Introduction
The detection of anthelmintic drug resistance in nematode parasites during the early phases of its emergence is problematic in both animals and humans. Methods for anthelmintic resistance detection that are based on phenotype, whether by in vivo drug efficacy or in vitro bioassay, lack sensitivity, with resistance typically only being detected once the parasite population comprises more than 25% drug-resistant individuals (Martin et al., Reference Martin, Anderson and Jarrett1989; Coles et al., Reference Coles, Bauer, Borgsteede, Geerts, Klei, Taylor and Waller1992; Rendell, Reference Rendell2010; De Graef et al., Reference De Graef, Sarre, Mills, Mahabir, Casaert, De Wilde, Van Weyenberg, Geldhof, Marchiondo, Vercruysse, Meeus and Claerebout2012). Consequently, by the time resistance is detected, effective mitigation strategies, such as the use of drug combinations and/or refugia management, are already severely comprised. Molecular diagnostic techniques that detect the causal mutations of resistance, or genetically linked markers, have the potential to allow resistance to be detected at an early stage and enable more effective evidence-based resistance management. Further, the identification of known drug resistance mutations at a low frequency in parasite populations that are phenotypically susceptible to anthelmintics may help assess the risk of resistance emergence under the influence of drug selection pressure. Current progress in parasite genomics is increasing our ability to elucidate the genetic basis of resistance in many parasite species (Doyle and Cotton, Reference Doyle and Cotton2019). Combining the results of genomic research with new DNA sequencing and genotyping technologies will provide exciting opportunities for resistance surveillance and risk assessment. In this paper, we apply deep-amplicon sequencing, using the Illumina MiSeq short read sequencing platform, to detect low-frequency benzimidazole resistance-associated mutations in cattle and bison parasites as a proof-of-concept and example of a post-genomic approach to resistance surveillance.
The combined endo- and ectoparasite activity, convenient pour-on formulation and low cost of macrocyclic lactone drugs such as ivermectin have resulted in their widespread use for parasite control in cattle for decades. In contrast, although the benzimidazoles are highly effective against a large range of internal nematode parasites, their lack of ectoparasite activity and less convenient oral formulation has meant they have been less commonly used in cattle, particularly in North America. Macrocyclic lactone resistance is now common in gastrointestinal nematodes in North American cattle (Gasbarre et al., Reference Gasbarre, Smith, Lichtenfels and Pilitt2009, Reference Gasbarre, Ballweber, Stromberg, Dargatz, Rodriguez, Kopral and Zarlenga2015). Anecdotal evidence suggests that more cattle producers are beginning to consider using benzimidazole drugs for gastrointestinal nematode control and this trend is likely to continue as the awareness of ivermectin resistance grows. Many of the same gastrointestinal nematode species that occur in cattle also infect bison (Avramenko et al., Reference Avramenko, Redman, Lewis, Bichuette, Palmeira, Yazwinski and Gilleard2017, Reference Avramenko, Bras, Redman, Woodbury, Wagner, Shury, Liccioli, Windeyer and Gilleard2018). Due to the greater risk of clinical disease associated with gastrointestinal nematodes in bison than in cattle, although commercial bison herds still predominantly rely on pour-on macrocyclic lactones for control, there has been somewhat greater use of benzimidazole drugs in this host species (pers comm ref from Dr Roy Lewis, Merck Animal Health). Consistent with the relatively limited use, there has, as yet, only been a few cases of confirmed benzimidazole-resistant parasites in North American cattle (Gasbarre et al., Reference Gasbarre, Smith, Lichtenfels and Pilitt2009; Chaudhry et al., Reference Chaudhry, Miller, Yazwinski, Kaplan and Gilleard2014). However, in countries where the benzimidazoles have been more heavily used in cattle, such as New Zealand, Australia and South America, resistance is becoming widespread in gastrointestinal nematodes of cattle (McKenna, Reference McKenna1991; Waghorn et al., Reference Waghorn, Leathwick, Rhodes, Lawrence, Jackson, Pomroy, West and Moffat2006; Cotter et al., Reference Cotter, van Burgel and Besier2015; Ramos et al., Reference Ramos, Portella, Rodrigues, Reginato, Pötter, Cezar, Sangioni and Vogel2016).
We have a good understanding of the causal mutations most likely to be found in cattle trichostrongylid species from research in Haemonchus contortus and other phylogenetically related nematode parasites of sheep (Gilleard, Reference Gilleard2013; Gilleard and Redman, Reference Gilleard and Redman2016). Three non-synonymous single nucleotide polymorphisms (SNPs), F167Y (TTC > TAC), E198A (GAA > GCA) and F200Y (TTC > TAC), in the isotype-1 β-tubulin gene are associated with benzimidazole resistance in several sheep trichostrongylid gastrointestinal nematodes (Kwa et al., Reference Kwa, Veenstra and Roos1994, Reference Kwa, Veenstra, Van Dijk and Roos1995; Prichard, Reference Prichard2001; Ghisi et al., Reference .Ghisi, Kaminsky and Mäser2007; Avramenko et al., Reference Avramenko, Redman, Melville, Bartley, Wit, Queiroz, Bartley and Gilleard2019). These amino acid codons (167, 198 and 200) have been shown to be important residues in the benzimidazole binding pocket and their effect on drug sensitivity has been functionally demonstrated (Aguayo-Ortiz et al., Reference Aguayo-Ortiz, Méndez-Lucio, Romo-Mancillas, Castillo, Yépez-Mulia, Medina-Franco and Hernández-Campos2013). The role of the F200Y (TTC > TAC) polymorphism in benzimidazole resistance has also been functionally confirmed in the free-living nematode Caenorhabditis elegans and H. contortus, a parasitic nematode of sheep (Kwa et al., Reference Kwa, Veenstra, Van Dijk and Roos1995). The F200Y (TTC > TAC) and F167Y (TTC > TAC) polymorphisms have shown to be under selection and/or associated with benzimidazole resistance in natural field populations for several parasitic nematodes of sheep including H. contortus, Teladorsagia circumcincta, Trichostrongylus axei, Trichostrongylus colubriformis and Cooperia oncophora among others (Grant and Mascord, Reference Grant and Mascord1996; Njue and Prichard, Reference Njue and Prichard2003; Gilleard, Reference Gilleard2006; Avramenko et al., Reference Avramenko, Redman, Melville, Bartley, Wit, Queiroz, Bartley and Gilleard2019). For codon 198, a substitution of glutamic acid for alanine in H. contortus and glutamic acid for leucine substitution in T. circumcincta and T. axei have been also described in natural field populations (Redman et al., Reference Redman, Whitelaw, Tait, Burgess, Bartley, Skuce, Jackson and Gilleard2015; Keegan et al., Reference Keegan, Good, de Waal, Fanning and Keane2017; Avramenko et al., Reference Avramenko, Redman, Melville, Bartley, Wit, Queiroz, Bartley and Gilleard2019). A substitution of glutamic acid for valine (E198V; GAA > TTA) in T. circumcincta and T. axei was also recently identified (Avramenko et al., Reference Avramenko, Redman, Melville, Bartley, Wit, Queiroz, Bartley and Gilleard2019).
We recently developed deep-amplicon sequencing methodology to screen for DNA sequence polymorphisms at codons 167, 198 and 200 of the isotype-1 β-tubulin gene in the major trichostrongylid nematode parasites of sheep (Avramenko et al., Reference Avramenko, Redman, Melville, Bartley, Wit, Queiroz, Bartley and Gilleard2019). Gastrointestinal nematodes in North American cattle and bison provide a practical situation in which a similar deep-amplicon sequencing approach can be used to screen drug resistance mutations either before, or at an early stage of emergence, to help assess the risk of phenotypic resistance emerging under the influence of drug selection pressure.
To date, no large-scale analysis of benzimidazole drug resistance mutations has been completed on cattle farms in either North or South America. In this paper, we apply our previously developed isotype-1 β-tubulin deep-amplicon sequencing assay to parasite populations isolated from beef cattle herds from Canada, the mid-southern USA and Sao Paulo State, Brazil and from both commercial and conservation bison herds from Western Canada. This paper represents the largest screen of benzimidazole resistance mutations in cattle and bison nematodes to date. It demonstrates a proof-of-concept of the detection of low-frequency drug resistance mutations in the early stages of emergence and suggests benzimidazole resistance has the potential to emerge quite quickly in cattle parasite populations if this drug class is applied to a greater extent in North American cattle and bison populations.
Materials and methods
Parasite material
Mid-southern US cattle herds
Samples used were originally described in Avramenko et al. (Reference Avramenko, Redman, Lewis, Bichuette, Palmeira, Yazwinski and Gilleard2017), and have been used in this paper with permission. Fecal samples were collected from 38 individual stocker cattle entering feedlot operations throughout 2014 in Oklahoma (22), Arkansas (3) and Nebraska (13). Each calf was from a different stocker cattle delivery from farms across the mid-southern USA, and thus likely represent animals derived from different farms. Collected fecal samples were cultured and stored as previously described.
Sao Paulo State, Brazilian cattle herds
Samples used were originally described in Avramenko et al. (Reference Avramenko, Redman, Lewis, Bichuette, Palmeira, Yazwinski and Gilleard2017), and have been used in this paper with permission. Fecal samples were collected from 26 farms, from calves 6–9 months of age, across Sao Paulo State in Brazil during August and September of 2015. Three individual fecal samples were collected per farm, and separately cultured before pooling all collected L3s into a single sample. Collected fecal samples were cultured as and stored previously described.
Canadian cattle herds
Samples used were originally described in Avramenko et al. (Reference Avramenko, Redman, Lewis, Bichuette, Palmeira, Yazwinski and Gilleard2017), and have been re-used in this paper with permission (Avramenko et al., Reference Avramenko, Redman, Lewis, Bichuette, Palmeira, Yazwinski and Gilleard2017). Fecal samples were originally collected from beef herds across Canada from June to December of 2012. Twenty individual fecal samples were collected per rectum or freshly voided on pasture, from groups of calves on pasture or entering feedlots. Fecal samples were collected with an approved Animal Use Protocol (Animal Care Committee, Study #AC13-0157, University of Calgary, Canada), which is in accordance with the principles outlined in the Guidelines of the Canadian Council on Animal Care. Exact details regarding sample collection can be found in Avramenko et al. (Reference Avramenko, Redman, Lewis, Bichuette, Palmeira, Yazwinski and Gilleard2017). Coprocultures were set up as described in Roberts and O'Sullivan (Reference Roberts and O'Sullivan1950); however, vermiculite was used in place of sawdust, and samples were incubated at room temperature (~20°C). Third stage larvae (L3) were harvested from each individual fecal sample and subsequently pooled by herd. These pools of larvae were split into aliquots of ~1000–2000 when there were sufficient larvae. Larval aliquots were fixed in 70% ethanol and stored at −80°C until needed. Following quality assurance, 43 beef herd samples were included in the analysis; Alberta (19), Saskatchewan (7), Manitoba (2) and Ontario (15).
Canadian bison herds
Sampled bison herds were originally described in Avramenko et al. (Reference Avramenko, Bras, Redman, Woodbury, Wagner, Shury, Liccioli, Windeyer and Gilleard2018) and have been reused in this paper with permission (Avramenko et al., Reference Avramenko, Bras, Redman, Woodbury, Wagner, Shury, Liccioli, Windeyer and Gilleard2018). Exact information regarding sample collection and herd details can be found in Avramenko et al. (Reference Avramenko, Bras, Redman, Woodbury, Wagner, Shury, Liccioli, Windeyer and Gilleard2018). Approximately 10–20 individual, freshly voided fecal pats were sampled and pooled from the pasture of each of the main production groups within a herd during farm visits, including cow–calf production groups (mature cows and bulls, replacement heifers and calves) and feeder production groups (yearling bison being fed for slaughter). Samples were collected between October 2014 and January 2015. Several of these production groups were managed by the same producer, making them part of the same overall herd. In addition, after quality assurance, 51 bison production group samples were included in this analysis: British Columbia (BC) (5), Alberta (16), Saskatchewan (15) and Manitoba (15). Further details regarding these samples can be found in Avramenko et al. (Reference Avramenko, Bras, Redman, Woodbury, Wagner, Shury, Liccioli, Windeyer and Gilleard2018). In addition, freshly voided fecal samples were collected from individual bison from three conservation bison herds in Canadian national parks. These were Grasslands National Park (GNP) plains bison herd (Bison bison bison) (19 samples), Elk Island National Park (EINP) wood bison herd (Bison bison athabascae) (16 samples) and EINP plains bison herd (B. bison bison) (20 samples). Collected fecal samples were cultured and stored as previously described.
Isotype-1 β-tubulin deep-amplicon sequencing
DNA preparations were made from the pooled larval samples as described in Avramenko et al. (Reference Avramenko, Redman, Lewis, Yazwinski, Wasmuth and Gilleard2015). A fragment of the isotype-1 β-tubulin gene was amplified and sequenced from these pooled larval populations by deep-amplicon sequencing as previously described and validated in Avramenko et al. (Reference Avramenko, Redman, Melville, Bartley, Wit, Queiroz, Bartley and Gilleard2019). Sequencing was undertaken using the Illumina MiSeq, with the 2 × 250 bp v2 reagent kit (Illumina Inc., San Diego, CA, USA). Up to 384 samples were pooled in a single run and an average read depth of ~16 000 reads was obtained for each sample. Any samples, not providing a distinct first round PCR amplicon, as visualized on an agarose gel, or samples resulting in less than 2000 sequence reads were removed from the analysis as this is indicative of poor sample preparation.
Bioinformatic analysis
Samples were analysed following the bioinformatic analysis pipeline outlined in Avramenko et al. (Reference Avramenko, Redman, Melville, Bartley, Wit, Queiroz, Bartley and Gilleard2019). In its current format, the deep-amplicon sequencing assay and subsequent bioinformatic pipeline are capable of detecting isotype-1 β-tubulin sequences from the following species: C. oncophora, Cooperia punctata, Cooperia pectinata, Cooperia curticei, H. contortus, Haemonchus placei, T. circumcincta, Ostertagia ostertagi, Orloffia bisonis, T. axei, T. colubriformis and Trichostrongylus vitrinus. For the purposes of this paper, the data were mined only for sequence variants at codons 167, 198 and 200 of the isotype-1 β-tubulin gene for each species.
Nemabiome ITS-2 metabarcoding of populations
Nemabiome ITS-2 metabarcoding was previously carried out on all populations assessed in this paper. This provides the relative quantification of all nematode species present within mixed-species samples. Exact details regarding the method and the original results can be found in Avramenko et al. (Reference Avramenko, Redman, Lewis, Bichuette, Palmeira, Yazwinski and Gilleard2017) for the cattle samples from Canada, the USA and Brazil, while information pertaining to the Canadian bison samples can be found in Avramenko et al. (Reference Avramenko, Bras, Redman, Woodbury, Wagner, Shury, Liccioli, Windeyer and Gilleard2018). The nemabiome barcoding technique is fully described in Avramenko et al. (2015) and at https://www.nemabiome.ca/index.html, and the results from these previous papers have been included with permission. Figures from both Avramenko et al. (Reference Avramenko, Redman, Lewis, Bichuette, Palmeira, Yazwinski and Gilleard2017, Reference Avramenko, Bras, Redman, Woodbury, Wagner, Shury, Liccioli, Windeyer and Gilleard2018) are reproduced in this paper under the terms of the Creative Commons Attribution 4.0 International License (http://creativecommons.org/licenses/by/4.0/). These data provide context for the species assessed for each sample, and are a reflection of the total percentage of the population a particular species represents.
Results
Beef cattle herds from the mid-southern USA, Sao Paulo State, Brazil, Canada, and commercial and conservation bison herds from Western Canada were screened for the presence and frequency of non-synonymous SNPs at codons 167, 198 and 200 of the isotype-1 β-tubulin using a previously developed and validated deep-amplicon sequencing assay.
Beef cattle from the mid-southern USA
A total of 38 individual stocker cattle entering feedlots in Oklahoma (22), Arkansas (3) and Nebraska (13) were assessed. Isotype-1 β-tubulin reads were identified in these samples, above the 200 reads per species threshold, for C. oncophora, O. ostertagi, C. punctata, H. placei and T. axei. The frequencies of non-synonymous mutations at codons 167, 198 and 200 were determined for these five species [Fig. 1, Table 1 (F200Y (TTC > TAC)), Table 2 (F167Y (TTC > TAC)), Supplementary Table S1 (F200L (TTC > TTA)) and S2 (F167L (TTC > TTA))]. The F200Y (TTC > TAC) SNP was found above the 0.1% species threshold in all five species, primarily in calves from Oklahoma; C. oncophora (five calves, frequency range 0.19–0.34), O. ostertagi (15 calves, frequency range 0.29–12.03%), C. punctata (16 calves, frequency range 0.18–7.75%), H. placei (15 calves, frequency range 0.57–27.45%) and T. axei (five calves, frequency range 8.49–57.43%) (Fig. 1 and Table 1). The F200Y mutation was also found in H. contortus in one US animal (US 10) at 1.7% [data not shown as H. contortus were only identified at >200 reads in two samples (US6 and US10)]. The F167Y (TTC > TAC) SNP was identified in just two of the five species at low frequency; O. ostertagi (four calves frequency range 0.13–0.38%) and C. punctata (two calves, range 0.23–0.3%) (Fig. 1, Table 2). The E198A (GAG > GCG) mutation was detected in O. ostertagi in one animal (US 6) at 0.51%, but was not detected in any other animal or species. The F167L and F200L SNPs were identified in C. punctata, C. oncophora, O. ostertagi and H. contortus in several animals at <1% frequency (Supplementary Tables S1 and S2).
Beef cattle from Sao Paulo State, Brazil
Calves from a total of 26 herds from Sao Paulo State, Brazil were assessed; isotype-1 β-tubulin reads were identified in these samples, above the 200 reads per species threshold, for C. punctata, C. pectinata, H. placei, H. contortus and T. axei. The frequencies of non-synonymous mutations at codons 167, 198 and 200 were determined for these five species [Fig. 2 (F200Y (TTC > TAC)), Table 2 (F167Y (TTC > TAC)), Supplementary Table S1 (F200L (TTC > TTA)) and S2 (F167L (TTC > TTA))]. The F200Y (TTC > TAC) SNP was found above 0.1%, in C. punctata [one herd (BR6), 0.25%], C. pectinata [one herd (BR21), 0.47%], H. placei [three herds (BR6, BR15, BR16), range 0.4–3.33%] and H. contortus (three herds, range 48.78–90.22%). The F167Y (TTC > TAC) SNP was also found above 0.1% for C. punctata [one herd (BR21), 0.13%], H. placei [one herd (BR6), 0.25%] and H. contortus (three herds, range 2.22–40.58%). The F200L (TTC > TTA) SNP was detected in C. punctata (three herds, range 0.18–0.21%), C. pectinata (one herd, 0.14%) and H. placei (two herds, 0.51–4.68%). The F167L (TTC > TTA) SNP was detected in C. pectinata, H. placei and T. colubriformis in several herds <1%.
Beef cattle from Canada
A total of 43 Canadian beef cattle herds were assessed comprising herds from Alberta (19), Saskatchewan (7), Manitoba (2) and Ontario (15). Consistent with the species composition of these herds, as previously determined by ITS-2 rDNA nemabiome sequencing of the same samples, isotype-1 β-tubulin reads mapping to just three species were identified; C. oncophora, O. ostertagi and C. punctata (Supplementary Fig. S1). The data for C. punctata were analysed for just those four herds for which there were at least 200 reads mapping to this parasite species (being the threshold that we have designated for reliable analysis). The frequencies of non-synonymous mutations at codons 167, 198 and 200 were determined [Supplementary Fig. S1, Table 1 (F200Y (TTC > TAC)), Table 2 (F167Y (TTC > TAC)), Supplementary Table S1 (F200L (TTC > TTA)) and S2 (F167L (TTC > TTA))]. At the detection frequency threshold of 0.1%, none of the F167Y (TTC > TAC), E198A (GAA > GCA) and F200Y (TTC > TAC) SNPs that have been previously associated with benzimidazole resistance in trichostrongylid nematodes were identified in any of these herds. The majority of worms had the susceptible genotype at each of the three codons. F167L (TTC > TTA) and F200L (TTC > TTA) SNPs, which have not been previously associated with benzimidazole resistance in previous studies, were identified at low frequencies in C. oncophora and O. ostertagi from several herds. An E198Stop (GAA > TAA) SNP was identified in C. oncophora in two herds (CAN14 and CAN19) at the frequencies of 2.07% and 2.78%, respectively.
Commercial and conservation Bison herds from Western Canada
A total of 51 Canadian commercially farmed bison production groups from BC (5), Alberta (16), Saskatchewan (15) and Manitoba (15) were assessed. In addition, 55 individual animal samples from three Canadian national park conservation herds were assessed [GNP plains bison herd (19); EINP plains bison herd (16); EINP wood bison herd (20)]. Isotype-1 β-tubulin reads were identified in these samples, above the 200 reads per species threshold, for C. oncophora, O. ostertagi, O. bisonis, H. placei and T. axei. The frequencies of non-synonymous mutations at codons 167, 198 and 200 were determined for these five species [Supplementary Fig. S2 (F200Y (TTC > TAC)), Table 2 (F167Y (TTC > TAC)), Supplementary Table S1 (F200L (TTC > TTA)) and S2 (F167L (TTC > TTA))]. In the commercial bison herds, the F200Y (TTC > TAC) SNP was identified above 0.1% O. ostertagi (seven herds, range 0.38–15.21%) and O. bisonis (one herd, 0.58%), most of which were from Manitoba. The F167Y (TTC > TAC) SNP was not identified in any species from any herd. The F200L (TTC > TTA) SNP was identified in C. oncophora (three herds, range 0.25–0.68%), O. ostertagi (one herd, 2.76%) and H. placei (two herds, range 0.15–0.39%). The F167L (TTC > TTA) SNP was identified in O. ostertagi (five herds, range 0.31–0.98%), H. placei (two herds, range 0.11–0.29%) and T. axei (one herd, 0.11%).
In the conservation herds, neither the F200Y (TTC > TAC) nor F167Y (TTC > TAC) SNPs were identified in any species, in any animal. However, the F200L (TTC > TTA) SNP was identified in C. oncophora (five animals, range 0.12–0.39%), O. ostertagi (three animals, range 0.14–1.06%) and T. axei (four animals, range 0.2–40.55%). The F167L (TTC > TTA) SNP was identified in C. oncophora (two animals, range 0.91–2.4%), O. ostertagi (two animals, range 0.2–5.68%), O. bisonis (one animal, 0.18%) and T. axei (one animal, 0.18%).
Discussion
Benzimidazole resistance-associated SNPs were detected in multiple trichostrongylid nematode species in calves derived from multiple beef cattle herds in the mid/southern USA
There have been no large-scale studies specifically investigating benzimidazole drug resistance in cattle parasites in North America. A recent large study investigated the levels of anthelmintic resistance in 72 beef cattle herds across 19 US states (Gasbarre et al., Reference Gasbarre, Ballweber, Stromberg, Dargatz, Rodriguez, Kopral and Zarlenga2015). Evidence of macrocyclic lactone resistance was found on approximately 1/3 of surveyed farms, mainly for Cooperia spp. However, benzimidazole efficacy was only tested for five of these herds and there was a >90% reduction of egg counts in each of these cases. Benzimidazole resistance has only been clinically confirmed for H. contortus from parasites infecting cattle from the USA, and so benzimidazole resistance is not considered to be a major issue at present (Gasbarre et al., Reference Gasbarre, Smith, Lichtenfels and Pilitt2009; Gasbarre, Reference Gasbarre2014). Nevertheless, the F200Y (TTC > TAC) SNP has been detected at low frequency in H. placei from Georgia, Florida and Arkansas, using a pyrosequence genotyping assay suggesting resistance is at the early stages of emergence in this parasite species (Chaudhry et al., Reference Chaudhry, Miller, Yazwinski, Kaplan and Gilleard2014). In this study, we have performed a much wider and deeper scan for benzimidazole resistance-associated SNPs in multiple parasitic nematode species in US beef cattle, compared to previous efforts. Parasites were harvested from individual stocker calves upon feedlot entry, each being derived from separate deliveries of stocker cattle entering feedlots, so as to broadly sample the parasites derived from 38 different stocker herds. We detected the F200Y (TTC > TAC) SNP in all of the six trichostrongylid nematode species identified (C. oncophora, C. punctata, O. ostertagi, H. placei, H. contortus and T. axei) (Fig. 1 and Tables 1 and 2). Of particular concern is the detection of the F200Y (TTC > TAC) SNP in O. ostertagi, generally considered to be the most pathogenic GI nematode of cattle, from as many as 15 out of 34 of the stocker cattle tested (Navarre, Reference Navarre2020). These were generally present at relatively low frequency but were as high as 12.03% in one calf. This suggests that benzimidazole resistance-conferring mutations, although still at the early stages of emergence, are already widespread in the parasite species in the mid-southern regions of the USA (particularly in Oklahoma).
The low frequency of benzimidazole resistance mutations that we have found in each parasite population means that resistance would not be phenotypically apparent and would not be detected by fecal egg count reduction test (FECRT) tests, particularly in mixed-species infections (Martin et al., Reference Martin, Anderson and Jarrett1989). A similar situation is true for both H. placei and to a lesser extent C. punctata, both of which are also pathogenic nematodes capable of causing clinical disease and production loss. Trichostrongylus axei is one of the less common trichostrongylid nematode species in cattle and was only found in sufficiently high numbers to test for the presence of benzimidazole-resistant SNPs in just five stocker cattle tested. The F200Y (TTC > TAC) SNP was found in T. axei from four out of the five animals for which this parasite species was tested and was as high as 57.43% in one of these animals (US5). This suggests that benzimidazole resistance may be more advanced for this parasite species in the USA. However, since T. axei comprised only 6.1% of the parasite population in this sample, this level of benzimidazole resistance would still not have been detected using the standard FECRT without coproculture, which does not discriminate between different trichostrongylid nematode species. It will be interesting to investigate if this parasite species becomes more predominant under the influence of selection if benzimidazole use increases in US beef cattle. The F167Y (TTC > TAC) SNP was also identified in both C. oncophora (four animals) and O. ostertagi (two animals), though it was only found at a frequency of <1%.
Overall, these results demonstrate that benzimidazole resistance mutations are widespread, but generally still at low frequencies in the mid-southern USA in all the cattle nematode species we assessed. This suggests that, if benzimidazole drug use is increased in grazing cattle, widespread emergence of benzimidazole resistance is likely and could emerge quite quickly at multiple locations depending on the selection pressure applied. This suggests mitigation strategies, such as the use of drug combinations and refugia management, will be critical to prevent resistance emergence in this region. It will be important to undertake follow-up studies to track this emergence in US cattle in the coming years.
Benzimidazole resistance-associated SNPs were rare and at very low frequency in cattle nematode species but at high frequency in H. contortus isolated from beef cattle from Sao Paulo State, Brazil
Although there have been relatively few published benzimidazole resistance studies in cattle in Brazil, the available evidence suggests that phenotypic resistance is higher than in the USA (Jaeger and Carvalho-Costa, Reference Jaeger and Carvalho-Costa2017). Phenotypic benzimidazole resistance has been reported in several regions of Brazil (Brasil et al., Reference Brasil, Nunes, Bastianetto, Drummond, Carvalho, Leite, Molento and Oliveira2012; Ramos et al., Reference Ramos, Portella, Rodrigues, Reginato, Pötter, Cezar, Sangioni and Vogel2016, Reference Ramos, Marques, Reginato, Bräunig, Osmari, Fernandes, Sangioni and Vogel2019; Jaeger and Carvalho-Costa, Reference Jaeger and Carvalho-Costa2017). A study in Sao Paulo State published in 2007 reported five out of 25 beef cattle herds to have moderate to high levels of benzimidazole resistance (FECR of <90%), although the resistant parasite species was not determined and the presence of resistance mutations not assessed (Soutello et al., Reference Soutello, Seno and Amarante2007).
In our study of calves screened from 26 different herds from Sao Paulo State, the F200Y (TTC > TAC) SNP was only identified for a very small number of herds; C. punctata (one herd), C. pectinata (one herd) and H. placei (three herds) and was at very low frequency in each case (<4%) (Fig. 2, Table 1). The F167Y (TTC > TAC) mutation was also found in C. punctata and H. placei in just one herd for each and at very low frequency in each case (<0.5%) (Fig. 2, Table 2). Hence, the herd prevalence and frequencies of these two benzimidazole resistance-associated SNPs were very low in cattle parasite species in the region of Sao Paulo sampled. Indeed, the frequencies of these SNPs were lower than those found in the mid-southern US herds which is perhaps surprising. Interestingly, however, for H. contortus, found to be present in three different herds in this study, the F200Y (TTC > TAC) SNP was present at a very high frequency in each case (48.78–90.22%). The F167Y (TTC > TAC) SNP was also present at moderate to low frequencies in each of these cases (2.22–40.58%). Haemonchus contortus is primarily a sheep parasite, which can also infect cattle, and surveys of sheep have shown high levels of benzimidazole resistance throughout Brazil, including Sao Paulo State (Niciura et al., Reference Niciura, Veríssimo, Gromboni, Rocha, de Mello, Barbosa, Chiebao, Cardoso, Silva, Otsuk, Pereira, Ambrosio, Nardon, Ueno and Molento2012; Chagas et al., Reference Chagas, Sampaio Junior, Pacheco, da Cunha, Cruz, J. dos, Scofield and Góes-Cavalcante2016). Since co-grazing of sheep and cattle is relatively common in Brazil, much more so than in the USA or Canada, it is possible that many of the cases of phenotypic benzimidazole resistance reported in Brazilian cattle could be due to H. contortus infections. Interestingly, a recent study provides some support for this hypothesis: Molecular identification of the parasite species surviving benzimidazole treatments in seven different cattle herds in Rio Grande du Sul revealed the only parasite species surviving treatment was H. contortus (Ramos et al., Reference Ramos, Marques, Reginato, Bräunig, Osmari, Fernandes, Sangioni and Vogel2019). Further, cattle on these seven farms were all co-grazing with sheep. These results suggest a hypothesis in which the higher prevalence of phenotypic benzimidazole resistance in cattle parasites in Brazil compared to the USA could be due, at least in part, to cattle co-grazing with resistant parasite-infected sheep, rather than greater drug selection in the Brazilian cattle themselves. More work is required to explore this hypothesis further.
Benzimidazole resistance-associated SNPs at codons 167, 198 and 200 were not detected in trichostrongylid nematode populations from 43 Canadian beef herds sampled in 2012
None of the previously described benzimidazole resistance-associated SNPs at codons 167, 198 and 200 of the isotype-1 β-tubulin gene were detected in the Canadian beef cattle herds by deep-amplicon sequencing using a sensitivity threshold of 0.1% frequency for each species in each population. Each of the samples used to generate DNA templates contain approximately 1000 L3 larvae in total, with C. oncophora and O. ostertagi comprising ~50% of the nematode populations each. Consequently, an average of ~500 L3 larvae, equating to ~1000 isotype-1 β-tubulin alleles, were screened for each species in each sample. Theoretically, this means that the lowest frequency that any allele can be present in any sample, corresponding to a single heterozygote, is 0.1%. Although we recognize that this could equate to lower than 0.1% frequency of sequence reads derived from a sample, due to the effect of amplification biases, we have used 0.1% as our operational detection threshold, to take a conservative approach. Nevertheless, we further explored the potential for O. ostertagi and C. oncophora being present below our 0.1% operational frequency threshold by determining the absolute number of each non-synonymous SNP at codons 167, 198 and 200 in the total dataset for each species when all samples were combined. For O. ostertagi, the F200Y (TTC > TAC) SNP was identified in 98 out of 276 852 sequences, and the F167Y (TTC > TAC) SNP in 23 out of 276 852 sequences; an overall prevalence of 0.035% and 0.008% across the 43 herds, respectively. For C. oncophora, the F200Y (TTC > TAC) SNP was identified in 212 out of 415 272 sequences, and the F167Y (TTC > TAC) SNP in 20 out of 415 272 sequences, giving them an overall frequency of 0.05% and 0.005% across the 43 herds, respectively. Consequently, it is possible that these benzimidazole resistance SNPs are present in the Canadian parasite populations at an extremely low frequency. However, at these very low frequencies, it is possible that these sequences were the result of contamination from other samples (which is unlikely as these mutations were not present at high frequency in any of the samples analysed in the whole study), or were more likely a result of PCR amplification or sequencing errors. More experimental work will need to be done to resolve this question.
The absence, or extremely low frequency, of the F200Y (TTC > TAC), E198A (GAA > GCA) and F167Y (TTC > TAC) resistance mutations in the Canadian cattle herds suggests that the emergence of benzimidazole resistance is less likely than in the mid-southern USA. This is probably due to even lower use of this drug class in the Canadian beef cattle cow–calf sector over the last few decades than in the USA (Hildreth and McKenzie, Reference Hildreth and McKenzie2020; Navarre, Reference Navarre2020). It is important to note though that these samples were collected during 2012, and so it will be important to repeat similar studies over the next few years.
Benzimidazole resistance-associated SNPs are present in O. ostertagi in parasite populations from Canadian bison herds
We detected the F200Y (TTC > TAC) benzimidazole resistance-associated SNP in O. ostertagi and O. bisonis in seven and one out of 50 commercial bison production groups, respectively. Although these were at relatively low frequency in most herds, the frequency was as high as 15.21% for O. ostertagi in one of the herds (Fig. 3). This contrasts with the result for the Canadian beef cattle herds in which the F200Y (TTC > TAC) SNP was not seen above the 0.1% threshold frequency for O. ostertagi in any of 43 herds assessed (Fig. 3). This result might be due to benzimidazoles being more commonly used in commercial bison herds due to the greater concern of clinical problems in bison than in cattle in Canada although we are not aware of any data to support this (pers. comm. Dr Roy Lewis). The finding of the F200Y (TTC > TAC) SNP present in O. ostertagi, derived from Canadian commercial bison herds, is of concern. This parasite is highly pathogenic in bison and the emergence of resistance to benzimidazoles would be a major problem for the industry both in terms of animal welfare and production. Furthermore, O. ostertagi is the most economically important and pathogenic parasitic nematode of cattle in temperate regions. Consequently, the presence of benzimidazole-resistant O. ostertagi in the Canadian grazing ecosystem presents a risk of transmission into cattle (Avramenko et al., Reference Avramenko, Redman, Lewis, Bichuette, Palmeira, Yazwinski and Gilleard2017, Reference Avramenko, Bras, Redman, Woodbury, Wagner, Shury, Liccioli, Windeyer and Gilleard2018). This risk will depend on the extent of pasture sharing/rotation between cattle and bison which needs to be carefully considered for the future management of anthelmintic resistance in both bison and cattle.
Additional SNPs identified in codons 167, 198 and 200 of the isotype-1 β-tubulin gene and their potential for conferring benzimidazole resistance of trichostrongylid nematode populations
One of the inherent advantages of the deep-amplicon sequencing approach, compared with other diagnostic approaches such as real-time PCR and pyrosequence genotyping, is its ability to detect new unanticipated sequence polymorphisms. In this paper, we have confined the focus to the three codons of interest in the isotype-1 β-tubulin gene; 167, 198 and 200. Nevertheless, we identified several SNPs not previously reported in parasitic nematodes.
The F200L (TTC > TTA) and F167L (TTC > TTA) SNPs were identified at low frequencies across a variety of species in a number of herds from all locations surveyed (Fig. 1, Supplementary Figs S1–3). There is clear functional evidence that benzimidazole resistance is conferred by the F200Y (TTC > TAC) and F167Y (TTC > TAC) SNPs in nematodes and fungi (Roos et al., Reference Roos, Boersema, Borgsteede, Cornelissen, Taylor and Joost Ruitenberg1990; Kwa et al., Reference Kwa, Kooyman, Boersema and Roos1993, Reference Kwa, Veenstra and Roos1994, Reference Kwa, Veenstra, Van Dijk and Roos1995; Njue and Prichard, Reference Njue and Prichard2003; Gilleard, Reference Gilleard2006; Kitchen et al., Reference Kitchen, Ratnappan, Han, Leasure, Grill, Iqbal, Granger, Halloran and Hawdon2019). In addition to these SNPs, the E198A (GAA > GCA), (E198 V GAA > GTA) and E198L (GAA > TTA) polymorphisms have clear functional evidence in fungi (Zou et al., Reference Zou, Ying, Shen and Feng2006; Banno et al., Reference Banno, Fukumori, Ichiishi, Okada, Uekusa, Kimura and Fujimura2008; Aguayo-Ortiz et al., Reference Aguayo-Ortiz, Méndez-Lucio, Romo-Mancillas, Castillo, Yépez-Mulia, Medina-Franco and Hernández-Campos2013; Liu et al., Reference Liu, Chen, Jiang, Hamada, Yin and Ma2014; Zhang et al., Reference Zhang, Brankovics, van der Lee, Waalwijk, van Diepeningen, Xu, Xu, Chen and Feng2016). Although there have been no such functional studies in nematodes for F200L (TTC > TTA) and F167L (TTC > TTA), the F167L (TTC > TTA) polymorphism has been implicated in benzimidazole resistance in fungi (Zou et al., Reference Zou, Ying, Shen and Feng2006; Msiska and Morton, Reference Msiska and Morton2009). Structural modelling studies suggest that the F167Y (TTC > TAC) and F200Y (TTC > TAC) SNPs reduce the binding affinity of benzimidazoles by increasing the polarity in the binding pocket while the E198A (GAA > GCA) SNP and E198L (GAA > TTA) polymorphism are predicted to disrupt the formation of a key H-bond interaction (Aguayo-Ortiz et al., Reference Aguayo-Ortiz, Méndez-Lucio, Romo-Mancillas, Castillo, Yépez-Mulia, Medina-Franco and Hernández-Campos2013). Hence it seems a reasonable hypothesis that the F200L (TTC > TTA) and F167L (TTC > TTA) SNPs could also affect benzimidazole binding affinity; however, further functional work in nematodes will be required to determine if this is the case.
A stop codon at codon 198 (GAA > TAA) of the isotype-1 β-tubulin gene was detected at a frequency of ~2% in two populations of C. oncophora from Canadian cattle (CAN14, CAN19). This mutation is predicted to result in a null allele and so a resistance phenotype. Null alleles have not been previously reported in the isotype-1 β-tubulin gene of trichostrongylid nematodes. This could be partly due to a bias in the approaches routinely used to screen for β-tubulin mutations which are unlikely to detect frameshift mutations or deletions. Alternatively, it could be due to a fitness cost to the loss of a functional copy of this gene, limiting the potential of null mutations to be selected to high frequency in the field. As with most previous studies, we have focused specifically on mutations previously shown to be associated with benzimidazole resistance. In future studies, it will be important to screen for additional mutations. Mining the data across the other codons in the amplified isotype-1 β-tubulin fragment in this study revealed premature stop codons in all species identified, from all regions sampled at codons 144, 153, 157, 158, 166, 172, 181, 183, 194, 208 (data not shown). In the majority of cases, these appeared at <1% frequency. The highest frequency was 18.5% at codon 183 in C. oncophora from farm CAN38. Such null alleles essentially remove the major drug target from the worm and so would be predicted to result in a resistance phenotype.
In conclusion, this study provides a proof-of-concept of the power of deep-amplicon sequencing to screen for anthelmintic resistance mutations and the value of the information generated. The rapid progress in sequencing technologies coupled with our increasing understanding of the genetic basis of anthelmintic resistance will make such approaches increasingly feasible for both animal and human helminths. In the latter case, such approaches are urgently required to assess the risk and monitor for anthelmintic resistance emergence in mass drug administration programmes.
Supplementary material
The supplementary material for this article can be found at https://doi.org/10.1017/S0031182020000426.
Acknowledgements
All the samples described in this work were collected and archived as part of previously published studies and reused here to screen for benzimidazole resistance SNPs. We would like to thank the following individuals for collecting the samples for the previously co-published work. Dr Tom Yazwinski and Eva Wray for collecting and providing the larvae from the US cattle. We would also like to thank Dr Murilo A. Bichuette for collecting the larvae from Sao Paulo State, Brazil. We would like to thank Dr Roy Lewis for organizing the samples from the Canadian cattle farms, and Bruna M. Palemeria for her help in sample processing. We would additionally like to thank Dr Claire Windeyer and Ana Bras for the collection of the Canadian commercial bison samples, as well as Dr Murray R. Woodbury, Dr Todd Shury, Dr Stefano Liccioli and Brent Wagner for collecting and providing the samples from the Canadian National Park bison herds.
Financial support
Funding for this work was supported by the Natural Sciences and Engineering Research Council of Canada (NSERC) (J.S.G., grant number RGPIN/371529-2209); University of Calgary, Canada, NSERC-CREATE Host Parasite Interactions (HPI) graduate training program; Alberta Agriculture and Forestry (AAF) (J.S.G., grant number 2014R027R).
Conflict of interest
None.
Ethical standards
Not applicable.