The Effect of Solid Surfaces upon Bacterial Activity

ZoBell, Claude E.

doi:10.1128/jb.46.1.39-56.1943

Cited by 865 publications

(266 citation statements)

References 30 publications

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“…1) may be seen as a change in the rate of production in response to a surfaceassociated stimulus, that is used by the cell to achieve irreversible sorption. This behaviour of enhanced polymer synthesis upon sorption is consistent with the early observations by ZoBell [49], confirmed by e.g. [38,50], of two phases of sorption, the second of which was associated with production of extracellular adhesive material.…”

Section: Discussionsupporting

confidence: 91%

Bacterial exopolymer and PHB production in fluctuating ground-water habitats

Bengtsson

1991

FEMS Microbiology Letters

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Section: Discussionsupporting

confidence: 91%

Bacterial exopolymer and PHB production in fluctuating ground-water habitats

Bengtsson

1991

FEMS Microbiology Letters

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“…Sorption of nutrients on soil particles is helpful for attached bacteria. Solid particles larger than bacteria were reported to be more beneficial than smaller ones (Zobell, 1943). Therefore, the improved growth of S. suis in the exponential stage may be attributed to the accumulation of nutrients on the surfaces of silts and sands.…”

Section: Effect Of Ca 2+ Concentrationsmentioning

confidence: 99%

Sorption of Streptococcus suis on various soil particles from an Alfisol and effects on pathogen metabolic activity

Zhao¹,

Liu²,

Huang³

et al. 2012

European J Soil Science

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The potential contamination of soil environments by pathogens from agricultural manures has received great attention in recent years. However, few studies of the sorption and metabolic activity of pathogens on soil particles have been conducted to date. In this study, we investigated the sorption of pathogen Streptococcus suis on various soil particles from an Alfisol as a function of pH and calcium chloride (CaCl2) concentration. S. suis metabolic activity in the presence of different soil particles was also studied by micro‐calorimetric techniques. The amount of S. suis sorbed followed the order: inorganic clay > organic clay > inorganic silt > organic silt > inorganic sand > organic sand. Zeta potentials of S. suis were negative over the experimental conditions and increased with the decrease of pH or the increase of Ca2+ concentrations. A gradual decrease in the sorption of S. suis on soil particles was observed with the increase of pH from 4.0 to 9.0. Increasing Ca2+ concentrations (0–1 mm) resulted in an increase of S. suis sorption on clays, silts and sands, while larger Ca2+ concentrations (20–50 mm) depressed S. suis sorption on silts and sands. The exponential growth of S. suis was stimulated by silts and sands, but inhibited by clays. Our results show that electrostatic forces play a major role in the sorption behaviour and that an additional non‐DLVO type interaction (electrosteric repulsion) occurs at large Ca2+ concentrations. Different sorption affinities of S. suis on soil particles may be the dominant factor influencing S. suis activities.

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“…Heterotrophic bacteria degrade and decompose organic matter, so attachment to zooplankton feces, lysed phytoplankton, or other particulate organic matter clearly provides increased substrate availability to attached microorganisms capable of digesting those substrates. ZoBell(1943) and Kjellcbcrg et al ( 1983) speculated that nonnutritive surfaces concentrate dilute substrates. An increased availability of substrate would result in enhanced microbial growth at surfaces when compared to growth of dispersed cells, assuming growth is proportional to substrate concentration.…”

mentioning

confidence: 99%

Advantages to microbes of growth in permeable aggregates in marine systems1

Logan

Hunt

1987

Limnology & Oceanography

126

103

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Highly porous microbial aggregates occur in a variety of environments ranging from marine snow in oceans to floes in biological reactors. For permeable aggregates undergoing gravitational settling or subjected to fluid shear, predicted velocities of intra-aggregate flow range from 1 to 100 pm s I. Estimation of intra-aggregate velocities requires spccihcation of the aggregate size, porosity, and permeability, as well as a mean fluid shear rate characterizing the fluid turbulence. We have examined substrate removal by microorganisms in permeable aggregates with an analysis of mass transfer. The overall uptake by bacteria in aggregates can be up to 60% greater than uptake by dispcrscd bacteria. In general, a model of substrate uptake based on advective transport is more appropriate than a model based on diffusive transport for cells in large, permeable aggregates that utilize substrates with diffusivities < 1 Op6 cm2 s-l.

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The Effect of Solid Surfaces upon Bacterial Activity

Cited by 865 publications

References 30 publications

Bacterial exopolymer and PHB production in fluctuating ground-water habitats

Bacterial exopolymer and PHB production in fluctuating ground-water habitats

Sorption of Streptococcus suis on various soil particles from an Alfisol and effects on pathogen metabolic activity

Advantages to microbes of growth in permeable aggregates in marine systems1

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