Characterization of Pathogenesis and Inflammatory Responses to Experimental Parechovirus Encephalitis.

Human parechovirus type 3 (PeV-A3) infection has been recognized as an emerging etiologic factor causing severe nerve disease or sepsis in infants and young children. But the neuropathogenic mechanisms of PeV-A3 remain unknown. To understand the pathogenesis of PeV-A3 infection in the neuronal system, PeV-A3-mediated cytopathic effects were analyzed in human glioblastoma cells and neuroblastoma cells. PeV-A3 induced interferons and inflammatory cytokine expression in these neuronal cells. The pronounced cytopathic effects accompanied with activation of death signaling pathways of apoptosis, autophagy, and pyroptosis were detected. A new experimental disease model of parechovirus encephalitis was established. In the disease model, intracranial inoculation with PeV-A3 in C57BL/6 neonatal mice showed body weight loss, hindlimb paralysis, and approximately 20% mortality. PeV-A3 infection in the hippocampus and cortex regions of the neonatal mouse brain was revealed. Mechanistic assay supported the in vitro results, indicating detection of PeV-A3 replication, inflammatory cytokine expression, and death signaling transduction in mouse brain tissues. These in vitro and in vivo studies revealed that the activation of death signaling and inflammation responses is involved in PeV-A3-mediated neurological disorders. The present results might account for some of the PeV-A3-associated clinical manifestations.

Childhood Outcomes Following Parechovirus Infections in a US Young Infant Cohort.

BACKGROUND: Parechovirus A type 3 (PeV-A3) is associated with central nervous system infection in young infants. There are limited data regarding long-term outcomes, mostly reported from Australia and European populations. The objective of this study was to assess frequency of neurodevelopmental impairment (NDI) following PeV-A3 infection in our US cohort. METHODS: Infants hospitalized during the 2014 outbreak with laboratory-confirmed PeV-A3 infection were evaluated with medical history, neurologic examination, parental completion of Ages and Stages Questionnaire and developmental assessment using Bayley Scales of Infant and Toddler Development, Third Edition cognitive, motor and language quotients. Determination of NDI was based on published criteria. Relationship of severity of PeV disease to outcome measures was determined using Fisher exact, χ2 and Mann-Whitney U test as appropriate. RESULTS: Nineteen children, term gestation, were evaluated at ~3 years of age; PeV-A3 illness was uncomplicated for 6 (32%), complex, non-neurologic for 9 (47%) and encephalitis/seizures for 4 (21%). No differences were noted in mean Bayley Scales of Infant and Toddler Development, Third Edition quotients between infants by clinical presentation. Quotients for all were within 1 SD of population norms. Two (11%) children had mild NDI; 1 with mild cerebral palsy. Ages and Stages Questionnaire results included 11% at referral level and 37% suspect concern. Parents of 6 (32%) noted behavior concerns. These findings were unrelated to severity of the PeV-A3 illness. CONCLUSIONS: Parent concerns were identified frequently following infant PeV-A3 disease. Eleven percent had neurodevelopmental impairment at 3 years of age. Severity at presentation did not correlate with adverse childhood outcomes. Longitudinal developmental monitoring following infantile PeV-A3 disease is warranted.

Identification and molecular characterization of the first complete genome sequence of Human Parechovirus type 15.

Using a metagenomics approach, we have determined the first full-length genome sequence of a human parechovirus type 15 (HPeV15) strain, isolated from a child with acute flaccid paralysis and co-infected with EV-A71. HPeV15 is a rarely reported type. To date, no full-length genome sequence of HPeV15 is available in the GenBank database, where only limited VP1 sequences of this virus are available. Pairwise comparisons of the complete VP1 nucleotide and deduced amino acid sequences revealed that the study strain belongs to type 15 as it displayed 79.6% nucleotide and 93.4% amino acid identity with the HPeV15 prototype strain. Comparative analysis of available genomic regions and phylogenetic analysis using the P2 and P3 coding regions revealed low nucleotide identity to HPeV reference genomes. Phylogenetic and similarity plot analyses showed that genomic recombination events might have occurred in the UTRs and nonstructural region during HPeV15 evolution. The study strain has high similarity features with different variants of HPeV3 suggesting intertypic recombination. Our data contributes to the scarce data available on HPeVs in Africa and provides valuable information for future studies that aim to understand the evolutionary history, molecular epidemiology or biological and pathogenic properties of HPeV15.

Epidemic and Inter-epidemic Burden of Pediatric Human Parechovirus Infection in New South Wales, Australia, 2017-2018.

BACKGROUND: Human parechovirus (HPeV) typically infects young children, and although infection is often asymptomatic, some types (eg, HPeV3) are associated with severe clinical manifestations, including central nervous system infection or sepsis-like syndrome, particularly affecting young infants. The third documented national epidemic of HPeV occurred in Australia in 2017-2018. METHODS: Four public laboratories that perform almost all of the HPeV PCR testing in New South Wales provided data regarding HPeV tests performed from July 1, 2017 to June 30, 2018. Limited demographic and clinical data were obtained from electronic medical records for laboratory test-positive cases that presented to each of the 3 pediatric hospitals in New South Wales. RESULTS: Five hundred eighty-one HPeV-positive samples obtained from 395 cases were included in the analysis. The peak of the outbreak occurred in late November 2017 (approximately 35 new cases each week), with the main HPeV epidemic occurring between the spring and summer months of September 2017 to January 2018; although this seasonality was observed primarily in infants less than 12 months of age. Among the 388 pediatric cases, almost half were younger than 2 months (188; 47%) and only 10 were children older than 2 years. The annualized estimated incidence of laboratory confirmed HPeV infection in children was approximately 142.4 cases per 100,000 children younger than 5 years in New South Wales during the epidemic season. CONCLUSIONS: The large burden of HPeV infection and disease identified in young infants in this and previous Australian studies highlight the need for more comprehensive national surveillance of HPeV infections and improved prevention strategies.

Repeated viral meningitis in a newborn.

Human enteroviruses (EV) are the most common cause of viral meningitis in children. Human parechoviruses (HPeV) are increasingly being recognized as a cause of central nervous system (CNS) infections and sepsis-like disease in children. Both viruses belong to Picornaviridae family. The clinical picture in EV and HPeV infections is usually nonspecific. Therefore, molecular detection of both viruses is needed for etiological diagnosis. In this case report, we describe and discuss clinical and laboratory findings of two consecutive episodes of viral meningitis caused by EV and HPeV, respectively, occurring in the first month of a newborn's life.

Mittens and Booties Syndrome: A Unique Manifestation of Human Parechovirus Infection in Infants.

We describe the first 2 cases from the United States, of human parechovirus infection in infants manifesting a distinct rash of the hands and feet. We propose the term "Mittens and Booties Syndrome" and provide a review of the literature of all published cases.

Evolutionary analysis of human parechovirus type 3 and clinical outcomes of infection during the 2017-18 Australian epidemic.

Human parechovirus type 3 (HPeV3) can cause severe sepsis-like illness in young infants and may be associated with long term neurodevelopmental delay later in childhood. We investigated the molecular epidemiology of HPeV infection in thirty three infants requiring hospitalization before, during and after the peak of the 2017/18 HPeV epidemic wave in Australia. During the peak of the epidemic, all cases were infected with an HPeV3, while before and after the peak, HPeV1 was the predominant type detected. The predominant HPeV3 was the recombinant HPeV3 also detected in the 2013/14 and 2015/16 Australian epidemics. Sepsis-like or meningitis-like symptoms were only reported in cases infected with the recombinant HPeV3. Phylogenetic analysis of the recombinant HPeV3 revealed that the virus continued to evolve, also between the Australian outbreaks, thus indicating continued circulation, despite not being detected and reported in Australia or elsewhere in between epidemic waves. The recombinant HPeV3 continued to show a remarkable stability in its capsid amino acid sequence, further strengthening our previous argument for development of a vaccine or immunotherapeutics to reduce the severity of HPeV3 outbreaks due to this virus.

Emergence of Parechovirus A4 Central Nervous System Infections among Infants in Kansas City, Missouri, USA.

Among known parechovirus (PeV) types infecting humans, PeV-A3 (formerly HPeV3) and PeV-A1 (formerly HPeV1) are associated with pediatric central nervous system (CNS) infections. The prevalence of PeV-A3 among hospitalized infants with sepsis-like illness and viral CNS infection is well described; however, the contribution of PeV-A4 to infant CNS infection is relatively unexplored. We report the first 11 U.S. cases of PeV-A4 CNS infections occurring in Kansas City infants during 2010 to 2016 and compare the clinical presentation with that of PeV-A3. PeV-positive cerebrospinal fluid (CSF) specimens from 2010 to 2016 underwent sequencing for genotyping. Among all PeV-CSF positives, PeV-A4 was detected in 11 CSF samples from 2010 to 2016. PeV-A4 was first detected in 2010 (n = 1/4), followed by detections in 2014 (n = 1/39), 2015 (n = 6/9), and 2016 (n = 3/33). The median age of PeV-A4-infected infants in weeks (median, 4; range, 1 to 8) was similar to that of infants infected with PeV-A3 (median, 4; range, 0.25 to 8). Clinical characteristics of PeV-A4 (n = 11) were compared with those of select PeV-A3-infected children (n = 34) with CNS infections and found to be mostly similar, although maximum temperature was higher (P = 0.017) and fever duration was shorter (P = 0.03) for PeV-A4 than for PeV-A3. Laboratory test results were also similar between genotypes, although they showed significantly lower peripheral white blood cell (P = 0.014) and absolute lymphocyte (P = 0.04) counts for PeV-A4 infants. Like PeV-A3, PeV-A4 caused summer-fall seasonal clusters of CNS infections in infants, with mostly similar presentations. Further surveillance is necessary to confirm potential differences in laboratory findings and in fever intensity/duration.

Longitudinal Association Between Human Parechovirus Central Nervous System Infection and Gross-Motor Neurodevelopment in Young Children.

BACKGROUND: A paucity of studies investigated the association between human parechovirus (HPeV) central nervous system (CNS) infection and motor and neurocognitive development of children. This study describes the gross-motor function (GMF) in young children during 24 months after HPeV-CNS infection compared with children in whom no pathogen was detected. METHODS: GMF of children was assessed with Alberta Infant Motor Scale, Bayley Scales of Infant and Toddler Development or Movement Assessment Battery for Children. We conducted multivariate analyses and adjusted for age at onset, maternal education and time from infection. RESULTS: Of 91 included children, at onset <24 months of age, 11 had HPeV-CNS infection and in 47 no pathogen was detected. Nineteen children were excluded because of the presence of other infection, preterm birth or genetic disorder, and in 14 children, parents refused to consent for participation. We found no longitudinal association between HPeV-CNS infection and GMF (ß = -0.53; 95% confidence interval: -1.18 to 0.07; P = 0.11). At 6 months, children with HPeV-CNS infection had suspect GMF delay compared with the nonpathogen group (mean difference = 1.12; 95% confidence interval: -1.96 to -0.30; P = 0.03). This difference disappeared during 24-month follow-up and, after adjustment for age at onset, both groups scored within the normal range for age. Maternal education and time from infection did not have any meaningful influence. CONCLUSIONS: We found no longitudinal association between HPeV-CNS infection and GMF during the first 24-month follow-up. Children with HPeV-CNS infection showed a suspect GMF delay at 6-month follow-up. This normalized during 24-month follow-up.

A Case Series of Parechovirus Encephalopathy: Apnea and Autonomic Dysregulation in Critically Ill Infants.

This article aims to describe a rare cause of severe encephalitis in 2 cases of infants with signs of intracranial hypertension and severe autonomic dysregulation. The authors conclude that human parechoviruses are becoming a more recognized cause of encephalitis because of the increasing use of rapid detection methods. With early recognition of this clinical entity, improved care can be administered.

Increased detection of human parechovirus infection in infants in England during 2016: epidemiology and clinical characteristics.

BACKGROUND: Human parechovirus (HPeV), like enteroviruses, usually causes mild self-limiting respiratory and gastrointestinal symptoms. In infants, HPeV can occasionally cause serious illnesses, including sepsis-like syndrome and encephalitis. In summer 2016, Public Health England (PHE) received increasing reports of severe HPeV infections nationally. We, therefore, reviewed all infants with confirmed HPeV across England during 2016. METHODS: HPeV cases in infants aged <12 months reported to PHE during 2016 were followed up using a clinical questionnaire. Additional cases identified by clinicians completing the questionnaire were also included. RESULTS: We identified 106 infants with confirmed HPeV infection during 2016. The disease peaked during early summer. Most infants (98/106, 92%) were aged <90 days, and 43% (46/106) were neonates. Fever was the most commonly reported symptom (92%) and signs of circulatory shock were present in 53%. Eighteen infants (18%) required paediatric intensive care admission. Most infants had normal or low C reactive protein concentrations (<10 mg/dL in 75%, <50 mg/dL in 98%). A lumbar puncture was performed in 98% of cases; 92% (33/36) of neonates and 93% (53/57) of older infants had normal white cell count in the cerebrospinal fluid (CSF). Nearly all reported cases (98%) were confirmed by CSF PCR. All infants survived, but five had ongoing seizures after hospital discharge. CONCLUSIONS: HPeV is an important cause of febrile illness in infants and can have severe clinical presentations. Early diagnosis may help reduce antimicrobial use, unnecessary investigations and prolonged hospitalisation. While prognosis remains favourable, some infants will develop long-term complications-paediatricians should ensure appropriate follow-up after discharge.

Epidemiology and clinical profile of pathogens responsible for the hospitalization of children in Sousse area, Tunisia.

This study aimed to identify a broad spectrum of respiratory pathogens from hospitalized and not-preselected children with acute respiratory tract infections in the Farhat Hached University-hospital of Sousse, Tunisia. Between September 2013 and December 2014, samples from 372 children aged between 1 month and 5 years were collected, and tested using multiplex real-time RT-PCR by a commercial assay for 21 respiratory pathogens. In addition, samples were screened for the presence of Streptococcus pneumoniae 16S rDNA using real-time PCR. The viral distribution and its association with clinical symptoms were statistically analyzed. Viral pathogens were detected in 342 (91.93%) of the samples of which 28.76% were single positive and 63.17% had multiple infections. The most frequent detected viruses were rhinovirus (55.64%), respiratory syncytial virus A/B (33.06%), adenovirus (25.00%), coronavirus NL63, HKU1, OC43, and 229E (21.50%), and metapneumovirus A/B (16.12%). Children in the youngest age group (1-3 months) exhibited the highest frequencies of infection. Related to their frequency of detection, RSV A/B was the most associated pathogen with patient's demographic situation and clinical manifestations (p<0.05). Parainfluenza virus 1-4 and parechovirus were found to increase the risk of death (p<0.05). Adenovirus was statistically associated to the manifestation of gastroenteritis (p = 0.004). Rhinovirus infection increases the duration of oxygen support (p = 0.042). Coronavirus group was statistically associated with the manifestation of bronchiolitis (p = 0.009) and laryngitis (p = 0.017). Streptococcus pneumoniae DNA was detected in 143 (38.44%) of tested samples. However, only 53 samples had a concentration of C-reactive protein from equal to higher than 20 milligrams per liter, and 6 of them were single positive for Streptocuccus pneumoniae. This study confirms the high incidence of respiratory viruses in children hospitalized for acute respiratory tract infections in the Sousse area, Tunisia.

An outbreak of severe infections among Australian infants caused by a novel recombinant strain of human parechovirus type 3.

Human parechovirus types 1-16 (HPeV1-16) are positive strand RNA viruses in the family Picornaviridae. We investigated a 2015 outbreak of HPeV3 causing illness in infants in Victoria, Australia. Virus genome was extracted from clinical material and isolates and sequenced using a combination of next generation and Sanger sequencing. The HPeV3 outbreak genome was 98.7% similar to the HPeV3 Yamagata 2011 lineage for the region encoding the structural proteins up to nucleotide position 3115, but downstream of that the genome varied from known HPeV sequences with a similarity of 85% or less. Analysis indicated that recombination had occurred, may have involved multiple types of HPeV and that the recombination event/s occurred between March 2012 and November 2013. However the origin of the genome downstream of the recombination site is unknown. Overall, the capsid of this virus is highly conserved, but recombination provided a different non-structural protein coding region that may convey an evolutionary advantage. The indication that the capsid encoding region is highly conserved at the amino acid level may be helpful in directing energy towards the development of a preventive vaccine for expecting mothers or antibody treatment of young infants with severe disease.

Enterovirus and parechovirus infection in children: a brief overview.

UNLABELLED: Enterovirus and parechovirus are a frequent cause of infection in children. This review is an overview of what is known from enterovirus and parechovirus infection in children and contains information about the epidemiology, pathogenesis, clinical presentation, diagnosis, treatment, and prognosis of enterovirus and parechovirus infection in children. CONCLUSIONS: EV and HPeV infections are a frequent cause of infection in childhood. The clinical presentation is diverse. RT-qPCR is the best way to detect an EV or HPeV. Cerebrospinal fluid, blood and feces have the highest sensitivity for detecting an EV or HPeV. There is no treatment for EV and HPeV infections. Two vaccines against EV 71 are just licensed in China and will be available on the private market. Little is known about the prognosis of EV and HPeV infections. WHAT IS KNOWN: •EV and HPeV are a frequent cause of infection in children. What is new: •This review gives a brief overview over EV and HPeV infection in children.

Human Parechovirus 1 Infection Occurs via αVß1 Integrin.

Human parechovirus 1 (HPeV-1) (family Picornaviridae) is a global cause of pediatric respiratory and CNS infections for which there is no treatment. Although biochemical and in vitro studies have suggested that HPeV-1 binds to αVß1, αVß3 and αVß6 integrin receptor(s), the actual cellular receptors required for infectious entry of HPeV-1 remain unknown. In this paper we analyzed the expression profiles of αVß1, αVß3, αVß6 and α5ß1 in susceptible cell lines (A549, HeLa and SW480) to identify which integrin receptors support HPeV-1 internalization and/or replication cycle. We demonstrate by antibody blocking assay, immunofluorescence microscopy and RT-qPCR that HPeV-1 internalizes and replicates in cell lines that express αVß1 integrin but not αVß3 or αVß6 integrins. To further study the role of ß1 integrin, we used a mouse cell line, GE11-KO, which is deficient in ß1 expression, and its derivate GE11-ß1 in which human integrin ß1 subunit is overexpressed. HPeV-1 (Harris strain) and three clinical HPeV-1 isolates did not internalize into GE11-KO whereas GE11-ß1 supported the internalization process. An integrin ß1-activating antibody, TS2/16, enhanced HPeV-1 infectivity, but infection occurred in the absence of visible receptor clustering. HPeV-1 also co-localized with ß1 integrin on the cell surface, and HPeV-1 and ß1 integrin co-endocytosed into the cells. In conclusion, our results demonstrate that in some cell lines the cellular entry of HPeV-1 is primarily mediated by the active form of αVß1 integrin without visible receptor clustering.

Role of Maternal Antibodies in Infants with Severe Diseases Related to Human Parechovirus Type 3.

Human parechovirus type 3 (HPeV3) is an emerging pathogen that causes sepsis and meningoencephalitis in young infants. To test the hypothesis that maternal antibodies can protect this population, we measured neutralizing antibody titers (NATs) to HPeV3 and other genotypes (HPeV1 and HPeV6) in 175 cord blood samples in Japan. The seropositivity rate (≥1:32) for HPeV3 was 61%, similar to that for the other genotypes, but decreased significantly as maternal age increased (p<0.001). Furthermore, during the 2014 HPeV3 epidemic, prospective measurement of NATs to HPeV3 in 45 patients with severe diseases caused by HPeV3 infection showed low NATs (≤1:16) at onset and persistently high NATs (≥1:512) until age 6 months. All intravenous immunoglobulin samples tested elicited high NATs to HPeV3. Our findings indicate that maternal antibodies to HPeV3 may help protect young infants from severe diseases related to HPeV3 and that antibody supplementation may benefit these patients.

Emerging Infections of CNS: Avian Influenza A Virus, Rift Valley Fever Virus and Human Parechovirus.

History is replete with emergent pandemic infections that have decimated the human population. Given the shear mass of humans that now crowd the earth, there is every reason to suspect history will repeat itself. We describe three RNA viruses that have recently emerged in the human population to mediate severe neurological disease. These new diseases are results of new mutations in the infectious agents or new exposure pathways to the agents or both. To appreciate their pathogenesis, we summarize the essential virology and immune response to each agent. Infection is described in the context of known host defenses. Once the viruses evade immune defenses and enter central nervous system (CNS) cells, they rapidly co-opt host RNA processing to a cataclysmic extent. It is not clear why the brain is particularly susceptible to RNA viruses; but perhaps because of its tremendous dependence on RNA processing for physiological functioning, classical mechanisms of host defense (eg, interferon disruption of viral replication) are diminished or not available. Effectiveness of immunity, immunization and pharmacological therapies is reviewed to contextualize the scope of the public health challenge. Unfortunately, vaccines that confer protection from systemic disease do not necessarily confer protection for the brain after exposure through unconventional routes.

Human Parechovirus 3: The Most Common Viral Cause of Meningoencephalitis in Young Infants.

Human parechoviruses (HPeVs) were initially classified as echoviruses. HPeVs occur worldwide, comprising up to 17 genotypes. HPeV1 and HPeV3 are most common. Clinical disease varies somewhat among genotypes. HPeV1 causes mostly gastrointestinal infections. HPeV3's prominence is due to its causing sepsis syndromes and central nervous system (CNS) infections in young infants. Currently, HPeV3 is the most common single cause of aseptic meningitis/meningoencephalitis in infants less than 90 days old in North America, usually with biannual summer-fall seasonality. HPeV3 CNS infections usually lack cerebrospinal fluid pleocytosis. Mortality and sequelae are uncommon, usually accompanying initially severe or neurologically complicated acute illnesses.

Human Parechoviruses.

Human parechoviruses (HPeVs) are single-stranded, positive-sense RNA viruses and are classified in the genus Parechovirus of the family Picornaviridae. Echovirus 22 and 23 were reclassified as HPeV1 and 2 in 1999. Although HPeVs were considered to be one of the common viruses which cause mild gastroenteritis and respiratory infections, the concept of HPeVs has changed significantly after the discovery of HPeV3 in 2004. HPeV3 infection is an emerging infectious disease which attracts the attention of pediatricians, because it can cause sepsis and meningoencephalitis in neonates and infants younger than 3 months, which could lead to neurological sequelae and death. In Japan, the epidemics of HPeV3 infection have occurred every 2 or 3 years since 2006 and we had an epidemic in 2014 summer. Fever, severe tachycardia, poor activity and appetite are typical symptoms of HPeV3 infection.In addition, abdominal distention, umbilical protrusion, palmar-plantar erythema,and mottled skin are occasionally observed in patients with HPeV3 infection. Currently diagnosis is usually made by PCR using serum and/or cerebrospinal fluid. The reason why severe disease occur only in neonates and young infants remain unknown; however, negative or low maternally derived neutralizing antibody titers to HPeV3 are suggested to be a risk factor for developing severe HPeV3-related diseases in neonates and young infants. So far, no specific antiviral therapy is available, thus supportive care is the only option. It is likely that epidemics of HPeV3 continue to occur given there are children with absence or lack of neutralizing antibodies against HPeV3. The research related to HPeV3 pathogenesis, specific therapy, and prevention are definitely warranted.