The differentiation of cells into distinct cell types, each of which is heritable for many generations, underlies many biological phenomena. White and opaque cells of the fungal pathogen Candida albicans are two such heritable cell types, each thought to be adapted to unique niches within their human host. To systematically investigate their differences, we performed strand-specific, massively-parallel sequencing of RNA from C. albicans white and opaque cells. With these data we first annotated the C. albicans transcriptome, finding hundreds of novel differentially-expressed transcripts. Using the new annotation, we compared differences in transcript abundance between the two cell types with the genomic regions bound by a master regulator of the white-opaque switch (Wor1). We found that the revised transcriptional landscape considerably alters our understanding of the circuit governing differentiation. In particular, we can now resolve the poor concordance between binding of a master regulator and the differential expression of adjacent genes, a discrepancy observed in several other studies of cell differentiation. More than one third of the Wor1-bound differentially-expressed transcripts were previously unannotated, which explains the formerly puzzling presence of Wor1 at these positions along the genome. Many of these newly identified Wor1-regulated genes are non-coding and transcribed antisense to coding transcripts. We also find that 5’ and 3’ UTRs of mRNAs in the circuit are unusually long and that 5’ UTRs often differ in length between cell-types, suggesting UTRs encode important regulatory information and that use of alternative promoters is widespread. Further analysis revealed that the revised Wor1 circuit bears several striking similarities to the Oct4 circuit that specifies the pluripotency of mammalian embryonic stem cells. Additional characteristics shared with the Oct4 circuit suggest a set of general hallmarks characteristic of heritable differentiation states in eukaryotes.

A biofilm is a surface-associated population of microorganisms embedded in a matrix of extracellular polymeric substances. Biofilms are a major natural growth form of microorganisms and the cause of pervasive device-associated infection. This report focuses on the biofilm matrix of Candida albicans, the major fungal pathogen of humans. We report here that the C. albicans zinc-response transcription factor Zap1 is a negative regulator of a major matrix component, soluble beta-1,3 glucan, in both in vitro and in vivo biofilm models. To understand the mechanistic relationship between Zap1 and matrix, we identified Zap1 target genes through expression profiling and full genome chromatin immunoprecipitation. On the basis of these results, we designed additional experiments showing that two glucoamylases, Gca1 and Gca2, have positive roles in matrix production and may function through hydrolysis of insoluble beta-1,3 glucan chains. We also show that a group of alcohol dehydrogenases Adh5, Csh1, and Ifd6 have roles in matrix production: Adh5 acts positively, and Csh1 and Ifd6, negatively. We propose that these alcohol dehydrogenases generate quorum-sensing aryl and acyl alcohols that in turn govern multiple events in biofilm maturation. Our findings define a novel regulatory circuit and its mechanism of control of a process central to infection.

Bacteria have developed mechanisms to communicate and compete with each other for limited environmental resources. We found that certain Escherichia coli, including uropathogenic strains, contained a bacterial growth-inhibition system that uses direct cell-to-cell contact. Inhibition was conditional, dependent upon the growth state of the inhibitory cell and the pili expression state of the target cell. Both a large cell-surface protein designated Contact-dependent inhibitor A (CdiA) and two-partner secretion family member CdiB were required for growth inhibition. The CdiAB system may function to regulate the growth of specific cells within a differentiated bacterial population.

Bacteria have developed epigenetic mechanisms to control the reversible Off-to-On switching of cell surface structures such as pyelonephritis-associated pili (PAP). The pap pili switch is primarily controlled by the global regulator leucine-responsive regulatory protein (Lrp), the local regulator PapI, and DNA adenine methylase (Dam). There are two sets of binding sites for Lrp in the pap regulatory region: promoter proximal sites 1,2,3 and promoter distal sites 4,5,6. The pilin promoter proximal (GATCprox) and distal (GATCdist) targets for Dam are located within Lrp binding sites 2 and 5, respectively. In the Off state, Lrp binds cooperatively to sites 1,2,3 overlapping the papBA pilin promoter, shutting off pilin transcription, and blocking methylation of GATCprox. Binding of Lrp at sites 1,2,3, together with methylation of GATCdist, reduces the affinity of Lrp for sites 4,5,6, preventing simultaneous binding of Lrp at sites 4,5,6 upstream. Switching to the phase. On state requires the environmentally regulated PapI co-regulator, which increases the affinity of Lrp for sites 5 and 2. PapI binds specifically to Lrp-pap DNA complexes via binding with Lrp as well as contact with DNA sequences within pap sites 5 and 2. Directionality in switching from Off to On appears to be due to methylation of GATCprox, which prevents formation of the PapI-Lrp-pap site 2 ternary complex. A switch model is presented in which DNA replication is proposed to play a critical role by generating a hemimethylated GATCdist site and displacing Lrp from sites 1,2,3. This facilitates methylation of GATCprox and binding of PapI-Lrp to sites 4,5,6, with subsequent activation of pap transcription. The first gene product of the pap operon, PapB, positively regulates papI transcription, resulting in a positive feedback loop that helps maintain the On state. The pap switch is environmentally regulated by a number of factors including the CpxAR two-component regulatory system, the Histone-like nucleoid structuring protein H-NS, and cAMP-Catabolite Gene Activator Protein (CAP), which all involve binding of regulatory binding proteins to pap DNA sequences with subsequent alteration of PapI and Lrp binding. The Pap switch mechanism, with interesting variations, is conserved among a number of enteric bacteria, controlling expression of many unrelated pili-adhesin complexes.

Pap pili gene expression is controlled by a reversible OFF/ON phase switch that is orchestrated by binding of Lrp to pap pilin promoter proximal sites 1, 2, and 3 (OFF) or pap promoter distal sites 4, 5, and 6 (ON). Movement of Lrp between proximal and distal sites controls pap pilin transcription and is modulated by PapI and DNA adenine methylase. Here we show that activation of the environmentally responsive CpxAR two-component regulatory system inhibits Pap phase variation by generation of phosphorylated CpxR (CpxR-P). CpxR-P competes with Lrp for binding to both promoter proximal and distal pap DNA binding sites, inhibiting pap transcription in vitro and pili expression in vivo. In contrast to Lrp, CpxR-P is methylation insensitive and does not form DNA methylation patterns in vivo. CpxAR-dependent repression of pap transcription is also observed in response to alkaline growth conditions. These results provide insight into a mechanism for environmental control of epigenetically regulated gene expression.

The expression of pyelonephritis-associated pili (Pap) in uropathogenic Escherichia coli is epigenetically controlled by a reversible OFF to ON switch. In phase OFF cells, the global regulator Lrp is bound to pap sites proximal to the pilin promoter, whereas in phase ON cells, Lrp is bound to promoter distal sites. We have found that the local regulator PapI increases the affinity of Lrp for the sequence "ACGATC," which contains the target "GATC" site for DNA adenine methylase (Dam) and is present in both promoter proximal and distal sites. Mutational analyses show that methylation of the promoter proximal GATC(prox) site by Dam is required for transition to the phase ON state by specifically blocking PapI-dependent binding of Lrp to promoter proximal sites. Furthermore, our data support the hypothesis that PapI-dependent binding of Lrp to a hemimethylated GATC(dist) site generated by DNA replication is a critical component of the switch mechanism.

Bacteria have developed an epigenetic phase variation mechanism to control cell surface pili-adhesin complexes between heritable expression (phase ON) and nonexpression (phase OFF) states. In the pyelonephritis-associated pili (pap) system, global regulators [catabolite gene activator protein (CAP), leucine-responsive regulatory protein (Lrp), DNA adenine methylase (Dam)] and local regulators (PapI and PapB) control phase switching. Lrp binds cooperatively to three pap DNA binding sites, sites 1-3, proximal to the papBA pilin promoter in phase OFF cells, whereas Lrp is bound to sites 4-6 distal to papBA in phase ON cells. Two Dam methylation targets, GATC(prox) and GATC(dist), are located in Lrp binding sites 2 and 5, respectively. In phase OFF cells, binding of Lrp at sites 1-3 inhibits methylation of GATC(prox), forming the phase OFF DNA methylation pattern (GATC(dist) methylated, GATC(prox) nonmethylated). Binding of Lrp at sites 1-3 blocks pap pili transcription and reduces the affinity of Lrp for sites 4-6. Together with methylation of GATC(dist), which inhibits Lrp binding at sites 4-6, the phase OFF state is maintained. We hypothesize that transition to the phase ON state requires DNA replication to dissociate Lrp and generate a hemimethyated GATC(dist) site. PapI and methylation of GATC(prox) act together to increase the affinity of Lrp for sites 4-6. Binding of Lrp at the distal sites protects GATC(dist) from methylation, forming the phase ON methylation pattern (GATC(dist) nonmethyated, GATC(prox) methylated). Lrp binding at sites 4-6 together with cAMP-CAP binding 215.5 bp upstream of the papBA transcription start, is required for activation of pilin transcription. The first gene product of the papBA transcript, PapB, helps maintain the switch in the ON state by activating papI transcription, which in turn maintains Lrp binding at sites 4-6.