Abstract
Identification of the causative infectious agent is essential in the management of infectious diseases, with the ideal diagnostic method being rapid, accurate, and informative, while remaining cost-effective. Traditional diagnostic techniques rely on culturing and cell propagation to isolate and identify the causative pathogen. These techniques are limited by the ability and the time required to grow or propagate an agent in vitro and the facts that identification based on morphological traits are non-specific, insensitive, and reliant on technical expertise. The evolution of next-generation sequencing has revolutionized genomic studies to generate more data at a cheaper cost. These are divided into short- and long-read sequencing technologies, depending on the length of reads generated during sequencing runs. Long-read sequencing also called third-generation sequencing emerged commercially through the instruments released by Pacific Biosciences and Oxford Nanopore Technologies, although relying on different sequencing chemistries, with the first one being more accurate both platforms can generate ultra-long sequence reads. Long-read sequencing is capable of entirely spanning previously established genomic identification regions or potentially small whole genomes, drastically improving the accuracy of the identification of pathogens directly from clinical samples. Long-read sequencing may also provide additional important clinical information, such as antimicrobial resistance profiles and epidemiological data from a single sequencing run. While initial applications of long-read sequencing in clinical diagnosis showed that it could be a promising diagnostic technique, it also has highlighted the need for further optimization. In this review, we show the potential long-read sequencing has in clinical diagnosis of fungal infections and discuss the pros and cons of its implementation.
Highlights
Rapid and accurate diagnosis of pathogens is essential in the management of infectious disease and is the ultimate goal for clinical microbiology laboratories
This review explores previous and potential use of longread sequencing in the clinical diagnosis, focusing on fungal infections
Additional regions have been targeted by species-specific primers, e.g., the D1/D2 region of the large ribosomal subunit (LSU) of the rDNA gene cluster is used for the identification of Candida species (Mannarelli and Kurtzman, 1998) and for P. jirovecii (Tia et al, 2012)
Summary
Rapid and accurate diagnosis of pathogens is essential in the management of infectious disease and is the ultimate goal for clinical microbiology laboratories. Many identification techniques have been developed and are currently used in clinical diagnosis, public health, animal welfare, plant protection, quarantine implications, and many other industrial fields (Figure 1). These conventional diagnostic tools vary in their success depending on the type of sample. Fungal pathogens may be identified based upon simple characteristics, such as the color, size, and smell of the isolates. Often, these do not allow for complete diagnosis, as these features may be shared among many species. More in-depth observations are required, including the analysis of the complexity of morphology, the presence of sexual reproductive structures, the effect on surrounding media, and the effect of different staining techniques (Kurtzman et al, 2011; Schelenz et al, 2015)
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