Naomi M. Gardiner

Relationships between pair formation, site fidelity and sex in a coral reef cardinalfish

Coral reef fishes are characterised by extreme site fidelity and are often socially monogamous, forming pair bonds within larger social groups. Despite this, the strong link between reproductive behaviour and site fidelity in such social species is poorly understood. We examine these relationships in the cardinalfish Ostorhinchus cyanosoma on the central Great Barrier Reef. We tagged and followed over 100 individuals for 5 weeks to investigate pair fidelity, and behavioural differences between pairs and singles and between sexes, and we experimentally tested the strength of site and mate fidelity. Tagged pairs were typically highly site attached, and lasted throughout the study period. Sex had very little effect on pairing behaviour or habitat use. Paired individuals showed three times higher site fidelity than single ones, with singles frequently relocating. There was a two-fold increase in the movement of individuals that had their partners experimentally removed. Paired individuals exhibited greater homing success, and homed regardless of whether their mate had been displaced with them or was left on the home site. These results suggest that individuals of this species form at least seasonally stable monogamous pair bonds within larger groups, and that pair formation is closely associated with site fidelity.

Homing is not for everyone: displaced cardinalfish find a new place to live

It was tested whether the pajama cardinalfish Sphaeramia nematoptera (Apogonidae) could home by displacing individuals up to 250 m within and among isolated reefs. Contrary to expectations, only two of 37 (5·4%) displaced S. nematoptera returned home and another 16 (43·2%) were found to have joined other social groups and did not home after 26 months of observations; while over the same period, 94% of control S. nematoptera remained associated with home corals, demonstrating strong site attachment. Hence, while this species has the potential to return home, being able to do so may not be as critical as previously assumed.

Sniffing out the competition? Juvenile coral reef damselfishes use chemical cues to distinguish the presence of conspecific and heterospecific aggregations.

Aquatic animals commonly rely on chemical cues to provide information regarding their surroundings. They can respond either by being attracted to (potential mates, preferred habitats) or avoiding (predators, competitors) the source of the stimuli. Coral reef fishes use chemical cues to detect habitats, avoid predators and recognise conspecifics. However, the extent to which chemical cues are used to detect and respond to potential competitors, has received little attention. Here we test olfactory preferences for conspecifics and heterospecifics in newly settled juvenile coral reef fishes. Juveniles of 4 common coral-associated damselfish species: Dascyllus melanurus, Dascyllus reticulatus, Chrysiptera arnazae and Pomacentrus moluccensis, were subjected to olfactory choice tests. Three of the 4 species (excluding P. moluccensis) demonstrated preferences for waterborne conspecifics odours. All species exhibited an avoidance towards heterospecific odours; this aversion was consistently greatest towards P. moluccensis. A neutral response toward heterospecifics was only evident in two instances (1) between the two congeneric Dascyllus species, with D. melanurus toward D. reticulatus, and (2) with C. arnazae toward D. melanurus. While it is already known that the presence of conspecifics plays a vital role in settlement site selection, we show here that the presence of heterospecifics may also be key in determining the spatial distributions of juveniles across areas of coral reef.

The dynamics of coral reef benthic and reef fish communities in Batam and Natuna Islands, Indonesia

ABSTRACT The dynamics of coral reef benthic and fish communities and their relationship within the Batam and Natuna Islands were investigated in 2004, 2007, 2010 and 2013. Hard coral covers declined at both locations (Batam by 18.69% and Natuna by 16.50%) in 2013, after which a mass bleaching event occurred in 2010. This dramatically affected fish abundance, given that there was a decline of 39.18 individuals per transect in Batam but strangely there was an increase by 47.36 individuals per transect for Natuna. This increase might be related to the isolated location of Natuna, which prevented fishes from migration, especially juveniles. In the same year, the benthic compositions in both locations changed from Acroporidae dominated reefs to become less complex reefs. Following this, the fish composition became less diverse for Batam but in reverse for Natuna. The changes in benthic communities correlate significantly with fish functional group diversity for Batam and the abundance for Natuna. These differences might be related to geographical conditions and human impacts which are different between the locations, such as being surrounded by group of islands or open sea, and fishing activities. The communities are dynamic spatially and temporally as a result of natural conditions of the environment and human activities.

Olfactory responses of coral-reef fishes to coral degradation and crown-of-thorns (Acanthaster planci)

Coral degradation is a major threat towards the biodiversity of coral-reef ecosystems, either through the physical effects of environmental change, or biological agents such as crown-of-thorns (Acanthaster planci). Coral loss is leading to significant declines in reef-fish assemblages, particularly those dependent on live coral as settlement sites. Most reef fishes use olfactory stimuli at settlement; however, their ability to detect chemical stimuli from degraded corals or A. planci is unknown. Here, olfactory responses of juvenile reef fishes to the presence of stressed corals and A. planci were tested. Juveniles of eight common coral-associated species were subjected to a series of pair-wise choice tests, where the period of time spent in two differing water sources was noted. All species demonstrated a significant attraction towards healthy coral (≥76%), avoiding cues emitted by stressed coral colonies. When given the choice between a control water (untreated reef water) and water containing chemical cues from A. planci, most species elicited no response. Finally, when given the choice between chemical cues derived from feeding A. planci or the control, all species avoided A. planci (≥70%). Our results indicated that juvenile reef fish are capable of distinguishing the state of coral health, but not directly from disturbance agents.