Influence of Divalent Cations in the Protein Crystallization Process Assisted by Lanthanide-Based Additives

This paper reviews investigations on protein crystallization. It aims to present a comprehensive rather than complete account of recent studies and efforts to elucidate the most intimate mechanisms of protein crystal nucleation. It is emphasized that both physical and biochemical factors are at play during this process. Recently-discovered molecular scale pathways for protein crystal nucleation are considered first. The bond selection during protein crystal lattice formation, which is a typical biochemically-conditioned peculiarity of the crystallization process, is revisited. Novel approaches allow us to quantitatively describe some protein crystallization cases. Additional light is shed on the protein crystal nucleation in pores and crevices by employing the so-called EBDE method (equilibration between crystal bond and destructive energies). Also, protein crystal nucleation in solution flow is considered.

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Design of protein crystallization process guided by phase diagram

10.14711/thesis-b1136736 ◽

2011 ◽

Author(s):

Sze Kee Tam

Keyword(s):

Phase Diagram ◽

Crystallization Process ◽

Protein Crystallization

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Optimization and control of crystal shape and size in protein crystallization process

Computers & Chemical Engineering ◽

10.1016/j.compchemeng.2013.04.022 ◽

2013 ◽

Vol 57 ◽

pp. 133-140 ◽

Cited By ~ 23

Author(s):

Jing J. Liu ◽

Yang D. Hu ◽

Xue Z. Wang

Keyword(s):

Crystallization Process ◽

Protein Crystallization ◽

Crystal Shape ◽

Optimization And Control ◽

And Control ◽

Shape And Size

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Accurate multistage prediction of protein crystallization propensity using deep-cascade forest with sequence-based features

Briefings in Bioinformatics ◽

10.1093/bib/bbaa076 ◽

2020 ◽

Author(s):

Yi-Heng Zhu ◽

Jun Hu ◽

Fang Ge ◽

Fuyi Li ◽

Jiangning Song ◽

...

Keyword(s):

Crystallization Process ◽

Solvent Accessibility ◽

Protein Crystallization ◽

Protein Structures ◽

X Ray ◽

X Ray Crystallography ◽

Benchmark Datasets ◽

Pass Through ◽

Matthew’S Correlation Coefficient ◽

Dcf Model

Abstract X-ray crystallography is the major approach for determining atomic-level protein structures. Because not all proteins can be easily crystallized, accurate prediction of protein crystallization propensity provides critical help in guiding experimental design and improving the success rate of X-ray crystallography experiments. This study has developed a new machine-learning-based pipeline that uses a newly developed deep-cascade forest (DCF) model with multiple types of sequence-based features to predict protein crystallization propensity. Based on the developed pipeline, two new protein crystallization propensity predictors, denoted as DCFCrystal and MDCFCrystal, have been implemented. DCFCrystal is a multistage predictor that can estimate the success propensities of the three individual steps (production of protein material, purification and production of crystals) in the protein crystallization process. MDCFCrystal is a single-stage predictor that aims to estimate the probability that a protein will pass through the entire crystallization process. Moreover, DCFCrystal is designed for general proteins, whereas MDCFCrystal is specially designed for membrane proteins, which are notoriously difficult to crystalize. DCFCrystal and MDCFCrystal were separately tested on two benchmark datasets consisting of 12 289 and 950 proteins, respectively, with known crystallization results from various experimental records. The experimental results demonstrated that DCFCrystal and MDCFCrystal increased the value of Matthew’s correlation coefficient by 199.7% and 77.8%, respectively, compared to the best of other state-of-the-art protein crystallization propensity predictors. Detailed analyses show that the major advantages of DCFCrystal and MDCFCrystal lie in the efficiency of the DCF model and the sensitivity of the sequence-based features used, especially the newly designed pseudo-predicted hybrid solvent accessibility (PsePHSA) feature, which improves crystallization recognition by incorporating sequence-order information with solvent accessibility of residues. Meanwhile, the new crystal-dataset constructions help to train the models with more comprehensive crystallization knowledge.

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A simple and efficient innovation of the vapor-diffusion method for controlling nucleation and growth of large protein crystals

Journal of Applied Crystallography ◽

10.1107/s0021889801004666 ◽

2001 ◽

Vol 34 (3) ◽

pp. 388-391 ◽

Cited By ~ 7

Author(s):

Genpei Li ◽

Ye Xiang ◽

Ying Zhang ◽

Da-Cheng Wang

Keyword(s):

Crystallization Process ◽

Protein Crystallization ◽

Protein Crystals ◽

Diffusion Method ◽

Capillary Barrier ◽

Large Protein ◽

Vapor Diffusion ◽

Crystallization Experiments ◽

Water Vaporization ◽

Improved Technique

The rate of water vaporization in the vapor-diffusion method is critical for the protein crystallization process. Present methods, however, allow little or no control of the equilibration rates. This paper presents a relatively simple innovation of the conventional vapor-diffusion method by introducing a capillary barrier (for hanging drop) or a punched film barrier (for both hanging and sitting drop) between drop and reservoir, which can be beneficial in controlling the water vaporization rate, thereby promoting growth of large protein crystals. The crystallization experiments for lysozyme, trichosanthin and a novel neurotoxin BmK Mu9 show that this modified vapor-controlling-diffusion method is very effective for producing large protein crystals. The improved technique can be routinely used as a method for the preparation of other macromolecular and small-molecule crystals whose crystallization involves vaporization of water.

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Effect of mechanical vibration on protein crystallization

Journal of Applied Crystallography ◽

10.1107/s0021889810009313 ◽

2010 ◽

Vol 43 (3) ◽

pp. 473-482 ◽

Cited By ~ 13

Author(s):

Qin-Qin Lu ◽

Da-Chuan Yin ◽

Yong-Ming Liu ◽

Xi-Kai Wang ◽

Peng-Fei Yang ◽

...

Keyword(s):

Crystallization Process ◽

Protein Crystallization ◽

Mechanical Vibration ◽

Supersaturated Solution ◽

Factors Influencing ◽

Crystallization Conditions ◽

Temperature Controlled

Mechanical vibration often occurs during protein crystallization; however, it is seldom considered as one of the factors influencing the crystallization process. This paper reports an investigation of the crystallization of five proteins using various crystallization conditions in a temperature-controlled chamber on the table of a mechanical vibrator. The results show that mechanical vibration can reduce the number of crystals and improve their optical perfection. During screening of the crystallization conditions it was found that mechanical vibration could help to obtain crystals in a highly supersaturated solution in which amorphous precipitates often normally appear. It is concluded that mechanical vibration can serve as a tool for growing optically perfect crystals or for obtaining more crystallization conditions during crystallization screening.

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Development and Workflow of a Continuous Protein Crystallization Process: A Case of Lysozyme

Crystal Growth & Design ◽

10.1021/acs.cgd.8b01534 ◽

2019 ◽

Vol 19 (2) ◽

pp. 983-991 ◽

Cited By ~ 14

Author(s):

Huaiyu Yang ◽

Wenqian Chen ◽

Peter Peczulis ◽

Jerry Y. Y. Heng

Keyword(s):

Crystallization Process ◽

Protein Crystallization

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Influence of divalent cations in protein crystallization

Protein Science ◽

10.1002/pro.5560040925 ◽

1995 ◽

Vol 4 (9) ◽

pp. 1914-1919 ◽

Cited By ~ 36

Author(s):

Sergei Trakhanov ◽

Florante A. Quiocho

Keyword(s):

Divalent Cations ◽

Protein Crystallization

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Ultrastructural Localization of Acid Mucosubstance in Skeletal Muscle

Proceedings, annual meeting, Electron Microscopy Society of America ◽

10.1017/s0424820100060271 ◽

1967 ◽

Vol 25 ◽

pp. 52-53 ◽

Cited By ~ 2

Author(s):

William J. Dougherty ◽

Samuel S. Spicer

Keyword(s):

Striated Muscle ◽

Divalent Cations ◽

Ultrastructural Localization ◽

Major Elements ◽

Frozen Sections ◽

Thorium Dioxide ◽

Iron Solution ◽

Coupling System ◽

Psoas Muscles ◽

Formalin Fixed

In recent years, considerable attention has focused on the morphological nature of the excitation-contraction coupling system of striated muscle. Since the study of Porter and Palade, it has become evident that the sarcoplastic reticulum (SR) and transverse tubules constitute the major elements of this system. The problem still exists, however, of determining the mechamisms by which the signal to interdigitate is presented to the thick and thin myofilaments. This problem appears to center on the movement of Ca++ions between myofilaments and SR. Recently, Philpott and Goldstein reported acid mucosubstance associated with the SR of fish branchial muscle using the colloidal thorium dioxide technique, and suggested that this material may serve to bind or release divalent cations such as Ca++. In the present study, Hale's iron solution adapted to electron microscopy was applied to formalin-fixed myofibrils isolated from glycerol-extracted rabbit psoas muscles and to frozen sections of formalin-fixed rat psoas muscles.

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