Animals, management and experimental treatments

The study was carried out at the Department of Animal Sciences, University of Göttingen, Germany between November 2015 and January 2016. Twelve non-pregnant Boer goats aged between 1.5 and 7.5 years with an average body weight of 50.5 ± 9.0 kg were involved. Animals originated from the breeding herd of the Department. Animals were transferred to the experimental pens 2 weeks before the start of the trial for acclimatization. Animals were kept individually. As described in a previous experiment (Runa et al., Reference Runa, Brinkmann, Riek, Hummel and Gerken2019), three identical rooms, subdivided into four individual straw pens each (each pen 3.0 m²) were used. Each pen was equipped with an individual feed trough (diameter 53 cm, approximate capacity: 3 kg hay) and two water buckets (diameter 28 cm, 10 l capacity per bucket), which were placed at each side of the feed trough to allow free choice between contents. Animals had ad libitum access to chopped hay, salt lick and water (fresh and saline water) throughout the experimental period. The rooms were equipped with windows to provide natural light. The lighting schedule was kept constant at 14 h light : 10 h dark, with additional artificial lighting from 0630 h until 2030 h.

Throughout the study, a two-choice preference test (Goatcher and Church, Reference Goatcher and Church1970a) was used. The study was conducted in four phases (Figure 1). In the control phase (phase 1), only fresh tap water was supplied in two identical buckets for 1 week to record individual water intake from each bucket. In phase 2 (sensitivity test, 2 weeks), water with ascending salt concentrations (0.25%, 0.5%, 0.75%, 1.0%, 1.25% and 1.5% NaCl) was offered in one container and unsalted tap water in the other. Each salt concentration was tested for two consecutive days. This procedure allowed to determine the individual salt sensitivity. During the third phase (adaptation, 4 weeks), goats were stepwise habituated to saline water by offering only saline water in both buckets. The saline water of the lower concentration was offered in one container and the salt water with higher concentration in the other (Figure 1). The concentrations were gradually increased between 0% and 1.5% NaCl. The highest concentration was close to the rejection threshold (RET) described by Bell (Reference Bell1959) and Goatcher and Church (Reference Goatcher and Church1970a). Each combination of salt concentrations was tested for four consecutive days during phase 3 (adaptation). Subsequently, in phase 4 (sensitivity re-test, 2 weeks), the same treatment as in phase 2 was repeated to test for differences in discrimination thresholds after the habituation period.

Figure 1 Experimental design with Boer goats based on a two-choice preference test: provision of different concentrations of salt in drinking water during the different phases of the experiment. Two water containers were placed at each side of the feed trough for ad libitum intake. The positions of the concentrations were changed daily at random in order to avoid a bias due to position effects. The same combination of concentrations was offered for two (phases 2 and 4) or four (phase 3) consecutive days, respectively.

The water buckets were replenished with test solutions daily and the positions of the concentrations were changed daily at random in order to avoid a bias due to position effects. The individual water intake from each container was determined daily. The average Na⁺ content of tap water was 7.55 mg/l. Saline water was prepared by adding a defined amount of salt (EscoSiede-Speisesalz, Hannover, Germany) with 99.8% NaCl purity to tap water. The accurate salt concentration provided was measured by using a refractometer (HI96821 refractometer, Hanna Instruments Inc., Woonsocket, RI, USA) (Runa et al., Reference Runa, Brinkmann, Riek, Hummel and Gerken2019).

Body weight, body condition score, water and feed intakes

As described in Runa et al. (Reference Runa, Brinkmann, Riek, Hummel and Gerken2019), individual body weight was recorded every 2^nd week with a mobile scale (Salter Brecknell LS300, capacities: 300 kg, resolution: 0.2 kg, Salter Brecknell, Smethwick, West Midlands, UK). The body condition score (BCS scale: 1 = emaciated, 5 = obese with 0.5 increments), a palpable and visual assessment of the degree of fatness and muscle over and around the lumbar vertebrae, sternum, ribs and intercostal (between ribs) spaces was assessed every 2^nd week according to Villaquiran et al. (Reference Villaquiran, Gipson, Merkel, Goetsch and Sahlu2007).

As described in a previous experiment (Runa et al., Reference Runa, Brinkmann, Riek, Hummel and Gerken2019), individual water intake from each bucket was recorded daily by weighing and re-weighing water buckets before and after water administration with an electronic scale (Sartorius model CP 34000, Sartorius AG, Göttingen, Germany). Water refusals were discarded and the buckets refilled after cleaning. The daily amount of test solution consumed was expressed as a percentage of the total fluid taken from both containers. A separate bucket (10 l) containing water was placed in an adjacent area and reweighed daily to estimate the amount of water lost by evaporation and the total daily drinking water intake (TDWI) was corrected accordingly. The total water intake (TWI) was determined as the sum of TDWI from both containers and the water content in consumed hay. Water intake was also expressed as intake per kg BW^0.82 since water use by animals is related to the live weight of animals to the power of 0.82, as water is used in the body for intermediary metabolism and also for evaporative cooling (Wilson, Reference Wilson and Cloudsley-Thompson1989).

Hay was chopped to avoid spillage. The hay with an average dry matter content of 90.3% ± 0.2% and metabolizable energy concentration of 8.8 ± 0.1 MJ/kg DM was offered for ad libitum intake daily and individual feed consumption was measured by weighing the remaining feed on the next day. As described in a previous experiment (Runa et al., Reference Runa, Brinkmann, Riek, Hummel and Gerken2019), hay samples of approximately 150 g were collected weekly and analyzed for dry matter content. Collected hay samples were ground through a 1-mm screen and analysed using standard methods (Verband Deutscher Landwirtschaftlicher Untersuchungs- und Forschungsanstalten (VDLUFA), 2012) for dry matter (VDLUFA method 3.1), ash (method 8.1), crude protein (method 4.1.2 – Dumas; ElementarVarioMAX CN, Langenselbold, Germany), ether extracts (method 5.1.1), neutral detergent fibre and acid detergent fibre (expressed without residual ash – NDFom and ADFom, methods 6.5.1 and 6.5.2; Fiber Analyzer 220, Ankom Technology, Macedon, NY, USA). The metabolizable energy was estimated using prediction equations for ruminants, including values from Hohenheim gas test (Menke et al., Reference Menke, Raab, Salewski, Steingass, Fritz and Schneider1979; VDLUFA method 25.1). For the feed and water, Na and Cl were determined from aqueous extract using ion chromatography with conductivity detection (VDLUFA 10.5.2) (Dionex DX-100, Dionex, Sunnyvale, CA, USA). For Ca, Mg, P and K analyses, samples were ashed and dissolved in HCl. Ca, Mg and K were measured via atomic absorption spectroscopy (Varian SpectrAA-300, Varian, Palo Alto, CA, USA), and P was measured photometrically. A mineral licking block (Solsel^®, Esco-European Salt Company, Hannover, Germany) containing 37% sodium, 1.1% calcium, 0.6% magnesium, 0% phosphorous, manganese oxide (1000 mg/kg), zinc oxide (1000 mg/kg), calcium iodate (100 mg/kg), cobalt carbonate (20 mg/kg) and sodium selenite (20 mg/kg) was supplied for each animal throughout the experimental period. To avoid spillage, the mineral block was placed into the feeding trough. Consumption of the mineral lick was determined by weekly re-weighing the salt block with a scale (Sartorius model CP 34000, Sartorius AG, Göttingen, Germany) to the nearest 1 g. Total sodium (Na⁺) intake was determined as the sum of the amount of sodium consumed from hay, licking mineral block, fresh and saline drinking water. To correct for differences in animals’ body weights, feed and sodium intakes were also expressed on the basis of their metabolic body weight (kg BW^0.75.)

Statistical analysis

The results from earlier studies showed a higher salt sensitivity in young compared to adult sheep (Wilson and Dudzinski, Reference Wilson and Dudzinski1973). In order to take into account a possible age effect, goats were classified as young (n = 4) or adult (n = 8) when younger or older than 2 years, respectively. Data recorded on a daily basis were averaged for each goat per phase. Analyses of variance were performed using the PROC MIXED procedure of the software package Statistical Analysis Systems version 9.3 (SAS, Inst. Inc., Cary, NC). Animal was included as a random factor to account for repeated measurements of the same individuals. For all traits, the model included the fixed effect of the room, the experimental phase, age of the animal, their interactions, and the random effect of the goats. The model (1) was

$${Y_{ijklm}} = \mu + {R_i} + {P_j} + {A_k} + {\left( {R*P} \right)_{ij + }}{\left( {P*A} \right)_{jk}} + {\left( {R*A} \right)_{ik}} + {\left( {R*P*A} \right)_{ijk}} + {G_l} + {e_{ijklm}}$$

where Y_ijklm : observation value; μ: overall mean; R_i : room (i = rooms 1 to 3); P_j : phase (j = control, phases 2, 3 and 4); A_k : age (k = young, old); interactions: (R*P), (P*A), (R*A), (R*P*A); G_l : random effect of the goat; and e_ijklm : random error.

Data related to different salt concentrations during experimental phases 2, 3 and 4 were analysed by using the following mixed model (2):

$${Y_{ijklmno}} = \mu + {R_i} + {P_j} + {A_k} + {C_l} + {B_m} + {\left( {P*A} \right)_{jk}} + {\left( {P*C} \right)_{jl}} + {\left( {P*B} \right)_{jm}} + {\left( {A*C} \right)_{kl}} + {\left( {C*B} \right)_{lm}} + {\left( {P*A*C} \right)_{jkl}} + {G_n} + {e_{ijklmno}}$$

where Y_ijklmno : observation value; μ: overall mean; R_i : room (i = rooms 1 to 3); P_j : phase (j = phases 2, 3 and 4); A_k : age (k = young, old); C_l : concentration (l = 1 to 7); B_m : bucket position (m = right, left); interactions: (P*A), (P*C), (P*B), (A*C), (C*B), (P*A*C); G_n : random effect of the goat; and e_ijklmno : random error.

An integrated Tukey test was used to detect the differences between means at a 5% significance level. All values are presented as least squares means ± SEM. Theoretically, 50% of the TWI was expected to be consumed from each bucket. A 95% confidence interval was then placed on the theoretical mean. The 40% level of intake referred to as lower discrimination threshold (LDT) and the 60% intake as upper discrimination threshold (UDT). An RET was set at 20% intake (Bell, Reference Bell1959; Goatcher and Church, Reference Goatcher and Church1970a).