In
a new study, published in Nature this week, a research team led from
Uppsala University in Sweden presents the discovery of a new microbe
that represents a missing link in the evolution of complex life. The
study provides a new understanding of how, billions of years ago, the
complex cell types that comprise plants, fungi, but also animals and
humans, evolved from simple microbes.
♦
Μελέτη, η οποία εκπονήθηκε από ερευνητική
ομάδα του Πανεπιστημίου της Ουψάλα στην Σουηδία και δημοσιεύθηκε αυτήν
την εβδομάδα στην επιστημονική επιθεώρηση Nature,
παρουσιάζει την ανακάλυψη νέου μικροβίου, το οποίο αντιπροσωπεύει
συνδετικό παράγοντα στην πολύπλοκη εξελικτική πορεία της ζωής.
Παρέχει
βαθύτερη κατανόηση του τρόπου με τον οποίον δισεκατομμύρια χρόνια πριν,
οι σύνθετοι τύποι κυττάρων που απαρτίζουν φυτά, μύκητες καθώς επίσης ζώα
και ανθρώπους, εξελίχθηκαν από απλά μικρόβια.
Η προέλευση των ευκαρυωτικών κυττάρων, παραμένει ένα από τα πλέον αμφιλεγόμενα ζητήματα στη σύγχρονη βιολογία. Πρόσφατες
μελέτες, παρέχουν υποστήριξη για την ανάδυση του ευκαρυωτικού
κυττάρου-ξενιστή, μέσα από τα πρώιμα στάδια της ζωής, αλλά η ταυτότητα
και η φύση του υποτιθέμενου προγονικού αρχαίου νουκλεοσώματος, παραμένει
θέμα συζήτησης. Στην παρούσα μελέτη περιγράφεται η ανακάλυψη του Lokiarchaeota,
ενός νέου υποψηφίου της συνομοταξίας αρχαιοϊστονών, ο οποίος συνιστά
μονοφυλετική ομάδα με τους ευκαρυώτες στις φυλογενετικές αναλύσεις και
των οποίων το γονιδίωμα, κωδικοποιεί ένα διευρυμένο φάσμα ευκαρυωτικών
πρωτεϊνών, ένδειξη εξελιγμένων ικανοτήτων αναδιαμόρφωσης της κυτταρικής
μεμβράνης. 
Τα αποτελέσματά μας, στηρίζουν σθεναρά την υπόθεση ότι, ο ευκαρυωτικός ξενιστής εξελίχθηκε από κάποιο δεκτικό
αρχαιοβακτήριο και καταδεικνύει ότι, πολλά στοιχεία που ενισχύουν τα
ειδικά χαρακτηριστικά του ευκαρυώτη, ήταν ήδη παρόντα στον πρόγονο αυτό.
Αυτά,
προίκησαν τον ξενιστή με πλούσιο γονιδιωματικό καταπίστευμα, ώστε να
υποστηριχθεί η αύξηση της κυτταρικής και γονιδιωματικής πολυπλοκότητός
του, κάτι που χαρακτηρίζει τα ευκαρυωτικά κύτταρα.__Π.Δ.Λιβάς (απόδοση της σύνοψης που παρέχεται από το Nature)
Evolution
News • Uppsala University in Sweden • May 07, 2015
by Linda Koffmar
The microbe was found at 2,352 metres depth in the Atlantic between Norway and Greenland. Photograph: R.B. Pedersen, Centre for Geobiology (University of Bergen, Norge)
Cells are the basic building blocks of
all life on our planet. Yet, whereas the cells of bacteria and other
microbes are small and simple, all visible life, including us humans, is
generally made up of large and complex cell types. The origin of these
complex cell types has long been a mystery to the scientific community,
but now researchers from Uppsala University in Sweden have discovered a
new group of microorganisms that represents a missing link in the
evolutionary transition from simple to complex cells.
In the 1970s, the acclaimed biologist
Carl Woese discovered a completely new group of microorganisms, the
Archaea, and showed that these represented a separate branch in the Tree
of Life – a finding that stunned the scientific community at the time.
Despite that archaeal cells were simple and small like bacteria,
researchers found that Archaea were more closely related to organisms
with complex cell types, a group collectively known as ‘eukaryotes’.
This observation has puzzled scientists for decades: How could the
complex cell types from eukaryotes have emerged from the simple cells of
Archaea?
In this weeks’ edition of Nature,
researchers from Uppsala University in Sweden, along with collaborators
from the universities in Bergen (Norway) and Vienna (Austria) report the
discovery of a new group of Archaea, the Lokiarchaeota (or ‘Loki’ for
short), and identify it to be a missing link in the origin of
eukaryotes.
“The puzzle of the origin of the
eukaryotic cell is extremely complicated, as many pieces are still
missing. We hoped that Loki would reveal a few more pieces of the
puzzle, but when we obtained the first results, we couldn’t believe our
eyes. The data simply looked spectacular”, says Thijs Ettema at the
Department of Cell and Molecular Biology, Uppsala University, who lead
the scientific team that carried out the study.
“By studying its genome, we found that
Loki represents an intermediate form in-between the simple cells of
microbes, and the complex cell types of eukaryotes”, says Thijs Ettema.
When Loki was placed in the Tree of Life, this idea was confirmed.
“Loki formed a well-supported group with
the eukaryotes in our analyses”, says Lionel Guy, one of the senior
scientists involved in the study from Uppsala University.
“In addition, we found that Loki shares
many genes uniquely with eukaryotes, suggesting that cellular complexity
emerged in an early stage in the evolution of eukaryotes”, says Anja
Spang, researcher at Department of Cell and Molecular Biology , Uppsala
University, and one of the lead-authors of the study.
The name Lokiarchaeota is derived from
the hostile environment close to where it was found, Loki’s Castle, a
hydrothermal vent system located on the Mid-Atlantic Ridge between
Greenland and Norway at a depth of 2,352 meters.
“Hydrothermal vents are volcanic systems
located at the ocean floor. The site where Loki is heavily influenced by
volcanic activity, but actually quite low in temperature”, says Steffen
Jørgensen from the University of Bergen in Norway, who was involved in
taking the samples where Loki was found.
“Extreme environments generally contain a
lot of unknown microorganisms, which we refer to as microbial dark
matter”, says Jimmy Saw, researcher at Department of Cell and Molecular
Biology, Uppsala University, and co-lead author of the paper.
By exploring microbial dark matter with
new genomics techniques, Thijs Ettema and his team hope to find more
clues about how complex cells evolved.
“In a way, we are just getting started.
There is still a lot out there to discover, and I am convinced that we
will be forced to revise our biology textbooks more often in the near
future”, says Thijs Ettema.
Provided by
Research paper
Complex archaea that bridge the gap between prokaryotes and eukaryotes – Nature(2015)doi:10.1038/nature14447
Further Information
MICROBIOLOGY AND MOLECULAR BIOLOGY REVIEWS,1092-2172/97/$04.0010
Dec. 1997, p. 456–502 Vol. 61, No. 4
Copyright © 1997, American Society for Microbiology
-Archaea and the Prokaryote-to-Eukaryote Transition
JAMES R. BROWN and W. FORD DOOLITTLE
Canadian Institute for Advanced
Research, Department of Biochemistry, Dalhousie University, Halifax,
Nova Scotia, Canada, and Department of Bioinformatics, SmithKline
Beecham Pharmaceuticals, Collegeville, Pennsylvania
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