In vitro sexual dimorphism establishment in schistosomes

Remi Pichon; Magda E Lotkowska; Jude LD Bulathsinghalage; Madeleine McMath; Mary Evans; Benjamin J Hulme; Kirsty Ambridge; Geetha Sankaranarayanan; Simon Kershenbaum; Sarah D Davey; Josephine E Forde-Thomas; Karl F Hoffmann; Matthew Berriman; Gabriel Rinaldi

doi:10.7554/eLife.111066.1

eLife Assessment

This useful study presents an improved protocol for long-term in vitro culture of Schistosoma mansoni that enables progression toward sexually dimorphic stages, representing a meaningful advance for studying parasite development and reducing reliance on animal models. The findings show that host-specific culture conditions support essential developmental and metabolic functions required for parasite maturation, although development remains delayed compared to in vivo conditions. The evidence is solid overall, but limited pairing efficiency and the absence of egg production indicate that the system does not yet fully recapitulate complete reproductive development.

https://doi.org/10.7554/eLife.111066.1.sa4

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Abstract

Schistosomes are parasitic flatworms that cause Schistosomiasis, a major Neglected Tropical Disease (NTD) that affects more than 250 million people worldwide. With two morphologically distinct sexes, a heterogametic female (ZW) and a homogametic male (ZZ), schistosomes are an exception among flatworms, which are largely hermaphroditic. Sexual dimorphism in schistosomes only becomes apparent by adulthood within the mammalian host. The cellular and molecular mechanisms underlying the sexual differentiation of these parasites are poorly understood, partly due to intrinsic challenges in assessing parasite development in vivo. Therefore, robust and reproducible approaches for maintaining and developing parasites in vitro may help to overcome these difficulties. However, to date, only a few studies have focused on protocols that allow cultured parasites to reach sexual dimorphic stages, and none have been reproduced, limiting the ability to understand the unique sexual biology of this major human parasite. Here, we refine a protocol for long-term culture of newly transformed cercariae that developed in vitro into sexually dimorphic forms. We assessed the effect of two different sera, Foetal Bovine Serum (FBS) and Human Serum (HS), added to the culture medium supplemented with human red blood cells. We found that in contrast to FBS-cultured worms, HS-cultured parasites digested red blood cells, a crucial step for long term parasite culture. Additionally, while most FBS-cultured parasites did not progress beyond an early liver stage, sexual dimorphism was clearly established in the HS-cultured worms, albeit delayed compared to in vivo development. Moreover, EdU pulse-chase experiments revealed a continuous proliferation of parasite cells over time in HS-cultured parasites, while a significantly lower number of proliferating cells were detected in FBS-cultured worms. This protocol paves the way to study parasite development in vitro, positively impacting the principles of the 3Rs (Replacement, Reduction and Refinement) for animal research, and allowing for in-depth studies of sexual dimorphism establishment as well as in vitro screening for novel control strategies across the life cycle of these major human parasites.

Introduction

Schistosomiasis, a major Neglected Tropical Disease (NTD) affecting >250 million people worldwide, is caused by the infection with blood flukes (class Trematoda) in the genus Schistosoma¹. The pathology associated with schistosomiasis is largely driven by egg trapping in different tissues depending on the species. The infection with Schistosoma mansoni leads to eggs lodged mainly in the liver inducing inflation, fibrosis and granuloma formation². This suggests that interfering with the sexual development of these parasites could potentially restrict human pathology. Currently, the complete reliance on a single drug (Praziquantel), to treat the infection and its use in drug mass administration programs in endemic areas threatens the development of drug resistance³. Therefore, identifying novel targets for alternative, more efficient control strategies is a priority that could be addressed by elucidating mechanisms involved in schistosome development, including the establishment of sexual dimorphism.

While most of the parasitic flatworms are hermaphrodites, schistosomes are dioecious with genetically determined female (2n=16, ZW) and male (2n=16, ZZ) individuals. Whilst male and female parasites are morphologically indistinguishable across most developmental stages, sexual dimorphism becomes apparent by adulthood within the mammalian host⁴. Male and female worms undergo separate but concurrent sexual differentiation of their gonads and somatic tissues that eventually allows intersexual pairing, a critical step for female maturation, egg production and life cycle propagation^5,6. Transcriptomic studies, at both the bulk^7–11 and single cell^12–14 levels, have revealed key pathways and molecular mediators underlying this critical process of female sexual maturation induced by pairing. However, the cellular and molecular mechanisms driving sexual dimorphism prior to pairing remain poorly characterised, partly due to intrinsic challenges in assessing the development of the parasite in vivo¹¹.

Approaches for better understand the biology of parasites at large have been developed and optimised using in vitro or ex vivo refined culture systems^15,16. Combinations of culture media components, sera from different sources and additives have been tested^17,18. In addition, organ-on-a-chip systems and organoid-based 2D and 3D culture platforms^19,20 have first been implemented for protozoa parasites such as Plasmodium, Toxoplasma, and Cryptosporidium species. These methods have facilitated the molecular dissection of processes underlying single-cell parasite development and interaction with the host^21–23. Recently, these technologies have started to be transferred to metazoan parasites to study host-parasite interaction and immune response in the context of helminth infections^24–28. In vitro cultivation of both larval tapeworms (cestodes) and stem cells isolated from cestodes, coupled with ‘omic’ and imaging analyses have unveiled the role of stem cells in parasite development^29,30. However, despite these significant developments in the field, reproducing the natural development of trematodes under controlled in vitro conditions remains extremely challenging¹⁶.

Significant progress was achieved in culturing schistosomes when, more than forty years ago, Paul F. Basch developed and optimised comprehensive culture protocols for intra-mammalian developmental stages of schistosomes^31–33. Basch reported for the first time the development of male and female parasites from cercariae, with worm pairing and production of infertile eggs entirely in vitro ³¹. Remarkably, to the best of our knowledge, these results have not been replicated and no further attempt to obtain egg-laying worm pairs developed in vitro from cercariae has been reported since Basch’s seminal studies¹⁶. More recently, in vitro culture protocols for schistosomes have been refined either to maintain ex vivo parasites collected from infected mice to study parasite reproduction biology^34,35, or to culture juvenile parasites from cercariae and develop drug screening approaches^36–39. However, no long-term culture conditions to specifically assess schistosome sexual differentiation have been reported since 1981³². Despite one research group referring to the approach⁴⁰, there has been no detailed description and no widespread adoption. In fact, published culturing studies have continued to utilise FBS^34,41.

Novel functional approaches applied to culture systems that allow reliable and reproducible in vitro establishment of sexual dimorphism will shine new light into molecular mechanisms underlying schistosome intra-mammalian development. Here, we refined a protocol for long-term culture of newly transformed cercariae by assessing the effect of two different sera, Foetal Bovine Serum (FBS) and Human Serum (HS), added to the medium supplemented with human Red Blood Cells (hRBCs). Striking differences were evident between parasites maintained in either FBS or HS. First, hRBC were digested and hemozoin became apparent in the intestines of HS-cultured parasites within 5 days in contrast to FBS-cultured parasites that mostly lacked visible hemozoin. Second, while most of the FBS-cultured parasites did not progress beyond lung and early liver stage, HS-cultured parasites reached sexually dimorphic stages, albeit at a slightly delayed rate compared to in vivo development. Furthermore, phenotypic differences between FBS- and HS-cultured parasites became evident as early as 48 hours in culture, with HS-cultured parasites exhibiting higher rates of cell proliferation. Taken together, this protocol allows early sexual development of schistosomes to be studied in vitro, provides a method for high throughput drug screening targeting parasite development, and reduces the reliance on mammalian hosts in research.

Results

Sexually dimorphic schistosomes developed entirely in vitro from cercariae

Searching for culture media able to cultivate parasites from cercariae to maturity, we decided to test Human Serum (HS) compared to the commonly used Foetal Bovine Serum (FBS). This rationale is based both on the fact that humans are the definitive host of schistosomes, and that two previous reports in 1981 showed that HS was capable of producing mature schistosomes in vitro^31,32, but they were never replicated. Therefore, to ascertain the in vitro sexual dimorphism establishment of schistosomes entirely developed from cercariae, we compared the effect of two different sources of blood serum: FBS and HS. The development of schistosomula derived from mechanically transformed cercariae was assessed in at least 15 independent experiments, five of which were maintained over a period of at least 10 weeks (Figure 1A; Supplementary Table S1).

Dimorphic female and male schistosomes entirely developed *in vitro* from cercariae.
A. Schematic representation of the collection and mechanical transformation of cercariae into schistosomula for long-term *in vitro* culture. B. Morphological scoring of cultured S. *mansoni* schistosomula at the indicated time points after *in vitro* transformation (week 1 to week 10) for worms in Long Term Culture (LTC) medium supplemented either with Human Serum (HS - left) or Foetal Bovine Serum (FBS - right). Heatmap columns represent five distinct morphological categories, and rows indicate 5 independent culture experiments, i.e. parasites obtained from different batches of infected snails. Heatmap colours represent the percentage of worms for each replicate in each morphological category. Middle panel: Representative images of *in vitro* schistosomula cultured in either HS or FBS as indicated. Scale bars: 100 µm. Category 1: Early schistosomula; Category 2: Lung schistosomula; Category 3: Early liver schistosomula; Category 4: Late liver schistosomula; Category 5: Dimorphic schistosomula.

No morphological differences were observed between parasites cultured either in FBS or HS within the first week in culture; in both conditions most parasites (76% in FBS and 72% in HS in average) were classified as early schistosomula (Supplementary Figure S1) with few lung and early liver schistosomula (Figure 1B, Week 1). The mean mortality at Week 1 was slightly higher, but not statistically significant (P= 0.8), in worms cultured in HS (11.3 ± 2.7%) compared to the mortality registered in FBS-cultured parasites (5 ± 2.3%), consistent with previous findings³⁸.

From Week 2 onwards, differences in parasite development between the two conditions became apparent (Figure 1B). Parasites cultured in FBS were no longer able to develop beyond early liver stage (14.8% in average), with the vast majority of worms (79% in average) still stunted and classified as early and lung schistosomula. The mortality rate of FBS-cultured parasites continued to increase, reaching an average of ∼80% by Week 10, after which the experiments under this condition were stopped as most parasites were dead (Supplementary Figure S2). On the other hand, parasites cultured in HS further developed over time throughout all categories, achieving marked sexual dimorphism by Week 6 (Figure 1B; Supplementary Figure S3A), confirmed by PCR (Supplementary Figure S3B; Supplementary Table S2). As previously described for the in vivo development of schistosomes¹¹, the in vitro cultured parasite showed developmental asynchrony in agreement with Basch’s observations³²; however, by Week 10 the majority of the worms (73.7 ± 25.4%) have acquired sexual dimorphism (Figure 1B).

The differences in parasite development between the two tested conditions were also confirmed by measuring worm areas at different time points in culture (Figure 2; Supplementary Table S3). Parasites cultured in the presence of HS grew exponentially over time to reach ∼0.1 mm², ∼24-fold larger than parasites cultured in FBS for 10 weeks, which only grew slightly, plateauing at an average 0.005 mm², similar to the size reached by parasites after only two weeks in HS (Figures 1 and 2).

Parasites cultured in Human Serum grew in size unlike those cultured in Foetal Bovine Serum.
Bar plot representing area measurements of schistosomula developed *in vitro* and cultured in media complemented either in Foetal Bovine Serum (FBS) or Human Serum (HS) at indicated weeks after cercarial transformation. Bars indicate mean area (µm²) ± SEM. HS: Human Serum (light brown); FBS: Foetal Bovine Serum (blue). *: P-value < 0.05 in indicated pairwise comparisons.

Parasites developed in human serum readily digest red blood cells

It is widely accepted that within the mammalian host schistosomes begin to feed on blood cells through their digestive tract at 10 days post-infection; at this time the majority of the parasites have left the lungs and started to colonise the portal system veins in the liver⁴². On the 13^th day of culture, human Red Blood Cells (hRBCs) were added to the parasites to allow them to feed and thus continue their development. At this point, they begin to capture and degrade erythrocytes producing hemozoin, a black pigment derived from host haemoglobin degradation and visible in the worms’ intestines. Even though few parasites in FBS reached the early liver stage within the first week in culture, a minority of them were able to digest hRBCs (3.6 ± 4.7 %), indicated by displaying black guts (BG+, Figure 3). In contrast, a significant proportion of HS-cultured parasites (36.2 ± 33.6 %) had already reached the early liver stage by the second week in 3 out of 5 experiments (Figure 1B, Week 2). Moreover, parasites cultured in HS displayed a functional digestive system capable of assimilating hRBCs; more than half of the HS-cultured parasites (65 ± 6 %, P-value < 0.05) were BG+ in comparison to FBS-cultured parasites (3.7 ± 4.7 %) (Figure 3; Supplementary Table S4).

Development of parasites in human serum may be driven by stem cell proliferation

The growth and development of an organism is driven by a finely regulated combination of cell hyperplasia, hypertrophy, and apoptosis across different tissues⁴³. In schistosomes, a complex stem cell system comprised of both somatic and germline stem cells has been described by leveraging recent single cell transcriptomics⁴⁴. Therefore, we decided to investigate whether the differences in development, growth and feeding capacity between parasites cultured in either FBS- or HS-complemented medium were associated with distinct cellular proliferation rates. EdU pulse-chase experiments revealed notably lower cell proliferation in FBS-cultured parasites as early as 2 days post transformation (Figure 4). It has previously been demonstrated that a group of 5 well-defined somatic stem cells is the only set of cells that actively proliferate in 2-day schistosomula⁴⁵. Hence, the proliferating cells observed and quantified in our study were most likely stem cells (Supplementary Figure S4; Supplementary Video S1). The difference between the number of proliferating stem cells in parasites cultured in FBS or HS increased significantly over time. HS-cultured schistosomula showed higher numbers of proliferating stem cells, with an average of >60 EdU+ cells per worm (Figure 4), whereas most FBS-cultured parasites remained stunted in the lung or early liver stages. These stunted worms displayed no more than an average of 20 EdU+ cells per worm (Figure 4). hRBCs were added at day 13 post-cercarial transformation to both FBS- and HS-complemented culture media. Worms kept in FBS or HS in the absence of hRBCs were included as controls. Regardless of the serum employed, no significant differences in the numbers of proliferating cells were observed between worms cultured in the presence or absence of hRBCs (Supplementary Tables S5 and S6).

In vitro cultured schistosomes display sexual dimorphism, developing reproductive systems and pairing capacity

In vitro-developed schistosomes began to show sexually dimorphic features from day ∼42 onwards in HS-complemented culture medium (Figure 1, Week 6). Confocal microscopy of DAPI- and Phalloidin-stained in vitro cultured male worms confirmed the presence of gynaecophoric canal, developing 3 to 5 testis lobes containing sperm cells, and cirrus (Figure 5A-D; Supplementary Video S2). Likewise, we confirmed the presence of primordial ovaries, oviduct, ootype and uterus in female parasites entirely developed in vitro (Figure 5E-H; Supplementary Video S3). In some experiments sexually dimorphic parasites cultured in HS medium were kept alive for more than 150 days (Supplementary Figure S5). While the establishment of sexual dimorphism was robust and reproducible across more than 15 independent experiments, pairing between male and female parasites was rare. Pairing was observed in ∼7% of the experiments, and usually after day ∼80 in culture (Figures 6A and 6B; Supplementary Video S4).

*In vitro* cultured schistosomes display sexual dimorphism and developing reproductive systems.
Representative confocal microscopy images of *in vitro* developed male (A-D) and female (E-H) at day 60 in culture. Worms shown in panels G and H are different individuals. CellMask Green Actin Tracking Stain: green, DAPI: grey (A-E, G), cyan (F, H). C: Cirrus. T: Testis, OS: Oral sucker. VS: Ventral sucker. GC: Gynaecophoric canal. G: Gut. GP: Genital pore. U: Uterus. O: Ovary. Oo: Ootype. OV: Oviduc. S: sperm. Scale bar: 50 µm.

*In vitro* cultured schistosomes are capable of pairing.
**A, B:** Representative bright-field images of pairs of schistosomes developed entirely *in vitro* after 80 (A) and 150 (B) days of culture in culture medium supplemented with HS. Scale bars: 500 µm (A), 100 µm (B). **C, D**: Representative bright-field images of a worm pairs between *ex vivo-*collected males and *in vitro-*developed females (C) and *ex vivo-*collected females and *in vitro*-developed males (D) within 24 hours after placing the worms in the same well to facilitate pairing. Scale bars: 100 µm, **E, F**: Confocal microscopy image of a schistosome pair (*ex vivo*-collected male and *in vitro*-developed female) *in copula* (E), and magnification of the ovarian area, highlighting maturing oocytes (F). CellMask Green Actin Tracking Stain: green, DAPI: grey, CellMask Deep Red Plasma Membrane Stain: magenta. Scale bar: 150 µm (E), 50 µm (F).

Considering the rarity of the pairing between in vitro developed worms, we investigated whether these parasites display the capacity of pairing with in vivo developed worms collected from experimentally infected mice. Male and female adult worms developed in vivo and recovered from mice by portal perfusion on day 42 post-infection, were sorted by sex and placed in the same tissue culture plate well with worms of the opposite sex developed in vitro (>70 days). Within 24 hours after co-culturing the in vitro developed with ex vivo collected worms, couples were observed (Figure 6C, D; Supplementary Video S5). These findings suggested that the in vitro developed and sexually dimorphic parasites are capable of intersexual pairing. Moreover, in vitro developed females coupled with ex vivo collected mature males displayed signs of primordial ovaries maturation with larger oocytes towards the posterior region of the ovary (Figure 6E, F; Supplementary Video S6). Remarkably, in more than 30 independent in vitro culture experiments, where male and female parasites developed sexual dimorphism and eventually paired up, no eggs were produced or laid. This indicates that further refinements in the culture protocol are needed to accelerate the parasite development (the in vitro development is delayed compared to the in vivo development), increase the likelihood of pairing, and facilitate the production of eggs.

Discussion

Recent progress in culture systems and functional genomic tools is allowing researchers to address long standing questions in helminth biology that were previously inaccessible to experimentation^46–50. Among these enduring questions, stand those related to the unique sexual biology of the trematode family Schistosomatidae. Schistosomes are dioecious with genetically determined female and male individuals, which is unusual for flatworms^4,51. However, the sexual dimorphism of male and female schistosome worms only becomes established within the mammalian host, and represents a critical step towards worm maturation, intersexual pairing, and egg production⁵². A better understanding of the molecular and cellular basis underlying sexual dimorphism establishment in schistosomes would lead to approaches to block parasite development and life cycle propagation. Studying the sexual development of schistosomes by performing controlled experiments in which parasites can be co-cultured, genetically manipulated or treated with different compounds requires robust and reproducible protocols for long-term in vitro culture.

Culture protocols have recently been developed to maintain ex vivo schistosomes collected from infected mice^34,35, or to obtain juvenile parasites from cercariae for drug screening experiments^36–39. However, no long-term culture conditions have been successfully refined to experimentally assess sexual differentiation and dimorphism establishment in schistosomes. Here, aiming to refine a culture medium formulation that supports in vitro parasite development and establishment of sexual dimorphism, we decided to compared the effect of modified Basch’s media¹⁸, supplemented with human Red Blood Cells (hRBCs) and 20% of either Fetal Bovine Serum (FBS) or Human Serum (HS). While initial parasite survival and development appeared comparable in both conditions during the first week in culture, striking morphological differences emerged from Week 2 onwards. Parasites cultured in HS, progressed through all developmental categories, and acquired sexual dimorphism by Week 6. On the other hand, parasites maintained in FBS were stunted at early stages (mainly lung stage). These experimental outcomes were consistent with the findings reported by Paul F. Basch³¹ in 1980. Probably, from the 1980s onwards a combination of factors that include ethical concerns, variability associated with human-derived products and safety considerations related to blood borne viruses such as HIV, and Hepatitis B and C, determined that parasitologists favoured the use of FBS over HS for helminth culture. FBS has been extensively used in cell culture media, refined and adapted to diverse human and animal cell types since 1958⁵³ providing a reliable source of amino acids, carbohydrates, hormones, lipids, proteins, vitamins, and growth factors⁵⁴. Nevertheless, the scientific community is increasingly advocating for the replacement of FBS as a supplement in tissue culture⁵⁵. This trend is driven by limitations associated with FBS, including the presence of undefined tentatively harmful factors for the cells in culture, lack of reproducibility, lack of transparency in its production, and critically ethical concerns related to animal welfare⁵⁶.

Our protocol, that supports a fully in vitro development of schistosomes, would also positively impact the 3Rs (i.e., Reduction, Replacement, Refinement) for minimising the use of animals for research and serum production^57,58.

Parasites cultured in the presence of HS not only developed into sexually dimorphic male and female worms, but strikingly, were able to digest hRBC and process haemoglobin within one day after the addition of hRBC. These findings may reflect differences in the gastrodermis development; worms cultured in the presence of HS may display a differentiated gastrodermis that enables haemoglobin digestion and accumulation of hemozoin within the intestines⁵⁹. On the other hand, most parasites cultured in FBS were unable to produce hemozoin in the presence of hRBCs. This may be due to impaired gastrodermis differentiation that ultimately would lead to stunted development and death. Hematophagous parasites including Plasmodium species and schistosomes, obtain key nutrients via the proteolysis of host hemoglobin. However, this process leads to the production of free-heme groups which in turn generate highly toxic oxygen free radicals and lipid peroxidation⁶⁰. These toxic free-heme derivatives become inactive when aggregated into an inert crystalline polymer, named hemozoin, observed as dark pigment within the intestines of schistosome intra-mammalian stages⁵⁹. In addition, increasing evidence shows that hemozoin may play critical roles during parasite development by supplying iron for egg production⁵⁹, and interaction with the mammalian host by an immune modulatory role⁶¹. In the mouse model, schistosomula begin to feed on blood once they have left the lungs and reached the portal system 9 to 11 days post infection^42,62. Moreover, schistosomula collected from experimentally infected mice at day 13 post infection already show hemozoin in their guts¹¹. Similarly, HS-developed schistosomula were able to feed on blood in vitro within a comparable time window; hRBCs were added in the medium on day 13 in culture, and within 24 hours most of the parasites’ gut contained hemozoin. These findings suggest that our in vitro culture system successfully recapitulates in vivo gastrodermis development of schistosomula. A better understanding of the in vitro development of the parasite gastrodermis and its role in the production of hemozoin will expose tentative novel targets for control⁶³.

Although previous reports have shown that it is possible to cultivate parasites in cell-free environments^38,64, adding hRBC has proven essential for long-term maintenance of parasites and for establishing sexual dimorphism. EdU pulse-chase experiments suggested that schistosome in vitro development in the presence of HS may be driven by the proliferation and differentiation of stem cells. The stem cell system in schistosomes has been extensively studied since the first description of somatic stem cells in adult worms⁶⁵, followed by single cell transcriptomic identification and functional characterisation of three key stem cell populations in intra-snail stages⁴⁵. Two of these stem cell types, maintained in intra-mammalian stages, proliferate and differentiate into precursors of somatic and germ line cells throughout development¹³. Although we have not performed transcriptomic analyses in this study, the positive correlation between number of EdU+ cells, and growth (determined by increasing worms’ area) and gross development in HS-developed parasites was evident already within the first 48 hours in culture. These findings indicate that stem cells may play a central role in driving organised growth, tissue differentiation and ultimately the establishment of the sexual dimorphism in HS-developed parasites. Conversely, FBS-cultured parasites displayed no more than 20 EdU+ cells per worm in average, reaching a plateau in the number of proliferating cells from day 8 in culture, which probably underlie the arrested development of these worms. Overall, the FBS-cultured parasites did not progress beyond the lung stage. Consistent with these findings, confocal microscopy imaging revealed in HS-developed parasites clear somatic and reproductive anatomical structures, including male gynaecophoric canals and testes, as well as female ovary primordia, oviducts, ootypes and uteri. These developmental features illustrate the capacity of our culture system to capture key biological transitions previously only accessible from experimentally infected animal models. That said, while our system was highly efficient in producing sexually dimorphic worms, spontaneous pairing between male and female parasites was extremely rare, mainly in aged in vitro cultures (from 80 to 100 days in culture) indicating that other factors, e.g., cholesterol, may be missing³⁴. In any case, we decided to test the pairing capacity of the dimorphic worms by conducting pairing experiments between in vitro-developed females and ex vivo-collected males, and vice versa. Strikingly, couples were observed within 24 hours after co-cultivating in vivo and ex vivo opposite sex parasites, albeit no eggs were produced. However, we observed evidence of pairing-trigger oocyte maturation in in vitro-developed females paired with ex vivo-collected male worms. Our research group has recently been involved in the discovery and functional characterisation of a transcription factor of the retinoic acid receptor family, SmRAR, and related genes⁶⁶. SmRAR and associated genes may play a key role in oocyte differentiation triggered by pairing. Our pairing experiments and confocal imaging analyses suggested that in vitro developed female oocytes started to differentiate after pairing with an in vivo developed male worm, probably mediated the activation of the SmRAR pathway⁶⁶. Moreover, the involvement of a male-derived nonribosomal peptide pheromone, i.e., β-alanyl-tryptamine or ‘BATT’, in the pairing-driven female sexual maturation was demonstrated⁵. In addition, soluble factors produced by the worms with effect on the opposite sex cannot be ruled out⁶. It has been suggested that host-derived factors, such as the cytokine transforming growth factor β (TGF-β) may be critical for female reproductive development and embryogenesis⁶⁷. More recently, other host-derived factors that include cholesterol and ascorbic acid have been shown to be critical for maintaining ex vivo fully mature females collected from infected mice³⁴. Further research is needed to assess the role of these host- and parasite-derived cues in schistosome development.

In summary, we have demonstrated that the presence of HS is essential to support fully in vitro development of S. mansoni parasites from mechanically transformed cercariae to sexually dimorphic adults. Differences in the numbers of proliferating stem cells between worms developed in HS versus FBS were observed as early as 48 hours in culture. These findings may raise some concerns about studies that rely on in vitro culture protocols using FBS, including those focused on parasite developmental biology, interaction with the host, and drug screening. Human serum contains essential host-specific molecules that are absent or insufficient in FBS, and future efforts should aim to identify these factors. Optimising schistosome long-term culture systems will: (1) deepen our understanding of fundamental aspects of schistosome biology, development and host-parasite molecular crosstalk; (2) positively impact the 3Rs principles for animal research; and (3) reveal tentative targets for novel control strategies.

Material and Methods

Ethics statement

The complete life cycle of Schistosoma mansoni (NMRI strain) was maintained at the Wellcome Sanger Institute (WSI) and Aberystwyth University (AU), by infecting Biomphalaria glabrata snails and outbred mice (TO strain). All the animal regulated procedures were conducted under Home Office Project Licences P77E8A062 (WSI) and PP2955700 (AU), following the ARRIVE guidelines (https://arriveguidelines.org) and in accordance with guidelines and regulations stated by the UK Animals (Scientific Procedures) Act 1986 Amendment Regulations 2012. All the protocols were presented and approved by the Animal Welfare and Ethical Review Bodies (AWERB) of the WSI and AU. The AWERB is constituted as required by the UK Animals (Scientific Procedures) Act 1986 Amendment Regulations 2012. Human blood products, including serum and red blood cells were obtained from NHS Blood and Transplant (NHSBT), Non-Clinical Issue (NCI) services for research purposes. NHSBT-NCI provides donated material surplus to clinical requirements or unsuitable for therapeutic use that has been appropriately consented. The supply chain complies with all statutory and regulatory obligations including (but not limited to) the Human Tissue Act (2004) and associated Codes of Practice. The NHSBT-NCI products were acquired under the Study ‘In vitro development of the human parasite Schistosoma’, Integrated Research Application System (IRAS) project ID 319400, protocol number AU/DLS/011, Research Ethics Committee (REC) reference number 23/SS/0017.

Cercariae transformation and culture of schistosomula

Schistosoma mansoni (NMRI strain) schistosomula were obtained and cultured as previously described with minor modifications¹⁸. In brief, patent mix strain of Biomphalaria glabrata snails⁶⁸ experimentally infected en masse with ∼20 miracidia per snail, were thoroughly rinsed, transferred to Lepple water (∼100 ml) and exposed to light for 2 h at 26 °C to induce cercarial shedding. Cercariae were collected, passed through a 100 μm filter into 50 ml tubes to remove snail debris and faeces, placed 1 h on ice, and concentrated by centrifugation (300 g for 3 min at 4°C with half break deceleration). Cercariae were washed 3 times in 1X PBS supplemented with 200 U/ml penicillin, 200 μg/ml streptomycin, 500 ng/ml amphotericin B (Merck). During the washes, the cercarial pellets were successively combined and finally resuspended in ‘Schistosomula wash medium’ (Dulbecco’s modified Eagle medium - DMEM, supplemented with 10 mM Hepes, 200 U/ml penicillin, 200 g/ml streptomycin, 500 ng/ml amphotericin B). Cercariae were vortexed full speed for 30 sec and placed on ice for 1 min. Thereafter, the cercarial tails were sheared off by ∼10 back and forth passes through a 19-gauge (19-G) needle, a ∼3 μl aliquot of parasites inspected under microscope to confirm that >90% of cercariae had their tail removed, and the cercarial heads were separated from the tails by a Percoll (Merck) gradient (1.5:1 percoll:DMEM) and centrifugation (300g for 15 min at 4 °C, half break deceleration). The pellet containing purified cercarial heads, was collected and washed 3 times by centrifugation (300g for 3 min at 4°C) in ‘Schistosomula wash medium’. Newly transformed schistosomula were counted in 12 5μl-aliquots under the microscope. To reduce parasite mortality due to a high density of worms, ∼8,000 schistosomula were transferred to each well of a 6-well tissue culture plate (Fisher Scientific, Loughborough, UK) containing 5 ml of modified Basch’s medium¹⁸ supplemented with additives and FBS or HS heat-inactivated FBS or HS serum, i.e., ‘Long-term culture medium’ (LTC) as indicated in Table 1. Parasites were cultured in a tissue culture incubator at 37°C under 5% CO₂ in air. Washed human red blood cells (hRBCs) were added into the culture medium at indicated time points. LTC medium was replaced twice a week and washed hRBCs added to a final concentration of 0.02% v/v at indicated days after transformation. All human blood products, obtained from NHSBT-NCI, were handled with universal precautions within a biosafety cabinet class II and suitable PPE. The HS was heat-inactivated at 56°C for 30 min in an incubator, aliquoted and stored at −20°C until use. The hRBC were washed in ‘Schistosomula wash medium’ and stored at 4°C until use as previously described¹⁸. Briefly, the hRBCs were transferred from the pack to 50 ml tubes and washed by centrifugation at 500g for 5 min at 4°C. Half the supernatant was removed, tubes’ content combined, centrifuged as above and resuspended in ∼25 ml of ‘Schistosomula wash medium’. The washes were repeated 4 more times.

Long term culture medium (LTC medium) composition.

Phenotype scoring of developing schistosomula

To analyse the in vitro development of schistosomula, images and videos were taken at regular intervals of at least once a week in >10 independent culture experiments, using a digital Euromex camera connected to an Olympus CK2 optical microscope. Up to 18 pictures per experiment with an average of ∼400 worms per picture were used for parasite staging from at least 5 independent experiments (Supplementary Table S1). The investigators who assigned categories were blinded to experiment conditions. Based on a well-defined staging system^11,32, the parasites were classified into 6 developmental categories as described³⁸ (Supplementary Figure S1); category 0: dead parasites showing granulation, rounded shape and degraded or broken tegument - the number of dead parasites may be underestimated due to the loss of some dead worms during the media change; category 1: newly transformed schistosomula, corresponding to the in vivo ‘skin stage’, these worms retain the cercarial head shape with no visible internal structures such as gut; category 2: lung stage schistosomula, elongated and slim worms, usually with a bulged end; category 3: early liver stage, bigger and wider worms compared to the previous stage, with hemozoin pigment (i.e., haemoglobin degradation product) and two ceca gut; category 4: late liver stage, in which the gut is further developed, the two intestinal ceca have fused behind the ventral sucker, and the parasites started to acquire an evident vermiform shape; category 5: sexually dimorphic stage, comprising large, vermiform male- and female-looking worms. The females are longer and thinner than males, the ceca fusion localises closer to the anterior end of the worm (i.e., ∼⅓ of the worm length from the anterior end), and both suckers are smaller compared to the male suckers. The male worms are characterised by a larger and wider head, larger suckers, the ceca fusion closer to the posterior end of the animal (i.e., ∼⅔ of the worm length from the anterior end), and a clearly visible gynecophoral groove^11,32.

To quantify positive or negative parasites for the presence of hemozoin within their intestines, i.e., black guts + (BG+) or BG- parasites, respectively, hRBCs were added to the culture at day 13, and one or two days later bright field microscopy images were taken. Counts of BG+ and BG- parasites were collected from 5 independent in vitro culture experiments. Statistical analysis was performed by ANOVA followed by Tuckey’s post-hoc multiple pairwise comparison with P≤0.05 considered significant (Supplementary Table S6).

Measurement of parasite area

Images of in vitro developing parasites were taken at weeks 1, 2, 3, 4, 6, 8 and 10 after cercariae transformation with an Euromex camera fitted to an Olympus CK2 optical microscope at 4x and 10x magnification. For these magnifications images of scale bars were captured for pixel to area values (µm²). Parasites from 5 independent long-term culture experiments were masked in COCO format from captured images using the CVAT (Computer Vision Annotation Tool) online server (https://www.cvat.ai/). Area metrics were then calculated for each parasite by leveraging the pycocotools package in a customised Python script. Raw and processed data is provided in Supplementary Table S3. Normal distribution was checked using Shapiro test and Mann Whitney tests performed with a significant value set up for P≤0.05 (Supplementary Table S6).

PCR for sexing and confirmation of sexual dimorphism

To confirm the in vitro establishment of sexual dimorphism, parasites were individually collected from culture by day ∼80, for blind sex assignment by bright field microscopy and confirmation by sex-specific PCR⁶⁹ (Supplementary Figure S3B). Briefly, pictures from individual in vitro developed parasites were taken and sex assigned based on morphological features. Thereafter, genomic DNA from the sex-assigned individual parasites was extracted by lysing the worms at 95°C for 1h in 50mM NaOH, 0.4mM disodium ethylenediaminetetraacetic acid (EDTA), followed by the addition of neutralising buffer (80 mM Tris–HCl in water). Samples were stored at 4°C until use. PCR reactions were performed in a final volume of 10 μl consisting of 5 μl Platinum 2X hot start PCR master mix (Invitrogen, California, USA), 0.5 μl (10 μM stock) of forward and reverse primers targeting W1 repeat⁷⁰ and actin⁷¹ (Supplementary Table S2), 1 μl of template DNA and 3 μl of water. The PCR program comprised an initial denature step at 94°C for 2 min followed by 30 cycles of denature at 98°C for 5 secs, and annealing/elongation at 60°C for 15 secs. The PCR products were resolved on a 1% agarose gel using 1% TAE buffer and 1kb GeneRuler DNA ladder (Thermo Scientific, UK).

Detection and quantification of proliferating cells

Parasites cultured for 15 days (D15) in media supplemented with either HS or FBS and hRBC added at D13 were harvested at days 2, 8 or 15 after cercariae transformation. Parasites cultured under the same conditions but with no hRBC were included as controls. The day before each indicated time point, a solution of 5-ethynyl-2’-deoxyuridine (EdU) was added to the culture medium at 10 μM final concentration. At each indicated time point, parasites from each group were collected and transferred to a 35 µm mesh basket (CEM Microwave Tech) in a well of a 24-well plate, washed in 1x PBS, fixed in 4% Paraformaldehyde (PFA) in 1x PBS for 30 min, washed in 1x PBS and stored at 4°C until use. The worms were incubated in PBST (1x PBS + 0.3% Triton x-100) ccontaining 2μl of Proteinase K (20 mg/ml) for 5 min at room temperature, washed three times in PBST, fixed in 4% PFA in 1x PBS for 10 min at room temperature and washed 5 times in PBST. EdU-positive cells were revealed by incubating the parasites for 30 min in the dark in a solution containing Azide fluor 488 (Sigma-Aldrich), diluted in a solution of 1 mM CuSo4, 0.025 mM Azide fluor 488, 95 mM L-Ascorbic Acid in 1x PBS. The worms were washed 5 times in PBST and incubated in mounting media containing DAPI (Fluoromount-G™ Mounting Medium, with DAPI, Invitrogen) before mounting for confocal microscopy (Leica SP8 super resolution laser confocal microscope). EdU+ cells per parasite were counted for an average of 100 parasites across three independent experiments. Statistical analysis was performed by Kruskal-Wallis test with Dunn multiple comparison post-hoc test, with P≤0.05 considered significant (Supplementary Table S6).

Pairing experiments

Schistosoma mansoni adult male and female worms were collected from experimentally infected mice at 47 days post infection¹⁸. Briefly, mice were euthanised by intraperitoneal injection of 200 μl of 200 mg/ml pentobarbital supplemented with 100 U/ml heparin, and worms collected by portal perfusion (the hepatic portal vein was sectioned followed by intracardiac perfusion with phenol-red-free DMEM, containing 10 U/mL heparin) and washed in DMEM. In 24-well plates, in vitro developed female worms were cultured in the presence of in vivo developed male worms and vice versa at a ratio of 1 female every 2 males in the well containing culture medium (Table 1) supplemented with 20% HS. The parasites were cultured for several days in an incubator at 37°C, 5 % CO2 and checked daily under microscope for the presence of pairing.

Parasite staining and confocal imaging

Live parasites collected from culture at indicated time points were stained with 1:1000 dilutions of CellMask^TM Green Actin Tracking Stain (Invitrogen) and CellMask^TM Deep Red Plasma Membrane Stain (Invitrogen) to label polymerized/filamentous actin (F-actin) and cell membranes, respectively. Nuclei were stained by adding two drops per millilitre of NucBlue^TM Live ReadyProbes^TM Reagent (Invitrogen). After an overnight incubation at 37°C, worms were collected in 15 ml tubes, washed by gravity 3 times in 1x PBS, fixed in 4% PFA (in 1x PBS) overnight at 4°C, washed 3 times in 1x PBS and stored in 200 μl of Fluoromount-G, with DAPI (Invitrogen) before mounting on slides for confocal microscopy. All the images were acquired using a Leica SP8 super resolution laser confocal microscope.

Data availability

All raw data and statistical analyses provided in Supplementary Tables.

Acknowledgements

The authors thank Julie Hirst for technical assistance with the Schistosoma mansoni life cycle maintenance at Aberystwyth University, and Anais Bordes for technical support with the Schistosoma mansoni life cycle maintenance at University of Oxford. The authors also gratefully acknowledge the Biology Dept Imaging Suite, University of Oxford for their support & assistance in this work (Funder: EPA Cephalosporin Fund and Department of Biology, Project Number CBR00830/REF CF 401). The authors acknowledge NHS Blood and Transplant (NHSBT), Non-Clinical Issue (NCI) for providing human blood products (detailed information in Methods). The study was partially funded by the Wellcome Trust (grants 098051 and 206194), and the European Union [Project 101080784 – WORMVACS2.0]. GR is supported by UKRI Future Leaders Fellowships [MR/W013568/2].

Additional information

Author contributions

Remi Pichon, Conceptualization, Methodology, Investigation, Data curation, Formal analysis, Visualization, Writing – original draft, Writing – review and editing; Magda E Lotkowska, Conceptualization, Methodology, Investigation, Data curation, Formal analysis, Visualization; Jude L. D. Bulathsinghalage, Methodology, Investigation, Data curation; Madeleine McMath, Methodology, Investigation, Data curation, Formal analysis, Visualization; Mary Evans, Methodology, Investigation; Benjamin J. Hulme, Methodology, Investigation; Kirsty Ambridge, Methodology, Investigation, Visualization; Geetha Sankaranarayanan, Methodology, Investigation; Simon Kershenbaum, Formal analysis, Writing – original draft, Writing – review and editing; Sarah D. Davey, Methodology, Investigation, Data curation, Formal analysis, Visualization; Josephine E. Forde-Thomas, Methodology, Investigation, Visualization; Karl F. Hoffmann, Conceptualization, Supervision, Funding acquisition; Matthew Berriman, Supervision, Funding acquisition, Project administration; Gabriel Rinaldi, Conceptualization, Methodology, Investigation, Data curation, Formal analysis, Visualization, Supervision, Funding acquisition, Project administration, Writing – original draft, Writing – review and editing.

Funding

Wellcome Trust (WT)

https://doi.org/10.35802/098051

Matthew Berriman

Wellcome Trust (WT)

https://doi.org/10.35802/206194

Matthew Berriman

European Union

https://doi.org/10.3030/101080784

Karl F Hoffmann

UKRI- Future Leaders Fellowship (MR/W013568/2)

Gabriel Rinaldi

Additional files

Supplementary Figures. Supplementary Figure S1. Developmental staging scoring. Summary of morphological attributes for the five different categories of development of worms cultivated in vitro (HS), as well as representative bright field images of each of these morphological categories. Arrows in categories 2 and 4 indicate elongated lung schistosomula, and the fusion of the two ceca posterior to the ventral sucker in the late liver schistosomula, respectively. Scale bar: 100 µm. Supplementary Figure S2. Representative FBS-cultured parasites by Week 10 in culture; most of the worms are dead (red arrows) and the few still alive are lung schistosomula (green arrows). Scale bar: 100 µm. Supplementary Figure S3. A. Representative pictures of in vitro developed parasites by day ∼80 in culture, male or female worms as indicated. Scale bar: 500 µm B. Representative results of the PCR-based sex genotyping using primers to amplify a fragment of the control actin gene in both male and female (upper band), and primers to amplify a W-specific region only in female worms (lower band). A non-template control, and male and female positive controls were included as indicated. Assigned sexes for each of the groups of clonal cercariae emitted by individual snails infected with single miracidia. Supplementary Figure S4. Representative confocal high magnification images of individual parasites displaying Edu+ cells at each indicated time point and culture condition. Edu+ cells and nuclei were labelled with Alexa fluor 488 (green) and DAPI (white/grey), respectively. Scale bars: 50 µm. Supplementary Figure S5. Representative bright-light pictures parasites cultured in HS supplemented medium for more than 100 days, indicating male and female worms. A-F: parasites cultured for 103 days. G, H. Parasites cultured for 145 days. Scale bar: 100 µm.

Supplementary Tables. Supplementary Table S1. Raw counts of parasites for each developmental stage. Supplementary Table S2. Primers used in PCR for sexing parasites. Supplementary Table S3. Area raw measurements of developing worms. Supplementary Table S4. Raw counting of parasites with either black positive (hemozoin) or negative (no hemozoin) intestine. Supplementary Table S5. Raw counting of Edu positive cells per parasite. Supplementary Table S6. Summary of all statistical tests.

Supplementary Videos. Supplementary Video S1. Representative Z-stack of EdU+ cells after 2 days of in vitro culture with human serum (A) or foetal bovine serum (B). EdU+ cells and nuclei were labelled with Alexa fluor 488 (green) and DAPI (grey), respectively. Scale bars: 50 µm. Supplementary Video S2. Representative Z-stack of an in vitro developed male worm. CellMask Green Actin Tracking Stain (green), and DAPI-stained nuclei (cyan). Scale bar: 25 µm. Supplementary Video S3. Representative Z-stack of an in vitro developed female worm. CellMask Green Actin Tracking Stain (green), and DAPI-stained nuclei (cyan). Scale bar: 10 µm. Supplementary Video S4. Representative video of in vitro developed females and males in copula at ∼80 days in culture. Scale bar: 100 µm. Supplementary Video S5. Representative videos of in vivo developed male and in vitro developed female in copula (A), and in vivo developed female and in vitro developed male in copula (B) Scale bar: 100 µm. Supplementary Video S6. Z-stack of a schistosome pair (in vivo-developed male and in vitro-developed female) in copula (A), and magnification of the ovarian area (B), highlighting maturing oocytes. CellMask Green Actin Tracking Stain: green, DAPI: grey, CellMask Deep Red Plasma Membrane Stain purple. Scale bars: 25 µm (top panel) and 50 µm (bottom panel).

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Article and author information

Author information

Remi Pichon
Department of Biology, University of Oxford, Oxford, United Kingdom, Department of Life Sciences, Aberystwyth University, Aberystwyth, United Kingdom
ORCID iD: 0000-0002-5821-9529
- co-first authors
Magda E Lotkowska
Wellcome Sanger Institute, Hinxton, United Kingdom
- co-first authors
Jude LD Bulathsinghalage
Department of Life Sciences, Aberystwyth University, Aberystwyth, United Kingdom
Madeleine McMath
Department of Life Sciences, Aberystwyth University, Aberystwyth, United Kingdom
Mary Evans
Department of Life Sciences, Aberystwyth University, Aberystwyth, United Kingdom
ORCID iD: 0009-0001-9120-6017
Benjamin J Hulme
Department of Life Sciences, Aberystwyth University, Aberystwyth, United Kingdom
ORCID iD: 0000-0002-5638-6323
Kirsty Ambridge
Wellcome Sanger Institute, Hinxton, United Kingdom
Geetha Sankaranarayanan
Wellcome Sanger Institute, Hinxton, United Kingdom
ORCID iD: 0000-0001-8303-2451
Simon Kershenbaum
Department of Biology, University of Oxford, Oxford, United Kingdom
ORCID iD: 0009-0000-1797-1282
Sarah D Davey
Department of Life Sciences, Aberystwyth University, Aberystwyth, United Kingdom
ORCID iD: 0000-0001-8676-7330
Josephine E Forde-Thomas
Department of Life Sciences, Aberystwyth University, Aberystwyth, United Kingdom
ORCID iD: 0000-0002-7202-3565
Karl F Hoffmann
Department of Life Sciences, Aberystwyth University, Aberystwyth, United Kingdom
ORCID iD: 0000-0002-3932-5502
Matthew Berriman
Wellcome Sanger Institute, Hinxton, United Kingdom, School of Infection and Immunity, College of Medical, Veterinary & Life Sciences, University of Glasgow, Glasgow, United Kingdom
ORCID iD: 0000-0002-9581-0377
- For correspondence: Matt.Berriman@glasgow.ac.uk
Gabriel Rinaldi
Department of Biology, University of Oxford, Oxford, United Kingdom, Department of Life Sciences, Aberystwyth University, Aberystwyth, United Kingdom, Wellcome Sanger Institute, Hinxton, United Kingdom
ORCID iD: 0000-0002-7767-4922
- For correspondence: gabriel.rinaldi@biology.ox.ac.uk

Author Notes

Competing interests: No competing interests declared

Version history

Preprint posted: January 23, 2026
Sent for peer review: February 20, 2026
Reviewed Preprint version 1: April 20, 2026

Cite all versions

You can cite all versions using the DOI https://doi.org/10.7554/eLife.111066. This DOI represents all versions, and will always resolve to the latest one.

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This article is distributed under the terms of the Creative Commons Attribution License, which permits unrestricted use and redistribution provided that the original author and source are credited.

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Significance of findings

Strength of evidence

Abstract

Introduction

Results

Sexually dimorphic schistosomes developed entirely in vitro from cercariae

Dimorphic female and male schistosomes entirely developed in vitro from cercariae.

Parasites cultured in Human Serum grew in size unlike those cultured in Foetal Bovine Serum.

Parasites developed in human serum readily digest red blood cells

Parasites developed in Human Serum readily digest red blood cells.

Development of parasites in human serum may be driven by stem cell proliferation

Development of parasites in human serum may be driven by stem cell proliferation.

In vitro cultured schistosomes display sexual dimorphism, developing reproductive systems and pairing capacity

In vitro cultured schistosomes display sexual dimorphism and developing reproductive systems.

In vitro cultured schistosomes are capable of pairing.

Discussion

Material and Methods

Ethics statement

Cercariae transformation and culture of schistosomula

Long term culture medium (LTC medium) composition.

Phenotype scoring of developing schistosomula

Measurement of parasite area

PCR for sexing and confirmation of sexual dimorphism

Detection and quantification of proliferating cells

Pairing experiments

Parasite staining and confocal imaging

Data availability

Acknowledgements

Additional information

Author contributions

Funding

Additional files

References

Article and author information

Author information

Remi Pichon*

Magda E Lotkowska*

Jude LD Bulathsinghalage

Madeleine McMath

Mary Evans

Benjamin J Hulme

Kirsty Ambridge

Geetha Sankaranarayanan

Simon Kershenbaum

Sarah D Davey

Josephine E Forde-Thomas

Karl F Hoffmann

Matthew Berriman

Gabriel Rinaldi

Author Notes

Version history

Cite all versions

Copyright

Metrics

Remi Pichon

Magda E Lotkowska