Why the Lipid Divide? Membrane Proteins as Drivers of the Split between the Lipids of the Three Domains of Life

Sojo, Víctor

doi:10.1002/bies.201800251

Cited by 37 publications

(32 citation statements)

References 63 publications

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“…If there is no obvious penalty for mixing lipids, then why did the lipid divide occur? One possibility is that membrane proteins rather than lipids drove the divergence [61]. While appealing, this idea is undermined by the propensity of membrane proteins to evolve rapidly [62], which could compensate for subtle differences in lipid chemistry.…”

Section: Discussionmentioning

confidence: 99%

Isoprenoids enhance the stability of fatty acid membranes at the emergence of life potentially leading to an early lipid divide

2019

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Two key problems concern cell membranes during the emergence and early evolution of life: what was their initial composition, and why did the membranes of archaea and bacteria diverge? The composition of the first cell membranes could shed light on the most likely environment for the emergence of life. The opposing stereochemistry of modern lipid glycerol-phosphate headgroups in bacteria and archaea suggests that early membranes were composed of single chain amphiphiles, perhaps both fatty acids and isoprenoids. We investigated the effect of adding isoprenoids to fatty acid membranes using a combination of UV–visible spectroscopy, confocal microscopy and transmission electron microscopy. We tested the stability of these membranes across a pH range and under different concentrations of ionic species relevant to oceanic hydrothermal environments, including Na 2+ , Cl − , Mg 2+ , Ca 2+ , HC O 3 − , Fe 3+ , Fe 2+ and S 2− . We also tested the assembly of vesicles in the presence of Fe particles and FeS precipitates. We found that isoprenoids enhance the stability of membranes in the presence of salts but require 30-fold higher concentrations for membrane formation. Intriguingly, isoprenoids strongly inhibit the tendency of vesicles to aggregate together in the presence of either Fe particles or FeS precipitates. These striking physical differences in the stability and aggregation of protocells may have shaped the divergence of bacteria and archaea in early hydrothermal environments.

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Section: Discussionmentioning

confidence: 99%

Isoprenoids enhance the stability of fatty acid membranes at the emergence of life potentially leading to an early lipid divide

2019

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“…Fibrobacteres/Chlorobi/Bacteroidetes), a membrane typical of archaea (Villanueva et al 2018). However, phylogenetic analyses tend to suggest that the acquisition of specific pathways from one domain to another are better explained by lateral transference and natural selection once the archaeal membrane is known to be more stable in high temperatures (Coleman et al 2019, Sojo 2019.…”

Section: B) Ribosomes Genetic Code and The Translation Machinerymentioning

confidence: 99%

“…Since then, the search for characteristics of LUCA and explanations about how it originated have been guiding important works in the origin of life research program (Forterre et al 2005, Mat et al 2008, Gogarten and Deamer 2016, Martin et al 2016. Today, however, we know that the domain Eukarya evolved from a specific group of archaebacteria from the phylum Lokiarchaeota (subphylum Asgard) that was involved in symbiotic relationships with bacterial clades (Spang et al 2015, Spang et al 2019. Eukaryotes are therefore a derivate clade and were not involved in the constitution of LUCA.…”

Section: Introductionmentioning

confidence: 99%

Is it possible that cells have had more than one origin?

Farías

José²,

Prosdocimi

2021

Biosystems

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Cells occupy a prominent place in the history of life on planet Earth. The central role of cellular organization is observed by the fact that "cellular life" is often used as a synonym for life itself. Thus, most characteristics used to define cells overlap with the ones used to define life. Notwithstanding, new scenarios about the origin of life are bringing alternative views to describe how cells may have evolved from the open biological systems named progenotes. Here, using a logical and conceptual analysis, we re-evaluate the characteristics used to infer a single origin for cells. We argue that some evidences used to support cell monophyly, such as the presence of elements from both the translation mechanism and the universality of the genetic code, actually indicate a unique origin for all "biological systems", a term used to define not only cells, but also virus and progenotes. Besides, we present evidence that at least two biochemical pathways as important as (i) DNA replication and (ii) lipid biosynthesis may not homologous between Bacteria and Archaea. The identities observed between the proteins involved in those pathways along representatives of these two ancestral Domains are too low to indicate common genic ancestry. Altogether these facts can be seen as an indication that cellular organization has possibly evolved two or more times and that LUCA (the Last Universal Common Ancestor) might not have existed as a cellular entity. Thus, we aim to consider the possibility that different strategies acquired by biological systems to exist, such as viral, bacterial and archaeal were originated independently from the evolution of different progenote populations.

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“…Though archaeal and bacterial membranes are functional homologues, the chemical structure of their lipidic components reveals a split that is difficult to reconcile with a common origin, to the point that it has been proposed that the divide started from LUCA [1][2][3] and has been maintained until today. Archaea have sn-glycerol-1phosphate (G1P) phospholipids with ether-bond isoprenoid chains, while bacteria have sn-glycerol-3phosphate (G3P) esterified to fatty-acids.…”

Section: An Ester Phospholipid Membranementioning

confidence: 99%

“…Although there are pathways for synthesis of isoprenoids and fatty-acids in both domains [4], there are marked differences in their utilization of these biomolecules in membrane lipid synthesis. Recent research (see [3]) suggests that a transition could have taken place, during which the two sets of enzymatic machineries coexisted. Supporting this view, it is known that bacteria living in some extreme environments contain lipids with ether bonds in addition to the "normal" ester ones ( [5] and references therein).…”

Section: An Ester Phospholipid Membranementioning

confidence: 99%

The archaeal-bacterial lipid divide, could a distinct lateral proton route hold the answer?

Mencı́a

2020

Biol Direct

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The archaea-bacteria lipid divide is one of the big evolutionary enigmas concerning these two domains of life. In short, bacterial membranes are made of fatty-acid esters whereas archaeal ones contain isoprenoid ethers, though at present we do not have a good understanding on why they evolved differently. The lateral proton transfer mode of energy transduction in membranes posits that protons utilize the solvation layer of the membrane interface as the main route between proton pumps and ATPases, avoiding dissipation of energy to the bulk phase. In this article I present the hypothesis on a proton-transport route through the ester groups of bacterial phospholipids as an explanation for the evolutionary divergence seen between bacteria and archaea. Reviewers: This article was reviewed by Uri Gophna (Editorial Board member) and Víctor Sojo.

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Why the Lipid Divide? Membrane Proteins as Drivers of the Split between the Lipids of the Three Domains of Life

Cited by 37 publications

References 63 publications

Isoprenoids enhance the stability of fatty acid membranes at the emergence of life potentially leading to an early lipid divide

Isoprenoids enhance the stability of fatty acid membranes at the emergence of life potentially leading to an early lipid divide

Is it possible that cells have had more than one origin?

The archaeal-bacterial lipid divide, could a distinct lateral proton route hold the answer?

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