Synthesis of ribosomes in Saccharomyces cerevisiae.

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Microbiol Mol Biol Rev. 1989 June; 53(2): 256-271

Synthesis of ribosomes in Saccharomyces cerevisiae.

J R Warner

SUMMARY

The assembly of a eucaryotic ribosome requires the synthesisof four ribosomal ribonucleic acid (RNA) molecules and morethan 75 ribosomal proteins. It utilizes all three RNA polymerases;it requires the cooperation of the nucleus and the cytoplasm,the processing of RNA, and the specific interaction of RNA andprotein molecules. It is carried out efficiently and is exquisitelysensitive to the needs of the cell. Our current understandingof this process in the genetically tractable yeast Saccharomycescerevisiae is reviewed. The ribosomal RNA genes are arrangedin a tandem array of 100 to 200 copies. This tandem array hasled to unique ways of carrying out a number of functions. Replicationis asymmetric and does not initiate from every autonomouslyreplicating sequence. Recombination is suppressed. Transcriptionof the major ribosomal RNA appears to involve coupling betweenadjacent transcription units, which are separated by the 5SRNA transcription unit. Genes for many ribosomal proteins havebeen cloned and sequenced. Few are linked; most are duplicated;most have an intron. There is extensive homology between yeastribosomal proteins and those of other species. Most, but notall, of the ribosomal protein genes have one or two sites thatare essential for their transcription and that bind a commontranscription factor. This factor binds also to many other placesin the genome, including the telomeres. There is coordinatedtranscription of the ribosomal protein genes under a varietyof conditions. However, the cell seems to possess no mechanismfor regulating the transcription of individual ribosomal proteingenes in response either to a deficiency or an excess of a particularribosomal protein. A deficiency causes slow growth. Any excessribosomal protein is degraded very rapidly, with a half-lifeof 1 to 5 min. Unlike most types of cells, yeast cells appearnot to regulate the translation of ribosomal proteins. However,in the case of ribosomal protein L32, the protein itself causesa feedback inhibition of the splicing of the transcript of itsown gene. The synthesis of ribosomes involves a massive transferof material across the nuclear envelope in both directions.Nuclear localization signals have been identified for at leastthree ribosomal proteins; they are similar but not identicalto those identified for the simian virus 40 T antigen. Thereis no information about how ribosomal subunits are transportedfrom the nucleus to the cytoplasm.(ABSTRACT TRUNCATED AT 400WORDS)

Microbiol Mol Biol Rev. 1989 June; 53(2): 256-271

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