Mechanical Forces Program the Orientation of Cell Division during Airway Tube Morphogenesis.

Oriented cell division plays a key role in controlling organogenesis. The mechanisms for regulating division orientation at the whole-organ level are only starting to become understood. By combining 3D time-lapse imaging, mouse genetics, and mathematical modeling, we find that global orientation of cell division is the result of a combination of two types of spindles with distinct spindle dynamic behaviors in the developing airway epithelium. Fixed spindles follow the classic long-axis rule and establish their division orientation before metaphase. In contrast, rotating spindles do not strictly follow the long-axis rule and determine their division orientation during metaphase. By using both a cell-based mechanical model and stretching-lung-explant experiments, we showed that mechanical force can function as a regulatory signal in maintaining the stable ratio between fixed spindles and rotating spindles. Our findings demonstrate that mechanical forces, cell geometry, and oriented cell division function together in a highly coordinated manner to ensure normal airway tube morphogenesis.

Morphogenesis of the rhea (Rhea americana) respiratory system in different embryonic and foetal stages / Morfogênese do sistema respiratório da ema (Rhea americana) em diferentes estágios embrionários e fetais

The rhea (Rhea americana) is an important wild species that has been highlighted in national and international livestock. This research aims to analyse embryo-foetal development in different phases of the respiratory system of rheas. Twenty-three embryos and foetuses were euthanized, fixed and dissected. Fragments of the respiratory system, including the nasal cavity, larynx, trachea, syrinx, bronchi and lungs, were collected and processed for studies using light and scanning electron microscopy. The nasal cavity presented cubic epithelium in the early stages of development. The larynx exhibited typical respiratory epithelium between 27 and 31 days. The trachea showed early formation of hyaline cartilage after 15 days. Syrinx in the mucous membrane of 18-day foetuses consisted of ciliated epithelium in the bronchial region. The main bronchi had ciliated epithelium with goblet cells in the syringeal region. In the lung, the parabronchial stage presented numerous parabronchi between 15 and 21 days. This study allowed the identification of normal events that occur during the development of the rhea respiratory system, an important model that has not previously been described. The information generated here will be useful for the diagnosis of pathologies that affect this organic system, aimed at improving captive production systems.(AU)

A ema (Rhea americana) representa importante espécie silvestre que vem se destacando na pecuaria nacional e internacional. Esta pesquisa objetiva analisar o desenvolvimento embrionário-fetal, em diferentes fases, do sistema respiratório de emas. Vinte e três embriões e fetos foram eutanasiados, fixados e dissecados. Fragmentos do sistema respiratório: cavidade nasal, laringe, traqueia, siringe, brônquios e pulmões, foram coletados e processados para estudos por meio de microscopia de luz e microscopia eletrônica de varredura. A cavidade nasal apresentou, nas primeiras fases de desenvolvimento, epitélio estratificado cúbico. A laringe exibiu epitélio respiratório típico entre 27 e 31 dias. A traqueia aos 15 dias apresentou início de formação da cartilagem hialina. Na siringe a túnica mucosa de fetos de 18 dias e formada por epitélio estratificado ciliado na região bronquial. Os brônquios principais apresentavam epitélio estratificado ciliado com células caliciformes na região siringeal. No pulmão, o estágio parabronquial apresentou numerosos parabrônquios entre 15 a 21 dias. Este estudo permitiu a identificação de eventos normais que ocorrem durante o desenvolvimento do sistema respiratório de emas, importante modelo ainda não descrito. As informações geradas serão úteis para o diagnóstico de patologias que acometem este sistema orgânico, visando a melhoria dos sistemas de produção em cativeiro.(AU)

Hydrogen Sulfide: A Novel Player in Airway Development, Pathophysiology of Respiratory Diseases, and Antiviral Defenses.

Hydrogen sulfide (H2S) is a biologically relevant signaling molecule in mammals. Along with the volatile substances nitric oxide (NO) and carbon monoxide (CO), H2S is defined as a gasotransmitter. It plays a physiological role in a variety of functions, including synaptic transmission, vascular tone, angiogenesis, inflammation, and cellular signaling. The generation of H2S is catalyzed by cystathionine ß-synthase (CBS), cystathionine γ-lyase (CSE), and 3-mercaptopyruvate sulfurtransferase (3-MST). The expression of CBS and CSE is tissue specific, with CBS being expressed predominantly in the brain, and CSE in peripheral tissues, including lungs. CSE expression and activity are developmentally regulated, and recent studies suggest that CSE plays an important role in lung alveolarization during fetal development. In the respiratory tract, endogenous H2S has been shown to participate in the regulation of important functions such as airway tone, pulmonary circulation, cell proliferation or apoptosis, fibrosis, oxidative stress, and inflammation. In the past few years, changes in the generation of H2S have been linked to the pathogenesis of a variety of acute and chronic inflammatory lung diseases, including asthma and chronic obstructive pulmonary disease. Recently, our laboratory made the critical discovery that cellular H2S exerts broad-spectrum antiviral activity both in vitro and in vivo, in addition to independent antiinflammatory activity. These findings have important implications for the development of novel therapeutic strategies for viral respiratory infections, as well as other inflammatory lung diseases, especially in light of recent significant efforts to generate controlled-release H2S donors for clinical therapeutic applications.

Transient junction anisotropies orient annular cell polarization in the Drosophila airway tubes.

In contrast to planes, three-dimensional (3D) structures such as tubes are physically anisotropic. Tubular organs exhibit a striking orientation of landmarks according to the physical anisotropy of the 3D shape, in addition to planar cell polarization. However, the influence of 3D tissue topography on the constituting cells remains underexplored. Here, we identify a regulatory network polarizing cellular biochemistry according to the physical anisotropy of the 3D tube geometry (tube cell polarization) by a genome-wide, tissue-specific RNAi screen. During Drosophila airway remodelling, each apical cellular junction is equipotent to establish perpendicular actomyosin cables, irrespective of the longitudinal or transverse tube axis. A dynamic transverse enrichment of atypical protein kinase C (aPKC) shifts the balance and transiently targets activated small GTPase RhoA, myosin phosphorylation and Rab11 vesicle trafficking to longitudinal junctions. We propose that the PAR complex translates tube physical anisotropy into longitudinal junctional anisotropy, where cell-cell communication aligns the contractile cytoskeleton of neighbouring cells.

Cardiac misconceptions among healthy adults: implications for the promotion of health in the community / Crenças erróneas sobre as doenças cardíacas em adultos saudáveis: implicações para a promoção da saúde na comunidade

This study sought to confirm the structure and to investigate the psychometric properties of an experimental Portuguese version of the York Cardiac Beliefs Questionnaire (YCBQ) in a general population sample. It also set out to identify the prevalent misconceptions in the community and to assess the differences according to socio-demographic characteristics. It involved a cross-sectional survey in which both test and validation samples were collected (n = 476), including participants aged between 18 and 40, recruited via e-mail and social networks. The Confirmatory Factor Analysis on both samples suggested a shorter, three factor version of the YCBQ. Also, misconceptions differed significantly according to sociodemographic variables. The validation of the YCBQ for samples in the community constitutes an important starting point to promote research on misconceptions held in the community by specific groups, as well as to provide key points for health promotion.

Este estudo teve como objetivo confirmar a estrutura e investigar as propriedades psicométricas de uma versão experimental portuguesa do York Cardiac Beliefs Questionnaire numa amostra da população geral; identificar as crenças erróneas mais fortes na comunidade; e avaliar as diferenças de acordo com características sociodemográficas. Trata-se de um estudo transversal com uma amostra de teste e outra de validação, incluindo um total de 476 participantes, com idade entre 18 e 40 anos, recrutados via e-mail e nas redes sociais. A Análise Fatorial Confirmatória em ambas as amostras indicou uma versão reduzida do YCBQ de três factores. As crenças erróneas diferiram significativamente de acordo com as variáveis sociodemográficas. A validação do YCBQ para amostras da comunidade constitui um importante ponto de partida para promover a investigação sobre crenças erróneas em grupos específicos da comunidade, assim como fornecer indicadores relevantes para a promoção da saúde.

Understanding the development of the respiratory glands.

BACKGROUND: The submucosal glands (SMGs) of the respiratory system are specialized structures essential for maintaining airway homeostasis. The significance of SMGs is highlighted by their involvement in respiratory diseases such as cystic fibrosis, asthma and chronic bronchitis, where their phenotype and function are severely altered. Uncovering the normal development of the airway SMGs is essential to elucidate their role in these disorders, however, very little is known about the cellular mechanisms and intracellular signals involved in their morphogenesis. RESULTS: This review describes in detail the embryonic developmental journey of the nasal SMGs and the postnatal development of the tracheal SMGs in the mouse. Current knowledge of the genes and signalling molecules involved in SMG organogenesis is also explored. CONCLUSION: Here we review the temporal localisation and development of the murine respiratory glands in the hope of stimulating further research into the mechanisms required for successful SMG patterning and function.

Btk-dependent epithelial cell rearrangements contribute to the invagination of nearby tubular structures in the posterior spiracles of Drosophila.

The Drosophila respiratory system consists of two connected organs, the tracheae and the spiracles. Together they ensure the efficient delivery of air-borne oxygen to all tissues. The posterior spiracles consist internally of the spiracular chamber, an invaginated tube with filtering properties that connects the main tracheal branch to the environment, and externally of the stigmatophore, an extensible epidermal structure that covers the spiracular chamber. The primordia of both components are first specified in the plane of the epidermis and subsequently the spiracular chamber is internalized through the process of invagination accompanied by apical cell constriction. It has become clear that invagination processes do not always or only rely on apical constriction. We show here that in mutants for the src-like kinase Btk29A spiracle cells constrict apically but do not complete invagination, giving rise to shorter spiracular chambers. This defect can be rescued by using different GAL4 drivers to express Btk29A throughout the ectoderm, in cells of posterior segments only, or in the stigmatophore pointing to a non cell-autonomous role for Btk29A. Our analysis suggests that complete invagination of the spiracular chamber requires Btk29A-dependent planar cell rearrangements of adjacent non-invaginating cells of the stigmatophore. These results highlight the complex physical interactions that take place among organ components during morphogenesis, which contribute to their final form and function.

Fascin links Btl/FGFR signalling to the actin cytoskeleton during Drosophila tracheal morphogenesis.

A key challenge in normal development and in disease is to elucidate the mechanisms of cell migration. Here we approach this question using the tracheal system of Drosophila as a model. Tracheal cell migration requires the Breathless/FGFR pathway; however, how the pathway induces migration remains poorly understood. We find that the Breathless pathway upregulates singed at the tip of tracheal branches, and that this regulation is functionally relevant. singed encodes Drosophila Fascin, which belongs to a conserved family of actin-bundling proteins involved in cancer progression and metastasis upon misregulation. We show that singed is required for filopodia stiffness and proper morphology of tracheal tip cells, defects that correlate with an abnormal actin organisation. We propose that singed-regulated filopodia and cell fronts are required for timely and guided branch migration and for terminal branching and branch fusion. We find that singed requirements rely on its actin-bundling activity controlled by phosphorylation, and that active Singed can promote tip cell features. Furthermore, we find that singed acts in concert with forked, another actin cross-linker. The absence of both cross-linkers further stresses the relevance of tip cell morphology and filopodia for tracheal development. In summary, our results on the one hand reveal a previously undescribed role for forked in the organisation of transient actin structures such as filopodia, and on the other hand identify singed as a new target of Breathless signal, establishing a link between guidance cues, the actin cytoskeleton and tracheal morphogenesis.

Effects of the inflammatory cytokines TNF-α and IL-13 on stromal interaction molecule-1 aggregation in human airway smooth muscle intracellular Ca(2+) regulation.

Inflammation elevates intracellular Ca(2+) ([Ca(2+)]i) concentrations in airway smooth muscle (ASM). Store-operated Ca(2+) entry (SOCE) is an important source of [Ca(2+)]i mediated by stromal interaction molecule-1 (STIM1), a sarcoplasmic reticulum (SR) protein. In transducing SR Ca(2+) depletion, STIM1 aggregates to form puncta, thereby activating SOCE via interactions with a Ca(2+) release-activated Ca(2+) channel protein (Orai1) in the plasma membrane. We hypothesized that STIM1 aggregation is enhanced by inflammatory cytokines, thereby augmenting SOCE in human ASM cells. We used real-time fluorescence microscopic imaging to assess the dynamics of STIM1 aggregation and SOCE after exposure to TNF-α or IL-13 in ASM cells overexpressing yellow fluorescent protein-tagged wild-type STIM1 (WT-STIM1) and STIM1 mutants lacking the Ca(2+)-sensing EF-hand (STIM1-D76A), or lacking the cytoplasmic membrane binding site (STIM1ΔK). STIM1 aggregation was analyzed by monitoring puncta size during the SR Ca(2+) depletion induced by cyclopiazonic acid (CPA). We found that puncta size was increased in cells expressing WT-STIM1 after CPA. However, STIM1-D76A constitutively formed puncta, whereas STIM1ΔK failed to form puncta. Furthermore, cytokines increased basal WT-STIM1 puncta size, and the SOCE triggered by SR Ca(2+) depletion was increased in cells expressing WT-STIM1 or STIM1-D76A. Meanwhile, SOCE in cells expressing STIM1ΔK and STIM1 short, interfering RNA (siRNA) was decreased. Similarly, in cells overexpressing STIM1, the siRNA knockdown of Orai1 blunted SOCE. However, exposure to cytokines increased SOCE in all cells, increased basal [Ca(2+)]i, and decreased SR Ca(2+) content. These data suggest that cytokines induce a constitutive increase in STIM1 aggregation that contributes to enhanced SOCE in human ASM after inflammation. Such effects of inflammation on STIM1 aggregations may contribute to airway hyperresponsiveness.

Mitotic cell rounding accelerates epithelial invagination.

Mitotic cells assume a spherical shape by increasing their surface tension and osmotic pressure by extensively reorganizing their interphase actin cytoskeleton into a cortical meshwork and their microtubules into the mitotic spindle. Mitotic entry is known to interfere with tissue morphogenetic events that require cell-shape changes controlled by the interphase cytoskeleton, such as apical constriction. However, here we show that mitosis plays an active role in the epithelial invagination of the Drosophila melanogaster tracheal placode. Invagination begins with a slow phase under the control of epidermal growth factor receptor (EGFR) signalling; in this process, the central apically constricted cells, which are surrounded by intercalating cells, form a shallow pit. This slow phase is followed by a fast phase, in which the pit is rapidly depressed, accompanied by mitotic entry, which leads to the internalization of all the cells in the placode. We found that mitotic cell rounding, but not cell division, of the central cells in the placode is required to accelerate invagination, in conjunction with EGFR-induced myosin II contractility in the surrounding cells. We propose that mitotic cell rounding causes the epithelium to buckle under pressure and acts as a switch for morphogenetic transition at the appropriate time.

CDC42 is required for structural patterning of the lung during development.

The formation of highly branched epithelial structures is critical for the development of many essential organs, including lung, liver, pancreas, kidney and mammary glands. Elongation and branching of these structures require precise control of complex morphogenetic processes that are dependent upon coordinate regulation of cell shape, apical-basal polarity, proliferation, migration, and interactions among multiple cell types. Herein, we demonstrate that temporal-spatial regulation of epithelial cell polarity by the small GTPase, CDC42, is essential for branching morphogenesis of the developing lung. Epithelial cell-specific deletion of CDC42 in fetal mice disrupted epithelial cell polarity, the actin cytoskeleton, intercellular contacts, directional trafficking of proteins, proliferation and mitotic spindle orientation, impairing the organization and patterning of the developing respiratory epithelium and adjacent mesenchyme. Transition from a pseudostratified to a simple columnar epithelium was impaired, consistent with coordinate dysregulation of epithelial cell polarity, mitotic spindle orientation, and repositioning of mitotic cells within the epithelium during cell cycle progression. Expression of sonic hedgehog and its receptor, patched-1, was decreased, while fibroblast growth factor 10 expression in the mesenchyme was expanded, resulting in disruption of branching morphogenesis and bronchiolar smooth muscle formation in this model. CDC42 is required for spatial positioning of proliferating epithelial cells, as well as signaling interactions between the epithelium and mesenchyme and is, therefore, essential for formation and maintenance of the respiratory tract during morphogenesis of the fetal lung.

Embryology of the early foregut.

In embryology, no agreement exists how the early foregut differentiates into the respiratory tract and the intestinal tract. In particular, the formation of the early lung anlage as well as the process of separation of trachea and esophagus remains unclear. This process is explained in a rather schematic way and aims more to explain pathologic findings, whereas true embryologic investigations are extremely rare in this field. Here, scanning electron microscopy of the normal foregut development illustrates the steps, which finally leads to the development of larynx and trachea on the one hand, and pharynx and esophagus on the other hand. This study was performed in chicken embryos in accordance to the developmental stages described. As the main results from these illustrations show, we found no evidence for lateral foregut ridges inside the undivided foregut chamber and no fusion of lateral foregut components to form a trachea-esophageal septum.

Neural crest cell origin and signals for intrinsic neurogenesis in the mammalian respiratory tract.

Our study investigates the innervation of the respiratory tract during mouse embryonic development, with a focus on the identification of cell origin and essential developmental signals for the resident, or intrinsic, neurons. Using lineage tracing, we show that these intrinsic neurons are exclusively derived from neural crest cells, and cluster to form ganglia that reside in the dorsal trachea and medial bronchi with diminishing frequency. Comparisons of intrinsic neurogenesis between wild-type, glial cell-derived neurotrophic factor (GDNF)(-/-), neurturin(-/-), and tyrosine kinase receptor Ret(-/-) embryos, in combination with lung organ cultures, identified that Ret signaling, redundantly activated by GDNF family members, is required for intrinsic neurogenesis in the trachea and primary bronchi. In contrast, Ret deficiency exerts no effect on the innervation of the rest of the respiratory tract, suggesting that innervation by neurons whose cell bodies are located outside of the lung (so-called extrinsic neurons) is independent of Ret signaling. Furthermore, although the trachea, the esophagus, and their intrinsic neurons share foregut endoderm and a neural crest cell origin, respectively, the signals required for their intrinsic neurogenesis are divergent. Together, our results not only establish the neural crest lineage of intrinsic neurons in the respiratory tract, but also identify regional differences in the abundance and developmental signals of intrinsic neurons along the respiratory tract and in the esophagus.

Expression of TMEM16 paralogs during murine embryogenesis.

The TMEM16 protein family has recently been identified through several different experimental strategies including bioinformatic and microarray-based approaches. In mice and humans, there exist 10 paralogs with each containing eight putative transmembrane domains and a conserved C-terminal domain of unknown function. Mutation of at least one member of this family is associated with a human disorder, and several members of this gene family are overexpressed in different types of cancer. Despite their apparent relevance to normal development and disease, little is known about the expression of TMEM16 paralogs during embryonic development. Here, we provide a phylogenetic analysis of mouse and human TMEM16 paralogs and report the expression of Tmem16a, Tmem16b, Tmem16c, Tmem16f, Tmem16h, Tmem16j, and Tmem16k during murine embryogenesis with an emphasis on the respiratory, digestive, skeletal, and integumentary systems. These data should encourage investigations into the functions of TMEM16 paralogs in vertebrate development.

The glandular stem/progenitor cell niche in airway development and repair.

Airway submucosal glands (SMGs) are major secretory structures that lie beneath the epithelium of the cartilaginous airway. These glands are believed to play important roles in normal lung function and airway innate immunity by secreting antibacterial factors, mucus, and fluid into the airway lumen. Recent studies have suggested that SMGs may additionally serve as a protective niche for adult epithelial stem/progenitor cells of the proximal airways. As in the case of other adult stem cell niches, SMGs are believed to provide the localized environmental signals required to both maintain and mobilize stem/progenitor cells, in the setting of normal cellular turnover or injury. Aberrant proliferation and differentiation of glandular stem/progenitor cells may be associated with several hypersecretory lung diseases, including chronic bronchitis, asthma, and cystic fibrosis. To better understand the molecular mechanisms that regulate the specification and proliferation of glandular stem/progenitor cells in lung diseases associated with SMG hypertrophy and hyperplasia, researchers have begun to search for the molecular signals and cell types responsible for establishing the glandular stem/progenitor cell niche, and to dissect how these determinants of the niche change in the setting of proximal airway injury and repair. Such studies have revealed certain similarities between stem/progenitor cell niches of the distal conducting airways and the SMGs of the proximal airways.

Prenatal nicotine alters maturation of breathing and neural circuits regulating respiratory control.

While perinatal nicotine effects on ventilation have been widely investigated, the prenatal impact of nicotine treatment during gestation on both breathing and neural circuits involved in respiratory control remains unknown. We examined the effects of nicotine, from embryonic day 5 (E5) to E20, on baseline ventilation, the two hypoxic ventilatory response components and in vivo tyrosine hydroxylase (TH) activity in carotid bodies and brainstem areas, assessed at postnatal day 7 (P7), P11 and P21. In pups prenatally exposed to nicotine, baseline ventilation and hypoxic ventilatory response were increased at P7 (+48%) and P11 (+46%), with increased tidal volume (p<0.05). Hypoxia blunted frequency response at P7 and revealed unstable ventilation at P11. In carotid bodies, TH activity increased by 20% at P7 and decreased by 48% at P11 (p<0.05). In most brainstem areas it was reduced by 20-33% until P11. Changes were resolved by P21. Prenatal nicotine led to postnatal ventilatory sequelae, partly resulting from impaired maturation of peripheral chemoreceptors and brainstem integrative sites.

Desarrollo pulmonar / Lung development

El desarrollo pulmonar es un proceso complejo y altamente organizado, en el que se reconocen varias etapas dinámicas: embrionaria, pseudoglandular, canalicular, sacular, alveolar, maduración microvascular, hiperplasia activa e hipertrofia. El desarrollo de la vía aérea es seguido de modo estrecho por el desarrollo de la vasculatura pulmonar, para concluir en la formación de la unidad alvéolo-capilar. Todos estos procesos se encuentran controlados estrechamente por factores genéticos, tales como factores de crecimiento y otras moléculas, de acción sólo parcialmente comprendida. Para alcanzar un normal desarrollo, son fundamentales los movimientos respiratorios fetales, un adecuado espacio intratorácico, fluido intra y extrapulmonar en volumen suficiente y una adecuada irrigación y nutrición. Durante los procesos de organogénesis pueden ocurrir diversas alteraciones, debidas a factores materno-fetales, genéticos o ambientales, originando así anomalías del desarrollo, tanto en el período prenatal como postnatal. La respiración fetal y el fluido pulmonar juegan un papel importante en la delicada relación entre los epitelios de la vía aérea y el mesénquima, al promover el crecimiento pulmonar. Los movimientos respiratorios son fundamentales en la preservación del volumen pulmonar. Se postula que las contracciones peristálticas espontáneas de la vía aérea, favorecen la expansión de los brotes pulmonares al facilitar su crecimiento hacia el mesénquima circundante. Los corticoides, administrados en el período pre o postnatal, aceleran el crecimiento pulmonar por variados mecanismos, a costa de acortar el período de formación de los septos y disminuir el número final de alvéolos.

[Developmental peculiarities of gas transporting system in chick embryo under respiratory surface restriction].

The half of the chick eggshell surface was covered by the gas-proof layer on the 11th day and the incubation was continued up to the 14th day. The histological investigation of the chorioallantoic membrane after three days of experiment revealed that the blood vessels reduction in the covered part was completely compensated for by vessel dilatation and the growing in the mesodermal layer of intact part with parallel reorganization and dilation of capillary network on its surface. The blood gas capacity increase was supported for by haematocrit and haemoglobin growth and erythropoiesis stimulation. Cardiac work intensification was provided with the left ventricular myocyte hyperplasia and accelerated differentiation. The coordinated mobilization of all branches of gas transporting system compensated for surface half diminution to maintain the normal metabolic level in embryo during 11-14th days of incubation.

Interaction of epithelium with mesenchyme affects global features of lung architecture: a computer model of development.

Lung airway morphogenesis is simulated in a simplified diffusing environment that simulates the mesenchyme to explore the role of morphogens in airway architecture development. Simple rules govern local branching morphogenesis. Morphogen gradients are modeled by four pairs of sources and their diffusion through the mesenchyme. Sensitivity to lobar architecture and mesenchymal morphogen are explored. Even if the model accurately represents observed patterns of local development, it could not produce realistic global patterns of lung architecture if interaction with its environment was not taken into account, implying that reciprocal interaction between airway growth and morphogens in the mesenchyme plays a critical role in producing realistic global features of lung architecture.

Un modelo anfibio para el estudio evolutivo del control respiratorio / Anphibian model study for evolutionary respiratory control

Los enormes progresos de la medicina perinatal han permitido la sobrevivencia de recién nacidos prematuros en estadios de desarrollo cada vez más precoces. Estos pequeños pacientes requieren de medios muy sofisticados y costosos para paliar su inmadurez respiratoria. Además de las complicaciones asociadas al desarrollo pulmonar, la inestabilidad respiratoria y las apneas asociadas a la inmadurez de los circuitos nerviosos productores del control respiratorio, contribuyendo éstos últimas, como factor principal de morbilidad, a las prolongadas hospitalizaciones que presenta esta tan vulnerable población. Éstos imperativos médicos combinados a la curiosidad fisiológica han contribuido al desenvolvimiento de novedosas investigaciones en neurobiología respiratoria. Si bien la mayoría de los trabajos realizados en éste campo utilizan a los múridos como modelos experimentales, las investigaciones recientes efectuadas a partir del tronco cerebral aislado de anfibios (Rana catesbeiana) han revelado las ventajas técnicas de este modelo animal, para mostrar los principales fenómenos que rigen el funcionamiento y el desarrollo del sistema de control respiratorio entre los vertebrados. El presente artículo se propone repasar los avances más recientes realizados en la investigación de la neurobiología evolutiva del control respiratorio, prestando una atención particular a la respiración episódica, así como al rol que desempeñan la modulación serotoninérgica y Gabaérgica de la actividad respiratoria en el curso del desarrollo.

Recent perinal advances have made possible that premature newborns survive increasingtly in earlier developmental stages. This babies requires sophisticated and costly critical intensive care to address the problems associated with inmadurity of the respiratory system. In addition respiratory instability and apnea reflecting inmaturity of the respiratory control system are major causes of morbidity and prolonged hospitalization in this highly vulnerable group of patients. These concerns have contributed to the development of research in respiratoy evolutionary neurobiology. While the majority of researchers working in this field use rodents as an animal model, recent research using in vitro brainstem preparations from bullfrog (Rana catesbeiana) have reveled the technical advantages of this model to study the basic principles underlying respiratory control and its ontogeny between vertebrates. The present article review the recent advances in the area of research with special interest on episodic breathing and the role of serotoninergic and GABAergic modulation of respiratory control during development.