Justin P. Gallivan

In vivo incorporation of unnatural amino acids into ion channels in Xenopus oocyte expression system

A general method for the incorporation of unnatural amino acids into ion channels and membrane receptors using a Xenopus oocyte expression system has been described. A large number of unnatural amino acids have been incorporated into the nAChR, GIRK, and Shaker K+ channels. Continuing efforts focus on incorporating unnatural amino acids that differ substantially from the natural amino acids, for example, residues that include fluorophores. In addition, we are addressing the feasibility of incorporating unnatural amino acids into ion channels and membrane receptors in mammalian cells.

Emerging Applications of Riboswitches in Chemical Biology

Living systems use RNA sequences known as riboswitches to detect the concentrations of small-molecule metabolites within cells and to regulate the expression of genes that produce these metabolites. Like their natural counterparts, synthetic riboswitches also regulate gene expression in response to small molecules. Because synthetic riboswitches can be engineered to respond to nonendogenous small molecules, they are powerful tools for chemical and synthetic biologists interested in understanding and reprogramming cellular behavior. In this review, we present an overview of natural riboswitches, highlight recent studies toward developing synthetic riboswitches and provide an overview of emerging applications of these RNA switches in chemical biology.

Site-specific incorporation of biotinylated amino acids to identify surface-exposed residues in integral membrane proteins

BACKGROUND A key structural issue for all integral membrane proteins is the exposure of individual residues to the intracellular or extracellular media. This issue involves the basic transmembrane topology as well as more subtle variations in surface accessibility. Direct methods to evaluate the degree of exposure for residues in functional proteins expressed in living cells would be highly valuable. We sought to develop a new experimental method to determine highly surface-exposed residues, and thus transmembrane topology of membrane proteins expressed in Xenopus oocytes. RESULTS We have used the in vivo nonsense suppression technique to incorporate biotinylated unnatural amino acids into functional ion channels expressed in Xenopus oocytes. Binding of 125I-streptavidin to biotinylated receptors was used to determine the surface exposure of individual amino acids. In particular, we studied the main immunogenic region of the nicotinic acetylcholine receptor. The biotin-containing amino acid biocytin was efficiently incorporated into five sites in the main immunogenic region and extracellular streptavidin bound to one residue in particular, alpha 70. The position of alpha 70 as highly exposed on the receptor surface was thus established. CONCLUSIONS The in vivo nonsense suppression technique has been extended to provide the first in a potential series of methods to identify exposed residues and to assess their relative exposure in functional proteins expressed in Xenopus oocytes.

Riboswitches in unexpected places—A synthetic riboswitch in a protein coding region

In natural and engineered systems, cis-RNA regulatory elements such as riboswitches are typically found within untranslated regions rather than within the protein coding sequences of genes. However, RNA sequences with important regulatory roles can exist within translated regions. Here, we present a synthetic riboswitch that is encoded within the translated region of a gene and represses Escherichia coli gene expression greater than 25-fold in the presence of a small-molecule ligand. The ability to encode riboswitches within translated regions as well as untranslated regions provides additional opportunities for creating new genetic control elements. Furthermore, evidence that a riboswitch can function in the translated region of a gene suggests that future efforts to identify natural riboswitches should consider this possibility.

Retraction: Reprogramming bacteria to seek and destroy an herbicide

The authors wish to retract their article. While performing further studies on the riboswitch reported in the article, a postdoctoral researcher in our laboratory was unable to reproduce the results reported in Figure 4.