Christopher A. Teske scite author profile

Confocal laser scanning microscopy (CLSM) is being increasingly used for observing protein uptake in porous chromatography resins. Recent CLSM studies have revealed the possible existence of a nondiffusive protein transport mechanism. Observing protein uptake with CLSM requires labeling the protein with a fluorescent probe. This study examines the effect of the probe identity on the subsequent CLSM adsorption profiles. The adsorption of lysozyme conjugated with different fluorescent probes (Cy5, BODIPY FL, Atto 635, and Atto 520) on SP Sepharose Fast Flow was measured using CLSM and zonal chromatography experiments. Results from zonal chromatography show that the retention time of lysozyme-dye conjugates differ significantly from unlabeled lysozyme. The change in retention of lysozyme upon conjugation with a fluorescent probe is consistent with the difference in net charge between the lysozyme-dye conjugate and unlabeled lysozyme. The adsorption profiles measured by CLSM show significantly different behavior depending upon whether the lysozyme-dye conjugate is retained longer or shorter than the unlabeled lysozyme. These results strongly suggest that the lysozyme concentration overshoot observed in previous CLSM experiments is the result of displacement of weaker binding labeled lysozyme by stronger binding unlabeled lysozyme.

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Measurement of Lysozyme−Lysozyme Interactions with Quantitative Affinity Chromatography

Teske

Blanch

Prausnitz

2004

J. Phys. Chem. B

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A chromatographic method is used to measure lysozyme-lysozyme interactions in aqueous salt solutions as a function of solution conditions (pH, ionic strength, and salt type). Compared to static light scattering and membrane osmometry, the chromatographic method requires significantly less protein. To interpret retentiontime data, it is necessary to account for multibody interactions between a mobile lysozyme molecule and immobilized lysozyme molecules on the support surface. The interaction between lysozyme molecules may be described by a potential of mean force that contains hard-sphere, electrostatic, and square-well contributions. Square-well depths from chromatographic data are in semiquantitative agreement with those from osmotic second virial coefficients from static light scattering measurements.

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Changes in retention behavior of fluorescently labeled proteins during ion‐exchange chromatography caused by different protein surface labeling positions

Teske

Simon

Niebisch

et al. 2007

Biotech & Bioengineering

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Confocal laser scanning microscopy (CLSM) is a method allowing in situ visualization of protein transport in porous chromatography resins. CLSM requires labeling a protein with a fluorescent probe. Recent work has shown that conjugation of the protein with fluorescent probes can lead to significant changes in the retention time of the protein-dye conjugate with respect to the unlabeled protein. In this study, we show that common labeling procedures result in a heterogeneous mixture of different variants and that attachment location of the fluorescent probe on the protein surface can have a strong effect on the retention of protein-dye conjugate. Lysozyme was labeled with Cy5 and BODIPY-FL succinimidyl esters, followed by chromatographic separation of the different lysozyme-dye conjugates and subsequent determination of the label position using MALDI-TOF-MS. Finally, homogenously labeled lysozyme-dye conjugates were used in CLSM experimentation and compared to published results arising from heterogeneously labeled feedstocks. The results confirm that the attachment location of the fluorescent probe has a strong effect on chromatographic retention behavior. When addressing the binding affinities of the different labeled protein fractions, it was found that native lysozyme was able to displace lysozyme-dye conjugates when the fluorescent label was attached to lysine-33, but not when attached to lysine-97. Finally, it could be shown that when superimposing the single profiles of the three major fractions obtained during a labeling procedure a qualitative picture of the net profile is obtained.

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Chromatographic measurement of interactions between unlike proteins

Teske

Blanch

Prausnitz

2004

Fluid Phase Equilibria

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Competitive adsorption of labeled and native protein in confocal laser scanning microscopy

Teske

Lieres

Schröder

et al. 2006

Biotech & Bioengineering

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Confocal laser scanning microscopy has been previously applied to the study of protein uptake in porous chromatography resins. This method requires labeling the protein with a fluorescent probe. The labeled protein is then diluted with a large quantity of native protein so that the fluorescence intensity is a linear function of the labeled protein concentration. Ideally, the attachment of a fluorescent probe should not affect the affinity of the protein for the stationary phase; however, recent experimental work has shown that this assumption is difficult to satisfy. In the present study, we present a mathematical model of protein diffusion and adsorption in a single adsorbent particle. The differences in adsorption behavior of labeled and native protein are accounted for by treating the system as a two-component system (labeled and native protein) described by the steric mass action isotherm (SMA). SMA parameters are regressed from experimental linear gradient elution data for lysozyme and lysozyme-dye conjugates (for the fluorescent dyes Cy3, Cy5, Bodipy FL, and Atto635). When the regressed parameters are employed in the model, an overshoot in the labeled lysozyme concentration is predicted for Cy5- and Bodipy-labeled lysozyme, but not for Atto635-labeled lysozyme. The model predictions agree qualitatively well with recent work showing the dependence of the concentration overshoot on the identity of the attached dye and provide further evidence that the overshoot is likely caused by the change of binding characteristics due to the fluorescent label.

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Inline ultrafiltration

Teske¹,

Lebreton²,

Reis³

2010

Biotechnology Progress

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Inline ultrafiltration (UF) can significantly increase the recoverable mass of biopharmaceutical products when pool tank volumes are limiting. Using relatively small commercially available ultrafiltration cassettes, a proof-of-concept study demonstrates that inline UF can significantly increase recoverable mass in an antibody purification process. With ever-increasing cell culture titers pushing product masses to higher levels, inline UF offers a relatively easy-to-implement and less disruptive alternative to installing larger pool tanks and enables more cost-effective production utilizing facilities designed for smaller bulk sizes.

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Characterizing solute binding to macroporous ion exchange membrane adsorbers using confocal laser scanning microscopy

Wickramasinghe

Carlson

Teske

et al. 2006

Journal of Membrane Science

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Balancing the Affinity and Pharmacokinetics of Antibodies by Modulating the Size of Charge Patches on Complementarity-Determining Regions

Cai¹,

Hu²,

Boswell³

et al. 2020

Journal of Pharmaceutical Sciences

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