The zinc-finger transcription factor Sfp1 imprints specific classes of mRNAs and links their synthesis to cytoplasmic decay

Elife. 2024 Oct 2:12:RP90766. doi: 10.7554/eLife.90766.

Abstract

To function effectively as an integrated system, the transcriptional and post-transcriptional machineries must communicate through mechanisms that are still poorly understood. Here, we focus on the zinc-finger Sfp1, known to regulate transcription of proliferation-related genes. We show that Sfp1 can regulate transcription either by binding to promoters, like most known transcription activators, or by binding to the transcribed regions (gene bodies), probably via RNA polymerase II (Pol II). We further studied the first mode of Sfp1 activity and found that, following promoter binding, Sfp1 binds to gene bodies and affects Pol II configuration, manifested by dissociation or conformational change of its Rpb4 subunit and increased backtracking. Surprisingly, Sfp1 binds to a subset of mRNAs co-transcriptionally and stabilizes them. The interaction between Sfp1 and its client mRNAs is controlled by their respective promoters and coincides with Sfp1's dissociation from chromatin. Intriguingly, Sfp1 dissociation from the chromatin correlates with the extent of the backtracked Pol II. We propose that, following promoter recruitment, Sfp1 accompanies Pol II and regulates backtracking. The backtracked Pol II is more compatible with Sfp1's relocation to the nascent transcripts, whereupon Sfp1 accompanies these mRNAs to the cytoplasm and regulates their stability. Thus, Sfp1's co-transcriptional binding imprints the mRNA fate, serving as a paradigm for the cross-talk between the synthesis and decay of specific mRNAs, and a paradigm for the dual-role of some zinc-finger proteins. The interplay between Sfp1's two modes of transcription regulation remains to be examined.

Keywords: S. cerevisiae; chromosomes; gene expression; mRNA decay; mRNA synthesis; transcription backtracking; transcription factor; zinc-finger proteins.

Plain language summary

The ability to fine-tune the production of proteins in a cell is essential for organisms to exist. An imbalance in protein levels can be the cause of various diseases. Messenger RNA molecules (mRNA) link the genetic information encoded in DNA and the produced proteins. Exactly how much protein is made mostly depends on the amount of mRNA in the cell’s cytoplasm. This is controlled by two processes: the synthesis of mRNA (also known as transcription) and mRNA being actively degraded. Although much is known about mechanisms regulating transcription and degradation, how cells detect if they need to degrade mRNA based on the levels of its synthesis and vice versa is poorly understood. In 2013, researchers found that proteins known as 'RNA decay factors' responsible for mRNA degradation are actively moved from the cell’s cytoplasm into its nucleus to instruct the transcription machinery to produce more mRNA. Kelbert, Jordán-Pla, de-Miguel-Jiménez et al. – including some of the researchers involved in the 2013 work – investigated how mRNA synthesis and degradation are coordinated to ensure a proper mRNA level. The researchers used advanced genome engineering methods to carefully manipulate and measure mRNA production and degradation in yeast cells. The experiments revealed that the protein Sfp1 – a well-characterized transcription factor for stimulating the synthesis of a specific class of mRNAs inside the nucleus – can also prevent the degradation of these mRNAs outside the nucleus. During transcription, Sfp1 bound directly to mRNA. The investigators could manipulate the co-transcriptional binding of Sfp1 to a certain mRNA, thereby changing the mRNA stability in the cytoplasm. This suggests that the ability of Sfp1 to regulate both the production and decay of mRNA is dependent on one another and that transcription can influence the fate of its transcripts. This combined activity can rapidly change mRNA levels in response to changes in the cell’s environment. RNA plays a key role in ensuring correct levels of proteins. It can also function as an RNA molecule, independently of its coding capacity. Many cancers and developmental disorders are known to be caused by faulty interactions between transcription factors and nucleic acids. The finding that some transcription factors can directly regulate both mRNA synthesis and its destruction introduces new angles for studying and understanding these diseases.

MeSH terms

  • Cytoplasm / metabolism
  • DNA-Binding Proteins / genetics
  • DNA-Binding Proteins / metabolism
  • Promoter Regions, Genetic
  • Protein Binding
  • RNA Polymerase II* / genetics
  • RNA Polymerase II* / metabolism
  • RNA Stability
  • RNA, Messenger* / genetics
  • RNA, Messenger* / metabolism
  • Saccharomyces cerevisiae / genetics
  • Saccharomyces cerevisiae / metabolism
  • Saccharomyces cerevisiae Proteins
  • Transcription Factors* / genetics
  • Transcription Factors* / metabolism
  • Transcription, Genetic
  • Zinc Fingers

Substances

  • RNA, Messenger
  • RNA Polymerase II
  • Transcription Factors
  • DNA-Binding Proteins
  • RPB4 protein, S cerevisiae
  • Saccharomyces cerevisiae Proteins

Associated data

  • GEO/GSE202748
  • GEO/GSE230761
  • GEO/GSE57467