Several Yeast Species Induce Iron Deficiency Responses in Cucumber Plants (Cucumis sativus L.)

Iron (Fe) deficiency is a first-order agronomic problem that causes a significant decrease in crop yield and quality. Paradoxically, Fe is very abundant in most soils, mainly in its oxidized form, but is poorly soluble and with low availability for plants. In order to alleviate this situation, plants develop different morphological and physiological Fe-deficiency responses, mainly in their roots, to facilitate Fe mobilization and acquisition. Even so, Fe fertilizers, mainly Fe chelates, are widely used in modern agriculture, causing environmental problems and increasing the costs of production, due to the high prices of these products. One of the most sustainable and promising alternatives to the use of agrochemicals is the better management of the rhizosphere and the beneficial microbial communities presented there. The main objective of this research has been to evaluate the ability of several yeast species, such as Debaryomyces hansenii, Saccharomyces cerevisiae and Hansenula polymorpha, to induce Fe-deficiency responses in cucumber plants. To date, there are no studies on the roles played by yeasts on the Fe nutrition of plants. Experiments were carried out with cucumber plants grown in a hydroponic growth system. The effects of the three yeast species on some of the most important Fe-deficiency responses developed by dicot (Strategy I) plants, such as enhanced ferric reductase activity and Fe2+ transport, acidification of the rhizosphere, and proliferation of subapical root hairs, were evaluated. The results obtained show the inductive character of the three yeast species, mainly of Debaryomyces hansenii and Hansenula polymorpha, on the Fe-deficiency responses evaluated in this study. This opens a promising line of study on the use of these microorganisms as Fe biofertilizers in a more sustainable and environmentally friendly agriculture.

Telomere length regulation by Rif1 protein from Hansenula polymorpha

Rif1 is a large multifaceted protein involved in various processes of DNA metabolism – from telomere length regulation and replication to double-strand break repair. The mechanistic details of its action, however, are often poorly understood. Here, we report functional characterization of the Rif1 homologue from methylotrophic thermotolerant budding yeast Hansenula polymorpha DL-1. We show that, similar to other yeast species, H. polymorpha Rif1 suppresses telomerase-dependent telomere elongation. We uncover two novel modes of Rif1 recruitment at H. polymorpha telomeres: via direct DNA binding and through the association with the Ku heterodimer. Both of these modes (at least partially) require the intrinsically disordered N-terminal extension – a region of the protein present exclusively in yeast species. We also demonstrate that Rif1 binds Stn1 and promotes its accumulation at telomeres in H. polymorpha.

Advantages of yeast-based recombinant protein technology as vaccine products against infectious diseases

The yeast expression system is widely used to produce functional recombinant proteins in the biopharmaceutical industry, such as vaccine products. The expression system choices using yeast as the host has many advantages. Various vaccines have been produced commercially using yeast expression systems. This review aims to explore the advantages of the yeast expression system in Saccharomyces cerevisiae, Pichia pastoris, and Hansenula polymorpha, which emphasize vaccine products to prevent human infectious diseases. Selection of the appropriate expression system is carried out by identification at the genetic and fermentation levels, taking into account host features, vectors and expression strategies. We also demonstrate the development of a yeast expression system that can produce recombinant proteins, virus-like particles and yeast surface displays as a novel vaccine strategy against infectious diseases. The recombinant protein produced as a vaccine in the yeast system is cost-effective, immunogenic, and safe. In addition, this system has not introduced new microbe variants in nature that will be safe for the environment. Thus, it has the potential to become a commercial product used in vaccination programs to prevent human infectious diseases.

Evolution of the interactions between GII.4 noroviruses and histo-blood group antigens: Insights from experimental and computational studies

Norovirus (NoV) is the major pathogen causing the outbreaks of the viral gastroenteritis across the world. Among the various genotypes of NoV, GII.4 is the most predominant over the past decades. GII.4 NoVs interact with the histo-blood group antigens (HBGAs) to invade the host cell, and it is believed that the receptor HBGAs may play important roles in selecting the predominate variants by the nature during the evolution of GII.4 NoVs. However, the evolution-induced changes in the HBGA-binding affinity for the GII.4 NoV variants and the mechanism behind the evolution of the NoV-HBGA interactions remain elusive. In the present work, the virus-like particles (VLPs) of the representative GII.4 NoV stains epidemic in the past decades were expressed by using the Hansenula polymorpha yeast expression platform constructed by our laboratory, and then the enzyme linked immunosorbent assay (ELISA)-based HBGA-binding assays as well as the molecular dynamics (MD) simulations combined with the molecular mechanics/generalized born surface area (MMGBSA) calculations were performed to investigate the interactions between various GII.4 strains and different types of HBGAs. The HBGA-binding assays show that for all the studied types of HBGAs, the evolution of GII.4 NoVs results in the increased NoV-HBGA binding affinities, where the early epidemic strains have the lower binding activity and the newly epidemic strains exhibit relative stronger binding intensity. Based on the MD simulation and MMGBSA calculation results, a physical mechanism that accounts for the increased HBGA-binding affinity was proposed. The evolution-involved residue mutations cause the conformational rearrangements of loop-2 (residues 390–396), which result in the narrowing of the receptor-binding pocket and thus tighten the binding of the receptor HBGAs. Our experimental and computational studies are helpful for better understanding the mechanism behind the evolution-induced increasing of HBGA-binding affinity, which may provide useful information for the drug and vaccine designs against GII.4 NoVs.

Customized yeast cell factories for biopharmaceuticals: from cell engineering to process scale up

The manufacture of recombinant therapeutics is a fastest-developing section of therapeutic pharmaceuticals and presently plays a significant role in disease management. Yeasts are established eukaryotic host for heterologous protein production and offer distinctive benefits in synthesising pharmaceutical recombinants. Yeasts are proficient of vigorous growth on inexpensive media, easy for gene manipulations, and are capable of adding post translational changes of eukaryotes. Saccharomyces cerevisiae is model yeast that has been applied as a main host for the manufacture of pharmaceuticals and is the major tool box for genetic studies; nevertheless, numerous other yeasts comprising Pichia pastoris, Kluyveromyces lactis, Hansenula polymorpha, and Yarrowia lipolytica have attained huge attention as non-conventional partners intended for the industrial manufacture of heterologous proteins. Here we review the advances in yeast gene manipulation tools and techniques for heterologous pharmaceutical protein synthesis. Application of secretory pathway engineering, glycosylation engineering strategies and fermentation scale-up strategies in customizing yeast cells for the synthesis of therapeutic proteins has been meticulously described.

Reconstruction of genome-scale metabolic model for Hansenula polymorpha using RAVEN toolbox

Genome scale metabolic models (GEMs) provide a useful framework for modeling the metabolism of microorganisms. While the applications of GEMs are wide and far reaching, the reconstruction and continuous curation of such models can be perceived as a tedious and time consuming task. Using the RAVEN toolbox, this protocol practically demonstrates how researchers can create their own GEMs using a homology based approach. To provide a complete example, we reconstruct a draft GEM for the industrially relevant yeast Hansenula polymorpha.

Full-length Genome of the Ogataea polymorpha strain HU-11 reveals large duplicated segments in subtelomeric regions

Background: Currently, methylotrophic yeasts (e.g., Pichia pastoris, Hansenula polymorpha, and Candida boindii) are subjects of intense genomics studies in basic research and industrial applications. In the genus Ogataea, most research is focused on three basic O. polymorpha strains—CBS4732, NCYC495, and DL-1. However, these three strains are of independent origin and unclear relationship. As a high-yield engineered O. polymorpha strain, HU-11 can be regarded as identical to CBS4732, because the only difference between them is a 5-bp insertion. Results: In the present study, we have assembled the full-length genome of O. polymorpha HU-11 using high-depth PacBio and Illumina data. Long terminal repeat (LTR) retrotransposons, rDNA, 5' and 3' telomeric, subtelomeric, low complexity and other repeat regions were curated to improve the genome quality. We took advantage of the full-length HU-11 genome sequence for the genome annotation and comparison. Particularly, we determined the exact location of the rDNA genes and LTR retrotransposons in seven chromosomes and detected large duplicated segments in the subtelomeric regions. Three novel findings are: (1) O. polymorpha NCYC495 is so phylogenetically close to CBS4732/HU-11 that the syntenic regions covers nearly 100% of their genomes with a nucleotide identity of 99.5%, while NCYC495 is significantly distinct from DL-1; (2) large segment duplication in subtelomeric regions is the main reason for genome expansion in yeasts; and (3) the duplicated segments in subtelomeric regions may be integrated at telomeric tandem repeats (TRs) through a molecular mechanism, which can be used to develop a simple and highly efficient genome editing system to integrate or cleave large segments into yeast genomes. Conclusions: Our findings provide new opportunities for in-depth understanding of genome evolution in methylotrophic yeasts and lay the foundations for the industrial applications of O. polymorpha HU-11 and CBS4732. The full-length genome of the O. polymorpha strain HU-11 should be included into the NCBI RefSeq database for future studies of O. polymorpha CBS4732, NCYC495, and their derivative strains.

Full-length Genome of the Ogataea polymorpha strain HU-11 reveals large duplicated segments in subtelomeic regions

Background: Currently, methylotrophic yeasts (e.g., Pichia pastoris, Hansenula polymorpha, and Candida boindii) are subjects of intense genomics studies in basic research and industrial applications. In the genus Ogataea, most research is focused on three basic O. polymorpha strains—CBS4732, NCYC495, and DL-1. However, these three strains are of independent origin and unclear relationship. As a high-yield engineered O. polymorpha strain, HU-11 can be regarded as identical to CBS4732, because the only difference between them is a 5-bp insertion. Results: In the present study, we have assembled the full-length genome of O. polymorpha HU-11 using high-depth PacBio and Illumina data. Long terminal repeat (LTR) retrotransposons, rDNA, 5' and 3' telomeric, subtelomeric, low complexity and other repeat regions were curated to improve the genome quality. We took advantage of the full-length HU-11 genome sequence for the genome annotation and comparison. Particularly, we determined the exact location of the rDNA genes and LTR retrotransposons in seven chromosomes and detected large duplicated segments in the subtelomeic regions. Three novel findings are: (1) the O. polymorpha NCYC495 is so phylogenetically similar to HU11 that a nearly 100% of their genomes is covered by their syntenic regions, while NCYC495 is significantly distinct from DL-1; (2) large segment duplication in subtelomeic regions is the main reason for genome expansion in yeasts; and (3) the duplicated segments in subtelomeric regions may be integrated at telomeric tandem repeats (TRs) through a molecular mechanism, which can be used to develop a simple and highly efficient genome editing system to integrate or cleave large segments at telomeric TRs. Conclusions: Our findings provide new opportunities for in-depth understanding of genome evolution in methylotrophic yeasts and lay the foundations for the industrial applications of O. polymorpha CBS4732 and HU11. The full-length genome of the O. polymorpha strain HU-11 should be included into the NCBI RefSeq database for future studies of O. polymorpha CBS4732 and its derivatives LR9, RB11 and HU-11.

Evaluation of Ogataea (Hansenula) polymorpha for Hyaluronic Acid Production

Hyaluronic acid (HA) is a biopolymer formed by UDP-glucuronic acid and UDP-N-acetyl-glucosamine disaccharide units linked by β-1,4 and β-1,3 glycosidic bonds. It is widely employed in medical and cosmetic procedures. HA is synthesized by hyaluronan synthase (HAS), which catalyzes the precursors’ ligation in the cytosol, elongates the polymer chain, and exports it to the extracellular space. Here, we engineer Ogataea (Hansenula) polymorpha for HA production by inserting the genes encoding UDP-glucose 6-dehydrogenase, for UDP-glucuronic acid production, and HAS. Two microbial HAS, from Streptococcus zooepidemicus (hasAs) and Pasteurella multocida (hasAp), were evaluated separately. Additionally, we assessed a genetic switch using integrases in O. polymorpha to uncouple HA production from growth. Four strains were constructed containing both has genes under the control of different promoters. In the strain containing the genetic switch, HA production was verified by a capsule-like layer around the cells by scanning electron microscopy in the first 24 h of cultivation. For the other strains, the HA was quantified only after 48 h and in an optimized medium, indicating that HA production in O. polymorpha is limited by cultivation conditions. Nevertheless, these results provide a proof-of-principle that O. polymorpha is a suitable host for HA production.