Specificity of the amino acid transfer reaction inE. coli strains carrying different alleles of the RNA control (RC) gene

Summary The idea has been tested here that the aberration in amino acid controlled regulation of RNA synthesis in a mutant strain ofE. coli might reflect a major breakdown in the specificity of transfer of amino acids to S-RNA. For this purpose, S-RNA and amino acid activating enzymes were extracted from bacteria carrying either the normalRC ^st or the aberrantRC ^rel allele of the RNA control gene. The purified S-RNA preparations were first charged enzymatically with one or more of the 20 standard amino acids, then oxidized with periodate, and finally reisolated and retested for their residual capacity to accept an amino acid that was absent from the preliminary charging mixture. If preliminary charging transferred an amino acid to a non-cognate S-RNA species belonging to an absent amino acid, then the acceptor capacity for the missing amino acid would survive periodate oxidation and reveal its presence on recharging with that amino acid after post-periodate reisolation of the S-RNA. The results presented here show that there does not appear to exist any such major breakdown of transfer specificity in eitherRC ^st orRC ^rel bacteria: preliminary charging of the S-RNA fromRC ^rel bacteria with 19 of the 20 standard amino acids by use of the homologous amino acid activating enzymes does not afford protection against periodate oxidation for any appreciable fraction of the acceptor capacity for the absent 20th amino acid (when that amino acid is either methionine or arginine). It is unlikely, therefore, that thecatholic inducer, postulated to explain the continued RNA synthesis ofRC ^rel amino acid auxotrophs in the absence of their growth requirement, is one of the 20 standard amino acids.This investigation was supported by Public Health Service Research Grant CA 02129, from the National Cancer Institute.     

Biogenesis of Tim23 and Tim17, integral components of the TIM machinery for matrix-targeted preproteins.

We analysed the import pathway of Tim23 and of Tim17, components of the mitochondrial import machinery for matrix-targeted preproteins. Tim23 contains two independent import signals. One is located within the first 62 amino acid residues of the hydrophilic domain that, in the assembled protein, is exposed to the intermembrane space. This signal mediates translocation of Tim23 across the outer membrane independently of the membrane potential, DeltaPsi. A second import signal is located in the C-terminal membrane-integrated portion of Tim23. It mediates translocation across the outer membrane and insertion into the inner membrane in a strictly DeltaPsi-dependent fashion. Structurally, Tim17 is related to Tim23 but lacks a hydrophilic domain. It contains an import signal in the C-terminal half and its import requires DeltaPsi. The DeltaPsi-dependent import signals of Tim23 and Tim17 are located at corresponding sites in these two homologous proteins. They exhibit features reminiscent of the positively charged N-terminal presequences of matrix-targeted precursors. Import of Tim23 and its insertion into the inner membrane requires Tim22 but not functional Tim23. Thus, biogenesis of the Tim23.17 complex depends on the Tim22 complex, which is the translocase identified as mediating the import of carrier proteins.     

Characterization of an electrogenic ATP and chloride-dependent proton translocating pump from rat renal medulla

To study acidification mechanisms in the distal nephron, microsomes were prepared from rat renal medulla by differential centrifugation. Microsomes were enriched in the enzyme marker gamma-glutamyl transferase and contained an ATP-dependent proton pump, as evidenced by ATP-dependent, 3,3',4',5-tetrachlorosalicylanilide-reversible quenching of acridine orange fluorescence. Acidification was vanadate-insensitive, but was completely inhibited by micromolar N-ethylmaleimide. Maximal acidification was achieved in the presence of halide (Cl-, Br-) only and was not attainable with potassium-valinomycin diffusion potentials without halide ion. Microsomal ATPase activity was neither chloride- nor N-ethylmaleimide-sensitive. A chloride conductance was observed only with vesicles which had undergone ATP-dependent acidification. An ATP-dependent, N-ethylmaleimide-inhibitable, 3,3',4',5-tetrachlorosalicylanilide-reversible, and chloride-attenuated quench of bis(1,3-dibutylbarbituric acid-(5] pentamethinoxonol fluorescence was seen, consistent with net transfer of positive charge into the vesicles. Nonetheless, positive intravesicular potentials increased the ATP-dependent initial acidification rate, perhaps by increasing availability of chloride ion to the transport site. Our results are consistent with an electrogenic, ATP-dependent proton pump regulated by a voltage-sensitive chloride site.     

Antifolding activity of hsp60 couples protein import into the mitochondrial matrix with export to the intermembrane space.

Cytochrome b2 reaches the intermembrane space of mitochondria by transport into the matrix followed by export across the inner membrane. While in the matrix, the protein interacts with hsp60, which arrests its folding prior to export. The bacterial-type export sequence in pre-cytochrome b2 functions by inhibiting the ATP-dependent release of the protein from hsp60. Release for export apparently requires, in addition to ATP, the interaction of the signal sequence with a component of the export machinery in the inner membrane. Export can occur before import is complete provided that a critical length of the polypeptide chain has been translocated into the matrix. Thus, hsp60 combines two activities: catalysis of folding of proteins destined for the matrix, and maintaining proteins in an unfolded state to facilitate their channeling between the machineries for import and export across the inner membrane. Anti-folding signals such as the hydrophobic export sequence in cytochrome b2 may act as switches between these two activities.     

The Only Known Jawed Vertebrate with Four Eyes and the Bauplan of the Pineal Complex

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