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Record of Viminella flagellum (Alcyonacea: Ellisellidae) in Italian waters (Mediterranean Sea)

Published online by Cambridge University Press:  25 April 2012

M. Giusti ,
M. Bo ,
G. Bavestrello ,
M. Angiolillo ,
E. Salvati  and
S. Canese
M. Giusti*
Affiliation:
ISPRA (ex ICRAM), Via di Casalotti 300, 00166 Roma, Italy
M. Bo
Affiliation:
Dipartimento di Scienze del Mare, Università Politecnica delle Marche, 60131 Ancona, Italy
G. Bavestrello
Affiliation:
Dipartimento di Scienze del Mare, Università Politecnica delle Marche, 60131 Ancona, Italy
M. Angiolillo
Affiliation:
ISPRA (ex ICRAM), Via di Casalotti 300, 00166 Roma, Italy
E. Salvati
Affiliation:
ISPRA (ex ICRAM), Via di Casalotti 300, 00166 Roma, Italy
S. Canese
Affiliation:
ISPRA (ex ICRAM), Via di Casalotti 300, 00166 Roma, Italy
*
Correspondence should be addressed to: M. Giusti, ISPRA (ex ICRAM), Via di Casalotti 300, 00166 Roma, Italy e-mail: michela.giusti@isprambiente.it

Abstract

The occurrence of the whip coral Viminella flagellum in Italian waters (Strait of Sicily, Mediterranean Sea), is reported for the first time. The specimens were photographed and sampled at locations situated from 130 to 250 m depth on the north-eastern coasts of Pantelleria Island, by means of a remotely operated vehicle, during a research cruise carried out by ISPRA in May 2010 on-board of the RV ‘Astrea’. A description of the living colonies and other taxonomic characteristics is given. Our finding extends the known geographical distribution of this species in the Mediterranean Sea to the Strait of Sicily.

Keywords

Viminella flagellummesophotic zoneROV explorationbiogeographyPantelleria Island
Type
Research Article
Information
Marine Biodiversity Records , Volume 5 , August 2012 , e34
Copyright
Copyright © Marine Biological Association of the United Kingdom 2012

INTRODUCTION

Viminella flagellum (Johnson, 1863) (family Ellisellidae) is a whip-like gorgonian characterized by unbranched colonies up to 3 m high and has been only uncommonly observed with one or a few side branches (Carpine & Grasshoff, Reference Carpine and Grasshoff1975; Fabricius & Alderslade, Reference Fabricius and Alderslade2001; Grasshoff & Bargibant, Reference Grasshoff and Bargibant2001; Weinberg & Grasshoff, Reference Weinberg and Grasshoff2003). In the longest specimens the distal portion may be coiled, giving rise to a spiral structure that may detach generating young colonies (Grasshoff & Bargibant, Reference Grasshoff and Bargibant2001) as commonly observed for other whip alcyonaceans (Walker & Bull, Reference Walker and Bull1983).

Viminella flagellum is mainly diffused along the Eastern Atlantic coasts (Azores Islands, Cape Verde Islands, Canaries Islands, Madeira, Josephine Bank, Great Meteor Bank and Moroccan coast), where it may form dense meadows, especially over seamount plateaux, and may reach great depths (up to about 1000 m, but usually below 350 m) (Grasshoff, Reference Grasshoff1972; Carpine & Grasshoff, Reference Carpine and Grasshoff1975; Brito & Ocaña, Reference Brito and Ocaña2004).

This species, together with Ellisella paraplexauroides (Stiasny, 1936), are the only two Mediterranean components of the family Ellisellidae. The species was first recorded by Carpine & Grasshoff (Reference Carpine and Grasshoff1975) at 120 m depth off of western Corsica, and a dubious record exists from Naples (Simpson, Reference Simpson1910; Grasshoff, Reference Grasshoff1972). Several other records from the Alboran and Balearic Seas (Alboran Isle, Seco de los Olivos Seamount, Seco de Palos Seamount and Emile Baudot Seamount) were recently obtained through remotely operated vehicle (ROV) explorations conducted by Aguilar et al. (Reference Aguilar, Pastor and de Pablo2006) (Figure 1).

Fig. 1. Map of the geographical distribution of Viminella flagellum (black dots) in the Mediterranean Sea. Black triangle is the present record.

In these Mediterranean localities, the species was always recorded between 90 and 200 m depth, generally on rocky substrata arising from detritic bottoms. Viminella flagellum may form dense monospecific aggregations, but was also recorded in mixed assemblages with Callogorgia verticillata (Pallas, 1766), Eunicella verrucosa (Pallas, 1766) and several species of other sea fans, like Swiftia pallida Madsen, 1970, Paramuricea macrospina (Koch, 1882), and E. paraplexauroides (Aguilar et al., Reference Aguilar, Pastor and de Pablo2006). In the Atlantic, (Tenerife, Canary Islands) the species was described as occurring on detritic bottoms associated with C. verticillata, and on soft bathyal bottoms together with Isidella elongata (Esper, 1788) (Brito & Ocaña, Reference Brito and Ocaña2004). The specimens from Corsica were yellow-orange (Carpine & Grasshoff, Reference Carpine and Grasshoff1975), as those described on the Josephine Bank (Grasshoff, Reference Grasshoff1972), but those photographed through ROV explorations along the Spanish coasts, and in most of the Atlantic spots, were generally white (Grasshoff, Reference Grasshoff1972; Aguilar et al., Reference Aguilar, Pastor and de Pablo2006). Unlike the Atlantic specimens, the Mediterranean ones are usually less than 1 m high and characterized by a thinner basal diameter of the stem (Grasshoff, Reference Grasshoff1972; Carpine & Grasshoff, Reference Carpine and Grasshoff1975).

The majority of Mediterranean deep coral species have been described only on the basis of dredged specimens and fragments, therefore our knowledge concerning natural populations of these anthozoans is very limited (Bo et al., Reference Bo, Bavestrello, Canese, Giusti, Angiolillo, Cerrano, Salvati and Greco2011). The aim of this study is the description of a population of V. flagellum observed through ROV explorations in the coastal waters of Pantelleria Island (Strait of Sicily). Morphological data of the specimens are provided together with a description of their habitat and geographical distribution in the Mediterranean basin.

MATERIALS AND METHODS

Pantelleria Island is situated 85 km south-west of Sicily and represents the emerged top of a volcano situated in the centre of the Strait of Sicily rift zone (Civile et al., Reference Civile, Lodolo, Tortorici, Lanzafame and Brancolini2008). This feature, defined by deep troughs with bathymetric lows reaching depths of over 1300 m, is located in the part of the Strait of Sicily which is considered to represent the limit between the western and eastern Mediterranean Sea (Bianchi, Reference Bianchi2007). The study area, named Cala Caruscia, in the north-east side of Pantelleria (Figure 2), was explored through a ROV survey conducted in May 2010 on-board of the RV ‘Astrea’. The ROV was equipped with a digital camera (Nikon D80, 10 megapixel), an underwater strobe (Nikon SB 400), a high definition video camera (Sony HDR-HC7) and a 3 jaw grabber (SeaBotix Inc.) used for sample collection. The ROV was also equipped with a depth sensor, a compass, and three laser beams spaced 10 cm apart, to form an equilateral triangle, used as reference scale to assist the observers in estimating frame area and the size (height and width) of the photographed samples. Photographic and direct samplings were carried out in the mesophotic zone, between 130 and 250 m depth. Photographs were analysed to describe the general morphology of the whip coral colonies and their in vivo appearance. Gorgonian sclerites were analysed at SEM after dissolving the coenenchyme in sodium hypochlorite. A fragment fixed in 95° ethanol was used for the morphological analysis of polyps carried out with SEM and stereomicroscope.

Fig. 2. Map of the sampling area (black dot). In the inset are shown the remotely operated vehicle tracks.

RESULTS

The two ROV tracks carried out in the study area (Figure 2 inset, A & B) (845 m and 620 m long, respectively) covered a surface of approximately 4600 m2. The explored area is characterized by inclined rocky walls extending up to approximately 200 m depth, after which the bottom turns into heavily silted rocky boulders ending into a gently inclined soft bottom slope.

In total, 10 colonies of V. flagellum were observed sparsely occurring on the rocky bottom (Figure 3A–D). Specimens, characterized by a white-orange colour, were found at depths ranging between 156 and 242 m and inside a community mainly composed of a mixed assemblage of V. flagellum, Swiftia pallida (Figure 3A) and other undetermined small gorgonians. Encrusting sponges and ascidians were the only other components of the benthic assemblage, strongly influenced by the sediment deposition.

Fig. 3. Viminella flagellum from Pantelleria. A–D. Underwater photographs of V. flagellum. Sparse single stem white colonies living on rocky bottoms. Occasionally (Figure C), colonies may be ramified. The sea bottom host few other species, for example colonies of Swiftia pallida (Figure A, yellow colonies indicated by arrows); (E) collected specimen; (F) expanded polyps of a living colony; (G–H) SEM and stereomicroscope photographs of the arrangement of calyces on the apical portion of the stem; (I) Close-up view of calyces; (J) sclerites of V. flagellum composed of: a. double head from the superficial layer of coenenchyme; b. thick capstan; c. slender capstan; d, e. blunt spindle and deformed double-head from the deeper layer of the coenenchyme and from calyces; f. rod from the pharynx. Scale bar: A–D: 10 cm, E: 5 cm, F: 5 mm, G–I 1 mm.

The colonies' height ranged from 2 to 79 cm (on average 41.2 ± 8.0 cm) and their basal diameter was approximately 2–3 mm. Most of them were unbranched with only 3 specimens bearing one or two branches (Figure 3C). The length of the branches varied between 2 and 20 cm (on average 7.4 ± 3.5) and the distance from the base to the first ramification ranged from 1 to 30 cm (on average 14.0 ± 6.0 cm). No epibionts were recorded on the colonies.

During the ROV survey, a sample of 49 cm length, was collected from an unbranched colony 79 cm high (Figure 3A, E). The observed polyps were monomorphic and highly contractile. Underwater images indicate the presence of extended polyps characterized by tentacles almost of the same length of calyces (Figure 3F). In the studied apical portion, polyps were arranged in two longitudinal opposite rows (Figure 3F–H). Commonly, calyces may show different inclinations with respect to the main stem (Figure 3H). In the most basal portions of the colony instead, the photographs indicate the presence of multiple rows of calyces extending almost perpendicularly from the stem, a feature previously described by other authors (Carpine & Grasshoff, Reference Carpine and Grasshoff1975). Calyces (up to 1.5 mm high) (Figure 3I) were characterized by thick walls and upon contraction, the polyps formed knobs on the surface of the branches.

Sclerites were colourless, highly tuberculated and can be described as belonging to various types (Figure 3J): symmetrical double heads (up to 55 µm high) that are densely packed on the surface of the coenenchyme (Figure 3Ja), slightly elongated double heads, capstans, and spindles (between 60 and 80 µm high) that are organized in the subsurface of the coenenchyme and in the wall of calyces (Figure 3Jb–e), and 60 µm high rods occurring on the pharynx of the anthocodiae (Figure 3Jf). The size of the observed sclerites was slightly smaller than that reported for Atlantic species (Carpine & Grasshoff, Reference Carpine and Grasshoff1975).

DISCUSSION

Viminella flagellum is an Atlantic–Mediterranean species living in temperate and subtropical waters. Until now, with the exception of a record on the western coast of Corsica, knowledge about the species' occurrence in the Mediterranean Sea was limited to the immediate surroundings of the Gibraltar Strait (Alboran Isle, Seco de los Olivos and Seco de Palos) and the Balearic Sea (Marion Boudet Seamount). The present record, occurring on the norhth-eastern coast of Pantelleria Island, in the Strait of Sicily, is the most eastern record of the species in the Mediterranean, and represents the first observation of the species in Italian waters thereby increasing the number of recorded anthozoan alcyonacean species in Italian waters (Morri et al., Reference Morri, Esposito and Pessani2008) to 26. Moreover, this record extends to about 250 m the bathymetric distribution limit of the species in the Mediterranean basin.

Unlike previously described specimens, the Pantelleria colonies are characterized by a limited height extension and by a thin basal diameter. The highest and thickest specimens ever described were found on the Meteor Bank (Grasshoff, Reference Grasshoff1972), and were about 4 times the length and 3 times the thickness of the presently described colonies. It is known that highly energetic environments, such as seamounts, often host very dense whip coral meadows (Genin et al., Reference Genin, Dayton, Lonsdale and Spiess1986), since these organisms are the best adapted to turbulent conditions, due also to their thick basal stem.

Almost no data are available on the population structure of the meadows of V. flagellum, Grasshoff (Reference Grasshoff1972) reported a patchy distribution with densely colonized rocky areas alternated with non-colonized sandy zones. The images reported by Aguilar et al. (Reference Aguilar, Pastor and de Pablo2006) indicate very dense meadows in the Mediterranean populations. In the studied area of Pantelleria, colonies show a sparse distribution and no traces of aggregations are observed probably in relation to a low food availability of the area.

The predominant Mediterranean water circulation explains the gradual colonization of the southern coasts of the basin by Atlantic species entering the Strait of Gibraltar. In particular, the recorded distribution of the studied species seems related to different branches of the incoming Atlantic waters flowing from the Strait of Gibraltar along the Algerian coast towards the Strait of Sicily. It is also to be noted that the southern side of the Balearic Archipelago (where, recently, populations of V. flagellum were discovered) is influenced, during summer, by a superficial input of Atlantic waters through eddies that stem from the main Algerian current (Bianchi, Reference Bianchi2007).

The Strait of Sicily represents, from a geomorphologic and oceanographic point of view, an important boundary area, where species are known to be subjected to great selective pressures (Bianchi & Morri, Reference Bianchi and Morri2000; Pinardi & Masetti, Reference Pinardi and Masetti2000; Bianchi et al., Reference Bianchi, Boero, Fraschetti, Morri, Argano, Chemini, La Posta, Minelli and Ruffo2002; Bianchi, Reference Bianchi2007).

The presence of V. flagellum in both the Strait of Sicily and the Balearic Islands may be explained also by some common environmental and oceanographic features of these two areas. Both are characterized by an intense geostrophic circulation of water masses and by a complex topography, that, due to the presence of islands and seamounts, generate mesoscale eddies and convergent fronts (López-Jurado et al., Reference López-Jurado, Garcia Lafuente and Cano1995; Pinot et al., Reference Pinot, Tintoré, López-Jurado, Fernández de Puelles and Jansá1995; Vélez-Belchí & Tintoré, Reference Vélez-Belchí and Tintoré2001; García et al., Reference García, Alemany, Vélez-Belchí, López Jurado, Cortés, de la Serna, González Pola, Rodríguez, Jansá and Ramírez2003; Oray et al., Reference Oray, Karakulak, Garcia, Piccinetti, Rollandi and de la Serna2005; Alemany et al., Reference Alemany, Deudero, Morales-Nin, Lopez-Jurado, Jansa, Palmer and Palomera2006). The peculiar ocean circulation patterns found in these areas are at the base of a high biological productivity, thereby contributing to the presence of biodiversity hotspots (Greenpeace International, 2009). The anthropogenic threats exerted on these vulnerable habitats and species gives to these areas high priority for inclusion in any future comprehensive and fully representative network of marine protected areas for the Mediterranean basin.

ACKOWLEDGEMENTS

We thank the crew members of RV ‘Astrea’ for their precious help and work during field operations, our colleague Dr Giulia Mo and two anonymous referees whose comments helped to improve the paper. This work was financed by Italian Ministry of the Environment, Land and Sea protection.

References

REFERENCES

Aguilar, R., Pastor, X. and de Pablo, M.J. (2006) Habitats in danger. Oceana: Fundación Biodiversidad.Google Scholar
Alemany, F., Deudero, S., Morales-Nin, B., Lopez-Jurado, J.L., Jansa, J., Palmer, M. and Palomera, I. (2006) Influence of physical environmental factors on the composition and horizontal distribution of summer larval fish assemblages off Mallorca Island (Balearic archipelago, Western Mediterranean). Journal of Plankton Research, 28, 473487.CrossRefGoogle Scholar
Bianchi, C.N. (2007) Biodiversity issues for the forthcoming tropical Mediterranean Sea. Hydrobiologia, 580, 721.Google Scholar
Bianchi, C.N., Boero, F., Fraschetti, S. and Morri, C. (2002) La fauna del Mediterraneo. In Argano, R., Chemini, G., La Posta, S., Minelli, A. and Ruffo, S. (eds), La fauna in Italia. Touring Club Italiano, Milan and Ministero dell'Ambiente e della Tutela del Territorio, Rome, pp. 247335.Google Scholar
Bianchi, C.N. and Morri, C. (2000) Marine biodiversity of the Mediterranean Sea: situation, problems and prospects for future research. Marine Pollution Bulletin, 40, 367376.Google Scholar
Bo, M., Bavestrello, G., Canese, S., Giusti, M., Angiolillo, M., Cerrano, C., Salvati, E. and Greco, S. (2011) Coral assemblages off the Calabrian Coast (South Italy) with new observations on living colonies of Antipathes dichotoma. Italian Journal of Zoology 10.1080/11250001003652619.CrossRefGoogle Scholar
Brito, A. and Ocaña, O. (2004) Corales de las Islas Canarias. La Laguna. Antozoos con esqueleto de los fondos litorales y profundos. Francisco Lemus Editor.Google Scholar
Carpine, C. and Grasshoff, M. (1975) Les gorgonaires de la Méditerranée. Bulletin de l'Institut Océanographique 71, 1140.Google Scholar
Civile, D., Lodolo, E., Tortorici, L., Lanzafame, G. and Brancolini, G. (2008) Relationships between magmatism and tectonics in a continental rift: the Pantelleria Island region (Sicily Channel, Italy). Marine Geology 251, 3246.Google Scholar
Fabricius, K. and Alderslade, P. (2001) Soft corals and sea fans: a comprehensive guide to the tropical shallow water genera of the central-west Pacific, the Indian Ocean and the Red Sea. Townsville, QL: Australian Institute of Marine Science.Google Scholar
García, A., Alemany, F., Vélez-Belchí, P., López Jurado, J.L., Cortés, D., de la Serna, J.M., González Pola, C., Rodríguez, J.M., Jansá, J. and Ramírez, T. (2003) Characterization of the bluefin tuna spawning habitat off the Balearic Archipelago in relation to key hydrographic features and associated environmental conditions. Collective Volume of Scientific Papers ICCAT 58, 535549.Google Scholar
Genin, A., Dayton, P.K., Lonsdale, P.F. and Spiess, F.N. (1986) Corals on seamount peaks provide evidence of current acceleration over deep-sea topography. Nature, 322, 5961.Google Scholar
Grasshoff, M. (1972) Die Gorgonaria des östlichen Nordatlantik und des Mittelmeeres. I. Die Familie Ellisellidae (Cnidaria: Anthozoa). Meteor Forschungsergen-Ergebnisse (D) 10, 7387.Google Scholar
Grasshoff, M. and Bargibant, G. (2001) Coral reef gorgonians of New Caledonia. Paris: IRD Éditions.Google Scholar
Greenpeace International (2009) High Seas Mediterranean Marine Reserves: a case study for the Southern Balearics and the Sicilian Channel. CBD's Expert workshop on scientific and technical guidance on the use of biogeographic classification systems and identification of marine areas beyond national jurisdiction in need of protection. Ottawa, September–October, 2009.Google Scholar
López-Jurado, J.L., Garcia Lafuente, J. and Cano, N. (1995) Hydrographic conditions of the Ibiza Channel during November 1990, March 1991, July 1992. Oceanologica Acta 18, 235243.Google Scholar
Morri, C., Esposito, F. and Pessani, D. (2008) Anthozoa. Checklist della flora e della fauna dei mari italiani (Parte I). Biologia Marina Mediterranea 15, 92101.Google Scholar
Oray, I., Karakulak, S., Garcia, A., Piccinetti, C., Rollandi, L., and de la Serna, J.M. (2005) Report on the Mediterranean BYP tuna larval meeting. SCRS/2004/189 Collection Volume of the Scientific Papers ICCAT 58, 14291435.Google Scholar
Pinardi, N. and Masetti, E. (2000) Variability of the large-scale general circulation of the and Mediterranean Sea from observations and modelling: a review. Palaeogeography, Palaeoclimatology, Palaeoecology 158, 153173.Google Scholar
Pinot, J.M., Tintoré, J., López-Jurado, J.L., Fernández de Puelles, M. L. and Jansá, J. (1995) Three-dimensional circulation of a mesoscale eddy/front system and its biological implications. Oceanologica Acta 18, 389400.Google Scholar
Simpson, J.J. (1910) VII. A revision of the Gorgonellidae: 1. The Juncellid group. Proceedings of the Royal Irish Academy 28, 247386.Google Scholar
Vélez-Belchí, P. and Tintoré, J. (2001) Vertical velocities at an ocean front. Scientia Marina 65 (Supplement 1), 291300.CrossRefGoogle Scholar
Walker, T.A. and Bull, G.D. (1983) A newly discovered method of reproduction in gorgonian coral. Marine Ecology Progress Series 12, 137143.Google Scholar
Weinberg, S. and Grasshoff, M. (2003) Gorgonias. El Mar Mediterraneo. Fauna, Flora, Ecologia. II/1. Guia Sistematica y de Identificacion. Ediciones Omega.Google Scholar
Figure 0

Fig. 1. Map of the geographical distribution of Viminella flagellum (black dots) in the Mediterranean Sea. Black triangle is the present record.

Figure 1

Fig. 2. Map of the sampling area (black dot). In the inset are shown the remotely operated vehicle tracks.

Figure 2

Fig. 3. Viminella flagellum from Pantelleria. A–D. Underwater photographs of V. flagellum. Sparse single stem white colonies living on rocky bottoms. Occasionally (Figure C), colonies may be ramified. The sea bottom host few other species, for example colonies of Swiftia pallida (Figure A, yellow colonies indicated by arrows); (E) collected specimen; (F) expanded polyps of a living colony; (G–H) SEM and stereomicroscope photographs of the arrangement of calyces on the apical portion of the stem; (I) Close-up view of calyces; (J) sclerites of V. flagellum composed of: a. double head from the superficial layer of coenenchyme; b. thick capstan; c. slender capstan; d, e. blunt spindle and deformed double-head from the deeper layer of the coenenchyme and from calyces; f. rod from the pharynx. Scale bar: A–D: 10 cm, E: 5 cm, F: 5 mm, G–I 1 mm.