ECDC: Influenza Characterization – Sept 2014

Credit NIAID

 

# 9229

 

Although we tend to talk of seasonal H1N1, or H3N2 (or the B viruses) as individual entities – in truth within each subtype there are many clades and variants, and they are all evolving over time. The more `biologically fit’ strains tend to succeed, while less fit viruses fade away. 

 

Geographically, these viruses can vary widely, and so the dominate strains in Europe may differ from the dominant strains in North America or Asia.

 

Success for these strains is always fleeting, though,  as they leave behind varying degrees of immunity in their hosts and must either evolve or eventually die out for lack of susceptible hosts. 

 

All which makes the flu world dynamic and ever-changing, and presents a genuine challenge for vaccine manufacturers to stay ahead of. NIAID has a terrific 3-minute video that shows how influenza viruses drift over time, and why the flu shot must be frequently updated, which you can view at this link.

As flu vaccine formulations must be decided upon six months in advance of each flu season, public health agencies like the CDC, ECDC, the World Health Organization, Hong Kong’s CHP  (and others) spend considerable resources on influenza surveillance, looking for signs of any up-and-coming viral strains.

 

All of which brings us to the ECDC’s latest influenza virus characterization summary, that looks at the ongoing evolution of these seasonal strains over the past few months. As you will see, there are changes in the evolving fluscape that have necessitated a change to the next year’s Southern Hemisphere Flu shot composition.

 

Detailed PDF file

 

Influenza virus characterisation, Summary Europe, September 2014

During the 2013–14 season, A(H1N1)pdm09, A(H3N2), B/Victoria- and B/Yamagata-lineage influenza viruses co-circulated in EU/EEA Member States. The relative prevalence has varied between countries. The WHO Collaborating Centre in London received viruses with collection dates after 31 January 2014 from 21 EU/EEA countries.

Type A and type B viruses have been received at a ratio of approximately 10:1. A(H3N2) outnumbered A(H1N1)pdm09 viruses at a ratio of 1.4:1.

Recently circulating A(H1N1)pdm09 viruses, in Europe and worldwide, belonged to genetic subgroup 6B. Viruses in this subgroup are antigenically similar to the vaccine virus, A/California/07/2009.

Recently circulating A(H3N2) viruses have fallen within genetic group 3C represented by the recommended vaccine virus for the 2013–14 and 2014–15 seasons, A/Texas/50/2012. Antigenic analysis using antisera raised against cell-propagated H3N2 viruses indicates that the majority of circulating viruses are antigenically similar to those in circulation in the 2012–13 and 2013–14 influenza seasons, but those in a newly emerging genetic cluster, 3C.3a, are poorly recognised by some antisera.

Two genetic clades of B/Yamagata-lineage viruses continue to circulate: clade 3 represented by B/Phuket/3073/2013 and clade 2 represented by B/Massachusetts/02/2012 (the recommended vaccine component for the 2013–14 and 2014–15 influenza seasons). Viruses in clade 3 predominate in those samples collected since 31 January 2014.

Only two viruses of the B/Victoria-lineage were antigenically characterised since the July 2014 report. Neither was recognised well by the antiserum raised against the egg-propagated reference virus, A/Brisbane/60/2008, recommended as a component of quadrivalent influenza vaccines for 2013–14 and 2014–15 influenza seasons. Phylogenetic analysis revealed that all B/Victoria-lineage viruses received in 2014 were in genetic clade 1A, the B/Brisbane/60/2008 genetic clade.

In light of the emergence of antigenically distinct groups of influenza A(H3N2) and the altered prevalence of influenza B viruses, the WHO recommended composition of influenza vaccines for use in the 2015 southern hemisphere influenza season differed from that recommended for use in the 2014–15 northern hemisphere influenza season.

 

Remarkably, the H1N1 strains in circulation remain very stable, and antigenically similar to the vaccine virus which has been unchanged for five years (A/California/07/2009).  

The situation with the H3N2 viruses is more variable, with 7 distinct genetic groups detected since 2009, making vaccine strain selection more problematic. 

 

Since the fall 2014 vaccines strains were selected last February, surveillance has detected a rise in the number of antigenically drifted H3N2 isolates, prompting the WHO to recommend a strain change for next year.

The same can be said for recent detections of the Influenza B – Yamagata lineage of viruses, and so the WHO is recommending a change next year for the vaccine as well. 

How all of this will affect the performance of this year’s flu vaccine in the Northern Hemisphere is unknown.  If we see a heavy H1N1 year, then probably not much. Nor does the detection of these divergent strains in Europe guarantee when, or even if, we’ll see the same strains in North America.

 

There is always a degree of uncertainty over how good a match the vaccine will be when we enter a new flu season. But even when there is a less than a perfect match – the flu shot can offer significant levels of protection against a virus that claims thousands of American lives every year.  

 

As we’ve discussed before, flu vaccines – while considered very safe – most years can only offer a moderate level of protection against influenza. Their VE (vaccine effectiveness) can vary widely between flu shot recipients, and is often substantially reduced among those older than 65 or with immune problems.

 

Although the vaccine can’t promise 100% protection, it – along with practicing good flu hygiene (washing hands, covering coughs, & staying home if sick) – remains your best strategy for avoiding the flu (and other viruses) this winter.

ECDC Influenza Virus Characterization – June 2014

Credit NIAID

 

# 8889

 

Although we talk about seasonal flu strains like H1N1, H3N2, and influenza B as if they were single entities, in truth within each sub-type are numerous clades, sub-strains, and variants. 

 

These influenza viruses are constantly mutating (via antigenic drift) as they replicate and spread, and are engaged in a perpetual game of  viral king-of-the-mountain, as they jostle for dominance and superiority in the global community.

 

Success for these strains is always fleeting, though,  as they leave behind varying degrees of immunity in their hosts and must either evolve or eventually die out for lack of susceptible hosts.  All which makes the flu world dynamic and ever-changing, and presents a genuine challenge for vaccine manufacturers to stay ahead of.

 

To keep abreast of the changes to the flu strains in circulation, labs around the world send samples to the WHO Collaborating Centre in London for classification, and the ECDC publishes reports roughly once a month.  These reports can help give us some idea whether the strains contained the latest vaccine match up antigenically with those strains currently circulating.

 

As you might expect, given the diversity of flu strains in circulation, the best that can be hoped for is that the majority of viruses tested are antigenically similar to the components in the vaccine.  That said, we won’t really have a good idea of how well this year’s vaccine will perform until the flu season is over, next spring.

 

The summary is printed below.  The full report is available as a PDF File.

 

Influenza virus characterisation, June 2014

29 Jul 2014

Abstract

​During the 2013–14 season, A(H1N1)pdm09, A(H3N2), B/Victoria- and B/Yamagata-lineage influenza viruses have continued to co-circulate in EU/EEA Member States. The relative prevalence has varied between countries. Viruses with collection dates after 31 December 2013, from 22 countries, have been received by the WHO Collaborating Centre in London.

• Type A and type B viruses have been received at a ratio of nearly 20:1.
• A(H3N2) and A(H1N1)pdm09 viruses have been received in similar numbers.
• Recently circulating A(H1N1)pdm09 viruses belonged to genetic subgroup 6B. Viruses in subgroup 6B are antigenically similar to the vaccine virus, A/California/07/2009.
• Recently circulating A(H3N2) viruses have fallen within genetic group 3C represented by the recommended vaccine virus for the 2013–14 and 2014–15 seasons, A/Texas/50/2012, with viruses of genetic subgroup 3C.3 predominating. Antigenic analysis using antisera raised against cell-propagated H3N2 viruses indicates that the majority of circulating viruses are antigenically similar to those in circulation in the 2012–13 and 2013–14 influenza seasons. Antisera raised against two reference viruses representative of viruses in genetic subgroup 3C.3 – with HA gene sequences encoding several amino acid substitutions compared to other viruses in genetic group 3C.3 – have been prepared. These antisera recognised the majority of test viruses well.
• Two genetic clades of B/Yamagata-lineage viruses continue to circulate: clade 3 represented by B/Wisconsin/1/2010 and clade 2 represented by B/Massachusetts/02/2012 (the recommended vaccine component for the 2013–14 and 2014-15 influenza seasons). Viruses in each clade have been received in similar numbers but with viruses in clade 3 predominating in those samples collected in 2014.
• Antigenic characterisation of two viruses of the B/Victoria lineage was performed in June. Neither virus was recognised well by the antiserum raised against the egg-propagated reference virus, A/Brisbane/60/2008, a virus previously recommended as a component of the trivalent influenza vaccine and recommended as a component of quadrivalent influenza vaccines for 2013–14 and 2014–15 influenza seasons. The test viruses were not recognised well by antisera raised against other reference viruses propagated in eggs. The test viruses were better recognised by some, but not all, antisera raised against reference viruses exclusively propagated in cells. Phylogenetic analysis revealed that all B/Victoria-lineage viruses received in 2014 were in genetic clade 1A, the B/Brisbane/60/2008 genetic clade.

ECDC: Influenza Virus Characterization Sept-Dec 2013

 

Photo Credit NIAID

 

# 8154

 

The ECDC publishes a periodic review of recently isolated flu viruses in the EU they call an Influenza Virus Characterization Report. The last one we looked at was in August (see ECDC: Influenza Virus Characterization – July 2013), and the news ;last summer was pretty good; the majority of the viruses analyzed still appeared to be antigenically similar to those in this year’s vaccine.

 

While flu season is going full steam in North America, flu reports from the EU indicate a much later start to the season.  Additionally, while we are seeing a season heavily dominated by the pH1N1 virus, in Europe it is the H3N2 virus that leads the way.

 

While we talk about the four main strains of influenza that are currently circulating in humans (A/H1N1(pdm), A/H3N2, B Victoria, B Yamagata) as if they were single entities - in reality – within each strain, you will find a good deal of diversity. New `prototypes’ from  these strains are constantly being generated (mostly by antigenic drift) and `field tested’ for biological fitness and transmissibility.

 

Most are evolutionary failures.

 

But since decisions regarding what strains to include in the next flu vaccine must be made 6 months in advance, it is important to detect any new `trends’  among the flu viruses in circulation.  Which is why scientists must monitor these viruses constantly.

 

Today the ECDC has published a new influenza characterization report, that like the last one, finds most of the viruses tested still antigenically similar to the vaccine strains.  But they do report several new H3N2 samples with specific HA amino acid substitutions, and that `antigenic characterization is pending’.

 

Here then is the summary of today’s report, with a link to the full document.

 

Influenza virus characterisation report for Europe: September to December 2013

10 Jan 2014

​The latest issue of ECDC’s series on 'Influenza virus characterisation’ covers the time period since 1 September 2013.

Indicative of the late start of the 2013-14 influenza season, a low number of 46 influenza-positive specimens have been received from six EU/EEA countries so far in WHO Collaborating Centre for Reference and Research on Influenza in London.

 

Influenza type A viruses (91%) are dominating over type B (9%), as is often seen at the beginning of Northern Hemisphere influenza seasons. For type A, H3N2 viruses have been received in greater numbers than H1N1pdm09 viruses, with the ratio of 2:1.

The report further summarises the findings as follows:

• Compared to the 2012–13 influenza season where genetic subgroup 6C dominated among A(H1N1)pdm09 viruses, and based on the current global situation, genetic subgroup 6B viruses have been detected in increasing frequency. Subgroup 6B viruses have been antigenically similar to the vaccine virus, A/California/07/2009.
• Recently circulating A(H3N2) viruses have fallen within genetic subgroup 3C represented by the recommended vaccine virus for the 2013–14 season, A/Texas/50/2012; some new genetic clusters defined by specific HA amino acid substitutions have been observed for which antigenic characterisation is pending.
• No B/Victoria-lineage viruses have been received to date.
• Two genetic clades of B/Yamagata-lineage viruses continue to circulate: clade 3 represented by B/Wisconsin/1/2010 and clade 2 represented by B/Massachusetts/2/2012 (the recommended vaccine component for the 2013–14 influenza season). The great majority of recently circulating viruses fall within clade 2.

The report is prepared under ECDC framework contract and is based on analysis of influenza-positive specimens received by the MRC National Institute for Medical Research, the WHO Collaborating Centre for Reference and Research on Influenza in London.

ECDC: Influenza Virus Characterization – July 2013

Photo Credit NIAID

 

 

# 7537

 

 

As summer moves inexorably towards fall, those of us in the northern hemisphere begin to think about the upcoming flu season, and just how good of a match this year’s flu vaccine will turn out to be.

 

It requires 6 months of lead time to develop, manufacture, and distribute the yearly seasonal influenza vaccine. During that time it is possible that the strains in circulation can drift antigenically (or change completely) from the strains selected last February for the vaccine.

 

NIAID has a terrific 3-minute video that shows how influenza viruses drift over time, and why the flu shot must be frequently updated, which you can view at this link.

So we watch surveillance reports - like those coming from the CDC’s FluView and the ECDC’s  monthly Virus characterization reports – for any signs that there’s a `new flu’ in town.

 

Today, the ECDC released their latest Influenza Virus Characterization report (for July 2013).

 

While antigenic changes continue to show up in both influenza A/H1N1 and A/H3N2, the good news is – the majority of the viruses being analyzed still appear to be antigenically similar to those in this year’s vaccine. The influenza B vaccine strain also appears to be a good match for the bulk of the B viruses tested.

 

This year, you can get a little added protection, as  a new quadrivalent (4 strain) vaccine will be available which can help protect you against both (Yamagata & Victoria) influenza B strains.

 

This Abstract from the ECDC, follow the link to read the entire report.

 

 

Influenza Virus Characterisation, July 2013

Surveillance reports - 02 Aug 2013

Available as PDF in the following languages:

This document is free of charge.

ABSTRACT

In the course of the 2012–13 season, A(H1N1)pdm09, A(H3N2) and B/Victoria- and B/Yamagata-lineage influenza viruses have co-circulated in ECDC-affiliated countries over what was an extended influenza season. The relative prevalences of each virus type/subtype has varied between countries.

• Type A and type B viruses have been detected in similar proportions but with type A peaking and declining slightly before type B.

• A(H1N1)pdm09 viruses have been detected at approximately twice the level of A(H3N2) viruses.

• The vast majority of A(H1N1)pdm09 viruses have remained antigenically similar to the vaccine virus, A/California/07/2009, but continued to show genetic drift with an increasing prevalence of genetic group 6 viruses.

• The vast majority of A(H3N2) viruses have been antigenically and genetically similar to cell-propagated A/Victoria/361/2011, a genetic group 3C virus and the prototype vaccine virus for the 2012–13 influenza season; group 3C viruses have circulated exclusively in recent months and the recommended vaccine virus for the 2013–14 season, A/Texas/50/2012, is in this genetic group.

• Viruses of the B/Yamagata-lineage have predominated over those of the B/Victoria-lineage.

• B/Victoria-lineage viruses have remained antigenically similar to cell-propagated reference viruses of the B/Brisbane/60/2008 genetic clade.

• B/Yamagata-lineage viruses formed two antigenically distinguishable genetic clades: clade 3 represented by B/Wisconsin/1/2010 (the recommended vaccine component for the 2012–13 influenza season) and, in increasing numbers, clade 2 represented by B/Massachusetts/2/2012 (the recommended vaccine component for the 2013–14 influenza season).

CIDRAP: Yesterday’s H7N9 Studies In Nature

 

 

# 7469

 

 

Last night, in Nature: H7N9 Pathogenesis and Transmissibility In Ferrets & Mice, we looked at the first of two H7N9 studies that appeared yesterday in the journal Nature.  

 

This morning my intent had been to examine the second paper, but quite frankly, Lisa Schnirring at CIDRAP News did such a great job covering both studies last night, the only sensible thing is to direct you to her report.

 

Lisa includes expert commentary on these two studies by Marion Koopmans, DVM, PhD, with the National Institute of Public Health and the Environment in the Netherlands and Michael T. Osterholm, .PhD, MPH, Director of CIDRAP.

 

 

New studies on H7N9 raise pandemic concerns

Lisa Schnirring | Staff Writer | CIDRAP News

Jul 10, 2013

 

iStockphoto

Two new studies found limited spread of the new H7N9 flu virus via respiratory droplets. About a third of ferrets were infected via that route.

Two research teams that conducted a massive number of experiments on the new H7N9 influenza virus found more signs that it could be a pandemic virus, though their animal tests showed that its ability to spread through coughs and sneezes isn't as robust as seasonal flu.

 

The two studies are among several recent efforts to assess the threat from the new virus, which infected 134 people, 43 of them fatally, before tapering off in early June. Experts aren't sure if the virus has died out or if it has temporarily retreated due to warmer weather and perhaps the effects of outbreak response measures aimed at live-poultry markets in some of China's biggest cities.

 

Both studies were published in the same issue of Nature. One of the teams is from Japan and the University of Wisconsin, Madison, lab of Yoshihiro Kawaoka, DVM, PhD. That team conducted several types of tests and comparisons on two novel H7N9 strains from China, an earlier avian H7N9 strain, and the 2009 H1N1 virus. They also examined how the new virus behaves in mice, ferrets, miniature pigs, macaques.

 

The second group includes scientists from the US Centers for Disease Control and Prevention (CDC), which also studied two novel H7N9 strains from China, focusing on how it infects human cells and how it spreads in ferrets and mice.

 

(Continue . . . )

 

Watanabe T, Kiso M, Fukuyama S, et al. Characterization of H7N9 influenza A viruses isolated from humans, letter. Nature 2013 Jul 10 [Abstract]

 

Belser JA, Gustin KM, Pearce MB, et al. Pathogenesis and transmission of avian influenza A (H7N9) virus in ferrets and mice, letter. Nature 2013 Jul 10 [Abstract]

 

ECDC: Influenza Virus Characterization Summary

 

# 7426

 

The only real constant with influenza strains is that they are constantly changing. As viruses, they leave behind (varying degrees) of immunity in every host they infect. Were they not to change, they would eventually run out of susceptible hosts.

 

Influenza viruses evolve via two well established routes; Antigenic drift & Antigenic Shift (reassortment).

 

Antigenic drift causes small, incremental changes in the virus over time. Drift is the standard evolutionary process of influenza viruses, and often come about due to replication errors that are common with single-strand RNA viruses.

 

Shift occurs when one virus swap out chunks of their genetic code with gene segments from another virus. This is known as reassortment. While far less common than drift, shift can produce abrupt, dramatic, and sometimes pandemic inducing changes to the virus.

 

And while we talk about the four main strains of influenza that are currently circulating in humans (A/H1N1(pdm), A/H3N2, B Victoria, B Yamagata) as if they were single entities - in reality – within each strain, you will find a good deal of diversity.

 

New `prototypes’ from  these strains are constantly being generated (mostly by antigenic drift) and `field tested’ for biological fitness and transmissibility.

 

Most are evolutionary failures.

 

But occasionally, a new, biologically fit virus will emerge that can compete with its parental strains, and it begins to spread.

 

NIAID has a terrific 3-minute video that shows how influenza viruses drift over time, and why the flu shot must be frequently updated, which you can view at this link.

 

 

As flu vaccine formulations must be decided upon six months in advance of each flu season, public health agencies like the CDC, ECDC, the World Health Organization, Hong Kong’s CHP  (and others) spend considerable resources on influenza surveillance, looking for signs of any up-and-coming viral strains.

 

All of which brings us to the ECDC’s latest influenza virus characterization summary, that looks at the ongoing evolution of these seasonal strains over the past 6 months.

 

Influenza virus characterisation: Summary Europe, December 2012 to May 2013

26 Jun 2013

ECDC

The latest issue of ECDC’s monthly series on 'Influenza virus characterisation’ covers the time period from 1 December 2012 to 31 May 2013, spanning the entire 2012-13 season.

 

It is prepared by the European Reference Laboratory Network for Human Influenza (ERLI-Net). Until June 2013, ERLI-Net was called the Community Network of Reference Laboratories for Human Influenza in Europe (CNRL).

 

During the 2012–13 season, A(H1N1)pdm09, A(H3N2) and B/Victoria- and B/Yamagata-lineage influenza viruses have been detected in ECDC-affiliated countries. The relative prevalences varied between countries.

The report summarises the findings as follows:

• Type A and type B viruses have continued to co-circulate in similar proportions.
• A(H1N1)pdm09 viruses have been detected at comparable levels to A(H3N2) viruses.
• A(H1N1)pdm09 viruses continued to show genetic drift from the vaccine virus, A/California/07/2009, but the vast majority remained antigenically similar to it.
• The vast majority of A(H3N2) viruses have been antigenically and genetically similar to cell-propagated A/Victoria/361/2011, the prototype vaccine virus for the 2012–13 influenza season.
• Viruses of the B/Yamagata lineage predominated over those of the B/Victoria lineage.
• B/Victoria lineage viruses were antigenically similar to cell-propagated reference viruses of the B/Brisbane/60/2008 genetic clade.
• Recent B/Yamagata-lineage viruses fell into two antigenically distinguishable genetic clades: clade 2, represented by B/Estonia/55669/2012, and clade 3, represented by B/Wisconsin/1/2010 (the recommended vaccine component for the 2012–13 influenza season).

For further details, download the complete report 'Influenza virus characterisation - Summary Europe, May 2013'.

 

Last February the World Health Organization met with influenza expert from around the globe to decide on this fall’s flu vaccine composition.  Their decision:

 

Recommended composition of influenza virus vaccines for use in the 2013-14 northern hemisphere influenza season

21 February 2013

It is recommended that trivalent vaccines for use in the 2013-14 influenza season (northern hemisphere winter) contain the following:

• an A/California/7/2009 (H1N1)pdm09-like virus^a;
• an A(H3N2) virus antigenically like the cell-propagated prototype virus A/Victoria/361/2011^b*;
• a B/Massachusetts/2/2012-like virus.

It is recommended that quadrivalent vaccines containing two influenza B viruses contain the above three viruses and a B/Brisbane/60/2008-like virus^c.

 

^a A/Christchurch/16/2010 is an A/California/7/2009-like virus;
^b A/Texas/50/2012 is an A(H3N2) virus antigenically like the cell-propagated prototype virus A/Victoria/361/2011;
^c B/Brisbane/33/2008 is a B/Brisbane/60/2008-like virus.

 

* It is recommended that A/Texas/50/2012 is used as the A(H3N2) vaccine component because of antigenic changes in earlier A/Victoria/361/2011-like vaccine viruses (such as IVR-165) resulting from adaptation to propagation in eggs.

 

It is always difficult – six months in advance – to predict which flu strains are likely to predominate in the upcoming flu season. Some years the vaccine is a good match, other years, not so much.

 

The good news is that despite the inevitable evolution of the flu strains in circulation, so far, the vast majority of those tested by the ECDC are described as being antigenically similar to the components of this year’s flu vaccine.

ECDC Influenza Virus Characterization

# 6784

 

The only constant with influenza viruses is their ability to change over time. Since immune systems can learn to recognize and defeat previously seen viral infections, they would soon run out of susceptible hosts if they could not continually evolve.

 

Most of the time, these changes are incremental, and are due to a process called Antigenic drift. Drift comes about due to replication errors that are common with single-strand RNA viruses.

 

Over time these minor changes can accumulate to the point that previously infected immune systems will fail to recognize it, giving the virus a fresh supply of hosts. 

 

NIAID has a nice 3-minute video illustrating the process, which you can view on their Youtube Channel or in the box below.

 

 

 

So, while we talk about seasonal A/H3N2 or A/H1N109 as if they are single entities, in truth, there are a good many minor variations on each theme circulating around the world.

 

Within each strain, we can see numerous `clades’, or genetically distinct groups.  We watch the formation, and progress of these clades carefully, since they may eventually require a change in the flu vaccine’s formulation.

 

Roughly once a month the ECDC releases an influenza virus characterization report, providing laboratory analysis of recently collected flu virus samples across Europe. Collection dates only extend through week 39, but this latest ECDC report indicates continued diversity among the viruses in circulation.

 

The vast majority of flu viruses identified (68%) were of the type A/H3N2. Relatively few A/H1N1 viruses were collected.

 

Among the influenza B viruses received, samples were pretty evenly divided between the Victoria lineage (included in last year’s vaccine) and the Yamagata lineage (part of this year’s vaccine).

 

 

Here’s the link to their report, and the abstract.

 

Influenza virus characterisation - Summary Europe, November 2012

Surveillance reports - 14 Dec 2012

Available as PDF in the following languages:

 

ABSTRACT

During the 2011/2012 season, A(H1N1)pdm09, A(H3N2) and B/Victoria and B/Yamagata lineage influenza viruses, with collection dates between 1 January and 30 September 2012 (weeks 1–39), have been detected in ECDC-affiliated countries.

• Type A viruses predominated over type B.
• A(H3N2) viruses predominated over A(H1N1)pdm09 viruses.
• A(H1N1)pdm09 viruses continued to show genetic drift from the vaccine virus, A/California/07/2009, but the vast majority remained antigenically similar to it.
• Antigenic drift of A(H3N2) viruses compared to the A/Perth/16/2209 vaccine virus resulted in a recommendation to change to an A/Victoria/361/2011-like component for the 2012/2013 influenza season.
• B/Victoria lineage viruses fell within the B/Brisbane/60/2008 genetic clade and were antigenically similar to reference cell-propagated viruses of the B/Brisbane/60/2008 genetic clade.
• Recent B/Yamagata-lineage viruses fell into two genetic clades in approximately equal proportions: clade 3 represented by the recommended vaccine component for the 2012/2013 influenza season, B/Wisconsin/1/2010, and clade 2 represented by B/Estonia/55669/2012. Viruses in each clade are antigenically distinguishable.

 

 

The split between clade 2 and clade 3 of the Yamagata B virus lineage bears watching, and A/H3N2 shows the most variety with samples falling into 5 distinct genetic groups.

 

The good news, despite this growing diversity among flu viruses, is that the majority of those collected in Europe through week 39 still appear antigenically similar to this year’s vaccine strains.