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  2. Nov 2024
    1. accumulation of all of that movement of charge is contributing to that electrical phenomenon and therefore in the end what you're doing is talking about a higher level of causation U than the components of the cell

      for - evolutionary biology - Denis Noble - journey from reductionist to non-reductionist - ion channel and cell membrane work - connects to bioelectricity in the entire body

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    1. Review coordinated by Life Science Editors.

      Reviewed by: Dr. Helen Pickersgill, Life Science Editors

      Potential Conflicts of Interest: None

      Main point of the paper: By combining multiple stains and antibodies with ultrastructural expansion (light) microscopy in Plasmodium falciparum during the course of mitosis within red blood cells (the asexual blood stage), when it causes the symptoms of malaria, the authors identified new structural features of cell division in this important human parasite.

      Why this is interesting: Imaging the dramatic physical events that occur when cells divide tells us a lot about the biology of the process and is insightful to compare between different eukaryotes, but many organisms are too small to visualise by light microscopy, which is the most versatile imaging technique. So, they used an existing preparation technique to enlarge the parasites, a wide array of dyes and antibodies, and sampled at multiple timepoints so that more intracellular structures could be visualised and their behaviour and potential functions in cell division revealed.

      Background: Expansion microscopy (ExM) has been around since 2015 (doi: 10.1126/science.1260088) and is a fairly simple and affordable technique. It involves physically magnifying a specimen by embedding it in a polyelectrolyte gel that swells up in water enabling super-resolution imaging. It has been previously applied to Plasmodium and other Apicomplexa, but not with so many different labels across different timepoints at this important life-stage.

      Results: • They imaged 13 subcellular structures (including microtubules, microtubule organising centres, apicoplasts, Golgi and the ER) at multiple timepoints covering the entire asexual blood stage. • Among many results were the following: • They found a central role for the nuclear MTOC in coordinating mitosis and likely in establishing apical-basal polarity early during the asexual cycle. o the MTOC is tethered to the parasite plasma membrane (via cytoplasmic extensions) throughout mitosis. o the cytoplasmic extensions of the MTOC were closely associated (in numbers and positions) with several apical structures including the Golgi and the basal complex. o the MTOC is tethered to the mitochondria and apicoplast during fission and may also regulate their copy numbers. • They performed the first detailed characterization of the short-lived interpolar spindles, previously difficult to visualize, which consist of microtubules connecting duplicated MTOCs as they move to opposite sides of the cell. They found a large variation in their size, which may be how they enable the MTOCs to move without detaching from the plasma membrane. • They were able to study the biogenesis of rhoptries, which secrete proteins required for the parasite to invade host red blood cells, and discovered that: o biogenesis begins earlier than thought and that they associate with MTOCs during the remaining rounds of mitosis. o Rhoptry pairs are likely synthesized independently because over 95% are different sizes and densities.

      Remaining thoughts: • Clearly written and easy to read paper with stunning images. • Comprehensive (including descriptions of when things didn’t work), but remains largely descriptive (of course). • Could be shortened/sharpened to make it more manageable to read without losing the main messages, which are somewhat lost in the text. • A top-level, specialised paper that opens the door for more targeted studies of organelle functions during mitosis and comparisons of these functions with other (higher) eukaryotes. • By identifying key players in mitosis during the asexual blood stage it may reveal candidate therapeutic targets for treating malaria.

  21. Feb 2023
    1. Review coordinated by Life Science Editors

      Reviewed by: Dr. Helen Pickersgill, Life Science Editors

      Potential Conflicts of Interest: None

      Impact Point: Transcription factors may mediate the release of specific genes in extracellular vesicles that could be taken up by other cells and directly influence their behaviour.

      Background: Extracellular vesicles (EVs) are nanoscale, membrane-bound vesicles containing proteins, nucleic acids and lipids that are released by most cell types. Originally thought of as a cell waste disposal mechanism, they have since been rebranded as a means of intercellular communication, both short and long range, (like a cellular postal service), and can, for example, modify gene expression and function in recipient cells via the transfer of specific RNAs (DOI: 10.1038/s41580-020-0251-y). One interesting function for EVs was the recent discovery that antigen presenting cells (APCs) could donate telomeres via EVs to recipient T cells and rescue them from senescence (DOI: 10.1038/s41556-022-00991-z).

      Given EVs contain a wide variety of cargos derived from the secreting cells, which have been extensively profiled (e.g., DOI: 10.1016/j.cell.2020.07.009) they are particularly interesting as sources of biomarkers for diagnosing diseases such as cancer (e.g., DOI: 10.1038/s12276-019-0219-1). We might also be able to use them as stable delivery mechanisms for controlling cell behaviour or targeting therapeutics/diagnostics.

      We know quite a bit about how RNAs and proteins are selected for secretion by EVs (mediated by the autophagy protein LC3: e.g., DOIs: 10.1080/15548627.2020.1756557; 10.1038/s41556-019-0450-y). But little is known about DNA. DNA presents a particular challenge as it is packed up into the nucleus. This is also particularly important to understand in the context of horizontal gene transfer, i.e., passing functional genes between cells.

      Main question: How does a cell ‘select’ specific DNA cargo from the nucleus and enable it to be released by EVs?

      The advance: They discover that a transcription factor (FOXM1) plays a central role in mediating DNA release in EVs.

      Results: • FOXM1 and LC3 (autophagy protein) colocalize and interact in cultured cells (coIP endogenous and exogenous, EMSA, immunostaining and identify an FOXM1-binding domain mutant). • FOXM1, LC3 and DNA colocalise in the cytoplasm in cultured cells, which increases upon starvation-induced autophagy (immunofluorescence). • FOXM1 and LC3 are found in EVs released from cultured cells (Western blot). • 15,544 DNA identified in EVs released from cultured cells (evDNA sequencing), of which 25 overlapped with DNA loci binding FOXM1 (ChIP). • FOXM1-bound nuclear DNA is transported to the cytoplasm upon induction of autophagy and is released in EVs in cultured cells (knock-in tagged chromatin with CRISPR-cas9, IF and PCR). This is dependent on FOXM1 (knock-out in cultured cells).

      Significance: Transcription factors display strong DNA binding specificity and so are ideal candidates for directing specific genes into EVs for potential transfer to recipient cells.

      Remaining questions/points: Care needs to be taken with regard to purification of EVs. Are the FOXM1-DNAs in the EVs functional in recipient cells? Is the DNA being actively ‘selected’ for an intercellular signalling purpose or is this just random degradation? Is it all FOXM1 bound DNA that has the potential to be trafficked to EVs or just a subset? Do other transcription factors have the same function or is it specific to this protein/family? Does this mechanism occur in other contexts (e.g., in vivo, under disease conditions).

    1. Review coordinated by Life Science Editors.

      Reviewed by: Dr. Angela Andersen, Life Science Editors

      Potential Conflicts of Interest: Dr. Mill has worked with Life Science Editors on other manuscripts.

      Background: Retinitis pigmentosa (RP) is a group of rare eye diseases that cause vision loss. Symptoms usually start in childhood, and most people eventually lose most of their sight. There is no cure for RP. Mutations in retinitis pigmentosa GTPase regulator (RPGR) cause RP and compromise the renewal of light-sensitive “disc” membranes (specialized cilia) at the outer segment of photoreceptors, resulting in the loss of these cells over time. Evidence suggests that disc formation is similar to the release of ectosomes (small extracellular vesicles) and that both rely on the actin cytoskeleton. Knockdown of RPGR in retinal pigmented epithelium cells showed stronger actin filaments and reduced cilia suggesting that it may regulate nascent photoreceptor disc formation by regulating actin-mediated membrane extension in the retina (Gakovic et al., Human Molecular Genetics, 2011). In addition, RPGR patient iPSC-retinal models displayed phenotypes consistent with abnormal actin regulation (Megaw et al., Nature Communications, 2017; Karam et al., J Personalized Medicine, 2022).

      Question: What function of RPGR is compromised in photoreceptors to cause RP?

      Advance: The authors generated novel Rpgr mutant mice harboring human disease-causing mutations that recapitulate human disease phenotypes: aborted membrane shedding as ectosome-like vesicles, photoreceptor death and visual loss. RPGR is located at the site of disc formation – to test if it plays a role in disc genesis, they engineered a novel reporter mouse to track outer segment turnover. Rhodopsin was tagged with the self-labelling peptide SNAP- Rhodopsin is the major protein component of outer segment discs, and so incubating RhodSNAP retinal slice cultures with SNAP fluorophores results in outer segment labelling. Perturbation of RPGR resulted in a slowed rate of disc formation, leading to shortened outer segments and increased vesicle shedding. To me, the breakthrough is in the last figure: the actin depolymerizing drug Cytochalasin D in PBS was injected intravitreally, and fixed retinas were analyzed 6 hours later by electron microscopy. Cytochalasin D treatment significantly reduced the number of shed vesicles from the base of the outer segment in Rpgr-mutant mice (they now look like wild-type).

      Significance: Nails down the disease-relevant function of RPGR and a molecular mechanism of RP in photoreceptor cells, in vivo, in mice. Pharmacological rescue not only demonstrates the importance of the mechanism to disease but also sheds light on a potential therapeutic avenue for RP.

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