Early rhythmicity in the fetal suprachiasmatic nuclei in response to maternal signals detected by omics approach

We used fetal SCN from 2 groups of rats maintained in constant darkness (DD) (Fig 1) for RNA-Seq and proteomic analyzes. The control group had sham surgery and was fed ad libitum (Group A). In this group, signals to the fetuses were derived from maternal SCN clock and its complex downstream pathways, including those responsible for timing the feeding and locomotor activity. The SCN-lesioned group was behaviorally arrhythmic in DD and had access to food restricted to 8 hours per day (time-restricted feeding; tRF) to impose a synchronous feeding rhythm (Group B; the activity records are shown in S1 Fig). The 8-hour presence of food did not induce food anticipatory activity that could be distinguished from fragmented bouts of activity detected by infrared detectors in constant darkness. In Group B, direct signals from maternal SCN clock to the fetuses were lacking, with rhythmic signals related to feeding behavior being preserved (provided by tRF) in a similar phase as in Group A (for more details, see Materials and methods).

First, we tested whether and how the experimental protocol (mainly surgery and the tRF regime) affected maternal body weight (a measure of potential metabolic challenge) and the number of fetuses in the litter and their weight (a factor that can plausibly affect the variance between fetuses sampled at each time point) (Fig 2). Specifically, we used 3 additional groups of pregnant rats, which were SCN lesioned and fed ad libitum (Group C; n = 8), sham operated and exposed to the tRF regime (Group D; n = 11), and intact without any intervention (Group E; n = 6). The results show that sham surgery of Group A had no effect on the maternal body weight gain and importantly did not decrease number of fetuses in the litter. The rats of Group B had lower body weight gain confirming a higher metabolic challenge (due to exposure to tRF), which they compensated to maintain normal fetal growth. Hence, compared to ad libitum fed animals, food-related and SCN-independent signaling pathways are probably up-regulated in this group. The results showed that the fetal weights and their number in the litters were not different between the experimental groups A and B, in which the transcriptomic and proteomic analyses were performed (the groups C, D, and E were not employed further in these analyses). We also confirmed that the sham operation had no effect on diurnal variation of daily food intake in pregnant rats fed ad libitum (Group A), as they foraged mainly during night hours (approximately 75% of daily food intake; S2 Fig), which was similar to our previous measurements in nonpregnant Wistar rats (36). In Group B, monitoring of feeding behavior was redundant, as rats could forage only during the 8-hour tRF interval.

Temporal gene expression in the SCN of E19 fetuses was investigated using RNA-Seq (for details on sample collection, see Materials and methods). We obtained 11.9 to 17.9 million reads per sample (S3 Fig), 92.6% to 93.8% of which were uniquely mapped to the rat genome. Exactly 6,973 transcripts from Group A and 6,992 transcripts from Group B had average fragments per kilobase of transcript per million mapped reads (FPKM) values > 10 across all time points, while approximately 13,000 transcripts in both groups had average FPKM values > 1. We used deseq2 to analyze all transcripts that had at least 1.5 raw count per million mapped reads in at least 3 sample libraries and were assigned a unique gene ID (n = 12,844). There was no difference in overall expression levels between the 2 groups, as none of the transcripts showed significant up- or down-regulation (lowest multiplicity adjusted P = 0.055). This was reflected in the incomplete separation of both groups by whole-transcriptome clustering analysis and likely reflects time-dependent in-group differences.

All major clock genes were detected at low levels with average FPKM values < 10 (Fig 3), except more highly expressed Bmal1 (FPKM approximately 20) and Rora/b (FPKM approximately 20 to 40). Various rhythm analysis tools were used to identify the presence or absence of rhythmicity, including conventional approaches (MetaCycle, eJTK), model selection methods for differential rhythmicity comparison (dryR, CompareRhythms), and machine learning tool BioCycle, with thresholds for multiple testing (FDR < 0.05) and a Bayes information criterion weight (BICW > 0.5) for model selection methods applied. Transcripts of none of the major clock genes were significantly rhythmic as confirmed by all tools (S2 Data). There was an exception for Per1 expression selectively in Group B (BICW = 0.73 dryR, BICW = 0.81 CompareRhythms).

Model selection approaches were used to compare rhythms between Group A (SHAM, ad libitum) and B (SCN-X, tRF) and assign transcripts to subsets according to the presence or absence of rhythmicity in their expression (n = 12,844) with application of an additional BICW > 0.5 (n = 9,174 for dryR; n = 8,167 for CompareRhythms). The majority of transcripts were found to be nonrhythmic in both groups (n = 7,676 for dryR; n = 5,346 for CompareRhythms). Because the rhythms in the expression of clock genes are necessary for the operation of an endogenous fetal clock mechanism and they were not detectable by any of the previously mentioned methods, we assume the rhythmic genes in the remaining subsets identified by dryR (n = 1,498; Fig 4) and CompareRhythms (n = 3,828; S3 Data) were of maternal origin. They included transcripts with similar rhythmic parameters (phase and amplitude) in both groups (ABsync), differentially rhythmic genes (ABdiff), transcripts rhythmic only in Group A (Arhy), and those rhythmic only in Group B (Brhy).

Most transcripts were rhythmic in Groups A and B, according to both dryR (approximately 43%) and CompareRhythms (approximately 25%), and the majority of these rhythmic genes reached their peak in expression between CT15 and CT21, with a smaller group of genes in the opposite phase (peaking at CT3-6, respectively). The dryR analysis (Fig 5) identified 644 transcripts of similar circadian parameters (ABsync) and differential rhythmicity in only 35 (approximately 2%) genes (ABdiff), while CompareRhythms found 976 synchronous (Absync) and 294 (approximately 8%) differentially rhythmic genes (ABdiff). Transcripts rhythmic only in Group B (Brhy; n = 518 dryR; n = 902 for CompareRhythms) made up approximately 35% (approximately 24% for CompareRhythms) mostly peaking around CT21-3. Those rhythmic only in Group A (Arhy; n = 301 for dryR; n = 458 for CompareRhythms) made up approximately 20% (approximately 12% for CompareRhythms), with the majority of associated genes peaking between CT15-18 (and to less extent CT3-6, in similar distribution to the ABsync subset).

For enrichment analysis of these subsets of rhythmically expressed genes, we used both single- and multi-gene list enrichment analysis on MetaScape targeting GO Biological Process, Molecular Function and Cellular Component, as well as KEGG and Reactome pathways to assign functions to gene subsets representing the models identified by dryR and CompareRhythms. The most notable observations point toward an enrichment of genes associated with neurodevelopment, (synaptic) signaling and activity (S4 Data). The relationship of these subsets (based on multi-gene list GO-BP enrichment analysis of the dryR subsets) is shown in a network visualized with Cytoscape, representing 10 of the 12 most highly significant clusters assigned by MetaScape (-log(p) > 9), as clusters 8 and 12 were not connected to any of the other nodes via edges and were therefore addressed separately. The most significantly enriched GO-BP term from each cluster was used as term description. Two main branches can be observed in the network (Fig 6, highlighted in yellow and purple, respectively), in which color and size of the nodes represent the number of genes originated from each respective subset: Arhy, Brhy, ABsync, or ABdiff (highlighted in red, blue, white, and green, respectively).

The right branch (purple) is associated with neuronal activity and is comprised of the clusters behavior (3, -log(p) = 15.05), regulation of membrane potential (5, -log(p) = 10.75), glutamate receptor signaling (6, -log(p) = 10.28), locomotory behavior (7, -log(p) = 10.11), regulation of secretion by cell (8, -log(p) = 10.02), and modulation of chemical synaptic transmission (9, -log(p) = 9.19). Most of the genes (n = 318) are rhythmic in both groups with similar phase and amplitude (ABsync approximately 56%), followed by genes rhythmic only in Group B (Brhy approximately 27%), only in Group A (Arhy approximately 14%) and differentially rhythmic genes (ABdiff approximately 4%). Numerous genes within this branch are associated with catalytic and transporter activity or encode for transmembrane signal receptors and downstream signaling enzymes. This includes various relevant subunits of adenylate cyclases, ionotropic and metabotropic glutamate/GABA receptors, sodium/potassium-transporting ATPases, Ca-, K-, Na-, and Cl-channels. The majority of rhythmically expressed genes associated with neuronal activity peaked between CT15-18 (Fig 6, S3 Data).

The left branch (yellow) represents genes associated with neurodevelopment and is made up of the clusters cell junction organization (1, -log(p) = 17.76), cell projection morphogenesis (2, -log(p) = 16.26), forebrain development (4, -log(p) = 11.11), and regulation of cell development (10, -log(p) = 9.53). As in the right branch, most of the genes (n = 335) were mutually rhythmic in both groups with similar phase and amplitude (ABsync approximately 52%), followed by genes rhythmic only in Group B (Brhy approximately 28%), only in Group A (Arhy approximately 16%) and differentially rhythmic genes (ABdiff approximately 3%). Additional genes that are found in multiple clusters of this branch include signaling enzymes, growth factors, and receptors such as Egfr, Akt1, Map2k1, Notch1, Stat3, Lhx2/9, Ncor1/2, and Plcb1 (ABsync), as well as Pdgfra, Tgfb1, and Vegfa (Brhy) or Ntrk2/3 (ABdiff). Rhythmically expressed genes associated with neuronal development peaked between CT15-3 (Fig 6, S3 Data).

We examined the expression of key receptors binding molecules previously associated with maternal entrainment of the fetal circadian system, namely hormones melatonin [35,36], glucocorticoids [21], dopamine [37], and the SCN major neurotransmitters vasopressin and vasoactive intestinal polypeptide [38]. The level of Mtnr1a, a gene encoding melatonin receptor 1 (MT1), was very low (FPKM = 0.6) and Mtnr1b (MT2) was undetectable. Glucocorticoid receptor (Nr3c1), Vasopressin (Avp), and its receptors (Avpr1a and Avpr2) were expressed at higher levels (FPKM = 1.5–6). Vasoactive intestinal polypeptide (Vip) and its receptor (Vipr2), as well as Dopamine receptor 1 (Drd1) exhibited the highest expression (FPKM = 10–15) of the investigated transcripts, while Dopamine receptor 2 (Drd2, FPKM = 0.4) was detected at expression below threshold. All mentioned genes were identified as nonrhythmic in both Groups A and B by dryR, with the exception of Drd1 (BICW = 0.51) observed as rhythmic in both groups. Avpr2 was initially also identified as rhythmic in Group A (BICW = 0.35 in dryR) but did not pass the confidence threshold and was therefore left unassigned (S3 Data). Most of the rhythmically expressed genes were assigned to be rhythmic in both Groups A and B (ABsync), with all previously mentioned GO term clusters significantly enriched in the respective dryR subset (Fig 6, white). Additionally, GO term rhythmic process (GO:48511, -log(p) = 6.26) was found to be significantly enriched within the ABsync subset due to the presence of genes such as Adcy1, Adora1, Drd1, Gabrb1, Grin1/2b, Hspa8, Ncor1/2, Sox14, or Tp53 within this subset. These (and other) genes could potentially provide a link between observed oscillations present in response to rhythmic maternal signals and the establishment of independent rhythms in the offspring during later development.

The subset of genes found rhythmic in Group A (Arhy) was represented twice in the network (Fig 4, red) due to the presence of genes such as Avp, Hdac5/9, Hspa4, Pax6, Shh, and Tbx2/3, as well as further subunits of previously mentioned receptor/transporter genes (e.g., Cacna1g/i, Grik1). Individual analysis of the subset revealed an exclusive enrichment for the GO term cellular response to leucine (GO:0071233, -log(p) = 4.89), including genes for sestrins Sesn1/2/3, Mtor, Map3k5 (also known as Ask1), Gck, and Slc38a2.

The dryR model comprised of genes found rhythmic in fetal SCN of Group B litters (Brhy) displayed enrichment in 5 of the 12 most significant clusters (Fig 4, blue), including the clusters blood vessel development (9) and sensory organ development (12), which are not connected to other top 12 clusters and not visualized in the network (S4 Data). Individual analysis also revealed enrichment in transmembrane receptor protein tyrosine kinase signaling pathway (GO:0007169). These clusters contain a variety of growth factors, receptors, and signaling enzymes rhythmic only in Group B, such as Bmp7, Csf1 and Csf1r, Dlx1/2, Egfl, Fgf1 and Fgfbp3, Igf2r and Igfbp2/4, Pdgfra, Prkcd and Prkcq, Tgfb1 or Vegfa.

dryR identified only 35 differentially rhythmic genes (ABdiff), but 4 of the 12 GO terms were significantly enriched in this subset (Fig 4, green). Member genes of these clusters include Gria3/2a, Slc17a6 and Slc32a1, Hspa5, Ntrk2/3, Stxbp5, Syt5 and Cacna1d. The differential phases are shown in S3 Data.

We used independent batch of identically sampled fetal SCN from mothers of Groups A and B for liquid chromatography coupled with mass spectrometry to identify label-free quantification (LFQ) values of 3,707 unique proteins. The average LFQ values ranged from 18.9 to 35.2 with similar distribution in both groups (t test, P = 0.69; Fig 7A). The major canonical clock proteins were undetectable at E19, with the exception of casein kinases CSNK1D (LFQ 25.1) and CSNK1E (LFQ = 22.1).

Normalized LFQ values were analyzed by various conventional tools for rhythm detection, but no significant circadian changes in protein levels across time points were found by any of the methods and the majority of genes identified to be expressed rhythmically on transcriptomic level were undetectable or not reported in the proteomic analysis.

Using BioCycle as a deep learning system capable of estimating the periodic signal in noisy datasets revealed that both the A and B group datasets were remarkably stable over time, with a maximum of 5% difference between peak and trough values. Nevertheless, BioCycle identified 21 proteins in Group A and 26 proteins in Group B as potentially rhythmic (unadjusted P < 0.01; Fig 7B–7D).

Additionally, normalized LC-MS data of proteins identified as rhythmic on transcript level (n < 500) were compared via CompareRhythms, in spite of apparent limitations of this approach. Only 20 genes (= 4%) were identified as rhythmic in both transcriptomic and proteomic analyses via model-selecting methods (with 9 displaying BICW < 0.5). Most of those genes/proteins were assigned to ABsync (n = 11), followed by Brhy (n = 5) and Arhy (n = 4) by both dryR and CompareRhythms. Only Cdk3 was assigned to different subsets by the 2 methods, with Brhy according to dryR (BICW = 0.39), while CompareRhythms identified it as ABdiff both on transcript and protein level (BICW = 0.58 and 0.60, respectively).

Results of rhythm detection analyses are summarized in. Due to the small number of rhythmic proteins identified both by deep learning system BioCycle and model selection tool CompareRhythms, we did not employ any additional enrichment analyses. S5 Data

Adult male and female Wistar rats (Institute of Physiology, the Czech Academy of Sciences) were housed individually before mating in a temperature-controlled facility at 23 ± 2°C with free access to food and water. They were maintained under a light/dark cycle with 12 hours of light and 12 hours of darkness (LD12:12) with lights on and off at 06:00 and 18:00, respectively. The females were subjected to vaginal smears to determine stage of the estrous cycle phase. Mating was set on the night of pro-estrus and confirmed by presence of sperm in the vaginal smears on the next morning. In case of sperm positivity, this day was defined as day 0 of embryonic development (E0). The pregnant rats were weighted immediately after mating and then again before killing at E18 to E19 to calculate their body weight gain (with and without uterus), and a number of fetuses in the litters were recorded. The locomotor activity was monitored throughout the entire experiment (as described below).

All experiments were approved by the Animal Care and Use Committee of the Institute of Physiology (33/2019) and were performed in accordance with the Animal Protection Law of the Czech Republic as well as the European Community Council directives 86/609/EEC. All efforts were made to reduce the suffering of the animals.

A total of 32 pregnant rats were used in the experiments. On day 7 of gestation, 16 rats were exposed to the sham surgery (Group A; transcriptomic study: n = 8, proteomic study: n = 8) and 16 rats to the surgical procedure for the SCN ablation (Group B; transcriptomic study: n = 8, proteomic study: n = 8); for details on the surgery procedure, see below. Group B included only rats with complete SCN lesion, as confirmed by the absence of locomotor rhythmicity in constant darkness and postmortem histological examination of the coronal brain sections throughout hypothalamic structures. Immediately after the surgery, both groups were released into constant darkness until the end of the experiment. Starting from E11, the rats of Group A continued in the ad libitum feeding regime, whereas the arrhythmic rats of the Group B had food access limited for only 8 hours a day (9:00 to 17:00) to impose group-synchronized feeding rhythmicity. The times of the onset of free-running locomotor activity (Group A) and the beginning of food-related activity (Group B) were assigned as the beginning of subjective night (CT12). The pregnant rats were killed under constant darkness in 3-hour intervals (1 rat per time point) to cover the 24-hour profile (CT0 to CT21) spanning fetal age approximately E18.5 to E19.5 (for clarity, we use E19 in the text). Fetal heads were frozen in dry ice, stored at −70°C, and then sectioned on Cryocut (Leica, Germany) for dissection of the SCN. For RNA-Seq, SCN from 8 fetuses of the same litter/time point were isolated by precooled microbiopsy punch, resulting in a cylindrical sample of SCN-containing frozen tissue with 0.3 mm diameter and approx. 0.4 mm height, then pooled together by immersion in lysis buffer and their RNA isolated on the same day. For proteomics, fetal SCNs were sampled and pooled in a similar way and kept at −70°C until protein extraction at mass spec facility.

The bilateral SCN lesion was performed as previously described (2). The rats were anesthetized with isoflurane inhalation (Isoflurin, Vetpharma Animal Health, Spain) and mounted in a stereotactic instrument (David Kopf Instruments, Tujunga, CA, USA). The eyes were treated with eye drops Ophthalmo-Septonex (Zentiva, Czech Rep.). The electrode tips (0.2 mm diameter) were placed bilaterally into the SCN through drilled holes in the skull (coordinates: 1.3 mm caudal to bregma; ± 0.4 mm to midline; 9.2 mm below brain surface) and 1 mA current pulse was delivered for 20 seconds (53500 Lesion Making Device, Ugo Basile, Italy). The parameters were determined empirically to achieve complete lesion of the SCN and avoiding damage of surrounding tissue. Rats recovered in their home cages that were placed in constant darkness for the rest of the experiment. They received analgesic (NUROFEN Reckitt Benckiser Healthcare International, Great Britain) immediately after the surgery (applied per oral) and then in drinking water (2.5 ml per 250 ml) during the next day. The locomotor activity was monitored by infrared detectors. The success of the surgery was carefully checked behaviorally and histologically; rats with detectable rhythm in locomotor activity in constant darkness, and/or whose in which postmortem histological examination of the hypothalamic sections revealed presence of the SCN or its remaining parts, were excluded from the study. Sham surgery was performed to Group A in order to control for the plausible aftereffects of the surgical procedure on the pregnant rats and their fetuses. The sham-operated animals underwent the same procedure, including anesthesia and electrode insertion but without current application. None of the sham-operated rats exhibited disruption in circadian locomotor rhythmicity under constant darkness. For confirmation of the success of the surgery and intactness of the sham surgery, see Fig 1B.

The locomotor activity was monitored throughout the experiment. The rats were maintained individually in cages equipped with infrared movement detectors attached centrally above the top of each cage, and the activity was detected using a circadian activity monitoring system (Dr. H.M. Cooper, INSERM, France). The activity was recorded every minute and double-plotted activity records and periodograms were generated for visualization of the data. The parameters of circadian rhythmicity were analyzed using the ClockLab toolbox (Actimetrics, Illinois, USA) and Actiwatch Activity & Sleep Analysis V 5.42 software (Cambridge Neurotechnology, UK).

Individual fetal SCN from 1 mother killed at each time point were pooled (n = 8 for Group A, n = 5 to 10 for Group B). RNA was isolated by RNeasy Micro Kit (Qiagen, Germany) according to manufacturer’s instructions, treated with On-Column DNAse I digestion set (Sigma) for 15 minutes at 37°C, then quantified by spectrophotometry. RNA integrity was tested by capillary electrophoresis (Agilent Tech., USA). Samples of purified total RNA (n = 16, 26 to 80 ng/μl, RIN > 9) were processed at Functional Genomics and Bioinformatics Service Laboratory of Institute of Molecular Genetics (Prague, Czechia) as follows: rRNA depletion, polyA RNA enrichment, and library preparation using Smarter Stranded low input tot-RNA-Seq kit v2 (Takara, Japan); sequencing using Illumina NextSeq 500 High output kit v2 (150 cycles, SE). Bioinformatics was performed using nf-core/rnaseq workflow pipeline (10.5281/zenodo.1400710). Reads were mapped to the latest UCSC rn6 (RGSC Rnor_6.0) rat genome assembly by HISAT2 v.2.1.0; read counts and FPKM were calculated by Salmon and Stringtie; all samples passed quality control. Before analysis, deseq2 was used to detect differential expression and to filter out less abundant transcripts—only transcripts with at least 1.5 raw count per million reads (up from default filter of 0.5/million) in at least 3 sample libraries were subsequently analyzed by dryR [33] and CompareRhythms [34] for detection of (differential) circadian expression patterns, clustering, and gene ontology. Normalized transcripts from both groups were categorized into 5 modules with a threshold of BICW > 0.5 based on their time-resolved expression pattern. Moreover, data were independently analyzed by Biocycle [48], eJTK [49], and MetaCycle [50].

Single- and multi-list pathway and process enrichment analysis was carried out on MetaScape [51] (GO Biological Process, Molecular Function and Cellular Component, KEGG, and Reactome pathways; R. norvegicus genome as background) for the subsets identified by dryR and CompareRhythms. Enriched terms (P < 0.01, min. gene count = 3, enrichment factor > 3) were grouped into clusters based on membership similarities (Kappa scores as similarity metric and sub-trees with Kappa > 0.3 considered as 1 cluster represented by the most statistically significant (GO) term). The 12 most statistically significant clusters of the GO Biological Process enrichment analysis of subsets identified by dryR (BICW > 0.5) were rendered as a network plot by Cytoscape 3.8.2. Additional enrichment analyses for each individual model were carried out on GOrilla, using arrhythmic and/or unassigned genes in as background, to confirm the MetaScape results.

Samples (n = 16) of pooled fetal SCN were processed at Laboratory of Mass Spectrometry, Biocev (Prague, Czech Republic). Briefly, total proteins were extracted and digested, and peptides were subsequently analyzed on Orbitrap Fusion Tribrid Mass Spectrometer coupled with UltiMate 3000 RSLCnano liquid chromatography system (Thermo Fisher Scientific, USA). MaxQuant software package v.1.6.10.43 was used to gain final LFQ intensity values of 3,707 unique proteins in all samples; additional 183 peptides were assigned to 2 or more proteins and ca. 1,940 peptides showed undetectable LFQ in one or more samples; these were excluded from the analysis. Normalized data were then evaluated by Biocycle with P < 0.01 required to report potentially significant circadian change in protein levels across time points.

RNA seq data are available at GEO Series accession no. GSE183172. Proteomics data are available as. S5 Data