Associative Interactions in Crowded Solutions of Biopolymers Counteract Depletion Effects

Groen, J.P.; Foschepoth, David; Brinke, Esra te; Boersma, Arnold J.; Imamura, Hiromi; Rivas, Germán; Heus, Hans A.; Huck, Wilhelm T. S.

doi:10.1021/jacs.5b07898

Cited by 60 publications

(81 citation statements)

References 51 publications

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“…Volume occupancy by Ficoll was calculated from a reported partial specific volume of 650 cm 3 ·g −1 , a value in agreement with our experimental verification of volume change upon dissolution of a known mass of solute. The volume fraction occupied by the crowder, ϕ C , in a 200 g·L −1 Ficoll solution was determined to be 13%, assuming no volume changes resulted from perturbations of solvent molecules.…”

Section: Methodssupporting

confidence: 77%

Identification of primary and secondary UBA footprints on the surface of ubiquitin in cell‐mimicking crowded solution

et al. 2017

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Despite significant advancements in our understanding of ubiquitin-mediated signaling, the influence of the intracellular environment on formation of transient ubiquitin-partner complexes remains poorly explored. In our work, we introduce macromolecular crowding as a first level of complexity towards the imitation of a cellular environment in the study of such interactions. Using NMR spectroscopy, we find that the stereospecific complex of ubiquitin and ubiquitin-associated domain (UBA) is minimally perturbed by the crowding agent Ficoll. However, in addition to the primary canonical recognition patch on ubiquitin, secondary patches are identified, indicating that in cell-mimicking crowded solution, UBA contacts ubiquitin at multiple sites.

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Section: Methodssupporting

confidence: 77%

Identification of primary and secondary UBA footprints on the surface of ubiquitin in cell‐mimicking crowded solution

et al. 2017

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“…The incorporation of paired lysines and glutamates would prevent interactions, allowing steric effects to govern the conformation. In general, the observation that in-cell behavior is different compared to in vitro crowding is not very surprising: chemical nonspecific interactions seem to dominate over the steric crowding for most reported small proteins (6)(7)(8)(9)(10)(11)(12). Hence, this is the most likely explanation, and it is remarkable that the steric compression appears to be regained by the presence of these helices.…”

Section: Discussionmentioning

confidence: 99%

“…The probes expanded in the presence of small amounts (1% wt/wt) of g-Globulins, which suggests that g-Globulins bind the probes. The probes did not expand further by addition of 10% wt/wt g-Globulins, which could be due to saturation of binding sites, balancing excluded volume effects (9), or the decrease of attractive interactions of concentrated antibodies (37,38). We observed compression of the three probes in the presence of a variety of macromolecular crowders based on the carbohydrates Ficoll 70 and 400 kDa, Dextran 40 and 6 kDa, and the proteins BSA and ovalbumin, all at 10% wt/wt (Fig.…”

Section: Compression Is Related To Crowder Radiusmentioning

confidence: 99%

“…The entropic penalty can be relieved by reducing the volume of the introduced protein. In the cell, other interactions are able to attenuate this entropic effect, resulting in net effects that are often different from what would be predicted solely due to steric exclusion (5)(6)(7)(8)(9)(10)(11)(12). This makes that crowding effects are unpredictable in cells, and can be overshadowed by other nonspecific interactions if the excluded volume effects are small.…”

Section: Introductionmentioning

confidence: 99%

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Design and Properties of Genetically Encoded Probes for Sensing Macromolecular Crowding

Zhang

Åberg

Eerden

et al. 2017

Biophysical Journal

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100

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Cells are highly crowded with proteins and polynucleotides. Any reaction that depends on the available volume can be affected by macromolecular crowding, but the effects of crowding in cells are complex and difficult to track. Here, we present a set of Fö rster resonance energy transfer (FRET)-based crowding-sensitive probes and investigate the role of the linker design. We investigate the sensors in vitro and in vivo and by molecular dynamics simulations. We find that in vitro all the probes can be compressed by crowding, with a magnitude that increases with the probe size, the crowder concentration, and the crowder size. We capture the role of the linker in a heuristic scaling model, and we find that compression is a function of size of the probe and volume fraction of the crowder. The FRET changes observed in Escherichia coli are more complicated, where FRETincreases and scaling behavior are observed solely with probes that contain the helices in the linker. The probe with the highest sensitivity to crowding in vivo yields the same macromolecular volume fractions as previously obtained from cell dry weight. The collection of new probes provides more detailed readouts on the macromolecular crowding than a single sensor.

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“…Excluded volume theory predicts that the contribution of excluded volume to a particular reaction equilibrium will only become substantial when the size of the probe is comparable to or exceeds that of the major crowding species 13 and when the probe reaction (isomerization or association) is accompanied by a substantial reduction of the ratio of solvent-exposed surface to volume 12 . These predictions are borne out by the following observations: (1) The formation of polymers of sickle hemoglobin (HbS) is facilitated by high concentrations of bovine serum albumin and hemoglobin mutants that do not coprecipitate with HbS 90 ; (2) the formation of amyloid fibers of alpha synuclein is strongly promoted by high concentrations of other proteins as well as by nonionic polymers 91 ; and (3) the formation of fiber bundles of FtsZ is strongly facilitated not only by the addition of traditional polymeric crowding agents, but also by the addition of 10 % (by volume) of BSA, ovomucoid, and Escherichia coli lysate 92 .…”

Section: Concluding Remarks and Future Perspectivesmentioning

confidence: 99%

Macromolecular Crowding In Vitro , In Vivo , and In Between

Rivas

Minton

2016

Trends in Biochemical Sciences

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405

370

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Biochemical processes take place in heterogeneous and highly volume occupied or crowded environments that can considerably influence the reactivity and distribution of participating macromolecules. Here we summarize the thermodynamic consequences of excluded volume and longer-ranged nonspecific intermolecular interactions for macromolecular reactions in volume-occupied media. In addition, we summarize and compare the information content of studies of crowding in vitro and in vivo. We emphasize the importance of characterizing the behavior not only of labeled tracer macromolecules, but also the composition and behavior of unlabeled macromolecules in the immediate vicinity of the tracer. Finally, we propose strategies for extending quantitative analyses of crowding in simple model systems to increasingly complex media up to and including intact cells.

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Associative Interactions in Crowded Solutions of Biopolymers Counteract Depletion Effects

Cited by 60 publications

References 51 publications

Identification of primary and secondary UBA footprints on the surface of ubiquitin in cell‐mimicking crowded solution

Identification of primary and secondary UBA footprints on the surface of ubiquitin in cell‐mimicking crowded solution

Design and Properties of Genetically Encoded Probes for Sensing Macromolecular Crowding

Macromolecular Crowding In Vitro , In Vivo , and In Between

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