Group composition, relatedness, and dispersal in the cooperatively breeding cichlid Neolamprologus obscurus

Tanaka, Hirokazu; Heg, Dik; Takeshima, Hirohiko; Takeyama, Tomohiro; Awata, Satoshi; Nishida, Mutsumi; Kohda, Masanori

doi:10.1007/s00265-014-1830-8

Cited by 30 publications

(80 citation statements)

References 60 publications

(81 reference statements)

Supporting

Mentioning

Contrasting

Order By: Relevance

“…Subordinate males in a closely related species ( Neolamprologus obscurus ) seem to adopt this strategy: they disperse from the territory of their mother, but remain within the larger territory of their father (Tanaka et al . ).…”

Section: Discussionmentioning

confidence: 97%

“…), they may wait to disperse from their father's territory until they reach a size at which they may be able to challenge for a dominant breeding position in another group or can opportunistically disperse to a vacant territory (Tanaka et al . ). Subordinates in the closely related N. obscurus appear to adopt similar strategies—subordinate females disperse away from their father's territory at a smaller size, but subordinate males remain in their father's territory, likely because subordinate males are more tolerated in the territory of their father than a territory of an unrelated male (Tanaka et al .…”

Section: Discussionmentioning

confidence: 97%

See 1 more Smart Citation

Within‐group relatedness is correlated with colony‐level social structure and reproductive sharing in a social fish

et al. 2016

View full text Add to dashboard Cite

In group-living species, the degree of relatedness among group members often governs the extent of reproductive sharing, cooperation and conflict within a group. Kinship among group members can be shaped by the presence and location of neighbouring groups, as these provide dispersal or mating opportunities that can dilute kinship among current group members. Here, we assessed how within-group relatedness varies with the density and position of neighbouring social groups in Neolamprologus pulcher, a colonial and group-living cichlid fish. We used restriction site-associated DNA sequencing (RADseq) methods to generate thousands of polymorphic SNPs. Relative to microsatellite data, RADseq data provided much tighter confidence intervals around our relatedness estimates. These data allowed us to document novel patterns of relatedness in relation to colony-level social structure. First, the density of neighbouring groups was negatively correlated with relatedness between subordinates and dominant females within a group, but no such patterns were observed between subordinates and dominant males. Second, subordinates at the colony edge were less related to dominant males in their group than subordinates in the colony centre, suggesting a shorter breeding tenure for dominant males at the colony edge. Finally, subordinates who were closely related to their same-sex dominant were more likely to reproduce, supporting some restraint models of reproductive skew. Collectively, these results demonstrate that within-group relatedness is influenced by the broader social context, and variation between groups in the degree of relatedness between dominants and subordinates can be explained by both patterns of reproductive sharing and the nature of the social landscape.

show abstract

Section: Discussionmentioning

confidence: 97%

Section: Discussionmentioning

confidence: 97%

Within‐group relatedness is correlated with colony‐level social structure and reproductive sharing in a social fish

et al. 2016

View full text Add to dashboard Cite

show abstract

“…Comparing N. pulcher 's genetic architecture of social behaviours to those of other closely related cichlid species that differ in their degree of sociality and cooperative breeding might shed light on the evolution of sociality within this lineage. For instance, the Lamprologini tribe of Lake Tanganyika cichlids comprises around one hundred species which range from nonsocial to highly social and represent a system in which cooperative breeding has evolved repeatedly (Dey et al., ; Heg & Bachar, ; Taborsky, ; Tanaka et al., ). Furthermore, comparisons of genetic correlations between social behaviours in other cooperatively breeding animals, for instance meerkats (Huchard et al., ), red squirrels (Taylor et al., ), yellow‐bellied marmots (Petelle et al., ) but also cooperatively breeding birds (Hunter, ; Komdeur, ) and insects (Leadbeater et al., ; Queller et al., ), could also reveal whether general patterns in cooperative breeders exist, which would contribute to better understand how cooperative breeding evolves.…”

Section: Discussionmentioning

confidence: 99%

Heritabilities, social environment effects and genetic correlations of social behaviours in a cooperatively breeding vertebrate

Kasper

Schreier

Taborsky

2019

J of Evolutionary Biology

View full text Add to dashboard Cite

Social animals interact frequently with conspecifics, and their behaviour is influenced by social context, environmental cues and the behaviours of interaction partners, allowing for adaptive, flexible adjustments to social encounters. This flexibility can be limited by part of the behavioural variation being genetically determined. Furthermore, behaviours can be genetically correlated, potentially constraining independent evolution. Understanding social behaviour thus requires carefully disentangling genetic, environmental, maternal and social sources of variations as well as the correlation structure between behaviours. Here, we assessed heritability, maternal, common environment and social effects of eight social behaviours in Neolamprologus pulcher, a cooperatively breeding cichlid. We bred wild‐caught fish in a paternal half‐sibling design and scored ability to defend a resource against conspecifics, to integrate into a group and the propensity to help defending the group territory (“helping behaviour”). We assessed genetic, social and phenotypic correlations within clusters of behaviours predicted to be functionally related, namely “competition,” “aggression,” “aggression‐sociability,” “integration” and “integration‐help.” Helping behaviour and two affiliative behaviours were heritable, whereas there was little evidence for a genetic basis in all other traits. Phenotypic social effects explained part of the variation in a sociable and a submissive behaviour, but there were no maternal or common environment effects. Genetic and phenotypic correlation within clusters was mostly positive. A group's social environment influenced covariances of social behaviours. Genetic correlations were similar in magnitude but usually exceeding the phenotypic ones, indicating that conclusions about the evolution of social behaviours in this species could be provisionally drawn from phenotypic data in cases where data for genetic analyses are unobtainable.

show abstract

“…The multi-male/multi-female category described in Heg and Bachar (2006), which has been referred to by Tanaka et al (2018), denotes groups consisting of multiple sexually mature males and females. To what extent these adult subordinates gain reproductive share is known from 6 cooperatively breeding cichlids for which genetic data are available (Neolamprologus pulcher, N. savoryi, N. obscurus, N. multifasciatus, Julidochromis ornatus, J. transcriptus;see Kohler, 1998;Awata, Munehara, & Kohda, 2005;Dierkes, Heg, Taborsky, Skubic, & Achmann, 2005;Kohda et al, 2009;Tanaka et al, 2015;Hellmann et al, 2016;Heg et al in revision; see Taborsky, 2009Taborsky, , 2016. Without exception, all these studies revealed that groups in the respective species contain larvae, young or helpers of different degrees of relatedness to the breeders, revealing that they are genetically non-monogamous.…”

Section: Introductionmentioning

confidence: 99%

“…Additionally, immigration, which occurs regularly in the cooperatively breeding cichlids investigated thus far (see Taborsky, 2016 for review), significantly reduces relatedness between helpers and beneficiaries. Consequently, in the cooperatively breeding cichlids for which genetic data are available, the mean within-group relatedness values are clearly below 0.5 (Awata et al, 2005;Dierkes et al, 2005;Kohler, 1998;Taborsky, 2009;Tanaka et al, 2015), varying with age and size of the subordinates (Dierkes et al, 2005). Dey et al (2019) state that the alternative phylogenetic trees presented in Tanaka et al (2018) also suggest 4-5 transitions to cooperative breeding.…”

Section: Introductionmentioning

confidence: 99%

Insufficient data render comparative analyses of the evolution of cooperative breeding mere speculation: A reply to Dey et al.

et al. 2019

Self Cite

View full text Add to dashboard Cite

Group composition, relatedness, and dispersal in the cooperatively breeding cichlid Neolamprologus obscurus

Cited by 30 publications

References 60 publications

Within‐group relatedness is correlated with colony‐level social structure and reproductive sharing in a social fish

Within‐group relatedness is correlated with colony‐level social structure and reproductive sharing in a social fish

Heritabilities, social environment effects and genetic correlations of social behaviours in a cooperatively breeding vertebrate

Insufficient data render comparative analyses of the evolution of cooperative breeding mere speculation: A reply to Dey et al.

Contact Info

Product

Resources

About