Next-Generation Sequencing (NGS) in Clinical Mycology-Introduction, Application, and Keynote

Introduction

Table of Contents

Next-generation sequencing (NGS) in Clinical Mycology is revolutionizing the diagnosis, typing, and antifungal resistance profiling of fungal pathogens.

Application

Here’s an overview of its applications:

  1. Pathogen Identification-NGS can identify fungal species with high precision, including rare and emerging pathogens that are difficult to detect using conventional methods.
  • Whole Genome Sequencing (WGS): Identifies fungal species based on entire genomes.
  • Targeted Sequencing (e.g., ITS, 18S rRNA): Amplifies specific fungal genomic regions for species-level identification.
  • Metagenomics: Enables detection of fungi in mixed microbial communities directly from clinical specimens without culture.
  1. Antifungal Resistance Detection-NGS can identify genetic mutations associated with resistance to antifungal drugs, such as:

Candida spp.:

  • CDR1, CDR2: Efflux pumps contribute to azole resistance.
  • ERG11: Azole resistance due to mutations in ergosterol synthesis.
  • FKS1, FKS2: Echinocandin resistance (glucan synthase mutations).


Aspergillus spp.: CYP51A: Azole resistance due to mutations in ergosterol synthesis.

  1. Epidemiological Studies and Outbreak Investigations-NGS is instrumental in understanding the spread of fungal infections within healthcare settings by:
  • Comparing genomic sequences of fungal isolates to identify sources of infection.
  • Tracking the evolution of multidrug-resistant fungal strains.
  1. Study of Host-Fungal Interactions-Transcriptomic and metatranscriptomic studies (RNA sequencing) provide insights into:
  • Host immune responses to fungal infections.
  • Mechanisms by which fungi evade immune defenses.
  1. Fungal Microbiome Analysis-NGS facilitates the study of the fungal microbiota (mycobiome) in various clinical conditions, such as:
  • Pulmonary aspergillosis.
  • Gastrointestinal and systemic fungal infections.
  • Dermatological conditions caused by dermatophytes.
  1. Detection of Polymicrobial Infections-NGS can detect co-infections involving fungi and bacteria or viruses in complex clinical specimens, guiding more effective treatment strategies.
  2. The Discovery of New Fungal Species- NGS enables the discovery and characterization of novel fungal species, improving our understanding of fungal biodiversity and its clinical relevance.
  3. Functional Genomics and Proteomics-NGS supports functional studies of fungal genes and proteins, which can lead to:
  • Identification of virulence factors.
  • Discovery of novel therapeutic targets.

Advantages of NGS in Clinical Mycology

  • Culture-independent identification.
  • High sensitivity for detecting low fungal loads.
  • Simultaneous detection of multiple fungal species.
  • Comprehensive profiling of antifungal resistance.


Challenges

  • High costs and technical expertise required.
  • Interpretation of results requires bioinformatics tools and databases.
  • Limited standardization for clinical application.

Keynote

NGS has immense potential to advance clinical mycology by improving diagnostic accuracy, understanding antifungal resistance, and guiding personalized treatment approaches for fungal infections.

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