Giant reed (Arundo donax L.) is a plant species with a high growth rate and low requirements, which makes it particularly interesting for the production of different bioproducts, including natural fibers. This work assesses the use of fibers obtained from reed culms as reinforcement for a high-density polyethylene (HDPE) matrix. Two different lignocellulosic materials were used: i) shredded culms and ii) fibers obtained by culms processing, which have not been reported yet in literature as fillers for thermoplastic materials. A good stress transfer for the fibrous composites was observed, with significant increases in mechanical properties; composites with 20% fiber provided a tensile elastic modulus of almost 1900 MPa (78% increase versus neat HDPE) and a flexural one of 1500 MPa (100% increase), with an improvement of 15% in impact strength. On the other hand, composites with 20% shredded biomass increased by 50% the tensile elastic modulus (reaching 1560 MPa) and the flexural one (up to 1500 MPa), without significant changes in impact strength. The type of filler is more than its ratio; composites containing fibers resulted in a higher performance than the ones with shredded materials due to the higher aspect ratio of fibers.

Giant reed (Arundo donax L.) has great potential for phytoremediation of N balance-disrupted soils due to its large plant biomass production and strong N use efficiency. Soil properties and the artificial modification in agricultural production cause a heterogeneous distribution of N. However, little is known about the differential responses of A. donax at varying N abundances. Herein, giant reed seedlings were grown in solutions with low, moderate and high N supply under hydroponic culture system. We found that both nonoptimal N inhibited the growth and biomass accumulation of A. donax, which was severely repressed by high N. While phytophysiological assays showed that N stress decreased photosynthetic rate and Fv/Fm by increasing reactive oxygen species (ROS) accumulation and lipid peroxidation, the activity of antioxidant enzymes and redox poise in leaves and roots was promoted to minimize excessive ROS accumulation and oxidative stress. High-throughput transcriptomic profiling revealed a total of 19,848 and 16,736 differentially expressed genes (DEGs) under low N and high N conditions, respectively. Based on the results of DEG function annotation and enrichment analyses, varying N abundances up-regulated the expression of a number of genes involved in ROS production and antioxidant defense systems and down-regulated most genes related to photosynthesis, which may contribute to plant response. The expression of 76 and 64 transcription factors (TFs) in leaves, 88 and 110 TFs in roots were up-regulated under low N and high N conditions, respectively, which may contribute to alleviating damage caused by varying N treatment. Our findings would enrich our understanding of the growth and development changes of A. donax plants under low N or high N conditions, and might also provide suitable gene resources and important implications for the genetic improvement of plant N resistance and accumulation through molecular engineering of these genes under varying N abundances in soils.