4.2. Soil C balance and the respons

4.2. Soil C balance and the response to changes in nutrient stoichiometry
Our data suggest that the introduction of grasses (light disturbance)
increased both soil C storage and respiration,which led to a high density
of plants, increased grazing activity and soil compaction. Soil C storage
and respiration decreased for the other land uses except the rice cropland
(Fig. 6). Soil C storage and respiration were correlated, in agreement
with previous studies (Carbone et al., 2011; De Deyn et al.,
2011; Dias et al., 2010), indicating that soil respiration could be correlated
with plant productivity (Caprez et al., 2012). Both soil C storage and
respirationwere higher grassland plots, likely due to the introduction of
grasses, which led to a high density of plants, increased grazing activity
and soil compaction. Thus, in grasslands the higher plant productivity,
with higher belowground and aboveground C storage would increase
by higher root (autotrophic) respiration. Soil C storage and respiration
were lower at the other disturbed sites except under rice croplands.
Human disturbance can increase soil CO2 emissions (Shang et al.,
2013), but soil respiration in the present studywas not higher at all disturbed
sites, only in grassland and rice cropland communities (Fig. 6).
When comparing the different soil uses, the relationship between soil
C storage and soil C released by respiration is not clear, showing that distinct
land-uses exerted different impacts on soil C-cycle. Taking out
grassland communities, C respiration and C storage in soilwere inversely
correlated when comparing different sites, with rice cropland having
the highest C respiration and lowest soil C storage andwith flat breeding
and pond aquaculture having the contrary patterns. Thus, our findings
are not completely consistent with previous studies conducted in
other ecosystems such as subtropical forests, where soil respiration decreased
when plant productivity decreased (Sheng et al., 2010).
Total soil C:N, C:P and N:P ratios were positively correlated with soil
C storage and respiration(P b 0.05, Table 8), consistentwith similar previous
studies (Hessen et al., 2004; Kirkby et al., 2013). These results
showed that N was the limiting nutrient in these ecosystems; when
the soil concentration of N was lower with respect to C and P soil respiration
decreases thus indicating a limitation of soil biological activity
under low N concentration. Notably, under the different land uses, the
changes on N:P ratios were mainly due to changes in soil N concentrations
since total soil P remained more or less constant.