From screen to structure with a harvestable microfluidic device

V. Stojanoff; J. Jakoncic; D. A. Oren; V. Nagarajan; Jens-Christian Navarro Poulsen; M. A. Adams-Cioaba; T. Bergfors; M. O. A. Sommer

From screen to structure with a harvestable microfluidic device

V. Stojanoff, J. Jakoncic, D. A. Oren, V. Nagarajan, Jens-Christian Navarro Poulsen, M. A. Adams-Cioaba, T. Bergfors, M. O. A. Sommer

Department of Chemistry

18 Citations (Scopus)

Abstract

Advances in automation have facilitated the widespread adoption of high-throughput vapour-diffusion methods for initial crystallization screening. However, for many proteins, screening thousands of crystallization conditions fails to yield crystals of sufficient quality for structural characterization. Here, the rates of crystal identification for thaumatin, catalase and myoglobin using microfluidic Crystal Former devices and sitting-drop vapour-diffusion plates are compared. It is shown that the Crystal Former results in a greater number of identified initial crystallization conditions compared with vapour diffusion. Furthermore, crystals of thaumatin and lysozyme obtained in the Crystal Former were used directly for structure determination both in situ and upon harvesting and cryocooling. On the basis of these results, a crystallization strategy is proposed that uses multiple methods with distinct kinetic trajectories through the protein phase diagram to increase the output of crystallization pipelines.

Original language	English
Journal	Acta Crystallographica. Section F: Structural Biology and Crystallization Communications Online
Volume	67
Issue number	8
Pages (from-to)	971-975
ISSN	1744-3091
Publication status	Published - Aug 2011

Cite this

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title = "From screen to structure with a harvestable microfluidic device",

abstract = "Advances in automation have facilitated the widespread adoption of high-throughput vapour-diffusion methods for initial crystallization screening. However, for many proteins, screening thousands of crystallization conditions fails to yield crystals of sufficient quality for structural characterization. Here, the rates of crystal identification for thaumatin, catalase and myoglobin using microfluidic Crystal Former devices and sitting-drop vapour-diffusion plates are compared. It is shown that the Crystal Former results in a greater number of identified initial crystallization conditions compared with vapour diffusion. Furthermore, crystals of thaumatin and lysozyme obtained in the Crystal Former were used directly for structure determination both in situ and upon harvesting and cryocooling. On the basis of these results, a crystallization strategy is proposed that uses multiple methods with distinct kinetic trajectories through the protein phase diagram to increase the output of crystallization pipelines.",

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AU - Stojanoff, V.

AU - Jakoncic, J.

AU - Oren, D. A.

AU - Nagarajan, V.

AU - Poulsen, Jens-Christian Navarro

AU - Adams-Cioaba, M. A.

AU - Bergfors, T.

AU - Sommer, M. O. A.

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N2 - Advances in automation have facilitated the widespread adoption of high-throughput vapour-diffusion methods for initial crystallization screening. However, for many proteins, screening thousands of crystallization conditions fails to yield crystals of sufficient quality for structural characterization. Here, the rates of crystal identification for thaumatin, catalase and myoglobin using microfluidic Crystal Former devices and sitting-drop vapour-diffusion plates are compared. It is shown that the Crystal Former results in a greater number of identified initial crystallization conditions compared with vapour diffusion. Furthermore, crystals of thaumatin and lysozyme obtained in the Crystal Former were used directly for structure determination both in situ and upon harvesting and cryocooling. On the basis of these results, a crystallization strategy is proposed that uses multiple methods with distinct kinetic trajectories through the protein phase diagram to increase the output of crystallization pipelines.

AB - Advances in automation have facilitated the widespread adoption of high-throughput vapour-diffusion methods for initial crystallization screening. However, for many proteins, screening thousands of crystallization conditions fails to yield crystals of sufficient quality for structural characterization. Here, the rates of crystal identification for thaumatin, catalase and myoglobin using microfluidic Crystal Former devices and sitting-drop vapour-diffusion plates are compared. It is shown that the Crystal Former results in a greater number of identified initial crystallization conditions compared with vapour diffusion. Furthermore, crystals of thaumatin and lysozyme obtained in the Crystal Former were used directly for structure determination both in situ and upon harvesting and cryocooling. On the basis of these results, a crystallization strategy is proposed that uses multiple methods with distinct kinetic trajectories through the protein phase diagram to increase the output of crystallization pipelines.

M3 - Journal article

SN - 2053-230X

VL - 67

SP - 971

EP - 975

JO - Acta Crystallographica Section F: Structural Biology Communications

JF - Acta Crystallographica Section F: Structural Biology Communications

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ER -

From screen to structure with a harvestable microfluidic device

Abstract

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