Nature Genetics homepage
Advanced search
 Journal home > Archive > Table of Contents > Article > Abstract
Journal home
Advance online publication
Current issue
Archive
Press releases
Free Association (blog)
Supplements
Focuses
Guide to authors
Online submissionOnline submission
For referees
Free online issue
Contact the journal
Subscribe
Advertising
work@npg
Reprints and permissions
About this site
For librarians
 
NPG Resources
Nature
Nature Biotechnology
Nature Cell Biology
Nature Medicine
Nature Methods
Nature Reviews Cancer
Nature Reviews Genetics
Nature Reviews Molecular Cell Biology
news@nature.com
Nature Conferences
RNAi Gateway
NPG Subject areas
Biotechnology
Cancer
Chemistry
Clinical Medicine
Dentistry
Development
Drug Discovery
Earth Sciences
Evolution & Ecology
Genetics
Immunology
Materials Science
Medical Research
Microbiology
Molecular Cell Biology
Neuroscience
Pharmacology
Physics
Browse all publications
Article
Nature Genetics  7, 136 - 142 (1994)
doi:10.1038/ng0694-136

Glycine receptor bold beta−subunit gene mutation in spastic mouse associated with LINE−1 element insertion

Stephen F. Kingsmore1, 4, 5, Bruno Giros2, David Suh1, Mark Bieniarz1, Marc G. Caron1, 2 & Michael F. Seldin1, 3

  1Department of Medicine, Duke University Medical Center, Durham, North Carolina 27710, USA

  2Department of Cell Biology and Howard Hughes Medical Institute Laboratories, Duke University Medical Center, Durham, North Carolina 27710, USA

  3Department of Microbiology, Duke University Medical Center, Durham, North Carolina 27710, USA

  4New address: PO Box 100221, University of Florida, Gainesville, Florida 32610, USA

  5Correspondence should be addressed to S.F.K.

Congenital myoclonus is a widespread neurologic disorder characterized by hyperexcitability, muscular spasticity and myoclonus associated with marked reduction in neural glycine binding sites. The recessive mouse mutation spastic (spa) is a prototype of inherited myoclonus. Here we show that defects in the gene encoding the beta−subunit of the glycine receptor (Glrb) underlie spa: Glrb maps to the same region of mouse chromosome 3 as spa, and Glrb mRNA is markedly reduced throughout brains of spa mice, most likely as a result of an insertional mutation of a 7.1 kilobase LINE−1 element within intron 6 of Glrb. These results provide evidence that Glrb is necessary for postsynaptic expression of glycine receptor complexes, and suggest Glrb as a candidate gene for inherited myoclonus in other species.

REFERENCES
  1. Betz, H. Structure and function of inhibitory glycine receptors. Quart. Rev. Biophys. 25, 381−394 (1992). | ISI | ChemPort |
  2. Betz, H. Ligand-gated ion channels in the brain: the amino acid receptor family. Neuron 5, 383−392 (1990). | Article | PubMed  | ISI | ChemPort | Add to Connotea (beta) |
  3. Grenningloh, G. et al. The strychnine-binding subunit of the glycine receptor shows homology with nicotinic acetylcholine receptors. Nature 328, 215−220 (1987). | Article | PubMed  | ISI | ChemPort | Add to Connotea (beta) |
  4. Kuhse, J., Schmieden, V. & Betz, H. Identification and functional expression of a novel ligand binding subunit of the inhibitory glycine receptor. J. biol. Chem. 265, 22317−22320 (1990). | PubMed  | ISI | ChemPort | Add to Connotea (beta)  |
  5. Kuhse, J., Schmieden, V. & Betz, H. A single amino acid exchange alters the pharmacology of neonatal rat glycine receptor subunit. Neuron 5, 867−873 (1990). | PubMed  | ISI | ChemPort | Add to Connotea (beta)  |
  6. Grenningloh, G. et al. Cloning and expression of the 58 kd beta subunit of the inhibitory glycine receptor. Neuron 4, 963−970 (1990). | Article | PubMed  | ISI | ChemPort | Add to Connotea (beta) |
  7. Schmieden, V., Kuhse, J. & Betz, H. Agonist pharmacology of neonatal and adult glycine receptor alpha subunits: identification of amino acid residues involved in taurine activation. EMBO J. 11, 2025−2032 (1992). | PubMed  | ISI | ChemPort | Add to Connotea (beta)  |
  8. Schmieden, V., Grenningloh, G., Schofield, P.R. & Betz, H. Functional expression in Xenopus oocytes of the strychnine binding 48 kd subunit of the glycine receptor. EMBO J. 3, 695−700 (1989).
  9. Sontheimer, H. et al. Functional chloride channels by mammalian cell expression of rat glycine receptor subunit. Neuron 2, 1491−1497 (1989). | Article | PubMed  | ISI | ChemPort | Add to Connotea (beta) |
  10. Pribilla, I., Takagi, T., Langosch, D., Bormann, J. & Betz, H. The atypical M2 segment of the beta subunit confers picrotoxinin resistance to inhibitory glycine receptor channels. EMBO J. 11, 4305−4311 (1992). | PubMed  | ISI | ChemPort | Add to Connotea (beta)  |
  11. White, W.F. & Heller, A.H. Glycine receptor alteration in the mutant mouse spastic. Nature 298, 655−657 (1982). | PubMed  | ISI | ChemPort | Add to Connotea (beta)  |
  12. Gundlach, A.L. et al. Deficit of glycine/strychnine receptors in inherited myoclonus of Poll Hereford calves. Science 241, 1807−1810 (1988). | PubMed  | ISI | ChemPort | Add to Connotea (beta)  |
  13. Gundlach, A.L. Disorder of the inhibitory glycine receptor: inherited myoclonus in Poll Hereford calves. FASEB J. 4, 2761−2766 (1990). | PubMed  | ISI | ChemPort | Add to Connotea (beta)  |
  14. Gundlach, A.L., Kortz, G., Burazin, T.C.D., Madigan, J. & Higgins, R.J. Deficit of inhibitory glycine receptors in spinal cord from Peruvian Pasos: evidence for an equine form of inherited myoclonus. Brain Res. 628, 263−270 (1993). | Article | PubMed  | ISI | ChemPort | Add to Connotea (beta) |
  15. Shiang, R. et al. Mutations in the alpha1 subunit of the inhibitory glycine receptor cause the dominant neurologic disorder, hyperekplexia. Nature Genet. 5, 351−358 (1993). | Article | PubMed  | ISI | ChemPort | Add to Connotea (beta) |
  16. Ryan, S.G. et al. A missense mutation in the gene encoding the alpha1 subunit of the inhibitory glycine receptor causes the spasmodic mouse phenotype. Nature Genet. 7, 131−135 (1994). | Article | PubMed  | ISI | ChemPort | Add to Connotea (beta) |
  17. Heller, A.H. & Hallett, M. Electrophysiological studies with the spastic mutant mouse. Brain Res. 234, 299−308 (1982). | Article | PubMed  | ISI | ChemPort | Add to Connotea (beta) |
  18. Chai, C.K. Hereditary spasticity in mice. J. Hered. 52, 241−243 (1961). | ISI |
  19. Chai, C.K., Roberts, E. & Sidman, R.L. Influence of aminooxyacetic acid, a gamma-aminobutyrate transaminase inhibitor, on hereditary spastic defect in the mouse. Proc. Soc. exp. Biol. Med. 109, 491−495 (1962). | PubMed  | ISI | ChemPort | Add to Connotea (beta)  |
  20. Meier, H. & Chai, C.K. spastic, an hereditary neurological mutation in the mouse characterized by vertebral arthropathy and leptomeningeal cyst formation. Exp. Med. Surg. 28, 24−38 (1970). | PubMed  | ISI | ChemPort | Add to Connotea (beta)  |
  21. Ziv, I., Blackburn, N., Rang, M. & Koreska, J. Muscle growth in normal and spastic mice. Dev. Med. child Neurol. 26, 94−99 (1984). | PubMed  | ISI | ChemPort | Add to Connotea (beta)  |
  22. Lane, P.W. Two new mutations in linkage group XVI of the house mouse, flaky tail and varitint-waddler-J. J. Hered. 63, 135−140 (1972). | PubMed  | ISI | ChemPort | Add to Connotea (beta)  |
  23. Eicher, E.M. & Lane, P.W. Assignment of LG XVI to chromosome 3 in the mouse. J. Hered. 71, 315−318 (1980). | PubMed  | ISI | ChemPort | Add to Connotea (beta)  |
  24. White, W.F. The glycine receptor in the mutant mouse spastic (spa): strychnine binding characteristics and pharmacology Brain Res. 329, 1−6 (1985). | Article | PubMed  | ISI | ChemPort | Add to Connotea (beta) |
  25. Becker, C.M., Hermans-Borgmeyer, I., Schmitt, B. & Betz, H. The glycine receptor deficiency of the mutant mouse spastic: evidence for normal glycine receptor structure and localization. J. Neurosci. 6, 1358−1364 (1986). | PubMed  | ISI | ChemPort | Add to Connotea (beta)  |
  26. Becker, C.M., Schmieden, V., Tarroni, P., Strasser, U. & Betz, H. Isoform-selective deficit of glycine receptors in the mouse mutant spastic. Neuron 8, 283−289 (1992). | PubMed  | ISI | ChemPort | Add to Connotea (beta)  |
  27. White, W.F. & Heller, A.H. Glycine and GABA uptake in the mutant mouse spastic. Soc. Neurosci. (Abstr.) 8, 575 (1982).
  28. Biscoe, T.J., Fry, J.P., Martin, I.L. & Rickets, C. Binding of GABA and benzodiazepine receptor ligands in the spinal cord of the spastic mouse, (ab). J. Physiol. 317, 32−33 (1981).
  29. Biscoe, T.J. & Fry, J.P. GABA and benzodiazepine receptor in neurologically mutant mice. in Actions and Interactions of GABA and Benzodiazepines, N.G. Bowery, Ed. 217−237 (Raven Press, New York, 1984). | ChemPort |
  30. Seldin, M.F. et al. Genetic analysis of autoimmune gld mice. I. Identification of a restriction fragment length polymorphism closely linked to the gld mutation within a conserved linkage group. J. exp. Med. 167, 688−693 (1988). | Article | PubMed  | ISI | ChemPort | Add to Connotea (beta) |
  31. Green, E.L. Linkage, recombination and mapping. in Genetics and Probability in Animal Breeding Experiments 77−113 (Macmillan, New York, 1981).
  32. Bishop, D.T. The information content of phase-known matings for ordering genetic loci. Genet. Epidemiol. 2, 349−361 (1985). | PubMed  | ChemPort | Add to Connotea (beta)  |
  33. Seldin, M.F., Prins, J-B., Rodrigues, N.R., Todd, J.A. & Meisler, M.H. Mouse chromosome 3. Mamm. Genome 4, S47−S57 (1993). | PubMed  | ISI | ChemPort | Add to Connotea (beta)  |
  34. El Mestikawy, S. et al. Characterization of an atypical member of the Na+/Cl- dependent transporter family: Chromosomal localization and distribution in GABAergic and glutamatergic neurons in the rat brain. J. Neurochem. 62, 445−455 (1994). | PubMed  | ChemPort | Add to Connotea (beta)  |
  35. Gregor, P. et al. Chromosomal localization of glutamate receptor genes: Relationships to familial amyotrophic lateral sclerosis and other neurologic disorders of mice and humans. Proc. natn. Acad. Sci. U.S.A. 90, 3053−3057 (1993). | ChemPort |
  36. Moseley, W.S. & Seldin, M.F. Definition of mouse chromosome 1 and 3 gene linkage groups that are conserved on human chromosome 1: Evidence that a conserved linkage group spans the centromere of human chromosome 1. Genomics 5, 899−905 (1989). | PubMed  | ISI | ChemPort | Add to Connotea (beta)  |
  37. Malosio, M-L., Marqueze-Pouey, B., Kuhse, J. & Betz, H. Widespread expression of glycine receptor subunit mRNAs in the adult and developing rat brain. EMBO J. 10, 2401−2409 (1991). | PubMed  | ISI | ChemPort | Add to Connotea (beta)  |
  38. Betz, H. Glycine receptors: heterogeneous and widespread in the mammalian brain. Trends Neurosci. 14, 458−461 (1991). | Article | PubMed  | ISI | ChemPort | Add to Connotea (beta) |
  39. Sommer, B., Poustka, A., Spurr, N.K. & Seeburg, P.H. The murine GABAA receptor delta-subunit gene: structure and assignment to human chromosome 1. DNA Cell Biol. 9, 561−568 (1990). | PubMed  | ISI | ChemPort | Add to Connotea (beta)  |
  40. Kirkness, E.F., et al. Isolation, characterization, and localization of human genomic DNA encoding the beta1 subunit of GABAA, receptor (GABRB1) Genomics 10, 985−995 (1991). | PubMed  | ISI | ChemPort | Add to Connotea (beta)  |
  41. Lasham, A., Vreugdenhil, E., Bateson, A.N., Barnard, E.A. & Darlison, M.G. Conserved organization of gamma-aminobutyric acidA receptor genes: cloning and analysis of the chicken beta4-subunit gene. J. Neurochem. 57, 352−355 (1991). | PubMed  | ISI | ChemPort | Add to Connotea (beta)  |
  42. Fanning, T.G. Size and structure of the highly repetitive BAM HI element in mice. Nuci. Acids Res. 11, 5073−5091 (1983). | ChemPort |
  43. Loeb, D.D. et al. The sequence of a large L1 Md element reveals a tandemly repeated 5' end and several features found in retrotransposons. Molec. cell. Biol. 6, 168−182 (1986). | PubMed  | ISI | ChemPort | Add to Connotea (beta)  |
  44. Kuhse, J., Laube, B., Magalei, D. & Betz, H. Assembly of the in hibitory glycine receptor: Identification of amino acid sequence motifs governing subunit stoichiometry. Neuron 11, 1049−1056 (1993). | Article | PubMed  | ISI | ChemPort | Add to Connotea (beta) |
  45. Hoch, W., Betz, H. & Becker, C.M. Primary cultures of mouse spinal cord express the neonatal isoform of the inhibitory glycine receptor. Neuron 3, 339−348 (1989). | Article | PubMed  | ISI | ChemPort | Add to Connotea (beta) |
  46. Eickbush, T.H. Transposing without ends: the non-LTR retrotransposable elements. New Biologist 4, 430−440 (1992). | PubMed  | ISI | ChemPort | Add to Connotea (beta)  |
  47. Kazazian, Jr H.H. et al. Hemophilia A resulting from de novo insertion of L1 sequences represents a novel mechanism for mutation in man. Nature 332, 164−166 (1988). | Article | PubMed  | ISI | ChemPort | Add to Connotea (beta) |
  48. Narita, N. et al. Insertion of a 5' truncated L1 element into the 3' end of exon 44 of the dystrophin gene resulted in skipping of the exon during splicing in a case of Duchenne muscular dystrophy. J. clin. Invest. 91, 1862−1867 (1993). | PubMed  | ISI | ChemPort | Add to Connotea (beta)  |
  49. Morse, B., Rotherg, P.G., South, V.J., Spandorfer, J.M. & Astrin, S.M. Insertional mutagenesis of the MYC locus by a LINE-1 sequence in a human breast carcinoma. Nature 333, 87−90 (1988). | Article | PubMed  | ISI | ChemPort | Add to Connotea (beta) |
  50. Steinmeyer, K. et al. Inactivation of muscle chloride channel by transposon Insertion in myotonic mice. Nature 354, 304−308 (1991). | Article | PubMed  | ISI | ChemPort | Add to Connotea (beta) |
  51. Adachi, M., Watanabe-Fukunaga, R. & Nagata, S. Aberrant transcription caused by the insertion of an early transposable element in an intron of the Fas antigen gene of Ipr mice. Proc. natn. Acad. Sci. U.S.A. 90, 1756−1760 (1993). | ChemPort |
  52. Kobayashi, S., Hirano, T., Kakinuma, M. & Uede, T. Transcriptional repression and differential splicing of FAS mRNA by early transposon (ETn) insertion in autoimmune Ipr mice. Biochem. Biophys. res. Commun. 191, 617−624 (1993). | Article | PubMed  | ISI | ChemPort | Add to Connotea (beta) |
  53. Sambrook, J., Fritsch, E.F. & Maniatis, T. in Molecular Cloning: A Laboratory Manual 2nd edn (Cold Spring Harbor Laboratory Press, New York, 1989).
  54. Giros, B., El Mestikawy, S., Bertrand, L. & Caron, M.G. Cloning and functional characterization of a cocaine-sensitive dopamine transporter. FEBS Lett. 295, 149−154 (1991). | Article | PubMed  | ISI | ChemPort | Add to Connotea (beta) |
 Top
 Top
Abstract
Previous | Next
Table of contents
Download PDFDownload PDF
Send to a friendSend to a friend
Save this linkSave this link

Open Innovation Challenges

naturejobs

More science jobs
Post a job for free
References
Export citation
Export references
natureproducts

Search buyers guide:

 
ADVERTISEMENT
 
Nature Genetics
ISSN: 1061-4036
EISSN: 1546-1718		 Journal home | Advance online publication | Current issue | Archive | Press releases | Supplements | Focuses | For authors | Online submission | Permissions | For referees | Free online issue | About the journal | Contact the journal | Subscribe | Advertising | work@npg | naturereprints | About this site | For librarians
Nature Publishing Group, publisher of Nature, and other science journals and reference works©1994 Nature Publishing Group | Privacy policy