Chromosoma

, Volume 102, Issue 4, pp 233–248 | Cite as

Transcriptional regulation in Drosophila during heat shock: A nuclear run-on analysis

  • Julio Vazquez
  • Daniel Pauli
  • Alfred Tissières
Article
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Revised:
Accepted:

Abstract

We used a nuclear run-on assay as a novel approach to study the changes in transcriptional activity that take place in Drosophila melanogaster during heat shock. In response to a rapid temperature upshift, total transcriptional activity in cultured K C161 cells decreased proportionally to the severity of the shock. After extended stress at 37° C (15 min or more), transcription was severely reduced, and at 39° C most transcription was instantaneously arrested. However, strikingly different responses were observed for individual genes. Transcription of histone H1 genes was severely inhibited even under mild heat shock conditions. Transcription of the actin 5C gene decreased progressively with increasing temperature, while transcription of the core histone genes or of the heat shock cognate genes was repressed only under severe heat shock conditions. Transcriptional activation of the D. melanogaster heat shock genes was also investigated. In unshocked cells, hsp84 was moderately transcribed, while transcriptional activity at the other protein-coding heat shock genes was undetectable (less than 0.2 polymerases per gene). Engaged but paused RNA polymerase molecules were found at the hsp70 and hsp26 genes, but not at the other heat shock genes. The rates of transcription increased with increasing temperature with a peak of expression at around 35° C. At 37° C, induction was less efficient, and no induction was achieved after a rapid shift to 39° C. Increased transcription of the heat shock genes was observed within 1–2 min of heat shock, and maximal rates were reached within 2–5 min. Despite very similar profiles of response, different heat shock genes were transcribed at strikingly different rates, which varied over a 20-fold range. The noncoding heat shock locus 93D was transcribed at a very high rate under non-heat shock conditions, and showed a transcriptional response to elevated temperatures different from that of protein-coding heat shock genes. An estimation of the absolute rates of transcription at different temperatures was obtained.

Keywords

Heat Shock Heat Shock Gene Heat Shock Condition Mild Heat Shock Temperature Upshift 
These keywords were added by machine and not by the authors. This process is experimental and the keywords may be updated as the learning algorithm improves.
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Copyright information

© Springer-Verlag 1993

Authors and Affiliations

  • Julio Vazquez
    • 1
  • Daniel Pauli
    • 1
  • Alfred Tissières
    • 1
  1. 1.Department de Biologie MoléculaireUniversité de Genève, Sciences II. 30Genève 4Switzerland

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