Bacteriolytic effect of cessation of glucosamine supply, induced by specific inhibition of glucosamine-6-phosphate synthetase

The antibiotic tetaine (bacilysin) and its C-terminal epoxyaminoacid--anticapsin--are powerful inhibitors of glucosamine-6-phosphate synthetase (EC 5.3.1.19.) in cell-free extracts of Escherichia coli K-12. Tetaine acts on growing cells as a bactericidal agent. This bactericidal action, measured from 10 to 160 muM concentration, is a consequence of the induction of lysis of growing cells. The induction of lysis by tetaine is compared with the lytic action of some beta-lactams. Hypertonic medium, destruction of the antibiotic, presence of chloramphenicol or the addition of N-acetylglucosamine protect E. coli K-12 cells against lysis induced by tetaine. These effects are compared with those observed in the presence of penicillin G. The results indicate that inhibition of early or late stages of peptidoglycan synthesis all result in more or less the same consequence, i.e. death via cell lysis.     

Antibiotic tetaine, a new inhibitor of murein precursors synthesis in Escherichia coli K-12

tetaine, a low molecular weight broad spectrum antibiotic of aminoacid derivative type and of low toxicity, is an inhibitor of cell wall synthesis in $\text{Escherichia coli}$ K-12 3000 HFr strain. Tetaine inhibits the incorporation of ³H DAP and ³H L-Ala to murein of E. coli. In the presence of tetaine nucleotide precursors of murein synthesis were radioactive mainly due to the ³H uridine and not ¹⁴C alanine, what indicates the lack of incorporation of alanine to UDP-Mur-NAc. It is postulated that tetaine inhibits the synthesis of murein nucleotide precursors at the level of incorporation of first alanine moiety.     

Differential inhibition of DNA and RNA biosynthesis in HeLa S3 cells by tetaine, a dipeptide antibiotic

A dipeptide antibiotic, tetaine, was found to diminish the rate of incorporation of 3H-labelled precursors into nucleic acids of intact and permeabilized HeLa S3 cells with concomitant negligible effect on protein synthesis. Comparison of the inhibitory effects of tetaine indicates that the antibiotic at 0.03-0.1 mM is a selective inhibitor of cellular DNA biosynthesis and, at higher concentration, of DNA and RNA biosynthesis. Tetaine is also an inhibitor of DNA and RNA polymerase reactions in a cell-free system, as determined using partially purified extracts from HeLa S3 cells that served as a source of the enzymes. The pretreatment experiments showed that tetaine inactivated the polymerases without affecting DNA template function. The tetaine effect on biosynthesis of nucleic acids in HeLa S3 cells can be attributed rather to the intact antibiotic than to the product of its enzymatic cleavage, anticapsin.     

Pleiotropic effect of anticapsin on HeLa S3 cells

Anticapsin, the terminal epoxyaminoacid moiety of tetaine, inhibits irreversibly growth of HeLa S3 cells. The antibiotic decreases to a similar extent incorporation of 3H-labelled precursors into nucleic acids and protein in intact cells: inhibition of protein synthesis prevails on prolonged incubation. Also incorporation of [3H]dTTP and [3H]UTP is inhibited in the presence of anticapsin into permeabilized cells. These effects, however, are not due to the interference with DNA or RNA polymerases since anticapsin only slightly suppresses RNA polymerase activity and has no effect on DNA polymerase in the cell-free systems. The results indicate that the mechanism of antiproliferative action of anticapsin in HeLa S3 cells differs from that of tetaine and imply that inhibition of protein synthesis might be the primary effect of anticapsin.     

Reconstitution of interactions of Murine gammaherpesvirus 68 M11 with Bcl-2 family proteins in yeast

One of the mechanisms of defense against viral infection is induction of apoptosis in infected cells. To escape this line of protection, genomes of many viruses encode for proteins that inhibit apoptosis. Murid herpesvirus 4 gene M11 encodes for homologue of cellular Bcl-2 proteins that inhibits apoptosis and autophagy in infected cell. To study a role of M11 in regulation of apoptosis we have established a yeast model system in which the action of M11 together with proapoptotic proteins Bax, Bak and Bid can be studied. When expressed in yeast, M11 did not inhibit autophagic pathway, so only effects of expression of M11 on activity of coexpressed proapoptotic proteins could be observed. In this experimental setting M11 potently inhibited both proapoptotic multidomain proteins Bax and Bak. The antiapoptotic activity of M11 was suppressed by coexpression of proapoptotic BH3-only protein tBid, indicating that M11 inhibits apoptosis likely by the same mechanism as cellular antiapoptotic proteins Bcl-2 or Bcl-XL.     

Cell wall composition of the yeast and mycelial forms of Paracoccidioides brasiliensis

Isolation and chemical analyses of the cell walls of the yeast (Y form) and mycelial forms (M form) of Paracoccidioides brasiliensis and Blastomyces dermatitidis revealed that their chemical composition is similar and depends on the form. Lipids, chitin, glucans, and proteins are the main constituents of the cell walls of both forms of these fungi. There is no significant difference in the amount of lipids (5 to 10%) and glucans (36 to 47%) contained by the two forms. In both fungi, the Y form has a larger amount of chitin (37 to 48%) than the M form (7 to 18%), whereas the M form has a larger amount of proteins (24 to 41%) than the Y form (7 to 14%). Several properties of the glucan of P. brasiliensis were studied. Almost all of the glucan in the Y form was soluble in 1 n NaOH, was weakly positive in the periodic acid-Schiff reaction, was not hydrolyzed by snail digestive juice, and had alpha-glycosidic linkage. Glucans of the M form were divided into alkali-soluble (60 to 65%) and alkali-insoluble (35 to 40%) types. The alkali-soluble glucan was similar to that of the Y form; the alkali-insoluble glucan was positive in the periodic acid-Schiff reaction and was hydrolyzed by snail digestive juice.     

In vitro susceptibility of isolates of Sporothrix schenckii to amphotericin B, itraconazole, and terbinafine: comparison of yeast and mycelial forms

Forty-three clinical isolates of Sporothrix schenckii derived from humans and animals were evaluated in vitro for their susceptibility to amphotericin B, itraconazole, and terbinafine. MICs were determined by the method of micro dilution in liquid media, using protocols M27-A2 for the yeast form and M38-A for the mycelial form, both standardized by the Clinical Laboratory Standards Institute. In general, higher MICs were found for the mycelial form (intervals of up to two dilutions). In the case of amphotericin B, a significant difference in activity was observed, with higher values (p<0.05) found for the mycelial form. MICs for itraconazole and terbinafine were similar for both yeast and mycelial forms but slightly higher for mycelia. Although data presented here indicate different levels of susceptibility when both growth forms were compared, indicating an intrinsic difference between them, it is still difficult to draw a consensus as to which form correlates better with clinical findings. More studies are necessary to determine the criteria for in vitro tests that will lead to efficient therapeutic choices.     

Ca2+-calmodulin-activated cyclic nucleotide phosphodiesterase from the rabbit myometrium

Two forms of soluble phosphodiesterase of cyclic nucleotides separating by DEAE-cellulose ion-exchange chromatography and not only differing in physicochemical and catalytic parameters but also differently regulated by calmodulin are found in the doe myometrium. Calmodulin with 10(-7)-10(-5) M concentrations of Ca2+ promotes the two-fold activation of the 3':5'-AMP (but not of 3':5'-GMP) hydrolysis by the first form of phosphodiesterase. Trifluoperazine (10 microM) lowers the activating action of calmodulin. The second form of soluble phosphodiesterase is not sensitive to the action of both calmodulin and Ca2+. 3':5'-GMP (10 microM) inhibits the 3':5'-AMP hydrolysis by the first form of phosphodiesterase; calmodulin exerts no effect on this process. The data obtained testify to the possible participation of Ca2+ and calmodulin in Ca2+-calmodulin-dependent phosphodiesterase regulation of the content of cyclic nucleotides (3':5'-AMP, in particular) in the doe myometrium.     

Antibiotic tetaine — a selective inhibitor of chitin and mannoprotein biosynthesis in Candida albicans

The antibiotic tetaine inhibits in Candida albicans the biosynthesis of two important cell wall constituents, chitin and mannoprotein. This effect is a consequence of inactivation of the enzyme glucosamine-6-phosphate synthetase. Due to the lack of glucosamine-6-phosphate the effective secretion of mannoprotein enzymes, acid phosphatase and invertase, by Candida albicans spheroplasts is inhibited. In the presence of tetaine, probably a modified mannoprotein, lacking a branched polymannan, is synthesized. The antibiotic action decreases the viability of Candida albicans cells, especially that of mycelial forms of this fungus.Abbreviations GlcNAc N-acetyl-d-glucosamine - GlcN-6-P d-glucosamine-6-phosphate - ManNAc N-acetyl-d-mannosamine - -MM -methylmannoside - EGTA 1,2 di/2-aminoethoxy/ethane - N,N,N,N tetra-acetic acid     

Kinetic study of interaction between [14C]amphotericin B derivatives and human erythrocytes: relationship between binding and induced K+ leak

The relationship between polyene antibiotic binding to red cells and their membrane permeabilization was studied using two 14C-labelled amphotericin B (AmB) derivatives: N-fructosyl AmB and N-acetyl methyl ester AmB. The binding kinetics of both derivatives were determined on whole red cells and ghosts. The resulting experimental points were well fitted by monoexponential functions, and the characteristic t1/2 for both derivatives were calculated from these functions. At 2 X 10(-5) M, the half time t1/2 for N-acetyl methyl ester AmB (30.2 min) which forms aqueous aggregates was longer than the t1/2 for the more soluble species N-fructosyl AmB (4.5 min). At lower concentrations (10(-7) M), the t1/2 for N-acetyl methyl ester AmB (6.3 min) in a more solubilized form was close to that of N-fructosyl AmB (7.9 min). These results suggest that only solubilized species bound to red cell membranes and that disaggregation of aggregates is the limiting step in the binding process. The permeabilization of red cell membranes by N-fructosyl AmB, measured as intracellular K+ leak, was not instantaneous and at 10 degrees C external K+ was only detected 20 min after antibiotic addition. In contrast, binding occurs without lag time. Consequently, different mecanisms underlie binding and K+ permeability inducement. Absorption spectroscopy data showed that bound antibiotic is located in the hydrophobic membrane interior and that this penetration of the membrane by AmB derivatives occurs without lag time. Consequently, the lag time occurring for K+ permeability inducement would be due to some steps subsequent to binding and probably located in the hydrophobic membrane interior. This statement is further supported by the observation that the lag time is sensitive to changes in membrane fluidity as shown here by the break between 20 and 30 degrees C in the slope of the Arrhenius plot for the lag time, coinciding with the phase transition in red cell membranes.     

The effect of pH and reversible inhibitors on decarbamylation of acetylcholinesterase

Decarbamylation rate of membrane-bound methyl- and dimethyl-carbamylated acetylcholinesterase of human erythrocytes and bovine brain is reliably 1.1-1.6 times lower than that of the soluble enzyme. Such reversible inhibitors as tacrine (of non-competition action), ambenonium (mixed action) and galanthamine (competitive type of action) decelerate the decarbamylation rate of acetylcholinesterase. At pH 6 tacrine inhibits the reduction rate of soluble acetylcholinesterase activity of human erythrocytes more intensively than that of membrane-bound acetylcholinesterase. No differences in decarbamylation rate were found for the both forms of the enzyme at pH 8. Tacrine, a non-competitive inhibitor in concentrations below the inhibition constant (Ki = 1.4 x 10(-7) M) exerts the most intensive effect on the decarbamylation rate of methyl- and dimethylcarbamylated acetylcholinesterase of the mouse brain, while ambenonium and galanthamine in concentrations much (tens times) exceeding their Ki (3.1 x 10(-10) M and 4.4 x 10(-7) M, respectively) provide a decrease of the decarbamylation rate.     

Cell Wall Glucans of the Yeast and Mycelial Forms of Paracoccidioides brasiliensis

Glucans were isolated from the cell wall of the yeast (Y) and mycelial (M) forms of Paracoccidioides brasiliensis. The alkali-soluble glucan of the Y form had properties of alpha-1,3-glucan. The alkali-insoluble glucan of the M form was identified as a beta-glucan which contains a beta-(1 --> 3)-glycosidic linkage by infrared absorption spectrum, by effect of beta-1,3-glucanase, and by partial acid hydrolysis. The alkali-soluble glucans of the M form were a mixture of alpha- and beta-glucans and the ratio of alpha- to beta-glucan was variable, depending on the preparations.     

Enzymes in glycolysis and the citric acid cycle in the yeast and mycelial forms of Paracoccidioides brasiliensis

Kanetsuna, Fuminori (Instituto Venezolano de Investigaciones Cientificas, Caracas, Venezuela), and Luis M. Carbonell. Enzymes in glycolysis and the citric acid cycle in the yeast and mycelial forms of Paracoccidioides brasiliensis. J. Bacteriol. 92:1315-1320. 1966.-Enzymatic activities in glycolysis, the hexose monophosphate shunt, and the citric acid cycle in cell-free extracts of the yeast and mycelial forms of Paracoccidioides brasiliensis were examined comparatively. Both forms have the enzymes of these pathways. Activities of glucose-6-phosphate dehydrogenase and malic dehydrogenase of the mycelial form were higher than those of the yeast form. Another 15 enzymatic activities of the mycelial form were lower than those of the yeast form. The activity of glyceraldehyde-3-phosphate dehydrogenase showed the most marked difference between the two forms, its activity in the mycelial form being about 20% of that in the yeast form.     

Identification and characterization of a novel RanGTP-binding protein in the yeast Saccharomyces cerevisiae

The small Ras-like GTPase Ran plays an essential role in the transport of macromolecules in and out of the nucleus and has been implicated in spindle (1,2 ) and nuclear envelope formation (3,4 ) during mitosis in higher eukaryotes. We identified Saccharomyces cerevisiae open reading frame YGL164c encoding a novel RanGTP-binding protein, termed Yrb30p. The protein competes with yeast RanBP1 (Yrb1p) for binding to the GTP-bound form of yeast Ran (Gsp1p) and is, like Yrb1p, able to form trimeric complexes with RanGTP and some of the karyopherins. In contrast to Yrb1p, Yrb30p does not coactivate but inhibits RanGAP1(Rna1p)-mediated GTP hydrolysis on Ran, like the karyopherins. At steady state, Yrb30p localizes exclusively to the cytoplasm, but the presence of a functional nuclear export signal and the localization of truncated forms of Yrb30p suggest that the protein shuttles between nucleus and cytoplasm and is exported via two alternative pathways, dependent on the nuclear export receptor Xpo1p/Crm1p and on RanGTP binding. Whereas overproduction of the full-length protein and complete deletion of the open reading frame reveal no obvious phenotype, overproduction of C-terminally truncated forms of the protein inhibits yeast vegetative growth. Based on these results and the exclusive conservation of the protein in the fungal kingdom, we hypothesize that Yrb30p represents a novel modulator of the Ran GTPase switch related to fungal lifestyle.     

A comparative study of functional properties of calf chymosin and its recombinant forms

The action of calf chymosin obtained from transgenic sheep milk and the recombinant protein expressed in yeast Kluyveromyces lactis (Maxiren) on fluorogenic peptide substrates, namely Abz-A-A-F-F-A-A-Ded, Abz-A-A-F-F-A-A-pNA, Abz-A-F-F-A-A-Ded, Abz-A-A-F-F-A-Ded, Abz-A-A-F-F-Ded, Abz-A-A-F-F-pNA, and heptapeptide L-S-F-M-A-I-P-NH2, a fragment of kappa-casein (the native chymosin substrate), was investigated. It has been established that transgenic chymosin and recombinant chymosin (Maxiren) differ from the native enzyme in their action on low molecular weight substrates, whereas there was no difference in enzymatic action on protein substrates. Pepstatin, a specific inhibitor of aspartic proteinases, inhibits the recombinant chymosin forms less efficiently than the native enzyme. Perhaps this is associated with local conformational changes in the substrate binding site of recombinant chymosin occurring during the formation of the protein globule.     

Selective and asymmetric action of trypsin on the dimeric forms of seminal RNase.

Dimeric seminal RNase (BS-RNase) is an equilibrium mixture of conformationally different quaternary structures, one characterized by the interchange between subunits of their N-terminal ends (the MXM form); the other with no interchange (the M=M form). Controlled tryptic digestion of each isolated quaternary form generates, as limit digest products, folded and enzymatically active molecules, very resistant to further tryptic degradation. Electrospray mass spectrometric analyses and N-terminal sequence determinations indicate that trypsin can discriminate between the conformationally different quaternary structures of seminal RNase, and exerts a differential and asymmetric action on the two dimeric forms, depending on the original quaternary conformation of each form. The two digestion products from the MXM and the M=M dimeric forms have different structures, which are reminiscent of the original quaternary conformation of the dimers: one with interchange, the other with no interchange, of the N-terminal ends. The surprising resistance of these tryptic products to further tryptic action is explained by the persistence in each digestion product of the original intersubunit interface.     

Hexosaminidases and ganglioside catabolism in the GM2-gangliosidoses

The G_M2-gangliosidoses are a set of neurological diseases whose common features include the storage of the ganglioside G_M2, N-acetyl galactosaminyl (N-acetylneuraminyl-) galactosylglucosylceramide and related neutral glycosphingolipids in various organs (particularly brain) of affected individuals and the inability of such individuals' hexosaminidases to catalyze the hydrolysis of G_M2. Associated with this finding has been the demonstration of a deficiency in none, one or both major forms (A and B) of hexosaminidase which can be measured with artificial flurogenic or chromogenic substrates. Additionally, a deficiency in the A form of hexosaminidase which is usually associated with Tay-Sachs disease has been demonstrated in certain clinically normal adults.Recent advances in the purification of the two forms of hexosaminidase have allowed their catalytic, immunological, physical and genetic characteristics to be examined in great detail. This examination has resulted in the proposal of several models for the relationship of the hexosaminidases and their involvment in the G_M2-gangliosidoses. I discuss the evidence for these models and the implications which can be drawn from them in this review.     

Ultrastructure of Dimorphic Transformation in Paracoccidioides brasiliensis

The fine structure of Paracoccidioides brasiliensis undergoing temperature-dependent transformation from mycelium to yeast and vice versa (M right harpoon over left harpoon Y) was studied. The transitional form to mycelium from the yeast appears as an elongated bud that extends from the yeast and which has a mixture of characteristics from both the yeast and the mycelium. The transitional form to yeast from the mycelium starts with enlargement of the interseptal spaces and cracking of the outer electron-dense layer of the cell wall of the hypha. Later the interseptal spaces tend to become round and separate. In M --> Y only few interseptal spaces seem to transform. The yeast is produced by self-transformation of the hypha. In Y --> M a new structure is formed and the yeast dies. Intrahyphal hyphae are observed during the transformation from M --> Y, and intrayeast hyphae during the Y --> M. Due to the high mortality and breakage observed in both types of transformations, we believe that wound of the yeast or the mycelium could elicit this phenomenon.     

Fibroblast growth factor 3, a protein with a dual subcellular fate, is interacting with human ribosomal protein S2

The secreted isoform of fibroblast growth factor 3 (FGF3) induces a mitogenic cell response, while the nuclear form inhibits cell proliferation. Recently, we identified a nucleolar FGF3-binding protein which is implicated in processing of pre-rRNA as a possible target of nuclear FGF3 signalling. Here, we report a second candidate protein identified by a yeast two-hybrid screen for nuclear FGF3 action, ribosomal protein S2, rpS2. Recombinant rpS2 binds to in vitro translated FGF3 and to nuclear FGF3 extracted from transfected COS-1 cells. Characterization of the FGF3 binding domain of rpS2 showed that both the Arg-Gly-rich N-terminal region and a short carboxyl-terminal sequence of rpS2 are necessary for FGF3 binding. Mapping the S2 binding domains of FGF3 revealed that these domains are important for both NoBP and rpS2 interaction. Transient co-expression of rpS2 and nuclear FGF3 resulted in a reduced nucleolar localization of the FGF. These findings suggest that the nuclear form of FGF3 inhibits cell proliferation by interfering with ribosomal biogenesis.