Regulation of protein synthesis by hemin. Evidence that the hemin-controlled translational repressor inhibits the rate of formation of 40S.Met-tRNAf complexes directly

Differential effect of Mn2+ on the hemin-controlled translational repressor and the double-stranded RNA-activated inhibitor

The inhibition of protein synthesis that occurs when rabbit reticulocyte lysate is incubated in the absence of hemin is due to the activation of a protein kinase termed the hemin-controlled translational repressor, and that occurring when reticulocyte lysate is incubated with a low level of double-stranded RNA is mediated by the activation of a separate protein kinase termed the double-stranded RNA-activated inhibitor. Both the hemin-controlled translational repressor and the double-stranded RNA-activated inhibitor act by phosphorylating the Mr = 35,000 (alpha) subunit of eIF-2. MnCl2 (0.5 mM) partly reverses the inhibition of protein synthesis produced by hemin deficiency but not that induced by double-stranded RNA. In addition, Mn2+ reverses the inhibition of binding of [35S]Met-tRNAf to reticulocyte ribosomal components, isolated on Sepharose 6B, produced by the hemin-controlled translational repressor but not by the double-stranded RNA-activated inhibitor. The effect of Mn2+ is mediated at the level of activation and eIF-2 alpha kinase activity of these two regulatory protein kinases. Specifically, Mn2+ inhibits activation of the hemin-controlled translational repressor in the absence of hemin and the phosphorylation of eIF-2 alpha by pre-activated translational repressor. In contrast, the phosphorylation of eIF-2 alpha by the double-stranded RNA-activated inhibitor is not suppressed by Mn2+, and the activation and autophosphorylation of this inhibitor is enhanced by Mn2+. Finally, while the activation and inactivation of the hemin-controlled translational repressor does not appear to be mediated by autophosphorylation and dephosphorylation, the activation of the double-stranded RNA-activated inhibitor does appear to require autophosphorylation.

Translation in vivo and in vitro of mRNAs coding for vitellogenin, serum albumin and very-low-density lipoprotein II from chicken liver. A difference in translational efficiency

Characterisation of polysomes from estrogenized chicken liver revealed that very-low-density lipoprotein II (VLDLII), serum albumin and vitellogenin mRNAs are differently packed with ribosomes during translation in vivo. Tne ribosome density per number of nucleotides is high for VLDLII mRNA, intermediate for serum albumin mRNA and low for vitellogenin mRNA. This difference in ribosomal load is maintained throughout the period of hormone effect. The differential utilisation observed for vitellogenin and VLDLII mRNAs partly explains the large difference in molar production rate between these yolk protein precursors. Translation properties and efficiency of the three hepatic mRNAs were also compared in the mRNA-depleted reticulocyte lysate. Elongation of the nascent chains for vitellogenin and serum albumin proceeded in a discontinuous fashion. Initiation in vitro was studied at varying ionic strengths, in the presence of aurintricarboxylic acid, and at suboptimal hemin concentrations. VLDLII mRNA expression is by far the most resistant to 7-methylguanosine 5'-triphosphate (m7GTP) and high salt concentrations, vitellogenin mRNA the least. This behaviour resembles the differential utilisation of the mRNAs in vivo. The putative structural basis of these differences is discussed.

Effect of intravenous administration of d-lysergic acid diethylamide on subsequent protein synthesis in a cell-free system derived from brain

An initiating cell-free protein synthesis system derived from brain was utilized to demonstrate that the intravenous injection of d-lysergic acid diethylamide (LSD) to rabbits induced a transient inhibition of translation following a brief stimulatory period. Subfractionation of the brain cell-free system into postribosomal supernatant (PRS) and microsome fractions demonstrated that LSD in vivo induced alterations in both of these fractions. In addition to the overall inhibition of translation in the cell-free system, differential effects were noted, i.e., greater than average relative decreases in in vitro labeling of certain brain proteins and relative increases in others. The brain proteins of molecular weights 75K and 95K, which were increased in relative labeling under conditions of LSD-induced hyperthermia, are similar in molecular weight to two of the major "heat shock" proteins reported in tissue culture systems. Injection of LSD to rabbits at 4 degrees C prevented LSD-induced hyperthermia but behavioral effects of the drug were still apparent. The overall decrease in cell-free translation was still observed but the differential labeling effects were not. LSD appeared to influence cell-free translation in the brain at two dissociable levels: (a) an overall decrease in translation that was observed even in the absence of LSD-induced hyperthermia and (b) differential labeling effects on particular proteins that were dependent on LSD-induced hyperthermia.