| Literature DB >> 29904052 |
Zhongnan Wang1, Xia Yuan1, Deli Wang2, Yang Zhang1, Zhiwei Zhong1, Qinfeng Guo3, Chao Feng1.
Abstract
Large herbivores act as a major driver of plant litter decomposition in grasslands. The modifications of soil biotic and abiotic properties, as well as the changes in quality (C/N ratio) of plant litter, are two key pathways by which large herbivores can affect litter decomposition. Yet we know little about the relative role of these two mechanisms in mediating decomposition. Here, by combining a large-scale and a small-scale field manipulative experiment, we examined how livestock (cattle andEntities:
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Year: 2018 PMID: 29904052 PMCID: PMC6002471 DOI: 10.1038/s41598-018-26835-1
Source DB: PubMed Journal: Sci Rep ISSN: 2045-2322 Impact factor: 4.379
Figure 6Structural equation models (SEM) depicting the control of cattle (A) vs. sheep grazing (B) on litter decomposition by affecting soil properties (n = 8) and litter quality (n = 6). The numbers on the arrows are standardized path coefficients, continuous and dashed arrows indicate positive and negative effects, respectively. The path widths are scaled proportionally to the path coefficient. The R2 value represents the proportion of total variance explained for the dependent variable of interest. Overall, goodness of-fit tests are shown in the bottom of the figure. *P < 0.05, **P < 0.01 and ***P < 0.001.
Figure 1Litter mass remaining (mean ± SE) under the same initial quality but at different grazing sites after 135 days of incubation in 2012 (A), n = 4; and that under different initial qualities influence by different large herbivores at the same site after 120 days of decomposition in 2013 (B), n = 3. Different letters indicate significant differences between the treatments.
Litter mass remaining and general properties of surface soils of 0–10 cm in depth under different grazing treatments in 2012 (nested linear-mixed models analysis with grazing as the fixed factor, and plot as the random factor). n = 4.
| Variables† | degree of freedom | ||
|---|---|---|---|
| MR | 2, 45 | 27.529 | <0.001 |
| SM | 2, 45 | 7.428 | 0.002 |
| BD | 2, 45 | 13.656 | <0.001 |
| pH | 2, 45 | 8.435 | 0.001 |
| EC | 2, 45 | 5.219 | 0.009 |
| TC | 2, 45 | 0.779 | 0.465 |
| TN | 2, 45 | 6.386 | 0.004 |
| C:N | 2, 45 | 4.027 | 0.025 |
| MBC | 2, 45 | 2.068 | 0.138 |
| NM | 2, 45 | 3.642 | 0.034 |
†Key to abbreviations: MR = litter mass remaining; SM = soil moisture; BD = soil bulk density; pH = soil pH value; EC = soil electric conductivity; TC = soil total carbon; TN = soil total nitrogen; C:N = soil total C/N ratio; MBC = soil microbial biomass carbon; and NM = Net N mineralization rate.
Litter mass remaining (n = 3) and main nutrients of L. chinensis standing litter (n = 4) under different grazing treatments in 2013 (nested linear-mixed models analysis with grazing as the fixed factor, and plot as the random factor).
| Variables† | degree of freedom | ||
|---|---|---|---|
| MR | 2, 42 | 4.040 | 0.025 |
| LC | 2, 33 | 2.116 | 0.137 |
| LN | 2, 33 | 105.149 | <0.001 |
| C:N | 2, 33 | 117.541 | <0.001 |
†Key to abbreviations: MR = litter mass remaining; LC = L. chinensis litter’s carbon content; LN = L. chinensis litter’s nitrogen content; and C:N = L. chinensis litter’s C/N ratio.
Figure 2General properties (mean ± SE) of surface soils of 0–10 cm in depth under different grazing treatments in 2012. (A) moisture; (B) bulk density; (C) pH value; (D) electric conductivity; (E) total carbon content; (F) total nitrogen content; (G) total C/N ratio; (H) microbial biomass carbon; and (I) Net N mineralization rate. Different letters above the bars indicate significant differences. n = 4.
Figure 3Relationships between litter mass remaining (on day 135 of incubation) and soil characteristics. (A) moisture; (B) bulk density; (C) pH value; (D) electric conductivity; (E) total carbon content; (F) total nitrogen content; (G) total C/N ratio; (H) microbial biomass carbon; and (I) Net N mineralization rate (mean ± SE). n = 12.
Figure 4Leymus chinensis standing litter nitrogen content (A), carbon content (B), and C/N ratio (C) (mean ± SE) from different grazing treatments. Significant differences are indicated by different letters (NS = not significant). n = 4.
Figure 5Leymus chinensis and forbs density (A), coverage (B), and height (C) were affected by different grazing treatments. Values represent mean ± SE. Different letters above the bars indicate significant differences. n = 4.
Leymus chinensis and forbs density, coverage, and height under different grazing treatments in 2012 (nested linear-mixed models analysis with grazing as the fixed factor, and plot as the random factor). n = 4.
| Variables† | degree of freedom | ||
|---|---|---|---|
| LD | 2, 45 | 30.168 | <0.001 |
| LC | 2, 45 | 28.480 | <0.001 |
| LH | 2, 45 | 3.527 | 0.038 |
| FD | 2, 45 | 10.529 | <0.001 |
| FC | 2, 45 | 6.287 | 0.004 |
| FH | 2, 45 | 3.465 | 0.040 |
†Key to abbreviations: LD = L. chinensis density; LC = L. chinensis coverage; LH = L. chinensis height; FD = forbs density; FC = forbs coverage; and FH = forbs height.