Real-time RT-PCR for H5N1 avian influenza A virus detection

doi:10.1099/jmm.0.47014-0

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Real-time RT-PCR for H5N1 avian influenza A virus detection

Weijun Chen¹^,, Bo He¹^,, Changgui Li²^,, Xiaowei Zhang¹, Weili Wu¹, Xuyang Yin³, Baoxing Fan⁴, Xingliang Fan² and Jian Wang¹

¹ Beijing Genomics Institute, Chinese Academy of Sciences, Beijing, China

² National Institute for the Control of Pharmaceutical and Biological Products, Beijing, China

³ Wenzhou Medical College, Wenzhou, China

⁴ Beijing 301 Hospital, Beijing, China

Correspondence
Weijun Chen
chenwj{at}genomics.org.cn
Jian Wang
wangjian{at}genomics.org.cn

Received 20 October 2006
Accepted 11 January 2007

The recent recurrence of highly pathogenic avian influenza virusA H5N1 was firstly reported in mid-December 2003 and continuedthrough 2005. This study describes a sensitive and specificreal-time RT-PCR method for the detection of influenza A subtypeH5 and for monitoring virus loads. Using serial dilutions ofinfluenza A H5N1 cultures, this assay reproducibly determinedthe lowest detection limit to be approximately 5x10^–250 % egg infective doses (EID₅₀). In contrast, the minimum detectionlimit was approximately 3 EID₅₀ in conventional RT-PCR withWHO primers and 10 EID₅₀ in antigen-capture ELISA. In testsof serial dilutions of in vitro-transcribed influenza A H5 geneRNA, there was linear amplification from 40 copies to 4x10⁸copies of target RNA per reaction and approximately six copies,and sometimes even as few as three copies, of target RNA testedpositive in our assay. Thirty-five throat swabs from ill birdswere tested: 33 samples tested positive using this assay. Incomparison, 27, 13 and 19 samples tested positive using conventionalRT-PCR, antigen-capture ELISA and virus isolation, respectively.To evaluate further the sensitivity of this real-time RT-PCR,a standard panel and 60 H5N1 isolates that contained differentclades of influenza virus A/H5N1 were tested and all testedpositive. To evaluate the specificity of the assay, 60 throatswabs from patients infected with influenza virus A H1 weretested; all were negative. Thirteen other viruses were alsotested and all tested negative.

Abbreviations: EID₅₀, 50 % egg infective dose; FAM, 6-carboxyfluorescein; HA, haemagglutinin; HPAIV, highly pathogenic avian influenza virus; RRT-PCR, real-time RT-PCR; TAMRA, 6-carboxytetramethylrhodamine; WHO, World Health Organization.

${dagger}$ These authors contributed equally to this paper.

INTRODUCTION

TOP
INTRODUCTION
METHODS
RESULTS AND DISCUSSION
REFERENCES

The highly pathogenic avian influenza virus (HPAIV) H5N1 wasfirst isolated from humans during the 1997 outbreak in HongKong. Eighteen patients were confirmed to have been infectedwith H5N1 after close contact with poultry and six patientsdied (CDC, 1997). The recent recurrence of influenza A H5N1,which was first reported in Southeast Asia in mid-December 2003,is severe and has involved increasing numbers of countries.It had infected 218 people and caused 124 deaths in ten countriesby May 2006 (WHO, 2006). HPAIV has not only posed a continuingglobal human public health risk, but also endangered the poultryindustry (CDC, 2004; FAO, 2005; Tran et al., 2004; Viseshakul et al., 2004).The recurrence of influenza A H5N1 has highlighted the needfor a highly sensitive, accurate and rapid diagnostic test forthe infection. Such a test is important, not only for infectioncontrol, but also to facilitate early antiviral therapy. However,cell culture and subsequent haemagglutinin (HA) and neuraminidasesubtyping by serological testing require 1–2 weeks forresults; thus they are less useful in making therapeutic andinfection-control decisions. On the other hand, commerciallyavailable rapid antigen tests for influenza A are rapid andsimple, but subtyping (H1 and H5) of viruses shows cross-reactivity(WHO, 2005). Molecular diagnosis of influenza A H5 by real-timeRT-PCR (RRT-PCR) can be a rapid assay: results, including subtyping,may be available in less than 1 day.

Standard RT-PCR has been applied previously to the detectionof AIV and each of the 15 HA subtypes (Lee et al., 2001; Munch et al., 2001;Starick et al., 2000). The World Health Organization (WHO) hasalso recommended a pair of primers for H5 subtype detectionas a laboratory test (WHO, 2005). RRT-PCR with hydrolysis probeshas been applied successfully to the detection of various RNAviruses (Chen et al., 2004; Holland et al., 1991; Livak et al., 1995).RRT-PCR offers the advantages of speed, viral load analysis,sensitivity and specificity compared with standard RT-PCR. Inthis study, we developed a rapid, highly sensitive and specificreal-time, fluorescent, quantitative RT-PCR for direct detectionof influenza A H5.

METHODS

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INTRODUCTION
METHODS
RESULTS AND DISCUSSION
REFERENCES

Samples. Throat swab samples were collected from 35 birds presentingwith abnormal neurological signs and diarrhoea in Qinghai Lake,China, during the HPAIV (H5N1) outbreak in 2005 (Liu et al., 2005).Throat swab samples were also collected from 60 patients whowere confirmed to be infected with influenza A H1 by RT-PCRassay (Wright et al., 1995) at Beijing 301 Hospital, China.The swabs were kept at 4 °C and transported to the laboratorywithin 48 h in PBS at 4 °C supplemented with 200 mg streptomycinml^–1, 100 U penicillin ml^–1 and 10 µg amphotericinB ml^–1. On receipt of the specimen, prior to any manipulationof the specimen, some aliquots were removed in a type II biologicalsafety cabinet for molecular analysis and virus isolation.

Viruses. Sixty isolates of AIV/H5N1 that originated from different speciesfrom 1997 to 2005 were provided by the HPAIV study team. Thegenomes of these isolates were sequenced and they divided intodifferent clades (Table 1 and unpublished data). The other14 viruses were kindly provided by China Agriculture University,the Academy of Military Medicine Science and the National Institutefor the Control of Pharmaceutical and Biological Products: influenzavirus A/PR/8/34 (H1N1); influenza virus A/Beijing/30/95 (H3N2);influenza virus A/duck/Taiwan/4201/99 (H7N7); influenza virusA/Swine/Shandong/nb/2003 (H9N2); influenza virus B (Hongkong/5/72);parainfluenza viruses 1, 2 and 3; severe acute respiratory syndrome-associatedcoronavirus (TJF); respiratory syncytial virus; human immunodeficiencyvirus 1; cytomegalovirus; Epstein–Barr virus; and adenovirustype 2. The titres of all influenza viruses were determinedby 50 % egg infective dose (EID₅₀), whilst the titres of theother viruses were determined by quantitative PCR (Chen et al., 2004;Kubar et al., 2005; Kuypers et al., 2006; Palmer et al., 2003;Perkins et al., 2005); they were determined to be approximately10⁴ EID₅₀ ml^–1 or 10⁶ copies ml^–1, respectively.

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Table 1. Species of origin and clades of 60 H5N1 isolates

Primers and probe. In view of the divergence of the H5 gene, we aligned all H5gene sequences in the NCBI GenBank database (n=252) and ourunpublished H5N1 genome sequences (n=60) and chose a conservativeregion from which to design the primers and probe using PRIMEREXPRESS software v2.0 (Table 2

). Another H5 subtype primerset was synthesized according to data published by WHO (WHO, 2005).The probe was labelled at the 5' end with 6-carboxyfluorescein(FAM) reporter dye and at the 3' end with 6-carboxytetramethylrhodamine(TAMRA) quencher dye. All primers and the probe were synthesizedby Shanghai Sangon Company.

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Table 2. PCR primers and probe used for AIV H5 subtype detection

Transcription of AIV H5 RNA in vitro. We designed a pair of universal primers to amplify the completeHA gene (forward: 5'-TATTGGTCTCAGGGAGCGAAAGCAGGGG-3'; reverse:5'-ATATGGTCTCGTATTAGTAGAAACAAGGGTGTTTT-3'). The influenza Avirus [A/Swine/Anhui/cb/2004 (H5N1)] H5 gene was amplified byRT-PCR and the product was cloned into the pGEM-T Easy vector(Promega). The recombinant plasmid was linearized with PstI,purified with a PCR purification kit (Shanghai Biotech) andtranscribed with T7 RNA polymerase using a RiboMax Express large-scaleRNA production system (Promega). The template DNA was degradedwith 5 U RNase-free DNase I and the RNA transcripts were purifiedtwice with an RNeasy kit (Qiagen). The RNA was quantified spectrophotometricallyat 260 nm, divided into aliquots and stored at –80 °C.Diluted AIV H5 transcripts (4x10⁸–4x10^–2 copiesµl^–1 at tenfold dilutions; 4x10¹–7.8x10^–2copies µl^–1 at twofold dilutions) were used forthe determination of detection limits and the amplificationefficiency of the assay.

Standard influenza virus A/H5N1 panel. The standard avian influenza A virus/H5N1 panel was suppliedby the Influenza virus A/H5N1 Quality Assurance Laboratory,National Institute for the Control of Pharmaceutical and BiologicalProducts. It contained eight volumes of different isolates ofinfluenza virus A/H5N1: Hong Kong/213/03 (clade 1), black-headedGoose/QH/1/05 (clade 2), Anhui/1/2005 (clade 2) and Hong Kong/156/97(clade 3) (two volumes of each). The concentration of each volumewas approximately 10⁴ EID₅₀ ml^–1.

RNA extraction. Total RNA was extracted using a QIAamp RNA extraction kit (Qiagen)according to the manufacturer’s instructions. Briefly,140 µl of each sample was used for the extraction of viralgenomic RNA. The RNA was eluted from the columns with 50 µlDEPC-treated water and used in the following experiments immediatelyor stored at –80 °C. All of the above methods wereperformed in a Biosafety level 3 facility.

DNA extraction. DNA was extracted using a QIAamp DNA mini kit (Qiagen) accordingto the manufacturer’s instructions. Briefly, 100 µlof each virus culture was used for the extraction of viral genomicDNA. The DNA was eluted from the columns with 50 µl double-distilledwater. DNA was used in the following experiments immediatelyor stored at –80 °C.

Conventional RT-PCR. The Qiagen one-step RT-PCR kit was used for RT-PCR with a 30µl reaction mixture containing 10 µl RNA, 6 µl5x buffer, 1.2 µl dNTP mix (25 mM), 1.2 µl enzymemix (25x), 0.3 µl RNase inhibitor (20 U µl^–1),0.6 µM WHO forward primer and 0.6 µM WHO reverseprimer. The reverse transcriptase step was carried out at 50°C for 30 min and 95 °C for 15 min, followed by 40 cyclesof amplification (94 °C for 30 s; 55 °C for 30 s; 72°C for 30 s). Amplified products were detected by agarosegel electrophoresis and sequence identification. Sequencingwas carried out using an ABI PRISM 3730 DNA sequencer.

RRT-PCR. RRT-PCR was carried out in a 30 µl mixture containing10 µl RNA, 15 µl 2x Taqman one-step RT-PCR mastermix (ABI), 0.75 µl 40x MultiScribe and RNase inhibitormixture, 0.25 µM forward primer, 0.25 µM reverseprimer and 0.125 µM probe in a fluorometric PCR thermocycler(ABI 7300). The reaction was carried out for 30 min at 48 °C,followed by 10 min at 95 °C, with a subsequent 40 cyclesof amplification (95 °C for 15 s; 60 °C for 1 min; fluorescencewas recorded at 60 °C).

Antigen-capture ELISA. All samples were also tested by antigen-capture ELISA employingbiotin-labelled monoclonal antibodies (Wang et al., 2004). Themonoclonal antibodies (H5) were a gift from Professor Qin, Instituteof Microbiology and Epidemiology, Academy of Military MedicalScience. Briefly, 96-well plates (Shenzhen Jinchanhua International)were coated overnight at 4 °C with purified monoclonal antibodies(3B2B9C5, 3B5C11A10) to AIV H5 diluted 1000-fold in 50 mM NaHCO₃buffer (pH 9.6). Each well was rinsed and blocked with PBS containing0.05 % Tween 20 and 3 % BSA. Samples were centrifuged (3000r.p.m., 5 min) and the supernatant was tested. After incubationat 37 °C for 1 h, the plates were washed five times withPBS/0.5 % Tween 20. The other monoclonal antibody (3D1D11B2,diluted 1 : 3000) labelled with biotin was added to the plates.The plates were incubated at 37 °C for 30 min and washedfive times with PBS/0.5 % Tween 20. Diluted HRP–streptavidin(diluted 1 : 1000 in PBS supplemented with 0.5 % Tween 20 and1.5 % BSA) was added to each well, followed by incubation at37 °C for 30 min. The plates were washed five times withPBS/0.5 % Tween 20 before the addition of tetramethylbenzidinesubstrate. The reaction was stopped by the addition of 2 M H₂SO₄.The A_450/630 value was measured in triplicate. A blank control,a negative control and a positive control were included on eachplate. All reagents were used in a standard volume of 100 µl.

Virus isolation. Samples were diluted in PBS containing 2 mg streptomycin ml^–1,1000 IU penicillin ml^–1 and 20 µg amphotericin Bml^–1. Nine-day-old embryonated chicken eggs were inoculatedwith 100 µl sample by the chorioallantoic sac route. Fiveeggs were inoculated per dilution. At 4 days post-inoculation,chorioallantoic fluid was collected and tested by RT-PCR combinedwith sequencing and by RRT-PCR. RNA extraction was carried outusing a QIAamp RNA extraction kit (Qiagen) as described previously.Virus isolation was undertaken in a Biosafety level 3 facility.

RESULTS AND DISCUSSION

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INTRODUCTION
METHODS
RESULTS AND DISCUSSION
REFERENCES

Sensitivity and specificity of the RRT-PCR assay

Serial dilutions of in vitro-transcribed AIV H5 gene RNA weretested. A wide linear range (from 40 copies per reaction to4x10⁸ copies per reaction of target RNA, R²=0.997) was detected(Fig. 1). To determine the minimum copy number of H5 geneRNA that could be detected, each low-concentration dilutionwas repeated 48 times. Approximately six copies of in vitro-transcribedRNA per reaction could be detected reproducibly (95 % confidencelower limits P=94.5 %), and sometimes even as few as three copiesof target RNA tested positive in our assay (Table 3). Inview of the divergence of the H5 gene, a standard panel containingdifferent clades of influenza virus A/H5N1 was tested. All isolatestested positive. For further evaluation of the sensitivity ofthe system, 60 H5N1 isolates originating from different specieswere tested and all tested positive.

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Fig. 1. Sensitivity and dynamic range of RRT-PCR in detection of AIV H5 RNA. Serial dilutions of in vitro-transcribed AIV H5 gene RNA were tested. A wide linear range (from 40 copies to 4x10⁸ copies of the control RNA per reaction) was determined in this assay. The intercept of the magnitude of the fluorescence signal (PCR baseline minus curve fit relative fluorescence units) with the horizontal threshold line represents the Ct value for a given sample.

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Table 3. Detection of different concentrations of in vitro-transcribed AIV H5 gene RNA tested by RRT-PCR

To determine the specificity, throat swabs from 60 patientspreviously shown to have H1N1 infection were tested and allsamples tested negative. To test cross-reactivity with otherviruses, nuclear acids (RNA or DNA) extracted from clinicalisolates of 14 other viruses (listed in Methods) were evaluated.None of these viruses reacted positively in our assay.

Comparison of RRT-PCR with conventional RT-PCR

The WHO primers are a reliable identification method and areused for H5 gene detection in many countries as a laboratorytest. To compare the sensitivity of RRT-PCR with that of conventionalRT-PCR using the WHO primers, throat swabs from 35 birds takenduring an HPAIV (H5N1) outbreak and serial dilutions of AIVH5N1 cultures were tested. Thirty-three samples tested positivein our assay, but only 27 samples tested positive by conventionalRT-PCR (Table 4). Six of the amplified products that testedpositive only in the RRT-PCR were cloned into the pGEM-T Easyvector and sequence identification showed that they were truepositive results. The detection limits determined for each testmay explain the discordance among the tests, as conventionalRT-PCR could only detect 3 EID₅₀ whilst our assay detected downto approximately 5x10^–2 EID₅₀ (Ct value=37.5).

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Table 4. Comparison of RRT-PCR results with conventional RT-PCR, antigen-capture ELISA and virus isolation results for H5 subtype influenza virus

Comparison of RRT-PCR with antigen-capture ELISA

To compare the sensitivity of RRT-PCR with that of antigen-captureELISA, the same 35 avian samples and serial dilutions of AIVH5N1 cultures were analysed. Two samples were negative by bothassays and 13 samples were positive by both assays; i.e. 42.9% of the samples were in agreement (Table 4

). The 20 samplesfor which the results differed were positive by RRT-PCR butnegative by ELISA; thus ELISA detected 39.4 % of the samplesthat were positive by RRT-PCR. In tests of serial dilutionsof AIV H5N1 cultures, the minimum dilution of AIV H5N1 cultureswas approximately 10 EID₅₀ for antigen-capture ELISA, showingthat it has lower sensitivity than RRT-PCR. This coincides withpreviously reported data (Ng et al., 2005).

Comparison of RRT-PCR with virus isolation

The sensitivity of the RRT-PCR assay was compared with thatof virus isolation in embryonating eggs from clinical swab samples.One sample was negative by both assays and 18 were positiveby both assays (Table 4). The serum sample from the birdwhose throat swab was negative in both assays was positive byan HA inhibition assay. Overall, the results of the two assaysagreed for 19 samples (54.3 %) and disagreed for 16 samples(45.7 %). Of the 16 samples for which results differed, onesample was positive by virus isolation and negative by RRT-PCR,and 15 samples were positive by RRT-PCR but negative by virusisolation. Thus virus isolation detected 54.5 % of the samplesthat were positive by RRT-PCR, but 45.5 % (15/33) of the samplesthat were positive by RRT-PCR were negative by virus isolation.This can partly be explained by the fact that virus isolationdetects only live virus; thus virus that may have been inactivatedduring long-term shipping or storage from Qinghai to Beijingwould not be detected, whereas it potentially can be detectedby RRT-PCR. On the other hand, one of the 35 samples (2.9 %)that was negative by RRT-PCR was positive by virus isolation.The cultured material was tested further by RRT-PCR and testedpositive. Factors that may adversely affect the sensitivityof the RRT-PCR assay include RT-PCR inhibitory substances inthe samples, inefficient RNA extraction procedures and rapiddegradation of RNA before testing.

Conclusions

We have developed a sensitive and specific RRT-PCR assay forthe detection of influenza virus A H5 subtype. Compared withconventional RT-PCR, antigen-capture ELISA and virus isolation,RRT-PCR is a more sensitive and convenient method.

ACKNOWLEDGEMENTS

We thank the HPAI pathogens study team for virus culture andtitre determination in this work. This study was supported bygrants from the National High Technology Research and DevelopmentProgram of China (863 Program) from the Ministry of Scienceand Technology, People’s Republic of China.

REFERENCES

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METHODS
RESULTS AND DISCUSSION
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