidy in a fraction of treated Chinese hamster embryo cells; (2) aneuploidy preceded malignant transformation; (3) transformation of carcinogen-treated cells occurred only months after carcinogen treatment, i.e., autocatalytically; (4) preneoplastic aneuploidy segregated with malignant transformation in vitro and with 14 of 14 tumors in animals; and (5) karyotypes of tumors were heterogeneous. We conclude that, with the carcinogens studied, aneuploidy precedes cancer and is necessary for carcinogenesis.

Auto-catalysed progression of aneuploidy explains the Hayflick limit of cultured cells, carcinogen-induced tumours in mice, and the age distribution of human cancer.

Evidence continues to accumulate that aneuploidy, an imbalance in the number of chromosomes, is responsible for the characteristic phenotypes of cancer, including the abnormal cellular size and morphology of cancer cells, the appearance of tumour-associated antigens, as well as the high levels of membrane-bound and secreted proteins responsible for invasiveness and loss of contact inhibition. Aneuploidy has also been demonstrated to be the self-perpetuating source of the karyotypic instability of cancer cells. Here it is shown that the auto-catalysed progression of aneuploidy explains the kinetics of the finite lifetime of diploid cells in culture, the time course of the appearance of papillomas and carcinomas in benzo[a]pyrene-treated mice, and the age-dependence of human cancers. Modelling studies indicate that the ease of spontaneous transformation of mouse cells in culture may be due to a chaotic progression of aneuploidy. Conversely, the strong preference towards senescence and resistance to transformation of human cells in culture may be the result of a non-chaotic progression of aneuploidy. Finally, a method is proposed for quantifying the aneuploidogenic potencies of carcinogens.

Aneuploidy vs. gene mutation hypothesis of cancer: recent study claims mutation but is found to support aneuploidy.

For nearly a century, cancer has been blamed on somatic mutation. But it is still unclear whether this mutation is aneuploidy, an abnormal balance of chromosomes, or gene mutation. Despite enormous efforts, the currently popular gene mutation hypothesis has failed to identify cancer-specific mutations with transforming function and cannot explain why cancer occurs only many months to decades after mutation by carcinogens and why solid cancers are aneuploid, although conventional mutation does not depend on karyotype alteration. A recent high-profile publication now claims to have solved these discrepancies with a set of three synthetic mutant genes that "suffices to convert normal human cells into tumorigenic cells." However, we show here that even this study failed to explain why it took more than "60 population doublings" from the introduction of the first of these genes, a derivative of the tumor antigen of simian virus 40 tumor virus, to generate tumor cells, why the tumor cells were clonal although gene transfer was polyclonal, and above all, why the tumor cells were aneuploid. If aneuploidy is assumed to be the somatic mutation that causes cancer, all these results can be explained. The aneuploidy hypothesis predicts the long latent periods and the clonality on the basis of the following two-stage mechanism: stage one, a carcinogen (or mutant gene) generates aneuploidy; stage two, aneuploidy destabilizes the karyotype and thus initiates an autocatalytic karyotype evolution generating preneoplastic and eventually neoplastic karyotypes. Because the odds are very low that an abnormal karyotype will surpass the viability of a normal diploid cell, the evolution of a neoplastic cell species is slow and thus clonal, which is comparable to conventional evolution of new species.

How aneuploidy affects metabolic control and causes cancer.

The complexity and diversity of cancer-specific phenotypes, including de-differentiation, invasiveness, metastasis, abnormal morphology and metabolism, genetic instability and progression to malignancy, have so far eluded explanation by a simple, coherent hypothesis. However, an adaptation of Metabolic Control Analysis supports the 100-year-old hypothesis that aneuploidy, an abnormal number of chromosomes, is the cause of cancer. The results demonstrate the currently counter-intuitive principle that it is the fraction of the genome undergoing differential expression, not the magnitude of the differential expression, that controls phenotypic transformation. Transforming the robust normal phenotype into cancer requires a twofold increase in the expression of thousands of normal gene products. The massive change in gene dose produces highly non-linear (i.e. qualitative) changes in the physiology and metabolism of cells and tissues. Since aneuploidy disrupts the natural balance of mitosis proteins, it also explains the notorious genetic instability of cancer cells as a consequence of the perpetual regrouping of chromosomes. In view of this and the existence of non-cancerous aneuploidy, we propose that cancer is the phenotype of cells above a certain threshold of aneuploidy. This threshold is reached either by the gradual, stepwise increase in the level of aneuploidy as a consequence of the autocatalysed genetic instability of aneuploid cells or by tetraploidization followed by a gradual loss of chromosomes. Thus the initiation step of carcinogenesis produces aneuploidy below the threshold for cancer, and the promotion step increases the level of aneuploidy above this threshold. We conclude that aneuploidy offers a simple and coherent explanation for all the cancer-specific phenotypes. Accordingly, the gross biochemical abnormalities, abnormal cellular size and morphology, the appearance of tumour-associated antigens, the high levels of secreted proteins responsible for invasiveness and loss of contact inhibition, and even the daunting genetic instability that enables cancer cells to evade chemotherapy, are all the natural consequence of the massive over- and under-expression of proteins.

How aneuploidy may cause cancer and genetic instability.

It has been difficult to find a common cause for the many and complex phenotypes of cancer such as dedifferentiation, invasiveness, abnormal morphology, growth rate and metabolism, genetic instability, progression to malignancy, cellular heterogeneity of phenotypes and karyotypes, and clonal origin despite heterogeneity. Over 100 years ago aneuploidy, an abnormal balance of chromosomes, was proposed to cause cancer. However, the aneuploidy hypothesis has since been abandoned, in favor of the gene mutation hypothesis, because it could not offer conventional explanations for cancer-specific phenotypes. For example, the aneuploidy hypothesis seemed unable to (i) explain the genesis of abnormal, cancer-specific phenotypes, (ii) reconcile the heterogeneous karyotypes with the clonal origin of cancers, (iii) explain aneuploidy in non-cancerous cells, and (iv) explain how carcinogens would cause aneuploidy. Here we introduce new evidence that aneuploidy offers a simple, coherent explanation of all cancer-specific phenotypes: (i) Congenital and experimental aneuploidy is now known to generate abnormal phenotypes, such as Down syndrome in humans and cancer in animals. (ii) Based on metabolic control analysis, we have derived equations that correlate degrees of aneuploidy with the resulting phenotype abnormalities. These equations suggest that aneuploidy must exceed a certain threshold to generate cancer-specific phenotypes. Therefore, we propose that multistep carcinogenesis corresponds to multiple steps of aneuploidization. (iii) Aneuploidy is also sufficient to explain cancer-specific, karyotypic instability. Since aneuploidy imbalances the highly balance-sensitive components of the spindle apparatus it destabilizes symmetrical chromosome segregation. This autocatalytic instability is the reason why cancers have heterogeneous karyotypes, but are clonal for aneuploidy. Progression to malignancy corresponds to selection of ever more aggressive karyotypic variants. (iv) Both non-genotoxic and genotoxic carcinogens can cause aneuploidy by physical or chemical interaction with mitosis proteins. We conclude that aneuploidy offers a mechanism of phenotype alteration which--above a certain threshold--is sufficient to cause all cancer-specific phenotypes, and is independent of gene mutation.

Genetic instability of cancer cells is proportional to their degree of aneuploidy.

Genetic and phenotypic instability are hallmarks of cancer cells, but their cause is not clear. The leading hypothesis suggests that a poorly defined gene mutation generates genetic instability and that some of many subsequent mutations then cause cancer. Here we investigate the hypothesis that genetic instability of cancer cells is caused by aneuploidy, an abnormal balance of chromosomes. Because symmetrical segregation of chromosomes depends on exactly two copies of mitosis genes, aneuploidy involving chromosomes with mitosis genes will destabilize the karyotype. The hypothesis predicts that the degree of genetic instability should be proportional to the degree of aneuploidy. Thus it should be difficult, if not impossible, to maintain the particular karyotype of a highly aneuploid cancer cell on clonal propagation. This prediction was confirmed with clonal cultures of chemically transformed, aneuploid Chinese hamster embryo cells. It was found that the higher the ploidy factor of a clone, the more unstable was its karyotype. The ploidy factor is the quotient of the modal chromosome number divided by the normal number of the species. Transformed Chinese hamster embryo cells with a ploidy factor of 1.7 were estimated to change their karyotype at a rate of about 3% per generation, compared with 1.8% for cells with a ploidy factor of 0.95. Because the background noise of karyotyping is relatively high, the cells with low ploidy factor may be more stable than our method suggests. The karyotype instability of human colon cancer cell lines, recently analyzed by Lengnauer et al. [Lengnauer, C., Kinzler, K. W. & Vogelstein, B. (1997) Nature (London) 386, 623-627], also corresponds exactly to their degree of aneuploidy. We conclude that aneuploidy is sufficient to explain genetic instability and the resulting karyotypic and phenotypic heterogeneity of cancer cells, independent of gene mutation. Because aneuploidy has also been proposed to cause cancer, our hypothesis offers a common, unique mechanism of altering and simultaneously destabilizing normal cellular phenotypes.

The AIDS dilemma: drug diseases blamed on a passenger virus.

Almost two decades of unprecedented efforts in research costing US taxpayers over $50 billion have failed to defeat Acquired Immune Deficiency Syndrome (AIDS) and have failed to explain the chronology and epidemiology of AIDS in America and Europe. The failure to cure AIDS is so complete that the largest American AIDS foundation is even exploiting it for fundraising: 'Latest AIDS statistics-0,000,000 cured. Support a cure, support AMFAR.' The scientific basis of all these unsuccessful efforts has been the hypothesis that AIDS is caused by a sexually transmitted virus, termed Human immunodeficiency virus (HIV), and that this viral immunodeficiency manifests in 30 previously known microbial and non-microbial AIDS diseases. In order to develop a hypothesis that explains AIDS we have considered ten relevant facts that American and European AIDS patients have, and do not have, in common: (1) AIDS is not contagious. For example, not even one health care worker has contracted AIDS from over 800,000 AIDS patients in America and Europe. (2) AIDS is highly non-random with regard to sex (86% male); sexual persuasion (over 60% homosexual); and age (85% are 25-49 years old). (3) From its beginning in 1980, the AIDS epidemic progressed non-exponentially, just like lifestyle diseases. (4) The epidemic is fragmented into distinct subepidemics with exclusive AIDS-defining diseases. For example, only homosexual males have Kaposi's sarcoma. (5) Patients do not have any one of 30 AIDS-defining diseases, nor even immunodeficiency, in common. For example, Kaposi's sarcoma, dementia, and weight loss may occur without immunodeficiency. Thus, there is no AIDS-specific disease. (6) AIDS patients have antibody against HIV in common only by definition-not by natural coincidence. AIDS-defining diseases of HIV-free patients are called by their old names. (7) Recreational drug use is a common denominator for over 95% of all American and European AIDS patients, including male homosexuals. (8) Lifetime prescriptions of inevitably toxic anti-HIV drugs, such as the DNA chain-terminator AZT, are another common denominator of AIDS patients. (9) HIV proves to be an ideal surrogate marker for recreational and anti-HIV drug use. Since the virus is very rare (< 0.3%) in the US/European population and very hard to transmit sexually, only those who inject street drugs or have over 1,000 typically drug-mediated sexual contacts are likely to become positive. (10) The huge AIDS literature cannot offer even one statistically significant group of drug-free AIDS patients from America and Europe. In view of this, we propose that the long-term consumption of recreational drugs (such as cocaine, heroin, nitrite inhalants, and amphetamines) and prescriptions of DNA chain-terminating and other anti-HIV drugs, cause all AIDS diseases in America and Europe that exceed their long-established, national backgrounds, i.e. > 95%. Chemically distinct drugs cause distinct AIDS-defining diseases; for example, nitrite inhalants cause Kaposi's sarcoma, cocaine causes weight loss, and AZT causes immunodeficiency, lymphoma, muscle atrophy, and dementia. The drug hypothesis predicts that AIDS: (1) is non-contagious; (2) is non-random, because 85% of AIDS causing drugs are used by males, particularly sexually active homosexuals between 25 and 49 years of age, and (3) would follow the drug epidemics chronologically. Indeed, AIDS has increased from negligible numbers in the early 1980s to about 80,000 annual cases in the early '90s and has since declined to about 50,000 cases (US figures). In the same period, recreational drug users have increased from negligible numbers to millions by the late 1980s, and have since decreased possibly twofold. However, AIDS has declined less because since 1987 increasing numbers of mostly healthy, HIV-positive people, currently about 200,000, use anti-HIV drugs that cause AIDS and other diseases. (ABSTRACT TRUNCATED)

Kinetics analysis of consecutive HIV proteolytic cleavages of the Gag-Pol polyprotein.

The ordered, sequential cleavages of the Gag-Pol polyprotein by human immunodeficiency virus (HIV) protease present the virus with severe limitations on viable mutations of the enzyme. An extension of the method of Kuchel et al. (Kuchel, P. W., Nichol, L. W., and Jeffrey, P. D. (1974) J. Theor. Biol. 48, 39-49) for the analysis of consecutive enzyme reactions leads to a simple description of the catalytic efficiency of mutant and wild type HIV protease in the presence or absence of inhibitors. The overall catalytic efficiency of a mutant HIV protease relative to the wild type enzyme is given by the product of the ratios of their respective efficiencies for the 8 obligatory cleavages. Under no conditions is HIV viable when the geometric mean efficiency of a mutant HIV protease is less than 61% of the wild type activity for each cleavage. The lower catalytic efficiencies of the mutant enzymes coupled with the exponential dependence on 1/(1 + [I]/Ki) more than offset the inhibitor resistance acquired by HIV protease. The conclusion of this analysis is that inhibitor-resistant mutant HIV proteases are very unlikely to contribute to viral viability in vivo. The results strongly suggest that future protease inhibitor clinical trials should measure the infectivity of the virions in blood plasma instead of relying on viral RNA levels.

Nucleophile labeling of cysteine and serine protease substrates.

Dipeptides containing fluorescein or biotin have been incorporated into proteolytic substrate cleavage products of bovine serum albumin generated by human cathepsin S or neutrophil elastase and into a fragment of the 31-kDa interleukin 1beta precursor by human interleukin 1beta-converting enzyme. Incorporation of the nucleophile is blocked by prior inhibition of the enzymes, and is not seen when proteolysis occurs in the absence of label, and the protease is then inhibited before the addition of label. Labeling is dependent on the pH, the time of reaction, and the concentrations of the nucleophile and substrate. Labeling of proteins can be readily detected by SDS-polyacrylamide gel electrophoresis. The pattern of elastase-labeled bovine serum albumin bands differs among P1' Phe, Ala, and Gly, suggesting that nucleophilic attack on acyl enzyme intermediates derived from a large protein may differ from attack on small intermediates. The only observed labeled fragment catalyzed by interleukin 1beta-converting enzyme is fragment 28-116 from the interleukin 1beta precursor, suggesting that the cleavage between residues 27 and 28 is at least as efficient as between residues 116 and 117. This labeling method does not require organic solvent or nonphysiological pH values and thus may be useful for the discovery of novel protease substrates in cells or other in vivo systems or for diagnostic applications.

Antimalarial effects of vinyl sulfone cysteine proteinase inhibitors.

We evaluated the antimalarial effects of vinyl sulfone cysteine proteinase inhibitors. A number of vinyl sulfones strongly inhibited falcipain, a Plasmodium falciparum cysteine proteinase that is a critical hemoglobinase. In studies of cultured parasites, nanomolar concentrations of three vinyl sulfones inhibited parasite hemoglobin degradation, metabolic activity, and development. The antimalarial effects correlated with the inhibition of falcipain. Our results suggest that vinyl sulfones or related cysteine proteinase inhibitors may have promise as antimalarial agents.

Peptidyl vinyl sulphones: a new class of potent and selective cysteine protease inhibitors: S2P2 specificity of human cathepsin O2 in comparison with cathepsins S and L.

Peptidyl vinyl sulphones are a novel class of extremely potent and specific cysteine protease inhibitors. They are highly active against the therapeutically important cathepsins O2, S and L. The highest kinact/K1 values exceed 10(7)M(-1) x s(-1) for cathepsin S and 10(5)M(-1) x s(-1) for cathepsins O2 and L. To study the primary specificity site of the novel human cathepsin O2 and the effectiveness of this novel class of inhibitors, a series of peptidyl vinyl sulphones with variations in the P2 residue was synthesized. Leucine in the P2 position was proven to be the most effective residue for cathepsin O2 and also for cathepsins S and L. Cathepsins O2 and S share a decreased accessibility towards P2 hydrophobic non-branched residues such as aminohexanoic acid (norleucine), methionine and oxidized methionine, but are distinguished by their different affinity towards phenylalanine in the P2 position. In contrast, cathepsin S accepts a broader range of hydrophobic residues in its S2 subsite than cathepsins O2 and L. The primary specificity-determining subsite pocket S2 in cathepsin O2 appears to be spatially more restricted than those of cathepsins S and L.

Antimalarial effects of peptide inhibitors of a Plasmodium falciparum cysteine proteinase.

We previously identified a Plasmodium falciparum trophozoite cysteine proteinase (TCP) and hypothesized that it is required for the degradation of host hemoglobin by intraerythrocytic malaria parasites. To test this hypothesis and to evaluate TCP as a chemotherapeutic target, we examined the antimalarial effects of a panel of peptide fluoromethyl ketone proteinase inhibitors. For each inhibitor, effectiveness at inhibiting the activity of TCP correlated with effectiveness at both blocking hemoglobin degradation and killing cultured parasites. Benzyloxycarbonyl (Z)-Phe-Arg-CH2F, the most potent inhibitor, inhibited TCP at picomolar concentrations and blocked hemoglobin degradation and killed parasites at nanomolar concentrations. Micromolar concentrations of the inhibitor were nontoxic to cultured mammalian cells. These results support the hypothesis that TCP is a necessary hemoglobinase and suggest that it is a promising chemotherapeutic target.

Plasmodium falciparum: inhibitors of lysosomal cysteine proteinases inhibit a trophozoite proteinase and block parasite development.

Trophozoites of Plasmodium falciparum obtain free amino acids for protein synthesis by degrading host erythrocyte hemoglobin in an acidic food vacuole. We previously reported that leupeptin and L-trans-epoxysuccinyl-leucylamido(4-guanidino)butane (E-64), two inhibitors of the cysteine class of proteinases, blocked hemoglobin degradation in the trophozoite food vacuole, and we identified a 28-kDa trophozoite cysteine proteinase as a potential food vacuole hemoglobinase. We now report that the biochemical properties of the trophozoite cysteine proteinase closely resembled those of the lysosomal cysteine proteinases cathepsin B and cathepsin L. The trophozoite proteinase had a pH optimum of 5.5-6.0, near that of both lysosomal proteinases, and it was efficiently inhibited by highly specific diazomethylketone and fluoromethylketone inhibitors of cathepsin B and cathepsin L. The trophozoite proteinase preferred peptide substrates with arginine adjacent to hydrophobic amino acids, as does cathepsin L. Micromolar concentrations of the fluoromethylketone inhibitor Z-Phe-Ala-Ch2F blocked the degradation of hemoglobin in the trophozoite food vacuole and prevented parasite multiplication. In previous studies much higher concentrations of the inhibitor were not toxic for mice. Our results provide additional evidence that the 28-kDa trophozoite proteinase is a food vacuole hemoglobinase and suggest that specific inhibitors of the enzyme may have potential as antimalarial drugs.

Cathepsin B in cells of two rat sarcomas with different rates of spontaneous metastasis.

The cysteine proteinase cathepsin B (EC 3.4.22.1) is believed to take part in biochemical processes underlying tumor metastasis. In the present study, the cellular localization, intracellular levels and extracellular release of cathepsin B activity were examined in vitro in cells of two rat sarcoma variants, LW13K2 and RPS, differing in their capacity to metastasize spontaneously to the lung of syngeneic LEW/CUB rats. The LW13K2 sarcoma metastasizes rarely, whereas the LW13K2-derived RPS variant produces a metastasis incidence of above 50%. Using fluorescent cytochemical staining, microgranular reaction centers of cathepsin B were observed in the cell cytoplasm, in some cellular processes, with apical localization in some of them, as well as at the extreme cell periphery in cells of both sarcoma variants. The appearance of this distribution of cathepsin B activity was delayed in the RPS variant. Biochemically, the intracellular level of cathepsin B activity was significantly higher in homogenates of LW13K2 cells than RPS cells. In contrast to the intracellular enzyme activity, RPS cells cultured in serum-free medium at pH 6.5 released a substantially higher amount of cathepsin B activity than LW13K2 cells into the extracellular environment; at pH 7.4 the initially higher release of cathepsin B activity from RPS cells later equalized with that from LW13K2 cells. Taken together, the results indicate that changes of pericellular pH can modulate the extracellular release of cathepsin B in both sarcoma cell variants and suggest that the rate of cathepsin B release under conditions of mildly acid pericellular pH could be related to the incidence of metastases observed in these rat sarcoma variants. Total intracellular cathepsin B activity did not exhibit positive correlation with the metastatic potential of the studied rat sarcoma variants.

Cysteine proteinase activity in arthritic rat knee joints and the effects of a selective systemic inhibitor, Z-Phe-AlaCH2F.

The role of cathepsin B, H and L activities in arthritic processes was studied histochemically using specific synthetic substrates in a postcoupling method on unfixed and undecalcified cryostat sections of rat knee joints. Only cathepsin B in synoviocytes, chondrocytes and fibroblasts showed a strong increase in activity due to antigen induced arthritis. The addition of a tissue stabilizer, polyvinyl alcohol, to the incubation medium enabled us to demonstrate extracellular enzymic activity within the articular cartilage matrix of arthritic joints. Both intravenous and oral treatment of the animals with a selective inhibitor of cathepsin B, Z-Phe-Ala fluoromethyl ketone (CH2F), during the development of arthritis suppressed the degree of inflammation and resulted in decreased intracellular and extracellular cathepsin B activity as detected histochemically, and less cartilage damage. Our study indicates that (a) cathepsin B-like activity plays a role in the cascade of proteolytic cartilage destruction, (b) chondrocytes and fibroblasts may well be involved in the breakdown of cartilage and ligaments, and (c) Z-Phe-AlaCH2F could be of therapeutic value.

Visualization of time-dependent inactivation of human tumor cathepsin B isozymes by a peptidyl fluoromethyl ketone using a fluorescent print technique.

A peptidyl fluoromethyl ketone (Z-Phe-Ala CH2F) was found to be an effective compound in a time dependent inactivation of cathepsin B isozymes from a number of tissues including human tumors. The effect was visualized by employing an activity-specific fluorescent print technique preceded by isoelectric focusing. The technique could yield additional information of selective inhibition of isozymes as observed with rat pancreas. The fluoromethyl ketone is 30-fold more potent than the known inhibitor of cathepsin B, Z-Phe-AlaCHN2 in parallel evaluation. Furthermore, the fluoromethyl ketone may have in vivo potential in the inhibition of cathepsin B, in view of the results of toxicological studies. The findings demonstrate that the application of enzyme-directed overlay membranes, impregnated with specific substrates, following isoelectric focusing could be very useful in the study of proteases and their involvement in the oncogenic process.

A direct, highly sensitive assay for cytochrome P-450 catalyzed O-deethylation using a novel coumarin analog.

The microsomal O-deethylation of a novel coumarin analog, 7-ethoxy-4-trifluoromethylcoumarin (EFC), to a fluorescent product was characterized. Results indicate that this analog provides a rapid, convenient and highly sensitive means to assay cytochrome P-450-mediated metabolism. Like microsomal 7-ethoxycoumarin (7-EC) O-deethylation, EFC O-deethylation responded to both phenobarbital was greater than that seen with 7-EC (5- to 6-fold over control after 50 mg/kg/day for 4 days in Sprague-Dawley rats compared to approximately 2-fold for 7-EC). Since the reaction was monitored by direct fluorometry of the product, any departures from linearity under a particular set of reaction conditions (e.g. with highly induced samples) were immediately apparent. In the absence of an NADPH-regenerating system, background drift was very low (less than 0.01 fluorescent units), so the sensitivity of the assay was limited primarily by that of the fluorometer employed. This makes the assay particularly useful in situations where test material is limited, e.g. when measuring activity in cultured hepatocytes. Its simplicity, reproducibility, and response to a variety of inducing agents also make it suitable for a rapid screening assay for cytochrome P-450 induction.