Sodium channel mutation leading to saxitoxin resistance in clams increases risk of PSP

V. Monica Bricelj; Laurie Connell; Keiichi Konoki; Scott P. MacQuarrie; Todd Scheuer; William A. Catterall; Vera L. Trainer

doi:10.1038/nature03415

Sodium channel mutation leading to saxitoxin resistance in clams increases risk of PSP

V. Monica Bricelj, Laurie Connell, Keiichi Konoki, Scott P. MacQuarrie, Todd Scheuer, William A. Catterall, Vera L. Trainer

Research output: Contribution to journal › Article › peer-review

254 Citations (Scopus)

Abstract

Bivalve molluscs, the primary vectors of paralytic shellfish poisoning (PSP) in humans, show marked inter-species variation in their capacity to accumulate PSP toxins (PSTs) which has a neural basis. PSTs cause human fatalities by blocking sodium conductance in nerve fibres. Here we identify a molecular basis for inter-population variation in PSP resistance within a species, consistent with genetic adaptation to PSTs. Softshell clams (Mya arenaria) from areas exposed to 'red tides' are more resistant to PSTs, as demonstrated by whole-nerve assays, and accumulate toxins at greater rates than sensitive clams from unexposed areas. PSTs lead to selective mortality of sensitive clams. Resistance is caused by natural mutation of a single amino acid residue, which causes a 1,000-fold decrease in affinity at the saxitoxin-binding site in the sodium channel pore of resistant, but not sensitive, clams. Thus PSTs might act as potent natural selection agents, leading to greater toxin resistance in clam populations and increased risk of PSP in humans. Furthermore, global expansion of PSP to previously unaffected coastal areas might result in long-term changes to communities and ecosystems.

Original language	English
Pages (from-to)	763-767
Number of pages	5
Journal	Nature
Volume	434
Issue number	7034
DOIs	https://doi.org/10.1038/nature03415
Publication status	Published - 2005 Apr 7
Externally published	Yes

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This output contributes to the following UN Sustainable Development Goals (SDGs)

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@article{3dd07ca1452e47f2b05cc905c69863dd,

title = "Sodium channel mutation leading to saxitoxin resistance in clams increases risk of PSP",

abstract = "Bivalve molluscs, the primary vectors of paralytic shellfish poisoning (PSP) in humans, show marked inter-species variation in their capacity to accumulate PSP toxins (PSTs) which has a neural basis. PSTs cause human fatalities by blocking sodium conductance in nerve fibres. Here we identify a molecular basis for inter-population variation in PSP resistance within a species, consistent with genetic adaptation to PSTs. Softshell clams (Mya arenaria) from areas exposed to 'red tides' are more resistant to PSTs, as demonstrated by whole-nerve assays, and accumulate toxins at greater rates than sensitive clams from unexposed areas. PSTs lead to selective mortality of sensitive clams. Resistance is caused by natural mutation of a single amino acid residue, which causes a 1,000-fold decrease in affinity at the saxitoxin-binding site in the sodium channel pore of resistant, but not sensitive, clams. Thus PSTs might act as potent natural selection agents, leading to greater toxin resistance in clam populations and increased risk of PSP in humans. Furthermore, global expansion of PSP to previously unaffected coastal areas might result in long-term changes to communities and ecosystems.",

author = "Bricelj, {V. Monica} and Laurie Connell and Keiichi Konoki and MacQuarrie, {Scott P.} and Todd Scheuer and Catterall, {William A.} and Trainer, {Vera L.}",

note = "Funding Information: Acknowledgements We thank B. M. Twarog, whose seminal work in the 1970s inspired this study, for conducting the initial nerve tests; P. Chang for participating in the burrowing experiment; M. Quilliam and the IMB analytical toxins group for providing STX for nerve tests; and E. M. Sharp and M. Iszard for technical assistance. This work was supported by a US NOAA-ECOHAB grant to V.L.T. and V.M.B., a NOAA-ECOHAB grant to L.C., V.L.T. and V.M.B., and an NIH research grant to W.A.C. Funding Information: Acknowledgements We thank A. Correa for advice regarding the cut-open oocyte voltage clamp; S. Durham for advice regarding the statistical analysis; C. Feldman and M. Pfrender for advice regarding the phylogenetic analysis; J. Caldwell for primers; A. Goldin for sharing his sodium channel sequence alignment; and C. Hanifin and the USU herpetology group for comments that improved the manuscript. This work was supported by research grants from the National Institute of Health (P.C.R.) and from the National Science Foundation (E.D.B. Jr and E.D.B. III).",

year = "2005",

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doi = "10.1038/nature03415",

language = "English",

volume = "434",

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T1 - Sodium channel mutation leading to saxitoxin resistance in clams increases risk of PSP

AU - Bricelj, V. Monica

AU - Connell, Laurie

AU - Konoki, Keiichi

AU - MacQuarrie, Scott P.

AU - Scheuer, Todd

AU - Catterall, William A.

AU - Trainer, Vera L.

N1 - Funding Information: Acknowledgements We thank B. M. Twarog, whose seminal work in the 1970s inspired this study, for conducting the initial nerve tests; P. Chang for participating in the burrowing experiment; M. Quilliam and the IMB analytical toxins group for providing STX for nerve tests; and E. M. Sharp and M. Iszard for technical assistance. This work was supported by a US NOAA-ECOHAB grant to V.L.T. and V.M.B., a NOAA-ECOHAB grant to L.C., V.L.T. and V.M.B., and an NIH research grant to W.A.C. Funding Information: Acknowledgements We thank A. Correa for advice regarding the cut-open oocyte voltage clamp; S. Durham for advice regarding the statistical analysis; C. Feldman and M. Pfrender for advice regarding the phylogenetic analysis; J. Caldwell for primers; A. Goldin for sharing his sodium channel sequence alignment; and C. Hanifin and the USU herpetology group for comments that improved the manuscript. This work was supported by research grants from the National Institute of Health (P.C.R.) and from the National Science Foundation (E.D.B. Jr and E.D.B. III).

PY - 2005/4/7

Y1 - 2005/4/7

N2 - Bivalve molluscs, the primary vectors of paralytic shellfish poisoning (PSP) in humans, show marked inter-species variation in their capacity to accumulate PSP toxins (PSTs) which has a neural basis. PSTs cause human fatalities by blocking sodium conductance in nerve fibres. Here we identify a molecular basis for inter-population variation in PSP resistance within a species, consistent with genetic adaptation to PSTs. Softshell clams (Mya arenaria) from areas exposed to 'red tides' are more resistant to PSTs, as demonstrated by whole-nerve assays, and accumulate toxins at greater rates than sensitive clams from unexposed areas. PSTs lead to selective mortality of sensitive clams. Resistance is caused by natural mutation of a single amino acid residue, which causes a 1,000-fold decrease in affinity at the saxitoxin-binding site in the sodium channel pore of resistant, but not sensitive, clams. Thus PSTs might act as potent natural selection agents, leading to greater toxin resistance in clam populations and increased risk of PSP in humans. Furthermore, global expansion of PSP to previously unaffected coastal areas might result in long-term changes to communities and ecosystems.

AB - Bivalve molluscs, the primary vectors of paralytic shellfish poisoning (PSP) in humans, show marked inter-species variation in their capacity to accumulate PSP toxins (PSTs) which has a neural basis. PSTs cause human fatalities by blocking sodium conductance in nerve fibres. Here we identify a molecular basis for inter-population variation in PSP resistance within a species, consistent with genetic adaptation to PSTs. Softshell clams (Mya arenaria) from areas exposed to 'red tides' are more resistant to PSTs, as demonstrated by whole-nerve assays, and accumulate toxins at greater rates than sensitive clams from unexposed areas. PSTs lead to selective mortality of sensitive clams. Resistance is caused by natural mutation of a single amino acid residue, which causes a 1,000-fold decrease in affinity at the saxitoxin-binding site in the sodium channel pore of resistant, but not sensitive, clams. Thus PSTs might act as potent natural selection agents, leading to greater toxin resistance in clam populations and increased risk of PSP in humans. Furthermore, global expansion of PSP to previously unaffected coastal areas might result in long-term changes to communities and ecosystems.

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EP - 767

JO - Nature

JF - Nature

IS - 7034

ER -

Sodium channel mutation leading to saxitoxin resistance in clams increases risk of PSP

Abstract

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