Home

Dr. Diane Herson

Associate Professor

Contact

Herson

Office: 229 McKinly Lab

Mailing address:
Department of Biological Sciences
Wolf Hall
University of Delaware
Newark, DE 19716

Phone: (302) 831-8439
Fax: (302) 831-2281
E-mail: herson@udel.edu

Go to top of page

Education

B.S.: Cornell University
Ph.D.: Rutgers University

Go to top of page

Research Interests

In our laboratory we are studying the physiology of organisms in water and soil. We are particularly interested in the detection of these organisms and their ability to survive in these environments. Our previous studies with coliform organisms in drinking water have demonstrated the protective role of attachment when these organisms are exposed to chlorine. They respond to chlorine by synthesizing a subset of new proteins, one of which is in the outer membrane. Our studies using INT, a tetrazolium dye, have indicated that INT reduction is a more sensitive assay than plate counts in detecting chlorine-injured organisms.

Helicobacter pylori, the causative agent of ulcers, is considered an emerging pathogen. We are interested in determining if this organism is spread by ground and surface waters and in the relative efficacy of ozone disinfection on H. pylori and coliforms.

We have also shown that genetic transfer can occur in the low-nutrient, low temperature environment found in drinking water. Using a recombinant coliform harboring a non-transmissible plasmid, we demonstrated plasmid mobilization resulting from a tri-parental mating. Our studies with Pseudomonas stutzeri have demonstrated that DNA from this organism can persist and function as transforming DNA in a variety of waters.

Our current projects with organisms in soil involve bioremediation, a technology that uses microbes to degrade toxic chemicals. In this process an attempt is made to enhance microbial growth by initially assessing the biotic and abiotic factors at a site and then appropriately modifying them to optimize growth conditions. Although numerous remediation projects have been successfully carried out with a large variety of chemicals, the mechanisms which enable the microorganisms responsible for the degradation to survive and grow in the presence of the toxic chemical are not well understood. We have carried out studies using Pseudomonas putida (pWWO), an organism which can use toluene as a carbon and energy source. Using 2-D polyacrylamide gel electrophoresis we studied the physiological response of this organism when it was exposed to low, intermediate and high concentrations of toluene.

Go to top of page

Current Projects

The physiological response of Helicobacter pylori to ozone - We are interested in the effect of ozone on Helicobacter pylori. These studies will be carried out by ozonating the cells in the presence of 35S methionine. Amino acid uptake will be measured to determine effect of ozone on transport. Changes in the protein profile will be monitored using two dimensional PAGE. We are also interested in determining the cellular site of the proteins that are produced in response to ozonation.

The detection of Helicobacter pylori in ground and surface waters - We are using fluorescent-antibody INT (FAINT) and PCR to determine if viable Helicobacter pylori is present in a variety of surface and ground waters. We will also attempt to determine the effect of ozonation on the ability to detect H. pylori. Finding viable organisms would provide additional proof water can be a route of transmission for this pathogen.

The effect of MTBE on the ability of Pseudomonas putida mt-2 (pWWO) to degrade toluene - In recent years MTBE has been added to gasoline as an oxygenate. Although this practice is now being questioned and there are concerns about its use, there are currently numerous sites contaminated with this chemical. Pseudomonas putida mt-2 (pWWO) is able to degrade toluene, one of the components of gasoline. It is an example of an organism that can be used to carry out bioremediation. The goal of this study is to determine the effect of MTBE on P. putida. We are specifically interested in determining if P. putida can use MTBE as a carbon and energy source and if the presence of MTBE affects the ability of P. putida to grow on toluene.

Go to top of page

Teaching

BISC 171* - Microbiology in Modern Society
BISC 300* - Introduction to Microbiology
BISC 467* - Epidemics and Plagues
BISC 648 - Bioremediation

*Course web site available through MyCourses

Go to top of page

Selected Publications

Dentel, S.K., Y. Qi, and D. Herson. 2008. Improving the Assessment of Risk from Pathogens in Biosolids: Fecal Coliform Regrowth, Survival, Enumeration, and Assessment. Water Sci. Technol. 57:189-193.

Deitzel. J., Z. Sun, D. Herson, and N. Lamba. 2007. Processing of Biocidal Electrospun Nanofibers. (Reviewed) Proceedings of the 52nd International Technical Conference of the Society for the Advancement of Material and process Engineering (SAMPE).

Minnigh, H.A., G.I. Ramirez toro, P. Hunter, D. Herson, and K. Verville. 2007. Correlations between Standard Indicators and Frank Pathogens in a Pilot Community Intervention Study in Small Rural Water Systems in Puerto Rico. Proceedings of the 2nd International Water Association - Asia-Pacific Water Association (IWA-ASPIRE) Conference and Exhibition: Water and Sanitation in the Asia - Pacific Region Opportunities, Challenges and Technology.

Qi, Y.N., S.K. Dentel, and D.S. Herson. 2007. Increases in Fecal Coliform Bacteria Resulting from Centrifugal Dewatering of Digested Biosolids. Water Res. 41:571-580.

Qi, Y., S. Gillow, D.S. Herson, and S.K. Dentel. 2004. Reactivation and/or Growth of Fecal Coliform Bacteria During Centrifual dewatering of Digested Biosolids. Water Sci. Technol. 50:115-120.

Baker, K.H., B. Redmond, and D.S. Herson. 2004. False Positive Fecal coliforms in Biosolids Samples Assayed using A-1 Medium. Water Environ. Res. 77:423-424.

Baker, K.H., J.P. Hegarty, B. Redmond, N.A. Reed, and D.S. Herson. 2002. Effect of oxidizing disinfectants (Chlorine, Monochloramine, and ozone) on Helicobacter pylori. Appl. Environ. Microbiol. 68:981-984.

Chirnside, A.E., D.S. Herson, C. Huang, M. Radosevich, and W.F. Ritter. 2001. Bioremediation strategies for pesticide-contaminated soil: 1. microbial consortium isolation. in Ex Situ Biological Treatment Technologies. Magar, V.S., von Fahnestock, F.M., and A. Leeson 9 eds.) Battelle Press, Columbus, pp. 9-16.

Ma, Y. and D.S. Herson. 2000. cloning and sequencing of the catechol 2,3-dioxygenase gene and toluene monooxygenase genes from Burkholderia cepacia AA1, an isolate capable of degrading aliphatic hydrocarbons and toluene. J. Ind. Microbiol. and Tech. 25:127-131.

Baker, K.H., M. Troy, and D.S. Herson. 2000. Detection and occurrence of indicator organisms and pathogens. Water Environ. Rsh. Lit. Rev. Sept./Oct. (88 pgs.).

Baker, K.H. and D.S. Herson. 1999. Detection and occurrence of indicator organisms and pathogens. Water Environ. Res. 71:530-551.

Berlin, D., D.S. Herson, D.T. Hicks, and D.G. Hoover. 1999. Response of pathogenic species of Vibrio to high hydrostatic pressure. Appl. Environ. Microbiol. 65:2776-2780.

Vercellone-Smith, P.A. and D.S. Herson. 1997. Toluene elicits a carbon starvation response in Pseudomonas putida mt-2 containing TOL-plasmid pWWO. Appl. Environ. Microbiol. 63:1925-1932.

Go to top of page

People
» Faculty Directory
» Dr. Diane Herson

Shortcuts to:

Contact
Education
Research Interests
Current Projects
Teaching
Selected Publications

E-mail link to this page
Printer-friendly format

Home	Search for

About Us	Education	Research	People	News & Events
Dr. Diane Herson Associate Professor Contact Herson Office: 229 McKinly Lab Mailing address: Department of Biological Sciences Wolf Hall University of Delaware Newark, DE 19716 Phone: (302) 831-8439 Fax: (302) 831-2281 E-mail: herson@udel.edu Go to top of page Education B.S.: Cornell University Ph.D.: Rutgers University Go to top of page Research Interests In our laboratory we are studying the physiology of organisms in water and soil. We are particularly interested in the detection of these organisms and their ability to survive in these environments. Our previous studies with coliform organisms in drinking water have demonstrated the protective role of attachment when these organisms are exposed to chlorine. They respond to chlorine by synthesizing a subset of new proteins, one of which is in the outer membrane. Our studies using INT, a tetrazolium dye, have indicated that INT reduction is a more sensitive assay than plate counts in detecting chlorine-injured organisms. Helicobacter pylori, the causative agent of ulcers, is considered an emerging pathogen. We are interested in determining if this organism is spread by ground and surface waters and in the relative efficacy of ozone disinfection on H. pylori and coliforms. We have also shown that genetic transfer can occur in the low-nutrient, low temperature environment found in drinking water. Using a recombinant coliform harboring a non-transmissible plasmid, we demonstrated plasmid mobilization resulting from a tri-parental mating. Our studies with Pseudomonas stutzeri have demonstrated that DNA from this organism can persist and function as transforming DNA in a variety of waters. Our current projects with organisms in soil involve bioremediation, a technology that uses microbes to degrade toxic chemicals. In this process an attempt is made to enhance microbial growth by initially assessing the biotic and abiotic factors at a site and then appropriately modifying them to optimize growth conditions. Although numerous remediation projects have been successfully carried out with a large variety of chemicals, the mechanisms which enable the microorganisms responsible for the degradation to survive and grow in the presence of the toxic chemical are not well understood. We have carried out studies using Pseudomonas putida (pWWO), an organism which can use toluene as a carbon and energy source. Using 2-D polyacrylamide gel electrophoresis we studied the physiological response of this organism when it was exposed to low, intermediate and high concentrations of toluene. Go to top of page Current Projects The physiological response of Helicobacter pylori to ozone - We are interested in the effect of ozone on Helicobacter pylori. These studies will be carried out by ozonating the cells in the presence of 35S methionine. Amino acid uptake will be measured to determine effect of ozone on transport. Changes in the protein profile will be monitored using two dimensional PAGE. We are also interested in determining the cellular site of the proteins that are produced in response to ozonation. The detection of Helicobacter pylori in ground and surface waters - We are using fluorescent-antibody INT (FAINT) and PCR to determine if viable Helicobacter pylori is present in a variety of surface and ground waters. We will also attempt to determine the effect of ozonation on the ability to detect H. pylori. Finding viable organisms would provide additional proof water can be a route of transmission for this pathogen. The effect of MTBE on the ability of Pseudomonas putida mt-2 (pWWO) to degrade toluene - In recent years MTBE has been added to gasoline as an oxygenate. Although this practice is now being questioned and there are concerns about its use, there are currently numerous sites contaminated with this chemical. Pseudomonas putida mt-2 (pWWO) is able to degrade toluene, one of the components of gasoline. It is an example of an organism that can be used to carry out bioremediation. The goal of this study is to determine the effect of MTBE on P. putida. We are specifically interested in determining if P. putida can use MTBE as a carbon and energy source and if the presence of MTBE affects the ability of P. putida to grow on toluene. Go to top of page Teaching BISC 171* - Microbiology in Modern Society BISC 300* - Introduction to Microbiology BISC 467* - Epidemics and Plagues BISC 648 - Bioremediation *Course web site available through MyCourses Go to top of page Selected Publications Dentel, S.K., Y. Qi, and D. Herson. 2008. Improving the Assessment of Risk from Pathogens in Biosolids: Fecal Coliform Regrowth, Survival, Enumeration, and Assessment. Water Sci. Technol. 57:189-193. Deitzel. J., Z. Sun, D. Herson, and N. Lamba. 2007. Processing of Biocidal Electrospun Nanofibers. (Reviewed) Proceedings of the 52nd International Technical Conference of the Society for the Advancement of Material and process Engineering (SAMPE). Minnigh, H.A., G.I. Ramirez toro, P. Hunter, D. Herson, and K. Verville. 2007. Correlations between Standard Indicators and Frank Pathogens in a Pilot Community Intervention Study in Small Rural Water Systems in Puerto Rico. Proceedings of the 2nd International Water Association - Asia-Pacific Water Association (IWA-ASPIRE) Conference and Exhibition: Water and Sanitation in the Asia - Pacific Region Opportunities, Challenges and Technology. Qi, Y.N., S.K. Dentel, and D.S. Herson. 2007. Increases in Fecal Coliform Bacteria Resulting from Centrifugal Dewatering of Digested Biosolids. Water Res. 41:571-580. Qi, Y., S. Gillow, D.S. Herson, and S.K. Dentel. 2004. Reactivation and/or Growth of Fecal Coliform Bacteria During Centrifual dewatering of Digested Biosolids. Water Sci. Technol. 50:115-120. Baker, K.H., B. Redmond, and D.S. Herson. 2004. False Positive Fecal coliforms in Biosolids Samples Assayed using A-1 Medium. Water Environ. Res. 77:423-424. Baker, K.H., J.P. Hegarty, B. Redmond, N.A. Reed, and D.S. Herson. 2002. Effect of oxidizing disinfectants (Chlorine, Monochloramine, and ozone) on Helicobacter pylori. Appl. Environ. Microbiol. 68:981-984. Chirnside, A.E., D.S. Herson, C. Huang, M. Radosevich, and W.F. Ritter. 2001. Bioremediation strategies for pesticide-contaminated soil: 1. microbial consortium isolation. in Ex Situ Biological Treatment Technologies. Magar, V.S., von Fahnestock, F.M., and A. Leeson 9 eds.) Battelle Press, Columbus, pp. 9-16. Ma, Y. and D.S. Herson. 2000. cloning and sequencing of the catechol 2,3-dioxygenase gene and toluene monooxygenase genes from Burkholderia cepacia AA1, an isolate capable of degrading aliphatic hydrocarbons and toluene. J. Ind. Microbiol. and Tech. 25:127-131. Baker, K.H., M. Troy, and D.S. Herson. 2000. Detection and occurrence of indicator organisms and pathogens. Water Environ. Rsh. Lit. Rev. Sept./Oct. (88 pgs.). Baker, K.H. and D.S. Herson. 1999. Detection and occurrence of indicator organisms and pathogens. Water Environ. Res. 71:530-551. Berlin, D., D.S. Herson, D.T. Hicks, and D.G. Hoover. 1999. Response of pathogenic species of Vibrio to high hydrostatic pressure. Appl. Environ. Microbiol. 65:2776-2780. Vercellone-Smith, P.A. and D.S. Herson. 1997. Toluene elicits a carbon starvation response in Pseudomonas putida mt-2 containing TOL-plasmid pWWO. Appl. Environ. Microbiol. 63:1925-1932. Go to top of page				People » Faculty Directory » Dr. Diane Herson Shortcuts to: Contact Education Research Interests Current Projects Teaching Selected Publications E-mail link to this page Printer-friendly format
University of Delaware • Department of Biological Sciences • 118 Wolf Hall • Newark, DE 19716