Abstract
Hereditary hyperekplexia, or startle disease, is a neuromotor disorder caused mainly by mutations that either prevent the surface expression of, or modify the function of, the human heteromeric α1 β glycine receptor (GlyR) chloride channel. There is as yet no explanation as to why hyperekplexia mutations that modify channel function are almost exclusively located in the α1 to the exclusion of β subunit. The majority of these mutations are identified in the M2–M3 loop of the α1 subunit. Here we demonstrate that α1 β GlyR channel function is less sensitive to hyperekplexia-mimicking mutations introduced into the M2–M3 loop of the β than into the α1 subunit. This suggests that the M2–M3 loop of the α subunit dominates the β subunit in gating the α1 β GlyR channel. A further attempt to determine the possible mechanism underlying this phenomenon by using the voltage-clamp fluorometry technique revealed that agonist-induced conformational changes in the β subunit M2–M3 loop were uncoupled from α1 β GlyR channel gating. This is in contrast to the α subunit, where the M2–M3 loop conformational changes were shown to be directly coupled to α1 β GlyR channel gating. Finally, based on analysis of α1 β chimeric receptors, we demonstrate that the structural components responsible for this are distributed throughout the β subunit, implying that the β subunit has evolved without the functional constraint of a normal gating pathway within it. Our study provides a possible explanation of why hereditary hyperekplexia-causing mutations that modify α1 β GlyR channel function are almost exclusively located in the α1 to the exclusion of the β subunit.
Highlights
Imbalance between the excitatory and inhibitory neurotransmission systems is the cause of many neurological disorders
We examined conformational changes that the M2–M3 loops of the a1 and b subunits experienced during channel gating by using voltage-clamp fluorometry (VCF)
The concentration-response curves of fluorescence and current overlapped and the respective glycine EC50 value was not significantly different from each other (329657 mM and 396631 mM, respectively, p.0.05, Table 2). This implies that the conformational changes of the a1 M2–M3 loop are coupled to the channel gating in the a1 b glycine receptor (GlyR), which is similar to the situation previously demonstrated in the homomeric a1R199C GlyR [33]
Summary
Imbalance between the excitatory and inhibitory neurotransmission systems is the cause of many neurological disorders. We concentrated on one of the essential structural components of the channel gating pathway, the M2–M3 loop (Fig. 2A) Mutations in this region have been shown to cause drastic effects on channel function in many members of the Cys-loop receptor superfamily [18,19,20,21]. This region of the GlyR a1 subunit hosts mutations responsible for most cases of hereditary hyperekplexia, such as R271(199)Q/L, K276(249)E, and Y279(279)C [1,4,20]. Our study provides a possible explanation of why hereditary hyperekplexiacausing mutations that modify a1 b GlyR channel function are almost exclusively located in the a1 to the exclusion of the b subunit
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