Difference between revisions of "Template:Heidelberg/pages/overview/ribozymes"
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− | + | Figure 1. Hammerhead Ribozyme | |
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− | + | The secondary structure of a Hammerhead Ribozyme (HHR). Arrow indicates position of cleavage between third and first stem. First and second stem are stem loops while stem three is open. | |
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− | In 1982 the first catalytic RNA (Ribozyme): a self-spicing intron from <i>Tetrahymena</i> pre-rRNA was described.<x-ref> | + | In 1982 the first catalytic RNA (Ribozyme): a self-spicing intron from <i>Tetrahymena</i> pre-rRNA was described.<x-ref>Cech1981</x-ref><x-ref>Kruger1982</x-ref> Shortly after the discovery of these self-spicing introns further ribozymes were identified in different organisms. Amongst which the hammerhead ribozyme (HHR) is a very prominent example (Fig.1) that has been employed by many laboratories since its discovery in 1986.<x-ref>Prody1986</x-ref><x-ref>Forster1987</x-ref> This ribozyme has the capability of self-cleavage. A HHR consists of three stems of which one is open. The complementary region of this open stem can be designed so that the HHR cleaves off a customized sequence without leaving a scar<x-ref>Meyer2014</x-ref>. (Click for design guide) This makes it a valuable tool in the work with functional RNA as it leaves defined 5’- or 3’-ends after cleavage that are essential for some applications.<x-ref>Balke2014</x-ref> |
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Another ribozyme that is related to the HHR is the hepatitis δ virus ribozyme (HDV).<x-ref>Sharmeen1988</x-ref> In contrast to the HHR it cleaves itself off a RNA at a specific position without a recognition site and without leaving a scar. This advantage of being independent from an upstream sequence makes it widely applicable and thus is used in our new BBF RFC 110 that aims to simplify and standardize the use of functional RNA. | Another ribozyme that is related to the HHR is the hepatitis δ virus ribozyme (HDV).<x-ref>Sharmeen1988</x-ref> In contrast to the HHR it cleaves itself off a RNA at a specific position without a recognition site and without leaving a scar. This advantage of being independent from an upstream sequence makes it widely applicable and thus is used in our new BBF RFC 110 that aims to simplify and standardize the use of functional RNA. | ||
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− | + | Figure 2. Hairpin Ribozyme | |
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− | + | Naturally occurring Hairpin Ribozyme with cleavage site indicated by arrow. | |
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+ | Both of the mentioned types of ribozymes are found in satellite RNA of plant origin<x-ref>Serganov2007</x-ref> as does the so called hairpin ribozyme (Fig. 2). It is a ribozyme capable of cleaving and ligating a RNA complementary to itself.<x-ref>Buzayan1986</x-ref> While researchers were looking for naturally occurring ribozymes, they developed methods to <i>in vitro</i> evolve the function of existing ribozymes and to discover new ones from random pools.<x-ref>Beaudry1992</x-ref> This way scientists were able to establish catalytic systems with new function. For example Joyce developed a self-replicating system consisting of two hairpin-ribozyme-derived parts that replicate each other.<x-ref>Lam2009</x-ref><x-ref>Lincoln2009</x-ref></p> | ||
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+ | <p class="basictext">Our idea of working with functional nucleic acids originated from this system. We were fascinated by the vast variety of processes that they can perform and started digging deeper into the potential of nucleic acids as tools. During this process we came across interesting systems amongst which we found the twin ribozyme (Fig. 3). Another famous hairpin-ribozyme-derived functional nucleic acid developed by Müller.<x-ref>Schmidt2000</x-ref> It is able to specifically cleave a RNA at two designed specific positions and afterwards re-ligate it. Balke <x-ref>Balke2014</x-ref> applied the twin ribozyme as tool to edit mRNA <i>in vitro</i>.<x-ref>Balke2014</x-ref> In our project we want to use this system to specifically repair the mutation in a mRNA leading to the malfunction of a protein. The function of the protein is restored by inserting the missing bases and thus the patients symptoms disappear. | ||
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− | + | Next to the directed evolution of existing ribozymes <i>in vitro</i> selection methods<x-ref>Bartel1993</x-ref> were developed to select nucleic acids with new catalytic activities from a random pool. Catalytic RNA of versatile functions arose from these methods. For instance Seelig and Jäschke selected a diels alderase ribozyme catalyzing the Diels-Alder reaction leading to the formation of a carbon-carbon bond.<x-ref>Seelig1999</x-ref> Not only can <i>in vitro</i> selection methods be applied to reveal new catalytic RNA but also to select aptamers. | |
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− | + | Figure 3. Twin Ribozyme | |
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− | + | Secondary structure of the Twin Ribozyme. With cleavage and ligation sites indicated by arrows. The Hairpin Ribozyme is derived from the Hairpin Ribozyme. | |
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Latest revision as of 17:07, 19 November 2015
Catalytic RNA – Ribozymes
In 1982 the first catalytic RNA (Ribozyme): a self-spicing intron from Tetrahymena pre-rRNA was described.
Another ribozyme that is related to the HHR is the hepatitis δ virus ribozyme (HDV).
Both of the mentioned types of ribozymes are found in satellite RNA of plant origin
Our idea of working with functional nucleic acids originated from this system. We were fascinated by the vast variety of processes that they can perform and started digging deeper into the potential of nucleic acids as tools. During this process we came across interesting systems amongst which we found the twin ribozyme (Fig. 3). Another famous hairpin-ribozyme-derived functional nucleic acid developed by Müller.
Next to the directed evolution of existing ribozymes in vitro selection methods