https://www.sciencedirect.com/science/article/pii/S0306987720309154
Medical Hypotheses
Volume 144, November 2020, 109976

Deceiving SARS-CoV-2 molecular-tropism clues – A combinational contemporary strategy
Author links open overlay panelAPBBalajiab
SrinivasanBhuvaneswaribcD NandaKumarbhttps://doi.org/10.1016/j.mehy.2020.109976

Abstract

Several attempts to control the dreadfulness of SARS-CoV-2 are still underway.
Based on the literature evidences we have speculated a prospective contemporary
remedy, which was categorized into Specificity, Remedy, and a Conveyor. In
which, pros and cons were discussed and inferred the possible alternatives. (a)
Specificity: Implicit to express the ACE2 receptors in conveyor cells to deceive
SARS-CoV-2 from prepone targets. (b) Remedy: As depletion of pulmonary
surfactants causes strong acute respiratory distress syndrome, we propose an
entity of a cost-effective artificial surfactant system as a remedy to pulmonary
complications. (c) Conveyor: We propose red blood cells (RBCs) as a conveyor
with embedded artificial surfactant and protruding ACE2 receptors for the
target-specific delivery. Overall we postulate focused insights by employing a
combinational contemporary strategy to steer towards a prospective direction on
combating SARS-CoV-2.

Keywords
SARS-CoV-2
COVID-19
Coronavirus
ACE2 receptors
Pulmonary surfactant
Molecular tropism
ARDS


Specificity

Viruses are typically parasites, which pounce the host cell, hijacks cellular
processes to develop several copies of viral progenies. The molecular cascades
progress upon viral entry into the host is complex and makes it much more
complicated to develop drugs at the time of pandemic or endemic situation to
comprehend the novel viruses [3]. Hopes on deploying quick vaccination as a
safeguard measure were also down as recurrent of viral antigenic shift is
higher. Restricting the SARS-CoV-2 attachment to the host cell shall be a simple
and effectual means to avoid infection. In general, sialic acid, a small sugar
moiety attached to the several proteins of the host cell serves as a receptor
for viral attachment. However specific receptor domain of the host becomes the
first point of viral contact, a recent report has elucidated the SARS-CoV-2
possesses a similar binding domain to that of SARS-CoV [4]. In closer
prospective viral spike glycoprotein present in SARS-CoV-2 exhibit tropism
towards ACE2 receptors in the host cells with 10–20-fold higher affinity than
SARS-CoV [5]. The interaction studies on SARS-CoV-2 have interpolated a precise
interaction with ACE2, which are largely displayed by the oral tissues and,
oesophagus tract paving the viral entry points [6]. In specific, SARS-CoV-2
causes a devastating effect on type II alveolar cells which are highly rich in
the ACE2 receptor [7]. Due to this, a post-infection outbreaks cascade of immune
response events such as ‘Cytokine storm’, vasodilatation and, congregating heap
of cells leading to dilution of pulmonary surfactants. Eventually causing
decreased bloodstream gas exchange, and attributing to ARDS [8]. As to counter
to this, drugs like tocilizumab were projected to block the IL-6 activity
thereby restricting the immunological events. However, this is not an ideal
solution, as these drugs restrict other immunological events causing further
illness, a primitive message learned not to target host cells [9]. Moreover,
viruses undergo antigenic shifts by mutation inorder to evade from the antibody
therapies. Also, it devastates the agonist or antagonist efforts on viral
membrane receptors. Aforementioned thumps a ray of hope only on the virus
receptor specificity, implicit to express the ACE2 receptors in conveyor cells,
to deceive the virus from prepone targets.
Remedy

A remedy to shade away from the catastrophic events of COVID-19 is to protect
alveolar collapsing by restoring the pulmonary surfactant. Pulmonary surfactant
is a lipoprotein mixture, secreted into the alveolar space, to maintain the
air–liquid interface. The lipoprotein mixture comprises majorly of
phospholipids, in which zwitterionic saturated phosphatidylcholines are
primarily responsible for decreasing the surface tension to near-zero. While,
negatively charged phosphatidylglycerol, unsaturated phospholipids, hydrophobic
proteins SP-B and SP-C plays a major role in re-spreading, flexibility and to
maintain the surfactant film [10], [11]. Several attempts were made to
synthesize artificial surfactant, Dwivedi MV et al [12] have developed a
reproducible model system consisting of zwitterionic
1,2-dipalmitoyl-sn-glycero-3-phosphocholine, negatively charged
1,2-dipalmitoyl-sn-glycero-3-phosphoglycerol and surfactant-specific protein
SP-C to mimic the natural ones. On a commercial note, Surfacten® prepared from
the extracts of the bovine lungs were used to treat ARDS in the Newborn Infants.
However, the drawbacks of unknown antigenicity have restricted its usage.
Further development of Surfaxin®, a protein or peptide-based surfactant
consisting majorly of phospholipids dipalmitoyl-l—phosphatidylcholine, aliphatic
acid, synthetic peptide KL4, and phosphatidylglycerol have shown promising
results [13]. Nevertheless, owing to the expensiveness they could not serve the
pandemic or epidemic situations to treat large population.

A prevailing measure is to develop a low-cost pulmonary surfactant mixture from
less expensive sources such as egg yolk lecithin or soy lecithin (as a
1,2-dipalmitoyl-sn-glycero-3-phosphocholine substitute), palmitic or stearic
acid (as a higher aliphatic acid substitute), triacylglycerol or cholesterol (as
a neutral lipid substitute) and Hel 13–5, P24, Hel 7–11-P24, KL4 (as a peptide
substitute) [14]. Further, K Yukitate et al [15] have postulated Hel 13–5
(amphipathic -helical peptide), consisting a low hydrophilic and a highly
hydrophobic portion enables them to stay on the membrane surface, while stearoyl
group of hydrogenated soy lecithin execute a similar function of palmitoyl group
in 1,2-dipalmitoyl-sn-glycero-3-phosphocholine, thereby convincingly exerting
equivalency to the commercial ones. Besides, the introduction of D-amino acids
into Hel 13–5 could improve the potency [15]. In conclusion, an entity of a
cost-effective artificial surfactant system could ease the acute respiratory
distress, and propound to be an effectual remedy.
Conveyor

As the target precision and the remedy were depicted, an envoy is required to do
the task. We propose RBCs as an effective conveyor to severe the present
essence. As they pose biocompatibility, a higher half-life period, profusely
present at the site of infection, biodegradable with no harmful by-products.
Most importantly RBCs are largely involved in the lung alveolar region membrane
interaction for the respiration process. In addition to the candidacy of RBCs
they are enucleated, cannot be prey for virus proliferation. Several attempts
were made to incorporate the drugs into RBCs by employing osmosis-based methods,
electroporation, Drug-induced endocytosis [16]. However, most of them propounded
to create pores by disrupting the RBC membrane, which may hamper the delivery
efficiency. In contrast, He H et al. [17] have developed a non-invasive
encapsulation procedure by utilizing low molecular weight protamine, as a
cell-penetrating peptide without causing any perturbation on the cell membrane.
The above-mentioned method would be effectual and felicitous to incorporate
pulmonary surfactant on to the RBCs.

On the other hand, RBCs should fulfill the feasibility of target-specific
delivery. As aforementioned ACE2 as a specific receptor for the SARS-CoV-2
attachment, RBCs protruding these receptors on membranes warrant specificity.
Several methods portrayed appending protein complexes or peptides on to the RBC
cell wall by using chemical cross-linkers, complement fragments and,
glycosylphosphatidylinositol as an anchor or biotinylation [18]. Asher DR et al
[19] have reported a pinnacle approach of expressing viral receptors on RBCs, to
utilize them as a viral trap against coxsackie virus. The above-mentioned
methodology presents the effective way of deceiving the viruses’ infectivity
from the vulnerable tissues. An execution of antagonist activity to prohibit
pathogenicity. In addition, RBCs displays complement receptor type 1 (CR 1 -
CD35) which binds with immune components and executes antibody-mediated
opsonization.
Conclusion

Herein we postulate the ideology of utilizing RBCs as a conveyor, impregnated
with artificial surfactants (of a cost-effective source which may include
hydrogenated soy lecithin, a higher aliphatic acid substitute, triacylglycerol
or cholesterol and Hel 13–5 with D-amino acids) to restore the pulmonary
surfactant concentration in the alveolar region. Further, RBCs expressing the
ACE2 receptor on the cell membrane optimistically yields the target specificity
towards the SARS-CoV-2. We anticipate at the site of infection SARS-CoV-2 binds
and penetrates on to RBCs via protruding ACE2 receptors and releases the
pulmonary surfactant (Fig. 1), Eventually executing antagonistic effect on the
virus (as RBCs are enucleated) and deceived them from binding to prepone targets
(i.e. type II alveolar cells). Comprehensively, we have presented focused
insights to steer towards a novel direction to control the SARS-CoV-2 infection
by deploying combinational contemporary strategy. We believe our hypothesis
shall throw lights to head researchers towards our perspectives with or without
certain modifications inorder to combat SARS-CoV-2.

    Download : Download high-res image (375KB)Download : Download full-size
image

Fig. 1. . Schematic representation of fabricating artificial surfactant loaded
RBCs with protruding ACE2 receptors for SARS-Co-V-2 specific binding.
Role of the funding source

None.
Declaration of Competing Interest

The authors declare that they have no known competing financial interests or
personal relationships that could have appeared to influence the work reported
in this paper.
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