Efficient transformation of Rhizopus delemar by electroporation of germinated spores

CRISPR/Cas9-based genome engineering in the filamentous fungus Rhizopus oryzae and its application to L-lactic acid production

The filamentous fungus Rhizopus oryzae is one of the main industrial strains for the production of a series of important chemicals such as ethanol, lactic acid, and fumaric acid. However, the lack of efficient gene editing tools suitable for R. oryzae makes it difficult to apply technical methods such as metabolic engineering regulation and synthetic biology modification. A CRISPR-Cas9 system suitable for efficient genome editing in R. oryzae was developed. Firstly, four endogenous U6 promoters of R. oryzae were identified and screened with the highest transcriptional activity for application to sgRNA transcription. It was then determined that the U6 promoter mediated CRISPR/Cas9 system has the ability to efficiently edit the genome of R. oryzae through NHEJ and HDR-mediated events. Furthermore, the newly constructed CRISPR-Cas9 dual sgRNAs system can simultaneously disrupt or insert different fragments of the R. oryzae genome. Finally, this CRISPR-Cas9 system was applied to the genome editing of R. oryzae by knocking out pyruvate carboxylase gene (PYC) and pyruvate decarboxylase gene (pdcA) and knocking in phosphofructokinase (pfkB) from Escherichia coli and L-lactate dehydrogenase (L-LDH) from Heyndrickxia coagulans, which resulted in a substantial increase in L-LA production. In summary, this study showed that the CRISPR/Cas9-based genome editing tool is efficient for manipulating genes in R. oryzae.

Mucorales and Mucormycosis: Recent Insights and Future Prospects

The classification of Mucorales encompasses a collection of basal fungi that have traditionally demonstrated an aversion to modern genetic manipulation techniques. This aversion led to a scarcity of knowledge regarding their biology compared to other fungal groups. However, the emergence of mucormycosis, a fungal disease caused by Mucorales, has attracted the attention of the clinical field, mainly because available therapies are ineffective for decreasing the fatal outcome associated with the disease. This revitalized curiosity about Mucorales and mucormycosis, also encouraged by the recent COVID-19 pandemic, has spurred a significant and productive effort to uncover their mysteries in recent years. Here, we elaborate on the most remarkable breakthroughs related to the recently discovered genetic advances in Mucorales and mucormycosis. The utilization of a few genetic study models has enabled the identification of virulence factors in Mucorales that were previously described in other pathogens. More notably, recent investigations have identified novel genes and mechanisms controlling the pathogenic potential of Mucorales and their interactions with the host, providing fresh avenues to devise new strategies against mucormycosis. Finally, new study models are allowing virulence studies that were previously hampered in Mucorales, predicting a prolific future for the field.

Microbial cell factories based on filamentous bacteria, yeasts, and fungi

BACKGROUND

Advanced DNA synthesis, biosensor assembly, and genetic circuit development in synthetic biology and metabolic engineering have reinforced the application of filamentous bacteria, yeasts, and fungi as promising chassis cells for chemical production, but their industrial application remains a major challenge that needs to be solved.

RESULTS

As important chassis strains, filamentous microorganisms can synthesize important enzymes, chemicals, and niche pharmaceutical products through microbial fermentation. With the aid of metabolic engineering and synthetic biology, filamentous bacteria, yeasts, and fungi can be developed into efficient microbial cell factories through genome engineering, pathway engineering, tolerance engineering, and microbial engineering. Mutant screening and metabolic engineering can be used in filamentous bacteria, filamentous yeasts (Candida glabrata, Candida utilis), and filamentous fungi (Aspergillus sp., Rhizopus sp.) to greatly increase their capacity for chemical production. This review highlights the potential of using biotechnology to further develop filamentous bacteria, yeasts, and fungi as alternative chassis strains.

CONCLUSIONS

In this review, we recapitulate the recent progress in the application of filamentous bacteria, yeasts, and fungi as microbial cell factories. Furthermore, emphasis on metabolic engineering strategies involved in cellular tolerance, metabolic engineering, and screening are discussed. Finally, we offer an outlook on advanced techniques for the engineering of filamentous bacteria, yeasts, and fungi.

High-Efficiency Electroporation for Genetic Improvement of Fungal Strains

Electroporation is a method for the introduction of molecules (usually nucleic acids) into a cell, consisting of submitting the cells to high-voltage and short electric pulses in the presence of the exogenous DNA/molecule. It is a versatile method, adaptable to different types of cells, from bacteria to cultured cells to higher eukaryotes, and thus has applications in many diverse fields, such as environmental biology, biotechnology, genetic engineering, and medicine. Electroporation has some advantages over other genetic transformation strategies, including the simplicity of the method, a wide range of adjustable parameters (possibility of optimization), high reproducibility and avoidance of the use of chemicals toxic to cells. Here we describe an optimized electroporation procedure for the industrially important fungus Acremonium chrysogenum, using germinated conidia and fragmented young mycelium. In both cases, the transformation efficiency was higher compared to the conventional polyethylene glycol (PEG)-mediated transformation of protoplasts.

Genes, Pathways, and Mechanisms Involved in the Virulence of Mucorales

The order Mucorales is a group of ancient fungi with limited tools for gene manipulation. The main consequence of this manipulation unwillingness is the limited knowledge about its biology compared to other fungal groups. However, the emerging of mucormycosis, a fungal infection caused by Mucorales, is attracting the medical spotlight in recent years because the treatments available are not efficient in reducing the high mortality associated with this disease. The result of this renewed interest in Mucorales and mucormycosis is an extraordinarily productive effort to unveil their secrets during the last decade. In this review, we describe the most compelling advances related to the genetic study of virulence factors, pathways, and molecular mechanisms developed in these years. The use of a few genetic study models has allowed the characterization of virulence factors in Mucorales that were previously described in other pathogens, such as the uptake iron systems, the mechanisms of dimorphism, and azole resistances. More importantly, recent studies are identifying new genes and mechanisms controlling the pathogenic potential of Mucorales and their interactions with the host, offering new alternatives to develop specific strategies against mucormycosis.

Genetic Transformation of the Filamentous Fungus Pseudogymnoascus verrucosus of Antarctic Origin

Cold-adapted fungi isolated from Antarctica, in particular those belonging to the genus Pseudogymnoascus, are producers of secondary metabolites with interesting bioactive properties as well as enzymes with potential biotechnological applications. However, at genetic level, the study of these fungi has been hindered by the lack of suitable genetic tools such as transformation systems. In fungi, the availability of transformation systems is a key to address the functional analysis of genes related with the production of a particular metabolite or enzyme. To the best of our knowledge, the transformation of Pseudogymnoascus strains of Antarctic origin has not been achieved yet. In this work, we describe for the first time the successful transformation of a Pseudogymnoascus verrucosus strain of Antarctic origin, using two methodologies: the polyethylene glycol (PEG)-mediated transformation, and the electroporation of germinated conidia. We achieved transformation efficiencies of 15.87 ± 5.16 transformants per μg of DNA and 2.67 ± 1.15 transformants per μg of DNA for PEG-mediated transformation and electroporation of germinated conidia, respectively. These results indicate that PEG-mediated transformation is a very efficient method for the transformation of this Antarctic fungus. The genetic transformation of Pseudogymnoascus verrucosus described in this work represents the first example of transformation of a filamentous fungus of Antarctic origin.

CRISPR-Cas9 induces point mutation in the mucormycosis fungus Rhizopus delemar

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 5-fluoroorotic 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.

A modified single-cell electroporation method for molecule delivery into a motile protist, Euglena gracilis

Single-cell transfection is a powerful technique for delivering chemicals, drugs, or probes into arbitrary, specific single cells. This technique is especially important when the analysis of molecular function and cellular behavior in individual microscopic organisms such as protists requires the precise identification of the target cell, as fluorescence labeling of bulk populations makes tracking of individual motile protists virtually impossible. Herein, we have modified current single-cell electroporation techniques for delivering fluorescent markers into single Euglena gracilis, a motile photosynthetic microalga. Single-cell electroporation introduced molecules into individual living E. gracilis cells after a negative pressure was applied through a syringe connected to the micropipette to the target cell. The new method achieves high transfection efficiency and viability after electroporation. With the new technique, we successfully introduced a variety of molecules such as GFP, Alexa Fluor 488, and exciton-controlled hybridization-sensitive fluorescent oligonucleotide (ECHO) RNA probes into individual motile E. gracilis cells. We demonstrate imaging of endogenous mRNA in living E. gracilis without interfering with their physiological functions, such as swimming or division, over an extended period of time. Thus the modified single-cell electroporation technique is suitable for delivering versatile functional molecules into individual motile protists.