A healthy agricultural soil can maintain productivity, whilst delivering essential ecosystem services. An unhealthy soil can result in erosion, compaction and reductions in above and below ground diversity, nutrient cycling efficiency, drought tolerance and yield1. Grasslands for livestock production cover 26 % of total global ice free land 2, improvement of grassland soil health is essential for global food security. We aimed to combine a range of ‘low-tech’ and ‘hi-tech’ methods to understand the effect of different forage varieties and management techniques on soil health in both temperate (UK) and tropical (Colombia) grasslands and to develop a scientifically ratified soil health assessment protocol for use by farmers globally.
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Developing global soil health metrics: Is SOM the key to grassland soil health?
1. Developing global soil health metrics: Is SOM the
key to grassland soil health?
C. A. Horrocksa, J. Arangob, J. Núñezb, A. Arevalob, J.A. Cardosob, J.A.J. Dungaita
Corresponding author: Claire.Horocks@Rothamsted.ac.uk
aRothamsted Research, North Wyke, Okehampton, Devon
b CIAT, Km 17 Recta Cali-Palmira CP 763537 Apartado Aéreo 6713, Cali, ColombiaC
INTRODUCTION
A healthy agricultural soil can maintain productivity, whilst delivering essential ecosystem services. An
unhealthy soil can result in erosion, compaction and reductions in above and below ground diversity,
nutrient cycling efficiency, drought tolerance and yield1. Grasslands for livestock production cover 26 %
of total global ice free land 2, improvement of grassland soil health is essential for global food security.
We aimed to combine a range of ‘low-tech’ and ‘hi-tech’ methods to understand the effect of different
forage varieties and management techniques on soil health in both temperate (UK) and tropical
(Colombia) grasslands and to develop a scientifically ratified soil health assessment protocol for use by
farmers globally.
RESULTS
METHODS
Soil was sampled from tropical forage field plots, 3 replicate plots of Brachiaria hybrid Mulato (Mu.), B.humidicola cv. CIAT 679 (Bh 679),
B.humidicola cv CIAT 16888 (Bh 16888), and Panicum maximum (P. m), plus a bare soil control were sampled. Due to the tufted growth habit of
Mu. and P. m, samples were collected from both within and between tussocks. Multiple proposed soil health metrics were assessed using ‘hi-
tech’ and ‘low-tech’ methods.
CONCLUSIONS
a a
a
a
ab ab
b
0
1
2
3
4
5
6
7
Bh 679 Bh16888 PM within
tussock
PM
between
tussocks
Mu.
within
tussock
Mu.
between
tussocks
Bare soil
soilorganicmatter(%drymass)
0
20
40
60
80
100
120
Bare soil Bh 16888 Bh 679 Mu. P. m
Lossinteamassafter1month(%drymass)
Lipton Green Tea Lipton Redbush Tea
Further Work
• There was some
evidence of an
effect of tropical
forage variety on
SOM
concentration
qPCR of microbial markers - ‘Hi-
tech’ metric
• SOM showed a
positive correlation
with the ratio of
fungal (18s) :
bacterial (16S)
marker genes
• SOM showed a
negative correlation
with the functional
gene AMOa, which
plays a key role in
nitrification
• Increased SOM
concentration increased
aggregate stability in
water, reducing the
proportion lost through a
fine mesh
• Despite differences in
microbial gene
abundances the rate of
decomposition of tea bags
buried did not differ
between forages
SOM by loss on
ignition
Tea-bag test and
‘slake test’ – low tech
FIELD SITE
The data presented here are from a plot
experiment at CIAT, Cali Colombia.
The methods used have also been applied
in livestock systems in the UK and Kenya.
‘Hi-Tech’ methods include:
• QPCR to measure abundance of marker genes and functional gene
• Next generation sequencing to measure fungal and bacterial diversity
• Loss on ignition to measure total soil organic matter (SOM)
• Gas chromatography to determine organic matter composition
‘Low-tech’ methods include:
• An adapted slake test using a handmade sieve to measure aggregate
stability in water
• A soil crusher to measure aggregate friability
• ‘Tea bag index’3- burial of tea bags to measure decomposition rates
Collaboration with the NGO ‘Send a
Cow’ to test farmer friendly soil
health metrics in Kenya through peer
farmer education.
Figure 2. Correlation between soil organic matter
concentration and gene copy number ratio of the 18S
fungal marker and 16S bacterial marker gene.
Figure 3. Correlation between soil organic matter
concentration and total ammonia monooxygenase
(AMOa) genes in bacteria and archaea.
Figure 1. Mean (n=3) soil organic matter determined by loss on
ignition from soils under 4 different tropical forages and bare soil.
Error bars show ± 1 standard deviation.
Figure 4 Correlation between soil organic matter
concentration and % soil lost through a 50µm mesh on
weight sieving.
Figure 5. Mean (n=3) % mass loss of Green and Redbush tea
buried for 1 month in soil under four tropical forages and a
bare soil control. Error bars show ± 1 standard deviation.
Handmade sieves for adapted ‘slake test’
Soil Crusher for measuring aggregate
friability
• Work in Colombia and the UK has shown differences in total SOM under different
forage varieties
• SOM shows a positive correlation with increased aggregate stability in water, and
friability, indicators of improved soil health
• Differences in total SOM also correlate with the abundance of key microbial marker
genes but less so with potential decomposition (teabag test)
• Ongoing work will identify differences in other soil health indicators in grassland
systems and determine to what extent this can be predicted through measurement
of SOM
1 Kibblewhite, M.G., Ritz, K. and Swift, M.J., 2008. Soil health in agricultural systems. Philosophical Transactions of the Royal Society B: Biological
Sciences, 363(1492), pp.685-701.
2FAO, 2012. Livestock and landscapes. Available online http://www.fao.org/docrep/018/ar591e/ar591e.pdf accessed 12/07/2017.
3 The Teabag index. Available online http://www.teatime4science.org/colophon accessed 31/08/17.
We gratefully acknowledge the support of the staff at Send a Cow and colleagues at CIAT Nairobi and CIAT Cali for all their ongoing support. This work was
fund through a BBSRC Newton Fund Post Doctoral Fellowship.