The influences of breed, sex and age on seasonal changes in haematological
variables of kids (1–4 months old) belonging to Red Sokoto (
In many developing countries of the world, different breeds of goats play vital roles in the economy, religion, nutrition and tradition of poor livestock owners. In Nigeria, the three distinct indigenous breeds of goats are Red Sokoto (Maradi or Savanna Brown), Sahel (West African Long-legged or White Bornu) and West African Dwarf (Egwu et al., 1995). Distribution of the goat breeds indicates that the Red Sokoto goats are common in the Sudanian Savanna region of the Republic of Niger and the Guinea and Sudanian Savanna regions of Nigeria; the Sahel or desert goats are found in the Sahel belt of West Africa (Fig. 1), while the West African Dwarf goats are largely restricted to the coast of West and Central Africa (Gall, 1996; Habibu et al., 2016a). In recent years, adaptation of these breeds of goats, particularly the Sahel goats, to new geographical regions of the country, including the northern Guinea savanna zone and rainforest zone has been observed (Habibu et al., 2017).
Map of West Africa indicating the geographical zones and
transportation of Sahel goats. The map was carved and modified using a
section of the map of Africa obtained from Bioclimatic Regions Map
(
The Guinea savanna climate of West Africa is found north of the rainforest zone, while the Sahel climate is located south of the Sahara (Fig. 1). The northern Guinea savanna zone of Nigeria is a semi-arid region with three distinct seasons, namely the cold-dry (CDS), hot-dry (HDS) and rainy (RAS) seasons (Igono and Aliu, 1982; Dzenda et al., 2015). Like the young offspring of other livestock species, goat kids are confronted with the challenge of extra-uterine environment that is entirely different from that in the uterus, which makes them metabolically unstable and may increase their susceptibility to perinatal diseases, resulting in high neonatal mortality, most especially in thermally stressful seasons (Piccione et al., 2007). In West Africa, pre- and post-weaning kid mortality has been reported to be as high as 10 and 23.1 %, respectively (Turkson et al., 2004). The newborns that survive usually adapt by developing functional changes in almost all organs and systems through a series of tissue-based metabolic and morphologic remodelling (Saddiqi et al., 2011), which greatly affects the survival of the newborn and, if effective, may reduce the incidence of newborn mortality (Nowak et al., 2000). The adaptive response of the newborn to the novel environments may differ due to differences in breed (Sawalha et al., 2007). Since most tropical breeds of goats are non-seasonal breeders, they cycle year-round and parturition may occur in any season of the year. Accordingly, kids may be exposed to all the distinct seasons of the year.
Like other tissues, the blood may undergo series of adaptive remodelling on exposure to the extra-uterine environment in different seasons. Haematological parameters are generally used to monitor and evaluate the health of small ruminants (Fazio et al., 2016). Due to the economic importance of goats, a lot of information is available on their haematology (Tibbo et al., 2004; Zumbo et al., 2011; Piccione et al., 2014). Breed, sex, age and season may greatly influence haematological profile of goats, with season classically increasing or decreasing haematological variables (Egbe-Nwiyi et al., 2000; Tibbo et al., 2004; Zumbo et al., 2011; Habibu et al., 2017). However, there is a paucity of information on the haematological responses of different breeds, sexes and age groups of goat kids in different seasons of the tropics. Findings from the current study may provide valuable information on variations in physiological variables of tropical goats in relation to different endogenous and exogenous factors. Similarly, the study may provide information that could be useful in the management of goat kids in different seasons and in the design of a breeding programme to ensure parturition occurs in seasons that are less stressful. Therefore, the aim of the present study was to evaluate the influence of breed, sex and age on the seasonal changes in haematological variables of goat kids in the northern Guinea savanna zone of Nigeria.
The study was carried out in the Small Ruminant Research Section of the
National Animal Production Research Institute (NAPRI), Ahmadu Bello
University, Shika, Zaria, Nigeria, located at 11
The goat kids were sampled at the peak of the CDS, HDS and RAS during the
months of December, April and July, respectively. A total of 120 goat kids,
aged between 1 and 4 months and with body weight ranging from 2 to 8 kg, were
used throughout the study period. In each season, 40 different sets of kids
(20 kids from each of the two breeds) of both sexes were sampled as follows:
Red Sokoto buck kids (
The study protocol and animal experimentation were reviewed and approved by the Animal Use and Welfare Committee of Ahmadu Bello University, Zaria, and the research followed the international guidelines for animal welfare.
Five millilitres (5 mL) of blood was obtained from each kid once in every
season during the morning hours, between 08:00 and 10:00 (GMT
The morning (09:00–10:00 h) and afternoon (13:00–14:00 h) values of air
temperature and relative humidity, as well as duration of sunshine (h) and
total rainfall (mm), recorded daily during the week the study was conducted,
were obtained from the Meteorological Unit, Institute for Agricultural
Research, Ahmadu Bello University, Zaria, located about 5 km away from the
experimental site. The values of the morning and afternoon
temperature–humidity index (THI) were used to evaluate the level of heat
stress induced by the environment. The formula reported by Ravagnolo et al. (2000)
was used to calculate THI:
The Statistical Package for Social Sciences (SPSS) version 20 was used to
analyse the data. Values obtained were expressed as mean (
Mean values of meteorological parameters during the study period.
Source: Meteorological Unit, Institute for Agricultural Research, Ahmadu Bello University, Zaria.
Effect of season on haematological parameters of Red Sokoto and Sahel buck kids.
Mean values of the same parameter with superscripts
Effect of season on haematological parameters of Red Sokoto and Sahel doe kids.
Mean values of the same parameter with superscripts
Overall effect of season on haematological parameters of male and female Red Sokoto and Sahel goat kids.
Mean values of the same parameter with superscripts
Mean values of meteorological parameters for each season are presented in Table 1. The peak minimum and maximum ambient temperatures were recorded during the HDS in the morning and afternoon, respectively, while the corresponding nadir values were obtained during the CDS. Values of relative humidity at both morning and afternoon hours were lowest during the CDS but highest in the RAS. Duration of sunshine was longest and shortest during the CDS and RAS, respectively. Rainfall was recorded only during the RAS.
Results on the effect of season on haematological variables of buck kids,
doe kids and both sexes are presented in Table 2, 3 and 4 respectively,
while the effect of season on haematological variables in different age
groups of Red Sokoto and Sahel goat kids are presented in Tables 5 and 6,
respectively. Irrespective of sex, significantly higher (
Although no sex difference in haematological parameters of both breeds was
observed in any season, sex variation was observed in the pattern of
haematological changes in different seasons. Except for the significantly
lower RBC during the HDS in buck kids of Red Sokoto, haematological
variables in different sexes of Red Sokoto kids were not affected by season.
This was unlike the Sahel goats, in which the haematological parameters of
buck kids were significantly (
In both breeds of goats, the increase in PCV and RBC and decrease in MCH
and MCHC during the HDS were observed to be more marked (
During the HDS, values of TLC in both sexes of Sahel goats were
significantly lower (
Results on the discriminating powers of the variables are presented in Table 7. The variable with the greatest seasonal discriminating power was MCV, followed by MCHC, MCH, PCV and RBC. Both the clusters formed in the canonical plot representation (Fig. 2) and classification of goats into their predicted group membership (Table 8) showed distinct separation in haematological variables between the CDS and the other two seasons, and close similarity in haematological variables between the HDS and RAS. The classification error was relatively low, while 89.7 % of the kids were correctly classified into their respective groups. The only misclassification observed was between HDS and RAS.
Effect of season on haematological parameters of younger (1–2 months) and older (3–4 months) Red Sokoto goat kids.
Mean values of the same parameter with superscripts
Canonical discriminant functions for the three seasons: 0, CDS; 1, HSD; and 2, RAS.
In comparison to the thermoneutral zone for goats (THI: 65–75; Hamzaoiu et al., 2013), the kids were exposed to cold stress during the morning hours of the CDS (THI: 59.44) and heat stress during the afternoon hours of the HDS (THI: 84.15) and RAS (THI: 82.01). Generally, the haematological parameters recorded in the present study were within the normal range for goats reported by other authors (Jain, 1986; Addass et al., 2010; Zumbo et al., 2011), except for some deviations observed in PCV, RBC, MHC and MCHC during the HDS, particularly in the Sahel goat kids.
The high PCV and RBC recorded during the HDS of the current study, particularly in the Sahel and younger kids, agreed with the findings of previous studies (Sejian et al., 2013; Hashem, 2014). Severe dehydration has been reported in livestock exposed to thermal stress, which ultimately led to an increase in PCV, RBC and Hb (McManus et al., 2009; Sejian et al., 2014; Habibu et al., 2017). Thus, heat stress during the HDS was likely responsible for the high PCV and RBC observed in the current study, apparently due to increased thermoregulatory loss of body fluids. In contrast, other studies reported a decrease in PCV, RBC and Hb during heat stress, which was believed to be provoked by compensatory excess water intake (Mazzullo et al., 2014; Singh et al., 2016).
Effect of season on haematological parameters of younger (1–2 months) and older (3–4 months) Sahel goat kids.
Mean values of the same parameter with superscripts
Structural matrix with discriminant function for the three seasons.
Asterisks (
Since the increase in PCV during the HDS of the present study was not accompanied by a corresponding increase in Hb, decreases in haemoglobin content (MCH) and the cellular concentration (MCHC) were observed. The decrease in MCH and MCHC during the HDS affected both breeds, but with a more than 50 % decrease in Sahel kids during this season compared with the other seasons. Several studies have reported a decrease in blood Hb parameters during the hot season or amid experimental heat exposure. For instance, MCH in goats (Abdelatif et al., 2009) and MCHC in Saanen goat kids (Temizel et al., 2009) and Niamey sheep (Al-Haidary, 2004) were reported to decrease due to high environmental temperature. Oxidative stress due to high ambient temperature may denature and precipitate haemoglobin molecules in the erythrocytes followed by their degradation (Pacifici et al., 1993; Giulivi et al., 1994), contributing to the low MCH and MCHC, particularly in the younger kids and kids of Sahel goats. The significantly low MCH and MCHC may also be indicative of low nutritional status as feed intake has been reported to decrease during heat stress (Srikandakumar et al., 2003; Sejian et al., 2014). Although there was a decrease in MCV, MCH and MCHC during the HDS in the current study, this may not be due to iron deficiency, since the Hb during the HDS was within the normal range for goats (Byers and Kramer, 2010) and comparable to other seasons.
In the current study, the values of MCV decreased during the HDS in comparison to the CDS and RAS, particularly in Sahel goats, and also showed the strongest discriminating power in distinguishing the kids based on the prevailing season. The finding agreed with those of Ribeiro et al. (2015) in Brazilian Azul goats and Mazzullo et al. (2014) in cattle, who also reported a decrease in MCV in animals exposed to natural heat stress. However, the finding disagreed with that of Abdelatif et al. (2009), who reported higher MCV values in Nubian goats of Sudan during summer than in winter. The decrease in MCV (average size of the erythrocytes) during the HDS may be due to an increase in the number of erythrocyte membrane vesicles formed and shed from the erythrocytes as a result of elevation in body temperature, with a resultant decrease in the size of the parent erythrocytes (Foller et al., 2010; Moore et al., 2013; Habibu et al., 2017). Thus, it is logical to infer that a decrease in MCV may have the potential of being used as an indicator of heat stress in tropical goats naturally exposed to heat stress.
The dramatic change in some haematological parameters of the younger goat kids compared to the relatively stable parameters in older kids observed during the HDS in the current study indicates that the former were more susceptible to heat stress than the latter. The finding agrees with that of Haque et al. (2013), in which the effect of thermal stress was higher in young buffalos, with an alteration in TLC of young buffalos, while the value was stable in the adults.
Percentage of kids classified into the three seasons.
Previous studies in tropical (Banerjee et al., 2015; Singh et al., 2016) and arid (Srikandakumar et al., 2003) climates demonstrated diverse physiological responses of different breeds of goats and sheep to changes in meteorological parameters with some breeds showing better thermoregulation then others. Similarly, results of the current study revealed remarkable influence of breed in the seasonal changes in erythrocytic variables in both sexes. The kids of Red Sokoto goats apparently employed more efficient adaptive and survival strategies than Sahel goat kids, particularly during the HDS, which prevented the dramatic change in haematological parameters that was observed in Sahel goats. The higher magnitude of the increase in PCV and RBC in Sahel compared with Red Sokoto kids during the HDS may imply higher thermoregulatory fluid loss in Sahel kids, probably due to higher respiratory rate (Habibu et al., 2016b). This difference in breed response may be due to variation in thermoregulatory plasma fluid dynamics, as higher plasma volume, indicated by decrease in RBC and Hb has been reported in adult bucks of Red Sokoto, while an increase in PCV and RBC was observed in Sahel goats during the HDS when compared with CDS and RAS (Habibu et al., 2017). The ability of Red Sokoto goats to maintain relatively higher plasma volume, despite the expected thermoregulatory fluid loss during heat stress, indicates a higher level of adaptation to the tropical savanna and may, at least in part, explain why they naturally survive in diverse geographic locations (Sudan and Guinea savannas) and are the predominant breed of goats in Nigeria. The relatively stable haematological response demonstrated by Red Sokoto goats in the current study was probably because the breed is indigenous to the northern Guinea savanna region of Nigeria. This is unlike the Sahel goats, which are indigenous to the Sahel region of West Africa. Both regions have high ambient temperatures, but the Sahel region has a lower relative humidity due to its closeness to the Sahara (Fig. 1; Nicholson, 1995). Although a previous study reported higher erythrocyte membrane integrity in Sahel than Red Sokoto kids during the HDS (Habibu et al., 2016a), the higher relative humidity in the Guinea savanna of Nigeria may be a negative factor influencing thermoregulation of Sahel kids in the geographical area and may be responsible for the changes observed in erythrocytic parameters observed during the HDS (Habibu et al., 2017).
The current study revealed a remarkable influence of sex on the seasonal changes in erythrocytic variables in both breeds. The seasonal fluctuations in erythrocytic variables were better profound in buck kids than doe kids of both breeds, suggesting that the latter adapted more to the prevailing ambient conditions. Similarly, a previous study reported greater hazard during all postnatal periods in male compared with female lambs (Sawalha et al., 2007). In addition to other factors, a relatively poor homeostasis in the buck kids may, at least in part, contribute to the low survival rate generally reported in males compared with females among various breeds of goat kids (Awemu et al., 1999; El-Abid and Abu Nikhaila, 2009) and lambs (Turkson and Sualisu, 2005). Although more studies are needed to substantiate this hypothesis, these corroborative findings may imply that the female newborns of small ruminants have more efficient mechanisms of responding to postnatal challenges than their male counterparts.
The low TLC in Sahel as compared with Red Sokoto kids during the HDS in the current study supports the findings of Haldar (2012), who reported a decrease in TLC in goats exposed to heat stress. Similarly, this agreed with the report of Fadare et al. (2012), who indicated that heat stress suppressed the immune status of sheep that were more susceptible to thermal stress in the hot-humid tropics. The finding further demonstrates that the Red Sokoto kids were better adapted to the northern Guinea savanna zone of Nigeria than the Sahel kids.
In the current study, lower LYMP was observed during the RAS as compared with the HDS in the Red Sokoto goat kids. In a related study, higher LYMP was reported in Dhofari goats during the summer compared with the winter (Al-Busaidi et al., 2008). The comparable level of NEUT in all groups of kids in the current study was similar to that reported in Nubian goats by Abdelatif et al. (2009), but disagreed with that of Temizel et al. (2009), who reported a decrease in NEUT in heat-stressed goat kids.
In agreement with the findings of a previous study in Garfagnina goats (Ribeiro et al., 2015), the current study also reported strong discriminant power in MCV and PCV. This finding indicates that such haematological parameters (MCV MCHC, MCH, PCV and RBC) are influenced by the three seasons through thermoregulatory mechanisms that cause different physiological effects, and thus they vary markedly in different seasons. However, both the canonical plot representation and the group membership prediction showed that the CDS imposed distinct effects on haematological variables from those by the HDS and RAS which were similar. This was probably due to the low THI during the CDS and high THI during the HDS and RAS, which may induce cold stress and heat stress, respectively (Habibu et al., 2016b).
Season significantly influenced haematological variables, with the impact of heat stress during the HDS being more profound in kids of Sahel goats, and in younger and male kids of both breeds. The marked seasonal fluctuations in haematological variables of Sahel kids compared to Red Sokoto kids may indicate that the Red Sokoto goats, which are indigenous to the study area, were better adapted to the seasons. Moreover, the TLC was lower in Sahel goats compared with the Red Sokoto goats during the HDS, indicating a higher susceptibility of Sahel goats to heat stress in the study area. These factors necessitate the need for additional support such as provision of ad libitum drinking water and protective shading to the young kids, and especially the kids of the Sahel goats, during the peak of the HDS. It is suggested that the breeding programme be designed in such a way that the hot season coincides with the time when the kids. The influence of season on haematological parameters was more pronounced than those of breed, sex and age, hence the need to consider the environmental conditions in which goats are reared in defining reference intervals of haematological parameters. The higher risk of postnatal period of buck kids needs further investigation so as to know whether there is the need for a special managerial provision for the buck kids during thermal stress.
All authors made essential contributions to all steps of the experimental design and manuscript preparation and also approved the final manuscript. However, special contribution was made by Buhari Habibu, Mohammed Kawu, Hussaina Makun and Tagang Aluwong in designing the work. In particular, Buhari Habibu, Lukman Yaqub and Hussaina Makun carried out the field work. Buhari Habibu, Lukman Yaqub and Hajarah Buhari did the laboratory work and statistical analysis. Buhari Habibu, Lukman Yaqub, Mohammed Kawu and Hajarah Buhari wrote the manuscript.
The authors declare that they have no conflict of interest.
The Management of NAPRI, Ahmadu Bello University, Shika, Zaria, granted us the permission to use the institution's animals. The staff of the Small Ruminant Research Programme, NAPRI, and Department of Veterinary Physiology, Ahmadu Bello University, Zaria, gave technical assistance. J. O. Ayo and M. Tauheed assisted in drafting the manuscript. Edited by: M. Mielenz Reviewed by: F. Fazio and one anonymous referee