Social genetic effects (aka indirect genetic effects) occur when the phenotype of an organism is influenced by the genotypes of conspecifics. Previous work has highlighted the major potential evolutionary consequences of social genetic effects (Moore et al., 1997; Wolf et al., 1998), with evidence for such effects to be present both in interactions between related (e.g. mothers and offspring Champagne and Meaney, 2006; Wilson et al., 2004) and unrelated individuals (e.g. sexual displays (Petfield et al., 2005), aggression Wilson et al., 2011; Sartori and Mantovani, 2013; Santostefano et al., 2017). More recently, the importance of social genetic effects for health and disease has also been recognized (Baud et al., 2017), which may explain the pervasiveness of the social environment as a mortality risk in humans (Holt-Lunstad et al., 2010; Holt-Lunstad et al., 2015). Interestingly, the potential consequences of social genetic effects for the interpretation of research results using genetically modified organisms (GMO) has been greatly neglected. GMOs have been widely used in behavioral neuroscience to investigate the causal role of candidate genes and behavioral phenotypes. Typically Knock-in and Knock-out transgenics and mutants have been used to causally link the gain or loss of behavioral function to a specific gene (Huang and Zeng, 2013). In recent years, the development of genome editing techniques, such as CRISPR-Cas9-and TALEN-induced mutations, have increased the interest in this approach and opened the door to studying the genetic basis of behavior in non-model organisms (Hsu et al., 2014).

However, most studies using GMO in behavioral neuroscience have ignored the potential contribution of the genotypic composition of the social environment to the behavioral phenotype studied. This is because it has been assumed that if the genetic background of these mutants is identical and their environment has been kept constant, any phenotypic differences must come from the genetic manipulation. However, when GMOs are incrossed or visually screened at a very young age (e.g. using reporter genes, GFP) and thereafter raised and housed together until used in experiments, changes in their behavior might be affected by the divergent genotypic composition of social environments experienced by these mutants. In other words, modified behavior might be a result of growing with their peer mutants, rather than the canonical social environment provided by wild-type conspecifics. Such problem is particularly relevant when studying social behavior. Thus, given the rising interest in the study of social behavior in model organisms from worms to higher vertebrates, an assessment of the potential effect of the interaction between the genotype of the individual (G_i) and the genotypic composition of its social environment (G_s), on the behavioral phenotype of interest in GMOs used in social neuroscience is crucial.

Despite the wide variety of species-specific social behaviors, a wealth of evidence has implicated the paralog nonapeptides vasopressin (VP) and oxytocin (OXT) and their receptors in the regulation of different aspects of social behavior across vertebrates (Donaldson and Young, 2008; Goodson and Thompson, 2010), suggesting a genetic toolkit role (sensu evo-devo, i.e. ancient genes highly conserved among taxa that control the same biological process) for these nonapeptides in social behavior. Nonapeptides are an ancestral neuropeptide family found both in vertebrates and invertebrates, that derived from a VP-like peptide, and that evolved along two parallel clades of VP- and OXT-like peptides from the duplication of the VP gene in early jawed fish (ca. 500 Mya). Both peptides have been implicated in the regulation of behavior and physiology across different taxa, with VP being more involved in aggression and agonistic behaviors and OXT-like peptides consistently acting in affiliative behaviors and species-specific social behaviors across diverse taxa (i.e. sexual behavior, social interactions) (Stoop, 2012; Goodson, 2013). Despite this wealth of evidence on the direct genetic effects of OXT on social behavior, social genetic effects (i.e. G_ixG_s effects) of OXT genotypes have never been studied.

In this study, we aimed to provide a proof of principle for G_ixG_s effects in behavioral phenotypes observed in GMO by assessing the occurrence of such effects in a knockout line for the OXT receptor in zebrafish, a commonly used model species in behavioral neuroscience (Orger and de Polavieja, 2017), which forms social groups (aka shoals, Miller and Gerlai, 2007; Miller and Gerlai, 2012) and expresses a rich repertoire of social behavior (Zebrafish Neuroscience Research Consortium et al., 2013; Nunes et al., 2017). For this purpose, we studied the G_ixG_s interaction in the effects of the OXT gene (oxtr) in different aspects of social behavior, by raising individual zebrafish of the WT (oxtr^(+/+)) or knock-out genotype (oxtr^(-/-)) in different social environments (i.e. oxtr^(+/+) shoal or oxtr^(-/-) shoal; Figure 1A). Since sociality encompasses motivational, cognitive and collective behavioral traits, we have selected a set of tests that aim to characterize these different aspects at a fundamental level: (Moore et al., 1997) the social preference and social habituation tests assess the motivation to approach conspecifics, and how it varies with the repeated access to conspecifics; (Wolf et al., 1998) the social recognition test, which provides an insight into the ability of zebrafish to discriminate between conspecifics based on one-trial learning; and (Champagne and Meaney, 2006) tests of shoaling behavior that assess how well the focal individual is able to integrate itself into an unfamiliar shoal and what influence it has on the behavior of the other shoal members.

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Effects of individual and conspecifics genotype on Social Preference.

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Effects of individual and conspecifics genotype on social habituation.

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Effects of individual and conspecifics genotype on social recognition.

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Effects of individual and conspecifics genotype on social integration.

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Effects of individual and conspecifics genotype on social influence.

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Adult zebrafish, like many other social animals, express a tendency to approach and interact with conspecifics (social preference, Figure 1B; Engeszer et al., 2004). Here, we show that there was no significant effect of either genotype or G_ixG_s interaction on social preference, but there was a marginally significant main effect of G_s (Table 1; Figure 1C). When fish were presented for a second time to a shoal to measure social habituation (i.e. expected reduction in social preference), we found a G_ixG_s interaction, where oxtr^(-/-) individuals raised in oxtr^(-/-) shoals express enhanced social habituation (F_1,44 = 5.642, p=0.022; Figure 1D). Thus, social motivation in zebrafish seems to be influenced by the genotype of conspecifics rather than by the genotype of the individual. Hence, the increased social habituation in oxtr^(-/-) fish does not seem to be due to reduced social motivation, but rather to an heightened habituation to the stimuli, suggesting that the observed G_ixG_s interaction effect is related to changes in single-stimulus learning mechanisms in mutant fish rather than to changes in social motivation.

When we tested social recognition, which is a form of social memory needed for individuality in social interactions (i.e. differential expression of social behavior depending on identity of interacting individual), that is known to be modulated by oxytocin both in mammals and zebrafish (Ferguson et al., 2000; Ribeiro et al., 2020), we observed that oxtr^(-/-) individuals exhibit a deficit in acquisition and retention of social recognition irrespective of the social environment (oxtr^(-/-) or oxtr^(+/+)) in which they were raised (F_1,44 = 7.600, p=0.008; Figure 1F). Thus, in contrast to social motivation, social memory seems to rely on the individual’s genotype. This result is in accordance with a recent study from our lab (Ribeiro et al., 2020) that has shown a deficit in one-trial recognition memory of both conspecifics and objects in oxt^(-/-) fish, suggesting that this deficit is not specific to the social domain but is rather a general domain cognitive deficit.

Given that social behavior of zebrafish mainly occurs in the context of shoaling we have also investigated two shoaling behavior parameters: social integration and social influence. Social integration assesses how well the focal individual integrates in the social group (aka shoal), and is measured by its average distance to the centroid of the shoal (Figure 1G,H). A G_ixG_s interaction was found for social integration, where oxtr^(-/-) individuals raised in oxtr^(-/-) shoals exhibit a significantly lower social integration than oxtr^(-/-) individuals raised in oxtr^(+/+) shoals; in contrast, oxtr^(+/+) individuals exhibit high levels of social integration irrespective of the shoal type in which they were raised (Table 1; Figure 1H). Social influence assesses how the focal individual affects the shoaling behavior of the remaining shoal members, by measuring the shoal dispersion as defined by the perimeter of the other shoal members (Figure 1I,J). The presence of a single WT (oxtr^(+/+)) individual in a oxtr^(-/-) shoal was enough to increase its dispersion, whereas the presence of a single oxtr^(-/-) individual in a oxtr^(+/+) shoal did not affect its dispersion (Table 1; Figure 1J). In summary, we show that distinct components of social behavior are differentially affected by the genetic composition of the social environment versus the oxtr genotype of the focal individual. Social preference shows a marginally significant influence of the genotype of conspecifics. Social recognition exhibited a pure effect of the individual genotype. And clear G_ixG_s interactions were observed in the cases of social habituation and social integration. Social influence had a major contribution of the social environment, which is also the case, to a lesser extent, with social preference. Thus, we demonstrated that genetic variation in the social environment interacts with individual genotype during the developmental acquisition of social behavior. In other words, variation in the genotypes present in the social environment can revert particular phenotypes associated with specific genes. These results are in line with reported interactions between other aspects of the social environment and oxytocin receptor genotype in the determination of social behavior phenotypes in human populations (Thompson et al., 2011; Wade et al., 2015; McQuaid et al., 2013). Our results suggest that more caution is needed in the interpretation of studies using transgenic or mutant individuals that are raised in cohorts of the same genotype, and that some phenotypes observed in transgenic or mutant lines may in fact result from G_ixG_s interactions.

Data used in this study is provided as supplemental material at this stage. Data available on Dryad at doi: https://doi.org/10.5061/dryad.xwdbrv1bq.

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Author details

1. Diogo Ribeiro

   Instituto Gulbenkian de Ciência, Oeiras, Portugal

   Contribution

   Data curation, Formal analysis, Investigation, Visualization, Methodology, Writing - original draft, Writing - review and editing

   Competing interests

   No competing interests declared

2. Ana Rita Nunes

   Instituto Gulbenkian de Ciência, Oeiras, Portugal

   Contribution

   Data curation, Formal analysis, Investigation, Visualization, Methodology, Writing - review and editing

   Competing interests

   No competing interests declared

3. Magda Teles

   Instituto Gulbenkian de Ciência, Oeiras, Portugal

   Contribution

   Resources, Data curation, Formal analysis, Methodology, Writing - review and editing

   Competing interests

   No competing interests declared

4. Savani Anbalagan

   1. Weizmann Institute of Science, Rohovot, Israel
   2. ReMedy-International Research Agenda Unit, Centre of New Technologies, University of Warsaw, Warsaw, Poland

   Contribution

   Resources, Methodology

   Competing interests

   No competing interests declared

5. Janna Blechman

   Weizmann Institute of Science, Rohovot, Israel

   Contribution

   Resources, Funding acquisition, Methodology, Writing - review and editing

   Competing interests

   No competing interests declared

6. Gil Levkowitz

   Weizmann Institute of Science, Rohovot, Israel

   Contribution

   Conceptualization, Resources, Supervision, Funding acquisition, Methodology, Writing - original draft, Project administration, Writing - review and editing

   Competing interests

   No competing interests declared

   "This ORCID iD identifies the author of this article:" 0000-0002-3896-1881

7. Rui F Oliveira

   1. Instituto Gulbenkian de Ciência, Oeiras, Portugal
   2. ISPA – Instituto Universitário, Lisboa, Portugal
   3. Champalimaud Research, Lisboa, Portugal

   Contribution

   Conceptualization, Resources, Data curation, Formal analysis, Supervision, Investigation, Writing - original draft, Project administration, Writing - review and editing

   For correspondence

   ruiol@ispa.pt

   Competing interests

   No competing interests declared

   "This ORCID iD identifies the author of this article:" 0000-0003-1528-618X

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