Probe-based Multiplex QPCR Identifies Blood-meal Hosts in Anopheles Mosquitoes from Papua New Guinea

Overview

Journal Parasit Vectors

Publisher Biomed Central

Specialties Parasitology
Tropical Medicine

Date 2020 Mar 1

PMID 32111232

Citations 9

Authors

John B Keven

Georgia Artzberger

Mary L Gillies

Rex B Mbewe

Edward D Walker

Affiliations

Soon will be listed here.

Abstract

Background: Determination of blood-meal hosts in blood-fed female Anopheles mosquitoes is important for evaluating vectorial capacity of vector populations and assessing effectiveness of vector control measures. Sensitive molecular methods are needed to detect traces of host blood in mosquito samples, to differentiate hosts, and to detect mixed host blood meals. This paper describes a molecular probe-based quantitative PCR for identifying blood-meal hosts in Anopheles malaria vectors from Papua New Guinea.

Methods: TaqMan oligonucleotide probes targeting specific regions of mitochondrial or nuclear DNA of the three primary Anopheles blood-meal hosts, humans, pigs and dogs, were incorporated into a multiplex, quantitative PCR which was optimized for sensitivity and specificity.

Results: Amplification of serially diluted DNA showed that the quantitative PCR detected as low as 10 ng/μl of host DNA. Application to field-collected, blood-fed Anopheles showed that the quantitative PCR identified the vertebrate hosts for 89% (335/375) of mosquitoes whereas only 55% (104/188) of blood-meal samples tested in a conventional PCR were identified. Of the 104 blood-fed Anopheles that were positive in both PCR methods, 16 (15.4%) were identified as mixed blood meals by the quantitative PCR whereas only 3 (2.9%) were mixed blood meals by the conventional PCR.

Conclusions: The multiplex quantitative PCR described here is sensitive at detecting low DNA concentration and mixed host DNA in samples and useful for blood-meal analysis of field mosquitoes, in particular mixed-host blood meals.

Citing Articles

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Mbewe R, Keven J, Mangani C, Wilson M, Mzilahowa T, Mathanga D Malar J. 2023; 22(1):115.

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Vector composition, abundance, biting patterns and malaria transmission intensity in Madang, Papua New Guinea: assessment after 7 years of an LLIN-based malaria control programme.

Keven J, Katusele M, Vinit R, Rodriguez-Rodriguez D, Hetzel M, Robinson L Malar J. 2022; 21(1):7.

PMID: 34983530 PMC: 8729043. DOI: 10.1186/s12936-021-04030-4.

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