Minimal requirements for the epigenetic inheritance of engineered silent chromatin domains.

Mechanisms enabling genetically identical cells to differentially regulate gene expression are complex and central to organismal development and evolution. While gene silencing pathways involving DNA sequence-specific recruitment of histone-modifying enzymes are prevalent in nature, examples of sequence-independent heritable gene silencing are scarce. Studies of the fission yeast indicate that sequence-independent propagation of heterochromatin can occur but requires numerous multisubunit protein complexes and their diverse activities.

Measuring prion propagation in single bacteria elucidates a mechanism of loss.

Prions are self-propagating protein aggregates formed by specific proteins that can adopt alternative folds. Prions were discovered as the cause of the fatal transmissible spongiform encephalopathies in mammals, but prions can also constitute nontoxic protein-based elements of inheritance in fungi and other species. Prion propagation has recently been shown to occur in bacteria for more than a hundred cell divisions, yet a fraction of cells in these lineages lost the prion through an unknown mechanism.

A bacteria-based genetic assay detects prion formation.

Prions are infectious, self-propagating protein aggregates that are notorious for causing devastating neurodegenerative diseases in mammals. Recent evidence supports the existence of prions in bacteria. However, the evaluation of candidate bacterial prion-forming proteins has been hampered by the lack of genetic assays for detecting their conversion to an aggregated prion conformation.

A bacterial global regulator forms a prion.

Prions are self-propagating protein aggregates that act as protein-based elements of inheritance in fungi. Although prevalent in eukaryotes, prions have not been identified in bacteria. Here we found that a bacterial protein, transcription terminator Rho of Clostridium botulinum (Cb-Rho), could form a prion.

The bacterial cell cycle regulator GcrA is a σ70 cofactor that drives gene expression from a subset of methylated promoters.

Cell cycle progression in most organisms requires tightly regulated programs of gene expression. The transcription factors involved typically stimulate gene expression by binding specific DNA sequences in promoters and recruiting RNA polymerase. Here, we found that the essential cell cycle regulator GcrA in Caulobacter crescentus activates the transcription of target genes in a fundamentally different manner.

Prion propagation can occur in a prokaryote and requires the ClpB chaperone.

Prions are self-propagating protein aggregates that are characteristically transmissible. In mammals, the PrP protein can form a prion that causes the fatal transmissible spongiform encephalopathies. Prions have also been uncovered in fungi, where they act as heritable, protein-based genetic elements.

Key features of σS required for specific recognition by Crl, a transcription factor promoting assembly of RNA polymerase holoenzyme.

Bacteria use multiple sigma factors to coordinate gene expression in response to environmental perturbations. In Escherichia coli and other γ-proteobacteria, the transcription factor Crl stimulates σ(S)-dependent transcription during times of cellular stress by promoting the association of σ(S) with core RNA polymerase. The molecular basis for specific recognition of σ(S) by Crl, rather than the homologous and more abundant primary sigma factor σ(70), is unknown.

Direct activator/co-activator interaction is essential for bacteriophage T4 middle gene expression.

The bacteriophage T4 AsiA protein is a bifunctional regulator that inhibits transcription from the major class of bacterial promoters and also serves as an essential co-activator of transcription from T4 middle promoters. AsiA binds the primary s factor in Escherichia coli, sigma(70), and modifies the promoter recognition properties of the sigma(70)-containing RNA polymerase(RNAP) holoenzyme. In its role as co-activator, AsiA directs RNAP to T4 middle promoters in the presence of the T4-encoded activator MotA.

The bacteriophage T4 AsiA protein contacts the beta-flap domain of RNA polymerase.

To initiate transcription from specific promoters, the bacterial RNA polymerase (RNAP) core enzyme must associate with the initiation factor sigma, which contains determinants that allow sequence-specific interactions with promoter DNA. Most bacteria contain several sigma factors, each of which directs recognition of a distinct set of promoters. A large and diverse family of proteins known as "anti-sigma factors" regulates promoter utilization by targeting specific sigma factors.

Rsd family proteins make simultaneous interactions with regions 2 and 4 of the primary sigma factor.

Bacterial anti-sigma factors typically regulate sigma factor function by restricting the access of their cognate sigma factors to the RNA polymerase (RNAP) core enzyme. The Escherichia coli Rsd protein forms a complex with the primary sigma factor, sigma(70), inhibits sigma(70)-dependent transcription in vitro, and has been proposed to function as a sigma(70)-specific anti-sigma factor, thereby facilitating the utilization of alternative sigma factors. In prior work, Rsd has been shown to interact with conserved region 4 of sigma(70), but it is not known whether this interaction suffices to account for the regulatory functions of Rsd.