Maternal high-fat diet during pregnancy and lactation affects factors that regulate cell proliferation and apoptosis in the testis of adult progeny

Animal model

All animal procedures were performed under the guidelines of the Animal Ethics Committee of the University of Auckland (R402). An established model of developmental programming based on manipulation of maternal nutrition was used (Howie et al. 2012). Female Wistar rats (120 days old; n = 10) from the Vernon Jansen Unit at the University of Auckland were time-mated using a rat oestrous cycle monitor (Fine Science Tools, USA). Thereafter, they were housed individually in standard rat cages in the same room, with free access to water, a constant temperature of 25°C and a 12:12 light:dark cycle. Pregnant dams were randomly allocated to two dietary treatments (five per group): (1) Control – dams fed ad libitum throughout pregnancy and lactation with a standard diet (fat 6.2%, protein 18.6%; carbohydrate 44.2%; Teklad Global 18% Protein Diet, Diet 2018, calories (kcals/g) from fat 18%, from protein 24%, calories from carbohydrate 58%, https://insights.envigo.com/hubfs/resources/data-sheets/2018-datasheet-0915.pdf); and (2) HFat – dams were fed a high-fat diet throughout pregnancy and lactation (fat 24%, protein 24%, carbohydrate 41%; calories (kcals/g) from fat 45%, calories from protein 20%, calories from carbohydrate 35%, High fat D12451, Research Diets, Inc New Brunswick, NJ, USA, http://67.20.83.195/china/pdf/Data%20Sheets/D12451.pdf). After birth, pups were weighed, and litters were adjusted to comprise four males plus four females to ensure standardised nutrition until weaning (day 22). After weaning, male pups were housed in pairs and fed the standard chow diet ad libitum until the end of the study (day 160). Offspring body weight were recorded at birth, early post-puberty (day 42) and at the end of the trial on postnatal day 160.

Testis sampling and histological processing

On postnatal day 160, male pups (n = 20; 10 per dietary group) were fasted overnight, weighed, anaesthetised with pentobarbital (60 mg kg⁻¹ i.p.) and then killed by decapitation. Blood was collected into heparinised tubes, and plasma was separated by centrifugation (2400g, 20 min) and stored at −20°C until later analysis. Testes were weighed and the data were used to calculate relative testis mass (g testis mass per g body mass) and thus the gonadosomatic index (relative testis mass × 100). Left testes were frozen in liquid nitrogen and stored at −80°C for molecular analyses. Right testes were immersed in fixative (4% formaldehyde phosphate buffer, pH 7.4) for 24 h for histology and immunohistochemistry (Fig. 1).

Fig. 1.

Schematic representation of the experimental design. There were two treatments for maternal nutrition (Control and High-fat) for gestation days (GD) 0–21, and for lactation, from birth (prenatal day 21) to weaning on postnatal day (PD) 22. After weaning, male pups were fed ad libitum with a control diet until the end of the study (PD 160) when blood and testes were sampled. Puberty (P) was observed over the period 35-37 PD. PP, pre-puberty.

Fixed testes were progressively dehydrated by immersion in increasing concentrations of ethanol (70%, 95%, 100%), embedded in paraffin resin (Historesin; Leica, Germany) and sectioned at 5 μm by microtome (Leica 149 Reichert Jung Biocut 2030, Wetzlar, Germany) in preparation for hematoxylin–eosin staining and immunohistochemistry.

Endocrine assays

Commercially available assays from Diagnostic Systems Laboratories Inc. (Webster, TX, USA) were used to measure the plasma concentrations of testosterone (DSL-4100) and androstenedione (DSL-4200). We followed the manufacturer’s instructions and included all samples within a single assay. For testosterone, the limit of detection was 0.10 ng/mL and the within-assay coefficient of variation (WACV) was 2.8%. For androstenedione, the limit of detection was 0.10 ng/mL and the WACV was 5.7%.

Immunohistochemistry

Slides were processed for the detection by immunoexpression of ETV5, GDNF, IGF-I, caspase-3 Bax, Bcl-2 and Ki-67 using the streptavidin–biotin–peroxidase protocol, as described previously (Pedrana et al. 2020). In brief: the tissue sections were immersed in 250 mL of 0.01 M citrate buffer solution (pH 6.0) with Tween-20 (5 mL) at a concentration of 2% for dewaxing, hydration and epitope retrieval by heating for 5 min in microwave oven (100% power); slides were then washed with distilled water and phosphate-buffered saline (PBS, pH 7.4); endogenous peroxidases were inactivated by treatment with 3% hydrogen peroxide 200 (20 min), followed by washing in PBS; non-specific binding proteins were blocked by incubation with normal rat serum; each slide was then incubated for 30 min with a different primary antibody (Table 1), for 30 min with biotinylated secondary antibody (rabbit-specific HRP/DAB; ab 64261; Abcam, USA), and for 30 min with streptavidin–peroxidase enzyme complex; to visualize the antigen, slides were incubated for 5 min with diaminobenzidine (DAB) chromogen solution (1 mL hydrogen peroxide + 30 μL DAB); sections were counterstained with Mayer’s hematoxylin, dehydrated, and mounted with Entellan® (Merck) on glass coverslips. All assays contained a negative control for the immunohistochemistry using different testicular sections incubated with rat serum diluted 1:100 in PBS.

Morphometry, immunohistochemistry and image analysis

Following hematoxylin-eosin staining, seminiferous tubule diameters were measured in 50 transverse cross-sections of seminiferous tubules at a final magnification of 100×, and Sertoli cells were counted in each of 50 transverse cross-sections of seminiferous tubules at a final magnification of 400×. Digital images were retrieved using a light microscope (Olympus CX23, Olympus Scientific Solutions Americas Corp., MA, USA) connected to a digital camera (Dino-Eyepiece Edge, AM-7025X) and then captured with DinoCapture 2.0 software (https://www.dinolite.us/es/features/dinocapture/).

Immunohistochemistry images showing the immunostained area (IA) for ETV5, GDNF, IGF-I, caspase-3, Bax, Bcl-2 and the number of Ki-67-positive spermatogonial cells per transverse section of seminiferous tubules were analysed using ImageJ software (Ver. 1.52b 6 May 2018; Wayne Rasband, National Institutes of Health, USA; https://imagej.net/ij/index.html). Immunostained areas were measured using a locally written macro that included colour threshold values from processing RGB images and conversion to binary images. The threshold values were verified and normalised with controls carried across several runs for calibration. This process provided quantitative values for percentage (%) IA in 1000 digital images per testis, per animal and per immunohistochemically stained factor.

Gene expression analysis by qPCR

Total RNA was extracted using commercially available kits (AllPrep DNA/RNA mini kit; cat 80204; Qiagen, Germantown, MD, USA). Genomic DNA was removed from each sample by treatment with RNase-free DNase (Invitrogen Life Technologies, New Zealand) according to the manufacturer’s instructions. RNA quantity and purity were analysed using a NanoDrop spectrophotometer (ND-1000; BioLab Ltd) and NanoDrop software (ver. 3.1.2). All RNA samples were stored at −80°C until required. For first-strand cDNA synthesis, we used 5 mg total RNA, Moloney Murine Leukaemia Virus Reverse Transcriptase (MMLV- RT; Promega Corp., WI, USA) and a standard thermocycler (GeneAmp PCR System 9700; Applied Biosystems). A master mix was prepared containing 5 mL M-MLV 5x (cat M531A; In Vitro Technologies, Madison, WI, USA), 0.5 mL M-MLV-RT (cat. M170B; In Vitro Technologies) and 1.25 mL 10 mM deoxynucleoside-triphosphates (cat. R0181, Thermo Fisher Scientific, USA). The cycling conditions were: initial denaturation for 5 min at 96°C followed by 30 cycles (30 s each) at 96°C (denaturation), 60°C (annealing) and 72°C (extension). The cDNAwas stored at −20°C until assay by quantitative polymerase chain reaction (qPCR). Testicular gene expression for caspase-3, Bax and Bcl-2, as well as the endogenous reference (b-actin), was measured by qPCR using the ABI PRISM 7900 HT Sequence Detection System (Applied Biosystems, New Zealand). All primers were designed using Primer 3 software (Primer3, 0.4.0, Whitehead Institute for Biomedical Research, https://bioinfo.ut.ee/primer3-0.4.0/) and manufactured by Invitrogen Life Technologies. Primer set controls were b-actin (Table 2). Optimal primer conditions were adjusted to the cycling conditions: length, 20 bp (range 17–23 bp); temperature, 63°C (range 60–65°C); and amplicon length, 100–300 bp. Dissociation analyses were used to ensure specificity and only samples producing a single peak in the dissociation curves were retained. Amplified products were visualised on an agarose gel using the E-Gel CloneWell 0.8% SYBR Safe gel (cat. G6618-08; Invitrogen, Burlington, ON, Canada), run on the E-Gel iBase^TM Power System (cat. G6400; Invitrogen, CA, USA) and sequenced by spectrophotometry (Allan Wilson Centre, Massey University, New Zealand). The resulting sequences were evaluated using NCBI BLAST to ensure specificity. Transcript levels were quantified by qPCR under the following conditions: an initial 2-min hold period at 50°C for normalisation (Stage 1), followed by enzyme activation at 95°C for 2 min (Stage 2); amplification of the gene product through 40 successive cycles of 95°C for 15 s and then 60°C for 1 min (Stage 3); a dissociation stage of 15 s at 95°C, 15 s at 60°C, and 2 min at 99°C (Stage 4). A standard curve was generated from the mean cycle threshold (Ct) of eight standards (1:5 serial dilution) of a known concentration in triplicate and amplification and dissociation curves were generated for all standards and samples (Applied Biosystems, CA, USA). Each sample was run in triplicate.

Statistical analysis

The mother was used as the biological replicate. The pups were derived from the various litters, and they were compared statistically, not the mothers. With 10 litters and 2 males per litter, we obtained 10 males per dietary group (two males from each of five litters). Although the numbers of Sertoli cells and germ cells are ordinal and discrete, we treated them as continuous variables. The data were checked for normal distribution and met the criteria for parametric testing. For each dependent variable, differences between Control and HFat were compared using two-sample Student’s t-tests, aided by PROC TTEST and SAS statistical analysis (SAS, v. 9.1, SAS Institute Inc., Cary, NC, USA). The level of significance was P < 0.05. All data are expressed as mean ± standard error of mean (s.e.m.).

Physiological parameters

The data are summarised in Table 3. There were no differences between treatments in plasma concentrations of androstenedione and testosterone. Compared to the Control group, the HFat group showed a decrease in birth weight, an earlier onset of puberty and a decrease in body weight at puberty. However, as adults at age 160 days, HFat animals were heavier than Control animals. At 160 days, testis weight did not differ between groups but, due to the differences in body mass, relative testis weight, and thus gonadosomatic index, were smaller in the HFat group than in the Control group (Table 3).

Testis morphometry

In both groups, the testicular parenchyma showed a normal structure with seminiferous tubules and interstitial tissue, although some images show alterations in seminiferous tubules in the HFat group. Seminiferous tubule diameter was greater in the HFat group than in the Control group (Table 3, Fig. 2a, b). Compared to the Control group, the HFat group had greater numbers of Sertoli cells (Table 3, Fig. 2c, d) and Ki-67-positive spermatogonial cells (Table 3, Fig. 2e, f).

Fig. 2.

Testis histology in male rats born to mothers fed either the Control or the High-fat diet during pregnancy and lactation. (a, b) Hematoxylin–eosin-stained seminiferous tubules (magnification, 100×; scale bar, 50 μm). (c, d) Sertoli cells (white arrows) in hematoxylin–eosin-stained seminiferous tubule cross-sections (magnification, 600×; scale bar, 20 μm). (e, f) Ki-67-positive spermatogonia (black arrows; magnification 400×; scale bar, 20 μm. (g) Negative control for immunohistochemistry.

Testis protein immunoexpression

Immunoexpression of the transcription factors, ETV5 and GDNF, was clearly evident in both groups. The ETV5 was localised in the spermatogonia, spermatocytes and the acrosome region of round spermatids, elongated spermatids and Sertoli cells (Fig. 3a–d). The IA for ETV5 was greater in the HFat group than in the Control group. For GDNF, immunoexpression was localised in cytoplasm of Sertoli cells, spermatogonia and Leydig cells (Fig. 3e–h). The IA for GDNF was lower in the HFat group than in the Control group.

Fig. 3.

Immunohistochemical localisation transcription factors in the testis in rats born to mothers fed either the Control or the High-fat diet during pregnancy and lactation. (a–d) Brown immunostaining for transcription variant 5 (ETV5) evident in the acrosome region in round spermatids (black arrow), spermatocytes (black arrowhead) and Sertoli cells (white arrows). (e–h) Brown immunostaining for glial-cell line-derived neurotrophic factor (GDNF) evident in elongated spermatids (black triangle), spermatocytes (black arrowhead) and Leydig cells (asterisk). (i–l) Brown immunostaining for insulin-like growth factor I (IGF-1) in Leydig cells (asterisk) and in Sertoli cells (intense immunostaining; white arrow) and spermatids (segmented arrow). Negative controls for immunohistochemistry are presented in the three panes on the right (magnification, 400×; scale bar, 20 μm).

The IGF-I immunoexpression was localised in the Leydig cells, the acrosome region of sperm and in Sertoli cells (Fig. 3i–l). The IA for IGF-I was lower in the HFat group than in the Control group.

Active caspase-3 immunoexpression was evident in round and elongated spermatids (Fig. 4a–d). The IA for caspase-3 was greater in the HFat group than in the Control group. For Bax, immunoexpression was localised in the cytoplasm of spermatogonia, elongated spermatids and Sertoli cells (Fig. 4e–h). The IA for Bax did not differ between dietary treatments. For Bcl-2, immunoexpression was detected in round spermatids, elongated spermatids and Sertoli cells (Fig. 4i–l). The IA for Bcl-2 was greater in the HFat group than in the Control group (Table 3).

Fig. 4.

Effects of maternal high-fat diet during pregnancy and lactation in apoptosis proteins in the testis. (a–d) Brown immunostaining for caspase-3 in spermatids (black arrows) and spermatozoa in the lumen. (e–h) Brown immunostaining for Bax evident in Sertoli cells and spermatogonia. (i–l) Brown immunostaining for Bcl-2 evident in acrosome region of round spermatids (black arrow) and in Sertoli cells (white arrow). Negative controls for immunohistochemistry are presented in the three panes on the right (magnification, 400×; scale bar, 20 μm).

Testis gene expression

The testis levels of caspase-3 mRNA and Bax mRNA did not differ between dietary treatments. In contrast to Bcl-2 protein, the concentration of Bcl-2 mRNA was lower in the HFat group than in the Control group (Table 3).