Introduction

Toxoplasma gondii (phylum Apicomplexa), an intracellular protozoan parasite responsible for toxoplasmosis, affects a wide number of hosts including non-human animals and humans with varying morbidity and mortality (Howe and Sibley, 1995; Dubey, 2010; Calero-Bernal and Gennari, 2019). Notwithstanding, T. gondii is known to cause sporadic clinical disease and fatality in marine mammals in many geographic areas. It is considered emergent in certain locations, such as the Arctic (Donahoe et al., 2014). T. gondii was first described in Brazil and Tunisia in 1908 (Nicolle and Manceaux, 1908; Splendore, 1908; Ferguson, 2009). Furthermore, the first record of toxoplasmosis in cetaceans was in a Guiana dolphin (Sotalia guianensis) from Rio de Janeiro state, Brazil, in the 1970s (Bandoli and Oliveira, 1977). Since then, knowledge on the exposure and the infection of this protozoan has been gained primarily by serological, pathological, and molecular techniques in a wide variety of captive and free-ranging cetaceans worldwide (Inskeep et al., 1990; Omata et al., 2006; Mazzariol et al., 2012; Gonzales-Viera et al., 2013; Costa-Silva et al., 2019).

In recent years, T. gondii has increasingly been recognized in odontocetes, pinnipeds, and mustelids (Van Wormer et al., 2016; Reisfeld et al., 2019; Shapiro et al., 2019). Nonetheless, there is very limited information in mysticetes, including a seropositive humpback whale (Megaptera novaeangliae) from the Atlantic Ocean (Forman et al., 2009) and a fin whale (Balaenoptera physalus) co-infected with Cetacean Morbillivirus (CeMV) in the Mediterranean Sea (Mazzariol et al., 2012). The Bryde’s whale (B. edeni) is one of the least known baleen whales (Kato and Perrin, 2008) being currently regarded as “data deficient” by the International Union for Conservation of Nature (Redlist of threatened species, 2013). The geographical location of the Bryde’s whale ranges from 40° N to 40° S in tropical and temperate waters, including the Indian, North and South Pacific, and Atlantic oceans (Kato and Perrin, 2008). This species occurs regularly along the coast off the states of S o Paulo and Rio de Janeiro, southeastern Brazil (Lodi et al., 2015).

Toxoplasma gondii has been typically regarded as a secondary or opportunistic pathogen for cetaceans (Migaki et al., 1990; Domingo et al., 1992; Kennedy, 1998; Mikaelian et al., 2000; Dubey et al., 2008; Van Bressem et al., 2009), yet various reports have suggested its primary pathogenic role in the absence of evident concomitant disease and/or demonstrated toxicologic stress levels (Miller et al., 2001; Di Guardo et al., 2011; Gonzales-Viera et al., 2013). Genotyping of T. gondii may provide insight into the dynamics of the protozoan at terrestrial and aquatic environments and their interfaces with implications for public health. Three clonal lineages (I, II, and III) and various atypical (non-archetypal) strains are described based on their variability in genetic markers and pathogenicity in mice (Howe and Sibley, 1995; Ajzenberg et al., 2004; Pena et al., 2008; Sibley et al., 2009; Shwab et al., 2014). Overall, there is very limited information available on T. gondii genotypes affecting marine mammals. In North America, the T. gondii genotypes identified in marine mammals include types I, II, X, and A (Conrad et al., 2005; Dubey, 2010; Gibson et al., 2011). Interestingly, most human infections in North America and Europe are linked to type II T. gondii, which is also common in livestock in these regions (Sibley et al., 2009). Type II and atypical type II T. gondii isolates were detected in striped dolphins (Stenella coeruleoalba) stranded on the Ligurian Sea coast of Italy (Di Guardo et al., 2011). Atypical type II genotypes were also recently identified in Hector’s dolphins (Cephalorhynchus hectori) from New Zealand (Roe et al., 2013) and a fur seal (Arctocephalus forsteri) from New South Wales, Australia (Donahoe et al., 2014). Given the relatively limited knowledge on T. gondii genotype distribution among marine mammals worldwide and more specifically in Brazil, as well as the elusive potential epidemiological associations with public health and terrestrial T. gondii epidemiology, this study aimed at reporting the results of pathological, immunohistochemical, and molecular genotyping analyses in a Bryde’s whale with disseminated toxoplasmosis.

Method

A 10.7-m-long, adult, male Bryde’s whale was stranded alive on August 21, 2018 in “Pontal do Ipiranga,” Linhares, Espirito Santo state (Brazil). The animal died shortly after stranding and autopsy was performed promptly as per standard protocol (Geraci and Lounsbury, 2005). Representative tissue samples of the heart, aorta, lung, trachea, mediastinal, pulmonary, tracheobronchial, mesenteric and prescapular lymph nodes, diaphragm, tongue, stomach, intestine, liver, kidney, urinary bladder, spleen, pancreas, testicle, epididymis, skin, rectus abdominis, and longissimus dorsi were collected and fixed in 10% neutral buffered formalin. All these tissues were processed routinely and embedded in paraffin wax, and 5-μm-thick sections were stained with hematoxylin and eosin (H&E) for microscopic analysis. Selected tissue samples were collected and kept frozen (−20°C) for molecular analyses. For immunohistochemistry (IHC), a primary polyclonal anti-T. gondii antibody (1:400 dilution; VMRD Inc., Pullman, WA, United States) was employed, followed by an avidin-biotin-peroxidase complex method (Elite ABC kit, Vector Laboratories, Burlingame, CA, United States) (Costa-Silva et al., 2019), in the lung, liver, spleen, and lymph node (prescapular, pulmonary, mediastinal, and mesenteric) tissue sections. A positive control included the adrenal gland from a T. gondii-positive Guiana dolphin (Gonzales-Viera et al., 2013). As negative control, sequential tissue sections were incubated with non-immune homologous serum.

For the molecular analysis, tissue fragments (∼1 g each) of lung, liver, spleen, and lymph nodes (prescapular, mediastinal, pulmonary, and mesenteric) were homogenized separately with 500 μl of Tris-ethylenediaminetetraacetic acid (EDTA) buffer (10 mM Tris–HCl and 1 mM EDTA, pH 8.0) using a pestle and a mortar. Furthermore, 250 μl of each homogenate was used with a commercial kit (DNeasy Blood^® & Tissue kit, Qiagen, Hilden, Germany) for DNA extraction, according to the manufacturer’s instructions. A polymerase chain reaction (PCR) targeting the amplification of the repetitive 529-bp fragment from T. gondii genome was employed for the molecular detection of T. gondii (Homan et al., 2000). PCR-restriction fragment length polymorphism (RFLP) was performed to identify the genotypes of T. gondii. Reference archetypal strains RH (type I), PTG (type II), and CTG (type III) and T. gondii non-archetypal strains (TgCgCa1, MAS, and TgCatBr5) were included as positive controls in all reactions. The following markers were used: SAG1, 5′3′SAG2 and alternatively SAG2, SAG3, BTUB, GRA6, c22-8, c29-2, L358, PK1, Apico (Su et al., 2010), and CS3 (Pena et al., 2008). The genotyping by microsatellite (MS) technique employed 15 markers (TUB2, W35, TgM-A, B18, B17, M33, MIV.1, MX1, M48, M102, N60, N82, AA, N61, and N83) (Ajzenberg et al., 2010). The reference archetypal strain PTG was used as the positive control. An automatic sequencer (3500 Genetic analyzer AB Hitachi, Life Tech, São Paulo, Brazil) and the GeneMapper software (version 4.1; Applied Biosystems) were used for electrophoresis and fragment analysis, respectively. All DNA from the positive controls used in this study were kindly provided by Dr. Chunlei Su from the Department of Microbiology, The University of Tennessee, Knoxville, Knoxville, TN, United States. This study was approved by the Instituto Chico Mendes de Conservação da Biodiversidade and was conducted under SISBIO license #48279-4. This study is in agreement with the Ethical Principles in Animal Research adopted by the “Ethic Committee in the Use of Animals” of the School of Veterinary Medicine and Animal Science of the University of São Paulo (protocol #5580110315).

Results

Grossly, the main pathologic findings were diffuse axial skeletal muscle atrophy, systemic congestion, petechiation, ecchymoses, necrotizing splenitis, hepatitis, myocarditis, pneumonia, lymphadenitis (prescapular, pulmonary, mediastinal, and mesenteric), bilateral scapulohumeral hemarthros, and severe pulmonary edema (Figure 1). Microscopically, the lymphoid system had marked, multifocal to coalescing, acute multicentric necrotizing lymphadenitis and splenitis with necrotizing vasculitis and thrombosis. The liver had marked, multifocal to coalescing, acute necrotizing hepatitis with vasculitis and thrombosis. In the respiratory system, there was marked, diffuse, acute fibrinonecrotizing interstitial pneumonia with abundant hyaline membranes, vasculitis, and thrombosis. The cardiovascular system had mild to moderate, multifocal, acute/subacute lymphohistiocytic myocarditis with necrosis and hemorrhage and moderate, multifocal, chronic fibrosing endarteritis and endocarditis with hemorrhage. In the reproductive system, there was necrotizing orchitis and periorchitis with hemorrhage and acute neutrophilic and lymphohistiocytic epididymitis with vasculitis and hemorrhage. In the digestive system, there was multifocal, acute enteritis with fibrin and edema and mild, multifocal, acute necrotizing gastric leiomyositis with vasculitis and fibrin. The inflammatory foci in all the aforementioned organs had moderate to large numbers of protozoan cysts and extracellular tachyzoites morphologically compatible with T. gondii (Figure 2). Additional relevant pathologic findings non-related to toxoplasmosis were those attributed to live stranding stress response, primarily characterized by acute, hyaline segmental myodegeneration and necrosis in the rectus abdominis and longissimus dorsi muscles.

FIGURE 1

FIGURE 2

Results of the immunohistochemistry showed cysts and tachyzoites in tissues (Figure 2). All analyzed whale tissues were T. gondii-positive by the 529-bp fragment PCR. This strain from B. edeni was designated as PS-TgBaledBrES1. Based on genotyping by PCR-RFLP and MS analysis, the novel ToxoDB-RFLP genotype #3001 (Table 1), a non-archetypal, unique genotype (Table 2), was revealed in all the samples analyzed.

TABLE 1

TABLE 2

Discussion

Fatal toxoplasmosis in marine mammals often is associated with hepatitis, meningoencephalitis, adrenalitis, lymphadenitis, interstitial pneumonia, retinochoroiditis, thymitis, placentitis, and myocarditis. Early embryonic death and resorption, fetal death and mummification, and stillbirth and neonatal death may be seen in animals with transplacental infections (Inskeep et al., 1990; Migaki et al., 1990; Jardine and Dubey, 2002; Resendes et al., 2002; Dubey et al., 2008; Dubey, 2010). In the present case, the pathological signature was characterized by multisystemic necrotizing inflammation with vasculitis and disseminated intravascular coagulation with thrombosis and myriads of intralesional protozoal cysts morphologically compatible with T. gondii. These pathological findings are analogous to various previous reports of fatal systemic acute toxoplasmosis in susceptible marine and terrestrial animal species, including man (Dubey and Jones, 2008). To the best of our knowledge, only one previous report documented toxoplasmosis in a mysticete, specifically a fin whale (Mazzariol et al., 2012). Although no pathological findings were observed in the latter (probably related to decomposition status), the IHC analysis revealed protozoan cysts in kidney and heart (Mazzariol et al., 2012). Moreover, the PCR analyses detected T. gondii genomic sequences in renal, cardiac, and skeletal muscle and in mesenteric lymph node (Mazzariol et al., 2012). The whale had positive PCR results for CeMV but no evident morbilliviral antigen in the tissues examined (Mazzariol et al., 2012). The findings observed in the present case suggest that T. gondii may be a cause of severe systemic infection and death in Bryde’s whales, widening the host record for this pathogenic protozoan. Immunosuppression by chemical pollutants, such as polychlorinated biphenyls, or concurrent infections, such as CeMV, are known predisposing factors for toxoplasmosis in cetaceans (Mikaelian et al., 2000; Di Guardo and Mazzariol, 2013; Lair et al., 2016). In this case, CeMV infection was ruled out on the basis of immunohistochemical and molecular analyses (data not shown). We did not perform toxicologic analyses; thus, potential chemical pollutant-based immunosuppression could not be excluded in this case.

The genus Toxoplasma consists of only one species that shows a clonal population structure in the northern hemisphere with few dominant genotypes and an epidemic population structure in the southern hemisphere with high diversity, particularly in Central and South America (Shwab et al., 2014). RFLP genotype #1 (type II), #2 (type III), #3 (type II variant), and #10 (type I) are identified globally. Genotypes #2 and #3 dominate in Africa, genotypes #9 and #10 are prevalent in Asia, genotypes #1, #2, and #3 are prevalent in Europe, and genotypes #1, #2, #3, #4, and #5 dominate in North America. In Central and South America, there is no clear dominance of any genotype, even though a few have relatively higher frequencies (Shwab et al., 2014). In Brazil, considering all published studies, the three most frequent genotypes are #6 (Type BrI), #11 (Type BrII), and #13 (Pena et al., 2008; Shwab et al., 2014; Feitosa et al., 2017). There are limited reports of T. gondii with genotyping characterization in marine mammals, particularly in cetaceans. The three clonal lineages are sporadically reported in marine mammals, but other genotypes (atypical, type A, type X, and type 12) appear to be common (Jardine and Dubey, 2002; Conrad et al., 2005; Miller et al., 2004; Honnold et al., 2005; Dubey et al., 2007, 2008, 2009, 2011; Sundar et al., 2008; Dubey, 2010; Gibson et al., 2011). Molecular analyses in stranded St. Lawrence Estuary (Québec, Canada) belugas identified primarily genotype II (Iqbal et al., 2018), which predominates in humans from North America and Europe, and two new atypical genotypes of T. gondii (De Guise et al., 1995; Mikaelian et al., 2000; Haman et al., 2013; Lair et al., 2016). Interestingly, in North America and Europe, type II T. gondii is also common in livestock (Sibley et al., 2009).

Mixed or atypical infections of genotypes with unique alleles, combinations of alleles, or multiple genotypes have been rarely documented in marine mammals (Gibson et al., 2011). Types X, A, and II-like were shown to comprise a new 4th clonal lineage, haplogroup 12 (Dubey et al., 2011; Khan et al., 2011). Type II and atypical type II T. gondii isolates were detected in striped dolphins (S. coeruleoalba) stranded on the Ligurian Sea coast of Italy (Di Guardo et al., 2011). Atypical type II genotypes were also recently identified in Hector’s dolphins (C. hectori) from New Zealand (Roe et al., 2013) and a fur seal (A. forsteri) from New South Wales, Australia (Donahoe et al., 2014). In the present case, the genotyping results identified a novel non-archetypal T. gondii, which in this case appears to be highly pathogenic for the whale host species, although many factors other than strain type can be related to pathogenicity, including dose, infective stage, and immunity status. The potential public health implications/associations of this novel non-archetypal T. gondii remain elusive in this case due to lack of identical isolates to date. It is worth mentioning that there is potential risk for transmission of T. gondii by whale meat consumption in geographic areas where this practice may still occur, including Brazil (Lima et al., 2006a).

The transmission pathways through which “inshore” and “offshore” cetaceans acquire T. gondii infection remain uncertain. Three main infective stages of T. gondii are recognized: (1) sporozoites (in sporulated oocysts), (2) bradyzoites (in tissue cysts of intermediate hosts), and (3) tachyzoites (Dubey et al., 1998). T. gondii oocysts have been demonstrated in runoff waters, shellfish, and filter-feeding fish (Van Bressem et al., 2009; Massie et al., 2010; Putignani et al., 2011). Multiple T. gondii genotypes have been reported in marine invertebrates (Shapiro et al., 2015). Furthermore, oocysts may survive in seawater and remain infective for up to 6 months (Lindsay and Dubey, 2009). Domestic and wild felids are the only known definitive hosts, shedding unsporulated oocysts. After sporulation, the oocysts can be infectious to susceptible intermediate hosts, which include most vertebrate species (Dubey, 2010). The carnivorous intermediate hosts can also become infected by consuming tissue cysts within other intermediate hosts (Dubey, 2010).

The source of T. gondii infection in the present Bryde’s whale is unknown. In Brazil, in the post-whaling era, Bryde’s whales are reported mainly along the southeastern coast (Gonçalves and Andriolo, 2006; Figueiredo et al., 2015; Lodi et al., 2015) and in offshore areas of São Paulo (Goncalves et al., 2016). This species primarily occurs in deep waters far off the coast (Andriolo et al., 2010) at different depths and at relatively high densities in upwelling areas (Wiseman et al., 2011; Forney et al., 2012; Weir et al., 2012). It possibly uses coastal areas for feeding and may migrate to oceanic areas for breeding (Goncalves et al., 2016). Sardines (Siciliano et al., 2004), Engraulidae fish (Lima et al., 2006b), aviu shrimp (Acetes americanus) (Moura and Siciliano, 2012), snubnose anchovy (Anchoviella brevirostris), and white snake mackerel (Thyrsitops lepidopoides) are part of the known diet of Bryde’s whale in Brazil (Lodi et al., 2015). Recent evidence showed Bryde’s whales feeding in the coastal waters of Brazil, primarily preying upon sardines (Goncalves et al., 2016). Furthermore, in coastal waters, the likelihood of exposure to runoff waters and interactions with seabirds increases. Interestingly, sardines and anchovies are able to pass T. gondii oocysts in their feces (Massie et al., 2010). If exposed to contaminated nearshore waters, sardines could then serve as biotic vectors for T. gondii in neritic and oceanic waters (offshore migrations) (Marino et al., 2019). Waterborne T. gondii exposure by infective oocysts in polluted water is an increasingly recognized source of infection. Surface water runoff tributes to coastal streams or directly to the ocean from urban and non-urban areas with no pre-treatment (Miller et al., 2002). Seabirds, including Brazilian species of orders Suliformes and Phaethontiformes, are known to be exposed to T. gondii (Gennari et al., 2016); however, their potential contribution to T. gondii transmission from land to sea environments remains unknown. From the discussion above, the ingestion of infecting oocysts or cysts from the water column or preys is the most plausible possibility in this case. Unfortunately, this whale had no solid gastrointestinal contents that might shed some light into a potential prey-associated T. gondii transmission. Further source and transmission-related conclusions are precluded by the lack of any previous report on this novel non-archetypal T. gondii strain, which also highlights the genetic diversity yet to be reported of the agent.

Concluding Remarks

In summary, we documented a case of fatal, acute systemic toxoplasmosis in a Bryde’s whale stranded in Brazil. The pathologic signature in this animal was characterized by multisystemic necrotizing inflammation with vasculitis and disseminated intravascular coagulation with thrombosis and numerous intralesional protozoan cysts and extracellular tachyzoites morphologically compatible with T. gondii. This pathogen was further confirmed by IHC and PCR analyses. PCR-RFLP and MS techniques identified a novel non-archetypal T. gondii called PS-TgBaledBrES1 (ToxoDB-RFLP genotype #300). These novel results add to the scarce data on T. gondii genotype distribution in cetaceans, represent the first record of toxoplasmosis in a Bryde’s whale, and set the baseline knowledge for future research on T. gondii genotyping research in marine mammals from South America.

Data Availability Statement

The datasets generated for this study can be found in the http://toxodb.org/toxo.

Ethics Statement

Ethical review and approval was not required for the animal study because no specific ethical review and approval was required for this particular study involving a single stranded marine mammal. However, our laboratory and our coworkers’ research projects operate with multiple permits from multiple institutions including the Brazilian Government.

Author Contributions

JD-D, KG, HR, AC, and JC-D contributed to the conception and design of the study. HR and AC performed the necropsy examination. JD-D, KG, and JC-D conducted histopathological, immunohistochemical, and molecular analyses. BA and HP conducted molecular analyses. JD-D and KG wrote the first draft of the manuscript. All the authors contributed to manuscript revision and read and approved the submitted version.

Funding

The authors are grateful to Dr. Larissa Pavanelli, volunteers and staff members of the Instituto Baleia Jubarte and CTA-Meio Ambiente for their assistance in necropsy procedures. The rescue program was carried out as required by state environmental licensing of the Terminal Marítimo de Belmonte-BA, conducted by INEMA. This study comprised a parallel research initiative while conduction of post-doctoral fellowship projects funded by São Paulo Research Foundation (FAPESP Grants #2014/24932-2; #2017/243352; #2017/02223-8; and #2018/01876). This research was also supported by Coordination for the Improvement of Higher Education Personnel – Brazil (CAPES), finance code 001 PNPD grant #1812894. JC-D is the recipient of a fellowship by the National Research Council (CNPq; grant #304999/2018-0).

Conflict of Interest

The authors declare that the research was conducted in the absence of any commercial or financial relationships that could be construed as a potential conflict of interest.

Footnotes

1. ^ http://toxodb.org/toxo/