High-pressure small-angle X-ray scattering cell for biological solutions and soft materials

Rai, D.K.; Gillilan, Richard E.; Huang, Qingqiu; Miller, Robert C.; Ting, Edmund; Lazarev, Alexander; Täte, Mark W.; Grüner, Sol M.

doi:10.1107/s1600576720014752

“…This can potentially provide insights into the influence of protein thermodynamic stability under cold-temperature conditions. Rosa et al proposed that the pressure effect on a model globular protein (bovine hemoglobin) in the cold-temperature regime was negligible by performing isochoric experiments ( ex situ approach) . Both globular proteins tested here have shown to be resistant to pressures up to 3 kbar under low-temperature conditions, which is higher than the pressure range associated with isochoric methods (pressure increases up to ∼1.5 kbar at −15 °C).…”

Section: Results and Discussionmentioning

confidence: 79%

“…Rosa et al proposed that the pressure effect on a model globular protein (bovine hemoglobin) in the cold-temperature regime was negligible by performing isochoric experiments (ex situ approach). 80 Both globular proteins tested here have shown to be resistant to pressures up to 3 kbar under low-temperature conditions, which is higher than the pressure range associated with isochoric methods (pressure increases up to ∼1.5 kbar at −15 °C). Instead, Ova structural changes and the first protein− protein assembly steps detected via in situ HP-SANS below −10 °C are assumed to be induced solely by cold-temperature conditions.…”

Section: C)mentioning

confidence: 71%

“…Preliminary studies were also carried out using a custom-made HP cell for SAXS, at the Cornell High Energy Synchrotron Source (CHESS). The SAXS HP cell design and corresponding protein studies under pressure environment have been described elsewhere. − The results obtained from SAXS runs show that no significant conformational changes can be detected for Ova and aCgn (prepared in the corresponding H 2 O-based buffer) at a temperature range of ∼20 to −7 °C and pressures up to ∼3 kbar (data not shown). A lower-temperature range was not possible to test with the available SAXS HP cell.…”

Section: Results and Discussionmentioning

confidence: 99%

See 1 more Smart Citation

In Situ Monitoring of Protein Unfolding/Structural States under Cold High-Pressure Stress

Gomes

¹

,

Teixeira

²

,

Leão

³

et al. 2021

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Biopharmaceutical formulations may be compromised by freezing, which has been attributed to protein conformational changes at a low temperature, and adsorption to ice–liquid interfaces. However, direct measurements of unfolding/conformational changes in sub-0 °C environments are limited because at ambient pressure, freezing of water can occur, which limits the applicability of otherwise commonly used analytical techniques without specifically tailored instrumentation. In this report, small-angle neutron scattering (SANS) and intrinsic fluorescence (FL) were used to provide in situ analysis of protein tertiary structure/folding at temperatures as low as −15 °C utilizing a high-pressure (HP) environment (up to 3 kbar) that prevents water from freezing. The results show that the α-chymotrypsinogen A (aCgn) structure is reasonably maintained under acidic pH (and corresponding pD) for all conditions of pressure and temperature tested. On the other hand, reversible structural changes and formation of oligomeric species were detected near −10 °C via HP-SANS for ovalbumin under neutral pD conditions. This was found to be related to the proximity of the temperature of cold denaturation of ovalbumin (T CD ∼ −17 °C; calculated via isothermal chemical denaturation and Gibbs–Helmholtz extrapolation) rather than a pressure effect. Significant structural changes were also observed for a monoclonal antibody, anti-streptavidin IgG1 (AS-IgG1), under acidic conditions near −5 °C and a pressure of ∼2 kbar. The conformational perturbation detected for AS-IgG1 is proposed to be consistent with the formation of unfolding intermediates such as molten globule states. Overall, the in situ approaches described here offer a means to characterize the conformational stability of biopharmaceuticals and proteins more generally under cold-temperature stress by the assessment of structural alteration, self-association, and reversibility of each process. This offers an alternative to current ex situ methods that are based on higher temperatures and subsequent extrapolation of the data and interpretations to the cold-temperature regime.

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“…Glucose isomerase, a well-studied tetrameric protein standard for SAXS, is structurally stable at pressures up to at least 300 MPa 11 . Figure 1A compares elution profiles of a 100 µl injection of concentrated glucose isomerase (17.9 mg/ml) at room pressure and at 102.3 MPa ( P inlet ).…”

Section: Resultsmentioning

confidence: 99%

“…Glucose isomerase used in this study was from the same batch as used in evaluating our static HP-SAXS system. The preparation protocol can be found in the paper describing that work 11 .…”

Section: Samplesmentioning

confidence: 99%

Inline SAXS-coupled chromatography under extreme hydrostatic pressure

Miller

¹

,

Cummings

²

,

Huang

³

et al. 2022

Preprint

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0

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As continuing discoveries highlight the surprising abundance and resilience of deep ocean and subsurface microbial life, the effects of extreme hydrostatic pressure on biological structure and function have attracted renewed interest. Biological small angle X-ray scattering (BioSAXS) is a widely used method of obtaining structural information from biomolecules in solution under a wide range of solution conditions. Due to its ability to reduce radiation damage, remove aggregates, and separate monodisperse components from complex mixtures, size-exclusion chromatography coupled SAXS (SEC-SAXS) is now the dominant form of BioSAXS at many synchrotron beamlines. While BioSAXS can currently be performed with some difficulty under pressure with non-flowing samples, it has not been clear how, or even if, continuously flowing SEC-SAXS, with its fragile media-packed columns, might work in an extreme high-pressure environment. Here we show, for the first time, that reproducible chromatographic separations coupled directly to high-pressure BioSAXS can be achieved at pressures up to at least 100 MPa and that pressure-induced changes in folding and oligomeric state and other properties can be observed. The apparatus described here functions at a range of temperatures (0° C - 50° C), expanding opportunities for understanding biomolecular rules of life in deep ocean and subsurface environments.

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Inline small‐angle X‐ray scattering‐coupled chromatography under extreme hydrostatic pressure

Miller

¹

,

Cummings²,

Huang³

et al. 2022

Protein Science

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4

0

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As continuing discoveries highlight the surprising abundance and resilience of deep ocean and subsurface microbial life, the effects of extreme hydrostatic pressure on biological structure and function have attracted renewed interest.Biological small-angle X-ray scattering (BioSAXS) is a widely used method of obtaining structural information from biomolecules in solution under a wide range of solution conditions. Due to its ability to reduce radiation damage, remove aggregates, and separate monodisperse components from complex mixtures, size-exclusion chromatography-coupled SAXS (SEC-SAXS) is now the dominant form of BioSAXS at many synchrotron beamlines. While Bio-SAXS can currently be performed with some difficulty under pressure with non-flowing samples, it has not been clear how, or even if, continuously flowing SEC-SAXS, with its fragile media-packed columns, might work in an extreme high-pressure environment. Here we show, for the first time, that reproducible chromatographic separations coupled directly to high-pressure BioSAXS can be achieved at pressures up to at least 100 MPa and that pressure-induced changes in folding and oligomeric state and other properties can be observed. The apparatus described here functions at a range of temperatures (0 C-50 C), expanding opportunities for understanding biomolecular rules of life in deep ocean and subsurface environments.extreme biophysics, high-pressure biology, SEC-SAXS, size-exclusion chromatography, small-angle X-ray solution scattering | INTRODUCTIONSince the early realization that hydrostatic pressure has effects on biological molecules, 1 pressure has become a useful, though not always easily accessible tool for gaining insight into basic biophysical processes. 2 In addition to being a tool for understanding phenomena such as enzymatic action, folding, and association, it is now appreciated that pressure itself is a biologically significant variable. An extraordinary portion of the biomass of our planet resides deep in the oceans, below the seafloor, and in the continental subsurface. 3 Structural biology and biophysics of these organisms should clearly be understood in the context of high pressure, yet biomolecular structural information under pressure is scarce to nonexistent. As interest in deep life biology continues to grow, structural biology studies conducted under high pressure are becoming increasingly important and new

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High-pressure small-angle X-ray scattering cell for biological solutions and soft materials

Cited by 28 publications

References 61 publications

In Situ Monitoring of Protein Unfolding/Structural States under Cold High-Pressure Stress

In Situ Monitoring of Protein Unfolding/Structural States under Cold High-Pressure Stress

Inline SAXS-coupled chromatography under extreme hydrostatic pressure

Inline small‐angle X‐ray scattering‐coupled chromatography under extreme hydrostatic pressure

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