Dersleri yüzünden oldukça stresli bir ruh haline sikiş hikayeleri bürünüp özel matematik dersinden önce rahatlayabilmek için amatör pornolar kendisini yatak odasına kapatan genç adam telefonundan porno resimleri açtığı porno filmini keyifle seyir ederek yatağını mobil porno okşar ruh dinlendirici olduğunu iddia ettikleri özel sex resim bir masaj salonunda çalışan genç masör hem sağlık hem de huzur sikiş için gelip masaj yaptıracak olan kadını gördüğünde porn nutku tutulur tüm gün boyu seksi lezbiyenleri sikiş dikizleyerek onları en savunmasız anlarında fotoğraflayan azılı erkek lavaboya geçerek fotoğraflara bakıp koca yarağını keyifle okşamaya başlar
Reach Us +443308186230

GET THE APP
Advances in Crop Science and Technology - Influence of Harvesting Age and Genotype on Growth Parameters and Herbage Yield of Sweet Basil (Ocimum basilicum L.) at Wondo Genet, Southern Ethiopia
ISSN: 2329-8863

Advances in Crop Science and Technology
Open Access

Our Group organises 3000+ Global Conferenceseries Events every year across USA, Europe & Asia with support from 1000 more scientific Societies and Publishes 700+ Open Access Journals which contains over 50000 eminent personalities, reputed scientists as editorial board members.

Open Access Journals gaining more Readers and Citations
700 Journals and 15,000,000 Readers Each Journal is getting 25,000+ Readers

This Readership is 10 times more when compared to other Subscription Journals (Source: Google Analytics)

Influence of Harvesting Age and Genotype on Growth Parameters and Herbage Yield of Sweet Basil (Ocimum basilicum L.) at Wondo Genet, Southern Ethiopia

Damtew Abewoy1*, Derbew Belew2 and Zewdinesh Damtew Zigene1
1Ethiopian Institute of Agricultural Research, Wondo Genet Agricultural Research Center, Ethiopia
2Department of Plant Sciences and Horticulture, College of Agriculture, Jimma University, Ethiopia
*Corresponding Author: Damtew Abewoy, Ethiopian Institute of Agricultural Research, Wondo Genet Agricultural Research Center, Ethiopia, Tel: +251921582397, Email: damtewabewoy@gmail.com

Received: 22-Sep-2018 / Accepted Date: 29-Nov-2018 / Published Date: 07-Dec-2018 DOI: 10.4172/2329-8863.1000407

Abstract

The field experiment was carried out at Wondo Genet Agricultural Research Center (WGARC) in 2017 under irrigation condition to determine the effects of genotypes and harvesting ages on herbage yield of sweet basil. The experiment consisted of four harvesting ages (40, 60, 80 and 100 days after transplanting (DAT)) and three genotypes (B01, B04, and B05). A 3 × 4 factorial experiment arranged in randomized complete block design (RCBD) with three replications was used. The analysis of variance revealed that the interaction effect of genotype and harvesting age was not significant for plant height, primary and secondary branches of sweet basil. However, all other tested parameters were significantly affected by the interaction of genotype and harvesting ages. The highest leaf area and leaf weight/plant were obtained from genotype B01 harvested at 80 DAT. The maximum aboveground biomass was recorded from genotype B04 harvested at 100 DAT. Genotype B01 harvested at 80 DAT produced the highest fresh herbage yield/ha (16.00 t/ha), which however, was not statistically different from genotype B04 harvested at 100 DAT. On the other hand, the highest dry herbage yield (3.10 t/ha) was produced from genotype B04 harvested at 100 DAT followed by genotype B01 harvested at 80 DAT (2.78 t/ha) and 100 DAT (2.72 t/ha). Therefore, genotype B04 harvested at 100 DAT can be recommended for maximum herbage yield of basil at Wondo Genet area. Since the present experiment was conducted under irrigation condition, further study is suggested to assess the effect of season on herbage yield of this plant under Wondo Genet condition.

View PDF Download PDF Supplementary File

Keywords: Essential oil content; Genetic variation; Herbage; Maturity; Plant age

Introduction

Sweet basil or common basil (Ocimum basilicum L.) is an annual herbaceous aromatic, spice and medicinal plant belonging to the Lamiaceae family [1]. The name basil is derived from the Greek word basileus which means "king” [2]. Basil consists of more than 150 species distributed in the tropics and subtropics of the world. The most widely cultivated species in the world are O. basilicum , O. gratissimum , O. xcitriodorum , O. americanum L., O. minimo L., and O. tenuiflorum L. They are grown widely throughout temperate and tropical regions of the world for their essential oil product [3]. Sweet basil (O. basilicum L. ) is most widely used due to its high economical value, popularity and demands among the economically important species of basil [4]. Basil originated from tropical and warm areas, such as India, Africa and southern Asia [5] and widely cultivated in India, Iran, Japan, China and Turkey.

Sweet basil is known by different names depending on the location. In the English language, it is called basil, common basil or sweet basil. In India, specifically in Hindi and Bengali, it is called babui tulsi. Other common names of basil are basilica (in French), basilikum or basilienkraut (in German), basilico (in Italian), and albahaca (in Spanish). In Arabic, it is known as hebak as well as rihan. In Ethiopia, different ethtnic group has different names for sweet basil. For instance, it is locally known as besobila in Amharic, Sikakibe or Duguno in Afan oromo, seseg in Tigrigna, Gimenja in Hadiya, qantalama in sidamigna, Kepowa in Wolayita [6]. There are more than 160 named cultivars of basil in existence today. Popular examples include O. basilicum ‘Cinnamon’, O. basilicum ‘Dark Opal’ and holy basil (the species O. tenuiflorum L., previously known as O. sanctum L.). Scents and flavors can range from cinnamon, liquorice and lemon to anise. Probably the most familiar basil is sweet basil (O. basilicum ); however, this has a large number of cultivars, varying in flavour, scent and uses. Most of the regular varieties of basil are considered as annuals; however, in warm tropical regions many perennial varieties exist, e.g., O. tenuiflorum [4,7]. Their wide range of forms, colors and sizes have elevated the ornamental importance of basil and have increased the economic value globally [8].

Basil is used in food, perfumery and pharmaceutical industries. Jansen [9] explained that both dried and fresh inflorescences and leaves of basil are used as flavoring agent in the preparation of all kinds of wät. Dried ground basil is also used to flavor butter and is sometimes sprinkled in tea or coffee to add flavor. Farrell [10] also wrote that the herb complements meat, vegetables, cheese, and egg dishes. Etana [11] and Mesfin et al. [12] also noted the spice use of O. basilicum .

Yield of Ocimum species were influenced by interaction between the genotype and environment, method of distillation, kind of storage, crop age, spacing, diseases and insects, time of harvest and season [5,13-15]. Among the various factors, which affect the production of this plant, harvesting age is important. Yield of fresh and dried herbage yields were strongly dependent on developmental stage of the plant (ontogeny), and therefore harvesting age is one of the most important factors influencing basil oil [5]. Therefore, the extraction of essential oil at an appropriate age of plant makes it possible to obtain the highest herbage yield of sweet basil.

Farmers of Ethiopia conventionally cultivate and use sweet basil for house consumption and provide for local market. Demand of basil for international market is high due to its multipurpose nature, and is being exported to different countries to fetch foreign currency. According to Yimer [16], export of sweet basil herb is mainly destined to Sudan with 91.4% share of total export value of basil herb from Ethiopia, and the rest of export goes to Israel (7.4%) and USA (1.2%). Ethiopia earned a total of 60,162.20 US dollar total income from export of sweet basil herb in 2010 year. Even though research undertaking on basil in Ethiopia is very minimal, so far, preliminary and national variety trials of basil were done at Wondo Genet Agricultural Research Center (WARC) and promising genotypes have been identified. Moreover, a research on those identified sweet basil genotype with different plant spacing was done by Alemu [17]. However, little research has been conducted to determine at what age the herbage should be harvested or the age at which the plant can produce the highest herbage yield [18-22]. Thus, it is necessary to identify the right harvesting age that could give maximum herbage yield of this economically important plant. Therefore, this study was undertaken with the following objectives:

General objective

To examine the effects of genotypes and harvesting ages on herbage yield of sweet basil at Wondo Genet condition.

Specific objectives

To determine optimum harvesting age for maximum herbage yield of selected genotypes of sweet basil.

To determine a possible interaction effect of harvesting age and genotype on herbage yield of sweet basil.

Materials And Methods

Description of the experimental site

Field experiment was conducted at Wondo Genet Agricultural Research Center (WGARC) in 2017 under irrigation condition. The center is situated at about 264 km south of the capital, Addis Ababa. Geographically it is located at 07°19' North latitude, 38°38' East longitude and an altitude of 1876 m.a.s.l. According to the records from 1997 to 2017, the site receives mean annual rainfall of 1182 mm with an average minimum and maximum temperature of 9.86 and 28.28°C, respectively. The soil textural class of the experimental area is sandy clay loam (Nitosol) with pH of 6.4 [23].

Treatments and experimental design

The experiment consisted of four levels of harvesting ages (40, 60, 80 and 100 days after transplanting (DAT)) with three genotypes (B01, B04, and B05). A 3 × 4 factorial experiment was laid out in randomized complete block design (RCBD) with three replications. Thus, there were 12 treatment combinations in triplicates as shown in the Appendix Table 1. The treatments were randomly allotted to each plot. The experimental plot had an area of 7.2 m2 (3 m width × 2.4 m length). The space between replications and plots was 1 m. The seedlings were planted at spacing of 60 cm and 40 cm between rows and plants respectively. Plants in the three middle rows out of the five rows per plot constituted the net plot used as the sampling unit. Randomly five plants from the middle rows were taken for sampling and data collection.

Cultural practices

Two-month old fresh soft-wood cuttings, having 10-15 cm length, were taken from the top parts of disease-free plants. The cuttings were planted in 10 cm polyethylene bags filled with fine mixtures of top soil, sand and compost (3:1:2 ratio), respectively at the nursery site of WGARC. The rooted cuttings were allowed to grow at the nursery for about 30 days. The experimental field was ploughed and harrowed to provide a fine and pulverized soil. Then, uniformly grown rooted cuttings were selected, hardened and transplanted to the experimental field at a spacing of 60 cm × 40 cm between rows and plants respectively. All appropriate agronomic practices such as weeding, watering and hoeing were applied uniformly both at the nursery and experimental field.

Data collected

Growth parameters: The following growth parameters were collected from five randomly sampled plants of each plot at the respective harvesting ages (40, 60, 80 and 100 DAT).

Plant height (cm) : Plant height was measured from the base of the plant to tip of the main stem and was expressed in centimeter. It was taken from five randomly sampled plants using a ruler and the sum total divided by number of sampled plants was made to get mean plant height per plant. The mean value was used for data analysis.

Number of primary branches per plant: Primary branches are emerged from the main stem of sampled plants. The sum of primary branch number of all sampled plants was divided by the number of sampled plants to work out the mean of primary branches per plant, which was used for data analysis.

Number of secondary branches: Secondary branches emerged from primary branches, were counted from the middle two rows of five plants. The mean values were taken as the representative of the plot, and were used for data analysis.

Leaf area per plant (cm2) : Leaf area per plant (cm2) was measured according to Bazaz et al. model:

LA=0.209(L2+W2)+0.25

Where, LA=Leaf area; L=Leaf length from the tip of the leaf to petiole attachment; W=Leaf width from the widest lamina or middle part of the leaf 0.209 and 0.25 are fitted coefficient and constant.

Hence, three leaves taken from the top, middle and bottom of five plants from the middle three rows were selected and length (from the tip of leaf to petiole attached) and width (from the widest part) were measured and expressed in centimeter. Therefore, the average leaf area of each plant from the plot, was multiplied by the average leaf number of each plant and mean value was calculated.

Yield and yield component parameters:

Fresh leaf weight/plant (g): The average fresh leaf weight of the randomly sampled plants was immediately recorded after the leaves were separated from stem. All leaves and top tender parts of the plants were weighed by using sensitive balance (Model No. yt-1002 and reading scale 0.01).

Dry leaf weight/plant (g):Leaf dry weights per plant was estimated by taking 100 g of leaf and top tender parts of the plants from each sampled plant and were dried in hot oven at 100°c for 24 hours until constant weight was reached. Then, dried sample was weighed by sensitive balance (Model No. yt-1002 and reading scale 0.01). Finally, the sum of dry leaf weight of sampled plant was divided by the number of sampled plants to work out the mean; and was expressed in gram per plant.

Fresh aboveground biomass (t/ha): All plants in the central three rows of each plot were harvested and weighed by sensitive balance (Model No. yt-1002 and reading scale 0.01). Then fresh aboveground biomass per net plot was estimated, and converted to ton per hectare.

Dry aboveground biomass (t/ha): All plants in the central three rows of each plot were harvested and drying of harvested biomass was made in the hot oven. Then, dry aboveground biomass was weighed by sensitive balance using (Model No. yt-1002 and reading scale 0.01). Finally, dry aboveground biomass per hectare was determined, and converted to ton per hectare.

Fresh herbage yield (t/ha): All plants in the central rows of each plot were harvested and fresh herbage yield per net plot was weighed using sensitive balance model no. yt-1002 and reading scale 0.01, and it was converted to ton per hectare.

Dry herbage yield (t/ha): All plants in the central rows of each plot were harvested and dry herbage yield per plot was estimated by taking composite sample of leaves and dried in oven. Then dry herbage yield per hectare was estimated using the following formula and expressed as ton per hectare.

Yield per hectare (t)=[Dry yield per net plot (kg) × 10,000 (m2)/Net area of the plot (m2)] × 1000

Data analysis: The data collected for parameters studied were subjected to analysis of variance (ANOVA) for RCBD and mean separation procedure was also undertaken. The ANOVA model used for the analysis was:

Yikj=μ+Gi+HAj+(GHA)ij+Rk+εijk

Where, Yikj=the mean value of the response variable of the ith genotype at the jth harvesting ages in kth blocks, μ=the overall mean, Gi=effect of genotypes, HAj=effect of harvesting ages, (GHA)ij=interaction effect of genotypes and harvesting ages, Rk=effect of block and εijk is a random error term due to those uncontrolled factors. After fitting analysis of variance (ANOVA) model for those significant interactions or main effects a mean separation procedure using LSD (Least significance difference) mean methods were done at required levels of probability (5%). Simple correlation analysis between different characters was also computed to observe associations between characters. All the statistical analysis was carried out using Statistical Analysis System (SAS) version 9.3 (SAS, 2012).

Results And Discussion

Growth parameters of sweet basil

Plant height: The difference in plant height at different treatment combination of genotypes and harvesting ages were not significant (p=0.19) (Appendix Table 2). However, genotypes exerted significant (p=0.0001) effect on plant height. The tallest plant height (46.84 cm) was recorded from sweet basil genotype B01, followed by genotypes B04 (40.92 cm) and B05 (39.32 cm), both of which were statistically on par (Table 1). The difference in plant height might be due to the presence of genetic variation among tested genotypes having different growth habit. The present study is in line with the work of Runyoro et al. [24], Svecova and Neugebauerova [8], and Fikadu et al. [25] who reported significant variations among different genotypes of basil with regard to plant height and other morphological characteristics. Similarly, Patel et al. [26] and Saran et al. [27] have also observed significant variations in height of plants obtained from different Ocimum species based on their distinct morphological characters. Kassahun et al. [28] also reported significant differences among spearmint genotypes with plant height and other morphological characters.

Treatments Plant Height (cm) Primary Branches/Plant Secondary Branches/Plant
Genotypes
B01 46.84a 9.67a 130.23a
B04 40.92b 7.90b 107.47b
B05 39.32b 7.68b 93.30c
LSD(0.05) 2.52 0.65 8.32
Harvesting Ages (DAT)
40 31.05d 4.64c 34.00d
60 38.18c 6.58b 86.24c
80 47.42b 11.11a 147.27b
100 52.79a 11.33a 173.82a
LSD(0.05) 2.92 0.75 9.61
CV (%) 7.04 9.1 8.9

Table 1: Main effect of genotypes and harvesting ages on plant height, number of primary and secondary branches of sweet basil at Wondo Gent in 2017. Means followed by the same letter in the same column are not significantly different at 5% level of probability. DAT=Days after transplanting, LSD=Least significant difference, CV=Coefficient of variation.

Similarly, harvesting age had significant (p=0.0001) influence on plant height of sweet basil plant (Appendix Table 2). Higher plant height (52.79 cm) was recorded at harvesting age of 100 days after transplanting (DAT). On the other hand, the lowest plant height (31.05 cm) was recorded at 40 DAT (Table 1). When harvesting age of sweet basil was delayed from 40 to 100 DAT, plant height was increased significantly. This increase in plant height might be due to conductive growth condition and extended duration of harvesting age. In harmony with the present result, Motsa [29] and Blank et al. [30] reported increase in plant height of rose-scented geranium due to delayed harvesting. Likewise, Galanopulou-Sendouca et al. and Damtew et al. [31] in Artemisia annua, Zigene et al. [32] in rosemary and Kumar and Kumar in kalmegh also reported increase in plant height with increasing harvesting age of the respective plants. Avci and Giachino [33] also found plant height increase in lemon balm with increase harvesting ages.

Primary and Secondary branches: The present study revealed that the interaction effect of genotypes and harvesting ages was not significant (p=0.082) and (p=0.068) on primary and secondary branches respectively. However, the main effects of genotypes and harvesting age showed a highly significant (p=0.0001) effect on both primary and secondary branches of sweet basil (Appendix Table 2). Genotype B01 gave the highest number of both primary (9.67) and secondary (130.23) branches, which were statistically different from B04 (107.47) and B05 (93.30) genotypes. The minimum primary branch (7.68) was recorded from genotype B05 which was not statistically different from genotype B04 (7.90) and minimum secondary branches (93.30) was recorded from genotype B05 (Table 1). Generally, the significant differences in primary and secondary branches among the studied genotypes of basil could be attributed to the substantial genetic variability among genotypes [34-40]. Similar results were observed in earlier studies involving sixteen different genotypes of Ocimum species to assess the variability of qualitative and quantitative morphological characters among genotypes [41]. The authors observed that there was a variation among different genotypes of Ocimum species for branch number. In addition, Kassahun et al. [28] also reported morphological character differences amongst spearmint genotypes with respect to branch number. Fikadu et al. [25] also observed significant differences among Ethiopian sweet basil accessions for number of branches per plant.

The main effect of harvesting age also showed a significant (p=0.0005) effect on both primary and secondary branches (Appendix Table 2). Primary branches increased with increasing harvesting age and the highest primary branches (11.33) was obtained at harvesting age of 100 DAT, which, however, did not statistically differ from the same genotype harvested at earlier harvesting age of 80 DAT (Table 1). In addition, the maximum secondary branches (173.82) were recorded at harvesting age of 100 DAT but the minimum primary and secondary branches were obtained when the plant harvested at 40 DAT. In harmony with the present study, Nassar et al. [42] reported increased primary and secondary branches of basil as plant age increased.

Leaf area per plant: The main effects of genotype and harvesting age and their interaction had a significant (p=0.0048) effect on leaf area per plant (Appendix Table 2). The highest leaf area per plant (5232.84 cm2) was recorded from genotype B01 when harvested at 80 DAT while the lowest leaf area per plant was obtained from genotype B04 (758.85 cm2) and B05 (661.38 cm2) with harvesting age of 40 DAT (Table 2). The variation in leaf area per plant might be due to the age of leaves, which resulted in plants to have lower leaf area at early and older growth ages and highest leaf area at bud initiation stage containing matured leaves. For genotype B01, the leaf area per plant was increased as harvesting age was increased up to 80 DAT and then declined when delaying to 100 DAT but for genotypes B04 and B05 leaf area being increased as the crop age increased even though there was no a statistically significant difference when the plant reached to 80 DAT and 100 DAT. Consistent to the present study, Nassar et al. [42] reported that total leaf area had a significant difference with plant ages of basil. The authors observed that the maximum leaf area per plant was recorded at 14 week old after planting which did not show a significant difference with leaf area obtained at 16 weeks old. Gebremeskle [43] also reported that harvesting age had a significant effect on leaf area per plant in rose scented geranium.

Genotypes Harvesting ages (DAT)
40 60 80 100
B01 1056.92h 3553.02e 5232.84a         5051.22b
B04 758.85i 3012.03f 4498.71c     4588.98c
B05 661.38i 2487.56g 3903.72d        4026.52d 
LSD (0.05)=131.19 CV (%)=2.39

Table 2: Interaction effect of genotype and harvesting age on leaf area/plant (cm2) of sweet basil at Wondo Genet in 2017. Means followed by the same letter in the same column and row are not significantly different at 5% level of probability. LSD=Least significant difference, CV=Coefficient of variation, DAT=Days after transplanting.

Herbage and yield component characters

Fresh and dry leaf weight/plant: Both the main effects of genotype and harvesting age, and their interaction significantly (p=0.0001) influenced fresh leaf weight/plant of sweet basil (Appendix Table 3). The maximum fresh leaf weight per plant (384.02 g) was obtained at treatment combination of B01 with harvesting age of 80 DAT, which was statistically similar with that of genotype B04 harvested at 100 DAT [44-49]. On the other hand, the minimum fresh leaf weight was obtained from genotypes B05 (45.79 g/plant) and B04 (46.58 g/plant) when both harvested at 40 DAT (Table 3). Fresh herb yield increased significantly with increase in crop age (delay in harvesting) for all tested genotypes. This might be due to better growth of plants in terms of plant height and number of branches per plant, which might have resulted due to longer growth period. In agreement with this, Kassahun et al. [50] reported that fresh leaf yield per plant was increased with harvesting age in peppermint. Contrary to this finding, Solomon and Beemnet [51] reported a decrease in fresh leaf weight with delaying of harvesting age in Japanese mint.

Genotypes Harvesting ages (DAT) Fresh leaf weight/plant (g) Dry leaf weight/plant (g)
B01 40 87.88g 11.27h
  60 247.55d 38.26ef
  80 384.02a 67.14b
  100 294.38c 65.25b
B04 40 46.58h 6.30h
  60 207.51e 32.63f
  80 295.20c 46.61d
  100 380.41a 74.42a
B05 40 45.79h 5.72h
  60 157.90f 23.75g
  80 326.56b 44.73de
  100 324.65b 57.15c
LSD(0.05)   26.49 2.07
CV (%)   6.71 10.6

Table 3: Interaction effect of genotypes and harvesting age on fresh and dry leaf weight of sweet basil at Wondo Genet in 2017. Means followed by the same letter in the same column are not significantly different at 5% level of probability. LSD=Least significant difference, CV=Coefficient of variation, DAT=Days after transplanting.

Similarly, dry leaf weight of sweet basil was significantly (p=0.0004) affected by interaction of genotypes and harvesting ages (Appendix Table 3). The highest dry leaf weight per plant (74.42 g) was recorded from genotype B04 harvested at 100 DAT, followed by genotype B01 harvested at 80 DAT (67.14 g) and 100 DAT (65.25 g) respectively while the lowest dry leaf weight per plant was obtained from all genotypes with harvesting age of 40 DAT. The dry leaf weight was increased when harvesting was delayed for all genotypes. This might be due to reduction of moisture content in the leaves of the plant associated with prolonged age. In agreement with the present study, Zigene et al. [32] observed that there was an increment of dry leaf weight per plant with increase in harvesting age of rosemary. Contrary, Damtew et al. [31] reported a decrease in dry leaf yield per plant with delaying of harvesting time in Artemisia.

Fresh and dry aboveground biomass/plant: Fresh and dry aboveground biomass per plant was highly significantly (p=0.0006) influenced by both the main effects of genotype and harvesting age, and their interaction (Appendix Table 3). The highest fresh aboveground biomass per plant was recorded from genotype B04 (592.81 g) harvested at 100 DAT, followed by B01 (542.17 g) genotype harvested at 80 DAT (Table 4). Similarly, the highest dry aboveground biomass per plant (127.65 g) was also recorded from genotype B04 harvested at 100 DAT followed by genotypes B05 and B01 harvested at 100 and 80 DAT respectively. On the other hand, the lowest values of fresh (84.04 g) and dry weight (3.50 g) were obtained from genotype B04 when harvested at 40 DAT, which was statistically similar with the value obtained from genotype B05 (5.72 g) harvested at 40 DAT. Contrary to the present study, Solomon and Beemnet [51] reported that fresh biomass weight was decreased with increasing crop age in Japanese mint.

Genotypes Harvesting Ages FABPP (g) DABPP (g)
B01 40 115.84i 13.74g
60 377.52f 57.71e
80 542.17b 106.73b
100 430.67e 109.26b
B04 40 84.04j 9.80g
60 336.21g 55.04e
80 473.94d 82.61c
100 592.81a 127.65a
B05 40 95.23ij 10.05g
60 284.10h 37.26f
80 491.40cd 73.14d
100 511.95c 105.37b
LSD(0.05)   26.54 7.2
CV (%)   4.34 6.48

Table 4: Interaction effect of genotypes and harvesting age on fresh and dry aboveground biomass per plant of sweet basil at Wondo Genet in 2017. Note: Means followed by the same letter in the same column are not significantly different at 5% level of probability. LSD=Least significant difference, CV=Coefficient of variation, FABPP=Fresh aboveground biomass per plant, DABPP=Dry aboveground biomass per plant.

Fresh and dry aboveground biomass/ha: The ANOVA table showed that both the main effects and their interaction had a significant (p=0.0001) effect on fresh aboveground biomass/ha (Appendix Table 4). The maximum fresh aboveground biomass (24.70 t/ha) was recorded from genotype B04 harvested at 100 DAT followed by genotype B01 (22.59 t/ha) and B05 (21.33 t/ha) with harvesting ages of 80 and 100 DAT respectively, while the lowest fresh aboveground biomass was obtained from all tested genotypes with harvesting age of 40 DAT (Table 3). For genotypes B04 and B05, fresh aboveground biomass/ha was increased with their ages which could be because the plants have a good opportunity to attain their maximum overall growth components. Jimayu and Gebre [52] also reported that delaying of harvesting age in lemongrass had a contribution for obtaining highest fresh aboveground biomass yield.

The analysis of variance showed that both the main effects and their interaction had a significant (p=0.0003) effect on dry aboveground biomass/ha (Appendix Table 4). The maximum dry aboveground biomass (5.32 t/ha) was recorded from genotype B04 harvested at 100 DAT and the lowest dry aboveground biomass was obtained from all tested genotypes with harvesting age of 40 DAT (Table 5). This indicated that dry aboveground biomass was increased with increasing of the age of sweet basil [53-58]. This might be due to the increasing of other contributing characters like plant height and dry leaf weight with harvesting age. Moreover, the loss of moisture with the ages of the plant also contributed for the increasing of dry aboveground biomass per hectare.

Genotypes Harvesting ages FABPH (t/ha) DABPH (t/ha)
B01 40 4.83i 0.57g
60 15.73f 2.40e
80 22.59b 4.45b
100 17.94e 4.55b
B04   40  3.50j 0.41g
60 14.01g 2.29e
80 19.75d 3.44c
100 24.70a 5.32a
B05   40 3.97ij 0.42g
60 11.84h 1.55f
80 20.47cd 3.05d
100 21.33c 4.39b
LSD(0.05)   1.11 0.3
CV (%)   5.64 7.22

Table 5: Effect of genotypes and harvesting ages on fresh and dry aboveground biomass/ha at Wondo Genet in 2017. Note: Means followed by the same letter in the same column are not significantly different at 5% level of probability. LSD=Least significant difference, CV=Coefficient of variation, FABPHA=Fresh aboveground biomass per hectare, DABPHA=Dry aboveground biomass per hectare.

Fresh and dry herbage yield/ha: Fresh herbage yield/ha was significantly (p=0.0011) influenced by the interaction effect of genotype and harvesting age (Appendix Table 5). The highest fresh herbage yield (16.00 t/ha) was produced from genotype B01 when harvesting was done at 80 DAT, which was statistically similar with genotype B04 harvested at 100 days after transplanting (Table 4). The lowest fresh herbage yield/ha was recorded from genotype B04 and B05 when both harvested at 40 DAT. Generally, the herbage yield was increased for both genotypes (B01 and B05) until they reached to 80 days old after transplanting and eventually the yield became decreased for genotype B01. This yield reduction after 80 DAT might be due to senescence of older leaves as observed in the field. In agreement with the present investigation, Kassahun et al. [50] also found that fresh and dry leaf yield of peppermint increased with increase in harvesting ages up to 120 DAT, there after decreased with plant age, which was consistent with the result reported by Bekele [59] in lemongrass. In addition, Kizil and Tocer [60] reported that the highest yield in terms of fresh herbage and dry herbage in spearmint was obtained as plant age increased.

Similarly, genotypes and harvesting ages had a significant (p=0.0032) interaction effect on dry herbage yield/ha (Appendix Table 5). The highest dry herbage yield (3.10 t/ha) was produced from genotype B04 harvested at 100 DAT (B04*100 DAT) followed by genotype B01 when harvesting was done at 80 DAT (2.78 t/ha) and 100 DAT (2.72 t/ha) respectively. The lowest dry herbage yield (0.24 t/ha) was obtained from genotype B05 harvested at 40 DAT, which was not statistically different from the yield produced from genotypes B04 and B01 when both harvested at 40 DAT (Table 6). Generally, dry leaf yield/ha was increased for all tested genotypes with delaying of harvesting age. This may be because the moisture content of the herb is decreased when the plants get older [61-69]. This result is in line with that of Leal et al. [70-75] who reported that dry matter production was increased with plant age. Bekele [59,76-79] also reported that dry herbage yield per hectare was affected by the interaction between varieties and harvesting age in lemongrass. Moreover, Jimayu and Gebre [52] also found that fresh and dry herbage yield of lemongrass were affected by various growth ages [80-85]. Moreover, Avci and Giachino [33] found that the highest fresh herbage yield and dry herbage yield of lemon balm were recorded with increasing harvesting ages [86-89].

Genotypes Harvesting Ages (DAT) Fresh Herbage Yield (t/ha) Dry Herbage Yield (t/ha)
B01   40 3.66g 0.47h
60 10.31d 1.59ef
80 16.00a 2.80b
100 12.27c 2.72b
B04   40 1.94h 0.26h
60 8.65e 1.36f
80 12.30c 1.94d
100 15.85a 3.10a
B05   40 1.91h 0.24h
60 6.58f 0.99g
80 13.61b 1.86de
100 13.53b 2.38c
LSD(0.05)   1.1 0.29
CV (%)   5.25 11.81

Table 6: Interaction effect of genotypes and harvesting age on fresh and dry herbage yield of sweet basil at Wondo Genet in 2017. Note: Means followed by the same letter in the same column are not significantly different at 5% level of probability. LSD=Least significant difference, CV=Coefficient of variation, DAT=Days after transplanting.

Summary And Conclusion

Sweet basil (Ocimum basilicum L.) is an annual aromatic and medicinal crop, which widely grown as home garden plant throughout the world for its multipurpose use such as medicinal value, flavoring food, spice and blended with different spices for local consumption. The growth, biomass and oil yield of sweet basil plant is known to be affected by numerous factors, which are difficult to separate from each other; among these climatic conditions, genetic variation, and cultural practices such as harvesting time, harvesting age, plant spacing (population density), postharvest drying and storage are the most important ones. Even though the plant has diverse advantages, its production has not been supported by research work in the country/ Ethiopia especially on variation of genotypes responses for different harvesting age. The field experiment was conducted at Wondo Genet Agricultural Research Center (WGARC) to determine the effects of genotypes and harvesting ages on herbage yield of sweet basil.

Growth parameters of plant height, number of primary and secondary branches were not significantly affected by the interaction effect of genotypes and harvesting ages. However, leaf area /plant, fresh leaf weight/plant, dry leaf weight /plant, fresh aboveground biomass/ plant, dry aboveground biomass/plant, fresh aboveground biomass/ha, dry aboveground biomass/ha, fresh herbage yield/ha, dry herbage yield/ha were significantly influenced by the interaction effect of genotypes and harvesting age. The highest leaf area per plant (5232.84 cm2) was recorded from genotype B01 when harvested at 80 DAT. The highest fresh yield per plant was recorded from genotype B01 (384.02 g) at harvesting age of 80 DAT, which was statistically similar with genotype B04 harvested at 100 DAT.

The highest values of fresh and dry aboveground biomass/plant were recorded from genotype B04 harvested at 100 DAT, followed by genotype B01 at harvesting age of 80 DAT. The aboveground biomass yield was increased up to 80 and 100 DAT for genotype B01 and genotypes (B04 and B05) respectively. This indicated that, aboveground biomass yield was increased with their ages, which could be due to the plants having a good opportunity to attain their maximum overall growth components. The highest fresh leaf yield (16.00 t/ha) was produced from genotype B01 harvested at 80 DAT, which was statistically similar with genotype B04 when harvested at 100 DAT. On the other hand, the highest dry herbage yield (3.10 t/ha) was produced from genotype B04 harvested at 100 DAT followed by genotype B01 when harvesting was done at 80 DAT (2.78 t/ha) and 100 DAT (2.72 t/ha) respectively. Generally, dry leaf yield/ha was increased for all tested genotypes with delaying of harvesting age.

It can be concluded that, interaction of genotypes and harvesting age significantly influenced herbage yield of sweet basil. Therefore, genotype B04 harvested at 80 DAT can be recommended for maximum herbage yield of basil at Wondo Genet area. Since other factors, such as location and season affect herbage yield, further study is suggested for assessing the effect of season on herbage yield of sweet basil under Wondo Genet condition.

References

  1. Makri O, Kintzios S (2008) Ocimum sp.(basil): Botany, cultivation, pharmaceutical properties, and biotechnology. Journal of Herbs, Spices & Medicinal Plants 13: 123-150.
  2. Carvalho Filho JLS, Blank AF, Alves PB, Ehlert PA, Melo AS, et al. (2006) Influence of the harvesting time, temperature and drying period on basil (Ocimum basilicum L.) essential oil. Revista Brasileira de Farmacognosia 16: 24-30.
  3. Simon JE, Morales MR, Phippen WB, Vieira RF, Hao Z (1999) Basil: a source of aroma compounds and a popular culinary and ornamental herb. Perspectives on new crops and new uses, pp: 499-505.
  4. Randhawa GS, Gill BS (1995) Transplanting dates, harvesting stage, and yields of French basil (Ocimum basilicum L.). Journal of Herbs, Spices & Medicinal Plants 3: 45-56.
  5. Engels JM, Hawkes JG, Worede M (1991). Plant genetic resources of Ethiopia. Cambridge University Press.
  6. Tilebeni HG (2011) Review to basil medicinal plant. International Journal of Agronomy and Plant Production 2: 5-9.
  7. Svecova E, Neugebauerova J (2010) A study of 34 cultivars of basil (Ocimum L.) and their morphological, economic and biochemical characteristics, using standardized descriptors. Acta Univ. Sapientiae, Alimentaria 3: 118-135.
  8. Jansen PCM (1981) Spices, condiments and medicinal plants in Ethiopia, their taxonomy and agricultural significance. Pudoc.
  9. Farrell KT (1998) Spices, condiments and seasonings. Springer Science & Business Media.
  10. Etana T (2007) Use and conservation of traditional medicinal plants by indigenous people in Gimbi woreda, western Wellega. Doctoral Dissertation, AAU, Ethiopia.
  11. Mesfin F, Demissew S, Teklehaymanot T (2009) An ethnobotanical study of medicinal plants in Wonago Woreda, SNNPR, Ethiopia. Journal of Ethnobiology and Ethnomedicine 5: 28.
  12. Gupta SC (1996) Variation in herbage yield, oil yield and major component of various Ocimum species/varieties (chemotypes) harvested at different stages of maturity. Journal of Essential Oil Research 8: 275-279.
  13. FrÄ…szczak B, Golcz A, Zawirska-Wojtasiak R, Janowska B (2014) Growth rate of sweet basil and lemon balm plants grown under fluorescent lamps and LED modules. Acta Sci. Pol. Hortorum Cultus 13: 3-13.
  14. Smitha GR, Tripathy V (2016) Seasonal variation in the essential oils extracted from leaves and inflorescence of different Ocimum species grown in Western plains of India. Industrial Crops and Products 94: 52-64.
  15. Alemu A (2017) Influences of Genotypes and Plant Spacing on Essential Oil, Biomass Yield and Yield Components of Basil (Ocimum basilicum L.) at Jimma, Southwest Ethiopia. Doctoral Dissertation, Jimma University.
  16. Al-Maskri AY, Hanif MA, Al-Maskari MY, Abraham AS, Al-sabahi JN, et al. (2011) Essential oil from Ocimum basilicum (Omani Basil): a desert crop. Natural Product Communications 6: 1487-1490.
  17. Badawy EM, El-Maadawy EI, Heikal AAM (2009) Effect of nitrogen, potassium levels and harvesting date on growth and essential oil productivity of Artemisia Annua L. plant. Journal of Applied Sciences Research 9: 2093-2103.
  18. Badi HN, Yazdani D, Ali SM, Nazari F (2004) Effects of spacing and harvesting time on herbage yield and quality/quantity of oil in thyme, Thymus vulgaris L. Industrial Crops and Products 19: 231-236.
  19. Barakoti TP (2004) Cultivation of Medicinal and Aromatic Plants in Nepal: An Overview. Agricultural Research for Enhancing Livelihood of Nepalese People, 30: 47.
  20. Baydar H, Erbas S (2005) Effects of harvest time and drying on essential oil properties in lavender. Acta Horticulture 4: 321-335.
  21. Abayneh E, Demeke T, Ashenafi A (2006) Soils of Wondo Genet Agricultural Research Center. National soil Research Center, p: 67.
  22. Runyoro D, Ngassapa O, Vagionas K, Aligiannis N, Graikou K, et al. (2010) Chemical composition and antimicrobial activity of the essential oils of four Ocimum species growing in Tanzania. Food Chemistry 119: 311-316.
  23. Fikadu D (2017) Phenotypic characterization and evaluation of ethiopian sweet basil (ocimum basilicum l.) accessions. Doctoral Dissertation, Hawassa University.
  24. Patel RP, Singh R, Rao BR, Singh RR, Srivastava A, et al. (2016) Differential response of genotype× environment on phenology, essential oil yield and quality of natural aroma chemicals of five Ocimum species. Industrial Crops and Products 87: 210-217.
  25. Saran PL, Tripathy V, Meena RP, Kumar J, Vasara RP (2017) Chemotypic characterization and development of morphological markers in Ocimum basilicum L. germplasm. Scientia Horticulturae 215: 164-171.
  26. Kassahun BM, Egata DF, Lulseged T, Yosef WB, Tadesse S (2014) Variability in agronomic and chemical characteristics of Spearmint (Mentha spicata L.) genotypes in Ethiopia. International Journal of Advanced Biological and Biomedical Research 2: 2704-2711.
  27. Motsa NM (2006) Essential oil yield and composition of rose-scented geranium (Pelargonium sp.) as influenced by harvesting frequency and plant shoot age. Doctoral Dissertation, University of Pretoria.
  28. Blank AF, De Souza EM, De Paula JW, Alves PB (2010) Phenotypic and genotypic behavior of basil populations. Horticultura Brasileira 28: 305-310.
  29. Damtew Z, Tesfaye B, Bisrat D (2011) Leaf, essential oil and artemisinin yield of artemisia (Artemisia annua L.) as influenced by harvesting age and plant population density. World Journal of Agricultural Sciences 7: 404-412.
  30. Zigene ZD, Kassahun BM, Ketaw TT (2012) Effects of Harvesting Age and Spacing on Leaf Yield and Essential Oil Yield of Rosemary (Rosmarinus officinalis L.). The African Journal of Plant Science and Biotechnology.
  31. Avci AB, Giachino RRA (2016) Harvest stage effects on some yield and quality characteristics of lemon balm (Melissa officinalis L.). Industrial Crops and Products 88: 23-27.
  32. Daniel MB, Solomon MA, Wossen MK (2009). Laboratory manual for plant products analysis.
  33. DeBaggio T, Belsinger S (1996) Basil: An herb lover's guide. Colorado: Interweave Press, pp: 62-72.
  34. Fischer R, Nitzan N, Chaimovitsh D, Rubin B, Dudai N (2011) Variation in essential oil composition within individual leaves of sweet basil (Ocimum basilicum L.) is more affected by leaf position than by leaf age. Journal of Agricultural and Food Chemistry 59: 4913-4922.
  35. Atey G (2008) Local Use of Spices, Condiments and Non-Edible Oil Crops in some Selected Woredas in Tigray, Northern Ethiopia. Doctoral Dissertation, Addis Ababa University.
  36. Galambosi B (1982) Results of cultivation trials with Artemisia annua L. Herba Hungarica (Hungary).
  37. Ghasemi PA (2014) Diversity in chemical composition and yield of essential oil from two Iranian landraces of sweet basil. Genetika 46: 419-426.
  38. Ghawas MM, Ahmad AW (2002) Preliminary study on yield performance and chemical composition of 10 locally selected Ocimum accessions. Journal of Tropical Agriculture and Food Science 30: 25-30.
  39. Agarwal C, Sharma NL, Gaurav SS (2013) An analysis of basil (Ocimum sp.) to study the morphological variability. Indian J Fundam Appl Life Sci 3: 521-525.
  40. Nassar MA, El-Segai MU, Mohamed SN (2013) Botanical Studies on Ocimum basilicum L.(Lamiaceae). Research Journal of Agriculture and Biological Sciences 9: 150-163.
  41. Gebremeskle H (2015) Effect of plant spacing and harvesting age on growth, biomass and oil yield of rose-scented geranium (Pelargonium graveolens L. Herit).
  42. Golparvar AR, Bahari B (2011) Effects of phenological stages on herbage yield and quality/quantity of oil in garden thyme (Thymus vulgaris L.). Journal of Medicinal Plants Research 5: 6085-6089.
  43. Gora J, Lis A, Kula J, Staniszewska M, Wołoszyn A (2002) Chemical composition variability of essential oils in the ontogenesis of some plants. Flavour and Fragrance Journal 17: 445-451.
  44. Guenther E (1972) The production of essential oils: Methods of distillation, enflorage, maceration and extraction with volatile solvents.
  45. Hiltunen R (1999) Basil: The Genus Ocimum (Medicinal and Aromatic Plants--industrial Profiles, 1027-4502; V. 10). 1st World Publishing.
  46. Hochmuth RC, Leon LL (1999) Evaluation of six basil cultivars grown in a vertical hydroponic production system inside a greenhouse. Univ. of Florida, FLO, NFREC-SV Research Report, pp: 99-106.
  47. Kassahun BM, Teixeira da Silva JA, Mekonnen SA (2011) Agronomic characters, leaf and essential oil yield of peppermint (Mentha piperiata L.) as influenced by harvesting age and row spacing. Medicinal and Aromatic Plant Science and Biotechnology 5: 49-53.
  48. Solomon A, Beemnet M (2011) Row spacing and harvesting age affect agronomic characteristics and essential oil yield of Japanese mint (Mentha arvensis L.). Medicinal and Aromatic Plant Science and Biotechnology 5: 74-76.
  49. Jimayu G, Gebre A (2017) Influence of harvesting age on yield and yield related traits of lemongrass (Cymbopogon Citratus L.) varieties at Wondo genet, southern Ethiopia.
  50. Hussain AI, Anwar F, Sherazi STH, Przybylski R (2008) Chemical composition, antioxidant and antimicrobial activities of basil (Ocimum basilicum) essential oils depends on seasonal variations. Food Chemistry 108: 986-995.
  51. Jacqueline AS (2001) Father Kino’s herbs: growing and using them today. Tierra Del Sol Institute Press, Tucson, Arizona.
  52. Koba K, Poutouli PW, Raynaud C, Chaumont JP, Sanda K (2009) Chemical composition and antimicrobial properties of different basil essential oils chemotypes from Togo. Bangladesh J. Pharmacol 4: 1-8.
  53. Lambers H, Chapin FS, Pons TL (1998) Plant physiological ecology. New York, USA.
  54. Liber Z, Carović‐Stanko K, Politeo O, Strikić F, Kolak I, et al. (2011) Chemical characterization and genetic relationships among Ocimum basilicum L. cultivars. Chemistry & Biodiversity 8: 1978-1989.
  55. Lupton D, Khan MM, Abdullah R (2016) Basil. Leafy Medicinal Herbs: Botany, Chemistry, Postharvest Technology and Uses, p: 27.
  56. Bekele W (2017) Influence of harvesting age and drying periods on herbage yield, essential oil content, oil yield, and citral yield of two lemongrass (Cymbopogon citratus (DC) Stapf) varieties at Wondo Genet, South Ethiopia. Doctoral Dissertation, Hawassa University.
  57. Kizil S, Toncer O (2006) Influence of different harvest times on the yield and oil composition of spearmint (Mentha spicata L. var. spicata). Journal of Food Agriculture and Environment 4: 135.
  58. Missanjo E (2014) Essential Oil Yield of Corymbia citriodora as Influenced by Harvesting Age, Seasonal Variation and Provenance at Citrifine Plantations in Northern Malawi. J Biodivers Manage Forestry.
  59. Nurzyńska-Wierdak R (2013) Does mineral fertilization modify essential oil content and chemical composition in medicinal plants. Acta Sci Pol Hortorum Cultus 12: 3-16.
  60. Nurzyńska-Wierdak R, Bogucka-Kocka A, Kowalski R, Borowski B (2012) Changes in the chemical composition of the essential oil of sweet basil (Ocimum basilicum L.) depending on the plant growth stage. Chemija 23: 216-222.
  61. Olle M, Bender I, Koppe R (2010) The content of oils in umbelliferous crops and its formation. Agronomy Research 8: 687-696.
  62. Padalia RC, Verma RS, Upadhyay RK, Chauhan A, Singh VR (2017) Productivity and essential oil quality assessment of promising accessions of Ocimum basilicum L. from north India. Industrial Crops and Products 97: 79-86.
  63. Purohit SS, Vyas SP (2008) Medicinal Plants Cultivation, Agrobios, India, pp: 488-490.
  64. Putievsky E, Galambosi B (1999) Production systems of sweet basil. Basil: the genus Ocimum 10: 39-65.
  65. Ram M, Ram D, Roy SK (2003) Influence of an organic mulching on fertilizer nitrogen use efficiency and herb and essential oil yields in geranium (Pelargonium graveolens). Bioresource Technology 87: 273-278.
  66. Prakasa Rao EVS, Ganesha Rao RS, Puttanna K, Ramesh S (2005) Effect of harvesting time on oil yield and oil quality of Ocimum basilicum. Indian Perfumer 49: 107-109.
  67. Leal TC, Freitas SP, Silva JF, Carvalho AJC (2001) Evaluation of the effect of season variation and harvest time on the foliar content of essential oil from lemongrass (Cymbopogon citratus (DC) Stapf.). Crop Husbandry 48: 445-453.
  68. Sangwan NS, Farooqi AHA, Shabih F, Sanguan RS (2001) Regulation of essential oil production in plants. Plant Growth Regulation 34: 3-21.
  69. Sedibe MM (2012) Yield and quality response of hydroponically grown rose-scented geranium (Pelargonium Sp.) to changes in the nutrient solution and shading. PhD. Dissertation, University of the Free State, Free State, South Africa.
  70. Sellami IH, Maamouri E, Chahed T, Wannes WA, et al. (2009) Effect of growth stage on the content and composition of the essential oil and phenolic fraction of sweet majoram (Origanum majorana L.). Industrial crops and products 30: 395-402.
  71. Simon JE, Quinn J, Murray RG (1990) Basil: a source of essential oils. Advances in New Crops, pp: 484-489.
  72. Singh MP, Panda H (2005) Medicinal herbs with their formulations. Daya Books.
  73. Singh S, Singh M, Singh AK, Kalra A, Yadav A, et al. (2010) Enhancing productivity of Indian basil (Ocimum basilicum L.) through harvest management under rainfed conditions of subtropical north Indian plains. Industrial Crops and Products 32: 601-606.
  74. Suppakul P, Miltz J, Sonneveld K, Bigger SW (2003) Antimicrobial properties of basil and its possible application in food packaging. Journal of Agricultural and Food Chemistry 51: 3197-3207.
  75. Telci I, Hisil Y (2008) Biomass yield and herb essential oil characters at different harvest stages of spring and autumn sown Coriandrum sativum. European Journal of Horticultural Science 73: 267.
  76. Varga F, Carović-Stanko K, Ristić M, Grdiša M, Liber Z, et al. (2017) Morphological and biochemical intraspecific characterization of Ocimum basilicum L. Industrial Crops and Products 109: 611-618.
  77. Verma PK, Gupta SN, Khabiruddin M, Sharma GD (1998) Genetic variability parameters for herb and oil yield in different Ocimum species. Indian Perfumer 42: 36-38.
  78. Verma RS, Padalia RC, Chauhan A (2012) Variation in the volatile terpenoids of two industrially important basil (Ocimum basilicum L.) cultivars during plant ontogeny in two different cropping seasons from India. Journal of the Science of Food and Agriculture 92: 626-631.
  79. Wetzel SB, Krüger H, Hammer K, Bachmann K (2002) Investigations on morphological, biochemical and molecular variability of Ocimum L. species. Journal of Herbs, Spices & Medicinal Plants 9: 183-187.
  80. Zhang JW, Li SK, Wu WJ (2009) The main chemical composition and in vitro antifungal activity of the essential oils of Ocimum basilicum Linn.var. pilosum (Willd.) Benth. Molecules 14: 273-278.
  81. Zheljazkov VD, Astatkie T, Hristov AN (2012) Lavender and hyssop productivity, oil content, and bioactivity as a function of harvest time and drying. Industrial Crops and Products 36: 222-228.
  82. Zheljazkov VD, Callahan A, Cantrell CL (2007) Yield and oil composition of 38 basil (Ocimum basilicum L.) accessions grown in Mississippi. Journal of Agricultural and Food Chemistry 56: 241-245.
  83. VD, Cantrell CL, Ebelhar MW, Rowe DE, Coker C (2008) Productivity, oil content, and oil composition of sweet basil as a function of nitrogen and sulfur fertilization. HortScience 43: 1415-1422.

Citation: Abewoy D, Belew D, Zigene ZD (2018) Influence of Harvesting Age and Genotype on Growth Parameters and Herbage Yield of Sweet Basil (Ocimum basilicum L.) at Wondo Genet, Southern Ethiopia. Adv Crop Sci Tech 6: 407. DOI: 10.4172/2329-8863.1000407

Copyright: © 2018 Abewoy D, et al. This is an open-access article distributed under the terms of the Creative Commons Attribution License, which permits unrestricted use, distribution, and reproduction in any medium, provided the original author and source are credited.

Post Your Comment Citation
Share This Article