Resumen

Introducción: El citomegalovirus (CMV) es capaz de provocar enfermedades graves e incluso mortales en pacientes inmunocomprometidos. Es importante contar con pruebas moleculares de detección viral, sensibles y específicas, utilizando como blanco los genes clave para la replicación viral. En la detección molecular de CMV se han utilizado los genes UL122 (replicación) y UL83 (proteína más abundante del tegumento).

Objetivo: Detectar y cuantificar el CMV mediante reacción en cadena de la polimerasa (PCR) dúplex en tiempo real, a partir de una mínima cantidad de plasma.

Material y métodos: Los genes UL122 y UL83 se amplificaron con diferentes fluoróforos mediante PCR dúplex en tiempo real. Para cuantificar el CMV se generó una recta estándar, a partir de DNA del CMV (1.0-0.0000001 ng).

Resultados: El rango dinámico de la «recta maestra» tuvo una pendiente (m) de −3.0; la eficiencia de amplificación fue del 115.44%; de los plasmas de pacientes con infección por el virus de la inmunodeficiencia humana (VIH) con una carga viral ≥ 100,000 copias/ml, el 11.36% fueron verdaderos positivos para CMV y el 88.64% no tuvieron amplificaciones o estuvieron fuera del rango lineal de detección molecular.

Conclusiones: Esta prueba identificó dos genes importantes del CMV (UL122 y UL83) en una sola reacción (FAM:VIC), y se ratificó la detección viral a partir de una mínima cantidad de plasma. Esto se traduce en una menor cantidad de muestra biológica requerida y sumaría una herramienta al área clínica, así como un menor consumo de reactivos y materiales.

Abstract

Background: Cytomegalovirus (CMV) is able to cause serious and even deadly diseases in immunocompromised patients. It is important to have a sensitive, specific and molecular viral tests for its detection, using as targets, key genes for viral replication. The following genes have been used in the molecular detection of CMV: UL122 (replication) and UL83 (most abundant protein of the tegument).

Objective: Detect and quantify CMV, by real-time duplex PCR, from a minimum amount of plasma.

Material and methods: The UL122 and UL83 genes were amplified with different fluorophores, by real-time duplex PCR. To quantify CMV, curves were generated, starting with DNA-CMV (1.0-0.0000001 ng).

Results: The dynamic range of “master” duplex straight had a pendent (m) −3.0, the amplification efficiency was 115.44% plasmas from patients with HIV viral load ≥ 100,000 copies/mL, 11.36% were true positive for CMV and 88.64% had no amplifications or they were outside of the linear range of molecular detection.  

Conclusions: This test identified two important CMV genes (UL122 and UL83) in a single reaction (FAM:VIC), viral detection was confirmed from a minimum amount of plasma. This mean a smaller amount of biological sample required and would add a tool to the clinical area, as well as a lower consumption of reagents and materials.

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