Animal husbandry

Nine-week-old female Sprague-Dawley rats were housed in pairs and allowed a 1-week acclimatisation period before being fed ad libitum a NP (19.4% wt/wt, Glen Forrest WA, Australia) or a near-isocaloric LP (8.4% wt/wt, Glen Forrest WA, Australia) diet (Table 1). This dietary manipulation continued throughout pregnancy and suckling (21 d postnatal). Then, offspring were weaned to a control diet (20% wt/wt protein, Meat Free Rat and Mouse Diet, Glen Forrest WA, Australia) which was fed ad libitum until the time of experimentation. It should be noted that this post-weaning diet is lower in fat (4.8% wt/wt fat), than the so-called ‘growth’ diet (7% fat wt/wt, AIN93G. Glen Forrest WA, Australia) which many animal facilities provide to stimulate growth in all rodents for several weeks post weaning.

Table 1.

Nutritional parameters of dietary groups

Energy and nutrient composition of normal-protein (NP) and low-protein (LP) maternal diets.

Dams were weighed when a breeder male was introduced for mating and regularly thereafter (three times a week). Pregnancy weight gain was determined based on the difference between the weight when breeder male was introduced and the last recorded weight prior to giving birth (1–3 d before giving birth). Litter size was standardised to between 6 and 12 pups (where possible, equal numbers of male and female pups). When litters consisted of more than 12 pups, additional pups were humanely killed at 1 d after birth at PN1. Litters prior to standardisation of less than 6 pups or more than 20 pups were not included in this study. Offspring were weighed on PN1 and then every 2–3 d (Monday, Wednesday & Friday) until weaning at PN21. During the first week post-partum maternal food and water intake were measured every 2–3 d. Offspring were then weighed every 5 d from PN25 (as animals were able to be individually identified at this time point) until PN180 and then every 15 d until PN360. In order to uphold the 3 Rs of animal ethics (reuse, reduction and refinement) there are variations in the number of offspring used at the various time points, as all animals were used. As there was variability in litter size, not all litters could contribute to every experiment.

Analysis of body composition, organ weight, food and water intake, and blood glucose level

Body composition was determined under isoflurane anaesthesia by dual X-ray absorptiometry (DEXA) at weaning (PN21), PN180 and PN360. Body fat, lean muscle and bone mineral content were all determined by dual energy X-ray absorptiometry (DXA, QDR-4500 DOS Series, Hologic, USA) specifically calibrated for small animals (such as rodents) using the step phantom as per manufacturer’s guidelines.

Organ weight was determined at PN21, PN180 and PN360. These included the kidneys, heart, pancreas, liver, brain, mesenteric fat, peri-renal fat and abdominal fat. At PN360, prior to organ collection, blood glucose concentration was measured using a handheld glucometer. Measurement of food and water intake occurred in PN360 offspring. Food and water were weighed daily over 5 d to determine the average 24-h intake.

Determination of nephron number

Nephron number was estimated in 21-d old offspring using the physical dissector-fractionator method. ^{Reference Cullen-McEwen, Armitage, Nyengaard, Moritz and Bertram36} PN21 was selected as the time-point for study as nephrogenesis is complete at this age yet there is unlikely to have been nephron loss associated with ageing or secondary to cardiometabolic factors such as obesity or hypertension. ^{Reference Kanzaki, Tsuboi, Shimizu and Yokoo37-Reference Geraci, Chacon-Caldera and Cullen-McEwen39}

The left kidney was fixed in 4% paraformaldehyde, ^{Reference Cullen-McEwen, Armitage, Nyengaard, Moritz and Bertram36,Reference Bertram40} transferred to 70% ethanol, processed to paraffin, and exhaustively sectioned at 5 µm.

Total nephron number per kidney was estimated using the equation:

$${N_{glom}} = SSF*{1 \over 2}*{1 \over 2}*{Q^ - }$$

where N_glom is the total number of peanut agglutinin (PNA)-positive glomeruli in the kidney, SSF (section sampling fraction, 100) is the reciprocal of the section sampling fraction (the number of sections advanced between section pairs), one fraction (½) accounts for PNA-positive structures that were counted in both directions between the two sections of a disector pair, the other fraction (½) accounts for the disector pair consisting of the n and n + 2 sections, and Q- is the actual number of PNA-positive glomeruli appearing and disappearing between the reference and look-up sections of the disector. ^{Reference Cullen-McEwen, Armitage, Nyengaard and Bertram41} For glomerular counting, kidney sections were observed at a magnification of 150x using a projection microscope.

Measurement of renal function

At PN180 and PN360, under general anaesthesia, glomerular filtration rate (GFR) was determined from the renal clearance of ³H inulin (1μCi/hr ³H-inulin, Perkin-Elmer Life Sciences, Victoria, Australia) while effective renal plasma flow (ERPF) was determined from the renal clearance of ¹⁴C- para-aminohippuric acid (0.5 μCi/hr ¹⁴C-PAH, Perkin Elmer, Boston, MA). ^{Reference Lim, Lombardo, Schneider-Kolsky, Hilliard, Denton and Black42} Rats were anaesthetised with thiobutabarbitone sodium (150 mg/kg in saline, Inactin, Sigma-Aldrich Co., St Louis, USA). Catheters were then placed in the carotid artery (for measurement of BP and collection of blood), jugular vein (for infusions) and bladder (for collection of urine). ^{Reference Lim, Lombardo, Schneider-Kolsky, Hilliard, Denton and Black42,Reference Walter, Zewde and Shirley43} To maintain fluid balance during surgery, 2% bovine serum albumin (BSA, Sigma-Aldrich) dissolved in 154 mM NaCl was infused at 1 ml/h/100 g body weight.

³H inulin and ¹⁴C PAH, dissolved in 154 mM NaCl, were infused at 0.4 ml/h/100 g body weight for a total of 100 min. After a 60-min stabilisation period, urine was collected over the final 40-min of the infusion. At the end of this 40-min period, blood (approximately 2 ml) was collected. Haematocrit was determined in a small aliquot and the remainder was centrifuged (10 min, 3000 g). Plasma was aspirated and stored at −20 °C prior to subsequent analysis.

Urine and plasma levels of ¹⁴C-PAH and ³H-inulin were determined by scintillation counting (Beckman LS6000TA, Beckman Coulter, USA). Each sample was counted for 10 min and the disintegrations per minute (DPM) from each triplicate were averaged. Under general anaesthesia, measurements of GFR, ERPF, filtration fraction (FF), and urine flow (UF) were then calculated as the clearance of ³H-inulin and ¹⁴C-PAH, respectively, where:

$${\rm{GFR}} = {{\left[ {{\rm{dpm\;of\;Inulin}}} \right]{\rm{\;urine}} \times {\rm{volume\;}}\left( {{\rm{ml}}} \right)} \over {\left[ {{\rm{dpm\;of\;Inulin}}} \right]{\rm{\;plasma}} \times {\rm{collection\;time\;}}\left( {{\rm{mins}}} \right)}}$$

$${\rm{ERPF}} = {{\left[ {{\rm{dpm\;of\;PAH}}} \right]{\rm{\;urine}} \times {\rm{UF}}} \over {\left[ {{\rm{dpm\;of\;PAH}}} \right]{\rm{\;plasma}}}}$$

$${\rm{UF}} = {{{\rm{\;urine\;volume\;}}\left( {{\rm{ml}}} \right)} \over {{\rm{collection\;time\;}}\left( {{\rm{mins}}} \right)}}$$

$$FF = {{GFR} \over {ERBF\;\left( {effective\;renal\;blood\;flow} \right)}}$$

$${\rm{ERBF}} = ERPF \times {1 \over {1 - \% \;Hematocrit\;}}$$

Osmolality

Osmolality of urine and plasma were measured by freezing point depression using an osmometer (Advanced Osmometer 2020; Advanced Instruments, Needham Heights, MA).

Electrolytes

Concentrations of Na⁺, Cl^- and K⁺ (mmol/l) were measured using a RapidChem 744 Electrolyte Analyser (Bayer Australia Limited, Australia).

Telemetry

Blood pressure and heart rate were measured by radiotelemetry (DataSciences Incorporated, Minnesota, USA) coupled to a customised data acquisition system. ^{Reference Head, Lukoshkova, Mayorov and van den Buuse44} Animals were anaesthetised with isoflurane and the probe surgically implanted in the descending aorta and tethered to the peritoneal wall as per the manufacture instructions. Post-operative analgesia and antibiotics were provided and animals recovered for a period of 5 d prior to the commencement of any recording.

Measurement of blood pressure and data collection

Systolic and diastolic blood pressure and heart rate were recorded continuously in unrestrained rats for a minimum of 5 d. The sampling rate was set at 2 s and data pooled to obtain 12 hourly (day and night) average readings over the experimental period.

Cardiovascular arousal tests were also performed to provide a proxy measurement of sympathetic nervous system tone and activation. Animals were exposed to an aversive stimulus of being placed on an oscillating table for 10 min (novel acute stimulus) at 100 rpm. On a different occasion, they were exposed to a novel non-aversive cardiovascular arousal stimulus (presentation of a sultana which was determined to be a favoured treat). For both arousal tests, blood pressure and heart rate were recorded for 5 min prior to and the 10 min during exposure to the stress test, as well as the 30 min after the stress test.

Statistical analysis

Data were analysed using a mixed linear model (maternal diet and offspring sex as independent variables) incorporating least means square regression to account for litter representation (n represents number of litters) (SPSS 21, IBM). ^{Reference Festing45} This statistical method has been used by various investigators to account for the potential within-litter bias. ^{Reference Hoppe, Evans, Bertram and Moritz46-Reference Wood-Bradley, Henry and Barrand53} This statistical analysis was used to reduce confounding due to over-representation of a particular litter in the data. Therefore, herein we report findings from an n (litter) of 4-18, which represents between 2 and 79 animals. Throughout the text, figures and tables, n is presented as the number of litters in the analysis (N_litter) and also the total number of male and female animals contributing to each observation. Growth curve data from PN1-21 were analysed via non-linear regression (GraphPad Prism v8, GraphPad Software Inc.). An exponential growth equation model was fitted with all parameters unconstrained. Data are expressed as mean ± SEM. Two-tailed P ≤ 0.05 was considered statistically significant. In the linear model P_diet represents the impact of maternal LP diet, P_sex represents the influence of offspring sex and P_diet*sex represents the interaction between these between-subjects factors. When appropriate, repeated measures ANOVA was used, with the Greenhouse-Geisser correction applied to within-subjects factors to account for asphericity.