Desenvolvimento de um método de PCR em tempo real para o diagnóstico de rotavírus suíno do grupo A / Development of a real time PCR method for porcine rotavirus group A diagnosis

Marconi, Elizabeth Cristina Mota

26 July 2013

Os rotavírus são um dos principais agentes causadores de doenças entéricas em várias espécies animais, com ocorrência generalizada na suinocultura do Brasil. O seu diagnóstico é um componente essencial para estudos epidemiológicos e delimitação de medidas profiláticas visando o controle da doença. Apesar da relevância, não existem testes, tais como PCR em tempo real desenvolvido para detectar a diversidade genética de rotavírus suíno do grupo A (RVA). Este trabalho descreve o desenvolvimento de uma PCR em tempo real com SYBR® Green, para a detecção de rotavírus suíno e os seus resultados comparados com a PCR convencional e ELISA. Foram desenhados primers visando o segmento codificador da proteína NSP5 (137pb) e também foram utilizados primers visando o mRNA do gene mitocondrial bovino NADH5 (191pb) para o controle interno exógeno. Amostras de fezes de suínos de até 60 dias de idade de suínos do estado de São Paulo foram usadas para compor um painel de teste. Foram utilizadas como amostras de referencia o isolado 32/00 (controle positivo de rotavírus suíno do grupo A), concentrado de células MDBK (controle positivo do controle interno exógeno) e água tratada com DEPC (controle negativo). A extração do RNA total foi realizado com Trizol a partir de suspensões fecais contendo MDBK e o cDNA foi sintetizado utilizando primers aleatórios e M-MLV. Para as reações de PCR em tempo real utilizou-se o reagente MaximaTM SYBR Green qPCR Master Mix (Fermentas Life Science). Durante a padronização da PCR convencional, a temperatura de 54°C foi definida como a Tm ótima para a reação. O desempenho do ensaio foi validado em sete amostras positivas inicialmente testadas pelos métodos ELISA e PAGE. O isolado viral RV8209 foi utilizado para determinar o limiar de detecção da PCR em tempo real através de diluições seriadas sendo defino como ponto de corte Ct=33,5 (10-12,28TCID50%). O segmento codificador da NSP5 foi clonado no vetor pTZ57R/T submetido a restrição enzimática e usado como alvo para gerar uma curva padrão, onde obteve-se uma eficiência de 93,39%, slope de -3,49 e R2 de 0,993. A detecção do controle interno exógeno mostrou 82,9% de positividade para PCR convencional e 76,31% para a PCR em tempo real, com correlação significativa (0,718). O ensaio de ELISA para RVA apresentou 10,5% (8/78) de positividade, enquanto que as taxas de detecção da PCR em tempo real e PCR convencional foram de 50% (29/58) e 30,1% (24/63), respectivamente. Foi encontrada uma correlação moderada (0,546) entre PCR convencional e PCR em tempo real; baixa (0,056) entre a PCR convencional e ELISA; ausente (0,0) entre a PCR em tempo real e ELISA. Os resultados obtidos sugerem que a detecção por PCR em tempo real para a detecção do rotavírus suíno do grupo A em amostras fecais possa ser utilizada como diagnostico rápido e eficiente aumentando o repertório dos testes já estabelecidos, de modo a proporcionar uma maior sensibilidade para o diagnóstico clínico e epidemiológico. / Rotavirus is one of the main causative agents of enteric diseases in several animal species with widespread occurrence in Brazilian pig farm. Diagnosis is an essential component for epidemiological studies and delineation of prophylactic measures aiming disease control. Despite the relevance, there are no assays such as real-time PCR developed to detect the genetic diversity of porcine rotavirus from group A (RVA). This work describes the development of SYBR Green real-time PCR assay for the detection of porcine rotavirus and the results were compared with conventional PCR and ELISA. Primers were designed targeting the coding segment of the protein NSP5 (137pb) and also primers targeting the bovine mitochondrial gene mRNA NAD5 (191pb) were used for the exogenous internal control. Fecal samples from pigs up to 60 days of age from São Paulo state were used to compose a panel test. The reference sample was the isolate 32/00 (positive control for porcine rotavirus group A), concentrated MDBK cells (Exogenous Internal Positive Control) and DEPC-treated water (negative control). Total RNA extraction from supernatants of fecal samples containing MDBK cells were carried out with TRIzol reagent and cDNA was synthesized using random primers and M-MLV Reverse Transcriptase. For real-time PCR reactions were used MaximaTM SYBR Green qPCR Master Mix (Fermentas Life Science). For conventional PCR optimization, 54oC was defined as the optimum reaction temperature (Tm). The performance of the assay was validated on seven samples initially tested positive by ELISA and PAGE methods. The limit of detection of the developed real-time-PCR assay was determined using serial dilutions of the isolated RV8209 with Ct=33,5 (10-12,28TCID50%). The NSP5 gene segment was cloned into vector pTZ57R/T submitted to enzymatic restriction and used as template to generate a standard curve which Efficiency of 93.39%, slope of -3.49 and R2 □ 0.993. The Exogenous internal control showed 82.9% positivity for conventional PCR and 76.31% for real-time PCR with substantial correlation (0.718). The ELISA assay detected porcine RVA in 10,5% (8/78) of fecal samples, whereas the detection rates of both SYBR Green real-time PCR and conventional PCR assays were 50% (29 of 58) and 30.1% (24 of 63), respectively. A moderate correlation (0.546) was found between conventional PCR and real-time PCR; low (0.056) between the conventional PCR and ELISA; absent (0.0) between the real-time PCR and ELISA. Our findings suggest that detection of Group A porcine rotavirus in fecal samples by use of the real-time PCR assay may be fast and efficient increasing the repertoire of tests established to improve sensitivity for epidemiology and clinical diagnosis.

Detecção

Detection

Group A

Grupo A

NSP5

NSP5

PCR em tempo real

Real time PCR

Rotavirus

Rotavírus

Suínos

Swine

Desenvolvimento de um método de PCR em tempo real para o diagnóstico de rotavírus suíno do grupo A / Development of a real time PCR method for porcine rotavirus group A diagnosis

Elizabeth Cristina Mota Marconi

26 July 2013

Os rotavírus são um dos principais agentes causadores de doenças entéricas em várias espécies animais, com ocorrência generalizada na suinocultura do Brasil. O seu diagnóstico é um componente essencial para estudos epidemiológicos e delimitação de medidas profiláticas visando o controle da doença. Apesar da relevância, não existem testes, tais como PCR em tempo real desenvolvido para detectar a diversidade genética de rotavírus suíno do grupo A (RVA). Este trabalho descreve o desenvolvimento de uma PCR em tempo real com SYBR® Green, para a detecção de rotavírus suíno e os seus resultados comparados com a PCR convencional e ELISA. Foram desenhados primers visando o segmento codificador da proteína NSP5 (137pb) e também foram utilizados primers visando o mRNA do gene mitocondrial bovino NADH5 (191pb) para o controle interno exógeno. Amostras de fezes de suínos de até 60 dias de idade de suínos do estado de São Paulo foram usadas para compor um painel de teste. Foram utilizadas como amostras de referencia o isolado 32/00 (controle positivo de rotavírus suíno do grupo A), concentrado de células MDBK (controle positivo do controle interno exógeno) e água tratada com DEPC (controle negativo). A extração do RNA total foi realizado com Trizol a partir de suspensões fecais contendo MDBK e o cDNA foi sintetizado utilizando primers aleatórios e M-MLV. Para as reações de PCR em tempo real utilizou-se o reagente MaximaTM SYBR Green qPCR Master Mix (Fermentas Life Science). Durante a padronização da PCR convencional, a temperatura de 54°C foi definida como a Tm ótima para a reação. O desempenho do ensaio foi validado em sete amostras positivas inicialmente testadas pelos métodos ELISA e PAGE. O isolado viral RV8209 foi utilizado para determinar o limiar de detecção da PCR em tempo real através de diluições seriadas sendo defino como ponto de corte Ct=33,5 (10-12,28TCID50%). O segmento codificador da NSP5 foi clonado no vetor pTZ57R/T submetido a restrição enzimática e usado como alvo para gerar uma curva padrão, onde obteve-se uma eficiência de 93,39%, slope de -3,49 e R2 de 0,993. A detecção do controle interno exógeno mostrou 82,9% de positividade para PCR convencional e 76,31% para a PCR em tempo real, com correlação significativa (0,718). O ensaio de ELISA para RVA apresentou 10,5% (8/78) de positividade, enquanto que as taxas de detecção da PCR em tempo real e PCR convencional foram de 50% (29/58) e 30,1% (24/63), respectivamente. Foi encontrada uma correlação moderada (0,546) entre PCR convencional e PCR em tempo real; baixa (0,056) entre a PCR convencional e ELISA; ausente (0,0) entre a PCR em tempo real e ELISA. Os resultados obtidos sugerem que a detecção por PCR em tempo real para a detecção do rotavírus suíno do grupo A em amostras fecais possa ser utilizada como diagnostico rápido e eficiente aumentando o repertório dos testes já estabelecidos, de modo a proporcionar uma maior sensibilidade para o diagnóstico clínico e epidemiológico. / Rotavirus is one of the main causative agents of enteric diseases in several animal species with widespread occurrence in Brazilian pig farm. Diagnosis is an essential component for epidemiological studies and delineation of prophylactic measures aiming disease control. Despite the relevance, there are no assays such as real-time PCR developed to detect the genetic diversity of porcine rotavirus from group A (RVA). This work describes the development of SYBR Green real-time PCR assay for the detection of porcine rotavirus and the results were compared with conventional PCR and ELISA. Primers were designed targeting the coding segment of the protein NSP5 (137pb) and also primers targeting the bovine mitochondrial gene mRNA NAD5 (191pb) were used for the exogenous internal control. Fecal samples from pigs up to 60 days of age from São Paulo state were used to compose a panel test. The reference sample was the isolate 32/00 (positive control for porcine rotavirus group A), concentrated MDBK cells (Exogenous Internal Positive Control) and DEPC-treated water (negative control). Total RNA extraction from supernatants of fecal samples containing MDBK cells were carried out with TRIzol reagent and cDNA was synthesized using random primers and M-MLV Reverse Transcriptase. For real-time PCR reactions were used MaximaTM SYBR Green qPCR Master Mix (Fermentas Life Science). For conventional PCR optimization, 54oC was defined as the optimum reaction temperature (Tm). The performance of the assay was validated on seven samples initially tested positive by ELISA and PAGE methods. The limit of detection of the developed real-time-PCR assay was determined using serial dilutions of the isolated RV8209 with Ct=33,5 (10-12,28TCID50%). The NSP5 gene segment was cloned into vector pTZ57R/T submitted to enzymatic restriction and used as template to generate a standard curve which Efficiency of 93.39%, slope of -3.49 and R2 □ 0.993. The Exogenous internal control showed 82.9% positivity for conventional PCR and 76.31% for real-time PCR with substantial correlation (0.718). The ELISA assay detected porcine RVA in 10,5% (8/78) of fecal samples, whereas the detection rates of both SYBR Green real-time PCR and conventional PCR assays were 50% (29 of 58) and 30.1% (24 of 63), respectively. A moderate correlation (0.546) was found between conventional PCR and real-time PCR; low (0.056) between the conventional PCR and ELISA; absent (0.0) between the real-time PCR and ELISA. Our findings suggest that detection of Group A porcine rotavirus in fecal samples by use of the real-time PCR assay may be fast and efficient increasing the repertoire of tests established to improve sensitivity for epidemiology and clinical diagnosis.

Detecção

Grupo A

NSP5

PCR em tempo real

Rotavírus

Suínos

Detection

Group A

NSP5

Real time PCR

Rotavirus

Swine

Evaluation of Interactions of COVID Nonstructural Proteins 3, 5, and 6 With Human Proteins and Potentially Therapeutic Molecules

Huitsing, Jessica

01 January 2022

The COVID-19 pandemic, caused by Severe Acute Respiratory Syndrome Coronavirus 2, or SARS-CoV-2, has been ongoing for over two years. The virus spreads easily and is more unpredictable than well-known viruses like the flu, making it important to have reliable combative measures before we fully drop non-vaccine preventive actions, like mask-wearing.Therefore, we used computational protein modeling to investigate the interactions of three nonstructural proteins (abbreviated Nsp) encoded in the viral RNA genome– Nsp3, Nsp5, and Nsp6 – which are involved in the viral life cycle, with human P-type polyamine transporting ATPases ATP13A2 and ATP13A3, whose disease symptoms when mutated mimic certain COVID-19 complications. Understanding these interactions can help shed light on the mechanism of unexpected symptoms seen in COVID-19 and provide an avenue through which to treat infections. Additionally, papain-like protease (PLpro) and 3-chymotrypsin-like protease (3CLpro), which correspond to Nsp3 and Nsp5, respectively, are highly conserved between SARS-CoV and SARS-CoV-2 and thus make good potential drug targets due to their active sites and presumable lower ability to tolerate mutations (reducing the likelihood of treatments becoming ineffective), although the potential effects on the human proteasome would need to be further investigated. In addition, Nsp6 may help the virus evade host defenses by limiting the ability of autophagosomes to deliver viral particles to lysosomes, so limiting its interactions may increase the ability of the host cell to target its viral invader. One compound in particular, Haloperidol, showed promising results; predicted docking (via computational molecular docking software) to Nsp6 alone, as well as to Nsp6-heteroprotein complexes suggested strong binding, indicating a potential strong interaction that could impact the viral protein function and thus the viral life cycle.

COVID-19

SARS-CoV-2

Nsp3

Nsp5

Nsp6

ATP13A3

Genetic Structures

Studies On Phosphorylation And Oligomerization Of Rotavirus Nonstructural Protein 5 (NSP5) And Cellular Pathways That Regulate Virus Replication

Namsa, Nima Dondu

07 1900

Rotavirus is one of the leading etiological agents of gastroenteritis in young of many species including humans worldwide and is responsible for about 600,000 infant deaths per annum. Rotavirus belongs to the Reoviridae family, and its genome is composed of 11 double-stranded RNA segments that encode six structural proteins and six nonstructural proteins. Rotavirus replication is fully cytoplasmic and occurs within highly specialized regions called viroplasms. NSP2 and NSP5 have been shown to be essential for viroplasm formation and, when co-expressed in uninfected cells, to form viroplasm¬like structures. A recent study suggest a key role for NSP5 in architectural assembly of viroplasms and in recruitment of viroplasmic proteins, containing four structural (VP1, VP2, VP3 and VP6) and two nonstructural (NSP2 and NSP5) proteins. NSP5, the translation product of gene segment 11 has a predicted molecular eight of 21 kDa. NSP5 has been reported to exist in multiple isoforms ranging in size from 28-and 32-35 kDa from a 26-kDa precursor has been attributed to O-glycosylation and hyperphosphorylation. To study different properties of the protein, recombinant NSP5 containing an N-terminal hisidine tag was expressed in bacteria and purified by affinity chromatography. A significant observation was the similarity in phosphorylation property of the bacterially expressed and that expressed in mammalian cells. While the untagged recombinant protein failed to undergo phosphorylation in vitro, addition of His tag or deletions at the N-terminus promoted phosphorylation of the protein in vitro, which is very similar to the reported properties exhibited by the corresponding proteins expressed in mammalian cells. Phosphorylation of NSP5 in vitro is independent of the cell type from which the extract is derived suggesting that the kinases that phosphorylate NSP5 are distributed in all cell types. Among the C-terminal deletion mutants studied, NH-∆C5 and NH-∆C10 were phosphorylated better than full-length NSP5, but NH-∆C25 and NH¬∆C35 showed substantial reduction in the level of phosphorylation compared to full-length NSP5. These results indicate that the C-terminal 30 residues spanning the predicted α-helical domain of NSP5 are critical for its phosphorylation in vitro which is in correspondence with previous findings that C-terminal 21 amino acids of NSP5 direct its insolubility, hyperphosphorylation, and VLS formation. The results revealed that though the tagged full-length and some of the mutants could be phosphorylated in vitro, they are not suitable substrates for hyperphosphorylation unlike the similar proteins expressed in mammalian cells or infected cells. Analysis by western blot and mass spectrometry revealed that the bacterially expressed NH-NSP5 is indeed phosphorylated. It appears that prior phosphorylation in bacteria renders the protein conformationally not amendable for hyperphosphorylation by cellular kinases in vitro. Mutation of the highly conserved proline marginally enhanced its phosphorylation in vitro but the stability of protein is affected. Notably, mutation of S67A, identified as a critical residue for the putative caesin kinase-I and-II pathways of NSP5 phosphorylation, affected neither the phosphorylation nor the ATPase activity of NSP5. These results suggest that bacterially expressed NSP5 by itself has undectable auto-kinase activity and it is hypophosphorylated. Purified recombinant NSP5 has been reported to possess an Mg¬ 2+-dependent ATP-specific triphosphatase activity. The results indicated that deletion of either C-terminal 48 amino acids or N-terminal 33 residues severely affected the ATPase activity of recombinant NSP5, underlying the importance of both N-and C-terminal domains for NSP5 ATP hydrolysis function. NSP5 expressed in rotavirus infected cells exists as inter-molecular disulfide-linked dimeric forms and it appears that the 46 kDa isoforms, that are phosphorylated, corresponds to dimer as revealed by western blotting. Analytical gel filtration analysis of NH-NSP5, NH-ΔN43 and NH-ΔN33-ΔC25 showed most of the proteins in void volume, but an additional peak corresponding to the mass of dimeric species further supports that NSP5 is basically a dimer that undergoes oligomerization. Analysis by sucrose-gradient fractionation revealed that NH-NSP5 and NH-ΔN43 proteins were mainly distributed in the lower fraction of the gradient suggesting the existence of high molecular weight complexes or higher oligomers. The multimeric nature of NSP5 and its mutants was further confirmed by dynamic light scattering which suggests that high molecular weight complexes are of homogenous species. The correlation curves showed a low polydispersity distribution and a globular nature of recombinant NH-NSP5 proteins. The present results clearly demonstrate that dimer is the basic structural unit of NSP5 which undergoes oligomerization to form a complex consisting of about 20-21 dimers. The nonstructural protein 5 is hyperphosphorylated in infected cells and cellular kinases have been implicated to be involved in its phosphorylation. NSP5 contains multiple consensus sites for phosphorylation by several kinases, but the cellular kinases that specifically phosphorylate NSP5 in infected cells are yet to be identified. Previous studies from our laboratory using signaling pathway inhibitors revealed that recombinant NH¬NSP5 and its deletion mutants can be phosphorylated in vitro by purified cellular kinases and by mammalian cell extracts. These studies also showed the involvement of PI3K-Akt and MAPK signaling pathways in NSP5 phosphorylation and a negative role for GSK3β in the phosphorylation of bacterially expressed recombinant NSP5 in vitro. In the present work, using phospho-specific anti-Ser9 GSK3β antibody, we observed that GSK3β is inactivated in a rotavirus infected MA104 cells in a strain-independent manner. GSK3β¬specific small interfering RNA (siRNA-GSK3β) reduced GSK3β levels leading to increased level of synthesis of the structural rotavirus protein VP6 and NSP5 hyperphosphorylation compared to control siRNA. The pharmacological kinase inhibitors (LY294002, Genistein, PD98059, and Rapamycin) studies at the concentrations tested did not significantly affect rotavirus infection as seen from the number foci, while U0126 severely affected rotavirus replication. The results clearly demonstrated the importance of the MEK1/2 signaling pathway in the successful replication of rotavirus and NSP5 hyperphosphorylation in rotavirus-infected cells. In contrast inhibition of GSK3β activity by LiCl, increased in general, the number of foci by greater than 2-fold for all viral strains studied. These results suggest that MEK1/2 pathway majorly contributes to GSK3β inactivation in rotavirus infected cells. Thus, our results reveal that rotavirus activates both the PI3K/Akt and FAK/ERK1/2 MAPK pathways and appears to utilize them as a strategy to activate mTOR, and inhibit GSK3β through phosphorylation on serine 9, the negative regulator of rotavirus NSP5 phosphorylation, and thus facilitate translational competence of rotaviral mRNAs during virus replication cycle. It was shown previously in the laboratory by co-immunoprecipitation assay that Hsp70 interacts with rotaviral proteins VP1 and VP4 in rotavirus-infected mammalian cells. In this study, the interactions between Hsp70 with VP1 and VP4 were further evaluated in vitro by GST-pull down assay. It was observed that the N-terminal ATPase and C-terminal peptide-binding domain of Hsp70 is necessary for its direct interaction with VP1 and VP4. The presence of Hsp70 in purified double-and triple-layered virus particles further supported the observed interactions of rotaviral proteins VP1 and VP4 with Hsp70. However, the specific interaction observed between Hsp70 and rotaviral capsid proteins, VP1 and VP4 in viral particles suggests that Hsp70 has an important role during rotavirus assembly which requires further investigation.

Rotaviruses

Rotaviral Nonstructural Proteins

Nonstructural Protein

Viral Proteins

Heat Shock Protein 70 (Hsp70)

Viral Replication

Rotaviral Replication

Rotavirus Nonstructural Protein 5 (NSP5)

Rotavirus

Rotaviral Structural Proteins

Rotaviral Proteins

Nonstructural Protein 5

VP1

VP4

Virology