African Journal of
Agricultural Research

  • Abbreviation: Afr. J. Agric. Res.
  • Language: English
  • ISSN: 1991-637X
  • DOI: 10.5897/AJAR
  • Start Year: 2006
  • Published Articles: 6865

Full Length Research Paper

Effect of planting density on yield and yield components of lettuce (Lactuca sativa L.) at two agro-ecologies of Ethiopia

Fekadu Gebretensay Mengistu
  • Fekadu Gebretensay Mengistu
  • Debre Zeit Agricultural Research Center, Ethiopian Institute of Agricultural Research, P. O. Box 32, Debre Zeit, Ethiopia.
  • Google Scholar
Getachew Tabor
  • Getachew Tabor
  • Debre Zeit Agricultural Research Center, Ethiopian Institute of Agricultural Research, P. O. Box 32, Debre Zeit, Ethiopia.
  • Google Scholar
Zebenay Dagne
  • Zebenay Dagne
  • Holeta Agricultural Research Center, Ethiopian Institute of Agricultural Research, P. O. Box 31, Holeta, Ethiopia.
  • Google Scholar
Gizachew Atinafu
  • Gizachew Atinafu
  • Debre Zeit Agricultural Research Center, Ethiopian Institute of Agricultural Research, P. O. Box 32, Debre Zeit, Ethiopia.
  • Google Scholar
Fasil Tadesse Tewolde
  • Fasil Tadesse Tewolde
  • Debre Zeit Agricultural Research Center, Ethiopian Institute of Agricultural Research, P. O. Box 32, Debre Zeit, Ethiopia.
  • Google Scholar


  •  Received: 08 December 2020
  •  Accepted: 18 February 2021
  •  Published: 30 April 2021

 ABSTRACT

Use of optimum plant spacing (planting density) is one of the important agronomic practices to maximize the productivity of lettuce. A field experiment was conducted to assess the responses of two lettuce varieties to different plant spacing at Debrezeit and Holeta Agricultural Research Centers representing two different agro-ecologies in Ethiopia. Nine treatment combinations of three levels of inter-row and three levels of intra-row spacing were studied on two types of lettuce varieties. The treatments were arranged in a randomized complete block design (RCBD) with three replications in a factorial experiment. The results revealed that marketable and total fresh leaf yield, and fresh leaf weight per plant were significantly affected by the main effect of plant spacing and variety as well as its interaction (p<0.05). Increasing planting density increased the total fresh leaf yield per unit area in both varieties, however reduced the fresh leaf weight per plant. The highest fresh leaf yield was obtained using 40 cm x 20 cm (125000 plants ha-1) planting density from variety Great Lakes, while variety Rsk-3 recorded its highest fresh leaf yield at the highest planting density of 30 cm x 20 cm (166667 plants ha-1). Great Lakes was superior over Rsk-3 in most yield parameters studied though Rsk-3 was better in leaf dry weight percent. Besides, both varieties responded differently in both sites while Great Lakes performed better at Debrezeit than at Holeta and Rsk-3 did well at Holeta than at Debrezeit. Hence, 40 cm x 20 cm and 30 cm x 20 cm could be used as the optimum plant spacing to grow Great Lakes and Rsk-3 respectively in the respective agro-ecologies.

Key words: Agronomic practices, planting density, inter-and intra-row spacing, competition.


 INTRODUCTION

Lettuce (Lactuca sativa L.) is one of the most popular vegetable crops which occupy the largest production area among salad crops in the world. It is produced commercially in many countries and also widely grown as a vegetable  in  home  gardens  (Kristkova  et  al.,  2008). Lettuce is an important dietary vegetable, which is primarily consumed fresh in salads. Consumption of lettuce has some health benefits attributed to the presence of vitamin C, phenolic compounds, and fiber content (Vanisree et al., 2010).  It  is also rich in vitamin A and minerals like calcium and iron and also contains protein, and carbohydrate (MRC, 1954). Lettuce can grow in a variety of soil types and climatic conditions, which usually likes temperature between 23°C during the day and 7°C at night and grows within an altitude of 1800 to 2100 m.a.s.l. It is best grown in silt loams and sandy soils as these soil types provide better drainage and warm up more readily during the day, which is especially important during cooler periods of the growing season (Kristkova et al., 2008).

Globally, average production share of lettuce by region for the last 25 years (1994-2018) shows Asia (60.6%) took the lead followed by Americas (22.2%), Europe (14.8%), Africa (1.6%), and Oceana (0.8%). World production/yield quantities of the world of lettuce, has grown significantly during this period,; while in 2018 alone, about 27.3 million metric tons of lettuce was harvested from 1.27 million hectare of land (FAO, 2020).

Lettuce is among the widely grown vegetable crops in Ethiopia. In the Meher (or rainy) season of 2018, it was grown on 244.92 ha of land and produced 2,163.35 quintals involving 41,963 households (CSA, 2018). In Ethiopia, however data are not readily available for lettuce off-season production, although it is usually grown using irrigation in the dry season and, hence the quantity of production as well as the area coverage could certainly be higher than what was reported above. The average productivity of lettuce in Ethiopia is however very low compared to that of the world’s average (CSA, 2018).

Plant spacing for lettuce cultivation is an important criterion for attaining maximum vegetative growth and an important aspect of crop production for maximizing the yield. Optimum plant spacing ensures judicious use of natural resources and makes the intercultural operations easier. It helps to increase the number of leaves, branches and healthy foliage. Densely planted crop obstruct the proper growth and development while on the other hand, wider spacing ensures the basic nutritional requirements but decrease the total number of plants as well as total yield.

Yield may be increased for any crop up to 25% by using optimum spacing in leafy vegetables such as lettuce (Bansal et al., 1995). There are different lettuce cultivars currently under production with different morphological characteristics such as head size, compactness, leaf color, and growth habits requiring different plant spacing. In Ethiopia, lettuce is usually grown by small holders where they cultivate few commercial and locally available varieties. However, due to lack of research recommended agronomic practices such as optimum planting density, growers use blanket recommendations which usually influence the crop performances and consequently reduce the productivity and quality attributes of the produce. Hence the present study was undertaken to find out the suitable plant spacing/or planting density for ensuring the higher yield and quality of two lettuce varieties in two agro-ecologies in Ethiopia.


 MATERIALS AND METHODS

Description of study area

The present study was conducted at Debre Zeit and Holeta Agricultural Research Centers representing two different agro-ecologies in the Central and West Showa of the Oromia Regional State respectively in Ethiopia. The agro-ecological characteristics of the two experiment sites are described in Table 1.

Experimental plant materials

The study was conducted on two lettuce varieties (Great Lakes and Rsk-3). The varieties were selected for this study based on their domination in the production system, particularly Great Lakes and their differences in morphological traits, that is, head size, compactness and nature of growth habits. Great Lakes is a very popular head lettuce commercially available in the markets and widely grown by farmers. Its crisp heads have the perfect crunch that makes it perfect for garnishing sandwiches (Compositdb, 2006) (Figure 1A). Rsk-3 (Red lettuce) was introduced from Korea and was registered recently (2019) as variety in Ethiopia. It is red lettuce and open head growing type with high mineral content, rich in vitamin A, and suitable for continuous piece meal harvests (Zebenay et al., 2019) (Figure 1B).

Experimental design and treatment randomization

Nine combined spacing treatments of three levels of inter (30, 40 and 50 cm) and three levels of intra row spacing (20, 30 and 40 cm) were studied on the aforementioned two lettuce varieties. The treatments were laid out in a randomized complete block design (RCBD) in factorial arrangement in three replications.

Field management

Seedlings were raised on seed beds sown at a seed rate of 0.2 kg ha-1 and transplanted to the experimental plots (2 m x 1.8 m) at 3-4 weeks after sowing. At transplanting, seedlings were spaced on each experimental plot based on the spacing treatments to attain different planting densities (50000, 62500, 66667, 83333, 83333, 100000, 111111, 125000 and 166000 plants ha-1). The plots were uniformly irrigated every 2-3 days after transplanting and soil moisture was kept at field capacity to avoid transplanting shock and irrigation continued at weekly interval until harvest. All experimental plots were fertilized with 100 kg of DAP ha-1 at transplanting and 180 kg ha-1 of Urea in splits, half applied at transplanting and the rest half three weeks after transplanting. Other agronomic practices including weeding, cultivation, pesticide application, etc were applied uniformly to all the experimental plots as per required.

Data collection and analysis

Fresh leaf weight per plant (g plant-1), marketable fresh leaf yield per hectare (t ha-1), unmarketable fresh leaf yield (t ha-1), total fresh leaf yield (t ha-1) and leaf dry weight percent (%), were the parameters for which data were collected for the study. Fresh leaf weight per plant and dry weight percent were measured from five sample plants taken per plot at full maturity. Leaf dry weight was measured by drying fresh leaf sample from each treatment in the oven at 65-70°C for about 48 h until a constant weight was attained.

Data were subjected to analysis of variance (ANOVA) using R statistical software (http://www.R-project.org/, accessed online on June 5, 2020) and means were separated using least significant difference (LSD) test at 5% probability level.


 RESULTS AND DISCUSSION

All parameters except unmarketable leaf yield were significantly influenced by the individual effect of spacing, variety, location and their interaction, while the leaf dry weight percent was varied by variety only (Table 2).

The interaction of spacing and variety significantly affected fresh leaf yield (marketable and total, t ha-1) and leaf fresh weight (g plant-1) while unmarketable fresh leaf yield and leaf dry weight were not significantly affected by the interaction (Table 3). Nevertheless, the latter two parameters were significantly  affected  by the main effect of variety (Table 4). The highest total fresh leaf yield (70.49 t ha-1) was obtained at 40 cm x 20 cm (125,000 plants ha-1) from variety Great Lakes followed by 65.60 t ha-1 at 50 cm x 20 cm (100,000 plants ha-1) and 53.36 t ha-1 at 40 cm x 30 cm (83,333 plants ha-1), while the least (37.39 t ha-1) was resulted from the wider spacing of 50 cm x 40 cm (50,000 plants ha-1). The highest fresh leaf yield (28.11 t ha-1) of Rsk-3 was obtained at 30 cm x 20 cm (166,667 plants ha-1) followed by 22.73 t ha-1 at 40 cm x 20 cm (125,000 plants ha-1), which continued to decrease with decreasing planting densities (wider spacing). The highest fresh yield obtained from Rsk-3 was 60% less than the highest yield obtained from Great Lakes.

Variety Rsk-3 was found to be inferior in total fresh leaf yield and fresh leaf weight plant-1 than Great Lakes in all the spacing treatments; however, both varieties exhibited significant increase in fresh leaf yields with increasing planting density (Figure 2). Regardless of the overall differences in fresh leaf yield performance between the two  lettuce   varieties,   both    responded    positively   to increasing planting density. Leaf fresh yield increased with increasing planting density although the trend varied (Figure 2) and was positive and significant (R2=0.60 for Great Lakes and R2=0.89 for Rsk-3). In the case of variety Great Lakes, the increment started to drop after the planting density reached 125,000 plants ha-1 (40 cm x 20 cm) at which the maximum yield was attained whereas variety Rsk-3 showed no sign of dropping after attaining its maximum yield (Figure 2). It was observed that closely spaced plants grow very fast as compared to wider spaced plants. This is mainly the result of competition for photosynthetic active radiation which stimulates growth and increased total yield parameters (Maboko and Du Plooy, 2009).

In case of Great Lakes, the highest fresh leaf yield was obtained at 125,000 plants ha-1 due to the larger number of heads harvested; however, at higher density (166,667 plants ha-1), yields started to drop again due to the fact that at higher density size of individual heads reduced although the number is high. On the other hand, regardless  of  the  increasing  planting density, Rsk-3 did not show yield dropping. This could be due to the fact that the plant densities used in the study did not reach the level at which Rsk-3 responds to reach its maximum yield.

The higher number of plants at the closer spacing contributed to higher fresh leaf and dry mass per unit area of lettuce compared to wider spacing, while a tendency of increased fresh leaf and dry mass per unit area was obtained as the plant spacing decreases (Maboko and Du Plooy, 2009). According to Maboko and Du Plooy (2009), although on different lettuce cultivars and locations, planting density significantly affected different growth and yield parameters including fresh and dry leaf mass, with significantly higher values of all variables at the closest spacing 10 cm x 20 cm (50 plants m-2). The results indicate that an increase in planting density results in a significant increase in yield and yield components of leafy lettuce. This holds true mainly for our leafy lettuce Rsk-3 variety in the present study, which gave the highest fresh leaf yield at a higher density (17 plants m-2) at 30 cm x 20 cm (166,667 plants ha-1).

Cultivar differences observed were mostly due to differences on fresh mass, higher leaf area, plant height and leaf number (Maboko and Du Plooy 2009), although the latter three parameters were not included in the present study The higher fresh leaf yield obtained in the present study was also from the closest spacing 40 cm x 20 cm (13 plants ha-1) for Great Lakes and 30 cm x 20 cm (17 plants ha-1) for Rsk-3, although the spacing used in this study was wider (low plant density) compared to what was used in Maboko and Du Plooy (2009). A related study conducted on variety “Tesfa Mekele” in Tigray region showed similar results of the increasing trend of fresh leaf biomass with increasing plant density (Beyenesh et al., 2017) in which the highest leaf biomass was obtained at 60 cm x 40 cm spacing (4 plants ha-1), although it is wider compared to the present study. A spacing of 30 cm x 30 cm (11 plants ha-1) gave the highest fresh weight of leaves in an experiment conducted on Great Lakes in Ghana (Abdul-Halim et al., 2011), which is much more closer to our results as both studies are on the same variety-Great Lakes. Abdul-Halim et al. (2011) also found 1.254% of leaf dry weight at 30 cm x 30 cm from Great Lakes although spacing did not affect leaf dry weight in our study, but similar average leaf dry mass (1.85%) (Table 3). A spacing of 40 cm x 25 cm (10 plants ha-1) gave the maximum yield (7.68 t ha-1) on cultivar Grand Ratids in Bangladesh, which is of course small yield compared to ours, although the highest yield from variety Great Lakes in the present study was obtained at this plant density (40 cm x 20 cm), but different variety (Alahi et al., 2014).

Great Lakes was superior in fresh leaf weight plant-1 over Rsk-3 (Table 3). The average fresh leaf weight plant-1 of Great Lakes was 752.45 g ranging from 575.4 to 905.93 g, while the highest weight was obtained at 40 cm x 40 cm (62,500 plants ha-1) and the least was at 50 cm x 20 cm (100,000 plants ha-1). However, the average fresh leaf weight plant-1 obtained from Rsk-3 was only 257.96 g at 40 cm x 30 cm (83,333 plants ha-1) which is three times less than that of the Great Lakes (752.45 g). The maximum fresh weight of lettuce plant was observed from 40 cm × 30 cm while the minimum fresh weight per plant was found from 40 cm × 20 cm (Hasan et al., 2017).

Genetic differences between the varieties (compactness, head size, growth habit, etc) could be the reason for this much differences in fresh yield performances. Great Lakes is headed type lettuce and has compacted/folded leaves which contributed to having a higher weight per plant and total fresh yield, while Rsk-3 is loose and open non heading type which could result in a reduced fresh weight per plant and total fresh yield. Variations in genetic makeup between lettuce varieties made differences in yield contributing components such as leaf area, plant height, number of leaves that would create differences in fresh weight per plant and total fresh yield per unit area (Maboko and Du Plooy, 2009). Besides, unlike the total fresh leaf yield (t ha-1), increasing planting density decreased fresh leaf weight per plant in both varieties (in other words, increasing plant spacing increased fresh weight plant-1) (Figure 3).

Our results are in agreement with similar studies which revealed that fresh weight plant-1 of lettuce showed statistically significant variation due to different plant spacing. The increases of spacing showed increasing trend in fresh weight of plant. In case of wider spacing, plants receive enough light and nutrients which leads to attaining maximum fresh weight of plant (Rincon et al., 1998; Tittonell et al., 2003; Boroujerdnia and Ansari, 2007). Hence, optimum plant spacing ensured maximum vegetative growth that ensured highest fresh weight plant-1 (Hasan et al., 2017).

Although spacing did not affect the leaf dry weight of both varieties, varietal differences was obtained. Rsk-3 (5.95%) was better in dry weight percent than Great Lakes (1.85%) unlike the other parameters such as total fresh leaf yield and fresh leaf weight per plant (Table 4).

Significant interaction between variety and spacing treatments was also observed over locations in most of the parameters measured (Table 5). Great Lakes performed better at Debrezeit than at Holeta and Rsk-3 did well at Holeta than at Debrezeit at all spacing treatment combinations (Table 5). In particular, the total fresh leaf yield performance of Great Lakes at Debrezeit (106.58 t ha-1) was three-fold higher than at Holeta (34.41 t ha-1) at optimum planting density (125000 plants ha-1) while Rsk-3 was better at Holeta (30.02 t ha-1) than at Debrezeit (26.19 t ha-1) at planting density of 166,667 plants ha-1 although this difference was not as high as observed in Great Lakes between the locations.

Nevertheless, the average yield performance of Great Lakes over the spacing treatments at Debrezeit was 71.79 t ha-1, which was still superior over its performance at  Holeta  (29.90 t ha-1).  On  the other hand, the average yield performance of Rsk-3 was better at Holeta (24.37 t ha-1) than at Debrezeit (15.27 t ha-1) (Table 5). Lettuce is considered a crop of mild climate and its production in regions of low altitude is impaired due to the high temperatures and the predominance of long days (Cardoso et al., 2018). Using the results of the present study, it is possible to suggest that the different varieties respond differently to different agro-ecologies, depending on their adaptation. Hence, based on the results obtained in the present study, Great Lakes preferred relatively a mid-low altitude and warm temperature of Debrezeit compared to Rsk-3 which rather preferred a higher altitude and cooler environment of Holeta.


 CONCLUSIONS AND RECOMMENDATION

Based on the results of the present study, marketable and total fresh leaf yield, fresh leaf weight per plant and dry weight were significantly affected by the main effect of plant spacing and variety as well as its interaction. Increasing planting density increased the total fresh leaf yield per unit area in both varieties; but reduced the fresh leaf weight per plant. Variety Great Lakes was superior over Rsk-3 in total fresh leaf yield as well as fresh leaf weight per plant. However, leaf dry weight of Rsk-3 was higher than that of Great Lakes although spacing did not affect the leaf dry weight of both varieties. Besides, both lettuce varieties responded differently in both sites while Great lakes performed better at Debrezeit than at Holeta, and Rsk-3 did well at Holeta than at Debrezeit. Nevertheless, increasing leaf yield at higher plant densities should conform with the quality attributes such as head size, plant weight and etc as it may have high implication for consumer preferences as far as lettuce is considered, while too small or too large-sized lettuce head is not usually preferred by consumers. It should be noted that the results presented here are only for the data collected in the experimental season with irrigation and cannot be extrapolated to other production systems and production seasons. Whether the increased plant density will affect head size, leaf numbers, leaf area, growth season, etc will be investigated in future studies.


 CONFLICT OF INTERESTS

The authors have not declared any conflict of interests.



 REFERENCES

Abdul-Halim A, George N, Maalinyuur S (2011). Preliminary Studies on Growth and Fresh Weight of Lettuce (Lactuca sativa) as Affected by Clay Pot Irrigation and Spacing. Pakistan Journal of Biological Sciences 14(14):747-751.
Crossref

 

Alahi A, Hossain MI, Kabir K, Shahjahan M, Arefin SMA, Hosain MT (2014). Effect of Phosphorus and Plant Spacing On the Growth and Yield of Lettuce. Advance in Agriculture and Biology 2(1):1-7.
Crossref

 

Bansal GL, Rana MC, Upadhyay RG (1995). Response of grain amaranth (Amaranthus hypochondriacus) to plant density. Indian Journal of Agricultural Science 65 (11):818-820.

 

Beyenesh Z, Mereseit H, Niguse A (2017). Effect of Inter and Intra-Row Spacing on Yield and Yield Components of Lettuce (Lactuca Sativa) in South East Tigray, Ethiopia. Biomedical Journal of Scientific & Technical Research 1(6): 1698-1709. BJSTR. MS.ID.000516. 
Crossref

 

Boroujerdnia M, Ansari NA (2007). Effect of Different Levels of Nitrogen Fertilizer and Cultivars on Growth, Yield and Yield Components of Romaine Lettuce (Lactuca sativa L.). Department of Horticultural, Faculty of Agriculture, Shahid Chamran University, Ahwaz, Iran. Middle Eastern and Russian Journal of Plant Science and Biotechnology 1(2):47-53.

 

Cardoso SS, Guimarães MA, Neto HSL, Tello JPJ, Júlio CV (2018). Morphological and productive aspects of lettuce in low altitude and latitude. Revista Ciência Agronômica 49(4):644-652., 
Crossref

 

Central Statistical Agency (CSA) (2018). Agricultural Sample Survey. 2018/19 (2011 E.C.) Volume I Report On Area and Production of Major Crops (Private Peasant Holdings, Meher Season). Statistical Bulletin 589, Federal Democratic Republic of Ethiopia. Addis Ababa.

View

 

Compositdb (2006). Lettuce cultivar database. 02 Jan. 2007.

View

 

Food and Agriculture Organization of the United Nations (FAO) (2020). FAOSTAT Crops data.

View

 

Hasan MR, Tahsin AK, Islam MN, Ali MA, Uddain J (2017). Growth and Yield of Lettuce (Lactuca Sativa L.) Influenced As Nitrogen Fertilizer and Plant Spacing. Journal of Agriculture and Veterinary Science 10(6):62-71.
Crossref

 

Kristkova E, Dolezalova I, Lebeda A, Vinter V, Novotna A (2008). 'Description of morphological characters of lettuce (Lactuca sativa L.) genetic resources'., Horticultural Science (Prague) 35(3):113-129.
Crossref

 

Maboko MM, Du Plooy CP (2009). Effect of plant spacing on growth and yield of lettuce (Lactuca sativa L.) in a soilless production system. South African Journal of Plant and Soil 26(3):195-198. 
Crossref

 

Ministry of Agriculture (MOA) (1998). Agro-ecological Zones of Ethiopia. Ethiopian Institute of Agriculture Research publication. Available at: Agro-ecological Zones of Ethiopia (eiar.gov.et).

 

Medical Research Council (MRC) (1954). Plant Proteins in Child Feeding. Special Report Series 279. Postgraduate Medical Journal 30:262.
Crossref

 

Rincon L, Pellicer C, Saez J (1998). Effect of different nitrogen application rates on yield and nitrate concentration in lettuce crops. Agrochemia 42:304-312.

 

Tittonell PA, de Grazia J, Chiesa A (2003). Nitrate and dry water concentration in a leafy lettuce (Lactuca sativa L.) cultivar as affected by N fertilization and plant population. AgriculturaTropica and Subtropica 36:82-87.

 

Vanisree M, Mathieu N, Ajay N, Yanjun Z, Aditya LG, Gottumukkala, Muraleedharan GN (2010). In vitro evaluation of red and green lettuce (Lactuca sativa) for functional food properties. Elsevier, Food Chemistry 118(2):300-306.
Crossref

 

Zebenay D, Samuel T, Ousman Y, Gete F, Fekadu G, Fasil Te, Getachew T, Gizachew A (2019). Evaluation of Lettuce (Lactuca sativa L.) genotypes for yield and quality in Ethiopia: Proceedings of the national Conference on Crop Improvement and Management Research. Addis Ababa, Ethiopia pp. 389-396.

 




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