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A description of Haliclona (gellius), Gray 1867


Olivia Hannah Hewitt 2017

Summary

Here we have a juvenile specimen collected from Heron Island, on the southern end of the Great Barrier Reef(GBR). Juveniles lack the development of an ectosomal skeleton, with this being a key feature for classification within this group (Fromont, 1993), species level identification was not possible. Consequently the descriptions that follow, will be based on its genus and subgenus (gellius). 


Gellius
 lies within the family, Chalinidae and the order Haplosclerida of the demosponges. Haliclona has been described as a heterogenous and unmanageable group but through a mixture of Chalinidae revisions, the Australian species could be placed (Hooper and Wiedenmayer, 1994). It is an uncommon subgenus, and uncertain as to how many shallow water varieties occur in the Pacific and Antarctic waters (Hooper and van Soest, 2002). This species web page outlines key ecological, physiological, behavioral and evolutionary traits of Haliclona gellius. Sponge taxonomy is challenging and still remains a developing area, with few specialists in the field, consequently here there is a focus on anatomical and physical traits for their crucial role in the taxonomy of this group. 


Physical Description

Haliclona have been described as soft, friable and easily torn. They mostly consist of reduce fibres and spicules (Hooper, 2003). The study specimen here is a small delicate sponge, about 5cm in height and 1cm diameter. It is of a very pale white colour. However it must be considered that this specimen is still a juvenile and will continue to go through some morphological changes. 

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Figure 1

Ecology

Symbiosis

It is well established that many marine sponges are host to and have a symbiotic relationship with a wide variety of microorganisms. Often these bacteria live within the sponge mesophyl, though it varies whether this is intra- or extracellular. It is considered that in high-microbial-abundance-sponges (HMAS), microorganisms makeup about 40-60% of the total sponge biomass, the “bacteriosponge”, whereas this is much lower in low-microbial-abundance sponges (LMAS) (Khan et al, 2014).

Whilst this is a growing area of research, it remains difficult to harvest and cultivate the bacteria (Sipkema et al, 2011). Moreover, currently little is really known about the nature of this symbiotic relationship, and how sponges acquire and maintain the specific bacteria.

Sipkema et al, (2009) studied the bacterial symbionts of Haliclona gellius and concluded it is most likely a LMA sponge. LMAS are usually smaller and less dense than HMAS (Khan et al, 2014). Details of the specific bacteria and densities may be found in their study.

Sponge bacterial symbionts are of particular interest because of their production of potentially useful bioactive compounds, of which there is a vast array. They may have properties such as,antimicrobial, antiviral, antioxidant and antitumor (Faulkner, 2002). Khan et al, (2014) believe that species of Haliclona may be a rich source of ‘novel bacteria’. In their study they found bacteria from Haliclona sp. to be producing novel polyketides. Polyketides are a large family of structurally diverse natural products, which may be useful to the pharmaceutical industry (Khan et al, 2014).

Nutrient recycling

Sponges have an important role to play in the recycling of dissolved organic matter (DOM) in what otherwise may be a nutrient poor oligotrophic coral reef ecosystem. Coral reef crevices and cavities are known to be major sinks of DOM but the microbial loop is insufficient to explain DOM removal on coral reefs.

Through their filter feeding, sponges are able to uptake DOM from the water column. Sponges respire only 42% of the carbon from their uptake, and it is believed that the remainder goes into a rapid tissue turnover.  Choanocyte cells divide every 5- 6 hours and thus this is accompanied by a rapid shedding of old choanocyte cells. This cell shedding produces particulate organic matter (POM), or detritus. This available detritus material in the water column is consumed by detritivores (e.g. small crustaceans) which thus provides an energy source for the higher tropic levels up the trophic web. This process has become known as the “sponge loop” and is depicted in Figure 2.  

(Goeji et al, 2013).

This process has not been documented for Haliclona gellius specifically, however it is a reef dwelling sponge and the choanocyte ultrastructure and basal apparatus has been described as almost constant across adult sponges (Woollacott and Pinto, 1995). Thus, it is likely that Haliclona gellius does have this functional role in nutrient recycling for coral reef ecosystems. Additionally although Haliclona gellius preferentially inhabits cold waters, the “spongeloop” has now since also been documented to occur in cold water coral reef ecosystems (Rix et al, 2016). 

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Figure 2

Life History and Behaviour

The Aquiferous system

The aquiferous system, characterizes sponges. It functions as their feeding, excretion, respiration, gamete release and transport systems. Flagellated collar cells (choanocytes), beat their flagella and draw water into inhalent canals through small pores called ostia. The water is eventually drawn into choanocyte chambers where suspended food particles and oxygen are trapped and filtered by particular cells. This filtered water is then passed out through a series of exhalent canals and eventually leaves the sponge through its oscula. The aquiferous system is flexible and can easily be rearranged (Ereskovsky, 2010).

As is the case for most sponges, Haliclona gellius has a leuconoid structured aquiferous system (Figure 9).This structure is the most complex, consisting of a net like structure of small-diameter incurrent and excurrent canals between choanocyte chambers of flagellated collar cells. Leuconoid sponges are densely packed with many choanocyte chambers. This structure allows sponges to grow large in size whilst still maintaining a high surface area to volume ratio for obtaining the nutrition they require for their size (Ruppert et al, 2004). 

Reproduction and larval development

The specific reproductive and development strategies for this specimen have not yet been described. However there have been some detailed studies on a few species of Haliclona. Additionally, the Australian coral reef sponge, Amphimedon Queenslandica (Degnan et al, 2015) has been extensively studied, and considered to be a close relative, based on 18s rDNA sequence analysis (Sipkema et al, 2009).

Most species within Haplosclerida are oviparous, with some being gonochorich, and others hermaphrodites. Sexual reproduction is most often alternated with asexual blastogenesis (gemmule production) throughout the Haploscerida life cycle (Ereskovsky, 2010). Both mechanisms are outlined below. 

Sexual

Spermatogenesis occurs via spermatocycts diffused within the choanosome by the same process that is common to most demospongae. It has not yet been studied from which cells male gametes are derived in marine Haplosclerids, but for their freshwater varieties and all other demosponges, (except carnivorous poecilosclerids), they derive from choanocytes within the choanocyte chambers. The newly formed spermatocysts fuse with exhalent canals, and once mature are released into the water column through their canal lumens.

It is believed that female gametes, by the process of oogenesis are derived in nucleated ameobocytes or choanocytes diffused in the choanosome. A distinguishing feature for Haplosclerida oogenesis, is the presence of “nurse cells” (or “trophocytes”).  These are somatic cells and provide the yolk source for oocytes during vitellogenesis. This “nurse cell” presence indicates a higher level of oogenesis specialization within Haplosclerida.

Most haplosclerids are oviparous, with internal fertilization. However, little is known about the cleavage process for marine Haplosclerida as, with the eggs and blastomeres full of yolk granules (from the “nurse cells”), dividing nuclei and blastomere borders are concealed from view.

After cleavage is the morula stage, and differentiation of cells for larval structure formation. Often in haplosclerids sclerocytes are the first cells to differentiate and begin functioning.  

(Ereskovsky, 2010) 

The larvae settle, anterior pole first, attach to the substrate and under go metamorphosis, which is completed by their development of a functioning aquiferous system (Ereskovsky, 2010).

Chalidinae larva is paranchymella and it may be uniformly ciliated or have extended cilia on its posterior (Hooper and weidenmayer, 1994). Paranchymella larva have all or some of the spicule types seen in its adult form (Simpson, 1984). 
Interestingly it has been suggested that larval morphology may be a useful character in determining sponge taxonomy (Levi,1956). In a study of Haliclona indistincta (Stephens et al, 2013) they were able to distinguish the larvae as H.indistincta because of their sticky characteristic, and they suggest this may be a useful feature within sponge taxonomy. Moreover, Haplosclerida larva have a number of distinguishing features (Figure3) which can be diagnostically useful; absence of ciliated cells in the posterior pole, which is encircled by cells of elongated cilia, a skeleton of densely bundled oxeas in posterior portion, and a concentration of pigment cells at the posterior end, either within the long ciliated cells or the non-ciliated cells (Ereskovsky, 2010). This reflects how there is a wide range of taxonomic features that may be useful in sponge identifications. These could be especially useful in this case, where it is not possible to use the usual features (e.g. ectosomal skeleton) due to the juvenile nature of the sponge. However Stephens et al, (2013) do note that further morphological data on larva is required and thus indicate the infancy of which much sponge research remains and perhaps why sponge taxonomy is so challenging.

Asexual

Asexual reproduction in sponges can be via gemmule production, fragmentation, or budding, however budding is generally not considered a characteristic in Haploscerida and thus is not documented here.

Fragmentation occurs mostly when a sponge has been damaged in wave or current action and fragments break off. Dislodged fragments can reattach to the substrate and re-order itself into a functional sponge (Ruppert et al, 2004).

Gemmules are produced by some marine Chalinidae and occurs occurs after the completion of sexual reproduction.

Gemmule trophocytes, archaeocytes and spongocytes migrate and densely aggregate in specific parts of the mesophyl. Archaeocytes begin phagocytosing trophocytes and yolk plates develop, consisting of flattened archaeocytes internally, and flattened spongiocytes externally. A Gemmule envelope then begins to form spreading from one pole to the other. Prior to hatching, thesocytes synthesize collagen ready for substrate attachment. After hatching the gemmule attaches to the substrate and differentiation of totipotent thesocytes begins.

Gemmule germination may be triggered by a range of external factors, such as temperature, humidity, illumination and ionic composition of water etc. Though in cold climates germination can only occur after a certain lapse of time, diapause.

Gemmules are well adapted to extreme environments, for instance they are capable of germinating after 2 months of exposure to -80°C and -100°C. Additionally 25% of gemmules have shown the ability to survive 4 months at +5°C out of the water.

(Ereskovsky, 2010). 

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Figure 3
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Figure 4

Anatomy and Physiology

Spicules

Often, in silicious sponges,megascleres may be observed to protrude from the animal’s surface. This is visible in the study specimen here, seen in Figure 11. One possible explanation for this from Simpson (1984) is that protruding spicules form a protective armour to prevent detritus from settling on the sponge surface. Also, protruding spicules are normally seen covered in exopinacocytes.

Spicule morphology, arrangement, chemical nature and microstructure has historically been the basis for sponge taxonomy (Simpson, 1984). Demosponge spicules are siliceous (SiO2) and can be either of large sizes (megascleres) or small sizes (microscleres). It is important to note that this size differentiation must be considered with respect to the sames species or groups as megascleres of one species may be much smaller than another (Simpson, 1984). 

In demosponges, spicules are formed intracellularly by one or more sclerocyte. A siliceous monaxon spicule is formed around an organic filament within an intracellular vesicle. The cell at first elongates as the spicule grows and crystalizes. Next, the cell divides and each of the two cells function to add silica at opposite ends of the spicule’s growing tips (Ruppert 
et al, 2004). 

Interestingly the morphology of spicules’ axons and rays may be used for understanding sponge phylogenies and evolutionary relationships, detailed in ‘Evolution and Systematics’. 


Gellius oxeas are usually long and stout with hastate (narrow/spearhead) ends. Microslceres, are not always present, but may be, sigmas, toxas or raphides (or a mixture) (Hooper and Van Soest, 2002). Usually microscleres are easily distinguished by their size and morphology, and megascleres, although less easily identified, can be done so based on morphology (Simpson, 1984). 


This specimen has...

 
Megascleres include; fusiformoxeas, Strongyles, strongyleoxeas, and tornate. Microscleres include; sigmas and toxas. Images for all of these are displayed in Figures. 5-11. Foreign spicules were also found during the analysis, including a Verticillate (Figure.12) which may be from an associated species and a triactine (Figure. 13), common to calcareous sponges. 


References for the specific spicules can be found using 'Thesaurus of Sponge Morphology' (Boury-Esnault and Rutzler, 1997). 

Thank you to Anita George from the Queensland Museum for helping to provide spicule identifications and many of the photos of this specimen. 

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Figure 5
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Figure 9
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Figure 11
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Figure 12
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Figure 13

Skeleton

Haplosclerida have a siliceous skeletal structure that may include either or both a choanosomal skeleton and ectosomal (surface) skeleton.The study species here is a juvenile and thus has not yet developed the ectosomal skeleton which is so crucial for species level identification within this group (Fromont, 1993).

The skeletons of Haplosclerida are delicate and usually a simple unispicular reticulation, connected by spongin or a network of fibers in which spicules are incorporated (Fromont, 1993).

The choanosomal skeleton of Chalinidae is described as a confused, isodyctyal (triangular patterned) structure consisting of pauci- to multispicular primary lines that are connected irregularly at nodes of collagenous spongin (Hooper and Wiedenmayer, 1994) by unispicular lines (Hooper and van Soest, 2002). More specifically Gellius has an anisotrophic, ladder-like structure, consisting of uni- or paucispicular ascending primary lines. They may regularly or less regularly be connected by unispicular secondary lines (Hooper and Van Soest, 2002).

The original Chalinidae definition by Gray (1867), was based only on the choanosomal skeleton, however (Weerdt, 1986) later revised this to include an ectosomal description in this definition (Fromont, 1993). Characteristics of the ectosomal skeleton have been useful in family level classification. This really highlights, not only the importance of skeletal structure, but also the changing nature of sponge taxonomy.

Weerdt’s (1986) definition for the ectosomal skeleton was, ‘if present, a unispicular tangential reticulation’. For Chalinidae if present, Hooper and Van soest (2002) describe it to be either a tangential, unispicular, isotrophic reticulation, or to consist of irregularly strewn, tangentially orientated spicules. 

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Figure 14
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Figure 15

Cell types and structure

Cross sections depicting the specific cell structure of the study specimen here are displayed in Figures 16-22. 

Demosponges have two epithelial cell layers, pinacoderm and choanoderm.

It is of some debate as to whether these cell layers may be considered as “true” epithelial layers. The traditional definition for epithelium requires there to be the presence of a basal lamina and junctions between the epithelial cells (Stephens et al, 2013). However, more modern definitions recognize that the sponge epithelial layer forms a very similar function as those deemed as “true” epitheliums in other animals and thus must be considered as such. This of course may have an impact on the phylogeny of sponges within the metazoan lineages.

Pinacoderm is formed from pinacocytes (flattened cells) which make up the external layer of the aquiferous system and some of the internal cavities. Choanoderm, consisting of the flagellated collar cells (choanocytes) lines the choanocyte chambers. Between the outer layer of the pinacocytes and the aquiferous system, is the mesophyl (Ereskovsky, 2010).

The mesophyl, an extracellular matrix between the internal pinacoderm layer and flagellated collar cells is a dynamic cell layer, with the capacity to constantly remodel itself. It is highly variable and contains a vast variety of cell types for different functions, many of which have yet to be determined (Simpson, 1984). The functions of these cells collaboratively create major parts of the skeleton, including minerals, collagen and ground substance (Simpson, 1984). Some of the most significant mesophyl cell types have been outlined below. 

Archeocytes – Polyblasts – Thesocytes

These cells all have a very similar structure and function. It is actually considered that they do not have a specific function, but generally it is said they are involved with the storage and processing of nutrients. Interestingly, they are pluripotent or have an embryonic nature meaning they can potentially develop into any sponge cell type e.g. for growth or gamete formation. However the specific cells that they develop into varies for each sponge species, and unfortunately this has not been studied for the study species here (Simpson, 1984).  

Lophocytes
                                                                                                                                         
Considered to have archeocyte type properties and functions, there is no complete agreement on the function of this cell type. Some consider it to be a transient stage of an archeocyte, whilst others believe lophocyctes to specifically function as cells to biosynthesize collagen (Simpson, 1984).

Trophocytes
                                                                                                                                             
These function as a source of nutrients for archeocytes during gemmule production in asexual reproduction. Additionally they are involved with providing nutrients for developing oocytes, as mentioned in the reproduction section. However in that case they can be considered as “nurse cells’ in order to avoid confusion (Simpson, 1984).

Sclerocytes                                                                                                These cells are responsible for secreting the mineralized megascleres and microscleres (Ruppert et al, 2004).                                                                                                                                      
Spongocytes                                                                                                                                           
These cells secrete collagen that polymerizes into thick fibre, called sponging (Ruppert et al, 2004).                                                                                                                                                 
Choanocytes                                                                                                  
Otherwise known as flagellated collar cells, they generate the water flow through the sponge aquiferous system (see‘Life History and Behaviour’) with their pumping flagellum (Ruppert et al, 2004). 


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Figure 22

Taxonomy

Sponge taxonomy is notoriously challenging due to the huge morphological variety of forms that sponge species can take on. The family, Chalinidae first described by Gray 1867 and resurrected by Weerdt (1986), is no exception to this. Despite there being a worldwide distribution of 27 nominal genera described (Hooper and Van Soest, 2002), currently only four are considered valid; Chalinula, Cladocroce, Dendroxea, Haliclona. This is largely due to taxonomic discrepancies and unsuccessful revisions of the family. Mostly revisions have dealt with regional fauna, but even at a more generic level, the North Atlantic and Caribbean studies often do not agree with those from Australasian specimens (Hooper and Wiedenmayer, 1994). Further to this, Hooper and Wiedenmayer (1994) doubt a world review of the fauna will be successful, with problems such as not being able to distinguish sibling species from preserved specimen samples.

The solution, in order to place the Australian species, was to use an amalgamation of previous Chalinidae revisions, even with the knowledge that Haliclona itself is an ‘unmanageable and heterogeneous’ genus (Hooper and Wiedenmayer, 1994). Taxonomic characteristics, such as larval morphology have been suggested as useful diagnostic tools to aid the classifications (Levi, 1956; Ereskovsky, 2010). However this of course requires an in depth knowledge and data on sponge larva morphologies, which is still being developed. 

Langenbruch and Jones (1990) further the disagreements by demonstrating that even the order, Haplosclerida is not polyphyletic and contains sponges suggested to be of poecilosclerid origin. Unlike most demosponges, in the majority of haploscredia the choanocytes do not touch the mesohylar tissue and are mostly directly covered with pinacocytes of the incurrent canal walls. However Lengenbruch and Jones (1990) show that this is not the case in Haliclona indistincta, whereby the choanocytes are in contact with the mesohyl on their outer surface and thus suggest a polyphyletic order. 


Biogeographic Distribution

The subgenus Gellius is not considered particularly common (Hooper and Van Soest, 2002). Though it is argued that maybe it is just not easily detectable, due to its preference for residing in cold water and situating under rocks (Sipkema et al, 2009). 

It is suggested to have a preference for deep waters. As for shallow water varieties, only three species are known to occur in the North East Atlantic region, one in the Caribbean, and for the Pacific and Antarctic, it still remains unknown (Hooper and Van Soest, 2002). Some species of Haliclona have been reported to occur as deep as 2460m (Hooper and Wiedermayer, 1994).

Figure 23 depicts a distribution abundance map around Australia and surrounding areas for Haliclona Gellius from the world register of marine species. 


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Figure 23

Evolution and Systematics

Paleontological records indicate that sponges are the oldest multicellular animals (Ereskovsky, 2010). Li et al, (1998) describe their findings of sponge specimens (Central Guizhou, China) that date to the Early Vendian (580 Ma) and the earliest sponge spicules, (Mongolia) were of the Late Ediacaran (543 to 549 Ma) (Li et al, 1998).

However, more controversial is the occurrence in which the different sponge classes derived. Traditionally, Hexactinellida is considered to be the oldest lineage of the extant sponges, with Demospones occurring from the late Proterozoic (about 750 million years ago), and calcareous sponges later still (Ereskovsky,2010). However, Li et al, (1998) proposed that the sponge fossils they found from central Guizhou, China were monaxonid demosponges and thus propose a revision of the phylogenetic class of porifera.

Further confusion in sponge phylogeny stems from inferences based on demosponge spicule geometries. Simpson (1984) describes how micro- and megascleres are derived from tetractines, and the loss of one or more axis. This is a simplistic approach, and although is not the basis for current sponge phylogeny, it still remains heavily relied upon (Simpson, 1984).

Even considering porifera within the rest of the animal kingdom, traditional views are being questioned. Degnan et al, (2015) describe how new molecular data indicate porifera may not be the oldest living phyletic lineage. The molecular analysis suggests that ctenophores may be the sister group to all other animals, thus indicating that sponges have derived simplicity. However this still remains heavily under debate and a current area of extensive research.  

Conservation and Threats

It is unknown specifically whether there are any particular threats to Haliclona gellius. In general porifera are a very abundant and diverse phylum that has been successful all around the world. Of course this does not exclude them from threats such as, disease, pollution, predation and trawler net fishing which have been documented for certain species or localities.

However in the case of the order, Haplosclerida it was found (amongst other sponge orders) to be a dominant organism amongst the mega benthic invertebrates on Australia’s Western continental margin (Fromont, 2012). In addition new species of Haliclona are still being documented (Kim and Sim, 2004; Fromont and Abdo, 2014).  Consequently there are no known conservation efforts in place that are specifically targeting sponges, though they may benefit from marine protected zones which are becoming increasingly more common across Australia (Przeslawski et al, 2015).

References

Boury-Esnault, N. and Rutzler, K. (1997). Thesaurus of Sponge Morphology. (Smithsonian Institution Press: Washington, D.C.)

De Goeji, J.M., van Oevelen, D., Vermeij, M.J.A.,  Osinga, R., Middelburg, J.J.,  de Goeij, A.F.P.M., and Admiraal, W. (2013). Surviving in a Marine Desert: The Sponge Loop Retains Resources within Coral Reefs. Science 342, 108-110.

Degnan, B.M., Adamska, M., Richards, G.S., Larroux, C., Leininger, S., Bergum, B.,Calcino, A., Taylor, K., Nakanishi, N., and Degnan, S.M. (2015). Porifera. In(Eds  A. Wanninger) ‘Evolutionary developmental biology of invertebrates 1: introduction, non-bilateria, acoelomorpha, xenoturbellida, chaetognatha’. p.65-106 (Springer Verlag: Vienna, Austria).

Ereskovsky, A.V. (2010). The comparative embryology of sponges. (Springer: Dordrecht, Netherlands).

Fromont, J. (1993). Description of species of the Haplosclerida (Porifera: Demospongiae) occurring in the tropical waters of the Great Barrier Reef. The Beagle, Records of the Northern Territory Museum of Arts and Sciences 10, p.7-40.

Fromont, J. and Abdo, D.A.(2014). New species of Haliclona (Demospongiae: Haplosclerida: Chalinidae) from Western Australia. Zootaxa 3835, 97-109.

Fromont, J., Althaus, F., McEnnulty, F.R., Williams, A., Salotti, M., Gomez, O., and Gowlett-Holmes, K. (2012). Living on the edge: the sponge fauna of Australia’s south western and north western deep continental margin. Hydrobiologia 687,127–142.

Gray, J.E. (1867). Noteson the Arrangement of Sponges, with the Descriptions of some New Genera. Proceedings of the Zoological Society of London 2, 492-558.

Hooper, J.N.A. (2003). ‘Sponguide’. Guide to sponge collection and identification. Queensland Museum, Australia. Available online at ‘www.qm.qld.gov.au’ [accessed: 30th April 2017].

Hooper, J.N.A., and VanSoest, R.W.M. (2002). Family Chalinidae Gray, 1867. In ‘SystemaPorifera: a guide to the classification of sponges. Volume 1.’ p.852-873.(Kluwer Academic/ Plenum Publishers: New York).

Hooper, J.N.A., and Wiedenmayer, F. (1994). Chalinidae. In ‘Zoological Catalogue of Australia.Volume 12.’ (Eds A. Wells). p.109-121 (CSIRO: Melbourne, Australia).  

Khan, S.T., Musarrat,J., A. Alkhedhairy, A.A., and Kazuo, S. (2014). Diversity of bacteria and polyketide synthase associated with marine sponge Haliclona sp. Annals of microbiology 64, 199-207.

Kim, H.J., and Sim, C.J.(2004). A new sponge of the genus haliclona (gellius) (haplosclerida:Chalinidae) from gageodo island (so‐huksando), Korea. Korean Journal of Biological Sciences 8, 247-250.

Langenbruch, P.L., and Jones, W.C. (1990). Body Structure of Marine Sponges. VI. Choanocyte Chamber Structure in the Haplosclerida (Porifera, Demospongiae) and its Relevance to the Phylogenesis of the Group. Journal of Morphology 204, 1-8.

Levi C.(1956). Etude des Halisarca de Roscoff: Embryologie et systematique desDemosponges. (Centre national de la recherche scientifique: Paris, France) p.3–181.

Li, C.W., Chen, J.Y., and Hua, T.E. (1998). Precambrian sponges with cellular structures. Science 279,879-882.

Przeslawski, R., Alvarez, B., Kool, J., Bridge, T., Caley, M.J., and Nichol, S. (2015). Implications of Sponge Biodiversity Patterns for the Management of a Marine Reserve in Northern Australia. PLoS ONE 10, e0141813.

Rix, L., de Goeij, J.M., Mueller, C. E., Struck, U., Middelburg, J. J., van Duyl, F. C., Al-Horani, F.A., Wild, C., Naumann, M.S., and van Oevelen, D. (2016). Coral mucus fuels the sponge loop in warm- and cold-water coral reef ecosystems. Scientific Reports 6, e18715.

Ruppert, E.E., Fox, R.S.,and Barnes, R.D. (2004). Invertebrates Zoology, A functional approach. 7th EDs.(Brooks/Cole: Belmont, CA, USA).

Simpson, T.L. (1984). The cell biology of sponges. (Springer-Verlag: New York).

Sipkema, D., Holmes, B., Nichols, S.A., and Blanch, H.W. (2009). Biological Characterisation of Haliclona (?gellius) sp.: Sponge and Associated Microorganisms. Microbial Ecology 58, 903-920.