Staff Publications

Staff Publications

  • external user (warningwarning)
  • Log in as
  • language uk
  • About

    'Staff publications' is the digital repository of Wageningen University & Research

    'Staff publications' contains references to publications authored by Wageningen University staff from 1976 onward.

    Publications authored by the staff of the Research Institutes are available from 1995 onwards.

    Full text documents are added when available. The database is updated daily and currently holds about 240,000 items, of which 72,000 in open access.

    We have a manual that explains all the features 

    Current refinement(s):

    Records 1 - 2 / 2

    • help
    • print

      Print search results

    • export

      Export search results

    Check title to add to marked list
    De novo sequencing, assembly and analysis of the genome of the laboratory strain Saccharomyces cerevisiae CEN.PK113-7D, a model for modern industrial biotechnology
    Nijkamp, J.F. ; Broek, M. van den; Datema, E. ; Kok, S. de; Bosman, L. ; Luttik, M.A. ; Daran-Lapujade, P. ; Vongsangnak, W. ; Nielsen, J. ; Heijne, W.H.M. ; Klaassen, P. ; Paddon, C.J. ; Platt, D. ; Kotter, P. ; Ham, R.C.H.J. van; Reinders, M.J.T. ; Pronk, J.T. ; Ridder, D. de; Daran, J.M. - \ 2012
    Microbial Cell Factories 11 (2012). - ISSN 1475-2859
    l-arabinose - alcoholic fermentation - biotin-prototrophy - chemostat cultures - gene prediction - yeast genome - glucose - evolutionary - protein - xylose
    Saccharomyces cerevisiae CEN.PK 113-7D is widely used for metabolic engineering and systems biology research in industry and academia. We sequenced, assembled, annotated and analyzed its genome. Single-nucleotide variations (SNV), insertions/deletions (indels) and differences in genome organization compared to the reference strain S. cerevisiae S288C were analyzed. In addition to a few large deletions and duplications, nearly 3000 indels were identified in the CEN.PK113-7D genome relative to S288C. These differences were overrepresented in genes whose functions are related to transcriptional regulation and chromatin remodelling. Some of these variations were caused by unstable tandem repeats, suggesting an innate evolvability of the corresponding genes. Besides a previously characterized mutation in adenylate cyclase, the CEN. PK113-7D genome sequence revealed a significant enrichment of non-synonymous mutations in genes encoding for components of the cAMP signalling pathway. Some phenotypic characteristics of the CEN. PK113-7D strains were explained by the presence of additional specific metabolic genes relative to S288C. In particular, the presence of the BIO1 and BIO6 genes correlated with a biotin prototrophy of CEN. PK113-7D. Furthermore, the copy number, chromosomal location and sequences of the MAL loci were resolved. The assembled sequence reveals that CEN. PK113-7D has a mosaic genome that combines characteristics of laboratory strains and wild-industrial strains.
    Malic acid production by Saccharomyces cerevisiae: engineering of pyruvate carbosylation, oxaloacetate reduction and malate export
    Zelle, R.M. ; Hulster, E. de; Winden, W.A. van; Waard, P. de; Dijkema, C. ; Winkler, A.A. ; Geertman, J.M.A. - \ 2008
    Applied and Environmental Microbiology 74 (2008)9. - ISSN 0099-2240 - p. 2766 - 2777.
    metabolic-flux analysis - aspergillus-flavus - chemostat cultures - alcoholic fermentation - carbon metabolism - escherichia-coli - organic-acids - mdh2 isozyme - yeast - glucose
    Malic acid is a potential biomass-derivable "building block" for chemical synthesis. Since wild-type Saccharomyces cerevisiae strains produce only low levels of malate, metabolic engineering is required to achieve efficient malate production with this yeast. A promising pathway for malate production from glucose proceeds via carboxylation of pyruvate, followed by reduction of oxaloacetate to malate. This redox- and ATP-neutral, CO2-fixing pathway has a theoretical maximum yield of 2 mol malate (mol glucose)¿1. A previously engineered glucose-tolerant, C2-independent pyruvate decarboxylase-negative S. cerevisiae strain was used as the platform to evaluate the impact of individual and combined introduction of three genetic modifications: (i) overexpression of the native pyruvate carboxylase encoded by PYC2, (ii) high-level expression of an allele of the MDH3 gene, of which the encoded malate dehydrogenase was retargeted to the cytosol by deletion of the C-terminal peroxisomal targeting sequence, and (iii) functional expression of the Schizosaccharomyces pombe malate transporter gene SpMAE1. While single or double modifications improved malate production, the highest malate yields and titers were obtained with the simultaneous introduction of all three modifications. In glucose-grown batch cultures, the resulting engineered strain produced malate at titers of up to 59 g liter¿1 at a malate yield of 0.42 mol (mol glucose)¿1. Metabolic flux analysis showed that metabolite labeling patterns observed upon nuclear magnetic resonance analyses of cultures grown on 13C-labeled glucose were consistent with the envisaged nonoxidative, fermentative pathway for malate production. The engineered strains still produced substantial amounts of pyruvate, indicating that the pathway efficiency can be further improved
    Check title to add to marked list

    Show 20 50 100 records per page

     
    Please log in to use this service. Login as Wageningen University & Research user or guest user in upper right hand corner of this page.