Taproot structure

Out of 253 uprooted plants, taproot excavation was complete for 229 and incomplete for 21 plants, the remaining three (all D. cinerea) had no taproots. Among plants with incomplete excavations, one was a shrub and the other 20 were tree species. The taproot distal diameter for plants with complete excavations was 3.3 ± 0.4 mm (range, 0.5–34.0 mm) compared to 8.7 ± 1.0 mm (range, 6.0–19.0 mm) for incomplete excavations and the difference was significant (F _1,126 = 24.32, P < 0.0001). Five percent of the taproots with complete excavations ended abruptly at a distal diameter of >6.0 mm but the majority (74%) ended at <4.0 mm. The mean vertical taproot length among plants with complete excavations was 57.9 ± 7.2 cm for shrubs and 107.4 ± 4.7 cm for tree species. Shrubs growing on shallow soil at plot C had shorter taproots at 40.9 ± 8.3 cm than that of 86.9 ± 10.8 cm on deep soil at plots A and B. Similarly, tree species growing on shallow soil had a vertical taproot length of 84.0 ± 8.9 cm that was shorter than that of 115.9 ± 5.4 cm. In 2.4% of the plants with complete excavations, the taproot had a distal horizontal portion with an average length of 49.8 ± 15.9 cm; the mean vertical taproot length in these plants was 107.8 ± 42.4 cm compared to that of 157.6 ± 35.8 cm for total taproot length.

For plants with complete excavations, the overall taproot specific root length (SRL) averaged 0.07 ± 0.008 m g⁻¹ with shrub species having a significantly higher value of 0.13 ± 0.024 m g⁻¹ than that of 0.05 ± 0.008 m g⁻¹ for tree species (F _1,213 = 18.40, P < 0.0001). Among tree species, there was no significant difference in taproot SRL between deep and shallow soil types (F _1,162 = 1.70, P = 0.19). In contrast, shrubs had a significantly higher taproot SRL in shallow soil (0.18 ± 0.03 m g⁻¹) than in deep soil (0.04 ± 0.008 m g⁻¹): F _1,49 = 9.14, P = 0.004.

Lateral root structure

There was a clear difference in the distribution of lateral roots along the vertical taproot length between shrub and tree species (Figure 3). Shrubs had more lateral roots in the top 60 cm than trees but in deep soil lateral roots in trees occurred at deeper layers than in shrubs. Trees also had more lateral roots at a given vertical taproot length in deep soil than in shallow soil (Figure 3). Sample size of shrubs in shallow soil was too small to be shown in Figure 3. Among the most abundant shrub species, L. camara had more lateral roots (13.8 ± 1.4) in the top 20 cm of soil than D. cinerea (10.7 ± 2.0) but the latter had a steady decrease in the density of lateral roots up to a depth of 100 cm. This was in contrast with L. camara that had a sharp decrease in lateral roots from 13.8 ± 1.4 in the top 20 cm to 1.0 ± 1.0 at a depth of 60 cm. Among the most abundant tree species, there was a gradual decrease in the density of lateral roots from the top (5.7 ± 0.4) to 0.2 ± 0.1 at a depth of 200 cm.

Figure 3. Average lateral roots per 20-cm segment along the vertical taproot length in shrub (empty circles) and tree (filled circles) species in deep soil type and in tree species in shallow soil type (filled triangles). Vertical lines show standard error of mean given in one direction only for clarity.

Lateral roots averaged 10.6 ± 0.76 per taproot in deep soil and 7.6 ± 0.77 in shallow soil among tree species. Among shrubs the average number of lateral roots was also different between deep (14.0 ± 2.0) and shallow (8.9 ± 0.9) soil. Coarse lateral roots made up 67% of the lateral roots in deep soil and 28% in shallow soil. There was no significant difference in coarse lateral roots per vertical taproot length between deep and shallow soil (5.6 ± 0.65) among tree species (F _1,113 = 0.10, P = 0.76). However, among shrub species, the number of coarse lateral roots per vertical taproot length of 18.7 ± 3.25 in deep soil was significantly higher than that of 5.9 ± 2.4 in shallow soil (F _1,47 = 10.06, P = 0.003).

Estimating root structure from incomplete sampling

For incomplete taproot excavations, the following model was used to estimate vertical taproot length (VTL_est) using the excavated portion of the taproot (VTL_excv, cm).

$${\rm{VT}}{{\rm{L}}_{{\rm{est}}}} = {\rm{VT}}{{\rm{L}}_{{\rm{excv}}}} + \left( {\left( {{\rm{TRDD}}/{\rm{RTD}}} \right)*{\rm{VT}}{{\rm{L}}_{{\rm{excv}}}}} \right)$$

where VTL_est is estimated vertical taproot length (excluding the horizontal portion) in cm, TRDD is distal diameter of the taproot in mm at the end of the incomplete excavation and TRD is taproot top diameter in mm. A simple way of evaluating the performance of a model is by measuring the deviation of the predicted VTL_est from measured observed VTL_excv for each sample taproot. This error (sometimes referred to as bias) is defined as (Chave et al. Reference Chave, Andalo, Brown, Cairns, Chambers, Eamus, Fölster, Fromard, Higuchi, Kira, Lescure, Nelson, Ogawa, Puig, Riéra and Yamakura2005):

$${\rm{Bias}}\left( \% \right) = \left( {\left( {{\rm{VT}}{{\rm{L}}_{{\rm{est}}}} - {\rm{VT}}{{\rm{L}}_{{\rm{excv}}}}} \right)/{\rm{VT}}{{\rm{L}}_{{\rm{excv}}}}} \right)*100$$

In order to evaluate the performance of the model, it was applied to data for complete excavations in which the taproot distal diameter was the proximal diameter of the last taproot segment (see above) and the estimate was compared to the observed vertical taproot length. The model tended to overestimate total taproot length by an average of 11 ± 0.9% and this bias decreased with increasing excavated depth from 30% at 10 cm depth to 20% at 25 cm, 12% at 80 cm and 8% at 200 cm depth.

For tree species with incomplete excavations, the model estimated a vertical taproot length of 196.7 ± 20.9 cm which was nearly 52.0 cm below the depth of the incomplete excavation of 144.7 ± 17.6 cm. Given that the model estimates have an average bias of 11%, the vertical taproot length of plants with incomplete excavations was in the range of 175 cm to 220 cm depth.

Two models were evaluated for their accuracy in estimating lateral root biomass: (i) a logarithmic linear model (ln(y) = ln(a) + bln(x)) and (ii) a Freundlich power model (y = ax ^b) where y is lateral RDM in g and x is proximal diameter (PD) of the largest lateral in mm, as follows:

$${\rm{Ln}}\left( {\rm{y}} \right) = {\rm{ln}}\left( { - 2.4257} \right) + 2.1053*{\rm{ln}}\left( {{\rm{PD}}} \right)\,\,{\rm{and}}$$

$${\rm{y}} = 0.041*{\rm{P}}{{\rm{D}}^{2.3753}}$$

The two models were tested for accuracy using the observed data (as explained above) before selecting the best model. Derived logarithmic data were back-transformed without application of a correction factor, because Chidumayo (Reference Chidumayo2013b) found little difference in the estimates after applying a first-order correction factor (Chave et al. Reference Chave, Andalo, Brown, Cairns, Chambers, Eamus, Fölster, Fromard, Higuchi, Kira, Lescure, Nelson, Ogawa, Puig, Riéra and Yamakura2005). Across 239 sample laterals with biomass data, the mean bias of the logarithmic linear model was 28.9 ± 7.9% while the power model had a mean bias of 23.3 ± 7.5% and the latter model with a lower bias was selected for estimating biomass of coarse laterals of each excavated plant.

Belowground biomass relationships and plant height

The relationship between RDM and shoot dry mass (SDM) for plants with complete excavations was linear: RDM = 106.2 + 0.28SDM, R ² = 0.80, P < 0.0001, indicating the influence of plant size on RDM. This relationship held for both shrub and tree species. The average R/S ratio for all plants was 1.52 ± 0.22 but this was higher among tree (1.81 ± 0.25) than among shrub (0.52 ± 0.46) species: F _1,234 = 5.98, P = 0.02. Similarly, there was a significant difference in the root mass fraction (RMF) between shrub (0.31 ± 0.03) and tree (0.50 ± 0.02) species: F _1,235 = 34.96, P < 0.0001. The relationship between root/shoot (R/S) ratio and RMF was curvilinear and was best described by an Asymptotic Regression: RMF = 0.76 – 0.74*0.342^R/S, AICc = −1884, RMSE = 0.0003; the R/S ratio reached an asymptote at 8.0 when RMF was 0.84. There was no significant difference in R/S ratio between tree species growing in deep and shallow soil: F _1,181 = 3.31, P = 0.07 but the difference was significant among shrub species with those on deep soil having an R/S ratio of 0.74 ± 0.10 compared to that of 0.40 ± 0.08 on shallow soil: F _1,51 = 7.07, P = 0.01. Among shrub species the RMF of 0.37 ± 0.03 in deep soil was significantly higher than that of 0.27 ± 0.02 in shallow soil: F _1,51 = 8.49, P = 0.005. Among tree species, RMF was also higher in deep (0.53 ± 0.02) than in shallow (0.40 ± 0.03) soil: F _1,182 = 12.79, P = 0.0004.

The relationship between belowground and aboveground biomass (R/S ratio) was weakly related to plant height, root top diameter, vertical taproot length, proximal diameter of largest lateral root and plant age, either together or singularly. These predictor variables together only explained 33% of the variation in R/S ratio although the explanatory power was higher in shrubs (58%) than in trees (32%). In contrast, plant height, vertical taproot length and proximal diameter of largest lateral root explained 54% of the variance in RMF when all plants were considered. However, among shrubs this explanatory power was 68% compared to 54% among trees.

There was no significant relationship between vertical taproot length and tap RDM, similarly there was no significant relationship between vertical taproot length and lateral RDM. However, taproot dry mass explained 56% (F = 300, P < 0.0001) of the variance in lateral RDM and this relationship was more pronounced among shrub species (R ² = 86%, F = 319, P < 0.0001) than among tree species (R ² = 48%, F = 167, P < 0.0001).

The relationship between taproot dry mass fraction and estimated lateral RDM was curvilinear and was best described by the Farazdaghi–Harris function (Figure 4). This curvilinear relationship suggests that woody plants at the study site initially invested more biomass in taproots until the taproot dry mass fraction approached 0.5, after which more biomass was allocated to coarse lateral roots, such that the latter made up more than 60% of the total RDM in large shrubs and trees.

Figure 4. Curvilinear relationship between taproot dry mass fraction of root mass and estimated lateral root dry mass at the study site.

There was a significant, albeit weak, correlation between age and plant height for all sown plants (Figure 5a). The studied species are slow-growing and had a median plant height lying at or below 200 cm, with the exception of B. petersiana and S. polyacantha at the age of 13 years (Figure 5b). Some cohorts grew faster than others. For example, in P. thonningii, the 2008 cohort at 11 years old was growing faster than that of the 2004 cohort at 16 years old (H = 46, P < 0.0001) and the average plant height for the cohorts was 143 ± 35.5 cm and 45 ± 3.1 cm, respectively. The mean plant height of excavated plants was 168.4 ± 10.8 cm (range, 5.0–990.0 cm) and there was no significant difference between shrub (145.9 ± 15.3 cm) and tree (175.4 ± 13.3 cm) species: F _1,227 = 1.36, P = 0.25. Among the sown plants, plant height was 194.1 ± 15.7 cm (range, 15.0–990.0 cm) for trees aged 2–26 years. The sample of excavated sown shrubs was small (n = 3) but among natural recruits, average plant height was 137.7 ± 14.7 cm (range, 5.0–410.0 cm) for shrubs and 141.5 ± 23.0 cm (range, 6.5–960.0 cm) for trees.

Figure 5. (a) Linear relationship between age and height for all sown plants with height measurements and (b) box-whisker plots of plant height for five selected cohorts aged 2, 5, 11, 13 and 16 y of eight species on Plot A. The box hinges in (b) represent the first and third quantiles, the centre horizontal line in the box is the median, and the vertical lines indicate the range of values that are within 1.5 of the hinges. Different letters above the boxes in (b) indicate significant differences for the age group. Species are abbreviated as follows: Bauhinia pertesiana (Bp), Combretum zehyeri (Cz), Dichrostachys cinerea (Dic), Diplorhynchus condlycarpon (Dip), Piliostigma thonningii (Pt), Senegalia polyacantha (Sp), Strychnos spinosa (Ss) and Vachellia sieberiana (Vs).

Among shrub species, 82% of the variation in plant height was explained by root top diameter but among tree species it was the additive effects of vertical taproot length, root top diameter and proximal diameter of the largest lateral root that explained 75% of the variation in plant height (Table 3). However, the explanatory power of root top diameter varied among shrub species from 75% in L. camara to 92% in F. virosa and 95% in P. engleri (Table 3). In D. cinerea, it was the additive effects of proximal diameter and total RDM that explained 85% of the variance in plant height. There was more diversity in the predictor variables of plant height among tree species, root top diameter explained a significant proportion of the variance in plant height in three species: E. abyssinica (92%) and S. araliacea (96%) and V. sieberiana (96%), vertical taproot length explained 77% of the variation in plant height in D. condlycarpon while the explanatory power of proximal diameter of coarse lateral roots ranged from 65% in T. indica, 71% in P. thonningii and 94% in C. molle. The combination of vertical taproot length and root top diameter explained 84% in B. petersiana and 99% in L. stuhlmannii of the variance in plant height. The additive effects of root top diameter and proximal diameter of largest lateral root were significant only in S. goetzei in which they explained 99% of the variance in plant height. In S. polyacantha, the additive effects of taproot dry mass and total RDM explained 82% of the variance in plant height.

Table 3. Best fit linear regression models for predicting plant height (y, cm) from (i) vertical taproot length (x₁, cm), (ii) root top diameter (x₂, mm), (iii) proximal diameter of the largest lateral root (x₃, mm), (iv) taproot dry mass (x₄, g) and (v) total root dry mass (x₅, g) at the study site