A critical review on heat and mass transfer modelling of viral infection and virion evolution: The case of SARS-COV2

Is it possible to characterize the SARS-CoV-2 viral infection by analyzing the viral hijacking of cellular metabolism for its reproduction and multiplication? Gibbs free energy appears to be the critical factor of successful virus infection. A virus always has a more negative Gibbs free energy of growth than its host. Hence, the synthesis of viral components is thermodynamically favourable. On the other side, it could be essential to better thermodynamically understand how S1 and S2 spike protein interacts with the ACE2 receptors and the cell membrane more efficiently than the usual nutrients, which are intercepted. Gibbs energy gives a static model, which does not include the time arrow of viral evolution. A better comprehension of this evolutional path could require an accurate analysis of entropy generation or exergy disruption of binding, replication, and multiplication.

Herbivore-induced activation of viral phosphatase disarms plant antiviral immunities for pathogen transmission

The survival of pathogens depends on their ability to overcome host immunity, especially arthropod-borne viruses (arboviruses) which must withstand the immune responses of both the host and the arthropod vector. Successful arboviruses often modify host immunity to accelerate pathogen transmission; however, few studies have explored the underlying mechanism. Here we report attracted herbivore infestation on the virus-infected plants promote transmission by the associated vector herbivore. This herbivore-induced defense suppression underpins a subversive mechanism used by Begomovirus, the largest genus of plant viruses, to compromise host defense for pathogen transmission. Begomovirus-infected plants accumulated βC1 proteins in the phloem where they were bound to host defense regulators, transcription factor WRKY20 and two mitogen-activated protein kinases MPK3 and MPK6. Once perceiving whitefly herbivory or endogenous secreted peptide PEP1, the plants started dephosphorylation on serine33 and stimulated βC1 protein as a phosphatase. βC1 dephosphorylated MPK3/6 and WRKY20, the latter negatively regulated salicylic acid signaling and vascular callose deposition. This viral hijacking of WRKY20 accumulated more vascular callose by which enforced whitefly prolonged salivation and phloem sap ingestion, therefore impelling more virus transmission among plants. We present a scenario in which viruses dynamically respond to the presence of their vectors, suppressing host immunity and promoting pathogen transmission only when needed.

Viruses mobilize plant immunity to deter nonvector insect herbivores

A parasite-infected host may promote performance of associated insect vectors; but possible parasite effects on nonvector insects have been largely unexplored. Here, we show that Begomovirus, the largest genus of plant viruses and transmitted exclusively by whitefly, reprogram plant immunity to promote the fitness of the vector and suppress performance of nonvector insects (i.e., cotton bollworm and aphid). Infected plants accumulated begomoviral βC1 proteins in the phloem where they were bound to the plant transcription factor WRKY20. This viral hijacking of WRKY20 spatiotemporally redeployed plant chemical immunity within the leaf and had the asymmetrical benefiting effects on the begomoviruses and its whitefly vectors while negatively affecting two nonvector competitors. This type of interaction between a parasite and two types of herbivores, i.e., vectors and nonvectors, occurs widely in various natural and agricultural ecosystems; thus, our results have broad implications for the ecological significance of parasite-vector-host tripartite interactions.

Exosome Biogenesis and Biological Function in Response to Viral Infections

Introduction: Exosomes are extracellular vesicles that originate as intraluminal vesicles during the process of multivescular body formation. Exosomes mediate intercellular transfer of functional proteins, lipids, and RNAs. The investigation into the formation and role of exosomes in viral infections is still being elucidated. Exosomes and several viruses share similar structural and molecular characteristics. Explanation: It has been documented that viral hijacking exploits the exosomal pathway and mimics cellular protein trafficking. Exosomes released from virus-infected cells contain a variety of viral and host cellular factors that are able to modify recipient host cell responses. Recent studies have demonstrated that exosomes are crucial components in the pathogenesis of virus infection. Exosomes also allow the host to produce effective immunity against pathogens by activating antiviral mechanisms and transporting antiviral factors between adjacent cells. Conclusion: Given the ever-growing roles and importance of exosomes in both host and pathogen response, this review will address the impact role of exosome biogenesis and composition after DNA, RNA virus, on Retrovirus infections. This review also will also address how exosomes can be used as therapeutic agents as well as a vaccine vehicles.