Influence of manure and inorganic fertilizer on yield and quality of Vicia villosa intercropped with Sorghum almum in Ol-joro-orok, Kenya

T P Lanyasunya, Wang H Rong*, E A Mukisira,  S A Abdulrazak** and W O Ayako

Kenya Agricutural Research Institute (KARI)/Kenya
*Yangzhou University/Jiangsu Province / P.R. China
**Animal Science Department,.Egerton University /Kenya
planyasunya@yahoo.com

Abstract

This experiment was carried out at the regional research sub-station Ol'Joro Orok in Nyandarua District over a period of 2 years. Thirty-six plots of 2 x 2 sq. m were demarcated. Vicia villosa (common vetch) and Sorghum almum (Columbus grass) were allotted at random to three (3) treatment blocks (Manure [M]; Fertilizer [F] and control [C]). Each of the forages under investigation had 6 replicates in each block. Forage height was monitored on weekly basis over 12-week period using a one metre wooden ruler. Air and total dry matter (aDM and tDM) and chemical components were determined using standard procedures. The obtained values were used to predict forage digestibility of dry matter (DDM), dry matter intake (DMI), gross energy digestibility (% GED), relative feed value (RFV), relative feed quality (RFQ) and quality index (QI) using NRC and NFTA recommended equations. At the 19^th week all plots were harvested (5 cm from the ground) to determine fresh matter yield (FMY) from which dry and organic matter yields (DMY and OMY) were derived. The data were stored in MS excel and later subjected to SPSS (2000) to determine descriptive statistics. One-way ANOVA and t-test were also applied to determine treatment differences.

At 12 weeks of age, forage height ranged between 28.6 - 36.4 cm (C); 36.2 - 45.2 cm (F) and 42.3 - 47.7 cm (M) for Vicia villosa. The significant differences in height observed between C and M or F were attributed to the supplied N and the climbing anchor provided by Sorghum almum. Dry matter contents were not significantly different. Pure vetch stand under M or F registered the highest CP level (18.3 and 18.7% in DM, respectively). The same was reflected in Sorghum almum (M - 11% and F - 11.1%). Significant differences were also observed on yields. In pure stand, common vetch plots receiving either manure or inorganic fertilizer recorded 32% (8.75 or 7.5 kg m^-2) higher yields compared to C (5.95 kg m^-2). Under intercrop, the same treatments also recorded 33.4% (3.5 or 3.38 kg m^-2) higher yields compared to C (2.33 kg m^-2). However, intercropping had negative implication on FMY of common vetch (ranging 5.95 - 8.75 kg m^-2 pure stand and 2.33 - 3.5 kg m^-2 intercropped: 59 - 60% less). A similar trend was observed with Sorghum almum (in pure stand: C - 8.7; M - 14.3 and F - 14 kgm^-2 and under intercrop: C - 8.2; M - 9.6 and F - 10.8 kg m^-2). RFV, RFQ and QI values were slightly higher for M and F compared to C.

It was therefore concluded that manure or fertilizer can significantly increase Common vetch and Columbus grass yields and improve the overall quality. However, intercropping negatively impacted on branching of both crops particularly vetch thereby reducing their biomass yields.

Key words: Dry and organic matter digestibility, gross energy digestibility, inter-cropping, quality index, relative feed quality, relative feed value

Introduction

In Kenya, the dairy sub-sector is predominantly a smallholder domain (Peeler and Omore 1997; Staal et al 1999; Conelly  1998; Thorpe et al 2000). Presently, dairy production in Kenya is threatened by a myriad of constraints. Inadequate nutrition is the single most critical constraint militating against increased dairy production, especially during dry season when forage quality and quantity is low. This is largely attributed to sub-division of land resources into small uneconomic units and the subsequent decline in soil fertility (which arises from continuous nutrient mining). This has led to rapid decline in fodder crop yields and therefore lack of adequate feed and  prevalence of malnutrition-related ailments on smallholder dairy farms. This is evidenced by the reported low milk yield per cow (average 7 kg/cow/d; Lanyasunya et al 1998), high rate of infertility (65%; Lokwaleput et al 1999), mortality and stagnation of dairy cattle population growth over the last decade (CBS 1999). The challenge therefore is how to enhance milk production on these farms. This calls for judicial utilization of cheaply available feed resources, application of cost effective forage production and utilization technologies, particularly those known to enhance soil fertility to ensure feed self-sufficiency throughout the year. Vicia sativa and Vicia villosa have widely been used to improve soil fertility and protein supplements for ruminants. Their excellent compatibility with cereals (such as Zea mays) when under sown is well recognized. They are however both less utilized in Kenya. One reason is that they are less known among smallholder farmers. It is strongly believed that their integration in the smallholder farming systems will offer an alternative to less cold tolerant but very popular forages such as Pennisetum purpureum (Napier grass). They have the potential of enhancing the quality of crop residues during the dry season.

The current study was conducted to determine the influence of age (growth stage) and secondary sources of nitrogen (N) on dry matter yield (DMY) and nutritive values of vetches and Columbus grass grown either as pure stand or intercrop. The goal was to find ways of enhancing feed availability through integration of cost effective fodder production and soil fertility improvement strategies into dairy farming systems particularly in the cooler, frost-prone dairying areas such as Nyandarua district.

The study area

Ol'Joro Orok division is relatively small and largely dominated by smallholder resource-poor farmers owning between 2.9 to 6.0 ha farms. Approximately half of the area is grazing land, with most of the farmers' income coming from dairy cows herds of between 3 and 10 heads (mix breed). Arable farming is based on maize, beans, potatoes and vegetables. Due to declining farm size, the production of wheat, barley and pyrethrum, which were previously the main crops, have decreased. The area has a hilly topography with altitudes around 2,400 meters above sea level. According to Jaetzold and Schmidt (1983), the area is classified as Upper Highland Wheat Pyrethrum Zone. Two major soil types are found in the area; moderately well drained, dark reddish-brown Luvisols ranging from 0.80 to 1.80 m depth, and extremely deep (> 1.80 m), well drained, red to reddish-brown nitisols (Kenya Soil Survey 1982). The soils of the area have a moderate to low fertility. Water-holding capacity is moderate with moderate to good soil work-ability (Jaetzold and Schmidt 1983). The subtropical highland climate of the area is influenced by its proximity to the equator and its altitude (Ojany and Ogendo 1973). Mean annual rainfall is around 980 mm, with rain falling throughout the year and peaks in April and July/August.

Materials and methods

This experiment was carried out (November 2002 to August 2004) in the forage experimental unit at the regional research sub-station Ol'Joro Orok in Nyandarua district. Ol'Joro Orok is a sub-station for the National Animal Husbandry Research Centre (NAHRC)/Naivasha. Thirty-six plots, of 2 x 2 sq. m, were demarcated and prepared (seedbed, shedding, fertilization) for establishment of the test forages: Vicia villosa (referred to in Kenya as common vetch) and Sorghum almum (Columbus grass) which were planted as pure stands or as mixtures in three blocks. The plots in each block were allotted at random to three (3) treatments (Manure [M]; Fertilizer [F] and Control [C]) with four replicates each per block (Figure 1)..

Experimental lay-out

Vicia sativa

Sorghum almum

Mixture

NB:    30 cm wide guard rows between plots and 60 cm wide between Replicatess

One to 5 day old dry sheep manure bulked in a heap outside the kraal and covered with a polythene sheet to minimize effects of either rain, winds or sunshine was used, Diammonium phosphate, (NH₄)₂HPO₄ (DAP: 18 - 46 - 0) and Calcium Ammonium Nitrate CAN (50% N) fertilizers were used to fertilize the soil at the rate of 50 kg/acre (Snijders 1995) which translated to 49.5 g/4 m².

In the absence of rainfall, moderate soil moisture level was maintained manually through a watering can. Watering was done once after every 3 days for the first 2 weeks and once after 5 days thereafter. All plots received equal amount of water.

Sampling for chemical analysis commenced 4 weeks after planting. Samples were harvested 5 cm from the ground. They were chopped using hand operated chuff cutter to small pieces (2 cm long), mixed thoroughly and 2 composite samples (500 gm each) were taken from each test forage plot for laboratory analysis. DM on fresh herbage was determined by drying the samples at 65^o C for 24 h. These samples were then milled and residual moisture determined by drying at 105^o C for 24 h, before  subjecting the samples to chemical analysis.

Ash content was determined by ashing in a muffle furnace at 550^o C for 3 h (Abdulrazak and Fujihara 1999). Crude protein content was analyzed by the Kjeldahl method (%N x 6.25). Acid detergent fibre (ADF), neutral detergent fibre (NDF) and acid detergent lignin (ADL) were determined according to Van Soest et al (1991) and AOAC (1988). Hemicellulose and cellulose were determined as described by Abdulrazak and Fujihara (1999). Mineral profiles were determined according to Varma (1991) and Fick et al (1999).

The obtained values were used to predict forage digestibility (DDM), intake (DMI), gross energy digestibility (%GED), relative feed value (RFV), relative feed quality (RFQ) and quality index (QI). Digestible dry matter (DDM) was calculated from ADF using the equation defined by Grant (1994). At the end of the trial fresh matter yield (FMY) was determined by harvesting the whole herbage in each plot at 5 cm above the ground. The harvested herbage was immediately weighed using field-weighing balance (50 kg). The data collected for 9 weeks (4 - 12) were used to demonstrate variation in growth among treatments.

The data were stored in MS Excel (2000) and later subjected to SPSS (2003) to determine descriptive statistics. One-way ANOVA and t-test were also applied to investigate the statistical differences between treatments.

Results

The results showing the influence of treatment on DM, OM, chemical composition, Yield (tonnes/ha), DDM, GED and quality (RFV; RFQ and IQ) of Vicia villosa intercropped with Sorghum almum harvested at the age of 18 weeks, are presented in table 1 and 2.

The DM,  OM and cell wall components were not different among treatments (P>0.05). A slight elevation in %CP was however observed in pure Vicia villosa stand under M and F treatments. Large differences in yield were observed between Vicia villosa pure stand and that intercropped with Sorghum almum (Table 2). Fresh matter yield (FMY; kgm^-2 or tonha^-1) in Vicia villosa pure stand were higher than that of Vicia villosa in Sorghum almum mixture (Table 2) (P<0.01). Though not significantly different, slight elevations were noted in the derived values (DDM, GED, RFV, RFQ, QI for M and F treatments. This was similarly reflected in estimated Dry matter yield (Ton. DMha^-1) and Organic matter yield (Ton. OMha^-1; P<0.05). Generally DM, OM and cell wall component were not significantly different for Sorghum almum under the 3 treatments (Table 3; P>0.05).

Slightly higher crude protein content was observed for M and F treatments. Mean heights of Sorghum almum under M and F were evidently higher compared to C.  The mean fresh matter yields for M and F within pure stand blocks were significantly higher compared to C (Table. 4).