Perceptual decision making in larval zebrafish revealed by whole-brain imaging

Animals are able to accumulate sensory evidence over considerable timescales in order to select behaviors fundamental for their survival. Despite the importance and ubiquity of this phenomenon, how activity in different brain regions contributes to this process is not understood. In this study, I develop a novel perceptual decision making assay in the larval zebrafish, based on whole-field visual motion of varying strength. Upon presentation of motion, fish integrate this noisy sensory evidence in time before swimming in the direction of perceived motion, a behavior known as the optomotor response. Behavioral parameters such as the latency to initiate swimming and the fraction of correct turns are modulated by motion strength. Whole-brain functional imaging experiments with single-cell resolution enable identification of almost all neural activity relevant to the different stages of the decision making process, including evaluation of momentary sensory input, accumulation of this sensory evidence, and behavioral output. Fitting a generalized integrator model to every neuron reveals a wide range of time constants, which are distributed in functional clusters across different brain regions. Based on the behavior and the imaging data, a model is proposed where integrating units set the left and right turning rates. An unbiased whole-brain analysis revealed that the interpeduncular nucleus, a circular structure located ventrally on the midline of the brain, reliably encodes these rates

Collective motion of cells: from experiments to models

Swarming or collective motion of living entities is one of the most common and spectacular manifestations of living systems having been extensively studied in recent years. A number of general principles have been established. The interactions at the level of cells are quite different from those among individual animals therefore the study of collective motion of cells is likely to reveal some specific important features which are overviewed in this paper. In addition to presenting the most appealing results from the quickly growing related literature we also deliver a critical discussion of the emerging picture and summarize our present understanding of collective motion at the cellular level. Collective motion of cells plays an essential role in a number of experimental and real-life situations. In most cases the coordinated motion is a helpful aspect of the given phenomenon and results in making a related process more efficient (e.g., embryogenesis or wound healing), while in the case of tumor cell invasion it appears to speed up the progression of the disease. In these mechanisms cells both have to be motile and adhere to one another, the adherence feature being the most specific to this sort of collective behavior. One of the central aims of this review is both presenting the related experimental observations and treating them in the light of a few basic computational models so as to make an interpretation of the phenomena at a quantitative level as well.Comment: 24 pages, 25 figures, 13 reference video link

Phenotypic Architecture and Genetic polymorphims Associated with Social Behaviour in Zebra fish

"Social behaviour is fundamental for the survival and reproduction of organisms, and most animals are social to some degree. It is generally recognized that many neuropsychiatric diseases are associated with some form of social deficit or are accompanied by social impairments. There is also evidence that actual and perceived social isolation are both related with increased mortality risk. Given that social behaviour is central in both humans and other animals’ lives, many researchers with different backgrounds have been actively engaged in the challenge of understanding the nature of this highly complex and dynamic phenomenon. Social behaviour that independently evolved multiple times across animals is an extremely diverse behavioural category, influenced by multiple factors (genes, hormones, environment, ecology, development, life history trait, etc.) requiring a multidisciplinary approach, integrative analysis and standardized terminologies. However, despite its great diversity (both between and within species), there are similarities namely at mechanistic and functional level, which allows organizing social behaviours in functional modules, similar to those used in gene ontology categories.

Socially driven changes in neural and behavioural plasticity in zebrafish

Tese de doutoramento, Biologia (Etologia), Universidade de Lisboa, Faculdade de Ciências, 2015Social competence, the ability of individuals to regulate the expression of their social behaviour in order to optimize their social relationships in a group, is especially benefic for individuals living in complex social environments, and implies the ability to perceive social cues and produce appropriate behavioural output responses (Social Plasticity). Numerous examples of social competence can be found in nature, where individuals extract social information from the environment, and change their behavioural response based on the collected information. At the neuronal level, two major plasticity mechanisms have been proposed to underlie social plasticity, structural reorganization and biochemical switching of the neuronal networks underlying behaviour. The neural substrate for behavioural plasticity has been identified as the social decision-making (SDM) network, such that the same neural circuitry may underlie the expression of different behaviours depending on social context. The goal of this work is to study the proximate mechanism underlying behavioural flexibility in the context of experience-dependent behavioural shifts, in an integrative framework. For this purpose we exposed male zebrafish to two types of social interactions: (1) real-opponent interactions, from which a Winner and Loser emerged; and (2) Mirror-elicited interactions, that produced individuals that did not experience a change in social status, despite expressing similar levels of aggressive behaviour to those participating in real-opponent fights. In a first set of experiments, we studied the influence of neuromodulators on social plasticity mechanisms, by characterizing the endocrine response to social challenges, as well as the social modulation of brain monoamines and nonapeptides. Next we tested the SDM network hypothesis by contrasting changes in functional localization vs. connectivity across this network. Finally we characterized changes in expression of key genes for different neuroplasticity mechanisms in response to changes in social status. Our research suggests different social plasticity mechanisms underlying Winners and Losers both at physiological and molecular levels, for Mirror-fighters, where the experience of winning or losing was decoupled for the fighting experience, few changes were detected. This, by itself suggests a pivotal role of social perception in triggering shifts between socially driven behavioural states

The malleable brain: plasticity of neural circuits and behavior: A review from students to students

One of the most intriguing features of the brain is its ability to be malleable, allowing it to adapt continually to changes in the environment. Specific neuronal activity patterns drive long-lasting increases or decreases in the strength of synaptic connections, referred to as long-term potentiation (LTP) and long-term depression (LTD) respectively. Such phenomena have been described in a variety of model organisms, which are used to study molecular, structural, and functional aspects of synaptic plasticity. This review originated from the first International Society for Neurochemistry (ISN) and Journal of Neurochemistry (JNC) Flagship School held in Alpbach, Austria (Sep 2016), and will use its curriculum and discussions as a framework to review some of the current knowledge in the field of synaptic plasticity. First, we describe the role of plasticity during development and the persistent changes of neural circuitry occurring when sensory input is altered during critical developmental stages. We then outline the signaling cascades resulting in the synthesis of new plasticity-related proteins, which ultimately enable sustained changes in synaptic strength. Going beyond the traditional understanding of synaptic plasticity conceptualized by LTP and LTD, we discuss system-wide modifications and recently unveiled homeostatic mechanisms, such as synaptic scaling. Finally, we describe the neural circuits and synaptic plasticity mechanisms driving associative memory and motor learning. Evidence summarized in this review provides a current view of synaptic plasticity in its various forms, offers new insights into the underlying mechanisms and behavioral relevance, and provides directions for future research in the field of synaptic plasticity.Fil: Schaefer, Natascha. University of Wuerzburg; AlemaniaFil: Rotermund, Carola. University of Tuebingen; AlemaniaFil: Blumrich, Eva Maria. Universitat Bremen; AlemaniaFil: Lourenco, Mychael V.. Universidade Federal do Rio de Janeiro; BrasilFil: Joshi, Pooja. Robert Debre Hospital; FranciaFil: Hegemann, Regina U.. University of Otago; Nueva ZelandaFil: Jamwal, Sumit. ISF College of Pharmacy; IndiaFil: Ali, Nilufar. Augusta University; Estados UnidosFil: García Romero, Ezra Michelet. Universidad Veracruzana; MéxicoFil: Sharma, Sorabh. Birla Institute of Technology and Science; IndiaFil: Ghosh, Shampa. Indian Council of Medical Research; IndiaFil: Sinha, Jitendra K.. Indian Council of Medical Research; IndiaFil: Loke, Hannah. Hudson Institute of Medical Research; AustraliaFil: Jain, Vishal. Defence Institute of Physiology and Allied Sciences; IndiaFil: Lepeta, Katarzyna. Polish Academy of Sciences; ArgentinaFil: Salamian, Ahmad. Polish Academy of Sciences; ArgentinaFil: Sharma, Mahima. Polish Academy of Sciences; ArgentinaFil: Golpich, Mojtaba. University Kebangsaan Malaysia Medical Centre; MalasiaFil: Nawrotek, Katarzyna. University Of Lodz; ArgentinaFil: Paid, Ramesh K.. Indian Institute of Chemical Biology; IndiaFil: Shahidzadeh, Sheila M.. Syracuse University; Estados UnidosFil: Piermartiri, Tetsade. Universidade Federal de Santa Catarina; BrasilFil: Amini, Elham. University Kebangsaan Malaysia Medical Centre; MalasiaFil: Pastor, Verónica. Consejo Nacional de Investigaciones Científicas y Técnicas. Oficina de Coordinación Administrativa Houssay. Instituto de Biología Celular y Neurociencia ; ArgentinaFil: Wilson, Yvette. University of Melbourne; AustraliaFil: Adeniyi, Philip A.. Afe Babalola University; NigeriaFil: Datusalia, Ashok K.. National Brain Research Centre; IndiaFil: Vafadari, Benham. Polish Academy of Sciences; ArgentinaFil: Saini, Vedangana. University of Nebraska; Estados UnidosFil: Suárez Pozos, Edna. Instituto Politécnico Nacional; MéxicoFil: Kushwah, Neetu. Defence Institute of Physiology and Allied Sciences; IndiaFil: Fontanet, Paula. Consejo Nacional de Investigaciones Científicas y Técnicas. Oficina de Coordinación Administrativa Houssay. Instituto de Biología Celular y Neurociencia ; ArgentinaFil: Turner, Anthony J.. University of Leeds; Reino Unid

Neuroendocrine regulation of social Interactions in a cichlid fish

Tese apresentada para cumprimentos dos requisitos necessários à obtenção do grau de Doutor em Biologia do Comportamento apresentada no ISPA - Instituto Universitário no ano de 2019.O estudo do comportamento animal e em particular do comportamento social tem atraído investigadores desde há muito tempo. Todos os animais interagem com os outros, característica fundamental para a sua sobrevivência e reprodução. No entanto, para obter uma total compreensão do comportamento social, é necessária a integração de seus vários componentes. Com esta tese, pretendemos clarificar este tópico, estudando como o cérebro controla o comportamento através da ação conjunta de seus circuitos neurais, genes e moléculas, e também como o ambiente social de forma recíproca influencia o cérebro. Baseado neste objetivo e usando a tilápia de Moçambique (Oreochromis mossambicus) como espécie modelo, num primeiro estudo investigámos como o comportamento social é controlado por uma rede dinâmica de regiões cerebrais, a Social Decision Making Network (SDMN). Aqui, tentámos entender quais são as pistas específicas que desencadeiam mudanças no padrão de ativação dessa rede neural, usando lutas entre machos. Os nossos resultados sugerem que é a avaliação mútua do comportamento de combate que impulsiona mudanças temporárias no estado do SDMN, e não a avaliação do resultado da luta ou apenas a expressão de comportamento agressivo. Em seguida, explorámos a modulação hormonal do comportamento social, em particular pelo neuropeptídeo vasotocina. Para isso, manipulámos o sistema da vasotocina injetando vasotocina e um antagonista específico dos receptores de vasotocina V1A em machos. Para distinguir se a vasotocina afeta o comportamento isoladamente ou em combinação com andrógenios, conduzimos esta experiência em peixes castrados e peixes controlo. Curiosamente, descobrimos que a vasotocina afetou o comportamento dos machos em relação às fêmeas, mas não em relação aos machos, e que os andrógenios e a vasotocina modularam a agressividade dos machos em relação às fêmeas. Em seguida, procurámos compreender como as interações sociais afetam os sistemas neuroendócrinos. Nesse sentido, utilizámos um paradigma de intrusões territoriais para avaliar os padrões temporais dos níveis de andrógenios e tentámos relacioná-los ao fenótipo comportamental de cada indivíduo. Obtivemos padrões distintos de resposta androgénica às interações sociais devido a diferenças individuais subjacentes em sua extensão de resposta. Este estudo oferece uma importante contribuição para a área de investigação, fornecendo possíveis razões para as discrepâncias associadas à hipótese de desafio, o principal modelo em endocrinologia comportamental que descreve a relação entre andrógenios e interações sociais. Finalmente, pensa-se que os andrógenios respondem às interações sociais como forma de preparar os indivíduos para outras interações. Assim, tentámos descobrir como um aumento de andrógenios no sangue afeta o cérebro. Para esse efeito, injetámos peixes com andrógenios e estudámos as mudanças transcriptómicas que ocorrem no cérebro usando a técnica de RNAseq, permitindo uma compreensão mais detalhada do efeito dos andrógenios no cérebro. Em suma, o comportamento social é complexo e depende de vários fatores internos e externos. Os resultados desta tese fornecem um contributo significativo para pesquisas futuras.The study of animal behavior and in specific of social behavior has attracted researchers for a long time. All animals interact with others, a feature which is fundamental to their survival and reproduction. However, to get a complete understanding of social behavior, the integration of its various components is required. In this thesis, we aimed to shed light on this topic, studying how the brain controls behavior through the concerted action of its neural circuits, genes and molecules, and also how the social environment feedbacks and impacts the brain. Grounded upon this objective and using the Mozambique tilapia (Oreochromis mossambicus) as a model species, in a first study we investigated how social behavior is controlled by a dynamic network of brain regions, the Social Decision Making Network (SDMN). Here, we tried to understand what are the specific cues that trigger changes in the pattern of activation of this neural network, by using staged fights between males. Our results suggest that it is the mutual assessment of relative fighting behavior that drives acute changes in the state of the SDMN, and not the assessment of fight outcome or just the expression of aggressive behavior. Then, we explored the hormonal modulation of social behavior, in particular of the neuropeptide vasopressin. For this purpose, we manipulated the vasotocin system by injecting vasotocin and a specific antagonist of vasotocin receptors V1A in males. To distinguish if vasotocin affected behavior alone or in combination with androgens, we conducted this experiment in both castrated and control fish. Interestingly, we found that vasotocin affected the behavior of males towards females but not towards males and that both androgens and vasotocin modulated aggressiveness towards females. Next, we sought to comprehend how social interactions affect neuroendocrine systems. In that sense, we used a paradigm of territorial intrusions to assess temporal patterns of androgen levels and tried to relate them to the behavioral phenotype of each individual. We obtained distinct patterns of androgen response to social interactions due to underlying individual differences in their scope for response. This study makes an important contribution to the field by providing possible reasons for discrepancies associated with the Challenge Hypothesis, the major framework in behavioral endocrinology which describes the relationship between androgens and social interactions. Finally, it is believed that androgens respond to social interactions as a way to prepare individuals for further interactions. Thus, we tried to uncover how an androgen surge in the blood affects the brain. To accomplish this, we injected fish with androgens and studied brain transcriptomic changes with the RNAseq technique, allowing the achievement of a thorough understanding of the effect of androgens on the brain. In sum, social behavior is complex and dependent on several internal and external factors. The findings from this thesis provide significant insights for future research.Fundação para a Ciência e Tecnologi