Heat-labile Activity Research Articles

Potential Applications for Annona squamosa Leaf Extract in the Treatment and Prevention of Foodborne Bacterial Disease

Foodborne disease is a major public health problem. The present study examined Annona squamosa leaves, which are traditionally used to treat diarrhea and other infections, for their potential to be used in modern food safety or medicine. Active constituents were partially purified by ethanol extraction and column chromatography. MICs of the extract were 62.5 to 125 microg/mL against Bacillus cereus, Listeria monocytogenes and Staphylococcus aureus, and 250 microg/mL against Campylobacter jejuni. In time-kill assays, 500 microg/mL of the extract reduced colony forming unit numbers of C. jejuni almost 10 000-fold within 12 hours. Similar decreases were seen against B. cereus, but over a longer time-frame. LC-MS analysis indicated the presence of reticuline and oxophoebine. Assessment of stability by MIC assay showed activity was heat-labile, with loss of activity greatest following high temperature treatments. Activity was relatively stable at refrigeration temperature. These results indicate A. squamosa has broad-spectrum but heat-labile activity against foodborne bacterial pathogens, and bactericidal activity against B. cereus and C. jejuni. This bactericidal activity is not sufficiently rapid for A. squamosa to be used as a food sanitizer, but the extract could potentially be developed as an additive for refrigerated foods, or a modern treatment for foodborne illness.

Unsuccessful search for DNA transfer from transgenic plants to bacteria in the intestine of the tobacco horn worm, Manduca sexta

DNA transfer from transgenic plants to native intestinal bacteria and introduced Acinetobacter BD413 was assessed in the gut of the tobacco horn worm (Manduca sexta). The marker was kanamycin resistance gene (nptll), and tobacco carrying the nptll gene in the chloroplasts served as the donor. We detected neither whole gene transfer to native bacteria, nor transfer of fragments of nptll to Acinetobacter, using a marker exchange assay. This negative result was attributed to a heat-labile activity that degraded DNA in the feces, probably DNAase. Nevertheless, a few intact leaf cells survived transit through the gut, and DNA extracted from feces did transform Acinetobacter, albeit at lower frequencies than DNA extracted from leaves.

Inhibition of Escherichia coli heat-labile enterotoxin by neoglycoprotein and anti-lectin antibodies which mimic GM1 receptor.

Escherichia coli producing heat-labile enterotoxin is responsible for numerous cases of diarrhea worldwide, leading to considerable morbidity and mortality. The B subunits of this toxin are responsible for the binding to the receptor, the complex ganglioside GM1 which has galactose as its terminal sugar. In this study we showed that analogs of galactose (gal) and N-acetylgalactosamine (GalNAc) interfere with the binding of heat-labile toxin to GM1. Antibodies to lectins which mimic sugar structures and neoglycoprotein were employed. These compounds were able to inhibit heat-labile toxin activity efficiently in Vero cells: 37 microg of IgG-enriched fraction from an antiserum inhibited up to 70% of this activity, and 50% of the binding of heat-labile toxin to GM1. Neoglycoprotein was more efficient than antibodies, since 2.5 microg of this ligand completely abolished the activity of heat-labile toxin on Vero cells. These data suggest that these molecules could be developed for prophylaxis and diagnosis of diarrhea caused by heat-labile toxin.

Irreversible conversion of xanthine dehydrogenase into xanthine oxidase by a mitochondrial protease

Irreversible conversion of xanthine dehydrogenase (XDH) to its oxygen free radical producing oxidase (XO) form occurs through an uncharacterized proteolytic process, which was studied in human liver. Upon incubation of fresh unfrozen liver cytosol, XDH remained intact. When recombinant human XDH was coincubated with subcellular fractions of human liver, the mitochondrial intermembrane space was shown to contain a heat-labile activity that converted XDH irreversibly to XO. This activity is resistant to inhibitors of all major groups of proteases. We postulate that this novel type of proteolytic enzyme is released into the cytosol upon mitochondrial damage.

Production of two extracellular alkaline phosphatases by a psychrophilic arthrobacter strain

We surveyed our collection of psychrophilic bacteria to determine the types of phosphatases they produce and whether any had heat-labile activities with potential applications. Assays at different temperatures showed that the activity from one isolate was optimal at 45(deg)C and decreased dramatically above 55(deg)C. This isolate, D10, had the rod-coccus morphological cycle and cell wall amino acids associated with members of the Arthrobacter genus. Interestingly, we found that this strain made two extracellular phosphatases that could be separated by ammonium sulfate fractionation and migration during polyacrylamide gel electrophoresis. One enzyme, designated D10A, hydrolyzed both X-phos (5-bromo-4-chloro-3-indolyl phosphate) and para-nitrophenyl phosphate as substrates and had activity over a broad pH range of 7 to 11. The second enzyme, D10B, lacked activity against X-phos and had a narrow pH range of about 8 to 9. In addition, the D10B enzyme required calcium for activity. The levels of activity of both enzymes decreased for cells grown in media containing more than 100 (mu)M P(infi). These results not only demonstrate the existence of different enzymes from one Arthrobacter strain but also suggest ways in which other studies may have missed phosphatases with unknown requirements.

A teratocarcinoma-derived neurotrophic activity.

In a search for nerve growth factor (NGF) in tissue extracts of a murine transplantable teratocarcinoma that harbours immature neural tissue in abundance, a trypsin-sensitive and heat labile neurotrophic activity was identified. The final protein fraction obtained by cation exchange chromatography contained five proteins with mol. wts ranging from 52 to 72 kD. It supported the growth and differentiation of immature neurones in neonatal rat cerebellar cultures but had no effect on embryonic chick dorsal root ganglia which are the classical targets for NGF.

Plant cell wall-lysing enzymes in the apoplast of tomato leaves infected with Fulvia fulva

Apoplastic fluid recovered from healthy (uninfected) tomato leaves and from leaves infected with races of Fulvia fulva (Cooke) Ciferri (syn. Cladosporium fulvum (Cooke)) contained heat-labile lytic activities that solubilised carbohydrates from plant cell walls. Total activity was slightly enhanced in apoplastic fluid from infected plants. Material solubilised from uniformly 14C-labelled plant cell walls by apoplastic fluid from compatible and incompatible interactions and from the uninfected plant was analysed. 14C-Labelled poly-, oligo-, and mono-saccharides were detected, suggesting that both exo- and endo-hydrolase activities were present; endoactivity predominated during the early stages of infection. Fluid collected from incompatible interactions as early as 5–7 days postinoculation contained enhanced levels of an activity that solubilised arabinose-rich polysaccharide; by 9–11 days postinoculation, this activity had decreased and was comparable to that of the healthy plant. A similar activity was also seen in fluid from compatible interactions, but this was enhanced slightly later in the infection and increased rapidly during days 9–11 postinoculation. We suggest that the early and short-lived enhanced expression of an endohydrolase that attacks an arabinose-rich polymer may be related to disease resistance. Key words: tomato, Fulvia fulva (Cooke) Ciferri (syn. Cladosporium fulvum (Cooke)), apoplastic fluid, cell wall degrading enzymes, compatibility, oligosaccharin.

Regulation of the human ApoA-II gene by the synergistic action of factors binding to the proximal and distal regulatory elements.

We have recently shown that the human apoA-II promoter contains a set of 11 distal regulatory elements between nucleotides -903 and -255 and three proximal regulatory elements between nucleotides -126 and -33 that are essential for hepatic and intestinal transcription of the apoA-II gene (Chambaz, J., Cardot, P., Pastier, D., Zannis, V. I., and Cladaras, C. (1991) J. Biol. Chem. 266, 11676-11685). Deletion or nucleotide substitution analysis has shown that alterations in elements L (nucleotides -803 to -773) and K (nucleotides -760 to -743) reduced hepatic transcription to 25 and 20% and intestinal transcription to 8 and 4% of control, respectively, as measured by chloramphenicol acetyltransferase assays, indicating that these elements play an important regulatory role. Nucleotide substitutions in element AB (nucleotides -65 to -33) reduced hepatic and intestinal transcription to 60 and 36% of control, respectively. The factors that recognize regulatory regions L, K, and AB were analyzed by DNA binding gel electrophoretic and competition assays. This analysis has shown that elements AB, K, and L bind with different affinities to a newly characterized heat-stable factor, CIIIB1, which is a transcriptional activator of the human apoC-III gene (Ogami, K., Kardassis, D., Cladaras, C., and Zannis, V. I. (1991) J. Biol. Chem. 266, 9640-9646). In addition, elements AB and K bind a heat-labile activity, designated AIIAB1, and element L binds to several CCAAT box binding activities. Mutations in domain L that prevented the binding of CCAAT box binding activities reduced both hepatic and intestinal transcription to 30% of control, indicating the importance of these factors in transcription. Simultaneous nucleotide substitutions that prevented the binding of CIIIB1 activity in elements AB, K, and L reduced hepatic and intestinal transcription to 7 and 6% of control, respectively, suggesting that the synergistic interaction of CIIIB1 (bound to the proximal and distal regulatory elements) with CCAAT box proteins (bound to element L) can modulate the level of transcription of the human apoA-II gene.

Identification of transcription factors required for the expression of mammalian U6 genes in vitro.

Transcription factors, required for the basal expression of the mouse U6 gene were identified in extracts from HeLa cells. This gene is transcribed at least four times more efficiently than its human counterpart in extracts from mouse or HeLa cells and hence provides an excellent in vitro system for the identification of transcription factors involved in the basal expression of mammalian U6 genes. At least four separate protein components were found to be required in addition to RNA polymerase III for correct synthesis of U6 RNA in vitro. These correspond to: (i) TFIIIB; (ii) a heat labile activity contained in a protein fraction enriched in TFIID; (iii) an, as yet, uncharacterized component contained in the flow-through upon rechromatography on phosphocellulose, and finally; (iv) a protein specifically binding to the mouse U6 gene promoter and transactivating its expression. Transcription factors IIIA and IIIC are not involved in mammalian U6 transcription in vitro. The U6-specific transcription factor has a molecular mass of approximately 90 +/- 10 kDa. It specifically binds to the U6 gene from bp -42 to -78 on the coding and from bp -37 to -79 on the non-coding strand thereby centrally encompassing the PSE motif of the mouse U6 promoter. The binding activity of this protein is correlated with the efficiency with which the U6 gene is transcribed in vitro, thereby indicating a crucial role of the PSE-binding protein for U6 transcription.

Antibody-dependent alternate pathway of complement activation in opsonophagocytosis of Porphyromonas gingivalis

It has been suggested that the ability of Porphyromonas gingivalis to proteolyse complement, as well as its production of a capsule, contributes to resistance to phagocytosis by polymorphonuclear leukocytes. In this report, the opsonic role of serum complement and its activation pathways were investigated, using individual sera heat treated or depleted of factors B, C2, and C1q and the divalent cations Mg2+ and Ca2+. A fluorochrome microassay was used to quantitate phagocytosis of P. gingivalis A7436 by human polymorphonuclear leukocytes. Heat treatment of rabbit antiserum to P. gingivalis (RaPg) (56 degrees C, 30 min) resulted in a reduction in phagocytosis from 100% to 55% +/- 5%, while heat treatment of chronic adult periodontal disease serum abrogated phagocytosis. The heat-labile activity of RaPg was fully restored with MgEGTA-chelated rabbit serum but not EDTA- or EGTA-chelated rabbit serum. The addition of serum depleted of factor B but not C2 or C1q restored most of the heat-labile activity; however, the factor B-depleted serum was suspect, due to low-level opsonization of zymosan (inhibitable by EDTA but not MgEGTA). Adding C1q at 80 micrograms/ml to serum depleted of C1q restored much but not all of the activity lost through heat treatment or through depletion of C1q. A large part of opsonic activity with C2- and C1q-depleted sera was enhanced by the addition of 4 x 10(-3) M Mg2+. The data indicate that although opsonophagocytosis of P. gingivalis A7436 is dependent on the classical complement pathway, a significant contribution is made by an antibody-dependent alternate pathway.

A Monocyte-Derived Factor Interferes with Detection of Reverse Transcriptase in HIV-1 Infection

Culture supernatants from the rabbit macrophage cell line 6083 infected with a retrovirus, human immunodeficiency virus type 1 (HIV-1), were negative for reverse transcriptase (RT) expression although the line was shown to be productively infected by all other criteria tested. Supernatants from uninfected cultures of 6083, the human monocyte line U937, and from freshly isolated peripheral human monocytes, were found to contain a monocyte-derived inhibitory factor (MDIF) which interferes with a standard assay for RT. MDIF is a heat-labile activity of approximately of 40 kD. Both substrates and products of the reverse transcriptase assay are degraded by MDIF which is not affected by reduction and alkylation of disulfide bonds. MDIF is inhibited by the addition of a particular thioated oligonucleotide (S-dG30) to the reaction mixture but this addition also inhibits RT. The optimum method to minimize MDIF interference in the RT assay is by addition of ethylene glycol bis-(beta-aminoethyl ether)N,N,N',N'-tetraacetic acid (EGTA); MDIF requires divalent cations for activity and has a strong preference for calcium which is preferentially chelated by EGTA. The potential presence of this inhibitory activity should be considered when using RT levels as a measure of retroviral infection.

HPLC separation of alkaline phosphatase isoenzymes. Application to the amniotic fluid

Alkaline phosphatase (AP; orthophosphoric-monoester phosphohydrolase, alkaline optimum; EC 3.1.3.1) is a polymorph glycoprotein. Three gene loci encode two tissue-specific isoenzymes intestinal and placental and a third nonspecific isoenzyme found in liver, bone and kidney. These last isoforms differ by their carbohydrate content [l]. In a previous publication, we described the link existing between the lecithin/ sphingomyelin ratio [2] and the amniotic fluid (AF) AP activity expressed as the ratio; AP heat labile activity versus AP total activity. This ratio, independent of analytical conditions and amniotic fluid volume variations, allowed the prediction of foetal lung maturity and was considered to be helpful in assessing the risk of respiratory distress syndrome in the neonate [3]. In order to account for the relationship between amniotic fluid AP activity and foetal lung maturity, it is necessary to identify the AP isoenzyme responsible for the increasing activity demonstrated during the last term of gestation [3,4]. In this study we describe a rapid and reproducible HPLC method to separate and identify AP isoenzymes in low-activity biological medium such as amniotic fluid.

Thyroid Hormone Receptors Form Distinct Nuclear Protein-Dependent and Independent Complexes with a Thyroid Hormone Response Element

We have examined the binding of nuclear proteins and recombinant thyroid hormone receptors (TRs) to the palindromic thyroid hormone responsive element AGGTCATGACCT (TREp) using a gel electrophoretic mobility shift assay. Four specific protein-DNA complexes were detected after incubation of nuclear extracts (NE) from T3-responsive pituitary (GH3) cells with a TREp-containing DNA fragment. This was compared with the TREp binding of reticulocyte lysate-synthesized TRs. TR alpha 1 and TR beta 2 each formed a single major TR:TREp complex which comigrated with the least retarded complex formed by GH3 NE, while TR beta 1 formed multiple complexes suggesting that it can bind to TREp as an oligomer. Interestingly, coincubation of 35S-TR alpha 1, GH3 NE, and unlabeled TREp resulted in not only the 35S-TR:TREp complex, but in two additional more greatly retarded complexes containing 35S-TR alpha 1 and comigrating with those formed by GH3 extract alone. Incubation of each of the TRs with NE from COS-7 cells, which do not possess sufficient endogenous TRs to mediate T3-responses, resulted in formation of a new, more greatly shifted complex. A similar, heat labile activity which altered mobility of the TR:TRE complex was also present in NE from T3-unresponsive JEG-3 cells. At high concentration of NE, all of the TR bound to TREp was more greatly retarded than in the absence of NE. Truncation of TR alpha 1 at amino acid 210 prevented additional complex formation in the presence of NE without affecting DNA binding, suggesting that the carboxyl-terminus of the TRs is essential for interaction with nuclear proteins.(ABSTRACT TRUNCATED AT 250 WORDS)

Strain Differences in the Opsonisation of Staphylococcus Epidermidis

Ten isolates of coagulase-negative staphylococci, collected from patients receiving treatment with continuous ambulatory peritoneal dialysis (CAPD), exhibited marked differences in the degree of opsonisation when incubated in 10% and 1% pooled human serum, 10% and 1% heat-treated serum, Hanks' Balanced Salt Solution, and timed peritoneal dialysis (PD) effluent. The addition of exogenous IgG to PD effluent results in a greater increase in opsonisation in those fluids with the weakest inherent opsonic activity, but is ineffective against the majority of isolates in the absence of heat-labile opsonic activity. The results of this in vitro study suggest that host resistance to CAPD peritonitis due to coagulase-negative staphylococci may be determined as much by the characteristics of the contaminating strain, as by the opsonising activity of PD effluent.

Demonstration of an endogenous activator for the Na+, K+-ATPase system

A heat-labile, non-dialysable and protease-sensitive endogenous activator (NaAF) capable of stimulating the Na+, K(+)-ATPase system has been demonstrated. The activator (NaAF) activity was partially enriched (about 10 fold) by dialysis (30 kDa cutoff) under negative pressure and pH 4.8 precipitation. The NaAF has been found to occur in the cytosolic fractions of tissues such as the kidney and brain from two different species (rabbit and pig) tested so far. Also, the factor from one tissue stimulates with equal efficacy the Na+, K(+)-ATPase systems of other tissues regardless of the species; thus demonstrating universal nature of the activator. Some degree of cross-reactivity was noted between the activating effects of this activator (for the Na+,K(+)-ATPase) and that for the H+,K(+)-ATPase recently described (J. Biol. Chem. 262:5664-5670, 1987). The purified NaAF obtained from sephacryl S-300 column chromatography activates the pure renal medullary Na+,K(+)-ATPase in a dose dependent manner.

Host-Pathogen Interactions XXXIV. A Heat-Labile Activity Secreted by a Fungal Phytopathogen Releases Fragments of Plant Cell Walls that Kill Plant Cells

Host-Pathogen Interactions XXXIV. A Heat-Labile Activity Secreted by a Fungal Phytopathogen Releases Fragments of Plant Cell Walls that Kill Plant Cells

RNA 3' processing regulates histone mRNA levels in a mammalian cell cycle mutant. A processing factor becomes limiting in G1-arrested cells.

Post-transcriptional regulation of histone gene expression in a mouse mastocytoma cell cycle mutant (21-Tb) depends largely on conserved DNA sequences that are essential for RNA 3' processing. We have analyzed whether this regulation occurs at the level of RNA 3' processing. We show, by RNase mapping, that nuclear H4 mRNA precursors, which are hardly detectable in total RNA from exponentially dividing cells, accumulate in G1-arrested cells, i.e. when mature mRNAs are drastically reduced. Furthermore, we show that a heat-labile component of the processing apparatus, recently identified in HeLa cell nuclear extracts, is limiting in extracts from G1-arrested 21-Tb cells. In contrast, this activity is in excess in extracts from exponentially dividing cells, whereas both extracts contain similar amounts of snRNPs of the Sm serotype. These fluctuations in the heat-labile activity may generally contribute to proliferation or cell cycle dependent histone gene regulation.

Mitotic spindle pulls but fails to separate chromosomes in type II DNA topoisomerase mutants: uncoordinated mitosis

The fission yeast top2 locus is defined by five temperature-sensitive mutations that cause heat-labile activity of type II DNA topoisomerase in the cell extracts. We show that the top2 locus is a structural gene for type II topoisomerase by cloning a genomic DNA fragment that complements top2. The top2 mutants at restrictive temperature produce abnormal chromosomes at the time of mitosis; these are transiently extended into filamentous structures along with the elongating mitotic spindle but are not separated. A primary defect in top2 appears to be the formation of aberrant mitotic chromosomes inseparable by the force generated by the spindle apparatus. Consistently, the top2 cells that become lethal during mitosis contain a catenated dimer of an ARS plasmid. DNA and RNA continue to be synthesized if cytokinesis is blocked. Uncoordinated mitosis, that is the occurrence of spindle dynamics without chromosome separation, is revealed in top2, and is discussed in relation to mitotic regulation. Different phenotypes between top2 and top1-top2 described in the present paper can be explained by a previously proposed hypothesis that type II topoisomerase has dual in vivo functions: one that decatenates and unknots duplex DNAs is essential in mitosis, whereas the other which relaxes supercoils is required throughout the cell cycle if type I topoisomerase is absent.

The role of formaldehyde in hydrazine-induced methylation of liver DNA guanine.

Administration of the hepatotoxin and carcinogen, inorganic hydrazine, to rodents results in the formation of 7-methylguanine and O6-methylguanine in liver DNA; co-administration of [methyl-14C]methionine or [14C]formate with the hydrazine labels the methylguanines, suggesting involvement of the 1-carbon pool in the methylation process. The present study investigates the proposal that the methylation mechanism involves reaction of hydrazine with endogenous formaldehyde to yield formaldehyde hydrazone, which could be metabolized to the potent methylating agent diazomethane. Hamsters were pretreated with methanol, ethanol or cyanamide to alter the endogenous hepatic aldehyde levels prior to administration of hydrazine. Formaldehyde levels were refractory to the pretreatments; hepatic acetaldehyde levels were increased, but hydrazine administration under such conditions did not result in the formation of ethylated guanines in DNA. Methanol and ethanol inhibited hydrazine-induced methylation of DNA. Hydrazine incubated with liver S9 fraction and calf thymus DNA induced the formation of 7-methylguanine and O6-methylguanine when formaldehyde was present in the incubation system; substitution of formaldehyde with acetaldehyde in the incubation medium did not result in any detectable alkylation of DNA. Both liver microsomal and cytosolic fractions demonstrated heat-labile activity in supporting the hydrazine-induced methylation process. Tetraformyltrisazine, or a similar reaction product of hydrazine and formaldehyde, may be a more important intermediate than formaldehyde hydrazone in the hydrazine-induced methylation of DNA.

Characterization of VP-16-induced DNA damage in isolated nuclei from L1210 cells

Based on the observation that VP-16-induced DNA damage can be demonstrated in isolated nuclei but not in purified DNA, and that this effect is temperature-dependent, it is postulated that the mechanism of action of VP-16 involves an essential intranuclear event, perhaps enzyme-mediated, which is a prerequisite for the cleavage of DNA. Using alkaline elution to assay single-strand breaks in isolated L1210 nuclei, we have further characterized conditions influencing this putative intranuclear reaction. We have found drug activity to be dependent on magnesium and pH and to be stimulated by low concentrations of ATP (0.05–1 mM), an effect which was not observed with a nonhydrolyzable analog of ATP. Heat-labile activity in a nuclear non-histone protein extract was critical to VP-16-mediated DNA damage. This new evidence lends further credence to the hypothesis that activity of an intranuclear enzyme, possessing characteristics consistent with a type II DNA topoisomerase, is a prerequisite for the cleavage of DNA by VP-16.