Prediction of SARS-CoV-2 Variant Lineages Using the S1-Encoding Region Sequence Obtained by PacBio Single-Molecule Real-Time Sequencing

The severe acute respiratory syndrome coronavirus 2 (SARS-CoV-2), is the causal agent of the COVID-19 pandemic that emerged in late 2019. The outbreak of variants with mutations in the region encoding the spike protein S1 sub-unit that can make them more resistant to neutralizing or monoclonal antibodies is the main point of the current monitoring. This study examines the feasibility of predicting the variant lineage and monitoring the appearance of reported mutations by sequencing only the region encoding the S1 domain by Pacific Bioscience Single Molecule Real-Time sequencing (PacBio SMRT). Using the PacBio SMRT system, we successfully sequenced 186 of the 200 samples previously sequenced with the Illumina COVIDSeq (whole genome) system. PacBio SMRT detected mutations in the S1 domain that were missed by the COVIDseq system in 27/186 samples (14.5%), due to amplification failure. These missing positions included mutations that are decisive for lineage assignation, such as G142D (n = 11), N501Y (n = 6), or E484K (n = 2). The lineage of 172/186 (92.5%) samples was accurately determined by analyzing the region encoding the S1 domain with a pipeline that uses key positions in S1. Thus, the PacBio SMRT protocol is appropriate for determining virus lineages and detecting key mutations.

Transferability of heterologous microsatellite primers in Leiarius marmoratus

The Amazonian Jundiá (Leiarius marmoratus) (Siluliformes: Pimelodidae) is a species of catfish with social and economic importance in some South American countries such as Brazil and Colombia. Genetic evaluation of this species is limited due to the lack of specific molecular markers, hindering studies on genetic diversity and structure in animals under captive conditions or in natural populations. The objective of the present study was to evaluate the transferability of heterologous microsatellite markers in Leiarius marmoratus. Thirty-two heterologous primers were tested in L. marmoratus. The primers that presented the best standards were applied to 20 specimens, and the number of alleles (Na), number of effective alleles (Ne), gene diversity per Locus (GdL) and percentage of amplification failure (Md) were calculated. Eleven primers demonstrated satisfactory transferability patterns, all from the fish of the Pimelodidae family, of which, seven were monomorphic and four polymorphic. The eleven markers presented low percentage of Md (mean was 5.9% samples per locus). Na varied from one to two alleles per locus, revealing low polymorphism in the evaluated samples. The mean Ne and GdL numbers were 1.77 and 0.32, respectively. The transferability of the heterologous microsatellite loci in L. marmoratus was shown to be possible. However, further tests are needed to apply these markers in population genetic studies.

Performance of 2 Polymerization Protocols Targeting Cloned Toxoplasma Parasites

BACKGROUND: Toxoplasma gondii is a common parasitic infection of humans. Infection is usually mild. Serious complications can occur in pregnant and immunocompromised patients. AIM: The present study aims to investigate the performance of 2 different PCR protocols; real-time quantitative molecular assays (qPCR) and conventional molecular assays (cPCR), using 2 different sets of primers and by using cloned purified Toxoplasma genomic substances to be evaluated as reference samples. METHODS: The target DNA was provided in 8 different quantities. RESULTS: Amplification failure was reported only with the cPCR in samples of low concentrations using both primer sets. Quantitative PCR detected the 8 different dilutions of the purified Toxoplasma gondii using the 2 sets of primers while cPCR was sensitive to detect only 6 different dilutions. CONCLUSION: Generally real-time quantitative molecular assays, is easy to use method compared to conventional PCR assay and produces more reliable results within only one hour time but still the possible application of qPCRs in routine diagnosis necessitates analysis of a large number of clinical samples in further studies to make the proper choice.

Microsatellite Amplification From Museum Feather Samples: Effects of Fragment Size and Template Concentration on Genotyping Errors

We address the problem of microsatellite genotyping errors associated with polymerase chain reaction (PCR) amplification from degraded and dilute template DNA and provide suggestions for improving the accuracy of genotype data in studies using older museum specimens as a source of DNA. In the course of a population genetics study of African indigobirds (Vidua spp.), we used replicate PCR to evaluate genotyping reliability for nine microsatellite loci in relation to PCR fragment length and DNA template concentration (DNA extracted from the calamus of one vs. two wing feathers). Complete amplification failure and the dropout of one allele from heterozygous genotypes were the predominant problems encountered. For samples with heterozygous genotypes, allele dropout occurred in 19.2 and 12.1% of PCR using extracts derived from one and two feathers, respectively. The amplification of artifact bands was less frequent (affecting 4.9 and 1% of positive PCR reactions with one- and two-feather extracts, respectively). Those results indicate that multiple replicates per sample and locus are required to obtain accurate genotype data from museum feather samples. Although higher DNA concentration improved success, PCR fragment size had a much stronger influence on the success and repeatability of microsatellite amplification, which suggests that the accuracy and efficiency of genotyping can be improved most easily by designing primers that amplify smaller DNA fragments.