Probing the role of a conserved M1 proline residue in 5-hydroxytryptamine(3) receptor gating.

A conserved proline residue is found in the first transmembrane domain (M1) of every subunit in the ligand-gated ion channel superfamily. The position of this proline between the N-terminal extracellular agonist binding and the second transmembrane (M2) channel lining domains in the primary sequence suggests its possible involvement in the gating of the receptor. Replacing this proline with alanine, glycine, or leucine in the 5-hydroxytryptamine (5-HT)(3A) homomeric receptors expressed in Xenopus laevis oocytes resulted in the absence of 5-HT-induced whole-cell currents, although there were normal levels of specific surface [(3)H]granisetron ([(3)H]BRL-43694) binding sites. To determine what properties of the conserved proline are critical for the function of the channel, two imino acids and an alpha-hydroxy acid were incorporated at the proline position using the nonsense suppression method. trans-3-Methyl-proline, pipecolic acid, and leucic acid were able to replace the conserved proline to produce active channels with EC(50) values similar to that for the wild-type receptor. These trends are preserved in the heteromeric receptors consisting of 5-HT(3A) and 5-HT(3B) subunits in oocytes. The prominent common feature among these residues and proline is the lack of hydrogen bond donor activity, potentially resulting in a flexible secondary structure in the M1 region. Thus, lack of hydrogen bond donor activity may be a key element in channel gating and may explain the high degree of conservation of this M1 proline.

Mapping disulfide connectivity using backbone ester hydrolysis.

The site-specific incorporation of alpha-hydroxy acids into proteins using nonsense suppression can provide a powerful probe of protein structure and function. The resulting backbone ester may be selectively hydrolyzed in the presence of the peptide backbone, providing an "orthogonal" chemistry that can be useful both as an analytical tool and as a structural probe. Here we describe in detail a substantial substituent effect on this hydrolysis reaction. Consistent with mechanistic expectations, the steric bulk of the amino acid immediately N-terminal of the hydroxy acid has a large effect on the hydrolysis rate. On the basis of these results, we also describe a simple protocol for identifying disulfide loops in soluble and membrane proteins, exemplified by the alpha subunit of the muscle nicotinic acetylcholine receptor (nAChR). If a backbone ester is incorporated outside a disulfide loop, hydrolysis alone gives two fragments, but if the ester is incorporated within a disulfide loop, both hydrolysis and reduction are required for cleavage. This test could be useful in characterizing the disulfide topology of complex, membrane proteins.

Backbone mutations in transmembrane domains of a ligand-gated ion channel: implications for the mechanism of gating.

An approach to identify backbone conformational changes underlying nicotinic acetylcholine receptor (nAChR) gating was developed. Specific backbone peptide bonds were replaced with an ester, which disrupts backbone hydrogen bonds at the site of mutation. At a conserved proline residue (alphaPro221) in the first transmembrane (M1) domain, the amide-to-ester mutation provides receptors with near-normal sensitivity, although the natural amino acids tested other than Pro produce receptors that gate with a much larger EC50 than normal. Therefore, a backbone hydrogen bond at this site may interfere with normal gating. In the alphaM2 domain, the amide-to-ester mutation yielded functional receptors at 15 positions, 3 of which provided receptors with >10-fold lower EC50 than wild type. These results support a model for gating that includes significant changes of backbone conformation within the M2 domain.

Flash decaging of tyrosine sidechains in an ion channel.

A nonsense codon suppression technique was employed to incorporate ortho-nitrobenzyl tyrosine, "caged tyrosine," in place of tyrosine at any of three positions (93, 127, or 198) in the alpha subunit of the muscle nicotinic ACh receptor (nAChR) expressed in Xenopus oocytes. The ortho-nitrobenzyl group was then removed by 1 ms flashes at 300-350 nm to yield tyrosine itself while macroscopic currents were recorded during steady ACh exposure. Responses to multiple flashes showed (1) that each flash decages up to 17% of the tyrosines and (2) that two tyrosines must be decaged per receptor for a response. The conductance relaxations showed multiple kinetic components; rate constants (<0.1 s(-1) to 10(3) s(-1)) depended on pH and the site of incorporation, and relative amplitudes depended on the number of prior flashes. This method, which is potentially quite general, (1) provides a time-resolved assay for the behavior of a protein when a mutant sidechain is abruptly changed to the wild-type residue and (2) will also allow for selective decaging of sidechains that are candidates for covalent modification (such as phosphorylation) in specific proteins in intact cells.

Site-specific, photochemical proteolysis applied to ion channels in vivo.

A method for site-specific, nitrobenzyl-induced photochemical proteolysis of diverse proteins expressed in living cells has been developed based on the chemistry of the unnatural amino acid (2-nitrophenyl)glycine (Npg). Using the in vivo nonsense codon suppression method for incorporating unnatural amino acids into proteins expressed in Xenopus oocytes, Npg has been incorporated into two ion channels: the Drosophila Shaker B K+ channel and the nicotinic acetylcholine receptor. Functional studies in vivo show that irradiation of proteins containing an Npg residue does lead to peptide backbone cleavage at the site of the novel residue. Using this method, evidence is obtained for an essential functional role of the "signature" Cys128-Cys142 disulfide loop of the nAChR alpha subunit.

IS900-promoted stable integration of a foreign gene into mycobacteria.

An artificial mycobacterial transposon was constructed by placing two copies of the insertion sequence IS900 flanking a kanamycin resistance gene into a non-(mycobacterial) replicating vector. Constructs were introduced into mycobacteria by electroporation and transposition events conferring kanamycin resistance were selected. Integration of IS900 into several genomic sites was analysed by Southern blotting and shown to involve both simple insertions and cointegrate formation, suggesting that IS900 can transpose by a replicative mechanism. Kanamycin resistance of IS900-integrated transformants was shown to be stable in the absence of selection.