Food securityResearch on bacteria-invading virus to help the agriculture community

Published 14 February 2014

Innovative work by two Florida State University scientists shows the structural and DNA breakdown of a bacteria-invading virus. This type of virus is called a bacteriophage, and the deconstruction of its DNA could be particularly useful for the agriculture community and seed companies. Important crop plants depend on biological nitrogen fixation by the bacteria which is preyed upon by this phage. Nitrogen fixation is the process by which abundant nitrogen gas in the atmosphere is converted to the scarce soil resources ammonia and nitrate.

Schematic of virus defeating bacterium // Source: tufts.edu

Innovative work by two Florida State University scientists which shows the structural and DNA breakdown of a bacteria-invading virus is being featured on the cover of the February issue of the journal Virology.

Kathryn Jones and Elizabeth Stroupe, both assistant professors in the Department of Biological Science, have deconstructed a type of virus called a bacteriophage, which infects bacteria. Their work will help researchers in the future have a better understanding of how the virus invades and impacts bacteria, and could be particularly useful for the agriculture industry.

“It turns out there are a lot of novel things about it,” Jones said.

An FSU release reports that until now, there was little known about this particular bacteriophage, called the ϕM12, which infects a nitrogen-fixing bacterium called Sinorhizobium meliloti.

Jones focused on the sequencing the DNA of ϕM12 and analyzing its evolutionary context, while Stroupe looked at its overall physical structure.

“The bacteriophage is really just a tool for studying the bacterium,” Stroupe said. “No one thought to sequence it before.”

That tool, Stroupe said, will give scientists more insight into the basic functions of the ϕM12 bacteriophage. ϕM12 is the first reported bacteriophage to have its particular combination of DNA sequences and the particular shape of its protein shell. Understanding both the DNA and structure can provide an understanding of the proteins a bacteriophage produces and how it chooses the bacteria it invades.

In the case of ϕM12, this could be particularly useful in the future for the agriculture community and seed companies. Important crop plants depend on biological nitrogen fixation by the bacteria which is preyed upon by this phage. Nitrogen fixation is the process by which abundant nitrogen gas in the atmosphere is converted to the scarce soil resources ammonia and nitrate.

Jones and Stroupe’s work, divided into two articles, is featured on the cover of Virology. One, authored primarily by Jones and an undergraduate honors thesis student, Tess Brewer, focuses on the genetic makeup of the virus, while the other by Stroupe and colleagues, examines the physical structure.

— Read more in Tess E. Brewer et al., “The genome, proteome and phylogenetic analysis of Sinorhizobium meliloti phage ΦM12, the founder of a new group of T4-superfamily phages,” Virology 450–451 (February 2014): 84–97; and M. Elizabeth Stroupe et al., “The structure of Sinorhizobium meliloti phage ΦM12, which has a novel T=19l triangulation number and is the founder of a new group of T4-superfamily phages,” Virology 450–451 (February 2014): 205–12