Abstract
One of approaches to maintain the yield stability of the lowland tropical wheat is the use of secondary traits in the selection process. The identification of these characters requires a statistical approach in the form of genetic parameter analysis and multivariate analysis. The objective of this study was to determine the secondary traits of adaptive wheat mutants in the lowlands through the use of genetic parameters and multivariate analysis on the parameters. The study consisted of three field trials conducted in three different regencies, namely Jeneponto (135 m above sea level (asl)), Maros (100 m asl) and Bantaeng (125 m asl). The study used a nested design, where replications were nested in the environments. The genotype factors consisted of 20 genotypes repeated three times. 11 characters were observed including vegetative and reproductive characters. The analysis used consisted of repeatability, correlation, cluster analysis, principal component analysis, factor analysis, and cross print analysis. The overall results of the analysis indicate that the number of productive tillers is the main secondary trait for the selection of adaptive wheat in the lowlands. The character can be recommended for selection criteria in testing wheat lines in the lowlands to make an effective selection.
-
Key words: Genetic parameters, Multivariate analysis, Productive tillers, Secondary traits, Tropical wheat
INTRODUCTION
Wheat is the main raw material widely used in making flour and bread (
Kumar et al. 2011). In the developing countries, such as in Indonesia, more people consume bread made from wheat flour not only for its dietary fibre but also to obtain beneficial components such as protein, vitamins, and other phytochemicals (
Shewry and Hey 2015). However, the development of these plants is generally not suitable for the tropical climate in Indonesia (
Farid 2018). This makes Indonesia import wheat from other countries, especially from subtropical countries. The high volume of wheat import of Indonesia, reached 8.1 million tons in 2016, making Indonesia very dependent on other countries and burden the country’s foreign exchange (APTINDO 2016). Therefore, the development of wheat in the tropics, including Indonesia, is a long-term solution to reduce the proportion of imports and dependence on other countries.
Development of tropical wheat can be done through the development of plant varieties. In general, there are several accessions of wheat grown in Indonesia (
Nur et al. 2018). However, the accession only grows optimally in the highlands. It is considered less able to compete with horticultural commodities that have high selling values. Hence, it is necessary to develop an optimal tropical wheat in the lowlands (
Nasaruddin et al. 2018). One way to induce these characteristics is through initiation of mutation. This has been developed by
Nur et al. (2018),
Farid (2018), and
Nasaruddin et al. (2018). Therefore, the continued development of this research is important for obtaining wheat varieties adaptive under the lowlands.
MATERIALS AND METHODS
The study was conducted in three growing environments. The first environment was conducted in Kelara Village, South Tolo District, Jeneponto Regency, South Sulawesi province, Indonesia (latitude 5°24'58.0"S, longitude 119º54'58.2"E, and 135 m above sea level (asl)) from March to June 2018. The second experiment was conducted in Allopolea Village, Lau District, Maros Regency, South Sulawesi province, Indonesia (latitude -4º-58'-55.1"S, longitude 119º34'27.4"E, and 100 m asl) in the same time frame of the first experiment. The last and third experiment was carried out in Bonto Manai Village, Bissappu District, Bantaeng Regency, South Sulawesi province, Indonesia (latitude 5º32'03.0"S, longitude 119º54'17.5"E, and 120 m asl) from July to October 2018. The plant conditions in each environment was shown in
Fig. 1.
Experimental design and observation
The experiment used a nested randomized complete block design (RCBD) with two factors namely genotype and environment. The replications were three times and nested in the environment. 20 genotypes were used consisting of 16 mutant lines and 4 control varieties, namely Dewata, Selayar, Nias, and Munal. Based on the design, the total experimental units were 180. Each plot is 1 m × 4 m divided into 4 rows. Each genotype was planted with spacing of 25 cm × 2 cm (12 g /row according to CIMMYT standards).
Fertilization was conducted twice during plant growth. The first fertilization was carried out 10 days after planting (DAP) with 150 kg/ha Urea, 200 kg/ha SP36, and 100 kg/ha NPK. The second fertilization was at 30 DAP using 150 kg/ha Urea. Weeding was done twice, at 30 and 45 DAP. Pest control was conducted by spraying insecticide on wheat. Harvesting was conducted when the plants reached its physiological maturity, marked 80% of panicles, stems and leaves of plants have turned yellow, and the seeds have hardened. Harvesting was done by cutting the base of the stem above the soil surface using a sickle. Panicles that have been harvested are then dried and seeded. Observations were carried out for plant height before harvest, number of productive tillers, days to flowering, days to harvest, number of spikelet, panicle length, number of seeds per panicle, seed weight per panicle, weight 100 seeds, percentage of unfilled grains, and yield.
Data analysis
Data analysis conducted on the observed data in this study consists of analysis on the genetic parameters and multivariate analysis. Data analysis carried out were analysis of variance using STAR 2.1, and identification on genetic variability, repeatability, genetic correlation and phenotypic correlation for each character using META-R software (
Anshori et al. 2019).
Four analyses were conducted in the multivariate analysis on the genotypes average values at the three locations consisted of cluster analysis, principal component analysis, factor analysis and path analysis (
Mattjik and Sumertajaya 2011). Cluster and path analysis were carried out using Rstudio software with
Cluster Maechler et al. (2019) and Agricolae packages (
Mendiburu 2014), respectively. Meanwhile, the analysis of the principal component analysis and factor analysis were carried out with minitab v 17. For PCA visualitation in 3D, the three principal component were analized by scatterplot3d package in Rstudio (
Ligges and Mächler 2003), respectively. Finally, all the results of genetic parameters and multivariate analysis were evaluated by scoring secondary characters in each analysis. The score consisted of three scores, 1, 3 and 5. The nearer of score indicated that the character has a stronger relationship to the yield. All scores on all characters were summed and formed as for the percentage of conformity. This value served as a quantitative benchmark of the suitability of a character to be a character of the selection. The formula of conformity explained below:
RESULTS
Analysis of variance in
Table 1 showed that all responses to growth character were influenced by environmental variability, genotypes and their interactions (
P ≤ 0.01), except for the characters of the number of productive tillers and yield (
Table 1). Besides that, the repeatability also showed that the characters of the number of productive tillers and yield had the highest value of repeatability of 89.38% and 87.92%, respectively. Other characters also classified as having high repeatability were grain weight per panicle (61.98%), the number of spikelets (55.41%), and panicle length (51.96%). Meanwhile, the character of 100 grains weight was classified as medium repeatability (27.36%) and the rest were classified as low repeatability (
Table 1). The information of wheat mutant morphology was attached in
Supplementary Table S1.
The results of phenotype and genotype correlation analysis showed that plant height (0.503, 0.999), number of productive tillers (0.771, 0.835), number of spikelets (0.831, 0.999), panicle length (0.559, 0.705), number of grains per panicle (0.674, 0.999), grain weight per panicle (0.663, 0.921), and weight of 100 grains (0.645, 0.999) have significant correlations with yield. On the other hand, days to flowering, days to harvest and percentage of unfilled grains had a low phenotype correlation and are undefined in the genetic correlations. Based on
Table 2, the number of productive tillers (0.065) was the character showing the lowest difference between phenotype and genetic correlations compared to other characters, followed by characters of panicle length (0.146) and number of spikelets (0.169).
The results of the cluster analysis showed that there were two large groups with a degree of dissimilarity and agglomerative coefficients reaching values of 0.6 and 0.89, respectively (
Fig. 2). The yield as the main character was grouped in group 2. In general, group 2 was divided into two sub-groups with a degree of dissimilarity of 0.2. Based on the division of the subgroups in group 2, the yield was in subgroup 1 together with the number of productive tillers, the weight of 100 grains, seed weight per panicle, and panicle length. On the other hand, the number of spikelets and number of grains per panicle were in subgroup 2. Meanwhile, plant height, days to flowering, percentage of unfilled grains, and days to harvest were in group 1.
The results of the principal components analysis were visualized in the 3D plot form (
Fig. 3). Based on
Fig. 3, the yield was in quadrant 2 together with the number of productive tillers, panicle length, number of spikelets and weight of 100 grains. On the other hand, days to harvest was in quadrant which is opposite to quadrant 2 or there was in quadrant 8. Meanwhile, the closest quadrant that has a vector close to the yield was quadrant 3 (plant height and weight of grains per panicle) and 7 (number of grains per panicle).
Factor analysis in this study showed representative results. This was supported by a total variance of data that reached 85.58% and the overall character trait that was above 0.8, except for plant height (0.774) and days to harvest (0.698) (
Table 3). Based on the factor loading values, panicle length and weight of 100 grains were the determinants of the first-factor variance represented 34.2% of the total initial data variance. Then the second factor, which represented 19.9% of the total data variance, had a variance direction that was largely determined by the number of grains per panicle and the percentage of unfilled grains in the opposite directions. The greatest variance of the yield, as the main character, was in the third factor with a factor loading value of 0.321. Besides the yield, another main character in factor 3 was the number of productive tillers (0.592).
Path analysis showed fairly representative results with a determination value of 79.01% (
Table 4). Based on the path analysis, the number of productive tillers was the character that had the greatest direct influence value with a value of 0.563. As for the other characters that have a significant direct effect were the weights of 100 grains (0.239) and the number of spikelets (0.237). However, the direct influence of the two characters was only half of the direct effect of the number of productive tillers.
Evaluation of conformity of all multivariate analysis results and genetic parameters was shown in
Table 5. The number of productive tillers was a character with the highest degree of conformity value of 91.67%. Meanwhile, other characters that have a suitability value above 50% were the number of spikelets (75%), weight of 100 grains (75%), weight of grains per panicle (66.67%) and panicle length (66.67%). Based on these results, the number of productive tillers, number of spikelets, weight of 100 grains, weight of grains per panicle, and panicle length could be used as a selection character in the development of tropical wheat in Indonesia. However, the number of productive tillers was the best selection character highly recommended in developing wheat under the lowland.
DISCUSSION
Based on the analysis results of variance and repeatability, the number of productive tillers and yield were genetically stable characters in the lowlands (
Table 1). This was also reported by
Erkul et al. (2010),
Tripathi et al. (2011) and
Bhushan et al. (2013) which stated that the number of tillers or the number of productive tillers and yield had high repeatability. A different result reported by
Joshi et al. (2018) showed the number of productive tillers had moderate repeatability and the yield had high heritability. The not significant character in interaction effect indicate that the different environment relative does not change the rank of genotype or in general all genotype have the same pattern to environmental alteration. Moreover, if characters also showed high repeatability or heritablity (
Arief et al. 2015;
Anshori et al. 2019). Based on these, the characters who have high repeatability deserve to be used as selection characters. However, the determination of secondary traits in selection need to do some data analysis testing on the yield, so that the precision of secondary traits could increase the effectiveness of lowland wheat selection.
Phenotypic and genetic correlation is one way to determine the stability of a selection character (
Garg et al. 2017). The large difference in the two correlations shows the magnitude of the influence of environmental and interactions effect affecting the correlation (
Manjunatha et al. 2017;
Anshori et al. 2019). In
Table 2, genetic correlations had a greater value than phenotypic correlations for most growth characters. This result explained that there was a negative influence of the environments and their interactions, so that the value of phenotypic correlations to be lower than their genetic correlations (
Patil and Lokesha 2018). Based on these, the character considered very stably in this study was the number of productive tillers followed by panicle length and number of spikelets. These characters had low correlation subtraction between the two correlations, especially the number of productive tillers. This result has also been reported by
Bhushan et al. (2013),
Malek et al. (2014), and
Meier et al. (2019). Therefore, the three characters, especially the number of productive tillers, are recommended as selection characters in the lowland wheat selection based on phenotypic and genetic correlation analysis.
Cluster analysis is a semi-qualitative and subjective multivariate analysis (
Mattjik and Sumertajaya 2011). The results of this analysis are groupings with a certain degree of closeness based on the grouping method chosen by the researcher (
Malek et al. 2014; Awan 2015). However, the analysis is quite effective and easy to understand, so it is widely used in determining selection (
Arain et al. 2018). Based on
Fig. 2, the number of productive tillers, weight of 100 grains, the weight of grains per panicle have a pattern of mean values almost identical to all 20 genotypes tested. Therefore, the number of productive tillers, weight of 100 grains and weight of grains per panicle can be considered as selection characters in selecting the lowland wheats based on cluster analysis.
The principal component analysis is a multivariate analysis used by many researchers to reduce and simplify character dimensions with still maintaining most of the initial data variance (
Awan et al. 2015;
Anshori et al. 2018). It is very useful in determining secondary traits which have the same variance direction as the main characters without overlapping variations (
Mattjik and Sumertajaya 2011;
Awan et al. 2015). Based on
Fig. 3, the number of productive tillers in this analysis had a vector quite far towards the yield character compared to the characters of panicle length, the weight of 100 grains, and the number of spikelets. Nevertheless, the number of productive tillers remained representative to be categorized in one group with the yield because of the cumulative percentage between PComp1 and PComp3 reached 60% and had a vector direction that was consistent with the yield. On the other hand, the plant height and seed weight per panicle were still considered as different groups, even though both characters had a small vector angle to the yield. This is due to the consistency of the vectors of the two characters towards the yield. Therefore, based on the principal component analysis, the number of productive tillers, panicle length, weight of 100 grains, and number of spikelets can be considered as selection characters in the selection of lowland wheats.
Factor analysis is a multivariate analysis that has similarities with the principal component analysis (PCA) (
Mattjik and Sumertajaya 2011). The difference in this analysis lies in the process of reducing the variance of the non-specific covariates and optimizing variances on specific characters that have high covariance in a factor dimension (
Mattjik and Sumertajaya 2011;
Dormann et al. 2013;
Awan et al. 2015). This is indicated by the low loading factor value on non-specific characters and conversely the high factor loading value on the main character dimensions of the factor (
Dormann et al. 2013;
Yong and Pearce 2013;
Rocha et al. 2018). Based on
Table 3, the number of productive tillers and yield characterizes factor 3 with a loading factor value exceeding 0.32 (
Yong and Pearce 2013). This value is a standard loading factor based on the principal component. Based on this, the number of productive tillers had the same directional relationship with the yield. It is strong proof that the number of productive tillers was a very suitable character to be used as a selection character on lowland wheat plants.
Path analysis is a multivariate analysis used to divide a multivariate correlation into direct and indirect effects (
Carvalho et al. 2017;
Anshori et al. 2018). The direct effect is one indicator in projecting how large a character variance influences the total variance of the main characters (
Yagdi 2009). The results of this analysis are often used as a standard in determining selection characters (
Anshori et al. 2019). Based on
Table 4, the number of productive tillers is very suitable as a selection character compared to other characters. This result was also reported by
Arya et al. (2017) and
Ibrahim (2019) who stated that the number of productive tillers and number of spikelets had a large direct effect on the yield in F6 wheat lines. This completed the evidence in the previous multivariate analysis. Besides that, the number of spikelets and weights of 100 grains also could be considered as a selection character. However, both characters were not better than the number of productive tillers. Based on all the analyses, the evaluation of all results needs to be done as a systematic consideration in the selection of secondary traits in lowland wheat.
Productive tillers become one of the main keys in supporting wheat yield (
Monpara 2011). Every tiller may not be a productive one (Moral and Moral 1995). This is due to the competition of the energy distribution in initiating flowering apparatus including the spikelet formation (
Xie et al. 2016). Based on the results of this study, wheat grown in lowland areas will make the formation of tillers efficiently to be productive tillers. It made the number of tillers less than that of the highlands (
Bányai et al. 2014) so that plants can be more effective in supporting their production and yield components in the lowlands. Therefore, the number of productive tillers was strongly recommended as the main secondary trait in the lowland wheat selection.
In conclusions, the number of productive tillers, number of spikelets, panicle length, weight of 100 grains and weight of grains per panicle can be used as secondary traits in the selection of lowland wheats. The number of productive tillers is the main secondary trait for adaptive wheat in the lowlands. These characters can be recommended for selection criteria in testing wheat lines in the lowlands to make selection effective.
SUPPLEMENTARY MATERIALS
Fig. 1The general plant condition in each study environment, (a) Kelara village, (b) Allopolea Village, and (c) Bonto Manai Village.
Fig. 2Dendrogram of characters of wheat mutant adaptive to lowland. DF: Days to flowering, DH: Days to harvest, NGP: Number of grains per panicle, NPT: The number of productive tillers, NS: Number of spikelet, PH: Plant height, PL: Panicle length, PUG: Percentage of unfilled grains, W100: Weight of 100 grains, WGP: Weight of grains per panicle.
Fig. 33D plot of principal component analysis (PCA) of the character of wheat mutant adaptive to lowland. DF: Days to flowering, DH: Days to harvest, NGP: Number of grains per panicle, NPT: The number of productive tillers, NS: Number of spikelet, PH: Plant height, PL: Panicle length, PUG: Percentage of unfilled grains, W100: Weight of 100 grains, WGP: Weight of grains per panicle.
Table 1Analysis of variance and repeatability of the characters of wheat mutant adaptive to tropical lowland.
Table 1
|
Character |
Location (E) |
Genotype (G) |
G × E |
CV |
Vg |
R |
|
PH |
2211.88**
|
64.97**
|
55.31**
|
8.63 |
0.02 |
14.86% |
|
NPT |
30.55*
|
5.97**
|
0.55ns |
20.05 |
0.37 |
89.38% |
|
DF |
181.52**
|
19.44*
|
31.12**
|
5.48 |
0.00 |
0.00% |
|
DH |
1886.16**
|
15.97**
|
17.84**
|
2.76 |
0.00 |
0.00% |
|
NS |
202.43**
|
7.0**
|
3.13**
|
7.95 |
0.09 |
55.41% |
|
PL |
46.12**
|
1.15**
|
0.55**
|
5.46 |
0.08 |
51.96% |
|
NGP |
778.65**
|
57.61**
|
45.56**
|
16.32 |
0.04 |
20.92% |
|
WPG |
1.821**
|
0.085**
|
0.032**
|
19.1 |
0.13 |
61.98% |
|
W100 |
0.28**
|
0.32**
|
0.23**
|
8.51 |
0.07 |
27.36% |
|
PUG |
411.84**
|
133.96**
|
175.34**
|
12.05 |
0.00 |
0.00% |
|
Yield |
7.49**
|
1.59**
|
0.19ns |
22.07 |
0.38 |
87.92% |
Table 2Analysis genetic correlation (above the diagonal line) and phenotypic correlation (below diagonal line) on the yield of wheat mutant adaptive to tropical lowland.
Table 2
|
Traits |
PH |
NPT |
DF |
DH |
NS |
PL |
NGP |
WGP |
W100 |
PUG |
Yield |
|
PH |
|
0.599 |
NA |
NA |
0.999 |
0.999 |
0.999 |
0.999 |
0.999 |
NA |
0.999**
|
|
NPT |
0.167 |
|
NA |
NA |
0.682 |
0.364 |
0.797 |
0.441 |
0.423 |
NA |
0.835**
|
|
DF |
‒0.508 |
0.019 |
|
NA |
NA |
NA |
NA |
NA |
NA |
NA |
NA |
|
DH |
0.057 |
‒0.380 |
‒0.287 |
|
NA |
NA |
NA |
NA |
NA |
NA |
NA |
|
NS |
0.606 |
0.443 |
‒0.315 |
‒0.379 |
|
0.822 |
1.000 |
1.000 |
1.000 |
NA |
0.999**
|
|
PL |
0.632 |
0.216 |
‒0.241 |
‒0.173 |
0.745 |
|
0.550 |
0.978 |
1.000 |
NA |
0.705**
|
|
NGP |
0.386 |
0.247 |
‒0.331 |
‒0.172 |
0.755 |
0.377 |
|
1.000 |
1.000 |
NA |
0.999**
|
|
WGP |
0.671 |
0.262 |
‒0.228 |
0.054 |
0.667 |
0.765 |
0.633 |
|
1.000 |
NA |
0.921**
|
|
W100 |
0.729 |
0.189 |
‒0.198 |
‒0.180 |
0.642 |
0.669 |
0.517 |
0.749 |
|
NA |
0.999**
|
|
PUG |
‒0.108 |
‒0.011 |
0.176 |
0.011 |
‒0.366 |
‒0.020 |
‒0.874 |
‒0.424 |
‒0.325 |
|
NA |
|
Yield |
0.503**
|
0.771**
|
‒0.137 |
‒0.413 |
0.831**
|
0.559**
|
0.674**
|
0.663**
|
0.645**
|
‒0.386 |
|
|
Difference |
0.497 |
0.065 |
|
|
0.169 |
0.146 |
0.326 |
0.258 |
0.355 |
|
|
Table 3Factor analysis of wheat mutant adaptive to tropical lowland character.
Table 3
|
Variable |
Factor1 |
Factor2 |
Factor3 |
Factor4 |
Communality |
|
PH |
0.218 |
0.14 |
‒0.017 |
‒0.233 |
0.774 |
|
NPT |
‒0.185 |
0.121 |
0.592 |
‒0.219 |
0.86 |
|
DF |
0.127 |
‒0.027 |
‒0.126 |
0.775 |
0.878 |
|
DH |
0.015 |
‒0.011 |
‒0.293 |
‒0.364 |
0.698 |
|
NS |
0.105 |
‒0.034 |
0.152 |
‒0.035 |
0.836 |
|
PL |
0.366 |
0.202 |
‒0.086 |
0.118 |
0.85 |
|
NGP |
‒0.067 |
‒0.43 |
0.011 |
‒0.03 |
0.976 |
|
WPG |
0.274 |
‒0.068 |
‒0.163 |
0.101 |
0.841 |
|
W100 |
0.326 |
0.001 |
‒0.167 |
0.203 |
0.805 |
|
PUG |
0.135 |
0.59 |
0.125 |
‒0.069 |
0.978 |
|
Yield |
0.002 |
‒0.043 |
0.321 |
‒0.035 |
0.946 |
|
Variance (Var) |
3.764 |
2.1886 |
2.177 |
1.3137 |
9.4433 |
|
% Var |
0.342 |
0.199 |
0.198 |
0.119 |
0.858 |
Table 4Path analysis on yield of wheat mutant adaptive to tropical lowland.
Table 4
|
Character |
Direct effect |
JAP |
JS |
JBM |
BBM |
B100 |
Residual |
|
NPT |
0.563 |
|
0.104 |
0.051 |
0.017 |
0.045 |
0.044 |
|
NS |
0.237 |
0.248 |
|
0.142 |
0.041 |
0.153 |
0.044 |
|
NGP |
0.189 |
0.152 |
0.178 |
|
0.039 |
0.122 |
0.044 |
|
WGP |
0.061 |
0.152 |
0.157 |
0.121 |
|
0.179 |
0.044 |
|
W100 |
0.239 |
0.107 |
0.152 |
0.096 |
0.046 |
|
0.044 |
Table 5Conformity value of secondary trait on the yield of wheat mutant adaptive to tropical lowland.
Table 5
|
Character |
R |
CA |
Dr |
PCA |
FcA |
PA |
Total |
Conformity |
|
Plant height |
5 |
3 |
5 |
3 |
5 |
5 |
26 |
16.67 |
|
Number of productive tillers |
1 |
1 |
1 |
3 |
1 |
1 |
8 |
91.67 |
|
Days to flowering |
5 |
5 |
5 |
5 |
5 |
5 |
30 |
0.00 |
|
Days to harvest |
5 |
5 |
5 |
5 |
5 |
5 |
30 |
0.00 |
|
Number of spikelet |
1 |
1 |
3 |
1 |
5 |
1 |
12 |
75.00 |
|
Panicle length |
1 |
1 |
3 |
1 |
3 |
5 |
14 |
66.67 |
|
Number of grains per panicle |
3 |
3 |
3 |
3 |
5 |
3 |
20 |
41.67 |
|
Weight of grains per panicle |
1 |
3 |
1 |
1 |
5 |
3 |
14 |
66.67 |
|
Weight of 100 grains |
3 |
3 |
1 |
1 |
3 |
1 |
12 |
75.00 |
|
Percentage of unfilled grains |
5 |
5 |
5 |
5 |
3 |
5 |
28 |
8.33 |
|
Max score |
5 |
5 |
5 |
5 |
5 |
5 |
30 |
|
|
Min Score |
1 |
1 |
1 |
1 |
1 |
1 |
6 |
|
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