B14C-05
A Study of Mercury Methylation Genetics: Qualitative and Quantitative Analysis of hgcAB in Pure Culture
Monday, 14 December 2015: 17:00
2010 (Moscone West)
Geoff Alex Christensen1, Ann M Wymore2, Andrew J King2, Mircea Podar2, Richard A Hurt Jr.2, Eugenio F U Santillan3, Cynthia C Gilmour4, Craig c Brandt2, Steven D Brown2, Anthony V Palumbo1 and Dwayne A Elias2, (1)Oak Ridge National Laboratory, Oak Ridge, TN, United States, (2)Oak Ridge National Laboratory, Biosciences Division, Oak Ridge, TN, United States, (3)Smithsonian Environmental Research Center Edgewater, Edgewater, MD, United States, (4)Smithsonian Institution, Smithsonian Environmental Research Center, Edgewater, MD, United States
Abstract:
Two proteins (HgcA and HgcB) have been determined to be essential for mercury (Hg)-methylation and either one alone is not sufficient for this process. Detection and quantification of these genes to determine at risk environments is critical. Universal degenerate polymerase chain reaction (PCR) primers spanning hgcAB were developed to ascertain organismal diversity and validate that both genes were present as an established prerequisite for Hg-methylation. To confirm this approach, an extensive set of pure cultures with published genomes (including methylators and non-methylators: 13 Deltaproteobacteria, 9 Firmicutes, and 10 methanogenic Archaea) were assayed with the newly designed universal hgcAB primer set. A single band within an agarose gel was observed for the majority of the cultures with known hgcAB and confirmed via Sanger sequencing. For environmental applications, once the potential for Hg-methylation is established from PCR amplification with the universal hgcAB primer set, quantification of clade-specific hgcAB gene abundance is desirable. We developed quantitative polymerase chain reaction (qPCR) degenerate primers targeting hgcA from each of the three dominate clades (Deltaproteobacteria, Firmicutes and methanogenic Archaea) known to be associated with anaerobic Hg-methylation. The qPCR primers amplify virtually all hgcA positive cultures overall and are specific for their designed clade. Finally, to ensure the procedure is robust and sensitive in complex environmental matrices, cells from all clades were mixed in different combinations and ratios to assess qPCR primer specificity. The development and validation of these high fidelity quantitative molecular tools now allows for rapid and accurate risk management assessment in any environment.