Yields and the nutritive value of early harvested common bean (Phaseolus vulgaris L.) crop residues for ruminants
Mesfin Dejene1,6, Rob M Dixon1, Alan J Duncan2,7, Kerry B Walsh3, David McNeill4 and Endalkachew Wolde-meskel5
1 Queensland Alliance for Agriculture and Food Innovation (QAAFI), The University of Queensland, Gatton, Qld, 4343, Australia mesfindegene@yahoo.co.uk 2 International Livestock Research Institute (ILRI), PO Box 5689, Addis Ababa, Ethiopia 3 Central Queensland University, Rockhampton, 4701, Qld, Australia 4 School of Veterinary Science, The University of Queensland, Gatton, Qld, 4343, Australia 5 World Agroforestry (ICRAF), Addis Ababa, Ethiopia 6 Etiophian Institute of Agricultural Research (EIAR), Holetta Research Centre, PO Box 2003, Addis Ababa, Ethiopia 7 Global Academy of Agriculture and Food Security, The Royal (Dick) School of Veterinary Studies and The Roslin Institute, Easter Bush Campus, Midlothian, EH25 9RG United Kingdom
Abstract
The yields and nutritive value of haulm (stem and leaf) and pod wall
(HPW) crop residues of common bean early-harvested at the green pod fill
stage were measured in nine genotypes grown in two dissimilar environments (Boricha
and Mandura) in Ethiopia. The concentrations of total N, neutral
detergent fibre (NDF) and acid detergent fibre (ADF), and the in vitro
DM digestibility (IVDMD), in the HPW fractions (stem, leaf and pod wall) were
measured. At Mandura the yields of seed and HPW averaged
1.03 and 2.26 t/ha, respectively, and varied (p<0.001) among
genotypes (0.31 - 1.57 t/ha and 1.19 - 2.93 t/ha, respectively). However no
such differences among genotypes (p>0.05) were observed at
Boricha. Stem, leaf and pod wall comprised 52.4, 23.1 and 24.5% of HPW,
respectively. The concentrations of N, NDF and ADF, and IVDMD in the HPW,
and the HPW fractions, generally varied (p<0.05) among genotypes.
The digestible DM (DDM) yields of HPW ranged among genotypes from 0.75 -
1.81 t/ ha at Mandura, and averaged
1.89 t/ha at Boricha. N yield ranged from 35.3 - 70.3 kg N/ha at
Boricha and 18.3 - 43.4 kg N/ha at Mandura. Since yields of
seed were positively correlated with yields of HPW DM, DDM and N, common
bean genotypes can be selected concurrently for seed and HPW yields. Uses of
high-yielding genotype can double the N and DDM yields without reducing seed
yield. The N and IVDMD of HPW residue showed that early-harvested common
bean is a high nutritive value feedstuff for ruminants.
In many developing countries smallholder crop-livestock systems provide the
majority of animal products (Randolph et al 2007; Herrero et al 2013) and
provide the greatest potential for increased production of animal
foods (Wright et al 2012; Herrero et al 2013). In such systems the crop and
livestock components are usually closely integrated with ruminant livestock
dependant primarily on crop residues as feeds for much of the annual cycle
(Williams et al 2000; Moritz 2010). However, the poor nutritive value of most
crop residue feeds is a major constraint to livestock productivity (Kabaija
and Little 1988; Tolera and Sundstřl 2000; Zerbini and Thomas 2003). Thus
locally available high quality feeds are important to improve productivity.
Grain legume food crops are often grown to provide high-protein foods and in
rotation with cereal crops in smallholder farming systems. Importantly, the
harvest residues of grain legume crops are usually higher in nutritive
value, especially in N, than cereal crop residues. In many global regions
common bean (Phaseolus vulgaris L.) is grown as a food legume crop
(Beebe et al 2013), often grown in smallholder crop-livestock systems in
association or rotation with maize, sorghum, bananas, or other crops
(Broughton et al 2003). Most of the crop is harvested at seed maturity, but
some is early-harvested at the green pod fill growth stage (Early or
Eshet harvest) to provide a vegetable when food is scarce and to
provide seasonal food variety. These are known as ‘green beans’ or ‘snap
beans’ when harvested before seed development, or as ‘shell beans’ if
harvested when the seeds are physiologically mature but before desiccation.
The haulm (stem and leaf) and pod wall crop residues (collectively HPW), of
such early harvested common beans are expected to be of high nutritive value
for ruminants. For example it has been demonstrated that they can be used
with maize or sorghum stover for fattening cattle (Gebreyohannes and
Hailemariam 2011). However, information is lacking on the yield, nutritive
value and variation among genotypes of early harvested common bean crop
residues.
The objectives of the present study were to: (1) assess the yield and
nutritive value for ruminants of the various morphological fractions of the
crop residues from a range of genotypes of common bean when early-harvested
at green pod fill stage, (2) examine the relationships between yield and HPW
crop residue quality parameters, and (3) compare the yields and nutritive
values with those observed in common bean crop residues harvested at seed
maturity.
Materials and methods
Location, experimental design, and sample collection
The study was undertaken at two trial sites, one in the South-west (at
Boricha Wereda; 6°947’N and 38°222’E) and the other in the North-west (at
Mandura Wereda; 11°118’N and 36°722’E) regions of Ethiopia during the 2013
cropping season. These sites had been selected to represent smallholder
crop-livestock systems in differing environments where common bean is an
important crop (Farrow 2014). The nine genotypes grown at each site were chosen
to represent those well-adapted and often grown in the regions. At each trial
site genotypes were examined in a randomized complete-block design with three
replicates. The trial sites descriptions, genotypes, management, planting,
sampling and measurements at mature seed harvest at the two sites have been
previously reported (Dejene et al 2018). The plants harvested at early maturity
at the green pod fill stage for the present study were sampled from a 0.5 m x 2
m area in the plots also harvested at seed maturity and with a 0.5 m border
between the harvested areas. Dates of sowing at Boricha and Mandura
were on 07 and 24 August 2013, respectively. The early harvest at Boricha
was on 14 and 17 October 2013 at the R6 (mid-seed fill) stage when 50% of pods
have fully developed seeds (Schwartz and Langham 2016). Due to unavoidable delay
the harvest at the Mandura was on 2 and 4 November 2013 when~80% of
pods had fully developed seeds (i.e. shortly before physiological maturity). At
harvest the numbers of plants were counted, the plants were harvested at the
soil surface and then separated with care to avoid leaf loss into seed, pod
wall, stem and leaf; the last 2 fractions comprised the haulm. Following
measurement of fresh weight, samples (~500 g) were placed into cotton bags,
sun-dried and later oven-dried (60 °C for 48 h).
Laboratory analyses
Samples of leaf, stem and pod wall fractions were analysed for in vitro
dry matter digestibility (IVDMD), and the concentrations of total N, neutral
detergent fibre (assayed with α–amylase and corrected for the ash concentration
of the residue, NDF), and acid detergent fibre (corrected for the ash
concentration of the residue, ADF) using near infrared spectroscopy (NIRS). The
laboratory procedures used to analyse the reference samples, and the calibration
and validation procedures, have been described by Dejene et al (2018).
Calculations and statistical analyses
The yields and composition of haulm and pod wall (HPW) were calculated from
the measurements for the leaf, stem and pod wall fractions. Analysis of
variance was performed for yields, morphological traits and nutritional
attributes of the residues as described by Dejene et al (2018)
except that the results from the stage of seed maturity at harvest (early or
mature) were also included as a main effect. Since there were interactions
for genotype (G) and site (i.e. environment (E) (i.e. G x E) and harvest
stage in the pooled analyses of treatments across sites (Tables 1 and 2) the
results from each E were also analysed and are presented separately. Within
each E the effects of genotype, morphological fractions and harvest stage
were examined. When averaged across harvest stage at each E, replicate was
considered as nested within G and the replication x genotype mean square was
used as the error term for testing the significance of G. When averaged
across E, replicate was considered as nested within E and the replication x
environment mean square was used as the error term to test E. Differences
among means were compared using the least significant difference (LSD) test
in PROC MIXED with the PDIFF option of the LSMEANS statement. Relationships
between yield, residue composition and residue digestibility were analysed
using linear regression approach.
Results
Seed and early harvest residue yields of haulm and pod wall (HPW)
and proportions of HPW fractions
There were large (p<0.05) effects of genotype on the yields of both
seed (range 0.31 - 1.57 t/ha) and of HPW (range 1.19 - 2.93 t/ha) at Mandura,
but no differences (p>0.05) were observed at Boricha
(Table 1). Genotype sometimes affected the proportions of leaf, stem and pod
wall in the HPW within environment, but the effects were not consistent
(Table 1). The stem comprised the largest component of the HPW (mean 50.2
and 54.7%), while there were similar proportions of leaf (means 25.2 and
21.0 %) and pod wall (means 24.7 and 24.3%) at the Boricha and
Mandura sites, respectively (Table 1).
Table 1.
Yields of seed, haulm and pod wall (HPW) dry matter (DM),
nitrogen (N) and digestible dry matter (DDM), and
proportions of the HPW morphological fractions of nine
common bean genotypes harvested at green pod fill stage at Boricha (n = 3) and Mandura (n = 3) sites
in 2013
Environment
Genotype
Seed yield (t/ha)
HPW yields
Proportions of HPW fractions (%)
DM (t/ha)
N(kg/ha)
DDM(t/ha)
Pod wall
Leaf
Stem
Boricha
A-Melka1
1.26
2.95
58.6ab
1.97
18.3
23.9bc
57.7a
Argene
0.85
2.74
70.3a
1.87
27.3
27.5a
45.2bc
Awash-1
1.13
2.75
56.8ab
1.84
22.0
25.1bc
52.9ab
Dimtu
0.82
2.06
38.8bc
1.42
22.7
24.7bc
52.7ab
Dinknesh
1.43
3.16
69.9a
2.12
25.8
26.1ab
48.1bc
H-Dume2
1.40
3.17
57.1ab
2.14
27.8
25.1bc
47.1bc
Ibado
0.83
2.06
35.3bc
1.36
23.8
23.3c
52.8ab
Nasir
1.53
3.15
58.9ab
2.15
31.6
24.8bc
43.6c
SARI
1.35
3.15
63.2a
2.17
22.7
26.0ab
51.3abc
Mean
1.18
2.80
56.5
1.89
24.7
25.2
50.2
SEM
0.201
0.291
6.94
0.202
2.81
0.76
2.80
p
value
0.12
0.06
0.03
0.07
0.12
0.05
0.05
Mandura
A-Melka1
0.65d
1.79c
28.7d
1.07c
20.9b
21.4
57.7ab
Argene
0.31e
1.19d
18.3e
0.75d
20.2b
20.7
59.2a
Awash-1
0.87cd
1.88c
31.7cd
1.15c
21.8b
20.2
58.1ab
Dimtu
1.24b
2.57b
41.9a
1.64ab
25.1a
20.6
54.4bc
Dinknesh
1.21b
2.52b
43.4a
1.62ab
26.1a
22.1
51.8c
H-Dume2
1.57a
2.93a
36.5bc
1.81a
26.6a
20.7
52.7c
Ibado
1.26b
2.68ab
39.7ab
1.64ab
25.2a
21.4
53.4c
Nasir
1.07bc
2.35b
31.7cd
1.44b
26.9a
21.0
52.1c
SARI
1.09bc
2.40b
36.3bc
1.51b
26.3a
21.2
52.6c
Mean
1.03
2.26
34.2
1.40
24.3
21.0
54.7
SEM
0.085
0.112
1.667
0.072
0.78
0.98
1.26
p
value
<0.001
<0.001
<0.001
<0.001
<0.001
0.93
<0.01
Pooled
Mean
1.10
2.53
45.4
1.65
24.5
23.1
52.4
p
value
Genotype (G)
<0.001
<0.001
0.04
<0.01
<0.01
0.38
<0.01
Environment (E)
0.23
0.08
0.01
0.04
0.81
<0.001
0.02
G x E
<0.01
<0.001
<0.001
<0.001
0.21
0.28
0.06
1 Awash-Melka; 2 Hawassa Dume; SEM, standard error of means
abc Means in the same column without common letter are different at p<0.05
Quality attributes of the haulm and pod wall (HPW) fractions
The N concentrations in the entire HPW varied (p<0.05) among
genotypes at both environments, ranging from 17.1 – 25.3 g/kg DM at Boricha
and 12.5 – 17.4 g/kg DM at Mandura (Table 2). At Mandura
site the IVDMD of leaf, stem, pod wall and HPW differed among genotypes (p
<0.05) and the IVDMD of HPW ranged from 602– 642 g/kg DM. There were
comparable differences among genotypes within the morphological fractions.
Table 2.
Quality attributes (g/kg dry matter) of haulm and pod wall
(HPW) morphological fractions (pod wall, leaf and stem) and
HPW of nine common bean genotypes harvested at green pod
fill stage at Boricha (n = 3) and Mandura
(n = 3) in 2013
Genotype
N
IVDMD
Pod wall
Leaf
Stem
HPW
Pod wall
Leaf
Stem
HPW
Boricha
A-Melka1
21.3bc
32.5b
14.0bc
19.8bcd
750ab
735
614
667
Argene
28.2a
36.5a
16.6a
25.3a
695bcd
720
653
683
Awash-1
23.3b
30.7bc
14.7ab
20.7bc
687cd
732
630
667
Dimtu
23.0b
30.7bc
11.4d
18.8cde
779a
732
628
688
Dinknesh
28.4a
31.4bc
13.3bcd
22.0b
739abc
692
621
670
H-Dume2
16.9de
30.7bc
11.8cd
18.0cde
691bcd
719
636
674
Ibado
13.9e
30.2bc
13.0bcd
17.1e
677d
726
631
662
Nasir
18.5cd
30.4bc
12.1cd
18.7cde
708bcd
737
631
682
SARI
22.5b
28.2c
14.9ab
20.1bcd
724abcd
724
657
689
Mean
21.8
31.2
13.5
20.1
717
724
634
676
SEM
1.185
1.234
0.832
0.820
0.02
12.37
9.58
8.82
p
value
<0.001
0.02
<0.01
<0.001
0.02
0.35
0.10
0.31
Mandura
A-Melka
15.1ab
31.2b
10.8a
16.0abc
715a
726a
514d
602d
Argene
14.2ab
30.3b
10.9a
15.5bc
681bc
732a
580a
632abc
Awash-1
14.4ab
34.9a
11.5a
16.8ab
665bcd
722ab
553abc
611cd
Dimtu
15.1ab
34.1a
10.1ab
16.3abc
694ab
750a
576ab
641ab
Dinknesh
15.7a
34.5a
10.9a
17.4a
694ab
749a
571ab
642a
H-Dume
9.6c
25.9c
8.6c
12.5e
638d
766a
550bc
618bcd
Ibado
9.9c
30.4b
10.9a
14.8cd
642d
679b
572ab
612cd
Nasir
10.9c
28.7b
8.8bc
13.5de
649cd
731a
542c
610cd
SARI
13.4b
28.6b
10.6a
15.1bcd
680bc
752a
557abc
631abc
Mean
13.1
30.9
10.3
15.3
673
734
557
622
SEM
0.582
0.857
0.493
0.575
11.16
15.34
9.23
7.77
p
value
<0.001
<0.001
<0.01
<0.001
<0.01
0.04
<0.01
0.01
Pooled
Mean
17.5
31.1
11.9
17.7
695
729
595
649
p
value
Genotype
<0.001
<0.001
<0.001
<0.001
<0.001
0.18
<0.001
<0.01
Environment
<0.001
0.76
<0.01
<0.01
<0.01
0.17
<0.001
<0.001
G x E
<0.001
<0.001
0.12
<0.001
0.54
0.02
0.06
0.39
1Awash-Melka; 2 Hawassa Dume; SEM, standard error of means;
IVDMD, in vitro dry matter digestibility; N,concentrations of total nitrogen
abcMeans in the same column without common letter are
different at p <0.05
Concentrations of N, NDF and ADF, and IVDMD content, differed among the HPW
fractions (p<0.001) at both environments (Table 3). When averaged
across environments and genotypes, generally the leaf was higher ( p<0.001)
in N and IVDMD (31 and 729 g/kg DM, respectively) than in pod wall and stem
fractions, while the concentrations of NDF and ADF followed the inverse
trends (Table 3).
Table 3. Quality attributes (g/kg DM), and nitrogen (N)
(kg/ha) and digestible dry matter (DDM) (t/ha) yields, of
residue morphological fractions (pod wall, leaf and stem)
of nine common bean genotypes harvested at green pod fill
stage at Boricha (n=27) and Mandura
(n=27) in 2013
Environment
Morphological fractions
Quality attributes (g/kg DM)
Nutrient yields
N
IVDMD
NDF
ADF
N (kg/ha)
DDM (t/ha)
Boricha
Pod wall
21.8b
717a
480b
357b
15.0c
0.49b
Leaf
31.2a
724a
357c
300c
22.2a
0.51b
Stem
13.5c
634b
557a
424a
19.3b
0.89a
SEM
0.364
4.819
6.836
6.250
0.965
0.030
p
value
<0.001
<0.001
<0.001
<0.001
<0.001
<0.001
Mandura
Pod wall
13.1b
673b
527b
387b
7.2c
0.38b
Leaf
30.9a
734a
384c
308c
14.6a
0.35b
Stem
10.3c
557c
627a
484a
12.5b
0.68a
SEM
0.259
4.187
4.884
4.792
0.255
0.010
p
value
<0.001
<0.001
<0.001
<0.001
<0.001
<0.001
Pooled
Pod wall
17.5b
695b
504b
372b
11.1c
0.43b
Leaf
31.1a
729a
370c
304c
18.4a
0.43b
Stem
11.9c
595c
592a
454a
15.9b
0.79a
SEM
0.223
3.192
4.201
3.938
0.499
0.016
p
value
<0.001
<0.001
<0.001
<0.001
<0.001
<0.001
ADF, acid detergent fibre corrected for the ash
concentration of the residue;
IVDMD, dry matter digestibility; N, total nitrogen;
NDF, neutral detergent fibre assayed with α–amylase and
corrected for the ash concentration of the residue;
SEM, standard error of means
abc
Means in the same column without common letter are
different at p <0.05
Nutrient yields of the haulm and pod wall (HPW) fractions
The N yields in the HPW varied (p<0.05) among genotypes at both
environments, ranging from 35.3 – 70.3 kg/ha at Boricha and 18.3 –
43.4 kg/ha at Mandura. Digestible dry matter (DDM) yield of HPW
varied among genotypes (p<0.05) (range 0.75 – 1.81 t/ha) at
Mandura, but did not vary with genotype (p>0.05) at
Boricha (Table 1). Among the morphological fraction of the HPW averaged
across environment and genotypes, the leaf had highest (p
<0.001) N yield (18.4 kg/ha), followed by stem (15.9 kg/ha), and then by pod
wall (11.1 kg/ha) (Table 3). In contrast stem had the highest (p<0.001)
DDM yield (0.79 t/ha), followed by similar DDM yields for the leaf and pod
wall (both 0.43 t/ha).
Relationships between yield and HPW quality attributes
There were correlations between the yields of seed harvested at green pod
fill stage and the yields of HPW (r = 0.79; p<0.001), of DDM in the
HPW (r = 0.76; p<0.001), and to a lesser extent with the yield of N
in the HPW (r = 0.57; p<0.001) (Figure 1a, 1b and 1c,
respectively). The seed yield harvested at green pod fills stage was closely
correlated with the seed yield at harvest maturity (r = 0.98; p<0.001)
(Figure 1d), and was generally not correlated with the N content or IVDMD
attributes of the HPW or the HPW fractions. Also the composition of HPW
constituents was generally not related (p
>0.05) to HPW yield in either site (data not shown). Total N concentrations
of the HPW were strongly correlated with IVDMD of HPW (r = 0.70; p<0.001)
and leaf-to-stem-ratio in the haulm (r = 0.73; p<0.001) (Figure 1e
and 1f). Nitrogen yields of HPW were strongly correlated with the yields of
HPW DM (r = 0.86; p
<0.001) and DDM in the HPW (r = 0.90; p<0.001, respectively) (Figure
1g and 1h). There were stronger associations between stem and HPW IVDMD at
Boricha and Mandura (r=0.66 and r = 0.82; p<0.001)
than for leaf (r=0.45 and r = 0.40; p
<0.05) and pod wall (r=0.41 and r = 0.44; p<0.05) fractions,
respectively (data not shown).
Figure 1.
The regression relationships between the seed yield (SY) at
early harvest with the yields of (haulm + pod wall; HPW) DM,
digestible dry matter (DDM) or total N concentration in HPW
are shown in Figs (a), (b) and (c). The seed yields at early
harvest and mature seed harvest (Dejene et al 2018) are shown
in Fig (d). The relationships between total N concentration
of HPW and the in vitro DM digestibility (IVDMD) or the
leaf-to-stem ratio of HPW are shown in figs(e) and (f). The
relationships between yields of total N with yield of HPW DM
or DDM are shown in Figs (g) and (h). Measurements at
Boricha site (○) and at Mandura site (●) were pooled
Discussion
The measurements in the present experiment clearly demonstrated that the
crop residues of early-harvested common bean crops are of high nutritional
value for ruminants. This was evident from the high total N concentration
(mean 17.7 g/kg DM) and IVDMD (mean 649 g/kg DM) and low concentrations of
NDF and ADF in the HPW (Table 2). These measurements are in accord with the
general high nutritive value of forages of legumes in vegetative growth and
before seed maturity (Norton 1982; Norton and Poppi 1995). Diets comprised
mainly of the HPW of early-harvested common bean would be expected to
provide high voluntary intakes of DM and DDM by ruminants and metabolizable
energy, protein and other nutrients sufficient for high animal productivity
(e.g.> 0.5 kg live weight gain/day in young growing cattle) (CSIRO 2007).
Furthermore this good quality forage from common bean residue would usually
be even more valuable as a ruminant feedstuff when mixed with low quality
forage ssuch as cereal crop residues to achieve much higher ruminant
productivity than that usually observed in smallholder crop-livestock
systems.
The observations that at early harvest the HPW yields of N and DDM ranged
widely among the genotypes, up to 2-fold at Boricha site and up to
5-fold at Mandura site (Table 1), indicated that use of the most
appropriate genotypes for the environment could provide large increases in
the amounts of high quality forage from early-harvested common bean. Wide
variation among common bean cultivars in shoot mass at the green pod fill
growth stages was also reported by Araújo and Teixeira (2008). Furthermore
the close (r = 0.79) positive correlations between the yields of HPW and
seed in early harvested common bean in the present experiment indicated that
genotypes can be selected for higher yields of both seed and crop residue.
Similar positive correlations occurred in the same genotypes and
environments when harvested at seed maturity (Dejene et al 2018). These
results clearly showed that higher-yielding genotypes of common bean
provided higher yields of both seed and crop residue regardless of the stage
of harvest, and genotypes can be selected concurrently for both food and
forage irrespective of maturity at harvest.
Since the same sites and genotypes of common bean were harvested early and
at seed maturity (Dejene et al 2018) the effects of harvest maturity could
be compared directly (Table 4). As expected, at mature harvest the seed
yield was much (35%) higher at mature-seed-harvest. However there was a much
lower proportion of leaf in the HPW, a much lower yield of leaf, and lower
yields of both DDM and N. The leaf in legumes, including in common bean, is
clearly much higher in N concentration and IVDMD and lower in fibre
constituents than the stem or pod wall, and this was observed in the present
experiment. Variation in the leaf-to-stem ratio among genotypes in the
residue is thus expected to have an important effect on the nutritive value
of their harvest residues. Also the stage of physiological maturity of the
plant generally has an important influence on leaf shedding and leaf content
of the crop residue. This explains the generally lower leaf content at the
Mandura site where the early harvest was unavoidably at a later stage
of physiological maturity of plants than at the Boricha site. It
also explains the lower leaf content at the harvest at seed physiological
maturity at these sites (Dejene et al 2018); leaf yield at the mature
harvest was only 21% of that at the early harvest. Such differences
emphasise the importance of the leaf to maintain the nutritive value of the
common bean residue. Since leaf loss in common bean approaching seed
maturity is affected by genotype (Larbi et al 1999) consideration of leaf
loss during selection of common bean intended as a dual-purpose crop for
both food and forage is likely to be advantageous.
Table 4. Yields of seed, haulm and pod wall (HPW)
morphological fractions and HPW (t/ha), nitrogen (N)
(kg/ha) and digestible dry matter (DDM) yields of HPW
(t/ha), and proportions (%) of HPW morphological fractions
of nine common bean genotypes harvested at green pod fill
and seed maturity stages at Boricha (n = 27) and Mandura (n = 27) in 2013
Environment
Harvest stage
Seed yield (t/ha)
Yields of HPW and fractions (t/ha)
Yields of HPW
Proportions of HPW (%)
Pod wall
Leaf
Stem
HPW
N (kg/ha)
DDM
(t/ha)
Pod wall
Leaf
Stem
Boricha
Green pod fill
1.18b
0.68a
0.71a
1.41
2.80a
56.5a
1.89a
24.7b
25.2a
50.2b
Seed maturity
1.67a
0.61b
0.15b
1.41
2.17b
16.7b
1.02b
28.6a
6.9b
64.5a
SEM
0.017
0.007
0.017
0.015
0.013
1.466
0.024
0.371
0.203
0.313
p
value
<0.001
<0.001
<0.001
0.95
<0.001
<0.001
<0.001
<0.001
<0.001
<0.001
Mandura
Green pod fill
1.03b
0.56a
0.47a
1.22a
2.26a
34.2a
1.40a
24.3b
21.0a
54.7b
Seed maturity
1.32a
0.50b
0.10b
1.01b
1.61b
13.1b
0.78b
29.9a
6.8b
63.3a
SEM
0.008
0.004
0.007
0.008
0.008
0.453
0.010
0.137
0.235
0.269
p
value
<0.001
<0.001
<0.001
<0.001
<0.001
<0.001
<0.001
<0.001
<0.001
<0.001
N, total nitrogen; SEM, standard error of means
ab Means in the same column without common letter are
different at p <0.05
Conclusions
In conclusion the HPW residues of early harvested common bean had high
nutritive values for ruminants. They should be particularly valuable as a
supplement for N-deficient cereal crop residues. Leaf loss as plants
approached seed maturity had a major effect on the nutritive value of HPW as
a feedstuff. Use of the most appropriate genotypes can double the N and DDM
yields of HPW without reducing seed yield, and since yields of seed and of
HPW DM, DDM and N are positively correlated genotypes can be selected
concurrently for seed and HPW yields.
Acknowledgements
We greatly appreciate the support from Australian Centre for International
Agricultural Research through a John Allwright Fellowship for Mesfin Dejene
to study at the University of Queensland. The assistance received through
the SIMLESA (Sustainable Intensification of Maize-Legume cropping systems
for food security in Eastern and Southern Africa) project, CIMMYT, the
Ethiopian Institute of Agricultural Research and ILRI-Addis Ababa for
research support through N2Africa project is highly appreciated. We thank
the N2Africa project team members in the research centres and experimental
sites for assistance during field data collection, and staff at ILRI Addis
Ababa for support in sample grinding and processing for lab analysis and
staff at Gatton, UQ for laboratory analysis support. We would like to add
a sentence under this section. Plant samples were
imported to Australia under Australian Quarantine Permit-IP14007043.
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