Genetic Variability for the Yield and Yield-Related Traits in Some Maize ( Zea mays L.) Inbred Lines in the Central Highland of Ethiopia

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Introduction
Maize (Zea mays L.) is one of the most essential cereal crops grown worldwide, leading to the overall crop yield production (Gebre et al. [1]).According to Shaka et al. [2], maize comes in second place in terms of land area to wheat while taking the frst place in terms of output and productivity.After rice and wheat, it is the third most widely utilized cereal crop for human consumption (Mbuvi et al. [3]).According to [4], maize originated from South America and belongs to the grass family called Poaceae.With chromosomal number 2n � 20, it is the only species in the genus Zea.
Maize is a broadly cultivated crop throughout the world.According to the USDA [5], the annual production of maize for the top six countries of the world from 2019 to 2020 in terms of million metric tons were as follows: United States: 346.0, China: 260.8, Brazil: 102, Argentina: 51, Ukraine: 35.9, and India: 26, and account for 75.18% of the world's maize production.Ethiopia ranked 13 th in the world and 4 th in Africa by annual maize production.
According to Smale et al. [6], the most valuable cereal crop grown in Africa is maize.About 50% of the population relies on it as a staple food.It is a signifcant source of minerals, protein, carbohydrates, and vitamin B. African populations utilize maize in various forms such as porridge, beer, and pastes.Fresh green corn is consumed in the form of boiled and roasted.Te grain, tassel, stalk, cob, and leaves of the maize plant are all economically valuable and can be used to make a wide range of food and nonfood goods.
Based on the altitude and annual rainfall, Ethiopia's maize-growing regions are essentially divided into four ecological zones (Abera et al. [7]).Tese are the midaltitude subhumid zone (1000-1800 masl, with annual rainfall of 800-1500 mm), the highland subhumid zone (1800-2600 masl, with annual rainfall of 1000-2000 mm), the low moisture zone, which is between 500 and 1800 masl and receives less than 800 mm of rainfall, and the low altitude subhumid zone, which is below 1000 masl.
Maize is one of the most important cereal crops grown in Ethiopia.Among all the cereals crops, maize ranks frst in terms of overall production and second next to tef in terms of area coverage [8].It makes up roughly 24%-31% of the country's cereal consumption and is primarily supplied by Ethiopian local production.It is eaten as a staple in a variety of dishes, including as bread, injera (separately or combined with tef), porridge, "nefro.,"and grits.Moreover, it is eaten roasted or boiled (particularly when it is still green).Furthermore, it is brewed to create the native spirits "tella," "araki," and others [9].
According to Larik et al. [10], any breeding program must start with germplasm, which is a vital source of information since it allows for the development of genetic variability.Te true potential value of the genotype can be determined by investigating the genetic diversity, heritability, and genetic advance in the germplasm.In addition, understanding the relationships between the traits is crucial to the efectiveness of selection in any breeding program.
According to Hallauer et al. [11], the goal of maize breeding programs is always to increase genetic diversity in traits that are economically signifcant while maintaining a suitable level of genetic variability.It is crucial to understand the level of genetic variability already present in the germplasm for enhancing the genetic diversity of local germplasm.According to Ahmad et al. [12], an efcient long-term plant breeding program needs genetic diversity at a detectable level within a population to enable and support it.
According to Malik et al. [13], the most crucial agronomic characteristics of maize include grain yield, 1000 kernel weight, tassel branches, days to silking, plant height, days to tasseling, ear weight, ear height, leaf width, leaf length, leaf area, kernel rows, and kernel moisture.Te yield of grains is signifcantly infuenced by genotypes with desired characteristics.Te kernel set of maize, which is susceptible to environmental factors during the tasseling and silking stages, is closely associated with the grain production [14].
Te majority of local maize cultivars growing in the highland parts of Ethiopia are low-yielding variants.Our nation's maize breeding program struggles to produce highyielding hybrids and synthetic varieties for highlands because it lacks genetically varied source materials (Legesse et al. [15]).
However, not enough research has been done to fully understand and describe the extent and nature of genetic variability, phenotypic coefcient of variation, genotypic coefcient of variation, genetic advance, broad-sense heritability, and the relationship between the yield and traits that are related to the yield of maize inbred lines developed for central highland of Ethiopia.
Terefore, the purpose of the current study is to fnd out the nature and magnitude of the genetic variability of various traits of maize inbred lines.Te specifc objectives were to estimate the genetic variability, genetic advance, heritability, and phenotypic and genotypic coefcients of variation and assess the extent of association between the yield and yield-related traits of maize inbred lines.

Description of the Research Site.
Te experiment was carried out on the experimental feld of the Ambo Plant Protection Research Center (APPRC) from June 3 to December 30, 2013/14, during the major cropping season of Ethiopia in the West Shewa zone of Oromia Regional State.Te Ambo Plant Protection Research Center is situated 115 kilometers from Addis Ababa at an altitude of 2185 meters above the sea level, with coordinates of 8057′ N and 38007′ E. Te agroecology of APPRC is intermediate highland having the major soil type vertisols consisting of 1.5% organic matter, 18% silt, and 67% clay.Te pH of the soil is 6.12.Temperatures range from 10.13 °C to 27.63 °C, with an average annual rainfall of 1242.90 mm.

Experimental Materials.
Twenty-fve maize inbred lines, which have been maintained at the Ambo Plant Protection Research Center, were used for the study as indicated in Table 1.All the inbred lines were selected based on suitability to high land and picked based on the available amount of seeds.

Experimental Design and Trial Management.
Te study was conducted in a 5 × 5 triple lattice design with three replications.Te plot size was 3 m long and 1.5 m wide and consisted of two rows with 12 plants per row which comprised a total of 24 plants per plot.Te distances between the rows and the plants were 75 cm and 25 cm, respectively.An alley of 1.5 m was left between the plots.Te two rows were utilized to collect data.One row was sown around the experimental feld as a border to protect it from damage by unwanted animals or pests.DAP and urea were applied to the plots at rates of 150 and 200 kg ha −1 , respectively.Tree equal portions of nitrogen were applied.Te initial application was made during sowing together with the phosphorus dose.Te second and third nitrogen applications for maize were made at the knee-high stage and the third at the tasseling stage, respectively, during the growth stage.Two seeds were sown per hill and then seedlings were thinned to one plant at the 4-5 leaf stage to maintain 53, 333 plants/ha.Weeding was carried out in accordance with local 2 International Journal of Agronomy recommendations.Te experimental plants were protected from being damaged by pests using chemicals.

Data Collection.
With the exception of days to 50% tasseling and silking, fve plants were randomly selected to record observations of all the quantitative traits.For statistical analysis, the mean of fve plants for each entry in each replication was calculated.Te data recording for each quantitative trait were carried out at the diferent growth stages of the maize inbred lines as indicated in Supplementary Figures 1-5.

Quantitative Traits.
Quantitative traits were collected from days to 50 percent tasseling, a number of kernel rows per ear, days to 50 percent silking, the number of kernels per row, plant height (cm), the number of ears per plant thousand kernels weight (g), ear height (cm), grain yield per plant (g), number of leaves per plant, grain yield per hectare (kg), leaf length (cm), aboveground biomass yield per plant (g), leaf width (cm), harvest index (%), ear length (cm), a number of tassel branches, and ear diameter (cm).

Analysis of Variance.
All of the traits were subjected to analysis of variance using the procedure developed by [16] which is indicated in Table 2 by using the SAS GLM procedure, 2004, V.9.0 [17] and SPSS software.Diferences for mean separations of various traits were computed using least signifcance diferences (LSD) at 0.05 and 0.01 of probability.Te genotypic and phenotypic components and coefcients of genotypic and phenotypic variation were computed using the formula developed by the authors in [18].
Environmental variance (σ2f) � mean error square, where Mse � environmental variance, Msg � mean square due to the genotype, and r � the number of replication.
Te values of GCV and PCV were classifed as low, moderate, and high [19] as follows.

Heritability (H 2
).According to Hanson et al. [20], the ratio of genotypic variance to phenotypic variance, presented as a percentage, was used to measure heritability in a broad sense.
where Vg � genotypic variance and Vp � phenotypic variance.

Genetic Advance.
According to Robinson et al. [21], the following formula was used to determine the amount of genetic advance that may be predicted by choosing 5% of the superior ofspring. GA where GA � genetic advance and x � general mean of the trait.According to Johnson et al. [22], the genetic advance as a percent of the mean was grouped as high, moderate, and low as follows.

Association of Traits and Path Coefcient Analysis
2.8.1.Coefcient of Correlation (r).Phenotypic correlations were calculated by using the formula given by the authors in [23].
where Covxyp � phenotypic covariance between the traits x and y, Varxp and Varyp � phenotypic variance of the traits x and y, respectively, and rp � phenotypic correlation.rg � Covxyg/(Varxg × Varyg)1/2, where r g � genotypic correlation, Covxy g � genotypic covariance between the traits x and y, and Varx g and Vary g � genotypic variance of the traits x and y, respectively.

Path Coefcient Analysis.
Path analysis is a straightforward standardized partial regression coefcient that divides the correlation coefcient into the direct and indirect efects of the yield components on yield using the formula given in [24].
where Pij is a component of a direct efect of the independent variable (j) as measured by the phenotypic and genotypic path coefcients. r ik p ik is the summation of components of the indirect efect of a given independent variable (i) on a given dependent variable (j) through all the other independent variables.
r ij is an association between independent variables (i) and dependent variable j as measured by phenotypic and genotypic correlation coefcients.

Range and Mean
Values.Te range and mean values of the diferent traits are indicated in Table 3 and shown as follows.
Among the genotypes, the range of days to tasseling signifcantly varied from 91.49 to 114.51 with a mean of 103.55.Te inbred lines AMH169-22, AMH169-87, and AMH169-98 took the longest days to tasseling of 114.51, 109.18, and 109.18,respectively, after sowing.Te inbred lines AMH169-5 and AMH169-8 took the shortest days to tasseling of 91.49 and 91.8 days, respectively.Days to silking difered signifcantly among genotypes, with a mean of 105.99 and a range of 89.61-113.89.Te inbred lines AMH169-22 and AMH169-87 took the longest days to silking of 113.89 and 112.69 days after sowing, respectively.Sixty-eight percent of the genotypes under the study took a relatively long time for both tasseling and silking.
Signifcant variations in genotypes were detected for plant height, which ranged from 111.45 cm for AMH169-12 to 200.86 cm for AMH169-22, with an overall mean of 145.17.Ear height ranged from 44.06 to 118.64 cm for AMH169-12 and AMH169-22, respectively, with a mean of 67.29 cm.
Te recorded range for number of leaves per plant is 11.2-16.73,with a mean of 14.42.Te inbred lines AMH169-115 and AMH169-28 had the highest and least number of leaves per plant, respectively.Te leaf length ranged from 54.99 to 83.05 cm with an average of 67.83, demonstrating wide variation among the genotypes for this trait.Te inbred lines AMH169-81 and AMH169-33 had the longest and shortest leaf length, respectively.Leaf width varied from 8.35 to 11.27 cm, with an overall mean of 9.61.Te inbred lines AMH169-87 and AMH169-75 had the largest and smallest leaf width, respectively.
Te average value of the number of tassel branches per plant varied from 6.84 to 23.04 with an overall mean of 14.79.Te inbred lines AMH169-22 and AMH169-8 had the largest and smallest number of tassel branches per plant, showing the presence of signifcant diferences among the genotype.
Ear length varied from 8.25 to 15.1 cm, with a total mean of 11.59.Te inbred line AMH169-28 had the highest ear length which is superior among all the genotypes while the inbred line AMH169-114 is the least of all genotypes.Ear diameter varied among the genotypes from 3.29 to 4.6 cm, with an overall mean of 3.83.Te inbred lines AMB169-86 and AMB169-1 had maximum and minimum ear diameters, respectively, as shown in Table 3.
Te number of kernel rows per ear varies from 10.67 to 13.78, with an overall mean of 12.22.Te inbred lines AMH169-33 and AMH169-55 had the maximum and minimum values of the number of kernel rows per ear among the tested genotypes of the maize inbred line.Te number of kernels per row signifcantly ranged from 15.76 to 31.86, with an overall mean of 22.92.Te inbred line AMH169-28 had a maximum number of kernels per row (31.86), followed by AMH169-51 (29.11)Te mean grain yield per plant ranged signifcantly from 47.37 to 111.78 g, with a mean of 75.48 g.Te inbred line AMH169-55 showed the highest grain yield per plant (111.78g), followed by AMH169-87 (110.76),AMH169-51 (92.43), and AMH169-114 (91.47) while the inbred lines AMH169-116 (47.37),AMH169-33 (49.48), and AMH169-54 (54.78) showed poor performance for the grain yield per plant.
Te data recorded for grain yield per hectare showed signifcant diferences among the studied genotypes with a variation of range from 824.15 to 3384.52 kg, with a mean of 2137.57kg.According to the mean values, the inbred line AMH169-55 showed the highest performance for the grain yield per hectare (3384.52 kg) followed by AMH169-86 (3150.6),AMH169-81 (2999.92),AMH169-50 (2986.22),and AMH169-56 (2914.33)while the inbred lines AMH169-1 and AMH169-116 showed the least performance for the grain yield per hectare.
Te mean aboveground biomass yield per plant ranged signifcantly from 414.94 to 893.82 g, with a mean of 657.98 g.Te maximum value for aboveground biomass yield per plant was shown by the inbred line AMH169-87 (893.82 g), while the minimum value was recorded in the inbred line AMH169-33 (414.94 g).Te harvest index signifcantly ranged from 13.39 to 36.78, with a mean of 24.94.According to the mean values, the inbred line AMH169-55 showed the highest harvest index followed by AMH169-56 (31.46),AMH169-28 (29.66), and AMH169-86 (28.63) while the inbred lines AMH169-22 (13.39) and AMH169-116 (17.75) had the lowest harvest index.

Analysis of Variance.
Te mean square from the analysis of the variance of grain yield and other related traits in 25 inbred lines of maize is presented in Table 4.
Te analysis of variance showed that genotypic mean squares were highly signifcant (p ≤ 0.01) for days to 50% tasseling, days to 50% silking, plant height, ear height, number of leaves per plant, leaf length, leaf width, number of tassel branches, ear length, number of kernel rows per ear, number of kernels per row, thousand kernels weight, grain yield per plant, grain yield per hectare, aboveground biomass yield per plant, and harvest index and signifcant (p ≤ 0.05) for ear diameter and number of ears per plant.5 showed that there was sufcient genetic variability in most of the traits.For example, the GCV indicated a wide range of variation from 4.52 to 28.49% while the PCV ranged from 4.86 to 35.43% for the diferent traits studied.Te maximum coefcient of genotypic and phenotypic variation was recorded in the grain yield per hectare (28.49 and 35.43) followed by the number of tassel branches (23.14 and 24.92)In the present study, moderate PCV and GCV were observed in thousand kernel weights (16.37 and 19.54), ear height (18.17 and 15.55), and plant height (10.91 and 12.08), respectively.Te smallest PCV and GCV were found in days to 50% of tasseling (4.86 and 4.52) and days to 50% of silking (5.63 and 5.39), respectively.

Heritability and Genetic
Advance.Various plant traits under investigation were shown to have low, medium, and high broad-sense heritability estimates, as indicated in Table 6.High magnitude of broad-sense heritability was   (28.25) and the number of ears per plant (25.45).
Te highest genetic advance was observed in the grain yield per hectare (59.66) followed by the aboveground biomass yield per plant (83.8) and thousand kernels weight (35.31) showing additive gene efects.
High, moderate, and low estimates of genetic advance as a percent of the mean were detected in diferent plant traits under study in Table 6.For grain yield per hectare (28.05), a high genetic advance as a percent of the mean was observed.Grain yield per plant (18.95), number of tassel branches (16.43), ear height (16.38), harvest index (16.33),number of kernels per row (16.31), thousand kernel weight (15.42), ear length (14.18), aboveground biomass per plant (12.72), and number of ears per plant (10.79) all showed moderate genetic advance as a percent of the mean.

Phenotypic and Genotypic Correlations of the Grain Yield
with Other Traits.Te phenotypic and genotypic coefcients among various traits are given in Tables 7 and 8, respectively.
At both the phenotypic and genotypic levels, there was a strong and positive correlation of the grain yield with the number of kernels per row (rp � 0.386 * * and rg � 0.462 * ), the number of ears per plant (rp � 0.438 * * and rg � 0.435 * ), and grain yield per hectare (rp � 0.698 and rg � 0.787), respectively.Ear length (rp � 0.314 * * ) and number of tassel branches (rp � 0.280 * ) showed a positive and signifcant correlation with the grain yield per plant at the phenotypic level.
At both the phenotypic and genotypic levels, there was no signifcant correlation between grain yield per plant and days to 50% silking and tasseling, number of leaves per plant, plant and ear height, number of rows of kernels per ear, ear diameter, and weight of 1,000 kernels per ear.
Te phenotypic and genotypic correlation analysis revealed that the yield per plant had signifcant positive correlation with the grain yield per hectare (rp � 0.698 * * and rg � 0.787 * * ), number of ears per plant (rp � 0.438 * and rg � 0.435 * ), and number of kernels per row (rp � 0.386 * * and rg � 0.462 * ) at both phenotypic and positive genotypic correlations, respectively.

Path Analysis of the Grain Yield and Other Traits.
Table 9 presents the path coefcient analysis that demonstrates the direct and indirect efects on grain production per plant at the phenotypic level in the maize inbred line.International Journal of Agronomy GYPP 1 * and * * signifcant and highly signifcant at 5% and 1%, respectively.Note.DT �days to 50% tasseling, DS � days to 50% silking, PH � plant height (cm), EH � ear height (cm), NLPP � number of leaves per plant, LL � leaf length (cm), LW � leaf width, NTB � number of tassel branches, El � ear length (cm), ED � ear diameter (cm), NKRPE � number of kernel rows per ear, NKPR � number of kernel per row, NEPP � number of ear per plant, TKW � thousand kernel weight (g), GYPP � grain yield per plant (g), GYPH � grain yield per hectare (kg), AGBYPP � aboveground biomass yield per plant (g), HI � harvest index, and S/N � serial number.Te grain yield is primarily controlled by an independent variable's direct efects and its indirect efects through other yield components.In the current study, the path analysis only included 9 out of the 17 traits at the phenotypic level and 5 out of the 17 at the genotypic level that had a direct association with the grain yield per plant.Te grain yield per plant is used as a dependent variable to divide the phenotypic and genotypic correlations into direct and indirect efects.
According to the path coefcient analysis at the phenotypic level, the number of kernels per row (1.0570) had the highest positive direct efect on the grain yield, followed by grain yield per hectare (0.0900) and the number of tassel branches (0.0050).However, the traits such as ear length (−0.8180) and number of ears per plant (−0.057) had a negative direct efect on the grain yield per plant.
Te negative direct efect of the number of ears per plant on grain yield per plant was counterbalanced by its indirect efect via the number of kernels per row, which fnally resulted in a positive and highly signifcant phenotypic correlation with the grain yield per plant.
Table 10 presents the path coefcient analysis for maize inbred lines, which illustrates the direct and indirect efects on the grain yield per plant at the genotypic level.
Te number of kernels per row (0.8250) and number of ears per plant (0.1280) were found to have the strongest direct positive efects on the grain yield at the genotypic level according to the path coefcient analysis but the grain yield per hectare (−0.1160) had a negative direct efect on the grain yield per plant.However, the number of kernels per row had a positive and highly signifcant phenotypic correlation with the grain yield per plant, balancing out the direct efect of the grain yield per hectare on the grain yield per plant that was negative.

Discussion
Days to tasseling, plant height, leaf length, days to silking, number of leaves per plant, number of tassel branches per plant, leaf width, ear diameter, ear length, number of ears per plant, number of kernel rows per ear, weight of thousand kernels, grain yield per hectare, and grain yield per plant all difered signifcantly between the inbred line genotypes.Tis suggests that there is a lot of genetic variation among the genotypes for the improvement of these traits.Te fndings of the current study are consistent with the fndings reported by Tadesse et al. [25] and Gebre et al. [1].
Te results of the analysis of variance revealed that genotypic mean squares were highly signifcant for each of  International Journal of Agronomy the traits under study, showing that the inbred lines had a higher level of genetic diversity.Similar fndings were reported by Bartaula et al. [26], Mahmood et al. [27], Prakash et al. [28], and Kumsa et al. [29] for plant height, days to 50% tasseling, number of kernel per row, days to 50% silking, thousand kernel weight, ear height, and grain yield per plant; Kumar et al. [30] for the ear diameter, number of tassel branches, and ear length; and the author in [31] for the grain yield per hectare.Te reasonable coefcient of variation for each trait under study demonstrated the experiment's high level of precision.
Te highest results of PCV and GCV obtained in the number of tassel branches and grain yield per hectare reveal that there is sufcient variation for the traits in the available material and suggest that selection can be successful for these traits.Te present results correspond with results reported by Shakoor et al. [39], Rafq et al. [34] for the number of kernels per row, Kabdal et al. [40] for grain yield per plant, Hepziba et al. [36] for ear height, Tadesse et al. [25] for the grain yield, ear height, ear diameter, and 1000 kernel weight, Prakash et al. [28] for traits such as grain yield per plant, ear height, number of tassel per branches, and the number of kernel per row, and the authors in [38] for the grain yield per plant.
Te thousand kernel weights, ear heights, and plant heights in the current study all showed moderate GCV and PCV values.Te fndings of the present study are consistent with fndings from several studies on the variability of maize by the author in [33], Kumar et al. [41], and Prakash et al. [28].
In days to 50% of silking and days to 50% of tasseling, the lowest GCV and PCV were recorded.Tis fnding indicated that genotypes' genetic diversity for these traits was extremely low and that these genotypes should be eliminated from breeding programs.Te fndings obtained in the present study correspond with results reported by the authors in [31,33], Bello et al. [35], and [38] in the maize genetic diversity.
Te presence of high heritability values in the traits demonstrates that genetics mostly governed the variation seen and that environmental factors had a little efect.Tis suggested that these traits might be genetically improved through efcient selection.A similar fnding was reported by Begum et al. [37], Tadesse et al. [25] for ear length, plant height, and 1000 kernel weight [33], Prakash et al. [28] for the number of tassel branches, days to 50% silking, and the number of kernel per row, and the authors in [38] for the grain yield per plant.
Te grain yield per hectare and thousand kernel weight have strong heritability and reasonably high genetic advance, demonstrating that these traits are regulated by additive gene action and that phenotypic selection for these traits will be successful for maize improvement.For 1000grain weight, similar fndings were recorded by Begum et al. [37] and Tadesse et al. [25].
Te grain yield per hectare, the number of kernels per row, and the number of tassel branches all had high phenotypic and genotypic coefcients of variation, high heritability, and moderate genetic advance as a percentage of the mean.Similar observations were reported by Prakash et al. [28] for the number of tassel branches and the number of kernels per row.Tis demonstrates that these parameters were governed by additive gene efects and that these traits might be improved through efcient selection.
Te complicated trait of the yield is discovered as being quantitatively inherited.Tus, its efcient improvement could be achieved only through improving the associated traits.Consequently, a very signifcant positive correlation among yield attributes suggests that an increase in one trait will result in an increase in the linked trait, which would then result in an increase in the yield (Hepziba et al. [36]).
At the phenotypic and genotypic levels, there was a strong and positive association between grain yield and the number of ears per plant, ear length, and number of kernels per row.Tis suggests that traits that boost grain production in maize will be chosen for future maize breeding eforts.Similar fndings were reported by Hepziba et al. [36] for plant height, days to silking, and 50% tasseling; the author in [31] for days to silking and 50% tasseling, and ear and plant height; Ojo et al. [42]; Wannows et al. [43] for the number of kernels rows per ear, ear diameter, and plant and ear height; Golam et al. [44] for thousand kernels weight and days to 50% tasseling and silking; Prakash et al. [28] for ear diameter, number of kernels rows per ear, plant, ear height, 0.5820 * * * and * * Signifcant and highly signifcant at 5% and 1%, respectively.Note.NKPR � number of kernels per row, NEPP � number of ears per plant, TKW � thousand kernel weight (g), GYPP � grain yield per plant (g), GYPH � grain yield per hectare (kg), AGBYPP � aboveground biomass yield per plant (g), HI � harvest index, and S/N � serial number.Bold values represents the direct efects of diferent traits on the grain yields.10 International Journal of Agronomy and thousand kernels weight; Bartaula et al. [26] for the number of kernels rows per ear, grain yield, and ear diameter; and Abera et al. [7] for the number of kernels rows per ear, plant height, and thousand kernels weight.Te number of kernels per row and the number of kernel rows per ear signifcantly correlated negatively with thousand kernel weight at phenotypic and genotypic levels.Malik et al. [13] and Nastasić et al. [45] reported similar fndings in their maize study.
Te phenotypic and genotypic path coefcient analysis showed that parameters including the grain yield per hectare and number of kernels per row may be utilized as selection criteria to increase maize grain yield.Kumar et al. [41], Hepziba et al. [36], and Prakash et al. [28] for the number of kernels per row and Begum et al. [37] for kernel per row reported fndings that were similar.

Conclusions
Te results of the analysis of variance revealed that genotypic mean squares were signifcant for all traits, demonstrating that the inbred lines under study exhibited a higher level of genetic diversity.Te grain yield per hectare and the number of tassel branches exhibited the highest coefcients of genotypic and phenotypic variation.Tese GCV and PCV estimations imply that selection can be successful for these traits.
Te number of tassel branches, leaf length, number of leaves per plant, ear length, plant height, thousand kernels weight, leaf width, number of kernels per row, days to 50% silking, ear height, days to 50% tasseling, and grain yield per hectare were all estimated to have high magnitudes of broadsense heredity.Te values for these traits show that the variance was mostly under genetic control and was less afected by the environment.Tis suggested that these traits might be genetically improved efcient selection.
AMH169-55 and AMH169-86, two inbred lines, were discovered to be superior in terms of the grain yield as well as in other crucial yield components.Terefore, it is advised that these lines be applied to the maize crop in order to improve it further.
Furthermore, we recommend studying the genetic diversity of these 25 maize inbred lines using DNA-based molecular markers to identify the genetic diversity among and within maize populations.

Table 2 :
Analysis of variance.

Table 1 :
Maize inbred line samples used for the study.

Table 3 :
Maize inbred lines exhibiting minimum and maximum values for the traits evaluated with the means and standard deviations.

Table 6 :
Estimate of heritability (H 2 ), genetic advance, and genetic advance percent of the mean for grain yield and other related traits among 25 inbred lines of maize at APPRC.Note.H 2 � heritability, GA � genetic advance, GA% � genetic advance as a percent of the mean, and S/N � serial number.Plant height (8.72), leaf length (7.16), leaf width (7.07), number of kernel rows per ear (6.61), number of leaves per plant (6.02), ear diameter (5.99), days to 50% silking (3.09), and days to 50% tasseling (3.17) all showed low genetic advance as a percent of the mean.

Table 7 :
Analysis of the phenotypic correlation for the maize grain yield and other agronomic traits.

Table 8 :
Analysis of the genotypic correlation for maize grain yield and other agronomic traits.

Table 9 :
Path coefcient analysis showing direct (diagonal bold) and indirect (of-diagonal) efects on the grain yield per plant at the phenotypic level in maize inbred lines.and * * � signifcant and highly signifcant at 5% and 1%, respectively.Note.LL � leaf length (cm), LW � leaf width, NTB � number of tassel branches, El � ear length (cm), NKPR � number of kernel per row, NEPP � number of ears per plant, GYPP � grain yield per plant (g), GYPH � grain yield per hectare (kg), AGBYPP � aboveground biomass yield per plant (g), HI � harvest index, and S/N � serial number.Bold values represents the direct efects of diferent traits on the grain yield per plant. *

Table 10 :
Path coefcient analysis showing direct (diagonal bold) and indirect (of diagonal) efects of diferent traits on the grain yield per plant in maize inbred lines at the genotypic level.