Building computers from DNA?

Scientists have found a way to "switch" the structure of DNA using copper salts and EDTA (Ethylenediaminetetraacetic acid) -- an agent commonly found in shampoo and other household products. It was previously known that the structure of a piece of DNA could be changed using acid, which causes it to fold up into what is known as an "i-motif." But new research published today in the journal Chemical Communications reveals that the structure can be switched a second time into a hair-pin structure using positively-charged copper (copper cations). This change can also be reversed using EDTA. The applications for this discovery include nanotechnology -- where DNA is used to make tiny machines, and in DNA-based computing -- where computers are built from DNA rather than silicon. Credit: University of East Anglia

Scientists have found a way to “switch” the structure of DNA using copper salts and EDTA (Ethylenediaminetetraacetic acid) — an agent commonly found in shampoo and other household products. It was previously known that the structure of a piece of DNA could be changed using acid, which causes it to fold up into what is known as an “i-motif.” But new research published today in the journal Chemical Communications reveals that the structure can be switched a second time into a hair-pin structure using positively-charged copper (copper cations). This change can also be reversed using EDTA. The applications for this discovery include nanotechnology — where DNA is used to make tiny machines, and in DNA-based computing — where computers are built from DNA rather than silicon.
Credit: University of East Anglia

New research from the University of East Anglia could one day help build computers from DNA.

Scientists have found a way to ‘switch’ the structure of DNA using copper salts and EDTA (Ethylenediaminetetraacetic acid) — an agent commonly found in shampoo and other household products.

It was previously known that the structure of a piece of DNA could be changed using acid, which causes it to fold up into what is known as an ‘i-motif’.

But new research published today in the journal Chemical Communicationsreveals that the structure can be switched a second time into a hair-pin structure using positively-charged copper (copper cations). This change can also be reversed using EDTA.

The applications for this discovery include nanotechnology — where DNA is used to make tiny machines, and in DNA-based computing — where computers are built from DNA rather than silicon.

It could also be used for detecting the presence of copper cations, which are highly toxic to fish and other aquatic organisms, in water.

Lead researcher Dr Zoë Waller, from UEA’s school of Pharmacy, said: “Our research shows how the structure of our genetic material — DNA — can be changed and used in a way we didn’t realise.

“A single switch was possible before — but we show for the first time how the structure can be switched twice.

“A potential application of this finding could be to create logic gates for DNA based computing. Logic gates are an elementary building block of digital circuits — used in computers and other electronic equipment. They are traditionally made using diodes or transistors which act as electronic switches.

“This research expands how DNA could be used as a switching mechanism for a logic gate in DNA-based computing or in nano-technology.”


Story Source:

The above post is reprinted from materials provided by University of East Anglia. Note: Materials may be edited for content and length.


Journal Reference:

  1. Henry Albert Day, Elisé Patricia Wright, Colin John MacDonald, Andrew James Gates, Zoë Ann Ella Waller. Reversible DNA i-motif to hairpin switching induced by copper(ii) cations. Chem. Commun., 2015; DOI:10.1039/C5CC05111H

 


University of East Anglia. (2015, August 19). Building computers from DNA?.ScienceDaily. Retrieved October 13, 2015 from www.sciencedaily.com/releases/2015/08/150819083421.htm

 

Posted by Ahmad Aya Sanusi   @   13 October 2015
Tags : ,

Related Posts

Like this post? Share it!

RSS Digg Twitter StumbleUpon Delicious Technorati

0 Comments

No comments yet. Be the first to leave a comment !
Leave a Comment

Name

Email

Website

Previous Post
«
Next Post
»