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@ARTICLE{Hofmann:1010209,
      author       = {Hofmann, Diana and Thiele, Björn and Siebers, Meike and
                      Rahmati, Mehdi and Schütz, Vadim and Jeong, Seungwoo and
                      Cui, Jiaxin and Bigler, Laurent and Held, Federico and Wu,
                      Bei and Babic, Nikolina and Kovacic, Filip and Hamacher,
                      Joachim and Hölzl, Georg and Dörmann, Peter and Schulz,
                      Margot},
      title        = {{I}mplications of {B}elow-{G}round {A}llelopathic
                      {I}nteractions of {C}amelina sativa and {M}icroorganisms for
                      {P}hosphate {A}vailability and {H}abitat {M}aintenance},
      journal      = {Plants},
      volume       = {12},
      number       = {15},
      issn         = {2223-7747},
      address      = {Basel},
      publisher    = {MDPI},
      reportid     = {FZJ-2023-03018},
      pages        = {2815},
      year         = {2023},
      abstract     = {Toxic breakdown products of young Camelina sativa (L.)
                      Crantz, glucosinolates can elim-inate microorganisms in the
                      soil. Since microorganisms are essential for phosphate
                      cycling, onlyinsensitive microorganisms with
                      phosphate-solubilizing activity can improve C. sativa’s
                      phosphatesupply. In this study, 33P-labeled phosphate,
                      inductively coupled plasma mass spectrometry and
                      potexperiments unveiled that not only Trichoderma viride and
                      Pseudomonas laurentiana used as phosphate-solubilizing
                      inoculants, but also intrinsic soil microorganisms,
                      including Penicillium aurantiogriseum,and the assemblies of
                      root-colonizing microorganisms solubilized as well phosphate
                      from apatite,trigger off competitive behavior between the
                      organisms. Driving factors in the competitiveness areplant
                      and microbial secondary metabolites, while glucosinolates of
                      Camelina and their breakdownproducts are regarded as key
                      compounds that inhibit the pathogen P. aurantiogriseum, but
                      also seemto impede root colonization of T. viride. On the
                      other hand, fungal diketopiperazine combined
                      withglucosinolates is fatal to Camelina. The results may
                      contribute to explain the contradictory effects
                      ofphosphate-solubilizing microorganisms when used as
                      biofertilizers. Further studies will elucidateimpacts of
                      released secondary metabolites on coexisting microorganisms
                      and plants under different environmental conditions.},
      cin          = {IBG-3},
      ddc          = {580},
      cid          = {I:(DE-Juel1)IBG-3-20101118},
      pnm          = {2173 - Agro-biogeosystems: controls, feedbacks and impact
                      (POF4-217)},
      pid          = {G:(DE-HGF)POF4-2173},
      typ          = {PUB:(DE-HGF)16},
      pubmed       = {37570969},
      UT           = {WOS:001046259600001},
      doi          = {10.3390/plants12152815},
      url          = {https://juser.fz-juelich.de/record/1010209},
}