Dan E. Meyer scite author profile

Elastin-like polypeptides (ELPs) undergo a reversible, inverse phase transition. Below their transition temperature (Tt), ELPs are soluble in water, but when the temperature is raised above Tt, phase transition occurs, leading to aggregation of the polypeptide. We demonstrate a method for purification of soluble fusion proteins incorporating an ELP tag. Advantages of this method, termed "inverse transition cycling," include technical simplicity, low cost, ease of scale-up, and capacity for multiplexing. More broadly, the ability to environmentally modulate the physicochemical properties of recombinant proteins by fusion with ELPs will allow diverse applications in bioseparation, immunoassays, biocatalysis, and drug delivery.

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Quantification of the Effects of Chain Length and Concentration on the Thermal Behavior of Elastin-like Polypeptides

Meyer

2004

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At a specific temperature, elastin-like polypeptides (ELPs) undergo a sharp solubility transition that can be exploited in a variety of applications in biotechnology and medicine. The temperature of the transition varies with ELP sequence, molecular weight, and concentration. We present a single equation of three parameters that quantitatively predicts the transition temperature as a function of ELP length and concentration for an ELP of a fixed composition. This model should be useful both for the design of new ELP sequences that exhibit a desired transition temperature and for the selection of variables to trigger the phase transition of an ELP for a given application.

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Genetically Encoded Synthesis of Protein-Based Polymers with Precisely Specified Molecular Weight and Sequence by Recursive Directional Ligation: Examples from the Elastin-like Polypeptide System

2002

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We report a new strategy for the synthesis of genes encoding repetitive, protein-based polymers of specified sequence, chain length, and architecture. In this stepwise approach, which we term "recursive directional ligation" (RDL), short gene segments are seamlessly combined in tandem using recombinant DNA techniques. The resulting larger genes can then be recursively combined until a gene of a desired length is obtained. This approach is modular and can be used to combine genes encoding different polypeptide sequences. We used this method to synthesize three different libraries of elastin-like polypeptides (ELPs); each library encodes a unique ELP sequence with systematically varied molecular weights. We also combined two of these sequences to produce a block copolymer. Because the thermal properties of ELPs depend on their sequence and chain length, the synthesis of these polypeptides provides an example of the importance of precise control over these parameters that is afforded by RDL.

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Targeted drug delivery by thermally responsive polymers

Chilkoti

Dreher

Meyer

et al. 2002

Advanced Drug Delivery Reviews

545

368

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Drug targeting using thermally responsive polymers and local hyperthermia

Meyer

Shin

Kong

et al. 2001

Journal of Controlled Release

395

299

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Dan E. Meyer

Purification of recombinant proteins by fusion with thermally-responsive polypeptides

Quantification of the Effects of Chain Length and Concentration on the Thermal Behavior of Elastin-like Polypeptides

Genetically Encoded Synthesis of Protein-Based Polymers with Precisely Specified Molecular Weight and Sequence by Recursive Directional Ligation: Examples from the Elastin-like Polypeptide System

Targeted drug delivery by thermally responsive polymers

Drug targeting using thermally responsive polymers and local hyperthermia

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