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Abstract N⁶-adenine methylation occurs in both DNA and RNA (referred to as 6mA and m6A, respectively). As an extensively characterized epi-transcriptomic mark found in virtually all eukaryotes, m6A in mRNA is deposited by METTL3-METTL14 complex. As a transcription-associated epigenetic mark abundantly present in many unicellular eukaryotes, 6mA is coordinately maintained by two AMT1 complexes, distinguished by their mutually exclusive subunits, AMT6 and AMT7. These are all members of MT-A70 family methyltransferases (MTases). Despite their functional importance, no structure for holo-complexes with cognate DNA/RNA substrate has been resolved. Here, we employ AlphaFold3 (AF3) and molecular dynamics (MD) simulations for structural modeling ofTetrahymenaAMT1 complexes, with emphasis on ternary holo-complexes with double-stranded DNA (dsDNA) substrate and cofactor. Key structural features observed in these models are validated by mutagenesis and various other biophysical and biochemical approaches. Our analysis reveals the structural basis for DNA substrate recognition, base flipping, and catalysis in the prototypical eukaryotic DNA 6mA-MTase. It also allows us to delineate the reaction pathway for processive DNA methylation involving translocation of the closed form AMT1 complex along dsDNA. As the active site is highly conserved across MT-A70 family of eukaryotic 6mA/m6A-MTases, the structural insight will facilitate rational design of small molecule inhibitors, especially for METTL3-METTL14, a promising target in cancer therapeutics. 

Stable inheritance of DNA N⁶-methyladenine (6mA) is crucial for its biological functions in eukaryotes. Here, we identify two distinct methyltransferase (MTase) complexes, both sharing the catalytic subunit AMT1, but featuring AMT6 and AMT7 as their unique components, respectively. While the two complexes are jointly responsible for 6mA maintenance methylation, they exhibit distinct enzymology, DNA/chromatin affinity, genomic distribution, and knockout phenotypes. AMT7 complex, featuring high MTase activity and processivity, is connected to transcription-associated epigenetic marks, including H2A.Z and H3K4me3, and is required for the bulk of maintenance methylation. In contrast, AMT6 complex, with reduced activity and processivity, is recruited by PCNA to initiate maintenance methylation immediately after DNA replication. These two complexes coordinate in maintenance methylation. By integrating signals from both replication and transcription, this mechanism ensures the faithful and efficient transmission of 6mA as an epigenetic mark in eukaryotes. 

ABSTRACT The rapid expansion of food and nutrition information requires new ways of data sharing and dissemination. Interactive platforms integrating data portals and visualization dashboards have been effectively utilized to describe, monitor, and track information related to food and nutrition; however, a comprehensive evaluation of emerging interactive systems is lacking. We conducted a systematic review on publicly available dashboards using a set of 48 evaluation metrics for data integrity, completeness, granularity, visualization quality, and interactivity based on 4 major principles: evidence, efficiency, emphasis, and ethics. We evaluated 13 dashboards, summarized their characteristics, strengths, and limitations, and provided guidelines for developing nutrition dashboards. We applied mixed effects models to summarize evaluation results adjusted for interrater variability. The proposed metrics and evaluation principles help to improve data standardization and harmonization, dashboard performance and usability, broaden information and knowledge sharing among researchers, practitioners, and decision makers in the field of food and nutrition, and accelerate data literacy and communication.