Open Access

Genetic characterization of Toxoplasma gondii from pigs from different localities in China by PCR-RFLP

Parasites & Vectors20136:227

https://doi.org/10.1186/1756-3305-6-227

Received: 14 June 2013

Accepted: 1 August 2013

Published: 7 August 2013

Abstract

Background

Toxoplasma gondii is a widely prevalent protozoan parasite that causes serious toxoplasmosis in humans and animals. The present study aimed to determine the genetic diversity of T. gondii isolates from pigs in Jiangxi, Sichuan, Guangdong Provinces and Chongqing Municipality in China using multilocous polymerase chain reaction-restriction fragment length polymorphism (PCR-RFLP) technology.

Methods

A total of 38 DNA samples were extracted from hilar lymph nodes of pigs with suspected toxoplasmosis, and were detected for the presence of T. gondii by semi-nested PCR of B1 gene. The positive DNA samples were typed at 11 genetic markers, including 10 nuclear loci, namely, SAG1, 5′-SAG2 and 3′-SAG2, alternative SAG2, SAG3, BTUB, GRA6, c22-8, c29-2, L358, PK1, and an apicoplast locus Apico.

Results

Twenty-five of the 38 DNA samples were T. gondii B1 gene positive. Complete genotyping data for all loci could be obtained for 17 of the 25 samples. Two genotypes were revealed (ToxoDB PCR-RFLP genotypes #9 and #3). Sixteen samples belong to genotype #9 which is the major lineage in mainland China and one sample belongs to genotype #3 which is Type II variant.

Conclusions

To our knowledge, this is the first report of genetic typing of T. gondii isolates from pigs in Jiangxi, Sichuan Province and Chongqing Municipality, and the first report of ToxoDB #3 T. gondii from pigs in China. These results have implications for the prevention and control of foodborne toxoplasmosis in humans.

Keywords

Toxoplasma gondii ToxoplasmosisGenetic characterizationPigChina

Background

Toxoplasma gondii is an obligate intracellular protozoan parasite, infecting all warm-blooded animals and human beings worldwide [15]. It is transmitted to humans through consumption of undercooked meat containing T. gondii tissue cysts or food or water contaminated by oocysts shed in the feces of infected cats. Toxoplasmosis is one of the main illnesses related to foodborne hospitalizations and deaths [6]. One third of the world population is chronically infected with this parasite [7]. Although T. gondii infection in most people appears to be asymptomatic, it may result in life-threatening illness in some immuno-compromised individuals [8].

In China, pigs are the primary livestock raised for human consumption, and they are commonly susceptible to T. gondii. This provides the parasite a potential route to transmit the infection via consumption of raw or undercooked meat. T. gondii may cause serious diseases such as blindness through consuming raw pork [9].

According to genotypic analysis based on multi-locus approaches, such as PCR-RFLP and microsatellite typing, T. gondii strains isolated from humans and animals in North America and Europe have been sorted into 3 clonal lineages, referred to as type I, II, and III [1012]. A fourth clonal lineage (type 12) in North America was identified in wildlife recently [13]. However, T. gondii isolates from South America are characterized with higher genetic diversity [1416].

China is a big country, but only limited reports concerning genetic characterization of T. gondii isolates from pigs are available [1719]. Such information is still not available for some regions of China especially Jiangxi, Sichuan Provinces and Chongqing Municipality, where swine industry plays an important role in agricultural economy. Thus, the objective of this study is to better understand the genetic diversity of T. gondii isolates from pigs in these localities of China.

Methods

Sample collection

Hilar lymph nodes were collected, post slaughter, from 38 dead pigs (36 slaughter pigs and 2 sows) with suspected toxoplasmosis during May 2010-March 2013. No ethical approval is required. These pigs came from different geographic regions of China, including 33 from Jiangxi Province, 3 from Sichuan Province, 1 from Chongqing Municipality, and 1 from Guangdong Province, and they all exhibited typical symptoms of toxoplasmosis, which manifest primarily as high fever, dyspnea, subcutaneous hemorrhage, abortion, enlargement and necrosis of liver and spleen.

Genomic DNA extraction

Genomic DNA was extracted from these hilar lymph nodes using TIANamp Genomic DNA kit (TianGen™, Beijing, China) according to manufacturer’s recommendations. In brief, 30 mg of the hilar lymph nodes were treated with sodium dodecyl sulphate/proteinase K at 56°C for overnight digestion in a thermostat water bath. DNA samples were prepared after purification by silica gel column chromatography and eluted into 50 μl elution buffer. Then, a semi-nested PCR was performed to detect the T. gondii B1 gene following the previously described protocol [20].

Genetic characterization of T. gondii isolates

Multilocous polymerase chain reaction-restriction fragment length polymorphism (PCR-RFLP) method [21] was employed to genetically characterize the T. gondii isolates from pigs. Firstly, pre-amplification was carried out using a set of mixed external primers in a single reaction. Then 1 μl of the products served as template DNA for nested PCR with internal primers for each marker, respectively. The nested PCR products were digested with restriction endonucleases. The restriction fragments were resolved in 2.5%-3% agarose gel to display single nucleotide polymorphisms (SNPs) using a gel document system (UVP GelDoc-It™ Imaging System, Cambridge, U.K.), and the genotypes of T. gondii isolates were finally revealed.

Results and discussion

Twenty-five of the 38 DNA samples were T. gondii B1 gene positive, including 23 from slaughter pigs and 2 from sows. Due to low DNA concentration, only 17 DNA samples presented complete genotyping data. The results of genotyping of these isolates and 9 references were summarized in Table 1. Two genotypes were revealed (ToxoDB PCR-RFLP genotypes #9 and #3). It is interesting that only one genotype (ToxoDB#9) was identified from all 12 T. gondii isolates from different districts of Jiangxi Province, which suggests that this genotype is predominantly prevalent in Jiangxi Province and the genetic diversity of T. gondii may be low in pigs in this province, although further studies using more samples collected from much broader geographical localities of this province are warranted before a valid conclusion can be drawn. Moreover, ToxoDB#9 was also identified in 4 isolates from 3 localities (Zigong and Ziyang in Sichuan and Rongchang in Chongqing) near the border of Sichuan Province and Chongqing Municipality. This same genotype was previously identified in cats in Beijing Municipality, Guangdong and Anhui Provinces [2224], and it was also founded in pigs in Guangdong, Henan, Yunnan and Anhui Provinces [1719, 25]. Based on these data, ToxoDB#9 was a predominant lineage prevalent in Mainland China. Interestingly, ToxoDB#9 has been identified in North and Latin America [15, 2628], as well as other Asian countries, such as Sri Lanka, Vietnam [29, 30], indicating that it has a worldwide distribution. In the near future, it would be interesting to genotype T. gondii isolates from humans in the same localities to see if humans and animals share the same genotypes.
Table 1

Summary of genotyping of Toxoplasma gondii isolates from pigs in different geographic regions of China

Isolate ID

Host

Location

SAG1

5′ + 3′ SAG2

Alternative SAG2

SAG3

BTUB

GRA6

c22-8

c29-2

L358

PK1

Apico

Genotype

GT1

Goat

United States

I

I

I

I

I

I

I

I

I

I

I

Reference, Type I, ToxoDB #10

PTG

Sheep

United States

II/III

II

II

II

II

II

II

II

II

II

I

Reference, Type II, ToxoDB #1

CTG

Cat

United States

II/III

III

III

III

III

III

III

III

III

III

I

Reference, Type III, ToxoDB #2

MAS

Human

France

u-1

I

II

III

III

III

u-1

I

I

III

I

Reference, ToxoDB #17

TgCgCa1

Cougar

Canada

I

I

II

III

III

II

II

u-1

I

u-2

I

Reference, ToxoDB #66

TgCatBr5

Cat

Brazil

I

III

III

III

II

III

I

I

I

u-1

I

Reference, ToxoDB #19

TgWtdSc40

WTD

United States

u-1

II

II

II

II

II

II

II

I

II

I

Reference, Type 12, ToxoDB #5

TgCatBr64

Cat

Brazil

I

I

u-1

III

III

III

u-1

I

III

III

I

Reference, ToxoDB #111

TgRsCr1

Toucan

Costa Rica

u-1

I

II

III

I

III

u-2

I

I

III

I

Reference, ToxoDB #52

TgPSZ30

SP

Zigong, Sichuan

u-1

II

II

III

III

II

II

III

II

II

I

ToxoDB #9

TgPSZ41

SP

Zigong, Sichuan

u-1

II

II

III

III

II

II

III

II

II

I

ToxoDB #9

TgPSY19

SP

Ziyang, Sichuan

u-1

II

II

III

III

II

II

III

II

II

I

ToxoDB #9

TgPCR51

SP

Rongchang, Chongqing

u-1

II

II

III

III

II

II

III

II

II

I

ToxoDB #9

TgPJX1

Sow

Wannian, Jiangxi

u-1

II

II

III

III

II

II

III

II

II

I

ToxoDB #9

TgPJX2

SP

Xinjian, Jiangxi

u-1

II

II

III

III

II

II

III

II

II

I

ToxoDB #9

TgPJX3

SP

Nanchang, Jiangxi

u-1

II

II

III

III

II

II

III

II

II

I

ToxoDB #9

TgPJX4

Sow

Xingguo, Jiangxi

u-1

II

II

III

III

II

II

III

II

II

I

ToxoDB #9

TgPJX5

SP

Xingguo, Jiangxi

u-1

II

II

III

III

II

II

III

II

II

I

ToxoDB #9

TgPJX6

SP

Nanchang, Jiangxi

u-1

II

II

III

III

II

II

III

II

II

I

ToxoDB #9

TgPJX7

SP

Yujiang, Jiangxi

u-1

II

II

III

III

II

II

III

II

II

I

ToxoDB #9

TgPJX8

SP

Yujiang, Jiangxi

u-1

II

II

III

III

II

II

III

II

II

I

ToxoDB #9

TgPJX9

SP

Yujiang, Jiangxi

u-1

II

II

III

III

II

II

III

II

II

I

ToxoDB #9

TgPJX10

SP

Yujiang, Jiangxi

u-1

II

II

III

III

II

II

III

II

II

I

ToxoDB #9

TgPJX11

SP

Yujiang, Jiangxi

u-1

II

II

III

III

II

II

III

II

II

I

ToxoDB #9

TgPJX12

SP

Nanchang, Jiangxi

u-1

II

II

III

III

II

II

III

II

II

I

ToxoDB #9

TgPZS1

SP

Zhongshan, Guangdong

II

II

II

II

II

II

II

II

II

II

I

ToxoDB #3

u-1 and u-2*represent unique RFLP genotypes, respectively.

WTD White-tailed Deer.

SP Slaughter pig.

In this study, another genotype ToxoDB#3 (the type II variant) was identified in a pig in Zhongshan, Guangdong Province. This was the fourth time that ToxoDB#3 was identified in China. Previously, this type was founded from sheep in Qinghai Province [17], from birds in Xinjiang Uygur Autonomous Region [31] and from sparrow in Lanzhou, Gansu Province [32]. This is also the first report of ToxoDB#3 from pigs in China, which indicated that ToxoDB#3 is also a major lineage prevalent in Mainland China.

For Chinese people especially the Han ethnic, pork is the main meat of choice. With the development of the economy in China, the standard of life has greatly improved in recent years. As a result, the pig industry and pork products have been driven by increasing consumption for high quality animal protein. Unlike herbivorous cattle and sheep, pigs are omnivores, they feed on a variety of animal meat and vegetable matter, which increases the chance of contact with cat feces and exposure to T. gondii, especially for those free-range pigs. Thus, pigs pose a risk for transmission of toxoplasmosis to human beings.

Conclusions

The present study has genetically characterized T. gondii isolates from pigs in Jiangxi, Sichuan, Guangdong Provinces and Chongqing Municipality. Two genotypes were revealed (ToxoDB PCR-RFLP genotypes #9 and #3), with the genotype #9 as the major lineage in mainland China. To our knowledge, this is the first report of genetic typing of T. gondii isolates from pigs in these localities, and the first report of ToxoDB genotype #3 from pigs in China. These findings not only enrich genetic diversity of T. gondii, but also have implications for the prevention and control of foodborne toxoplasmosis in humans.

Declarations

Acknowledgements

Project support was provided by the National Natural Science Foundation of China (Grant Nos. 31228022, 31101812, 31230073 and 31172316), and the Science Fund for Creative Research Groups of Gansu Province (Grant No. 1210RJIA006).

Authors’ Affiliations

(1)
State Key Laboratory of Veterinary Etiological Biology, Key Laboratory of Veterinary Parasitology of Gansu Province, Lanzhou Veterinary Research Institute, Chinese Academy of Agricultural Sciences
(2)
College of Animal Science and Technology, Jiangxi Agricultural University
(3)
Department of Microbiology, The University of Tennessee
(4)
College of Agriculture, Yanbian University

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