PLOS Biology<p>Multiple <a href="https://fediscience.org/tags/myeloma" class="mention hashtag" rel="nofollow noopener noreferrer" target="_blank">#<span>myeloma</span></a> often requires IRE1 to sustain malignant growth, but why? This study shows that IRE1 promotes <a href="https://fediscience.org/tags/CellCycle" class="mention hashtag" rel="nofollow noopener noreferrer" target="_blank">#<span>CellCycle</span></a> progression via the transcription factor IRF4, paving the way for new therapeutic strategies <span class="h-card" translate="no"><a href="https://fediscience.org/@PLOSBiology" class="u-url mention" rel="nofollow noopener noreferrer" target="_blank">@<span>PLOSBiology</span></a></span> <a href="https://plos.io/43TnG0L" rel="nofollow noopener noreferrer" translate="no" target="_blank"><span class="invisible">https://</span><span class="">plos.io/43TnG0L</span><span class="invisible"></span></a></p>
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#cellcycle
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PLOS Biology<p>ER-resident IRE1 plays a role in <a href="https://fediscience.org/tags/cancer" class="mention hashtag" rel="nofollow noopener noreferrer" target="_blank">#<span>cancer</span></a> development via enzymatic activation of XPB1 TFs and regulated <a href="https://fediscience.org/tags/RNAdecay" class="mention hashtag" rel="nofollow noopener noreferrer" target="_blank">#<span>RNAdecay</span></a>. This study shows that some cancer cells also have an unexpected nonenzymatic dependency on IRE1 to promote <a href="https://fediscience.org/tags/CellCycle" class="mention hashtag" rel="nofollow noopener noreferrer" target="_blank">#<span>CellCycle</span></a> progression & tumor growth <span class="h-card" translate="no"><a href="https://fediscience.org/@PLOSBiology" class="u-url mention" rel="nofollow noopener noreferrer" target="_blank">@<span>PLOSBiology</span></a></span> <a href="https://plos.io/3EaNFX4" rel="nofollow noopener noreferrer" translate="no" target="_blank"><span class="invisible">https://</span><span class="">plos.io/3EaNFX4</span><span class="invisible"></span></a></p>
PLOS Biology<p>Current methods to study <a href="https://fediscience.org/tags/CellCycle" class="mention hashtag" rel="nofollow noopener noreferrer" target="_blank">#<span>CellCycle</span></a> progression in <a href="https://fediscience.org/tags/yeast" class="mention hashtag" rel="nofollow noopener noreferrer" target="_blank">#<span>yeast</span></a> ignore variations in cell size. The FLCCR reporter system can quantify the duration of cell cycle phase in single cells, allowing independent assessment of cell size & cell cycle progression <a href="https://fediscience.org/tags/plosbiology" class="mention hashtag" rel="nofollow noopener noreferrer" target="_blank">#<span>plosbiology</span></a> <a href="https://plos.io/4j48NxJ" rel="nofollow noopener noreferrer" translate="no" target="_blank"><span class="invisible">https://</span><span class="">plos.io/4j48NxJ</span><span class="invisible"></span></a></p>
Andrew Millar<p>From post 5,<br>Amino acids that are enriched/depleted next to the phospho-site reflect which protein kinase enzymes did the phosphorylation. </p><p>Phospho-dawn sees acid-directed sites being phosphorylated (D and E enriched at ZT0), <br>but by evening it's <a href="https://fediscience.org/tags/CellCycle" class="mention hashtag" rel="nofollow noopener noreferrer" target="_blank">#<span>CellCycle</span></a> kinases guided by Proline (P at ZT12-16). 😎 </p><p><a href="https://fediscience.org/tags/Shiftwork" class="mention hashtag" rel="nofollow noopener noreferrer" target="_blank">#<span>Shiftwork</span></a></p>
PLOS Biology<p>Apicomplexan <a href="https://fediscience.org/tags/parasite" class="mention hashtag" rel="nofollow noopener noreferrer" target="_blank">#<span>parasite</span></a> division: @MGissot &co show that the <a href="https://fediscience.org/tags/phosphatase" class="mention hashtag" rel="nofollow noopener noreferrer" target="_blank">#<span>phosphatase</span></a> TgPP1 in <a href="https://fediscience.org/tags/Toxoplasma" class="mention hashtag" rel="nofollow noopener noreferrer" target="_blank">#<span>Toxoplasma</span></a> regulates the <a href="https://fediscience.org/tags/CellCycle" class="mention hashtag" rel="nofollow noopener noreferrer" target="_blank">#<span>CellCycle</span></a> & amylopectin accumulation by dephosphorylating inner membrane complex & starch-binding domain proteins <a href="https://fediscience.org/tags/PLOSBiology" class="mention hashtag" rel="nofollow noopener noreferrer" target="_blank">#<span>PLOSBiology</span></a> <a href="https://plos.io/3XwMYgj" rel="nofollow noopener noreferrer" translate="no" target="_blank"><span class="invisible">https://</span><span class="">plos.io/3XwMYgj</span><span class="invisible"></span></a></p>
PLOS Biology<p>How do cells respond to defects in nuclear reassembly after <a href="https://fediscience.org/tags/mitosis" class="mention hashtag" rel="nofollow noopener noreferrer" target="_blank">#<span>mitosis</span></a>? This study in <a href="https://fediscience.org/tags/Drosophila" class="mention hashtag" rel="nofollow noopener noreferrer" target="_blank">#<span>Drosophila</span></a> shows that damaged cells are either removed by <a href="https://fediscience.org/tags/apoptosis" class="mention hashtag" rel="nofollow noopener noreferrer" target="_blank">#<span>apoptosis</span></a> or activate a p53-dependent <a href="https://fediscience.org/tags/CellCycle" class="mention hashtag" rel="nofollow noopener noreferrer" target="_blank">#<span>CellCycle</span></a> checkpoint to maintain tissue integrity <a href="https://fediscience.org/tags/PLOSBiology" class="mention hashtag" rel="nofollow noopener noreferrer" target="_blank">#<span>PLOSBiology</span></a> <a href="https://plos.io/3AA4g4c" rel="nofollow noopener noreferrer" translate="no" target="_blank"><span class="invisible">https://</span><span class="">plos.io/3AA4g4c</span><span class="invisible"></span></a></p>
preLights<p>“In this preprint, the authors (Saykali et al.) turned into cinematographers, capturing the real time dynamics of CDKs using a very sensitive sensor.” 🎬 🎥</p><p>Another lovely, entertaining preLight prepared by Mansi - check it out! ⬇️ 👀</p><p><a href="https://biologists.social/tags/preLight" class="mention hashtag" rel="nofollow noopener noreferrer" target="_blank">#<span>preLight</span></a> 👉 <a href="https://prelights.biologists.com/highlights/lineage-specific-cdk-activity-dynamics-characterize-early-mammalian-development/" rel="nofollow noopener noreferrer" translate="no" target="_blank"><span class="invisible">https://</span><span class="ellipsis">prelights.biologists.com/highl</span><span class="invisible">ights/lineage-specific-cdk-activity-dynamics-characterize-early-mammalian-development/</span></a></p><p><a href="https://biologists.social/tags/development" class="mention hashtag" rel="nofollow noopener noreferrer" target="_blank">#<span>development</span></a> <a href="https://biologists.social/tags/biology" class="mention hashtag" rel="nofollow noopener noreferrer" target="_blank">#<span>biology</span></a> <a href="https://biologists.social/tags/preprint" class="mention hashtag" rel="nofollow noopener noreferrer" target="_blank">#<span>preprint</span></a> <a href="https://biologists.social/tags/cellcycle" class="mention hashtag" rel="nofollow noopener noreferrer" target="_blank">#<span>cellcycle</span></a> <a href="https://biologists.social/tags/imaging" class="mention hashtag" rel="nofollow noopener noreferrer" target="_blank">#<span>imaging</span></a></p>
Haojia Wu<p>Quantifying DNA replication speeds in single cells by scEdU-seq <a href="https://mastodon.haojia-wu.com/tags/singlecell" class="mention hashtag" rel="nofollow noopener noreferrer" target="_blank">#<span>singlecell</span></a> <a href="https://mastodon.haojia-wu.com/tags/cellcycle" class="mention hashtag" rel="nofollow noopener noreferrer" target="_blank">#<span>cellcycle</span></a> <a href="https://mastodon.haojia-wu.com/tags/newtech" class="mention hashtag" rel="nofollow noopener noreferrer" target="_blank">#<span>newtech</span></a> </p><p><a href="https://www.nature.com/articles/s41592-024-02308-4?utm_source=nmeth_etoc&utm_medium=email&utm_campaign=toc_41592_21_7&utm_content=20240713" rel="nofollow noopener noreferrer" translate="no" target="_blank"><span class="invisible">https://www.</span><span class="ellipsis">nature.com/articles/s41592-024</span><span class="invisible">-02308-4?utm_source=nmeth_etoc&utm_medium=email&utm_campaign=toc_41592_21_7&utm_content=20240713</span></a></p>
micrordt<p>Unraveling the Mechanisms: Regulation of DNA Replication in Bacterial Cells</p><p><a href="https://mastodon.social/tags/Bacteria" class="mention hashtag" rel="nofollow noopener noreferrer" target="_blank">#<span>Bacteria</span></a>, <a href="https://mastodon.social/tags/CellCycle" class="mention hashtag" rel="nofollow noopener noreferrer" target="_blank">#<span>CellCycle</span></a>, <a href="https://mastodon.social/tags/DNA" class="mention hashtag" rel="nofollow noopener noreferrer" target="_blank">#<span>DNA</span></a>, <a href="https://mastodon.social/tags/DNAReplication" class="mention hashtag" rel="nofollow noopener noreferrer" target="_blank">#<span>DNAReplication</span></a>, <a href="https://mastodon.social/tags/DnaA" class="mention hashtag" rel="nofollow noopener noreferrer" target="_blank">#<span>DnaA</span></a>, <a href="https://mastodon.social/tags/OriC" class="mention hashtag" rel="nofollow noopener noreferrer" target="_blank">#<span>OriC</span></a>, <a href="https://mastodon.social/tags/RegulatoryProteins" class="mention hashtag" rel="nofollow noopener noreferrer" target="_blank">#<span>RegulatoryProteins</span></a>, <a href="https://mastodon.social/tags/Replication" class="mention hashtag" rel="nofollow noopener noreferrer" target="_blank">#<span>Replication</span></a> <a href="https://mastodon.social/tags/Genetics" class="mention hashtag" rel="nofollow noopener noreferrer" target="_blank">#<span>Genetics</span></a>, <a href="https://mastodon.social/tags/MolecularBiology" class="mention hashtag" rel="nofollow noopener noreferrer" target="_blank">#<span>MolecularBiology</span></a> DNA replication is a fundamental process in all living organisms, ensuring the faithful transmission of genetic information from one generation to the next. In bacterial cells, where simplicity meets efficiency…. Medical Microbiology & Recombinant DNA Technology (RDT) Labs…</p><p><a href="https://micrordt.wordpress.com/2024/05/01/unraveling-the-mechanisms-regulation-of-dna-replication-in-bacterial-cells/" rel="nofollow noopener noreferrer" translate="no" target="_blank"><span class="invisible">https://</span><span class="ellipsis">micrordt.wordpress.com/2024/05</span><span class="invisible">/01/unraveling-the-mechanisms-regulation-of-dna-replication-in-bacterial-cells/</span></a></p>
PLOS Biology<p>Cell cycle genes are re-activated in some <a href="https://fediscience.org/tags/neurons" class="mention hashtag" rel="nofollow noopener noreferrer" target="_blank">#<span>neurons</span></a> as our brains age. This study uses bioinformatics to characterize the prevalence, nature & fate of these <a href="https://fediscience.org/tags/CellCycle" class="mention hashtag" rel="nofollow noopener noreferrer" target="_blank">#<span>CellCycle</span></a> re-entry neurons, within the healthy <a href="https://fediscience.org/tags/aging" class="mention hashtag" rel="nofollow noopener noreferrer" target="_blank">#<span>aging</span></a> & diseased human brain. <a href="https://fediscience.org/tags/PLOSBiology" class="mention hashtag" rel="nofollow noopener noreferrer" target="_blank">#<span>PLOSBiology</span></a> <a href="https://plos.io/4dbHoXt" rel="nofollow noopener noreferrer" translate="no" target="_blank"><span class="invisible">https://</span><span class="">plos.io/4dbHoXt</span><span class="invisible"></span></a></p>
Andrew Burgess<p>When you have “ATM” in your name your destiny is to either work for a bank or become a researcher specialising in <a href="https://mastodon.social/tags/DNAdamage" class="mention hashtag" rel="nofollow noopener noreferrer" target="_blank">#<span>DNAdamage</span></a> <a href="https://mastodon.social/tags/science" class="mention hashtag" rel="nofollow noopener noreferrer" target="_blank">#<span>science</span></a> <a href="https://mastodon.social/tags/CellCycle" class="mention hashtag" rel="nofollow noopener noreferrer" target="_blank">#<span>CellCycle</span></a></p><p><a href="https://pubmed.ncbi.nlm.nih.gov/38625790/?utm_source=Feedly&utm_medium=rss&utm_campaign=None&utm_content=1TkPOxkdaxtnnrl5wnZzn2VRNhPyzrYC_QUuJ0PP1Pdf91LMB7&fc=None&ff=20240416205101&v=2.18.0.post9+e462414" rel="nofollow noopener noreferrer" translate="no" target="_blank"><span class="invisible">https://</span><span class="ellipsis">pubmed.ncbi.nlm.nih.gov/386257</span><span class="invisible">90/?utm_source=Feedly&utm_medium=rss&utm_campaign=None&utm_content=1TkPOxkdaxtnnrl5wnZzn2VRNhPyzrYC_QUuJ0PP1Pdf91LMB7&fc=None&ff=20240416205101&v=2.18.0.post9+e462414</span></a></p>
PLOS Biology<p>Proliferating cells need to maintain a stable size distribution across the generations. This study shows that this is achieved by tightly controlling <a href="https://fediscience.org/tags/CellSize" class="mention hashtag" rel="nofollow noopener noreferrer" target="_blank">#<span>CellSize</span></a> variation throughout the <a href="https://fediscience.org/tags/CellCycle" class="mention hashtag" rel="nofollow noopener noreferrer" target="_blank">#<span>CellCycle</span></a>, mainly via regulation of cell growth rate <a href="https://fediscience.org/tags/PLOSBiology" class="mention hashtag" rel="nofollow noopener noreferrer" target="_blank">#<span>PLOSBiology</span></a> <a href="https://plos.io/4aMUWHS" rel="nofollow noopener noreferrer" target="_blank"><span class="invisible">https://</span><span class="">plos.io/4aMUWHS</span><span class="invisible"></span></a></p>
The EMBO Journal<p>How do <a href="https://sciencemastodon.com/tags/cellcycle" class="mention hashtag" rel="nofollow noopener noreferrer" target="_blank">#<span>cellcycle</span></a> oscillators generate exactly two <a href="https://sciencemastodon.com/tags/meiotic" class="mention hashtag" rel="nofollow noopener noreferrer" target="_blank">#<span>meiotic</span></a> divisions for production of haploid <a href="https://sciencemastodon.com/tags/gametes" class="mention hashtag" rel="nofollow noopener noreferrer" target="_blank">#<span>gametes</span></a>?<br>Wolfgang Zachariae and colleagues show that <a href="https://sciencemastodon.com/tags/Spo13" class="mention hashtag" rel="nofollow noopener noreferrer" target="_blank">#<span>Spo13</span></a>/#MEIKIN and <a href="https://sciencemastodon.com/tags/Cdc5" class="mention hashtag" rel="nofollow noopener noreferrer" target="_blank">#<span>Cdc5</span></a>/#Plk1 cooperate to prevent premature APC/C-<a href="https://sciencemastodon.com/tags/Ama1" class="mention hashtag" rel="nofollow noopener noreferrer" target="_blank">#<span>Ama1</span></a> activation after <a href="https://sciencemastodon.com/tags/meiosis" class="mention hashtag" rel="nofollow noopener noreferrer" target="_blank">#<span>meiosis</span></a> I<br><a href="https://www.embopress.org/doi/full/10.15252/embj.2023114288" rel="nofollow noopener noreferrer" target="_blank"><span class="invisible">https://www.</span><span class="ellipsis">embopress.org/doi/full/10.1525</span><span class="invisible">2/embj.2023114288</span></a></p>
The EMBO Journal<p><a href="https://sciencemastodon.com/tags/Phosphorylation" class="mention hashtag" rel="nofollow noopener noreferrer" target="_blank">#<span>Phosphorylation</span></a> control in <a href="https://sciencemastodon.com/tags/mitosis" class="mention hashtag" rel="nofollow noopener noreferrer" target="_blank">#<span>mitosis</span></a>:<br>Julie Welburn and colleagues reveal the molecular basis for <a href="https://sciencemastodon.com/tags/cellcycle" class="mention hashtag" rel="nofollow noopener noreferrer" target="_blank">#<span>cellcycle</span></a> regulation of <a href="https://sciencemastodon.com/tags/Kif4A" class="mention hashtag" rel="nofollow noopener noreferrer" target="_blank">#<span>Kif4A</span></a> and <a href="https://sciencemastodon.com/tags/CENPE" class="mention hashtag" rel="nofollow noopener noreferrer" target="_blank">#<span>CENPE</span></a> motor interaction with <a href="https://sciencemastodon.com/tags/PRC1" class="mention hashtag" rel="nofollow noopener noreferrer" target="_blank">#<span>PRC1</span></a>, needed to organize antiparallel <a href="https://sciencemastodon.com/tags/microtubule" class="mention hashtag" rel="nofollow noopener noreferrer" target="_blank">#<span>microtubule</span></a> bundles and to ensure central spindle integrity, <a href="https://sciencemastodon.com/tags/midbody" class="mention hashtag" rel="nofollow noopener noreferrer" target="_blank">#<span>midbody</span></a> assembly and <a href="https://sciencemastodon.com/tags/cytokinesis" class="mention hashtag" rel="nofollow noopener noreferrer" target="_blank">#<span>cytokinesis</span></a></p><p><a href="https://www.embopress.org/doi/full/10.15252/embj.2023113647" rel="nofollow noopener noreferrer" target="_blank"><span class="invisible">https://www.</span><span class="ellipsis">embopress.org/doi/full/10.1525</span><span class="invisible">2/embj.2023113647</span></a></p>
Small Things Considered<p>cell 🚴♂️ cyclists & DNA replicationists take note 👇 </p><p>super interesting thread by kristina jonas on twitter (X):<br><a href="https://twitter.com/krijonas/status/1684903480069128192" rel="nofollow noopener noreferrer" target="_blank"><span class="invisible">https://</span><span class="ellipsis">twitter.com/krijonas/status/16</span><span class="invisible">84903480069128192</span></a></p><p><a href="https://mstdn.science/tags/microbiology" class="mention hashtag" rel="nofollow noopener noreferrer" target="_blank">#<span>microbiology</span></a> <a href="https://mstdn.science/tags/replication" class="mention hashtag" rel="nofollow noopener noreferrer" target="_blank">#<span>replication</span></a> <a href="https://mstdn.science/tags/cellcycle" class="mention hashtag" rel="nofollow noopener noreferrer" target="_blank">#<span>cellcycle</span></a></p>
Small Things Considered<p>bacterial cell cyclists take note 👇 <br> <br>'The Nordström Question' by William D. Donachie. This will remain one of the most memorable papers I’ve ever read by the end of my career. — Suckjoon Jun <span class="h-card"><a href="https://bird.makeup/users/junlab_ucsd" class="u-url mention" rel="nofollow noopener noreferrer" target="_blank">@<span>junlab_ucsd</span></a></span></p><p>(<a href="https://twitter.com/junlab_ucsd/status/1673262090734141440" rel="nofollow noopener noreferrer" target="_blank"><span class="invisible">https://</span><span class="ellipsis">twitter.com/junlab_ucsd/status</span><span class="invisible">/1673262090734141440</span></a>)</p><p><a href="https://www.mdpi.com/2075-1729/13/7/1442" rel="nofollow noopener noreferrer" target="_blank"><span class="invisible">https://www.</span><span class="">mdpi.com/2075-1729/13/7/1442</span><span class="invisible"></span></a></p><p><a href="https://mstdn.science/tags/microbiology" class="mention hashtag" rel="nofollow noopener noreferrer" target="_blank">#<span>microbiology</span></a> <a href="https://mstdn.science/tags/cellcycle" class="mention hashtag" rel="nofollow noopener noreferrer" target="_blank">#<span>cellcycle</span></a></p>
The EMBO Journal<p>A <a href="https://sciencemastodon.com/tags/transcription" class="mention hashtag" rel="nofollow noopener noreferrer" target="_blank">#<span>transcription</span></a>-independent mechanism -<a href="https://sciencemastodon.com/tags/RBM10" class="mention hashtag" rel="nofollow noopener noreferrer" target="_blank">#<span>RBM10</span></a>-mediated RNA alternative <a href="https://sciencemastodon.com/tags/splicing" class="mention hashtag" rel="nofollow noopener noreferrer" target="_blank">#<span>splicing</span></a> coupled to nonsense-mediated <a href="https://sciencemastodon.com/tags/mRNA" class="mention hashtag" rel="nofollow noopener noreferrer" target="_blank">#<span>mRNA</span></a> decay- determines rapid periodic fluctuations of <a href="https://sciencemastodon.com/tags/BRCA1" class="mention hashtag" rel="nofollow noopener noreferrer" target="_blank">#<span>BRCA1</span></a> expression throughout the <a href="https://sciencemastodon.com/tags/cellcycle" class="mention hashtag" rel="nofollow noopener noreferrer" target="_blank">#<span>cellcycle</span></a></p><p><a href="https://www.embopress.org/doi/full/10.15252/embj.2022111951" rel="nofollow noopener noreferrer" target="_blank"><span class="invisible">https://www.</span><span class="ellipsis">embopress.org/doi/full/10.1525</span><span class="invisible">2/embj.2022111951</span></a></p>
Thiago Carvalho<p>"In this study, we revisit and significantly extend the initiator-titration model, proposed thirty years ago, and explain how bacteria precisely and robustly control replication initiation based on the mechanism of protein copy-number sensing."</p><p><a href="https://qoto.org/tags/preprint" class="mention hashtag" rel="nofollow noopener noreferrer" target="_blank">#<span>preprint</span></a> <a href="https://qoto.org/tags/microbiology" class="mention hashtag" rel="nofollow noopener noreferrer" target="_blank">#<span>microbiology</span></a> <a href="https://qoto.org/tags/cellcycle" class="mention hashtag" rel="nofollow noopener noreferrer" target="_blank">#<span>cellcycle</span></a></p><p><a href="https://www.biorxiv.org/content/10.1101/2023.05.26.542547v1" rel="nofollow noopener noreferrer" target="_blank"><span class="invisible">https://www.</span><span class="ellipsis">biorxiv.org/content/10.1101/20</span><span class="invisible">23.05.26.542547v1</span></a></p>
eLife<p>Transferred <a href="https://fediscience.org/tags/mitochondria" class="mention hashtag" rel="nofollow noopener noreferrer" target="_blank">#<span>mitochondria</span></a> accumulate reactive oxygen species, promoting proliferation. <a href="https://fediscience.org/tags/Cancer" class="mention hashtag" rel="nofollow noopener noreferrer" target="_blank">#<span>Cancer</span></a> <a href="https://fediscience.org/tags/ReactiveOxygenSpecies" class="mention hashtag" rel="nofollow noopener noreferrer" target="_blank">#<span>ReactiveOxygenSpecies</span></a> <a href="https://fediscience.org/tags/CellCycle" class="mention hashtag" rel="nofollow noopener noreferrer" target="_blank">#<span>CellCycle</span></a> <a href="https://elifesciences.org/articles/85494?utm_source=mastodon&utm_medium=social&utm_campaign=organic" rel="nofollow noopener noreferrer" target="_blank"><span class="invisible">https://</span><span class="ellipsis">elifesciences.org/articles/854</span><span class="invisible">94?utm_source=mastodon&utm_medium=social&utm_campaign=organic</span></a></p>
Boris Tefsen<p>Very interesting work with implications beyond <a href="https://mas.to/tags/metabolism" class="mention hashtag" rel="nofollow noopener noreferrer" target="_blank">#<span>metabolism</span></a> / <a href="https://mas.to/tags/biosynthesis" class="mention hashtag" rel="nofollow noopener noreferrer" target="_blank">#<span>biosynthesis</span></a> and cell cycle in <a href="https://mas.to/tags/yeast" class="mention hashtag" rel="nofollow noopener noreferrer" target="_blank">#<span>yeast</span></a>.<br><a href="https://www.nature.com/articles/s42255-023-00741-x" rel="nofollow noopener noreferrer" target="_blank"><span class="invisible">https://www.</span><span class="ellipsis">nature.com/articles/s42255-023</span><span class="invisible">-00741-x</span></a><br><a href="https://mas.to/tags/Microbiology" class="mention hashtag" rel="nofollow noopener noreferrer" target="_blank">#<span>Microbiology</span></a> <a href="https://mas.to/tags/CellCycle" class="mention hashtag" rel="nofollow noopener noreferrer" target="_blank">#<span>CellCycle</span></a> <a href="https://mas.to/tags/Proteins" class="mention hashtag" rel="nofollow noopener noreferrer" target="_blank">#<span>Proteins</span></a> <a href="https://mas.to/tags/Carbohydrates" class="mention hashtag" rel="nofollow noopener noreferrer" target="_blank">#<span>Carbohydrates</span></a> <a href="https://mas.to/tags/Lipids" class="mention hashtag" rel="nofollow noopener noreferrer" target="_blank">#<span>Lipids</span></a></p>
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