MYADM binds human parechovirus 1 and is essential for viral entry.

Human parechoviruses (PeV-A) are increasingly being recognized as a cause of infection in neonates and young infants, leading to a spectrum of clinical manifestations ranging from mild gastrointestinal and respiratory illnesses to severe sepsis and meningitis. However, the host factors required for parechovirus entry and infection remain poorly characterized. Here, using genome-wide CRISPR/Cas9 loss-of-function screens, we identify myeloid-associated differentiation marker (MYADM) as a host factor essential for the entry of several human parechovirus genotypes including PeV-A1, PeV-A2 and PeV-A3. Genetic knockout of MYADM confers resistance to PeV-A infection in cell lines and in human gastrointestinal epithelial organoids. Using immunoprecipitation, we show that MYADM binds to PeV-A1 particles via its fourth extracellular loop, and we identify critical amino acid residues within the loop that mediate binding and infection. The demonstrated interaction between MYADM and PeV-A1, and its importance specifically for viral entry, suggest that MYADM is a virus receptor. Knockout of MYADM does not reduce PeV-A1 attachment to cells pointing to a role at the post-attachment stage. Our study suggests that MYADM is a multi-genotype receptor for human parechoviruses with potential as an antiviral target to combat disease associated with emerging parechoviruses.

Parechovirus infection in human brain organoids: host innate inflammatory response and not neuro-infectivity correlates to neurologic disease.

Picornaviruses are a leading cause of central nervous system (CNS) infections. While genotypes such as parechovirus A3 (PeV-A3) and echovirus 11 (E11) can elicit severe neurological disease, the highly prevalent PeV-A1 is not associated with CNS disease. Here, we expand our current understanding of these differences in PeV-A CNS disease using human brain organoids and clinical isolates of the two PeV-A genotypes. Our data indicate that PeV-A1 and A3 specific differences in neurological disease are not due to infectivity of CNS cells as both viruses productively infect brain organoids with a similar cell tropism. Proteomic analysis shows that PeV-A infection significantly alters the host cell metabolism. The inflammatory response following PeV-A3 (and E11 infection) is significantly more potent than that upon PeV-A1 infection. Collectively, our findings align with clinical observations and suggest a role for neuroinflammation, rather than viral replication, in PeV-A3 (and E11) infection.

The evolutionary phylodynamics of human parechovirus A type 3 reveal multiple recombination events in South Korea.

Human parechovirus A (HPeV-A) is a causative agent of respiratory and gastrointestinal illnesses, acute flaccid paralysis encephalitis, meningitis, and neonatal sepsis. To clarify the characteristics of HPeV-A infection in children, 391 fecal specimens were collected from January 2014 to October 2015 from patients with acute gastroenteritis in Seoul, South Korea. Of these, 221/391 (56.5%) HPeV-A positive samples were found in children less than 2 years old. Three HPeV-A genotypes HPeV-A1 (117/221; 52.94%), HPeV-A3 (100/221; 45.25%), and HPeV-A6 (4/221; 1.81%) were detected, among which HPeV-A3 was predominant with the highest recorded value of 58.6% in 2015. Moreover, recombination events in the Korean HPeV-A3 strains were detected. Phylogenetic analysis revealed that the capsid-encoding regions and noncapsid gene 2A of the four Korean HPeV-A3 strains are closely related to the HPeV-A3 strains isolated in Canada in 2007 (Can82853-01), Japan in 2008 (A308/99), and Taiwan in 2011 (TW-03067-2011) while noncapsid genes P2 (2B-2C) and P3 (3A-3D) are closely related to those of HPeV-A1 strains BNI-788St (Germany in 2008) and TW-71594-2010 (Taiwan in 2010). This first report on the whole-genome analysis of HPeV-A3 in Korea provides insight into the evolving status and pathogenesis of HPeVs in children.

Parechovirus A Circulation and Testing Capacities in Europe, 2015-2021.

Parechovirus infections usually affect neonates and young children; manifestations vary from asymptomatic to life-threatening. We describe laboratory capacity in Europe for assessing parechovirus circulation, seasonality, and epidemiology. We used retrospective anonymized data collected from parechovirus infection case-patients identified in Europe during January 2015-December 2021. Of 21 laboratories from 18 countries that participated in the study, 16 (76%) laboratories with parechovirus detection capacity reported 1,845 positive samples; 12/16 (75%) with typing capability successfully identified 517 samples. Parechovirus A3 was the most common type (n = 278), followed by A1 (153), A6 (50), A4 (13), A5 (22), and A14 (1). Clinical data from 1,269 participants highlighted correlation of types A3, A4, and A5 with severe disease in neonates. We observed a wide capacity in Europe to detect, type, and analyze parechovirus data. To enhance surveillance and response for PeV outbreaks, sharing typing protocols and data on parechovirus-positive cases should be encouraged.

An outbreak investigation of parechovirus-A3 in a newborn nursery.

OBJECTIVE: To investigate parechovirus-A3 (PeV-A3) transmission in a newborn nursery, after encountering 3 neonates with fever and rash. DESIGN: An observational study. SETTING: At a newborn nursery at the general hospital in Hyogo, Japan. PARTICIPANTS: Symptomatic neonates and their family members, and asymptomatic neonates born during the same period. METHODS: PCR assays for PeV-A and genotyping were used for the investigation of PeV-A3. Preserved umbilical cords were used to identify the route of transmission. RESULTS: PeV-A3 infection was confirmed in the three symptomatic neonates. The index case had fever and rash, and the 2 neonates treated later became symptomatic and had serum, cerebrospinal fluid, and stool specimens that were positive for PeV-A3 on PCR. The umbilical cord of the index case was positive for PeV-A3 on PCR. The family members of the index case, including the mother, were asymptomatic before delivery. The older sister and cousin of the PeV-A3-infected neonate had positive PCR results. The sequence analysis suggested 2 possible transmission routes: vertical and horizontal transmission in a newborn nursery and/or a family outside the hospital. The incubation period of PeV-A3 infection was estimated to be 1-3 days (maximum, 7 days). CONCLUSION: Horizontal transmission of PeV-A3 was confirmed in a newborn nursery. Vertical transmission was suggested by the detection of RNA in an umbilical cord sample from the index case. These observations indicate that PeV-A3 can be horizontally transmitted in a newborn nursery and that special caution is required to prevent healthcare-associated transmission of PeV-A3.

Detection of parechovirus A in respiratory, gastrointestinal, and neurological clinical samples of pediatric patients from Panama (2014-2015).

Parechovirus A (PeV-A, Parechovirus, Picornaviridae) are human pathogens associated with mild to severe gastrointestinal and respiratory diseases in young children. While several studies have investigated the association of PeV-A with human disease, little is known about its epidemiology or detection in Latin America. Between the years 2014 and 2015, a total of 200 samples were collected from Panamanian pediatric patients aged < 16 years old exhibiting symptoms associated with respiratory (n = 64), gastrointestinal (n = 68), or neurological (n = 68) diseases. These samples were gathered from patients who had previously received negative diagnoses for the main respiratory viruses, rotavirus, and neurological viruses like herpes virus, enterovirus, and cytomegalovirus. The presence of PeV-A was analyzed by real time RT-PCR.Eight positive PeV-A infections (4.0%, 95% CI: 1.7 to 7.7) were detected: two in respiratory samples (3.0%, 95% CI: 0.3 to 10.8), five in gastrointestinal samples (7.3%, 95% CI: 2.4 to 16.3), and one in cerebrospinal fluid (1.5%, 95% CI: 1.4 to 7.9). The study provides evidence of PeV-A circulation in Panama and the data collectively, remarked on the importance of considering PeV-A in the Panamanian pediatric diagnostic landscape, especially when conventional testing for more common viruses yields negative results.

First description and phylogenetic analysis of coxsackie virus A non-polio enteroviruses and parechoviruses A in South Sudanese children.

Enteroviruses (EV) and parechoviruses A (PeV-A) are commonly circulating viruses able to cause severe disease. Surveillance studies from sub-Saharan Africa are limited and show high but variable infection rates and a high variation in genotypes. This is the first study to describe EV and PeV-A circulation in children in South Sudan. Of the fecal samples collected, 35% and 10% were positive for EV and PeV-A, respectively. A wide range of genotypes were found, including several rarely described EV and PeV-A types. Coxsackie virus A (CVA) EV-C types, particularly CVA13, were the most dominant EV types. The CVA13 types had a high diversity with the majority belonging to four different previously described clusters. PeV-A1 and -A14 were the most common PeV-A genotypes. A lack of representative data from our and other studies from sub-Saharan Africa demonstrates the need for more systematic surveillance of non-polio EV and PeV-A types in this region.

Detection of parechovirus-A in hospitalized children with acute lower respiratory infection in Myanmar, 2017-2018.

Parechovirus-A (PeV-A) causes emerging infection in children, and clinical presentation depends on genotype. The virus has been investigated mainly in developed countries; however, data from developing countries, especially in Asia, are sparse. This study investigated whether PeV-A circulated in children in Myanmar. This retrospective study evaluated PeV-A in nasopharyngeal samples from children aged 1 month to 12 years who were hospitalized with acute lower respiratory infection at Yankin Children Hospital, Yangon, Myanmar, during the period from May 2017 to April 2019. Real-time polymerase chain reaction (PCR) was used to detect PeV-A, and PCR-positive samples were used for genotyping and phylogenetic analysis. In total, 11/570 (1.9%) of samples were positive for PeV-A; 7 were successfully genotyped by sequencing the VP3/VP1 region, as follows: PeV-A1 (n = 4), PeV-A5 (n = 1), PeV-A6 (n = 1), and PeV-A14 (n = 1). Median age was 10.0 months (interquartile range 4.0-12.0 months), and other respiratory viruses were detected in all cases. Phylogenetic analysis showed that all detected PeV-A1 strains were in clade 1 A, which was a minor clade worldwide. Four PeV-A genotypes were detected in Myanmar. The clinical impact of PeV-A in children should be evaluated in future studies.

EEG and clinical characteristics of neonatal parechovirus encephalitis.

RATIONALE: Human parechoviruses (HPeVs) are single -stranded ribonucleic (RNA) viruses belonging to the picornaviridae family with characteristics similar to enteroviruses. They either cause mild respiratory and gastrointestinal or no symptoms in older children and adults but can be a major cause of central nervous system (CNS) infection in the neonatal period and demonstrate a seasonal predilection. Starting in March 2022, we saw eight patients with polymerase chain reaction (PCR) proven HPeV encephalitis with seizures and some electroencephalographic (EEG) features raising concerns for neonatal genetic epilepsy. Although cerebrospinal fluid (CSF) and imaging findings have been previously described, there is little emphasis on seizure presentation and EEG findings of HPeV in the literature. We wish to highlight the EEG and seizure semiology of HPeV encephalitis that may mimic a genetic neonatal epilepsy syndrome. METHODS: Retrospective chart review of all neonates seen at Children's Health Dallas, UTSW Medical Center between 03/18/2022-06/01/2022 with HPeV encephalitis. RESULTS: Term neonates (postmenstrual age 37-40 weeks) presented with a variable combination of fever, lethargy, irritability, poor oral intake, erythematous rash, and focal seizures. One patient with a single episode of limpness and pallor did not undergo EEG due to a low suspicion for seizures. CSF indices were normal in all patients. EEG was abnormal in all patients where performed (n = 7). EEG features included dysmaturity (7/7, 100 %); excessive discontinuity (6/7, 86 %); excessive asynchrony (6/7, 86 %); multifocal sharp transients (7/7, 100 %). Focal/multifocal seizures were captured in 6/7 (86 %); tonic in 3/7 (42 %) and described as migrating in 2 patients. Subclinical seizures were noted in 6/7 (86 %) with status epilepticus in 5/7 (71 %) patients. In 2/7 (28 %) the EEG showed a burst suppression pattern with poor state variation and voltages of < 5-10 uV/mm during the inter-burst intervals. Repeat EEG (3-11 days post initial EEG) showed improvement in 3 of 4 patients. No patient had ongoing seizures beyond day two of admission (22.5 h after EEG initiation). MRI showed extensive restricted diffusion in the supratentorial white matter, thalami, and less frequently the cortex, mimicking imaging findings of a metabolic or hypoxic-ischemic encephalopathy (7/8). Seizures responded within 36 h of presentation to treatment with acute bolus doses of medications. One patient died due to diffuse cerebral edema and status epilepticus. Six patients had a normal clinical exam at discharge. All patients started on maintenance antiseizure medication (ASM) were sent home on either a single medication or two medications (phenobarbital and levetiracetam) with plans to wean phenobarbital after discharge. CONCLUSIONS: HPeV is a rare cause of seizures and encephalopathy in neonates. Prior studies have emphasized specific patterns of white matter injury on imaging. We demonstrate that HPeV also commonly presents with clonic or tonic seizures with or without apnea and often subclinical multifocal and migrating focal seizures that could mimic a genetic neonatal epilepsy syndrome. Interictal EEG shows a dysmature background with excessive asynchrony, discontinuity, burst-suppression pattern, and multifocal sharp transients. However, we note that 100 % of patients responded quickly to standard ASM, and did not have seizures after hospital discharge- a factor that can help distinguish it from a genetic epilepsy syndrome.

Prevalence and genetic diversity of Parechovirus A in children with diarrhea in Beijing, China, 2017-2019.

We analyzed the prevalence and genotypes of Parechovirus A (PeV-A) in children with diarrhea in Beijing, China, 2017-2019. A total of 1734 stool samples collected from children <5 years of age with diarrhea were tested for the presence of PeV-A. Viral RNA was detected by real-time RT-PCR, and then genotyped by nested RT-PCR. We detected PeV-A in 93 (5.4%, 93/1734) samples, of which 87 could be genotyped by amplification of either the complete or partial VP1 region or the VP3/VP1 junction region. The median age of PeV-A infected children was 10 months. Most PeV-A infections were observed between August and November, with a peak in September. Seven known genotypes of PeV-A1A, -A1B, -A3, -A4, -A6, -A8 and -A11 were detected and PeV-A1B was the most prevalent genotype. Coinfection with other diarrheal viruses was observed in 30.1% (28/93) of PeV-A positive samples. All strains of PeV-A1A, -A1B, -A4 and -A6 obtained in this study contained the arginine-glycine-aspartic acid (RGD) motif, while all strains of PeV-A3, -A8 and -A11 lacked it. This study revealed a high genetic diversity of PeV-A circulating in Beijing and PeV-A11 was reported for the first time in children with diarrhea in China.

Myeloid-associated differentiation marker is an essential host factor for human parechovirus PeV-A3 entry.

Human parechovirus (PeV-A) is an RNA virus that belongs to the family Picornaviridae and it is currently classified into 19 genotypes. PeV-As usually cause mild illness in children and adults. Among the genotypes, PeV-A3 can cause severe diseases in neonates and young infants, resulting in neurological sequelae and death. In this study, we identify the human myeloid-associated differentiation marker (MYADM) as an essential host factor for the entry of six PeV-As (PeV-A1 to PeV-A6), including PeV-A3. The infection of six PeV-As (PeV-A1 to PeV-A6) to human cells is abolished by knocking out the expression of MYADM. Hamster BHK-21 cells are resistant to PeV-A infection, but the expression of human MYADM in BHK-21 confers PeV-A infection and viral production. Furthermore, VP0 capsid protein of PeV-A3 interacts with one extracellular domain of human MYADM on the cell membrane of BHK-21. The identification of MYADM as an essential entry factor for PeV-As infection is expected to advance our understanding of the pathogenesis of PeV-As.

Update on nonpolio enterovirus and parechovirus infections in neonates and young infants.

PURPOSE OF REVIEW: To review the epidemiology, clinical manifestations, and treatment strategies of nonpolio enterovirus and parechovirus (PeV) infections, and identify research gaps. RECENT FINDINGS: There is currently no approved antiviral agent for enterovirus or PeV infections, although pocapavir may be provided on a compassionate basis. Elucidation of the structure and functional features of enterovirus and PeV may lead to novel therapeutic strategies, including vaccine development. SUMMARY: Nonpolio human enterovirus and PeV are common childhood infections that are most severe among neonates and young infants. Although most infections are asymptomatic, severe disease resulting in substantial morbidity and mortality occurs worldwide and has been associated with local outbreaks. Long-term sequelae are not well understood but have been reported following neonatal infection of the central nervous system. The lack of antiviral treatment and effective vaccines highlight important knowledge gaps. Active surveillance ultimately may inform preventive strategies.

Prevalence and genetic diversity in bovine parechovirus infecting Japanese cattle.

The first bovine parechovirus (Bo_ParV) was reported in 2021, and currently, only two nearly complete genome sequences of Bo_ParV are available. In this study, we detected Bo_ParVs in 10 out of 158 bovine fecal samples tested using real-time RT-PCR, and Bo_ParVs were isolated from three of these samples using MA104 cells. Analysis of the P1 region revealed that Bo_ParVs shared high pairwise amino acid sequence similarity (≥ 95.7% identity), suggesting antigenic similarity among Bo_ParVs, whereas nucleotide sequence identity values (≥ 84.8%) indicated more variability. A recombination breakpoint was identified in the 2B region, which may influence the evolution of this virus.

Enterovirus B types cause severe infection in infants aged 0-3 months.

BACKGROUND: Enterovirus (EV) infections are being increasingly seen in younger infants, often being more severe than in older children. The risk factors of EV infection in infants have been inadequately investigated till date. METHODS: We conducted a retrospective study on hospitalized children with laboratory-confirmed EV infection (50 infants aged 0-3 months and 65 older than 3 months) at a tertiary care center in China. Prevalence, clinical characteristics, and genetic features of the virus were analyzed, and independent predictors for severe infection were assessed. RESULTS: Clinical findings showed that severe infection was more common in infants aged 0-3 months than in older children (78.0% vs. 35.4%, p < 0.001), with higher morbidity of pneumonia, meningitis, and sepsis (p < 0.01). EV-B types were detected more frequently in infants aged 0-3 months than in older children (88.0% vs. 7.7%, p < 0.001). Echovirus 11 was the most identified EV-B, and it recombined with E6 in P2 and P3 regions. Risk factors for severe EV infection included EV-B types infection, age less than 3 months, elevated alanine aminotransferase level, abnormal platelet count, and abnormal cerebrospinal fluid characteristics. CONCLUSIONS: Our data indicated that EV-B types mainly cause severe infection in infants aged 0-3 months. Therefore, knowledge about EV-B types could have implications in designing effective intervention and prevention strategies for young infants with severe EV infection.

Novel Human Parechovirus 3 Diversity, Recombination, and Clinical Impact Across 7 Years: An Australian Story.

BACKGROUND: A novel human parechovirus 3 Australian recombinant (HPeV3-AR) strain emerged in 2013 and coincided with biennial outbreaks of sepsis-like illnesses in infants. We evaluated the molecular evolution of the HPeV3-AR strain and its association with severe HPeV infections. METHODS: HPeV3-positive samples collected from hospitalized infants aged 5-252 days in 2 Australian states (2013-2020) and from a community-based birth cohort (2010-2014) were sequenced. Coding regions were used to conduct phylogenetic and evolutionary analyses. A recombinant-specific polymerase chain reaction was designed and utilized to screen all clinical and community HPeV3-positive samples. RESULTS: Complete coding regions of 54 cases were obtained, which showed the HPeV3-AR strain progressively evolving, particularly in the 3' end of the nonstructural genes. The HPeV3-AR strain was not detected in the community birth cohort until the initial outbreak in late 2013. High-throughput screening showed that most (>75%) hospitalized HPeV3 cases involved the AR strain in the first 3 clinical outbreaks, with declining prevalence in the 2019-2020 season. The AR strain was not statistically associated with increased clinical severity among hospitalized infants. CONCLUSIONS: HPeV3-AR was the dominant strain during the study period. Increased hospital admissions may have been from a temporary fitness advantage and/or increased virulence.

Molecular Evolution and Epidemiology of Parechovirus-A3 in Japan, 1997-2019.

Parechovirus-A3 (PeV-A3), first reported in 2004 in Japan, is an emerging pathogen that causes sepsis and meningoencephalitis in neonates and young infants. Although PeV-A3 has been identified worldwide, its epidemiological characteristics differ by region. To investigate the molecular evolution and epidemiology of PeV-A3, we performed genetic analyses of 131 PeV-A3 strains from the years 1997-2019 in Niigata, Japan. During 2016-2019, annual numbers remained steady, in contrast to the PeV-A3 epidemic interval of every 2-3 years that was observed in Japan from 2006. Bayesian evolutionary analysis of the complete viral protein 1 region revealed alternate dominant clusters during years of PeV-A3 epidemics. The branch including the oldest and first isolated PeV-A3 strains in Japan has been disrupted since 2001. The year of PeV-A3 emergence was estimated to be 1991. Continuous surveillance with genetic analyses of different regions will improve understanding of PeV-A3 epidemiology worldwide.

Detection of Parechovirus and Enterovirus Among Infants Evaluated for Late-onset Sepsis in the Neonatal Intensive Care Unit: The Viral Respiratory Infections in the Neonatal Intensive Care Unit-Parechovirus-Enterovirus Study.

In a prospective cohort study of 65 inborn infants who were evaluated for late-onset sepsis at >72 hours of age in 2 academic neonatal intensive care units, none had parechovirus or enterovirus RNA detected by polymerase chain reaction performed on nasopharyngeal specimens during the first or subsequent sepsis evaluations (n = 80).

Isolation and characterization of phage display-derived scFv antibodies against human parechovirus 1 VP0 protein.

Human parechoviruses (PeVs) are common viruses that are associated with a variety of diseases from mild gastrointestinal and respiratory symptoms to severe central nervous system infections. Until now there has not been antibodies for visualizing parechovirus infection. We used E. coli recombinant PeV-A1-VP0 protein as a target in phage display single chain variable fragment (scFv) antibody library panning. Three rounds of panning allowed identification and isolation of several candidate scFv clones, which tested positive in enzyme-linked immunosorbent assay (ELISA) against VP0. Three scFv clones (scFv-55, -59 and -71) with different CDR-3 sequences were further purified and tested in ELISA, Western blot and immunofluorescence microscopy (IFA) against a set of PeV-A1 isolates and a few isolates representing PeV types 2-6. In IFA, all three scFv binders recognized twenty PeV-A1 isolates. ScFv-55 and -71 also recognized clinical representatives of PeV types 1-6 both in IFA and in capture ELISA, while scFv-59 only recognized PeV-A1, -A2 and -A6. PeV-A1-VP0 (Harris strain) sequence was used to generate a peptide library, which allowed identification of a putative unique conformational antibody epitope with fully conserved flanking regions and a more variable core VVTYDSKL, shared between the scFv antibodies. Sequencing of the VP0 region of virus samples and sequence comparisons against parechoviral sequences in GenBank revealed 107 PeV-A1, -A3, -A8, -A17, -A (untyped) sequences with this exact epitope core sequence, which was most dominant among PeV-A1 isolates. These data suggest the first-time isolation of broad range phage display antibodies against human parechoviruses that may be used in diagnostic antibody development.

Parechovirus A infection and risk of gastroenteritis in children: A systematic review and meta-analysis.

Parechovirus A (PeV-A) belongs to the genus Parechovirus in the family Picornaviridae associated with gastroenteritis illness, particularly in children, but prior studies have produced ambiguous results. This study aimed to provide a systematic review of the PeV-A prevalence in paediatric patients with gastroenteritis and the association between PeV-A infection and the risk of gastroenteritis. A systematic search of the literature was conducted in Embase, PubMed, Scopus, and Web of Science, in combination with the reference lists of potentially relevant articles. A random effect-based model was applied to analyse data from included studies. The pooled odds ratio (OR) and 95% confidence interval (CI) were used for assessing the risk between PeV-A and gastroenteritis. A total of 41 studies assessing 21,850 cases and 1746 healthy controls were analysed. The overall prevalence of PeV-A among paediatric patients with gastroenteritis was 10.4% (95% CI: 7.9%-13.2%), while it was estimated at 8.1% (95% CI: 5.1%-11.7%) based on studies only investigating children without gastroenteritis. The pooled OR for all eight case-control studies was 1.079 (95% CI: 0.730-1.597), indicating there was no statistically significant association. PeV-A genotype 1 was the most frequent genotype of PeV-A infection in children with gastroenteritis. The PeV-A prevalence in cases of gastroenteritis is higher than that in children without gastroenteritis. However, the present meta-analysis did not indicate a statistically significant association between PeV-A infection and risk of gastroenteritis. Given the considerable heterogeneity and various sample sizes among the included studies, relevant investigations in the future should be carried out based on a large-scale population.