Abstract
Human metapneumovirus (HMPV) is a newly identified pathogen causing acute respiratory tract infections in young infants worldwide. Since the initial document of HMPV infection in China in 2003, Chinese scientists have made lots of efforts to prevent and control this disease, including develo** diagnosis methods, vaccines and antiviral agents against HMPV, as well as conducting epidemiological investigations. However, effective vaccines or special antiviral agents against HMPV are currently not approved, thus develo** early diagnosis methods and knowing its epidemiological characteristics will be beneficial for HMPV control. Here, we summarized current research focused on the epidemiological characteristics of HMPV in China and its available detection methods, which will be beneficial to increase the public awareness and disease control in the future.
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Introduction
Acute respiratory tract infections (ARTIs) are responsible for the high morbidity and mortality of human beings, which have been considered one of the most significant factors threatening public health worldwide [1]. Moreover, ARTIs often result in lower respiratory tract infections (LRTIs) in clinical, which are responsible for millions of deaths worldwide [2]. Numerous viruses, such as the coronavirus, influenza virus, and human respiratory syncytial virus (hRSV), and others, are responsible for the incidence of ARTIs. In 2001, a research team in the Netherlands first discovered a novel virus associated with ARTIs, which was named human metapneumovirus (HMPV) [3]. Subsequently, the prevalence of HMPV has been documented in many countries and is considered a leading cause of ARTIs worldwide owing to the limited prevention and control measures [4, 5]. The clinical symptoms of HMPV infection in infants, elderly individuals, and immunocompromised individuals are mainly characterized by fever, cough, and gasp for breath, etc.,[6], which are similar to those of other common ARTIs-related viruses’ infection, including human bocavirus and hRSV [7].
HMPV is an enveloped, non-segmented, negative-stranded virus that belongs to the subfamily Pneumovirinae [8]. The HMPV genome (nearly 13 kb) contains eight genes that encode nine proteins, namely nucleoprotein (N), phosphoprotein (P), matrix protein (M), fusion protein (F), matrix-2 proteins (M2-1 and M2-2), small hydrophobic (SH) protein, glycoprotein (G), and large (L) polymerase protein [9]. According to the genetic features of the F and G genes, HMPV strains prevalent worldwide could be classified into four genotypes (A1, A2, B1 and B2), and further divided into six lineages (A1, A2a, A2b, A2c, B1, and B2) [10, 11]. Notably, co-prevalence of several sub-genotypes or sub-lineages of HMPV has been frequently reported in the areas under investigation, while the thorough relationship between the disease severity and HMPV genotype is yet unclear [12, 13].
HMPV has been widely prevalent worldwide and continuously brings a significant medical burden to the local area, as effective vaccine or antiviral drug for treating or preventing HMPV infection is not licensed [14]. For instance, HMPV infection is associated with nearly one million outpatient clinic visits with clinical symptoms of ARTIs, and the disease caused by HMPV infection poses huge threats to the health of more than 86% of children aged below 5 years worldwide [15, 16]. Thus, a comprehensive understanding of the epidemiological characteristics, and detection approaches targeting HMPV would be beneficial for preventing this disease. This review provides updated information on HMPV in China, mainly focusing on its diagnosis approaches, prevalence, and genotype characteristics.
Current molecular diagnosis methods for HMPV detection
Early diagnosis of HMPV infection will help to develop effective measures against the disease, such as limiting the outbreak and providing timely care for the patients. Since the highly conserved F protein amino acid sequences of HMPV and RSV [17], limited serological technologies were developed for detecting HMPV-specific antibodies [18,19,20,21]. Thus a variety of molecular diagnosis methods, probing viral nucleic acids, have been invented for HMPV molecular detection, which mainly include the reverse transcription polymerase chain reaction (RT-PCR), real-time quantitative reverse transcription polymerase chain reaction (RT-qPCR), and reverse transcription loop-mediated isothermal amplification (RT-LAMP), etc., (as summarized in Table 1).
Molecular detection methods developed based on PCR
RT-PCR
In the past decades, RT-PCR assays have been widely applied for viral molecular detection, including HMPV. Generally, the genomic regions with high sequence homology of HMPV, such as the F and N genes, are employed as molecular markers for develo** the RT-PCR methods, and these targeted regions can be used for genotype analysis [49]. Usually, the human Chang conjunctiva cell line (clone 1-5C4), LLC-MK2 cell line, and feline kidney CRFK cell line are suitable for HMPV isolation, and the LLC-MK2 cell line was more frequently used in HMPV isolation and cultivation [50, 51].
The procedures of virus isolation mainly include two steps: 1) the supernatants of the HMPV-positive sample are incubated with cell monolayer; 2) after 48–96 h of post-infection, the HMPV antigens or nucleic acids could be detected via serological or molecular detection methods. As HMPV grows slowly in cell lines, and cytopathic effects are rarely observed in HMPV-cell lines, subsequent serological/molecular assays are frequently used to detect HMPV antigens/nucleic acids [51].
Current epidemiology of HMPV in China
Since the first document of HMPV outbreaks in China in 2003 [52], the potential threats to public health have attracted widespread attention, thus epidemiological investigations have been frequently performed to monitor the prevalence of HMPV in China. To offer comprehensive and updated information on these, a total of 56 representative studies focusing on HMPV epidemiology across different regions in China were collected from the Chinese database and English database, the research was reported from January 1, 2003, to December 31, 2023 (Fig. 1). the detailed information of these research were shown in Supplementary Table 1.
Current epidemiology of HMPV in China. results of 56 representative studies investigating the epidemiological characteristics of HMPV in human populations across distinct regions covering 18 provinces or regions. These studies were collected from the English and Chinese databases from January 1, 2003, to December 31, 2023. Data of these provinces or regions marked with white were not available
Risk factors associated with HMPV epidemiology in China
A total of 188,104 clinical samples and 8846 HMPV-positive cases are included in this review, which yields the average positive rate of 4.70% (95% CI 4.61–4.80). In detail, the prevalence of HMPV among patients with acute respiratory illness from different provinces/regions ranged from 0.97% (95% CI 0.74–1.20) to 15.88% (95% CI 14.41–17.35). The highest prevalence of HMPV was observed in Chongqing city (15.88%, 95% CI 14.41–17.35), Henan (7.05%, 95% CI 5.48–8.62), Tian** (6.45%, 95% CI 3.72–9.18), and Jiangsu (6.26%, 95% CI 6.02–6.50), while Shanghai, Jiangxi, Hainan, and Bei**g showed the lowest prevalence, with < 3.0%.
Next, the potential risk factors in subgroups associated with HMPV infection, including gender, age, season, case type, and others, were estimated in this study. As shown in Table 2, in the age subgroups, the detection rate of HMPV infection among patients aged > 60 months (1.47%, 95% CI 1.30–1.64) was significantly lower than other age subgroups, while the prevalence of HMPV infection among in other age subgroups (< 6 months, 6–12 months, 12–36 months, and 36–60 months) showed no significant difference. Among different seasons, the highest positive rate of HMPV infection among patients was detected in spring (12.13%), followed by winter (3.56%), while the prevalence of which in summer (1.28%) and autumn (1.32%) showed no significant difference.
The epidemiological results of 17 studies showed that there is no significant relationship between gender and HMPV infection, the average positive rate of HMPV infection among male and female was 3.48% (95% CI 3.33–3.62) and 5.11% (95% CI 4.88–5.34). Moreover, the positive rate of HMPV-infected inpatients (3.56%, 95% CI 3.24–3.88) was not significantly different between the outpatients (3.22%, 95% CI 2.72–3.72).
The genetic features of HMPV in China
According to the genetic characteristics of HMPV, which could be divided into six lineages (A1, A2a, A2b, A2c, B1, and B2) [103, 104]. Though the relationships between pathogenicity and different HMPV lineages have been not fully explored, it is necessary to monitor the geographical distribution of different HMPV lineages in China. In this review, a total of 1253 HMPV gene sequences (G, F, M, or complete genome) were summarized in 19 articles to explore the genetic features of HMPV strains prevalent in China. As shown in Table 3, 8, 35, 544, 85, 299, and 282 HMPV strains belonged to the A1, A2, A2b, A2C, B1, and B2 lineages, which accounted for 0.64%, 2.79%, 43.42%, 6.78%, 23.86%, and 22.51%, respectively. The summarized results indicated that the A2b, B1, and B2 strains are the predominant lineages prevalent in China, while HMPV lineages prevalent in different provinces/regions in China are diverse. For example, the A2C was the predominant lineage prevalent in Henan province, while B1 and B2, but not A2b or A2C, predominated in Zhejiang province (Table 3).
Conclusion and further directions
HMPV is still one of the major infectious viruses that cause ARTIs today, and it has been continuously posing huge economic burdens on the World Public Health Organization. Despite numerous efforts focused to develop diagnostic technologies for HMPV detection, epidemiological surveys, vaccines and other antiviral agents against this pathogen, there are currently no effective vaccines or medications against HMPV infection [15]. In light of this, rapid identification of positive cases and comprehensive investigation of HMPV epidemiological features are essential to prevent HMPV outbreaks and lessen their harmful effects.
There are currently many nucleic acid-based technologies for molecular HMPV detection available, which significantly lessen the challenge of HMPV diagnosis in various diagnostic contexts [22,23,24, 26,27,28, 34, 35, 38, 45, 48]. Among these, RT-PCR has been extensively used for pathogen detection, while this method is not appropriate for early HMPV diagnosis because of its low sensitivity [22,23,24]. The RT-qPCR method has a higher sensitivity than the traditional RT-PCR, and requires less operation time and fewer equipment, thus RT-qPCR has been widely used for the timely molecular detection of HMPV [26]. Additionally, a number of multiple RT-qPCR techniques have been developed and are used to simultaneously detect different pathogens including HMPV, in light of the relatively low prevalence of HMPV compared to other ARTIs-related viruses and the frequent occurrence of co-infection[27, 28]. Compared with the single RT-qPCR, multiple RT-qPCR methods are less costly and less time-consuming [27, 28].
Moreover, visual detection methods such as LAMP [34], RAA [38], and CRISPR/Cas12a combined with RPA [45], have also been developed for HMPV detection. These detection methods exhibit high sensitivity and do not require complex or expensive equipment, making them alternative approaches for HMPV detection in certain special occasions, such as field inspections at home or customs centers. Furthermore, mNGS is an emerging molecular detection technology that can directly identify a large number of pathogenic microorganisms in clinical samples, as well as amplify the complete genome of causative agents [105, 106]. While mNGS is time-consuming and more expensive compared to other molecular detection technologies, it may not be suitable for severely infected patients [48]. Thus, each molecular detection method has its own advantages and disadvantages. These characteristics should be fully considered in the clinical application.
In terms of the epidemiological characteristics of HMPV in China, the documents obtained from English and Chinese databases showed that HMPV has been widely prevalent in different regions of China. Although the prevalence of HMPV is relatively lower than some ARTIs-related viruses, such as HRV and RSV, the threats of it poses to public health cannot be ignored [107]. Overall, the pooled molecular prevalence of HMPV was 4.70% (95% CI 4.61–4.80), as supported by a nationwide prospective surveillance survey conducted in China, which showed a 4.1% HMPV-positive rate among 231,107 eligible patients with acute respiratory infection from 2009 to 2019 [107]. Notably, the prevalence of HMPV varied significantly by geographical region. This variation may be attributed to the differences in molecular detection methods, sampling sizes, patients ages, and other factors, all of which require further investigation.
The results of additional analysis revealed a significant association between the occurrence of HMPV infection and sampling season as well as patients age. In terms of sampling seasons, patients with ARTIs in spring had nearly 9 times the risk of HMPV infection compared to those in summer and autumn. As for age, the prevalence of HMPV among patients with ARTIs was significantly higher in young children (< 60 months) compared to older patients (> 60 months). Young children are at a high risk of HMPV infection in spring, while the threat of this pathogen to elderly people in other seasons should not be neglected. However, the gender and disease severity (inpatients or outpatients) had limited effects on the rates of HMPV infection among patients in China.
Due to the significant genetic variation of HMPV strains, they can be divided into multiple genotypes (A1, A2, B1, B2) and lineages (A1, A2a, A2b, A2c, B1, B2) [10, 11]. It is important to note that the genotypes or lineages of HMPV may vary from one region to another [5, 108]. Our summarized data show that at least five HMPV lineages (A1, A2b, A2C, B1, and B2) have been prevalent in China, while the lineages and proportions of HMPV vary greatly from province to province or region to region. Overall, the A2b, B1, and B2 lineages have become the predominant strains in China, while the A1 lineage was seldom detected in the regions under investigation. However, several characteristics of different HMPV lineages have not been comprehensively uncovered, including virulence, pathogenicity, and clinical symptoms. These issues need to be addressed in the future.
It is worth noting that the epidemiological characteristics of HMPV in China were not comprehensively analyzed in this review, and several factors contributed to this. Firstly, the research scope in this review may not cover all available reports. Secondly, although 56 representative studies were included in this review to assess the prevalence of HMPV in China, essential background information such as sampling season and year, disease severity level (inpatients or outpatients), viral load of the tested sample, and other risk factors were not provided in some of the papers. Thirdly, most of the HMPV epidemiological research has been reported in Guangdong, Jiangsu, and Bei**g. The epidemiological characteristics of HMPV in other regions or provinces were relatively limited, and even in deficiency. Fourthly, this review summarized the types and proportions of different HMPV lineages in the investigated regions. However, most of the papers did not provide essential information on viral load, clinical signs, or disease severity of patients infected with different HMPV lineages. These limitations hinder a comprehensive evaluation of the epidemiological features of HMPV in China. Therefore, it is suggested that future HMPV epidemiological survey should overcome these potential drawbacks.
In summary, a variety of molecular diagnostic methods have been developed for detecting HMPV in China. RT-PCR, RT-qPCR, and multiple RT-qPCR are the most widely used approaches for clinical HMPV detection. As alternative options, other visual detection methods should be implemented in clinical testing as early as possible, with the consideration of lower cost, higher sensitivity, and higher convenience. The summarized data showed a relatively low prevalence (4.70%) of HMPV infection among patients with ARTIs in China. The prevalence was significantly associated with sampling seasons and patients' ages. Moreover, multiple HMPV lineages are prevalent in China, with high proportions of the A2b, B1, and B2 lineages. Given the persistent threat of HMPV to public health [109], it is crucial to continue monitoring the epidemiological spread and genetic evolution characteristics of this pathogen in China.
Data availability statement
The data presented in this review can be found in online repositories.
Abbreviations
- ARTIs:
-
Acute respiratory tract infections
- LRTIs:
-
Lower respiratory tract infections
- HRSV:
-
Human respiratory syncytial virus
- HMPV:
-
Human metapneumovirus
- RT-PCR:
-
Reverse transcription polymerase chain reaction
- RT-qPCR:
-
Real-time quantitative reverse transcription polymerase chain reaction
- RT-LAMP:
-
Reverse transcription loop-mediated isothermal amplification
- GeXP:
-
GenomeLab Gene Expression Profiler genetic analysis system
- HRV:
-
Human rhinovirus
- DMF:
-
Digital microfluidic
- LOD:
-
Limit of detection
- RAA:
-
Recombinase-aided amplification
- CRISPR:
-
Clustered regularly interspaced short palindromic repeat
- Cas:
-
CRISPR-associated proteins
- RPA:
-
Recombinase polymerase amplification
- LF:
-
Lateral flow
- mNGS:
-
Metagenomic next-generation sequencing
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This work was supported by the **angtan Medical Associated Project (No. 2022-xtyx-2), and the Project of Hunan Provincial Health Commission (No. D20230619358).
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Detailed information of 56 research investigating the epidemiological characteristics of HMPV in China.
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Feng, Y., He, T., Zhang, B. et al. Epidemiology and diagnosis technologies of human metapneumovirus in China: a mini review. Virol J 21, 59 (2024). https://doi.org/10.1186/s12985-024-02327-9
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DOI: https://doi.org/10.1186/s12985-024-02327-9