Functional balance between neuraminidase and haemagglutinin in influenza viruses.

Seasonal influenza A and B viruses are important human pathogens responsible for significant morbidity and mortality worldwide. In addition, influenza A zoonotic viruses are a constant pandemic threat. These viruses present two major surface glycoproteins: the haemagglutinin (HA) and the neuraminidase (NA). These two glycoproteins both recognize the sialic acid and have complementary activities, the HA binds the sialic acid through its receptor-binding site, the NA is a receptor-destroying enzyme that cleaves α2-3 and α2-6-linked sialic acids. Therefore, the functional HA/NA balance is a critical factor for a good viral fitness and plays a major role in overcoming the host barrier and the efficiency of sustained human-to-human transmission. Although the two glycoproteins are in constant evolution, the HA/NA balance seems to remain stable in human viruses because an optimal balance is required to maintain good viral fitness. Understanding the evolution of influenza viruses requires an in-depth exploration of the HA/NA balance.

Increased detection of Mycoplasma pneumoniae infection in children, Lyon, France, 2010 to 2011.

Recent reports from several northern European countries indicate an increase in detection of Mycoplasma pneumoniae infection in the past two years, notably in children aged 5­15 years. Analysis of our laboratory database showed a similar pattern, with a higher proportion of respiratory samples positive for M. pneumonia by real-time PCR in paediatric patients aged 5­15 years. Our data indicate that in 2010 and 2011, France experienced the first epidemic peak of M. pneumonia infection since 2005.

Pediatric neurological complications associated with the A(H1N1)pdm09 influenza infection.

BACKGROUND: Influenza-related neurological complications (INC) have been reported during seasonal flu in children. OBJECTIVES: To investigate the types, outcomes and incidence of INC occurring during the 2009 A(H1N1) pandemic, a retrospective analyze was conducted in the single French pediatric hospital of Lyon from October 2009 to February 2010. STUDY DESIGN: All children presenting with fever, influenza-like illness, respiratory distress or neurological symptoms were tested for influenza A(H1N1)pdm09 infection from respiratory specimens using real time RT-PCR. RESULTS: INC occurred in 14 A(H1N1)pdm09 positive children (7.7% of A(H1N1)pdm09 positive children admitted to hospital) with a median age of 5.1 years. Admission to the intensive care unit (ICU) was required for nine children (64.3%). Half of the children with INC had comorbidity and three had coinfection, both characteristics mainly found in children requiring the ICU. All children received oral oseltamivir treatment. Febrile seizures were observed in eight children, half of them having a chronic comorbidity (2 epilepsy, 1 nonketotic hyperglycinemia, 1 anoxic encephalopathy). Other INC, less commonly reported, included 2 cases of encephalitis, 1 encephalopathy, 1 basilar artery thrombosis, 1 myasthenic crisis and 1 coma. Eleven of the 14 children (78.6%) recovered, one had a minor disability, one child developed a locked-in syndrome and one died from complications of an acute necrotizing encephalopathy. DISCUSSION: INC can be observed even in children with no underlying disorder. It may lead to dramatic issue in a significant number of cases.

Respiratory viruses in children admitted to hospital intensive care units: evaluating the CLART® Pneumovir DNA array.

Viruses play a significant part in children's respiratory infections, sometimes leading to hospitalization in cases of severe respiratory distress. The aim of this study was to investigate respiratory infections in children treated in a hospital intensive care unit (ICU). Assays were performed using the CLART® Pneumovir DNA array assay (Genomica, Coslada, Madrid, Spain), which makes it possible to detect 11 genus of respiratory viruses simultaneously. During the winter of 2008-2009, 73 respiratory specimens collected from 53 children under 2 years of age and admitted to an ICU were tested. At least one virus was detected in 78% (57/73) of the samples. The virological diagnosis was based on single infections in 65% (37/57) and on multiple infections in 35% (20/57) of cases. The array assay revealed respiratory syncytial virus (RSV) in 73.6% (42/57) of the samples and rhinovirus in 24.6% (14/57), either on their own or in co-infections. All viruses identified in single and multiple infections were tested, taking into account clinical features, risk factors, and severity criteria. Children with no risk factors presented more multiple infections, up to 42% of cases, than children with at least one risk factor. RSV seemed to induce severe symptoms by itself as no difference in intubation needs was observed when RSV was detected on its own or in co-infection. The CLART® Pneumovir DNA array was useful for examining severe viral respiratory infections, when other viruses than those detected by conventional methods could be involved, particularly in an ICU.

[Role of neuraminidase inhibitors for the treatment of influenza A virus infections]. / Intérêts des inhibiteurs de la neuraminidase dans la prise en charge des infections dues aux virus influenza.

Oseltamivir and zanamivir are two neuraminidase inhibitors (NAIs) active on A and B influenza viruses. These analogues have been developed from the structure of sialic acid, the neuraminidase (NA) substrate. Resistance to NAIs have been detected. They are mainly associated to mutations located on the NA gene. The use of these antiviral drugs remains low in the context of seasonal flu, even the duration of symptoms can be reduced of one day if an antiviral treatment is started within 48 hours after disease onset. NAIs also present a significant effect when used in postexposition prophylaxis. Resistance, mainly to oseltamivir, have been detected but remained rare until the spontaneous emergence in 2007-2008 winter of a seasonal A(H1N1) variant resistant to this drug. NAIs are also interesting for the treatment of severe flu infections, specially those associated to A(H5N1). Finally, because of the pandemic A(H1N1)2009 virus, NAIs use has largely increased for prophylactic and therapeutic treatment of severe and non severe infections. This large use may be associated to an increased risk of selection of resistant viruses. Up to now, this phenomenon remains fortunately limited but has to be closely monitored.

Pandemic A(H1N1)2009 influenza virus detection by real time RT-PCR: is viral quantification useful?

The emergence of the influenza A(H1N1) 2009 virus prompted the development of sensitive RT-PCR detection methods. Most are real time RT-PCRs which can provide viral quantification. In this manuscript, we describe a universal influenza A RT-PCR targeting the matrix (M) gene, combined with an RNaseP RT-PCR. These PCRs allow the detection of all influenza A virus subtypes, including A(H1N1)2009, together with a real-time assessment of the quality of the specimens tested. These PCR procedures were evaluated on 209 samples collected from paediatric patients. Viral loads determined through Ct values were corrected according to the RNaseP Ct value. The mean viral load in the collected samples was estimated to be 6.84 log RNA copies/mL. For poor quality samples (RNaseP Ct > 27), corrections resulted in +3 to +8 Ct values for the M gene RT-PCR. Corrected influenza Ct values were lower in late samples. No correlation was established between viral loads and clinical severity or duration of disease.This study shows that real time RT-PCR targeting the matrix gene is a reliable tool for quantification of type A influenza virus but emphasises the need for sample quality control assessment through cellular gene quantification for reliable estimation of the viral load. This method would be useful for disease management when repeated specimens are collected from an infected individual.

Rhinoviruses delayed the circulation of the pandemic influenza A (H1N1) 2009 virus in France.

In contrast to the experience in other European countries, the onset of the A(H1N1)2009 influenza virus epidemic was unexpectedly slow in France during the first part of autumn 2009. Our objective was to test the hypothesis that intense circulation of rhinoviruses might have reduced the probability of infection by A(H1N1)2009 virus at the beginning of autumn 2009. Systematic analysis for the detection of A(H1N1)2009 (H1N1) and human rhinovirus (HRV) was performed by RT-PCR from week 36 to week 48 on respiratory samples sent to the diagnostic laboratory by the paediatric hospital (n = 2121). Retrospective analysis of the obtained data, using 2 x 2 contingency tables with Fisher's exact test, revealed evidence of an inverse relationship between HRV and H1N1 detection. Between weeks 36 and 48 of 2009, both HRV and H1N1 were detected but in different time frames. HRV dispersed widely during early September, peaking at the end of the month, whereas the H1N1 epidemic began during mid-October and was still active at the end of this survey. During the co-circulation period of these two respiratory viruses (weeks 43-46), HRV detection appeared to reduce the likelihood of H1N1 detection in the same sample (OR = 0.08-0.24 p <0.0001). These results support the hypothesis that HRV infections can reduce the probability of A(H1N1) infection. This viral interference between respiratory viruses could have affected the spread of the H1N1 viruses and delayed the influenza pandemic at the beginning of autumn in France.

Anti N1 cross-protecting antibodies against H5N1 detected in H1N1 infected people.

The A(H5N1) influenza virus pandemic may be the result of avian H5N1 adapting to humans, leading to massive human to human transmission in a context of a lack of pre-existing immunity. As A(H1N1) and A(H5N1) share the same neuraminidase subtype, anti-N1 antibodies subsequent to H1N1 infections or vaccinations may confer some protection against A(H5N1). We analysed, by microneutralization assay, the A/Vietnam/1194/04 (H5N1) anti-N1 cross-protection acquired either during A/New-Caledonia/20/99 (H1N1) infection or vaccination. In cases with documented H1N1 infection, H5N1 cross-protection could be observed only in patients born between 1930 and 1950. No such protection was detected in the sera of vaccinated individuals.