Toxicity of Fungicides

INTRODUCTION

Fungicides are agents that are used to prevent or eradicate fungal infections from plants or seeds. Numerous substances having widely varying chemical constituents are used as fungicides (Gupta, 1988; Gupta, 2016).Fungicides have been classified according to chemical structures or have been categorized agriculturally and horticulturally according to the mode of action (Ballantyne, 2004). According to the mode of application, fungicides are grouped as foliar, soil and dressing fungicides. Foliar fungicides are applied as liquids or powders to the aerial green parts of plants, producing a protective barrier on the cuticular surface and systemic toxicity in the developing fungus. Soil fungicides are applied as liquids, dry powders, or granules, acting either through the vapor phase or by systemic properties. Dressing fungicides are applied to the postharvest crop as liquids or dry powders to prevent fungal infestation of the crop, particularly if stored under less than optimum conditions of temperature and humidity. Thus, effective fungicides must be protective, curative, or eradicative and should possess the following properties: (1) low toxicity to the plant/animal but high toxicity to the particular fungus; (2) activity per se or the ability to convert themselves (by plant or fungal enzymes) into toxic intermediates; (3) the ability to penetrate fungal spores or the developing mycelium to reach the site of action; (4) low ecotoxicity; and (5) the ability to form a protective, tenacious deposit on the plant surface that will be resistant to weathering by sunlight, rain and wind (Phillips, 2001). With a few exceptions, most of the newly developed chemicals have a low order of toxicity to mammals. Public concern has focused on the positive mutagenicity tests obtained with many fungicides and the predictive possibility of both teratogenic and carcinogenic potential. The quantity of fungicides used on major crops is estimated to have increased 2.3-fold between 1964 and 1997. Use of inorganics (primarily copper compound) and dithiocarbamates has declined since the 1960s, but captan, chlorothalonils and other organic materials account for 90% of fungicide use. Newer groups, such as benzimidazoles, conazoles, dicarboximides and metal organic compounds, account for approximately 10% of fungicide use (Osteen and Padgitt, 2002). In this chapter, fungicides are discussed using a chemical classification system.

Background

The earliest fungicides were inorganic materials such as sulfur, lime, copper and mercury compounds. The use of element sulfur as a fungicide was recommended as early as 1803. It has become an important component of integrated pest management systems because it can be used in “organic farming.” There are an increasing number of instances of dermatitis in human farmworkers and diseases in ruminants caused by exposure to high levels of sulfur (Gammon et al., 2010). The mercury-containing fungicides have been responsible for many deaths or permanent neurological disability. Some of the earlier inorganic metallic fungicides have been withdrawn in many countries because of their toxicity and adverse environmental effects (Ballantyne, 2004). Another compound, hexachlorobenzene (HCB), was extensively used from the 1940s through the 1950s as a fungicidal dressing applied to seed grains as a dry powder. Between 1955 and 1959, an epidemic of poisoning occurred in Turkey and resulted in a syndrome called black sore and caused more than 4000 deaths. Although this agent has largely fallen by the wayside, it is still being used in developing countries. It is a highly toxic compound and can lead to severe skin manifestations including hypersensitivity (Hayes, 1982; Gupta, 2010a). Since that time, many compounds have been developed and used to control fungal diseases in plants, seeds and produce. Carbamic acid derivatives, including ethylenebisdithiocarbamates (EBDCs), are a group of fungicides that have been used widely throughout the world since the 1940s. The important members of this class include mancozeb, maneb, metiram, zineb and nabam. All the members have an EBDC backbone, with different metals associated with the individual compounds. Captan, folpet and captafol have been in use for more than 55 years. These compounds belong to the chloroalkylthiodicarboximide class of fungicides due to the presence of chlorine, carbon and sulfur in the side chain. Related compounds associated with this fungicide class are dichlofluanid and tolylfluanid. These two compounds have a fluorine atom substituted for one of the terminal chlorine atoms. Another compound, chlorothalonil, which is a halogenated benzonitrile fungicide, was first registered for use as an agrochemical in the United States in 1966. Chlorothalonil also has wider biocidal applications, including use in paints and lubricant fluids. The benzimidazole fungicides, benomyl and carbendazim, have been in use for more than 40 years, whereas anilinopyrimidines, a new class of fungicides (cyprodinil, mepanipyrim and pyrimethanil), were introduced in 1993 (cyprodinil by Ciba in France) for application on cereal grains (Ollinger et al., 2010).

Toxicokinetics

Toxicokinetic studies provide important data on the amount of toxicant delivered to a target as well as species-specific metabolism. Animals are exposed to fungicides through ingestion or they are absorbed through the skin or the respiratory system. Different factors regulate their absorption, distribution, metabolism and excretion. In general, the liver is the primary site for biotransformation and may include detoxification as well as activation reactions (Gupta, 1986). Some fungicides do not undergo any metabolism and bind with other active binding sites. The aryl organomercurials methyl- and ethylmercury chloride are poorly excreted and tend to accumulate in muscle, brain and other tissues, whereas the aryl organomercurial phenylmercury is more readily excreted via the kidney and less likely to accumulate in brain and muscles. Similarly, HCB possesses all the properties of chemical stability, slow degradation and biotransformation, environmental persistence and bioaccumulation in adipose tissue and organs containing a high content of lipid membranes (Costa, 2008). The newly introduced class of fungicides are rapidly absorbed, metabolized and excreted and do not accumulate in tissues, but some of them are partially absorbed from the gastrointestinal (GI) tract. For example, absorption of chlorothalonil from the GI tract is on the order of 30–32% of the administered dose. At least 80% of the administered dose is excreted in feces within 96 h. The highest concentrations are observed in the kidneys – approximately 0.1% of the dose. In this case, gut microflora plays a role in the disposition and metabolism in rats. Glutathione conjugation plays a central role in the metabolism and subsequent complex metabolic processing of these conjugates, resulting in selective renal uptake and urinary excretion of thiol-derived metabolites. Hepatic glutathione levels are decreased, and renal glutathione levels are elevated. The depletion of hepatic glutathione is considered a direct consequence of glutathione conjugation within the liver utilizing tissue resources. The increase in renal glutathione content is more difficult to explain, but it may be a consequence of urinary excretion of glutathione conjugates (Parsons, 2010).

The captan is rapidly degraded to 1,2,3,6-tetrahydrophthalimide (THPI) and thiophosgene (via thiocarbonyl chloride) in the stomach before reaching the duodenum. THPI has a half-life of 1–4 s, and thiophosgene is detoxified by reaction with cysteine or glutathione and is rapidly excreted. No captan is detected in blood or urine. It is therefore unlikely that these compounds or even thiophosgene would survive long enough to reach systemic targets such as the liver, uterus, or testes. Due to rapid elimination, meat, milk, or eggs from livestock/poultry would be devoid of the parent materials. Humans appear to metabolize captan in a similar manner to other mammals (Krieger and Thongsinthusak, 1993; JMPR, 2004; Gordon, 2010).

Cyprodinil, an anilinopyrimidine class fungicide, is rapidly absorbed from the GI tract into systemic circulation in rats. Approximately 48–68% of the administered dose is excreted in the urine, whereas 29–47% is found in the feces. Total excretions reach 92–97% of the administered dose within 48 h. Cyprodinil is almost completely metabolized. No unchanged parent molecule is found in urine, whereas minor amounts of unchanged cyprodinil are found in feces. Most of the administered cyprodinil is metabolized by sequential oxidation of the phenyl and pyrimidine ring (Figure 48.1). In urine and feces, there is no difference in the metabolite patterns of the phenyl or pyrimidyl labeled cyprodinil. Seven urinary, two biliary and two fecal metabolites have been identified, which in total account for 65–80% of the administered dose. Cyprodinil is absorbed in goats to a lesser extent and more slowly than in rats. The major route of excretion is in urine and feces, whereas excretion via milk is minimal. In laying hens, cyprodinil is rapidly and completely eliminated. Residues in eggs and edible tissues are very low. The metabolic pathways of cyprodinil in lactating goats and laying hens are similar to those observed in rats (Waechter et al., 2010).

Carbamic acid derivative fungicides, such as EBDCs, are only partially absorbed, and then they are rapidly metabolized and excreted with no evidence of long-term bioaccumulation. Absorption of oral doses is rapid, and doses are excreted within 24 h with approximately half eliminated in the urine and half in the feces. Their common metabolite is ethylenethiourea (ETU). Only low-level residues are found in tissues, particularly the thyroid. Another compound in this class, propamocarb, is rapidly and nearly completely absorbed and distributed with a concentration reaching peak levels within 1 h. Elimination from tissues is rapid; with a half-life ranging from 11 to 26 h, urine is the main route of excretion (~75–91% within 24 h). Up to 6% of the administered dose is excreted in feces. Propamocarb is extensively metabolized, and only small quantities are unchanged in urine. Metabolism involves aliphatic oxidation of the propyl chain (to form hydroxyl propamocarb) and N-oxidation and N-demethylation of the tertiary amine resulting in propamocarb N-oxide and mono demethyl propamocarb, respectively. Both benomyl and carbendazim are well absorbed after oral exposure (80–85%) but poorly absorbed after dermal exposure (1 or 2%) in rats, mice, dogs and hamsters. The major pathway of clearance is urinary elimination in rats and mice, but in dogs the majority of the dose (83.4%) is eliminated via feces, with only 16.2% of the dose eliminated in the urine after 72h of dosing. In animals, benomyl is converted into carbendazim through the loss of the n-butylcarbamyl side chain prior to further metabolism. In dogs and rats, carbendazim undergoes aryl hydroxylation–oxidation at the 5 and 6 positions of the benzimidazole ring, followed by sulfate or glucuronide conjugation before elimination. The urinary excretion half-life of carbendazim in both male and female rats is approximately 12 h. Benomyl or carbendazim or their metabolites are cleared rapidly from blood and exhibit minimal potential for bioaccumulation in rats exposed orally or intravenously (Gardiner et al., 1974; JMPR, 2005).

Similarly, amide fungicides are rapidly absorbed and eliminated. Metalaxyl-M and metalaxyl can lead to stimulation of hepatic and renal cytochrome P450 and some other drug metabolizing enzymes. Tolylfluanid is rapidly and extensively absorbed, followed by rapid metabolism and almost complete excretion, mainly in the urine and to a lesser extent in the bile, within 48 h. High tissue concentration has been seen soon after dosing in the kidney and liver, with lower concentrations in the perirenal fat, brain, gonads and thyroid. In most species, the concentration of fluoride in the bone and teeth increases in a dose-related manner (JMPR, 2002, 2005).

After oral dose, conazole fungicides such as triadimenol and triadimefon are rapidly absorbed and widely distributed in liver and kidney. Excretion and metabolism is rapid and extensive, predominantly through oxidation of the t-butyl methyl group. Propiconazole indicates rapid and extensive absorption (80% of the administered dose) and is widely distributed, having the highest concentration in liver and kidney. Excretion is more than 95% in the urine and feces within 48 h. There is extensive enterohepatic recirculation. The compound is extensively metabolized with oxidation of propyl side chain, hydroxylation of phenyl and triazole rings, and conjugation. The cleavage of dioxolane is significantly different according to species and sex (JMPR, 2004). The other compound, fludioxonil, is rapidly and extensively (80%) absorbed, widely distributed, extensively metabolized and rapidly excreted, primarily in feces (80%), with a small amount being excreted in the urine (20%). The maximum blood concentration is reached within 1 h after administration. Elimination is biphasic, with half-lives of between 2 and 5 h for the first phase and between 30 and 60 h for the second phase. The compound is extensively metabolized, involving primarily oxidation of the pyrrole ring (57% of the administered dose) and a minor oxo-pyrrole metabolite (4% of the administered dose), followed by glucuronyl and sulfate conjugation. There is no potential of accumulation in the tissues. Trifloxystrobin is rapidly absorbed (66%) in 48 h and is widely distributed, with highest concentrations in blood, liver and kidney. Within 72 h, 72–96% of the administered dose is eliminated in the urine and feces. Metabolism is extensive, and the compound undergoes hydroxylation, O-demethylation, oxidation, conjugation, chain shortening and cleavage between glyoxylphenyl and trifluoromethyl moieties (JMPR, 2004).

Mechanism of action

There are a series of biochemical changes or free radical-mediated processes; some may also be produced by other mechanisms that have been used to assess tissue injury. This is exemplified by the phenomenon of lipid peroxidation, which has been invoked as a toxic mechanism in many situations and also occurs subsequent to cell death and membrane lysis. However, in most situations, it is difficult to identify the exact mechanism of action. For example, in fungicides containing mercury, the mercury ions inhibit the sulfhydryl group of enzymes involved in the transfer of amino acids across the blood–brain barrier and then interfere with protein synthesis. Organomercurials can also release some mercury ions in the body, but their toxicity is not believed to be a primary action of mercury ions (Sandhu and Brar, 2009). There are several theories regarding the mechanism by which sulfur produces its toxic action. The oxidized sulfur theory attributes toxicity to its oxidation products, such as sulfur dioxide, sulfur trioxide, thiosulfuric acid, or pentathionic acid. The reduced sulfur theory ascribes toxicity to hydrogen sulfide. Direct action theory suggests toxicity due to crosslinking of proteins, formation of other cellular components by free radicals of sulfur or polysulfides, or extensive oxidation of thiol groups leading to loss of function or structural integrity of proteins. Pentachlorophenol (PCP), a halogenated substituted monocyclic aromatic, acts cellularly to uncouple oxidative phosphorylation, with the target enzyme being Na⁺/K⁺-ATPase. Oxygen consumption is increased, whereas adenosine triphosphate (ATP) formation is decreased. The energy is lost as heat instead of being stored as high-energy phosphate bonds. The electron transport chain responds by using increasingly more available oxygen (increased oxygen demand) in an effort to produce ATP, but much of the free energy is lost as body heat. This leads to depletion of energy reserves (Eaton and Gallagher, 1997). Similarly, organotin compounds, particularly triethyltin, uncouple oxidative phosphorylation, whereas other agents (e.g., sulfur) in the presence of sulfiting agents such as sulfur dioxide uncouple oxidative phosphorylation. Thiamine is cleaved into its constituent pyrimidine and thiazole moieties, rendering it inactive.

Although the biochemical and molecular mechanism(s) by which captan and its analogs exert their cellular toxicity has not been fully established, captan is known to react with cellular thiols to produce thiophosgene, a potent and unstable chemical capable of reacting with sulfhydryl-, amino-, or hydroxyl-containing enzymes (Cremlyn, 1978). Thiols reduce the potency of captan. A volatile product of captan is responsible for mutagenic activity, the intermediate being short-lived and formed more quickly at higher levels at an alkaline pH. There are several other mechanisms by which these chemicals can induce cellular toxicity. For example, mouse tumors develop with oral administration above a threshold if maintained for at least 6 months. As shown in Figure 48.1, epithelial cells that comprise the villi are damaged by exposure to captan and sloughed off into the intestinal lumen at an increased rate. Second, the basal cells in the crypt compartment that normally divide at a rate commensurate with the normal loss of villi cells from the tips of the villi increase, resulting in high cell proliferation, which is not carcinogenic per se but does play a role in tumor development. However, there appears to be no treatment-related duodenal tumor incidence of captan in rats or dogs. Some of the data have been compiled in reviews, and a task force and framework have been evolving for evaluation of the mode of toxicity and tumorogenicity findings in mice bioassay and human relevance for risk assessment purposes (Arce et al., 2010; Cohen et al., 2010; Gordon, 2010).

Chlorothalonil fungicide is a reactive molecule toward thio (–SH) groups. It is a soft electrophile with a preference for sulfur nucleophiles rather than nitrogen/oxygen nucleophiles. Such chemicals tend to show reactivity toward protein containing critical S electrophiles rather than toward DNA (containing critical O and N nucleophiles). A mechanistic interpretation for the carcinogenicity of chlorothalonil has been published by Wilkinson and Killeen (1996). Repeated administration of chlorothalonil causes hyperplasia in the forestomach of rats and mice. The data are consistent with a temporal sequence of events starting with increased cell proliferation, multifocal ulceration and erosion of the forestomach mucosa, regenerative hyperplasia and hyperkeratosis, and ultimately progressing to the formation of gastric tumors within the forestomach. In dogs, there is no evidence of either neoplastic development or the occurrence of pre-neoplastic lesions in the kidney or stomach. The absence of stomach lesions in dogs is attributable to the anatomical differences between rodents and dogs – dogs do not possess a forestomach. Continued administration of chlorothalonil leads to the development of a regenerative hyperplasia within the renal proximal tubular epithelium. Continued regenerative hyperplasia ultimately results in progression of the kidney lesion to tubular adenoma and carcinoma. Initial cytotoxicity and regenerative hyperplasia within the proximal tubular epithelium are essential prerequisites for subsequent tumor development. The proposed mode of action for the induction of renal toxicity in rodents is outlined in Figure 48.2.

Fig 48.2 here (plz insert fig 55.3 from 2^nd edition of Vety Toxicology)

The toxicology database supporting mechanism of action of carbamic acid derivatives such as EBDCs and their common metabolite ETU has been explained using modern studies with mancozeb, maneb and metiram because the principal target organ is the thyroid. These compounds inhibit the synthesis of thyroid hormone, thyroxine (T4), and triiodothyronine (T3), leading to elevated levels of thyroid-stimulating hormone (TSH) via feedback stimulation of the hypothalamus and pituitary (Atterwill and Aylard, 1995). Prolonged and continuous elevation of TSH levels results in hypertrophy and hyperplasia of the thyroid follicular cells in rats, mice, hamsters, monkeys and dogs, leading to development of follicular nodular hyperplasia, adenoma and/or carcinoma in rats and mice (Ollinger et al., 2010). Conazoles such as propiconazole have phenobarbital-type mode of action, leading to cell proliferation, increased liver weight and microsomal enzyme induction (JMPR, 2004).

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Gupta PK, (2018) Toxicity of fungicides. In Veterinary Toxicology- Basic and Clinical Principals, Gupta RC (ed.) 3^nd ed. Elsevier, USA pp 569-582.