A modified nicotinic acetylcholine receptor lacking the ‘ion channel amphipathic helices’

Monoclonal antibodies (mAbs) were derived from mice immunized with synthetic peptide sequence regions of the alpha subunit of the nicotinic acetylcholine receptor from Torpedo electric tissue (TAChR). Sequence-specific mAbs were obtained against the following peptides: alpha 1-20, alpha 291-308, alpha 304-322, alpha 332-350, alpha 346-364, alpha 360-378, alpha 376-393, alpha 390-409, and alpha 420-437. The ability of mAbs to recognize native TAChR was quantitated by immunoprecipitation of TAChR solubilized in the nondenaturing detergent Triton X-100. mAbs against peptide alpha 304-322, alpha 332-350, and alpha 360-378 cross-reacted with most or all Triton-solubilized TAChR molecules and, in immunoelectron microscopy experiments, bound to the cytoplasmic surface of AChR-rich postsynaptic membrane fragments. Two mAbs specific for the sequence alpha 376-393, proposed to form an amphypathic alpha helix possibly involved in formation of the ion channel, recognized only approximately 35% of Triton-solubilized TAChR molecules and did not react with membrane-bound TAChR. All of these sequence-specific antibodies recognized SDS-denatured TAChR alpha subunit in Western blots. MAbs specific for the amino-terminal sequence region of the alpha subunit, alpha 1-20, and for the sequences alpha 291-308, alpha 346-364, and alpha 390-409 did not recognize native TAChR. A mAb directed against the carboxyl-terminal region, alpha 420-437, recognized with low apparent titer Triton-solubilized TAChR, not membrane-bound TAChR. In conclusion, a complex membrane protein, TAChR, contains several continuous sequence segments exposed on the TAChR surface, because different mAbs raised against certain synthetic sequences recognized most or all native TAChR molecules. By analogy, it should be possible for most proteins of known sequence to raise anti-peptide antibodies fully cross-reactive with the native cognate protein.

Section: Discussionmentioning

confidence: 93%

Monoclonal antibodies against synthetic sequences of the nicotinic receptor cross-react fully with the native receptor and reveal the transmembrane disposition of their epitopes

Liu

Raftery²,

Conti‐Tronconi³

1993

“…Furthermore, the titers of antigen recognized by the antibodies in these experiments were very low, an observation which suggests that the sites at which colloidal gold was attached were denatured forms of the ß polypeptide. In a more recent experiment (Roth et al, 1987),…”

mentioning

confidence: 97%

“…Nevertheless, deletion of all or part of the amphipathic helix region of the a subunit diminishes but does not abolish channel activity. Recently, Roth et al (1987) prepared, by limited proteolytic digestion, a form of acetylcholine receptor that also seems to be missing entirely the sequence from the a subunit whose pattern is that of an amphipathic helix. No details of the effect of this degradation on the function of the protein or its structure were, however, presented.…”

mentioning

confidence: 99%

Evidence for the extramembranous location of the putative amphipathic helix of acetylcholine receptor

Dwyer

1988

Evidence has been obtained demonstrating that the peptides GVKYIAE and AIKYIAE found in the potential amphipathic helices of the alpha and beta subunits, respectively, of acetylcholine receptor are not buried in the membrane. The peptide KYIAE was synthesized, and polyclonal antibodies were prepared against a conjugate of bovine serum albumin and synthetic peptide. An immunoadsorbent capable of binding and subsequently releasing peptides ending with the sequence-YIAE was produced by attaching these specific antibodies to agarose. Native acetylcholine receptor was labeled with pyridoxal phosphate and Na[3H]BH4. The labeled protein was stripped of phospholipid and digested with the protease from Staphylococcus aureus strain V8. The digest was submitted to immunoadsorption to isolate the labeled indigenous peptides. As a control, alpha and beta polypeptides prepared by gel filtration of a solution of acetylcholine receptor in detergent were stripped of detergent and labeled with pyridoxal phosphate and Na[3H]BH4 in the presence of 8 M urea. The labeled alpha and beta polypeptides were digested and submitted to immunoadsorption. The specific radioactivities of the indigenous peptides from the alpha and beta subunits labeled under native and denaturing conditions were nearly equal. In similar experiments using isethionyl (2', 4'-dinitrophenyl)-3-amino-propionimidate as the labeling agent, the indigenous peptides from native and denatured receptor were also labeled to the same extent. Since these peptides are labeled to the same extent whether or not the protein is denatured, they cannot be buried in the membrane.

“…Additionally, each contains a segment of amino acids between the third and fourth hydrophobic segments that displays the pattern predicted for an amphipathic helix. It had been suggested that each amphipathic helix from each subunit spans the membrane and that together they form the lining of the ion channel (Finer-Moore & Stroud, 1984;Guy, 1984), but it has been shown that these regions of the sequences are fully exposed to the aqueous phase (Ratnam et al, 1986b;Roth et al, 1987;Dwyer, 1988).…”

mentioning

confidence: 99%

Topological dispositions of lysine .alpha.380 and lysine .gamma.486 in the acetylcholine receptor from Torpedo californica

Dwyer¹

1991

The locations have been determined, with respect to the plasma membrane, of lysine alpha 380 and lysine gamma 486 in the alpha subunit and the gamma subunit, respectively, of the nicotinic acetylcholine receptor from Torpedo californica. Immunoadsorbents were constructed that recognize the carboxy terminus of the peptide GVKYIAE released by proteolytic digestion from positions 378-384 in the amino acid sequence of the alpha subunit of the acetylcholine receptor and the carboxy terminus of the peptide KYVP released by proteolytic digestion from positions 486-489 in the amino acid sequence of the gamma subunit. They were used to isolate these peptides from proteolytic digests of polypeptides from the acetylcholine receptor. Sealed vesicles containing the native acetylcholine receptor were labeled with pyridoxal phosphate and sodium [3H]-borohydride. Saponin was added to a portion of the vesicles prior to labeling to render them permeable to pyridoxal phosphate. The effect of saponin on the incorporation of pyridoxamine phosphate into lysine alpha 380 and lysine gamma 486 from the acetylcholine receptor in these vesicles was assessed with the immunoadsorbents. The peptides bound and released by the immunoadsorbents were positively identified and quantified by high-pressure liquid chromatography. Modification of lysine alpha 380 in the native acetylcholine receptor in sealed vesicles increased 5-fold in the presence of saponin, while modification of lysine gamma 486 was unaffected by the presence of saponin. The conclusions that follow from these results are that lysine alpha 380 is on the inside surface of a vesicle and lysine gamma 486 is on the outside surface.(ABSTRACT TRUNCATED AT 250 WORDS)