Search

Your search keyword '"Teparić, Renata"' showing total 159 results
Start Over Author "Teparić, Renata"
159 results on '"Teparić, Renata"'

4. Utilizing Ccw12 as an effective anchor for yeast surface display of diverse recombinant proteins

Author

Martinić Cezar, Tea, Lozančić, Mateja, Žunar, Bojan, Mrša, Vladimir, Teparić, Renata, Teparić, Renata, Leboš Pavunc, Andreja, and Kifer, Domagoj

Subjects
yeast surface display, S.cerevisiae, GPI anchor
Abstract

Yeast surface display is an innovative technique that can improve the stability and activity of recombinant enzymes by attaching the enzymes to the yeast cell wall. In this study, we focused on the C-terminal immobilization of recombinant proteins, as certain proteins require exclusive immobilization through their C-terminus to prevent loss of activity. C-terminal immobilization via the anchor Ccw12 protein has been a promising approach for the efficient display of various industrially relevant recombinant proteins due to the high abundance and stable attachment of the Ccw12 protein in the yeast cell wall. To further enhance the efficiency of C-terminal immobilization, we conducted a study where we examined a series of strains in which genes associated with the regulation of transcription of genes related to wall structure maintenance, mRNA processing, translation, quality control, and maintenance of ER morphology were deleted. We investigated the activity of the reporter Ccw12BLA protein in these mutants and compared it to the wild-type strain. Increased Ccw12BLA activity was observed in mutants lacking protein involved in amino acid deprivation response (gcn2), translational repressor for cell wall proteins (ssd1), a protein involved in endoplasmic reticulum-associated protein degradation pathway (doa10), and covalently linked proteins of the cell wall (scw4pir1pir2pir3pir4). Additionally, Ccw12BLA optimization was applied to the surface display of sucrose phosphorylase, an enzyme that plays a role in glucosyl glycerol synthesis and has extensive applications in various industries including cosmetics, food, and pharmaceuticals. Sucrose phosphorylase (kindly provided by Prof. B. Nidetzky, TU Graz) was successfully expressed and immobilized through the Ccw12 anchor protein on the yeast cell wall in gcn2, doa10, ssd1, and scw4pir1pir2pir3pir4 mutants, and its binding was confirmed through Western blot analysis. The activity measurement of Ccw12SP in these mutants showed a similar trend as observed for the Ccw12BLA recombinant protein, suggesting that these mutants are promising candidates for glucosyl glycerol production using yeast surface display technology. Also, we expressed methionine adenosyltransferase, a key enzyme in S-adenosylmethionine production, and confirmed its localization on the yeast cell wall.

Published
2023

6. The Chloroquine Story in the First Year of the COVID-19 Pandemic

Author

Hunić, Matea, Teparić, Renata, Kovačević, Monika, Barišić, Lidij, Hunić, Matea, Teparić, Renata, Kovačević, Monika, and Barišić, Lidij

Abstract

The emergence of COVID-19 has caused worldwide concern due to its high infectivity and mortality. Research groups around the world have prioritised drug development against COVID-19. Repurposing of already approved drugs, including the antimalarial drug chloroquine, has attracted considerable attention. The aim of this article is to (i) provide an overview of the recent chemical methods used to synthesise chloroquine and hydroxychloroquine, and (ii) provide insight into the data collected in 2020 on their efficacy against COVID-19. Unfortunately, the promising early results have not been confirmed and a clear and unambiguous conclusion on their clinical efficacy has not yet been drawn., Pojava COVIDA-19 uzrokovala je globalnu zabrinutost zbog visoke zaraznosti i mortaliteta. Stoga je razvoj lijekova protiv COVIDA-19 postao prioritet istraživačkim skupinama diljem svijeta. Pri tom je posebnu pozornost privukla moguća prenamjena prethodno odobrenih lijekova, uključujući i antimalarijski lijek klorokin. Cilj ovog rada je (i) prikazati pregled recentnih kemijskih metoda primijenjenih za sintezu klorokina i hidroksiklorokina te (ii) dati uvid u podatke o njihovoj učinkovitosti protiv COVIDA-19 prikupljene tijekom 2020. Nažalost, početni obećavajući rezultati nisu potvrđeni, a jasni i nedvosmisleni zaključci o kliničkoj učinkovitosti klorokina i hidroksiklorokina još nisu postignuti.

Published
2022

7. INCREASING THE EFFICIENCY OF PIR2-BASED YEAST SURFACE DISPLAY SYSTEM

Author

Mrša, Vladimir, Matičević, Ana, Lozančić, Mateja, Žunar, Bojan, Teparić, Renata, and Martinić-Cezar, Tea

Subjects
recombinant proteins, surface display, Pir2
Abstract

BACKGROUND Saccharomyces cerevisiae is frequently used as a host for the production of recombinant proteins. S. cerevisiae also provides the immobilization of recombinant proteins on the cell surface as an alternative to conventional immobilization methods. Yeast surface display systems are based on genetic fusion of a gene coding for a protein of interest and a gene coding for one of yeast cell wall proteins. Since immobilization of the protein through its N- or C- terminal end can affect its activity, different surface display systems were developed. Proteins of the Pir family are standardly used for N- terminal immobilization of recombinant proteins. OBJECTIVES Pir-based display systems developed so far involve fusion of the whole Pir protein with the desired protein, resulting in a large recombinant protein whose expression cause problems in its secretion and cell wall binding. To address this problem, we introduced changes in the Pir2 sequence and the protein secretion mechanisms to increase the efficiency of the Pir2- based surface display system. METHODS Using bacterial β-lactamase as a reporter enzyme, we assessed the efficiency of surface display of non-modified and modified recombinant protein Pir2bla in different yeast mutants. Amount of protein incorporated in cell wall was assessed by measurement of β-lactamase activity and by western blot. RESULTS Results show higher β-lactamase activity in strains expressing recombinant proteins containing the modified Pir2 binding region, lacking multiple internal repeats, and an increase of activity in most of the tested strains lacking activity of certain genes involved in endoplasmic reticulum-associated degradation (ERAD) pathways, or endocytosis. ACKNOWLEDGEMENTS/REFERENCES This research was funded by The Croatian Science Foundation, grant No. IP-2019-04-2891.

Published
2022

8. Advancing Pir-based yeast surface display by reshuffling and truncating Pir2-β-lactamase constructs

Author

Žunar, Bojan, Lozančić, Mateja, Matičević, Ana, Matijević, Dominik, Martinić Cezar, Tea, Teparić, Renata, and Mrša, Vladimir

Subjects
Pir proteins, cell wall, yeast, surface display, Saccharomyces cerevisiae
Abstract

After synthesizing proteins, yeast Saccharomyces cerevisiae can retain them within the cell, secrete them into the medium, or bind them to the cell surface. In the third case, yeast anchors proteins by covalently binding them to β-glucan residues, thus allowing for surface display, a cell-engineering technique that can remake the entire cell surface into catalytically active living material. To immobilize proteins of interest closer to their N-terminus, the proteins are regularly fused with one of five Pir proteins (proteins with internal repeats), which covalently bind to β-1, 3-glucan. However, beyond the requirement for glutamine in their characteristic internal repeats, the mechanism of attaching these proteins to the yeast cell wall remains unclear. Thus, the Pir-based surface display continues to rely on guesswork and intuition, which is less than efficient. To address this issue, we inserted β-lactamase at five positions in Pir2 (Hsp150) protein and followed its activity and Pir2-binding efficiency through enzymatic and immunochemical methods. Moreover, we constructed and tested additional six truncated Pir2-β-lactamase variants, thus determining the minimal portion of Pir2 required for efficient binding to the yeast cell wall. Finally, to enrich our experimental results with structural insights, we used a deep- learning Alphafold2-based algorithm to in silico predict the structure of Pir2-β-lactamase fusions. Therefore, we present and rationalize a novel set of practical guidelines for a reproducible, straightforward, and efficient Pir-based yeast surface display.

Published
2022

9. Yeast cell wall protein Scw10 proteolytic processing

Author

Lozančić, Mateja, Grbavac, Antonija, Matičević, Ana, Hrestak, Dora, Teparić, Renata, and Mrša, Vladimir

Subjects
Scw10, yeast, cell wall
Abstract

The Scw4, Scw10, and Scw11 proteins form a group of putative glucanases located in the yeast Saccharomyces cerevisiae cell wall. In the previously published study, Scw10 protein was shown to be up to 10-fold more abundant in several clinical isolates compared with laboratory yeast strain, suggesting its possible role in yeast virulence. Its paralog Scw4 undergoes complex proteolytic processing. Scw4 is processed by the Kex2 protease and subsequently by yapsin proteases, which affects the biological activity of Scw4 and its ability to bind to cell walls. The proteolytic processing or binding of Scw10 has not been thoroughly investigated. It has also been shown that both Scw4 and Scw10 can form non- covalent and covalent bonds with the wall that differ from previously known protein-wall bonds. Although these bonds resemble those of Pir proteins, both Scw4 and Scw10 lack the typical Pir binding sequence. In this study, the processing of Scw10 and its potential impact on its biological function are investigated. In addition, the role of several putative Scw4/Scw10 binding sequences in the formation of a covalent bond to cell wall structures is explored.

Published
2022

10. THE ROLE AND DIVERSITY OF PIR PROTEINS IN CELL WALLS OF BUDDING YEASTS

Author

Žunar, Bojan, Lozančić, Mateja, Martinić-Cezar, Tea, Teparić, Renata, Mrša, Vladimir, Dulić, Morana, Sinčić, Nino, and Vrhovac Madunić, Ivana

Subjects
Pir proteins, Alphafold2, in silico prediction of protein structures
Abstract

Pir proteins (proteins with internal repeats) are the most prominent proteins that yeast Saccharomyces cerevisiae covalently binds to its cell wall through β-1, 3-glucan residues. As such, they are regularly used for yeast surface display when the displayed protein needs to be bound close to its N-termini. However, the role of Pir proteins in cells remains unclear, and their diversity in closely-related species unexplored. These unknowns hamper rational engineering of Pir- based surface display, a technique with the potential to convert the entire yeast cell wall into enzymatically active self-regenerating living material. To address this issue, we used a deep- learning Alphafold2-based algorithm to in silico predict the 3D protein structures of S. cerevisiae Pir proteins and compare them with structures deposited in the Protein Data Bank (PBD). Through this approach, we were able to infer proteins’ function solely through 3D homology. Moreover, we searched through the genomes of 77 species closely related to S. cerevisiae and identified over 300 Pir homologues, with which we mapped Pir evolution throughout the last 110 million years. Finally, by comparing homologous genomic loci, we show that S. cerevisiae is the only species within the Saccharomyces clade to lose one of its Pir proteins. As such, our findings point towards the role and diversity of Pir proteins in budding yeasts, thus opening novel avenues in yeast surface engineering.

Published
2022

11. Altering the cell wall to increase cell surface display efficiency

Author

Lozančić, Mateja, Martinić-Cezar, Tea, Vukšić, Lucija, Žunar, Bojan, Teparić, Renata, and Mrša, Vladimir

Subjects
Yeast, Surface Display, GPI anchor, SSD1, Pir proteins
Abstract

Yeast surface display is a powerful and robust method for the surface immobilization of heterologous proteins with potential application in different biomedical and biotechnological processes. In biotechnology, it could be used in various bioconversion processes as enzymes of interest can be fused with anchoring proteins. This allows secretion of such protein constructs and their binding to the cell wall. The major disadvantage of this method is the low binding capacity and low overall surface dis-play efficiency of currently used systems. There are several possible approaches to resolve this problem, and in this work, we focused on the modification of the cell wall of host cells. Several mutant strains were developed and/or tested to see if it is possible to increase display efficiency by introducing changes in cell wall structures. Tested strains contained mutations in genes coding for cell wall proteins (the strain with deleted genes coding for Pir proteins, and deltacwp2 strain) or in genes coding for proteins involved in the synthesis of the GPI anchor, and in the localization of GPI anchored wall proteins (deltagpi7, deltadfg5, deltadcw1 strains). Also, the effect of deletion of the SSD1 gene coding for the translation factor involved in the translation of many cell wall proteins was tested. Effects of these mutations were investigated using reporter systems previously developed in our laboratory, composed of beta- lactamase fused with either Pir2 or Ccw12. Our preliminary results show that it is possible to obtain more than two-fold higher surface display efficiency by these modifications.

Published
2022

12. Modifications of the UPR and ERAD Pathways to Improve Yeast Surface Display

Author

Martinić-Cezar, Tea, Lozančić, Mateja, Žunar, Bojan, Teparić, Renata, Mrša, Vladimir, Sviličić Petrić, Ines, Leboš Pavunc, Andrea, Šantić, Marina, and Kifer, Domagoj

Subjects
yeast, surface display, ERAD, UPR
Abstract

The yeast Saccharomyces cerevisiae is a prominent host for the production of recombinant proteins because it can perform protein modifications that are the same or similar to those found in other eukaryotes. At the same time, yeast provides quality control of the proteins produced, resulting in a high level of properly folded proteins. These proteins can be secreted and incorporated into the cell wall, providing their immobilization on a solid surface. Yeast surface display is an attractive alternative to classical immobilization methods because it is cost- effective, less time-consuming, and allows continuous production of immobilized protein. The major drawback is the low efficiency of surface display. There are several approaches to overcome this obstacle. One of them is the manipulation of the secretory pathway to increase the total amount of secreted protein. Overexpression of recombinant proteins increases cell stress because the increased protein load overwhelms protein production and folding mechanisms, increasing the number of misfolded proteins. Such events lead to activation of the unfolded protein response (UPR) and the endoplasmic reticulum-associated degradation (ERAD) pathways. Several published papers have indicated that activation of these pathways leads to decreased protein production. To test how mutations in genes involved in these pathways affect surface display efficiency, we have used two surface display systems in which β- lactamase is displayed using native cell wall proteins Pir2 or Ccw12 as anchors. Mutants used for the surface display contain mutations in IRE1 and YOP1 (involved in the UPR), HRD1, HRD3, DER1 and DOA10 (involved in ERAD). Additionally, we also checked the effect of a mutation in the gene SEC14, which is involved in protein secretion and regulation of UPR. Results showed increased β- lactamase activity in most of the tested strains. Results also showed that the effects of introduced mutations on surface display efficiency differed between two surface display systems.

Published
2022

13. Modification of protein synthesis and secretory pathway to improve surface display efficiency

Author

Martinić-Cezar, Tea, Lozančić, Mateja, Žunar, Bojan, Teparić, Renata, and Mrša, Vladimir

Subjects
Yeast, Surface Display, ER, transcription/translation regulation, UPR, ERAD
Abstract

Major disadvantages of protein surface display in yeasts as an alter-native to classical solid- surface immobilization techniques are low production, secretion, and binding capacity, or simply said low surface display efficiency of recombinant proteins. As several problems could lead to low display efficiency, we attempted to investigate how modification of different cellular processes involved in the production and secretion of proteins can affect and possibly enhance display efficiency. For this purpose, we tested the effects of mutations of genes involved in transcription and translation (deltagcn2, deltagc- n5, deltaopi1, deltarrp6) and mutations affecting properties of the endoplasmic reticulum (deltayop1). We also tested the effect of mutations of genes involved in unfolded protein response (UPR) and the endoplasmic reticulum- associated degradation (ERAD) pathways that are possibly activated due to stress conditions caused by increased protein production of overexpressed recombinant protein.To test the effect of these mutations we used two reporter systems previously developed in our laboratory. Both systems contain beta-lactamase fused with either Pir2 protein or with the GPI anchoring signal sequence of Ccw12. Results obtained by measuring the activity of surface-displayed beta-lactamase have shown that it was possible to increase surface display efficiency significantly by modifying processes involved in protein production and secretion in yeast cells.

Published
2022

14. Development of β-­lactamase based surface display systems in Saccharomyces cerevisiae for testing the effects of mutation in protein glycosylation on surface display efficiency

Author

Lozančić, Mateja, Žunar, Bojan, Teparić, Renata, and Mrša, Vladimir

Subjects
Surface display, β-lactamase, Ccw12, Pir2, glycosylation
Abstract

Surface display in yeast represents a valuable alternative to enzyme immobilization on solid surfaces as it is usually less complicated, less time-consuming, and eliminates the need for expensive enzyme purification. Instead, it provides constant production of recombinant protein composed of enzyme of interest fused with fragments of native yeast cell wall proteins. This way modified cells can be used in production processes for longer time compared to the purified enzymes. However, major disadvantages of these technique are low surface display efficiency and possible hyperglycosylation of recombinant proteins. By lowering the amount of glycosylation in cells, several effects are expected. Decreased glycosylation level of enzyme of interest could result in less disturbance of its conformation. It also causes a lesser density of the outer mannan layer of the cell wall, possibly increasing the availability of the substrate. To test the effects of inactivation of genes involved in O-glycosylation (genes from PMT group) and N-glycosylation (OCH1 and genes from MMN group) on the enzyme activity and surface display efficiency, two different systems using β-lactamase as a reporter were developed. In one, bla gene coding for β-lactamase was fused with HSP150 gene coding for cell wall protein resulting in recombinant protein covalently immobilized on the wall through linkage on its N- terminal end. Other system consists of bla gene fused with a fragment of CCW12 gene coding for its signalling sequence for binding of C-terminal part of protein onto GPI anchor. Immobilization can cause differences in protein folding, possibly leading to changes in enzyme activity. To reduce interference of this effect with observed changes in enzyme activity in mutant strains, we used different immobilization approach described earlier. Protein amount in the cell wall is assessed by measuring β-lactamase activity using nitrocefin as substrate and in a semi-quantitative manner by western blot.

Published
2021
Full Text
View/download PDF

15. Comparative analysis of cell wall-related proteins of different yeasts

Author

Lozančić, Mateja, Žunar, Bojan, Hrestak, Dora, Lopandić, Ksenija, Teparić, Renata, and Mrša, Vladimir

Subjects
Cell wall proteome, yeasts, cell wall protein profiles
Abstract

The yeast cell wall is an extracellular structure with a complex role in preserving cell shape and integrity, and in interaction with different molecules and cells in its surrounding. Fact that 1200 Saccharomyces cerevisiae genes directly or indirectly affect cell wall formation and regulation (de Groot et al., 2001) clearly speaks of the importance of the cell wall. Here we present results from our recently published manuscript of in silico analysis comparing 187 S. cerevisiae proteins involved in cell wall biogenesis and function with cell wall proteomes of 92 different yeast species. The main goal of the research was to estimate the evolutionary conservation of proteins involved in protein glycosylation, cell wall synthesis and remodeling, and of cell wall proteins with still unknown functions. As expected, proteins involved in processes of great importance for cell wall integrity and its protective function were highly conserved. However, GPI anchored proteins involved in flocculation, aggregation, cell separation, and those with still unknown functions were not highly conserved. This analysis was coupled with analysis of proteins located in the cell wall by protein biotinylation and western blotting. Results of this analysis show distinctive protein patterns and significant differences in the overall amount of cell wall proteins for different yeast genera, and even for different species of the same genera. de Groot, P.W. et al. 2001. Comp. Funct. Genomics, 2(3), pp.124-142.

Published
2021

16. Effects of mutations in endocytosis and glycosylation on efficiency of surface display of recombinant proteins in yeast

Author

Teparić, Renata, Žunar, Bojan, Lozančić, Mateja, Orešković, Nikolina, and Mrša, Vladimir

Subjects
Surface display, β-lactamase, Ccw12, Pir2, glycosylation, endocytosis
Abstract

Surface display in yeast provides an alternative to standard protein immobilization on solid surfaces as it reduces the costs of protein purification and possibility of protein denaturation during the immobilization. Also, it provides continuous synthesis of recombinant protein composed of enzyme of interest fused with native yeast cell wall proteins. However, its major disadvantage is low surface display efficiency. Lately, it has been reported that mutations in genes encoding proteins involved in endocytosis may increase the amount of secreted heterologous proteins from the yeast cells. Glycosylation can also affect the efficiency of surface display as it could possibly have negative effect on conformation of displayed proteins and cause high density of wall outer mannan layer, limiting accessibility of the substrate. In order to test whether inactivation of genes involved in these processes would enhance surface display efficiency, two different systems using β-lactamase as a reporter were developed. In one, bla gene was fused with a fragment of CCW12 gene coding for its C-terminal GPI anchoring signal sequence. Other system consisted of bla gene coding for β-lactamase fused with PIR2 gene coding for cell wall protein that covalently binds to cell wall through the linkage on its N-terminal end. Both constructs were set under the control of an inducible PHO5 promotor. By using two different immobilization systems, the effect of different folding of the recombinant enzyme, caused by immobilization itself, on affecting enzyme activity is reduced. Therefore, the described system for expression and immobilization of recombinant reporter enzyme in the wall was examined in mutants that cannot accomplish endocytosis (end6, end3, vam4) and have lower level of glycosylation (pmt and mnn mutants). Amount of recombinant protein incorporated in cell wall was assessed by measurement of β-lactamase activity using nitrocefin as substrate and in a semi- quantitative manner by western blot.

Published
2021

17. Scw4 and Scw10 as new potential platforms for yeast cell surface expression systems

Author

Lozančić, Mateja, Grbavac, Antonija, Teparić, Renata, Mrša, Vladimir, Slavica, Anita, Teparić, Renata, Leboš Pavunc, Andreja, and Kifer, Domagoj

Subjects
yeast, Scw4, Scw10, cell wall, surface display
Abstract

Yeast cell wall proteins can be used for surface display of various proteins of industrial interest. Generally, yeast cell wall contains proteins that are non-covalently (Scw- proteins) or covalently (Ccw-proteins) bound to β-1, 3-glucan, the latter either through GPI- anchors and β-1, 6-glucan, or by alkali labile ester linkages between γ-carboxyl groups of glutamic acid and hydroxyl groups of glucoses (Pir-proteins). Covalently bound proteins are usually used for immobilization of different recombinant proteins. Here we explore possibility of using Scw4 and Scw10 as novel immobilization platforms. Previously it was shown that Scw4 protein can be covalently and non-covalently linked to the cell wall structures. It was also shown that proteolytic processing of Scw4 by yapsins strongly affects its covalent binding. As Scw10 shares high level of similarity with Scw4, it is interesting to investigate whether Scw10 can also form both covalent and non-covalent interactions with cell wall structures. Although protein Scw10 also contains sequence charasteristic for Kex2 processing, it is not yet clearly confirmed whether Scw10 is substrate for Kex2. Furthermore, both of these proteins have potential to be used for development of new homologous and heterologous cell surface expression system for wide range of yeast species given that genomes of some other yeast species contain SCW4/SCW10 orthologs, as it is noted before. In order to develop Scw4/Scw10 based expression systems, further characterization of this two proteins is necessary. One line of the research was focused on Scw10 proteolytic processing. Results show that Scw10 undergoes processing by Kex2 and possibly by yapsins at the same site. Results also show that this processing doesn’t affect significantly Scw10 covalent binding efficiency. Other line of the research examines the level of evolutionary preservation of these proteins among different ascomycetes yeast by analysing cell wall protein profiles. Obtained results were coupled with results of in-sillico analysis of proteomes of different yeast species and it was found that Scw4 and Scw10 show high level of evolutionary preservation, given that all of analysed ascomycetes yeast, except two Schizosaccharomyces species, contained at least one protein with high similarity to them. Further research will focus on development of Scw4/Scw10 based expression system models and usage of this models in different yeast species

Published
2019

18. Overview of Catalytic Properties of Fungal Xylose Reductases and Molecular Engineering Approaches for Improved Xylose Utilisation in Yeast

Author

Hossain, Sk Amir, Švec, Danijel, Mrša, Vladimir, and Teparić, Renata

Subjects
Fungal xylose reductase, Xylitol, Xylose bioconversion, Xylose metabolism, ▪ Fungal xylose reductase ▪ Xylitol ▪ Xylose bioconversion ▪ Xylose metabolism, lcsh:Biotechnology, lcsh:TP248.13-248.65
Abstract

Background and Objective: Xylose reductases belong to the aldo-keto reductase family of enzymes, which catalyse the conversion of xylose to xylitol. Yeast xylose reductases have been intensively studied in the last two decades due to their significance in biotechnological production of ethanol and xylitol from xylose. Due to its GRAS status and pronounced tolerance to harsh conditions, Saccharomyces cerevisiae is the ideal organism for industrial production of both xylitol and ethanol. However, Saccharomyces cerevisiae is unable to use xylose as the sole carbon source due to the lack of xylose specific transporters and insufficient activity of metabolic pathways for xylose utilisation. The aim of this paper is to give an overview of attempts in increasing biotechnological potential of xylose reductases and to highlight the prospective of this application. Results and Conclusion: In order to create strains with improved xylose utilization, different approaches were attempted including simultaneous overexpression of xylitol dehydrogenase, xylose reductase and pentose phosphate pathway enzymes, heterologous expression of putative xylose transporters or heterologous expression of genes coding for enzymes included in the xylose metabolism, respectively. Furthermore, number of attempts to genetically modify different xylose reductases is increasing. This review presents current knowledge about yeast xylose reductases and the different approaches applied in order to improve xylose metabolism in yeast.Conflict of interest: The authors declare no conflict of interest.

Published
2018

22. Comparison of proteolytic processing of Saccharomyces cerevisiae cell wall proteins Scw4 and Scw10, and their evolutionary conservation among different yeast species

Author

Grbavac, Antonija, Lozančić, Mateja, Teparić, Renata, and Mrša, Vladimir

Subjects
Scw4, Scw10, cell wall, yeast
Abstract

Scw4p, one of noncovalently bound proteins in Saccharomyces cerevisiae cell wall, undergoes complex proteolytic processing by Kex2 and yapsins. It was suggested that this proteolytic processing can influence its cell wall incorporation, given that Scw4 can form covalent bond with βglucan, and it’s possible that processing has effect on Scw4 biological activity. Scw10 shares high level of similarity with Scw4, and also contains Kex2 processing site, but it remains unclear whether Scw10 is substrate for Kex2. Both of this proteins are considered to be glucanases, although this assumption hasn’t been proven yet. Nevertheless, importance of this two proteins is indicated through extensive phenotypic changes caused by simultaneous deletion of both SCW4 and SCW10. Their evolutionary preservation among different yeast species hasn’t been investigated, however it’s noted that genomes of some other yeast species contain SCW4/SCW10 orthologs.

Published
2019

23. Characetrisation of surface displayed recombinant xylose reductase in Saccharomyces cerevisiae

Author

Teparić, Renata, Hossain, Sk. Amir, Lozančić, Mateja, and Mrša, Vladimir

Subjects
Ccw12, Pir4, Recombinant protein, Saccharomyces cerevisiae, xylose reductase
Abstract

Two types of genetic cassettes for the surface display of heterologous proteins in S. cerevisiae were constructed and their functionality was tested by cloning recombinant enzyme xylose reductase (XR). Cassettes contained strong and regulated host promoter GAL1 or PHO5, a signal sequence for directing the protein into the secretory pathway, an anchoring domain of native cell wall proteins for C- or N-terminal immobilisation, and genetic tags for easy detection of the recombinant protein. YEp351Pir4 plasmid was constructed for the N-terminal immobilisation of heterologous proteins, containing PIR4 under a GAL1 promoter followed by the spacer region (a stretch of eight serine residues), a region consisting of several restriction sites for the insertion of the gene of interest and, finally, followed by the -6xHis and -HA tags. The plasmid pRS425Ccw12G and pRS425Ccw12P were prepared for C-terminal immobilisation of heterologous proteins. This plasmid contains a GAL1 or PHO5 promoter, respectively, followed by the part of CCW12 coding for the signal sequence, the -HA tag, restriction sites for the insertion of the gene of interest, the part of the CCW12 coding for the GPI anchoring signal, and the downstream genetic elements of the CCW12. The S. cerevisiae gene GRE3 coding for intracellular xylose reductase was inserted into the plasmids described above using suitable restriction sites. The construct pRS425Ccw12GXR was modified by introducing the STOP codon immediately after GRE3 coding region, resulting in a secretion of recombinant xylose reductase into the growth medium. Finally, the localization, activity and characteristics of different forms of recombinant xylose reductase were determined. Both types of cassettes proved to be functional, and for this recombinant protein N-terminal immobilisation showed to be better solution for surface display.

Published
2018

25. Overview of systems and techniques for surface display of recombinant proteins in yeast S. cerevisiae

Author

Teparić, Renata and Mrša, Vladimir

Subjects
Genetic immobilization, Heterologous protein, Surface display, Yeast cell wall, lcsh:Biotechnology, lcsh:TP248.13-248.65, Genetic immobilization, Heterologous protein, Surface display, Yeast cell wall
Abstract

In the past decade much effort has been devoted to the development of new expression systems and novel techniques for the surface display of heterologous proteins in yeast in order to improve their applications in biotechnology, food technology, pharmacology and medicine. Heterologous protein-encoding genes are generally fused with genes coding for yeast cell wall proteins or their fragments required for anchoring. The variety of reactions by which a protein can be displayed at the cell surface enables finding the appropriate one for each individual protein. However, it is still challenging how to improve the efficiency of display of protein complexes and increase the quantity of protein displayed on the yeast surface. Recently, synthetic protein chimeras that self-assemble into the scaffolds on the yeast surface displaying different proteins have been constructed. This review focuses on systems and techniques for display of recombinant proteins on the yeast cell surfaces and applications afforded by this technology.

Published
2015

26. Surface display of recombinant xylose reductase in the Saccharomyces cerevisiae

Author

Hossain, Sk Amir, Teparić, Renata, Mrša, Vladimir, Mrša, Vladimir, Teparić, Renata, and Kifer, Domagoj

Subjects
surface display, recombinant proteins, Saccharomyces cerevisiae
Abstract

Most of the vectors constructed so far for the surface display of recombinant proteins in the yeast have been created with ubiquitous plasmids. We have constructed three new plasmids for the surface display of heterologous proteins in the yeast S. cerevisiae that would enable easy insertion of the gene of interest into a prearranged genetic cassette consisting of a strong and regulated host promoter, signal sequence for directing the protein into the secretory pathway, anchoring domain of native cell wall proteins for C- or N-terminal immobilisation, and genetic tags for easy detection of the recombinant protein. YEp351Pir4 plasmid was constructed for the N-terminal immobilisation of the heterologous proteins, containing PIR4 under a GAL1 promoter followed by the spacer region (a stretch of eight serine residues), region consisting of several restriction sites and finally by the -6xHis and -HA tags. Plasmids pRS425Ccw12 and pRS425Ccw12_2 were prepared for C-terminal immobilisation of heterologous proteins. The pRS425Ccw12 plasmid contains GAL1 promoter followed by the part of CCW12 coding for the signal sequence, the -HA tag, restriction sites for the insertion of the gene of interest, the part of the CCW12 coding for the C-terminal part of Ccw12 containing the GPI anchoring signal and the downstream genetic elements of the CCW12. In the pRS425Ccw12_2 plasmid the -HA tag is placed after the heterologous gene insertion site, followed by the GPI anchoring signal and the downstream genetic elements of the CCW12. The gene GRE3 coding for xylose reductase was inserted into the plasmids described above using suitable restriction sites. Finally, the localization, abundance and the activity of the surface displayed xylose reductase were checked by Western blot method and spectrophotometric assay and the results obtained were compared to find out which type of immobilization is best for the surface display of this particular enzyme.

Published
2016

27. Cell wall protein Scw4 as a base for development of new homologous and heterologous expression system models

Author

Grbavac, Antonija, Hossain, Sk Amir, Teparić, Renata and Mrša, Vladimir, van Dijl, Jan Maarten, and Mattanovich, Diethard

Subjects
yeast, Saccharomyces cerevisiae, cell wall, mannoproteins
Abstract

Yeast cell wall contains proteins that are noncovalently (Scw-proteins) or covalently (Ccw-proteins) bound to β-1, 3-glucan, the latter either through GPI-anchors and β-1, 6-glucan, or by alkali labile ester linkages between γ-carboxyl groups of glutamic acid and hydroxyl groups of glucoses (Pir-proteins, extracted from the cell wall by mild alkali). It was shown that three forms of Scw4 with different molecular weights could be isolated from the cell wall. The fact that only one site for Kex2 processing is present in the Scw4 sequence indicates existence of an additional site for processing and an additional proteolytic enzyme involved in processing. Given that group of broad specific aspartic proteases called yapsines process other cell wall proteins, it was presumed that this group of enzymes might have a role in processing of Scw4. In order to investigate the possible role of this enzymes in processing and to find the additional processing site, different mutations were introduced in HA-tagged SCW4 by which potential proteolytic sites where mutated. Native and mutated forms of HA-tagged-Scw4 were expressed in wt, kex2 yeast strain and strain lacking all yapsin genes (5yps∆) and Scw4 processing was examined by Western blot. Protein glycosilation was also examined in order to determine whether forms differ in this way. Results confirmed that the differences in the molecular weight of Scw4 forms isolated from the yeast cell wall were a consequence of its proteolytic processing with Kex2 and/or yapsin proteases using different processing sites in Scw4 sequence. Scw4 was first identified as one of the cell wall proteins non-covalently incorporated in the wall. Later, it has been found that a part of Scw4 could be extracted by mild alkalis from walls previously depleted of non-covalently attached proteins. In order to examine which forms of Scw4 where covalently linked to structures of cell wall, HA-tagged Scw4 was extracted by NaOH from cell wall preparations of w.t., kex2 and yapsin mutants previously depleted of non-covalently linked proteins. Mutants were grown either at pH 4, or at pH 7 in order to obtain all three forms of Scw4 and covalently attached part of the proteins was analysed by Western blot. Results showed that all three forms of Scw4 protein are covalently linked to wall, although smallest form of protein bounds to wall less efficiently. Additional experiments are required in order to determine which part of Scw4 is essential for covalent binding to wall. Given that Scw4 forms covalent link to cell wall, this protein is a good candidate for application in development of new homologous and heterologous expression systems. Future research will focus on identifying part of Scw4 sequence responsible for covalent binding and development of Scw4 based expression system models.

Published
2017

28. Surface display of recombinant proteins in the Saccharomyces cerevisiae

Author

Hossain, Sk Amir, Teparić, Renata, Mrša, Vladimir, Diminić, Janko, Oros, Damir, Starčević Antonio, Uroić, Ksenija, and Žučko, Jurica

Subjects
surface display, recombinant proteins, Saccharomyces cerevisiae
Abstract

Most of the vectors constructed so far for the surface display of recombinant proteins in the yeast have been created with ubiquitous plasmids. We have constructed three new plasmids for the surface display of heterologous proteins in the yeast S. cerevisiae that would enable easy insertion of the gene of interest into a prearranged genetic cassette consisting of a strong and regulated host promoter, signal sequence for directing the protein into the secretory pathway, anchoring domain of native cell wall proteins for C- or N-terminal immobilisation, and genetic tags for easy detection of the recombinant protein. YEp351Pir4 plasmid was constructed for the N-terminal immobilisation of the heterologous proteins, containing PIR4 under a GAL1 promoter followed by the spacer region (a stretch of eight serine residues), region consisting of several restriction sites and finally by the -6xHis and -HA tags. Plasmids pRS425Ccw12 and pRS425Ccw12_2 were prepared for C-terminal immobilisation of heterologous proteins. The pRS425Ccw12 plasmid contains GAL1 promoter followed by the part of CCW12 coding for the signal sequence, the -HA tag, restriction sites for the insertion of the gene of interest, the part of the CCW12 coding for the C-terminal part of Ccw12 containing the GPI anchoring signal and the downstream genetic elements of the CCW12. In the pRS425Ccw12_2 plasmid the -HA tag is placed after the heterologous gene insertion site, followed by the GPI anchoring signal and the downstream genetic elements of the CCW12. The gene GRE3 coding for xylose reductase was inserted into the plasmids described above using suitable restriction sites. Finally, the localization, abundance and the activity of the surface displayed xylose reductase were checked by Western blot method and spectrophotometric assay and the results obtained were compared to find out which type of immobilization is best for the surface display of this particular enzyme.

Published
2016

29. Investigation of processing of the native and mutated forms of Saccharomyces cerevisiae cell wall protein Scw4p

Author

Grbavac, Antonija, Teparić, Renata, Mrša, Vladimir, and Antolović, Roberto

Subjects
Scw4p, Kex2p, yapsins
Abstract

It was previously shown that S. cerevisiae cell wall protein Scw4p undergoes proteolytic processing with Kex2p. However, we observed that three forms of Scw4p with different molecular weights could be isolated from the cell wall. The fact that only one site for Kex2p processing is present in the Scw4p sequence indicates existence of an additional site for processing and an additional proteolytic enzyme involved in processing. According to the potential proteolytic processing sites found in the Scw4p sequence we presumed that aspartic proteases called yapsins might have a role in processing of Scw4p. In order to investigate the possible role of this enzymes in processing and to find the additional processing site, different mutations were introduced in SCW4 by which potential proteolytic sites where mutated. Native and mutated forms of Scw4p were expressed in wt, kex2 yeast strain and strain lacking all yapsin genes (5yps∆) and Scw4p processing was examined. Protein glycosilation was also examined in order to determine whether forms differ in this way. Results confirmed that the differences in the molecular weight of Scw4p forms isolated from the yeast cell wall were a consequence of its proteolytic processing with Kex2p and/or yapsin proteases using different processing sites in Scw4p sequence. In order to determine if there is a link between proteolytic processing and protein activity, mortality rate of yeast strains expressing different forms of Scw4p was estimated by methylene blue staining and MTT test.

Published
2016

31. Proteolytic processing of Saccharomyces cerevisiae cell wall proteins Scw4p and Scw10p

Author

Teparić, Renata, Grbavac, Antonija, Čanak, Iva, Mrša Vladimir, Teparić, Renata, Frece, Jadranka, and Mrša, Vladimir

Subjects
yeast cell walls, cell wall proteins, Scw4p, Scw10p, Kex2p
Abstract

Yeast cell wall contains proteins that are noncovalently (Scw-proteins) or covalently (Ccw-proteins) bound to β-1, 3-glucan, the latter either through GPI-anchors and β-1, 6- glucan, or by alkali labile ester linkages between γ-carboxyl groups of glutamic acid and hydroxyl groups of glucoses (Pir-proteins, extracted from the cell wall by mild alkali). It was previously shown that one of the most abundant Scw protein, Scw4p is partly also covalently linked to the cell wall, as well as it’s homolog Scw10p. In this work it was shown that part of Scw4p and Scw10p underwent the proteolytic processing resulting in three forms of the protein in the cell wall. The proteolytic enzymes which might have a role in processing of Scw4p and Scw10p are Kex2p and a family of aspartic proteases called yapsins. To get a better insight in the processing of these proteins, different mutations were introduced to SCW4 in the region of predicted processing sites. Native and mutated forms of Scw4p were expressed in kex2 yeast strain and strain with all yapsin genes disrupted (5yps∆) and Scw4p processing was examined. Protein glycosilation was also examined in order to determine whether forms differ in this way.

Published
2013

32. Surface display of proteins – potential in food processing and control

Author

Mrša, Vladimir and Teparić, Renata, Yildiz, Fatih, Bagdadli, Volkan, and Arcan, Emre

Subjects
surface display, genetic immobilization, microbial cell walls
Abstract

Studies of microbial cell envelopes and particularly cell surface proteins and mechanisms of their localization brought about new biotechnological applications of gained knowledge in surface display of homologous and heterologous proteins. By fusing surface proteins, or their anchoring domains with different proteins of interest their so called genetic immobilization is achieved. Hybrid proteins are engineered in a way that they are expressed in the host cells, secreted to the cell surface and incorporated into the wall/envelope moiety. In this way laborious and often detrimental procedure of chemical immobilization of the protein is avoided by letting the cells do the whole procedure. Both bacterial and yeast cells have been used for this purpose and a number of potential biotechnological applications of surface displayed proteins have been reported. Examples range from microbial whole cell biocatalysts, biosorbents, biosensors and biostimulants development to design and screening of protein and peptide libraries. When surface immobilized enzymes are used, substrates do not need to cross membrane barriers, i.e. enzymes are free to access any externally added substrate. Thus, often complex and expensive purification of the enzymes used on an industrial scale is bypassed. In addition, the multi-step transformation can be performed using microbial cells displaying different enzymes that catalyze cascade reactions. In recent years particular attention has been paid to yeast systems for surface display of proteins since most yeasts are generally regarded as safe (GRAS) microorganisms, yeast cell walls are capable of binding more proteins, and the cells are bigger. Besides, yeasts are generally more suitable for expression of proteins originating from higher eukaryotes. In this talk our current knowledge on mechanisms and molecular systems for surface display of proteins on bacterial and yeast cell surfaces will be discussed.

Published
2015

33. Surface display of proteins - decorating cells, not just for fun

Author

Teparić, Renata and Mrša, Vladimir and Obradović, Dragojlo

Subjects
surface display, genetic immobilization, microbial cell walls
Abstract

Studies of microbial cell envelopes and particularly cell surface proteins and mechanisms of their localization brought about new biotechnological applications of gained knowledge in surface display of homologous and heterologous proteins. By fusing surface proteins, or their anchoring domains with different proteins of interest their so called genetic immobilization is achieved. Hybrid proteins are engineered in a way that they are expressed in the host cells, secreted to the cell surface and incorporated into the wall/envelope moiety. In this way laborious and often detrimental procedure of chemical immobilization of the protein is avoided by letting the cells do the whole procedure. Both bacterial and yeast cells have been used for this purpose and a number of potential biotechnological applications of surface displayed proteins have been reported. Examples range from microbial whole cell biocatalysts, biosorbents, biosensors and biostimulants development to design and screening of protein and peptide libraries. When surface immobilized enzymes are used, substrates do not need to cross membrane barriers, i.e. enzymes are free to access any externally added substrate. Thus, often complex and expensive purification of the enzymes used on an industrial scale is bypassed. In addition, the multi-step transformation can be performed using microbial cells displaying different enzymes that catalyze cascade reactions. In recent years particular attention has been paid to yeast systems for surface display of proteins since most yeasts are generally regarded as safe (GRAS) microorganisms, yeast cell walls are capable of binding more proteins, and the cells are bigger. Besides, yeasts are generally more suitable for expression of proteins originating from higher eukaryotes. In this talk our current knowledge on mechanisms and molecular systems for surface display of proteins on bacterial and yeast cell surfaces will be discussed.

Published
2015

34. Purification and Characterization of a Novel Cold-Active Lipase from the Yeast Candida zeylanoides

Author

Čanak, Iva, Berkics, Adrienn, Bajcsi, Nikolett, Kovacs, Monika, Belak, Agnes, Teparić, Renata, Maraz, Anna, and Mrša, Vladimir

Subjects
Lipase, Candida zeylanoides, Cold-active enzyme, Cold-active lipase, Lipase purification, Lipase properties
Abstract

Cold-active lipases have attracted attention in recent years due to their potential applications in reactions requiring lower temperatures. Both bacterial and fungal lipases have been investigated, each having distinct advantages for particular applications. Among yeasts, cold- active lipases from the genera Candida, Yarrowia, Rhodotorula , and Pichia have been reported. In this paper, biosynthesis and properties of a novel cold-active lipase from Candida zeylanoides isolated from refrigerated poultry meat are described. Heat-sterilized olive oil was found to be the best lipase biosynthesis inducer, while nonionic detergents were not effective. The enzyme was purified to homogeneity using hydrophobic chromatography and its enzymatic properties were tested. Pure enzyme activity at 7 ° C was about 60% of the maximal activity at 27°C. The enzyme had rather good activity at higher temperatures, as well. Optimal pH of pure lipase was between 7.3 and 8.2, while the enzyme from the crude extract had an optimum pH of about 9.0. The enzyme was sensitive to high ionic strength and lost most of its activity at high salt concentrations. Due to the described properties, cold-active C. zeylanoides lipase has comparative advantages to most similar enzymes with technological applications and may have potential to become an industrially important enzyme.

Published
2015

35. The role of Kex2p and yapsins in the proteolytic processing of Scw4p in the Saccharomyces cerevisiae cell wall

Author

Grbavac, Antonija, Rušev, Ana, Teparić, Renata, Mrša, Vladimir, Dumić, Jerka, Kovarik, Zrinka, Varljen, Jadranka, Mrša, Vladimir, and Teparić, Renata

Subjects
Scw4p, Kex2p, 5yps∆, yapsins
Abstract

Yeast cell wall contains proteins that are noncovalently (Scw- proteins) or covalently (Ccw-proteins) bound to β-1, 3-glucan, the latter either through GPI-anchors and β-1, 6-glucan, or by alkali labile ester linkages between γ-carboxyl groups of glutamic acid and hydroxyl groups of glucoses (Pir-proteins, extracted from the cell wall by mild alkali). It was previously shown that one of the most abundant Scw protein, Scw4p is partly also covalently linked to the cell wall. In this work it was shown that part of Scw4p underwent the proteolytic processing resulting in two forms of the protein in the cell wall. The proteolytic enzymes which might have a role in processing of Scw4p are Kex2p and a family of aspartic proteases called yapsins. To get a better insight in the processing of Scw4p, kex2 yeast strain and strain with all yapsin genes disrupted (5yps∆) were used. Scw4p was overproduced in these strains and Scw4p processing was examined.

Published
2012

36. THE EFFECT OF PROTEOLYTIC PROCESSING ON THE LOCALIZATION AND PHYSIOLOGICAL ACTIVITY OF THE Saccharomyces cerevisiae CELL WALL PROTEIN Scw4p

Author

Teparić, Renata, Grbavac, Antonija, Kunštek, Sandra, Mrša, Vladimir, Katalinić, Maja, and Kovarik, Zrinka

Subjects
Scw4p, Kex2p, yapsins
Abstract

Yeast cell wall contains proteins that are noncovalently (Scw- proteins) or covalently (Ccw-proteins) bound to β-1, 3-glucan, either through GPI-anchors and β-1, 6-glucan, or by alkali labile ester linkages between γ-carboxyl groups of glutamic acid and hydroxyl groups of glucoses (Pir-proteins). It was previously shown that one of the most abundant Scw protein, Scw4p is partly also covalently linked to the cell wall and that non- covalently bound Scw4p underwent the proteolytic processing, while the covalently bound Scw4p was not processed. Such finding indicates that the proteolytic processing might determine the localization of these two forms of the protein. Proteolytic enzymes which might have a role in processing of Scw4p are Kex2p and a family of aspartic proteases called yapsins. To get a better insight in the processing of Scw4p, different mutations were introduced to SCW4 in the region of predicted processing sites. On the other hand mutant strain was constructed missing all yapsin proteases and Kex2p (5yps∆kex2). Native and mutated forms of Scw4p were expressed in kex2 yeast strain, strain with all yapsin genes disrupted (5yps∆) and strain with all proteases disrupted (5yps∆kex2) and Scw4p processing was examined. Furthermore, phenotypes of strains overproducing native and genetically modified Scw4p forms were examined.

Published
2014

37. Surface display of proteins in microorganisms – potential applications in food control and processing

Author

Teparić, Renata and Mrša, Vladimir, Neyestani, Tirang, and Hajifaraji, Majid

Subjects
surface display, genetic immobilization, bacterial envelope, yeast cell wall, food processing enzymes
Abstract

Studies of microbial cell envelopes and particularly cell surface proteins and mechanisms of their localization brought about new biotechnological applications of gained knowledge in surface display of homologous and heterologous proteins. By fusing surface proteins, or their anchoring domains with different proteins of interest their so called genetic immobilization is achieved. Hybrid proteins are engineered in a way that they are expressed in the host cells, secreted to the cell surface and incorporated into the wall/envelope moiety. In this way laborious and often detrimental procedure of chemical immobilization of the protein is avoided by letting the cells do the whole procedure. Both bacterial and yeast cells have been used for this purpose and a number of potential biotechnological applications of surface displayed proteins have been reported. Examples range from microbial whole cell biocatalysts, biosorbents, biosensors and biostimulants development to design and screening of protein and peptide libraries. When surface immobilized enzymes are used, substrates do not need to cross membrane barriers, i.e. enzymes are free to access any externally added substrate. Thus, often complex and expensive purification of the enzymes used on an industrial scale is bypassed. In addition, the multi-step transformation can be performed using microbial cells displaying different enzymes that catalyze cascade reactions. In recent years particular attention has been paid to yeast systems for surface display of proteins since most yeasts are generally regarded as safe (GRAS) microorganisms, yeast cell walls are capable of binding more proteins, and the cells are bigger. Besides, yeasts are generally more suitable for expression of proteins originating from higher eukaryotes. In this talk our current knowledge on mechanisms and molecular systems for surface display of proteins on bacterial and yeast cell surfaces will be discussed. Particularly, potential applications of surface displayed proteins in food processing, as well as for creation of sensors suitable for food control will be summarized.

Published
2014

39. Proteolytic processing of Saccharomyces cerevisiae cell wall protein Scw4p

Author

Teparić, Renata, Grbavac, Antonija, Čanak, Iva, Mrša, Vladimir, and Polčic, Peter

Subjects
yeast cell walls, cell wall proteins, Scw4p, Kex2p
Abstract

Yeast cell wall contains proteins that are noncovalently (Scw-proteins) or covalently (Ccw-proteins) bound to β-1, 3-glucan, either through GPI-anchors and β-1, 6-glucan, or by alkali labile ester linkages between γ-carboxyl groups of glutamic acid and hydroxyl groups of glucoses (Pir- proteins). It was previously shown that one of the most abundant Scw protein, Scw4p is partly also covalently linked to the cell wall and that non-covalently bound Scw4p underwent the proteolytic processing, while the covalently bound Scw4p was not processed. Such finding indicates that the proteolytic processing might determine the localization of these two forms of the protein. Proteolytic enzymes which might have a role in processing of Scw4p are Kex2p and a family of aspartic proteases called yapsins. To get a better insight in the processing of Scw4p, different mutations were introduced to SCW4 in the region of predicted processing sites. Besides, native and mutated forms of Scw4p were expressed in kex2 yeast strain and strain with all yapsin genes disrupted (5yps∆) and Scw4p processing was examined.

Published
2013

40. Overview of Saccharomyces cerevisiae Ribonucleases

Author

Teparić, Renata, Didak, Blanka, and Landeka, Irena

Subjects
yeast RNases, RNA processing, RNA turnover
Abstract

Ribonucleases (RNases) are hydrolytic enzymes that hydrolyze single-stranded RNA, double-stranded RNA, and RNA hybridized with DNA. Cells produce some specific ribonucleases that are needed in a variety of cellular processes, but also a set of general RNases that are secreted or targeted to the lysosome or vacuole. Eukaryotes have developed highly complex RNA processing and turnover of multiple pathways. In general, each type of RNA has a distinctive complement of components that accomplish and regulate its biosynthesis and turnover, though there are components that are Adapted to act along the multiple pathways. In this paper overview of Saccharomyces cerevisiae RNases is given along with short description of their functions in RNA processing and turnover in the cell.

Published
2012

41. The role of proteolytic processing in the covalent attachment of Scw4p in the Saccharomyces cerevisiae cell wall

Author

Rušev, Ana, Grbavac, Antonija, Teparić, Renata, Stuparević, Igor, Mrša, Vladimir, and Antolović R, Miličević T

Subjects
Scw4, cell wall proteins
Abstract

Yeast cell wall contains proteins that are noncovalently (Scw-proteins) or covalently (Ccw-proteins) bound to β-1, 3-glucan, the latter either through GPI-anchors and β-1, 6-glucan, or by alkali labile ester linkages between γ-carboxyl groups of glutamic acid and hydroxyl groups of glucoses (Pir-proteins, extracted from the cell wall by mild alkali). It was previously shown that one of the most abundant Scw protein, Scw4p is partly also covalently linked to the cell wall. In this work it was shown that non-covalently bound Scw4p underwent the proteolytic processing, while the covalently bound Scw4p was not processed, indicating that the proteolytic processing might determine the localization of these two forms of the protein. Results showed that the proteolytic enzymes which might have a role in processing of Scw4p are Kex2p and a family of aspartic proteases called yapsins. Besides, it was shown that the two molecular forms reached the cell surface by different routes, the processed form via Sec14p dependent secretory pathway together with most other cell wall and periplasmic proteins, and the unprocessed form using the Sec14p independent pathway. To try to get a better insight in the biological role of Scw4p, phenotypes of strains overproducing Scw4p were examined. It was found that the overproduction of the proteins led to significantly higher mortality of cells, particularly in the stationary phase of growth, increased sensitivity to Calcofluor White, Congo Red and SDS, and to markedly increased cell size.

Published
2011

43. Effects of Dietary Lipids on Lipoprotein Profi le

Author

Landek, Irena, Teparić, Renata, Perica, Tomislav, Đikić, Domagoj, and Rogić, Dunja

Subjects
fatty acids, lipoproteins, cholesterol, lipoprotein metabolism, lipids (amino acids, peptides, and proteins)
Abstract

Cholesterol, fats and oils belongs to the family of lipids. Lipids are important source of energy and, beside that, they are biologically active molecules that have many important roles in organism. Fat and cholesterol can’t dissolve in blood, so they are transported in the plasma as triglicerydes or by large complexes called lipoproteins. In this paper an overview of dietary lipids, sources of diffrent dietary lipids and lipoprotein metabolism is presented as well as adverse effects of over consumption of cholesterol and fat on body weight and health.

Published
2010

44. Using S. cerevisiae cell wall protein Ccw12p as a anchor for expression of two yeast nucleases at the cell surface

Author

Teparić, Renata, Mrša, Vladimir, Kovarik, Zrinka, and Varljen, Jadranka

Subjects
yeast cell wall, Ccw12p, heterologous expression
Abstract

In the past several years a number of surface – engineered yeasts, displaying different heterologous proteins interesting for biotechnological or medical applications, have been constructed. Yeast cell surface systems for the display of heterologous proteins have the advantages of simplicity of genetic manipulation, ability for proper post-translational modifications and folding of mammalian proteins and immobilization of heterologous proteins covalently under mild, physiological conditions without risk of damage by chemical treatment. S. cerevisiae cell wall proteins that are covalently bound to the carbohydrate components of the wall can be divided in two main groups. Majority of proteins of this class are bound at their C-termini through a remnant of the GPI-anchor. A smaller group of proteins are directly covalently bound at their N-termini to -1, 3-glucan by the alkali labile ester linkage between the glutamic acid γ-carboxyl group and hydroxyl groups of glucoses (Pir–proteins). In this work Ccw12p cell wall protein, that belongs to the group of cell wall proteins bound through GPI-anchor remnant, is used for C-terminal immobilization of two yeast intracellular nucleases, Yblp and Rnyp, to the yeast cell surface.

Published
2010

45. Using S. cerevisiae cell wall proteins as a anchor for expression of heterologous proteins at the cell surface

Author

Teparić, Renata, Mrša, Vladimir, and Marialigeti, K.

Subjects
cell wall, Pir4p, Ccw12p, heterologous expression
Abstract

In the past several years much efforts have been devoted to the study of expression systems for the display of heterologous proteins at the surface of microorganisms, opening new perspectives in biotechnology. Yeast cell surface systems have the advantages of simplicity of genetic manipulation and ability for proper post-translational modifications and folding of mammalian proteins. Yeast whole-cell biocatalysts displaying enzymes on their cell surface can be produced at a low cost and show a high enzymatic activity. Recently a number of surface – engineered yeasts, displaying different heterologous proteins interesting for biotechnological or medical applications, have been constructed. S. cerevisiae cell wall proteins that are covalently bound to the carbohydrate components of the wall can be divided in two main groups. Majority of proteins of this class are bound at their C-termini through a remnant of the GPI-anchor. A smaller group of proteins are directly covalently bound at their N-termini to beta-1, 3-glucan by the alkali labile ester linkage between the glutamic acid gamma-carboxyl group and hydroxyl groups of glucoses (Pir – proteins). Almost all heterologous proteins constructed so far for yeast surface display are GPI-anchored to the cell wall using C-terminal part of alpha-agglutinin as anchor. Some enzymes, whose active sites are located near their C-terminiare not suitable for display through GPI anchor that must be fused at their C-terminal region. Possible approach for such enzymes is to use Pir –proteins as a cell wall anchor. In this work Pir4p was used as anchor for N-terminal immobilization and Ccw12p for C-terminal immobilization of heterologous proteins to the yeast cell surface.

Published
2009

46. Localization of yeast cell wall mannoproteins - impact on wall biogenesis

Author

Stuparević, Igor, Teparić, Renata, Mrša, Vladimir, and Marialigeti, K.

Subjects
cell wall, Pir proteins, Scw proteins, heterologous expression
Abstract

Yeast cell wall contains proteins that are noncovalently (Scw-proteins), or covalently (Ccw-proteins) bound to beta-1, 3-glucan, the latter either through GPI-anchors and beta-1, 6-glucan, or by alkali labile ester linkages between gamma-carboxyl groups of glutamic acid and hydroxyl groups of glucoses (Pir-proteins, extracted from the cell wall by mild alkali). Disruption of all four genes coding for Pir-proetins revealed that 67 kDa protein still remained in the NaOH extract. Disruption of the SCW4, a gene coding for one of most abundant SCW proteins resulted in the disappearance of the band, indicating that Scw4p was partly also covalently linked to the cell wall by an apparently new, so far unobserved alkali sensitive linkage. Structural analysis revealed that N-terminal part of the protein is required for anchoring in the wall. Both the absence and the increased concentration of Scw proteins resulted in undesirable changes in the wall and in the increase in cell mortality, particulary upon entering the stationary growth conditions. Possibilities for application of the knowledge gained on different mechanisms for incorporation of wall proteins in heterologous expression of proteins in yeast and their ˝genetic immobilisation˝ will be discussed.

Published
2009

47. Alkali-extractable proteins in Saccharomyces cerevisiae cell wall

Author

Stuparević, Igor, Teparić, Renata, Mrša, Vladimir, and Andrews, Brenda

Subjects
yeast, cell wall, Pir proteins, CCW5, SCW4
Abstract

The cell wall of yeast Saccharomyces cerevisiae contains more than 20 different manoproteins. They are considerd to play different roles in building, maintaining and modifying the wall itself when different cell cycle events and they are important for interactions of cells with their surrounding. Yeasts have evolved three different ways of attaching proteins to cell wall glucan. Some proteins are bound to β -1, 3-glucan noncovalently (Scw – soluble cell wall proteins ; extracted by hot SDS), while others are attached covalently (Ccw – covalently linked cell wall proteins ; extracted by glucanases) through GPI-anchor and β -1, 6-glucan, or directly to β -1, 3-glucan by alkali labile ester linkage between the γ -carboxyl groups of glutamic acid and hydroxyl groups of glucoses (Pir – proteins with internal repeats ; extracted by NaOH). Disruption of genes coding for the Pir-proteins was performed to investigate their potential role. After disruption of all PIR genes, 67kDa protein still remained in NaOH extract. SCW4 disruption resulted in disappearance of a 67kDa band from the extract, indicating that Scw4p could also be covalently linked to the cell wall simillar to Pir-proteins. Since it was reported previously that Scw4p was a noncovalently attached protein, this finding can be relevant for the role of Scw4p. In order to investigate the role of the Scw4p in the construction of the cell wall, yeast was transformed with a high copy number plasmid containing SCW4. In order to get further insight in the binding mechanism, a novel, simple binding assay for Pir family proteins was developed in which externally added Ccw5p/Pir4p was bound to different cell wall mutant strains. It has been shown that pir, as well as scw4 and scw10 mutants can bind externally added Ccw5p to their cell wall. Further, we investigated the conditions under which these proteins were attached to cell wall. The presence of EDTA blocked the binding of Ccw5p, indicating the cation dependence of the reaction. Both wild type and mutant cells showed enhanced binding in 0.6 M KCl. It was also shown that the native conformation of Ccw5p is required for its binding.

Published
2008

48. Expression of heterologous proteins at the S. cerevisiae cell surface using Pir4p as a cell wall anchor

Author

Teparić, Renata, Stuparević, Igor, Mrša, Vladimir, Strelec, Ivica, and Glavaš-Obrovac, Ljubica

Subjects
cell wall, Pir4p, heterologous expression
Abstract

In the past several years much efforts have been devoted to the study of expression systems for the display of heterologous proteins at the surface of microorganisms, opening new perspectives in biotechnology. Recently a number of surface – engineered yeasts, displaying different heterologous proteins interesting for biotechnological or medical applications, have been constructed. Yeast cell surface systems have the advantages of simplicity of genetic manipulation and ability for proper post-translational modifications and folding of mammalian proteins. Yeast whole-cell biocatalysts displaying enzymes on their cell surface can be produced at a low cost and show a high enzymatic activity without permeabilization treatment. S. cerevisiae cell wall proteins that are covalently bound to the carbohydrate components of the wall can be divided in two main groups. Majority of proteins of this class are bound at their C-termini through a remnant of the GPI-anchor. A smaller group of proteins are directly covalently bound at their N-termini to β -1, 3-glucan by the alkali labile ester linkage between the glutamic acid γ -carboxyl group and hydroxyl groups of glucoses (Pir – proteins). Almost all heterologous proteins constructed for yeast surface display are GPI-anchored to the cell wall. Most frequently used GPI-anchored yeast cell wall protein for this purpose is  -agglutinin. Some enzymes, whose active sites are located near their C-termini are not suitable for display through GPI anchor that must be fused at their C-terminal region. Possible approach for such enzymes is to use Pir – proteins as a cell wall anchor. In this work Pir4p was used as anchor for N-terminal immobilization of β -galactosidase and yeast lipase Tgl3p to the yeast cell surface.

Published
2008

Catalog

Books, media, physical & digital resources
See catalog results