Rhombomere transplantation repatterns the segmental organization of cranial nerves and reveals cell-autonomous expression of a homeodomain protein

S.C. Kuratani; G. Eichele

Summary

The developing vertebrate hindbrain consists of segmental units known as rhombomeres. Hindbrain neuroectoderm expresses 3′ Hox 1 and 2 cluster genes in characteristic patterns whose anterior limit of expression coincides with rhombomere boundaries. One particular Hox gene, referred to as Ghox 2.9, is initially expressed throughout the hindbrain up to the anterior border of rhombomere 4 (r4). Later, Ghox 2.9 is strongly upregulated in r4 and Ghox 2.9 protein is found in all neuroectodermal cells of r4 and in the hyoid crest cell population derived from this rhombomere. Using a polyclonal antibody, Ghox 2.9 was immunolocalized after transplanting r4 within the hindbrain. Wherever r4 was transplanted, Ghox 2.9 expression was cell-autonomous, both in the neuroectoderm of the graft and in the hyoid crest cell population originating from the graft. In all vertebrates, rhombomeres and cranial nerves (nerves V, VII+VIII, IX, X) exhibit a stereotypic relationship: nerve V arises at the level of r2, nerve VII+VIII at r4 and nerves IX-X extend caudal to r6. To examine how rhombomere transplantation affects this pattern, operated embryos were stained with monoclonal antibodies E/C8 (for visualization of the PNS and of even-numbered rhombomeres) and HNK-1 (to detect crest cells and odd-numbered rhombomeres). Upon transplantation, rhombomeres did not change E/C8 or HNK-1 expression or their ability to produce crest cells. For example, transplanted r4 generated a lateral stream of crest cells irrespective of the site into which it was grafted. Moreover, later in development, ectopic r4 formed an additional cranial nerve root. In contrast, transplantation of r3 (lacks crest cells) into the region of r7 led to inhibition of nerve root formation in the host. These findings emphasize that in contrast to spinal nerve segmentation, which entirely depends on the pattern of somites, cranial nerve patterning is brought about by factors intrinsic to rhombomeres and to the attached neural crest cell populations. The patterns of the neuroectoderm and of the PNS are specified early in hindbrain development and cannot be influenced by tissue transplantation. The observed cell-autonomous expression of Ghox 2.9 (and possibly also of other Hox genes) provides further evidence for the view that Hox gene expression underlies, at least in part, the segmental specification within the hindbrain neuroectoderm.

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Martinez S.,
Lance-Jones C. C.
(1990). Pluripotentiality of the 2-day-old avian germinative neuroepithelium. Dev. Biol. 139, 75–88

[2] Alvarado-Mallart R. M.,

[3] Martinez S.,

[4] Lance-Jones C. C.

[5] Bartelmez G. W.,
Dekaban A. S.
(1962). The early development of the human brain.Contr. Embryol. 253, 13–32

[6] Bartelmez G. W.,

[7] Dekaban A. S.

[8] Beraneck E.
(1884). Etude sur les replis medullaires du poulet. Rec. Zool Suisse. 4, 305–364

[9] Beraneck E.

[10] Bronner-Fraser M.,
Stern C. D.
(1991). Effects of mesodermal tissues on avian neural crest cell migration. Dev. Biol. 143, 213–217

[11] Bronner-Fraser M.,

[12] Stern C. D.

[13] Chisaka O.,
Musci T. S.,
Capecchi M. R.
(1992). Developmental defects of the ear, cranial nerves and hindbrain resulting from targeted disruption of the mouse homeobox gene Hox-1. 6. Nature 355, 516–520

[14] Chisaka O.,

[15] Musci T. S.,

[16] Capecchi M. R.

[17] Chang S.,
Fan J.,
Nayak J.
(1992). Pathfinding by cranial nerve VII (facial) motorneurons in the chick hindbrain. Development 114, 815–823

[18] Chang S.,

[19] Fan J.,

[20] Nayak J.

[21] Ciment G.,
Weston J. A.
(1985). Segregation of developmental abilities in neural-crest-derived cells: Identification of partially restricted intermediate cell types in the branchial arches of avian embryos. Dev. Biol 111, 73–83

[22] Ciment G.,

[23] Weston J. A.

[24] Ciment G.,
Ressler A.,
Letourneau C.,
Weston J. A.
(1986). A novel intermediate filament-associated protein, NAPA-73, that binds to different filament types at different stages of nervous system development. J. Cell Biol. 102, 246–251

[25] Ciment G.,

[26] Ressler A.,

[27] Letourneau C.,

[28] Weston J. A.

[29] Detwiler S. R.
(1934). An experimental study of spinal nerve segmentation in Amblystoma will reference to the plurisegmental contribution to the brachial plexus. J. Exp. Zool. 67, 395–441

[30] Detwiler S. R.

[31] Detwiler S. R.
(1937). Observations upon the migration of neural crest cells and upon the development of the spinal ganglia and vertebral arches in Amblystoma. Am. J. Anat. 61, 63–94

[32] Detwiler S. R.

[33] Dohrn A.
(1875). Der Ursprung der Wirbeltiere und das Prinzip des Funktionswechsels. Leipzig: Engelmann (cited by Hill, 1900).

[34] Dohrn A.

[35] Feulgen R.,
Rossenbeck H.
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[36] Feulgen R.,

[37] Rossenbeck H.

[38] Fraser S.,
Keynes R.,
Lumsden A.
(1990). Segmentation in the chick embryo hindbrain is defined by cell lineage restrictions. Nature 334, 431–435

[39] Fraser S.,

[40] Keynes R.,

[41] Lumsden A.

[42] Frohman M. A.,
Boyle M.,
Martin G. R.
(1990). Isolation of the mouse Hox-2.9 gene; analysis of embryonic expression suggests that positional information along the anterior-posterior axis is specified by mesoderm. Development 110, 589–607

[43] Frohman M. A.,

[44] Boyle M.,

[45] Martin G. R.

[46] Graham A.,
Papalopulu N.,
Krumlauf R.
(1989). The murine and Drosophila homeobox gene complex have common features of organization and expression. Cell 57, 367–378

[47] Graham A.,

[48] Papalopulu N.,

[49] Krumlauf R.

[50] Guthrie S.,
Lumsden A.
(1991). Formation and regeneration of rhombomere boundaries in the developing chick hindbrain. Development 112, 221–229

[51] Guthrie S.,

[52] Lumsden A.

[53] Guthrie S.,
Muchamore I.,
Kuroiwa A.,
Marshall H.,
Krumlauf R.,
Lumsden A.
(1992). Neuroectodermal autonomy of Hox-2.9 expression revealed by rhombomere transpositions. Nature 356, 157–159

[54] Guthrie S.,

[55] Muchamore I.,

[56] Kuroiwa A.,

[57] Marshall H.,

[58] Krumlauf R.,

[59] Lumsden A.

[60] Hamburger V.
(1961). Experimental analysis of the dual origin of the trigeminal ganglion in the chick embryo. J. Exp. Zool. 148, 91–124

[61] Hamburger V.

[62] Hamburger V.,
Hamilton H.
(1951). A series of normal stages in the development of the chick embryo. J. Morphol. 88, 49–92

[63] Hamburger V.,

[64] Hamilton H.

[65] Hill C.
(1900). Developmental history of primary segments of the vertebrate head. Zool. Jb. 13, 393–446

[66] Hill C.

[67] His W.
(1887). Die morphologische Betrachtung der Kopfnerven. Eine kritische Studie. Arch. Anat. Physiol. 1887, 379–453

[68] His W.

[69] Holland P. W. H.,
Hogan B. L. M.
(1988). Expression of homeobox genes during mouse development. A review. Genes Dev. 2, 773–782

[70] Holland P. W. H.,

[71] Hogan B. L. M.

[72] Hunt P.,
Wilkinson D.,
Krumlauf R.
(1991). Patterning the vertebrate head: murine Hox 2 genes mark distinct subpopulations of premigratory and migrating cranial neural crest. Development 112, 43–50

[73] Hunt P.,

[74] Wilkinson D.,

[75] Krumlauf R.

[76] Itasaki N.,
Ichijo H.,
Hama C.,
Matsuno T.,
Nakamura H.
(1991). Establishment of rostrocaudal polarity in tectal primordium: engrailed expression and subsequent tectal polarity. Development 113, 1133–1144

[77] Itasaki N.,

[78] Ichijo H.,

[79] Hama C.,

[80] Matsuno T.,

[81] Nakamura H.

[82] Jones F. S.,
Prediger E. A.,
Bittner D. A.,
DeRobertis E. M.,
Edelman G. M.
(1992). Cell adhesion molecules as targets for Hox genes: Neural cell adhesion molecule promoter activity is modulated by cotransfection with Hox-2.5 and -2.4. Proc. Natl. Acad. Sci. USA 89, 2086–2090

[83] Jones F. S.,

[84] Prediger E. A.,

[85] Bittner D. A.,

[86] DeRobertis E. M.,

[87] Edelman G. M.

[88] Kalcheim C.,
LeDouarin N. M.
(1986). Requirement of a neural tube signal(s) for the differentiation of neural crest cells into dorsal root ganglia. Dev. Biol. 116, 451–466

[89] Kalcheim C.,

[90] LeDouarin N. M.

[91] Kalcheim C.,
Teillet M.-A.
(1989). Consequences of somite manipulation on the pattern of dorsal root ganglion development. Development 106, 85–93

[92] Kalcheim C.,

[93] Teillet M.-A.

[94] Källen B.
(1956). Experiments on neuromery in Ambystoma punctatum embryos. J. Embryol. Exp. Morphol. 4, 66–72

[95] Källen B.

[96] Kessel M.,
Gruss P.
(1990). Variations of cervical vertebrae after expression of a Hox-1. 1 transgene in mice. Cell 61, 301–308

[97] Kessel M.,

[98] Gruss P.

[99] Keynes R. J.,
Stern C. D.
(1984). Segmentation in the vertebrate nervous system. Nature 310, 786–789

[100] Keynes R. J.,

[101] Stern C. D.

[102] Kruse F.,
Mailhammer R.,
Wernecke H.,
Faissner A.,
Sommer I.,
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Other journals from The Company of Biologists

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New funding scheme supports sustainable events

Read & Publish participation continues to grow

Upcoming special issues

Development presents...