To evaluate a sheep for meat production potential, growth performance is an important character which determines the overall productivity of the flock and the economic return from sheep production enterprise. Although heredity dictates the maximum amount of growth and development, nutrition along with other environmental factors govern the actual rate of growth and extent to which development is attained [10] [11]. Nevertheless any additional input than required for normal physiological needs may not induce growth beyond the genetic potential of the animal [12].

Washera sheep supplemented with 300 g/day of different forms of white lupin to Rhodes grass hay basal diet gained between 16 to 25 g/day [13]. This is lower than the values reported in other studies of the same sheep (Table 1). A higher average daily gain (ADG) of 73 - 91 g/day has been found in a study conducted by Likawent et al. [14] using Washera breed supplemented with sweet blue lupin seed as a substitute for concentrate mix (453 g/day/head). Yearling Washera sheep grazing natural pasture supplemented with 300 to 700 g/day (grass pea and maize grain at a ratio of 4:1 mixture) are reported to grow at the rate of 88 - 126 g/day [12]. The authors recommend feeding 500 g/day concentrate mix as optimal level.

A comparative study conducted by Getahun [15] using Blackhead Ogaden (BHO) and Afar sheep supplemented with increased concentrate levels (150, 300, and 450 g/d) recorded weight gain in the range of 33 to 65 g/day and 37 to 79 g/day for BHO and Afar sheep, respectively with no significant difference between the two breeds. The effect of increasing levels of protein (20% to 35% CP) and energy (1.75 to 4 MJ/day) supplements have also been investigated using BHO sheep [16]. In this study, ADG between 60 and 95 g/day were recorded. The figures are within the range of 30 to 116 g/day for BHO sheep supplemented with different levels of soybean meal to natural pasture hay [17]. Afar sheep fed Rhodes grass hay and supplemented with replacing commercial feed with Prosopis juliflora pods and leaves, attained daily body weight gain of 24 to 55 g/day [18]. The use of graded levels of wheat bran as supplement with basal diet of urea treated teff straw supported growth rate of 64 to 88 g/day for Afar sheep [19].

A growth rate, 40 g/d for Horro sheep supplemented with dried and ground Vernonia amygdalina leaves and ground sorghum grain mixture has been reported [20]. A similar growth rate of 24 to 47 g/day was reported for Adilo sheep supplemented with Enset (Ensete ventricosum), Atella and their mixtures at 300 g/day [21]. Higher value (117 g/day) than these have been reported for Horro

BHO = Blackhead Ogaden, HH = Hararghe Highland, ADG = average daily gain, SBW = slaughter body weight, HCW = hot carcass weight, EBW = empty body weight. Note: The range values represent results obtained from low and high supplement level.

sheep supplemented with 400 g/day concentrate (49.5% noug cake, 49.5% ground maize grain and 1% salt) to Rhodes hay basal diet [22]. Arsi-Bale sheep supplemented with 300 g/day with linseed cake and/or wheat bran gained 69 - 104 g/day [23]. Ermias et al. [24] also found ADG of 55 - 88 g/day for Arsi-Bale sheep fed faba bean haulms as a basal diet and supplemented with different proportions of barley bran and linseed meal.

In a study conducted by Aschalew and Getachew [25] the ADG observed in Farta sheep supplemented with different form of Lathyrus sativus was 47.8 to 65.6 g/day which is higher than 25 to 35 g/day gained when the same sheep breed was fed graded level of rape seed cake and rice bran mixture [26]. The growth rate of Hararghe Highland (HH) sheep supplemented with concentrate mixtures to a basal diet of urea-treated maize stover ranges from 32 to 63 g/day [27]. This is lower than 62 to 77 g/day gain reported by Tagaynesh [28] for the same breed of sheep. For Menz sheep fed grass hay and supplemented with 400 g/d concentrate mix, ADG of 45 g/day has been recorded [29].

Generally past feeding trials (Table 1) reported a maximum ADG of 126 g/day for Washera sheep supplemented with 300 to 500 g/day Lathyrus sativus and maize grain to natural pasture grazing as a basal diet [12] and the growth rate increased as level of supplement increases up to its genetic limit. The variation in growth rate within the same sheep breed could be attributed to the low amount of the supplement in some of the studies which is insufficient to the animal to support its genetic potential for growth. This is due to differences in nutrient concentration and characteristics of the supplements used and partly because of the response of the sheep breed to various feed types.

Most of the indigenous Ethiopian sheep in various feeding system may not attain the final weight between 25 to 30 kg in one year required by live animal exporters. However, there is too much potential for indigenous sheep to attain this weight with better feeding and health care [12] [15] [16] [29] [30] (Table 1). However, despite sizeable information upon the response of sheep to various types of supplementary feeding, their full growth and other production traits for the majority of sheep breeds of the country are not well studied. Therefore, in future research work emphasis should be given to explore the genetic potential for various production traits of indigenous sheep breeds of the country.

The carcass production potential of indigenous sheep in Ethiopia is between 7 to 18 kg/head (Table 1) and increased as supplement level increases. Hot carcass in the range between 6 to 17 kg has been reported for Washera breed (Table 1). The higher value (13 - 17 kg) of hot carcass weight (HCW) was reported by Tesfaye et al. [12] when grazing Washera sheep were supplemented with 300 to 700 g/day concentrate mix and attain final weight of 29 to 33 kg. On the contrary, different forms of white lupin (local variety) supplement to Rhodes grass hay basal diet to Washera sheep resulted in 6 kg HCW [13]. A wide variation among studies (Table 1) in HCW and SBW implies that the supplement is insufficient to support the genetic potential for carcass production due to the quality and quantity of the supplement. Wilson [31] in his review indicated that feeding is one of the most important factors to influence meat production and carcass quality of small ruminants.

Horro sheep fed different types of supplement produced 8 to 9 kg HCW [32] [33]. The use of concentrate mixture (50% WB, 30% maize, 20% cotton seed cake) supplement with basal diet of natural pasture hay can yield about 15 kg HCW by Horro sheep [29]. In another study, HCW up to 18 kg has been recorded in various ages and under different feeding regimes for Horro sheep [34], which is among the highest HCW recorded for Ethiopian indigenous sheep.

The HCW recorded for BHO sheep fed urea molasses and urea Attela blocks is about 5 to 7 kg [35]. This is close to the average HCW of 6 to 8 kg [36] but lower than 10 to 12 kg [16] and 6 to 11 kg [17] reported for BHO sheep fed different types of feed. In the work of Facil et al. [37], higher HCW (13 kg) has been reported for one and half year BHO sheep fattened for three months following a growth experiment of 90 days. Generally from the feeding trials, the HCW reported so far for yearling BHO sheep fed various types of basal diets and supplements are in the range of 7 to 13 kg (Table 1). A HCW of 10 to 12 kg was reported for Afar sheep by different researchers when fed various types of basal and supplement feeds (Table 1).

The average HCW for supplemented Arsi-Bale sheep are between 8 and 12 kg (Table 1). Carcass production potential of Arsi-Bale sheep increased as concentrate supplement level increases. Arsi-Bale sheep supplemented with 200 to 400 g/day concentrate mix to urea treated barley straw basal diet had produced HCW between 8 to 10 kg [40]. Hararghe Highland (HH) sheep fed grass hay and supplemented with sole wheat bran or its mixture with safflower seed cake had HCW of 9 to 10 kg [28]. The use of Ficus sur fruits and oat grain as supplement for HH produced HCW of 6 to 8 kg [45]. Similarly, urea treated wheat straw as basal diet supplemented with Ensete ventricosum, Atella and their mixture fed to Adilo sheep result in 6 - 8 kg HCW [41].

Generally, the past studies confirmed that at yearling age most of the indigenous Ethiopian sheep consumed various types of supplement feed produced carcass weight of 8 - 12 kg required by the export abattoirs to Middle East countries. However, there is potential for indigenous sheep to attain higher weight of carcass with better feeding [12] [34]. Moderate to high heritability estimates for slaughter (0.46 ± 0.15) and carcass weight (0.48 ± 0.15 [30] coupled with the traits increase with increasing level of supplement (Table 1) suggests that, improvement could be possible through selection and improved feeding.

Dressing percentage (DP) is an important measure of the potential yield of meat from an animal. According to the review by Ruvuna et al. [51], dressing percent is known to be affected by breed, age, castration and it is also highly affected by feeding and degree of fattening. Ewnetu et al. [30] studied the effect of breed on some carcass and non-carcass components of Horro and Menz sheep of Ethiopia. According to the authors, the two breeds had similar slaughter and carcass weights but have significantly different DP as slaughter body weight basis, which were 40% for Horro and 41% for Menz (Table 1), and the difference was ascribed to the higher gut fill in Horro sheep. The two breeds also significantly differ in edible non-carcass components, which were 4.3 kg for Menz and 4.6 kg for Horro sheep. These estimates represent about 21% and 23% of empty body weight in the Menz and Horro breeds, respectively. In another study, DP (SBW basis) of 49% and 48% has been recorded for Menz and Horro sheep, respectively in a trial compared the two breeds [29]. But, the result of the study did not show significant breed difference for DP since the higher SBW is offset by higher gut content in Horro sheep.

A comparative study was conducted to evaluate the effect of concentrate level and breed on carcass characteristics using BHO, Hararghe Highland (HH), and their F1crosses with Dorper sheep [47]. The study demonstrated significant breed and dietary level effect on most of the carcass parameters in general and in SBW, HCW, and DP in particular. However, significant difference was not observed between HH and BHO sheep. According to the study, DP in the range of 41% to 46% and 52% to 58% SBW and EBW, respectively were recorded.

As indicated in Table 1, the DP estimated for Ethiopia sheep ranged between 34% and 49% and 44% and 60% SBW and EBW basis, respectively. The values, 41% to 46% recorded for Ovin Martinik tropical hair sheep [52], 42% to 50% documented for ten Iranian native fat-tailed sheep breed [53], and 42.7% to 44.7% SBW basis recorded for Tanzanian long fat-tailed castrate sheep [54] and 56.5% to 61.0% as EBW basis reported for West African dwarf sheep [55] are within the range reported for the Ethiopian sheep.

The carcass quality of Ethiopian indigenous sheep has not been well studied in the past. Most of the studies were focused on increasing carcass quantity except few research works conducted on Horro and Menz breeds [29] [30] and on BHO, HH and their F1crosses with Dorper sheep [56]. On the other hand, meat production is shifting from a focus on quantity to quality in response to consumer demands [57]. Therefore the existing serious lack of information with regard to meat quality traits in Ethiopian indigenous sheep should be addressed in future research works.

It is well established that the main parameters of carcass quality are lean and fat proportions, lean: bone ratio and saleable meat yield because of their effect on the commercial value of sheep carcasses [58]. For these traits, significant variation is reported to exist among the two indigenous sheep breeds of Ethiopia [30]. According to the author, Menz sheep have significantly higher carcass fat (8.7% vs 5.9%), lean: bone ratio (2.7% vs 2.4%) but lower total saleable meat yield (carcass + edible non carcass component) than Horro sheep. This difference is attributed to breed effect as described by Ewnetu et al. [30]. With regard to chemical composition of carcass, Diriba et al. [45] reported chemical fat 4% to 7%, CP 19% to 21% and moisture 69% to 72% from longissimus dorsi muscle of HH sheep, which are within the range estimated for other sheep breeds found elsewhere [45].

Along with breed effect, the effect of nutrition on carcass composition and conformation in indigenous sheep of Ethiopia and their F1 crosses with Dorper sheep has been documented [56]. According to the study, leaner carcass (83.6% vs 51.4%), lean: bone ratio (3.5 vs 2.6), and lean: fat ratio (7.6 vs 5.2) were registered from lambs consumed 150 g/day of concentrate supplement as compared to those lambs consumed 350 g/day. With regard to total bone and fat percentage, the differences between the dietary levels were not apparent. Among breeds evaluated, Dorper × HH had significantly higher percent lean carcass (74.9% vs 61.5%) and lean: fat ratio (7.8 vs 4.7) than BHO sheep but pure HH breed and Dorper × BHO sheep had similar values. The result also revealed that, carcass with attractive conformation was obtained at 350 g/day of concentrate supplement as well as on Dorper × HH and BHO breeds.

Ethiopian hair sheep skin traditionally has a very good reputation for quality in the world leather market due to their fine grain and compact nature. It is among the main commodities used to earn foreign currency in the country [59]. Research results showed that breed, nutrition, age and sex affect chemical and physico-mechanical quality of skin [60] [61] [62]. However, there is limited empirical information on the physical and chemical quality of skins or leathers produced from different indigenous sheep breeds of Ethiopia.

The study by Tsegay et al. [56] evaluated the effect of breed and concentrate level on physico-mechanical and chemical skin quality of BHO, HH and their F1 crosses with Dorper sheep supplemented with two dietary concentrate levels (150 and 350 g/day/head) to a basal diet of natural pasture hay. According to the study, except skin thickness (only significant for diet), all other physico-mechanical skin/leather quality traits such as tensile strength and percentage elongation, tear strength, and grain strength were not significantly affected (P > 0.05) by level of supplementation and breeds. Similarly, chemical qualities of leather such as fat and chrome-oxide contents were not affected by both factors. In this study, although level of supplementation and breeds didn’t show significant difference on the physico-mechanical skin quality, better qualities were obtained at 350 g/day/head of concentrate supplementation. On the other hand, numerically better chrome-oxide content was recorded at 150 g/day of supplement than 350 g/day due to low fat content of leather as the two are inversely related. Among the breeds, the leather obtained from BHO and HH had relatively good tensile strength, thickness, grain strength, and extensibility than their crosses. Snyman and Jackson-Moss [63] reported that lamb’s genotype affected physico mechanical skin quality in comparative study of ten South African sheep breeds. Ebrahiem et al. [64] in Sudan also observed significant breed effect on the chemical and physico-mechanical skin quality. The effect of different roughage to concentrate ratio and amounts of supplement has also been investigated using BHO sheep [37]. In this study, diet has significant effect on skin thickness, moisture content (low), tear strength, tensile strength, percentage elongation, and grain strength in favor of high supplement but the difference was not apparent on fat and chrome-oxide contents.

Age at first lambing (AFL) is an important reproduction trait as greater population turnover and more rapid genetic progress can be obtained when sheep produce their first offspring at an earlier rather than later age. Early maturing females are known to have a relatively long and fruitful reproductive life.

Data on average AFL for most of the indigenous sheep in Ethiopia are between 11 and 16 months (Table 2) and most sheep breeds tend to have their first offspring before they are two years old. The AFL values found in most of Ethiopian sheep are within the range of 11.2 to 22.8 months reported for sub-Sahara

AFL = age at first lambing; LI = lambing interval, BHO = Blackhead Ogaden; on farm= under farmers management, on station= in research station (relatively under good management).

African sheep breeds [65] but slightly lower than 18.8 to 22.6 month documented for West African Dwarf, Djallonke, sheep [66]. The AFL (10 - 11 month, Table 2) reported for BHO sheep is longer than the values documented for most of the indigenous sheep in Ethiopia. This is consistent with 24.4 month reported for Balochi sheep in different ecological zones of Balochistan, Pakistan [67] and appears to be due to the seasonal scarcity of feed resources.

Among the most important parameters affecting AFL, genotype and various management components [65] are the main one. Management, with regard to whether breeding is controlled or uncontrolled also tends to affect the age at first parturition [68]. The author observed delayed first parturitions in sheep that were bred in controlled breeding systems compared with sheep reared under uncontrolled systems, where rams are free to run with females and serve them at the earliest possible display of oestrus. Poor nutrition and disease can leads to delayed age at first lambing through limiting early animal growth. Year and season of birth in which the ewe lamb was born influence age at first lambing through their effect on feed supply and quality.

The results from previous studies generally show that AFL of Ethiopian sheep seems to have wide variation within and among breeds. This implicates the presence of huge opportunity to improve this trait through improved management and selection.

Lambing interval (LI) is defined as, the number of days between two consecutive parturitions. Results from the past research showed that, the LI for most Ethiopian indigenous sheep under traditional management are between 7 and 10 months (Table 2). These differences might be due to variation in breed, season, sex of lamb, type of birth (single, twin), parity [39] [66] [69], and post-partum body weight and management practice [70]. The LI documented for Ethiopian sheep is within the range of 7 to 12 months reported for sub -Saharan African sheep [65]. A study conducted by Abegaz et al. [71] has indicated the possibility of indigenous Ethiopian sheep to have more than three lambing in two years time. Similarly, [72] [73] [74] and Fsahatsion et al. [75] reported 7 - 9 months of LI for some indigenous sheep breeds in Ethiopia. Similar to Ethiopian sheep, three lambing in two years time are reported for West African Dwarf, Djallonke, sheep [66] and Balochi sheep in Pakistan [67].

Generally from the previous research result it can be concluded that through the provision of adequate diet and proper flock management, it is practically possible to attain three lambing in two years in most Ethiopian indigenous sheep.

Litter size (LS) or prolificacy is defined as the number of progenies born per parturition [65]. It is one of the most important reproductive parameters affecting the productivity of a dam and thereby the profitability of a farm. Litter size is a trait that depends on ovulation rate and is affected by the number of fertilized oocytes. The higher the ovulation rate, the more oocytes will be available for fertilization during the estrous and increase the possibility of bigger litters [81].

The main factors influencing ovulation rate in the ewes are breed and level of nutrition while season and age related factors are also important. Ovulation rates vary within and among breeds [82], increase with ewe age up to 6 - 7 years [83]. It is also affected to a large extent by ewe body weight at mating which itself is linked to nutrition. Poor nutrition during service period leads to reduced ovulation rates and increase embryonic mortality and consequently decrease litter size [70]. Ibrahim [84] reported that litter size can be increased 10% to 40% by improving the nutrition management of the pre-mating ewe or by treatment with gonadotropins. According to Abegaz et al. [85], with respect to weight of ewes at mating, litter size increased by 2.5% for each kilogram increase in weight at mating in Horro sheep. Litter size increased with age to about four years of age and remained somewhat similar thereafter [84].

The least squares mean of litter size reported by various workers for different indigenous sheep breeds of Ethiopia are presented in Table 3. It varied from 1.01 in BHO [79] to 1.7 in Arsi-Bale breed [72]. The LS reported for Afar, BHO, and to some extent for Menz sheep are smaller than the values documented for most of the indigenous sheep in Ethiopia. This is consistent with the results of other studies [86] and appears to be one mechanism of adaptation to the harsh environmental conditions and to the seasonal scarcity of feed resources. Most estimates of litter size in tropical sheep range from 1.0 to 1.5 indicating that twinning rate is generally between 0% and 50% [84]. This trait in West African sheep breed was estimated at 1.24 ± 0.33 lambs [87], 1.149 ± 0.031 lambs in Afshari sheep breed [39]. Also litter size in sub-Saharan African sheep was 1.01 to 1.487 [65] with Arab sheep in the semi-arid zone of Chad showing the lowest values.

Generally from previous studies, it can be concluded that most Ethiopian sheep breeds have an ability to provide twining birth under traditional management system. Thus, there is huge opportunity to improve this trait through selection and improved management.

Lambs with higher birth weights (BW) are expected to grow faster in life. BW is strongly influenced by breed [2] [88] [89] [90]. It is also affected by sex of lamb, birth type, age of dam, feeding level, season of birth and production system.

Data on average BW for indigenous sheep breed in Ethiopia are summarized in Table 4. The reported BW of Ethiopian indigenous sheep breed in traditional and in improved management are between 2 and 2.9 kg. The BW (2.01 to 2.4 kg for Menz and 2.4 to 2.9 kg for Horro sheep) reported in improved management showed wide variation among studies. These difference could be arise mainly

LS = litter size, BHO = Blackhead Ogaden; on farm = under farmers management, on station = in research station (relatively under good management).

BW = birth weight, WW = Weaning weight, PWMR = pre-weaning growth rate; PWMR = pre-weaning mortality rate; BHO = Blackhead Ogaden; on farm = under farmers management, on station = in research station (relatively under good management).

due to varying climatic conditions (amount of annual rainfall) in years affecting the availability of pastures to the ewes carrying lambs as well as variation in supplementary feed offer. The differences in birth weight among lambs born with the same breed were attributed to differences in selection of rams and ewes [91]. The agro-climatic condition in which the experiment station is located could also be one source of variation. This is partly consistent with the results of other studies [92] who obtained 2.24 to 2.36 kg, 1.92 to 2.22 kg and 1.98 to 2.15 kg for Barri, Black Boni, and Whit Boni sheep breeds’ of Yemeni, respectively within the year 1992 to 2009.

The weaning weight (WW) or weight at the age of three month and pre-weaning growth rate (PWGR) of indigenous Ethiopian sheep breeds reported by various researchers are presented in Table 4. It varied from 8 to 12 kg and 58.2 to 134.4 g/d for WW and PWGR, respectively. The reason for variation in WW and PWGR among genotypes in the previous studies was partly because of difference in growth potential among breeds [3] [89] [90] [93]. It can also be due to differences in birth weight. Yilmaz [94] has reported a positive correlation between birth weight and subsequent live body weight development in sheep. Similarly, in the work of Tibbo [3] and Lakew et al. [90] indicated that lambs heavier at birth grow faster than light weight lambs.

Weaning weight and ADG are also known to be affected by the mothering ability of the dam [29]. This is because there is more dependency on the milk production of the ewe as the lamb meets most of its requirement through suckling rather than on forage at the early growth phase. The environment under which the animals are maintained including the availability of adequate feed supply in terms of both quantity and quality are also one source of variation [95]. The average WW (Table 4) tend to be closer in the ranges of 9.28 to 12.47 reported for Barri Black Boni and White Boni breeds of Yemeni [92].

Pre-weaning mortality rate (PWMR) refers to death occurring between births and weaning of lambs born alive including neonatal deaths [65]. The average PWMR of most Ethiopian indigenous sheep vary from 8% to 60% (Table 4), which is closer to 10% to 44% variation reported for sub-Saharan African sheep [65] and 12% to 50% range for tropical sheep [102]. The previous studies generally indicated that mortality is major constraint to improve productivity of sheep in Ethiopia.

Studies indicated that PWMR in the lambs is influenced by genotype, birth weight, litter size, and season while sex and parity are also important. Mukasa-Mugerwa et al. [88] working on indigenous Ethiopian Menz and Horro sheep reported significantly lower proportion of Menz lambs died before 1 year of age (28%) than the Horro lambs (59%) when the ewes were mated by single sir. Similarly, a study conducted in station on the same sheep breed show that, the survival rate between birth and weaning (90 days) for Menz lambs (89%) was significantly higher than that for the Horro (76%) [29].

Many studies indicated the negative relationship between birth weight and pre-weaning lamb mortality [2] [88]. Nowak and Poindron [109] identified curvilinear relationship between birth weight and most death of lambs. The chances of lamb survival tend to reduce considerably when the lamb is 2 kg or less [2] [110]. This is because lambs with low birth weights have lower energy reserves, lowered thermoregulatory capability, and therefore less able to withstand harsh environmental conditions. Mukasa-Mugerwa et al. [110] have recommended that lambs have to be born with birth weights of 2.0 kg or more to have a peri-natal survival rate of 90%. Therefore, to ensure lamb survival strategic energy and protein supplementation to ewe during the gestation period and at the time of lambing should be given due attention to improve birth weight of the offspring as well as the milk production of the ewe. Generally, breeding and management practices should aim at heavier weight at birth.

Litter size and dam parity influence PWMR through their effect on lamb birth weight. Dam parity also affects PWMR through mothering ability (milk production). Lambs from multiple births are usually weak and of low weights at birth as a result of physiological starvation in the uterus and this situation is even more critical if dams are not producing enough milk [29]. Birth weight and milk production potential of a dam increase as parity increases. Research report indicated that lambs born by younger ewes have depressed birth weight due to relative competition for nutrients between the still growing ewes and developing foetus [91].

As indicated in Table 3 there is high possibility of getting twin birth in Ethiopian indigenous sheep. Therefore, local farmers should be encourage to adopt discriminate supplementary feeding of the ewes (the pregnant, the single, and twin bearing ewes) or the ewe should be selected against multiple birth if supplementary feeds are not in place to curb pre weaning mortality through high birth weight.

Various studies indicated that the presence of sex difference in lamb survival is in favor of female lambs [2]. Low survival in male lambs than in female could be associated partly with hormonal effect on the immune function. This was indicated by Schuurs and Verhuel [111] that castrated males had similar risk with females and lesser risk compared to non-castrated. Norwak [112] reported, in twin born lambs that, the dam recognition ability of female lambs was superior to their male counterparts after separation. Dwyer [113] found out that the male lambs were slower to stand and suck than the female lambs in suffolk sheep breed, but not in black face breed. Therefore some level of prenatal treatment in favor of male lambs may be necessary to improve prenatal survival.

Seasonal influence on lamb mortality has been well established through its effect on feed availability. This is because sheep in tropics in general and in Ethiopia in particular are primarily depend on natural pasture grazing and crop residue whose supply and quality fluctuates seasonally. In Ethiopia, feed is relatively better both in quality and quantity in the rainy season and the reverse happen in the dry season. Consequently, lambs born in the wet season had higher birth weight, pre-weaning average daily gain and high survival than their contemporaries born in the dry season [2]. Therefore adjusting the breeding season to feed availability could be one possible solution. However, in Ethiopia breeding is not seasonal and uncontrolled.

Generally, the degree to which lambs survive to a marketable age and/or to a sustainable reproductive life is one of the key indicators of the efficiency of a sheep production system. Therefore to ensure lambs survival, improving nutritional conditions of the pregnant ewes and newly born lambs coupled with disease and parasite control measures should be adopted by local farmers. The concerned body should provide necessary support for farmers to reduce pre-weaning mortality in indigenous sheep of Ethiopia.