Canalized morphogenesis driven by inherited tissue asymmetries in Hydra regeneration

The emergence and stabilization of a body axis is a major step in animal morphogenesis, determining the symmetry of the body plan as well as its polarity. To advance our understanding of the emergence of body-axis polarity we study regenerating Hydra. Axis polarity is strongly memorized in Hydra regeneration even in small tissue segments. What type of processes confer this memory? To gain insight into the emerging polarity, we utilize frustrating initial conditions by studying regenerating tissue strips which fold into hollow spheroids by adhering their distal ends, of opposite original polarities. Despite the convoluted folding process and the tissue rearrangements during regeneration, these tissue strips develop a new organizer in a reproducible location preserving the original polarity and yielding an ordered body plan. These observations suggest that the integration of mechanical and biochemical processes supported by their mutual feedback attracts the tissue dynamics towards a well-defined developmental trajectory biased by weak inherited cues from the parent animal. Hydra thus provide an example of dynamic canalization in which the dynamic rules themselves are inherited, in contrast to the classical picture where a detailed developmental trajectory is pre-determined.

Effects of prismatic adaptation on balance and postural disorders in patients with chronic right stroke: protocol for a multicentre double-blind randomised sham-controlled trial

IntroductionPatients with right stroke lesion have postural and balance disorders, including weight-bearing asymmetry, more pronounced than patients with left stroke lesion. Spatial cognition disorders post-stroke, such as misperceptions of subjective straight-ahead and subjective longitudinal body axis, are suspected to be involved in these postural and balance disorders. Prismatic adaptation has showed beneficial effects to reduce visuomotor disorders but also an expansion of effects on cognitive functions, including spatial cognition. Preliminary studies with a low level of evidence have suggested positive effects of prismatic adaptation on weight-bearing asymmetry and balance after stroke. The objective is to investigate the effects of this intervention on balance but also on postural disorders, subjective straight-ahead, longitudinal body axis and autonomy in patients with chronic right stroke lesion.Methods and analysisIn this multicentre randomised double-blind sham-controlled trial, we will include 28 patients aged from 18 to 80 years, with a first right supratentorial stroke lesion at chronic stage (≥12 months) and having a bearing ≥60% of body weight on the right lower limb. Participants will be randomly assigned to the experimental group (performing pointing tasks while wearing glasses shifting optical axis of 10 degrees towards the right side) or to the control group (performing the same procedure while wearing neutral glasses without optical deviation). All participants will receive a 20 min daily session for 2 weeks in addition to conventional rehabilitation. The primary outcome will be the balance measured using the Berg Balance Scale. Secondary outcomes will include weight-bearing asymmetry and parameters of body sway during static posturographic assessments, as well as lateropulsion (measured using the Scale for Contraversive Pushing), subjective straight-ahead, longitudinal body axis and autonomy (measured using the Barthel Index).Ethics and disseminationThe study has been approved by the ethical review board in France. Findings will be submitted to peer-reviewed journals relative to rehabilitation or stroke.Trial registration numberNCT03154138.

Long-Distance Descending Commissural V0v Neurons Ensure Coordinated Swimming Movements Along The Body Axis in Larval Zebrafish

Developmental maturation occurs in slow swimming behavior in larval zebrafish; older larvae acquire the ability to perform slow swimming with keeping their head stable in the yaw dimension. A class of long-distance descending commissural excitatory V0v neurons, called MCoD neurons, are known to develop at later phase of neurogenesis, and participate in slow swimming in older larvae. This led to a hypothesis that MCoD neurons play a role to coordinate the activities of trunk muscles in the diagonal dimension (e.g., the rostral left and the caudal right) to produce S-shaped swimming form, which would contribute to the stability of the head. Here, we show that MCoD neurons indeed play this role. In larvae in which MCoD neurons were laser-ablated, swimming body form often became one-sided (C-shaped) bend with reduced appearance of normal S-shaped bend. With this change of swimming form, the MCoD-ablated larvae exhibited greater degree of head yaw displacement during slow swimming. The long-distance descending commissural V0v neurons are implicated in playing roles in diagonal interlimb coordination during walking in mice. Together with this, our study suggests that the long-distance descending commissural V0v neurons form an evolutionally conserved pathway in the spinal locomotor circuits that coordinates movements of the diagonal body/limb muscles.

How Dickkopf molecules and Wnt/beta-catenin interplay to self-organise the Hydra body axis

The antagonising interplay between canonical Wnt signalling and Dickkopf (Dkk) molecules has been identified in various processes involved in tissue organisation, such as stem cell differentiation and body-axis formation. Disruption of the interplay between these molecules is related to several diseases in humans. However, the detailed molecular mechanisms of the β-catenin/Wnt-Dkk interplay leading to robust formation of the body axis remain elusive. Although the β-catenin/Wnt signalling system has been shown in the pre-bilaterian model organism Hydra to interact with two ancestral Dkks (HyDkk1/2/4-A and -C) to self-organise and regenerate the body axis, the observed Dkk expression patterns do not match any current pattern-formation theory, such as the famous activator-inhibitor model. To explore the function of Dkk in Hydra patterning process, we propose a new mathematical model which accounts for the two Dkks in interplay with HyWnt3/β-catenin. Using a systematic numerical study, we demonstrate that the chosen set of interactions is sufficient to explain it de novo body-axis gradient formation in Hydra. The presented mutual inhibition model goes beyond the classical activator-inhibitor model and shows that a molecular mechanism based on mutual inhibition may replace the local activation/long-range inhibition loop. The new model is validated using a range of perturbation experiments. It resolves several contradictions between previous models and experimental data, and provides an explanation for the interplay between injury response and pattern formation.

Development of a new method for assessing otolith function in mice using three-dimensional binocular analysis of the otolith-ocular reflex

In the interaural direction, translational linear acceleration is loaded during lateral translational movement and gravitational acceleration is loaded during lateral tilting movement. These two types of acceleration induce eye movements via two kinds of otolith-ocular reflexes to compensate for movement and maintain clear vision: horizontal eye movement during translational movement, and torsional eye movement (torsion) during tilting movement. Although the two types of acceleration cannot be discriminated, the two otolith-ocular reflexes can distinguish them effectively. In the current study, we tested whether lateral-eyed mice exhibit both of these otolith-ocular reflexes. In addition, we propose a new index for assessing the otolith-ocular reflex in mice. During lateral translational movement, mice did not show appropriate horizontal eye movement, but exhibited unnecessary vertical torsion-like eye movement that compensated for the angle between the body axis and gravito-inertial acceleration (GIA; i.e., the sum of gravity and inertial force due to movement) by interpreting GIA as gravity. Using the new index (amplitude of vertical component of eye movement)/(angle between body axis and GIA), the mouse otolith-ocular reflex can be assessed without determining whether the otolith-ocular reflex is induced during translational movement or during tilting movement.

Crosstalk between nitric oxide and retinoic acid pathways is essential for amphioxus pharynx development

During animal ontogenesis, body axis patterning is finely regulated by complex interactions among several signaling pathways. Nitric oxide (NO) and retinoic acid (RA) are potent morphogens that play a pivotal role in vertebrate development. Their involvement in axial patterning of the head and pharynx shows conserved features in the chordate phylum. Indeed, in the cephalochordate amphioxus, NO and RA are crucial for the correct development of pharyngeal structures. Here, we demonstrate the functional cooperation between NO and RA that occurs during amphioxus embryogenesis. During neurulation, NO modulates RA production through the transcriptional regulation of Aldh1a.2 that irreversibly converts retinaldehyde into RA. On the other hand, RA directly or indirectly regulates the transcription of Nos genes. This reciprocal regulation of NO and RA pathways is essential for the normal pharyngeal development in amphioxus and it could be conserved in vertebrates.