Cynthia Lance-Jones

Functionally Related Motor Neuron Pool and Muscle Sensory Afferent Subtypes Defined by Coordinate ETS Gene Expression

Motor function depends on the formation of selective connections between sensory and motor neurons and their muscle targets. The molecular basis of the specificity inherent in this sensory-motor circuit remains unclear. We show that motor neuron pools and subsets of muscle sensory afferents can be defined by the expression of ETS genes, notably PEA3 and ER81. There is a matching in PEA3 and ER81 expression by functionally interconnected sensory and motor neurons. ETS gene expression by motor and sensory neurons fails to occur after limb ablation, suggesting that their expression is coordinated by signals from the periphery. ETS genes may therefore participate in the development of selective sensory-motor circuits in the spinal cord.

The somitic level of origin of embryonic chick hindlimb muscles

Studies of avian chimeras made by transplanting groups of quail somites into chick embryos have consistently shown that the muscle cells of the hindlimb are derived from the adjacent somites, however, the pattern of cell distribution from individual somites to individual hindlimb muscles has not been characterized. I have mapped quail cell distribution in the chick hindlimb after single somite transplantation to determine if cells from an individual somite populate discrete limb muscle regions and if there is a spatial correspondence between a muscles somitic level of origin and the known spinal cord position of its motoneuron pool. At stages 15-18 single chick somites or equivalent lengths of unsegmented somitic mesoderm adjacent to the prospective hindlimb region were replaced with the corresponding tissue from quail embryos. At stages 28-34, quail cell distribution was mapped within individual thigh muscles and shank muscle regions. A quail-specific antiserum and Feulgen staining were used to identify quail cells. Transplants from somite levels 26-33 each gave rise to consistent quail cell labeling in a unique subset of limb muscles. The anteroposterior positions of these subsets corresponded to that of the transplanted somitic tissue. For example, more anterior or anteromedial thigh muscles contained quail cells when more anterior somitic tissue had been transplanted. For the majority of thigh muscles studied and for shank muscle groups, there was also a clear correlation between somitic level of origin and motoneuron pool position. These data are compatible with the hypothesis that motoneurons and the muscle cells of their targets share axial position labels. The question of whether motoneurons from a specific spinal cord segment recognize and consequently innervate muscle cells derived from the same axial level during early axon outgrowth is addressed in the accompanying paper (C. Lance-Jones, 1988, Dev. Biol. 126, 408-419). Quail cell distribution was also mapped in chick embryos in which quail somites or unsegmented mesoderm had been placed 2-3 somites away from their position of origin. In all cases donor somitic tissues contributed to muscles in accord with their host position. These results indicate that muscle cell precursors within the somites are not specified to migrate to a predetermined target region.

THE INFLUENCE OF PRESUMPTIVE LIMB CONNECTIVE TISSUE ON MOTONEURON AXON GUIDANCE

During embryogenesis in the chick, the lumbosacral (LS) somatopleure gives rise to the connective tissue and the epidermis of the limb. We wished to determine if the LS somatopleure was a primary source of guidance cues for motoneuron pathway choices along the anteroposterior axis of the limb. At stage (st) 15, prior to its population by muscle cell precursors and the neural crest, the LS somatopleure was shifted anteriorly. This surgery resulted in the development of limbs that were shifted one to four segments into the thoracic region. Muscles within the anterior thigh of the shifted limb were normally patterned and of composite origin: connective tissues were of LS origin, while muscle cells were of LS and thoracic origin. Retrograde HRP labeling at st 35-37 indicated that motoneuron pools to these anterior thigh muscles were located within LS rather than thoracic cord segments. Pools to individual muscles were smaller than normal but occupied segmental and transverse positions in the LS cord that generally matched those of normal embryos. These findings suggest that individual muscles within somatopleure-shifted limbs are innervated specifically and are in accord with their connective tissue (and epidermal) level of origin. Reconstructions of nerve patterns at st 28-31 suggested that LS motoneurons corrected for the shift by altering their pathways at midthigh regions. We conclude that the somatopleure, and most likely its connective tissue component, contains the information for setting up a specific axon guidance system in the developing limb.

Ectopic expression of Hoxd10 in thoracic spinal segments induces motoneurons with a lumbosacral molecular profile and axon projections to the limb

Hox genes encode anterior–posterior identity during central nervous system development. Few studies have examined Hox gene function at lumbosacral (LS) levels of the spinal cord, where there is extensive information on normal development. Hoxd10 is expressed at high levels in the embryonic LS cord but not the thoracic cord. To test the hypothesis that restricted expression of Hoxd10 contributes to the attainment of an LS identity, and specifically an LS motoneuron identity, Hoxd10 was ectopically expressed in thoracic segments in chick embryos by means of in ovo electroporation. Regional motoneuron identity was assessed after the normal period of motoneuron differentiation. Subsets of motoneurons in transfected thoracic segments developed a molecular profile normally shown by LS motoneurons, including Lim 1 and RALDH2 expression. In addition, motoneurons in posterior thoracic segments showed novel axon projections to two muscles in the anterodorsal limb, the sartorius and anterior iliotibialis muscles. At thoracic levels, we also found a decrease in motoneuron numbers and a reduction in gonad size. These last findings suggest that early and high levels of Hox expression impeded motoneuron development and neural–mesodermal interactions. Despite these adverse effects, our data indicate that Hoxd10 expression is sufficient to induce LS motoneuron identity and axon trajectories characteristic of motoneurons in the LS region. Developmental Dynamics 231:43–56, 2004.

The development of sensory projection patterns in embryonic chick hindlimb under experimental conditions.

In the chick, sensory neurons grow to their segmentally appropriate target sites in the hindlimb from the outset during normal development. To elucidate the underlying mechanisms, we performed various manipulations of the neural tube, including the neural crest, or of the hindlimb, before axonal outgrowth and assessed the resulting sensory projections using retrograde and anterograde HRP labeling and electrophysiological techniques. Previous experiments had shown that motoneurons are specified to project to their appropriate target muscles prior to axon outgrowth and that they respond to cues in the limb in order to grow to those targets (C. Lance-Jones and L. Landmesser, 1980, J. Physiol. (London) 302, 559-602; C. Lance-Jones and L. Landmesser, 1981, Proc. R. Soc. London, B 214, 19-52). When several segments of neural tube and neural crest were deleted, sensory neurons in the remaining segments still projected along their correct pathways, as did motoneurons. In situations in which motoneurons grew to their correct targets from altered positions with respect to the limb (e.g., small neural tube reversals), sensory neurons also tended to project along the segmentally appropriate pathways both to skin and to muscle. In situations in which motoneurons were displaced greater distances from their normal point of entry into the limb and made wrong connections (e.g., large neural tube reversals, anterior-posterior limb reversals), sensory neurons also projected incorrectly. The patterns of sensory projections to muscles were, in each situation, generally similar to the motoneuron projections. These results are consistent with the possibility that sensory neurons, like motoneurons, are specified with respect to their peripheral connectivity. Alternatively, the results suggest that motoneurons may play a role in the process of pathway selection by sensory neurons.

The effect of somite manipulation on the development of motoneuron projection patterns in the embryonic chick hindlimb

Although the formation of motoneuron projections to individual muscles in the embryonic chick hindlimb has been shown to involve the specific recognition of environmental cues, the source of these cues and their mode of acquisition are not known. I show in the accompanying paper (C. Lance-Jones, 1988, Dev. Biol. 126, 394-407) that there is a correlation between the segmental level of origin of motoneurons and the somitic level of origin of the muscle cells of their targets in the chick hindlimb. These data are compatible with the hypothesis that the developmental basis for specific recognition is a positional one. Motoneurons and myogenic cells may be uniquely labeled in accord with their axial level of origin early in development and subsequently matched on the basis of these labels. To test this hypothesis, I have assessed motoneuron projection patterns in the embryonic chick hindlimb after somitic tissue manipulations. In one series of embryos, somitic mesoderm at levels 26-29 or 27-29 was reversed about the anteroposterior axis prior to myogenic cell migration and axon outgrowth. Since previous studies have shown that cells migrate from the somites in accord with their position and that somites 26-29 populate anterior thigh musculature, this operation will have reversed the somitic level of origin of anterior thigh muscles. Retrograde HRP labeling of projections to anterior thigh muscles at stage (st) 30 and st 35-38 showed that motoneuron projections were largely normal. This finding suggests that limb muscle cells or their source, the somites, do not contain the cues responsible for specific recognition prior to myogenic cell migration and axon outgrowth. To confirm that specific guidance cues were still intact after somitic mesoderm reversal, I also assessed motoneuron projections in embryos where somitic tissue plus adjacent spinal cord segments at levels 26-29 were reversed in a similar manner. Analyses of the distribution of retrogradely labeled motoneurons in reversed cord segments at st 35-36 indicated that motoneuron projections were reversed. This finding suggests that motoneurons have altered their course to project to correct targets despite the altered somitic origin of their targets and, thus, that specific guidance cues were intact. I conclude that if cues governing target or pathway choice are encoded positionally then they must be associated with other embryonic tissues such as the connective tissues or that guidance cues are acquired by myogenic cells after the onset of migration and motoneuron specification.

Müller glia stabilizes cell columns during retinal development: lateral cell migration but not neuropil growth is inhibited in mixed chick-quail retinospheroids.

Radial columnar organization of cell clones is a characteristic feature of vertebrate retinae that is structurally not understood. Here we provide in vitro evidence that Müller glia processes stabilize cells within columns. Dissociated embryonic chick retinal plus pigmented cells regenerate in vitro into fully laminated stratospheroids. After reaggregating chick and quail cells, quail‐derived spheroid areas are detected as isolated sectors, as shown by a quail‐specific antibody. Each sector contains one or multiple cell columns. The radial borders separating chick and quail sectors are fully congruent with the extension of 3A7‐labelled Müller glia processes. While cell somata do not show any lateral interspecies mixing, quail‐derived neuropil extends within the inner plexiform areas far into chick sectors. After selective damage of Müller cells by the gliotoxin dl‐α‐aminoadipic acid, the columnar organization is destabilized, as evidenced by a decrease in vimentin expression and by the migration of individual neurons out of their cell column. These data demonstrate that Müller cells actively stabilize cells within their columns, while neuritic growth is not hindered.

Motoneuron projection patterns in chick embryonic limbs with a double complement of dorsal thigh musculature.

During the normal development of the chick, lateral motoneurons within the lumbosacral motor column of the spinal cord consistently project to muscles of dorsal origin within the limb while medial motoneurons project to muscles of ventral origin. To determine if specific cues arising from each type of target are the dominant guidance cues used by lateral and medial motoneurons to create this pattern, I examined motoneuron projections in embryonic chick limbs with a double complement of dorsal thigh musculature and no ventral musculature. Results indicate that cues associated with muscles of a specific developmental origin do not invariably dominate. Before and after the major period of motoneuron death, all muscles in dorsal limb regions (host) were innervated by lateral or dorsal pool neurons. Most ventrally positioned (donor) muscles were innervated by medial or ventral pool neurons. Only the donor iliofibularis, a muscle located very near to its original source of innervation, received projections from some lateral neurons. Within the limb proper, medial or ventral pool neurons projected to donor muscles in a patterned manner suggesting that they were following nonspecific regional cues and perhaps also responding to the availability of uninnervated target tissue. I conclude that axon sorting into distinct lateral and medial classes is independent of limb target complement and that subsequent pathway choice is a separate event governed by both specific target cues and other guidance mechanisms.

Restricted patterns of Hoxd10 and Hoxd11 set segmental differences in motoneuron subtype complement in the lumbosacral spinal cord

During normal vertebrate development, Hoxd10 and Hoxd11 are expressed by differentiating motoneurons in restricted patterns along the rostrocaudal axis of the lumbosacral (LS) spinal cord. To assess the roles of these genes in the attainment of motoneuron subtypes characteristic of LS subdomains, we examined subtype complement after overexpression of Hoxd10 or Hoxd11 in the embryonic chick LS cord and in a Hoxd10 loss-of-function mouse embryo. Data presented here provide evidence that Hoxd10 defines the position of the lateral motor column (LMC) as a whole and, in rostral LS segments, specifically promotes the development of motoneurons of the lateral subdivision of the lateral motor column (LMCl). In contrast, Hoxd11 appears to impart a caudal and medial LMC (LMCm) identity to some motoneurons and molecular profiles suggestive of a suppression of LMC development in others. We also provide evidence that Hoxd11 suppresses the expression of Hoxd10 and the retinoic acid synthetic enzyme, retinaldehyde dehydrogenase 2 (RALDH2). In a normal chick embryo, Hoxd10 and RALDH2 are expressed throughout the LS region at early stages of motoneuron differentiation but their levels decline in Hoxd11-expressing caudal LS segments that ultimately contain few LMCl motoneurons. We hypothesize that one of the roles played by Hoxd11 is to modulate Hoxd10 and local retinoic acid levels and thus, perhaps define the caudal boundaries of the LMC and its subtype complement.

Programming neural Hoxd10: in vivo evidence that early node-associated signals predominate over paraxial mesoderm signals at posterior spinal levels

Studies of the programming of Hox patterns at anterior spinal levels suggest that these events are accomplished through an integration of Hensens node-derived and paraxial mesoderm signaling. We have used in vivo tissue manipulation in the avian embryo to examine the respective roles of node- derived and other local signals in the programming of a Hox pattern at posterior spinal levels. Hoxd10 is highly expressed in the lumbosacral (LS) spinal cord and adjacent paraxial mesoderm. At stages of LS neural tube formation (stages 12-14), the tailbud contains the remnants of Hensens node and the primitive streak. Hoxd10 expression was analyzed after transposition of LS neural segments with and without the tailbud, after isolation of normally positioned LS segments from the stage 13 tailbud, and after axial displacement of posterior paraxial mesoderm. Data suggest that inductive signals from the tailbud are primarily responsible for the programming of Hoxd10 at neural plate and the earliest neural tube stages. After these stages, the LS neural tube appears to differ from more anterior neural segments in its lack of dependence on Hox-inductive signals from local tissues, including paraxial mesoderm. Our data also suggest that a graded system of repressive signals for posterior Hox genes is present at cervical and thoracic levels and likely to originate from paraxial mesoderm.