Asgard archaea (previously known as Phylum "Asgard" or phylum "Asgardarchaeota"
After including the kingdom category into ICNP, the only validly published name of this group is kingdom Promethearchaeati. All formerly proposed "phyla" would be de-ranked to classes in this framework.
Discovery and nomenclature
In the summer of 2010, sediments were analysed from a gravity
Core sample taken in the rift valley on the Knipovich ridge in the Arctic Ocean, near the Loki's Castle hydrothermal vent site. Specific sediment horizons previously shown to contain high abundances of novel archaeal lineages were subjected to
Metagenomics.
In 2015, an Uppsala University-led team proposed the "
Promethearchaeia" phylum based on
phylogenetic analyses using a set of highly conserved protein-coding genes.
The group was named for the shape-shifting Norse god
Loki, in an allusion to the hydrothermal vent complex from which the first genome sample originated.
The Loki of mythology has been described as "a staggeringly complex, confusing, and ambivalent figure who has been the catalyst of countless unresolved scholarly controversies",
analogous to the role of "Lokiarchaeota" in the debates about the origin of eukaryotes.
In 2016, a University of Texas-led team discovered "Thorarchaeia" from samples taken from the White Oak River in North Carolina, named in reference to Thor, another Norse god.
Description
Proteins
Asgard archaea encode many eukaryotic signature proteins, including novel GTPases, membrane-remodelling proteins like
ESCRT and SNF7, a
ubiquitin modifier system, and
N-glycosylation pathway homologs.
Asgard archaea have a regulated actin cytoskeleton, and the and they use can interact with eukaryotic actins.
Metabolism
File:Asgard_archaea_Phyla_(cropped).png|Metabolic pathways of Asgard archaea, varying by phylaAsgard archaea are generally obligate anaerobes, though "Kariarchaeaceae", "Gerdarchaeales" and "Hodarchaeales" may be facultative aerobes.
They have a Wood–Ljungdahl pathway and perform
glycolysis. Members can be
,
, or
using
heliorhodopsin.
One member,
Promethearchaeum, is
Syntrophy with a sulfur-reducing
Pseudomonadota and a
methanogenic archaea.
The RuBisCO they have is not carbon-fixing, but likely used for nucleoside salvaging.
Ecology
Asgard archaea are widely distributed around the world, both geographically and by habitat. Many of the known clades are restricted to sediments, whereas Promethearchaeia, "Thorarchaeia" and another clade occupy many different habitats. Salinity and depth are important ecological drivers for most Asgard archaea. Other habitats include the bodies of animals, the rhizosphere of plants, non-saline sediments and soils, the sea surface, and freshwater. In addition, Asgard archaea are associated with several other microorganisms.
Eukaryote-like features in subdivisions
The class "Heimdallarchaeia" was found in 2017 to have N-terminal core
Histone code, a feature previously thought to be exclusively eukaryotic. Two other archaeal phyla, both non-Asgard archaea, were found to also have tails in 2018.
In January 2020, scientists found Promethearchaeum syntrophicum, a member of the Promethearchaeia, engaging in cross-feeding with two bacterial species. Drawing an analogy to symbiogenesis, they consider this relationship a possible link between the simple prokaryotic microorganisms and the complex eukaryotic microorganisms occurring approximately two billion years ago.
Phylogeny
The phylogenetic relationships of the Asgard archaea have been studied by several teams in the 21st century.
Varying results have been obtained, for instance using 53 marker proteins from the Genome Taxonomy Database.
In 2023, Eme, Tamarit, Caceres and colleagues reported that the Eukaryota
are deep within Asgard archaea, as sister of "Hodarchaeales" within the "Heimdallarchaeia".
Njordarchaea has recently been suggested as the closest branch to eukaryotes, but this result is debated.
Taxonomy
In the depicted scenario, the Eukaryota are deep in the Asgard archaeal tree. A favored scenario is syntrophy, where one organism depends on the feeding of the other. An α-proteobacterium was incorporated to become the
mitochondrion.
In culture, extant Asgard archaea form various syntrophic dependencies.
Gregory Fournier and Anthony Poole have proposed that Asgard archaea is part of "the Eukaryote tree", forming a
taxon they call "Eukaryomorpha" defined by "shared derived characters" (eukaryote signature proteins).
The kingdom contains one phylum, Promethearchaeota.
Genomic elements
Viruses
Several family-level groups of
associated with Asgard archaea have been discovered using metagenomics.
The viruses were assigned to Promethearchaeia, "Thorarchaeia", "Odinarchaeia" and "Helarchaeia" hosts using CRISPR spacer matching to the corresponding protospacers within the viral genomes. Two groups of viruses (called 'verdandiviruses') are related to archaeal and bacterial viruses of the class
Caudoviricetes, i.e., viruses with icosahedral capsids and helical tails;
two other distinct groups (called 'skuldviruses') are distantly related to tailless archaeal and bacterial viruses with icosahedral capsids of the realm
Varidnaviria;
and the third group of viruses (called
wyrdviruses) is related to archaea-specific viruses with lemon-shaped virus particles (family
Halspiviridae).
The viruses have been identified in deep-sea sediments
and a terrestrial hot spring of the Yellowstone National Park.
All these viruses display very low sequence similarity to other known viruses but are generally related to the previously described prokaryotic viruses,
with no meaningful affinity to viruses of eukaryotes.
Mobile genetic elements
In addition to viruses, several groups of cryptic mobile genetic elements have been discovered through
CRISPR spacer matching to be associated with Asgard archaea of the Promethearchaeia, "Thorarchaeia" and "Heimdallarchaeia" lineages.
These mobile elements do not encode recognizable viral hallmark proteins and could represent either novel types of viruses or plasmids.
See also
External links
