MECHANISM OF POST-SEGREGATIONAL KILLING BY HOK-HOMOLOG PND OF PLASMID R483 - 2 TRANSLATIONAL CONTROL ELEMENTS IN THE PND MESSENGER-RNA

AK NIELSEN; Kenn Gerdes

doi:10.1006/jmbi.1995.0296

MECHANISM OF POST-SEGREGATIONAL KILLING BY HOK-HOMOLOG PND OF PLASMID R483 - 2 TRANSLATIONAL CONTROL ELEMENTS IN THE PND MESSENGER-RNA

13 Citations (Scopus)

Abstract

The pnd system of plasmid R483 mediates plasmid stabilization by killing of plasmid-free cells. The pnd mRNA is very stable and can be translated into PndA protein, a cell toxin which kills the cells from within by damaging the cell membrane. Translation of the pnd mRNA is inhibited by the PndB antisense, a small labile RNA of 63 nt. The rapid decay of the PndB antidote leads to onset of PndA synthesis in plasmid-free segregants or after addition of rifampicin. Surprisingly however, the full-length pnd mRNA was found to be translationally inactive whereas a 3'-end truncated version of it was found to be active. We have therefore suggested previously, that the 3'-end of the full-length pnd mRNA encodes a fold-back inhibitory sequence (fbi), which prevents its translation. Here we present an analysis of the metabolism of the pnd mRNAs. A mutational analysis shows that single point mutations in the fbi motif results in more rapid truncation. The fbi mutations could not be complemented by second-site mutations in either of the pndA or pndC Shine-Dalgarno (SD) elements. Surprisingly, mutations in the pndC SD element also lead to a more rapid truncation. The effect of these latter mutations was, however, complemented by mutations in a proposed anti-SD element upstream of the pndC SD. Mutations in the anti-SD element were lethal. These results show, that the pnd mRNA contains two negative control elements, one located in its very 3'-end (fbi), and one located just upstream of the pndC SD region (the anti-SD element). These observations add to the complexity of the induction scheme previously proposed to explain activation of pndA expression in plasmid-free cells: In addition to its negative effect of translation, the fbi structure also maintains a reduced processing rate in the S'-end of the mRNA. This permits the accumulation of a reservoir of pnd mRNA, which can be activated by 3'-end processing in plasmid-free cells. The anti-SD may prevent translation of the pnd mRNA during transcription, thus preventing detrimental synthesis of toxin.

Original language	English
Journal	Journal of Molecular Biology
Volume	249
Issue number	2
Pages (from-to)	270-282
Number of pages	13
ISSN	0022-2836
DOIs	https://doi.org/10.1006/jmbi.1995.0296
Publication status	Published - 1995
Externally published	Yes

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10.1006/jmbi.1995.0296

Cite this

@article{26a5dd53d165479e955ad7f9ada1c810,

title = "MECHANISM OF POST-SEGREGATIONAL KILLING BY HOK-HOMOLOG PND OF PLASMID R483 - 2 TRANSLATIONAL CONTROL ELEMENTS IN THE PND MESSENGER-RNA",

abstract = "The pnd system of plasmid R483 mediates plasmid stabilization by killing of plasmid-free cells. The pnd mRNA is very stable and can be translated into PndA protein, a cell toxin which kills the cells from within by damaging the cell membrane. Translation of the pnd mRNA is inhibited by the PndB antisense, a small labile RNA of 63 nt. The rapid decay of the PndB antidote leads to onset of PndA synthesis in plasmid-free segregants or after addition of rifampicin. Surprisingly however, the full-length pnd mRNA was found to be translationally inactive whereas a 3'-end truncated version of it was found to be active. We have therefore suggested previously, that the 3'-end of the full-length pnd mRNA encodes a fold-back inhibitory sequence (fbi), which prevents its translation. Here we present an analysis of the metabolism of the pnd mRNAs. A mutational analysis shows that single point mutations in the fbi motif results in more rapid truncation. The fbi mutations could not be complemented by second-site mutations in either of the pndA or pndC Shine-Dalgarno (SD) elements. Surprisingly, mutations in the pndC SD element also lead to a more rapid truncation. The effect of these latter mutations was, however, complemented by mutations in a proposed anti-SD element upstream of the pndC SD. Mutations in the anti-SD element were lethal. These results show, that the pnd mRNA contains two negative control elements, one located in its very 3'-end (fbi), and one located just upstream of the pndC SD region (the anti-SD element). These observations add to the complexity of the induction scheme previously proposed to explain activation of pndA expression in plasmid-free cells: In addition to its negative effect of translation, the fbi structure also maintains a reduced processing rate in the S'-end of the mRNA. This permits the accumulation of a reservoir of pnd mRNA, which can be activated by 3'-end processing in plasmid-free cells. The anti-SD may prevent translation of the pnd mRNA during transcription, thus preventing detrimental synthesis of toxin.",

author = "AK NIELSEN and Kenn Gerdes",

year = "1995",

doi = "10.1006/jmbi.1995.0296",

language = "English",

volume = "249",

pages = "270--282",

journal = "Journal of Molecular Biology",

issn = "0022-2836",

publisher = "Academic Press",

number = "2",

}

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T1 - MECHANISM OF POST-SEGREGATIONAL KILLING BY HOK-HOMOLOG PND OF PLASMID R483 - 2 TRANSLATIONAL CONTROL ELEMENTS IN THE PND MESSENGER-RNA

AU - NIELSEN, AK

AU - Gerdes, Kenn

PY - 1995

Y1 - 1995

N2 - The pnd system of plasmid R483 mediates plasmid stabilization by killing of plasmid-free cells. The pnd mRNA is very stable and can be translated into PndA protein, a cell toxin which kills the cells from within by damaging the cell membrane. Translation of the pnd mRNA is inhibited by the PndB antisense, a small labile RNA of 63 nt. The rapid decay of the PndB antidote leads to onset of PndA synthesis in plasmid-free segregants or after addition of rifampicin. Surprisingly however, the full-length pnd mRNA was found to be translationally inactive whereas a 3'-end truncated version of it was found to be active. We have therefore suggested previously, that the 3'-end of the full-length pnd mRNA encodes a fold-back inhibitory sequence (fbi), which prevents its translation. Here we present an analysis of the metabolism of the pnd mRNAs. A mutational analysis shows that single point mutations in the fbi motif results in more rapid truncation. The fbi mutations could not be complemented by second-site mutations in either of the pndA or pndC Shine-Dalgarno (SD) elements. Surprisingly, mutations in the pndC SD element also lead to a more rapid truncation. The effect of these latter mutations was, however, complemented by mutations in a proposed anti-SD element upstream of the pndC SD. Mutations in the anti-SD element were lethal. These results show, that the pnd mRNA contains two negative control elements, one located in its very 3'-end (fbi), and one located just upstream of the pndC SD region (the anti-SD element). These observations add to the complexity of the induction scheme previously proposed to explain activation of pndA expression in plasmid-free cells: In addition to its negative effect of translation, the fbi structure also maintains a reduced processing rate in the S'-end of the mRNA. This permits the accumulation of a reservoir of pnd mRNA, which can be activated by 3'-end processing in plasmid-free cells. The anti-SD may prevent translation of the pnd mRNA during transcription, thus preventing detrimental synthesis of toxin.

AB - The pnd system of plasmid R483 mediates plasmid stabilization by killing of plasmid-free cells. The pnd mRNA is very stable and can be translated into PndA protein, a cell toxin which kills the cells from within by damaging the cell membrane. Translation of the pnd mRNA is inhibited by the PndB antisense, a small labile RNA of 63 nt. The rapid decay of the PndB antidote leads to onset of PndA synthesis in plasmid-free segregants or after addition of rifampicin. Surprisingly however, the full-length pnd mRNA was found to be translationally inactive whereas a 3'-end truncated version of it was found to be active. We have therefore suggested previously, that the 3'-end of the full-length pnd mRNA encodes a fold-back inhibitory sequence (fbi), which prevents its translation. Here we present an analysis of the metabolism of the pnd mRNAs. A mutational analysis shows that single point mutations in the fbi motif results in more rapid truncation. The fbi mutations could not be complemented by second-site mutations in either of the pndA or pndC Shine-Dalgarno (SD) elements. Surprisingly, mutations in the pndC SD element also lead to a more rapid truncation. The effect of these latter mutations was, however, complemented by mutations in a proposed anti-SD element upstream of the pndC SD. Mutations in the anti-SD element were lethal. These results show, that the pnd mRNA contains two negative control elements, one located in its very 3'-end (fbi), and one located just upstream of the pndC SD region (the anti-SD element). These observations add to the complexity of the induction scheme previously proposed to explain activation of pndA expression in plasmid-free cells: In addition to its negative effect of translation, the fbi structure also maintains a reduced processing rate in the S'-end of the mRNA. This permits the accumulation of a reservoir of pnd mRNA, which can be activated by 3'-end processing in plasmid-free cells. The anti-SD may prevent translation of the pnd mRNA during transcription, thus preventing detrimental synthesis of toxin.

U2 - 10.1006/jmbi.1995.0296

DO - 10.1006/jmbi.1995.0296

M3 - Journal article

SN - 0022-2836

VL - 249

SP - 270

EP - 282

JO - Journal of Molecular Biology

JF - Journal of Molecular Biology

IS - 2

ER -