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New opportunities in modulating microRNA

July 6, 2010

Emory geneticist Peng Jin and his colleagues have a review in the June 25, 2010 issue of Chemistry and Biology exploring whether microRNAs offer new possibilities for pharmacology.

MicroRNAs directly regulate other genes

The microRNA pathway represents both a way for scientists to “knock down” the activity of just one gene in the laboratory, and a major way for cells to regulate their genes during development.

MicroRNAs add a big wallop of complexity on top of the standard model of molecular biology, where the information in DNA is made into RNA, and RNAs make proteins. MicroRNAs don’t get turned into protein, but directly regulate other genes.

Andrew Fire and Craig Mello received the 2006 Nobel Prize in Medicine for their discovery that short pieces of RNA, when introduced into cells, can silence genes. This “RNA interference” tactic hijacks the natural machinery inside the cell that microRNAs use.

In 2008, Jin and coworkers published in Nature Biotechnology their discovery that certain antibiotics called fluoroquinolones (ciprofloxacin is one) can make the RNA interference process work more efficiently — in general. In the review, Jin notes that scientists are starting to look for drugs that act more selectively, disrupting or enhancing a particular microRNA rather than many at once:

Since miRNAs play major roles in nearly every cellular process, the identification and characterization of small-molecule modulators of the RNAi/miRNA pathway will yield fresh insights into fundamental mechanisms behind human disease… Moreover, these RNAi modulators, particularly RNAi enhancers, could potentially facilitate the development of RNA interference as a tool for biomedical research and therapeutic interventions.

qeastman 6 July 2010 News, Research , , , No Comments

Mapping mRNAs in the brain

December 1, 2009

If the brain acts like a computer, which of the brain’s physical features store the information? Flashes of electricity may keep memories and sensations alive for the moment, but what plays the role that hard drives and CDs do for computers?

A simple answer could be: genes turning on and off, and eventually, neurons growing and changing their shapes. But it gets more complicated pretty quickly. Genes can be regulated at several levels:

  • at the level of transcription — whether messenger RNA gets made from a stretch of DNA in the cell’s nucleus
  • at the level of translation — whether the messenger RNA is allowed to make a protein
  • at the level of RNA localization — where the mRNAs travel within the cell

Each neuron has only two copies of a given gene but will have many dendrites that can have more or less RNA in them. That means the last two modes of regulation offer neurons much more capacity for storing information.

Gary Bassell, a cell biologist at Emory, and his colleagues have been exploring how RNA regulation works in neurons. They have developed special tools for mapping RNA, and especially, microRNA — a form of RNA that regulates other RNAs.

In the dendrites of neurons, FMRP seems to control where RNAs end up

In the dendrites of neurons, FMRP seems to control where RNAs end up

Fragile X mental retardation protein (FMRP), linked to the most common inherited form of mental retardation, appears to orchestrate RNA traffic in neurons. Bassell and pharmacologist Yue Feng recently received a grant from the National Institute of Child Health and Development to study FMRP’s regulation of RNA in greater detail. The grant was one of several at Emory funded through the American Recovery and Reinvestment Act’s support for the NIH.

In the video interview above, Bassell explains his work on microRNAs in neurons. Below is a microscope image, provided by Bassell, showing the pattern of FMRP’s localization in neurons.

qeastman 1 December 2009 News, Research , , , , , , , , , , , No Comments