Application of PolyPRep tools on HIV protease polyproteins using molecular docking / Aplicação da ferramenta PolyPRep em poliproteínas de protease de HIV usando docking molecular

Abstract In recent years, the development of high-throughput technologies for obtaining sequence data leveraged the possibility of analysis of protein data in silico. However, when it comes to viral polyprotein interaction studies, there is a gap in the representation of those proteins, given their size and length. The prepare for studies using state-of-the-art techniques such as Machine Learning, a good representation of such proteins is a must. We present an alternative to this problem, implementing a fragmentation and modeling protocol to prepare those polyproteins in the form of peptide fragments. Such procedure is made by several scripts, implemented together on the workflow we call PolyPRep, a tool written in Python script and available in GitHub. This software is freely available only for noncommercial users.

Resumo Nos últimos anos, o desenvolvimento de tecnologias de alto rendimento para obtenção de dados sequenciais potencializou a possibilidade de análise de dados proteicos in silico. No entanto, quando se trata de estudos de interação de poliproteínas virais, existe uma lacuna na representação dessas proteínas, devido ao seu tamanho e comprimento. Para estudos utilizando técnicas de ponta como o Aprendizado de Máquina, uma boa representação dessas proteínas é imprescindível. Apresentamos uma alternativa para este problema, implementando um protocolo de fragmentação e modelagem para preparar essas poliproteínas na forma de fragmentos de peptídeos. Tal procedimento é feito por diversos scripts, implementados em conjunto no workflow que chamamos de PolyPRep, uma ferramenta escrita em script Python e disponível no GitHub. Este software está disponível gratuitamente apenas para usuários não comerciais.

Sequence similarity between thyroid self-protein and hepatitis c virus polyprotein: possible triggering mechanism of autoimmune thyroiditis / Similaridade de sequências entre auto-proteínas da tireoide e poliproteínas do vírus da hepatite C: possível mecanismo de desencadeamento da tireoidite auto-imune

ABSTRACT Background - Exposure to viral antigens that share amino acid sequence similar with self- antigens might trigger autoimmune diseases in genetically predisposed individuals, and the molecular mimicry theory suggests that epitope mimicry between the virus and human proteins can activate autoimmune disease. Objective - The purpose of this study is to explore the possible sequence similarity between the amino acid sequences of thyroid self-protein and hepatitis C virus proteins, using databanks of proteins and immunogenic peptides, to explain autoimmune thyroid disease. Methods - Were performed the comparisons between the amino acid sequence of the hepatitis C virus polyprotein and thyroid self-protein human, available in the database of National Center for Biotechnology Information on Basic Local Alignment Search Tool. Results - The sequence similarity was related each hepatitis C virus genotype to each thyroid antigen. The similarities between the thyroid and the viral peptides ranged from 21.0 % (31 identical residues out of 147 amino acid in the sequence) to 71.0% (5 identical residues out of 7 amino acid in the sequence). Conclusion - Bioinformatics data, suggest a possible pathogenic link between hepatitis C virus and autoimmune thyroid disease. Through of molecular mimicry is observed that sequences similarities between viral polyproteins and self-proteins thyroid could be a mechanism of induction of crossover immune response to self-antigens, with a breakdown of self-tolerance, resulting in autoimmune thyroid disease.

RESUMO Contexto - A exposição a antígenos virais que compartilham sequência de aminoácidos semelhantes a auto-antígenos pode provocar doenças auto-imunes em indivíduos predispostos geneticamente, e a teoria do mimetismo molecular sugere que o mimetismo entre epítopos de vírus e proteínas humanas pode ativar doenças auto-imunes. Objetivo - O objetivo deste estudo foi explorar a possível semelhança entre as sequências de aminoácidos de auto-proteinas da tireóide e proteínas do vírus da hepatite C, utilizando bancos de dados de proteínas e peptídeos imunogênicos, para explicar a doença auto-imune da tireóide. Métodos - Foram realizadas comparações entre as sequências de aminoácidos de poliproteínas do vírus da hepatite C e auto-proteinas da tireóide humana, disponível na base de dados do National Center for Biotechnology Information no Basic Local Alignment Search Tool. Resultados - A semelhança de sequências foi relacionada para cada genótipo de vírus da hepatite C e proteínas da tireóide. As semelhanças entre proteínas da tireóide e os peptídeos virais variaram de 21,0% (31 resíduos idênticos da sequência de 147 aminoácidos) a 71,0% (cinco resíduos idênticos da sequência de 7 aminoácidos). Conclusão - Dados de bioinformática sugerem uma possível ligação entre vírus da hepatite C e doença auto-imune da tireóide. Através de mimetismo molecular observa-se que as semelhanças entre as sequências de poliproteínas virais e auto-proteínas da tireóide pode ser um mecanismo de indução de resposta imune resultando em doença auto-imune da tireóide.

Activation and maturation of SARS-CoV main protease

The worldwide outbreak of the severe acute respiratory syndrome (SARS) in 2003 was due to the transmission of SARS coronavirus (SARS-CoV). The main protease (M(pro)) of SARS-CoV is essential for the viral life cycle, and is considered to be an attractive target of anti-SARS drug development. As a key enzyme for proteolytic processing of viral polyproteins to produce functional non-structure proteins, M(pro) is first auto-cleaved out of polyproteins. The monomeric form of M(pro) is enzymatically inactive, and it is activated through homo-dimerization which is strongly affected by extra residues to both ends of the mature enzyme. This review provides a summary of the related literatures on the study of the quaternary structure, activation, and self-maturation of M(pro) over the past years.

Three-dimensional domain swapping as a mechanism to lock the active conformation in a super-active octamer of SARS-CoV main protease

Proteolytic processing of viral polyproteins is indispensible for the lifecycle of coronaviruses. The main protease (M(pro)) of SARS-CoV is an attractive target for anti-SARS drug development as it is essential for the polyprotein processing. M(pro) is initially produced as part of viral polyproteins and it is matured by autocleavage. Here, we report that, with the addition of an N-terminal extension peptide, M(pro) can form a domain-swapped dimer. After complete removal of the extension peptide from the dimer, the mature M(pro) self-assembles into a novel super-active octamer (AO-M(pro)). The crystal structure of AO-M(pro) adopts a novel fold with four domain-swapped dimers packing into four active units with nearly identical conformation to that of the previously reported M(pro) active dimer, and 3D domain swapping serves as a mechanism to lock the active conformation due to entanglement of polypeptide chains. Compared with the previously well characterized form of M(pro), in equilibrium between inactive monomer and active dimer, the stable AO-M(pro) exhibits much higher proteolytic activity at low concentration. As all eight active sites are bound with inhibitors, the polyvalent nature of the interaction between AO-M(pro) and its polyprotein substrates with multiple cleavage sites, would make AO-M(pro) functionally much more superior than the M(pro) active dimer for polyprotein processing. Thus, during the initial period of SARS-CoV infection, this novel active form AOM(pro) should play a major role in cleaving polyproteins as the protein level is extremely low. The discovery of AOM(pro) provides new insights about the functional mechanism of M(pro) and its maturation process.

Liberation of SARS-CoV main protease from the viral polyprotein: N-terminal autocleavage does not depend on the mature dimerization mode

The main protease (M(pro)) plays a vital role in proteolytic processing of the polyproteins in the replicative cycle of SARS coronavirus (SARS-CoV). Dimerization of this enzyme has been shown to be indispensable for trans-cleavage activity. However, the auto-processing mechanism of M(pro), i.e. its own release from the polyproteins through autocleavage, remains unclear. This study elucidates the relationship between the N-terminal autocleavage activity and the dimerization of "immature" M(pro). Three residues (Arg4, Glu290, and Arg298), which contribute to the active dimer conformation of mature M(pro), are selected for mutational analyses. Surprisingly, all three mutants still perform N-terminal autocleavage, while the dimerization of mature protease and trans-cleavage activity following auto-processing are completely inhibited by the E290R and R298E mutations and partially so by the R4E mutation. Furthermore, the mature E290R mutant can resume N-terminal autocleavage activity when mixed with the "immature" C145A/E290R double mutant whereas its trans-cleavage activity remains absent. Therefore, the N-terminal auto-processing of M(pro) appears to require only two "immature" monomers approaching one another to form an "intermediate" dimer structure and does not strictly depend on the active dimer conformation existing in mature protease. In conclusion, an auto-release model of M(pro) from the polyproteins is proposed, which will help understand the auto-processing mechanism and the difference between the autocleavage and trans-cleavage proteolytic activities of SARS-CoV M(pro).

[Analysis of poly protein processing in human parechovirus Type 1 by gene cloning and expression]

Human parechovirus is a genus of picornaviridae. All of picornaviruses have a 3C protease which has a key role in virus protein processing and replication. The aim of this study was to analyse polyprotein processing in human Parechovirus type1 by cloning and expression of 3C gene. After preparation of cDNA from human parechovirus type 1[HPEV-1] RNA genome the region of cDNA that was encoded for 3C protein was inserted into plasmid pUBS by Ligase enzyme and recombinant plasmid was prepared. After transformation and replication of this plasmid in E.coli MC 10.22, DNA was isolated by phenol extraction and then expressed in prokaryotic [E.coli BL-21] and In vitro systems under T7 promoter. The results were detected by SDS-PAGE and analyzed. The products of expression of recombinant plasmids [with out 3C gene] in both prokaryotic and in vitro systems were analyzed. Just one large band same size as primary translation product was observed, but with plasmid including 3C gene, several small bands were detected. These results indicate that human Parechovirus type1 polyprotein processing occurs by 3C protease. 3C protease was checked by anti protease. Our results showed that HPEV-1 has a processing strategy different from other members of Picornaviruses, and 3C protein seems to be the only virus encoded protease that can catalyze cleavages of all sites in the Parechovirus type1 primary polyprotein

Expression of the infectious bursal disease virus polyprotein in Vero cells using attenuated Salmonella typhimurium as transgenic carrier / 生物工程学报

To examine if polyprotein gene (VP2/VP4/VP3) of Infectious Bursal Disease Virus (IBDV) could be delivered into mammalian cells and expressed using attenuated Salmonella typhimurium as vector. The IBDV polyprotein gene was amplified by RT-PCR and inserted in to pCI, an eukaryotic expression plasmid. The resulting recombinant pCI-VP2/VP4/VP3 was transformed by electroporation into attenuated Salmonella typhimurium strain ZJ111 (dam- and phoP-), which was then use to transfect the Vero cells. Gene specific RT-PCR revealed that VP2/VP4/VP3 was transcribed into mRNA in the Vero cells. Indirect immunofluorscence assay, SDS-PAGE and Western-blot analysis showed that VP2/VP4/VP3 was expressed and the product was immuno-reactive with anti-IBDV serum. This work provides essential precondition for developing a new oral DNA vaccine against IBDV.

Expression of polyprotein of infectious bursal disease virus in Bombyx mori / 生物工程学报

Segment A of the genome of infectious bursal disease virus(IBDV) encodes structure protein VP2 and VP3 and protease VP4. In this study a polyprotein gene of IBDV was inserted into a Bombyx mori baculovirus transfer vector pAcHLT--C and contransfected into BmN cells with linear genome DNA of virus Bm-BacPAK6. Dot hybridization suggested that the segment A of the virus genome was inserted in the genome of Bm-BacPAK6. The silkworm of fifth instars were infected by the recombinant virus and the immunogenicity of the infected larvae's blood were examined with ELISA, SDS-PAGE and Western blotting. It appears that the recombinant polyprotein has the property of immunoreactivity and the expression in larvae reached the pick 5-day post infection.