@article{fdi:010066135,
  title = {{N}od factor-independent nodulation in {A}eschynomene evenia required the common plant-microbe symbiotic toolkit},
  author = {{F}abre, {S}. and {G}ully, {D}jamel and {P}oitout, {A}. and {P}atrel, {D}elphine and {A}rrighi, {J}ean-{F}ran{\c{c}}ois and {G}iraud, {E}ric and {C}zernic, {P}. and {C}artieaux, {F}abienne},
  editor = {},
  language = {{ENG}},
  abstract = {{N}itrogen fixation in the legume-rhizobium symbiosis is a crucial area of research for more sustainable agriculture. {O}ur knowledge of the plant cascade in response to the perception of bacterial {N}od factors has increased in recent years. {H}owever, the discovery that {N}od factors are not involved in the {A}eschynomene-{B}radyrhizobium spp. interaction suggests that alternative molecular dialogues may exist in the legume family. {W}e evaluated the conservation of the signaling pathway common to other endosymbioses using three candidate genes: {C}a2+/{C}almodulin-{D}ependent {K}inase ({CC}a{MK}), which plays a central role in cross signaling between nodule organogenesis and infection processes; and {S}ymbiosis {R}eceptor {K}inase ({SYMRK}) and {H}istidine {K}inase1 ({HK}1), which act upstream and downstream of {CC}a{MK}, respectively. {W}e showed that {CC}a{MK}, {SYMRK}, and {HK}1 are required for efficient nodulation in {A}eschynomene evenia. {O}ur results demonstrate that {CC}a{MK} and {SYMRK} are recruited in {N}od factor-independent symbiosis and, hence, may be conserved in all vascular plant endosymbioses described so far.},
  keywords = {},
  booktitle = {},
  journal = {{P}lant {P}hysiology},
  volume = {169},
  numero = {4},
  pages = {2654--2664},
  ISSN = {0032-0889},
  year = {2015},
  DOI = {10.1104/pp.15.01134},
  URL = {https://www.documentation.ird.fr/hor/fdi:010066135},
}