Citation:Kameni M, Musaigwa F, Kamguia LM, Kamdem SD, Mbanya G, Lamberton PHL, et al. (2024) Harnessing Schistosoma-associated metabolite changes in the human host to identify biomarkers of infection and morbidity: Where are we and what should we do next? PLoS Negl Trop Dis 18(3): e0012009. https://doi.org/10.1371/journal.pntd.0012009

Editor:Edward Mitre, Uniformed Services University: Uniformed Services University of the Health Sciences, UNITED STATES

Published: March 21, 2024

Copyright: © 2024 Kameni et al. This is an open access article distributed under the terms of the Creative Commons Attribution License, which permits unrestricted use, distribution, and reproduction in any medium, provided the original author and source are credited.

Funding:Financial support was received for several research projects that led to the unveiling of insights that enabled the development of this review article. Namely, a Merck KGaA Global Health Institute research grant to JKN that supported salary (JKN) and fellowships (LMK and MK); a FLAIR Fellowship Program grant FLR\R1\191058 (a partnership between the African Academy of Sciences and the Royal Society funded by the UK Government’s Global Challenges Research Fund) to JKN that also supported salary (JKN) and fellowships (SDK, LMK and MK); a collaborative research Grant FCG/R1/211036 from the UK Royal Society through the University of Glasgow to PHLL and JKN that further supported fellowships (LMK and MK). The funders had no role in study design, data collection and analysis, decision to publish, or preparation of the manuscript.

Competing interests: I have read the journal’s policy and the authors of this manuscript have the following competing interests: Nono JK is a founding member of JRJ Health, a health-promoting association based in Cameroon. JRJ had no role in the conceptualization, design, analysis of collected data, decision to publish, and preparation of the manuscript. All the remaining authors declare no financial or non-financial competing interests.

Introduction

Schistosomiasis, also known as bilharzia, is a debilitating and potentially fatal neglected tropical disease (NTD) caused by some species of blood trematode parasites of the genus Schistosoma. Schistosomiasis infection in humans is mainly caused by S. mansoni, S. haematobium, or S. japonicum [1–3], which causes noticeably morbid and life-threatening diseases mostly in children with symptoms ranging from impaired growth, reduced learning abilities, fever, anemia, abdominal pain, organ enlargement, reduced vaccine response [4], and tissue damage [5]. As the second most debilitating parasitic disease in the world after malaria, 700 million people are living in endemic areas and approximately 250 million people are infected worldwide with more than 200,000 deaths annually [2]. An estimated 85% of global Schistosoma infections occur in Africa, highlighting a public health concern in resource-constrained communities [1]. In these areas, schistosomiasis is primarily propagated by poverty (especially inadequate sanitation) correlated with the absence of safe water, with daily household chores such as washing and cooking, and recreational activities including swimming occurring in unprotected and contaminated freshwater sources [6]. Additionally, water-related economic activities such as contaminated freshwater irrigation and fishing can also spread the parasite to people, making its control difficult in regions where such activities are essential for the survival of most households [1].

The infection cycle and associated pathophysiology

The infection is contracted by humans and animals when coming into contact with infested water, containing infective larvae of Schistosoma spp. released from freshwater snails (the intermediate hosts). Upon contact, the infective larvae of Schistosoma spp, cercariae, penetrate the host skin. After invading the host skin, cercariae move towards the dermal veins [2], and at this point, larvae metamorphose and develop into schistosomula with strong coats that block the host’s immune response [7]. The schistosomula enter the systemic circulation via the venous blood vessels and are transported to the lungs and pulmonary capillaries to join the arterial circulation. As a result of schistosome cercariae infection, the human host may exhibit dermatitis caused by host responses to cercariae penetration of the skin and bronchopulmonary distress as a result of schistosomula passing through the lungs [2,3].

Once the schistosomula arrive in the hepatic portal system, they migrate to the mesenteric veins of the liver or the uro-genital vasculature where they then mature into adults. More pronounced symptoms will occur with parasite development and increased antigenic release which may include fever, dry cough, weakness, headache, and abdominal symptoms that are not pathognomonic of schistosomiasis alone but are usually reported during the acute phase of the disease, also called Katayama fever or Katayama syndrome [2]. Acute schistosomiasis is typically seen in nonimmune travelers, rather than residents of endemic areas. In rare cases, acute schistosomiasis may cause severe symptomatology, including cardiac and neurological complications, depending on the size of the infective inoculum (cercaria burden) and the intensity of the host’s immune response to the parasite antigens [8,9].

In this hepatic/uro-genital vascular network, adult schistosomes now fully developed, will mate and produce highly antigenic eggs that are inefficiently expelled via the intestine or bladder wall, and excreted from the body in the urine or feces. This results in a considerable amount of eggs being sequestered in tissues such as the liver, gastrointestinal tract, or urogenital compartment depending on the Schistosoma spp. [7]. The egg deposition from adult worms that will lodge in host tissues will now cause the critical part of schistosomiasis morbidity. In this phase, which is termed chronic schistosomiasis, hundreds to thousands of eggs are laid each day by adult worms living in the mesenteric branches of the portal vein along the intestinal wall (S. japonicum and S. mansoni infection) or the venous plexus around the urinary bladder (S. haematobium infection). The blood carries a large number of the eggs to the liver (S. mansoni) and other organs (bladder or genitalia for S. haematobium), where they are trapped and the continuous deposition of eggs cause a granulomatous response resulting in chronic inflammation lesions [2,3,7]. Under the sustained, untamed, and overwhelming action of the host immune response to the sequestered parasite eggs and excreted antigens, the ova-surrounding granulomatous structures are gradually replaced by fibrotic meshes that progressively and deleteriously replace the tissue parenchyma as the disease is left untreated and the chronicity is consolidated [7]. These lesions and subsequent complications translate into the pathognomonic clinical features of the disease including uro-genital bleeding and haematuria (S. haematobium), hepatosplenomegaly, pathological liver fibrosis, and portal hypertension (S. mansoni and S. japonicum) [10] which can be fatal if left untreated.

The species-specific sequestration of Schistosoma spp. eggs is consequent to the species-specific mode of egg excretion. Notably, S. mansoni and S. japonicum (species causing intestinal schistosomiasis) eggs are excreted in human feces, while eggs from S. haematobium (causing urogenital schistosomiasis) are excreted in the urine [1–3,7]. Exceptionally, schistosome eggs or adult worms may also take up residence in unusual tissues, giving rise to ectopic forms of schistosomiasis which are often difficult to clinically diagnose and can lead to aberrant morbidities [8].

Control efforts against schistosomiasis

Throughout history, global strategies for controlling schistosomiasis have focused on preventing and/or treating the infection and disease through mass drug administration (MDA), with some countries implementing early and reliable diagnosis of infections and robust monitoring of the disease progression to ensure effectiveness of the actions [11]. Since their launch in multiple countries in the 1950s, schistosomiasis control programs have primarily focused on reducing disease burden in endemic areas by reducing snail population, removing vegetation, and treating all Schistosoma spp. with oxamniquine (for S. mansoni) and more recently with praziquantel (PZQ), active against all Schistosoma spp. [12]. The fight against schistosomiasis gained further impetus in 2003 when national control programs across sub-Saharan Africa were scaled up, supported by PZQ drug donations and new World Health Organization (WHO) recommendations and guidelines [13]. In these larger control programs, the aim was to expand the area subjected to MDA of PZQ and reduce infection intensities, as well as morbidity [14] and to measure (by 1 urine filtration or Kato-Katz) the prevalence of infection in the most vulnerable community group, the school-aged children. Moreover, stakeholders took measures beyond the WHO 2013 report and recommendation to decrease Schistosoma infection’s prevalence and intensity, primarily by strategically and periodically administering PZQ to high-risk adults in endemic areas, as well as to school-age populations in endemic areas [9,12]. In order to achieve such a goal, Schistosoma infection needs to be routinely diagnosed and the burden of infection determined as a linear proxy of morbidity. As such, control of morbidity was classified as achieved when the prevalence of heavy infections fell below 5% [9,12]. The use of egg burden as a metric for assessing MDA effectiveness has remained common practice, despite the limitations of microscopical-based Kato-Katz and urine filtration diagnostic techniques. Subsequently, the 2030 resolution NTDs, aims for the elimination of schistosomiasis as a public health problem [12,15,16]. This elimination as a public health problem is currently defined as achieving a target prevalence of less than 1% heavy infections among schoolchildren, as defined by a Kato-Katz-based microscopical assessment of patients’ excreta for S. mansoni [12,15,16]. Consistently through these evolving global schistosomiasis strategies [12–14], large-scale treatment through MDA of PZQ has proved to be effective and powerful in decreasing prevalence by 60% among school-aged children over the last 20 years [17]. However, the community remains cognizant of the need to diagnose infection early on and to grade morbidity reliably with easy-to-use tools. This need for new infection and morbidity markers for improved diagnostic and morbidity monitoring tools was formally raised in the most recent road map for the elimination of schistosomiasis as a public health problem by 2030 and the accompanying guidelines published in 2022 (Fig 1 [16]).

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Fig 1. Timeline of global schistosomiasis control and elimination strategies (2001–present).

Created in Biorender.com.

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Current diagnostic tools for Schistosoma infection and limitations: Why is there a need for alternative/complementary diagnostic markers and tools?

Effective diagnostics are a prerequisite to reaching the goals set in the 2030 road map for NTDs [18]. Robust diagnostic tools are key components of the strategy to reduce morbidity and costs of schistosomiasis disease control programs, e.g., from confirmation of infection and disease to mapping, screening, surveillance, monitoring, and evaluation. Combined with clinical observations profiles (hepatosplenomegaly, bloody stool or diarrhea for intestinal schistosomiasis and hematuria for urogenital schistosomiasis), multiple and effective diagnostic techniques are available for the identification of Schistosoma (Table 1). Examples of these are the microscopy detection of parasite eggs in the patient’s excreta, the immunological detection of parasite antigens in their body fluids, or the molecular detection of parasite nucleic acids in their tissues. However, they often have important drawbacks that limit their use as efficient large-scale control tools [19,20]. Specifically, the most commonly used, and WHO endorsed, diagnosis of Schistosoma infections are microscopic identification of eggs in the feces of clinical specimens via the Kato-Katz thick smear technique for stool (S. mansoni) or in the urine following the urine filtration method (S. haematobium). Despite their specificities, cost-effectiveness and ease of implementation, microscopy methods often fail to detect low-intensity infections, predominantly found in low-endemicity areas or post treated with PZQ [21,22]. Antibody-based serological tests can also be used; however, these are critically limited by the presence of antibodies in previously infected but cured individuals, a drawback that has also be reported for the DNA-based diagnostic by PCR [19,20]. Although highly specific to the parasite, the molecular detection of RNA is very poorly sensitive and strongly depends on the ability to obtain patients’ biopsies with transcriptionally active parasite material, which is not easily implementable in the field. Conversely, in addition to microscopical-based diagnostic tools, WHO recommends the use of a point-of-care (POC) lateral flow test based on circulating cathodic antigen (CCA) detection [23], where CCA identification reflects the presence of viable worms in current infections. This is a successful implementation of a biomarker of infection and its reliable use for S. mansoni diagnosis [23]. Although easy and quick to perform and interpret, this method is insensitive to S. haematobium, and validation has not been demonstrated for some other species [24]. In addition, POC-CCA has also been associated with potential high rates of false-positive results, and inconclusive results caused by “trace” readings. Compared to the increasingly validated up-converting particle lateral flow circulating anodic antigen test (UC-LF CAA), POC-CCA appears to be underperforming [25,26]. Hence, POC-CCA might unreliably estimate disease burdens as well and consequently limit cost-efficient strategic control interventions. At present the UCP-LF-CAA test requires a laboratory and is more expensive that the POC-CCA, but it is suitable for all human infecting Schistosoma spp. The UCP-LF-CAA test is currently under development as a rapid diagnostic test to assist the currently limited diagnostic tools in the fight against schistosomiasis, but a sensitive and specific field deployable CAA test has yet to be commercially produced. The need for improved markers in the context of Schistosoma infection for monitoring and surveillance is increasingly reinstated by the WHO in the ultimate quest for the most refined and deployable diagnostic test or combination of tests for the unequivocal surveillance of the true prevalence of active infection whatever the stage of advancement of the disease [15,16]. In addition, improved diagnostics would aid in the formation of longer term wide-scale monitoring of control program success, and the identification of hotspots to inform strategic program implementation, running time and improvements to programs where required [19,20]. To this end, the WHO has recently published a target product profile for new diagnostics to detect Schistosoma infections, for 2 end case scenarios [27].

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Table 1. Current and foreseeable Schistosoma diagnostic strategies: Benefits and limitations.

https://doi.org/10.1371/journal.pntd.0012009.t001

Current tools to monitor schistosomiasis-related morbidity and limitations: Why the need for alternative/complementary morbidity markers and monitoring tools?

The morbidity associated with schistosomiasis is pernicious and insidious, primarily arising from the host’s untoward reaction against the sequestered parasite eggs [2,3,7]. The general assumption hitherto was that of a linearity between the egg burden and the severity of the pathology [5,28,29]. Such an assumed linearity has been at the basis of morbidity assessment proceedings for control programs whereby thresholds of disease burden were defined based on the prevalence of heavy infections, assumed to be indicative of severe pathology [12,15]. This has had some merit, streamlining the assessment of an apparent morbidity profile in treated communities easily without having to roll out expensive, logistically demanding and time-consuming ultrasound devices to unequivocally assess the degree of organ pathology in schistosomiasis patients. However, it is now becoming increasingly clear that a higher egg burden does not automatically translate into severe morbidity or that low burden infections are not prone to severe pathologies [30–32]. The relationship between intensity (as measured by excreted egg counts) and host morbidity at that time point has therefore become questionable, especially for S. mansoni [30–32]. In addition, the gold standard morbidity monitoring tool for tissue pathology, ultrasonography, poses a clear logistical problem, given its poor amenability to large-scale deployment in remote and/or poorer areas, where the disease is often most prevalent. It is under these premises that the need for morbidity markers to reliably monitor the progression of schistosomiasis morbidity, and its successful regression, becomes paramount en route to truly achieving the 2030 WHO goal of eliminating the disease as a public health problem.

The relevance of host metabolomics in the identification of biomarkers of human diseases

Perturbation of the host homeostasis is typical of most infections and a robust basis for the biological marking of the infection and its disease, relative to the alterations reported in the host. Regardless of the alterations investigated at the gene or transcript level, proteins and metabolites are the most proximal and best sources of biomarkers [33]. This supports the widely emerging use of metabolomics. Metabolite analysis is used to identify novel biomarkers of infection and disease, which may be used to rationally design diagnostic, prophylactic, or therapeutic tools [33]. Recent advances in liquid chromatography coupled with tandem mass spectrometry (LC-MS/MS) have contributed to the rapid growth of this field, providing a snapshot of the physiological state of a biological system by profiling its small molecule metabolic products at a specific time and condition [34]. Profiling all metabolites and relating them to metabolic pathways is useful for the robust identification of key checkpoints associated with a given phenotype of the system [33,34]. Many cancers and other diseases have been studied using metabolomics to better understand the disease, aid in the detection of the disease, and/or aid in the development of treatment options [35–37]. Based on these checkpoints, diagnostic or therapeutic tools can be developed for the patient’s phenotype.

Nowadays, significant advances in spectroscopy-based metabolomics techniques favor flexible analyses and controlled diagnostics in a limited time compared to before [38]. The current trend towards automation and standardization of protocols regarding experimental design, sample handling, and pretreatment in metabolomic workflows is an effective way to improve clinical diagnosis, early detection, treatment prediction, and monitoring of treatment effectiveness [39]. Metabolomic studies on body fluids in diseased states [35–37] including helminth infections [38], shed light on some valuable biomarkers of several infectious diseases (Table 2). Due to the high sensitivity of metabolomics, it can often detect subtle biological changes. However, although altered metabolic activities due to parasitic infections have been studied in animal models [40,41], confirmation in humans is documented only in rare pilot studies [42,43]. The difficulty in validating such candidate biomarker often lies in the need for targeted and strictly designed follow up experiments. Challenges in human studies arise due to the effect of individual host heterogeneity on the variation of the metabolome whereby age, genetics, diet, and other lifestyle factors all create variation in the metabolome [44,45]. Case-control studies or longitudinal follow-up of the same individuals, reducing confounding factors, are often the basis for robust biomarker validation experiments but human studies are scarce to date. These limitations do not remove the powerful value of metabolomics in infectious disease research where the robust identification of small molecules, e.g., metabolites produced during infection, may elucidate potential diagnostic markers directly related to infection and associated pathology [33,38,39]. The use of this technique has recently gained momentum in schistosomiasis research but the sample sizes are small and the number of studies is limited (Table 2). Therefore, an appraisal of the current status of host metabolomics during schistosomiasis and a road map for future steps to be taken in achieving a robust mapping of the host metabolite biomarkers of infection and pathology are indicated and timely.

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Table 2. Metabolomic profiles of mammalian hosts infected by Schistosoma spp.

https://doi.org/10.1371/journal.pntd.0012009.t002

Host metabolomics during schistosomiasis: Status and outlook

Schistosoma infection and associated disease cause distinct alterations of the host metabolite profiles [42,43,48]. The metabolomic profile of schistosomiasis infection has been extensively explored in animal models [33,38–41,48] and recently reviewed [53]. The variety of metabolite pathways identified has enabled hypotheses to be explored and an increased understanding of the progression of the disease [54]. However, most of the metabolomics studies identified in this recent scoping review were animal-based, supporting the need for more human studies to identify and validate potential host metabolite biomarkers. The progress made through these initial studies provides strong starting points for shaping future robust metabolomics-based biomarking studies for human schistosomiasis.

In a seminal study on host metabolomics during schistosomiasis, Wang and colleagues induced chronic schistosomiasis in mice and used 1H nuclear magnetic resonance (NMR) spectroscopy to describe the metabolic signature of S. mansoni infection [55]. In this study, for the first time, the potential of metabolomics in deciphering parasitic infection with S. mansoni was demonstrated. Novel biomarkers that could potentially serve as a basis for future diagnostic tests due to their high sensitivity and specificity compared to the tools currently used in the field were unprecedentedly revealed in the NMRI mouse model [55]. The metabolite changes recorded in this study directed further clinical research. The emphasis was placed on the path of glycolysis, amino acid metabolism as well as the intestinal microbiota, highlighting liver-specific human metabolic reactions, for example, the de novo synthesis and the secretion of primary bile acids (glycocholate, taurocholate, glycochenodeoxycholate, and taurochenodeoxycholate), as well as the degradation of ornithine. Gradually, the same metabolic pathways were exposed in other animal models of Schistosoma spp. infections [49,56,57] and confirmed later in human schistosomiasis [42,43,46], although with slight divergences. Such differences between studies in mouse models and humans are attributed to host factors, the intensity of infection which commonly differs between mouse models and humans, the unaccounted likelihood of coinfections in humans, and the dissimilar metabolic cascade leading to the morbidity profile. In addition, an interesting preliminary discovery was made by Wu and colleagues, who worked on progressive metabolic changes in schistosomiasis in Balb/C mice, identifying urinary 3-ureidopropionate (3-UP) as a potential biomarker for the early diagnosis of Schistosoma infection [58]. They observed elevated urinary 3-UP suggesting that Schistosoma infection resulted in reduced beta-ureidopropionase activity. However, in another study, Basant and colleagues also identified this metabolite as a potential biomarker for early malaria detection [59] showing that this metabolite fingerprint is not specific to schistosomiasis. Given the extensive co-endemicity of these 2 parasite infections, this may limit its use for future diagnostic development. However, the profile of this metabolite requires further investigations in human schistosomiasis, before being fully excluded.

Osakunor and colleagues tracked S. haematobium infection in populations of preschool-aged children living in schistosome endemic areas in Zimbabwe, demonstrating changes in metabolic profiles during the progression of natural infections over time [42]. Levels of creatinine, citrulline, sarcosine/N-methylglycine, and GABA were higher in boys when compared to girls, demonstrating a possible association with sexual dimorphism in changes of certain metabolites. They also showed that within 3 months of the first schistosome infection in young children, there were significant increases in AMP, ADP, 3-PG, and G6P, compared to uninfected children, and these increases were positively correlated with infection intensity. Analysis of metabolic pathways showed that the increases were related to energy (glycolysis) and purine metabolism which the authors attributed to schistosomiasis infection, despite the possible co-occurrence of other infections in the studied individuals.

In other studies, patients with schistosomiasis experienced dyslipidemia resulting in a reduction in total cholesterol, LDL, and triglycerides compared to healthy people [60,61]. Only metabologenomic models revealed the difference in the profile of lipid metabolism, suggesting the integration of genomic traits with metabolomic data can broaden and deepen the analysis. Such a metabolomics-based approach had been already successfully used in cardiology [62], metabolic syndrome [63], and disease diagnosis with high sensitivity and specificity for hepatitis C-infected patients [64]. This was achieved by comparing the candidate biomarker performance in several other causes of human liver diseases to rule out nonspecific candidates, e.g., alcoholic liver disease, nonalcoholic fatty liver disease (NAFLD), nonalcoholic fatty liver (NAFL), and nonalcoholic steatohepatitis (NASH) that might be co-occurring in the study settings. This approach could be tested in the human schistosomiasis model to attempt to distinguish people infected with S. mansoni from uninfected before and after PZQ chemotherapy and on the background of commonly co-occurring diseases such as malaria, hepatitis, and soil transmitted helminthiases.

Studies in Nigeria and Angola focusing on urogenital schistosomiasis have led to the discovery of numerous estrogen-like metabolites, as characteristic features of pathology, in the serum of infected individuals [65]. Metabolomic analysis of urine samples from these infected individuals revealed the presence of catechol estrogen quinones (CEQ) and CEQ-DNA adducts [65]. New metabolites derived from 8-oxo-7, 8-dihydro-2′-desoxyguanosine (8-oxodG) were also identified in the urine of 40 cases of urogenital schistosomiasis caused by S. haematobium [65]. More specifically, in the Nigerian participants affected by S. haematobium, depending on the severity of the infection, the metabolomic profiles obtained were associated with a reduction in the levels of sex steroids and high levels of several benzenoids, catechols, and lipids (including ganglioside, phosphatidylcholine, and phosphatidylethanolamine) in infected and diseased individuals when compared to uninfected and disease-free controls [43]. Together, these studies [43,65] have highlighted steroid trials as candidate biomarkers of urogenital schistosomiasis, which may represent a promising metabolomic avenue [66].

The picture has also been gradually drawn for metabolite markers of schistosomiasis associated pathologies, through various indirect evidences. Periportal fibrosis is one of the heaviest morbidities diagnosed in schistosomiasis parasites carriers. The liver is the most metabolically active tissue, and several models of metabolomic studies have been conducted to understand the development of liver fibrosis, although induced by noninfectious pathological conditions, and interesting metabolic pathways have been highlighted [67]. For example, in humans affected by NAFLD, fibrosis progression was associated with increased serum sulfate concentrations of 3 steroids: etiocholanolone (major metabolite of testosterone), dehydroepiandrosterone (precursor of androgens and estrogens), and 16α-hydroxy-dehydroepiandrosterone (precursor of estriol) [68]. The authors of this study concluded that the metabolites were ultimately associated with the progression of fibrosis in NAFLD [68]. However, it appears that they were not specific to this model since the key biomarker identified in these NAFLD studies, 16α-hydroxy-dehydroepiandrosterone sulfate, had also been reported in the serum of patients with breast cancer and endometrial cancer [69]. Such a lack of specificity for this biomarker in NAFLD-associated fibrosis highlights the limited likelihood of this biomarker providing a signature and sensitive measurement of fibrosis and not just cancer. Indeed, up to 20% of cancers are linked to inflammation-related chronic fibrosis [70]. Moreover, this candidate metabolite, 16α-hydroxy-dehydroepiandrosterone sulfate, is also an intermediate of estriol formation during pregnancy [71], making it clearly unsuitable for biomarking fibrosis specifically, and for a distinct disease condition in general. This further highlights the difficulty in identifying a clear disease-associated fibrosis-specific biomarker and further raises the need to test the performance of candidate biomarkers in several conditions to properly profile fibrosis and rule out ambiguity.

Another seminal attempt to biomark fibrosis was performed by Zhang and colleagues in 2006 [72]. They explored the use of targeted amino acid profiling to re-evaluate an association between liver fibrosis and fisher’s ratio, the molar ratio of branched amino acids to aromatic acids, achieving a fibrosis index based on amino acid concentration that could be applied to diagnose advanced liver fibrosis in chronic hepatitis C patients [72]. Other studies similarly established a strong correlation between morbidity and levels of free amino acids in the serum of hepatitis B-infected patients [73,74] altogether strengthening the clinical biomarking value of amino acid metabolism in the noninvasive monitoring of fibrosis, a pathognomonic feature of diseases including schistosomiasis. Therefore, Wang and colleagues went on to justify the use of amino acid metabolism as a diagnostic biomarker to classify morbidity according to the severity of schistosomiasis infection [55], highlighting the overall potential of metabolomics-based studies in revealing novel robust biomarkers of pathology during schistosomiasis.

Nevertheless, a striking limitation of such biomarking studies remained the lack of performance assessment of identified candidate biomarkers under conditions of defined coinfections, a setting that is the norm in schistosomiasis endemic areas [30,75,76]. A study was conducted by Gouveia and colleagues using 1H-NMR-based metabolomics models to diagnose periportal fibrosis caused by S. mansoni in patients either coinfected, or not, with chronic HBV or HCV infection [75]. A clear separation between coinfected and mono-infected (Schistosomiasis only) patients was reported using a supervised model built using partial least squares-discriminant analysis (PLS-DA) that succeeded in showing 100% precision predictive ability between mono-infected and coinfected individuals. This finding unprecedentedly supported a potential of metabolomic-based identification of candidate biomarkers as an alternative to conventional predictive methods for the diagnosis of periportal fibrosis caused by schistosomiasis even on a background of host multimorbidity. Building on these first observations from the metabolomics-based biomarking of the human host during Schistosoma infection and associated pathology, even on a complex background of coinfections, the addition of more metabolome signatures of schistosomiasis to the currently available diagnostic and morbidity monitoring tools would certainly strengthen our understanding of the host–parasite interactions, in addition to ameliorating our current control strategies through improved diagnostics (Fig 2).

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Fig 2. The influence of schistosomiasis on host metabolism and how it can be harnessed for diagnostic and therapeutic gains through metabolomics guided biomarker discovery.

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https://doi.org/10.1371/journal.pntd.0012009.g002

Among the methods used in metabolomics involving mass spectrometry to identify new biomarkers, there are 3 types: (i) the untargeted metabolomics generally used to detect metabolites spike without prior knowledge; (ii) targeted metabolomics that analyze specific metabolites previously defined by the user; and (iii) a specialized form of targeted metabolomics combined with isotope flow also called fluxomic. The latter is achieved through the introduction of substrates labeled with heavy isotopes, which makes it possible to identify and quantify metabolites as they move through metabolic pathways. The heterogeneity of sensitivity of untargeted metabolomics is the main limitation compared to the 2 other targeted methods [77]. Thus, untargeted and targeted metabolomics can identify a plethora of metabolites acting differently in the metabolic pathways involved in schistosomiasis; however, none of them could tell us about their entangled conversion pathways deciphering the whole metabolic pathways along the progression of infection. By measuring the interconversion rates of metabolites, the stable isotope tracing technique will provide information not revealed by the untargeted conventional metabolomics [78], which could be a more powerful and complete approach to probe metabolic changes in pathological biological systems like in schistosomiasis infection. Thus, the application of serial circular studies on these different platforms of metabolomic investigations should be the key to helping elucidate previous inconclusive results of preclinical studies.

A fundamental requirement for a comprehensive assessment of the human host metabolomic variations of schistosomiasis infection and/or pathology is the refined phenotyping of patients from endemic areas, ensuring a wide range of age coverage (from preschool-aged children, school-aged children, to adolescent and adults), a mixed sex distribution (male and female), a diverse egg burden distribution (from low, moderate, and high burden infection candidates), and a comprehensive range of well-defined morbidities (from absent, mild, moderate to severe). This should enable a robust parallel between defined metabolome profiles and human host phenotypes during schistosomiasis.

Further analyses of a larger cohort of participants with schistosomiasis mono-infection or coinfections will also be essential to discovering relevant metabolites as biomarkers of infection and pathogenesis in Schistosoma spp. infections. Schistosomiasis infested sites are focal but rarely occur in isolation, and polyparasitism is the norm rather than the exception in endemic areas [75,76]. The robustness of host metabolome profiling should be unequivocally evaluated by the addition of coinfected individuals to the host metabolomics studies. Such an approach has been recently used for a canonical type-2 cytokine IL-33 and the biomarking potential for hepatosplenic schistosomiasis in a polyparasitic site of rural Cameroon [76]. This cytokine was negatively associated with schistosomiasis even in instances of host coinfection with hepatitis and malaria. Another key requirement for the identification of host metabolites that are pathognomonic of schistosomiasis infection and disease would be combining associative cross-sectional studies with follow-up longitudinal studies that would help validate the robustness of metabolite biomarkers identified. In the latter study design, the changes over time of the target metabolites alongside the infection and disease status of the host would be highly informative on the robustness of the candidate metabolite in real-life situations. Moreover, the use of cohorts undergoing treatment with praziquantel would help exclude non-robust candidate metabolites and uniquely reveal reliable metabolites that evolve in a timely manner with the host’s infection and disease status during schistosomiasis. Such attempts have already been undertaken in preclinical [79] as well as clinical settings [42], validating the power of such an approach of longitudinal follow up with treatment while also providing an exploitable list of candidate metabolite biomarkers during schistosomiasis. A consequent expectation would be the identification of metabolite biomarkers of infection acquisition or disease progression in individuals initially uninfected and disease-free upon long-term follow up in endemic areas. The use of such prognostic tools to accompany a test-and-treat strategy would be invaluable for the elimination of schistosomiasis whereby metabolite changes in finely clustered hosts could be robustly linked to the onset of schistosomiasis infection upon exposure and/or disease following infection. As such, the predictability of host metabolites for infectious disease acquisition and disease progression has been successfully tested in tuberculosis [80] demonstrating proof of concept. Critically, to ensure the informative value of such complex clinical sampling, phenotyping and metabolite assessment studies, sampling protocols are required, alongside strong clinical diagnostic skills and the accuracy of clinical and imaging techniques. Imaging for schistosomiasis pathology, as defined by the WHO, heavily relies on the local organometric and baseline values to conclude on abnormalities. As such, the generation of local referential of “normal” organometrics is critical as recently performed in rural Cameroon [81]. Only the use of such local referential can enable an accurate measurement of organ enlargement and thus disease grading, considering the dissimilar range of organometrics from one region to another [82]. Therefore, equipped with all these precautions, tools, and clinical settings, human metabolome profiling in the context of schistosomiasis and the wealth of robust metabolite biomarkers generated can then be further harnessed as bases to reliably evaluate the infectious status and severity of the disease process and its complications and further, perhaps enable species specific diagnosis as well as anticipate the risk of the individual being reinfected and/or developing infection-associated disease in the future.

The metabolomics profiling of schistosomiasis in humans can also be taken a step further than biomarker identification towards mechanisms of action [83]. As such, identified biomarkers can be utilized to detect how Schistosoma infection and/or associated disease impact biochemical pathways in the body. The key metabolites can be traced to metabolic pathways to understand which processes in the metabolic pathways are being affected in the body to produce the disease phenotype. Notably, however, the detection of altered biochemical pathways will require more advanced metabolomic techniques such as stable isotope tracing and integration of the data with other orthogonal datasets such as those resulting from other omics studies [83]. Tracing of the biochemical pathways would also require a firm understanding of the biochemical pathways and interactions to be able to tease out which parts are altered to drive the observed changes in the metabolome linked to the disease.

Conclusions

Helminth infections, including schistosomiasis, cause changes in metabolism by altering their host metabolite production, as well as patterns of use, excretion, and absorption of metabolites. As current diagnostics and monitoring tools are insufficient for the detection and assessment of low-burden Schistosoma infections in humans and enabling the reliable monitoring of the severity of tissue pathology, more sensitive markers are urgently needed [27]. Consequently, achieving the 2030 target of schistosomiasis elimination as a public health problem requires a thorough understanding of the metabolic mechanisms involved in infection acquisition and the development of various morbidity traits associated with Schistosoma spp. infection. Thus, the present review suggests the incorporation of a metabolome fingerprint of Schistosoma infection and/or morbidity into available monitoring tools that might enable us to better understand host–parasite interactions and refine our current control strategies en route to eliminating schistosomiasis.

Highlights

* Low-burden infections of Schistosoma spp. are difficult to be reliably detected using the current microscopy-based diagnostic tools.

* Schistosoma spp. egg excretion counts and morbidity profiles may differ substantially, making it difficult to monitor schistosomiasis pathology with egg burden as the sole proxy.

* Schistosoma spp. infections and coinfections with other parasites, and co-morbidities further complicate host profiles.

* Metabolomics is an emerging approach that can provide, in a short time, clear information on metabolic changes in the host associated with infection and disease.

* Data on human hosts metabolomic profiles, with and without Schistosoma spp. infection, cross-sectionally and longitudinally, with and without treatment, with and without coinfections, are still limited but could provide a deeper understanding, improved biomarking, and ameliorated monitoring of Schistosoma spp. infection and associated morbidity.

* Biomarkers, identified by metabolomic profiling of human hosts, might lead to improved diagnostic tools and posttreatment monitoring of disease progression or regression.

Acknowledgments

The authors are grateful to Drs. Thomas Spangenberg and Claudia Demarta-Gatsi for critically revising the present review.

References

1. 1. Chitsulo L, Engels D, Montresor A, Savioli L. The global status of schistosomiasis and its control. Acta Trop. 2000;77:41–51. pmid:10996119

* View Article

* PubMed/NCBI

* Google Scholar

2. 2. LoVerde PT. Schistosomiasis. Adv Exp Med Biol. 2019;1154:45–70. pmid:31297759

* View Article

* PubMed/NCBI

* Google Scholar

3. 3. McManus D P, Dunne D W, Sacko M, Utzinger J, Vennervald B J, Zhou X N. Schistosomiasis Nat Rev Dis Primers. 2018;4:13. pmid:30093684

* View Article

* PubMed/NCBI

* Google Scholar

4. 4. Musaigwa F, Kamdem S D, Mpotje T, Mosala P, Abdel A N, Herbert D R, et al. Schistosoma mansoni infection induces plasmablast and plasma cell death in the bone marrow and accelerates the decline of host vaccine responses. PLoS Pathog. 2022;18:e1010327. pmid:35157732

* View Article

* PubMed/NCBI

* Google Scholar

5. 5. Mawa P A, Kincaid-Smith J, Tukahebwa E M, Webster J P, Wilson S. Schistosomiasis morbidity hotspots: roles of the human host, the parasite and their interface in the development of severe morbidity. Front Immunol. 2021;12:635869. pmid:33790908

* View Article

* PubMed/NCBI

* Google Scholar

6. 6. Grimes J E, Croll D, Harrison W E, Utzinger J, Freeman M C, Templeton M R. The roles of water, sanitation and hygiene in reducing schistosomiasis: a review. Parasit Vectors. 2015;8:156. pmid:25884172

* View Article

* PubMed/NCBI

* Google Scholar

7. 7. Schwartz C, Fallon P G. Schistosoma “Eggs-Iting” the host: granuloma ormation and egg excretion. Front Immunol. 2018;9:2492. pmid:30459767

* View Article

* PubMed/NCBI

* Google Scholar

8. 8. Gobbi F, Tamarozzi F, Buonfrate D, van L L, Bisoffi Z, Bottieau E. New insights on acute and chronic schistosomiasis: do we need a redefinition? Trends Parasitol. 2020;36:660–667. pmid:32505540

* View Article

* PubMed/NCBI

* Google Scholar

9. 9. Jaureguiberry S, Paris L, Caumes E. Acute schistosomiasis, a diagnostic and therapeutic challenge. Clin Microbiol Infect. 2010;16:225–231. pmid:20222897

* View Article

* PubMed/NCBI

* Google Scholar

10. 10. Colley D G, Bustinduy A L, Secor W E, King C H. Human schistosomiasis. Lancet. 2014;383:2253–2264. pmid:24698483

* View Article

* PubMed/NCBI

* Google Scholar

11. 11. Chala B. Advances in diagnosis of schistosomiasis: focus on challenges and future approaches. Int J Gen Med. 2023;16:983–995. pmid:36967838

* View Article

* PubMed/NCBI

* Google Scholar

12. 12. World Health Organization (2022) Schistosomiasis: progress report 2001–2011, strategic plan 2012–2020.

13. 13. World Health Organization (2006) Neglected tropical diseases: preventive chemotherapy and transmission control: soil-transmitted helminthiasis, onchocerciasis, lymphatic filariasis, schistosomiasis, Guinea-worm disease. In: World Health Organization.

14. 14. World Health Organization (2012) Schistosomiasis and soil-transmitted helminth infections. In: Sixty-fifth World Health Assembly. Geneva, 2012, WHA65/2012/REC/1: PP. 36–37. 2012; World Health Organization. Accelerating Work to Overcome the Global Impact of Neglected Tropical Diseases: A Roadmap for Implementation. Geneva, Switzerland, 2012.

15. 15. WHO guideline on control and elimination of human schistosomiasis. Geneva: World Health Organization. (2022).

16. 16. Lo N C, Bezerra F S M, Colley D G, Fleming F M, Homeida M, Kabatereine N, et al. Review of 2022 WHO guidelines on the control and elimination of schistosomiasis. Lancet Infect Dis. 2022;22:e327–e335. pmid:35594896

* View Article

* PubMed/NCBI

* Google Scholar

17. 17. Kokaliaris C, Garba A, Matuska M, Bronzan R N, Colley D G, Dorkenoo A M, et al. Effect of preventive chemotherapy with praziquantel on schistosomiasis among school-aged children in sub-Saharan Africa: a spatiotemporal modelling study. Lancet Infect Dis. 2022;22:136–149. pmid:34863336

* View Article

* PubMed/NCBI

* Google Scholar

18. 18. World Health Organization (2021) Ending the neglect to attain the Sustainable Development Goals: a road map for neglected tropical diseases 2021–2030. World Health Organization.

19. 19. Utzinger J, Becker S L, van L L, van Dam G J, Knopp S. New diagnostic tools in schistosomiasis. Clin Microbiol Infect. 2015;21:529–542. pmid:25843503

* View Article

* PubMed/NCBI

* Google Scholar

20. 20. Weerakoon K G, Gobert G N, Cai P, McManus D P. Advances in the diagnosis of human schistosomiasis. Clin Microbiol Rev. 2015;28:939–967. pmid:26224883

* View Article

* PubMed/NCBI

* Google Scholar

21. 21. Dazo B C, Biles J E. Two new field techniques for detection and counting of Schistosoma haematobium eggs in urine samples, with an evaluation of both methods. Bull World Health Organ. 1974;51:399–408. pmid:4549491

* View Article

* PubMed/NCBI

* Google Scholar

22. 22. Katz N, Chaves A, Pellegrino J. A simple device for quantitative stool thick-smear technique in Schistosoma mansoni. Rev Inst Med Trop Sao Paulo. 1972;14:397–400. pmid:4675644

* View Article

* PubMed/NCBI

* Google Scholar

23. 23. Barenbold O, Garba A, Colley D G, Fleming F M, Haggag A A, Ramzy R M R, et al. Translating preventive chemotherapy prevalence thresholds for Schistosoma mansoni from the Kato-Katz technique into the point-of-care circulating cathodic antigen diagnostic test. PLoS Negl Trop Dis. 2018;12:e0006941. pmid:30550594

* View Article

* PubMed/NCBI

* Google Scholar

24. 24. Hoekstra P T, Madinga J, Lutumba P, van Grootveld R, Brienen E A T, Corstjens P L A M, et al. Diagnosis of schistosomiasis without a microscope: evaluating circulating antigen (CCA, CAA) and DNA detection methods on banked samples of a community-based survey from DR Congo. Trop Med Infect Dis. 2022;7. pmid:36288056

* View Article

* PubMed/NCBI

* Google Scholar

25. 25. Favre T C, Beck L C N H, Bezerra F S M Graeff-Teixeira C, Coelho P M Z, Enk M J, et al. Reliability of point-of-care circulating cathodic antigen assay for diagnosing schistosomiasis mansoni in urine samples from an endemic area of Brazil after one year of storage at -20 degrees Celsius. Rev Soc Bras Med Trop. 55:e0389. pmid:35239906

* View Article

* PubMed/NCBI

* Google Scholar

26. 26. Sousa M S, van Dam G J, Pinheiro M C C, de Dood C J, Peralta J M, Peralta RHS, et al. Performance of an ultra-sensitive assay targeting the Circulating Anodic Antigen (CAA) for detection of Schistosoma mansoni infection in a low endemic area in Brazil. Front Immunol. 2019;10:682. pmid:31019510

* View Article

* PubMed/NCBI

* Google Scholar

27. 27. World Health Organization (21 A.D.) Diagnostic target product profiles for monitoring, evaluation and surveillance of schistosomiasis control programmes.

28. 28. Cooppan R M, Schutte C H, Mayet F G, Dingle C E, Van Deventer J M, Mosese P G. Morbidity from urinary schistosomiasis in relation to intensity of infection in the Natal Province of South Africa. Am J Trop Med Hyg. 1986;35:765–776. pmid:3089036

* View Article

* PubMed/NCBI

* Google Scholar

29. 29. Tukahebwa E M, Magnussen P, Madsen H, Kabatereine N B, Nuwaha F, Wilson S, et al. A very high infection intensity of Schistosoma mansoni in a Ugandan lake Victoria fishing community is required for association with highly prevalent organ related morbidity. PLoS Negl Trop Dis. 2013;7:e2268. pmid:23936559

* View Article

* PubMed/NCBI

* Google Scholar

30. 30. Nono J K, Kamdem S D, Netongo P M, Dabee S, Schomaker M, Oumarou A, et al. Schistosomiasis burden and Its association with lower Measles vaccine responses in school children from rural Cameroon. Front Immunol. 2018;9:2295. pmid:30356757

* View Article

* PubMed/NCBI

* Google Scholar

31. 31. Wiegand R E, Secor W E, Fleming F M, French M D, King C H, Deol A K, et al. Associations between infection intensity categories and morbidity prevalence in school-age children are much stronger for Schistosoma haematobium than for S. mansoni. PLoS Negl Trop Dis. 2021;15:e0009444. pmid:34033646

* View Article

* PubMed/NCBI

* Google Scholar

32. 32. Wiegand R E, Fleming F M, de Vlas S J, Odiere M R, Kinung’hi S, King C H, et al. Defining elimination as a public health problem for schistosomiasis control programmes: beyond prevalence of heavy-intensity infections. Lancet Glob Health. 2022;10:e1355–e1359. pmid:35961358

* View Article

* PubMed/NCBI

* Google Scholar

33. 33. Whitman J D, Sakanari J A, Mitreva M. Areas of metabolomic exploration for helminth infections. ACS Infect Dis. 2021;7:206–214. pmid:33492932

* View Article

* PubMed/NCBI

* Google Scholar

34. 34. Xiao J F, Zhou B, Ressom H W. Metabolite identification and quantitation in LC-MS/MS-based metabolomics. Trends Anal Chem. 2012;32:1–14. pmid:22345829

* View Article

* PubMed/NCBI

* Google Scholar

35. 35. Beger R D. A review of applications of metabolomics in cancer. Metabolites. 2013;3:552–574. pmid:24958139

* View Article

* PubMed/NCBI

* Google Scholar

36. 36. Madsen R, Lundstedt T, Trygg J. Chemometrics in metabolomics—a review in human disease diagnosis. Anal Chim Acta. 2010;659:23–33. pmid:20103103

* View Article

* PubMed/NCBI

* Google Scholar

37. 37. Troisi J, Raffone A, Travaglino A, Belli G, Belli C, Anand S, et al. Development and validation of a serum metabolomic signature for endometrial cancer screening in postmenopausal women. JAMA Netw Open. 2020;3:e2018327. pmid:32986110

* View Article

* PubMed/NCBI

* Google Scholar

38. 38. Preidis G A, Hotez P J. The newest “omics”—metagenomics and metabolomics—enter the battle against the neglected tropical diseases. PLoS Negl Trop Dis. 2015;9:e0003382. pmid:25675250

* View Article

* PubMed/NCBI

* Google Scholar

39. 39. Kokova D, Mayboroda O A. Twenty Years on: metabolomics in helminth research. Trends Parasitol. 2019;35:282–288. pmid:30824203

* View Article

* PubMed/NCBI

* Google Scholar

40. 40. Loyo R M, Zarate E, Barbosa C S, Simoes-Barbosa A. Gas chromatography-mass spectrometry (GC/MS) reveals urine metabolites associated to light and heavy infections by Schistosoma mansoni in mice. Parasitol Int. 2021;80:102239. pmid:33157242

* View Article

* PubMed/NCBI

* Google Scholar

41. 41. Garcia-Perez I, Whitfield P, Bartlett A, Angulo S, Legido-Quigley C, Hanna-Brown M, et al. Metabolic fingerprinting of Schistosoma mansoni infection in mice urine with capillary electrophoresis. Electrophoresis. 2008;29:3201–3206. pmid:18633941

* View Article

* PubMed/NCBI

* Google Scholar

42. 42. Osakunor D N M, Mduluza T, Osei-Hyiaman D, Burgess K, Woolhouse M E J, Mutapi F. Schistosoma haematobium infection is associated with alterations in energy and purine-related metabolism in preschool-aged children. PLoS Negl Trop Dis. 2020;14:e0008866. pmid:33315875

* View Article

* PubMed/NCBI

* Google Scholar

43. 43. Adebayo A S, Mundhe S D, Awobode H O, Onile O S, Agunloye A M, Isokpehi R D, et al. Metabolite profiling for biomarkers in Schistosoma haematobium infection and associated bladder pathologies. PLoS Negl Trop Dis. 2018;12:e0006452. pmid:29708967

* View Article

* PubMed/NCBI

* Google Scholar

44. 44. Bouchard-Mercier A, Rudkowska I, Lemieux S, Couture P, Vohl M C. The metabolic signature associated with the Western dietary pattern: a cross-sectional study. Nutr J. 2013;12:158. pmid:24330454

* View Article

* PubMed/NCBI

* Google Scholar

45. 45. Navarro S L, Nagana Gowda G A, Bettcher L F, Pepin R, Nguyen N, Ellenberger M, et al. Demographic, health and lifestyle factors associated with the metabolome in older women. Metabolites. 2023;13. pmid:37110172

* View Article

* PubMed/NCBI

* Google Scholar

46. 46. Balog C I, Meissner A, Goraler S, Bladergroen M R, Vennervald B J, Mayboroda O A, et al. Metabonomic investigation of human Schistosoma mansoni infection. Mol Biosyst. 2011;7:1473–1480. pmid:21336380

* View Article

* PubMed/NCBI

* Google Scholar

47. 47. Rodrigues M L, da Luz T P S R, Pereira C L D, Batista A D, Domingues A L C, Silva R O, et al. Assessment of periportal fibrosis in Schistosomiasis mansoni patients by proton nuclear magnetic resonance-based metabonomics models. World J Hepatol. 2022;14:719–728. pmid:35646266

* View Article

* PubMed/NCBI

* Google Scholar

48. 48. Chienwichai P, Nogrado K, Tipthara P, Tarning J, Limpanont Y, Chusongsang P, et al. Untargeted serum metabolomic profiling for early detection of Schistosoma mekongi infection in mouse model. Front Cell Infect Microbiol. 2022;12:910177. pmid:36061860

* View Article

* PubMed/NCBI

* Google Scholar

49. 49. Liu R, Cheng W J, Tang H B, Zhong Q P, Ming Z P, Dong H F. Comparative metabonomic investigations of Schistosoma japonicum from SCID mice and BALB/c mice: clues to developmental abnormality of schistosome in the immunodeficient host. Front Microbiol. 2019;10:440. pmid:30915055

* View Article

* PubMed/NCBI

* Google Scholar

50. 50. Hu Y, Chen J, Xu Y, Zhou H, Huang P, Ma Y, et al. Alterations of gut microbiome and metabolite profiling in mice Infected by Schistosoma japonicum. Front Immunol. 2020;11:569727. pmid:33162984

* View Article

* PubMed/NCBI

* Google Scholar

51. 51. Huang Y, Wu Q, Zhao L, Xiong C, Xu Y, Dong X, et al. UHPLC-MS-based metabolomics analysis reveals the process of schistosomiasis in mice. Front Microbiol. 2020;11:1517. pmid:32760365

* View Article

* PubMed/NCBI

* Google Scholar

52. 52. Zhou C, Li J, Guo C, Zhou Z, Yang Z, Zhang Y, et al. Alterations in gut microbiome and metabolite profile of patients with Schistosoma japonicum infection. Parasit Vectors. 2023;16:346. pmid:37798771

* View Article

* PubMed/NCBI

* Google Scholar

53. 53. Midzi H, Vengesai A, Muleya V, Kasambala M, Mduluza-Jokonya L, Chipako I, et al. Metabolomics for biomarker discovery in schistosomiasis: A systematic scoping review. Front Trop Dis. 2023;4.

* View Article

* Google Scholar

54. 54. Hacariz O, Sayers G P. The omic approach to parasitic trematode research-a review of techniques and developments within the past 5 years. Parasitol Res. 2016;115:2523–2543. pmid:27126082

* View Article

* PubMed/NCBI

* Google Scholar

55. 55. Wang Y, Holmes E, Nicholson J K, Cloarec O, Chollet J, Tanner M, et al. Metabonomic investigations in mice infected with Schistosoma mansoni: an approach for biomarker identification. Proc Natl Acad Sci U S A. 2004;101:12676–12681. pmid:15314235

* View Article

* PubMed/NCBI

* Google Scholar

56. 56. Li JV, Holmes E, Saric J, Keiser J, Dirnhofer S, Utzinger J, et al. Metabolic profiling of a Schistosoma mansoni infection in mouse tissues using magic angle spinning-nuclear magnetic resonance spectroscopy. Int J Parasitol. 2009;39:547–558. pmid:19068218

* View Article

* PubMed/NCBI

* Google Scholar

57. 57. O’Sullivan C, Fried B, Sherma J. Metabolic profiling of Echinostoma caproni and Schistosoma mansoni in their definitive and intermediate hosts. Acta Parasitol. 2013;58:1–5. pmid:23377904

* View Article

* PubMed/NCBI

* Google Scholar

58. 58. Wu J, Xu W, Ming Z, Dong H, Tang H, Wang Y. Metabolic changes reveal the development of schistosomiasis in mice. PLoS Negl Trop Dis. 2010;4. e807 pmid:20824219

* View Article

* PubMed/NCBI

* Google Scholar

59. 59. Basant A, Rege M, Sharma S, Sonawat H M. Alterations in urine, serum and brain metabolomic profiles exhibit sexual dimorphism during malaria disease progression. Malar J. 2010;9:110. pmid:20412601

* View Article

* PubMed/NCBI

* Google Scholar

60. 60. Zinsou J F, Janse J J, Honpkehedji Y Y, Dejon-Agobe J C, Garcia-Tardon N, Hoekstra P T, et al. Schistosoma haematobium infection is associated with lower serum cholesterol levels and improved lipid profile in overweight/obese individuals. PLoS Negl Trop Dis. 2020;14:e0008464. pmid:32614822

* View Article

* PubMed/NCBI

* Google Scholar

61. 61. Martins da Fonseca C S, Pimenta Filho A A, dos Santos B S, da Silva C A, Domingues AL, Owen JS, et al. Human plasma lipid modulation in schistosomiasis mansoni depends on apolipoprotein E polymorphism. PLoS ONE. 2014;9:e101964. pmid:25051269

* View Article

* PubMed/NCBI

* Google Scholar

62. 62. Ussher J R, Elmariah S, Gerszten R E, Dyck J R. The emerging role of metabolomics in the diagnosis and prognosis of cardiovascular disease. J Am Coll Cardiol. 2016;68:2850–2870. pmid:28007146

* View Article

* PubMed/NCBI

* Google Scholar

63. 63. Monnerie S, Comte B, Ziegler D, Morais J A, Pujos-Guillot E, Gaudreau P. Metabolomic and lipidomic signatures of metabolic syndrome and its physiological components in adults: a systematic review. Sci Rep. 2020;10:669. pmid:31959772

* View Article

* PubMed/NCBI

* Google Scholar

64. 64. Godoy M M, Lopes E P, Silva R O, Hallwass F, Koury LC, Moura IM, et al. Hepatitis C virus infection diagnosis using metabonomics. J Viral Hepat. 2010;17:854–858. pmid:20070502

* View Article

* PubMed/NCBI

* Google Scholar

65. 65. Gouveia M J, Santos J, Brindley P J, Rinaldi G, Lopes C, Santos L L, et al. Estrogen-like metabolites and DNA-adducts in urogenital schistosomiasis-associated bladder cancer. Cancer Lett. 2015;359:226–232. pmid:25615421

* View Article

* PubMed/NCBI

* Google Scholar

66. 66. Botelho M C, Alves H, Barros A, Rinaldi G, Brindley P J, Sousa M. The role of estrogens and estrogen receptor signaling pathways in cancer and infertility: the case of schistosomes. Trends Parasitol. 2015;31:246–250. pmid:25837311

* View Article

* PubMed/NCBI

* Google Scholar

67. 67. Chang M L, Yang S S. Metabolic signature of hepatic fibrosis: from individual pathways to systems biology. Cells. 2019;8. pmid:31726658

* View Article

* PubMed/NCBI

* Google Scholar

68. 68. Tokushige K, Hashimoto E, Kodama K, Tobari M, Matsushita N, Kogiso T, et al. Serum metabolomic profile and potential biomarkers for severity of fibrosis in nonalcoholic fatty liver disease. J Gastroenterol. 2013;48:1392–1400. pmid:23478936

* View Article

* PubMed/NCBI

* Google Scholar

69. 69. Li J, Zheng Z, Liu M, Ren Y, Ruan Y, Li D. Relationship between the n-3 index, serum metabolites and breast cancer risk. Food Funct. 2021;12:7741–7748. pmid:34296713

* View Article

* PubMed/NCBI

* Google Scholar

70. 70. Chandler C, Liu T, Buckanovich R, Coffman L G. The double edge sword of fibrosis in cancer. Transl Res. 2019;209:55–67. pmid:30871956

* View Article

* PubMed/NCBI

* Google Scholar

71. 71. Schweigmann H, Sanchez-Guijo A, Ugele B, Hartmann K, Hartmann M F, Bergmann M, et al. Transport of the placental estriol precursor 16alpha-hydroxy-dehydroepiandrosterone sulfate (16alpha-OH-DHEAS) by stably transfected OAT4-, SOAT-, and NTCP-HEK293 cells. J Steroid Biochem Mol Biol. 2014;143:259–265. pmid:24717977

* View Article

* PubMed/NCBI

* Google Scholar

72. 72. Zhang Q, Takahashi M, Noguchi Y, Sugimoto T, Kimura T, Okumura A, et al. Plasma amino acid profiles applied for diagnosis of advanced liver fibrosis in patients with chronic hepatitis C infection. Hepatol Res. 2006;34:170–177. pmid:16436332

* View Article

* PubMed/NCBI

* Google Scholar

73. 73. Beyoglu D, Idle J R. Metabolomic and lipidomic biomarkers for premalignant liver disease diagnosis and therapy. Metabolites. 2020;10. pmid:32012846

* View Article

* PubMed/NCBI

* Google Scholar

74. 74. Xie G, Wang X, Wei R, Wang J, Zhao A, Chen T, et al. Serum metabolite profiles are associated with the presence of advanced liver fibrosis in Chinese patients with chronic hepatitis B viral infection. BMC Med. 2020;18:144. pmid:32498677

* View Article

* PubMed/NCBI

* Google Scholar

75. 75. Gouveia L R, Santos J C, Silva R D, Batista A D, Domingues A L C, Lopes E P A, et al. Diagnosis of coinfection by schistosomiasis and viral hepatitis B or C using 1H NMR-based metabonomics. PLoS ONE. 2017;12:e0182196. pmid:28763497

* View Article

* PubMed/NCBI

* Google Scholar

76. 76. Kamdem S D, Konhawa F, Kuemkon E M, Meyo K L, Tchanana G K, Nche F, et al. Negative association of interleukin-33 plasma levels and schistosomiasis infection in a site of polyparasitism in rural Cameroon. Front Immunol. 2019;10:2827. pmid:31849991

* View Article

* PubMed/NCBI

* Google Scholar

77. 77. Cui L, Lu H, Lee Y H. Challenges and emergent solutions for LC-MS/MS based untargeted metabolomics in diseases. Mass Spectrom Rev. 2018;37:772–792. pmid:29486047

* View Article

* PubMed/NCBI

* Google Scholar

78. 78. Jang C, Chen L, Rabinowitz JD. Metabolomics and Isotope Tracing. Cell. 2018;173:822–837. pmid:29727671

* View Article

* PubMed/NCBI

* Google Scholar

79. 79. Chienwichai P, Tipthara P, Tarning J, Limpanont Y, Chusongsang P, Chusongsang Y, et al. Metabolomics reveal alterations in arachidonic acid metabolism in Schistosoma mekongi after exposure to praziquantel. PLoS Negl Trop Dis. 2021;15:e0009706. pmid:34473691

* View Article

* PubMed/NCBI

* Google Scholar

80. 80. Weiner J III, Maertzdorf J, Sutherland J S, Duffy F J, Thompson E, Suliman S, et al. Metabolite changes in blood predict the onset of tuberculosis. Nat Commun. 2018;9:5208. pmid:30523338

* View Article

* PubMed/NCBI

* Google Scholar

81. 81. Kamdem S D, Kuemkon E M, Kamguia L M, Tchanana G K, Konhawa F, Nche F, et al. An ultrasound-based referential of body height-adjusted normal liver organometry in school children from Bokito in rural Cameroon. Sci Rep. 2020;10:2773. pmid:32066761

* View Article

* PubMed/NCBI

* Google Scholar

82. 82. Lee S, Bountziouka V, Lum S, Stocks J, Bonner R, Naik M, et al. Ethnic variability in body size, proportions and composition in children aged 5 to 11 years: is ethnic-specific calibration of bioelectrical impedance required? PLoS ONE. 2014;9:e113883. pmid:25478928

* View Article

* PubMed/NCBI

* Google Scholar

83. 83. Johnson C H, Ivanisevic J, Siuzdak G. Metabolomics: beyond biomarkers and towards mechanisms. Nat Rev Mol Cell Biol. 2016;17:451–459. pmid:26979502

* View Article

* PubMed/NCBI

* Google Scholar

Citation: Kameni M, Musaigwa F, Kamguia LM, Kamdem SD, Mbanya G, Lamberton PHL, et al. (2024) Harnessing Schistosoma-associated metabolite changes in the human host to identify biomarkers of infection and morbidity: Where are we and what should we do next? PLoS Negl Trop Dis 18(3): e0012009. https://doi.org/10.1371/journal.pntd.0012009