Uncovering the neural encoding of behavior in the adult Drosophila motor system

One of the most important goals in neuroscience research has always been to understand how animals control their behavior. However, the long focus on the role of brain neurons in behavioral control might be missing the full story. In fact, brain-wide fluctuations in neural activity are highly correlated to the behavioral state, suggesting a closed-loop system where the behavioral command and the body state interact to interpret sensory inputs and dynamically guide action selection. However, to date, little is known about how and where information about the behavioral state is generated. In principle, information about the behavioral state is a relatively high-level encoding of the body state derived from the integration of signals from primary sensors and the local network. Local motor circuits residing in the spinal cord of mammals or the ventral nerve cord (VNC) of insects may give rise to the behavioral state and pass to the brain via brain-projecting interneurons---termed ascending neurons (ANs). However, what information ANs carry and where this information originates is still a mystery due to the technical challenges in measuring these signals in behaving animals. Therefore, it is critical to develop tools to track neuron identity and record neuronal activity during behavior to crack the functional network. In this work, a method is introduced for imaging the motor circuit in the VNC of Drosophila melanogaster. This preparation demonstrates how to retain fly limb function after dissection and allows simultaneous recording of a tethered fly's behavior and its neural activity in the VNC. Incorporating this methodology with other approaches can verify the conclusions from the experiments such as those manipulating neuronal excitability, and motivate further investigation into neuronal function in specific types of behavior. Since it has long been theorized that ANs are the cellular basis of the behavioral state information sent in the brain, the technique introduced in this work was designed to resolve questions relating to what type of information ANs convey. Here, a large-scale functional screen was performed to relate neural activity, behavior, and neuronal morphology for 247 genetically identified ANs in the adult fly. This is the first large-scale screen of neural activity in a behaving animal, and this work uncovered three fundamental features of AN populations. First, rather than low-level limb movements, ANs encode high-level behaviors like walking, grooming, and resting. Second, ANs project nearly exclusively to an integrative sensory center (AVLP) and an action selection hub (GNG). Remarkably, the encodings projected to these distinct areas reflect their potential roles in contextualizing sensory cues (AVLP) and guiding future actions (GNG). Third, the behavioral encodings of ANs are closely linked to their motor system patterning. In conclusion, this work provides an indispensable tool to study the motor system beyond the brain network by overcoming a major technical barrier in in-vivo recording of the VNC of a behaving fly. This tool was used to help resolve what is encoded by ANs as a higher-level behavioral state, suggesting that the primary cellular origin of the behavioral information that is used to modulate brain function comes from the VNC. Overall, the technique and the findings on AN encoding should inspire follow-up studies to uncover additional neural mechanisms used in adaptive behavior generation.

Methods for acute and long-term imaging of the ventral nerve cord in behaving adult Drosophila

Laura Joan Hermans

Understanding how neural circuits remodel and adapt to animal behavior is a central theme in the field of Neuroscience. One strategy to reach this goal is to repeatedly record the same animal's neural circuits and observe how they adapt when facing different challenges. Research has primarily focused on identifying neural circuits and connectivity maps within the brains of model organisms. Nevertheless, it has become evident that functional recordings are essential to have a complete understanding of how neural circuits generate behaviors. Numerous techniques have been introduced to record activity from brain circuits in model animals spanning from monkeys to insects. However, imaging the spinal cord in mammals or the ventral nerve cord in insects remains an open challenge due to the complexity of obtaining optical access without impacting the animal's behavior and damaging neural tissues. As a result, we have very limited information on how neural circuits in the spinal cord generate behaviors and how they adapt to different experiences such as injury or aging. Drosophila is a perfect model organism for carrying out this line of research thanks to its small size, genetically tractable nervous system, and behavioral diversity. The results are relevant to human physiology and behavior as many mechanisms have homologs in mammals. What is missing is a technological advancement that allows recording of behavior, structural changes in the circuits, and spatiotemporal dynamics of neural activity on the same animal.This thesis addresses this gap and introduces two novel methods for in vivo functional recordings of the fly's ventral nerve cord (VNC). The first one gains short-term access to the fly's VNC using a novel dissection preparation. The second one enables long-term functional recordings of the fly's VNC thanks to a toolkit combining four microengineered devices: a surgical arm, a V-shape implant, an optically transparent and numbered window and a remounting stage. The toolkit is suitable for both male and female flies and provides optical access to the VNC for at least one month. Additionally, the long-term toolkit does not impact flies' behaviors compared to intact flies and can be used to image both sparse and large populations of neural activity in flies' cervical connective and VNC. The toolkit was tested in two proof-of-concept (POC) applications. In the first POC, the toolkit monitored the degradation of sensory neurons in the VNC over weeks following limb amputation. In the second POC, the toolkit monitored global changes in neural dynamics following ingestion of a high-concentration caffeine solution. In conclusion, this thesis introduces new techniques for functional recordings of the fly's cervical connective and VNC over short and long time scales. They enable optical access to the fly's cervical connective that can be leveraged to study the content of information transmitted between the brain and the VNC while the fly is behaving. The two POCs demonstrate that the novel technology is ideally suited for long-term experiments and could be applied to a wide range of studies. For instance, the toolkit could be used to investigate how behaviors are encoded in the fly's VNC and how they adapt over time to experiences such as disease, aging, drug intake and learning.

EPFL2022

Uncovering the neural substrates of communication between the brain and ventral nerve cord in Drosophila melanogaster (italic)

Florian Aymanns

Despite a long history of research in motor control, the exact mechanism of how the brain communicates with the the invertebrate ventral nerve cord (VNC) and the vertebrate spinal cord on a single neuron basis remains largely elusive.Drosophila melanogaster is an ideal model organism to address the role of individual neurons, thanks to its stereotyped nervous system.Descending neurons (DNs), interneurons in the brain that project to the invertebrate ventral nerve cord or vertebrate spinal cord, have been shown to elicit specific behaviors upon optogenetic activation in Drosophila.These results suggest that behavior is controlled by sparse sets of command neurons, each eliciting a particular behavior.However, it remains to be seen how many DNs are involved in the control of naturalistic behaviors and what other information they might encode.In order to avoid commands leading to physically impossible or destabilizing actions, the brain has to be aware of the current behavior state.Ascending neurons (ANs), interneurons in the invertebrate ventral nerve cord or vertebrate spinal cord projecting to the brain, are likely conveying this information to the brain.To which degree of fidelity and in what way ANs encode behavior state remains unclear.To address these questions, we developed a dissection approach that allows functional imaging of ANs and DNs in the cervical connective.This dissection gives us optical access to the cervical connective and parts of the VNC in behaving adult Drosophila such that a two-photon fluorescence microscope can be used to image neural activity via calcium indicators.We began by imaging a new library of sparse split GAL4 driver lines targeting ANs.Our recordings from 247 genetically identifiable ANs revealed neurons encoding walking, resting, turning, eye grooming, and foreleg movements.Anatomical characterization of these ANs showed that they predominantly project to two brain regions: the anterior ventrolateral protocerebrum (AVLP) and the gnathal ganglion (GNG).Our results suggest that ANs encoding the motion of the animal with respect to the surrounding environment (self-motion) predominantly project to the AVLP, an integrative sensory hub. ANs projecting to the GNG mostly encode discrete actions.We then proceeded to image populations of DNs.The majority of DNs we recorded encoded walking behavior, with smaller fractions encoding resting and head grooming.Some of these neurons are likely to drive walking, but we also identified neurons encoding walking speed and turning.This suggests that a core set of DNs drives a behavior whose features can be modulated by additional DNs.Besides encoding behaviors, some DNs encode sensory information, including the presence of odors and deflection of the antennae.

EPFL2022

Neurorehabilitation and neuroprosthetic technologies to regain motor function following spinal cord injury

Rubia van den Brand

Spinal cord injury (SCI) leads to a range of disabilities, including locomotor impairments that seriously diminish the patients’ quality of life. Strategies to promote functional recovery after severe SCI will undoubtedly include approaches to regenerate injured pathways. The present work pursues a less ambitious, but potentially more rapidly applicable approach to improve function after SCI by applying neurorehabilitation augmented with neuroprosthetic technologies. In an intact situation, the production of standing and walking results from the integration of information within spinal neuronal networks that receive signals from supraspinal centers and afferent pathways. In the majority of cases, the spinal neuronal networks that coordinate leg movements are located below the injury. Due to the interruption of supraspinal signals, these networks are in a non-functional state. Over the past decades multiple research groups have developed interventions to access dormant spinal networks in order to enable functional states during rehabilitation. The underlying objective is to promote activity-dependent plasticity in the trained sensorimotor pathways. During my thesis, I contributed to the development of neuroprosthetic technologies that provide a powerful means to reanimate non-functional networks. The aim of these paradigms is to mimic the supraspinal signals that are normally delivered to spinal locomotor circuits to generate hindlimb motor function. These technologies include: (i) An electrical spinal neuroprosthesis that replaces the supraspinal excitatory drive to augment the central state of excitability, and thus increase the susceptibility of spinal circuits to respond to afferent input. (ii) A chemical spinal neuroprosthesis mimicking the supraspinal source of monoaminergic neuromodulation that promotes locomotor permissive states of spinal circuits. (iii) A robotic postural neuroprosthesis that provides optimal conditions of posture and balance, which enable sensory feedback to become a source of motor control after severe SCI. Multifactorial statistical analyses revealed that each sub-system of the developed neuroprosthetic technologies mediates distinct influences on the production of gait performance, suggesting targeting of selective spinal circuits. Optimal combinations of neuroprosthetic technologies transformed lumbosacral locomotor circuits from dormant to highly functional states, which enabled paralyzed rats with complete SCI to perform weight-bearing stepping with plantar placement for extended periods of time. After 8-weeks of locomotor training enabled by an electrochemical neuroprosthesis, rats with complete SCI exhibited significantly improved gait performance, which was associated with activity-dependent plasticity in lumbosacral circuits. Trained rats were able to instantaneously adapt hindlimb locomotor patterns to changes in speed, load and direction of stepping in the complete absence of brain input. Under these conditions, ‘the smart spinal brain’ interprets multifaceted afferent information to generate motor outputs that meet both internal and external requirements for maintaining successful locomotor states despite dramatic changes in environmental conditions. Non-ambulatory individuals with severe SCI typically exhibit progressive neuronal dysfunction in the chronic stage of injury. To investigate the underlying mechanisms, we developed a new model of severe SCI that consists of 7 two opposite side, staggered lateral hemisections. This SCI completely interrupts direct supraspinal input to spinal locomotor circuits, but spares a bridge of intact neural tissue through which intraspinal remodeling could occur. This SCI not only led to permanent paralysis but also triggered various functional alterations that resembled the signature characteristics of neuronal dysfunction seen in human individuals. Anatomical analyses revealed that undirected compensatory plasticity of sub-lesional spinal circuits was in part responsible for neuronal dysfunction in the chronic stage of severe SCI. This aberrant sprouting led to a chaotic recruitment of sensorimotor circuits that contributed to the emergence of abnormal reflex properties and deterioration of gait performance. We next investigated whether neurorehabilitation augmented with neuroprosthetic technologies was able to prevent the development of neuronal dysfunction, and instead improve functional recovery, in rats with two opposite side, staggered lateral hemisections. For this aim, we developed a rehabilitation program combining (i) automated treadmill-based training to induce beneficial activity-dependent plasticity of sub-lesional spinal circuits and (ii) overground active training encouraging the rat to engage its paralyzed hindlimbs in order to promote remodeling of descending neuronal pathways. After eight weeks of active training, paralyzed rats recovered the capacity to initiate and sustain full-weight bearing bipedal locomotion overground, and even to climb staircases and avoid obstacles. Combinations of anatomical and complementary experiments demonstrated that training promoted multi-level plasticity of spared neuronal pathways above and across the lesion, which restored supraspinal control of lumbosacral locomotor circuits. Rats that were exclusively trained on the treadmill showed improved stepping capacities, but plasticity was restricted to the trained spinal circuits. They failed to initiate or sustain locomotion overground. These results demonstrate the importance of active training under highly functional states to promote reorganization of spared neuronal systems through activity-dependent mechanisms after a severe SCI. Activity-based approaches have become common medical practices to improve functional recovery following incomplete SCI in humans. However, after more severe SCI these interventions show limited efficacy, possibly due to the non-functional state of the spinal cord during training. A recent case study tested this hypothesis in a paraplegic man who suffered chronic motor paralysis. Epidural electrical spinal cord stimulation was applied during stand training to enable functional states of spinal circuits. After several months of rehabilitation, the chronically paralyzed individual regained supraspinal control over specific leg joint movements in a supine position. However, this capacity was only present when stimulation was applied. These results suggest that the therapeutic paradigms that we developed and demonstrated in rats may also apply to human patients. While challenges lie ahead, neurorehabilitation augmented with neuroprosthetic technologies may progressively become a new treatment option to improve functional recovery of spinal-cord-injured human patients. The present work emphasizes the importance of fostering bridges between neuroscience, technology and medicine to develop neurotechnologies and rehabilitation paradigms that have the potential to translate into clinical practices.

ETH Zurich2014

Uncovering the neural substrates of communication between the brain and ventral nerve cord in Drosophila melanogaster (italic)

Florian Aymanns

EPFL2022

Neurorehabilitation and neuroprosthetic technologies to regain motor function following spinal cord injury

Rubia van den Brand

ETH Zurich2014

Methods for acute and long-term imaging of the ventral nerve cord in behaving adult Drosophila

Laura Joan Hermans

EPFL2022