3.2. Relationships among the concen

3.2. Relationships among the concentrations of total soil C, N, P, K and
available N and P
The concentrations of C and N and of N and P were positively correlated
(P b 0.01) (Fig. 3A, D). C and P concentrationswere also positively
correlated (P b 0.05) (Fig. 3B). The concentrations of C and K and of N
and K were negatively correlated (P b 0.05) (Fig. 3C, E). The concentrations
of P and K and of available N and available Pwere not significantly
correlated (P N 0.05) (Fig. 3F, G).
SMA tests of common slopes revealed differences among nutrient
correlations. The slopes of the correlations among nutrients
were significantly different (P b 0.001), except for total soil N versus
P concentrations relative to available-N versus available-P concentrations
(P N 0.05).
3.3. Effect of human disturbance on the ratios among total soil C, N, P and K
concentrations and on soil available-N and available-P stoichiometry
Total soil C:N ratios were not significantly different in the various
types of land-use across the soil profile (Fig. 4A). Total soil C:P ratios increased
significantly in the grassland only at a soil depth of 0–10 cm,
and the C:P ratios were lower for flat breeding and pond aquaculture
(Fig. 4B). Total soil C:K ratios were significantly lower for grassland
relative to the control plots in soil layers below 10 cm (P b 0.05), and
the C:K ratios for flat breeding and pond aquaculture were lower than
those of the control plots at all soil depths (P b 0.05) (Fig. 4C). Total
soil N:P ratios were significantly higher for grassland in the 0–10 cm
layer and were lower for flat breeding and pond aquaculture (Fig. 4D).
Total soil N:K ratios were significantly lower for grassland in the
10–50 cm soil layers and were significantly lower for flat breeding and
pond aquaculture in the 0–50 cm soil layers (Fig. 4E). Total soil P:K
ratios were significantly lower in all soil layers in the plots of all types
of land uses respect to natural P. australis wetland (Fig. 4F). The available
soil N:P ratios were higher for flat breeding in the 30–50 cm soil layers.
Available N:P ratios were lower for grassland and pond aquaculture,
especially above 30 cm (Fig. 4G).
In summary, when comparing different soil layers under different
land-uses, soil C:N ratios were similar under different land-uses; they
had low coefficients of variation (Table 3), whereas soil C:K, C:P, N:P,
N:K and P:K ratios were strongly dependent of land-use and had higher
coefficients of variation than C:N (Table 3, Fig. 3). Our data suggest that
the soil influencing factors were changed by changes in land-use
(Table 1) and that they were also related to the variation in nutrient
stoichiometry (Table 4). Bulk density and pHwere correlated negatively
with total soil C:N, C:P, C:K, N:P and N:K ratios and with available N:P
ratios.
The overall chemical compositions of the soilswere significantly different
among all types of studied human land uses. The squared
Mahalanobis distances between the soils of the various disturbed sites
were significantly different in all pairwise comparisons (Table 5). The
total soil P and K concentrations, total soil C:P and P:K concentration ratios,
soil available-P concentration and available N:P concentration ratio
were the significant variables in themodel (Table 6). As indicated in the
biplot space originated by the first two roots of the FDA (explaining
86.6% of the total variance), total soil P and K concentrations were
higher and N:P, C:P and P:K ratios were lower in the soils of the croplands
(Fig. 5A, B).