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Assembly analysis of ribosomes from a mutant lacking the assembly-initiator protein L24: lack of L24 induces temperature sensitivity

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Summary

Previously, we have shown that the ribosomal protein L24 is one of two assembly-initiator proteins. L24 is essential for early steps of the assembly of the 50S ribosomal subunit but it is not involved in both the late assembly and the ribosomal functions. Surprisingly, an E. coli mutant (TA109-130) exists which lacks L24. This apparent paradox is analyzed and resolved in this paper. The phenotypic features of the mutant lacking L24, are a temperature sensitivity (growth severely reduced beyond 34° C), a very low growth rate already at permissive temperatures (at least six-fold slower than wild type) and an underproduction of 50S subunits (molar ratio of 30S to 50S about 1:0.5). The S value of the mutant large subunits is 47S, and they are normally active in poly(Phe) synthesis. The total protein of the mutant large subunits show negligible activity in the total reconstitution assay using the standard two-step procedure. Number analysis of the assembly-initiator proteins revealed that only one initiator protein is effective, as expected. The activity is restored upon addition of wild-type L24. However, when the temperature of the first step is lowered from 44° to 36° C, reconstitution of active particles occurs with a 50% efficiency in the absence of L24. The recovery of activity is accompanied by the appearance of again two initiator proteins, when the mutant TP50 lacking L24 is used in the reconstitution assay at the ‘permissive’ temperature of 36° C during the first step. These findings indicate that at least another protein or, alternatively, two other proteins take over the function of the assembly initiation at the lower temperature. Although the extent of the formation of active particles becomes independent of L24 below 36° C, the rate of formation is still strongly affected even at “permissive” temperatures. The presence of L24 reduces the activation energy of the rate-limiting step of the early assembly, i.e., the activation energy of RI *50 (1) formation is 43±4 kcal/mol in the presence and 83±9 kcal in the absence of L24. The results presented provide an explanation of the phenotypic features of the mutant solely due to the assembly effects caused by the lack of L24.

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References

  • Ceri H, Maeba PY (1973) Association of ribonuclease with the 50S ribosomal subunit of Escherichia coli MRE600. Biochim Biophys Acta 312:337–348

    Google Scholar 

  • Dabbs ER (1982) A spontaneous mutant of Escherichia coli with protein L24 lacking from the ribosome. Mol Gen Genet 187:453–458

    Google Scholar 

  • Dabbs ER, Hasenbank R, Kastner B, Rak K-H, Wartusch B, Stöffler G (1983) Immunological studies of Escherichia coli mutants lacking one or two ribosomal proteins. Mol Gen Genet 192:301–308

    Google Scholar 

  • Gausing K (1980) Regulation of ribosome biosynthesis in Escherichia coli. In: Chambliss G, Craven GR, Davies J, Davis K, Kahan L, Nomura M (eds) Ribosomes. University Park Press, Baltimore, pp 693–718

    Google Scholar 

  • Geyl D, Böck A, Isono K (1981) An improved method for two-dimensional gel-electrophoresis: Analysis of mutationally altered ribosomal proteins of Escherichia coli. Mol Gen Genet 181:309–312

    Google Scholar 

  • Kaltschmidt E, Wittmann HG (1970) Ribosomal proteins: VII. Two-dimensional polyacrylamide gel electrophoresis for fingerprinting of ribosomal proteins. Anal Biochem 36:401–412

    Google Scholar 

  • Kühlbrandt W, Garrett RA (1978) A ribonucleoprotein core in the 50S ribosomal subunit of Escherichia coli. FEBS Lett 94:207–212

    Google Scholar 

  • McEwen CR (1967) Tables for estimating sedimentation through linear concentration gradients of sucrose solution. Anal Biochem 20:114–149

    Google Scholar 

  • Nierhaus KH, Dohme F (1979) Total reconstitution of 50S subunits from Escherichia coli ribosomes. Methods Enzymol 59:443–449

    Google Scholar 

  • Nishi K, Dabbs ER, Schnier J (1985) DNA sequence and complementation analysis of a mutation in the rplX gene from Escherichia coli leading to loss of ribosomal protein L24. J Bacteriol 163:890–894

    Google Scholar 

  • Nowotny V (1981) Rekonstitution der 50S Untereinheit von E. coli Ribosomen. Initiatorproteine des in vitro Aufbaus. Thesis at the Technische Universität Berlin

  • Nowotny V, Nierhaus KH (1982) Initiator proteins for the assembly of the 50S subunit from Escherichia coli ribosomes. Proc Natl Acad Sci USA 79:7238–7242

    Google Scholar 

  • Roth HE, Nierhaus KH (1975) Structural and functional studies of ribonucleoprotein fragments isolated from Escherichia coli 50S ribosomal subunits. J Mol Biol 94:111–121

    Google Scholar 

  • Schulze H, Nierhaus KH (1982) Minimal set of ribosomal components for reconstitution of the peptidyltransferase activity. EMBO J 5:609–613

    Google Scholar 

  • Sieber G, Nierhaus KH (1978) Kinetic and thermodynamic parameters of the assembly in vitro of the large subunit from Escherichia coli ribosomes. Biochemistry 17:3505–3511

    Google Scholar 

  • Spillmann S, Dohme F, Nierhaus KH (1977) Assembly in vitro of the 50S subunit from Escherichia coli ribosomes: Proteins essential for the first heat-dependent conformational change. J Mol Biol 115:513–523

    Google Scholar 

  • Spillmann S, Nierhaus KH (1978) The ribosomal protein L24 of Escherichia coli is an assembly protein. J Biol Chem 253:7047–7050

    Google Scholar 

  • Watson JD (1976) Molecular biology of the gene. 3rd edn, Benjamin WA, New York

    Google Scholar 

  • Wystup G, Nierhaus KH (1979) A method for the 14C-labeling of proteins from the large subunit, without loss of biological activity. Methods Enzymol 59:776–782

    Google Scholar 

  • Wystup G, Teraoka H, Schulze H, Hampl H, Nierhaus KH (1979) 50S subunit from Escherichia coli: Isolation of active ribosomal proteins and protein complexes. Eur J Biochem 100:101–113

    Google Scholar 

  • Zimmermann RA (1980) Interaction among protein and RNA components of the ribosome. In: Chambliss G, Craven GR, Davies J, Davis K, Kahan L, Nomura M (eds) Ribosomes. University Park Press, Baltimore, pp 135–169

    Google Scholar 

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Authors and Affiliations

  1. Max-Planck-Institut für Molekulare Genetik, Innestraße 73, D-1000, Berlin 33

    Marzell Herold, Volker Nowotny, Eric R. Dabbs & Knud H. Nierhaus

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  1. Marzell Herold
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  2. Volker Nowotny
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  3. Eric R. Dabbs
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  4. Knud H. Nierhaus
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Communicated by A. Böck

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Herold, M., Nowotny, V., Dabbs, E.R. et al. Assembly analysis of ribosomes from a mutant lacking the assembly-initiator protein L24: lack of L24 induces temperature sensitivity. Molec Gen Genet 203, 281–287 (1986). https://doi.org/10.1007/BF00333967

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  • DOI: https://doi.org/10.1007/BF00333967

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