An Update on Gender Disparity in Critical Care Conferences.

This commentary's objective was to identify whether female representation at critical care conferences has improved since our previous publication in 2018. We audited the scientific programs from three international (International Symposium on Intensive Care and Emergency Medicine [ISICEM], European Society of Intensive Care Medicine [ESICM], and Society of Critical Care Medicine [SCCM]) and two national (State of the Art [SOA] and Critical Care Canada Forum) critical care conferences from the years 2017 to 2022. We collected data on the number of female faculty members and categorized them into physicians, nurses, allied health professions (AHPs), and other. Across all conferences, there was an increased representation of females as speakers and moderators over the 6 years. However, at each conference, male speakers outnumbered female speakers. Only two conferences achieved gender parity in speakers, SCCM in 2021 (48% female) and 2022 and SOA in 2022 (48% female). These conferences also had the highest representation of female nursing and AHP speakers (25% in SCCM, 2021; 19% in SOA, 2022). While there was a statistically significant increase in female speakers (p < 0.01) in 2022 compared with 2016, there was a persistent gender gap in the representation of men and female physicians. While the proportion of female moderators increased in each conference every year, the increase was statistically only significant for ISICEM, ESICM, and SCCM (p < 0.05). The proportion of female nurses and AHP speakers increased in 2022 compared with 2016 (p < 0.0001) but their overall representation was low with the highest proportion (25%) in the 2022 SCCM conference and the lowest (0.5%) in the 2017 ISICEM conference. This follow-up study demonstrates a narrowing but persisting gender gap in the studied critical care conferences. Thus, a commitment toward minimizing gender inequalities is warranted.

An inhibitor of oil body mobilization in Arabidopsis.

Fatty acid ß-oxidation is an essential process in many aspects of plant development, and storage oil in the form of triacylglycerol (TAG) is an important food source for humans and animals, for biofuel and for industrial feedstocks. In this study we characterize the effects of a small molecule, diphenyl methylphosphonate, on oil mobilization in Arabidopsis thaliana. Confocal laser scanning microscopy, transmission electron microscopy and quantitative lipid profiling were used to examine the effects of diphenyl methylphosphonate treatment on seedlings. Diphenyl methylphosphonate causes peroxisome clustering around oil bodies but does not affect morphology of other cellular organelles. We show that this molecule blocks the breakdown of pre-existing oil bodies resulting in retention of TAG and accumulation of acyl CoAs. The biochemical and phenotypic effects are consistent with a block in the early part of the ß-oxidation pathway. Diphenyl methylphosphonate appears to be a fairly specific inhibitor of TAG mobilization in plants and whilst further work is required to identify the molecular target of the compound it should prove a useful tool to interrogate and manipulate these pathways in a controlled and reproducible manner.

A small molecule with differential effects on the PTS1 and PTS2 peroxisome matrix import pathways.

The use of small molecules has great power to dissect biological processes. This study presents the identification and characterisation of an inhibitor of peroxisome matrix protein import. A mini-screen was carried out to identify molecules that cause alteration in peroxisome morphology, or mislocalization of a peroxisome targeted fluorescent reporter protein. A benzimidazole lead compound (LDS-003655) was identified that resulted in reduced GFP fluorescence in peroxisomes and cytosolic GFP accumulation. The effect of the compound was specific to peroxisomes as Golgi bodies, endoplasmic reticulum and the actin cytoskeleton were unaffected even at 25 µM, whereas peroxisome import via the PTS1 pathway was compromised at 100 nM. When seedlings were grown on 25 µM LDS-003655 they displayed morphology typical of seedlings grown in the presence of auxin, and expression of the auxin reporter DR5::GFP was induced. Analysis of a focussed library of LDS-003655 derivatives in comparison with known auxins led to the conclusion that the auxin-like activity of LDS-003655 is attributable to its in situ hydrolysis giving rise to 2,5-dichlorobenzoic acid, whereas the import inhibiting activity of LDS-003655 requires the whole molecule. None of the auxins tested had any effect on peroxisome protein import. Matrix import by the PTS2 import pathway was relatively insensitive to LDS-003655 and its active analogues, with effects only seen after prolonged incubation on high concentrations. Steady-state protein levels of PEX5, the PTS1 import pathway receptor, were reduced in the presence of 100 nM LDS-003655, suggesting a possible mechanism for the import inhibition.

Peroxisome biogenesis and positioning.

Plant peroxisomes are extremely dynamic, moving and undergoing changes of shape in response to metabolic and environmental signals. Matrix proteins are imported via one of two import pathways, depending on the targeting signal within the protein. Each pathway has a specific receptor but utilizes common membrane-bound translocation machinery. Current models invoke receptor recycling, which may involve cycles of ubiquitination. Some components of the import machinery may also play a role in proteolytic turnover of matrix proteins, prompting parallels with the endoplasmic-reticulum-associated degradation pathway. Peroxisome membrane proteins, some of which are imported post-translationally, others of which may traffic to peroxisomes via the endoplasmic reticulum, use distinct proteinaceous machinery. The isolation of mutants defective in peroxisome biogenesis has served to emphasize the important role of peroxisomes at all stages of the plant life cycle.

Shuttles and cycles: transport of proteins into the peroxisome matrix (review).

Peroxisomes are organelles that carry out diverse biochemical processes in eukaryotic cells, including the core pathways of beta-oxidation of lipid molecules and detoxification of reactive oxygen species. In multicellular organisms defects in peroxisome assembly result in multiple biochemical and developmental abnormalities. As peroxisomes do not contain genetic material, their protein content, and therefore function, is determined by the import of nuclearly encoded proteins from the cytosol and, presumably, removal of damaged or obsolete proteins. Import of matrix proteins can be broken down into four steps: targeting signal recognition by the cycling import receptors; receptor-cargo docking at the peroxisome membrane; translocation and cargo unloading; and receptor recycling. Import is mediated by a set of evolutionarily conserved proteins called peroxins that have been identified primarily via genetic screens, but knowledge of their biochemical activities remains largely unresolved. Recent studies have filled in some of the blanks regarding receptor recycling and the role of ubiquitination but outstanding questions remain concerning the nature of the translocon and its ability to accommodate folded, even oligomeric proteins, and the mechanism of cargo unloading and turnover of peroxisomal proteins. This review seeks to integrate recent findings from yeast, mammalian and plant systems to present an up to date account of how proteins enter the peroxisome matrix.

Arabidopsis PEX19 is a dimeric protein that binds the peroxin PEX10.

Peroxisomes are organelles found in all eukaryotic cells. Peroxisomes import integral membrane proteins post-translationally, and PEX19 is a predominantly cytosolic, farnesylated protein of mammalian and yeast cells that binds multiple peroxisome membrane proteins and is required for their correct targeting/insertion to the peroxisome membrane. We report the characterisation of the Arabidopsisthaliana homologue of PEX19 which is a predominantly cytosolic protein. AtPEX19 is encoded by two genes (designated AtPEX19-1 and AtPEX19-2) that are expressed in all tissues and at all developmental stages of the plant. Quantitative real time PCR shows that AtPEX19-1 and AtPEX19-2 have distinct expression profiles. Using in vitro translation and co-immunoprecipitation AtPEX19-1 was shown to bind to the Arabidopsis peroxisomal membrane protein PEX10. Additionally, bacterially expressed recombinant AtPEX19-1 was able to bind a fusion protein consisting of the C-terminus of PEX10 and glutathione S-transferase in pull-down assays, thereby demonstrating that non-farnesylated AtPEX19 can interact with the C-terminus of AtPEX10. Purified recombinant AtPEX19-1 was analysed by gel filtration chromatography and was found to have a molecular weight consistent with it forming a dimer and a dimer was detected in Arabidopsis cell extracts that was slightly destabilised in the presence of DTT. Moreover, cross-linking studies of native AtPEX19 suggest that in vivo it is the dimeric species of the protein that preferentially forms complexes with other proteins.

Peroxisome biogenesis and the role of protein import.

Peroxisomes are metabolic organelles with enzymatic content that are found in virtually all cells and are involved in beta-oxidation of fatty acids, hydrogen peroxide-based respiration and defence against oxidative stress. The steps of their biogenesis involves "peroxins", proteins encoded by PEX genes. Peroxins are involved in three key stages of peroxisome development: (1). import of peroxisomal membrane proteins; (2). import of peroxisomal matrix proteins and (3). peroxisome proliferation. Of these three areas, peroxisomal matrix-protein import is by far the best understood and accounts for most of the available published data on peroxisome biogenesis. Defects in peroxisome biogenesis result in peroxisome biogenesis disorders (PBDs), which although rare, have no known cure to-date. This review explores current understanding of each key area in peroxisome biogenesis, paying particular attention to the role of protein import.