BackgroundThe fungal pathogen Cryptococcus neoformans is a leading cause of illness and death in persons with predisposing factors, including: malignancies, solid organ transplants, and corticosteroid use. C. neoformans is ubiquitous in the environment and enters into the lungs via inhalation, where it can disseminate through the bloodstream and penetrate the central nervous system (CNS), resulting in a difficult to treat and often-fatal infection of the brain, called meningoencephalitis. Plasminogen is a highly abundant protein found in the plasma component of blood and is necessary for the degradation of fibrin, collagen, and other structural components of tissues. This fibrinolytic system is utilized by cancer cells during metastasis and several pathogenic species of bacteria have been found to manipulate the host plasminogen system to facilitate invasion of tissues during infection by modifying the activation of this process through the binding of plasminogen at their surface.MethodologyThe invasion of the brain and the central nervous system by penetration of the protective blood-brain barrier is a prerequisite to the establishment of meningoencephalitis by the opportunistic fungal pathogen C. neoformans. In this study, we examined the ability of C. neoformans to subvert the host plasminogen system to facilitate tissue barrier invasion. Through a combination of biochemical, cell biology, and proteomic approaches, we have shown that C. neoformans utilizes the host plasminogen system to cross tissue barriers, providing support for the hypothesis that plasminogen-binding may contribute to the invasion of the blood-brain barrier by penetration of the brain endothelial cells and underlying matrix. In addition, we have identified the cell wall-associated proteins that serve as plasminogen receptors and characterized both the plasminogen-binding and plasmin-activation potential for this significant human pathogen.ConclusionsThe results of this study provide evidence for the cooperative role of multiple virulence determinants in C. neoformans pathogenesis and suggest new avenues for the development of anti-infective agents in the prevention of fungal tissue invasion.
Rhizopus delemar causes devastating mucormycosis in immunodeficient individuals. Despite its medical importance, R. delemar remains understudied largely due to the lack of available genetic markers, the presence of multiple gene copies due to genome duplication, and mitotically unstable transformants resulting from conventional and limited genetic approaches. The clustered regularly interspaced short palindromic repeat (CRISPR)-associated nuclease 9 (Cas9) system induces efficient homologous and non-homologous break points and generates individual and multiple mutant alleles without requiring selective marker genes in a wide variety of organisms including fungi. Here, we have successfully adapted this technology for inducing gene-specific single nucleotide (nt) deletions in two clinical strains of R. delemar: FGSC-9543 and CDC-8219. For comparative reasons, we first screened for spontaneous uracil auxotrophic mutants resistant to 5fluoroorotic acid (5-FOA) and obtained one substitution (f1) mutationin the FGSC-9543 strain and one deletion (f2) mutation in the CDC-8219 strain. The f2 mutant was then successfully complemented with a pyrF-dpl200 marker gene. We then introduced a vector pmCas9:tRNA-gRNA that expresses both Cas9 endonuclease and pyrF-specific gRNA into FGSC-9543 and CDC-8219 strains and obtained 34 and 42 5-FOA resistant isolates, respectively. Candidate transformants were successively transferred eight times by propagating hyphal tips prior to genotype characterization. Sequencing of the amplified pyrF allele in all transformants tested revealed a single nucleotide (nt) deletion at the 4th nucleotide before the protospacer adjacent motif (PAM) sequence, which is consistent with CRISPR-Cas9 induced gene mutation through non-homologous end joining (NHEJ). Our study provides a new research tool for investigating molecular pathogenesis mechanisms of R. delemar while also highlighting the utilization of CRISPR-Cas9 technology for generating specific mutants of Mucorales fungi.
Rhizopus delemar is an emerging fungal pathogen causing devastating mucormycosis in immunocompromised individuals. The organism remains understudied and there are urgent needs for new methods of rapid disease diagnosis for timely therapy. Extracellular vesicles with encapsulated RNAs have recently been discovered to have great potential applications for disease diagnoses and treatments. To explore the utilization of ex-RNA in studies of mucormycosis, we have performed RNA-Seq of ex-sRNAs from two clinical strains of R. delemar. Approximately 3.3 and 3.2 million clean reads were obtained from FGSC-9543 and CDC-8219 strains, respectively. The median sequence length of the sRNAs was 22 nts, with a minimum of 18 and a maximum of 30 nts. Further annotation identified 560 and 526 miRNAs from FGSC-9543 and CDC-8219 strains, respectively. miRNA target prediction and analysis of GO and KEGG pathways have revealed that the regulation of metabolism, secondary metabolite biosynthesis, and two-component system signaling are important during growth. We have also validated RNA-Seq by qRT-PCR and Northern blotting analysis of randomly selected miRNAs. Our results show that R. delemar has a rich reservoir of secreted ex-sRNAs and our studies could facilitate the development of improved diagnostic methods as well as elucidating virulence mechanisms for R. delemar infection.
Aconitic acid (propene-1,2,3-tricarboxylic acid) is the most prevalent 6-carbon organic acid that accumulates in sugarcane and sweet sorghum. As a top value-added chemical, aconitic acid may function as a chemical precursor or intermediate for high-value downstream industrial and biological applications. These downstream applications include use as a bio-based plasticizer, cross-linker, and the formation of valuable and multi-functional polyesters that have also been used in tissue engineering. Aconitic acid also plays various biological roles within cells as an intermediate in the tricarboxylic acid cycle and in conferring unique survival advantages to some plants as an antifeedant, antifungal, and means of storing fixed pools of carbon. Aconitic acid has also been reported as a fermentation inhibitor, anti-inflammatory, and a potential nematicide. Since aconitic acid can be sustainably sourced from renewable, inexpensive sources such as sugarcane, molasses, and sweet sorghum syrup, there is enormous potential to provide multiple streams of additional income to the sugar industry through downstream industrial and biological applications that we discuss in this review.
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