Development of Enhanced Primer Sets for Detection of Norovirus

Norovirus (NV) is a major viral pathogen that causes nonbacterial acute gastroenteritis and outbreaks of food-borne disease. The genotype of NV most frequently responsible for NV outbreaks is GII.4, which accounts for 60–80% of cases. Moreover, original and new NV variant types have been continuously emerging, and their emergence is related to the recent global increase in NV infection. In this study, we developed advanced primer sets (NKI-F/R/F2, NKII-F/R/R2) for the detection of NV, including the variant types. The new primer sets were compared with conventional primer sets (GI-F1/R1/F2, SRI-1/2/3, GII-F1/R1/F2, and SRII-1/2/3) to evaluate their efficiency when using clinical and environmental samples. Using reverse transcription polymerase chain reaction (RT-PCR) and seminested PCR, NV GI and GII were detected in 91.7% (NKI-F/R/F2), 89.3% (NKII-F/R/R2), 54.2% (GI-F1/R1/F2), 52.5% (GII-F1/R1/F2), 25.0% (SRI-1/2/3), and 32.2% (SRII-1/2/3) of clinical and environmental specimens. Therefore, our primer sets perform better than conventional primer sets in the detection of emerged types of NV and could be used in the future for epidemiological diagnosis of infection with the virus.


Introduction
Norovirus (NV), belonging to family Caliciviridae, is a major cause of acute viral gastroenteritis [1]. Although symptoms, which typically appear between 12 and 48 h, are generally mild and self-limiting, they can be severe in immunocompromised groups such as infants and the elderly [2,3]. Viral infection is primarily related to foodborne illness, but person-to-person contact and waterborne outbreaks are also important vehicles for transmission [4][5][6][7].
The NV genome is composed of approximately 7.7 kb of single stranded positive sense RNA (+ssRNA), which includes three open reading frames (ORFs): ORF1, ORF2, and ORF3 [8]. Six nonstructural proteins in a polyprotein are encoded by ORF1, including an RNA-dependent RNA polymerase (RdRp) [9]. ORF2 and ORF3 encode major structural capsid protein (VP1) and minor structural capsid protein (VP2), respectively [10]. VP1 consists of a shell domain (S) and two protruding (P) domains [11]. The P1 domain, a protruding flexible hinge region, is located between the S and P2 domains [12]. The P2 domain is a hypervariable region that binds to host cell [13]. The stability of VP1 is increased by VP2, which prevents its degradation [14].
In the Republic of Korea, NV GII.4 Sydney type emerged between 2012 and 2013, during which time it accounted for 60.4% of NV GII.4 diagnoses [25]. Detection of the NV GII 2 BioMed Research International strain is difficult with existing RT-PCR primer sets (GII-F1/R1/F2, SRII-1/2/3) because of the continuous variation of the strain [26,27]. In addition, GI-F1/R1 primer set does not always have sufficient specificity to detect NV because falsepositive detection commonly occurs [28].
Therefore, the aim of this study was to develop primer sets for efficiently detecting NV GI and GII, including detection of newly emerged strains that could not previously be identified with conventional primer sets. Once new primer sets were developed, we evaluated their efficiency using an RT-PCR assay to test clinical and environmental specimens. All stool specimens were collected from patients who suffered from diarrhea caused by acute gastroenteritis. Environmental specimens were collected from groundwater in the Republic of Korea during June and October 2013. All samples were stored at −80 ∘ C until use.

Ethical Clearance.
All clinical samples were obtained during the medical treatment of patients with acute gastroenteritis. All patients provided written informed consent, which has been kept on file at the GIHE and WAVA. Human rights were not abused nor were ethical issues encountered during the study. All experimental work and collection of samples were supervised and approved by the Institutional Review Board (IRB) of Songeui Medical Campus, The Catholic University of Korea (approval number MC14SISI0039).

Primer Design.
In order to design new primer sets, 37 sequences of NV GI (Table 1) and 52 sequences of NV GII ( Table 2) were obtained from NCBI and imported into EditSeq and MegAlign in DNASTAR software (DNASTAR, USA).
We designed 3 candidates for the NV GI primer set and 5 candidates for the NV GII primer set in the conserved regions of ORF 1 and ORF 2. Among them, NKI and NKII (Table 3) which have outstanding efficiency were selected. Inner primers were designed to detect NV from water samples because NV generally presents with a low titer in water [29]. They were constructed based on conserved sites from primer sets NKI-F and NKII-R. We named the inner primers NKI-F2 and NKII-R2 and used them for nested PCR.

Viral RNA Extraction.
Viral RNA was extracted from clinical and environmental specimens with the QIAamp viral RNA extraction kit (Qiagen, Germany) according to the manufacturer's instructions. Each viral RNA sample was eluted with 60 L of elution buffer and stored at −80 ∘ C until use in the RT-PCR assay.
2.6. Sequence Analysis of PCR Products. The products of RT-PCR and seminested PCR were analyzed using 2% agarose gel electrophoresis in TAE buffer with DNA SafeStain solution (Lamda Biotech, USA) and were purified in agarose gel with a HiYield Gel/PCR DNA Fragments Extraction Kit (RBC,      Taiwan). For sequencing, PCR products were sent to Cosmo Genetech (Republic of Korea), and returned sequences were analyzed using the basic local alignment search tool (BLAST) in NCBI.

Nucleotide Sequence Registration.
The NV GI and NV GII sequences that were submitted to GenBank in NCBI (http://www.ncbi.nlm.nih.gov/) were isolated from stool and groundwater samples.

Selection of Primer Sets.
Collected NV sequences (37 from NV GI, 52 from NV GII) were aligned using EditSeq and MegAlign in DNASTAR software. Results showed that conserved sequences were selected in ORF1 and ORF2. From the 3 and 5 respective candidate NV GI and NV GII primer sets that were evaluated for efficiency using clinical samples, the most efficient primer sets were selected and used in this study (Table 3).

Discussion
In the USA, estimated 570-800 people die annually from outcomes associated with NV. Outbreaks of the virus occur regularly, and new variant strains are identified worldwide every 2 to 3 years [3,21,31,32]. Methods for detection of NV include RT-PCR, the enzyme-linked immunosorbent assay (ELISA), and transmission electron microscopy (TEM) [33,34]. In previous studies, virus concentrations up to 10 2 virus-copies/mL were detected using RT-PCR compared to 10 5 virus-copies/mL with other methods [33]. The widespread use of RT-PCR for NV detection can be attributed to its superior sensitivity compared to other methods [35,36]. For example, it is the recommended method for detection of NV in contaminated water, in which NV commonly exists at 4.91× 10 2 -3.51 ×10 3 copies/mL [29]. However, in order to minimize outbreaks and prevent potential deaths, improved 7 primer sets are required to accurately detect original and variant strains of NV. It is possible that the primer sets used for detection of NV are different in each laboratory because a standard method for detection has not yet been established [37]. In previously published work, the primer sets GI-F1/R1/F2 and GII-F1/R1/F2, SRI-1/2/3 and SRII-1/2/3 have typically been used to detect NV [38,39] [40]. They found that 117 sites were contaminated with NV GI and GII, and the study indicated that NV could more efficiently be detected with GI-F1/R1/F2 (35 samples) and GII-F1/R1/F2 (55 samples) compared to SRI-1/2/3 (27 samples) and SRII-1/2/3 (41 samples) [40]. Similarly, in the present study, the performance of SRI-1/2/3 and SRII-1/2/3 in detection of NV was inferior to other primer sets. In particular, SRI-1/2/3 and SRII-1/2/3 entirely failed to detect NV in water. Conversely, the majority of positive NV samples were detected using NKI-F/R/F2 (91.7%) and NKII-F/R/R2 (89.3%). We postulate that because the sequences of NKI-F/R/F2 and NKII-F/R/R2 were collected from 1968 to 2013, their design contained more conserved sequences in comparison to the GI-F1/R1/F2, GII-F1/R1/F2, SRI, and SRII primer sets and this could explain their superior performance. NV GII.4 is known to be the most prevalent strain of NV [41], and since 2012 a new variant of NV GII.4 has caused many cases of gastroenteritis [42]. In detecting NV GII.4, an RT-PCR assay using a GII-F1/R1/F2 primer set or another forward primer (Cog2F, F2 FB, GV21) with a GII-F1/R1/F2 reverse primer has typically been used [25,[42][43][44]. However, these primer sets were designed before 2005 and are not suitable for detection of new NV mutant types that have continuously emerged since, such as the 2012 Sydney strain. Their unsuitability is probably explained by differences in sequence between the primers and the new variant types [45,46].

Conclusions
In our study, we showed that the NKI-F/R/F2 and NKII-F/R/R2 primer sets could be important for epidemiological diagnosis of NV in the laboratory because of their superior performance compared to other primer sets. Where contamination with NV was suspected, these primer sets could be applied to specimens taken from water sample with a low titer or clinical samples with a high titer. Additionally, our newly developed primer sets can be used to detect variant types of NV. Therefore, we recommend the use of NKI-F/R/F2 and NKII-F/R/R2 in future research.