Fluorescence microscopy demonstrates enhanced targeting of telavancin to the division septum of Staphylococcus aureus.

The cellular binding patterns of fluorescent conjugates of telavancin and vancomycin were evaluated in Staphylococcus aureus by fluorescence microscopy and ratio imaging analysis. Telavancin showed enhanced binding at the division septum compared to vancomycin. This result is consistent with observations that telavancin binds with higher affinity to lipid II than to d-Ala-d-Ala residues in the cell wall, thus demonstrating the preferential binding of telavancin to the site of active cell wall biosynthesis.

Germ line transcripts are processed by a Dicer-like protein that is essential for developmentally programmed genome rearrangements of Tetrahymena thermophila.

Abundant approximately 28-nucleotide RNAs that are thought to direct histone H3 lysine 9 (H3K9) methylation and promote the elimination of nearly 15 Mbp of DNA from the developing somatic genome are generated during Tetrahymena thermophila conjugation. To identify the protein(s) that generates these small RNAs, we studied three Dicer-related genes encoded within the Tetrahymena genome, two that contain both RNase III and RNA helicase motifs, Dicer 1 (DCR1) and DCR2, and a third that lacks the helicase domain, Dicer-like 1 (DCL1). DCL1 is expressed upon the initiation of conjugation, and the protein localizes to meiotic micronuclei when bidirectional germ line transcription occurs and small RNAs begin to accumulate. Cells in which we disrupted the DCL1 gene (DeltaDCL1) grew normally and initiated conjugation as wild-type cells but arrested near the end of development and eventually died, unable to resume vegetative growth. These DeltaDCL1 cells failed to generate the abundant small RNAs but instead accumulated germ line-limited transcripts. Together, our findings demonstrate that these transcripts are the precursors of the small RNAs and that DCL1 performs RNA processing within the micronucleus. Postconjugation DeltaDCL1 cells die without eliminating the germ line-limited DNA sequences from their newly formed somatic macronuclei, a result that shows that this Dicer-related gene is required for programmed DNA rearrangements. Surprisingly, DeltaDCL1 cells were not deficient in overall H3K9 methylation, but this modification was not enriched on germ line-limited sequences as it is in wild-type cells, which clearly demonstrates that these small RNAs are essential for its targeting to specific loci.

Lia1p, a novel protein required during nuclear differentiation for genome-wide DNA rearrangements in Tetrahymena thermophila.

Extensive genome-wide rearrangements occur during somatic macronuclear development in Tetrahymena thermophila. These events are guided by RNA interference-directed chromatin modification including histone H3 lysine 9 methylation, which marks specific germ line-limited internal eliminated sequences (IESs) for excision. Several genes putatively involved in these developmental genome rearrangements were identified based on their proteins' localization to differentiating somatic nuclei, and here we demonstrate that one, LIA1, encodes a novel protein that is an essential component of the genome rearrangement machinery. A green fluorescent protein-Lia1 fusion protein exhibited dynamic nuclear localization during development that has striking similarity to that of the dual chromodomain-containing DNA rearrangement protein, Pdd1p. Coimmunoprecipitation experiments showed that Lia1p associates with Pdd1p and IES chromatin during macronuclear development. Cell lines in which we disrupted both the germ line and somatic copies of LIA1 (DeltaLIA1) grew normally but were unable to generate viable progeny, arresting late in development just prior to returning to vegetative growth. These mutant lines failed to properly form Pdd1p-containing nuclear structures and eliminate IESs despite showing normal levels of H3K9 methylation. These data indicate that Lia1p is required late in conjugation for the reorganization of the Tetrahymena genome.

Identification of novel chromatin-associated proteins involved in programmed genome rearrangements in Tetrahymena.

Extensive DNA rearrangements occur during the differentiation of the developing somatic macronuclear genome from the germ line micronuclear genome of Tetrahymena thermophila. To identify genes encoding proteins likely to be involved in this process, we devised a cytological screen to find proteins that specifically localize in macronuclear anlagen (Lia proteins) at the stage when rearrangements occur. We compared the localization of these with that of the chromodomain protein, Pdd1p, which is the most abundant known participant in this genome reorganization. We show that in live cells, Pdd1p exhibits dynamic localization, apparently shuttling from the parental to the developing nuclei through cytoplasmic bodies called conjusomes. Visualization of GFP-tagged Pdd1p also highlights the substantial three-dimensional nuclear reorganization in the formation of nuclear foci that occur coincident with DNA rearrangements. We found that late in macronuclear differentiation, four of the newly identified proteins are organized into nuclear foci that also contain Pdd1p. These Lia proteins are encoded by primarily novel genes expressed at the beginning of macronuclear differentiation and have properties or recognizable domains that implicate them in chromatin or nucleic acid binding. Three of the Lia proteins also localize to conjusomes, a result that further implicates this structure in the regulation of DNA rearrangement.