Glycogen synthase kinase 3beta phosphorylation of microtubule-associated protein 1B regulates the stability of microtubules in growth cones

R.G. Goold; R. Owen; P.R. Gordon-Weeks

Summary

We have recently shown that glycogen synthase kinase 3beta (GSK3beta) phosphorylates the microtubule-associated protein (MAP) 1B in an in vitro kinase assay and in cultured cerebellar granule cells. Mapping studies identified a region of MAP1B high in serine-proline motifs that is phosphorylated by GSK3beta. Here we show that COS cells, transiently transfected with both MAP1B and GSK3beta, express high levels of the phosphorylated isoform of MAP1B (MAP1B-P) generated by GSK3beta. To investigate effects of MAP1B-P on microtubule dynamics, double transfected cells were labelled with antibodies to tyrosinated and detyrosinated tubulin markers for stable and unstable microtubules. This showed that high levels of MAP1B-P expression are associated with the loss of a population of detyrosinated microtubules in these cells. Transfection with MAP1B protected microtubules in COS cells against nocodazole depolymerisation, confirming previous studies. However, this protective effect was greatly reduced in cells containing high levels of MAP1B-P following transfection with both MAP1B and GSK3beta. Since we also found that MAP1B binds to tyrosinated, but not to detyrosinated, microtubules in transfected cells, we propose that MAP1B-P prevents tubulin detyrosination and subsequent conversion of unstable to stable microtubules and that this involves binding of MAP1B-P to unstable microtubules. The highest levels of MAP1B-P are found in neuronal growth cones and therefore our findings suggest that a primary role of MAP1B-P in growing axons may be to maintain growth cone microtubules in a dynamically unstable state, a known requirement of growth cone microtubules during pathfinding. To test this prediction, we reduced the levels of MAP1B-P in neuronal growth cones of dorsal root ganglion cells in culture by inhibiting GSK3beta with lithium. In confirmation of the proposed role of MAP1B-P in maintaining microtubule dynamics we found that lithium treatment dramatically increased the numbers of stable (detyrosinated) microtubules in the growth cones of these neurons.

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Development

[1] Aletta, J. M.,
Lewis, S. A.,
Cowan, N. J. and
Greene, L. A.
(1988). Nerve growth factor regulates both the phosphorylation and steady-state levels of microtubule associated protein 1. 2 (MAP 1. 2). J. Cell Biol 106, 1573–1581
OpenUrl Abstract/FREE Full Text

[2] Aletta, J. M.,

[3] Lewis, S. A.,

[4] Cowan, N. J. and

[5] Greene, L. A.

[6] Argarana, C. E.,
Barra, H. S. and
Caputto, R.
(1978). Release of [14C]-tyrosine from tubilinyl-[14C]-tyrosine by brain extract. Separation of a carboxypeptidase from tubulin tyrosine ligase. Mol. Cell Biochem 19, 17–22
OpenUrl

[7] Argarana, C. E.,

[8] Barra, H. S. and

[9] Caputto, R.

[10] Avila, J.
(1991). Does MAP1B bind to tubulin through the interaction of-helices?. Biochem. J 274, 621–622
OpenUrl FREE Full Text

[11] Avila, J.

[12] Barra, H. S.,
Rodriguez, J. A.,
Arce, C. A. and
Caputto, R.
(1973). A soluble preparation from rat brain that incorporates into its own proteins [14C] arginine by a ribonuclease-sensitive system and [14C]-tyrosine by a ribonuclease-insensitive system. J. Neurochem 20, 97–108
OpenUrl CrossRef PubMed Web of Science

[13] Barra, H. S.,

[14] Rodriguez, J. A.,

[15] Arce, C. A. and

[16] Caputto, R.

[17] Black, M. M.,
Slaughter, T. and
Fischer, I.
(1994). Microtubule-associated protein 1b (MAP1b) is concentrated in the distal region of growing axons. J. Neurosci 14, 857–870
OpenUrl Abstract

[18] Black, M. M.,

[19] Slaughter, T. and

[20] Fischer, I.

[21] Bloom, G. S.,
Luca, F. C. and
Vallee, R. B.
(1985). Microtubule-associated protein 1B: Identification of a major component of the neuronal cytoskeleton. Proc. Nat. Acad. Sci. USA 82, 5404–5408
OpenUrl Abstract/FREE Full Text

[22] Bloom, G. S.,

[23] Luca, F. C. and

[24] Vallee, R. B.

[25] Brugg, B. and
Matus, A.
(1988). PC12 cells express juvenile microtubule-associated proteins during nerve growth factor-induced neurite outgrowth. J. Cell Biol 107, 643–650
OpenUrl Abstract/FREE Full Text

[26] Brugg, B. and

[27] Matus, A.

[28] Brugg, B.,
Reddy, D. and
Matus, A.
(1993). Attenuation of microtubule-associated protein 1B expression by antisense oligodeoxynucleotides inhibits initiation of neurite outgrowth. Neuroscience 52, 489–496
OpenUrl CrossRef PubMed Web of Science

[29] Brugg, B.,

[30] Reddy, D. and

[31] Matus, A.

[32] Bulinski, J. C.,
Richards, J. E. and
Piperno, G.
(1988). Posttranslational modifications of-tubulin: Detyrosination and acetylation differentiate populations of interphase microtubules in cultured cells. J. Cell Biol 106, 1213–1220
OpenUrl Abstract/FREE Full Text

[33] Bulinski, J. C.,

[34] Richards, J. E. and

[35] Piperno, G.

[36] Bush, M. S. and
Gordon-Weeks, P. R.
(1994). Distribution and expression of developmentally regulated epitopes on MAP 1B and neurofilament proteins in the developing rat spinal cord. J. Neurocytol 23, 682–698
OpenUrl CrossRef PubMed Web of Science

[37] Bush, M. S. and

[38] Gordon-Weeks, P. R.

[39] Bush, M. S.,
Goold, R. G.,
Moya, F. and
Gordon-Weeks, P. R.
(1996). An analysis of an axonal gradient of phosphorylated MAP 1B in cultured sensory neurons. Eur. J. Neurosci 8, 235–248
OpenUrl CrossRef PubMed Web of Science

[40] Bush, M. S.,

[41] Goold, R. G.,

[42] Moya, F. and

[43] Gordon-Weeks, P. R.

[44] Calvert, R. and
Anderton, B. H.
(1985). A microtubule associated protein MAP 1 which is expressed at elevated levels during development of rat cerebellum. EMBO J 4, 1171–1176
OpenUrl PubMed Web of Science

[45] Calvert, R. and

[46] Anderton, B. H.

[47] Challacombe, J. F.,
Snow, D. M. and
Letourneau, P. C.
(1997). Dynamic microtubule ends are required for growth cone turning to avoid an inhibitory guidance cue. J. Neurosci 17, 3085–3095
OpenUrl Abstract/FREE Full Text

[48] Challacombe, J. F.,

[49] Snow, D. M. and

[50] Letourneau, P. C.

[51] DiTella, M. C.,
Feiguin, F.,
Carri, N.,
Kosik, K. S. and
Cáceres, A.
(1996). MAP-1B/TAU functional redundancy during laminin-enhanced axonal growth. J. Cell Sci 109, 467–477
OpenUrl Abstract/FREE Full Text

[52] DiTella, M. C.,

[53] Feiguin, F.,

[54] Carri, N.,

[55] Kosik, K. S. and

[56] Cáceres, A.

[57] Díaz-Nido, J.,
Serrano, L.,
Mendez, E. and
Avila, J.
(1988). A casein kinase II-related activity is involved in phosphorylation of microtubule-associated protein MAP1B during neuroblastoma cell differentiation. J. Cell Biol 106, 2057–2065
OpenUrl Abstract/FREE Full Text

[58] Díaz-Nido, J.,

[59] Serrano, L.,

[60] Mendez, E. and

[61] Avila, J.

[62] Edelmann, W.,
Zervas, M.,
Costello, P.,
Roback, L.,
Fischer, I.,
Hammarback, J. A.,
Cowan, J.,
Davies, P.,
Wainer, B. and
Kucherlapati, R.
(1996). Neuronal abnormalities in microtubule-associated protein 1B mutant mice. Proc. Nat. Acad. Sci. USA 93, 1270–1275
OpenUrl Abstract/FREE Full Text

[63] Edelmann, W.,

[64] Zervas, M.,

[65] Costello, P.,

[66] Roback, L.,

[67] Fischer, I.,

[68] Hammarback, J. A.,

[69] Cowan, J.,

[70] Davies, P.,

[71] Wainer, B. and

[72] Kucherlapati, R.

[73] Fan, J.,
Mansfield, S. G.,
Redmond, T.,
Gordon-Weeks, P. R. and
Raper, J.
(1993). The organization of F-actin and microtubules in growth conesexposed to a brain-derived collapsing factor. J. Cell Biol 121, 867–878
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