Effects of ethyl and benzyl analogues of spermine on Escherichia coli peptidyltransferase activity, polyamine transport, and cellular growth.

Various ethyl and benzyl spermine analogues, including the anticancer agent N1,N12-bis(ethyl)spermine, were studied for their ability to affect the growth of cultured Escherichia coli cells, to inhibit [3H]putrescine and [3H]spermine uptake into cells, and to modulate the peptidyltransferase activity (EC 2. 3. 2. 12). Relative to other cell lines, growth of E. coli was uniquely insensitive to these analogues. Nevertheless, these analogues conferred similar modulation of in vitro protein synthesis and inhibition of [3H]putrescine and [3H]spermine uptake, as is seen in other cell types. Thus, both ethyl and benzyl analogues of spermine not only promote the formation and stabilization of the initiator ribosomal ternary complex, but they also have a sparing effect on the Mg2+ requirements. Also, in a complete cell-free protein-synthesizing system, these analogues at low concentrations stimulated peptide bond formation, whereas at higher concentrations, they inhibited the reaction. The ranking order for stimulation of peptide-bond formation by the analogues was N4,N9-dibenzylspermine > N4, N9-bis(ethyl)spermine congruent with N1-ethylspermine > N1, N12-bis(ethyl)spermine, whereas the order of analogue potency regarding the inhibitory effect was inverted, with inhibition constant values of 10, 3.1, 1.5, and 0.98 microM, respectively. Although the above analogues failed to interact with the putrescine-specific uptake system, they exhibited high affinity for the polyamine uptake system encoded by the potABCD operon. Despite this fact, none of the analogues could be internalized by the polyamine transport system, and therefore they could not influence the intracellular polyamine pools and growth of E. coli cells.

The effect of acylated polyamine derivatives on polyamine uptake mechanism, cell growth, and polyamine pools in Escherichia coli, and the pursuit of structure/activity relationships.

Two acetyl analogues of spermidine and five analogues of spermine were used to determine the structural specificity of the polyamine transport system in Escherichia coli by measuring their ability to compete with [14C]putrescine or [14C]spermine for uptake, as well as to inhibit cell growth, and, finally, to affect the intracellular polyamine pools. Spermine uptake follows simple Michaelis-Menten kinetics (Kt = 24.58 +/- 2.24 microM). In contrast, the putrescine uptake system involves two saturable Michaelis-Menten carriers exhibiting different affinity towards putrescine (Kt = 3.63 +/- 0.43 microM, Kt' = 0.61 +/- 0.10 microM). From the Ki values, it is inferred that N1-5-amino-2-nitrobenzoylspermine is the most effective competitive inhibitor followed by N1-acetylspermine, and then N1,N12-diacetylspermine. N1-acetylspermidine and N8-acetylspermidine also inhibit competitively the uptake of spermine, the latter being the most effective inhibitor. In addition, the above-mentioned analogues inhibit identically one of the carriers of putrescine uptake, suggesting the existence of a common transporter for both putrescine and spermine. The order of analogue potency, regarding the other carrier of putrescine is as follows: N1,N12-diacetylspermine approximately N1-5-amino-2-nitro-benzoylspermine > N1-acetylspermine. Both N1-acetylspermidine (Ki = 753 +/- 25 microM, Ki' = 128 +/- 5 microM) and N8-acetylspermidine (Ki = 22.4 +/- 0.4 microM, Ki' = 279 +/- 3 microM) also cause competitive inhibition of putrescine uptake, however with inverse affinity towards the putrescine carriers. Neither N4,N9-diacetylspermine, nor N1,N4-bis(beta-alanyl)diaminobutane affect the uptake of any polyamine. Interestingly, none of the acetyl analogues of spermine has a measurable effect on cell growth and cellular polyamine pools, although some of them are accumulated in cells. Based on these findings, the relative significance of the primary and secondary amines and of the chain flexibility as determinants of cellular uptake are discussed.

Structure/function correlation of spermine-analogue-induced modulation of peptidyltransferase activity.

In a cell-free system derived from Escherichia coli, various analogues of spermine were used to study their effect on the binding of AcPhe-tRNA to poly (U)-programmed ribosomes and on the puromycin reaction carried out at 6 mM Mg2+ (Ac, acetyl). In the absence of factors washable from ribosomes (FWR fraction), mono-acylated or di-acylated analogues of spermine stimulate the binding of AcPhe-tRNA to a lesser degree than spermine, in the order: N1-acetylspermine > N1,N12-diacetylspermine approximately = N1,N12-dipivaloylspermine. Also, the above analogues do not show any sparing effect on Mg2+ requirements for AcPhe-tRNA binding to ribosomes, in contrast to spermine. The presence of FWR fraction during the binding or acetylation of the secondary amines of spermine moderates or abolishes the stimulatory effect. In addition, all analogues tested enhance the stability of the ternary complex AcPhe-tRNA-poly(U)-ribosome and the extent of AcPhe-puromycin synthesis, particularly in the absence of the FWR fraction. At the kinetic phase of AcPhe-puromycin synthesis, the analogues display both stimulatory and inhibitory effects, depending on the absence (partial noncompetitive inhibition) or the presence of the FWR fraction (nonessential activation in concert with partial noncompetitive inhibition). Detailed kinetic analysis shows that the analogues tested can mimic the behaviour of spermine, however, the potency to affect the peptidyltransferase activity depends on their degree of acylation, acyl-substituent size, charge distribution and on their chain flexibility.

Aminoacyl and peptidyl analogs of chloramphenicol as slow-binding inhibitors of ribosomal peptidyltransferase: a new approach for evaluating their potency.

In a model system derived from Escherichia coli, acetylphenylalanyl-puromycin is produced in a pseudo-first-order reaction between the preformed acetylphenylalanyl/tRNA/poly(U)/ribosome complex (complex C) and excess puromycin. Two aminoacyl analogs [3, Gly-chloramphenicol (CAM): 4, L-Phe-CAM] and two peptidyl analogs (2, L-Phe-Gly-CAM: 5, Gly-Phe-CAM) of CAM (1) were tested as inhibitors in this reaction. Detailed kinetic analysis suggests that these analogs (I) react competitively with complex C and form the complex C*l, which is inactive toward puromycin. C*l is formed via a two-step mechanism in which C*l is the product of a slow conformational change of the initial encounter complex Cl according to the equation C + l reversible Cl reversible C*l. Furthermore, we provide evidence that analog 5 may react further with C*l forming the species C*l2. The values of the apparent association rate constant (K(assoc)) are 1.42 x microM-1 min-1 for 2, 0.55 x microM-1 min-1 for 3, and 0.18 x microM-1 min-1 for 4 and 0.038 x microM-1 min-1 for 5 [corrected]. In the case of analog 5, K(assoc) is a linear function of the inhibitor concentration; when [I] approaches zero, the K(assoc) value is equal to 3.8 x 10(2) M-1 sec-1. Such values allow the classification of CAM analogs as slow-binding inhibitors. According to K(assoc) values, we could surmise that analog 2 is 2.5-fold more potent than 3 and 8-fold more potent than 4. The relative potency of analog 5 is the lowest among the analogs and is dependent on its concentration. The results are compared with previous data and discussed on the basis of a possible retro-inverso relationship between CAM analogs and puromycin.

Preparation of the very acid-sensitive Fmoc-Lys(Mtt)-OH. Application in the synthesis of side-chain to side-chain cyclic peptides and oligolysine cores suitable for the solid-phase assembly of MAPs and TASPs.

N alpha-9-Fluorenylmethoxycarbonyl-N epsilon-4=methyltrityl-lysine, [Fmoc-Lys(Mtt)-OH], was prepared in two steps from lysine, in 42% overall yield. The N epsilon-Mtt function can be quantitatively removed upon treatment with 1% TFA in dichloromethane or with a 1:2:7 mixture of acetic acid/trifluoroethanol/dichloromethane for 30 min and 1 h at room temperature, respectively. Under these conditions, groups of the tert-butyl type and peptide ester bonds to TFA-labile resins, such as the 2-chlorodiphenylmethyl- and the Wang-resin, remained intact. The utility of the new derivative in peptide synthesis has been exemplified with the synthesis of a cyclic cholecystokinin analog. As an example of further application, five types of lysine cores suitable for the solid-phase synthesis of one, two or three epitopes containing antigenic peptides or template-assembled synthetic proteins have been synthesized on Merrifield, Wang and 2-chlorodiphenylmethyl resin.

Aminoacyl analogs of chloramphenicol: examination of the kinetics of inhibition of peptide bond formation.

Two aminoacyl analogs and one peptidyl analog of chloramphenicol (1, Cl2CHCO-CA) were prepared. These are 2 (L-Phe-CA), 3 (Gly-CA), and 4 (L-Phe-Gly-CA). The kinetics of inhibition of peptide bond formation by these analogs were examined in a cell-free system which was derived from E. coli and used previously for the study of 1 (Drainas; et al. Eur. J. Biochem. 1987, 164, 53-58). In the absence of inhibitor, the reaction follows first-order kinetics for the entire course of the reaction. In the presence of the analog the reaction gives biphasic log-time plots. The kinetic information pertaining to the initial slope of the plot is analyzed (initial-slope analysis). This information differentiates the analogs from the parent compound 1. The parent compound 1 gives complex inhibition kinetics; increasing the concentration of 1 changes the inhibition from competitive to mixed noncompetitive (Drainas; et al. Eur. J. Biochem. 1987, 164, 53-58). In contrast, the analogs give competitive kinetics even at high concentrations of the inhibitor. The following Ki values have been determined: 18.0 microM for 2, 5.5 microM for 3, 1.5 microM for 4. If we were to assume that compounds 2, 3 and 4 behave as classical competitive inhibitors, we could say that 4 is 12 times more potent than 3 and 4 times more potent than 2. On this assumption we could also compare 1 with 4 and see that 4 is 2 times weaker than 1. It is suggested that as compared with 1, the two aminoacyl analogs and the dipeptidyl analog have increased structural similarity to the 3'-terminus of aminoacyl-tRNA or of peptidyl-tRNA and that this similarity results in a more pronounced competitive inhibition.

Antiviral activity of C-alkylated purine nucleosides obtained by cross-coupling with tetraalkyltin reagents.

2-, 6-, And 8-alkylated (methyl, ethyl, and vinyl) adenosine analogues were synthesized by a palladium-catalyzed cross-coupling of a tetraalkyltin with the halogenated purine nucleosides. The synthesis of the 8-substituted analogues was accomplished using a transient protection procedure. The 6-alkylated-9-beta-D-ribofuranosylpurines as well as 2-ethyladenosine were cytotoxic at relatively low concentrations (0.8-10 micrograms/mL). 8-Methyladenosine was a potent and selective inhibitor of vaccinia virus, whereas 8-ethyl- and 8-vinyladenosine were specifically inhibitory to respiratory syncytial virus. 8-Vinyladenosine displayed particular activity against herpes simplex virus (type 1).