Roy C. Mootoosamy

Intrinsic, Hox-dependent cues determine the fate of skeletal muscle precursors.

It is generally held that vertebrate muscle precursors depend totally on environmental cues for their development. We show that instead, somites are predisposed toward a particular myogenic program. This predisposition depends on the somites axial identity: when flank somites are transformed into limb-level somites, either by shifting somitic boundaries with FGF8 or by overexpressing posterior Hox genes, they readily activate the program typical for migratory limb muscle precursors. The intrinsic control over myogenic programs can only be overridden by FGF4 signals provided by the apical ectodermal ridge of a developing limb.

Wnt6 marks sites of epithelial transformations in the chick embryo

In a screen for Wnt genes executing the patterning function of the vertebrate surface ectoderm, we have isolated a novel chick Wnt gene, chick Wnt6. This gene encodes the first pan-epidermal Wnt signalling molecule. Further sites of expression are the boundary of the early neural plate and surface ectoderm, the roof of mesencephalon, pretectum and dorsal thalamus, the differentiating heart, and the otic vesicle. The precise sites of Wnt6 expression coincide with crucial changes in tissue architecture, namely epithelial remodelling and epithelial-mesenchymal transformation (EMT). Moreover, the expression of Wnt6 is closely associated with areas of Bmp signalling.

LRP1 controls biosynthetic and endocytic trafficking of neuronal prion protein

The trafficking of normal cellular prion protein (PrPC) is believed to control its conversion to the altered conformation (designated PrPSc) associated with prion disease. Although anchored to the membrane by means of glycosylphosphatidylinositol (GPI), PrPC on neurons is rapidly and constitutively endocytosed by means of coated pits, a property dependent upon basic amino acids at its N-terminus. Here, we show that low-density lipoprotein receptor-related protein 1 (LRP1), which binds to multiple ligands through basic motifs, associates with PrPC during its endocytosis and is functionally required for this process. Moreover, sustained inhibition of LRP1 levels by siRNA leads to the accumulation of PrPC in biosynthetic compartments, with a concomitant lowering of surface PrPC, suggesting that LRP1 expedites the trafficking of PrPC to the neuronal surface. PrPC and LRP1 can be co-immunoprecipitated from the endoplasmic reticulum in normal neurons. The N-terminal domain of PrPC binds to purified human LRP1 with nanomolar affinity, even in the presence of 1 μM of the LRP-specific chaperone, receptor-associated protein (RAP). Taken together, these data argue that LRP1 controls both the surface, and biosynthetic, trafficking of PrPC in neurons.

Neural tube derived signals and Fgf8 act antagonistically to specify eye versus mandibular arch muscles

Recent knockout experiments in the mouse generated amazing craniofacial skeletal muscle phenotypes. Yet none of the genes could be placed into a molecular network, because the programme to control the development of muscles in the head is not known. Here we show that antagonistic signals from the neural tube and the branchial arches specify extraocular versus branchiomeric muscles. Moreover, we identified Fgf8 as the branchial arch derived signal. However, this molecule has an additional function in supporting the proliferative state of myoblasts, suppressing their differentiation, while a further branchial arch derived signal, namely Bmp7, is an overall negative regulator of head myogenesis.

Neuronal low-density lipoprotein receptor-related protein 1 binds and endocytoses prion fibrils via receptor cluster 4.

For infectious prion protein (designated PrPSc) to act as a template to convert normal cellular protein (PrPC) to its distinctive pathogenic conformation, the two forms of prion protein (PrP) must interact closely. The neuronal receptor that rapidly endocytoses PrPC is the low-density lipoprotein receptor-related protein 1 (LRP1). We show here that on sensory neurons LRP1 is also the receptor that binds and rapidly endocytoses smaller oligomeric forms of infectious prion fibrils, and recombinant PrP fibrils. Although LRP1 binds two molecules of most ligands independently to its receptor clusters 2 and 4, PrPC and PrPSc fibrils bind only to receptor cluster 4. PrPSc fibrils out-compete PrPC for internalization. When endocytosed, PrPSc fibrils are routed to lysosomes, rather than recycled to the cell surface with PrPC. Thus, although LRP1 binds both forms of PrP, it traffics them to separate fates within sensory neurons. The binding of both to ligand cluster 4 should enable genetic modification of PrP binding without disrupting other roles of LRP1 essential to neuronal viability and function, thereby enabling in vivo analysis of the role of this interaction in controlling both prion and LRP1 biology.

Polyglutamine repeat length influences human androgen receptor/c-Jun mediated transcription

The androgen receptor and c-Jun are known to interact to modulate each others transcriptional activities. The androgen receptor contains a polymorphic polyglutamine repeat and expansion of this repeat to beyond approximately 40 causes spinobulbar muscular atrophy (SBMA; also known as Kennedys disease), a genetic form of motor neurone disease. Here we show that the size of this polyglutamine tract influences both c-Jun regulation of androgen receptor-mediated transcription and androgen receptor regulation of c-Jun activity. c-Jun is a key mediator of neuronal survival and death by apoptosis. Inappropriate interactions between c-Jun and androgen receptors containing pathological length glutamine repeats may therefore be part of the pathogenic process in SBMA.

Lbx1 marks a subset of interneurons in chick hindbrain and spinal cord

The putative transcription factor Lbx1 is expressed in the mantle zone of the hindbrain and spinal cord caudal to rhombomere 1, in a specific domain of the alar plate. The Lbx1 domain overlaps with the expression domains for Tlx3 and partially with the domains for Pax2/Lim1. The ventral border of the Lbx1 domain coincides with the ventral border of the dorsalmost Serrate1 stripe in the ventricular zone. The latter borders the intermediate stripe of both Delta and Lunatic fringe expression. The Lbx1 domain contains differentiated interneurons that project into the lateral longitudinal fasciculus.

Hypaxial muscle development

Chordate larvae show a surprisingly uniform “bauplan”, with a front end carrying the sense organs plus the gill and feeding apparatus, and a posterior end used for locomotion (reviewed in Goodrich 1958; Young 1962). Although adult forms frequently give up this organisation when they switch to sessile life styles, motility based on trunk muscles is maintained in acrania, and both in jaw-less and jawed vertebrates (agnathans and gnathostomes). The mesoderm on either side of the neural canal is subdivided into metameric blocks of muscle. As the notochord, and in vertebrates the vertebral column, prevent telescoping of the body, the serial action of the muscles on either side leads to an undulating movement.