Environmental Biology of Fishes 67: 35–46, 2003. © 2003 Kluwer Academic Publishers. Printed in the Netherlands. First field studies of an Endangered South African seahorse, Hippocampus capensis Elanor M. Bella,∗ , Jacqueline F. Lockyearb , Jana M. McPhersona,∗∗ , A. Dale Marsdena,∗∗∗ & Amanda C.J. Vincenta,∗∗∗ a Project Seahorse, Department of Biology, McGill University, 1205 Avenue Docteur Penfield, Montréal, Québec, Canada H3A 1B1 b Department of Ichthyology & Fisheries Science, Rhodes University, Grahamstown, South Africa ∗ Current address: Department of Ecology and Ecosystem Modelling, Institute of Biochemistry and Biology, Potsdam University, Maulbeerallee 2, 14469 Potsdam, Germany (e-mail: [email protected]) ∗∗ Current address: Department of Zoology, University of Oxford, South Parks Road, Oxford OX1 3PS, UK ∗∗∗ Current address: Project Seahorse, Fisheries Centre, The University of British Columbia, 2204 Main Mall, Vancouver, B.C., Canada V6T 1Z4 Received 12 December 2001 Accepted 16 January 2003 Key words: Knysna Estuary, abundance, distribution, population structure, behaviour Synopsis South Africa’s endemic Knysna seahorse, Hippocampus capensis Boulenger 1900, is a rare example of a marine fish listed as Endangered by the IUCN because of its limited range and habitat vulnerability. It is restricted to four estuaries on the southern coast of South Africa. This study reports on its biology in the Knysna and Swartvlei estuaries, both of which are experiencing heavy coastal development. We found that H. capensis was distributed heterogeneously throughout the Knysna Estuary, with a mean density of 0.0089 m−2 and an estimated total population of 89 000 seahorses (95% confidence interval: 30 000–148 000). H. capensis was found most frequently in low density vegetation stands (≤20% cover) and grasping Zostera capensis. Seahorse density was not otherwise correlated with habitat type or depth. The size of the area in which any particular seahorse was resighted did not differ between males and females. Adult sex ratios were skewed in most transects, with more males than females, but were even on a 10 by 10 m focal study grid. Only three juveniles were sighted during the study. Both sexes were reproductively active but no greeting or courtship behaviours were observed. Males on the focal study grid were longer than females, and had shorter heads and longer tails, but were similar in colouration and skin filamentation. The level of threat to H. capensis and our limited knowledge of its biology mean that further scientific study is urgently needed to assist in developing sound management practices. Introduction Worldwide, seahorse populations are threatened by (a) degradation of their estuarine, seagrass, mangrove and coral habitats, (b) incidental capture in fishing gear (bycatch), and (c) over-exploitation for use in traditional medicines, the aquarium trade and as curiosities. Many species are experiencing population declines but the conservation status of African species is unknown (Vincent 1996). Seahorses are particularly vulnerable to population decline because of their distinctive life history, behaviour and ecology: they provide lengthy and vital parental care for small broods, exhibit low mobility and site-fidelity, have low natural rates of adult 36 mortality, and (in many species) maintain faithful pairbonds (reviewed in Lourie et al. 1999). In addition, seahorses inhabit shallow, coastal areas worldwide, where anthropogenic disturbances tend to be most frequent and severe. South Africa’s endemic Knysna Seahorse, Hippocampus capensis Boulenger 1900, is the only fully estuarine seahorse species among the 32 currently recognised (Lourie et al. 1999). It is also the only seahorse species thus far inferred to be primarily at risk from habitat damage (Whitfield 1995a, Day 1997, Lockyear 19991 ). H. capensis has the smallest known geographical range of any seahorse, inhabiting seagrass beds in only four estuaries on the southern coast of South Africa: Knysna, Swartvlei, Keurbooms and Klein Brak (Howard-Williamson & Allanson 1978,2 Kok 1981, Smith et al. 1986, Grindley 1985,3 Skelton 1987,4 Whitfield et al. 1983,5 Whitfield 1989a,b, 1995a, Hanekom & Russell 1991,6 Russell 1994). Anecdotal information suggests that H. capensis may also occupy the Breede River, Duiwenhoks, Kaffirkuils and Groot Brak (N. Grange, personal communication). Human settlements and associated industrial, domestic and recreational activities are increasing on the shores of waters harbouring H. capensis. The Knysna Estuary is among the most heavily used water bodies in South Africa. Surrounding development is known and inferred to have affected the estuarine 1 Lockyear, J. 1999. Proposal to Change the IUCN Red Listing of Hippocampus capensis Boulenger 1990 (Knysna Seahorse). Unpublished. 2 Howard-Williamson, C. & B.R. Allanson. 1978. Swartvlei Project Report, Part II. The limnology of Swartvlei with special reference to production and nutrient dynamics in the littoral zone. Grahamstown. Institute for Freshwater Studies Special Report No.78/3. 280 pp. 3 Grindley J.R. 1985. Report No. 30: Knysna (CMS 13). In: A.E.F. Heydorn & J.R. Grindley (ed.) Estuaries of the Cape. Part II: Synopses of available information on individual systems. CSIR Research Report 429. 82 pp. 4 Skelton, P.H. 1987. Knysna Seahorse/Knysna-Seeperdjie. South African Red Data Book – Fishes. South African National Scientific Programmes Report 137: 93–95. 5 Whitfield, A.K., B.R. Allanson & T.J.E. Heinecken. 1983. Report No. 22: Swartvlei (CMS 11). In: A.E.F. Heydorn & J.R. Grindley (ed.) Estuaries of the Cape. Part II: Synopses of available information on individual systems. CSIR Research Report 421. 62 pp. 6 Hanekom, N. & I.A. Russell. 1991. The distribution and abundance of the Knysna seahorse, Hippocampus capensis Boulenger 1900, in the Knysna Estuary. National Parks Board of Trustees, Internal Report (unpublished): 1–9. ecosystem (Grindley & Eagle 1978, Plumstead 1990, Whitfield 1995a) with trace metals, hydrocarbons, pesticides and organic wastes among the identified water pollutants (Chmelik 1975). However, information about the direct impact of these disturbances on either estuarine habitats or their inhabitants is scarce (Plumstead 1990). H. capensis appears to be vulnerable to temperature increases. In 1991, 3000 dead seahorses were found along the shores of the Swartvlei Estuary after heavy rainfall and flooding caused the breaching of the estuarine mouth and a sudden reduction in water level (Russell 1994). Mortality was attributed to the resultant increase in water temperature from the normal high of 28–32◦ C (Russell 1994). H. capensis recently became the first seahorse species to be listed as Endangered on the IUCN Red List of Threatened Species because of its limited extent of occurrence and area of occupancy, fragmented distribution, and ecosystem vulnerability (Hilton-Taylor 2000). It is protected by the South African Fisheries Act No. 58 (Grindley 19853 ), the Marine Living Resources Act 1998 and the White Paper for Sustainable Coastal Development in South Africa (Mayekiso 20007 ). Further protection is offered because the Knysna and Swartvlei estuaries are located in the designated National Lakes Area (Skelton 19874 ). Nonetheless, development around the estuary continues, with potentially considerable risk to H. capensis. A dearth of information on H. capensis population size, habitat requirements and population dynamics severely limits management capacity (Skelton 1987,4 Day 1997). There are no published reports of in situ biological or ecological studies focusing on this species. Most studies of H. capensis were conducted under captive conditions (Fourie 1997, Lockyear et al. 1997, Tops 1999, Le Cheminant 2000) or examined their genetics and morphology (Toeffie 2000). Only one unpublished and limited study has considered their population size (Hanekom & Russell 19916 ). Given the species’ apparent vulnerability to ecological perturbations and the threat of habitat degradation, a better understanding of the species’ basic ecology is imperative. This study provides preliminary baseline data on H. capensis individuals and populations. H. capensis is a medium-sized seahorse, with a described adult height (presumably the top of the 7 Mayekiso, M. 2000. Report on the National Estuaries Workshop, Port Elizabeth, 3–5 May 2000. 37 Figure 1. The Knysna Seahorse, H. capensis. Head length is measured from the tip of the snout to the mid-point of the cleithral ridge: (a) trunk length is the distance from the cleithral ridge to the lateral mid-point of the last trunk ring; (b) tail length is measured from the last trunk ring to the tip of the straightened tail. Reproduced with permission of L. Richardson. coronet to tip of the straightened tail) of 5.3–12.0 cm (Smith 1981, Smith et al. 1986, Skelton 1987,4 Lourie et al. 1999, Z. Toeffie in litt.). The species is characterised by a short snout, lack of coronet (Figure 1) and males have a slight keel above the brood pouch. Individuals are typically mottled brown with occasional darker patches, but are known to range in colour from white through yellow, orange, green and beige, to brown or black. Evidence suggests that H. capensis reach sexual maturity within 1 year of birth at approximately 6.5 cm standard length (defined as the sum of the head, trunk and tail lengths, Lourie et al. 1999, Whitfield 1995a). They brood their young for 14–45 days (depending on water temperature), and produce 7–120 young per brood, each of which is 0.8–1.6 cm standard length at birth (Grange & Cretchley 1995, Whitfield 1995a, Lockyear et al. 1997). H. capensis can live for at least 3 years in captivity (Lockyear et al. 1997), but there are no data on longevity in the wild. H. capensis are found at depths of 0.5–20 m (Toeffie 2000) in submerged vegetation, and are known to survive salinity changes from 1 to 59 ppt (Whitfield 1995a). In captivity, H. capensis are diurnally active and have an elaborate courtship and mating ritual involving brood pouch inflation, tail grasping and ‘face-to-face’ positioning (Grange & Cretchley 1995). We expect H. capensis, like most seahorses, to move slowly, ambush their prey, and rely on camouflage and crypsis to avoid predation (Vincent 1990). They may also form monogamous pair bonds as other seahorse Figure 2. Map of the Knysna Estuary, South Africa. Dashed lines = salt marshes; speckled area = intertidal mudflats; closed circles = one or more transects surveyed. Modified from Grindley 1985.3 species do (Dauwe 1992, Nijhoff 1993, Vincent 1995, Vincent & Sadler 1995, Jones et al. 1998, Kvarnemo et al. 2000, Perante et al. 2002). Materials and methods Study site H. capensis were studied in the Knysna and surrounding estuaries (Figure 2). The Knysna (position of mouth: 34◦ 04 35 S, 23◦ 03 40 E) is South Africa’s largest permanent estuary (Grindley 19853 ). It is approximately 21 km2 in area (Day 1981, Reddering & Esterhuysen 19848 ) but extensive sandbanks mean that the subtidal area covers only 10 km2 . Located at the mouth of the 59-km long Knysna River (Grindley 19853 ), its 526 km2 catchment (Day 1981) includes 8 Reddering, J.S.V. & K. Esterhuysen. 1984. Sedimentation of the Knysna Estuary. ROSIE Report No. 9. University of Port Elizabeth, Department of Geography. 79 pp. 38 approximately 20 tributaries and streams (Grindley 19853 ). The estuary’s tidal reach is approximately 10 km (Reddering & Esterhuysen 19848 ). The maximum depth is 12 m below mean sea level, but the water reaches a depth of greater than 16 m at the mouth of the estuary (Day et al. 1952, Grindley 19853 ). The water temperature varied between 14◦ C and 25◦ C (mean ± s.d. = 20 ± 2◦ C) during our study, and horizontal visibility ranged from less than 1–5 m. H. capensis is one of approximately 200 species of fish found in the estuary and is reported to inhabit beds of Zostera capensis seagrass, the dominant aquatic plant in the Knysna Estuary (Grindley 19853 ). The dry biomass of Z. capensis in the estuary ranges from 68 to 238 g m−2 (Grindley 1976,9 Grindley & Snow 1983) and it is most commonly found on shelving mud banks at the low-water level of the spring tide, often in mixed stands with Halophila ovalis (Grindley 19853 ). Above the Westford Bridge (Figure 2), Z. capensis is gradually replaced by Ruppia maritima (Grindley 19853 ). Descriptions of the Swartvlei system (34◦ 00 S, ◦ 23 46 E), the Keurbooms Estuary (34◦ 02 S, 23◦ 23 E) and the Groot Brak Estuary (34◦ 06 S, 22◦ 09 E) can be found in Whitfield et al. (1983),5 Duvenage & Morant (1984)10 and Morant (1983),11 respectively. Assessment of population parameters and habitat occupancy We conducted transect surveys to estimate the abundance of H. capensis in the Knysna Estuary, modifying established techniques for the rapid assessment of fish abundance (Ginsburg et al. 199812 ). Transect counts are well suited to sedentary species such as seahorses (Buxton & Smale 1989). A team of four divers spent 10 days familiarising themselves with estuarine 9 Grindley, J.R. 1976. Report on the ecology of Knysna Estuary and proposed Braamekraal Marina. University of Cape Town, School of Environmental Studies. 123 pp. 10 Duvenage, I.R. & P.D. Morant. 1984. Report No. 31: Keurbooms/Bitou System (CMS 19), Piesang (CMS 18). In: A.E.F. Heydorn & J.R. Grindley (ed.) Estuaries of the Cape. Part II: Synopses of available information on individual systems. CSIR Research Report 430. 64 pp. 11 Morant, P.D. 1983. Report No. 20: Groot Brak (CMS 3). In: A.E.F. Heydorn & J.R. Grindley (ed.) Estuaries of the Cape. Part II: Synopses of available information on individual systems. CSIR Research Report 429. 12 Ginsburg, R.N., P. Kramer, J. Lang, P. Sale & R. Steneck. 1998. Atlantic and Gulf Reef Assessment (AGRRA) Revised Rapid Assessment Protocol (RAP). diving conditions, developing survey techniques, and forming a search image for H. capensis before data collection began. Exploratory dives were also undertaken in Swartvlei Estuary, Swartvlei Lake, Keurbooms Estuary, Groot Brak and Klein Brak. We conducted 82 transect surveys throughout the Knysna Estuary from 23 February to 4 April 2000, surveying a total of 4920 m2 (82 transects, 30 m long×2 m wide). The GPS grid map of the Knysna Estuary was marked into 31 1-km2 grid squares, each surveyed at least once during the study period. The origin and direction of the transects were randomly chosen within each grid square. The number of transects per grid square, which varied from 1 to 5, was determined by available time and accessibility. Before entering the water, GPS location, transect bearing, weather, and water conditions were recorded. Pairs of divers swam the transect together on SCUBA, with the divers searching adjacent 1 m wide swaths as they reeled out a 30 m rope, fixed at the origin. Whenever a seahorse was located, one diver noted its location along the transect, depth, habitat type (Table 1), holdfast, sex, maturity, reproductive state, colour, the presence and length of filamentous appendages, and distinguishing features. The second diver used a plastic ruler marked in cm and mm to measure its head, trunk and tail lengths. Previous studies have used various metrics to describe H. capensis. We standardised our measurements according to Lourie et al. (1999) (Figure 1). Sex was determined by the presence (male) or absence (female) of a brood pouch. Table 1. Habitat categories employed in estimate of seahorse density and abundance. Category Description Bare Zostera capensis Total vegetation cover ≤2% Only species present or proportion of this species exceeds the proportion of other vegetation types by ≥10% Only species present or proportion of this species exceeds the proportion of other vegetation types by ≥10% Only species present or proportion of this species exceeds the proportion of other vegetation types by ≥10% ≥2 species present in proportions that differ by <10% <20% substrate covered with vegetation 20–40% substrate covered with vegetation >40% substrate covered with vegetation Caulerpa filiformis Halophila ovalis Mixed Low density Medium density High density 39 Small seahorses (below the 7.1 cm standard length at which we first observed pouches) were recorded as juvenile but may have been young females. We also noted whether males were pregnant or not pregnant. Female reproductive state is commonly defined by whether her trunk shape indicates that she is holding hydrated eggs or has just transferred eggs (Vincent & Sadler 1995, Perante et al. 2002), but we found this too difficult to determine with accuracy in H. capensis. The divers fixed the rope at the end of the transect and returned along the line, each noting habitat and vegetation type, percentage cover, vegetation height, sediment composition, slope, depth, topographical features and associated species of invertebrates (e.g. the stinging cnidarian, Tubularia warreni) and fish within two 1 m2 quadrats at 5 m intervals. Water temperature readings were taken underwater at the start and end point of each transect, and current strength and visibility were also noted. Transect lines were removed after the return swim. Spatial patterns and social behaviour We undertook a brief second study in order to document H. capensis movement and behaviour in a small and apparently densely populated part of the Knysna Estuary, following the protocol of Vincent & Sadler (1995). We used plastic tent pegs and photodegradable flagging tape to lay down a 10 m × 10 m grid (with 2 m × 2 m grid squares), hereafter referred to as the focal study grid, at the Laguna Grove jetty (Figure 2). We then monitored seahorses on 10 mornings between 13 March and 4 April 2000. Seahorses located within the focal study grid were tagged using numbered, green, plastic tags (approximately 4 mm × 2 mm), hung loosely around the neck of the seahorse with cotton thread. Such individual tagging is necessary for identification because seahorses can change colour and dermal appendages can be lost (Vincent 1990, Vincent & Sadler 1995). As we tagged each seahorse, we recorded its position on the focal study grid, holdfast, colour, sex, reproductive state, filaments on the body (percentage cover and length), head length, trunk length, tail length, distance to the nearest known neighbour, and the sex and reproductive state of the neighbouring seahorse. We monitored the tagged animals closely during our study, loosening or cleaning their tags as necessary. Tags were not removed at the end of our study as a colleague tracked them for further research. They were removed once the subsequent study was completed. The study site was visited daily when weather conditions and visibility permitted. Two divers swam over the focal study grid systematically searching each 4-m2 grid square for seahorses and tagging any new animals. When a tagged animal was resighted, the divers would briefly float a minimum of 1 m away from the seahorse and note its tag number, position on the focal study grid, and behaviour (as per Vincent 1990). Analysis of seahorse spatial patterns on the focal study grid was conducted using Minimum Convex Polygons (MCPs), a robust technique for use in short studies such as ours where very few recapture positions (fixes) are available per animal (Harris et al. 1990). The method calculates the area of the polygon that connects the outermost fixes for each animal. We calculated the MCP area occupied during the study and polygon length (the maximum distance between two corners of each polygon) for each seahorse, using Wildtrak version 1.2, a non-parametric home range analysis program (Todd 199213 ). The MCP area and length data were logarithmically transformed to normalise distributions, then analysed using Student’s t-tests. All means are reported with standard deviation unless otherwise stated. Results We found a total of 44 seahorses in the 82 transects, with 18 transects yielding one or more seahorses. In addition, we tagged and studied 91 seahorses on the focal study grid. Not all data are available for each of the seahorses observed in the Knysna Estuary. Of the other water bodies surveyed, we found H. capensis in only the Swartvlei Estuary (Table 2). Population parameters Observed seahorse densities in the randomly distributed transects ranged from 0 to 0.25 m−2 , with a mean overall density of 0.0089 m−2 (Figure 3). Extrapolating from our transects to the total 10 km2 subtidal area of the Knysna Estuary yielded a population 13 Todd, I.A. 1992. Wildtrak: Non-parametric home range analysis for Macintosh computers (Version 1.2). Department of Zoology, University of Oxford, U.K. Current address: University of Hertfordshire, UK. 40 Table 2. Number of H. capensis found and effort allocated to searching in the Knysna Estuary and surrounding water bodies. Table 3. Numbers of male, female and juvenile H. capensis found in the Knysna Estuary. Water body Number of No. sites Estuarine Person-hours∗ spent seahorses surveyed area surveying found (km2 ) Females Males Males : Total Juveniles Total adults Knysna 44 Swartvlei 19 Swartvlei 0 Lake Keurbooms 0 Groot Brak 0 Klein Brak 0 82 6 2 29 4 3 10.01§ 2.02 8.82 c. 3.03 0.54 164 24 4 12 7 3 Focal study 47 grid Transect 12 survey Total 59 44 0.484 0 91 29 0.707∗ 3 44 73 0.553 3 135 ∗ Indicates significantly biased sex ratio (chi-square test, p < 0.05). = Duration of survey in hours multiplied by the number of people on the survey team. § = Subtidal area. 1 = Grindley (1985)3 . 2 = Whitfield et al. (1983)5 . 3 = Duvenage & Morant (1984)10 . 4 = Morant (1983)11 . ∗ Figure 3. Density of H. capensis observed in all transects, in transects of habitat types defined in Table 1, and in different densities of vegetation. Values are mean ± bootstrapped 95% confidence intervals of the mean. No transects were dominated by H. ovalis. estimate of approximately 89 000 seahorses, with a bootstrapped (Efron & LePage 1992, Efron & Tibshirani 1993) 95% confidence interval of 30 000– 148 000 animals. The mean density of seahorses observed on the focal study grid over all days was 0.22 m−2 , but density ranged from 0.04 to 0.46 m−2 . Mature animals accounted for 93% of the observed population in the transects (with just three juveniles) and all of the seahorses on the focal study grid. Significantly more males than females were observed during the transect surveys (χ 2 = 7.05, n = 41, p = 0.008; Table 3). However, no sex ratio bias was found Figure 4. Relationship between seahorse density and total vegetation cover in the 82 transects. Each open circle represents one transect. among the seahorses on the focal study grid (χ 2 = 0.099, n = 91, p = 0.753; Table 3). Habitat occupancy Seahorse density in the transects was not significantly correlated with percent cover of Z. capensis, Caulerpa filiformis, H. ovalis, total vegetation cover, depth, or T. warreni density (Spearman rank order correlation: rs < 0.144, n = 82, p > 0.200 for all habitat parameters; Figure 4). However, when we broke vegetation density into categories we found that H. capensis were most commonly associated with relatively sparse (i.e. ≤20% cover) vegetation (Figures 3 and 4): such habitats accounted for only 60% of the area surveyed 41 but contained 82% of the seahorses we observed (χ 2 = 8.27, n = 44; p = 0.004). A holdfast choice was available in all of the 18 transects in which seahorses were observed. However, H. capensis were most likely to be found grasping Z. capensis holdfasts (χ 2 > 10.0, n = 41, p < 0.001). Zostera capensis accounted for 51% of available holdfasts, but 76% of seahorses were found grasping this seagrass. Spatial behaviour A total of 62% (57 of 91) of the seahorses on the focal study grid were resighted after tagging, on 1–5 subsequent days during the 10 days that we monitored them. Total fixes per resighted animal ranged from 2 to 6 (mean = 3.8 ± 1.1 fixes), with the last resighting a mean of 6.8 ± 3.7 days after tagging. Male and female H. capensis were resighted with approximately equal frequency (t29 = 0.466, p = 0.645). Movement patterns were analysed only for the 31 seahorses for which we had at least three fixes. We found no difference between the sizes of the areas over which males and females were resighted (t29 = 0.078, p = 0.938; Table 4), or the length of these areas (t29 = 0.976, p = 0.337; Table 4). Social behaviour H. capensis seahorses in the Knysna Estuary were reproductively active, with 77% of all males brooding embryos at some point during the study: this included 62% of the males (n = 18) in the transects and 86% of the males (n = 38) on the focal study grid. However, we observed no apparent greeting or courtship behaviours. No obvious social groupings were noticed during our research. The maximum number of seahorses present on the focal study grid on any one day was 46, a density of 0.46 m−2 , on 24 March 2000 (Figure 5). The mean known distance to the nearest neighbour was 61±35 cm (n = 43 seahorses), with a range of 0 to 143 cm. The nearest neighbour was equally likely to be of the same or the opposite sex (χ 2 = 0.37, p = 0.542). We noted a total of 21 occurrences of two neighbouring animals less than 50 cm apart from one other, the distance at which they could be assumed to be aware of one another in a similar seagrass habitat with low-horizontal visibility (Vincent & Sadler 1995): none were male–male combinations. Only 10 of these pairs of two animals were close enough (two mean body lengths; approximately 33 cm) that physical contact might have been possible. Most (60%) included one member of each sex, while the rest included two females. Sexual dimorphism Males were longer than females on the focal study grid (t86 = 1.86, p = 0.067), and had longer tails (t86 = 3.05, p = 0.003; Figure 6a) and shorter heads (t86 = 2.37, p = 0.020) than females, although trunk lengths were not different (t86 = 1.18, p = 0.241). When we controlled for standard length by including it as a covariate in an ANCOVA, small females on the focal study grid had proportionately shorter trunks (sex– standard length interaction: F1,84 = 6.83, p = 0.011; Figure 6b) and longer tails (sex–standard length interaction: F1,84 = 5.60, p = 0.020) than similar-sized males, while large females had proportionately longer Table 4. Minimum Convex Polygon areas of resighting, and their lengths, on the focal study grid. Females MCP area of resighting (n = 16) Mean 2.0 m2 SE 0.4 m2 Range 0.1–11.8 m2 Length of area of resighting (n = 15) Mean 3.3 m SE 0.2 m Range 1.5–6.5 m Males 1.5 m2 0.4 m2 0.2–6.2 m2 3.0 m 0.5 m 0.8–7.5 m Figure 5. Seahorse positions on the focal study grid on 24 March 2000. Open diamonds = females; filled squares = males; filled diamond = two females; open circle = one male and one female. 42 Figure 6. Seahorse morphometrics for the focal study grid: (a) mean (±95% confidence interval) standard length (diamonds), trunk length (circles), tail length (triangles), and head length (squares) for males (open symbols) and females (filled symbols). ∗ indicates a significant difference between males and females; (b) trunk (circles) and tail (triangles) lengths as a function of standard length, for males and females. The lines are regressions for each sex, and the slopes differ significantly between the sexes for each metric. trunks and shorter tails. There were not enough animals in the transect study to conduct a proper dimorphism analysis. Seahorse colour and adornment did not differ clearly by sex, but 87% of males observed throughout the estuary were darkly coloured (black, brown, grey, green) as compared with 61% of females. In addition, all black seahorses were males (n = 7) and all orange or white seahorses were females (n = 10). Dark spots or mottling were observed on 43% of individuals and 39% had skin filaments while the rest were smooth. Filaments were generally found dorsally and measured 0.5–5.0 mm long (mean = 2.2 ± 1.0 mm, n = 130). Discussion Population parameters This first published field study of H. capensis abundance and distribution takes on particular importance because the species’ entire area of occupancy probably measures less than 50 km2 (Lockyear 1999,1 Hilton-Taylor 2000). Our brief surveys found H. capensis in only the Knysna and Swartvlei estuaries, with the former having by far the larger population. Few person hours were spent outside the Knysna, however, and heavy rains led to very poor visibility in the Groot Brak and Klein Brak estuaries. Our population estimate of 89 000 adult H. capensis in the Knysna Estuary is higher than the 23 000 derived from a very limited seine net survey (Hanekom & Russell 19916 ), and must be used very tentatively. Further investigations (including markrecapture studies) are urgently needed in the Knysna and surrounding estuaries in order to obtain a more reliable estimate. Our transects were randomly stratified throughout the estuary but covered only a small proportion of the total area. We found seahorses in only 22% of the 82 transects. The habitat preferences we report in this paper should allow future assessments to stratify sampling by vegetation cover and estimate population abundance more precisely based on the proportion of ‘preferred’ habitat available. The mean density of H. capensis on our densely populated focal study grid (mean density = 0.22 m−2 ) was roughly the same as densities of unexploited Australian temperate seahorse species on similar study grids (0.080–0.215 m−2 : Vincent et al. submitted manuscript14 ; 0.162 m−2 : M.-A. Moreau unpublished data) but higher than those for an exploited seahorse population on coral reefs (0.019 m−2 : Perante et al. 2002) or a temperate pipefish in seagrasses (0.02–0.10 m−2 : Bayer 1980). The dearth of juvenile H. capensis observed in the Knysna Estuary corroborates the findings of previous research, in which no seahorse smaller than 5.1 cm standard length was found (P. Joubert personal communication), and is typical of seahorse population assessments (see above studies, K. Martin-Smith, unpublished data). Very young H. capensis may be spending time in the plankton, at least initially: channel nets deployed to catch ichthyoplankton in the Swartvlei Estuary yielded a net movement of 4 091 post-larval, juvenile seahorses out of the estuary mouth in October 1986 and a net movement into the estuary of 250 in November 1986, over a 24-h period (Whitfield 1989a). Older juvenile H. capensis may subsequently use different habitats from adults, a behavioural pattern observed in other species. For example, H. comes juveniles were found predominantly in Sargassum whereas adults used coral and sponge holdfasts (Perante et al. 1998). Sex ratios appear variable in syngnathids. The preponderance of male H. capensis in our transect 14 Vincent, A.C.J., K.L. Evans & A.D. Marsden. Home range behaviour of the monogamous Australian seahorse, Hippocampus whitei. Anim. Behav., submitted manuscript. 43 surveys contrasted with findings for H. comes (Perante et al. 1998) and H. zosterae (Strawn 1958) and some populations of H. abdominalis (K. Martin-Smith unpublished data), where females outnumbered males. However, the lack of sex-ratio bias observed on our H. capensis focal study grid was consistent with comparable studies of H. whitei (Vincent & Sadler 1995) and H. breviceps (M.-A. Moreau unpublished data). In contrast, sex ratios of a pipefish, Corythoichthys haematopterus, were female biased in Japan (Matsumoto & Yanagisawa 2001). Habitat occupancy The dearth of correlations between the density of H. capensis and vegetation or depth in our transects runs contrary to previously-noted associations between H. capensis and Z. capensis (Skelton 1987,4 Whitfield et al. 1989, Whitfield 1995a). We did, however, find that H. capensis tended to use Z. capensis holdfasts preferentially, so it may be that previous work had focused on smaller-scale assessments. Other species of seahorses have been recognised as preferentially associating with particular seagrasses, such as the Australian H. whitei with Posidonia sp. (Middleton et al. 1984) or with mixed Posidonia australis and Z. capricorni (Vincent et al. submitted manuscript14 ). The basis for such habitat associations is not understood, and could be a matter of post-settlement choice, an outcome of settlement patterns based on other parameters, or differential mortality (Kramer et al. 1997). The high density of H. capensis observed in low density vegetation stands (≤20% total cover) is probably a genuine distribution pattern, given the slow and careful search we undertook in dense vegetation areas and the fact that we were able to discover seahorses in very dense vegetation in the Swartvlei Estuary. Prey abundance and opportunities for crypsis are usually considered to be greater in denser vegetation (Bell & Westoby 1986, Ansari et al. 1991) but water exchange and some feeding opportunities may be greater in less dense vegetation. Other seahorse species are certainly also found in sparse vegetation for at least some activities (M.-A. Moreau unpublished data, Vincent & Sadler 1995), while some are found on bare soft bottoms (K. Martin-Smith unpublished data). H. capensis is also reported to sometimes rest on bare sediment or in shrimp burrows (N. Grange personal communication). Spatial and social behaviour Most seahorses in our study exhibited some spatial fidelity to an area, with nearly two-thirds resighted at least once after tagging and within 7 days of their first sighting. Since tagged seahorses were not resighted every day, they probably ranged beyond the perimeter of our 100 m2 focal study grid. Our focal study was too brief and small-scale to determine whether H. capensis maintained small home ranges as some species do (Perante et al. 2002, Vincent et al. submitted manuscript,14 J. Anticamara unpublished data), or ranged more widely as in others (J. Curtis unpublished data, K. Martin-Smith unpublished data). A large proportion of H. capensis in the Knysna Estuary were reproductively active. H. capensis has been reported to breed in the austral summer when water temperatures approach 20◦ C (Whitfield 1995a, Grange & Cretchley 1995, Fourie 1997, P. Joubert personal communication), which would put our study near the end of the season, consistent with the lack of observed courtship behaviours. There is, however, some evidence of breeding in the wild throughout the year (J.-.P. Arabonis personal communication) and that breeding season can be extended in captivity with photo-thermal manipulation (Lockyear et al. 1997). The lack of observed male–male encounters will need to be investigated further in light of research on other seahorse species showing that males compete more actively than females for access to mates (Vincent 1994, Masonjones & Lewis 1996) and earlier evidence of male competition in H. capensis (Fourie 1997). Sexual dimorphism The greater male standard length for H. capensis on the focal study grid is unusual in seahorses. A similar situation has been observed in H. spinosissimus and H. trimaculatus (J. Meeuwig unpublished data) but dimorphism was not found in studies on nine other species, although males frequently had longer tails than females and females had longer trunks than males (Vincent 1990, K. Martin-Smith unpublished data, M.-A. Moreau unpublished data). In general, longer male tails have been explained by their role in mate competition (males of some species wrestle with their tails: Vincent 1994), parental care (location of the brood pouch), and movement (anchoring the male with his heavy brood) (Vincent 1990, Vincent 1994, Fourie 1997). A similar situation is reported to 44 exist in the pipefish, Syngnathus typhle (Berglund et al. 1986). Conservation implications The majority of all known H. capensis are found in the Knysna Estuary, where the species’ apparent vulnerability to environmental change in parameters such as temperature (Russell 1994) is part of the reason for its IUCN Red Listing as Endangered (Hilton-Taylor 2000). This species is heterogeneously distributed, with seahorses in only 22% of transects and a disproportionately high concentration observed at the site chosen for our focal study grid. Development along the shores of the Knysna will need to proceed cautiously, with comprehensive and focused environmental impact assessments. Significant concentrations of H. capensis will require particularly careful management measures. In addition, it will be important to retain the low density (≤20% total cover) vegetation stands and Z. capensis holdfasts that appear to be the ‘preferred’ seahorse habitat in the Knysna Estuary. The Endangered status of H. capensis should preclude exploitation of these seahorses, whether wild or captive. Aquaculture ventures could pose significant threats to wild H. capensis: poor aquaculture practices often damage the marine environment and disrupt wild populations of the farmed species and others (Naylor et al. 2000). In particular, releases of captive-bred H. capensis could damage populations of wild seahorses by carrying disease, altering genetics and/or disrupting social and spatial behaviour (IUCN 1995). Any plans to culture H. capensis will need thorough environmental assessment. The threats to H. capensis are real. A closely related South African, estuarine pipefish species, Syngnathus watermeyeri, was considered to be a very rare example of an estuarine fish that had gone extinct (Groombridge 1993, Whitfield 1995b). It was re-discovered in 1995 in one estuary (East Kleinemonde), and there is a tiny remnant population in a second (Bushmans) (P. Cowley in litt.). Biologists moved 12 pipefish to the West Kleinemonde Estuary in 1997 and the population appears to be viable to this point in time (P. Cowley in litt., 19 November 2001, Cowley & Whitfield 2001). Releases must not, however, be contemplated in the case of H. capensis at present: supplementations and translocations carry so many risks (IUCN 1995) that they should only be considered if all other conservation approaches fail, as a last (and unreliable) resort. Substantially more research on the basic life history and ecology of H. capensis will help to secure its future and new approaches, such as molecular and genetic research, may be of use in clarifying the population structure and genotypic health of seahorse populations. The utility of any biological research will, however, depend on the value that decision-makers and stakeholders in the Knysna Estuary put on retaining healthy populations of this Endangered fish. Acknowledgements This is a contribution from Project Seahorse. The field study was funded by the John G. Shedd Aquarium, Chicago, U.S.A. A.D. Marsden was supported by Guylian Chocolates of Belgium. Project Seahorse gratefully acknowledges the help, enthusiasm and advice offered by many colleagues and supporters in South Africa. Particular thanks to P. Joubert, R. Milne and the entire South African National Parks staff in Knysna and Swartvlei for their logistic assistance and expertise; P. 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