virology blog – Page 4

Trial By Error: BBC’s Problematic Coverage of New Long COVID Study

3 October 2021 by David Tuller

By David Tuller, DrPH

Since the start of the coronavirus pandemic, suggesting an equivalence between COVID-19 and influenza has been a consistent approach among those seeking to downplay the current situation. So it’s not surprising to see something similar happen with comparisons between Long COVID and the delayed recovery some people experience after an acute bout of the flu. The BBC has just provided an excellent example of how this framing can appear to minimize the significance of Long COVID.

An article in PLoS Medicine, published on September 28^th, offered a look at Long COVID symptoms based on data from US electronic health records. The study, called “Incidence, co-occurrence, and evolution of long-COVID features: A 6-month retrospective cohort study of 273,618 survivors of COVID-19,” tracked nine key symptom clusters: “breathing difficulties/breathlessness, fatigue/malaise, chest/throat pain, headache, abdominal symptoms, myalgia, other pain, cognitive symptoms, and anxiety/depression.”

Gain of function to build therapeutically useful viral vectors

30 September 2021 by Vincent Racaniello

Another excellent example of gain of function research is modification of a viral vector to make it more useful for human gene therapy.

Adenovirus associated virus (AAV) is the most commonly used vector for a variety of gene therapy applications, including gene replacement and gene editing. These small viruses, which comprise a single-stranded DNA genome surrounded by an icosahedral protein shell (illustrated), have a number of features that make them useful for gene therapy, including easy manipulation and growth in large quantities, and induction of persistent gene expression for long periods of time. An example is the drug Luxturna which is an AAV vector containing a retinal pigment gene that is used to treat some forms of blindness.

Naturally occurring AAV vectors have some limitations, including the propensity to become sequestered in the liver after systemic injection. Consequently reaching other organs with AAV vectors requires injection of large amounts of recombinant virus, which may be accompanied by toxicity.

A number of approaches have therefore been developed to modify AAV vectors so they preferentially infect other tissues. A number of muscle diseases would benefit from gene therapy and therefore AAV vectors have been developed to target that tissue. In one approach that I described before, ancestral AAV viruses were recovered and shown to efficiently infect muscle cell types.

A more recent approach involved modifying the AAV genome by inserting random stretches of 7 amino acids into the viral capsid protein, infecting mice with large libraries of these variants, and identifying those that best infect muscle. In addition, muscle-specific promoter sequences were also incorporated in the viral genome. After multiple rounds of infection of mice, recovery of viruses from muscle and reinfection, capsids were identified that more efficiently infect muscle tissue and less efficiently infect liver, in multiple mouse strains and in nonhuman primates. The new AAV capsids can rescue two different types of muscle disease in mice: Duchenne muscular dystrophy and X-linked myotubular myopathy after intramuscular inoculation.

The ability of these new AAV vectors to preferentially infect muscle cells depends on the presence of three added amino acids in the viral capsid, RGD. This three amino acid motif is known to bind cell surface proteins called integrins. Indeed, the increased efficiency of these engineered vectors depends on the presence of integrins on target cells.

These findings not only have produced better AAV vectors for targeting muscle tissue, but establish a strategy to engineer viruses to preferentially infect any tissue. The new vectors are the product of gain of function research: the original AAV has been given new properties. This work constitutes another example of the broad potential benefits of gain of function research in virology.

Trial By Error: Good Long Covid Coverage from Atlantic; Skeptical Coverage from New Yorker and Others

24 September 2021 by David Tuller

By David Tuller, DrPH

On September 1st, The Atlantic published another excellent piece by Ed Yong—“Long-haulers are fighting for their future.” In exploring how this population has confronted widespread misunderstanding in the medical community, the article highlighted the links between the experiences of Long Covid and ME/CFS patients by focusing on the crucial symptom of post-exertional malaise. That led to discussion of the PACE trial, which investigated both graded exercise therapy and cognitive behavior therapy as ME/CFS treatments but was marred by methodological and ethical flaws. (The main results appeared in The Lancet in 2011.)

SARS-CoV-2 related viruses from bats in Laos

23 September 2021 by Vincent Racaniello

Various SARS-CoV-2 like viruses have been isolated from bats in China, Thailand, and Japan, but none have a spike protein that can bind ACE2 and allow entry into human cells. Sampling of bats in Laos has now revealed the presence of such viruses.

The genome of a virus called RaTG13, from Rhinolophus affinis bats in China, is the closest to SARS-CoV-2 (although infectious RaTG13 has never been isolated). However the spike receptor binding domain (RBD) encoded in this genome has low sequence similarity with that of SARS-CoV-2 and its affinity for ACE2 is very limited. RaTG13 is clearly not the proximal ancestor of SARS-CoV-2.

Sampling of 645 bats from limestone caves in Northern Laos (see map) yielded three Sarbecovirus genomes, called BANAL-52, -103, and -236, with high sequence similarity to SARS-CoV-2 and RaTG13. These three viral genomes were obtained from three different Rhinolophus species. Of the 17 amino acids that interact with the receptor binding domain of ACE2, 16 are conserved between SARS-CoV-2 and BANAL-52 or -103, and 15/17 conserved with BANAL-236. In contrast, only 11/17 RBD amino acids are conserved among SARS-CoV-2 and RaTG13. In other words, the RBD encoded in these BANAL genomes are closer to SARS-CoV-2 than that of any other known bat virus.

Binding affinity assays done with purified proteins revealed that the BANAL-52/103 and -236 spikes bind ACE2 with affinities in the low nanomolar range, comparable to reported values for the SARS-CoV-2 spike.

Lentiviral particles with the spike protein from BANAL-236 were able to bind and enter human cells producing ACE2. Entry of this virus was blocked by human sera containing antibodies to SARS-CoV-2 but not by control sera.

Infectious BANAL-236 virus was recovered from a bat fecal swab after inoculation of Vero cells, providing a rare virus isolate for a bat SARS-CoV-2 like virus. The virus will be useful for studying the biology of infection.

Recombination analysis demonstrated that the SARS-CoV-2 genome is a mosaic of at least five different genomes, including BANAL-52, -103, and -236, and the previously published RmYN02, RpYN06, and RaTG13, the latter all discovered in China. The implication of these observations is clear: SARS-CoV-2 likely arose from recombination of viruses circulating in different species of Rhinolophus bats in the limestone caves of South China and Southeast Asia. Because the RBD of the BANAL isolates can mediate binding to and entry into cells that produce ACE2, no host to host passage need be hypothesized to explain increased RBD affinity in an intermediate host before spillover into humans.

The spike proteins encoded in the BANAL isolates do not have the furin cleavage site found in the protein from SARS-CoV-2. Such sites might be present in viruses within these bat communities, but were missed due to insufficient sampling. Alternatively, it is possible that selection for the furin cleavage site occurred after spillover into humans or another intermediate host.

These findings further emphasize and demonstrate that SARS-CoV-2 came from Nature, not from a lab.

Trial By Error: Advocates Propose Fixes to Dysfunctional US Coding System for ME, CFS and ME/CFS

20 September 2021 by David Tuller

By David Tuller, DrPH

I have been focused lately on the continuing saga of the hijacked-and-still-unpublished ME/CFS clinical guidelines (HSUME/CFSCG) from Britain’s National Institute for Health and Care Excellence (NICE). The fate of the HSUME/CFSCG will apparently be addressed at an October so-called “roundtable” meeting of NICE and representatives from relevant interest groups. (I’m not sure what makes it a “roundtable” meeting or what the word “roundtable” is supposed to convey about the tenor of these HSUME/CFSCG proceedings.)

Anyway, while I’ve been focused on the HSUME/CFSCG, other stuff has been happening—like deliberations over proposed changes in how the US medical system should code the disease or diseases included under the constructs of ME, CFS, and ME/CFS. The US uses its own adapted version of the International Classification of Diseases (ICD), with is now in its tenth revision and continues to get updated.

A zero time point is essential

16 September 2021 by Vincent Racaniello

The recent release of grant materials from EcoHealth Alliance pertaining to their research with the Wuhan Institute of Virology has been used to demonstrate that gain of function research was funded by the NIH. This conclusion is correct, although not all the experiments done would fall into this category.

One of the figures from the released grant materials shows the results of two experiments using recombinant SARS-like coronaviruses that were constructed in the laboratory. As I described previously, after the SARS-CoV pandemic of 2003, wildlife sampling efforts in China revealed many SARS-like coronaviruses in bats. To assess the potential of these viruses for infecting humans, their spike protein encoding genes were substituted into the SARS-like CoV WIV1.

The reproduction of these recombinant viruses were assessed in two experimental systems. ACE2 transgenic mice were inoculated with the recombinant viruses to assess their pathogenic potential, by measuring weight loss. The results (figure below, left panel) show that only one recombinant virus, carrying the spike gene from SHC014, caused more rapid weight loss than did WIV-1. Hence, SCH014 has a gain of function. However the recombinant virus 4231 caused the same rate of weight loss as WIV-1 and therefore does not have a gain of function. Recombinant virus WIV-16 caused no weight loss – its curve resembles that of uninfected mice – and therefore this virus has a loss of function.

The second experiment is not, in my opinion, proof that any of these recombinant viruses have gained a new function. The experiment was to infect ACE2 transgenic mice with WIV1 and the three recombinant viruses, and then remove lung tissue at different times after infection and determine viral RNA loads. The first problem with this experiment is that RT-PCR was used to measure viral RNA loads, which does not directly measure viral infectivity. Therefore it cannot be concluded that any of the viruses reproduced to higher levels than WIV1. More problematic is that there is no time zero – the measurement of lung tissues begins at day 2. Consequently, one cannot reliably compare viral RNA loads of any of the recombinant viruses with WIV1. When doing kinetic experiments, a time zero is ALWAYS needed, so you can see how much virus was actually instilled in the mice. It gives you a baseline from which to compare subsequent time points. Even though the authors state the amount of virus added to the mice, they do not know how much was actually added. Operator error, binding to tissues, and a host of other factors can interfere early in the infection. For example, it is possible that the viral RNA loads on day 0 were the same as in subsequent time points, which showed little change over the course of the experiment. One cannot conclude from this experiment anything about the viral RNA loads without a time zero. No viruses gained any function in this experiment.

Unfortunately, many expert virologists do not have a problem with the absence of time zero. When I spoke to a reporter about these results, and told her my interpretation, she told me other ‘experts’ did not agree with me. You will find many examples of published time courses without a time zero – they are worthless.

Why the difference between virology experts? I was trained to always have a time zero; the others were not. They continue to get away with it so they believe it is correct. It is not proper research practice and no amount of arguing will make it right.

Trial By Error: An Updated Letter to the NICE Chief Executive About the Unpublished ME/CFS Guideline

15 September 2021 by David Tuller

By David Tuller, DrPH

I sent the following letter today to Professor Gillian Leng, chief executive of the National Institute for Health and Care Excellence (NICE). It was a follow-up to the letter I sent on September 1st about the agency’s decision to delay publication of it new ME/CFS guidelines. The letter has now been signed by more than 150 experts and more than 100 UK and international charities, support groups and other relevant organizations.

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Trial By Error: More Science-as-Promotion from the GET Campaigners

14 September 2021 by David Tuller

By David Tuller, DrPH

Professor Trudie Chalder, Professor Peter White and like-minded members of the CBT/GET ideological brigades have appeared desperate in the last year to promote their favored interventions, publishing one shoddy paper after another. This stream of sewage has seemed intended to influence the new ME/CFS clinical guidelines that Britain’s National Institute for Health and Care Excellence (NICE) has been developing since 2017. NICE called off the scheduled August 18^th publication of the new guidelines, which formally reject the longstanding treatment paradigm for ME/CFS, because of fierce objections from the cabal of CBT/GET true believers.

Gain of function research explained

9 September 2021 by Vincent Racaniello

The term ‘gain of function’ is perhaps one of the most misunderstood in the scientific lexicon. I would like to explain what the phrase means from the perspective of a scientist who has done gain of function research for the past 40 years.

Gain of function (GoF) research gives an organism a new property or enhances an existing one. The organism can be a virus, bacterium, fungus, rodent, bird, fish or anything that can be experimentally manipulated (technically whales and elephants could be included in the definition but it would be very difficult to to GoF research on them).

Many have the impression that GoF research involves making an organism more deadly – for example, increasing the capacity of a virus to cause disease. That impression is incorrect. Certainly GoF research might lead to a more dangerous organism, but most of the time that is not the goal.

There are two broad approaches to GoF research. I’ll illustrate them with viruses but the principles could apply to any organism. In one approach, a virus is passaged in a host until a virus with different properties is obtained. An example is the adaptation of a strain of poliovirus – the type 2 Lansing strain – to replicate in mice and paralyze them. The Lansing strain does not infect mice, but an investigator passed the virus 99 times from mouse to mouse and ended up with a new strain that could now paralyze the mice. The new version of the virus had a new property – it could now infect mice. This experiment was GoF research.

Another way to do GoF research is to use recombinant DNA technology to engineer changes in the genome of the organism. In experiments done in my laboratory, we took a small piece of the genome of the mouse-adapted Lansing strain of poliovirus – coding for just eight amino acids – and spliced it into the genome of another poliovirus that is unable to infect mice. The recombinant virus from this experiment had a new property – the ability to infect mice. This experiment would also be classified as GoF.

An illustration of how GoF can be done on mice is our creation of transgenic mice susceptible to poliovirus. Mice cannot be infected with the virus because they do not produce the cell receptor for poliovirus. We introduced the human poliovirus receptor gene into the mouse germline, leading to mice that produce poliovirus receptor. After infection, these poliovirus receptor transgenic mice can be infected with poliovirus and develop paralysis. The mice have a new property – susceptibility to poliovirus infection. The mice are a product of a GoF experiment.

GoF research may have a myriad of useful outcomes. Do you want to make a different tasting beer? Modify an enzyme in the yeast used for fermentation. But in the past 30 years GoF research has received a bad name. The catalyst was a series of experiments on highly pathogenic avian H5N1 influenza viruses. These viruses rarely infect humans and do not transmit well among people. In experiments to understand what limited transmission, the virus was genetically modified and passaged among ferrets. The result was a virus that could transmit among ferrets by respiratory droplets. These GoF experiments were met with criticism, entirely unwarranted as the passaged viruses had lost their virulence for ferrets! Nevertheless since then a dark cloud has unjustifiably hung over all GoF research.

GoF research has been in the press again recently as a consequence of the COVID-19 pandemic. After the SARS-CoV pandemic of 2003, wildlife sampling efforts in China revealed many SARS-like coronaviruses in bats. To assess the potential of these viruses for infecting humans, their spike protein encoding genes were substituted into the SARS-like CoV WIV1. These recombinant viruses reproduced in human airway cells – no different from WIV1 – but at least one caused more severe disease in mice. Consequently these are GoF experiments. Some have suggested that such GoF work gave rise to SARS-CoV-2 in a lab, but this notion is impossible, as none of these viruses are close enough to be a precursor of the current pandemic virus.

The production of recombinant coronaviruses to assess pandemic potential was carried out in several laboratories, all funded by the NIH. Recently Dr. Anthony Fauci told Congress that the NIH did not fund GoF coronavirus research. The press has suggested that he lied, but the truth is that his definition of GoF research is that it only involves passaged of organisms in animals. This interpretation is not correct but being wrong does not mean you are lying.

I want readers to understand that the goals of GoF research are laudable, and only a small subset has the potential to harm humans. Consequently these experiments are highly regulated and carried out under high levels of biological containment. GoF is not a dirty word.

Trial By Error: Jennie Spotila’s Annual Fact-Check of NIH Spending on ME/CFS Research

7 September 2021 by David Tuller

By David Tuller, DrPH

There is a lot going on in the ME and ME/CFS world that I don’t get around to. That’s why I’m always grateful that Jennie Spotila always deconstructs the numbers on the annual spending claims from the National Institutes of Health. Last month, on her blog Occupy M.E., Spotila submitted the NIH’s 2020 numbers to her usual sharp analysis. I am reposting it in full here with her permission.

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