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. 1988 Oct;170(10):4681–4692. doi: 10.1128/jb.170.10.4681-4692.1988

In vivo analysis of puf operon expression in Rhodobacter sphaeroides after deletion of a putative intercistronic transcription terminator.

B S DeHoff 1, J K Lee 1, T J Donohue 1, R I Gumport 1, S Kaplan 1
PMCID: PMC211508  PMID: 2459108

Abstract

The intercistronic region of the mRNA derived from the puf operon of Rhodobacter sphaeroides is capable of forming two stable stem-loop structures, the first of which resembles a factor-independent transcription terminator. A puf operon construction lacking the putative transcription terminator was made in vitro and crossed into the chromosome of R. sphaeroides PUFB1 to yield a single chromosomal copy in the terminator-deleted strain. The mutant strain, designated PUF delta 348-420 which was otherwise isogenic with the wild-type strain 2.4.1, showed a normal growth rate at high light intensity compared with the wild type, with the levels of the B875 and reaction center spectral complexes being approximately 7% and 25%, respectively, of those found in the wild type. The deletion mutation correlated with a reduction in the size of the fixed photosynthetic unit from 15:1 in the wild type to 4:1 in the mutant. The level of the B800-850 complex was increased approximately twofold in the mutant strain. However, substantial amounts of the B875 and reaction center polypeptides were not incorporated into spectrally active complexes, suggesting the importance of other factors in the assembly of these complexes. Removal of the intercistronic stem-loops resulted in increased readthrough of the puf operon terminator to regions downstream, as well as altering the stability of the resulting puf operon-specific transcripts. A model is proposed which links ribosome stalling within the open reading frame K leader region of the puf operon transcript with chain termination.

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Selected References

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