The benefits of animal manure and s

The benefits of animal manure and sewage sludge appli- cation to soil organic matter quantity, nutrient availability, soil aggregation, and other soil functions are well known (Mao et al., 2008; Roca-Perez et al., 2009). As seen, the organic wastes were rich in nutrients, such as N, P and K. This indicated that some manure-bound nutrients were gradually released from the organic component of the manure, which favored the growth of microorgan- isms and subsequently induced shifts in the metabolism of PAHs-degrading microorganisms, hence resulting in an improvement in PAHs biodegradation (Debosz et al., 2002; Xu and Obbard, 2003). As for DOM or dissolved organic carbon (DOC) originating from organic waste, this highlighted the possible role of DOM or DOC not only as nutrient source and PAHs-carrier but also as PAHs degradation enhancer (Kobayashi et al., 2009). Previous studies had shown that the DOM fraction of soil organic matter could positively contribute to PAHs bioavailability by enhancing the mobility of hydrophobic organic contam- inants in aquifers and soils (Maxin et al., 1995; Haftka et al., 2008; Kobayashi et al., 2008).
In our experiment, the response of PAHs biodegradation was greatly different between CM and SS samples: appar- ent dosage effects on stimulation of PAHs dissipation were observed with CM but not SS. There are several possible explanations for this phenomenon. First, the partition of PAHs depended on the origin and properties of DOM. As reported by Raber and Ko ̈gel-Knabner (1997), the DOM from compost and sewage sludge can influence the transport of non-ionic organic contaminants because of the large concentrations of DOC released from these materials. The DOM from compost contained a large percentage of organic molecules > 14000 Da (32%–46%), whereas DOM from waste disposal leachates contained only 7%–
10%, and so bonded less PAHs (Bengtsson and Zerhouni, 2003). Although the cattle manure and sewage sludge used were not characterized for their DOM component, the DOM concentrations were indeed different between them. Secondly, within an optimal concentration range of organic matter (or humic acid), biodegradation of PAHs in the plant-microbe system could be faster and more effec- tive. As an important component of organic matter, there are contradictory conclusions on the interactions between humic acid (HA) and PAHs; some studies showed HA could increase the aqueous solubility of PAHs (Johnson and Amy, 1995; Haderlein et al., 2001), but other studies indicated that HA had no effect or even had a negative effect (Shimp and Pfaender, 1985). Liang et al. (2007) showed that the addition of Elliott soil humic acid solution into spiked soil enhanced pyrene mineralization at the range of 20–200 μg ESHA/g soil, but inhibition and neutral effects occurred beyond this concentration range. It was suggested that inhibition could be caused by the formation of micelles, which interfered with substrate transportation to the cell under high HA concentrations (Maxin et al., 1995). Finally, the absence of PAHs-degrader adaptation to degrade PAHs sorbed to HA could feasibly be considered. Taking into account that sorption of PAHs to HA affects bioavailability, a specific group of competent bacteria needs to be isolated to breach this barrier. However, the majority of PAHs degraders isolated by conventional enrichments with PAHs supplied as crystals in aqueous solutions probably lack characteristics that enable inter- actions with sorbents (Vaccas et al., 2005). In this case, the role of PAHs-degrading bacteria inoculation may be hindered by interaction between HA and PAHs in soil.
4 Conclusions
The present study demonstrated that organic waste amend- ments helped to significantly decrease soil PAHs in a plant-microbe bioremediation system. The possible un- derlying mechanism could partly be due to the fact that