Cloning of the Rhizopus niveus pyr4 gene and its use for the transformation of Rhizopus delemar

OUP accepted manuscript

The Mucorales fungal genus Rhizopus is used for the industrial production of organic acids, enzymes and fermented foods. The metabolic engineering efficiency of Rhizopus could be improved using gene manipulation; however, exogenous DNA rarely integrates into the host genome. Consequently, a genetic tool for Mucorales fungi needs to be developed. Recently, programmable nucleases that generate DNA double-strand breaks (DSBs) at specific genomic loci have been used for genome editing in various organisms. In this study, we examined gene disruption in Rhizopus oryzae using transcription activator-like effector nucleases (TALENs), with and without exonuclease overexpression. TALENs with an overexpressing exonuclease induced DSBs, followed by target site deletions. Although DSBs are repaired mainly by nonhomologous end joining in most organisms, our results suggested that in R. oryzae microhomology-mediated end joining was the major DSB repair system. Our gene manipulation method using TALENs coupled with exonuclease overexpression contributes to basic scientific knowledge and the metabolic engineering of Rhizopus.

Repetitive genomic sequences as a substrate for homologous integration in the Rhizopus oryzae genome

The vast number of repetitive genomic elements was identified in the genome of Rhizopus oryzae. Such genomic repeats can be used as homologous regions for integration of plasmids. Here, we evaluated the use of two different repeats: the short (575 bp) rptZ, widely distributed (about 34 copies per genome) and the long (2053 bp) rptH, less prevalent (about 15 copies). The plasmid carrying rptZ integrated, but did so through a 2256-bp region of homology to the pyrG locus, a unique genomic sequence. Thus, the length of rptZ was below the minimal requirements for homologous strand exchange in this fungus. In contrast, rptH was used efficiently for homologous integration. The plasmid bearing this repeat integrated in multicopy fashion, with up to 25 copies arranged in tandem. The latter vector, pPyrG-H, could be a valuable tool for integration at homologous sequences, for such purposes as high-level expression of proteins.

Liposome-mediated mycelial transformation of filamentous fungi

Liposome-mediated transformation is common for cells with no cell wall, but has very limited usage in cells with walls, such as bacteria, fungi, and plants. In this study, we developed a procedure to introduce DNA into mycelium of filamentous fungi, Rhizopus nigricans LH 21 and Pleurotus ostreatus TD 300, by liposome-mediation but with no protoplast preparation. The DNA was transformed into R. nigricans via plasmid pEGFP-C1 and into P. ostreatus via 7.2 kb linear DNA. The mycelia were ground in 0.6 M mannitol without any grinding aids or glass powder for 15 min to make mycelial fragments suspension; the suspension was mixed with a mixture of the DNA and Lipofectamine 2000, and placed on ice for 30 min; 100 μL of the transformation solution was plated on potato dextrose agar (PDA) plate and cultivated at 28 °C for transformant screening. The plasmid and the linear DNA were confirmed to be integrated into the host chromosome, proving the success of transformation. The transformation efficiencies were similar to those of electroporation-mediated protoplast transformation (EMPT) of R. nigricans or PEG/CaCl2-mediated protoplast transformation (PMT) of P. ostreatus, respectively. The results showed that our procedure was effective, fast, and simple transformation method for filamentous fungi.

Genetic damage following introduction of DNA in Phycomyces

Introduction of plasmids in Phycomyces blakesleeanus caused extensive changes in the exogenous DNA and in the resident genome. Plasmids with a bacterial gene for geneticin resistance under a Phycomyces promoter were either injected into immature sporangia or incubated with spheroplasts. An improved method produced about one viable spheroplast per cell. Colonies resistant to geneticin were rare and only about 0.1% of their spores grew in the presence of geneticin. The transformation frequency was very low, < or =1 transformed colony per million spheroplasts or per microg DNA. Few nuclei in the transformants contained exogenous DNA, as shown by a selective procedure that sampled single nuclei from heterokaryons. The exogenous DNA was not integrated into the genome and no stable transformants were obtained. The plasmids were replicated in the recipient cells, but their DNA sequences were modified by deletions and rearrangements and the transformed phenotype was eventually lost. The spores developed in injected sporangia were often inviable; a genetic test showed that spore death was caused by impaired nuclear proliferation and induction of lethal mutations. About one-fourth of the viable spores from injected sporangia formed abnormal colonies with obvious changes in shape, texture, or color. The abnormalities that could be investigated were due to dominant mutations. The results indicate that incoming DNA is not only attacked, but signals a situation of stress that leads to increased mutation and nuclear and cellular death.

Development of a system for integrative and stable transformation of the zygomycete Rhizopus oryzae by Agrobacterium-mediated DNA transfer

Two transformation systems, based on the use of CaCl(2)/PEG and Agrobacterium tumefaciens, respectively, were developed for the zygomycete Rhizopus oryzae. Irrespective of the selection marker used, a pyr4 marker derived from R. niveus or a dominant amdS(+) marker from Aspergillus nidulans, and irrespective of the configuration of the transforming DNA (linear or circular), the transformants obtained with the CaCl(2)/PEG transformation method were found to carry multiple copies of tandemly linked vector molecules, which failed to integrate into the genomic DNA. Furthermore, these transformants displayed low mitotic stability. In contrast, transformants obtained by Agrobacterium-mediated transformation were mitotically stable, even under non-selective conditions. Detailed analysis of these transformants revealed that the transforming DNA had integrated into the genome of R. oryzae at a single locus in independently obtained transformants. In addition, truncation of the transforming DNA was observed, resulting in the integration of the R. niveus pyr4 marker gene, but not the second gene located on the transferred DNA. Modification of the transforming DNA, resulting in partial resistance to restriction enzyme digestion, was observed in transformants obtained with the CaCl(2)/PEG transformation method, suggesting that a specific genome defence mechanism may exist in R. oryzae. It is likely that the unique mechanism used by A. tumefaciens to deliver its transferred DNA to its hosts facilitates bypass of the host defence mechanisms, thus allowing the DNA to integrate into the chromosomal genome.

Isolation and sequence analysis of the orotidine-5'-phosphate decarboxylase gene (URA3) of Candida utilis. Comparison with the OMP decarboxylase gene family

The URA3 gene of Candida utilis encoding orotidine-5'-phosphate decarboxylase enzyme was isolated by complementation in Escherichia coli pyrF mutation. The deduced amino-acid sequence is highly similar to that of the Ura3 proteins from other yeast and fungal species. An extensive analysis of the family of orotidine-5'-phosphate decarboxylase is shown. The URA3 gene of C. utilis was able to complement functionally the ura3 mutation of Saccharomyces cerevisiae.