The numbers of CFUs were highest fo

The numbers of CFUs were highest for the three accelerated treatments (compost, sludge and manure), which had 2e3 times higher level of N compared to all the other treatments. But also the level of C input seemed to be important for the number of CFUs, as there was a trend of increase in CFU with increase in accumulated C input (Fig. 3). CFU in the human urine treated soil was significantly lower than in accelerated sludge and accelerated compost, but also lower than the unfertilized control, indicating that human urine somehow is limiting the microbial population in soil. Maybe this is due to high soil electrical conductivity after amendment with urine (Mnkeni et al., 2008). Generally, the number of CFU seemed low (5*105e1*106) compared to what is
The results on potential functional diversity indicated that the different organic fertilizer treatments had not affected the potential functional diversity of the soils and thus did not indicate lower functional capacity of the treatments with higher heavy metal loading, as the heterogeneity between plots having received the same treatment was of similar magnitude as between treatments. This is in accordance with investigations of effects of 160 years of fertilizer amendment, where multidimensional scaling revealed large within-group variation in community structure, as determined by 16S rRNA gene DGGE profiles. This masked any possible effects due to amendment with nitrogen fertilizer, farmyard manure or no fertilizer (Ogilvie et al., 2008). 16S rRNA DGGE profiles were also used in a field experiment with approximately 30 years of manure and sludge amendment, and here a separation of the different treatments were obtained (Marschner et al., 2003). In a laboratory experiment maize litter amendment increased functional diversity in three different soils determined using Biolog GN plates. The diversity decreased with time but was still higher than the control after 52 weeks (Sharma et al., 1998). It has been proposed that soil type is the primary determinant of the bacterial community structure in arable soils (Girvan et al., 2003; Ulrich and Becker, 2006) and that the particle size fractions are more important than the type of fertilizer applied (Sessitsch et al., 2001). Thus, it seems that unless specific bacteria are inhibited by toxic compounds, the soil microbial community in a particular soil is very robust and consequently retains its functional capacity. Considering the actual input to the soils, the limit for Zn should be reached after 19 years of accelerated sludge amendment and 9 years of accelerated compost amendment. The numbers would be 13 and 5 years, respectively, for Cu. The time to reach the limits would be approximately 3 times longer for the normal application rates of sludge and compost. The sampling time might have an effect on the microbial population, concerning which organisms are active, and presumably the picture could be different just after fertilizer amendment and in summer where the activity is highest due to degradation of organic matter, higher temperature and the presence of crop roots.
Within the given applied methodology, no ill effect is seen on the microbial functionality, despite heavily accelerated rates of fertilizer have been given in some of the treatments. In another study using these soils we found only few changes in the soil microbial community using 16S rRNA tag-encoded pyrosequencing (Poulsen et al., 2012). Investigation of antibiotic resistance in the soils could also be used to monitor changes in the microbial community, since several of the fertilizers can contain e.g. medicinal residues or antibiotic resistant microorganisms, which could disseminate these resistances to inherent soil microorganisms by horizontal gene transfer (manuscript in preparation).