Your search keyword '"Banaszynski LA"' showing total 2 results

1. Histone variant H3.3-mediated chromatin remodeling is essential for paternal genome activation in mouse preimplantation embryos.

Author

Kong Q, Banaszynski LA, Geng F, Zhang X, Zhang J, Zhang H, O'Neill CL, Yan P, Liu Z, Shido K, Palermo GD, Allis CD, Rafii S, Rosenwaks Z, and Wen D

Subjects

Animals, Blastocyst cytology, Blastomeres cytology, Blastomeres metabolism, Embryonic Development, Female, Gene Expression Regulation, Developmental, Green Fluorescent Proteins genetics, Green Fluorescent Proteins metabolism, Histones antagonists & inhibitors, Histones genetics, Male, Mice, Mice, Inbred ICR, Mice, Transgenic, Morula cytology, Morula metabolism, Octamer Transcription Factor-3 chemistry, Octamer Transcription Factor-3 genetics, Octamer Transcription Factor-3 metabolism, Protein Isoforms antagonists & inhibitors, Protein Isoforms genetics, Protein Isoforms metabolism, RNA Interference, Recombinant Fusion Proteins chemistry, Recombinant Fusion Proteins metabolism, Blastocyst metabolism, Chromatin Assembly and Disassembly, Histones metabolism, Paternal Inheritance, Transcriptional Activation

Abstract

Derepression of chromatin-mediated transcriptional repression of paternal and maternal genomes is considered the first major step that initiates zygotic gene expression after fertilization. The histone variant H3.3 is present in both male and female gametes and is thought to be important for remodeling the paternal and maternal genomes for activation during both fertilization and embryogenesis. However, the underlying mechanisms remain poorly understood. Using our H3.3B-HA-tagged mouse model, engineered to report H3.3 expression in live animals and to distinguish different sources of H3.3 protein in embryos, we show here that sperm-derived H3.3 (sH3.3) protein is removed from the sperm genome shortly after fertilization and extruded from the zygotes via the second polar bodies (PBII) during embryogenesis. We also found that the maternal H3.3 (mH3.3) protein is incorporated into the paternal genome as early as 2 h postfertilization and is detectable in the paternal genome until the morula stage. Knockdown of maternal H3.3 resulted in compromised embryonic development both of fertilized embryos and of androgenetic haploid embryos. Furthermore, we report that mH3.3 depletion in oocytes impairs both activation of the Oct4 pluripotency marker gene and global de novo transcription from the paternal genome important for early embryonic development. Our results suggest that H3.3-mediated paternal chromatin remodeling is essential for the development of preimplantation embryos and the activation of the paternal genome during embryogenesis., (© 2018 by The American Society for Biochemistry and Molecular Biology, Inc.)

Published

2018

2. A directed approach for engineering conditional protein stability using biologically silent small molecules.

Author

Maynard-Smith LA, Chen LC, Banaszynski LA, Ooi AG, and Wandless TJ

Subjects

Animals, Bacterial Proteins chemistry, Biophysics methods, Humans, Kinetics, Ligands, Luminescent Proteins chemistry, Mice, Models, Molecular, Mutation, NIH 3T3 Cells, Oligonucleotide Array Sequence Analysis, Protein Binding, Tacrolimus Binding Protein 1A chemistry, Thermodynamics, Protein Engineering methods

Abstract

The ability to regulate the function of specific proteins using cell-permeable molecules can be a powerful method for interrogating biological systems. To bring this type of "chemical genetic" control to a wide range of proteins, we recently developed an experimental system in which the stability of a small protein domain expressed in mammalian cells depends on the presence of a high affinity ligand. This ligand-dependent stability is conferred to any fused partner protein. The FK506- and rapamycin-binding protein (FKBP12) has been the subject of extensive biophysical analyses, including both kinetic and thermodynamic studies of the wild-type protein as well as dozens of mutants. The goal of this study was to determine if the thermodynamic stabilities (DeltaDeltaG(U-F)) of various amino acid substitutions within a given protein are predictive for engineering additional ligand-dependent destabilizing domains. We used FKBP12 as a model system and found that in vitro thermodynamic stability correlates weakly with intracellular degradation rates of the mutants and that the ability of a given mutation to destabilize the protein is context-dependent. We evaluated several new FKBP12 ligands for their ability to stabilize these mutants and found that a cell-permeable molecule called Shield-1 is the most effective stabilizing ligand. We then performed an unbiased microarray analysis of NIH3T3 cells treated with various concentrations of Shield-1. These studies show that Shield-1 does not elicit appreciable cellular responses.

Published

2007