Project description:ESCO1 is an acetyltransferase enzyme that regulates chromosome organization and gene expression. It does this by modifying the Smc3 subunit of the Cohesin complex. Although ESCO1 is enriched at the base of chromatin loops in a Cohesin-dependent manner, precisely how it interacts with chromatin is unknown. Here we show that the basic and intrinsically disordered tail of ESCO1 binds DNA with very high affinity, likely through electrostatic interaction. We show that neutralization of positive residues in the N-tail reduces both DNA binding in vitro and association of the enzyme with chromatin in cells. Additionally, disruption of the chromatin state and charge distribution reduces chromatin bound ESCO1. Strikingly, defects in DNA binding do not affect total SMC3 acetylation or sister chromatid cohesion, suggesting that ESCO1-dependent acetylation can occur independently of direct chromatin association. We conclude that the intrinsically disordered tail of ESCO1 binds DNA with both high affinity and turnover, but surprisingly, ESCO1 catalytic activity occurs independently of direct DNA binding by the enzyme.

Project description:All coelenterate fluorescent proteins cloned to date display some form of quaternary structure, including the weak tendency of Aequorea green fluorescent protein (GFP) to dimerize, the obligate dimerization of Renilla GFP, and the obligate tetramerization of the red fluorescent protein from Discosoma (DsRed). Although the weak dimerization of Aequorea GFP has not impeded its acceptance as an indispensable tool of cell biology, the obligate tetramerization of DsRed has greatly hindered its use as a genetically encoded fusion tag. We present here the stepwise evolution of DsRed to a dimer and then either to a genetic fusion of two copies of the protein, i.e., a tandem dimer, or to a true monomer designated mRFP1 (monomeric red fluorescent protein). Each subunit interface was disrupted by insertion of arginines, which initially crippled the resulting protein, but red fluorescence could be rescued by random and directed mutagenesis totaling 17 substitutions in the dimer and 33 in mRFP1. Fusions of the gap junction protein connexin43 to mRFP1 formed fully functional junctions, whereas analogous fusions to the tetramer and dimer failed. Although mRFP1 has somewhat lower extinction coefficient, quantum yield, and photostability than DsRed, mRFP1 matures >10 times faster, so that it shows similar brightness in living cells. In addition, the excitation and emission peaks of mRFP1, 584 and 607 nm, are approximately 25 nm red-shifted from DsRed, which should confer greater tissue penetration and spectral separation from autofluorescence and other fluorescent proteins.

Project description:Several intrinsically disordered proteins have been implicated in the process of amyloid fibril formation in neurodegenerative disease, and developing approaches to inhibit the aggregation of these intrinsically disordered proteins is critical for establishing effective therapies against disease progression. The aggregation pathway of the intrinsically disordered protein alpha-synuclein, which is implicated in several neurodegenerative diseases known as synucleinopathies, has been extensively characterized. Less attention has been leveraged on beta-synuclein, a homologous intrinsically disordered protein that co-localizes with alpha-synuclein and is known to delay alpha-synuclein fibril formation. In this review, we focus on beta-synuclein and the molecular-level interactions between alpha-synuclein and beta-synuclein that underlie the delay of fibril formation. We highlight studies that begin to define alpha-synuclein and beta-synuclein interactions at the monomer, oligomer, and surface levels, and suggest that beta-synuclein plays a role in regulation of inhibition at many different stages of alpha-synuclein aggregation.

Project description:S. cerevisiae rlm1Δ strain was grown on YEPD. For Congo Red experiments, yeast cells were grown overnight at 24 °C to an optical density 0.8 - 1 (A600). The culture was refreshed to 0.2 O.D and grown at 24 °C for 2h 30min. Next, culture was divided into two parts. One continues growing under same conditions (non-treated culture) while the other was supplemented with Congo Red to a final concentration of 30 μg/ml. Cells were collected at 4 hours of growth, frozen at -80 °C and processed for RNA extraction. Keywords: repeat sample

Project description:S. cerevisiae slt2Δ strain was grown on YEPD. For Congo Red experiments, yeast cells were grown overnight at 24 °C to an optical density 0.8 - 1 (A600). The culture was refreshed to 0.2 O.D and grown at 24 °C for 2h 30min. Next, culture was divided into two parts. One continues growing under same conditions (non-treated culture) while the other was supplemented with Congo Red to a final concentration of 30 μg/ml. Cells were collected at 4 hours of growth, frozen at -80 °C and processed for RNA extraction. Keywords: repeat sample

Project description:S. cerevisiae was grown on YEPD. For Congo Red experiments, yeast cells were grown overnight at 24 °C to an optical density 0.8 - 1 (A600). The culture was refreshed to 0.2 O.D and grown at 24 °C for 2h 30min. Next, culture was divided into two parts. One continues growing under same conditions (non-treated culture) while the other was supplemented with Congo Red to a final concentration of 30 μg/ml. Cells were collected at 6 hours of growth, frozen at -80 °C and processed for RNA extraction. Keywords: repeat sample

Project description:S. cerevisiae was grown on YEPD. For Congo Red experiments, yeast cells were grown overnight at 24 °C to an optical density 0.8 - 1 (A600). The culture was refreshed to 0.2 O.D and grown at 24 °C for 2h 30min. Next, culture was divided into two parts. One continues growing under same conditions (non-treated culture) while the other was supplemented with Congo Red to a final concentration of 30 μg/ml. Cells were collected at 4 hours of growth, frozen at -80 °C and processed for RNA extraction. Keywords: repeat sample

Project description:S. cerevisiae was grown on YEPD. For Congo Red experiments, yest cells were grown overnight at 24 °C to an optical density 0.8 - 1 (A600). The culture was refreshed to 0.2 O.D and grown at 24 °C for 2h 30min. Next, culture was divided into two parts. One continues growing under same conditions (non-treated culture) while the other was supplemented with Congo Red to a final concentration of 30 μg/ml. Cells were collected at 2hours of growth, frozen at -80 °C and processed for RNA extraction. Keywords: repeat sample

Project description:S. cerevisiae was grown on YEPD. For Congo Red experiments, yeast cells were grown overnight at 24 °C to an optical density 0.8 - 1 (A600). The culture was refreshed to 0.2 O.D and grown at 24 °C for 2h 30min. Next, culture was divided into two parts. One continues growing under same conditions (non-treated culture) while the other was supplemented with Congo Red to a final concentration of 30 μg/ml. At this time cells were collected t=0h. Keywords: repeat sample

Project description:We did transcription profiling on the effect of mid2 deletion, gene involved in cell wall stress response Keywords: cell wall stress response