Efficient formation of single-copy human artificial chromosomes.

Large DNA assembly methodologies underlie milestone achievements in synthetic prokaryotic and budding yeast chromosomes. While budding yeast control chromosome inheritance through ~125-base pair DNA sequence-defined centromeres, mammals and many other eukaryotes use large, epigenetic centromeres. Harnessing centromere epigenetics permits human artificial chromosome (HAC) formation but is not sufficient to avoid rampant multimerization of the initial DNA molecule upon introduction to cells.

Efficient Formation of Single-copy Human Artificial Chromosomes.

Large DNA assembly methodologies underlie milestone achievements in synthetic prokaryotic and budding yeast chromosomes. While budding yeast control chromosome inheritance through ~125 bp DNA sequence-defined centromeres, mammals and many other eukaryotes use large, epigenetic centromeres. Harnessing centromere epigenetics permits human artificial chromosome (HAC) formation but is not sufficient to avoid rampant multimerization of the initial DNA molecule upon introduction to cells.

High-throughput genetic screening of meiotic commitment using fluorescence microscopy in .

Simple genetic screens in budding yeast have identified many conserved meiotic regulators. However, the identification of genes involved in specific steps of meiosis may require a more complex genetic screen that allows visualization of meiosis. Here, we describe a high-throughput protocol using fluorescence microscopy to systematically screen an overexpression library to identify genes involved in meiotic commitment.

Chromosomes: A nuclear neighborhood conducive to centromere formation.

Centromere identity is specified by nucleosomes containing the histone variant CENP-A. A new study reveals that subnuclear location dictates the efficiency with which a new centromere forms.

Identification of 14-3-3 proteins, Polo kinase, and RNA-binding protein Pes4 as key regulators of meiotic commitment in budding yeast.

The initiation of the cell division process of meiosis requires exogenous signals that activate internal gene regulatory networks. Meiotic commitment ensures the irreversible continuation of meiosis, even upon withdrawal of the meiosis-inducing signals. A loss of meiotic commitment can cause highly abnormal polyploid cells and can ultimately lead to germ cell tumors.