Beyond Capricornia: Tropical Sea Slugs (Gastropoda, Heterobranchia) Extend Their Distributions into the Tasman Sea

Abstract

There is increasing evidence of poleward migration of a broad range of taxa under the influence of a warming ocean. However, patchy research effort, the lack of pre-existing baseline data, and taxonomic uncertainty for some taxa means that unambiguous interpretation of observations is often difficult. Here, we propose that heterobranch sea slugs provide a useful target group for monitoring shifts in distribution. As many sea slugs are highly colourful, popular with underwater photographers and rock-pool ramblers, and found in accessible habitats, they provide an ideal target for citizen scientist programs, such as the Sea Slug Census. This maximises our ability to rapidly gain usable diversity and distributional data. Here, we review records of recent range extensions by tropical species into the subtropical and temperate waters of eastern Australia and document, for the first time in Australian waters, observations of three tropical species of sea slug as well as range extensions for a further six to various locations in the Tasman Sea.

1. Introduction

By far the majority of Indo-Pacific sea slug species are tropical [1] with diversity declining away from the equator. The highest diversity occurs in the tropical western Pacific, and in particular in the area known as the Coral Triangle (bounded by Indonesia, the Philippines, and the Solomon Islands). However, records are extremely patchy both spatially and temporally, with many regions receiving very little recent attention (e.g., eastern Indonesia) [2]. On the Australian east coast, diversity attenuates from the northern Great Barrier Reef (GBR), Queensland (QLD), where approximately 1000 species have been recorded [3], to the southern tip of the mainland with 400 species recorded from Victoria and Bass Strait [4]. The subtropical region of New South Wales (NSW) supports both tropical and temperate taxa representing a biogeographic ecotone, as well as several endemic taxa restricted to this overlap zone [5].

The oceanographic conditions on the central eastern Australian coast, which extends from the southern GBR in southern QLD to northern NSW, are heavily influenced by the East Australian Current (EAC) which delivers warm water from the tropical Coral Sea into the subtropics [6]. Its southward-flowing waters move along the continental slope but are diverted east at South West Rocks, NSW to form an eastward-flowing current: the Tasman Front [7,8], which transports warm water across the northern Tasman Sea to Lord Howe Island and New Zealand [9]. In addition, eddies of the EAC regularly flood the continental shelf in the region. This combination of circulation patterns leads to rapid changes in water temperature, sometimes as high as 7 °C over a 24 h period, as the EAC drives upwelling in coastal waters [8,10].

In the Solitary Islands Marine Park, some 150 km north of the eastward diversion of the EAC, where shallow reefs are present along a cross-shelf gradient, temperature loggers deployed at depths of ~10 m, indicate a consistent gradient of water temperature with offshore sites (8–11 km offshore) experiencing temperatures that are 1–1.5 °C warmer than nearshore sites [8]. This gradient in water temperature is reflected in biological patterns with increasing representation of tropically affiliated species of coral [11], fish [12], and molluscs [13,14] offshore. It is hypothesised that these patterns are maintained by recruitment of entrained pelagic larvae transported southward by the EAC [11,13]. For example, some tropical reef fish are known to be transported six degrees of latitude south of their usual range [15,16,17]. Variability associated with recruitment events (supply, transport, settlement, survival) may lead to substantial changes in the structure of assemblages at the receiving sites [11]. Despite this variability, and in line with predictions of the biological effects of a strengthening EAC and increasing water temperatures, reports of southward range extensions are rapidly increasing.

1.1. An Emerging Trend—Poleward Range Extensions in Sea Slug Distributions

Over the past 10 years, records of sea slug species found poleward of their previously known range have proliferated in the scientific literature [18,19,20,21,22]. There is little doubt, however, that some of the reports simply reflect a lack of previous scientific scrutiny through limited survey effort. For example, the 23 sea slug species listed by Bertsch [21] as being new to the Gulf of California may simply be a product of increased search effort under the objective of generating a regional species list rather than recent introductions. It is also likely that increased effort associated with the development of a regional inventory resulted in the first reports of: Janolus fuscus O’Donoghue, 1924 into the Sea of Japan [23]; four species into southern Brazil [18]; the occurrence of Geitodoris planata (Alder & Hancock, 1846) on the North Sea coast of the United Kingdom [24]; and northern range extensions for nine taxa from temperate Chilean waters into Peru [22].

However, there are also many substantiated records which result from invasion by non-indigenous fauna, or poleward movement due to warming, for example, Spurilla neapolitana (Delle Chiaje, 1841) into Peru from Costa Rica [25] and Bathydoris aioca Marcus & Marcus, 1962 from Baja California, Mexico to Oregon USA [26]. Anomalous warming in the north-eastern Pacific also resulted in range-shifts for 30 mollusc species from California to Oregon [27]. The regional extinction and subsequent slow recovery of Felimare californiensis (Bergh, 1879) in California, putatively due to regional-scale anthropogenic effects rather than broadscale climatic changes [28], illustrates the importance of comprehensive baseline data to help interpret the scale, and likely causes, of subsequent changes.

Given that range extensions are occurring, an important question is how this will affect the ecology of the receiving sites. However, despite general consensus that cumulative impacts may have global consequences [29], data on species-specific impacts are lacking. Indeed, only one published study to date specifically addressed putative impacts of altered population dynamics. Goddard, Gosliner, & Pearse [30] investigated the effects of a poleward range shift by the nudibranch Phidiana hiltoni (O′Donoghue, 1927) in California. They noted a concomitant decline in the abundance of other nudibranch taxa with subsequent dietary analysis and feeding experiments indicating predation by P. hiltoni as a likely cause. On the eastern and southern coasts of Australia, the introduction and rapid spread of the aeolid nudibranch Spurilla braziliana on intertidal rocky reefs [5,31], has anecdotally been linked to a reduction in the abundance of an indigenous aeolid species, Austraeolis ornata (SDAS, MN, pers. obs.), although quantitative data are currently lacking.

Lessepsian migration, the unidirectional migration of marine taxa from the Red Sea to the eastern Mediterranean via the Suez Canal [32], is assumed to be the means by which several sea slugs have shifted their distribution into the eastern Mediterranean Sea [33,34] and southern European shores [34,35]. Whilst regarded as potentially invasive, many may simply be casual or vagrant animals. However, some are clearly invasive, such as the sea hares Syphonota geographica (Adams & Reeve, 1850) and Bursatella leachii De Blainville, 1817 [34,35,36].

1.2. Recent Poleward Range Extensions in Eastern Australia

The central eastern Australian coast is a known climate change hot-spot where warming conditions are proving favourable for gradual poleward shifts in southern range limits for several marine taxa (e.g., Harasti; Scott, et al.; Davis [37,38,39]). Since early 2014, we have identified and reported 28 species of sea slug south of their previously known range [5,40,41,42,43] (Figure 1). The distance of such shifts varies from a regional scale at distances of 100s of km to a bioregional scale of >1000 km. The majority of reported range extensions fall within the regional scale: only two of the 28 species were recorded >1000 km poleward of their previous geographical limit.

In this paper, we report nine further range extensions into central and southern NSW and to Lord Howe Island in the central Tasman Sea. The scale of these range shifts varies from <100 km to more than 4000 km and also includes three novel observations for Australian waters. In most cases, these records also represent the southernmost global observations.

2. Materials and Methods

The observations summarised in this paper were made by the authors and well-informed citizen scientists recruited through the Sea Slug Census (SSC) program. The SSC is a volunteer-based project developed by Southern Cross University and volunteers that engages with participants to photographically document sea slug diversity at specific locations (Smith and Davis, unpublished). Observations included here were made during the inaugural Sapphire Coast SSC (April 2017), the 15th Nelson Bay SSC (September 2017) and the second Gold Coast SSC (September 2017).

Sea Slug Census participants are primarily engaged through social media (Facebook https://www.facebook.com/groups/seaslugcensus/) which allows the upload of photos for identification and discussion by other users. Metadata are included for each image, including location, date, and depth. The establishment of a hub for photographic submission and discussion not only provides sharing of recent discoveries, but often uncovers information about the historical presence of species [5]. In this way, previously unpublished observation records for Lord Howe Island were recognised as a result of the development of a social media page for that location. Observations recorded by the authors were made using SCUBA, snorkeling or during searches in intertidal habitats. Photographs were taken using housed Olympus TG-3/5 cameras with iTorch video lights. Voucher specimens were collected in non-sanctuary zones, preserved in 90% ethanol, and deposited at the National Marine Science Centre, Southern Cross University, Coffs Harbour, NSW (NMSC) under NSW Department or Primary Industries permit P14/0014-1.1.

Comparison with published distribution sources and regional lists (e.g., [5]) enables ready detection of species in novel locations. Global distribution data were sourced from the literature and online sources (

Table 1. Summary of source documents for global distribution data.

Source Type	Reference
Published literature	Coleman [46,47]
	Nimbs & Smith [5]
	Gosliner et al. [1]
	Burn [4]
	Cobb & Willan [48]
	Debelius & Kuiter [49]
	Buchanan [50]
Electronic sources	NudiPixel [51]
	Atlas of Living Australia [52]
	Sea Slug Forum [53]
	OBIS [54]
	Cobb & Mullins [55]
	Köhler [56]
	Clarke & Buckland [57]
	Riek [58]
	GBIF [59]

). These data include location (latitude and longitude) and date of observation.

Identifications based on photographs alone can be problematic, particularly among groups where there is potential cryptic speciation, such as in the genus Chromodoris [44]. In the absence of genetic analysis, identifications should be regarded as hypotheses. Therefore, we consider our identifications as such and have only included those with which we have reasonable confidence. Additionally, in this paper we use the term ‘range extension′ to mean a potential extension of known distributional range whilst acknowledging that any conclusions are constrained by the distributional data available. For some species, this may be limited to only two or three records.

The familial and generic taxonomy of some species in this paper are in a state of flux at the time of manuscript preparation. Thus, we deferred to the nomenclature listed in World Register of Marine Species [45].

3. Results

Recent Southern Range Shifts in Eastern Australia

• Systematics
• Subclass Heterobranchia
• Order Cephalaspidea Fischer, 1883
• Family Aglajidae Pilsbry, 1895 (1847)
• Genus Mariaglaja Zamora-Silva & Malaquias, 2017
• Mariaglaja tsurugensis (Baba & Abe, 1959) (Figure 2A)
• Synonymy: Chelidonura sandrana Rudman, 1973, Chelidonura babai Gosliner, 1988.

Although highly variable, Mariaglaja tsurugensis is generally characterised by a predominantly black body with yellow spots surrounded by black rings among scattered patches of opaque white. There are, however, occasional specimens that are almost entirely white [60]. The pattern of yellow spots surrounded by white has been variously referred to as ‘floral′ [1,60].

In Australia, M. tsurugensis, has been found on both the east and west coasts (as C. sandrana in Nimbs & Smith [5]), consistent with its broad Indo-Pacific distribution [1,60]. Whilst occasionally abundant on the northern Great Barrier Reef at Lizard Island, QLD [61], it has not been seen elsewhere on the eastern mainland coast except at Angourie (pers. obs.) (specimen collected under permit and deposited at the NMSC [NMSC#0353SDAS]) and the Solitary Islands, NSW [50] (

Table 2. Distribution records of Mariaglaja tsurugensis from eastern Australia.

Location	Date	Latitude	Longitude	Reference
Lizard Island, QLD	1979	14°40′24″ S	145°27′05″ E	[61]
Angourie, NSW	2017	29°28′53″ S	153°21′54″ E	This paper
Solitary Islands, NSW	1988	30°12′13″ S	153°16′52″ E	[50]
Lord Howe Island, NSW	1979	31°33′20″ S	159°04′56″ E	[46]
Bermagui, NSW	2017	36°25′22″ S	150°05′13″ E	This paper

).

During the inaugural Sapphire Coast SSC on 10 April 2017, a 28-mm long specimen was observed at Blue Pool, Bermagui, NSW. This observation represents a 670 km poleward range extension from its previous southern distribution limit at Lord Howe Island, NSW.

• Family Haminoeidae Pilsbry, 1895
• Genus Haminoea Turton and Kingston [in Carrington], 1830
• Haminoea cymbalum (Quoy and Gaimard, 1832) (Figure 2B)
• Synonymy: Bulla cymbalum Quoy and Gaimard, 1832; Haminea cymbalum (Quoy and Gaimard, 1832); Haminoea simillima Pease, 1868; and, Lamprohaminoea cymbalum (Quoy and Gaimard, 1832) [45].

There are numerous species of Haminoea, many of which are undescribed (M. Malaquias, pers. comm., April 2017). In many cases, distinguishing among species is difficult based on external morphology alone. Indeed, among the European fauna for example, H. orbignyana cannot be reliably identified from its sympatric congeners without examination of the male reproductive system [62]. However, some species do exhibit external features that allow ready identification. Haminoea cymbalum is identified by the presence of orange spots and semi-transparent purple patches on a translucent body. The shell is evident beneath the parapodial lobes and possesses a distinctive ‘fried-egg′ pattern over a darker, often green, background [63].

Haminoea cymbalum has a wide Indo-Pacific distribution, from Mozambique in the west to Japan in the north, to Hawai′i and French Polynesia in the east [59]. On the Australian east coast, it has been found in several locations off Cape York, QLD, throughout the Great Barrier Reef, and south to Port Stephens in central NSW [5] (

Table 3. Distribution records of Haminoea cymbalum from eastern Australia.

Location	Date	Latitude	Longitude	Reference
Great Detached Reef	1981	11°44′23″ S	144°03′46″ E	[52]
Lizard Island, QLD	2004	14°57′23″ S	145°44′05″ E	[52]
Marble Island, QLD	2002	21°59′03″ S	150°09′21″ E	[52]
Saumarez Reef, QLD	1983	21°50′00″ S	153°39′59″ E	[52]
Heron Island, QLD	1981	23°26′35″ S	151°54′35″ E	[52]
Gold Coast, QLD	2007	28°03′12″ S	153°26′27″ E	[47]
Solitary Islands, NSW	2015	30°12′13″ S	153°16′52″ E	[5]
South West Rocks, NSW	2014	30°55′49″ S	153°05′33″ E	[52]
Port Stephens, NSW	1987	32°43′54″ S	152°32′00″ E	[52]
Bermagui, NSW	2017	36°25′22″ S	150°05′13″ E	This paper

). Several specimens were observed on 10 April 2017 at Blue Pool, Bermagui, NSW, by Libby Hepburn and Nick Shaw (Figure 2B). These observations represent a southern range extension of 500 km into the temperate waters of the Tasman Sea from its previous southernmost observation at Port Stephens, NSW.

• Order Sacoglossa
• Family Plakobranchidae Gray, 1840
• Genus Elysia Risso, 1818
• Elysia sp. (Figure 2C)

There are numerous undescribed species in the sacoglossan genus Elysia [1] and, consequently, determining their distributions can be very difficult, particularly as many are morphologically similar or highly cryptic [64]. Nevertheless, some have distinctive, characteristic morphology, and such is the case with Elysia sp. which exhibits a diagnostic mosaic pattern of olive-green patches outlined in black which are replaced with white patches outlined in black along the parapodial margins. No other Elysia is known to exhibit this pattern.

Published records of this species are scarce: indeed, the only existing observation is from Milne Bay in Papua New Guinea [46,47] (

Table 4. Global distribution records of Elysia sp.

Location	Date	Latitude	Longitude	Reference
Milne Bay, Papua New Guinea	2007	10°24′21″ S	150°36′36″ E	[46,47]
North Solitary Island, NSW	2017	29°55′30″ S	153°23′20″ E	This paper

). An observation of a single specimen at North Solitary Island, NSW on 27 May 2017 not only extends the range for this species 2200 km southward into the Tasman Sea, but represents the first Australian, and the most southern, global observation of this species.

• Genus Thuridilla Bergh, 1872
• Thuridilla flavomaculata Gosliner, 1995 (Figure 2D)

The herbivorous Thuridilla flavomaculata is one of the few species in its genus to exhibit scattered yellow spots [65]. An animal collected in the Philippines in 1995 was assigned as the holotype although one paratype was collected in Guam in 1970 [65]. As with many Thuridilla, distribution is generally restricted to the tropics, with observations recorded from the Mariana Islands in the north and Alor, Indonesia in the south. Longitudinally, its range extends from the western Pacific, across the Indian Ocean to Kenya (

Table 5. Selected global distribution records of Thuridilla flavomaculata.

Location	Date	Latitude	Longitude	Reference
Saipan, N. Mariana Islands	2006	15°09′15″ N	145°45′13″ E	[66]
Guam	2010	13°26′32″ N	144°51′35″ E	[65]
Marshall Islands	1995	07°07′53″ N	171°11′04″ E	[65]
Bunaken, Indonesia	2006	01°37′51″ N	124°45′42″ E	[67]
Lembeh, Indonesia	2009	01°26′43″ N	125°12′56″ E	[51]
Tukang Besi, Indonesia	2000	05°27′17″ S	123°39′30″ E	[68]
Alor, Indonesia	2010	08°15′01″ S	124°29′37″ E	[51]
Malindi, Kenya	2010	03°13′34″ S	040°08′38″ E	[51]
Lord Howe Island, NSW	2017	31°33′45″ S	159°05′36″ E	This paper

).

On 28 May 2017, a single individual was observed by Kathryn May in a tidal pool at Lord Howe Island, NSW. This observation extends the range of this species well outside the tropics, some 4250 km to the southeast of the nearest geographic observation at Alor, East Nusa Tenggara, Indonesia.

• Order Nudibranchia
• Family Chromodorididae Bergh, 1891
• Genus Chromodoris Alder & Hancock, 1855
• Chromodoris magnifica (Quoy & Gaimard, 1832) (Figure 2E)
• Synonym: Doris magnifica Quoy & Gaimard, 1832 [45]

There are several species of Chromodoris that exhibit longitudinal black lines and are difficult to identify based on morphology alone [69]. However, C. magnifica, whilst variable in colour, is readily distinguished by the presence of a submarginal orange band [69]. It has a wide distribution in the Indo-Pacific [51] and, in Australia, has been observed several times on the continental east coast from Fitzroy Island in QLD to Cook Island in northern NSW (

Table 6. Selected Australian distribution records of Chromodoris magnifica.

Location	Date	Latitude	Longitude	Reference
Cartier & Ashmore Reefs, WA	1999	12°15′26″ S	123°00′01″ E	[70]
Fitzroy Island, QLD	2015	16°55′18″ S	145°59′00″ E	[71]
Heron Island, QLD	1999	23°26′35″ S	151°54′38″ E	[72]
Gneering Shoals, QLD	2012	26°39′00″ S	153°11′00″ E	[48]
Cook Island, NSW	2013	28°11′46″ S	153°34′35″ E	[73]
North Solitary Island, NSW	2017	29°55′50″ S	153°23′29″ E	This paper
Lord Howe Island, NSW	2009	31°33′45″ S	159°05′36″ E	[51]

).

Although a single observation at Lord Howe Island in 2009 represents the southernmost global record for this taxon, here we report an observation at North Solitary Island, NSW on 18 May 2017 which extends its continental east coast range by 200 km poleward into the subtropical Solitary Islands Marine Park.

• Genus Doriprismatica d’Orbigny, 1839
• Doriprismatica dendrobranchia (Rudman, 1990) (Figure 2F)
• Synonym: Glossodoris dendrobranchia Rudman, 1990 [45]

Doriprismatica dendrobranchia is a high-bodied, robust nudibranch with a brown body and sinuous, white mantle margin [74]. Whilst similar in form, its colour pattern is almost the complete inverse of its more common, sympatric congener, D. atromarginata.

This species is known only from the waters of southern QLD and was described using one animal found at Horseshoe Reef (Swain Reefs) in the southern Great Barrier Reef [75]. During the 27 years since its original description, there have been only two additional observations recorded, from Noosa, QLD in 2004 and recently in 2018 (

Table 7. Australian distribution records of Doriprismatica dendrobranchia.

Location	Date	Latitude	Longitude	Reference
Swain Reefs, QLD	1990	21°45′18″ S	152°22′20″ E	[74]
Noosa, QLD	2004, 2018	26°21′33″ S	153°06′46″ E	[76]
Lord Howe Island, NSW	2017	31°33′45″ S	159°05′36″ E	This paper

). With no other global records, and a range extending across only 450 km of shallow shelf waters, this species appears to be rare and highly restricted.

A specimen photographed by Jasmin Freya at Lord Howe Island at 16 m on 3 February 2016 represents one of only a handful of observations for this taxon. This important record also extends the known range for this rare species some 820 km south and is the first observation in NSW.

• Doriprismatica paladentata (Rudman, 1986) (Figure 3A)
• Synonymy: Glossodoris paladentatus Rudman, 1986 [45]

Observations of Doriprismatica paladentata are few, potentially an artefact of its close similarity to Doriprismatica atromarginata [77] which, in some locations, can be one of the most frequently observed chromodorid nudibranchs [78]. Thus, D. paladentata may simply have been overlooked where distributions are sympatric. Nevertheless, it can be distinguished from D. atromarginata by the presence of sparse brown spots on the mantle and a light-blue sub-marginal band [77].

Although the type location is Milne Bay, Papua New Guinea, complete records indicate a western Pacific distribution from the Philippines in the north, to Vietnam in the west and Vanuatu in the southeast (

Table 8. Global distribution records of Doriprismatica paladentata.

Location	Date	Latitude	Longitude	Reference
Anilao, Philippines	2010	13°42′45″ N	120°51′10″ E	[56]
Vietnam	2005	11°12′06″ N	109°08′41″ E	[51]
Banda Islands, Indonesia	2010	04°43′09″ S	129°59′35″ E	[51]
Milne Bay, PNG	1982	10°02′45″ S	150°05′02″ E	[79]
Espiritu Santo Is., Vanuatu	1999	15°15′59″ S	166°40′44″ E	[53]
Cook Island, NSW	2017	28°11′46″ S	153°34′35″ E	This paper

). An observation at Cook Island, NSW on 25 September 2017 at 7 m by Sascha Hofmann as part of the second Gold Coast SSC, not only represents a range extension of 2000 km from its southernmost global observation at Vanuatu in 1999, but also the first observation for this species in Australian waters.

• Family Facelinidae Bergh, 1889
• Genus Phyllodesmium Ehrenberg, 1831
• Phyllodesmium magnum Rudman, 1991 (Figure 3C)

The nudibranch Phyllodesmium magnum is a large corallivorous aeolid which acquires photosynthetic Symbiodinium from its prey, the octocoral Sinularia [80]. These symbionts are sequestered into tissues giving the body and cerata a brown, blotched appearance. In some specimens, the oral tentacles, rhinophores, and cerata have blue or lilac patches (pers. obs.).

This species has a wide Indo-Pacific distribution from South Africa and the Red Sea [49] to Japan, the Philippines, Marshall Islands, Papua New Guinea, Australia [81,82] and east to the Kermadec Islands, New Zealand [83]. In eastern Australia, it has been found in the central Great Barrier Reef south to the Solitary Islands in northern NSW (

Table 9. Eastern Australian distribution records of Phyllodesmium magnum.

Location	Date	Latitude	Longitude	Reference
Keppel Island, QLD	1969	23°10′30″ S	150°55′38″ E	[46,47]
Heron Island, QLD	1999	23°26′35″ S	151°54′38″ E	[72]
Gneering Shoals, QLD	2011	26°39′00″ S	153°11′00″ E	[48]
Cook Island, NSW	1977	28°11′46″ S	153°34′35″ E	[46]
Julian Rocks, NSW	n.d.	28°36′42″ S	153°37′44″ E	[57]
Solitary Islands, NSW	1988	30°04′03″ S	153°20′15″ E	[50]
South West Rocks, NSW	2016	30°55′49″ S	153°05′33″ E	This paper, [5]

).

Although only 75 km south of its known southern limit on the east coast, an observation of Phyllodesmium magnum by Nicola Fraser at 7 m at Ladies Reef near South West Rocks, NSW on 23 May 2016, is important for several reasons. Firstly, it represents a contemporary observation of this species which is rare in NSW. Secondly, it extends the range south of the large marine protected area of the Solitary Islands Marine Park, and lastly, it illustrates the importance of the nearshore reefs of South West Rocks as habitat for a diverse range of taxa, especially molluscs [84].

• Family Trinchesiidae F. Nordsieck, 1972
• Genus Phestilla Bergh, 1874
• Phestilla minor Rudman, 1981 (Figure 3B)
• Synonym: Tenellia minor (Rudman, 1981) [45]

Few nudibranchs prey on scleractinian corals, however, species in the genus Phestilla do so exclusively. Phestilla minor was so named due its diminutive size in comparison to its congeners. It is aeolidiform with rows of four to six cerata arranged in series that slope to the rear. From above, these appear to project postero-horizontally, giving it a characteristic appearance [85]. The cerata themselves are also distinctive with a sub-apical swelling and ‘terminal bulb’ [85].

This species has a wide distribution from Tanzania in the west to Hawai′i in the east and south into the Great Barrier Reef [51,85]. On the Australian east coast, it has been recorded from Lizard Island in northern QLD south to Hastings Point in northern NSW (

Table 10. Eastern Australian distribution records of Phestilla minor.

Location	Date	Latitude	Longitude	Reference
Lizard Island, QLD	1979	14°40′24″ S	145°27′05″ E	[86]
Mooloolaba, QLD	2004	26°40′32″ S	153°08′12″ E	[55]
Hastings Point, NSW	2006	28°21′40″ S	153°34′50″ E	[58]
Port Stephens, NSW	2017	32°43′54″ S	152°32′00″ E	This paper

).

An observation of a single specimen at Nelson Bay, NSW during the 15th Nelson Bay SSC by Peter Davey extends this range south by 500 km.

4. Discussion

The addition of nine species of heterobranch sea slug that have extended their range southward into subtropical and warm-temperate waters in eastern Australia brings the total, poleward-shifting tally to 37. While there is little doubt that a lack of search effort at some locations, and the cryptic nature of some species, may account for a few of these records [5], by far the majority are for conspicuous species which occur in accessible habitats. This strongly suggests that they represent real shifts in species distribution patterns. Sporadic finds of tropically-affiliated species at southern range extremes is well documented for highly-collectable species with a long historical record of collection or observation (e.g., the Cypraeidae [87]). However, there is also increasing evidence that some species are now regularly found at their new southern limit, suggesting the establishment of populations rather than sporadic recruitment of individuals. For example, since our first observation of a single Tambja sp. at Split Solitary Island in 2016 [42], specimens have been regularly observed at nearby North West Solitary Island (2017, 2018). This is consistent with recent work in temperate waters that modelled the distribution of a number of range-shifting species and suggested not only poleward extension of records, but also a poleward shift in the species′ core range [88].

Of the five major benthic heterobranch orders found in Australian waters [89], four are represented within this list of 37 species: Aplysiida (1), Cephalaspidea (5), Nudibranchia (26), and the Sacoglossa (5). The Pleurobranchida is the only major order that lacks taxa known to have recently shifted poleward in southeastern Australia. Within the numerically largest group, the Nudibranchia, animals from both the major suborders Cladobranchia and Doridina are present, with 9 and 17 species, respectively. This broad taxonomic spread illustrates that range shifts are occurring across much of the Heterobranchia and are not confined to groups that contain potentially invasive taxa, such as the aeolids [28,30], polycerids [90,91], and sea hares [35,40].

The pace of southern migration is difficult to ascertain as there was little consistent, dedicated observation work on the NSW coast prior to 2010. Since the advent of the Nelson Bay SSC in 2013, concentrated research efforts on the north coast, and the phased introduction of regular SSC surveys at other locations, there have been at least five records of range extensions per year since 2014. The highest count for a single year was 13 in 2015 (

Table 11. Range extension observations by calendar year.

Year
2010	2011	2012	2013	2014	2015	2016	2017
1	-	-	3	5	13	7	8

).

There is also the suggestion of a seasonal pattern in observations of taxa south of their known range. Thus, most observations were noted in summer (n = 15) with fewer in spring and autumn, and none during winter (Figure 4). This may be partly attributed to the timing of SSC events which mostly occur between September and March, the period of maximum sea slug diversity and abundance (unpublished data). The Nelson Bay SSC program is the only one to incorporate observations in all seasons, but participation rates in winter are usually lower (~40%) than during other seasons. These winter censuses also yielded lower sea slug diversity. Nevertheless, the authors undertake regular diving activities throughout the year and are yet to find new southern records during winter.

The importance of citizen scientist efforts are further evidenced by the number of significant records generated. Of the 37 species with poleward range shifts, 13 were observed by this group with 4 of those observations made during census events. The remaining nine were generated either in the lead-up to censuses or immediately afterwards.

Gathering evidence of climate-related changes in the distribution of species and the ecology of marine habitats is problematic for many reasons [92]. Perhaps the most important relate to the likely slow pace of change in physico-chemical variables, the enormity of the task of keeping track of the distribution of the broader species pool, and predicting which ecological processes to monitor. While engagement with citizen scientists can vastly increase the spatial and temporal scale of efforts to document species distribution, it will arguably be impossible to monitor everything and so a surrogacy approach (e.g., [93,94,95]), targeting a group of organisms that are likely to respond in a way that reflects broader ecosystem change, is clearly needed. There are some clear candidates.

Corals are under threat from changing environmental conditions with increasing frequency of bleaching events and subsequent mortality [96]. As habitat formers, changes in coral communities are also likely to have considerable flow-on effects to broader biotic communities. However, while corals are expected to change their distribution patterns, with subtropical reefs forecast to act as refuges for species driven southward under thermal pressure [97], they will remain a feature only of warmer oceans.

Fishes are another likely candidate with considerable evidence of changing distribution patterns [16,88,98]. The importance of fishes as consumers and as key economic resources further underpin their potential. As some families are excellent proxies of broader assemblage patterns, it may be possible to increase the cost-effectiveness of monitoring by focusing primarily on these taxa (pomacentrids and labrids) [99].

While these taxa are undoubtedly useful targets for monitoring, effort is likely to be restricted by the availability of funding and expertise. Corals are notoriously difficult to identify [100] and, while there are some very successful citizen science programs focusing on fish among other taxa (Reef Life Survey, RedMap), access and volunteer capacity can restrict the acquisition of data [88].

In this study, we document the first observations of taxa at novel locations. This provides some focus for efforts to determine the establishment of populations which may herald ecological impacts in the receiving assemblages. For example, regular monitoring enabled Goddard, Gosliner, & Pearse [30] to recognise an increase in abundance of Phidiana hiltoni and the simultaneous collapse of other nudibranch populations in California. Whilst such a dramatic effect has yet to be observed on the Australian east coast, the acquisition of data through regular censuses increases the probability that large or unexpected changes in populations will be rapidly detected.

Through the Sea Slug Census program, we have not only been able to demonstrate the appeal of sea slugs as a target taxon, but also the ability of volunteers to find and record them photographically. Because they are generally very slow moving, photographic records are easy to generate, which facilitates capture of images that allow ready identification of species by scientists. However, apart from their popularity with divers and rock-pool ramblers, there are other reasons to suggest sea slugs as useful surrogates for monitoring ecosystem change. Most have short life cycles and the presence of species is strongly dependent on the availability of specific food sources. This means that populations, and whole assemblages, are likely to respond rapidly to changes in the environment. While this means they may be sensitive to a range of variable factors, increasing knowledge about natural patterns of variation [101,102] will help to distinguish additional effects of changing climate. The data presented here provide ample evidence that distribution patterns are changing rapidly, and that tropical species are able to recruit to warm temperate waters across the continuum of the Australian east coast. This supports a continuation of research effort, supported by volunteers, to further develop their use as an indicator of environmental change.