LAUSR

The functional importance of N-methyladenosine (mA) modification in human health and disease has recently entered the research spotlight. In a recent paper published in Cell Research, Li et al. report a remarkable finding that deficiency in mA reader Ythdf2 results in a striking expansion of mouse and human hematopoietic stem cells. RNA is made up of four nucleotides: A, C, G and U. Information on RNA molecules relies on their core sequence, and also their chemical modifications. RNA chemical modifications play important roles in various steps of RNA processing, degradation, translation, and thus in the regulation of gene expression. Amongst the more than 100 different chemical modifications on RNA identified, N-methyladenosine (mA) is the most abundant epigenetic mark on eukaryotic messenger RNAs (mRNAs). The mA modification has been implicated in regulating a range of biological processes, and dysregulation of mA modification has been associated with many human diseases including cancer and obesity. Recent research has identified enzymes specifically involved in adjusting mA methylation levels and their functional outcomes; this has been considered another layer of epigenetic control similar to DNA and histone modifications, and has increased our knowledge of epitranscriptomics. The mA methyltransferase complex, or the “writer”, consists of Methyl transferase-like 3 and 14 (METTL3 and METTL14) with the cofactor Wilms tumor 1 associated protein (WTAP). METTL3 and METTL14 play critical roles in both normal hematopoiesis and leukemogenesis. On the other hand, fat mass and obesity associated protein (FTO) and ALKBH5 act as demethylases to erase mA modifications, and thus maintain a dynamic balance of mA levels. The function of FTO has been associated with body fat homeostasis, and recently with oncogenesis of acute myeloid leukemia. The mA modification is recognized by its readers, YTH domain family proteins, amongst which YTHDF2 destabilizes mAmodified mRNAs after binding within the consensus sequences. A recent study reports that YTHDF2 deficiency results in female infertility in mice, and YTHDF2 is maternally required for oocyte maturation. However, the physiological role of YTHDF2 in hematopoietic stem cell (HSC) biology was still unknown. In the present study, Li et al. observe a significant increase in numbers of HSCs in Ythdf2 conditional knockout mice compared to wild-type littermates. The Ythdf2-knockout mice showed no difference in numbers of hematopoietic progenitors and mature lineage cells, suggesting that Ythdf2 deficiency in hematopoietic lineages specifically increases HSC numbers. Limiting dilution in vivo engraftment assay revealed a 2.2-fold increase in competitive repopulating units (a measure of the numbers of functionally active HSCs) in Ythdf2-knockout, compared with control, bone marrow cells. Importantly, Ythdf2-knockout HSCs manifested normal lineage differentiation, with no apparent signs of hematological malignancies. Another interesting observation is that the mA modifications are enriched in mRNAs of several transcriptional factors that are crucial for self-renewal of HSCs, such as Gata2, Tal1, Etv6 and Stat5. Ythdf2 deficiency resulted in extended stability of these mA-marked mRNAs and elevated expression of these transcriptional factors (Fig. 1). Decapping of mRNA is an important step in mRNA decay, and Dcp1a encodes an mRNA decapping enzyme. Using fluorescence in situ hybridization, Li et al. were able to demonstrate co-localization of Tal1 mRNA, Dcp1a and Ythdf2 in wild-type cells but not in Ythdf2-knockout cells. They also showed that knockdown of Tal1 suppressed the increased engraftment of Ythdf2-knockout HSCs, supporting their conclusion that upregulation of HSC self-renewal factors accounted for the HSC expansion phenotype in Ythdf2-knockout mice. Human cord blood (CB) is an alternative source of HSCs for transplantation in clinical applications. However, limited numbers of HSCs in single CB collections have hampered wider use of CB in patients with malignant and nonmalignant disorders. While progress has been made to expand CB HSC numbers ex vivo, additional means are still needed to meet clinical demands. In an attempt to reveal whether the function of mA and Ythdf2 in HSCs would be conserved in human cells, Li et al. first performed mA RNA-seq in human CB CD34 cells and found that many transcriptional factors involved in HSC self-renewal were marked by mA modifications. They were then able to show that knockdown of YTHDF2 resulted in increased HSC numbers with long-term engraftment capability in vivo in immune-deficient mice. Thus, the exciting work by Li et al. adds to our understanding of mA and YTHDF2 function in HSC expansion in both mouse and human (Fig. 1). Recent progress has shed new light on enhancing CB transplantation efficacy by several approaches: collecting and processing HSCs at physiological low oxygen levels to prevent their differentiation and increase numbers; modifying membrane expression of a homing receptor, CXCR4; modulating epigenetic regulations to promote the HSC homing process; and by manipulating the cellular metabolism of HSCs to ex vivo expand them. Thus, it would be interesting to see whether the effects will be even greater by combining several different approaches for both enhanced HSC homing and ex vivo expansion with YTHDF2 inhibition. To conclude, Li et al. present important information towards further understanding the physiological impact of mA modification and HSC biology. Looking to the future, the new findings that HSC expansion can be achieved by Ythdf2 suppression open up a new and potent direction to simultaneously target multiple key transcriptional factors for HSC self-renewal, and to engineer HSCs