Ascorbate regulates haematopoietic stem cell function and leukaemogenesis.

Stem-cell fate can be influenced by metabolite levels in culture, but it is not known whether physiological variations in metabolite levels in normal tissues regulate stem-cell function in vivo. Here we describe a metabolomics method for the analysis of rare cell populations isolated directly from tissues and use it to compare mouse haematopoietic stem cells (HSCs) to restricted haematopoietic progenitors. Each haematopoietic cell type had a distinct metabolic signature. Human and mouse HSCs had unusually high levels of ascorbate, which decreased with differentiation. Systemic ascorbate depletion in mice increased HSC frequency and function, in part by reducing the function of Tet2, a dioxygenase tumour suppressor. Ascorbate depletion cooperated with Flt3 internal tandem duplication (Flt3ITD) leukaemic mutations to accelerate leukaemogenesis, through cell-autonomous and possibly non-cell-autonomous mechanisms, in a manner that was reversed by dietary ascorbate. Ascorbate acted cell-autonomously to negatively regulate HSC function and myelopoiesis through Tet2-dependent and Tet2-independent mechanisms. Ascorbate therefore accumulates within HSCs to promote Tet activity in vivo, limiting HSC frequency and suppressing leukaemogenesis.

Use of pressure cycling technology for cell lysis and recovery of bacterial and fungal communities from soil.

Selection of cell lysis methodology is critical to microbial community analyses due to the inability of any single extraction technology to recover the absolute genetic structure from environmental samples. Numerous methodologies are currently applied to interrogate soil communities, each with its own inherent bias. Here we compared the efficacy and bias of three physical cell lysis methods in conjunction with the PowerLyzer PowerSoil DNA Isolation Kit (MO BIO) for direct DNA extraction from soil: bead-beating, vortex disruption, and hydrostatic pressure cycling technology (PCT). PCT lysis, which is relatively new to soil DNA extraction, was optimized for soils of two different textures prior to comparison with traditional bead-beating and vortex disruption lysis. All cell lysis methods successfully recovered DNA. Although the two traditional mechanical lysis methods yielded greater genomic, bacterial, and fungal DNA per gram soil than the PCT method, the latter resulted in a greater number of unique terminal restriction fragments by terminal RFLP (T-RFLP) analysis. These findings indicate the importance of diversity and quantity measures when assessing DNA extraction bias, as soil DNA retrieved by PCT lysis represented populations not found using traditional mechanical lysis methods.