Disordered proteins in COVID virus explained using computational tools
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Disordered proteins in COVID virus explained using computational tools


A research team from the Indian Institute of Technology (IIT), Mandi, in collaboration with researchers from Virginia Commonwealth University and the University of South Florida, USA, has used computational tools to understand an important part of the viral proteome called Intrinsically Disordered Protein Regions (IDPRs). 

The COVID-19 virus essentially consists of the genetic molecule, RNA, enclosed in an envelope made of lipid and proteins. Once in the host, the virus overpasses the host defence mechanisms and inserts its RNA into the host cells.

Then, the virus hijacks the host cell machinery to use the viral RNA for production of viral proteins in a process called ‘translation’, and the infected cell starts generating toxic viral proteins, which leads to various conditions and symptoms. It is known that proteins provide both structural and functional characteristics to living things and extraneous (viral) proteins can take over the functions of human cells.

“In COVID-19, the RNA is translated first into proteins which perform a wide range of functions. Since protein functions depend both on ordered and disordered regions, it is important to understand the whole proteome considering both ordered and disordered proteins”, explains Dr Rajanish Giri, Assistant Professor, School of Basic Sciences, IIT Mandi.

The set of proteins or proteome comprises both ordered regions and disordered regions in proteins. “Intrinsically Disordered Proteins (IDPs), and IDPRs are gaining attention in recent times because they have been discovered to play vital roles in various biological processes”, said Dr Giri.

The IDP and IDPRs have been strongly correlated with the virulence of viruses. Deciphering their structure and functions in COVID-19 can help find ways to mitigate the effects of the infection. Both the protein structure and non-structure are fundamental things and their knowledge is paramount to understand the virus pathogenesis. With computational tools it’s possible to investigate the propensities of the proteins and regions, that may or may not form the structure. 

“We have investigated the disordered side of SARS-CoV-2 proteome using a complementary set of computational approaches to check the prevalence of IDPRs in its proteins and to shed some light on their disorder-related functions, besides their disorder-based binding motifs, known as molecular recognition features”, said Dr Giri.

The studies have shown the crucial role of IDPRs in the maturation of individual proteins. It is found that many of these proteins contain disorder-based binding motifs. “Since many IDPs/IDPRs undergo structural changes upon association with their physiological partners, our study generates important grounds for better understanding of the functionality of these proteins, their interactions with other viral proteins, as well as interaction with host proteins in different physiological conditions”, Dr Giri said.

He added, “The process of rational drug design is currently limited, since it mostly ignores the presence of intrinsic disorder in target proteins. The understanding of the structure of these regions in the COVID-19 proteome is valuable to structural biologists involved in high throughput and structure-based screening for drug development”.

The IIT Mandi team has also compared IDPRs among the closely related viruses, human SARS and bat SARS-like CoVs. Such comparisons aid a better understanding of the sequence and structural peculiarities of the evolution of the virus and their virulence.

The IIT Mandi researchers plan to conduct more in-depth studies to establish structure-function relationships for a better understanding of the functioning of SARS-CoV-2 proteins. ‘Currently, we are also performing experiments to further investigate the disordered proteins in SARS-CoV-2’, Dr Giri said.

Credit: India Science Wire

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