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Rheology of liquid media influences bacterial physiology

Rheology of liquid media influences bacterial physiology. Maja Borić , Tjaša Danevčič , David Stopar University of Ljubljana, Biotechnical Faculty. Importance of rheology in biotechnological processes. Rheology studies the flow of liquids or soft matter Water treatment plants, bioreactors

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Rheology of liquid media influences bacterial physiology

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  1. Rheology of liquid media influences bacterial physiology MajaBorić, TjašaDanevčič, David Stopar University of Ljubljana, Biotechnical Faculty

  2. Importance of rheology in biotechnological processes • Rheologystudies the flow of liquids or soft matter • Water treatment plants, bioreactors • Influences pumping, hydrodynamics, mass transfer rates and sludge-water separation • Changes molecular diffusion as well as movement of microorganisms • Can a change in liquid medium rheology cause a change in bacterial physiology?

  3. Changing medium rheology in the lab • Ideal polymer: • increases viscosity • changes Newtonian liquid to non-Newtonian • can not be degraded by bacteria and used as a nutrient • does not affect other physico-chemical factors (pH, water activity, DOC) • Hydroxyethyl cellulose (HEC) • Viscosity range: 0.8 mPas – 26.5 mPas • Model organisms: • Bacillus subtilis • Escherichia coli • Vibrio harveyi

  4. Physiology of Bacillus subtilis • Growth rate increases but then returns to the previous level • Respiration activity is the same at all viscosities • PFK (phosphofructokinase) – glycolysis • GPD (glucose-6-P-dehydrogenase) – pentose phosphate pathway • PK (piruvate kinase) – flow to the citric acid cycle

  5. Physiology of Escherichia coli • At the highest tested viscosity the growth rate and respiration activity decreased significantly • PFK (phosphofructokinase) – glycolysis • GPD (glucose-6-P-dehydrogenase) – pentose phosphate pathway • PK (piruvate kinase) – flow to the citric acid cycle

  6. Physiology of Vibrio harveyi • V. harveyiincreased its respiration activity in order to maintain an unchanged growth rate. Despite this, the growth rate decreased at the highest tested viscosity. • PFK (phosphofructokinase) – glycolysis • GPD (glucose-6-P-dehydrogenase) – pentose phosphate pathway • PK (piruvate kinase) – flow to the citric acid cycle

  7. Growth efficiency • V. harveyi (A) • E. coli (B) • B. subtilis(C)

  8. Main conclusions and outlooks • Noteworthy differences in bacterial physiology at increased viscosity / changed rheology: • variability in bacterial response • Changes in viscosity / rheology can affect: • growth rates • total metabolic activity • efficiency • carbon flow through central metabolic pathways • Other bacteria might also be subject to changes in environmental viscosity/rheology – can this be the case in water treatment plants and other biotechnological settings?

  9. Acknowledgements • co-workers at the Chair of Microbiology, Biotechnical Faculty, Ljubljana • prof. dr. David Stopar • dr. TjašaDanevčič • JUB, d.d. • Slovenian Research Agency

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