Animals and feeding regimes

After weaning (6 weeks postnatal), twenty male White Saanen goats, purchased from a commercial breeder farm, were separated from their mothers and housed in pens bedded with sawdust. For 2 weeks, all animals were fed a mixture composed of all three concentrate diets and straw in a 4:1 ratio with a CP content of 12 % to allow the goats to acclimatise to pelleted diets. At the age of about 2 months with initial weights of 16·5 (se 0·5) kg, the goats were allocated to a diet containing either 19 % CP and 0·7 % Ca (19 % CP; n 7), 10 % CP and 0·6 % Ca (10 % CP; n 7) or 7 % CP and 0·5 % Ca (7 % CP; n 6), for 7–9 weeks. To maintain the Ca:P_i ratio in the diets, P_i was adjusted. The contents of each diet were assessed on an as-fed basis. The animals were housed in groups of six to seven on wooden shavings with water available ad libitum. The fed amount of concentrate per animal and day was 70 g/kg metabolic body weight (BW^0·75). Additionally, 33 % of the concentrate weight was given as chopped wheat straw and feeding was performed three times daily. Food was placed in broad feeding troughs to allow undisturbed food intake for each animal in the group. The total amounts of all feeds offered and refused were monitored daily to estimate the mean daily intake of nutrients and minerals over the entire experimental period (Table 2).

Diets

Dietary ingredients have been described in detail elsewhere⁽Reference Muscher, Schroder and Breves^3, Reference Muscher and Huber¹²⁾. The feed contents of DM, crude ash, crude fibre, crude fat and CP were determined by standard procedure in accordance with the methods of the Association of German Agricultural Investigation and Research Centre⁽Reference Naumann and Basler¹⁹⁾. The components and composition of wheat straw and concentrates are presented in Table 1. Sipernat 22S, a fine particle silica, which cannot be metabolised, was used to adjust the weight of reduced N diets.

Table 1 Components and composition of wheat straw and pelleted concentrate diets*

CP, crude protein; BDL, below detection level; DCAD, dietary cation anion difference; ME, metabolisable energy.

* Composition expressed as fed.

† Mineral–vitamin mix per kg: 180 g Ca; 60 g P; 100 g Na⁺; 30 g Mg; 500 000 IU (525 μmol/l) vitamin A; 80 000 IU (4992 nmol/l) vitamin D₃; 300 mg (697 μmol/l) vitamin E; 4200 mg Zn; 900 mg Mn; 16 mg Co; 20 mg iodine; 44 mg Se.

‡ Sipernat type 22S (Evonik Industries AG, Essen, Germany) is a fine particle silica with high oil absorption capacity. It is widely used as flow regulator, anti-caking and dusting agent especially in the food and feed industry.

Blood and urine samples

Plasma samples were taken 24 h before slaughter. Blood samples (9 ml each) were taken by venepuncture from the vena jugularis with EDTA or lithium heparinate covered syringes (Sarstedt, Nümbrecht, Germany). Blood plasma was separated by centrifugation (2000 g at room temperature for 15 min) and stored at − 20°C. Urine samples were collected during slaughter by aspiration from the bladder. For one goat in the 19 % CP group, no urine was present in the bladder.

Intestinal tissue samples

At the end of the study, the animals (3–4 months of age) were slaughtered by exsanguination after captive bolt stunning. Within 3–5 min after slaughter, segments of about 60 cm in length from the proximal and mid-jejunum were removed from the abdominal cavity beginning 1 m distal from the pylorus. Intestinal segments were rinsed with ice-cold saline (0·9 % w/v) and kept in a glucose-containing Krebs-Henseleit buffer solution, continuously aerated with carbogen (95 % O₂–5 % CO₂) until the tissue preparations were mounted in Ussing chambers⁽Reference Schröder, Kappner and Failing^20, Reference Schröder, Hattenhauer and Breves²¹⁾. For RNA isolation, nuclear extracts and preparation of plasma membrane-enriched fractions, samples were rinsed with ice-cold saline (0·9 % w/v). The mucosa of the proximal and mid-jejunum was stripped off, frozen in liquid N₂ and stored at − 80°C immediately.

Intestinal flux rate measurements of calcium and inorganic phosphate

Determination of Ca, P_i and mannitol flux rates across the intestinal epithelia was performed in Ussing chambers with an exposed surface of 1·13 cm² under short-circuit current conditions as described by Schröder et al. ⁽Reference Schröder, Kappner and Failing^20, Reference Schröder, Hattenhauer and Breves²¹⁾. The tissue conductance and the short-circuit current were determined by a computer-controlled voltage clamp device (Mussler Scientific Instruments, Aachen, Germany). Tissues were incubated on both sides with a 10 ml buffer solution (adjusted under carbogen saturation to pH 7·4 at 38°C with HCl) containing (mm): 113·6 NaCl, 5·4 KCl, 1·2 MgCl₂.6H₂O, 21·0 NaHCO₃, 1·2 CaCl₂.2H₂O, 1·2 Na₂HPO₄.2H₂O and 1·2 mannitol, respectively. The serosal buffer additionally contained 10·0 mm-glucose and 0·01 mm-indomethacin. During the experiments, the buffers were continuously aerated with carbogen at 38°C. After the tissue had been equilibrated for 30 min, ⁴⁵Ca, ³²P and (³H)-mannitol (each about 185 kBq/chamber) were used as radioisotopic tracers (Hartmann, Brunswick, Germany). Samples were taken at intervals of 10 min and replaced with equal volumes of the buffer solution. Radioactivity of the samples was measured by a liquid scintillation counter (Tri-Carb 2500 TR Packard Instruments Company, Downers Grove, IL, USA). The (³H)-mannitol was used as a paracellular marker⁽Reference Auchere, Tardivel and Gounelle²²⁾. Unidirectional flux rates from mucosal to serosal (J _ms) and serosal to mucosal (J _sm) of Ca, P_i and mannitol were calculated from the rate of tracer appearance on the unlabelled side using standard equations⁽Reference Schultz and Zalusky²³⁾. Net flux rates (J _net) were determined as differences between J _ms and J _sm of paired tissues.

Biochemical determinations

Haematocrit was determined in whole blood samples. An aliquot of each blood sample was placed in a microhaematocrit tube and spun to constant packed cell volume at 14 926 g for 5 min at room temperature. Plasma and urine urea concentrations were measured using a commercial kit (R-Biopharm, Darmstadt, Germany). The inter- and intra-assay CV for urea were 2·7 and 1 %, respectively. Plasma and urine creatinine were analysed by a standard diagnostic method in the Clinic for Diseases of Cattle at the University of Veterinary Medicine in Hannover. Total plasma protein concentration was measured with a commercial Coomassie blue protein assay (Bio-Rad, Munich, Germany) using bovine plasma gamma globulin as standard protein. Inter- and intra-assay CV of protein were 1·2 and 1·0 %, respectively. Plasma albumin concentrations were detected by a standard dye binding technique using bromocresol green (Hengler Analytik, Steinbach, Germany). Inter- and intra-assay CV of albumin were 7·7 and 2·3 %, respectively. Ionised Ca was measured in whole blood samples using an ion-sensitive electrode (Chiron Diagnostics GmbH, Wiesentheid, Germany). Inter- and intra-assay CV of ionised Ca were 2 and 1 %, respectively. Concentrations of total Ca and inorganic P_i were measured colorimetrically in plasma and urine by standard spectrometric techniques⁽Reference Sarkar and Chauhan^24, Reference Kruse-Jarres²⁵⁾. Inter- and intra-assay CV of total Ca were 4·4 and 2·4 % and for P_i they were 3·7 and 1·9 %, respectively. Na⁺ concentrations in plasma and urine were detected using a Na⁺-selective electrode (ABX Pentra 400; Horiba ABX, Montpellier, France). Inter- and intra-assay CV of Na⁺ were 0·4 and 0·2 %, respectively. The concentration of calcidiol was determined by a competitive EIA (Immundiagnostik AG, Bensheim, Germany). The declared inter- and intra-assay CV of the kit were < 13·2 and < 10·7 %, respectively. Calcitriol concentrations were measured by a commercial radioreceptor assay (Immundiagnostik AG). The intra-assay CV were < 15 and < 10 % for samples with calcitriol concentrations of 10 and 60 pg/ml, respectively. The inter-assay CV were < 20 and < 15 % for these two concentrations. The detection limit of this assay was 2 pg/ml. The calcitriol assay systems had already been used in other studies to determine the concentration of this hormone in goat plasma⁽Reference Muscher, Hattendorf and Pfeffer^26–Reference Widiyono, Huber and Failing²⁸⁾. For total plasma IGF-1 determination, an ACTIVE IGF-1 coated tube IRMA Kit (DSL-5600; Diagnostic Systems Laboratories, Inc., Webster, TX, USA) was used. The IGF-1 was separated from its binding proteins by an acid–ethanol extraction procedure, and IGF-1 concentrations were determined with a two-site immunoradiometric assay. The intra-assay CV was 1·5–3·5 % and the inter-assay CV was 1·5–8·5 %. The amount of growth hormone was measured by an ELISA as previously described⁽Reference Muscher, Piechotta and Breves^13, Reference Roh, Matsunaga and Miyamoto^29, Reference Kawashima, Sakaguchi and Suzuki³⁰⁾. Intra- and inter-assay CV were 9·8 and 12·6 %, respectively. The lowest detection limit was 1·0 ng/ml and the ED₅₀ in this assay system was 7·6 ng/ml.

Calculation of fractional excretion

The fractional excretion (FE) of urea was determined at the end of the experimental period using the following formula:

The FE of total Ca, P_i and Na⁺ was calculated by applying the same equation, but with the respective values for total Ca, P_i and Na⁺. The reliability of creatinine for measuring the renal function during protein reduction was suitably shown by Valtonen et al. ⁽Reference Valtonen, Uusi-Rauva and Eriksson³¹⁾.

Isolation of intestinal brush-border membrane vesicles, calcium and inorganic phosphate uptake studies

The preparation of small-intestinal BBMV, Ca and P_i uptake studies have already been described by Schröder et al. ⁽Reference Schröder and Breves²⁷⁾ and Muscher et al. ⁽Reference Muscher, Hattendorf and Pfeffer²⁶⁾. Briefly, BBMV from proximal and mid-jejunum were prepared according to a Mg²⁺ precipitation method, with two precipitation steps.

The uptake of Ca in BBMV of proximal jejunum was performed using a method described by Kaune et al. ⁽Reference Kaune, Kassianoff and Schroder³²⁾ with slight modifications. For the uptake of ⁴⁵Ca/Ca, BBMV of proximal jejunum were incubated at 21°C, with the uptake medium containing 75 mm-mannitol, 75 mm-KCl, 7·5 mm-HEPES–Tris, 0·5 mm-ethylene glycol tetraacetic acid, non-labelled Ca and 37 kBq/incubation vessel ⁴⁵Ca (Hartmann). The desired free Ca concentrations were obtained by adding appropriate amounts of Ca to 0·5 mm-ethylene glycol tetraacetic acid. The amounts of Ca were calculated by Winmax32 version 2.50 (Chris Patton, Stanford University, USA; http://www.stanford.edu/~cpatton/maxc.html). The concentration-dependent Ca uptakes were performed over a range of 0·045–4·0 mm-Ca.

For the uptake of ³²P/P_i, BBMV of mid-jejunum were incubated at 21°C with the uptake medium containing non-labelled P_i and α ³²P (Hartmann; 37 kBq/incubation vessel). Concentration-dependent P_i uptakes were performed over a range of 0·01–1·0 mm-P_i. Extravesicular incubation buffer contained 100 mm-mannitol, 10 mm-HEPES–Tris, pH 7·4, and 100 mm-NaCl. The Na⁺ dependency of P_i transport was established by incubating BBMV of mid-jejunum in solutions in which KCl replaced NaCl equimolarly. The proximal BBMV were washed with a stop solution containing 150 mm-KCl, 50 mm-mannitol, 10 mm-HEPES–Tris and 1 mm-ethylene glycol tetraacetic acid, pH 7·4, while the BBMV from mid-jejunum were washed with 150 mm-KCl, 1 mm-KH₂PO₄ and 10 mm-HEPES–Tris, pH 7·4, both on 0·65 μm cellulose nitrate filters. The activity of each filter was counted using a Packard Tri-Carb 2500TR scintillation counter. Kinetic parameters V _max (nmol Ca/(mg protein × 30 s) or nmol P_i/(mg protein × 10 s)) and K _m (mm) were calculated from the Michaelis–Menten kinetic of Ca or P_i uptake into the intestinal BBMV.

Intestinal expression of sodium-dependent phosphate transporter IIb and vitamin D receptor mRNA in goats fed a 19 % crude protein v. 7 % crude protein diet

Semi-quantitative detection of specific amounts of NaPi IIb and VDR mRNA in caprine proximal and mid-jejunum was performed via Northern blot analysis as described in detail elsewhere⁽Reference Muscher, Hattendorf and Pfeffer^26, Reference Huber, Walter and Schroder³³⁾. Briefly, isolated 6 μg poly(A)⁺RNA/lane from proximal or mid-jejunum was fractionated in 1·0 % formamide/agarose gels and transferred by capillary blotting onto nitrocellulose membranes. Radioactive ³²P-labelled NaPi IIb, VDR- and ß-actin-specific probes were hybridised to fixed mRNA. Hybridisation took place for 16 h at 42°C (40 % formamide). The membranes were analysed with a phosphorous imager system (Bio-Rad) after exposure to a phosphorous imager screen for 2–6 h. The relative amounts of specific mRNA were quantified by reference to β-actin as an internal standard using the quantification software Quantity One (Bio-Rad).

Intestinal expression of transient receptor potential vanilloid channel type 6, sodium-dependent phosphate transporter IIb, Na⁺K⁺ATPase and vitamin D receptor protein in goats fed a 19 % crude protein v. 7 % crude protein diet

Mucosa samples from proximal and mid-jejunum were homogenised and crude membranes prepared by performing differential centrifugation⁽Reference Wilkens, Mrochen and Breves³⁴⁾. From mid-jejunum, BBM were isolated using the Mg²⁺ precipitation method previously described. The isolation of nuclear extracts from caprine proximal and mid-jejunum was carried out by a method described by Schröder et al. ⁽Reference Schröder, Kaune and Harmeyer³⁵⁾ and Muscher et al. ⁽Reference Muscher, Hattendorf and Pfeffer²⁶⁾. The protein concentrations of all preparations were determined by the Bradford method (Bio-Rad). Immunoblot assays detecting TRPV6, NaPi IIb and VDR proteins in caprine intestinal tissues were performed as previously described⁽Reference Muscher, Hattendorf and Pfeffer^26, Reference Wilkens, Mrochen and Breves³⁴⁾. For the abundance of TRPV6, NaPi IIb and Na⁺K⁺ATPase, 15–50 μg of enriched plasma membranes or BBM were separated by 8·5 % SDS–PAGE and transferred to nitrocellulose membranes (GE Healthcare, Freiburg, Germany) using a tank blotting system (Bio-Rad). For the detection of VDR, 15 μg of nuclear extracts were separated in 10 % SDS–polyacrylamide gels in the same manner. Nitrocellulose membranes were blocked overnight at 4°C in PBS containing fat-free milk powder. Immunodetection of electrotransferred proteins was performed according to standard procedures. The following primary antibodies were used: anti-TRPV6 (H-90; Santa Cruz Biotechnology, Heidelberg, Germany), anti-NaPi IIb (gift from Professor Dr J. Biber), anti-VDR (Enzo Life Sciences GmbH, Lörrach, Germany), anti-villin (Biotrend Chemikalien GmbH, Cologne, Germany) and anti-Na⁺K⁺ATPase (Enzo Life Sciences GmbH). Immunoreactive proteins were visualised using the enhanced chemiluminescence system (Perbio Science GmbH, Bonn, Germany) according to the manufacturer's protocol. Villin was used as an internal standard to semiquantify relative protein expression amounts. Bands were analysed semiquantitatively using the Quantity One software (Bio-Rad).

Statistical analysis

All data are expressed as means with their pooled standard errors, with number of animals. Data were analysed by one-way ANOVA with Tukey's post test except Northern and Western Blot analyses which were analysed by unpaired Student's t test. Kinetic parameters of Ca or P_i uptake into isolated BBMV were calculated using non-linear regression analysis. Potential relationships between the measured parameters were calculated by linear regression analysis. All statistical analyses were performed using GraphPad Prism version 4·0 for Windows (GraphPad Software, San Diego, CA, USA, www.graphpad.com). In all cases, P < 0·05 was set to be significantly different and P < 0·1 was used to define trends.