Detection of multiple strains of rabies virus RNA using primers designed to target Mexican vampire bat variants

E. LOZA-RUBIO; E. ROJAS-ANAYA; V. M. BANDA-RUÍZ; S. A. NADIN-DAVIS; B. CORTEZ-GARCÍA

doi:10.1017/S095026880500405X

Abstract

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A reverse transcription–polymerase chain reaction (RT–PCR), that uses primers specifically designed to amplify a portion of the N gene of vampire bat strains of rabies that circulate in Mexico, but also recognizing most of the rabies variants circulating in endemic areas, was established. This standardized PCR assay was able to detect viral RNA in tenfold serial dilutions up to a 107 dilution using stock virus at an original titre of 107·5 LD50. The assay was highly specific for rabies virus. Forty different rabies isolates recovered from different species and geographical regions in the country were diagnosed as positive and negative by the fluorescent antibody test (FAT). These same samples were re-examined by both PCR and the mouse inoculation test (MIT). Compared with MIT the PCR exhibited an epidemiological sensitivity of 86% and a specificity of 91% while its positive predictive value was 96%.

Crossref Citations

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Rojas, Anaya Edith Loza-Rubio, Elizabeth Banda, Ruiz Víctor Manuel and Hernández, Baumgarten Eliseo 2006. Use of Reverse Transcription-Polymerase Chain Reaction to Determine the Stability of Rabies Virus Genome in Brains Kept at Room Temperature. Journal of Veterinary Diagnostic Investigation, Vol. 18, Issue. 1, p. 98.

Kang, BoKyu Oh, JinSik Lee, ChulSeung Park, Bong-Kyun Park, YoungNam Hong, KyungSoo Lee, KyungGi Cho, ByungKi and Song, DaeSub 2007. Evaluation of a rapid immunodiagnostic test kit for rabies virus. Journal of Virological Methods, Vol. 145, Issue. 1, p. 30.

TRIMARCHI, CHARLES V. and NADIN-DAVIS, SUSAN A. 2007. Rabies. p. 411.

NADIN-DAVIS, SUSAN A. 2007. Rabies. p. 69.

Araújo, Danielle B Langoni, Helio Almeida, Marilene F and Megid, Jane 2008. Heminested reverse-transcriptase polymerase chain reaction (hnRT-PCR) as a tool for rabies virus detection in stored and decomposed samples. BMC Research Notes, Vol. 1, Issue. 1,

MacKenzie, John S. Childs, James E. Field, Hume E. Wang, Lin-Fa and Breed, Andrew C. 2008. Neurotropic Viral Infections. p. 382.

Reiss, Carol Shoshkes 2008. Neurotropic Viral Infections. p. 263.

Loza-Rubio, Elizabeth Rojas-Anaya, Edith López, Juan Olivera-Flores, María Teresa Gómez-Lim, Miguel and Tapia-Pérez, Graciela 2012. Induction of a protective immune response to rabies virus in sheep after oral immunization with transgenic maize, expressing the rabies virus glycoprotein. Vaccine, Vol. 30, Issue. 37, p. 5551.

Hanlon, Cathleen A. and Nadin-Davis, Susan A. 2013. Rabies. p. 409.

Loza-Rubio, Elizabeth and Rojas-Anaya, Edith 2014. Commercial Plant-Produced Recombinant Protein Products. Vol. 68, Issue. , p. 153.

E. Escobar, Luis Peterson, A. Townsend Favi, Myriam Yung, Verónica and Medina-Vogel, Gonzalo 2015. BAT-BORNE RABIES IN LATIN AMERICA. Revista do Instituto de Medicina Tropical de São Paulo, Vol. 57, Issue. 1, p. 63.

Bastida-González, Fernando Ramírez-Hernández, Dolores G. Chavira-Suárez, Erika Lara-Padilla, Eleazar and Zárate-Segura, Paola 2016. Development of Primer Pairs from Molecular Typing of Rabies Virus Variants Present in Mexico. BioMed Research International, Vol. 2016, Issue. , p. 1.

Mackenzie, John S. Childs, James E. Field, Hume E. Wang, Lin-Fa and Breed, Andrew C. 2016. Neurotropic Viral Infections. p. 403.

GB, Manjunathareddy K, Sumana R, Yogisharadhya Cherian, Susan A, Prajapati SS, Patil V, Balamurugan KP, Singh R, Singh and H, Rahman 2016. Diagnosis of animal rabies: comparison of direct fluorescent antibody test (DFAT), reverse transcriptase -PCR and real-time PCR. Journal of Experimental Biology and Agricultural Sciences, Vol. 4, Issue. Spl-3-ADPCIAD, p. S69.

SEKAR, THANGARAJ MOHAN, GANESAN CHANDRA KARTHICK, BALA SUBRAMANIAN PREMKUMAR, ANANDA ARONE SUNDARAN, BHEEMAN and SEKAR, BALARAMAN 2018. Application of reverse transcriptase nested, hemi-nested And multiplex polymerase chain reaction techniques For the detection of pv 11, pv 3462 and cvs Strains of rabies virus. International Journal of Pharma and Bio Sciences, Vol. 9, Issue. 3,

Tolosa-Quintero, Narciso J. Loboa-Rodríguez, Nelly J. Gutierrez-Lesmes, Oscar A. and Góngora-Orjuela, Agustín 2018. Indicador compuesto en salud: riesgo de transmisión del virus de la rabia. Revista de Salud Pública, Vol. 20, Issue. 6, p. 764.

De Oliveira, Marcione B. and Bonvicino, Cibele R. 2020. Incidence of Viruses in Neotropical Bats. Acta Chiropterologica, Vol. 22, Issue. 2,

Loza Rubio, Elizabeth 2022. La Rabia, una enfermedad ancestral muy vigente. Archivos Latinoamericanos de Producción Animal, Vol. 30, Issue. Sup. 2, p. 5.

Mendoza-Guevara, Citlali Cecilia Ramon-Gallegos, Eva Martinez-Escobar, Alejandro Alonso-Morales, Rogelio Ramos-Godinez, Maria del Pilar and Ortega, Jorge 2022. Attachment and In Vitro Transfection Efficiency of an Anti-Rabies Chitosan-DNA Nanoparticle Vaccine. IEEE Transactions on NanoBioscience, Vol. 21, Issue. 1, p. 105.

Nadin-Davis, Susan A. Orciari, Lillian A. Fernandes, Elaine R. and Yager, Pamela A. 2023. History of Rabies in the Americas: From the Pre-Columbian to the Present, Volume I. p. 77.

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Detection of multiple strains of rabies virus RNA using primers designed to target Mexican vampire bat variants

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