The surface morphology of the ctenidia of Spondylus spinosus (Mollusca: Bivalvia) from Antalya Bay, Turkey

Aksit, Deniz; Mutaf, Beria Falakali; Balci, Ahmet

doi:10.1590/S1984-46702013000100008

Abstract

The surface morphology of the ctenidia of Spondylus spinosus Schreibers, 1793 was studied with light and scanning electron microscopy for comparison with the gill structures of other bivalves. The demibranch of S. spinosus is heterorhabdic, with the principal filaments at the descending lamellae and ordinary filaments at the ascending lamellae. The gill lamellae have a prominent gauze-like structure at their distal part, with numerous groups of eight ordinary filaments. They bear ciliary arrays on their frontal surfaces and ostia at their latero-frontal surfaces. Frequent cirral plates form regular interfilamentary junctions. The description of the gill structure of S. spinosus presented here can be used to derive implications for the correlations among the structure, habitat and mode of life of this species. At a particular stage of its adult life, Spondylus spinosus could be used as a subject for biomonitoring studies in natural and experimental environments.

Ciliary structures; ctenidia; morphology; scanning electron microscopy (SEM); spiny oyster

MORPHOLOGY AND PHYSIOLOGY

The surface morphology of the ctenidia of Spondylus spinosus (Mollusca: Bivalvia) from Antalya Bay, Turkey

Deniz Aksit^* * Corresponding author. E-mail: denizaksit@akdeniz.edu.tr ; Beria Falakali Mutaf; Ahmet Balci

Akdeniz University, Faculty of Aquatic Sciences and Fisheries, Antalya, Turkey

ABSTRACT

The surface morphology of the ctenidia of Spondylus spinosus Schreibers, 1793 was studied with light and scanning electron microscopy for comparison with the gill structures of other bivalves. The demibranch of S. spinosus is heterorhabdic, with the principal filaments at the descending lamellae and ordinary filaments at the ascending lamellae. The gill lamellae have a prominent gauze-like structure at their distal part, with numerous groups of eight ordinary filaments. They bear ciliary arrays on their frontal surfaces and ostia at their latero-frontal surfaces. Frequent cirral plates form regular interfilamentary junctions. The description of the gill structure of S. spinosus presented here can be used to derive implications for the correlations among the structure, habitat and mode of life of this species. At a particular stage of its adult life, Spondylus spinosus could be used as a subject for biomonitoring studies in natural and experimental environments.

Key words: Ciliary structures; ctenidia; morphology; scanning electron microscopy (SEM); spiny oyster.

Species of Spondylus Linnaeus, 1758, also known as spiny oysters, are the only bivalve molluscs of the family Spondylidae Gray, 1826. Spondylus spinosus Schreibers, 1793 is highly abundant on Mediterranean shores (ZENETOS et al. 2003), a habitat where these bivalves live attached to rocky substrates. As a result of evolutionary processes, the gills of Spondylus spp. perform many functions, collecting food particles and facilitating the dispersal of gametes in addition to their role in respiration, which includes establishing a water current in the mantle cavity as part of the circulatory system (GOSLING 2003). In brief, the gills consist of two ctenidia, each containing two demibranchs; each V-shaped demibranch has inner and outer components consisting of two lamellae with or without marginal grooves at their free end (GOSLING 2003).

The use of bivalve mollusks to assess national marine resources and their biological status has been the subject of many extensive studies (DOMOUHTSIDOU & DIMITRIADIS 2000, DAVID & FONTANETTI 2005, USHEVA et al. 2006). In species of Bivalvia, the gills and digestive glands are the first organs exposed to water and its pollutants (DOMOUHTSIDOU & DIMITRIADIS 2000). Despite the abundance of the genus in tropical and subtropical seawaters worldwide, very little is known about the basic biology and ecology of Spondylus spp. Although, some research on the reproductive biology of several species has been performed (VILLALEJO-FUERTE et al. 2002), very little information is available on the morphology of the organs of this bivalve (YOUNGE 1973).

The main purpose of this study was to use light and scanning electron microscopy to provide detailed information on the structure of the gill filaments of S. spinosus, as we believe that an understanding of this structure will serve as a tool of fundamental importance in biomonitoring studies.

MATERIAL AND METHODS

Spondylus spinosus individuals were collected from the littoral zone of the rocky shores of Antalya Bay (between 36°36'25.22"-36°53'04.26"N and 30°42'03.62"-31°46'31.30"E) on the southwestern coast of Turkey, a site where dense aggregations were found attached to the substrate. The individuals were extracted from rocks that were detached from the substrate by breakage using special sledgehammers during scuba diving excursions. All of the specimens were transported to the laboratory at the Faculty of Aquatic Sciences and Fisheries at Akdeniz University. Four specimens were washed, opened by breaking their shells and washed again in sea water.

The general morphology of the ctenidia of all the individuals was observed using stereo-light microscopy (LM). Undamaged areas of the gills were excised, and the dissected specimens were examined by LM and scanning electron microscopy (SEM). The gill lamellae were fixed in Bouin's solution for LM and in 2.5% glutaraldehyde in Sorensen's buffer (0.1 M, pH 7.3) for SEM. For LM, the specimens were cleared in xylene after rinsing in a graded-ethanol series and embedded in wax. Sections of 4-7 µm were stained with haematoxylin and eosin (H-E) (DRURY & WALLINGTON 1973). For SEM, the dehydrated and air-dried lamellae were mounted flat on aluminium stubs and coated with gold-palladium (AKSIT & FALAKALI MUTAF 2011). We examined the lamellar morphology using a Zeiss Leo 1430 Scanning Electron Microscope at the Akdeniz University Medical School EM Unit (TEMGA).

The following abbreviations are used in this report: (Af.bv) afferent blood vessel, (al) ascending lamella, (C.a) ctenidial axis, (cd) ciliary disc, (ce) ciliary epithelium, (dl) descending lamella, (Ef.bv.) efferent blood vessel, (H-E) haematoxylin and eosin, (mg) marginal gutter, (nce) non-ciliated epithelium, (of) ordinary filaments, (pf) principal filaments, (wt) water tubule, (lf) latero-frontal cilia, (fc) frontal cilia, (◄) ostia.

RESULTS

The ctenidia of S. spinosus represent the second largest gross anatomical structure of the visceral parts (Fig. 1), exceeded in size only by the single adductor muscle. Each of the ctenidia of S. spinosus is formed by two V-shaped demibranchs attached to a thick ctenidial axis, with the ascending lamella one-third shorter in length than the descending lamella (Fig. 2). The branchial haemolymph vessel was prominent (Fig. 3). There was no marginal food groove at the free distal end.

The filaments presented different appearances on the frontal surfaces of the ascending (al) and descending (dl) lamellae. The descending lamellae were thicker than the ascending, and the ascending lamellae differed from the descending by the presence of minor lamellar subunits and transparent water tubules (Fig. 3). The filaments of this fillibranch gill were heterorhabdic in appearance (Figs 1-6).

On the descending lamella, thick principal filaments were present, consisting of two different components: a straight outer part and spirally wound cord-like inner pieces (Figs 4-6). The straight branch was covered with a thick ciliary sheet, and the wound portion contained more than two pieced folds, which appeared to fold backwards, assuming a thick pocket-like appearance (Fig. 6). No interlamellar junctions were observed.

Ordinary filaments were the only components of the ascending lamellae located at the ventral part of each demibranch. Eight ordinary filaments formed the continuation of every principal filament formed by branching at the lower part of the demibranch. The ordinary filaments, resembling translucent channels, extended parallel and caused a fan-like expansion (Figs 6 and 7). Many ordinary filaments formed a group, and numerous groups were found in the terminal portion of the dorsal region with a flattened undulating edge, which was shaped into a marginal gutter by outwards folding.

Frequent ciliary discs connected each of the eight ordinary filaments to each other at regular intervals and extended in two directions (Figs 7 and 8). These interfilamentary connections showed a complex structure (Figs 9-11), with each connective disc consisting either of 5-7 cirral or microvillar plates, interlocked at the top with each other (Fig. 11). Their location on the surface epithelium was clearly visible under light and electron microscopy (Figs 8-11).

The frontal surface of the ordinary filaments showed a uniform array of cilia characterized by ciliary rootlets, whereas the abfrontal surfaces were covered with a non-ciliated epithelium consisting of microvilli (Figs 12 and 13). The latter cells were characterized by large nuclei. A frontal view of the ordinary filaments showed abundant ciliary cover. The composite microcilia with an elongated latero-frontal array were clearly evident when the filaments were inflated and expanded into the interfilamentary spaces (Fig. 14). No ciliar differentiation was detected. All the cilia appeared to be simple cilia. Next to the ciliary band, an irregular number of ostia were observed on the lateral surfaces (Fig. 15). No mucus strings or layers or any lesional morphology that could be associated with environmental stress were observed in any part of the gill lamellae.

DISCUSSION

Light microscopy revealed that the general structure of the gills in S. spinosus was similar, in part, to that described for other bivalves, such as Mytilidae and Pectinidae (BENNINGER & ST JEAN 1997, GREGORY & GEORGE 2000, BENNINGER & DECOTTIGNES 2008). In brief, the ctenidia of Spondylus spp. were described as Pecten type (Type B1b), without a marginal groove (ATKINS 1937a,b). The general morphology observed in the present study was in accordance with previous descriptions. However, the ascending lamella of S. spinosus was found to be two-thirds the size of the descending lamella, which is shorter than that described for S. americanus (YOUNGE 1973).

In many bivalve species, ciliation covers both the frontal surface and the lateral surfaces of the gill, and scattered cilia were described on the abfrontal surface of the ordinary filaments (DUFOUR & BENINGER 2001, DAVID & FONTANETTI 2005). Only the frontal surface showed a ciliary cover on the ordinary filaments of the gills of S. spinosus. AIELLO & SLEIGH (1972) suggested that the absence of ciliation provided a space for the eu-latero-frontal cilia to perform their movement, particularly in Mytilus edulis Linnaeus, 1758, whereas others have suggested that the lack of ciliation served to increase the surface available for the absorptive cells to obtain materials from the environment, as in Mytella falcata (Orbigny, 1846) (DAVID et al. 2008). Retention of the food particles in filter-feeding bivalves is performed either by the beating of cilia or the muscular control of ostia (GOSLING 2003). Spondylus spinosus appears to employ both mechanisms, exhibiting a sieve in many ostia next to the ciliary array. Oralwards currents could occur primarily in the dorsal channels, as described by YONGE (1973), and the prominent marginal gutter in S. spinosus could be proposed as an effective channel for particle movement because no marginal groove exists.

The regular distribution of ciliary junctions was similar to that found in certain species of Mytilidae, such as Perna perna Linnaeus, 1758 and M. falcata (GREGORY & GEORGE 2000, DAVID & FONTANETTI 2005), but several differences were also noted. The ciliary discs were located on either side of the ordinary filaments and extended laterally at eight filament intervals in Spondylus spinosus. The ciliary discs contained a smaller number of cirral plates and were, therefore, much more complex than those reported to occur in certain mytilid and pectinid species, such as M. falcata (DAVID & FONTANETTI 2005), Modiolus barbatus Linnaeus, 1758 (FALAKALI MUTAF et al. 2009) and Placopecten magellanicus (Gmelin, 1791) (MORSE & ZARDUS 1997), species in which only a single ciliary plate forms the disc. The distribution of the ciliary discs appears to serve predominantly to protect the filaments from hydrodynamic forces and to regulate the flow of water through the interfilamentary spaces, thus facilitating currents in the lower part of the demibranch in addition to those occurring in the dorsal channels.

Bivalve mollusks have been considered for monitoring aquatic habitats in many countries of the Northern and Southern Hemispheres, particularly well-settled species and those described as sentinel organisms in cases of pollution (GREGORY et al. 2002). In Turkey, only a few pilot projects of this nature have been conducted to establish a local assessment programme for marine pollution or to contribute to international surveys based on the study of sedentary species, such as S. spinosus. Indeed, gill morphology has been extensively used as an indicator organ of pollution (DOMOUHTSIDOU & DIMITRIADIS 2000, GREGORY & GEORGE 2000, DAVID & FONTANETTI 2005, KOEHLER et al. 2008).

The results presented here provide data on the general structure of the gills of S. spinosus, with no pollution effect, for comparison in histopathological studies. Although increased mucus production on gill surfaces has been suggested to result from the accumulation of metallic or microorganismal pollutants (GREGORY et al. 2002, AKSIT et al. 2008), no trace of mucus was observed on the specimens studied.

In summary, S. spinosus have gills with heterorhabdic filaments, with the principal ones showing a complex structure. The ascending lamellae of the ordinary filaments, consisting of many minor lamellar subunits, are shorter than the thicker descending lamellae. Every eight ordinary filaments, connected by regular ciliary discs of 5-7 cirral plates, ended with a marginal gutter at the dorsal end. No marginal food groove at the free distal end was evident.

In conclusion, the external morphology of the ctenidia of.S. spinosus can provide many useful features for evolutionary studies and can be the subject of biomonitoring studies within both natural and experimental contexts.

ACKNOWLEDGEMENTS

We thank M. Gokoglu for providing us with the specimens of S. spinosus. This work was funded by the Akdeniz University Research Projects Coordination Unit.

LITERATURE CITED

Submitted: 16.III.2011

Accepted: 26.VIII.2012

Editorial responsibility: Carolina Arruda Freire

AIELLO, E. & M.A. SLEIGH. 1972. The metachronal wave of lateral cilia of Mytilus edulis The Journal of Cell Biology 54: 493-506.
AKSIT, D.; B. FALAKALI- MUTAF; B. GOCMEN & G.GURELLI. 2008. A preliminary observations on Trichodina sp. (Ciliophora: Pertricha) on the gills of limpets (Patella spp.) in Antalya (Turkey). North-Western Journal of Zoology 4: 295-298.
AKSIT, D.& B. FALAKALI-MUTAF. 2011. The external morphology of the gill of Patella caerulea L. (Mollusca: Gastropoda). Turkish Journal of Zoology 35: 603-606.
ATKINS, D. 1937a. On the ciliary mechanisms and interelationships of lamellibranchs. Part II. Sorting devices on the gills. Quarterly Journal of Microscopical Science 78: 339-373.
ATKINS, D. 1937b. On the ciliary mechanisms and interelationships of lamellibranchs. Part III. Types of lamellibranch gills and their food currents. Quarterly Journal of Microscopical Science 79: 375-421.
BENINGER P.G. & S.D. ST-JEAN. 1997. The role of mucus in particle processing by suspension-feeding marine bivalves: unifying principles. Marine Biology 129: 389-397.
BENINGER, P.G. & P. DECOTTIGNES. 2008. Worth a second look: gill structure in Hemipecten forbesianus (Adams & Reeve, 1849) and taxonomic implications for Pectinidae. Journal of Molluscan Studies 74: 137-142. doi: 10.1093/mollus/eyn001
DAVID J.A.O. & C.S. FONTANETTI. 2005. Surface morphology of Mytella falcata gill filaments from three regions of the santos estuary. Brazillian Journal of Morphological Science 22: 203-210.
DAVID, J.A.O.; R.B. SALAROLI. & C.S. FONTANETTI. 2008. Fine structure of Mytella falcata (Bivalvia) gill filaments. Micron 39: 329-336. doi: 10.1016/j.micron.2007.06.002
DOMOUHTSIDOU, G.P. & V.K. DIMITRIADIS. 2000. Ultrastructural localization of heavy metals (Hg, Ag, Pb and Cu) in gills and digestive gland of mussels, Mytilus galloprovincialis (L). Archives of Environmental Contamination and Toxicology 38: 472-478. doi: 10.1007/s002449910062
DUFOUR, S.C. & P.G. BENINGER. 2001. A functional interpretation of cilia and mucocyte distributions on the abfrontal surface of bivalve gills. Marine Biology 138: 295-309.
DRURY, R.A. & E.A.WALLINGTON. 1973. Carleton's Histological Technique. London, Oxford University Press, 4^th ed., X+432p.
FALAKALI MUTAF, B.; D. AKSIT & M. GOKOGLU. 2009. Scanning electron microscopy of the gill morphology of Modiolus barbatus (Bivalvia: Mollusca). In: XV National Symposium of Aquatic Sciences, Rize, Turkey, p. 331.
GOSLING, E. 2003. Bivalve Molluscs. Biology and Culture. Oxford, Fishing New Books, Blackwell Scientific Publications, X+443p.
GREGORY, M.A. & R.C. GEORGE. 2000. The structure and surface morphology of gill filaments in the Brown mussel Perna perna Africa Zoology 35: 121-129.
GREGORY, M.A.; D.J. MARSHALL; R.C. GEORGE; ANANDRAJ A; T.P. MCCLURG. 2002. Correlation between metal uptake in the soft tissue of Perna perna and gill filament pathology after exposure to mercury. Marine Pollution Bulletin 45: 114-125.
KOEHLER, A.; U. MARX; K.BROEG; S. BAHNS & J.BRESSLING. 2008. Effects of nanoparticles in Mytilus edulis gills and hepatopancreas - A new threat to marine life? Marine Environmental Research 66: 12-14.
MORSE, M.P. & J.D. ZARDUS. 1997. Bivalvia. In: F.W. HARRISON & A.J. KOHN (Eds). "Microscopic Anatomy of Invertebrates: Mollusca II. New York, Wiley-Liss Inc., vol. 6A, p. 7-118.
VILLALEJO-FUERTE, M.; M ARELLALNO-MARTINEZ; B.P. CEBALLOS-VAZQUEZ & F. GARCIA-DOMINGUEZ. 2002. Reproductive cycle of Spondylus calcifer Carpenter, 1857 (Bivalvia: Spondyludae) in the "Bahai de Loreto" National Park, Gulf of California. The Journal of Shellfish Research 21: 103-108.
ZENETOS, A.; S. GOFAS; G. RUSSO & J. TEMPLADO. 2003. CIESM Atlas of Exotic Species in the Mediterranean. Monaco, CIESM Pub., vol. 3, 376p.
YONGE, C.M. 1973. Functional morphology with particular reference to hinge and ligament in Spondylus and Plicatula and a discussion on relations with superfamily Pectinicea (Mollusca:Bivalvia). Philosophical Transactions of the Royal Society of London B 267 (883): 173-208.

*

Corresponding author. E-mail:

denizaksit@akdeniz.edu.tr

Publication Dates

Publication in this collection
06 Mar 2013
Date of issue
Feb 2013

History

Received
16 Mar 2011
Accepted
26 Aug 2012

This work is licensed under a Creative Commons Attribution-NonCommercial 4.0 International License.

[1] AIELLO, E. & M.A. SLEIGH. 1972. The metachronal wave of lateral cilia of Mytilus edulis The Journal of Cell Biology 54: 493-506.

[2] AKSIT, D.; B. FALAKALI- MUTAF; B. GOCMEN & G.GURELLI. 2008. A preliminary observations on Trichodina sp. (Ciliophora: Pertricha) on the gills of limpets (Patella spp.) in Antalya (Turkey). North-Western Journal of Zoology 4: 295-298.

[3] AKSIT, D.& B. FALAKALI-MUTAF. 2011. The external morphology of the gill of Patella caerulea L. (Mollusca: Gastropoda). Turkish Journal of Zoology 35: 603-606.

[4] ATKINS, D. 1937a. On the ciliary mechanisms and interelationships of lamellibranchs. Part II. Sorting devices on the gills. Quarterly Journal of Microscopical Science 78: 339-373.

[5] ATKINS, D. 1937b. On the ciliary mechanisms and interelationships of lamellibranchs. Part III. Types of lamellibranch gills and their food currents. Quarterly Journal of Microscopical Science 79: 375-421.

[6] BENINGER P.G. & S.D. ST-JEAN. 1997. The role of mucus in particle processing by suspension-feeding marine bivalves: unifying principles. Marine Biology 129: 389-397.

[7] BENINGER, P.G. & P. DECOTTIGNES. 2008. Worth a second look: gill structure in Hemipecten forbesianus (Adams & Reeve, 1849) and taxonomic implications for Pectinidae. Journal of Molluscan Studies 74: 137-142. doi: 10.1093/mollus/eyn001

[8] DAVID J.A.O. & C.S. FONTANETTI. 2005. Surface morphology of Mytella falcata gill filaments from three regions of the santos estuary. Brazillian Journal of Morphological Science 22: 203-210.

[9] DAVID, J.A.O.; R.B. SALAROLI. & C.S. FONTANETTI. 2008. Fine structure of Mytella falcata (Bivalvia) gill filaments. Micron 39: 329-336. doi: 10.1016/j.micron.2007.06.002

[10] DOMOUHTSIDOU, G.P. & V.K. DIMITRIADIS. 2000. Ultrastructural localization of heavy metals (Hg, Ag, Pb and Cu) in gills and digestive gland of mussels, Mytilus galloprovincialis (L). Archives of Environmental Contamination and Toxicology 38: 472-478. doi: 10.1007/s002449910062

[11] DUFOUR, S.C. & P.G. BENINGER. 2001. A functional interpretation of cilia and mucocyte distributions on the abfrontal surface of bivalve gills. Marine Biology 138: 295-309.

[12] DRURY, R.A. & E.A.WALLINGTON. 1973. Carleton's Histological Technique. London, Oxford University Press, 4^th ed., X+432p.

[13] FALAKALI MUTAF, B.; D. AKSIT & M. GOKOGLU. 2009. Scanning electron microscopy of the gill morphology of Modiolus barbatus (Bivalvia: Mollusca). In: XV National Symposium of Aquatic Sciences, Rize, Turkey, p. 331.

[14] GOSLING, E. 2003. Bivalve Molluscs. Biology and Culture. Oxford, Fishing New Books, Blackwell Scientific Publications, X+443p.

[15] GREGORY, M.A. & R.C. GEORGE. 2000. The structure and surface morphology of gill filaments in the Brown mussel Perna perna Africa Zoology 35: 121-129.

[16] GREGORY, M.A.; D.J. MARSHALL; R.C. GEORGE; ANANDRAJ A; T.P. MCCLURG. 2002. Correlation between metal uptake in the soft tissue of Perna perna and gill filament pathology after exposure to mercury. Marine Pollution Bulletin 45: 114-125.

[17] KOEHLER, A.; U. MARX; K.BROEG; S. BAHNS & J.BRESSLING. 2008. Effects of nanoparticles in Mytilus edulis gills and hepatopancreas - A new threat to marine life? Marine Environmental Research 66: 12-14.

[18] MORSE, M.P. & J.D. ZARDUS. 1997. Bivalvia. In: F.W. HARRISON & A.J. KOHN (Eds). "Microscopic Anatomy of Invertebrates: Mollusca II. New York, Wiley-Liss Inc., vol. 6A, p. 7-118.

[19] VILLALEJO-FUERTE, M.; M ARELLALNO-MARTINEZ; B.P. CEBALLOS-VAZQUEZ & F. GARCIA-DOMINGUEZ. 2002. Reproductive cycle of Spondylus calcifer Carpenter, 1857 (Bivalvia: Spondyludae) in the "Bahai de Loreto" National Park, Gulf of California. The Journal of Shellfish Research 21: 103-108.

[20] ZENETOS, A.; S. GOFAS; G. RUSSO & J. TEMPLADO. 2003. CIESM Atlas of Exotic Species in the Mediterranean. Monaco, CIESM Pub., vol. 3, 376p.

[21] YONGE, C.M. 1973. Functional morphology with particular reference to hinge and ligament in Spondylus and Plicatula and a discussion on relations with superfamily Pectinicea (Mollusca:Bivalvia). Philosophical Transactions of the Royal Society of London B 267 (883): 173-208.

Brasil

Brasil

The surface morphology of the ctenidia of Spondylus spinosus (Mollusca: Bivalvia) from Antalya Bay, Turkey

Abstract

Publication Dates

History