袁建琴，常泓，趙江河，唐中偉，史宗勇，王俊東

1 山西農(nóng)業(yè)大學(xué) 生命科學(xué)學(xué)院，山西 太谷 030801 2 山西農(nóng)業(yè)大學(xué) 動(dòng)物科技學(xué)院，山西 太谷 030801

山西市場(chǎng)動(dòng)物飼料中轉(zhuǎn)基因成分的檢測(cè)

袁建琴1，常泓1，趙江河1，唐中偉1，史宗勇1，王俊東2

1 山西農(nóng)業(yè)大學(xué) 生命科學(xué)學(xué)院，山西 太谷 030801 2 山西農(nóng)業(yè)大學(xué) 動(dòng)物科技學(xué)院，山西 太谷 030801

袁建琴, 常泓, 趙江河, 等. 山西市場(chǎng)動(dòng)物飼料中轉(zhuǎn)基因成分的檢測(cè). 生物工程學(xué)報(bào), 2016, 32(11): 1576?1589.

Yuan JQ, Chang H, Zhao JH, et al. Detection of transgenic components in animal feeds on Shanxi markets. Chin J Biotech, 2016, 32(11): 1576?1589.

為了評(píng)估轉(zhuǎn)基因玉米和大豆在山西動(dòng)物飼料市場(chǎng)的占有率和標(biāo)識(shí)情況，采用改良十六烷基三甲基溴化銨法(Hexadecyltrimethy ammonium bromide, CTAB) 提取山西市場(chǎng)抽取的30份雞和豬飼料，通過(guò)定性PCR打包篩查，對(duì)檢測(cè)陽(yáng)性結(jié)果打包飼料拆包并檢測(cè)CaMV 35S啟動(dòng)子、NOS終止子、玉米內(nèi)標(biāo)zSSIIb、大豆內(nèi)標(biāo)Lectin和CryIA (b)基因。同時(shí)檢測(cè)玉米和大豆轉(zhuǎn)化體事件MON810和GTS40-3-2。結(jié)果表明，83.3%的飼料含有轉(zhuǎn)基因成分。所抽取的玉米、大豆、豬飼料和雞飼料轉(zhuǎn)基因成分陽(yáng)性率分別為6.67%、100%、93.3%和73.3%。實(shí)時(shí)熒光定量PCR檢測(cè)結(jié)果與定性PCR一致。結(jié)果提示，雞和豬飼料中轉(zhuǎn)基因成分在山西市場(chǎng)的占有率較高。

商業(yè)化雞飼料，商業(yè)化豬飼料，轉(zhuǎn)基因玉米，轉(zhuǎn)基因大豆，定性PCR，實(shí)時(shí)熒光定量PCR，轉(zhuǎn)化體事件MON810和GTS40-3-2

Introduction

By gene modification technique, compositions of plants, animals or microorganisms were altered to gain new characteristics, such as insect resistance, herbicide tolerance, modified nutritional composition or an enhanced shelf life, we call them genetically modified organisms (GMOs)[1-2]. Roundup ReadyTMsoybean (RRS) was firstly produced by the Monsanto Company in Canada in 1996, which was approved for consumption[3-4]. According to the final reports of 2014, the planting of GM crops worldwide had reached 181.5 million hectares and constantly increased 106-fold since that first crop in global area[5-6]. Although GMOs had many advances, consumer had very strong reaction[3]. In China, regulations have come into force, which are the labeling and traceability of GM food. The regulations stipulate the requirement of labeling containing GM material, such as soybean seed, soybean flour, soybean, soybean oil, soybean meal, maize seeds, maize, maize oil and maize flour etc[7]. To comply with the requirements of legislation, usually reliable and practical detection methods is required[1,8-13]. Before either GMO quantification or event identification, the starting point of GMO detection is generally evaluation of the screening method[2,14]. Most of the PCR screening methods usually are to detect either CaMV 35S promoter (the cauliflower mosaic virus) or NOS terminator (the nopaline synthase) or both, because most GM products contain two or one of these sequences[8,15]. ZSSIIb for maize and Lectin for soybean are species-specific PCR testing genes, which arepresent in both GM and non GM maize and soybean. For discrimination between non-approved and approved traits, event-specific PCR methods are used to identify the GMO event (for example GTS40-3-2 and MON810). PAT (Phosphinothricin acetyltransferase) gene mediates tolerance to the herbicide phosphinotricin (glufosinate). A number of soil bacteria naturally possess the PAT gene. Transgenic plants expressing the PAT gene are able to degrade the herbicide agent phospinotricin (glufosinate). BAR gene coding for phosphinothricin acetyltransferase had been isolated from Bacillus amylolique facions. PAT and BAR genes are widely used as selective markers for the transformation of higher plants. CryIA(b) gene is a synthetic gene encoding the 648 amino acids, insecticidal-active truncated product identical to CryIA(b) gene of Bacillus thuringiensis subsp (General Administration of Qality Spervision, Ispection and Quarantine of the People's Republic of China, SN/T 1202-2003).

Because GMOs have the worldwide high production and fairly uncertain of the current status of the foods, people pay particular attention to them. Soybean and maize were chosen because they were the staple constituents of feed[8,16]. The study objective was to determine the ratio of GM-containing soybean and maize feed obtained from local feed manufacturer and retail shops in Shanxi of China in 2015.

1 Materials and methods

1.1 Feed

Thirty soybean- and maize-containing feeds were purchased from 24 random local retail shops (20 feed manufacturers) in Shanxi of China in May 2015. In the 30 feeds (serial number: 01-30, there were layer feed and pig feed in three periods. Every period there were five different feed manufacturers or brands). In different periods, 5 kinds of feed manufacturers (brand) might be overlapping or different.), 15 layer feeds (including adding concentrate), accounted for about 50.0% of the total feeds, 15 pig feeds accounted for about 50% of the total feeds (Table 1).

1.2 Qualitative PCR

1.2.1 Reference materials

Certified reference samples (CRS) (GTS40-3-2 1% soybean flour, MON810 1% maize flour and flour mixture -Bt176 1%, Bt11 1% and kefeng6 1% positive sample mixture flour), which were provided by the science and technology development center of China’s ministry of agriculture, were used as the positive controls in the study.

1.2.2 DNA extraction

For DNA isolation from feed and CRS, an improved version of the cetyltrimethyl ammonium bromide (CTAB) method was used. The collected DNA quantification (concentration and purity) was achieved by measuring the UV absorption at 260 nm and 280 nm using a biophotometer (Eppendorf.AG, Germany) and stored at -20 ℃ until used.

Table 1 The composition of feed

1.2.3 PCR primers

The CaMV 35S promoter and the NOS terminator for amplifying the specific DNA sequences were used for the GMO screening of the products[17]. The amplification of extracted DNA was verified using plant-specific primers targeting the zSSIIb for maize, the Lectin for soybean, specific sequences present in MON 810 event and RRS (GTS40-3-2) for specific GMO detection[18-19]. Primers for amplifying CryIA(b),BAR and PAT genes were used[20-21]. The primer names, orientation, sequences and length synthesized by TAKARA BIOTECHNOLOGY (Dalian, China) in the study were summarized in Table 2.

Table 2 The primers used in the study

Table 3 Real-time PCR primer sequences

1.3 Real-time PCR of feed samples

1.3.1 Reference materials

Certified reference material (CRM) (Soya seed powder-GTS40-3-2 Soya (10%), Catalog Number: ERM-BF410GK, IRMM).

1.3.2 PCR primers

The names, orientation, sequences and length of the primer and probe (synthesized by TAKARA BIOTECHNOLOGY, Dalian, China) were summarized in Table 3[17,22]. The amplificationswere performed with using Code NO. RR390A from TAKARA BIOTECHNOL (Dalian, China).

1.3.3 Calculating transformant content

The experiment observed and analyzed standard curve and amplification curve, calculated transformant content.

2 Results and discussion

2.1 Concentration and purity of DNA

In our study, an appropriate quality and quantity of DNA could be extracted from the feed samples using the improved CTAB method (Fig. 1). The date showed that DNA concentration and purity (A260/A280) extracted by improved CTAB method ranged from 120.9 μg/mL to 778.3 μg/mL and 1.7 to 1.99, respectively. The results showed that improved CTAB method gave sufficient yield of DNA.

In order to isolate DNA from feeds with different components of GMOs, the improved CTAB were used (Fig. 1). According to the characteristics of the feed production and processing steps in the traditional, the CTAB method was simplified, reagents used commonly in laboratory could be done. Compared to the (high) cost of the kit (40 RMB per time), the cost of the improved CTAB method was 2 RMB per time. Simultaneously, the improved CTAB method could reduce the extraction time of the kit method by at least 50 min. With the improved CTAB method, successful species-specific PCR testing (zSSIIb for maize and Lectin for soybean) and high amplification success rate were achieved with 30 different kinds of feeds extracts just one time, which confirmed that these extracts contained a sufficient amount of amplifiable DNA. In our work, the improved CTAB method was more effective and less time-consuming in comparison with the existing kit methods for isolation of DNA from plant-derived foods and feed.

Fig. 1 The concentration and purity of DNA extracted from feeds. The graph A and B respectively on behalf of concentration and purity of DNA extracted from feeds; 01-30: 01-30 feed samples.

2.2 Screening of GMOs by packing feeds

The 30 feeds mentioned above were packaged as 5 packages (6 samples in each package) for detecting by the CaMV 35S promoter, NOS terminator, CryIA(b), BAR and PAT genes by PCR, all DNA of feeds were run in duplicate. A 195 bp fragment (CaMV 35S promoter) was detected in all 5 packages feeds produced through PCR amplification. Through the process of detecting, feeds of 5 packages gave 180 bp positive amplification signal of NOS gene. Both packed feeds 01-06, 19-24 amplified 146 bp CryIA(b) gene signal. The target fragments of BAR (175 bp) and PAT (191 bp) genes could not be detected in all feeds (Fig. 2).

2.3 Specific gene detection of GMOs

According to the results, the positive-packed feeds were subsequently unpacked and detected by CaMV 35S promoter, NOS terminator, CryIA(b), Lectin and zSSbⅡ genes. All DNA of feeds were run in duplicate excepting for zSSbⅡ gene (simple sample).

2.3.1 CaMV 35S promoter PCR

30 feed samples were detected by CaMV 35S promoter. 01-23, 25-26 feed samples gave 195 bp positive amplification signal (Fig. 3).

2.3.2 NOS terminator PCR

01-30 feed samples were detected by NOS terminator. 180 bp fragment of NOS terminator for 01-18, 20-23 and 25-26 feed samples were produced through PCR amplification (Fig. 4).

2.3.3 CryIA(b) gene PCR

01-30 feed samples were detected by CryIA(b) gene. The target fragments of CryIA(b) gene could be detected in 03 and 19 feeds (Fig. 5).

2.3.4 Lectin gene PCR

01-30 feed samples were detected by Lectin gene. 01-18, 20-23, 25-26 feeds gave 118 bp positive amplification signal of Lectin gene (Fig. 6).

2.3.5 ZSSIIb gene PCR

The 30 feed samples (01-30) were unpacked for detecting by the zSSIIb gene. The target fragments of 88 bp zSSIIb gene could be detected in all feed (Fig. 7).

2.4 Event-specific qualitative PCR

According to the results, the positive feeds were unpacked and detected by specific MON810 and GTS40-3-2 events.

2.4.1 GTS40-3-2 event PCR

The 24 positive feeds (01-18, 20-23 and 25-26) containing soybean (Lectin gene) were detected for the presence of specific GM GTS40-3-2 event. All these feeds gave 370 bp positive amplification signal of GTS40-3-2 (Fig. 8). DNA of feeds were run in single sample.

Fig. 2 The electrophoregram of CaMV 35S, NOS, CryIA(b), BAR and PAT genes of packing feeds. The electrophoregram A, B, C, D and E respectively on behalf of detecting CaMV35S, NOS, CryIA(b), BAR and PAT genes; 01-30: 01-30 feed samples; positive control (PC): Bt176 1%, Bt11 1% and kefeng6 1% positive sample mixture flour; negative control (NC): negative sample (maize flour); blank (BL): ultrapure water; M: DL2 000 marker (2 000 bp, 1 000 bp, 750 bp, 500 bp, 250 bp, 100 bp).

Fig. 3 The electrophoregram of CaMV 35S promoter. 01-30: 01-30 feed samples; positive control (PC): Bt176 1%, Bt11 1% and kefeng6 1% positive sample mixture flour; negative control (NC): negative sample (maize flour); blank (BL): ultrapure water, respectively; M: DL2 000 marker (2 000 bp, 1 000 bp, 750 bp, 500 bp, 250 bp, 100 bp).

Fig. 4 The electrophoregram of NOS terminator. 01-30: 01-30 feed samples; positive control (PC): Bt176 1%, Bt11 1% and kefeng6 1% positive sample mixture flour; negative control (NC): negative sample (maize flour); blank (BL): ultrapure water, respectively; M: DL2 000 marker (2 000 bp, 1 000 bp, 750 bp, 500 bp, 250 bp, 100 bp).

Fig. 5 The electrophoregram of CryIA(b) gene. 01-30: 01-30 feed samples; positive control (PC): Bt176 1%, Bt11 1% and kefeng6 1% positive sample mixture flour; negative control (NC): negative sample (maize flour); blank (BL): ultrapure water, respectively; M: DL2 000 marker (2 000 bp, 1 000 bp, 750 bp, 500 bp, 250 bp, 100 bp).

Fig. 6 The electrophoregram of Lectin gene of 01-30 feed samples. 01-30: 01-30 feed samples; PC: GTS40-3-2 event flour; NC: negative sample (soybean flour) and BL: ultrapure water, M: DL2 000 marker (2 000 bp, 1 000 bp, 750 bp, 500 bp, 250 bp, 100 bp).

Fig. 7 The electrophoregram of zSSbⅡ gene. 01-30: 01-30 feed samples; positive control (PC): Bt176 1%, Bt11 1% and kefeng6 1% positive sample mixture flour; negative control (NC): negative sample (maize flour); blank (BL): ultrapure water, respectively; M: DL2 000 marker (2 000 bp, 1 000 bp, 750 bp, 500 bp, 250 bp, 100 bp).

Fig. 8 The electrophoregram of GTS40-3-2. 1-12 lanes: 01-12 feed samples; 17-28 lanes: 13-18, 20-23, 25-26 feed samples; 13-14, 29-30 lanes: GTS40-3-2 positive sample flour; 15, 31 lanes: negative sample (soybean flour); 16, 32 lanes: ultrapure water; M: DL2 000 marker (2 000 bp, 1 000 bp, 750 bp, 500 bp, 250 bp, 100 bp).

2.4.2 MON810 event PCR

Feeds (03 and 19) were detected by MON810 event. By detecting, 106 bp amplification signal of MON810 was produced for both feeds (Fig. 9). DNA of feeds was run in triple.

Fig. 9 The electrophoregram of MON810 of 03 and 19 feed samples. 1-3 lanes: 03 feed sample; 4-6 lanes: 19 feed sample; 7-8 lanes: MON810 1% positive sample flour; 9 lane: negative sample (maize flour); 10 lane: ultrapure water; M: DL2 000 marker (2 000 bp, 1 000 bp, 750 bp, 500 bp, 250 bp, 100 bp).

2.5 The summary of detecting results of feeds

In 30 feeds, 25 feeds contained GM ingredients. 01-02, 04-18, 20-23, 25-26 feeds contained CaMV 35S promoter, NOS terminator, GTS40-3-2 event, zSSIIb and Lectin genes. 03 feed contained CaMV 35S promoter, NOS terminator, MON810 event,zSSIIb, Lectin and CryIA(b) genes. 19 feed contained CaMV 35S promoter, MON810 event, zSSIIb and CryIA(b) genes. 24, 27-30 feeds were non GM, only contained zSSIIb (Fig. 10). The overall results of GMO screening of 5 packed feeds were 100% for CaMV 35S promoter, 100% for NOS terminator, 20% for CryIA(b) and 0% for BAR gene and PAT gene. The detecting results of 30 feed samples showed that 83.3% of the feeds were tested positive for GMOs, in which positive rates of maize, soybean, pig and layer feeds were 6.67%, 100%, 93.3% and 73.3%, respectively. In conclusion, commercialized GM feed had a wide positive product scope in Shanxi province of China. The composition and positive rate of feeds were as shown (Fig. 11).

Fig. 11 The composition and positive rate of 30 feed samples.

2.6 Real-time PCR of feed samples

According to the qualitative results, 24 feed samples of containing genes of Lectin and GTS40-3-2 were detected by real-time PCR.

2.6.1 Lectin gene real-time PCR

The quantitative results of Lectin gene from identified 24 feeds DNA were presented in Fig. 12 and Fig. 13. The obtained real-time PCR results were according to those requirements since the correlation coefficient (R2) of standard curves was, generally, ≥ 0.98, while PCR efficiencies ranged, on average, from 93.9% to 100.6%, indicating the adequacy of the standard curves for quantification. In Fig.12, standard of Lectin gene had a typical amplification curve. Amplification efficiency was 98.0%, R2of standard curves was 0.984>0.98, slope of standard curve was -3.370>-3.6 and ＜-3.1, indicating the adequacy of the standard curves for quantification. In Fig. 13, negative control (salmon sperm DNA) and blank control (water) had not typical amplification curve of Lectin gene, the DNA of all feed samples in Lectin gene amplification curve appeared typical amplification curve. In amplification results (generated by the Excel table), Ct values and copy numbers of all feed samples were in Table 4.

Fig. 12 Lectin gene standard curve.

Fig. 13 Lectin gene amplification curve.

Table 4 The Ct value and copy number of Lectin gene from 24 feed samples

2.6.2 GTS40-3-2 gene real-time PCR

The quantitative results of special event GTS40-3-2 gene from identified 24 feeds DNA were presented in Fig. 14 and Fig. 15. In Fig. 14, standard of GTS40-3-2 gene had a typical amplification curve. Amplification efficiency was 99.9%, R2of standard curves was 0.988>0.98, slope of standard curve was -3.324>-3.6 and ＜-3.1, indicating the adequacy of the standard curves for quantification. In Fig. 15, negative control (salmon sperm DNA) and blank control (water) had not typical amplification curve of GTS40-3-2, the DNA of all feed samples in GTS40-3-2 gene amplification curve appeared typical amplification curve. In amplification results (generated by the Excel table), Ct values and copy numbers of all feed samples were in Table 5.

2.6.3 The content of the special event GTS40-3-2 in the feeds

The content of the special event GTS40-3-2 in the feeds was calculated according to the following formula:

nGTS40-3-2was copy number of GTS40-3-2 gene, nLectinwas copy number of Lectin gene. The GTS40-3-2 transformant content of feed samples was in Table 6.

Fig. 14 GTS40-3-2 gene standard curve.

Fig. 15 GTS40-3-2 gene amplification curve.

Table 5 The Ct value and copy number of GTS40-3-2 gene from 24 feed samples

Table 6 The GTS40-3-2 transformant content of 24 feed samples

In our study, all 30 feeds were packed (6 feeds of each package) and screened, 5 packages (100%) were determined to be positive for two or three of the novel sequences which indicated the presence of GMOs. The dispersion of these positive packed feeds within soybean and maize were as follows: 25 of the 30 total (83.3%) detected all feeds, 11 of the 15 total (73.3%) detected layer feeds, 14 of the 15 total (93.3%) detected pig feeds were positive (Fig. 11). All 30 feeds contained maize composition, 2 of 30 feeds (6.7%) which were layer feeds were positive of MON810. 30 feeds had 24 feeds containing soybean composition, 24 feeds (10 for chicken feed, 14 for pig feed) containing soybean (100%) tested positive for GTS40-3-2 event, that came mostly from soybean meal of oil residue from imported soybean. Layer feeds had 2 positive feeds of MON810 event, pig feeds had not been detected positively for the composition of MON810 event. The data showed maize sources varied in different feed manufacturers. The ratio of positive feed containing layer feed seemed to be lower than that of the pig feed, which was a different result than was expected. In fact, there were 4 concentrate supplements of layer feeds including DDGS protein feed, dry maize lees protein feed and shoetree maize husk powder and maize feed (raw material-layer), which were also included in the layer feeds. According to the test results, a positive rate of transgenic maize in feed was very low in the market of Shanxi. The results in which we did not detect genetically modified ingredients in these concentrate supplement were also normal. In this study, positive feeds only had one feed (soybean meal) marked as“genetically modified” composition; genetically modified product identification rate was only 3.33%. Furthermore, we also found that on the identified feed products’ packaging logo, the font was very small and hard to recognize.

Amplification of the maize-specific zSSbⅡsequence in 30 feeds and the soybean-specific Lectin sequence in 24 feeds confirmed that the feeds containing 5 negative feeds and 1 positive feed were negative for Lectin, which indicated that these feeds did not contain soybean DNA. The above mentioned 24 CaMV 35S and/or 23 NOS positive soybean feeds were analyzed for RRS and all of them gave positive amplification signal (GTS40-3-2 event) (Fig. 8). The other 2 positive feed samples containing CryIA(b) were screened for the presence of specific GM maize events. For this purpose, PCR detections of specific sequences of MON 810 event (containing zSSIIb, CaMV 35S, CryIA(b) and MON 810 genes) was performed (Fig. 9). 03 and 19 positive feeds (containing zSSIIb, CaMV 35S, CryIA(b) and MON810) were identified as containing MON810 event. The results of our study showed that 1 feed (19) was negative for the NOS terminator while positive for the CaMV 35S promoter (maize containing feed). In our study, the NOS negative feed was determined to be MON810 maize feed and thus confirmed that the feed was true positive although they did not give any amplification signal with the NOS. In case of maize, it could also be related to the lack of the NOS terminator common inseveral maize events, for example MON810. Similarly, detection of both the CaMV 35S and the NOS sequences in another feed (03) confirmed the GM maize MON810 event (containing CaMV 35S) and GM soybean GTS40-3-2 event (containing NOS) presence.

By real-time PCR, 24 feed samples of containing genes of Lectin and GTS40-3-2 were detected. The results showed that they contained different content of GTS40-3-2 transformant (0.05%-4.70%, Table 6). The results were consistent with qualitative PCR (Fig. 10).

In this study, we demonstrated that many layer and pig feeds containing GM GTS40-3-2 event and a small number of layer feeds containing GM MON810 event were sold commercially in Shanxi of China.

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(本文責(zé)編 陳宏宇)

March 24, 2016; Accepted: May 3, 2016

Jundong Wang. Tel: +86-354-6288206; Fax: +86-354-6222942; E-mail: wangjd53@outlook.com

Detection of transgenic components in animal feeds on Shanxi markets

Jianqin Yuan1, Hong Chang1, Jianghe Zhao1, Zhongwei Tang1, Zongyong Shi1, and Jundong Wang2
1 College of Life Science, Shanxi Agricultural University, Taigu 030801, Shanxi, China 2 College of Animal Science and Veterinary Medicine, Shanxi Agricultural University, Taigu 030801, Shanxi, China

To assess the presence of genetically modified (GM) maize and soybean in a range of commercialized feed in Shanxi province of China in 2015, improved hexadecyltrimethy ammonium bromide (CTAB) method was used to extract DNA. The screening of packed feeds was carried out by qualitative PCR. Then positive feeds were unpacked and detected by the CaMV 35S promoter, NOS terminator, zSSIIb, Lectin and CryIA (b) genes. The identified maize and soybean events were confirmed by event-specific MON810 and GTS40-3-2. Results showed that 83.3% of the feeds was tested positive for GMOs, in which positive rates of maize, soybean, pig and layer feeds were 6.67%, 100%, 93.3% and 73.3%, respectively. The results of real-time PCR were consistent with qualitative PCR. These results indicated that commercialized GM feed had a wide positive product scope in Shanxi province of China. Further studies are necessary to study effects of feeding livestock and poultry with feed containing GM ingredients on animals and their products.

commercialized layer feed, commercialized pig feed, genetically modified maize, genetically modified soybean, qualitative PCR, real-time PCR, event-specific MON810 and GTS40-3-2

Supported by: Key Projects in the National Science and Technology Pillar Program during the Twelfth Five-Year Plan Period of China (No. 2012BAD12B06-2), Science and Technology Key Program of Shanxi Province (No. 20140311025-3), Natural Science Foundation of Shanxi Province (No. 2013011028-2), Higher School Teaching Reform Project of Shanxi Province (No. J2012026).

“十二五”國(guó)家科技支撐計(jì)劃子課題 (No. 2012BAD12B06-2)，山西省科技攻關(guān)項(xiàng)目 (No. 20140311025-3)，山西省自然科學(xué)基金 (No. 2013011028-2)，山西省高等學(xué)校教學(xué)改革項(xiàng)目 (No. J2012026) 資助。

網(wǎng)絡(luò)出版時(shí)間：2016-06-12 網(wǎng)絡(luò)出版地址：http://www.cnki.net/kcms/detail/11.1998.Q.20160612.1648.003.html