Bryophytes are potent metal absorbers, thriving well on heavy metal (HM)-polluted soils. Mechanisms controlling uptake, compartmentalization and impacts of HMs on bryophytes life cycle are largely unknown. The current study is an effort to decipher mechanisms of nickel (Ni) excess-induced effects on the phenological events of two bryophytes, Asterella wallichiana and Plagiochasma apendiculatum growing in natural habitats. Observations revealed Ni-excess induced negative impacts on abundance, frequency of occurrence of reproductive organs, population viability and morphological traits, spore viability and physiological attributes of both the liverworts. Results led us conclude that P. appendiculatum survived better with the lowest impact on its life cycle events than A. wallichiana under Ni excess in natural habitats. Our findings collectively provide insights into the previously unknown mechanisms of Ni-induced responses in liverworts with respect to phenological attributes, as well as demonstrate the potential of P. appendiculatum to survive better in Ni excess habitats.
pan clpan> class="Chemical">ass="Species">Bryophytes are potent pan> class="Chemical">ass="Chemical">pan class="Chemical">metal absorbers, thriving well on heavy metal (HM)-polluted soils. Mechanisms controlling uptake, compartmentalization and impacts of HMs on bryophytes life cycle are largely unknown. The current study is an effort to decipher mechanisms of nickel (Ni) excess-induced effects on the phenological events of two bryophytes, Asterella wallichiana and Plagiochasma apendiculatum growing in natural habitats. Observations revealed Ni-excess induced negative impacts on abundance, frequency of occurrence of reproductive organs, population viability and morphological traits, spore viability and physiological attributes of both the liverworts. Results led us conclude that P. appendiculatum survived better with the lowest impact on its life cycle events than A. wallichiana under Ni excess in natural habitats. Our findings collectively provide insights into the previously unknown mechanisms of Ni-induced responses in liverworts with respect to phenological attributes, as well as demonstrate the potential of P. appendiculatum to survive better in Ni excess habitats.
Authors: O E Sala; F S Chapin; J J Armesto; E Berlow; J Bloomfield; R Dirzo; E Huber-Sanwald; L F Huenneke; R B Jackson; A Kinzig; R Leemans; D M Lodge; H A Mooney; M Oesterheld; N L Poff; M T Sykes; B H Walker; M Walker; D H Wall Journal: Science Date: 2000-03-10 Impact factor: 47.728
Authors: Yann Hautier; Forest Isbell; Elizabeth T Borer; Eric W Seabloom; W Stanley Harpole; Eric M Lind; Andrew S MacDougall; Carly J Stevens; Peter B Adler; Juan Alberti; Jonathan D Bakker; Lars A Brudvig; Yvonne M Buckley; Marc Cadotte; Maria C Caldeira; Enrique J Chaneton; Chengjin Chu; Pedro Daleo; Christopher R Dickman; John M Dwyer; Anu Eskelinen; Philip A Fay; Jennifer Firn; Nicole Hagenah; Helmut Hillebrand; Oscar Iribarne; Kevin P Kirkman; Johannes M H Knops; Kimberly J La Pierre; Rebecca L McCulley; John W Morgan; Meelis Pärtel; Jesus Pascual; Jodi N Price; Suzanne M Prober; Anita C Risch; Mahesh Sankaran; Martin Schuetz; Rachel J Standish; Risto Virtanen; Glenda M Wardle; Laura Yahdjian; Andy Hector Journal: Nat Ecol Evol Date: 2017-12-04 Impact factor: 15.460
Authors: Caio C Fabiano; Tiago Tezotto; José L Favarin; Joseph C Polacco; Paulo Mazzafera Journal: Front Plant Sci Date: 2015-09-23 Impact factor: 5.753