Nature of hematopoietic system alteration and organ damage induced by fungal filtrate of Pestalotiopsis microspora in vivo

Taofeeq Garuba1, Adebola Azeez Lateef1, Soliu Abiola Atunwa2, Abibat Yetunde Lateef1, Olajumoke Oluwabunmi Kolawole1, Saheed Sabiu3* 1Department of Plant Biology, University of Ilorin, Ilorin, Nigeria. 2Department of Pharmacology and Toxicology, University of Ilorin, Ilorin, Nigeria. 3Department of Biotechnology and Food Science, Faculty of Applied Sciences, Durban University of Technology, Durban, South Africa.


INTRODUCTION
For years, studies have demonstrated the diversity and richness of the plant kingdom in valuable bioactive substances of therapeutic importance against human diseases (Chin et al., 2006;Olumese and Oboh, 2016;Radhia et al., 2018). Specifically, the mushrooms including certain species of Pestalotiopsis have been reported as an excellent source of nutrients and therapeutic compounds for both animals and humans (Garuba et al., 2018).
Pestalotiopsis is a fungus belonging to ascomycetes. The species are widely distributed (Wei and Xu, 2004) and studies are emerging on their ability to incite disease development and their endophytic nature (Maharachchikumbura et al., 2011). This group of fungi is responsible for many diseases in plants such as leaf streak disease, leaf spot, and grape decay caused by Pestalotiopsis royenae, Pestalotiopsis heterocornis, and Pestalotiopsis menezesiana, respectively. Pestalotiopsis palmarum causes leaf spot, petiole blights, and bud rots in palms such as date palm, coconuts, and oil palm (Elliot, 2018). Pestalotiopsis longiseta and Pestalotiopsis theae that caused tea gray blight disease produce oxysporone that is phytotoxic (Nagata and Ando, 1989). Pestalopyrone, pestalotin, hydroxy-pestalotin, and oxysporone are secreted by Pestalotiopsis oenotherae that is responsible for leaf spot disease of evening primrose (Venkatasubbaiah et al., 1991). Despite their disease-causing potential, many of them including Pestalotiopsis microspora, which is usually saprophytic but endophytic in many plant species (Metz et al., 2000), produce bioactive compounds that are medicinally important. For instance, isoxazoline, indolizine, pestacin, isopestacin, yadanzioside D, and heptanol have been isolated from P. microspora and they are pharmaceutically useful in drug production against several diseases (Garuba et al., 2018;Joseph and Priya, 2011). Deshmukh et al. (2017) have also recognized this group of fungi as a prolific producer of beneficial secondary metabolites. While the fungus is industrially and pharmaceutically important as an efficient decomposer of wood, plastics, leather, and a reliable source of an anticancerous agent, taxol (Tiwari, 2015), it could also produce toxic metabolites that are noxious to body organs (Sharma et al., 2016).
Although studies by Thikare et al. (2011) andVinay et al. (2014) have, for instance, demonstrated and established toxicity profiles of culture filtrates from Rhizopus oryzae and Fusarium semitectum, respectively, continuous toxicological assessment of fungi to improve on the currently available limited data is imperative to elucidate their safety applications in animals and human. This is also the case with P. microscopora, where despite its economic and therapeutic significance there are no scientific reports on its safety profiles on the systemic organs of animals feeding on the parent plants from where it is normally isolated. Hence, for the first time, this study investigated the toxicological implications of the culture filtrate of P. microspora on the hematological indices and vital metabolic organs of Wistar rats.

Collection and authentication of P. microspora
Pestalotiopsis microspora was collected from the stock in Plant Pathology Laboratory of the Department of Plant Biology, University of Ilorin, Ilorin, Nigeria. The identity of the fungus had been previously authenticated using both morphological and molecular methods (Garuba et al., 2018) and kept under the voucher specimen number UIL/MYCOLOGY2018/PM003.

Preparation of P. microspora filtrate (PMF)
Adopting the method of Garuba et al. (2013), the culture filtrate of the fungi was prepared. Briefly, a 5 mm of agar disk from a 7-day-old culture of P. microspora was inoculated into potato dextrose broth (PDB) and incubated at 25°C ± 2°C for 14 days. The culture filtrate was filtered into presterilized conical flasks using Whatman no. 1 filter paper. The residue (fragments of mycelia) was discarded and the filtrate was stored in a refrigerator at 4°C ± 2°C (Jalander and Gachande, 2012).

Animals used and the experimental design
The study was reviewed and approved (UERC/ ASN/2019/1878) by the Animal Ethical Committee of the University of Ilorin, Ilorin, Nigeria, adopting the Guidelines of National Research Council Guide for the Care and Use of Laboratory Animals [National Research Council (NRC), 2011] and principles of Good Laboratory Procedures (World Health Organization, 1998). Healthy male Wistar rats (n = 30) weighing 120 ± 10 g, procured from the Central Animal House, University of Ilorin, Ilorin, were used in this study. The animals were kept in a well-aerated room (temperature 25°C ± 2°C, 12 hours alternating photoperiods, and 45%-50% relative humidity) and maintained on normal rat feed (Vita Feed R , Nigeria) and potable water ad libitum. After 7 days of acclimatization, the animals were separated into two groups for acute (n = 10) and repeated dose (n = 20) toxicity testing, respectively.
For the acute toxicity study, the method of Thikare et al. (2011) and Organization of Economic Co-operation and Development (OECD) guideline 420 [Organization of Economic Co-operation and Development (OECD), 2001] were adopted with slight modification. Briefly, the rats that were earlier fasted for 18 hours were randomly divided into two groups (n = 5 per cage). Rats in group 1 were orally given 2 ml PDB and served as a control, while group 2 animals were administered a single oral dose (2 ml/ kg b.w.) of PMF. Subsequently, the animals were placed under close monitoring within the first 4-12 hours and then 24 hourly for 14 days. The rats were weighed before the commencement of the experiment (day 0) and, respectively, on days 3, 7, 10, and 14 with attention paid to any notable changes in behavior and occurrence of diarrhea, depression, weakness and fatigue, sedation, salivation, lethargy, and so on (Sabiu et al., 2015).
In the 28-day repeated dose toxicity testing, the animals were randomly divided into four groups of five rats each as per OECD guideline 408 [Organization of Economic Co-operation and Development (OECD), 2006]. For the dose administration, the control group was administered 2 ml PDB and designated as group 1, while groups 2, 3, and 4 were given 0.25, 0.5, and 0.75 ml/kg b.w. of PMF, respectively, for 28 days following previously described methods (Thikare et al., 2011;Vinay et al., 2014) with slight modifications. All administrations were carried out once daily via oral gavage, while records of the weight of the rats were taken weekly with daily observation on possible signs of humane endpoint, morbidity, and behavioral changes (Sabiu et al., 2015). The observation on the weight changes was used to compute possible weight gain (%) as the relative weight of the animals at the start and end of the experiment, respectively (Sabiu et al., 2015).
On the 15th and 29th days for the acute and repeated dose testing periods, respectively, the rats were humanely euthanized under halothane (1.5%) anaesthetization and blood was collected from the jugular vein into ethylene diamine tetraacetic acid vacutainer tubes. The tubes were then centrifuged (15,000 rpm, 10 minutes) and used for hematological analysis. Organs including the liver, heart, and kidneys were immediately excised subsequent to dissection and thereafter preserved (10% buffered formalin solution) for histopathological examinations.

Histopathological analysis
This was carried out at the Histopathology Laboratory, Faculty of Veterinary Medicine, University of Ilorin, Nigeria, using the method of Bing and Edward (2015). Briefly, the representative sections of the preserved organs (liver, heart, and kidneys) were successively dehydrated in graded ethanol (70%-100%). This was followed by the replacement of the ethanol with an appropriate solvent that is readily mixable with the embedding medium in preparation for embedding. Subsequently, the tissue sections of the organs were treated with xylene to make them transparent (clearing) prior to embedding in an oven maintained at 58°C-60°C. This allowed for solvent evaporation and provision of spaces within the tissues for para-n. Exactly, 5 μm from each paraffin-impregnated tissue was floated on water and then transferred to a glass slide for staining (hematoxylin and eosin) and subsequent viewing (with a simple Olympus light microscope) with magnification of ×10.

Data analysis
The data were subjected to descriptive statistics and tests for significant difference were carried out by one-way analysis of variance complemented with Duncan's test using the Statistical Package for Social Science (SPSS) for Windows, version 16.0 (SPSS Inc., Chicago, IL). The results are expressed as the mean ± standard error of the mean (SEM) with p-values of <0.05 considered statistically significant.

Acute toxicity
The acute oral administration of 2 ml/kg b.w. of PMF produced no observable clinical sign or behavioral changes in Wistar rats. The data on weight changes of the animals at days 0, 3, 7, 10, and 14 revealed no significant difference (p > 0.05) between the PMF-treated rats and the animals in the control group with an overall weight gain of 14.23% and 17.44%, respectively (Fig. 1). Similarly, no statistically significant variation (p > 0.05) was observed in the hematological parameters investigated between the control group and the PMF-treated animals (Table 1).
Comparative observation across the photomicrographs of the hepatocytes of the animals showed well-outlined arrays of hepatic cells and vessels with no observable cytoarchitectural distortion in the control group ( Fig. 2A), while cellular damage characterized with hemorrhage, fibrosis, and necrosis was observed in the hepatic cytoarchitecture of the PMF-treated rats (Fig. 2B). The pericardium, myocardium, and endocardium were conspicuous in the cardiocytes of the rats in the control group (Fig. 3A) compared to the degenerative changes with mild fibrosis observed in the PMF-administered animals (Fig. 3B). Similarly, no deleterious effects and cell distortion was observed in the cytoarchitecture of the kidney cells in the control group (Fig. 4A) which is in sharp contrast to the observed features in PMF-treated animals, where the kidney cells are characterized by overly large capsular spaces and hemorrhagic glomeruli which appeared to be edematous/dropsy (Fig. 4B).

28-day toxicity testing
No mortality, behavioral changes such as convulsion, tremor, diarrhea, and excess urine output were recorded during cage-side observations throughout the experimental period. The weight of both the PMF-treated rats and the control animals increased significantly (p < 0.05) throughout the experimental period with the highest percentage weight gain (35.59%) observed in the rats administered 0.50 ml PMF (Table 2). Except for the observed significant differences (p < 0.05) in the WBC and PLT counts of the PMF-administered rats relative to the control, data obtained with respect to the hematological parameters of the PMFtreated animals are compared favorably with those of the control group (Table 3).
While the histoarchitecture of hepatocytes of the control group remained essentially well preserved (Fig. 5A), the 28-day repeated dosing with graded doses of PMF induced hepatocellular damage in the treated animals with obvious infiltrations including nuclear degeneration with significant cytotoxicity, necrosis, and distortion of the hepatic cytoarchitecture ( Fig. 5B-D). Also, the cardiocytes of the control group were intact with adequately demonstrated striations across the myocardium (Fig. 6A). However, the cardiocytes of the rats administered with the lowest dose of PMF (0.25 ml) showed degenerative changes with mild fibrosis (Fig. 6B), while those treated with 0.50 ml of PMF revealed mild areas of vegetation which have eroded the normal orientation and structure of the heart cells (Fig. 6C). Fibrous tissues densely infiltrated by sparse inflammatory cells were also     observed (Fig. 6C). Furthermore, large vascular spaces some of which contained blood lining by epithelial cells were observed in the group administered with the 0.75 ml PMF (Fig. 6D). Similarly, the repeated administration of the graded doses of PMF stimulated degeneration in the kidney cells with invasion by neutrophil and deposition of fibrin. The cortical tubules were shrunk and atrophic, and heavy polymorphonuclear infiltration was also observed around the renal artery ( Fig. 7B-D). However, the animals in the control group were devoid of these observations as their renal cells revealed no observable histoarchitectural infiltrations (Fig. 7A).

DISCUSSION
For years, endophytes and mushrooms have been recognized as an important source of medicines and valuable    Values carrying different superscript across the same row are significantly different (p < 0.05).
raw materials in the food, cosmetic, and biochemical industries (Sharma et al., 2016;Tiwari, 2015). Despite these immense applications, endophytes remain hugely underutilized with their full benefits untapped. One of the reasons for the underutilization, especially as medicines could be adduced to absence or inadequate toxicological data to establish their safety profiles. While data exist on the characterization of novel compounds of therapeutic significance from endophytes (Alvin et al., 2014;Bhardwaj and Agrawal, 2014;Garuba et al., 2018;Gouda et al., 2016), studies are just emerging on their toxicological dynamics when consumed by livestock and humans. In this study, the nature of the toxicological effect of P. microspora on vital metabolic organs was investigated in vivo.
Although the acute toxicity evaluation is normally an initial phase in the determination of LD 50 of a substance (Lorke, 1983), the observations in this study have suggested a probable no-observed-adverse-effect level of the 2 ml/kg b.w. dose of PMF at which the animals are expected to survive during a 14day observation period. However, while this observation was further corroborated by the nontoxic effect of the culture filtrate on the body weight and hematological parameters of the animals, the observed PMF-induced alterations and cytoarchitectural infiltrations in the hepatocytes, cardiocytes, and kidney cells of the treated rats are suggestive of selective toxicity of PMF on the investigated organs at the tested dose.
With the observed selective toxicity elicited by the 2 ml/ kg b.w. PMF acutely, a further probe was made through the repeated dosing toxicity testing of the filtrate at lower doses (0.25-0.75 ml/ kg b.w.) to better comprehend the pattern of the observed effect. Interestingly, the nature of the selective toxicity became more evident from the significantly increased body weight of the PMFtreated rats relative to the control and this could be attributed to PMF-induced weight hypertrophy. Changes in body weight index constitute one of the initial vital signs of toxicity and could be a useful indicator of the health status of animals (Sireatawong et al., 2008). Although PMF has been reportedly rich in compounds of therapeutic importance, the observation in this study suggests that the repeated administration of the filtrate at the tested doses could have impaired normal metabolism and facilitated abnormal growth and developmental mechanisms in the animals. Changes in body weight of animals resulting from treatment with culture filtrate of fungi species have also been similarly reported in previous studies (Kwack et al., 2009;Park et al., 1999).
Evaluation of hematological indices can be employed to establish both the blood-related functions of a substance such as fungi culture filtrate or the degree of alteration or toxicological  effect it has on the blood composition of animals (Sharma et al., 1983). Again, a type of parameter-specific toxicity nature of PMF was demonstrated by specifically altering the blood levels of PLTs and WBCs with no significant effect on other hematological parameters investigated in this study following 28-day exposure period. The blood level of WBC could be indicative of the defensive capability of an organism against pathogens or foreign substances (Ajani et al., 2014). In this study, the significantly increased WBCs of the PMF-administered rats could be indicative of inherent allergy, stress, inflammation, and infection attributable to PMF administration. Furthermore, the repeated dosing with PMF significantly and selectively increased PLT counts in the treated rats may be suggestive of its effect on thrombopoietin which could have impacted thrombopoiesis, enhanced vascular damage, and thrombocytopenia in animals. The observations on the WBCs and PLTs in this study are consistent with the reports of Fodor et al. (2006), Kwack et al. (2009), andTikare et al. (2016), on the parameters-related effects of fungi isolates on the hematopoietic systems of experimental animals.
Histopathological examination is a major consideration that could be used to assess the nature of toxicity of an agent on vital metabolic organs and the results are usually complementary to the results of hematological analysis (Sabiu et al., 2015). The characteristic fibrosis, necrosis, and hemorrhagic cytoarchitectural infiltrations observed in the hepatocytes, heart, and kidney cells of the PMF-treated animals is an attestation to the organ damage effect of the repeated dosing with PMF at the investigated doses. With this observation, the vital roles of these metabolic organs including those of the liver in detoxification, deamination, nutrient supply, and indeed homeostasis are prone to compromise and could result in eventual organ and system failure. This submission is not only supportive of the nature of organ damage induced by the acute dose of the culture filtrate but also a further attestation to the pattern of selective toxicity exhibited by PMF in this study. In addition to the doses investigated and the experimental period, the nature of toxicity elicited by PMF may be adduced to its toxins or antinutrients, which might have coexisted with its acclaimed therapeutic compounds. The findings on the histopathological analyses of the organs in this study agree with previous studies (Fodor et al., 2006;Sharma et al., 1983;Thikare et al., 2011;Tikare et al., 2016), where observed infiltrations and cytopathic effects on the key organs of laboratory animals were attributed to treatment with fungi isolates.

CONCLUSION
Consequent to the data presented in this study, PMF exhibited parameter-specific toxicity on the hematopoietic system with a well-defined pattern of organ damage in the experimental animals. While this study has provided baseline information on the nature of liver, heart, and kidney damage by PMF at the investigated doses and exposure periods in vivo, studies seeking to confirm the presence of toxins/antinutritional factors and establishing comprehensive pharmacokinetic and pharmacodynamic data about PMF are essential. In this direction, efforts are underway.

AUTHOR CONTRIBUTIONS
All authors made substantial contributions to conception and design, acquisition of data, or analysis and interpretation of data; took part in drafting the article or revising it critically for important intellectual content; agreed to submit to the current journal; gave final approval of the version to be published; and agree to be accountable for all aspects of the work. All the authors are eligible to be an author as per the international committee of medical journal editors (ICMJE) requirements/guidelines.

FUNDING
There is no funding to report.