| Literature DB >> 22844449 |
Rasmus Torbensen1, Henrik Devitt Møller, David Gresham, Sefa Alizadeh, Doreen Ochmann, Eckhard Boles, Birgitte Regenberg.
Abstract
Amino acids can induce yeast cell adhesion but how amino acids are sensed and signal the modulation of the FLO adhesion genes is not clear. We discovered that the buddingEntities:
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Year: 2012 PMID: 22844449 PMCID: PMC3406018 DOI: 10.1371/journal.pone.0041272
Source DB: PubMed Journal: PLoS One ISSN: 1932-6203 Impact factor: 3.240
Figure 1Invasive growth of haploid descendants after prolonged nitrogen limitation.
Descendants of CEN.PK113-7D in A, glutamine-limited culture, and C, ammonium-limited culture, grown on rich complex medium (YPD) for 3 days at 30°C and flushed with water to determine the proportion of adhering clones (B and D). Of descendants from the glutamine-limited population, 80% were invasive on YPD, while in the two ammonium-limited populations, 40% and 26% percent had become invasive (n>200).
Peptide modifications in six clonal isolates from prolonged nitrogen-limited populations.
| Gene | Glutamine-limited clones | Ammonium-limited clones | ||||
| I | II | III | IV | V | VI | |
| Invasive | Invasive | Non-invasive | Non-invasive | Invasive | Invasive | |
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| Δ | S388P | Δ | |||
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| G352S | |||||
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| T672A | |||||
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| Q320 STOP | |||||
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| 647::CWNKNPLSSIN | |||||
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| D206E | |||||
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| Synonymous | |||||
Denoted are the protein modifications resulting from mutations in the clonal isolates. The corresponding mutations are described in Material and Methods.
Figure 2Mutant alleles restore invasive growth in wildtype strain and invasiveness correlates with increased FLO11 mRNA.
Mutations from invasive descendants of glutamine- and ammonium-limited populations were reconstituted in the wildtype strain (A) and tested for invasive growth (B). Distribution of strains with pho (RB389), sfl1Δ (RB595), PTR3647::C…N (RB567), gdh (RB484), gap1Δ (RB318) (C). mRNA levels for FLO adhesion genes (italic) and amino acid permease genes (italic bold) are shown for glutamine-limited mutants Ptr3647::C…N and Sfl1Q320STOP after growth to mid-exponential phase in liquid YPD (D). Presented are log2-transformed ratios of transcripts. The color code bar illustrates fold-change in mRNA in mutants relative to the wildtype strain CEN.PK113-7D. For the entire clustering of genes with more than 2-fold altered mRNA levels see Fig. S2.
Figure 3Gap1-dependent FLO11 expression and invasive growth in Ptr3647::C…N.
Amino acid permease gene product in invasive growth ability in Ptr3647::C…N was tested in a ura3 PTR3647::C…N background (RB428) by introducing gene deletions dip5 (RB468), gnp1 (RB469) or gap1 (RB547). Cells were grown on rich complex medium (YPD) for 2 day at 30°C (A, upper panel) and flushed with water to expose invasive growth (A, lower panel). Northern blot of FLO11 mRNA for strains in A are shown in B (upper panel). RNA for ribosomal subunits 18S and 28S served as loading controls (B, lower panel). Genes of modulating proteins in invasive growth were deleted in the RB428 mutant: flo11 (RB457), tec1 (RB460), tpk2 (RB461), cyr1 (RB465), gcn4 (RB472), mss11 (RB474), ssy1 (RB477) and ptr3 (RB492). Cells were grown on YPD for 3 days at 30°C (C). The plate was flushed with water to test for invasive growth (D). Distribution of deletion strains in C and D are in E.
Figure 4Increased Gln, His, Arg and Lys pools in Ptr3647::C…N and invasive growth of mutants on glutamine minimal medium.
(A) shows amino acid concentrations (nmol 108 cells−1) in whole cells of ura3 strains isogenic to the wildtype (CEN.PK113-5D), Sfl1Q320STOP (RB20), Sfl1Q320STOP dip5 (RB317) and Ptr3647::C…N (RB428) after growth to 1–2×107 cells ml−1 in liquid YPD. Values shown are representative of three independent experiments. Descendants from glutamine-limited cultures of Sfl1Q320STOP and Ptr3647::C…N were grown as indicated (B) on complex YPD, synthetic minimal medium with 100 mM glutamine or 100 mM ammonium as the sole nitrogen source for 5 days at 30°C. Plates were washed to reveal adhesion.
Figure 5Amino acid permease genes DIP5 and GNP1 are essential for invasive growth in Sfl1Q320STOP.
Amino acid permease genes were deleted in ura3 Sfl1Q320STOP (RB20) to obtain the mutants dip5 (RB317), gnp1 (RB197) and gap1 (RB531). Strains were grown one day on YPD at 30°C (A, upper panel) and washed to expose invasive growth (A, lower panel). FLO11 mRNA from individual mutants was examined by Northern blotting (B, upper panel) with 18S and 28S rRNA as loading controls (B, lower panel). Regulators of invasive growth were deleted in the RB20 background: flo11 (RB184), tec1 (RB540); tpk2 (RB538), cyr1 (RB201), gcn4 (RB475), mss11 (RB488), ssy1 (RB199) and ptr3 (RB486). After 3 days of growth on YPD (C), plates were flushed with water to reveal invasive growth (D). Mutant Sfl1Q320STOP strains in C and D are shown in E.
Figure 6Dip5 interacts with Gnp1 and Mep2.
Physical interaction between Dip5 and transporters Hxt1, Mep1, Mep2, Dip5, Gnp1 was tested with the membrane protein-based split-ubiquitin system in the CEN.PK background. Ade- His- cells (THY.AP4) expressing the C-terminal part of ubiquitin fused to Dip5 and the transcriptional activator PLV were mated to Ade- His- cells (THY.AP5) expressing the N-terminal part of ubiquitin fused to either Hxt1, Mep1, Mep2, Dip5 or Gnp1. Interacting protein-pairs formed a functional ubiquitin that released PLV for induction of the HIS3 and ADE2 genes, enabling growth on synthetic complete medium without adenine and histidine.
Figure 7DIP5 and GNP1 are essential for biofilm formation and DIP5 depletion abolishes pseudohyphal differentiation of Sfl1Q320STOP.
Biofilm formation on a polystyrene surface was tested in the Sfl1Q320STOP trp1 background (RB52) of Sfl1Q320STOP dip5 (RB317), Sfl1Q320STOP gnp1 (RB196) and compared to ∑1278b strain 10560-2B, ∑1278b dip5 gnp1 (RB157) and the wildtype strain CEN.PK110-16D. After 24 hours growth, in either synthetic complete 0.1% glucose or synthetic complete 2.0% glucose, biofilms were visualized by crystal violet staining and then washed three times (A). Homozygous diploid strains in the Sfl1Q320STOP background were incubated on low-ammonium SLAD medium for 3 days at 30°C to test for pseudohyphal growth (B).
Figure 8Models of FLO gene regulation by amino-acid transporters.
Extracellular amino acids induce the SPS complex at the plasma membrane (PM) and the activated complex elicits gene expression of amino acid transporters DIP5 and GNP1. Dip5 and Gnp1 activate FLO11 transcription in a manner dependent on activity of the PKA-pathway (A). Inactive SPS signaling indirectly leads to increased transcript levels of GAP1. Gap1 increases the amino acid pool concentration, which in turn triggers a PKA independent signal for induction of FLO genes (B). PM, plasma membrane. NM, nuclear membrane.
S. cerevisiae strains and populations used in this study.
| Strain | Genotype | Reference/source |
| Wildtype CEN.PK113-7D |
|
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| CEN.PK113-5D |
|
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| CEN.PK110-16D |
|
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| 10560-2B (Σ1276 |
|
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| THY.AP4 |
|
|
| THY.AP5 |
|
|
| RB1 |
| this study |
| RB3 |
| this study |
| RB12 |
| this study |
| RB16 |
| this study |
| RB17 |
| this study |
| RB18 |
| this study |
| RB20 |
| this study |
| RB52 |
| this study |
| RB157 |
| this study |
| RB184 |
| this study |
| RB196 |
| this study |
| RB197 |
| this study |
| RB199 |
| this study |
| RB201 |
| this study |
| RB209 |
| this study |
| RB210 |
| this study |
| RB317 |
| this study |
| RB318 |
| this study |
| RB389 |
| this study |
| RB428 |
| this study |
| RB457 |
| this study |
| RB460 |
| this study |
| RB461 |
| this study |
| RB465 |
| this study |
| RB468 |
| this study |
| RB469 |
| this study |
| RB472 |
| this study |
| RB474 |
| this study |
| RB475 |
| this study |
| RB477 |
| this study |
| RB484 |
| this study |
| RB486 |
| this study |
| RB488 |
| this study |
| RB492 |
| this study |
| RB531 |
| this study |
| RB538 |
| this study |
| RB540 |
| this study |
| RB547 |
| this study |
| RB567 |
| this study |
| RB595 |
| this study |
| RB598 |
|
|
| RB599 |
|
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| RB600 |
|
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