Spatiotemporal patterns and transcription kinetics of induced RNA in single bacterial cells.

Bacteria have a complex internal organization with specific localization of many proteins and DNA, which dynamically move during the cell cycle and in response to changing environmental stimuli. Much less is known, however, about the localization and movements of RNA molecules. By modifying our previous RNA labeling system, we monitor the expression and localization of a model RNA transcript in live Escherichia coli cells. Our results reveal that the target RNA is not evenly distributed within the cell and localizes laterally along the long cell axis, in a pattern suggesting the existence of ordered helical RNA structures reminiscent of known bacterial cytoskeletal cellular elements.

RNA visualization in live bacterial cells using fluorescent protein complementation.

We describe a technique for the detection and localization of RNA transcripts in living cells. The method is based on fluorescent-protein complementation regulated by the interaction of a split RNA-binding protein with its corresponding RNA aptamer. In our design, the RNA-binding protein is the eukaryotic initiation factor 4A (eIF4A). eIF4A is dissected into two fragments, and each fragment is fused to split fragments of the enhanced green fluorescent protein (EGFP). Coexpression of the two protein fusions in the presence of a transcript containing eIF4A-interacting RNA aptamer resulted in the restoration of EGFP fluorescence in Escherichia coli cells. We also applied this technique to the visualization of an aptamer-tagged mRNA and 5S ribosomal RNA (rRNA). We observed distinct spatial and temporal changes in fluorescence within single cells, reflecting the nature of the transcript.

Visualization of RNA using fluorescence complementation triggered by aptamer-protein interactions (RFAP) in live bacterial cells.

This unit describes a method allowing RNA visualization in live cells. The method is based on fluorescent protein complementation regulated by RNA-aptamer/RNA-binding protein interactions. Based on these two principles, a fluorescent ribonucleoprotein complex is assembled inside the cell only in response to the presence of the aptamer sequence on the target RNA.

Different mating-type-regulated genes affect the DNA repair defects of Saccharomyces RAD51, RAD52 and RAD55 mutants.

Saccharomyces cerevisiae cells expressing both a- and alpha-mating-type (MAT) genes (termed mating-type heterozygosity) exhibit higher rates of spontaneous recombination and greater radiation resistance than cells expressing only MATa or MATalpha. MAT heterozygosity suppresses recombination defects of four mutations involved in homologous recombination: complete deletions of RAD55 or RAD57, an ATPase-defective Rad51 mutation (rad51-K191R), and a C-terminal truncation of Rad52, rad52-Delta327. We investigated the genetic basis of MAT-dependent suppression of these mutants by deleting genes whose expression is controlled by the Mata1-Matalpha2 repressor and scoring resistance to both campothecin (CPT) and phleomycin. Haploid rad55Delta strains became more damage resistant after deleting genes required for nonhomologous end-joining (NHEJ), a process that is repressed in MATa/MATalpha cells. Surprisingly, NHEJ mutations do not suppress CPT sensitivity of rad51-K191R or rad52-Delta327. However, rad51-K191R is uniquely suppressed by deleting the RME1 gene encoding a repressor of meiosis or its coregulator SIN4; this effect is independent of the meiosis-specific homolog, Dmc1. Sensitivity of rad52-Delta327 to CPT was unexpectedly increased by the MATa/MATalpha-repressed gene YGL193C, emphasizing the complex ways in which MAT regulates homologous recombination. The rad52-Delta327 mutation is suppressed by deleting the prolyl isomerase Fpr3, which is not MAT regulated. rad55Delta is also suppressed by deletion of PST2 and/or YBR052C (RFS1, rad55 suppressor), two members of a three-gene family of flavodoxin-fold proteins that associate in a nonrandom fashion with chromatin. All three recombination-defective mutations are made more sensitive by deletions of Rad6 and of the histone deacetylases Rpd3 and Ume6, although these mutations are not themselves CPT or phleomycin sensitive.

The MRE11-RAD50-XRS2 complex, in addition to other non-homologous end-joining factors, is required for V(D)J joining in yeast.

Lymphoid cells of the vertebrate immune system rely on factors in the non-homologous end-joining (NHEJ) DNA repair pathway to form signal joints during V(D)J recombination. Unlike other end-joining reactions, signal joint formation is a specialized case of NHEJ that also requires the lymphoid-specific RAG proteins. Whether V(D)J recombination requires the Mre11-Rad50-Nbs1 complex remains an open question, as null mutations in any member of the complex are lethal in mammals. However, Saccharomyces cerevisiae strains carrying null mutations in components of the homologous Mre11p-Rad50p-Xrs2p (MRX) complex are viable. We therefore took advantage of a recently developed V(D)J recombination assay in yeast to assess the role of MRX in V(D)J joining. Here we confirmed that signal joint formation in yeast is dependent on the same NHEJ factors known to be required in mammalian cells. In addition, we showed an absolute requirement for the MRX complex in signal joining, suggesting that the Mre11-Rad50-Nbs1 complex may be required for signal joint formation in mammalian cells as well.