Inhibition of peptide chain initiation by a nonhemin-regulated translational repressor from Friend leukemia cells.

A nonhemin-regulated translational repressor protein has been purified partially from the postribosomal supernatant fraction of Friend leukemia cells grown in the absence of dimethylsulfoxide. This repressor inhibits protein synthesis in lysates from rabbit reticulocytes or Friend leukemia cells and in a fractionated system using Artemia salina ribosomes, reticulocyte mRNA, and soluble components from reticulocytes. In contrast, the hemin-controlled repressor from reticulocytes does not inhibit protein synthesis in lysates from Friend leukemia cells. The repressor from Friend leukemia cells has no effect on poly(U)-directed synthesis of polyphenylalanine using reticulocyte ribosomes nor on the extension and release of nascent globin chains that were initiated in intact reticulocytes. It does not block completion of peptides on ribosomes isolated from reticulocytes incubated with NaF nor does it inhibit initiation factor-dependent formation of methionylpuromycin, but it inhibits globin mRNA-dependent methionylvaline synthesis. The Friend leukemia cell repressor promotes peptide synthesis-dependent breakdown of polysomes in reticulocyte lysates that appears to involve inhibition of ribosome reattachment to mRNA during peptide chain initiation. It is concluded that the Friend leukemia cell repressor blocks peptide initiation at a point between the addition of methionyl-tRNA^fMet to the ribosomal initiation complex and the NaF-sensitive reaction.     

Inhibition by cyanide of the respiratory chain oxidases of Escherichia coli

The kinetics of inhibition by KCN of NADH oxidation in respiratory particles from Escherichia coli could be related to the relative amounts of cytochromes d and o which were present. Particles which contained higher levels of cytochrome d relative to cytochrome o were less sensitive to inhibition by cyanide. When cyanide reacted with the respiratory particles, the absorption bands of reduced cytochrome d at 442 and 628 nm in the reduced plus cyanide minus reduced difference spectrum were eliminated, as also were the bands at 423, 428, and 555 nm of b- and/or c-type cytochromes.Cyanide appeared to react with the oxidized form of cytochrome d to eliminate its α-band absorption with a second-order rate constant of 0.011 m^?1 sec^?1 for the rate of formation of cyanocytochrome d in the absence of added substrate. Under turnover conditions using NADH as substrate, the rate constant was 0.58 m^?1 sec^?1. This value is close to that determined from cyanide inhibition of NADH oxidase activity. The magnitude of the second-order rate constant for the formation of cyanocytochrome d was directly related to the rate of electron flux through cytochrome d. It is suggested that an intermediate species formed during the normal oxidation-reduction cycle of cytochrome d reacts with cyanide.     

Inhibition of RNA chain initiation in E. coli core RNA polymerase with 2-hydroxy-5-nitrobenzyl bromide

The modification of $\text{E. coli}$ core RNA polymerase with 2-hydroxy-5-nitrobenzyl bromide (Koshland's Reagent) resulted in the benzylation of 6 out of 13 cysteines, and 10 out of 20 tryptophans in the polymerase, and occurred with an 8% decrease in its [θ]₂₂₀. The modification resulted in a maximal inhibition of 60% of the RNA chains on both calf thymus and micrococcal DNA templates. γ-³²P-ATP studies showed the inhibition occurred at RNA chain initiation. This study raises the possibility that the modified core polymerase may synthesize specific RNA(s).     

Inhibition of canavanyl-protein proteolysis in Escherichia coli by rifampin.

Rifampin inhibited the intracellular proteolysis of canavanine-induced, rapidly sedimenting protein complexes in Escherichia coli.     

Inhibition of initiation of bacteriophage T4 DNA replication by perturbation of Escherichia coli host membrane composition.

3-Decynoyl-N-acetylcysteamine (3-decynoyl-NAC) is an analog which specifically causes the immediate cessation of the biosynthesis of unsaturated fatty acids in Escherichia coli, whereas the synthesis of saturated fatty acids is actually stimulated. As a result, the cell membrane accumulates saturated fatty acids in its phospholipid. Addition of the inhibitor at the time of infection of E. coli by T4 phage had no effect on normal phage replication and development, implying that the synthesis of unsaturated fatty acids per se has little effect on T4 DNA replication. However, if the integrity and composition of the bacterial membrane was grossly perturbed by first treating the cells with the inhibitor for 60 min before infection, the proper initiation and the attainment of a rapid rate of T4 DNA synthesis were not observed. Under these conditions, a full complement of T4 early proteins was synthesized. The membrane associability of the known DNA delay proteins induced by wild-type T4 phage in the treated cells resembled that expected of a culture of untreated cells infected with a DNA delay mutant. When any one of three DNA delay mutants was used to infect 3-decynoyl-NAC-treated cells, T4 DNA replication was aborted. These findings suggest that some kind of specific interactions among the initiation proteins defined by the DNA delay mutants and the bacterial membrane may be necessary to facilitate the normal initiation and rapid rate of T4 DNA replication. A model for the involvement of the three different initiation proteins and the subsequent attainment of rapid DNA synthesis is discussed.     

Requirement for the Escherichia coli ribosomal protein L11 in peptide chain termination.

Subparticles of the Escherichia coli 50 S ribosome subunit containing varying amounts of the protein L11 have been prepared. These core particles have been used to form 70 S couples containing f[³H]Met-tRNA as a substrate for the peptidyl hydrolysis reaction of in vitro termination. Studies with antibodies against L11 suggested previously that the protein was involved in this event. The peptidyl transferase of the 50 S subunit core particles containing no more than 6% of the normal complement of L11 was fully active. The 70 S couples formed from 50 S cores lacking L11 showed some decrease in their ability to bind fMet-tRNA. Ribosomes lacking the proteins $\text{L}\text{7}\text{L}\text{12}$ retained about 50% of their activity for the peptidyl-tRNA hydrolysis event of in vitro termination. Cores lacking both $\text{L}\text{7}\text{L}\text{12}$ and L11 were almost as active as those lacking only $\text{L}\text{7}\text{L}\text{12}$. L11 is, therefore, not absolutely required for peptidyl-tRNA hydrolysis at termination in vitro. The ribosome subparticles lacking L11 have been reconstituted with $\text{L}\text{7}\text{L}\text{12}$. Despite the absence of L11, they regained significant activity for the codon-directed in vitro termination reaction.     

Recognition of tRNA Trp by initiation factors from Escherichia coli.

Binding of acetyl or formyltryptophanyl-tRNA Trp from Escherichia coli or beef liver to E. coli ribosomes is strongly stimulated by E. coli initiation factors and requires GTP. The N-acylated tryptophan is puromycin reactive. Polypeptide chain initiation with acetyltryptophan dependent on poly(U,G) has been demonstrated and is highly dependent on added initiation factors. tRNA Trp appears, therefore, to share some structural features with tRNAfMet of significance to the process of polypeptide chain initiation.