This research was supported by the Czech Academy of Sciences RVO 68378050, LM2018126 Czech Centre for Phenogenomics provided by MEYS CR, OP RDE CZ.02.1.01/0.0/0.0/16_013/0001789 (Upgrade of the Czech Centre for Phenogenomics: developing toward translation research by MEYS and ESIF), OP RDE CZ.02.1.01/0.0/0.0/18_046/0015861 (CCP Infrastructure Upgrade II by MEYS and ESIF), and OP RDI CZ.1.05/2.1.00/19.0395 (higher quality and capacity for transgenic models by MEYS and ERDF). In addition, this study received funding from the NGO &#34;Association of Gene Therapy (ASGENT)&#34;, Czechia (https://asgent.org/) and LM2023036 Czech Centre for Phenogenomics provided by Ministry of Education, Youth and Sports of the Czech Republic.

Validating a Murine Model of Angelman Syndrome Using Behavioral Tests

The authors have no conflicts of interest to disclose.

AS models created in different murine strains are commonly validated with tests of animal emotional state, motor functions, and cognitive abilities to facilitate comparison to human symptoms31,32. A motor deficit in AS models is the most consistent finding across laboratories, followed by an unchanged emotionality state of mutants and difficulties building nests31,32,33....

Angelman syndrome (AS) is a rare neurodevelopmental disease. The most common genetic origin of AS is a large deletion of the 15q11-q13 region of the maternally-derived chromosome, which is found in nearly 74% of patients1. Deletion of this region causes the loss of UBE3A, the main causative gene of AS that encodes an E3 ubiquitin ligase. The paternal allele of the UBE3A gene in neurons is silenced in a process known as imprinting. As a consequence, paternal imprinting of the gene allows only maternal expression in the central nervous system (CNS)2. Therefore, UBE3A gene deletion from the maternally-derived chromosome leads to the development of AS symptoms. In humans, AS manifests at around 6 months of age, with developmental retardation that persists throughout all developmental stages and results in severe debilitating symptoms in affected individuals3,4. The core symptoms of the disorder include the deficit of fine and gross motor skills, including jerky ataxic gait, serious speech impairment, and intellectual disability. Approximately 80% of AS patients also suffer from sleep disturbances and epilepsy. To date, the only available treatment are symptomatic drugs, which reduce epileptic seizures and improve sleep quality1. Therefore, the development of robust animal models with reproducible behavioral phenotypes alongside refined phenotyping analysis will be essential to elucidate the pathophysiological mechanisms of the disorder and discover effective medications and treatments.
The complexity of the human disorder affecting the CNS demands model organisms to possess a comparable genome, physiology, and behavior. Mice are popular as a model organism due to their short reproductive cycle, small size, and relative ease of DNA modification. In 1984, Paul Willner proposed three basic disease model validation criteria: the construct, face, and predictive validity, which are used to determine the model&#39;s value5. Simply, construct validity reflects the biological mechanisms responsible for the disorder development, face validity recapitulates its symptoms, and predictive validity describes the model response to therapeutic drugs.
To adhere to the above principles, we have chosen the most common genetic etiology, a large deletion of the maternal 15q11.2-13q locus including the UBE3A gene, to create AS model mice. We used the CRISPR/Cas9 technique to delete a 76,225 bp long region spanning the entire UBE3A gene, encompassing both the coding and non-coding elements of the gene, in mice from a C57BL/6N background6. We then bred the animals to obtain UBE3A+/&#8722; heterozygous mice. For face validation of the model, we used animals from crosses of UBE3A+/&#8722; females and wild-type males to gain UBE3A+/- progeny (strain named C57BL/6NCrl-UBE3A&#60;em1(IMPC)Ccpcz&#62;/Ph and later assigned as UBE3AmGenedel/+) and control littermates. We tested their fine and gross motor skills, emotionality, and affect to recapitulate core AS symptoms. In a previous article, we also evaluated the animals&#39; cognitive functions, as AS patients also suffer from intellectual disability6. However, we found no cognitive impairments in UBE3AmGenedel/+ mice, perhaps due to the young age of the animals at the time of testing7. Later examination of the older animals, around 18 weeks old, revealed a deficit in behavioral flexibility during reversal learning in the place preference paradigm. However, the complexity of the employed equipment for this analysis requires a separate methodological module and it is not included here.
The behavioral tests presented here belong to the common phenotyping tools in genetic research, thanks to their high predictive value and sufficient construct validity8,9,10. We used these tests to validate a mouse model of AS by recapitulating core symptoms of the human disease in a reproducible, age-independent manner. The emotionality of the animal was evaluated in the elevated plus maze and open field tests. Both of these tests are based on the approach-avoidance conflict, where animals explore a new environment in search of food, shelter, or mating opportunities while simultaneously avoiding anxiogenic compartments11. Additionally, the open field test is used to test a mouse&#39;s locomotor activity8. The tail suspension test is widely used in depression research to screen for new antidepressant drugs or depressive-like phenotypes in mouse knockout models12. This test evaluates the despair that animals develop over time in an inescapable situation. Motor learning and detailed gait characteristics were determined on the rotarod and in DigiGait, respectively. Animal endurance on the accelerating rod characterizes its balance and movement coordination skills, while detailed analysis of a mouse&#39;s step patterns is a sensitive evaluation of neuromuscular impairments connected to many neurogenerative movement disorders13,14,15. The nestlet shredding test is part of the standard methodology for detecting impulsive behavior in rodents, and since it utilizes natural rodent building behavior, it indicates the animal&#39;s well-being16,17.
The size of the experimental groups was a result of a compromise to meet the 3R rule demands and efficient usage of colony breeding performance. However, to obtain statistical power, the groups had no fewer than 10 individuals, due to the establishment of a sufficient amount of breeding pairs. Unfortunately, breeding performance did not always result in a sufficient number of animals.

<table><tbody><tr><td>Cages, individually ventilated</td><td>Techniplast</td><td></td><td></td></tr><tr><td>DigiGait</td><td>Mouse Specifics, Inc., 2 Central Street Level&lt;br/&gt; Unit 110&lt;br/&gt; Framingham, MA 01701, USA</td><td>Equipment was tendered, no catalogue&amp;nbsp; number was provided, nor could be find on company&#039;s web site</td><td>Detailed analysis of mouse gait, hardware and software provided.&amp;nbsp;</td></tr><tr><td>FDA Nestlet squares</td><td>Datesand Ltd., 7 Horsfield Way, Bredbury, Stockport SK6, UK</td><td>Material was bought from Velaz vendor via direct email request. Velaz do not provide any catalogue no.</td><td>Cotton nestlets for nest building test. Nestlet discription: 2-3 g each, with diameter around 5 x 5 x 0.5cm.</td></tr><tr><td>Mouse chow</td><td>Altramion</td><td></td><td></td></tr><tr><td>Rotarod</td><td>TSE Systems GmbH, Barbara-McClintock-Str.4&lt;br/&gt; 12489 Berlin, Germany</td><td>Equipment was tendered, no catalogue&amp;nbsp; number was provided, nor could be find on company&#039;s web site</td><td>Rotarod for 5 mice, hardware and software provided. Drum dimensions: Diameter: 30 mm, width per lane: 50 mm, falling distance 147 mm.</td></tr><tr><td>Tail Suspension Test</td><td>Bioseb, In Vivo Research Instruments, 13845 Vitrolles&lt;br/&gt; FRANCE</td><td>Reference: BIO-TST5</td><td>Fully automated equipment for immobility time evaluation of 3 mice hanged by tail, hardware and software provided</td></tr><tr><td>Transpore medical tape</td><td>Medical M, Ltd.</td><td>P-AIRO1291</td><td>The tape used to attach an animal to the hook by its tail.</td></tr><tr><td>Viewer - Video Tracking System</td><td>Biobserve GmbH, Wilhelmstr. 23 A&lt;br/&gt; 53111 Bonn, Germany</td><td>Equipment with software were tendered, no catalogue&amp;nbsp; number was provided, nor could be find on company&#039;s web site</td><td>Software with custom made hardware: maze, IR base, IR sensitive cameras. Custom-made OF dimensions: 42 x 42 cm area, 49 cm high wall, central zone area: 39 cm&lt;sup&gt;2&lt;/sup&gt;. A custom-made EPM was elevated 50 cm above the floor, with an open arm 79 cm long,&amp;nbsp; 9 cm wide, and closed arm 77 cm long, 7.6 cm wide.&amp;nbsp;</td></tr></tbody></table>

behavioral characterization of an angelman syndrome mouse model

This manuscript describes a battery of behavioral tests available to characterize Angelman syndrome (AS)-like phenotypes in an established murine model of AS. We use the rotarod learning paradigm, detailed gait analysis, and nest building test to detect and characterize animal motor impairments. We test animal emotionality in the open field and elevated plus maze tests, as well as the affect in the tail suspension test. When AS mice are tested in the open field test, the results should be interpreted with care, since motor dysfunctions influence mouse behavior in the maze and alter activity scores.
The reproducibility and effectiveness of the presented behavioral tests has already been validated in several independent Uba3a mouse lines with different knockout variants, establishing this set of tests as an excellent validation tool in AS research. Models with the relevant construct and face validity will warrant further investigations to elucidate the pathophysiology of the disease and grant the development of causal treatments.

Elevated plus maze and open field tests 
The EPM and OF tests use the natural tendency of rodents to explore new environments18,19. The exploration is governed by an approach-avoidance conflict, where rodents choose between the exploration of a new environment and avoidance of possible danger. Animals explore unknown places in search for shelter, social contact, or foraging. However, new places may involve risk factors such as predators or c...

Watch this Scientific Journal Video about A Battery of Highly Reproducible Behavioral Tests to Validate an Angelman Syndrome Murine Model at JoVE.com

Author Spotlight: A Battery of Highly Reproducible Behavioral Tests to Validate an Angelman Syndrome Murine Model 

This manuscript presents a set of highly reproducible behavioral tests to validate an Angelman syndrome mouse model.

Behavioral Characterization of an Angelman Syndrome Mouse Model

This manuscript describes a battery of behavioral tests available to characterize Angelman syndrome (AS)-like phenotypes in an established murine model of ...

behavioral-characterization-of-an-angelman-syndrome-mouse-model

Research

JoVE Journal

Behavior

4.2K Views.  Institute of Molecular Genetics of the Czech Academy of Sciences. This manuscript presents a set of highly reproducible behavioral tests to validate an Angelman syndrome mouse model.

Video: Author Spotlight: A Battery of Highly Reproducible Behavioral Tests to Validate an Angelman Syndrome Murine Model 

Inchworming: A Novel Motor Stereotypy in the BTBR T+ Itpr3tf/J Mouse Model of Autism

Autism Spectrum Disorder (ASD) is a behaviorally defined neurodevelopmental disorder characterized by decreased reciprocal social interaction, abnormal communication, and repetitive behaviors with restricted interest. As diagnosis is based on clinical criteria, any potentially relevant rodent models of this heterogeneous disorder should ideally recapitulate these diverse behavioral traits. The BTBR T+ Itpr3tf/J (BTBR) mouse is an established animal model of ASD, displaying repetitive behaviors such as increased grooming, as well as cognitive inflexibility. With respect to social interaction and interest, the juvenile play test has been employed in multiple rodent models of ASD. Here, we show that when BTBR mice are tested in a juvenile social interaction enclosure containing sawdust bedding, they display a repetitive synchronous digging motion. This repetitive motor behavior, referred to as &#34;inchworming,&#34; was named because of the stereotypic nature of the movements exhibited by the mice while moving horizontally across the floor. Inchworming mice must use their fore- and hind-limbs in synchrony to displace the bedding, performing a minimum of one inward and one outward motion. Although both BTBR and C56BL/6J (B6) mice exhibit this behavior, BTBR mice demonstrate a significantly higher duration and frequency of inchworming and a decreased latency to initiate inchworming when placed in a bedded enclosure. We conclude that this newly described behavior provides a measure of a repetitive motor stereotypy that can be easily measured in animal models of ASD.

Inchworming: A Novel Motor Stereotypy in the BTBR T+ Itpr3tf/J Mouse Model of Autism

Inchworming is a highly repetitive synchronous digging motion displayed by BTBR T+ Itpr3tf/J (BTBR) mice when placed in a testing cage with sufficient sawdust bedding. The procedure is a modification of the juvenile social interaction protocol and is used here to assess repetitive motor stereotypies relevant to Autism Spectrum Disorder.

Autism Spectrum Disorder (ASD) is a behaviorally defined neurodevelopmental disorder characterized by decreased reciprocal social interaction, abnormal ...

Nest Building as an Indicator of Health and Welfare in Laboratory Mice

The minimization and alleviation of suffering has moral and scientific implications. In order to mitigate this negative experience one must be able to identify when an animal is actually in distress. Pain, illness, or distress cannot be managed if unrecognized. Evaluation of pain or illness typically involves the measurement of physiologic and behavioral indicators which are either invasive or not suitable for large scale assessment. The observation of nesting behavior shows promise as the basis of a species appropriate cage-side assessment tool for recognizing distress in mice. Here we demonstrate the utility of nest building behavior in laboratory mice as an ethologically relevant indicator of welfare. The methods presented can be successfully used to identify thermal stressors, aggressive cages, sickness, and pain. Observation of nest building behavior in mouse colonies provides a refinement to health and well-being assessment on a day to day basis.

We demonstrate the utility of nest building behavior in laboratory mice as an indicator of welfare. Nest scoring is a sensitive technique that is altered by temperature, illness, and aggression. The time to integrate into nest test (TINT) is a simple cage-side assessment that can detect postoperative pain.

The minimization and alleviation of  suffering has moral and scientific implications. In order to mitigate this  negative experience one must be able to ...

Behavioral Phenotyping of Murine Disease Models with the Integrated Behavioral Station (INBEST)

Due to rapid advances in genetic engineering, small rodents have become the preferred subjects in many disciplines of biomedical research. In studies of chronic CNS disorders, there is an increasing demand for murine models with high validity at the behavioral level. However, multiple pathogenic mechanisms and complex functional deficits often impose challenges to reliably measure and interpret behavior of chronically sick mice. Therefore, the assessment of peripheral pathology and a behavioral profile at several time points using a battery of tests are required. Video-tracking, behavioral spectroscopy, and remote acquisition of physiological measures are emerging technologies that allow for comprehensive, accurate, and unbiased behavioral analysis in a home-base-like setting. This report describes a refined phenotyping protocol, which includes a custom-made monitoring apparatus (Integrated Behavioral Station, INBEST) that focuses on prolonged measurements of basic functional outputs, such as spontaneous activity, food/water intake and motivated behavior in a relatively stress-free environment. Technical and conceptual improvements in INBEST design may further promote reproducibility and standardization of behavioral studies.

Behavioral Phenotyping of Murine Disease Models with the Integrated Behavioral Station INBEST

Prolonged and comprehensive monitoring of mice in a home-cage environment provides a deeper understanding of aberrant behavior in murine models of brain diseases. This paper describes the Integrated Behavioral Station (INBEST) as the key component of contemporary behavioral analysis.

Due to rapid advances in genetic engineering, small rodents have become the preferred subjects in many disciplines of biomedical research. In studies of ...

Compensatory Limb Use and Behavioral Assessment of Motor Skill Learning Following Sensorimotor Cortex Injury in a Mouse Model of Ischemic Stroke

Mouse models have become increasingly popular in the field of behavioral neuroscience, and specifically in studies of experimental stroke. As models advance, it is important to develop sensitive behavioral measures specific to the mouse. The present protocol describes a skilled motor task for use in mouse models of stroke. The Pasta Matrix Reaching Task functions as a versatile and sensitive behavioral assay that permits experimenters to collect accurate outcome data and manipulate limb use to mimic human clinical phenomena including compensatory strategies (i.e., learned non-use) and focused rehabilitative training. When combined with neuroanatomical tools, this task also permits researchers to explore the mechanisms that support behavioral recovery of function (or lack thereof) following stroke. The task is both simple and affordable to set up and conduct, offering a variety of training and testing options for numerous research questions concerning functional outcome following injury. Though the task has been applied to mouse models of stroke, it may also be beneficial in studies of functional outcome in other upper extremity injury models.

Mouse models have become increasingly popular in studies of behavioral neuroscience. As models advance, it is important to develop sensitive behavioral measures specific to the mouse. This protocol describes the Pasta Matrix Reaching Task, which is a skilled motor task for use in mouse models of stroke.

Mouse models have become increasingly popular in the field of behavioral neuroscience, and specifically in studies of experimental stroke. As models ...

Assessment of Social Interaction Behaviors

Social interactions are a fundamental and adaptive component of the biology of numerous species. Social recognition is critical for the structure and stability of the networks and relationships that define societies. For animals, such as mice, recognition of conspecifics may be important for maintaining social hierarchy and for mate choice 1.
A variety of neuropsychiatric disorders are characterized by disruptions in social behavior and social recognition, including depression, autism spectrum disorders, bipolar disorders, obsessive-compulsive disorders, and schizophrenia. Studies of humans as well as animal models (e.g., Drosophila melanogaster, Caenorhabditis elegans, Mus musculus, Rattus norvegicus) have identified genes involved in the regulation of social behavior 2. To assess sociability in animal models, several behavioral tests have been developed (reviewed in 3). Integrative research using animal models and appropriate tests for social behavior may lead to the development of improved treatments for social psychopathologies.
The three-chamber paradigm test known as Crawley's sociability and preference for social novelty protocol has been successfully employed to study social affiliation and social memory in several inbred and mutant mouse lines (e.g. 4-7). The main principle of this test is based on the free choice by a subject mouse to spend time in any of three box's compartments during two experimental sessions, including indirect contact with one or two mice with which it is unfamiliar. To quantitate social tendencies of the experimental mouse, the main tasks are to measure a) the time spent with a novel conspecific and b) preference for a novel vs. a familiar conspecific. Thus, the experimental design of this test allows evaluation of two critical but distinguishable aspects of social behavior, such as social affiliation/motivation, as well as social memory and novelty. "Sociability" in this case is defined as propensity to spend time with another mouse, as compared to time spent alone in an identical but empty chamber 7. "Preference for social novelty" is defined as propensity to spend time with a previously unencountered mouse rather than with a familiar mouse 7. This test provides robust results, which then must be carefully analyzed, interpreted and supported/confirmed by alternative sociability tests. In addition to specific applications, Crawley's sociability test can be included as an important component of general behavioral screen of mutant mice.

Here we describe a detailed protocol for examination of sociability in mice by using Crawley's sociability and preference for social novelty test. We describe the advantages and possible applications for this procedure, including critical details important for correct interpretation of the results.

Social interactions are a fundamental and adaptive component of the biology of numerous species. Social recognition is critical for the structure and ...

Neuroscience

Using the Activity-based Anorexia Rodent Model to Study the Neurobiological Basis of Anorexia Nervosa

Anorexia nervosa (AN) is a psychiatric illness characterized by excessively restricted caloric intake and abnormally high levels of physical activity. A challenging illness to treat, due to the lack of understanding of the underlying neurobiology, AN has the highest mortality rate among psychiatric illnesses. To address this need, neuroscientists are using an animal model to study how neural circuits may contribute toward vulnerability to AN and may be affected by AN. Activity-based anorexia (ABA) is a bio-behavioral phenomenon described in rodents that models the key symptoms of anorexia nervosa. When rodents with free access to voluntary exercise on a running wheel experience food restriction, they become hyperactive &#8211; running more than animals with free access to food. Here, we describe the procedures by which ABA is induced in adolescent female C57BL/6 mice. On postnatal day 36 (P36), the animal is housed with access to voluntary exercise on a running wheel. After 4 days of acclimation to the running wheel, on P40, all food is removed from the cage. For the next 3 days, food is returned to the cage (allowing animals free food access) for 2 hr daily. After the fourth day of food restriction, free access to food is returned and the running wheel is removed from the cage to allow the animals to recover. Continuous multi-day analysis of running wheel activity shows that mice become hyperactive within 24 hr following the onset of food restriction. The mice run even during the limited time during which they have access to food. Additionally, the circadian pattern of wheel running becomes disrupted by the experience of food restriction. We have been able to correlate neurobiological changes with various aspects of the animals&#8217; wheel running behavior to implicate particular brain regions and neurochemical changes with resilience and vulnerability to food-restriction induced hyperactivity.

Here we present a protocol to induce activity-based anorexia (ABA) in female adolescent mice. ABA is a condition of hyperactivity evoked by imposing food restriction on rodents with access to a running wheel. This phenomenon is being used as a model to study the underlying neurobiology of anorexia nervosa.

Anorexia nervosa (AN) is a psychiatric illness characterized by excessively restricted caloric intake and abnormally high levels of physical activity. A ...

Assessing Activity-based Anorexia in Mice

Rodents develop activity-based anorexia (ABA) when exposed to a restricted feeding schedule and allowed free access to a running wheel. These conditions lead to a life-threatening reduction in body weight. However, rodents exposed to only one of these conditions ultimately adapt to re-establish normal body weight. Although increased running coupled with reduction in voluntary food intake appear paradoxical under ABA conditions, ABA behavior is observed across numerous mammalian species. 
The ABA paradigm provides an animal model for anorexia nervosa (AN), an eating disorder with severe dysregulation of appetite-behavior. Subjects are singly housed with free access to a running wheel. Each day, the subject is offered food for a limited amount of time. During the course of the experiment, a subject's body weight decreases from high activity and low caloric intake. The duration of the study varies based on how long food is offered daily, the type of food offered, the strain of mouse, if drugs are being tested, and environmental factors.
A lack of effective pharmacological treatments for AN patients, their low quality of life, high cost of treatment, and their high mortality rate indicate the urgency to further research AN. We provide a basic outline for performing ABA experiments with mice, offering a method to investigate AN-like behavior in order to develop novel therapies. This protocol is optimized for use in Balb/cJ mice, but can easily be manipulated for other strains, providing great flexibility in working with different questions, especially related to genetic factors of ABA.

Mice individually housed with a running wheel while given limited access to food develop reductions in food consumption and increase activity on the running wheel. This experimental phenomenon is called activity-based anorexia. This paradigm provides an experimental tool for studying the neurobiology and behaviors underlying aspects of anorexia nervosa.

Rodents develop activity-based anorexia (ABA) when exposed to a restricted feeding schedule and allowed free access to a running wheel. These conditions ...

Low-Cost Gait Analysis for Behavioral Phenotyping of Mouse Models of Neuromuscular Disease

Measurement of animal locomotion is a common behavioral tool used to describe the phenotype of a given disease, injury, or drug model. The low-cost method of gait analysis demonstrated here is a simple but effective measure of gait abnormalities in murine models. Footprints are analyzed by painting a mouse&#8217;s feet with non-toxic washable paint and allowing the subject to walk through a tunnel on a sheet of paper. The design of the testing tunnel takes advantage of natural mouse behavior and their affinity for small dark places. The stride length, stride width, and toe spread of each mouse is easily measured using a ruler and a pencil. This is a well-established and reliable method, and it generates several metrics that are analogous to digital systems. This approach is sensitive enough to detect changes in stride early in phenotype presentation, and due to its non-invasive approach, it allows for testing of groups across life-span or phenotypic presentation.

Footprint analysis is a low-cost alternative to digitized gait analysis programs for researchers quantifying movement abnormalities in mice. Because of its speed, simplicity, and longitudinal potential, it is ideal for behavioral phenotyping of mouse models.

Measurement of animal locomotion is a common behavioral tool used to describe the phenotype of a given disease, injury, or drug model. The low-cost method ...

Behavioral Assays for Autism Spectrum Disorder in Mouse Models

Strategies for Assessing Autistic-Like Behaviors in Mice

Autism spectrum disorder (ASD) is a neurobiologically complex condition with a heterogeneous genetic etiology. Clinically, ASD is diagnosed by social communication impairments and restrictive or repetitive behaviors, such as hand flapping or lining up objects. These behavioral patterns can be reliably observed in mouse models with ASD-linked genetic mutations, making them highly useful tools for studying the underlying cellular and molecular mechanisms in ASD. Understanding how genetic changes affect the neurobiology and behaviors observed in ASD will facilitate the development of novel targeted therapeutic compounds to ameliorate core behavioral impairments. Our lab has employed several protocols encompassing well-described training and testing procedures that reflect a wide range of behavioral deficits related to ASD. Here, we detail two assays to study the core features of ASD in mouse models: self-grooming (a measure of repetitive behavior) and the three-chamber social interaction test (a measure of social interaction approach and preference for social novelty).

Rodent models are valuable tools for studying core behaviors related to autism spectrum disorder (ASD). In this article, we expound on two behavioral tests for modeling the core features of ASD in mice: self-grooming, which assesses repetitive behavior, and the three-chamber social interaction test, which documents social impairments.

Autism spectrum disorder (ASD) is a neurobiologically complex condition with a heterogeneous genetic etiology. Clinically, ASD is diagnosed by social ...

Drosophila Models for Genetic and Behavioral Traits of Autism Spectrum Disorder

Paradigms for Behavioral Assessment in Drosophila Model of Autism Spectrum Disorder

Autism Spectrum Disorder (ASD) encompasses a heterogeneous group of neurodevelopmental disorders with common behavioral symptoms including deficits in social interaction and ability for communication, enhanced restricted or repetitive behaviors, and also, in some cases, learning disability and motor deficit. Drosophila has served as an unparalleled model organism for modeling a great number of human diseases. As many genes have been implicated in ASD, fruit flies have emerged as a powerful and efficient way to test the genes putatively involved with the disorder. As hundreds of genes, with varied functional roles, are implicated in ASD, a single genetic fly model of ASD is unfeasible; instead, individual genetic mutants, gene knockdowns, or overexpression-based studies of the fly homologs of ASD-associated genes are the common means for gaining insight regarding molecular pathways underlying these gene products. A host of behavioral techniques are available in Drosophila which provide easy readout of deficits in specific behavioral components. Social space assay and aggression and courtship assays in flies have been shown to be useful in assessing defects in social interaction or communication. Grooming behavior in flies is an excellent readout of repetitive behavior. Habituation assay is used in flies to estimate the ability for habituation learning, which is found to be affected in some ASD patients. A combination of these behavioral paradigms can be utilized to make a thorough assessment of the human ASD-like disease state in flies. Using Fmr1 mutant flies, recapitulating Fragile-X syndrome in humans, and POGZ-homolog row knockdown in fly neurons, we have shown quantifiable deficits in social spacing, aggression, courtship behavior, grooming behavior, and habituation. These behavioral paradigms are demonstrated here in their simplest and straightforward forms with an assumption that it would facilitate their widespread use for research on ASD and other neurodevelopmental disorders in fly models.

Author Spotlight: Exploring Autism Spectrum Disorder Symptoms in Fruit Flies &#8212; Genetic Models and Behavioral Tests

Autism Spectrum Disorder (ASD) is associated with impaired social and communicative behavior and the emergence of repetitive behavior. For studying the interrelation between ASD genes and behavioral deficits in the Drosophila model, five behavioral paradigms are described in this paper for assaying social spacing, aggression, courtship, grooming, and habituation behavior.

Autism Spectrum Disorder (ASD) encompasses a heterogeneous group of neurodevelopmental disorders with common behavioral symptoms including deficits in ...