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A Molecular Identity Crisis - a "Ribozyme
Without RNA"
Not all enzymes that are assumed to require an RNA component in order
to function do actually contain RNA. This surprising discovery was made
during a project supported by the Austrian Science Fund FWF that focussed
on the enzyme RNase P. Contrary to accepted scientific theory, the project
team from Vienna has long believed that certain forms of RNase P do not
contain any RNA. They have now succeeded in proving their point through
a series of sophisticated experiments, the results of which are being
published today in the journal CELL.
Although ribozymes are not quite living fossils, these enzymes - which
function only in the presence of RNA - hail from a long gone age when
biochemical processes were still controlled by RNA molecules. It was only
later that proteins came onto the molecular scene. RNase P, an enzyme
that modifies transfer RNAs, is one such RNA enzyme (ribozyme). All previously
characterised forms of this enzyme confirmed assumptions about their RNA
component. Nevertheless, evidence has also been uncovered over the past
20 years that has cast doubt on the universality of this finding and indicated
that this enzyme could be made up solely of proteins. The experts certainly
had plenty to debate.
RNA Not Always Essential
But the debate seems to have been brought to an end. A group headed by
Prof. Walter Rossmanith at the Medical University of Vienna has provided
conclusive evidence by successfully identifying the components of human
mitochondrial RNase P. Prof. Rossmanith: "RNase P is made up of three
proteins that are solely responsible for the catalytic capacity of the
enzyme without any RNA. This discovery has not been made before because
the enzyme breaks down easily during purification due to the loose connection
between its components. The approach we developed enabled us to get around
this problem. That was the breakthrough that enabled us to identify the
proteins." Johann Holzmann, a PhD student and member of Prof. Rossmanith's
team, explains further: "The most difficult task was to track down
the proteins. Everything started to move much faster once we had done
that. We produced the individual proteins separately in bacteria, purified
them and then used them to reconstitute mitochondrial RNase P in vitro.
This finally removed any shadow of doubt for us - and CELL: mitochondrial
RNase P does not contain RNA."
Reinventing the Wheel
The identification of the three proteins also resolved another previously
unanswered question in molecular evolution research: How is a ribozyme
replaced by a protein enzyme? The answer provided by data collected during
the project is that the protein-only mitochondrial RNase P developed in
parallel to a pre-existing ribozyme. Eventually, it replaced the latter.
It is interesting to note that the three protein components have been
recruited from entirely different biochemical pathways and yet they have
nevertheless retained their original functions. Prof. Rossmanith adds:
"We are also calling mitochondrial RNase P a patchwork enzyme, because
it seems to be assembled from components available by chance at the time
of its appearance in evolution." It is still unclear why only animal
mitochondrial RNase P and not all ribozymes have been replaced by protein
enzymes. Indeed, the results of this successful FWF project have opened
the door to a whole range of questions - and answers.
Original publication: "RNase P without
RNA: Identification and functional reconstitution of the human mitochondrial
tRNA processing enzyme" J. Holzmann, P. Frank, E. Löffler, K.
Bennett, C. Gerner & W. Rossmanith. Cell 135, 462-474, October 31,
2008, DOI 10.1016/j.cell.2008.09.013
Scientific Contact
Walter Rossmanith, PhD
Medical University of Vienna
Center for Anatomy & Cell Biology
Währingerstr. 13
1090 Vienna
Austria
M 0664 / 800 16 37 512
E walter.rossmanith@meduniwien.ac.at
Austrian Science Fund FWF
Stefan Bernhardt
Haus der Forschung
Sensengasse 1
1090 Vienna
Austria
T +43 / 1 / 505 67 40 - 8111
E stefan.bernhardt@fwf.ac.at
Copy Editing & Distribution
PR&D - Public Relations for Research & Education
Campus Vienna Biocenter 2
1030 Vienna
Austria
T +43 / 1 / 505 70 44
E contact@prd.at
W www.prd.at
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