Researchers find that the earliest bacteria had the tools to perform a crucial step in photosynthesis
By Hayley Dunning, Imperial College London
The finding also challenges expectations
for how life might have evolved on other planets. The evolution of
photosynthesis that produces oxygen is thought to be the key factor in the
eventual emergence of complex life. This was thought to take several billion
years to evolve, but if in fact the earliest life could do it, then other
planets may have evolved complex life much earlier than previously thought.
The research team, led by scientists
from Imperial College London, traced the evolution of key proteins needed for
photosynthesis back to possibly the origin of bacterial life on Earth. Their
results are published and freely accessible in BBA – Bioenergetics.
Lead researcher Dr Tanai Cardona, from
the Department of Life Sciences at Imperial, said: “We had previously shown
that the biological system for performing oxygen-production, known as
Photosystem II, was extremely old, but until now we hadn’t been able to place
it on the timeline of life’s history.
"Now, we know that Photosystem II
shows patterns of evolution that are usually only attributed to the oldest
known enzymes, which were crucial for life itself to evolve.”
Early oxygen production
Photosynthesis, which converts sunlight
into energy, can come in two forms: one that produces oxygen, and one that
doesn’t. The oxygen-producing form is usually assumed to have evolved later,
particularly with the emergence of cyanobacteria, or blue-green algae, around 2.5
billion years ago.
While some research has suggested
pockets of oxygen-producing (oxygenic) photosynthesis may have been around
before this, it was still considered to be an innovation that took at least a
couple of billion years to evolve on Earth.
The new research finds that enzymes
capable of performing the key process in oxygenic photosynthesis – splitting
water into hydrogen and oxygen – could actually have been present in some of
the earliest bacteria. The earliest evidence for life on Earth is over 3.4
billion years old and some studies have suggested that the earliest life could
well be older than 4.0 billion years old.
Like the evolution of the eye, the first
version of oxygenic photosynthesis may have been very simple and inefficient;
as the earliest eyes sensed only light, the earliest photosynthesis may have
been very inefficient and slow.
On Earth, it took more than a billion
years for bacteria to perfect the process leading to the evolution of
cyanobacteria, and two billion years more for animals and plants to conquer the
land. However, that oxygen production was present at all so early on means in
other environments, such as on other planets, the transition to complex life
could have taken much less time.
Measuring molecular clocks
The team made their discovery by tracing
the ‘molecular clock’ of key photosynthesis proteins responsible for splitting
water. This method estimates the rate of evolution of proteins by looking at
the time between known evolutionary moments, such as the emergence of different
groups of cyanobacteria or land plants, which carry a version of these proteins
today. The calculated rate of evolution is then extended back in time, to see
when the proteins first evolved.
They compared the evolution rate of
these photosynthesis proteins to that of other key proteins in the evolution of
life, including those that form energy storage molecules in the body and those
that translate DNA sequences into RNA, which is thought to have originated
before the ancestor of all cellular life on Earth. They also compared the rate
to events known to have occurred more recently, when life was already varied
and cyanobacteria had appeared.
The photosynthesis proteins showed
nearly identical patterns of evolution to the oldest enzymes, stretching far
back in time, suggesting they evolved in a similar way.
First author of the study Thomas Oliver,
from the Department of Life Sciences at Imperial, said: “We used a technique
called Ancestral Sequence Reconstruction to predict the protein sequences of ancestral
photosynthetic proteins.
"These sequences give us
information about how the ancestral Photosystem II would have worked and we
were able to show that many of the key components required for oxygen evolution
in Photosystem II can be traced to the earliest stages in the evolution of the
enzyme.”
Directing evolution
Knowing how these key photosynthesis
proteins evolve is not only relevant for the search for life on other planets,
but could also help researchers find strategies to use photosynthesis in new
ways through synthetic biology.
Dr Cardona, who is leading such a
project as part of his UKRI Future Leaders Fellowship, said: “Now we have a good
sense of how photosynthesis proteins evolve, adapting to a changing world, we
can use ‘directed evolution’ to learn how to change them to produce new kinds
of chemistry.
"We could develop photosystems that
could carry out complex new green and sustainable chemical reactions entirely
powered by light.”
https://www.imperial.ac.uk/news/217553/photosynthesis-could-life-itself/
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