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An improved method for isolating camallanid (Nematoda) spicules for scanning electron microscopy

Published online by Cambridge University Press:  07 February 2023

A.P. Nofal Open the ORCID record for A.P. Nofal [Opens in a new window] ,
Q.M. Dos Santos Open the ORCID record for Q.M. Dos Santos [Opens in a new window]  and
A. Avenant-Oldewage Open the ORCID record for A. Avenant-Oldewage [Opens in a new window]
A.P. Nofal
Affiliation:
Department of Zoology, University of Johannesburg, PO Box 524, Auckland Park, Johannesburg 2006, South Africa
Q.M. Dos Santos
Affiliation:
Department of Zoology, University of Johannesburg, PO Box 524, Auckland Park, Johannesburg 2006, South Africa
A. Avenant-Oldewage*
Affiliation:
Department of Zoology, University of Johannesburg, PO Box 524, Auckland Park, Johannesburg 2006, South Africa
*
Author for correspondence: A. Avenant-Oldewage, E-mail: aoldewage@uj.ac.za
Rights & Permissions [Opens in a new window]

Abstract

In nematodes, the structure of male copulatory organs is a significant taxonomic distinguisher and includes the morphometry of the spicules. The description of these structures mainly relies on the study of whole mounts using light microscopy. In rare instances, protruding spicules have been described with scanning electron microscopy. Even fewer studies have described the ultrastructure of isolated spicules following their isolation. In the present study, two different methods of spicule isolation were performed on two parasitic camallanid nematodes, Procamallanus (Procamallanus) pseudolaeviconchus Moravec & van As, 2015 and Paracamallanus cyathopharynx (Baylis, 1923), from African sharptooth catfish to determine the practicality and efficiency of the methodologies. The first method involved using sharpened tungsten needles and microdissection of the spicule pouch to free the spicules, followed by soft tissue digestion if necessary. Alternatively, the spicules were isolated through mechanical release instead of dissection in a method developed in the current study. This involved freeing the spicules from surrounding soft tissue by placing live specimens between a coverslip and a glass slide in a drop of water and exerting pressure with small rotational movements. Both methods yielded favourable results, but Method 2 is recommended for future studies due to the many advantages.

Keywords

AfricaaquaculturebiodiversityClarias gariepinusfish nematodereproductive structuretaxonomy
Type
Short Communication
Information
Journal of Helminthology , Volume 97 , 2023 , e17
Creative Commons
Creative Common License - CCCreative Common License - BY
This is an Open Access article, distributed under the terms of the Creative Commons Attribution licence (http://creativecommons.org/licenses/by/4.0/), which permits unrestricted re-use, distribution and reproduction, provided the original article is properly cited.
Copyright
Copyright © The Author(s), 2023. Published by Cambridge University Press

Introduction

Generic and species differentiation of male nematodes generally requires information about the morphometry of copulatory structures such as the spicules. Features mostly included are the length and number of spicules (e.g. Moravec, Reference Moravec1974, Reference Moravec1975; Ivashkin et al., Reference Ivashkin, Sobolev, Khromova and Skrjabin1977; Boomker, Reference Boomker1982), and later, detailed information about the spicule including their shape and tip characteristics (e.g. Scholz et al., Reference Scholz, Vanhove, Smit, Jayasundera and Gelnar2018; Moravec, Reference Moravec2019; Svitin et al., Reference Svitin, Truter, Kudlai, Smit and Du Preez2019; Rindoria et al., Reference Rindoria, Dos Santos and Avenant-Oldewage2020). Most observations of these copulatory structures are of intact specimens using light microscopy (LM). However, this approach can be limiting due to the mounting, clearing or orientation of specimens, as well as other tissue/organs, obscuring the gross morphology of copulatory structures in the whole nematode (Rammah & Hirschmann, Reference Rammah and Hirschmann1987). Gradinarov (Reference Gradinarov2003) exposed male nematode specimens to heated 10% potassium hydroxide and studied cuticle remains and spicules using LM. In other instances, protruding spicules were serendipitously studied using scanning electron microscopy (SEM) (e.g. Moravec & Jirků, Reference Moravec and Jirků2017; Moravec & Scholz, Reference Moravec and Scholz2017; Rindoria et al., Reference Rindoria, Dos Santos and Avenant-Oldewage2020; Al-Bassel et al., Reference Al-Bassel, Abu-Elhasan, Abdel-Haleem and Atwa2022) and these studies revealed additional detail. On rare occasions, spicules were isolated through dissection from the spicule pouch of specimens in glycerine or lactic acid, which were then studied with SEM (Eisenback, Reference Eisenback1985; Rammah & Hirschmann, Reference Rammah and Hirschmann1987). This process has not gained much traction, presumably due to the technical skill required. The present study isolated the unequal spicules, referred to as the left and right spicule, from the males of two parasitic camallanid nematode species from fish – Procamallanus (Procamallanus) pseudolaeviconchus Moravec & van As, 2015 and Paracamallanus cyathopharynx (Baylis, 1923) – using and optimizing available methodology.

Materials and methods

Parasitic nematodes were collected from Clarias gariepinus (Burchell, 1822) in the Crocodile River, North-West province, South Africa (Nofal et al., Reference Nofal, Dos Santos, Jirsa and Avenant-Oldewage2022). Specimens were fixed in either steaming hot 70% ethanol, room temperature 70% ethanol, steaming hot triethanolamine formalin or steaming hot 10% neutral buffered formalin, while other specimens were processed live. Spicules were isolated using one of the following two methods.

Method 1

Following Austin et al. (Reference Austin, Dos Santos and Avenant-Oldewage2023), the method from Rammah & Hirschmann (Reference Rammah and Hirschmann1987) was adapted. Fixed specimens (50 male nematodes; 25 of each species) were transferred to concavity glass slides and immersed in 40% lactic acid or lactophenol and left to clear. Using a dissection microscope (10×, 4×, 2× magnification), the posterior regions were separated from the rest of the body using two sharpened tungsten needles (Brady, Reference Brady1965; Bowen, Reference Bowen2010), securing the nematode with one needle and cutting with the other. Both the left and right spicules were released by systematically micro-dissecting the spicule pouch using the needles to tear away obstructing tissue.

Any remaining soft tissue was removed through soft tissue digestion using an enzymatic tissue digestion solution following the camallanid nematode buccal capsule isolation protocol of Rindoria et al. (Reference Rindoria, Dos Santos and Avenant-Oldewage2020) using the proteinase-K based digestion buffer from an E.Z.N.A DNA extraction kit (Omega Bio-tek, Inc. Norcross, USA). After that, isolated spicules were rinsed with 2% formalin (Rammah & Hirschmann, Reference Rammah and Hirschmann1987) to remove any remaining lactic acid and buffer. Isolated spicules were dried overnight in the concavity glass slides in a Sanplatec dry keeper desiccator cabinet (Sanplatec Corporation, Japan), sputter coated with gold using an Emscope SC500 sputter coater (Quoram Technologies, Newhaven, UK) and studied using a TESCAN Vega 3 LMH (Tescan, Brno, Czech Republic) scanning electron microscope at 8 kV.

Method 2

Three alternative versions were attempted

  1. a) Using live specimens, nematodes were transferred to a drop of Milli-Q water on a microscope glass slide and the posterior separated from the rest of the body using sharpened tungsten needles. The remaining nematode tissue was removed and stored in 96% ethanol for other applications. A 22 × 60 mm coverslip was placed onto the drop, containing the posterior section of the nematode (fig. 1a). The coverslip was placed in such a way that part of the coverslip was hanging over the short edge of the glass slide. The coverslip was then manually rotated in small circles, adding gentle pressure, if necessary, until both spicules were released from the tissue. Once isolated, the coverslip was removed, and 70% ethanol dropped over the spicules to fix the structures. The position of the spicules, on either the coverslip or glass slide, was marked with a permanent marker, stored in a desiccator overnight to dry, and studied using SEM as described above, except using microscope glass slides instead of concavity slides.

  2. b) To limit the loss of spicules when removing the coverslip post-isolation, the entire coverslip–slide complex was stored in a desiccator overnight, after dripping sufficient 70% ethanol on the sides of the coverslip to replace the Milli-Q water. When dry, the coverslip was removed from the slide while observing with a dissection microscope and the isolated spicules studied using SEM as described above.

  3. c) In the event that fresh material was not available, specimens in glycerol were also used. The glycerol was removed by rinsing the specimens with distilled water before processing, as described above.

Fig. 1. (a) photograph of the coverslip–slide complex used in Method 2 – the arrow shows the placement of the overhanging coverslip and the dashed circle shows the position of the specimen; (b–g) light (LM) and scanning electron (SEM) micrographs of the tail region and isolated spicules of male Paracamallanus cyathopharynx (Baylis, 1923): (b) LM of tail region – solid arrow shows right (large) spicule and dashed arrow shows left (small) spicule; (c) LM of the tail region using differential interference contrast – arrow shows right (large) spicule; (d) SEM of isolated right (large) spicule – arrow shows velum adhering to the glass slide and inlay highlights adhered velum with dotted lines; and (e) SEM of the alternate surface of the ethanol-fixed isolated right (large) spicule – the inlay shows the unadhered velum.

If required, spicules could be reorientated using an eyelash hair attached to a toothpick. Repositioning was also possible after initial SEM study, including sputter coating with gold. This allowed for the study of the opposite surface of the spicules.

Results and discussion

Both methods for spicule isolation provided good results; however, each had its advantages and disadvantages. Firstly, Method 1 required the accurate identification of the location and extent of the spicules within the whole nematode and to clearly distinguish between the left spicule and the right spicule (fig 1b, c), which was more challenging for the left spicule due to the limited magnification of a dissection microscope. Secondly, Method 1 required advanced fine-motor skills to free the spicules from tissue, with improper manipulation resulting in damage, breakage and/or loss of the spicules, necessitating many specimens to obtain ideal results. This method is, therefore, deemed impractical where a limited number of specimens are available. Furthermore, the large number of specimens needed for Method 1 required persistent sharpening of the tungsten needles. Enzymatic digestion of soft tissue, post microdissection, caused unintentional loss of structural integrity of the spicules and incomplete rinsing of the digestion buffer left residual material, obscuring structures.

Method 2 appeared superior to Method 1 as it required less advanced fine-motor skills due to the elimination of microdissection. Due to the ease and convenience of Method 2, it was, therefore, also more time-efficient, which is important when large sample sizes are studied. However, there was an initial high rate of spicule loss when removing the coverslip, but this was addressed by keeping the coverslip–slide complex intact during fixation as per Method 2b. Due to the manual rotations, the right spicule broke in some cases, probably owing to its size and shape. These rotations also resulted in the alteration of the natural shape of spicules on occasion. Method 2 also allows for using a digestion buffer after the spicules have been isolated to remove the remaining tissue. The use of Method 2 for specimens in glycerol was satisfactory; however, not as effective as using fresh material.

Eisenback (Reference Eisenback1985) reported that spicules could withstand airdrying as they are not hydrated, and usually sclerotized, and will therefore maintain their natural integrity. However, both Eisenback (Reference Eisenback1985) and Rammah & Hirschmann (Reference Rammah and Hirschmann1987) immersed live specimens in lactic acid or glycerine during spicule isolation and rinsed them with 2% formalin before drying. In this study (Method 2), live specimens that had not been exposed to any chemical were used, and the isolated spicules were initially dried unfixed. This caused structures such as the velum to adhere to the slide or coverslip, distorting the structure (fig. 1d). Therefore, 70% ethanol was added to isolated spicules in Method 2 to prevent this (fig. 1e). Both Method 1 and Method 2 enabled re-orientation of spicules (using an eyelash hairbrush) if a study of the alternate surface of some spicules is required, even after initial SEM (fig. 1e). This enabled observation of the ventral barb on the right spicule of P. cyathopharynx, which is only visible from one side.

Using these methods, isolated spicules can furthermore be studied using LM to provide paratype and voucher specimens as an additional method to the study of whole mounts. In this case, isolated spicules could be mounted using mountants such as glycerol (sealed with nail varnish or similar substance to prevent drying) or in Canada balsam. Importantly, it is suggested that these methods not be used when only a few specimens are available, especially in the case of a potential new species, as the entire posterior end of the specimen is destroyed. Therefore, morphometry (including illustrations) of the posterior end could be done before performing any of these methods if required.

Acknowledgements

The authors thank the SPECTRUM analytical facility and the Department of Zoology (UJ) for equipment and facilities, and Lucinda Austin for initial technical support.

Financial support

The University of Johannesburg (UJ) for funding to APN (UJ-GES and UJ faculty merit bursary), QMDS (UJ-GES PDRF) and AAO (UJ-URC, UJ-FRC). The Oppenheimer memorial for PDRF funding to QDMS. The National Research Foundation of South Africa (South Africa/Austria joint scientific and technological cooperation; Reference number STGR180409318751, Unique Grant number 116067) for funding to AAO.

Conflicts of interest

All three authors contributed equally to the manuscript and agreed to the publication of the paper.

Ethical standards

Animal procedures were carried out adhering to the South African National Standard: Care and Use of Animals for Scientific Purposes (2008) in agreement with ethics approval from the University of Johannesburg (Protocols number: 2018-02-15/Gilbert and 2021-04-01/Nofal _Oldewage) and collection permit (CPE2-000129) issued by the Gauteng Department of Agriculture and Rural Development.

References

Al-Bassel, DA, Abu-Elhasan, SN, Abdel-Haleem, HM and Atwa, MTM (2022) Parasitic helminths of the freshwater catfish (Clarias gariepinus) from Fayoum Governorate, Egypt. Egyptian Journal of Zoology. https://dx.doi.org/10.21608/ejz.2022.150510.1086.CrossRefGoogle Scholar
Austin, L, Dos Santos, QM and Avenant-Oldewage, A (2023) Additional taxonomic data for Spinitectus petterae (Nematoda: Rhabditida) from Clarias gariepinus (Siluriformes: Clariidae) in the Vaal River system: conserved morphology or high intraspecific genetic variability? Folia Parasitologica 70(1), 002.CrossRefGoogle ScholarPubMed
Boomker, J (1982) Parasites of South African freshwater fish. I. Some nematodes of the catfish [Clarias gariepinus (Burchell, 1822)] from Hartbeespoort Dam. Onderstepoort Journal of Veterinary Research 49(1), 4151.Google Scholar
Bowen, A (2010) Electrolytic tungsten needle sharpening. The Microscope 58(1), 131134.Google Scholar
Brady, J (1965) A simple technique for making very fine, durable dissecting needles by sharpening tungsten wire electrolytically. Bulletin of the World Health Organization 32(1), 143144.Google ScholarPubMed
Eisenback, JD (1985) Techniques for preparing nematodes for scanning electron microscopy. Journal of Microscopy 2(1), 79105.Google Scholar
Gradinarov, D (2003) The second spicules type of Steinernema bicomutum (Nematoda: Steinernematidae) – an atavistic sign, showing the evolutionary connection with Neosteinernema. Acta Zoologica Bulgarica 55(3), 5558.Google Scholar
Ivashkin, V, Sobolev, A and Khromova, L (1977) Camallanata of animals and man and diseases caused by them. pp. 381 in Skrjabin, KI (Ed) Essentials of nematology, Vol. 22, Jerusalem, Keter Publishing House.Google Scholar
Moravec, F (1974) The development of Paracamallanus cyathopharynx (Baylis, 1923) (Nematoda: Camallanidae). Folia Parasitologica 21(4), 333343.Google ScholarPubMed
Moravec, F (1975) The development of Procamallanus laeviconchus (Wedl, 1862) (Nematoda: Camallanidae). Věstík Česko Slovenské Společnosti Zoologické 39(1), 2328.Google Scholar
Moravec, F (2019) Parasitic nematodes of freshwater fishes of Africa, Vol. 17, Prague, Academia.Google Scholar
Moravec, F and Jirků, M (2017) Some nematodes from freshwater fishes in central Africa. Folia Parasitologica 64(033), 139.Google ScholarPubMed
Moravec, F and Scholz, T (2017) Some nematodes, including two new species, from freshwater fishes in the Sudan and Ethiopia. Folia Parasitologica 64(010), 119.Google ScholarPubMed
Nofal, AP, Dos Santos, QM, Jirsa, F and Avenant-Oldewage, A (2022) Camallanid nematodes from Clarias gariepinus (Burchell, 1822) in the Crocodile River, Gauteng, South Africa: exploring diversity and divergence in an acid-mine drainage impacted environment. International Journal for Parasitology: Parasites and Wildlife 19(1), 196210.Google Scholar
Rammah, A and Hirschmann, H (1987) Morphological comparison and taxonomic utility of copulatory structures of selected nematode species. Journal of Nematology 19(3), 314323.Google ScholarPubMed
Rindoria, NM, Dos Santos, QM and Avenant-Oldewage, A (2020) Additional morphological features and molecular data of Paracamallanus cyathopharynx (Nematoda: Camallanidae) infecting Clarias gariepinus (Actinopterygii: Clariidae) in Kenya. Parasitology 106(1), 157166.CrossRefGoogle Scholar
Scholz, T, Vanhove, M, Smit, N, Jayasundera, Z and Gelnar, M (2018) A guide to the parasites of African freshwater fishes. Abc Taxa 18(1), 1425.Google Scholar
Svitin, R, Truter, M, Kudlai, O, Smit, NJ and Du Preez, L (2019) Novel information on the morphology, phylogeny and distribution of camallanid nematodes from marine and freshwater hosts in South Africa, including the description of Camallanus sodwanaensis n. sp. International Journal for Parasitology: Parasites and Wildlife 10(1), 263273.Google ScholarPubMed
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Fig. 1. (a) photograph of the coverslip–slide complex used in Method 2 – the arrow shows the placement of the overhanging coverslip and the dashed circle shows the position of the specimen; (b–g) light (LM) and scanning electron (SEM) micrographs of the tail region and isolated spicules of male Paracamallanus cyathopharynx (Baylis, 1923): (b) LM of tail region – solid arrow shows right (large) spicule and dashed arrow shows left (small) spicule; (c) LM of the tail region using differential interference contrast – arrow shows right (large) spicule; (d) SEM of isolated right (large) spicule – arrow shows velum adhering to the glass slide and inlay highlights adhered velum with dotted lines; and (e) SEM of the alternate surface of the ethanol-fixed isolated right (large) spicule – the inlay shows the unadhered velum.