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. 2022 Apr 22;69(6):615–624. doi: 10.1111/zph.12950

Presence and antimicrobial resistance profiles of Escherichia coli, Enterococcusspp. and Salmonellasp. in 12 species of Australian shorebirds and terns

Hannah G Smith 1, David C Bean 1, Rohan H Clarke 2, Richard Loyn 3,4, Jo‐Ann Larkins 1,5, Chris Hassell 6,7, Andrew R Greenhill 1,
PMCID: PMC9544147  PMID: 35460193

Abstract

Antibiotic resistance is an ongoing threat to both human and animal health. Migratory birds are a potential vector for the spread of novel pathogens and antibiotic resistance genes. To date, there has been no comprehensive study investigating the presence of antibiotic resistance (AMR) in the bacteria of Australian shorebirds or terns. In the current study, 1022 individual birds representing 12 species were sampled across three states of Australia (Victoria, South Australia, and Western Australia) and tested for the presence of phenotypically resistant strains of three bacteria with potential to be zoonotic pathogens; Escherichia coli, Enterococcusspp., and Salmonellasp. In total, 206 E. coli, 266 Enterococcusspp., and 20 Salmonellasp. isolates were recovered, with AMR detected in 42% of E. coli, 85% of Enterococcusspp., and 10% of Salmonellasp. Phenotypic resistance was commonly detected to erythromycin (79% of Enterococcusspp.), ciprofloxacin (31% of Enterococcusspp.) and streptomycin (21% of E. coli). Resident birds were more likely to carry AMR bacteria than migratory birds (p ≤ .001). Bacteria isolated from shorebirds and terns are commonly resistant to at least one antibiotic, suggesting that wild bird populations serve as a potential reservoir and vector for AMR bacteria. However, globally emerging phenotypes of multidrug‐resistant bacteria were not detected in Australian shorebirds. This study provides baseline data of the carriage of AMR bacteria in Australian shorebirds and terns.

Keywords: antibiotic resistance, enteric bacteria, migratory shorebirds, wildlife

Impacts.

  • The AMR profiles of zoonotic pathogens E. coli, Enterococcus spp. and Salmonella sp. isolated from Australian shorebirds and terns was assessed over a 3‐year period (2016–2019). From 1022 individual bird samples, 266 Enterococcus spp., 206 E. coli and 20 Salmonella sp. isolates were recovered.

  • AMR was detected in 61% of all recovered bacteria, with 42% of E. coli, 85% of Enterococcus spp., and 10% of Salmonella sp. demonstrating some level of AMR. Resistance to clinically important antibiotic classes, such as the quinolones and aminoglycosides, was detected.

  • Resident species were more likely to carry AMR Enterococcus spp. than migrant species; however, this pattern of occurrence was not noted for AMR E. coli and Salmonella sp.

1. INTRODUCTION

Antimicrobial resistance (AMR) is recognized as a critical threat to human health (Nesme et al., 2014), increasing the length of stay and mortality risks in patients hospitalized with drug‐resistant infections (Heffernan et al., 2018). Through decades of selection pressures exerted by the misuse of antibiotics in clinical, community, and agricultural settings (i.e. prophylactic dosing, inappropriate prescriptions, antibiotic runoff causing environmental contamination), AMR bacteria have become increasingly common (McGettigan et al., 2019; Wright, 2010). Some bacteria are more capable of acquiring AMR genes than others and, as such, pose a significant risk in clinical settings (Gao et al., 2018). An estimated 700,000 deaths annually are reported worldwide due to antibiotic resistance, and this is expected to rise to 10 million extra deaths annually by 2050 (O'Neill, 2016).

Wild birds are known vectors of zoonotic enteric pathogens that can infect humans (Giacopello et al., 2016; Palmgren et al., 1997; Radhouani et al., 2012), and are reservoirs of enteric bacteria such as E. coli, Enterococcus spp., and Salmonella sp. (Blyton et al., 2015; Santos et al., 2013; Smith et al., 2020). Enterococcus spp. have drawn considerable attention due to the impact species such as E. faecalis and E. faecium have had in clinical settings, being one of the most commonly isolated Gram‐positive nosocomial pathogens in health settings globally (Gao et al., 2018). In addition, Salmonella is one of the most common causes of human morbidity and mortality associated with foodborne disease (Chlebicz & Slizewska, 2018).

Migratory shorebirds are potentially an important vector of emerging diseases and AMR due to their highly mobile behaviour. Many Australian shorebird species routinely migrate between the northern and southern hemisphere each year, stopping over on land masses that support approximately one‐third of the global human population on their migrations (Yong et al., 2018). Millions of migrant birds make regular movements between the Artic and Australia (Oldland et al., 2009), and come into close contact with human activity as they do so. Encroaching human development at major stopover sites such as the Yellow Sea and hunting of shorebirds for food increase the amount of contact these migrating birds have with humans (Piersma et al., 2017; Studds et al., 2017; Wauchope et al., 2017). This then increases the likelihood of the transfer of zoonotic diseases and AMR bacteria (Altizer et al., 2011) between birds, humans, and other wild animals.

Information regarding the presence of bacterial species of clinical importance and associated AMR in Australian shorebirds and other highly mobile coastal species such as terns is scarce. Globally, studies concerning shorebirds and terns are lacking, with most investigating the presence of pathogenic Enterobacteriaceae (Keeler & Huffman, 2009; Santos et al., 2012). Hence, it is important to develop baseline measures of AMR in these communities, covering both migrant and resident species. Due to the high number of shorebirds (37 species) and terns (19 species) present, Australia presents an exemplary study site for this purpose (Weller & Lee, 2017).

Here we investigate the presence and AMR profiles of E. coli, Enterococcus spp. and Salmonella sp. as three bacterial species that occur in shorebirds and terns as gut commensals, but with potential to cause disease in humans. Our aim was to quantify the proportions of AMR bacteria in a bird community that contains both migrant and resident species, and to explore factors that may influence AMR carriage in shorebirds and terns.

2. MATERIALS AND METHODS

2.1. Animal collection and sampling

Twelve bird species were investigated in this study, including ten shorebird species and two tern species (Table 1). All species were caught in tidal habitats on the Australian coast. The shorebirds included three species that breed within Australia; six that breed in Arctic Siberia or Alaska and migrate to Australia for the austral summer; and one that breeds in New Zealand in the austral spring and migrates to Australia for the non‐breeding season (February to September) (Marchant and Higgins 1993; Higgins and Davies 1996). The two terns have resident breeding populations in Australia as well as broad global distributions. Shorebirds were captured by the Victorian Wader Study Group (VWSG), Australasian Wader Study Group (AWSG), and Friends of Shorebirds South East (FOSSE) from December 2016 to February 2019, as part of ongoing scientific and conservation efforts addressing these focal species throughout the East‐Asian Australasian flyway. Birds were captured with the aid of cannon nets, handheld nets, or captured by hand, as appropriate for species. Terns were often captured in the same operations, and were included in this study as they often share habitats with shorebirds, and belong to the same taxonomic order (Charadriiformes).

TABLE 1.

Proportions of bacteria (E. coli, salmonellasp., and Enterococcusspp.) recovered from the ten shorebird and two tern species sampled in Australia

Species (number examined; breeding range; habitats used in Australia) E. coli Salmonellasp. Enterococcusspp.

Crested Tern Thalasseus bergii

(n = 95) Aus; Coastal

68 (72%) 2 (2%) 68 (72%)

Caspian Tern Hydroprogne caspia

(n = 89) Aus; Coastal & Inland

77 (87%) 0 (0%) 78 (88%)

Pied Oystercatcher Haematopus longirostris

(n = 31) Aus; Coastal

4 (13%) 1 (3%) 18 (58%)

Sooty Oystercatcher Haematopus fuliginosus

(n = 12) Aus; Coastal

5 (42%) 0 (0%) 10 (83%)

Sharp‐tailed Sandpiper Calidris acuminata

(n = 131) Artic; Coastal & Inland

22 (16%) 0 (0%) 23 (18%)

Sanderling Calidris alba

(n = 10) Artic; Coastal

1 (10%) 0 (0%) 4 (40%)

Red‐necked Stint Calidris ruficollis

(n = 86) Artic; Coastal & Inland

0 (0%) 0 (0%) 20 (23%)

Curlew Sandpiper Calidris ferruginea

(n = 180) Artic; Coastal & Inland

4 (2%) 0 (0%) 19 (11%)

Ruddy Turnstone Arenaria interpres

(n = 37) Artic; Coastal

1 (3%) 0 (0%) 3 (8%)

Bar‐tailed Godwit Limosa lapponica

(n = 264) Artic; Coastal

14 (5%) 17 (6%) 17 (6%)

Double‐banded Plover Charadrius bicinctus

(n = 84) NZ; Coastal & Inland

8 (10%) 0 (0%) 6 (7%)

Red‐capped Plover Charadrius ruficapillus

(n = 3) Aus; Coastal & Inland

1 (33%) 0 (0%) 0 (0%)

Total

(n = 1022)

206 (20%) 20 (2%) 266 (26%)
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Note:The proportion of birds tested that were positive for each bacterial species is provided in parenthesis. The breeding locations and habitat preference (coastal or inland) for each species is provided in italics after bacterial proportions.

Birds were sampled in 22 different geographic locations, across the Australian states of Victoria, South Australia and Western Australia. Cloacal swabs were taken from each bird using Mini Tip Amies with Charcoal specimen swabs (Copan). Transit time from sample collection to culture varied, ranging from 9–20 days due to the often‐remote nature of the fieldwork. During transit, swab samples were stored at ~5°C in a portable refrigeration unit.

All research was conducted under animal ethics permits issued by Federation University Australia (permit no. 16‐002), scientific research permits issued by the Department of Environment, Land, Water and Planning for Victoria (DELWP) (permit no. 10008032), the Department of Environment and Water for South Australia (DEW) (permit no. 35/2016), and the Department of Parks and Wildlife for Western Australia (DPaW) (permit no. 01‐000179‐1).

2.2. Bacterial culture and antimicrobial susceptibility testing

Swabs were pre‐enriched in 5 ml brain heart infusion broth (Oxoid) and incubated at 35°C for ~24 hr. Aliquots of 100 μl were subsequently used to inoculate each of mannitol broth (Oxoid), azide dextrose broth (Oxoid) and selenite broth (Becton Dickinson [BD]). All selective enrichment broths were incubated at 35°C for 18–48 hr, and then plated onto MacConkey II agar (Oxoid) or xylose lysine deoxycholate (XLD) agar (BD) as appropriate and incubated at 35°C for 24–48 hr.

Suspect E. coli, Enterococcus spp. or Salmonella sp. isolates were sub‐cultured to purity on the respective selective plates and preliminary testing included Gram reaction, catalase and oxidase testing. Presumptive E. coli isolates were confirmed by the indole test. Presumptive Salmonella sp. were confirmed by a PCR assay targeting the invA gene (Malorny et al., 2003), and presumptive Enterococcus spp. were confirmed by a PCR assay targeting the 16 s rRNA gene (Ryu et al., 2013).

Confirmed isolates were tested for antimicrobial susceptibility using the Kirby‐Bauer disk diffusion method, as outlined by the Clinical & Laboratory Standards Institute M100‐S22 (Clinical and Laboratory Standards Institute, 2012). The antimicrobials (Oxoid) tested were dependent upon the bacterial species in question (Tables 2 and 3). Antimicrobial resistance (AMR) was defined as reduced susceptibility to at least one agent tested, while multi‐drug resistance (MDR) was defined as reduced susceptibility to at least one agent in three or more antimicrobial classes (Magiorakos et al., 2012).

TABLE 2.

Antibiotic susceptibility of E. coliisolates recovered from Australian shorebird and tern species

Bird species (no. birds positive) AK AMC AMP CTX CAZ C CIP CN IPM NA S SXT TE

Crested Tern

(n = 68)

Resistant 3 3 1 5 1 5
Intermediate 5 1 2 11 1
Susceptible 60 67 63 68 68 68 68 68 68 67 52 67 62

Caspian Tern

(n = 78)

Resistant 2 1 14 1 6 3 13
Intermediate 1 2 4 1 1 18 1
Susceptible 75 75 60 78 78 77 77 78 77 78 54 75 64

Bar‐tailed Godwit

(n = 14)

Resistant 1
Intermediate 1 1
Susceptible 14 13 13 14 14 14 14 14 14 14 13 14 14

Sharp‐tailed Sandpiper

(n = 22)

Resistant 1 1
Intermediate 4
Susceptible 22 22 18 22 22 22 22 22 22 22 22 21 21

Other a

(n = 24)

Resistant 2 1 2 2 2 2
Intermediate 7 1 1 1
Susceptible 22 16 22 24 22 24 23 24 23 22 21 24 24

Total

(n = 206)

Resistant 7 3 19 2 1 3 13 5 19
Intermediate 6 10 11 1 1 2 31 2
Susceptible 193 193 176 206 204 205 204 206 204 203 162 201 185
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Note:For species with <10 isolates recovered, the total isolates recovered were as such: Pied oystercatcher (n = 4), sooty oystercatcher (n = 5), red‐capped plover (n = 1), curlew sandpiper (n = 4), Ruddy turnstone (n = 1), sanderling (n = 1), and double‐banded plover (n = 8).

Antibiotic abbreviations: AK, Amikacin; AMC, Amoxycillin; AMP, Ampicillin; C, Chloramphenicol; CAZ, Ceftazidime; CIP, Ciprofloxacin; CN, Gentamicin; CTX, Cefotaxime; IPM, Imipenem; NA, Nalidixic Acid; S, Streptomycin; SXT, Sulfamethoxazole‐trimethorpim; TE, Tetracycline.

a

Bird species for which less than 10 samples were collected.

TABLE 3.

Antibiotic susceptibility of Enterococcusspp. isolates recovered from Australian shorebird and tern species

Bird species (no. birds positive) AMP C CIP E CN S TE VA

Crested Tern

(n = 49)

Resistant 1 2 4 7 15 1
Intermediate 1 24 36 1 12
Susceptible 48 46 21 6 48 49 34 36

Caspian Tern

(n = 49)

Resistant 11 2 1 1 1 4
Intermediate 3 10 44 1
Susceptible 38 44 38 4 49 48 45 48

Pied Oystercatcher

(n = 16)

Resistant 1
Intermediate 3 11 1
Susceptible 16 16 13 4 16 16 16 15

Sooty oystercatcher

(n = 10)

Resistant
Intermediate 7
Susceptible 10 10 10 3 10 10 10 10

Bar‐tailed Godwit

(n = 16)

Resistant 1
Intermediate 5 6 1
Susceptible 16 16 11 10 16 14 16 16

Red‐necked Stint

(n = 20)

Resistant 5 1 1
Intermediate 2 4 15
Susceptible 15 18 16 4 20 20 19 20

Curlew Sandpiper

(n = 14)

Resistant
Intermediate 7 11
Susceptible 14 14 7 3 14 14 14 14

Sharp‐tailed Sandpiper

(n = 18)

Resistant 1
Intermediate 4 13
Susceptible 18 18 14 4 18 18 18 18

Other a

(n = 14)

Resistant
Intermediate 3 9 1
Susceptible 14 14 11 5 14 14 14 13

Total

(n = 206)

Resistant 17 4 5 11 2 20 1
Intermediate 6 60 152 1 1 15
Susceptible 189 196 141 43 205 203 186 190
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Note:For species with <10 isolates recovered, the total isolates recovered were as such: Ruddy turnstone (n = 3), sanderling (n = 4), and double‐banded plover (n = 7).

Antibiotic abbreviations: AMP, Ampicillin; C, Chloramphenicol; CN, Gentamicin; E, Erythromycin; S, Streptomycin; TE, Tetracycline; VA, Vancomycin.

a

Bird species for which less than 10 samples were collected.

2.3. Data analysis

Chi‐squared analysis was used in tandem with observed vs expected counts to investigate potential relationships between variables. For chi‐squared analysis, a p value of <.05 was considered significant and was indicative of a relationship between the explanatory variable (the species of bird sampled, the feeding ecology of the birds sampled, the habitat of the birds sampled, or the migratory habits of the birds) and the AMR profile of the bacteria recovered. All statistical analysis was performed using SPSS (IBM SPSS Statistics Version 25).

3. RESULTS

3.1. Sample collection and bacterial recovery

Between 20/12/16–18/02/19, 1022 swabs were collected from ten species of shorebird and two species of tern. From these swabs, E. coli was isolated from 20% (206 of 1022), Salmonella sp. isolated from 2% (20 of 1022), and Enterococcus spp. from 26% (266 of 1022), with all 12 species positive for one or more of the target bacterial species (Table 1).

The three species of bird from which E. coli was most commonly detected were the Caspian Tern (88%), Crested Tern (72%) and Sooty Oystercatcher (42%). The same three bird species had the highest proportions of Enterococcus spp. (Caspian Terns 88%, Crested Terns 72%, and Sooty Oystercatcher 83%). By contrast, Salmonella sp. was only rarely detected, being detected in only 2% of all birds sampled. Of the Salmonella sp. isolates, 85% were identified as Salmonella enterica serovar Hvittingfoss (n = 17, all from Bar‐tailed Godwit, previously reported in Smith et al., 2020), 10% as Salmonella enterica serovar Typhimurium (n = 2, one from a Crested Tern and one from a Pied Oystercatcher), and 5% as Salmonella enterica serovar Bahrenfeld (n = 1, from a Crested Tern). Further analysis of what effect variables such as species, feeding and habitat ecology, or migratory movements may have had on bacterial carriage were not possible due to the potential for confounding variables caused by the differing time periods between initial sampling and bacterial culture.

3.2. Antibiotic resistance among bacterial isolates

Due to lab restrictions as a result of the COVID‐19 pandemic, not all enterococcal isolates had susceptibility testing performed: in total, 206 of 266 isolates were tested for phenotypic resistance. Overall, AMR was observed in 88 of 206 (43%) E. coli, 175 of 206 (85%) Enterococcus spp., and 2 of 20 (10%) Salmonella sp. In total, 265 of 436 isolates (61%) demonstrated AMR.

For E. coli, AMR bacteria were detected in all focal bird species (Table 2). The species with the highest recovery of AMR bacteria was the Caspian Tern, with 45% (n = 35) of all E. coli isolated from this species demonstrating resistance to at least one antibiotic. Ciprofloxacin resistance was noted in two species (Caspian Tern and Bar‐tailed Godwit) and ceftazidime resistance was noted in two E. coli isolates, one each from a Sooty Oystercatcher and a Curlew Sandpiper.

Antibiotic susceptibility testing was performed on 206 of 266 (77%) enterococcal isolates. AMR Enterococcus spp. were recovered from all species sampled (Table 3). Vancomycin‐resistant Enterococcus (VRE) was isolated from three species (Crested Tern, Caspian Tern, and Double‐banded Plover). The most commonly observed resistance was to the macrolide class to which >70% of enterococcal isolates were resistant. One‐third (32%) of Enterococcus spp. demonstrated resistance to ciprofloxacin, and 20 isolates (10%) demonstrated resistance to tetracycline.

Two Salmonella sp. isolates demonstrated intermediate resistance against a single antibiotic (streptomycin). These isolates were recovered from a Bar‐tailed Godwit and a Crested Tern. All other Salmonella sp. isolates were susceptible to all 15 tested antibiotics.

The number of multi‐drug‐resistant (MDR) strains of bacteria was also investigated. No Salmonella sp. isolates were resistant to more than one class of antibiotic. Of Enterococcus spp., 17% (n = 35) were resistant to ≥3 classes of antibiotics, 4% (n = 8) to ≥4, and 1.5% (n = 3) to ≥5. Of the E. coli isolates, 7% (n = 15) were resistant to three or more classes of antibiotics. One percent (n = 2) of E. coli isolates were resistant to four or more classes of antibiotics.

3.3. Bird ecology and antibiotic resistance

A relationship was observed between species of bird and decreased antibiotic susceptibility (defined as any bacteria that demonstrated resistance to one or more antibiotic) and species of bird (p = ≤.001). Further analysis revealed that this relationship was only statistically significant for AMR Enterococcus spp. (p = ≤.001). Due to the low numbers of samples available for individual species, investigation into the relationship between AMR bacteria and each sampled species was not possible. As such, analysis into the impact different ecological variables may have had on AMR carriage was investigated.

The relationship between feeding ecology and the recovery of AMR bacteria was investigated, with birds assigned to one of two feeding guilds. ‘Probers’ (birds that obtain the majority of their food by using their beaks to probe muddy substrates for benthic invertebrates) included the Curlew Sandpiper, Sanderling, Bar‐tailed Godwit, Pied Oystercatcher, Sooty Oystercatcher, and Sharp‐tailed Sandpiper. ‘Peckers’ (birds that gain the majority of their food by hunting on the surface of the sand or mud by sight) included the Red‐necked Stint, Ruddy Turnstone, Double‐banded Plover, and Red‐capped Plover (Crested and Caspian Terns were excluded from this analysis, given they are piscivores). No statistically significant relationship was found between the birds' feeding habits and the recovery of AMR bacteria (of any species).

Next, the relationship between habitat of the birds sampled and recovery of AMR bacteria was investigated. Birds were assigned to one of two habitat guilds‐ ‘Coastal’, which were birds that lived exclusively on the coastline, and ‘Coastal/Inland’, which were birds that utilize both coastlines and inland habitats. No statistically significant relationship was found between habitat guild and the recovery of AMR bacteria (of any species). Additionally, no statistically significant relationship was found between recovery of AMR bacteria (of any species) and the state in which the bird was sampled (either Western Australia or Victoria, with samples from South Australia excluded due to the small sample size).

The relationship between the movement ecology of each species and the recovery of AMR bacteria was also investigated. Birds were defined as ‘migratory’ if they undertake trans‐equatorial migration on an annual basis between high Arctic breeding grounds and non‐breeding grounds in Australia, and ‘resident’ otherwise. Resident birds were more likely to carry AMR Enterococcus spp. than migratory birds. Results indicated resident species had significantly higher rates of AMR bacteria resistance than migrant species relationship (p ≤ .001) and closer investigation revealed this specifically applied to AMR Enterococcus spp. (p = .012). No such relationship was detected for AMR E. coli (p = .259) or Salmonella sp. recovery (p = .144).

4. DISCUSSION

Antibiotic resistance is present in Australian shorebirds and terns, though resistance to clinically important antibiotics and MDR is currently uncommon in the bacteria targeted in this study in wild bird populations. Resistance to clinically important classes of antibiotics such as glycopeptides and carbapenems was rare: less than 8% (n = 16) of all Enterococcus spp. isolated were resistant to glycopeptides, and less than 1% (n = 2) of all E. coli isolates were resistant to carbapenems. Notably, all resistance to carbapenems and >90% of glycopeptide resistance was intermediate, rather than complete resistance. Multidrug resistance was uncommon, with 17% of both Enterococcus spp. and E. coli isolates resistant to three or more classes of antibiotics. MDR was not detected in any Salmonella sp. isolates.

Resident birds were more likely to carry AMR Enterococcus spp. than migratory birds, though that trend was not apparent in E. coli or Salmonella sp. Due to their malleable genomes, Enterococcus spp. are able to acquire AMR genes with ease. As such, Enterococcus spp. may pick up resistance genes from other gut bacteria or the environment to a higher degree than E. coli (Ramos et al., 2020). Furthermore, Enterococcus spp. originating from faecal contamination (such as that from human sources) have greater persistence in environmental and aqueous environments than E. coli (Jin et al., 2004), which could potentially increase the likelihood of human isolates colonizing wild birds. Populations of both E. coli and Enterococcus are highly variable in wild bird populations (Fogarty et al., 2003) and further studies need to be conducted to confirm if our findings hold true across multiple bird species through different temporal periods.

One explanation for the lower rates of AMR bacteria in migratory birds compared to resident birds as observed here may be due to migratory culling and migratory separation (Altizer et al., 2011). These processes are theorized to curtail parasite and pathogen dispersal among migratory birds as infections negatively impact dispersal (migratory separation) and survival (migratory culling). Positive infection statuses in birds were associated with reduced movement and lowered survival rates (Risely et al., 2018). Despite enterococci being commensal bacteria in birds, previous studies have shown that some enterococcal species can cause disease in multiple species (Devriese et al., 1990; Devriese et al., 1992; Herdt et al., 2009). This may be the cause of the potential relationship seen here‐ migratory birds carrying Enterococcus could be less likely to thrive in the long term, while resident birds that do not undergo the same yearly movements are able to tolerate potential infections to a greater degree.

All three target bacterial species (E. coli, Enterococcus spp., and Salmonella sp.) were present in Australian shorebirds and terns. Enterococcus spp. and E. coli were present in the majority of species sampled, though E. coli was not isolated from the Red‐necked Stint. Salmonella sp. was present in only three species (Bar‐Tailed Godwit, Crested Tern, and Pied Oystercatcher). The overall isolation proportions of E. coli, Enterococcus spp. and Salmonella sp. in the tested species was 20%, 26% and 2%, respectively. Previous studies examining the presence of bacterial species via genetic sequencing techniques have shown that extended storage times only have a minor negative impact on bacteria present in swab samples; albeit in considerably different experimental settings (Bai et al., 2012; Lauber et al., 2010). While it remains a possibility in our study that bacterial isolation was affected by transport times, it may not have had a major impact on detection rates. Other studies have also found low carriage rates of E. coli, Enterococcus spp., and Salmonella sp. in migratory birds, with E. coli having a carriage rate of 1%–9% and Salmonella sp. having a 0%–2% carriage rate (Brittingham et al., 1988; Najdenski et al., 2018), similar to this study. While there are no studies that examine the prevalence of Enterococcus spp. in migratory birds, studies investigating wild bird populations detected carriage levels of 74%–84% (Marrow et al., 2009; Splichalova et al., 2015). Despite the extended duration between sample collection and culture, the prevalence of target bacteria in this study was broadly comparable to those observed in other studies. It is also important to note that due to the nature of wildlife sampling, some species were caught (and sampled) less often than others, which will affect the proportions of bacterial species recovered. In order to build a more comprehensive view of bacterial prevalence and AMR carriage in wild birds, studies such as this need to be repeated at different time points to account for potential impacts by outside events (such as poor breeding seasons or inclement weather affecting the availability of certain species).

Notwithstanding the similar proportion of culture positive samples in this study relative to previously published studies in birds, culture‐independent approaches could be used in future studies to improve detection of target bacteria. PCR is arguably the best way to determine the presence of target species, given the bacteria does not need be viable to be detected. Thereafter culture could be used for PCR positive samples to obtain isolates for phenotypic AMR testing; or alternatively gene detection by PCR or sequencing could be used. However, there is still some debate around the suitability of gene detection to predict phenotypic AMR, particularly in Gram negative bacteria (Hendriksen et al., 2019; Van Camp et al., 2020). Such challenges may soon be overcome with improved sequencing technologies and better computational approaches to data analysis (Nguyen et al., 2020; Ren et al., 2021).

Contrary to the findings of other studies on Australian birds, AMR in bacteria isolated from Australian shorebirds and terns was more prevalent than previously reported. Overall, 42% of E. coli were resistant to one or more antibiotics, as were 85% of Enterococcus spp. Resistance in Enterococcus spp. was confined mostly to older, broad‐spectrum antibiotic classes such as the macrolides. Among E. coli, resistance was evenly distributed among different classes of antibiotics such as the penicillin and aminoglycosides. Vancomycin resistance in Enterococcus spp. was found in ≤10% of all isolates, falling between previously reported rates of VRE in wild Australian birds. A study by Oravcova et al. (2017) detected VRE in less than 1% of the sampled birds, while a previous study by members of this research team (Smith et al., 2019) detected vancomycin resistance in 31% of recovered Enterococcus spp.

These findings suggest Australian shorebirds and terns harbour bacteria that are sensitive to clinically important antibiotics. This may be due to their ecology; Australian shorebirds and terns do not have significant interactions with anthropogenic or livestock populations, and may only interact with AMR bacteria through environmental sources such as wetland and coastal substrates and water. It is difficult to state with any certainty whether these species acquire AMR bacteria from the environment, as microbiome studies have demonstrated conflicting results. Shorebirds in particular were considered to have a low intake of environmental bacteria (around 2% transfer between environmental bacteria and bird gut microbiota) by Risely et al. (2017), but Grond (2017) suggested that sampling site is the main driver in variation of shorebird gut microbiota. Further studies investigating the genetics and origins of AMR bacteria in Australian shorebird and tern populations are needed to determine where these species acquire AMR bacteria and to provide a more comprehensive assessment of the scope of this problem. Investigations that determine whether migratory birds are capable of transferring AMR bacteria between their own populations, and between human and livestock populations would also be of value.

5. CONCLUSION

This study shows that shorebirds are a potential reservoir of AMR pathogens, and are capable of carrying bacteria that are resistant to clinically important antibiotics. This study also shows that migratory status may affect carriage of AMR bacteria, with resident shorebirds demonstrating higher rates of AMR Enterococcus spp. than migrant shorebirds. These populations have the potential to act as both hosts and vectors of AMR enteric bacteria. Further studies are required to track AMR in shorebird populations, and to begin to determine how wild populations are acquiring these bacteria.

CONFLICT OF INTEREST

The authors declare they have no conflicts of interest.

ACKNOWLEDGEMENTS

This work would not have been possible without the generous funding provided by Holsworth Wildlife Research Endowment (grant HLS‐18‐005) and the Stuart Leslie Bird Research Award provided by Birdlife Australia (grant FOST‐18‐416). We thank the AWSG, VWSG, Friends of Shorebirds South East (FOSSE), Rosalind Jessop, and the late Dr Clive Minton for their help with this project; assistance with permits, access to captured birds, and a deep understanding of the behaviour and movements of the shorebird species in Roebuck Bay have proved invaluable. We are enormously grateful to Stoate family of Anna Plains Station for hosting part of the field work. We acknowledge the Yawuru People, via the offices of Nyamba Buru Yawuru Limited, for permissions granted to AWSG to capture birds on the shores of Roebuck Bay, the traditional lands of the Yawuru people. We also acknowledge the Karajarri and Nyangumarta people for permission to catch birds to be sampled for this project on the shores of 80 Mile Beach, traditional lands of the Karajarri and Nyangumarta people. Open Access publishing facilitated by Federation University Australia, as part of the Wiley ‐ Federation University Australia agreement via the Council of Australian University Librarians.

Smith, H. G. , Bean, D. C. , Clarke, R. H. , Loyn, R. , Larkins, J‐A , Hassell, C. , Greenhill, A. R. (2022). Presence and antimicrobial resistance profiles of Escherichia coli, Enterococcusspp. and Salmonellasp. in 12 species of Australian shorebirds and terns. Zoonoses and Public Health, 69, 615–624. 10.1111/zph.12950

Funding information

CJH would like to thank GFN's major funders for the NWA work Spinoza Premium of Netherlands Organization Prize for Scientific Research to Theunis Piersma (2014–2017), WWF Netherlands (2010–2017) and MAVA, Foundation pour la nature (2018).

[Correction added on 09‐May‐2022, after first online publication: CAUL funding statement has been added.]

DATA AVAILABILITY STATEMENT

All new data is present in manuscript.

REFERENCES

  1. Altizer, S. , Bartel, R. , & Han, B. A. (2011). Animal migration and infectious disease risk. Science, 331(6015), 296–302. 10.1126/science.1194694 [DOI] [PubMed] [Google Scholar]
  2. Bai, G. , Gajer, P. , Nandy, M. , Ma, B. , Yang, H. , Sakamoto, J. , Blanchard, M. H. , Ravel, J. , & Brotman, R. M. (2012). Comparison of storage conditions for human vaginal microbiome studies. PLoS One, 7(5), e36934. [DOI] [PMC free article] [PubMed] [Google Scholar]
  3. Blyton, M. D. , Pi, H. , Vangchhia, B. , Abraham, S. , Trott, D. J. , Johnson, J. R. , & Gordon, D. M. (2015). Genetic structure and antimicrobial resistance of Escherichia coli and cryptic clades in birds with diverse human associations. Applied and Environmental Microbiology, 81(15), 5123–5133. 10.1128/AEM.00861-15 [DOI] [PMC free article] [PubMed] [Google Scholar]
  4. Brittingham, M. C. , Temple, S. A. , & Duncan, R. M. (1988). A survey of the prevalence of selected bacteria in wild birds. Journal of Wildlife Diseases, 24(2), 299–307. [DOI] [PubMed] [Google Scholar]
  5. Chlebicz, A. , & Slizewska, K. (2018). Campylobacteriosis, salmonellosis, yersiniosis, and listeriosis as zoonotic foodborne diseases: A review. International Journal of Environmental Research and Public Health, 15(5), 863. 10.3390/ijerph15050863 [DOI] [PMC free article] [PubMed] [Google Scholar]
  6. Clinical and Laboratory Standards Institute . (2012). Performance standards for antimicrobial susceptibility testing; Twenty‐second informational supplement (Vol. 32, p. 188). Clinical and Laboratory Standards Institute. [Google Scholar]
  7. Devriese, L. , Cruz Colque, J. , Haesebrouck, F. , Desmidt, M. , Uyttebroek, E. , & Ducatelle, R. (1992). Enterococcus hirae in septicaemia of psittacine birds. Veterinary Record, 130(25), 558–559. [DOI] [PubMed] [Google Scholar]
  8. Devriese, L. A. , Ceyssens, K. , Rodrigues, U. M. , & Collins, M. D. (1990). Enterococcus columbae, a species from pigeon intestines. FEMS Microbiology Letters, 59(3), 247–251. 10.1016/0378-1097(90)90228-i [DOI] [PubMed] [Google Scholar]
  9. Fogarty, L. , Haack, S. , Wolcott, M. , & Whitman, R. (2003). Abundance and characteristics of the recreational water quality indicator bacteria Escherichia coli and enterococci in gull faeces. Journal of Applied Microbiology, 94(5), 865–878. [DOI] [PubMed] [Google Scholar]
  10. Gao, W. , Howden, B. P. , & Stinear, T. P. (2018). Evolution of virulence in Enterococcus faecium, a hospital‐adapted opportunistic pathogen. Current Opinion in Microbiology, 41, 76–82. 10.1016/j.mib.2017.11.030 [DOI] [PubMed] [Google Scholar]
  11. Giacopello, C. , Foti, M. , Mascetti, A. , Grosso, F. , Ricciardi, D. , Fisichella, V. , & Lo Piccolo, F. (2016). Antimicrobial resistance patterns of Enterobacteriaceae in European wild bird species admitted in a wildlife rescue Centre. Veterinaria Italiana, 52(2), 139–144. 10.12834/VetIt.327.1374.2 [DOI] [PubMed] [Google Scholar]
  12. Grond, K. (2017). Development and dynamics of gut microbial communities of migratory shorebirds in the Western hemisphere. Doctoral Dissertation. Kansas State University. [Google Scholar]
  13. Heffernan, A. J. , Sime, F. B. , Lipman, J. , & Roberts, J. A. (2018). Individualising therapy to minimize bacterial multidrug resistance. Drugs, 78(6), 621–641. 10.1007/s40265-018-0891-9 [DOI] [PubMed] [Google Scholar]
  14. Hendriksen, R. , Bortolaia, V. , Tate, H. , Tyson, G. , Aarestrup, F. , & McDermott, P. (2019). Using genomics to track global antimicrobial resistance. Frontiers in Public Health, 7, 242. [DOI] [PMC free article] [PubMed] [Google Scholar]
  15. Herdt, P. D. , Defoort, P. , Steelant, J. V. , Swam, H. , Tanghe, L. , Goethem, S. V. , & Vanrobaeys, M. (2009). Enterococcus cecorum osteomyelitis and arthritis in broiler chickens. Vlaams Diergeneeskundig Tijdschrift, 78(1), 44–48. [Google Scholar]
  16. Higgins, P. J. , & Davies, S. J. J. F. (Eds.). (1996). Handbook of Australian, New Zealand and Antarctic Birds. Vol. 3. Snipe to Pigeons. Oxford University Press. [Google Scholar]
  17. Jin, G. , Englande, A. , Bradford, H. , & Jeng, H. W. (2004). Comparison of E. coli, enterococci, and fecal coliform as indicators for brackish water quality assessment. Water Environment Research, 76(3), 245–255. [DOI] [PubMed] [Google Scholar]
  18. Keeler, S. , & Huffman, J. (2009). Identification of staphylococcus spp. and aerobic gram‐negative bacteria from the cloacae of migratory shorebirds (family Scolopacidae) from Delware Bay, New Jersey. Journal of the Pennsylvania Academy of Science, 83, 34–37. [Google Scholar]
  19. Lauber, C. L. , Zhou, N. , Gordon, J. I. , Knight, R. , & Fierer, N. (2010). Effect of storage conditions on the assessment of bacterial community structure in soil and human‐associated samples. FEMS Microbiology Letters, 307(1), 80–86. 10.1111/j.1574-6968.2010.01965.x [DOI] [PMC free article] [PubMed] [Google Scholar]
  20. Magiorakos, A.‐P. , Srinivasan, A. , Carey, R. , Carmeli, Y. , Falagas, M. , Giske, C. , Harbarth, S. , Hindler, J. , Kahlmeter, G. , & Olsson‐Liljequist, B. (2012). Multidrug‐resistant, extensively drug‐resistant and pandrug‐resistant bacteria: An international expert proposal for interim standard definitions for acquired resistance. Clinical Microbiology and Infection, 18(3), 268–281. [DOI] [PubMed] [Google Scholar]
  21. Malorny, B. , Hoorfar, J. , Bunge, C. , & Helmuth, R. (2003). Multicenter validation of the analytical accuracy of salmonella PCR: Towards an international standard. Applied and Environmental Microbiology, 69(1), 290–296. [DOI] [PMC free article] [PubMed] [Google Scholar]
  22. Marchant, S. , & Higgins, P. J. (Eds.). (1993). Handbook of Australian, New Zealand and Antarctic Birds. Vol. 2. Raptors to Lapwings. Oxford University Press. [Google Scholar]
  23. Marrow, J. , Whittington, J. K. , Mitchell, M. , Hoyer, L. L. , & Maddox, C. (2009). Prevalence and antibiotic‐resistance characteristics of enterococcus spp. isolated from free‐living and captive raptors in Central Illinois. Journal of Wildlife Diseases, 45(2), 302–313. [DOI] [PubMed] [Google Scholar]
  24. McGettigan, P. , Roderick, P. , Kadam, A. , & Pollock, A. (2019). Threats to global antimicrobial resistance control: Centrally approved and unapproved antibiotic formulations sold in India. British Journal of Clinical Pharmacology, 85(1), 59–70. 10.1111/bcp.13503 [DOI] [PMC free article] [PubMed] [Google Scholar]
  25. Najdenski, H. , Dimova, T. , Zaharieva, M. M. , Nikolov, B. , Petrova‐Dinkova, G. , Dalakchieva, S. , Popov, K. , Hristova‐Nikolova, I. , Zehtindjiev, P. , & Peev, S. (2018). Migratory birds along the Mediterranean–Black Sea flyway as carriers of zoonotic pathogens. Canadian Journal of Microbiology, 64(12), 915–924. [DOI] [PubMed] [Google Scholar]
  26. Nesme, J. , Cecillon, S. , Delmont, T. O. , Monier, J. M. , Vogel, T. M. , & Simonet, P. (2014). Large‐scale metagenomic‐based study of antibiotic resistance in the environment. Current Biology, 24(10), 1096–1100. 10.1016/j.cub.2014.03.036 [DOI] [PubMed] [Google Scholar]
  27. Nguyen, M. , Olson, R. , Shukla, M. , VanOeffelen, M. , Davis, J. , & Papin, J. (2020). Predicting antimicrobial resistance using conserved genes. PLoS Computational Biology, 16(10), e1008319. 10.1371/journal.pcbi.100831 [DOI] [PMC free article] [PubMed] [Google Scholar]
  28. Oldland, J. , Rogers, D. , Clemens, R. , Berry, L. , Maguire, G. , & Gosbell, K. (2009). Shorebird conservation in Australia. Birds Australia Conservation Statment, 14(20). [Google Scholar]
  29. O'Neill, J. (2016). Tackling drug‐resistant infections globally: Final report and recommendations. HM Government and Wellcome Trust. Review on Antimicrobial Resistance, chaired by Jim O'Neill. https://amr‐review.org/sites/default/files/160525_Final%20paper_with%20cover.pdf [Google Scholar]
  30. Oravcova, V. , Svec, P. , & Literak, I. (2017). Vancomycin‐resistant enterococci with vanA and vanB genes in Australian gulls. Environmental Microbiology Reports, 9(3), 316–318. 10.1111/1758-2229.12542 [DOI] [PubMed] [Google Scholar]
  31. Palmgren, H. , Sellin, M. , Bergstrom, S. , & Olsen, B. (1997). Enteropathogenic bacteria in migrating birds arriving in Sweden. Scandinavian Journal of Infectious Diseases, 29(6), 565–568. 10.3109/00365549709035895 [DOI] [PubMed] [Google Scholar]
  32. Piersma, T. , Chan, Y.‐C. , Mu, T. , Hassell, C. J. , David, S. D. S. , Peng, H. B. , Ma, Z. , Zhang, Z. , & Wilcove, D. S. (2017). Loss of habitat leads to loss of birds: Reflections on the Jiangsu, China, coastal development plans. Wader Study, 124(2), 93–98. 10.18194/ws.00077 [DOI] [Google Scholar]
  33. Radhouani, H. , Poeta, P. , Goncalves, A. , Pacheco, R. , Sargo, R. , & Igrejas, G. (2012). Wild birds as biological indicators of environmental pollution: Antimicrobial resistance patterns of Escherichia coli and enterococci isolated from common buzzards (Buteo buteo). Journal of Medical Microbiology, 61(Pt 6), 837–843. 10.1099/jmm.0.038364-0 [DOI] [PubMed] [Google Scholar]
  34. Ramos, S. , Silva, V. , Dapkevicius, M. D. L. E. , Igrejas, G. , & Poeta, P. (2020). Enterococci, from harmless bacteria to a pathogen. Microorganisms, 8(8), 1118. [DOI] [PMC free article] [PubMed] [Google Scholar]
  35. Ren, Y. , Chakraborty, T. , Doijad, S. , Falgenhauer, L. , Falgenhauer, J. , Goesmann, A. , Hauschild, A. , Schwengers, O. , & Heider, D. (2021). Prediction of antimicrobial resistance based on whole‐genome sequencing and machine learning. Bioinformatics, 38, 325–334. 10.1093/bioinformatics/btab681 [DOI] [PMC free article] [PubMed] [Google Scholar]
  36. Risely, A. , Klaassen, M. , & Hoye, B. J. (2018). Migratory animals feel the cost of getting sick: A meta‐analysis across species. Journal of Animal Ecology, 87(1), 301–314. 10.1111/1365-2656.12766 [DOI] [PubMed] [Google Scholar]
  37. Risely, A. , Waite, D. , Ujvari, B. , Klaassen, M. , & Hoye, B. (2017). Gut microbiota of a long‐distance migrant demonstrates resistance against environmental microbe incursions. Molecular Ecology, 26(20), 5842–5854. [DOI] [PubMed] [Google Scholar]
  38. Ryu, H. , Henson, M. , Elk, M. , Toledo‐Hernandez, C. , Griffith, J. , Blackwood, D. , Noble, R. , Gourmelon, M. , Glassmeyer, S. , & Santo Domingo, J. W. (2013). Development of quantitative PCR assays targeting the 16S rRNA genes of Enterococcus spp. and their application to the identification of Enterococcus species in environmental samples. Applied and Environmental Microbiology, 79(1), 196–204. 10.1128/AEM.02802-12 [DOI] [PMC free article] [PubMed] [Google Scholar]
  39. Santos, S. , Pardal, S. , Proença, D. N. , Lopes, R. J. , Ramos, J. A. , Mendes, L. , & Morais, P. V. (2012). Diversity of cloacal microbial community in migratory shorebirds that use the Tagus estuary as stopover habitat and their potential to harbor and disperse pathogenic microorganisms. FEMS Microbiology Ecology, 82(1), 63–74. [DOI] [PubMed] [Google Scholar]
  40. Santos, T. , Silva, N. , Igrejas, G. , Rodrigues, P. , Micael, J. , Rodrigues, T. , Resendes, R. , Goncalves, A. , Marinho, C. , Goncalves, D. , Cunha, R. , & Poeta, P. (2013). Dissemination of antibiotic resistant Enterococcus spp. and Escherichia coli from wild birds of Azores archipelago. Anaerobe, 24, 25–31. 10.1016/j.anaerobe.2013.09.004 [DOI] [PubMed] [Google Scholar]
  41. Smith, H. G. , Bean, D. C. , Hawkey, J. , Clarke, R. H. , Loyn, R. , Larkins, J.‐A. , Hassel, C. , Valcanis, M. , Pitchers, W. , & Greenhill, A. R. (2020). Detection and characterisation of salmonella enterica serovar Hvittingfoss in Bar‐tailed godwits (Limosa lapponica) from Roebuck Bay, North‐Western Australia. Applied and Environmental Microbiology, 86, e01312–20. [DOI] [PMC free article] [PubMed] [Google Scholar]
  42. Smith, H. G. , Clarke, R. H. , Larkins, J.‐A. , Bean, D. C. , & Greenhill, A. R. (2019). Wild Australian birds and drug‐resistant bacteria: Characterisation of antibiotic‐resistant Escherichia coli and Enterococcus spp. Emu‐Austral Ornithology, 119(4), 384–390. [Google Scholar]
  43. Splichalova, P. , Svec, P. , Ghosh, A. , Zurek, L. , Oravcova, V. , Radimersky, T. , Bohus, M. , & Literak, I. (2015). Prevalence, diversity and characterization of enterococci from three coraciiform birds. Antonie van Leeuwenhoek, 107(5), 1281–1289. [DOI] [PubMed] [Google Scholar]
  44. Studds, C. E. , Kendall, B. E. , Murray, N. J. , Wilson, H. B. , Rogers, D. I. , Clemens, R. S. , Gosbell, K. , Hassell, C. J. , Jessop, R. , Melville, D. S. , Milton, D. A. , Minton, C. D. , Possingham, H. P. , Riegen, A. C. , Straw, P. , Woehler, E. J. , & Fuller, R. A. (2017). Rapid population decline in migratory shorebirds relying on Yellow Sea tidal mudflats as stopover sites. Nature Communications, 8, 14895. 10.1038/ncomms14895 [DOI] [PMC free article] [PubMed] [Google Scholar]
  45. Van Camp, P. J. , Haslam, D. , & Porollo, A. (2020). Prediction of antimicrobial resistance in gram‐negative bacteria from whole‐genome sequencing data. Frontiers in Microbiology, 11, 1013. 10.3389/fmicb.2020.01013 [DOI] [PMC free article] [PubMed] [Google Scholar]
  46. Wauchope, H. S. , Shaw, J. D. , Varpe, O. , Lappo, E. G. , Boertmann, D. , Lanctot, R. B. , & Fuller, R. A. (2017). Rapid climate‐driven loss of breeding habitat for Arctic migratory birds. Global Change Biology, 23(3), 1085–1094. 10.1111/gcb.13404 [DOI] [PubMed] [Google Scholar]
  47. Weller, D. R. , & Lee, C. (2017). Migratory shorebird conservation action plan. BirdLife Australia unpublished report. BirdLife Australia. [Google Scholar]
  48. Wright, G. D. (2010). Antibiotic resistance in the environment: A link to the clinic? Current Opinion in Microbiology, 13(5), 589–594. [DOI] [PubMed] [Google Scholar]
  49. Yong, D. L. , Jain, A. , Liu, Y. , Iqbal, M. , Choi, C. Y. , Crockford, N. J. , Milington, S. , & Provencher, J. (2018). Challenges and opportunities for transboundary conservation of migratory birds in the east Asian‐Australasian flyway. Conservation Biology, 32(3), 740–743. 10.1111/cobi.13041 [DOI] [PubMed] [Google Scholar]

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Data Availability Statement

All new data is present in manuscript.

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