For this reason, we cannot totally exclude that also in our conditions a fraction of AgNPs can be formed due to the release of root metabolites then absorbed by plant roots. MeNP synthesis, which occurs in plant tissues very
quickly, is influenced by environmental conditions. Starnes et al. [18] detected the formation of AuNPs in M. sativa and other species Copanlisib as early as 6 h after the start of exposure to KAuCl4. It was also verified that plant growth conditions have an effect on MeNP biosynthesis: variations in temperature, pH and photosynthetically active radiation (PAR) influence the size and shape of growing AuNPs [18]. Theoretically, this STI571 concentration suggests the SGC-CBP30 concentration possibility of managing living plants as nanofactories and promoting the synthesis of nanomaterials of desired size and shape. The most intriguing question about plant MeNP biosynthesis is where and how this phenomenon begins. So far, the steps of this process in living plants have not been completely clarified. Wherever this occurs, it is highly likely that the key factor is the presence of immediately available reducing agents. An investigation by Beattie and Haverkamp [33] demonstrated that in B. juncea
the sites of the most abundant reduction of metal salts to NPs were the chloroplasts, in which high reducing sugars (i.e. glucose and fructose) may 4-Aminobutyrate aminotransferase be responsible for the metal reduction. This might support the hypothesis that plants with the highest concentrations of reducing sugars are the ‘nanofactories’ par excellence. In our experiment, leaf extracts of the studied species were analyzed to detect the concentrations of two
reducing sugars (GLC and FRU) and the antioxidants AA, CA and PP, assuming that possible differences in the concentration of such substances may have some influence on MeNP biosynthesis. If the hypothesis by Beattie and Haverkamp [33] were true, and given our findings regarding the high concentration of GLC and FRU, among the species studied F. rubra should be a very promising species because it also translocated in its leaves very well. To verify this hypothesis would require a demonstration of a quantitative relationship between the concentration of reducing sugars and the amount of AgNPs; however, this was beyond the scope of the present study. Our data demonstrate that in the leaves of B. juncea and M. sativa (species used as model plants by several authors in studies on the biosynthesis MeNPs), there are concentrations of AA and PP that are considerably higher than those in F. rubra. In contrast, F. rubra had a level of reducing sugars much higher than B. juncea and M. sativa. This leads to the concept that there is no substance that is solely responsible for the process.