Biology – Page 19

04.03.2013

DNA transistors

Several media outlets have been reporting on the topic of DNA transistors, which use genetic material as a type of switch inside of a cell. NPR has a pretty good description of the project and a link to a YouTube video:

Transistors are simple on/off switches. Computers are made of many millions of these switches. And to program a cell, you need a biological version. As Endy reports this week in Science, he managed to make one out of DNA.

His switch, which he calls a “transcriptor,” is a piece of DNA that he can flip on and off, using chemicals called enzymes. Endy put several of these DNA switches inside his bacteria. He could use the switches to build logic circuits that program each cell’s behavior. For example, he could tell a cell to change color in the presence of both enzyme A and enzyme B. That’s a simple program: IF enzyme A AND enzyme B [are present] THEN turn green. For an in-depth look, check out Endy’s own explanation on YouTube.

There is also the following graphical explanation:

The enzymes turn on the switch and allow the transcription of a DNA sequence into RNA. This transcription will then lead to some observable cellular phenomenon. Note that both enzymes must be present in a cell for the switch to be turned on.

The research appears in Science.

04.01.2013

hollow viruses

Popular Science highlights this paper from PLOS Pathogens. The research discusses creating hollowed out versions of viral capsids. These capsids would stimulate the immune system to produce antibodies without any potential for infection since the virus’ genetic material has been removed.

Call it hollow-hearted. Researchers have built a mimic of the outer capsule of the foot-and-mouth disease virus. Inside, where the virus’ genetic material normally lives, is empty.

Such synthetic virus-like particles could go into a foot-and-mouth vaccine that’s cheaper to make because it doesn’t require the tight biosecurity that a factory that makes vaccines from live viruses needs, its creators say. The researchers have also built the virus mimic in such a way that it can stay out of a refrigerator for longer than current foot-and-mouth vaccines, so it could ship more easily around the world.

In the future, the same techniques could apply to vaccines to the polio virus, which belongs to a large group of viruses related to hoof-and-mouth, Andrew Macadam, a polio researcher at the U.K. National Institute for Biological Standards and Control, told the BBC. Polio vaccines are now made with either weakened or killed polio viruses. (The weakened type still carries a small risk of reverting to its original form and causing paralysis. That vaccine is no longer used in the U.S., but some other countries give it out because it doesn’t require a highly trained medical professional to administer.)

The researchers hope it will lead to cheaper and less risky vaccines.

03.29.2013

getting a caffeine fix

People aren’t the only organisms that can’t get going without a daily cuppa. Scientists have engineered a strain of E. coli to thrive on caffeine. To engineer this characteristic in the bacteria, the scientists cloned in genetic material from Psuedomonas putida bacteria. This Psuedomonas species was already known to be able to metabolize caffeine. They also needed to clone in another gene from Janthinobacterium in order for the E. coli to completely metabolize the caffeine. After cloning the genetic material into E. coli, they saw that the bacteria’s growth rate was severely limited by the amount of caffeine in their environment and they could tell how much caffeine was present in a drink by how much of the bacteria grew. The scientists are hoping that the bacteria can be used in decaffeinating waterways near major cities, as the water around population centers usually contains lots of caffeine pollution. If you can get access, check out the paper at ACS Synthetic Biology.

GOLLYGEE!

Category: Biology (page 19 of 63)

DNA transistors

hollow viruses

getting a caffeine fix