Estrela Neto

Neuropeptide Y and osteoblast differentiation - the balance between the neuro-osteogenic network and local control

Accumulating evidence has contributed to a novel view in bone biology: bone remodeling, specifically osteoblast differentiation, is under the tight control of the central and peripheral nervous systems. Among other players in this neuro‐osteogenic network, the neuropeptide Y (NPY) system has attracted particular attention. At the central nervous system level, NPY exerts its function in bone homeostasis through the hypothalamic Y2 receptor. Locally in the bone, NPY action is mediated by its Y1 receptor. Besides the presence of Y1, a complex network exists locally: not only there is input of the peripheral nervous system, as the bone is directly innervated by NPY‐containing fibers, but there is also input from non‐neuronal cells, including bone cells capable of NPY expression. The interaction of these distinct players to achieve a multilevel control system of bone homeostasis is still under debate. In this review, we will integrate the current knowledge on the impact of the NPY system in bone biology, and discuss the mechanisms through which the balance between central and the peripheral NPY action might be achieved.

Compartmentalized Microfluidic Platforms: The Unrivaled Breakthrough of In Vitro Tools for Neurobiological Research.

Microfluidic technology has become a valuable tool to the scientific community, allowing researchers to study fine cellular mechanisms with higher variable control compared with conventional systems. It has evolved tremendously, and its applicability and flexibility made its usage grow exponentially and transversely to several research fields. This has been particularly noticeable in neuroscience research, where microfluidic platforms made it possible to address specific questions extending from axonal guidance, synapse formation, or axonal transport to the development of 3D models of the CNS to allow pharmacological testing and drug screening. Furthermore, the continuous upgrade of microfluidic platforms has allowed a deeper study of the communication occurring between different neuronal and glial cells or between neurons and other peripheral tissues, both in physiological and pathological conditions. Importantly, the evolution of microfluidic technology has always been accompanied by the development of new computational tools addressing data acquisition, analysis, and modeling.

Microfluidics co-culture systems for studying tooth innervation

Innervation plays a key role in the development and homeostasis of organs and tissues of the orofacial complex. Among these structures, teeth are peculiar organs as they are not innervated until later stages of development. Furthermore, the implication of neurons in tooth initiation, morphogenesis and differentiation is still controversial. Co-cultures constitute a valuable method to investigate and manipulate the interactions of nerve fibers with their target organs in a controlled and isolated environment. Conventional co-cultures between neurons and their target tissues have already been performed, but these cultures do not offer optimal conditions that are closely mimicking the in vivo situation. Indeed, specific cell populations require different culture media in order to preserve their physiological properties. In this study we evaluate the usefulness of a microfluidics system for co-culturing mouse trigeminal ganglia and developing teeth. This device allows the application of specific media for the appropriate development of both neuronal and dental tissues. The results show that mouse trigeminal ganglia and teeth survive for long culture periods in this microfluidics system, and that teeth maintain the attractive or repulsive effect on trigeminal neurites that has been observed in vivo. Neurites are repealed when co-cultured with embryonic tooth germs, while postnatal teeth exert an attractive effect to trigeminal ganglia-derived neurons. In conclusion, microfluidics system devices provide a valuable tool for studying the behavior of neurons during the development of orofacial tissues and organs, faithfully imitating the in vivo situation.

Bone Injury and Repair Trigger Central and Peripheral NPY Neuronal Pathways

Bone repair is a specialized type of wound repair controlled by complex multi-factorial events. The nervous system is recognized as one of the key regulators of bone mass, thereby suggesting a role for neuronal pathways in bone homeostasis. However, in the context of bone injury and repair, little is known on the interplay between the nervous system and bone. Here, we addressed the neuropeptide Y (NPY) neuronal arm during the initial stages of bone repair encompassing the inflammatory response and ossification phases in femoral-defect mouse model. Spatial and temporal analysis of transcriptional and protein levels of NPY and its receptors, Y1R and Y2R, reported to be involved in bone homeostasis, was performed in bone, dorsal root ganglia (DRG) and hypothalamus after femoral injury. The results showed that NPY system activity is increased in a time- and space-dependent manner during bone repair. Y1R expression was trigged in both bone and DRG throughout the inflammatory phase, while a Y2R response was restricted to the hypothalamus and at a later stage, during the ossification step. Our results provide new insights into the involvement of NPY neuronal pathways in bone repair.

Communication from the periphery to the hypothalamus through the blood–brain barrier: An in vitro platform

One of the major routes of communication from the peripheral systems to the hypothalamus, the core structure of body homeostasis, is the humoral transmission through the blood-brain barrier (BBB). The BBB cultures are the in vitro model of choice to depict the mechanisms behind blood-brain interplay. Still, this strategy excludes the integration of the brain tissue response and, therefore, the resulting output might be limited. In this study, two in vitro assays were established: BBB coculture model and hypothalamic organotypic cultures. The combination of these two assays was used as a platform to address the two critical steps in the humoral transmission through the BBB to the brain: blood-BBB/BBB-brain. The in vitro model of the BBB was performed according to a coculture system using a brain microvascular endothelial cell line (bEnd.3) and primary astrocytes. The expression of junctional molecules as claudin-5, ZO-1, occludin and VE-cadherin was observed in the bEnd.3 cell-cell contact, confirming the BBB phenotype of these endothelial cells. Moreover, the transendothelial electrical resistance (TEER) values (71.1±9.4Ω× cm(2)) and the permeability coefficients (Pe) obtained in the transendothelial flux test (3.3±0.11×10(-6)cm/sec) support high integrity of the established barrier. The hypothalamic organotypic cultures were prepared from 8-days-old C57Bl/6 mice brains, based on the air-medium interface culture method. High cell viability (82±9.6%) and a dense neuronal network were achieved. The stimulation with dexamethasone resulted in an increased neuropeptide (NPY) expression, confirming the responsiveness of the neuronal system of these organotypic cultures. After optimization and characterization of each assay, the functionality of the platform was validated through the evaluation of the hypothalamic response to deep wound encompassing skin and muscle in mice. Results allowed to identify increased NPY activity in hypothalamic slices in response to peripheral signals within the plasma from wounded animals when compared with non-injured animals after surpassing and/or interacting with the BBB. This differential NPY response between the different animal conditions validated the functionality of the in vitro platform. In conclusion, this approach can be greatly anticipated as a useful tool for studying biologic or pharmacological circulating molecules and their impact on the hypothalamic activity.

Fracture pain—Traveling unknown pathways

An increase of fracture incidence is expected for the next decades, mostly due to the undeniable increase of osteoporotic fractures, associated with the rapid population ageing. The rise in sports-related fractures affecting the young and active population also contributes to this increased fracture incidence, and further amplifies the economical burden of fractures. Fracture often results in severe pain, which is a primary symptom to be treated, not only to guarantee individuals wellbeing, but also because an efficient management of fracture pain is mandatory to ensure proper bone healing. Here, we review the available data on bone innervation and its response to fracture, and discuss putative mechanisms of fracture pain signaling. In addition, the common therapeutic approaches to treat fracture pain are discussed. Although there is still much to learn, research in fracture pain has allowed an initial insight into the mechanisms involved. During the inflammatory response to fracture, several mediators are released and will putatively activate and sensitize primary sensory neurons, in parallel, intense nerve sprouting that occurs in the fracture callus area is also suggested to be involved in pain signaling. The establishment of hyperalgesia and allodynia after fracture indicates the development of peripheral and central sensitization, still, the underlying mechanisms are largely unknown. A major concern during the treatment of fracture pain needs to be the preservation of proper bone healing. However, the most common therapeutic agents, NSAIDS and opiates, can cause significant side effects that include fracture repair impairment. The understanding of the mechanisms of fracture pain signaling will allow the development of mechanisms-based therapies to effectively and safely manage fracture pain.

Axonal outgrowth, neuropeptides expression and receptors tyrosine kinase phosphorylation in 3D organotypic cultures of adult dorsal root ganglia

Limited knowledge from mechanistic studies on adult sensory neuronal activity was generated, to some extent, in recapitulated adult in vivo 3D microenvironment. To fill this gap there is a real need to better characterize the adult dorsal root ganglia (aDRG) organotypic cultures to make these in vitro systems exploitable for different approaches, ranging from basic neurobiology to regenerative therapies, to address the sensory nervous system in adult stage. We conducted a direct head-to-head comparison of aDRG and embryonic DRG (eDRG) organotypic culture focusing on axonal growth, neuropeptides expression and receptors tyrosine kinase (RTK) activation associated with neuronal survival, proliferation and differentiation. To identify alterations related to culture conditions, these parameters were also addressed in retrieved aDRG and eDRG and compared with organotypic cultures. Under similar neurotrophic stimulation, aDRG organotypic cultures displayed lower axonal outgrowth rate supported by reduced expression of growth associated protein-43 and high levels of RhoA and glycogen synthase kinase 3 beta mRNA transcripts. In addition, differential alteration in sensory neuropeptides expression, namely calcitonin gene-related peptide and substance P, was detected and was mainly pronounced at gene expression levels. Among 39 different RTK, five receptors from three RTK families were emphasized: tropomyosin receptor kinase A (TrkA), epidermal growth factor receptors (EGFR, ErbB2 and ErbB3) and platelet-derived growth factor receptor (PDGFR). Of note, except for EGFR, the phosphorylation of these receptors was dependent on DRG developmental stage and/or culture condition. In addition, EGFR and PDGFR displayed alterations in their cellular expression pattern in cultured DRG. Overall we provided valuable information particularly important when addressing in vitro the molecular mechanisms associated with development, maturation and regeneration of the sensory nervous system.

Ablation of Y1 receptor impairs osteoclast bone-resorbing activity.

Y1 receptor (Y1R)-signalling pathway plays a pivotal role in the regulation of bone metabolism. The lack of Y1R-signalling stimulates bone mass accretion that has been mainly attributed to Y1R disruption from bone-forming cells. Still, the involvement of Y1R-signalling in the control of bone-resorbing cells remained to be explored. Therefore, in this study we assessed the role of Y1R deficiency in osteoclast formation and resorption activity. Here we demonstrate that Y1R germline deletion (Y1R−/−) led to increased formation of highly multinucleated (n > 8) osteoclasts and enhanced surface area, possibly due to monocyte chemoattractant protein-1 (MCP-1) overexpression regulated by RANKL-signalling. Interestingly, functional studies revealed that these giant Y1R−/− multinucleated cells produce poorly demineralized eroded pits, which were associated to reduce expression of osteoclast matrix degradation markers, such as tartrate-resistant acid phosphatase-5b (TRAcP5b), matrix metalloproteinase-9 (MMP-9) and cathepsin-K (CTSK). Tridimensional (3D) morphologic analyses of resorption pits, using an in-house developed quantitative computational tool (BonePit), showed that Y1R−/− resorption pits displayed a marked reduction in surface area, volume and depth. Together, these data demonstrates that the lack of Y1Rs stimulates the formation of larger multinucleated osteoclasts in vitro with reduced bone-resorbing activity, unveiling a novel therapeutic option for osteoclastic bone diseases based on Y1R-signalling ablation.

Osteoclasts control sensory neurons axonal growth through epidermal growth factor receptor signaling

Dense ectopic sprouting of nerve fibers was reported in several bone pathologies featuring high osteoclast number and/or activity. Osteoclasts play a critical role on nociceptors activation; however, their contribution to nerve fibers outgrowth is unknown. This study provides compelling evidence that osteoclastic lineage has an intrinsic capacity to promote axonal outgrowth of dorsal root ganglia (DRG), surpassing the neurotrophic potential of bone marrow stromal cells. Using microfluidic devices, we showed that osteoclast-secreted molecules induced nerve growth via local action on nerve terminals. Interestingly, the axonal outgrowth mediated by osteoclast is neurotrophin-independent but implicate epidermal growth factor receptor (EGFR)/ErbB2 signaling. Ligand search studies showed lack of EGFR agonists in osteoclast secretome, however, demonstrated an increase of endogenous EGF in DRG under osteoclast stimulation. Moreover, proteomic analysis revealed molecules able to trigger EGFR signaling to induce osteoclast-mediated axonal outgrowth, as fibronectin, low-density lipoprotein receptor-related protein 1 and periostin.The patterning of peripheral innervation is accomplished through the tissue expression, in specific space and timeframe, of attractive or repulsive axonal guidance cues. At the bone microenvironment, neurotrophic factors such as nerve growth factor, brain-derived neurotrophic factor, vascular endothelial growth factor, netrin-1 and others were described to regulate the nerve ingrowth towards the bone compartment, by acting directly on receptors expressed at the nerve terminals. Interestingly, besides the gradient of soluble factors, neurons were described to be responsive to extracellular vesicles (EV) derived from myelinating cells and mesenchymal stem cells. Here we provide evidence on a new mechanism by which peripheral innervation can be coordinated. We show that sensory nerves outgrowth and electric signal propagation are dependent on the EV secreted by osteoclasts, the bone resorbing cells. Furthermore, we demonstrate that the axonal sprouting is achieved through the activation of epidermal-growth factor receptor (EGFR) family signaling pathway. We proved that the EV-depleted osteoclast secretome leads to a significant decrease of neurons firing rate and axonal sprouting, concomitant with a decrease of EGFR/ErbB2 activation levels. Excitingly, the proteomic analysis of the osteoclast-derived EV cargo shows a high correlation with synaptic components reinforcing the role on sensory neurons/osteoclast crosstalk. Our findings that osteoclast-derived EV hold effect in axonal outgrowth, contributing actively to the dynamics of the sensory neurons sprouting and electrophysiology, is a step toward unraveling target mechanisms to control electrical signal propagation and nerve fibers sprouting and consequently open new avenues for the development of innovative therapies to control bone pain. Significance Statement Sensory nerve fibers sprouting in bone pathologies is highly associated with pain. Thus, understanding the mechanisms behind sensory nerves ingrowth, sprouting and electrical activity, within the bone compartment, is essential for improving the strategies to overcome pain in bone disorders. We provide a new mechanism on the sensory nerves sprouting, indicating that the effect is dependent on the extracellular vesicles (EV) released by osteoclasts, through the epidermal growth factor receptor family targeting, by integrin independent pathways. We show different electrophysiology patterns being triggered in the presence of osteoclasts secretome and the abolishment of sensory neurons firing rate in EV-depleted conditions. Overall, our results elucidate novel mechanisms on the peripheral nerves sprouting, essential for pursuing new targets for bone pain therapies.

Bone marrow cell response after injury and during early stage of regeneration is independent of the tissue-of-injury in 2 injury models

Selectively recruiting bone marrow (BM)‐derived stem and progenitor cells to injury sites is a promising therapeutic approach. The coordinated action of soluble factors is thought to trigger the mobilization of stem cells from the BM and recruit them to lesions to contribute to tissue regeneration. Nevertheless, the temporal response profile of the major cellular players and soluble factors involved in priming the BM and recruiting BM‐derived cells to promote regeneration is unknown. We show that injury alters the BM cellular composition, introducing population‐specific fluctuations during tissue regeneration. We demonstrate that injury causes an immediate, transient response of mesenchymal stromal cells and endothelial cells followed by a nonoverlapping increase in hematopoietic stem and progenitor cells. Moreover, BM reaction is identical whether the injury is inflicted on skin and muscle or also involves a bone defect, but these 2 injury paradigms trigger distinct systemic cytokine responses. Together, our results indicate that the BM response to injury in the early stages of regeneration is independent of the tissue‐of‐injury based on the 2 models used, but the injured tissue dictates the systemic cytokine response.—Leitão, L., Alves, C. J., Alencastre, I. S., Sousa, D. M., Neto, E., Conceição, F., Leitão, C., Aguiar, P., Almeida‐Porada, G., Lamghari, M. Bone marrow cell response after injury and during early stage of regeneration is independent of the tissue‐of‐injury in 2 injury models. FASEB J. 33, 857–872 (2019). www.fasebj.org