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  1. Alternating terminal electron-acceptors at the basis of symbiogenesis: How oxygen ignited eukaryotic evolution.Dave Speijer - 2017 - Bioessays 39 (2):1600174.
    What kind of symbiosis between archaeon and bacterium gave rise to their eventual merger at the origin of the eukaryotes? I hypothesize that conditions favouring bacterial uptake were based on exchange of intermediate carbohydrate metabolites required by recurring changes in availability and use of the two different terminal electron chain acceptors, the bacterial one being oxygen. Oxygen won, and definitive loss of the archaeal membrane potential allowed permanent establishment of the bacterial partner as the proto‐mitochondrion, further metabolic integration and highly (...)
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  • Debating Eukaryogenesis—Part 1: Does Eukaryogenesis Presuppose Symbiosis Before Uptake?Dave Speijer - 2020 - Bioessays 42 (4):1900157.
    Eukaryotic origins are heavily debated. The author as well as others have proposed that they are inextricably linked with the arrival of a pre‐mitochondrion of alphaproteobacterial‐like ancestry, in a so‐called symbiogenic scenario. The ensuing mutual adaptation of archaeal host and endosymbiont seems to have been a defining influence during the processes leading to the last eukaryotic common ancestor. An unresolved question in this scenario deals with the means by which the bacterium ends up inside. Older hypotheses revolve around the application (...)
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  • Can All Major ROS Forming Sites of the Respiratory Chain Be Activated By High FADH 2 /NADH Ratios?Dave Speijer - 2019 - Bioessays 41 (1):1800180.
    Aspects of peroxisome evolution, uncoupling, carnitine shuttles, supercomplex formation, and missing neuronal fatty acid oxidation (FAO) are linked to reactive oxygen species (ROS) formation in respiratory chains. Oxidation of substrates with high FADH2/NADH (F/N) ratios (e.g., FAs) initiate ROS formation in Complex I due to insufficient availability of its electron acceptor (Q) and reverse electron transport from QH2, e.g., during FAO or glycerol‐3‐phosphate shuttle use. Here it is proposed that the Q‐cycle of Complex III contributes to enhanced ROS formation going (...)
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  • How mitochondrial cristae illuminate the important role of oxygen during eukaryogenesis.Dave Speijer - 2024 - Bioessays 46 (5):2300193.
    Inner membranes of mitochondria are extensively folded, forming cristae. The observed overall correlation between efficient eukaryotic ATP generation and the area of internal mitochondrial inner membranes both in unicellular organisms and metazoan tissues seems to explain why they evolved. However, the crucial use of molecular oxygen (O2) as final acceptor of the electron transport chain is still not sufficiently appreciated. O2 was an essential prerequisite for cristae development during early eukaryogenesis and could be the factor allowing cristae retention upon loss (...)
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  • Molecular characteristics of the multi‐functional FAO enzyme ACAD9 illustrate the importance of FADH 2 /NADH ratios for mitochondrial ROS formation. [REVIEW]Dave Speijer - 2022 - Bioessays 44 (8):2200056.
    A decade ago I postulated that ROS formation in mitochondria was influenced by different FADH2/NADH (F/N) ratios of catabolic substrates. Thus, fatty acid oxidation (FAO) would give higher ROS formation than glucose oxidation. Both the emergence of peroxisomes and neurons not using FAO, could be explained thus. ROS formation in NADH:ubiquinone oxidoreductase (Complex I) comes about by reverse electron transport (RET) due to high QH2 levels, and scarcity of its electron‐acceptor (Q) during FAO. The then new, unexpected, finding of an (...)
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  • Evolution of peroxisomes illustrates symbiogenesis.Dave Speijer - 2017 - Bioessays 39 (9):1700050.
    Recently, the group of McBride reported a stunning observation regarding peroxisome biogenesis: newly born peroxisomes are hybrids of mitochondrial and ER-derived pre-peroxisomes. What was stunning? Studies performed with the yeast Saccharomyces cerevisiae had convincingly shown that peroxisomes are ER-derived, without indications for mitochondrial involvement. However, the recent finding using fibroblasts dovetails nicely with a mechanism inferred to be driving the eukaryotic invention of peroxisomes: reduction of mitochondrial reactive oxygen species generation associated with fatty acid oxidation. This not only explains the (...)
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  • Birth of the eukaryotes by a set of reactive innovations: New insights force us to relinquish gradual models.Dave Speijer - 2015 - Bioessays 37 (12):1268-1276.
    Of two contending models for eukaryotic evolution the “archezoan“ has an amitochondriate eukaryote take up an endosymbiont, while “symbiogenesis“ states that an Archaeon became a eukaryote as the result of this uptake. If so, organelle formation resulting from new engulfments is simplified by the primordial symbiogenesis, and less informative regarding the bacterium‐to‐mitochondrion conversion. Gradualist archezoan visions still permeate evolutionary thinking, but are much less likely than symbiogenesis. Genuine amitochondriate eukaryotes have never been found and rapid, explosive adaptive periods characteristic of (...)
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  • Unmiraculous? Yes. Ancient? Probably not.Dave Speijer - 2017 - Bioessays 39 (6):1700048.
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  • Peroxisomes: A small step from mitochondria but a giant leap for eukaryotes.Andrew Moore - 2015 - Bioessays 37 (2):113-113.
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  • Unmiraculous facultative anaerobes.William F. Martin - 2017 - Bioessays 39 (6):1700041.
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  • Mitochondrial uncoupling proteins regulate angiotensin‐converting enzyme expression: crosstalk between cellular and endocrine metabolic regulators suggested by RNA interference and genetic studies.Sukhbir S. Dhamrait, Cecilia Maubaret, Ulrik Pedersen-Bjergaard, David J. Brull, Peter Gohlke, John R. Payne, Michael World, Birger Thorsteinsson, Steve E. Humphries & Hugh E. Montgomery - 2016 - Bioessays 38 (S1):107-118.
    Uncoupling proteins (UCPs) regulate mitochondrial function, and thus cellular metabolism. Angiotensin‐converting enzyme (ACE) is the central component of endocrine and local tissue renin–angiotensin systems (RAS), which also regulate diverse aspects of whole‐body metabolism and mitochondrial function (partly through altering mitochondrial UCP expression). We show that ACE expression also appears to be regulated by mitochondrial UCPs. In genetic analysis of two unrelated populations (healthy young UK men and Scandinavian diabetic patients) serum ACE (sACE) activity was significantly higher amongst UCP3‐55C (rather than (...)
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  • The evolution of eukaryotic cells from the perspective of peroxisomes.Kathrin Bolte, Stefan A. Rensing & Uwe-G. Maier - 2015 - Bioessays 37 (2):195-203.
    Beta‐oxidation of fatty acids and detoxification of reactive oxygen species are generally accepted as being fundamental functions of peroxisomes. Additionally, these pathways might have been the driving force favoring the selection of this compartment during eukaryotic evolution. Here we performed phylogenetic analyses of enzymes involved in beta‐oxidation of fatty acids in Bacteria, Eukaryota, and Archaea. These imply an alpha‐proteobacterial origin for three out of four enzymes. By integrating the enzymes' history into the contrasting models on the origin of eukaryotic cells, (...)
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