In the last 3 years, an exhaustive amount of research has been carried out to elucidate the precise events that directly cause progression of COVID from an early mild acute illness in the first few days, to a severe/fatal form in a subset.

Two specific early events key to such progression have been identified:

The first key event identified is the early interaction between SARS-CoV-2 and megakaryocytes (MKs) in the bone marrow.

PMID: 36920790, 35708858

If MKs are infected by SARS-CoV-2, the patient is anticipated to progress to severe COVID in the ensuing days.

Vice versa, if MKs remain uninfected, the patient is expected to experience a mild course and recover.

PMID: 35708858

The other key event that is thoroughly well-established to drive severe COVID is:

The early production of a distinct form of antibody against the spike protein ("afucosylated") that delivers a double blow to the host ...

PMID: 33361116

Multiple studies have shown this phenomenon.

That the *quality* of antibodies produced early on in response to SARS-CoV-2 spike protein differs between individuals, and this variation determines the fate of the patient.

PMID: 33361116, 33979301, 35040666

In fact, the detection of a distinct form of anti-spike IgG *early* in the illness accurately predicts who progresses to severe disease in the ensuing days, and who doesn’t progress and experiences only a mild illness.

IgG antibody structure comprises of:

(1) antigen-binding region (“Fab”), where antigens such as spike protein are recognized and bound, and …

(2) a tail region (“Fc”) that interacts with cell surface receptors called “Fc receptors.”

These Fc receptors are found on the surface of various immune cells and platelets, which exert immune actions against the antigen recognized by the IgG.

In the Fc regions of IgG, there are specific sites (at Asparagine 297) where modifications called “glycosylation” can change the inflammatory capability of each IgG.

For instance, the addition of a “fucose” moiety to this site on the Fc region would create a less inflammatory IgG.

90% of all IgGs in humans are formed this way, containing a fucose moiety, and referred to as “fucosylated” IgGs.

On the other hand (and of relevance to COVID), the lack of fucose in the Fc region of IgG, brings about an *intensely* inflammatory quality to the antibody.

IgGs lacking fucose (“afucosylated” IgGs) have a 100-fold *higher* affinity for the FcyRIlla receptors on immune cells.

This translates into an extremely intense activation of monocytes, macrophages, NK and dendritic cells — all of which are then recruited to attack the antigen recognized and bound by the antibody.

Our immune system relies on fucosylated IgGs — with much lower inflammatory quality than the afucosylated ones — to respond to a vast majority of infectious pathogens.

Afucosylated IgG responses are also seen in reaction to foreign antigens on blood cells such as platelets.

PMID: 24243971

In the case of COVID, multiple prominent studies have demonstrated the detection of afucosylated IgGs against the spike protein in severe COVID.

PMID: 33361116, 33979301

These studies have also shown that not only afucosylated anti-spike IgGs are present in severe COVID, but also …

their presence is an early predictor and a direct driver of progression to severe COVID.

Those with an early production of afucosylated anti-spike IgG detected on, for instance day 5 of illness as outpatient, reliably progressed to severe COVID on subsequent days, whereas …

On the other hand, the patients ...

... who only formed normally fucosylated IgGs against the spike protein experienced only a mild course and recovered.

The timing of antibody formation mattered too.

In those who progressed to severe disease, the afucosylated (and non-neutralizing) IgGs were formed prior to the normally fucosylated (and neutralizing) IgGs against the spike protein.

In other words, these afucosylated IgGs order our own immune system to most ferociously attack and eliminate any trace of spike protein in the body.

These afucosylated responses are *not* unique to severe COVID. We’ve seen them before.

They also drive severe dengue.

PMID: 31765380, 34083490

Dengue virus also happens to another enveloped RNA virus like SARS-CoV-2, that also infects bone marrow megakaryocytes like SARS-CoV-2.

... uses MK infection as a reservoir to cause persistence despite patients taking highly-active antiretroviral therapy.

PMID: 32188724

We thought there may be a pattern here, perhaps.

And naturally, this is where shaping of our hypothesis began.

Is there a relationship between enveloped viruses infecting MKs, and this infection causing afucosylated responses toward antigens of these enveloped viruses?

What do we know about the contexts and antigens that are associated with afucosylated responses?

Owing to a comprehensive study by Larsen et al. (PMID 33361116), we know that ...

Afucosylated responses can occur in response to a limited set of stimuli including …

(1) Enveloped virus antigens
(2) Alloantigens on surface of platelets
(3) Alloantigens on surface of RBCs

In contrast (bottom row):

(1) Soluble proteins
(2) Bacterials antigens, and
(3) Non-enveloped virus antigens

are not known to cause afucosylated responses — and instead form the typical fucosylated IgGs only.

To dig deeper …

In the case of enveloped viruses, not all viral proteins are known to trigger afucosylated responses.

Larsen et al. have demonstrated that the location of the viral protein matters.

Surface expression is the differentiator.

Surface proteins of enveloped viruses can cause afucosylated responses. An example of a surface protein would be the spike protein of SARS-CoV-2.

In contrast, viral proteins without any surface expression do not induce afucosylated responses.

Larsen et al. showed in the case of severe COVID patients, afucosylated IgGs are only detectable against the spike protein (has surface expression) …

Whereas very little to no afucosylated IgGs are formed against the nucleocapsid protein (no surface expression).

We also know that afucosylated responses are seen in response to foreign antigens expressed on the surface of platelets.

This is best illustrated in the case of a fetal platelet disorder called FNAIT.

PMID: 24243971

Further refining our hypothesis based on these lines of evidence …

We began to wonder whether ...

SARS-CoV-2 can infect platelets and pathogenically embed its spike protein on the surface of platelets ➡️leading to an afucosylated response and the associated immunopathology.

Two studies in particular demonstrated that not only SARS-CoV-2 infects MKs, but also …

The viral infection of bone marrow MKs — similar to the case of afucosylated anti-spike IgGs — was an early predictor of progression to severe COVID.

PMID: 36920790, 35708858

Strikingly, virus-infected MKs were shown to transfer viral antigens including the spike protein (red) to emerging platelets during differentiation to proplatelets and platelets (Fortmann et al.)

Such finding — similar to platelet alloantigens encountered in FNAIT — would provide a plausible pathway by which afucosylated IgGs form against the spike protein.

Moreover, thus far no group has explored the possibility of whether virus-infected bone marrow MKs may be the key trigger for the production of the pathogenic afucosylated IgGs against the spike protein.

These two questions formed the basis of our study.

The schematic below summarizes the four parts of our hypothesis.

Based on the described hypotheses, experiment was designed as depicted in this diagram.

After obtaining IRB and approval from ethics committee, human bone marrow megakaryocytes were isolated from hospitalized subjects who were in the early days of experiencing severe COVID.

Subsequently, human bone marrow MKs were isolated from the bone marrow aspirate.

PCR confirmed the infection of bone marrow MKs by SARS-CoV-2 in these living donors in early stage of severe COVID.

Next …

Virus-infected MKs were grown and allowed to differentiate under favorable conditions and assessed for evidence of spike protein expression on the surface of resultant platelet progenitors.

Proplatelets emerging from the virus-infected MKs were labeled to identify their periphery (α-tubulin, green) and to identify any evidence of spike protein (red).

Indeed, we found the spike protein expressed on the surface of virus-infected proplatelets!

We then pursued our second question.

Virus-infected human bone marrow MKs were injected intravenously to transgenic mice harboring human ACE2 to see whether it triggers the formation of fucosylated IgGs against the spike protein.

First:

We found that injection of virus-infected human MKs into transgenic mice significantly promoted the formation afucosylated IgG antibodies against the spike protein

To our knowledge, this is the 1st instance of afucosylated IgGs detection against a viral antigen in vivo.

Second:

The mortality rate in the infected mice was proportional to the level of afucosylated anti-spike IgG produced.

This finding suggests that the afucosylated anti-spike IgG antibodies were pathogenic and contributed significantly to the severity of COVID-19 in mice - as is the case in humans.

Third:

The plasma levels of PF4 and serotonin, as soluble markers of platelet activation and/or granule release, were significantly higher in the infected mice compared with the uninfected mice.

Lastly, and perhaps most importantly:

Injection of virus-infected MKs into the circulation of these mice (without inhalation of the virus) mimicked the lung pathology seen in human cases of severe COVID:

Inflammatory cell infiltrate in the lung, followed by clot formation in the pulmonary vascular lumen, and distortion of the lung tissue.

In summary, to the best of our knowledge, this is the first study that demonstrates direct evidence that bone marrow megakaryocytes are infected early on by SARS-CoV-2 in those experiencing severe COVID.

Additionally, to the best of our knowledge, this is the first study that demonstrates proplatelets express SARS-CoV-2 spike protein on the surface of their membranes during differentiation from virus-infected human MKs.

This surface expression of spike protein matters …

In millions infected by this virus, the immune response follows a predictable pattern.

Virus infects the respiratory tract. Immune system reacts in a typical fashion, and forms neutralizing fucosylated antibodies against the spike protein.

Virus clears. Acute disease resolves.

This leads to an intense FcyRIlla-mediated activation of monocytes, macrophages, NK and dendritic cells systemically, attacking every tissue harboring spike protein.

That is, unfortunately, a large part of body's tissues, including the vasculature, lung, neural tissue, etc.

... causing widespread immuno-thrombosis, and immune-mediated injury to vasculature, lungs, blood-brain barrier, nervous system, and other tissues in the body.

We acknowledge that this is a preprint, and has not been peer-reviewed.

We also acknowledge that we have a significant amount of future work left to be done to better characterize the preliminary findings described in this work.

Lastly, we would like to thank the entire team of Dr. Younes Zaid @ZaidYounes9, and acknowledge the generous funding by Balvi and @VitalikButerin to allow us to continue our work.