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ORIGINAL RESEARCH article

Front. Pediatr., 10 May 2023
Sec. Genetics of Common and Rare Diseases
This article is part of the Research Topic The Nexus of Respiratory Control, Autonomic, and Hypothalamic Disorders: Overlapping Phenotypes in CCHS, ROHHAD, and Prader-Willi Syndromes View all 5 articles

Analysis and comparisons of gene expression changes in patient- derived neurons from ROHHAD, CCHS, and PWS

  • 1IPBS Program, Neuroscience Institute, University of Tennessee Health Science Center, Memphis, TN, United States
  • 2Department of Neurology, University of Tennessee Health Science Center, Memphis, TN, United States
  • 3Department of Pediatric Dentistry and Community Oral Health, University of Tennessee Health Science Center, Memphis, TN, United States
  • 4Molecular Bioinformatics Core, University of Tennessee Health Science Center, Memphis, TN, United States
  • 5Department of Pediatrics, Division of Autonomic Medicine, Ann & Robert H. Lurie Children’s Hospital of Chicago and Stanley Manne Children’s Research Institute, Chicago, IL, United States
  • 6Department of Pediatrics, Northwestern University Feinberg School of Medicine, Chicago, IL, United States
  • 7Department of Pediatrics, University of Tennessee Health Science Center, Memphis, TN, United States
  • 8Department of Anatomy and Neurobiology, University of Tennessee Health Science Center, Memphis, TN, United States

Background: Rapid-onset obesity with hypothalamic dysfunction, hypoventilation, and autonomic dysregulation (ROHHAD) syndrome is an ultra-rare neurocristopathy with no known genetic or environmental etiology. Rapid-onset obesity over a 3–12 month period with onset between ages 1.5–7 years of age is followed by an unfolding constellation of symptoms including severe hypoventilation that can lead to cardiorespiratory arrest in previously healthy children if not identified early and intervention provided. Congenital Central Hypoventilation syndrome (CCHS) and Prader-Willi syndrome (PWS) have overlapping clinical features with ROHHAD and known genetic etiologies. Here we compare patient neurons from three pediatric syndromes (ROHHAD, CCHS, and PWS) and neurotypical control subjects to identify molecular overlap that may explain the clinical similarities.

Methods: Dental pulp stem cells (DPSC) from neurotypical control, ROHHAD, and CCHS subjects were differentiated into neuronal cultures for RNA sequencing (RNAseq). Differential expression analysis identified transcripts variably regulated in ROHHAD and CCHS vs. neurotypical control neurons. In addition, we used previously published PWS transcript data to compare both groups to PWS patient-derived DPSC neurons. Enrichment analysis was performed on RNAseq data and downstream protein expression analysis was performed using immunoblotting.

Results: We identified three transcripts differentially regulated in all three syndromes vs. neurotypical control subjects. Gene ontology analysis on the ROHHAD dataset revealed enrichments in several molecular pathways that may contribute to disease pathology. Importantly, we found 58 transcripts differentially expressed in both ROHHAD and CCHS patient neurons vs. control neurons. Finally, we validated transcript level changes in expression of ADORA2A, a gene encoding for an adenosine receptor, at the protein level in CCHS neurons and found variable, although significant, changes in ROHHAD neurons.

Conclusions: The molecular overlap between CCHS and ROHHAD neurons suggests that the clinical phenotypes in these syndromes likely arise from or affect similar transcriptional pathways. Further, gene ontology analysis identified enrichments in ATPase transmembrane transporters, acetylglucosaminyltransferases, and phagocytic vesicle membrane proteins that may contribute to the ROHHAD phenotype. Finally, our data imply that the rapid-onset obesity seen in both ROHHAD and PWS likely arise from different molecular mechanisms. The data presented here describes important preliminary findings that warrant further validation.

1. Introduction

Rapid-onset Obesity with Hypothalamic dysfunction, Hypoventilation, and Autonomic Dysregulation (ROHHAD) is a devastating disorder that affects children primarily between the ages of 1.5–7 years old with a rapid onset of symptoms (13). ROHHAD is an ultra-rare neurocristopathy with only 200 cases described or identified to date (3). The ROHHAD acronym describes the typical order in which this disease unfolds. Rapid-onset obesity, 20–30 pounds over a 3–12 month period, is typically the first symptom that appears for ROHHAD patients (3). This rapid-onset obesity is followed by hypothalamic issues including altered salt/water balance, hypothyroidism, growth hormone insufficiency, altered pubertal onset, and additional hypothalamic symptoms (2). The autonomic nervous system (ANS) dysfunction in ROHHAD includes gastrointestinal (GI) dysfunction, ophthalmologic issues, thermal dysregulation, and cardiac dysrhythmia (2). Nearly half of all ROHHAD patients will present with a neural crest tumor, typically a ganglioneuroma or ganglioneuroblastoma, but rarely a neuroblasoma (3). Alveolar hypoventilation is the most devastating symptom, as it can have a stealth onset and result in cardiorespiratory arrest, potentially leading to severe morbidity or sudden death in previously healthy children (1).

Currently there is no known genetic cause for ROHHAD. The leading theories for the cause of ROHHAD are genetic, epigenetic and autoimmune based (36). Potentially causative genes that have roles in nervous system development have been investigated including BDNF, ASCL1, NDN, ADCYAP1, OTP, PACAP, and HTR1A (2, 7, 8). None of these genes could be correlated to ROHHAD symptomology. Barclay et al. sequenced the exomes of seven ROHHAD trios and found that no two subjects had the same de novo variants (4). Monozygotic twins discordant for ROHHAD were also sequenced with no genetic coding differences noted (4). The authors suggest the possibility of varying epigenomes between the identical female twins leading to this discordance. The presence of anti-hypothalamus and anti-pituitary antibodies in cerebrospinal fluid of ROHHAD patients suggests a possible immune system mediated pathogenesis, although only three case studies have been reported (6, 9). Additionally, immunosuppressive drugs have been found to have a positive effect on the neurological function of one ROHHAD subject (10). To date, no underlying genetic or immunologic etiology has been identified that can explain the ROHHAD phenotype.

Currently, ROHHAD is diagnosed based on clinical presentation after a related syndrome, Congenital Central Hypoventilation Syndrome (CCHS) is ruled out. Similar to ROHHAD, CCHS is a rare neurocristopathy with approximately 3,000 cases identified since 1970 (3). CCHS subjects typically present with hypoventilation from birth and all subjects require ventilatory support (3, 1113). Unlike ROHHAD, CCHS is caused by a genetic lesion in PHOX2B, a transcription factor, primarily from polyalanine repeat expansion mutations (PARMs). The lengths of the PARM repeats correlate linearly with severity of symptoms while a subset of CCHS patients possessing non-PARMs in the PHOX2B gene present with more severe CCHS phenotypes (3, 11). CCHS presents with both ANS dysfunction and hypoventilation, however, there is no rapid-onset obesity and only rarely hypothalamic dysfunction. In terms of ANS dysregulation, CCHS and ROHHAD exhibit overlapping symptoms including ophthalmologic issues, GI dysmotility, and increased pain perception thresholds (1113). Some CCHS patients, typically with an NPARM mutation in PHOX2B, also present with neural crest tumors. The overlapping phenotypes in these syndromes imply a similar molecular etiology, although formal molecular links between ROHHAD and CCHS have not yet been identified.

Prader-Willi syndrome (PWS) is a hypothalamic disorder with some overlapping phenotypic features to ROHHAD including the rapid-onset obesity (14). PWS is caused by the loss of paternal specific expression of the genes SNRPN, SNURF, SNORD116 and MAGEL2 in the PWS critical region (15q11.2–q13.3) on the 15th chromosome. Although the trajectory of the rapid-onset childhood obesity in PWS is less steep than that seen in ROHHAD, and the age at onset differs, the obesity is a defining feature of PWS and is accompanied by extreme hyperphagia (15). Autonomic and hypothalamic dysfunction are present in both PWS and ROHHAD syndrome. Hypothalamic dysfunction overlapping both syndromes includes hypothyroidism, growth hormone insufficiency, and altered pubertal onset. Autonomic dysfunction overlapping the two syndromes includes GI dysmotility, ophthalmologic manifestations, elevated pain threshold and thermal dysregulation (2, 3, 8, 15, 16). Due to these overlapping clinical features, the PWS critical region has been studied in a ROHHAD cohort. Using both next-generation sequencing and methylation sensitive assays of the paternally expressed genes in the region, no variation or loss of heterozygosity was found in the ROHHAD cohort for this region of interest (14). Although no genes within the 15q11.2–q13.3 region were found to be perturbed in ROHHAD, the similarities between these syndromes leave open the possibility that the same molecular pathways are co-regulated and warrants further gene expression studies in patient-derived neurons.

To understand the molecular overlap among ROHHAD, CCHS, and PWS, we performed RNA sequencing (RNAseq) on neurons derived from dental pulp stem cells (DPSC) collected from ROHHAD and CCHS individuals as well as neurotypical controls. DPSC are multipotent stem cells of neural crest origin and have been differentiated to a variety of cell types including chondrocytes, adipocytes, and neurons (1719). DPSC have been found to recapitulate the epigenetic environment of embryonic stem cells more accurately than induced pluripotent stem cells and are obtainable without the need for invasive biopsies or viral reprogramming (20, 21). Many groups have differentiated DPSC to neuronal lineages showing morphological, transcriptional, and functional characteristics of terminally differentiated neurons (2236). Our group and others have had success modeling neurogenetic syndromes using these stem cells differentiated to neuronal cultures (3741). Using this unique patient-derived stem cell model, we have observed molecular signatures and cellular phenotypes of various syndromes in primary neurons including Prader-Willi, Angelman, and Duplication 15q syndromes (4244). Here we utilize this system to differentiate patient-derived DPSC lines to neuronal cultures for RNAseq in order to identify the molecular similarities and find genotype/phenotype correlations among ROHHAD, CCHS and PWS. Early diagnosis and clinical intervention is critical for ROHHAD patients, so identifying molecular markers distinguishing ROHHAD from clinically related syndromes is as important as identifying the molecular commonalities between these syndromes with known genetic lesions.

2. Materials and methods

2.1. Obtaining teeth for DPSC cultures

Neurotypical control teeth were obtained through the Department of Pediatric Dentistry and Community Oral Health at the University of Tennessee Health Science Center (UTHSC). Teeth from children with ROHHAD and CCHS were collected remotely by the caregivers of these subjects after confirmation of the underlying diagnosis. All subjects provided informed consent for tooth collection (IRB#2009-13905 at Lurie Children's Hospital). All 6 ROHHAD subjects have received a ROHHAD diagnosis. 8 of 11 patients were evaluated clinically at Lurie Children's Hospital and their diagnoses confirmed with CCHS-related PHOX2B mutations in CCHS subjects (n = 5) and with clinical phenotyping in ROHHAD subjects (n = 3). The excised deciduous teeth were broken to reveal the pulp, cells cultured and cell lines frozen during early passages for our DPSC Repository as previously described (21). The DPSC Repository and molecular studies on DPSC-derived neurons were approved by the UTHSC institutional review board prior to conducting research (IRB #10-00878-XP).

2.2. Generation of dental pulp stem cell cultures

DPSC used in this study were isolated and cultured according to our previously described protocol and cell lines stored in the DPSC Repository (21). Briefly, the dental pulp was removed from inside the tooth cavity and minced. Following removal, the pulp was digested with 3 mg/ml Dispase II and 4 mg/ml Collagenase I for 1 h. Cells were then seeded on poly-D-Lysine coated 12-well plates with DMEM/F12 1:1, 10% fetal bovine serum (FBS), 10% newborn calf serum (NCS), and 100 U/ml penicillin and 100 ug/ml streptomycin (Pen/Strep) (Fisher Scientific, Waltham, MA). Once confluent (80%) cultures were passaged using TrypLE™ Express. Only early passage cells (≤passage 4) were used for subsequent neuronal differentiation and molecular studies.

2.3. Neuronal differentiation

DPSC lines were seeded at 20,000 cells/cm2 on poly-D-lysine coated flasks with DMEM/F12 1:1, 10% fetal bovine serum (FBS), 10% newborn calf serum (NCS), with 100 U/ml penicillin and 100 ug/ml streptomycin (Pen/Strep). At 80% confluence, the neuronal differentiation protocol was followed as previously published in Kiraly et al., 2009 (37) with an extended maturation phase (4 weeks vs. 7 days) (21). Briefly, DPSC were placed in 10 μM 5-azacytidine (Acros Scientific, Geel, Belgium) in DMEM/F12 containing 2.5% FBS and 10 ng/ml bFGF (Fisher Scientific, Waltham, MA) for 48 h. Following epigenetic reprogramming, neuronal differentiation was induced by exposing the cells to 250 μM IBMX, 50 μM forskolin, 200 nM TPA, 1 mM db-cAMP (Santa Cruz, Dallas, TX), 10 ng/ml bFGF (Invitrogen, Carlsbad, CA), 10 ng/ml NGF (Invitrogen, Carlsbad, CA), 30 ng/ml NT-3 (Peprotech, Rocky Hill, NJ), and 1% insulin-transferrin-sodium selenite premix (ITS) (Fisher Scientific, Waltham, MA) in DMEM/F12 for 3 days. At the end of the neural induction period, neuronal maturation was performed by maintaining the cells in Neurobasal A media (Fisher Scientific, Waltham, MA) with 1 mM db-cAMP, 2% B27, 1% N2 supplement, 30 ng/ml NT-3, and 1X Glutamax (Fisher Scientific, Waltham, MA) for 28 days.

2.4. RNA sequencing of DPSC-neurons

After neuronal maturation for 28 days, total RNA was collected from the DPSC-neurons using the Zymo Directzol RNA extraction kit (Zymo, Irvine, CA). Prior to sequencing, RNA was assayed for integrity and quality using the Agilent Bioanalyzer 6000 pico chip (Agilent, Santa Clara, CA). Only RNA with an RNA Integrity Number (RIN) ≥9.0 was used for RNAseq studies. Library preparation and RNAseq was performed by Novogene (NovaSeq 6000 PE150) (Sacramento, CA) using the Illumina platform and paired end reads. 20 M paired-end reads per sample were collected.

2.5. RNAseq analysis

FASTQ files from Novogene were analyzed for quality and trimmed using FASTQC. All reads were trimmed to remove nucleotides with Phred scores <Q20. The trimmed FASTQ files were aligned to the human genome reference library hg19 using RNASTAR (45). Once aligned, the SAM files were collected and mined for read count information of each gene present in the reference file. Read counts were normalized using Counts per Million (CPM) method across groups for the entire experiment. Principle component analysis and Pearson's coefficient plots were performed on the normalized transcriptome profile. A lmfit and voom was used to perform differential expression analysis (45). All genes that fail to yield a p-value ≤0.05 and a fold change greater than 1.5 were removed. Benjamini and Hochberg false discovery rate (FDR) was performed on this trimmed gene list. All genes that failed to yield an FDR rate of ≤0.05 were removed. The PWS RNAseq dataset used here is from our previously published work (44) and accessible through the GEO database (GEO#: GSE178687). To generate Venn diagrams the final list of significantly differentially expressed genes were uploaded into an online Venn diagram tool (http://bioinformatics.psb.ugent.be/webtools/Venn/). Heatmaps were created using the ClustVis web tool (46). Additionally, the targets were loaded into the web based enrichment analysis tool, Gene Ontology Enrichment Analysis and Visualization Tool (GOrilla) to identify enriched gene ontology (GO) terms (47). The GOrilla software takes the full list of transcripts ranked by False Discovery Rate (FDR) and identifies GO terms that appear densely at the top of the ranked list. GOrilla assigns an enrichment score based on the total number of genes in the dataset (N), the total number of genes associated with a specific GO term (B), the number of genes in the top of the dataset (n), and the number of genes in the intersection (b). The enrichment score is calculated by the formula: (b/n)/(B/N).

2.6. Western blots

Protein was collected from 4-week mature neuronal cultures using N-PER Protein Extraction Reagent (Fisher Scientific, Waltham, MA) supplemented with a protease inhibitor cocktail (Fisher Scientific, Waltham, MA). Samples were resolved on a 4%–12% Bis-Tris gel run at a constant 125 V for 3 h, then transferred for 23 min onto a PVDF membrane using Genscript eBlot machine (L00686). Membranes were blocked at room temperature for 1.5 h in TBS-T with 5% nonfat milk and incubated at 4°C overnight in primary antibodies at 1:2,000. Primary antibodies used: α-ADORA2A (ProteinTech, 51092-1-AP) and α-PHACTR1 (ProteinTech, 23446-1-AP), and loading control α-GAPDH (Santa Cruz, sc-47724). Following overnight incubation with primary antibodies, three 25-minute washes with TBS-T were performed and membranes were incubated with secondary antibodies for 30 min at room temperature. Secondary antibodies used: HRP-conjugated α-rabbit (Cell Signaling, 7074P2) at 1:5,000 dilution and HRP-conjugated α-mouse (Cell Signaling, 7076P2) at 1:10,000 dilution. Following secondary antibody incubation, three 25-minute washes in TBS-T were performed followed by a final 25-minute wash in TBS. Pierce ECL Western (Fisher Scientific, Waltham, MA) reagents were used for GAPDH exposure. SuperSignal West Atto Ultimate Sensitivity ECL (Fisher Scientific, Waltham, MA) reagents were used to develop the ADORA2A and PHACTR1 membranes. Developed films were then digitized as non-compressed.tiff files using a V600 Epson scanner. Files were processed using ImageJ Fiji using the gel quantification plugin. The mean control sample measurements were used to normalize each lane for ADORA2A and GAPDH blots respectively. ADORA2A was then normalized against GAPDH for final protein fold change values. These values were then analyzed in Prism software (GraphPad).

3. Results

3.1. Molecular and phenotypic overlap between ROHHAD, CCHS, and PWS

Table 1 lists the defining ROHHAD features and the presence or absence of these in CCHS and PWS. The rapid-onset obesity, although a less steep trajectory in PWS and differing age at onset, is present in both ROHHAD and PWS. Additionally, PWS and ROHHAD share hypothalamic dysfunction including growth hormone insufficiency, hypothyroidism, and altered pubertal onset (precocious in ROHHAD but delayed in PWS). ROHHAD and CCHS share the hypoventilation phenotype which is the most severe symptom in both syndromes as well as neural crest tumors in a subset of individuals. All three syndromes display ANS dysregulation including gastrointestinal issues and ophthalmologic manifestations.

TABLE 1
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Table 1. Overlapping clinical phenotypes of ROHHAD, CCHS, and PWS. Data for ROHHAD and CCHS taken from Ceccherini, I., et al. (2022). “Developmental disorders affecting the respiratory system: CCHS and ROHHAD.” Handb Clin Neurol 189: 53–9. PWS data taken from Barclay, S. F., et al. (2018). “ROHHAD and Prader-Willi syndrome (PWS): clinical and genetic comparison.” Orphanet J Rare Dis 13(1): 124. Rapid-onset obesity with hypothalamic dysfunction, hypoventilation, and autonomic dysfunction (ROHHAD), Congenital Central Hypoventilation syndrome (CCHS).

To understand the molecular similarities and differences among these three syndromes, RNA sequencing (RNAseq) analysis was performed on DPSC-derived neuronal cultures from neurotypical controls (n = 3) and subjects with ROHHAD (n = 3) or CCHS (n = 2). Throughout this work, we use the term transcript to describe gene-level expression differences. Table 2 lists the GUIDs and clinical characteristics for each subject used in the molecular studies (RNAseq and western blots). For the PWS dataset, we used our previously published RNAseq data from DPSC-neurons (GSE178687) (44). Differential gene expression analysis for each of the syndromes vs. the neurotypical control subjects were analyzed by the UTHSC Bioinformatics Core and significantly (p-value ≤0.05, FDR ≤0.05, Fold change ≥1.5 or ≤0.5) differentially expressed transcripts were identified. Using this list of significantly different transcripts vs. control neurons as well as our previously published RNAseq data from PWS neurons vs. control (n = 4) (44), we created a Venn diagram (Figure 1A). Venn analysis shows ROHHAD neurons have their own unique signature, but also share molecular commonalities with CCHS and PWS. In addition, our data shows that these syndromes share three significantly differentially expressed transcripts vs. control. These transcripts are FOXK1, ZNF18, and FBH1. The normalized RNAseq expression for these shared transcripts across syndromes is shown in Figure 1B. The RNAseq data for each experiment was normalized to the average of the neurotypical control samples in the corresponding experiments. FOXK1 and ZNF18 are both transcriptional regulators. FBH1 is critical for repairing stalled or damaged replication forks during DNA replication. Broadly, these results indicate very little overlap among all three syndromes, but significant overlap between CCHS and ROHHAD gene expression signatures. It should be noted that, although each experiment was normalized to neurotypical control expression, the PWS experiment occurred separately and, as such, batch effects may be present.

FIGURE 1
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Figure 1. ROHHAD, CCHS, and PWS neurons share 3 differentially regulated genes vs. control neurons. (A) Venn diagram of the significantly differentially expressed transcripts (p-value ≤ 0.05, FDR ≤ 0.05, fold-change ≤0.5 or ≥1.5) vs. control for ROHHAD, CCHS, and PWS. Three transcripts were identified as differentially regulated vs. control subjects in all 3 syndromes, while 55 differentially expressed transcripts were shared between ROHHAD and CCHS vs. control. (B) Average RNAseq expression for each group across the three 3 genes shared by ROHHAD, CCHS and PWS vs. controls. Expression was normalized to the average of the control expression in each study. The dashed red line indicates control expression level. PWS data were gathered from our previous RNAseq experiment (44). Significance determined during RNAseq data analysis (p-value ≤ 0.05 and FDR ≤ 0.05). * = p-value ≤ 0.05, ** = p-value ≤ 0.01, *** = p-value ≤ 0.005. Rapid-onset obesity with hypothalamic dysfunction, hypoventilation, and autonomic dysregulation (ROHHAD), Congenital Central Hypoventilation Syndrome (CCHS), Prader-Willi Syndrome (PWS).

TABLE 2
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Table 2. Subjects included in molecular experiments listed by GUID (https://nda.nih.gov/general-query.html) with corresponding clinical phenotypes. For 3 ROHHAD subjects, we have limited clinical data. PHOX2B expansion number listed in parentheses. Age of onset listed in years. Type of neural crest tumor: GN (ganglioneuroma) or NB (neuroblastoma).

3.2. Gene ontology enrichment in receptor, acetylglucosaminyltransferase and immune-mediated processes in ROHHAD neurons

RNAseq analysis identified 225 genes to be significantly differentially expressed in ROHHAD vs. control neurons. Using GOrilla enrichment analysis, we found significant gene ontology (GO) enrichments in these data. GOrilla enrichments are presented in Figure 2A. The top enrichments (enrichment score ≥5) were ATPase transmembrane transporter activity (ATP6V1G2, ABCB9, TAPBP, ABCD4 and TCIRG1), acetylglucosaminyltransferase activity (MGAT1, GCNT3, LFNG and B3GALNT1) and phagocytic vesicle membrane (HLA-A, TAPBP, PIKFYVE and TCIRG1). A heatmap of the genes found in these enrichments across each subject sequenced is shown in Figure 2B. Most of these genes have significantly reduced expression vs. control, while three show increased expression. Gene functions are listed in Supplementary Table S1 (48). Several of the genes identified in the enrichment categories relate to immune system processes and neuroinflammatory syndromes. These enrichment studies on ROHHAD specific neuronal gene expression indicate that at least three molecular pathways may contribute to disease etiology: ATPase transmembrane transporters, acetylglucosaminyltransferases, and phagocytic vesical membrane proteins.

FIGURE 2
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Figure 2. Enrichment analysis of ranked gene expression differences between ROHHAD and control neurons shows significant enrichment in phagocytic vesicle membrane, acetylglucosaminyltransferase activity and transmembrane transporter activity. (A) GOrilla enrichment analysis was used to determine the gene ontology (GO) enrichments in our Control vs. ROHHAD dataset (47). GOrilla analysis identified 3 GO categories (enrichment score ≥ 5) that are significantly enriched (p-value ≤ 0.05) at the top of our ranked gene list. (B) A heatmap was created using the RNAseq expression counts for each ROHHAD and control individual for genes identified in each of the enrichment categories using ClustVis (46).

3.3. Molecular overlap between PWS and ROHHAD May not be related to rapid-onset obesity

The RNAseq data collected in this experiment compared with our previously published RNAseq data (44) revealed six genes that are significantly different in both PWS and ROHHAD vs. control. The Venn diagram in Figure 1A shows this overlap. Three of the six genes found in this intersection are unique to PWS and ROHHAD and are not significantly different in the CCHS vs. control dataset. These genes are ID1, CNN3, and OAZ3. To compare expression across two datasets, the RNAseq data for ROHHAD and PWS subjects was normalized to the average control expression of the transcript in each dataset. This normalized expression was used to create bar graphs for each gene (Supplementary Figure S1). For ID1, PWS and ROHHAD neurons show differing expression trends vs. control. In PWS, ID1 expression is significantly higher, while in ROHHAD expression is significantly lower. One of the primary reasons for comparing PWS to ROHHAD in this experiment was to see if any of the overlapping genes were related to the rapid-onset obesity phenotype seen in each syndrome. The three overlapping genes in our dataset do not currently have any links to an obesity pathogenesis. ID1 is a transcriptional regulator. OAZ3 plays a role in cell proliferation and maintenance. CNN3 is involved in cytoskeletal function and is actin-binding. These results suggest that the obesity in ROHHAD may not share a molecular pathway with PWS and may be distinct in origin. Further validation of this hypothesis in other relevant cell types will be necessary to confirm the independent obesogenic pathology in PWS and ROHHAD.

3.4. Gene expression analysis reveals shared molecular signature between ROHHAD and CCHS neurons

The Venn diagram in Figure 3A shows that there are 58 genes significantly differentially expressed in both ROHHAD and CCHS vs. control. Using the mean RNAseq counts per group, a heatmap was created using ClustVis (46). The heatmap (Figure 3B) indicates that most of these genes are significantly decreased vs. control in both ROHHAD and CCHS. Eight of these genes show higher expression in ROHHAD and CCHS vs. control. For all genes identified in this overlap, the expression trend vs. control is the same for both ROHHAD and CCHS. A list of these genes and their function is listed in Supplementary Table S2 (48). Several of the genes identified encode for proteins that have functions related to neuronal development, including ADAM8, KAT6B and ADIRF. Additionally, ASCC1, COL13A1, SYTL3, TANGO2, PHACTR1, and ADORA2A encode proteins that have functions related to ROHHAD and CCHS phenotypes. These expression studies have revealed molecular overlap between ROHHAD and CCHS neurons vs. neurotypical controls. This implies that similar or the same pathways may be disturbed in both syndromes leading to shared phenotypic characteristics.

FIGURE 3
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Figure 3. ROHHAD and CCHS share 58 differentially expressed genes vs. neurotypical control subjects. (A) Venn diagram created using the list of differentially expressed transcripts (p-value ≤ 0.05, FDR ≤ 0.05, fold-change ≤0.5 or ≥1.5) vs. control subjects. (B) Heatmap of the 58 overlapping transcripts differentially expressed in ROHHAD and CCHS neurons vs. control neurons. Heatmap was created using ClustVis (46).

3.5. ADORA2A protein does not consistently change in ROHHAD but shows reduction in CCHS with increasing PHOX2B PARM number

One gene that changed at the transcript level in neurons and could play a role in both ROHHAD and CCHS is the ADORA2A gene, which encodes an adenosine receptor. ADORA2A is a strong candidate for validation due to its link to Parkinson disease and functional overlap with CCHS phenotypes. We used western blot analysis of ADORA2A protein in ROHHAD and CCHS DPSC-derived neurons vs. neurotypical controls to verify that changes in gene expression are reflected at the protein level (Figure 4A). There was no consistency amongst ROHHAD individuals for ADORA2A protein regulation (Figure 4B). Two individuals, 5WLY and ERBJ, showed reduction (∼55% and ∼85%) in ADORA2A levels compared to the average control groups. One individual, 4GNH, showed an increase (∼132%) in ADORA2A. The remaining ROHHAD individual, 2JYM, displayed ADORA2A protein expression close to control levels.

FIGURE 4
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Figure 4. Western blot analysis of ADORA2A reveals differential expression in ROHHAD and CCHS neurons. (A) ECL western blot of ADORA2A in Control, ROHHAD, and CCHS groups. An average of all four controls was used for normalization and comparison to each of the four individual ROHHAD and the four individual CCHS cell lines. The graphs were scaled differently for ROHHAD vs. CCHS comparisons, but the same control samples and averages were used in B and C. (B) Quantification of ADORA2A protein in ROHHAD individuals. Standard deviation values (σ) are derived from the average of the control samples (n = 4). 5WLY and ERBJ show a reduction in ADORA2 protein, 4GNH shows a nominal increase in protein expression and 2JYM remains near control expression. (C) ADORA2A quantification in CCHS individuals. 0HZG (20/25) and 2YV2 (20/26) show a reduction in ADORA2A expression. 9GXE (20/27) and KWXE (20/33) show a dramatic reduction in signal >2 standard deviations from the control average value.

CCHS individuals exhibited a decrease in ADORA2A protein expression that correlated to an increase in PARM number. The 20/25 PARM individual (0HZG) showed a reduction (∼51%) in ADORA2A protein. Whereas the 20/26 (2YV2) individual showed a reduction of 23%. The PARM 20/27 (9GXE) and 20/33 (KWXE) individuals showed a reduction (∼62%) of ADORA2A protein, both raw expression values for these two samples were >2 standard deviations from the average control expression value (Figure 4C). Supplementary Figure S2 shows an additional ADORA2A western blot using a 10% Bis-Tris gel and nitrocellulose membrane performed prior to the optimized blot shown in Figure 4. Sample TP312 was replaced with sample TP195 in Figure 4. We also examined another protein of interest, PHACTR1, however, it showed no consistency amongst controls, ROHHAD, and CCHS DPSC-derived neuron lines (Supplementary Figure S3). These studies may indicate a possible trend between decreasing ADORA2A expression and more severe CCHS genotypes (i.e., PARMS ≥20/27). Further validation in a larger cohort of CCHS subjects with varying PARM mutations will be necessary to confirm PHOX2B-mediated regulation of ADORA2A.

4. Discussion

Uncovering the molecular commonalities and differences among these three syndromes is a crucial next step for identifying therapeutics and biomarkers specific to ROHHAD. Here, we used our unique model system, DPSC-derived neurons, to investigate molecular perturbations in these syndromes vs. neurotypical children and identify unique and overlapping transcriptional signatures. Previously, we used DPSC neuronal cultures to investigate neurogenetic syndromes including Prader-Willi, Angelman, and Duplication 15q syndrome (4244). In this study, using RNAseq from individuals with ROHHAD, CCHS, and neurotypical children, we identified differentially expressed transcripts with shared expression between ROHHAD and CCHS. We then used previously published RNAseq data from PWS DPSC-derived neuronal cultures to compare these syndromes to PWS subjects (44). We identified gene ontology enrichments in ROHHAD neurons, three transcripts that are differentially expressed in all three syndromes vs. neurotypical control neurons and 58 transcripts that are differentially expressed in both ROHHAD and CCHS neurons.

For ROHHAD, CCHS, and PWS the three transcripts that are significantly different between all three syndromes vs. control neurons were FOXK1, FBH1, and ZNF18. All three genes play roles in maintaining DNA integrity or transcriptional regulation.

4.1. FOXK1

FOXK1 is crucial in regulating glucose metabolism and aerobic glycolysis (49, 50). Compared to control neurons, ROHHAD, CCHS, and PWS neurons all had reduced expression of FOXK1. The reduction in expression in neurons from these three syndromes may pertain to a delay in neurogenesis, a feature shared among many developmental disorders. As stem cells develop into neurons, they switch their primary metabolic processes from glycolysis to mitochondrial respiration (51). FOXK1 plays a key role in this process (50). Additionally, FOXK1 has been associated with autism and delayed development in several studies (52, 53).

4.2. FBH1

FBH1 plays a role in responding to stalled or damaged replication forks. In response to DNA damage, FBH1 causes DNA double-stranded breaks and induces cell death (5456). ROHHAD, CCHS, and PWS have increased FBH1 expression compared to control neurons. The increased expression of FBH1 may be caused by or causative of increased DNA damage in disease neurons. Studies have shown that FBH1 is required for eliminating cells with excessive replicative stress (54). Additionally, accumulation of damaged DNA has been directly linked to neuronal death in other syndromes, such as Alzheimer's disease (57, 58).

4.3. ZNF18

ZNF18 is involved in regulating transcription through RNA polymerase II. Although the function of this protein has not been well characterized, mutations in this gene have been associated with autism (59). This association may explain the differing directionality in expression for ROHHAD and CCHS vs. PWS, where the incidence of autism spectrum disorder is higher (60, 61). Expression of ZNF18 in PWS neurons is significantly decreased vs. control. In contrast, ZNF18 expression is significantly increased in ROHHAD and CCHS neurons.

Enrichment analysis using the ranked list of differentially expressed transcripts between ROHHAD vs. neurotypical control neurons identified significant enrichments in the phagocytic vesicle membrane compartment (GO:0045335), transmembrane transporter activity (GO:0042626), and acetylglucosaminyltransferase activity (GO:0008375). The four transcripts identified in the phagocytic vesicle membrane enrichment were HLA-A, TAPBP, PIKFYVE and TCIRG1. A phagocytic vesicle is an intracellular vesicle that arises due to phagocytosis, a key cellular process for eliminating cellular waste and maintaining cellular homeostasis (62). In neurons, dysfunctional phagocytosis, either excessive or not enough, is detrimental to neuronal development and health (63). Excessive microglial phagocytosis of live neurons and synapses has been implicated in various neurodegenerative disorders including Alzheimer's and Parkinson's disease (64, 65).

In ROHHAD neurons, there was an increased expression in the HLA-A and PIKFYVE transcripts and decreased expression of the TAPBP and TCIRG1 genes. HLA-A encodes the antigen-presenting major histocompatibility complex class I, A. This molecule plays a critical role in the immune system by presenting peptides for recognition to cytotoxic T cells (48). Inhibition of PIKFYVE, an endosomal kinase, was shown to reduce excitotoxicity and restore lysosomal maturation, in a cell model of Amyotrophic Lateral Sclerosis (66). Most transcripts identified in the acetylglucosaminyltransferase activity enrichment (MGAT1, GCNT3, LFNG and B3GALNT1) were decreased in the ROHHAD neurons. Acetylglucosaminyltransferase activity is crucial for glycosylation, an important and complex post translational modification crucial for regulation of neuronal intercellular signaling. In Drosophila melanogaster, Mgat1 null mutants were found to have disrupted synaptogenesis and signaling (67). Interestingly, MGAT1 variants are associated with susceptibility to obesity (68). Decreased glycosylation activity is associated with neuronal death and neurodegenerative disease (69).

All transcripts identified in the transmembrane transporter activity category were decreased in the ROHHAD neurons. Several of the protein products of these transcripts localize to lysosomes. Neuronal lysosomes are crucial for degrading cellular debris and maintaining neuronal integrity. All the enrichment data taken together may allude to a dysfunction in clearing cellular debris and leading to decreased neuronal health in affected neurons or an immune mediated process related to ROHHAD and the propensity for ROHHAD neural crest cells to migrate and develop neural crest tumors in the body as DPSC are of neural crest origin.

We identified three transcripts that were uniquely significantly different between ROHHAD and PWS vs. control (ID1, CNN3, and OAZ3). Although one of the primary commonalities between these syndromes is childhood obesity, these three genes do not appear to be related to obesity and two of these genes appear to have opposing expression patterns vs. control neurons. Our molecular findings indicate that while both ROHHAD and PWS subjects present with childhood obesity, it is likely that the pathways responsible for obesity in these disorders arise from distinct molecular and perhaps even behavioral defects. Lending support to this theory, PWS subjects are profoundly hyperphagic which is not routinely an underlying cause of obesity in ROHHAD patients (3).

Of note, we identified 58 significantly differentially expressed transcripts vs. neurotypical controls in common between CCHS and ROHHAD, all following similar expression patterns [i.e., both syndromes show either increased or decreased expression for the same gene vs. control (see Figure 3B)]. Within the 58 genes, we did not find any significant gene ontology enrichments, however, we did identify transcripts that correlate with neuronal processes and the phenotypes observed in both ROHHAD and CCHS, including ASCC1, COL13A1, TANGO2, and PHACTR1.

4.4. ASCC1

ASCC1, a gene encoding for a transcriptional regulator, was found to be significantly increased in ROHHAD and CCHS neurons. This transcript has been associated with several congenital neuromuscular diseases including spinal muscular atrophy (7072).

4.5. COL13A1

COL13A1, which encodes an extracellular synaptic protein that is required for neuromuscular junction synapse function, was significantly decreased in ROHHAD and CCHS neurons. Mutations in this gene are associated with a spectrum of myasthenic diseases that result in breathing difficulties and apneas (7375).

4.6. TANGO2

TANGO2 mutations and deficiency are associated with a variety of symptoms including hypothyroidism, metabolic and cardiac dysfunction, and rhabdomyolysis (7679). This gene was found to be significantly decreased in our dataset for both ROHHAD and CCHS vs. control neurons.

4.7. PHACTR1

PHACTR1 encodes a phosphatase and actin regulatory protein that plays a role in neuronal migration and dendritic arborization. Although we did see a reduction in PHACTR1 protein by western blot in several of the ROHHAD and CCHS subjects (Supplementary Figure S3) in accordance with our RNAseq data, this result was variable from individual to individual.

An adenosine receptor gene, ADORA2A, was also found to be decreased in the ROHHAD and CCHS neurons vs. neurotypical controls. ADORA2A encodes a member of a G-protein coupled receptor family that functions by increasing cAMP levels using adenosine as its primary agonist and is associated with Parkinson's disease (80, 81). Physiologically, ADORA2A aides in regulation of cardiac rhythm and circulation, cerebral and renal blood flow, immune function, pain regulation and sleep. In Adora2a−/− mice, Adora2a specifically modulates the antiadrenergic effects of the Adora1 receptor (82). Treatment with isoproterenol, a β-adrenergic molecule agonist, in WT and Adora2a−/− mice both showed antiadrenergic responses, with Adora2a−/− mice exhibiting a ∼40% increase in antiadrenergic response. These findings supplement prior work showing decreased heart rate (HR) in Adora2a−/− mice and an increase in HR for Adora1−/− mice (83). Previous clinical studies on ROHHAD patients show that some cases may present with bradycardia, a low resting heart rate (84). The observed reduction of ADORA2A protein levels in two ROHHAD individuals may be able to explain this clinical feature. ADORA2A is thought to provide a protective effect against the development of pulmonary hypertension (85), another clinical phenotype that presents in some ROHHAD individuals consequent to recurrent low oxygen due to inadequately managed hypoventilation (5, 86). Our findings that CCHS individuals have decreasing ADORA2A protein expression with increasing PHOX2B PARM number suggests that ADORA2A regulation may be dependent on proper PHOX2B activity. In fact, two PHOX2B transcription factor binding sites can be found in or near the promoter of the ADORA2A gene (Supplementary Figure S4). The variance seen in the ROHHAD subjects for ADORA2A protein expression, as well as PHACTR1, is likely due to the spectrum of ROHHAD symptomology that unfolds across time and with varying severity. Further studies will be needed to establish that PHOX2B can directly regulate ADORA2A gene expression levels, which could be an important finding in both ROHHAD and CCHS.

The results presented here represent the first study using primary ROHHAD and CCHS neurons and showing molecular correlation between CCHS and ROHHAD pathogenesis. Although groundbreaking, there are some limitations to the interpretation of the data. As this is a rare syndrome, we were limited in the amount of specimen used for both RNAseq and western blot analysis. Further validation of these results in larger cohorts of ROHHAD and CCHS subjects will be necessary to confirm the results presented here. The PWS RNAseq data used for comparison here came from a separate experiment and, as such, batch effects may make comparing to the current study problematic. Additionally, these are developmentally young cortical-like neurons. However, the early neurodevelopmental timeframe that this model represents provides evidence of perturbed pathways seen even in immature neurons and provides insight into disease pathogenesis that is present from early neurodevelopment and may have significant downstream effects on later developmental phenotypes.

5. Conclusions

ROHHAD is a complex ANS disorder with an unknown genetic etiology. Although molecular, genetic, and clinical studies have been performed on ROHHAD and CCHS patients before, this is the first gene expression study on neurons derived from these individuals. In addition, no molecular or cellular pathways had previously been identified that reveal the underlying disease etiology. Here we uncovered an enrichment in differentially expressed transcripts related to phagocytic vesicle and receptor-mediated processes in ROHHAD neurons and an overlapping molecular signature between both ROHHAD and CCHS, a related ANS hypoventilation disorder. This overlap includes transcripts that control neurodevelopmental processes and molecular pathways that may be perturbed leading to ROHHAD pathology. We then validated the expression of a down-regulated transcript, ADORA2A, at the protein level and found a reduction in ADORA2A protein for CCHS neurons and several ROHHAD subjects, although expression appears to vary more in the ROHHAD cohort. This variability in ROHHAD subjects likely reflects the broad spectrum of ROHHAD symptoms, the unfolding of the phenotype over time, and the unknown etiology of the disease. The data presented here describes important preliminary findings that warrant further validation in other CCHS affected individuals. Continuing molecular studies and correlation with clinical phenotypes will be essential to uncovering the molecular pathways behind the various ROHHAD symptoms and identifying biomarkers that can be used to diagnose and treat ROHHAD early in the disease process.

Data availability statement

The data presented in the study are deposited in the NIH Gene Expression Omnibus (GEO), accession number GSE216125.

Ethics Statement

The UTHSC Institutional Review Board (IRB) approved this study and informed consent was obtained for both participation and publication of results in accordance with IRB policy at Lurie Children's Hospital.

Author contributions

LTR and DEW-M conceived of and acquired funding for this study. AKV and TH grew cultures and performed experiments. DEW-M and CMR collected clinical information, provided subject DPSC samples, and edited the manuscript. DJ performed bioinformatic analysis. AKV, TH and LTR analyzed data and wrote the manuscript. All authors contributed to the article and approved the submitted version.

Funding

These experiments were funded by a pilot research grant to LTR and DEW-M from ROHHAD Association as well as funds to LTR from the Foundation for Prader-Willi Research.

Acknowledgments

The authors would like to thank the ROHHAD, CCHS and PWS families who donated teeth to this study. We also thank the ROHHAD International Consortium and ROHHAD Fight for advertising this study to potential participants and for their continued support of our work.

Conflict of interest

The authors declare that the research was conducted in the absence of any commercial or financial relationships that could be construed as a potential conflict of interest.

Publisher's note

All claims expressed in this article are solely those of the authors and do not necessarily represent those of their affiliated organizations, or those of the publisher, the editors and the reviewers. Any product that may be evaluated in this article, or claim that may be made by its manufacturer, is not guaranteed or endorsed by the publisher.

Supplementary material

The Supplementary Material for this article can be found online at: https://www.frontiersin.org/articles/10.3389/fped.2023.1090084/full#supplementary-material.

References

1. Carroll MS, Patwari PP, Kenny AS, Brogadir CD, Stewart TM, Weese-Mayer DE. Rapid-onset obesity with hypothalamic dysfunction, hypoventilation, and autonomic dysregulation (ROHHAD): response to ventilatory challenges. Pediatr Pulmonol. (2015) 50(12):1336–45. doi: 10.1002/ppul.23164

PubMed Abstract | CrossRef Full Text | Google Scholar

2. Ize-Ludlow D, Gray JA, Sperling MA, Berry-Kravis EM, Milunsky JM, Farooqi IS, et al. Rapid-onset obesity with hypothalamic dysfunction, hypoventilation, and autonomic dysregulation presenting in childhood. Pediatrics. (2007) 120(1):e179–88. doi: 10.1542/peds.2006-3324

PubMed Abstract | CrossRef Full Text | Google Scholar

3. Ceccherini I, Kurek KC, Weese-Mayer DE. Developmental disorders affecting the respiratory system: CCHS and ROHHAD. Handb Clin Neurol. (2022) 189:53–91. doi: 10.1016/B978-0-323-91532-8.00005-7

PubMed Abstract | CrossRef Full Text | Google Scholar

4. Barclay SF, Rand CM, Borch LA, Nguyen L, Gray PA, Gibson WT, et al. Rapid-onset obesity with hypothalamic dysfunction, hypoventilation, and autonomic dysregulation (ROHHAD): exome sequencing of trios, monozygotic twins and tumours. Orphanet J Rare Dis. (2015) 10:103. doi: 10.1186/s13023-015-0314-x

PubMed Abstract | CrossRef Full Text | Google Scholar

5. Patwari PP, Rand CM, Berry-Kravis EM, Ize-Ludlow D, Weese-Mayer DE. Monozygotic twins discordant for ROHHAD phenotype. Pediatrics. (2011) 128(3):e711–5. doi: 10.1542/peds.2011-0155

PubMed Abstract | CrossRef Full Text | Google Scholar

6. Giacomozzi C, Guaraldi F, Cambiaso P, Niceta M, Verrillo E, Tartaglia M, et al. Anti-hypothalamus and anti-pituitary auto-antibodies in ROHHAD syndrome: additional evidence supporting an autoimmune etiopathogenesis. Horm Res Paediatr. (2019) 92(2):124–32. doi: 10.1159/000499163

PubMed Abstract | CrossRef Full Text | Google Scholar

7. Rand CM, Patwari PP, Rodikova EA, Zhou L, Berry-Kravis EM, Wilson RJ, et al. Rapid-onset obesity with hypothalamic dysfunction, hypoventilation, and autonomic dysregulation: analysis of hypothalamic and autonomic candidate genes. Pediatr Res. (2011) 70(4):375–8. doi: 10.1203/PDR.0b013e318229474d

PubMed Abstract | CrossRef Full Text | Google Scholar

8. De Pontual L, Trochet D, Caillat-Zucman S, Abou Shenab OA, Bougneres P, Crow Y, et al. Delineation of late onset hypoventilation associated with hypothalamic dysfunction syndrome. Pediatr Res. (2008) 64(6):689–94. doi: 10.1203/PDR.0b013e318187dd0e

PubMed Abstract | CrossRef Full Text | Google Scholar

9. Sartori S, Priante E, Pettenazzo A, Marson P, Suppiej A, Benini F, et al. Intrathecal synthesis of oligoclonal bands in rapid-onset obesity with hypothalamic dysfunction, hypoventilation, and autonomic dysregulation syndrome: new evidence supporting immunological pathogenesis. J Child Neurol. (2014) 29(3):421–5. doi: 10.1177/0883073812469050

PubMed Abstract | CrossRef Full Text | Google Scholar

10. Hawton KAC, Doffinger R, Ramanan AV, Langton Hewer SC, Evans HJ, Giri D, et al. Rituximab therapy in ROHHAD(NET) syndrome. J Pediatr Endocrinol Metab. (2022) 35(8):1102–6. doi: 10.1515/jpem-2022-0085

PubMed Abstract | CrossRef Full Text | Google Scholar

11. Zhou A, Rand CM, Hockney SM, Niewijk G, Reineke P, Speare V, et al. Paired-like homeobox gene (PHOX2B) nonpolyalanine repeat expansion mutations (NPARMs): genotype-phenotype correlation in congenital central hypoventilation syndrome (CCHS). Genet Med. (2021) 23(9):1656–63. doi: 10.1038/s41436-021-01178-x

PubMed Abstract | CrossRef Full Text | Google Scholar

12. Weese-Mayer DE, Rand CM, Khaytin I, Slattery SM, Yap KL, Marazita ML, et al. Congenital central hypoventilation syndrome. In: Adam MP, Everman DB, Mirzaa GM, Pagon RA, Wallace SE, Bean LJH, et al., editors. Genereviews(®). Seattle (WA): University of Washington, Seattle (2021). p. 626–44.

13. Weese-Mayer DE, Berry-Kravis EM, Ceccherini I, Keens TG, Loghmanee DA, Trang H. An official ATS clinical policy statement: congenital central hypoventilation syndrome: genetic basis, diagnosis, and management. Am J Respir Crit Care Med. (2010) 181(6):626–44. doi: 10.1164/rccm.200807-1069ST

PubMed Abstract | CrossRef Full Text | Google Scholar

14. Barclay SF, Rand CM, Nguyen L, Wilson RJA, Wevrick R, Gibson WT, et al. ROHHAD And prader-willi syndrome (PWS): clinical and genetic comparison. Orphanet J Rare Dis. (2018) 13(1):124. doi: 10.1186/s13023-018-0860-0

PubMed Abstract | CrossRef Full Text | Google Scholar

15. Cassidy SB, Schwartz S, Miller JL, Driscoll DJ. Prader-Willi syndrome. Genet Med. (2012) 14(1):10–26. doi: 10.1038/gim.0b013e31822bead0

PubMed Abstract | CrossRef Full Text | Google Scholar

16. Cassidy SB, Driscoll DJ. Prader-Willi syndrome. Eur J Hum Genet. (2009) 17(1):3–13. doi: 10.1038/ejhg.2008.165

PubMed Abstract | CrossRef Full Text | Google Scholar

17. Gronthos S, Brahim J, Li W, Fisher LW, Cherman N, Boyde A, et al. Stem cell properties of human dental pulp stem cells. J Dent Res. (2002) 81(8):531–5. doi: 10.1177/154405910208100806

PubMed Abstract | CrossRef Full Text | Google Scholar

18. Miura M, Gronthos S, Zhao M, Lu B, Fisher LW, Robey PG, et al. SHED: stem cells from human exfoliated deciduous teeth. Proc Natl Acad Sci U S A. (2003) 100(10):5807–12. doi: 10.1073/pnas.0937635100

PubMed Abstract | CrossRef Full Text | Google Scholar

19. Victor AK, Reiter LT. Dental pulp stem cells for the study of neurogenetic disorders. Hum Mol Genet. (2017) 26(R2):R166–R71. doi: 10.1093/hmg/ddx208

PubMed Abstract | CrossRef Full Text | Google Scholar

20. Dunaway K, Goorha S, Matelski L, Urraca N, Lein PJ, Korf I, et al. Dental pulp stem cells model early life and imprinted DNA methylation patterns. Stem Cells. (2017) 35(4):981–8. doi: 10.1002/stem.2563

PubMed Abstract | CrossRef Full Text | Google Scholar

21. Goorha S, Victor AK, Reiter LT. Culturing and neuronal differentiation of human dental pulp stem cells. Curr Protoc. (2022) 2(11):e600. doi: 10.1002/cpz1.600

PubMed Abstract | CrossRef Full Text | Google Scholar

22. Ferro F, Spelat R, Baheney CS. Dental pulp stem cell (DPSC) isolation, characterization, and differentiation. Methods Mol Biol. (2014) 1210:91–115. doi: 10.1007/978-1-4939-1435-7_8

PubMed Abstract | CrossRef Full Text | Google Scholar

23. Rafiee F, Pourteymourfard-Tabrizi Z, Mahmoudian-Sani MR, Mehri-Ghahfarrokhi A, Soltani A, Hashemzadeh-Chaleshtori M, et al. Differentiation of dental pulp stem cells into neuron-like cells. Int J Neurosci. (2020) 130(2):107–16. doi: 10.1080/00207454.2019.1664518

PubMed Abstract | CrossRef Full Text | Google Scholar

24. Geng YW, Zhang Z, Liu MY, Hu WP. Differentiation of human dental pulp stem cells into neuronal by resveratrol. Cell Biol Int. (2017) 41(12):1391–8. doi: 10.1002/cbin.10835

PubMed Abstract | CrossRef Full Text | Google Scholar

25. Gonmanee T, Arayapisit T, Vongsavan K, Phruksaniyom C, Sritanaudomchai H. Optimal culture conditions for neurosphere formation and neuronal differentiation from human dental pulp stem cells. J Appl Oral Sci. (2021) 29:e20210296. doi: 10.1590/1678-7757-2021-0296

PubMed Abstract | CrossRef Full Text | Google Scholar

26. Kogo Y, Seto C, Totani Y, Mochizuki M, Nakahara T, Oka K, et al. Rapid differentiation of human dental pulp stem cells to neuron-like cells by high K(+) stimulation. Biophys Physicobiol. (2020) 17:132–9. doi: 10.2142/biophysico.BSJ-2020023

PubMed Abstract | CrossRef Full Text | Google Scholar

27. Zainal Ariffin SH, Kermani S, Zainol Abidin IZ, Megat Abdul Wahab R, Yamamoto Z, Senafi S, et al. Differentiation of dental pulp stem cells into neuron-like cells in serum-free medium. Stem Cells Int. (2013) 2013:250740. doi: 10.1155/2013/250740

PubMed Abstract | CrossRef Full Text | Google Scholar

28. Al-Maswary AA, O'Reilly M, Holmes AP, Walmsley AD, Cooper PR, Scheven BA. Exploring the neurogenic differentiation of human dental pulp stem cells. PLoS One. (2022) 17(11):e0277134. doi: 10.1371/journal.pone.0277134

PubMed Abstract | CrossRef Full Text | Google Scholar

29. Chun SY, Soker S, Jang YJ, Kwon TG, Yoo ES. Differentiation of human dental pulp stem cells into dopaminergic neuron-like cells in vitro. J Korean Med Sci. (2016) 31(2):171–7. doi: 10.3346/jkms.2016.31.2.171

PubMed Abstract | CrossRef Full Text | Google Scholar

30. Osathanon T, Sawangmake C, Nowwarote N, Pavasant P. Neurogenic differentiation of human dental pulp stem cells using different induction protocols. Oral Dis. (2014) 20(4):352–8. doi: 10.1111/odi.12119

PubMed Abstract | CrossRef Full Text | Google Scholar

31. Liu Z, Tang Y, Lu S, Zhou J, Du Z, Duan C, et al. The tumourigenicity of iPS cells and their differentiated derivatives. J Cell Mol Med. (2013) 17(6):782–91. doi: 10.1111/jcmm.12062

PubMed Abstract | CrossRef Full Text | Google Scholar

32. Cho Y-A, Kim D-S, Song M, Bae W-J, Lee S, Kim E-C. Protein interacting with never in mitosis A-1 induces glutamatergic and GABAergic neuronal differentiation in human dental pulp stem cells. J Endod. (2016) 42(7):1055–61. doi: 10.1016/j.joen.2016.04.004

PubMed Abstract | CrossRef Full Text | Google Scholar

33. Young FI, Telezhkin V, Youde SJ, Langley MS, Stack M, Kemp PJ, et al. Clonal heterogeneity in the neuronal and glial differentiation of dental pulp stem/progenitor cells. Stem Cells Int. (2016) 2016:1290561. doi: 10.1155/2016/1290561

PubMed Abstract | CrossRef Full Text | Google Scholar

34. Solis-Castro OO, Boissonade FM, Rivolta MN. Establishment and neural differentiation of neural crest-derived stem cells from human dental pulp in serum-free conditions. Stem Cells Transl Med. (2020) 9(11):1462–76. doi: 10.1002/sctm.20-0037

PubMed Abstract | CrossRef Full Text | Google Scholar

35. Kanafi M, Majumdar D, Bhonde R, Gupta P, Datta I. Midbrain cues dictate differentiation of human dental pulp stem cells towards functional dopaminergic neurons. J Cell Physiol. (2014) 229(10):1369–77. doi: 10.1002/jcp.24570

PubMed Abstract | CrossRef Full Text | Google Scholar

36. Majumdar D, Kanafi M, Bhonde R, Gupta P, Datta I. Differential neuronal plasticity of dental pulp stem cells from exfoliated deciduous and permanent teeth towards dopaminergic neurons. J Cell Physiol. (2016) 231:2048–63. doi: 10.1002/jcp.25314

PubMed Abstract | CrossRef Full Text | Google Scholar

37. Kiraly M, Porcsalmy B, Pataki A, Kadar K, Jelitai M, Molnar B, et al. Simultaneous PKC and cAMP activation induces differentiation of human dental pulp stem cells into functionally active neurons. Neurochem Int. (2009) 55:323–32. doi: 10.1016/j.neuint.2009.03.017

PubMed Abstract | CrossRef Full Text | Google Scholar

38. Urraca N, Memon R, El-Iyachi I, Goorha S, Valdez C, Tran QT, et al. Characterization of neurons from immortalized dental pulp stem cells for the study of neurogenetic disorders. Stem Cell Res. (2015) 15(3):722–30. doi: 10.1016/j.scr.2015.11.004

PubMed Abstract | CrossRef Full Text | Google Scholar

39. Hirofuji S, Hirofuji Y, Kato H, Masuda K, Yamaza H, Sato H, et al. Mitochondrial dysfunction in dopaminergic neurons differentiated from exfoliated deciduous tooth-derived pulp stem cells of a child with rett syndrome. Biochem Biophys Res Commun. (2018) 498(4):898–904. doi: 10.1016/j.bbrc.2018.03.077

PubMed Abstract | CrossRef Full Text | Google Scholar

40. Nguyen HTN, Kato H, Masuda K, Yamaza H, Hirofuji Y, Sato H, et al. Impaired neurite development associated with mitochondrial dysfunction in dopaminergic neurons differentiated from exfoliated deciduous tooth-derived pulp stem cells of children with autism spectrum disorder. Biochem Biophys Rep. (2018) 16:24–31. doi: 10.1016/j.bbrep.2018.09.004

PubMed Abstract | CrossRef Full Text | Google Scholar

41. Pham TTM, Kato H, Yamaza H, Masuda K, Hirofuji Y, Sato H, et al. Altered development of dopaminergic neurons differentiated from stem cells from human exfoliated deciduous teeth of a patient with down syndrome. BMC Neurol. (2018) 18(1):132. doi: 10.1186/s12883-018-1140-2

PubMed Abstract | CrossRef Full Text | Google Scholar

42. Chen H, Victor AK, Klein J, Tacer KF, Tai DJ, de Esch C, et al. Loss of MAGEL2 in prader-willi syndrome leads to decreased secretory granule and neuropeptide production. JCI Insight. (2020) 5(17):e138576. doi: 10.1172/jci.insight.138576

PubMed Abstract | CrossRef Full Text | Google Scholar

43. Urraca N, Hope K, Victor AK, Belgard TG, Memon R, Goorha S, et al. Significant transcriptional changes in 15q duplication but not angelman syndrome deletion stem cell-derived neurons. Mol Autism. (2018) 9:6. doi: 10.1186/s13229-018-0191-y

PubMed Abstract | CrossRef Full Text | Google Scholar

44. Victor AK, Donaldson M, Johnson D, Miller W, Reiter LT. Molecular changes in prader-willi syndrome neurons reveals clues about increased autism susceptibility. Front Mol Neurosci. (2021) 14:747855. doi: 10.3389/fnmol.2021.747855

PubMed Abstract | CrossRef Full Text | Google Scholar

45. Phipson B, Lee S, Majewski IJ, Alexander WS, Smyth GK. Robust hyperparameter estimation protects against hypervariable genes and improves power to detect differential expression. Ann Appl Stat. (2016) 10(2):946–63. doi: 10.1214/16-AOAS920

PubMed Abstract | CrossRef Full Text | Google Scholar

46. Metsalu T, Vilo J. Clustvis: a web tool for visualizing clustering of multivariate data using principal component analysis and heatmap. Nucleic Acids Res. (2015) 43(W1):W566–W70. doi: 10.1093/nar/gkv468

PubMed Abstract | CrossRef Full Text | Google Scholar

47. Eden E, Navon R, Steinfeld I, Lipson D, Yakhini Z. GOrilla: a tool for discovery and visualization of enriched GO terms in ranked gene lists. BMC Bioinformatics. (2009) 10(1):48. doi: 10.1186/1471-2105-10-48

PubMed Abstract | CrossRef Full Text | Google Scholar

48. Safran M, Rosen N, Twik M, BarShir R, Stein TI, Dahary D, et al. The GeneCards suite. In: Abugessaisa I, Kasukawa T, editors. Practical guide to life science databases. Singapore: Springer Nature Singapore (2021). p. 27–56.

49. Sakaguchi M, Cai W, Wang CH, Cederquist CT, Damasio M, Homan EP, et al. FOXK1 and FOXK2 in insulin regulation of cellular and mitochondrial metabolism. Nat Commun. (2019) 10(1):1582. doi: 10.1038/s41467-019-09418-0

PubMed Abstract | CrossRef Full Text | Google Scholar

50. Sukonina V, Ma H, Zhang W, Bartesaghi S, Subhash S, Heglind M, et al. FOXK1 And FOXK2 regulate aerobic glycolysis. Nature. (2019) 566(7743):279–83. doi: 10.1038/s41586-019-0900-5

PubMed Abstract | CrossRef Full Text | Google Scholar

51. Hu C, Fan L, Cen P, Chen E, Jiang Z, Li L. Energy metabolism plays a critical role in stem cell maintenance and differentiation. Int J Mol Sci. (2016) 17(2):253. doi: 10.3390/ijms17020253

PubMed Abstract | CrossRef Full Text | Google Scholar

52. Narita A, Nagai M, Mizuno S, Ogishima S, Tamiya G, Ueki M, et al. Clustering by phenotype and genome-wide association study in autism. Transl Psychiatry. (2020) 10(1):290. doi: 10.1038/s41398-020-00951-x

PubMed Abstract | CrossRef Full Text | Google Scholar

53. Atsem S, Reichenbach J, Potabattula R, Dittrich M, Nava C, Depienne C, et al. Paternal age effects on sperm FOXK1 and KCNA7 methylation and transmission into the next generation. Hum Mol Genet. (2016) 25(22):4996–5005. doi: 10.1093/hmg/ddw328

PubMed Abstract | CrossRef Full Text | Google Scholar

54. Fugger K, Chu WK, Haahr P, Kousholt AN, Beck H, Payne MJ, et al. FBH1 co-operates with MUS81 in inducing DNA double-strand breaks and cell death following replication stress. Nat Commun. (2013) 4:1423. doi: 10.1038/ncomms2395

PubMed Abstract | CrossRef Full Text | Google Scholar

55. Jeong YT, Rossi M, Cermak L, Saraf A, Florens L, Washburn MP, et al. FBH1 Promotes DNA double-strand breakage and apoptosis in response to DNA replication stress. J Cell Biol. (2013) 200(2):141–9. doi: 10.1083/jcb.201209002

PubMed Abstract | CrossRef Full Text | Google Scholar

56. Potenski CJ, Klein HL. Death becomes her: FBH1, DNA damage and apoptosis. Cell Cycle. (2013) 12(9):1336–7. doi: 10.4161/cc.24668

PubMed Abstract | CrossRef Full Text | Google Scholar

57. Kieroń M, Żekanowski C, Falk A, Wężyk M. Oxidative DNA damage signalling in neural stem cells in Alzheimer's Disease. Oxid Med Cell Longev. (2019) 2019:2149812. doi: 10.1155/2019/2149812

CrossRef Full Text | Google Scholar

58. Lin X, Kapoor A, Gu Y, Chow MJ, Peng J, Zhao K, et al. Contributions of DNA damage to Alzheimer's disease. Int J Mol Sci. (2020) 21(5):1666. doi: 10.3390/ijms21051666

PubMed Abstract | CrossRef Full Text | Google Scholar

59. Chahrour MH, Yu TW, Lim ET, Ataman B, Coulter ME, Hill RS, et al. Whole-exome sequencing and homozygosity analysis implicate depolarization-regulated neuronal genes in autism. PLoS Genet. (2012) 8(4):e1002635. doi: 10.1371/journal.pgen.1002635

PubMed Abstract | CrossRef Full Text | Google Scholar

60. Butler MG, Hartin SN, Hossain WA, Manzardo AM, Kimonis V, Dykens E, et al. Molecular genetic classification in Prader-Willi syndrome: a multisite cohort study. J Med Genet. (2019) 56(3):149–53. doi: 10.1136/jmedgenet-2018-105301

PubMed Abstract | CrossRef Full Text | Google Scholar

61. Dykens EM, Roof E, Hunt-Hawkins H, Dankner N, Lee EB, Shivers CM, et al. Diagnoses and characteristics of autism spectrum disorders in children with Prader-Willi syndrome. J Neurodev Disord. (2017) 9:18. doi: 10.1186/s11689-017-9200-2

PubMed Abstract | CrossRef Full Text | Google Scholar

62. Uribe-Querol E, Rosales C. Phagocytosis: our current understanding of a universal biological process. Front Immunol. (2020) 11:1066. doi: 10.3389/fimmu.2020.01066

PubMed Abstract | CrossRef Full Text | Google Scholar

63. Stavoe AKH, Holzbaur ELF. Autophagy in neurons. Annu Rev Cell Dev Biol. (2019) 35:477–500. doi: 10.1146/annurev-cellbio-100818-125242

PubMed Abstract | CrossRef Full Text | Google Scholar

64. Butler CA, Popescu AS, Kitchener EJA, Allendorf DH, Puigdellívol M, Brown GC. Microglial phagocytosis of neurons in neurodegeneration, and its regulation. J Neurochem. (2021) 158(3):621–39. doi: 10.1111/jnc.15327

PubMed Abstract | CrossRef Full Text | Google Scholar

65. Fu R, Shen Q, Xu P, Luo JJ, Tang Y. Phagocytosis of microglia in the central nervous system diseases. Mol Neurobiol. (2014) 49(3):1422–34. doi: 10.1007/s12035-013-8620-6

PubMed Abstract | CrossRef Full Text | Google Scholar

66. Shi Y, Lin S, Staats KA, Li Y, Chang W-H, Hung S-T, et al. Haploinsufficiency leads to neurodegeneration in C9ORF72 ALS/FTD human induced motor neurons. Nat Med. (2018) 24(3):313–25. doi: 10.1038/nm.4490

PubMed Abstract | CrossRef Full Text | Google Scholar

67. Parkinson W, Dear ML, Rushton E, Broadie K. N-glycosylation requirements in neuromuscular synaptogenesis. Development. (2013) 140(24):4970–81. doi: 10.1242/dev.099192

PubMed Abstract | CrossRef Full Text | Google Scholar

68. Jacobsson JA, Rask-Andersen M, Risérus U, Moschonis G, Koumpitski A, Chrousos GP, et al. Genetic variants near the MGAT1 gene are associated with body weight, BMI and fatty acid metabolism among adults and children. Int J Obes (Lond). (2012) 36(1):119–29. doi: 10.1038/ijo.2011.11

PubMed Abstract | CrossRef Full Text | Google Scholar

69. Wang AC, Jensen EH, Rexach JE, Vinters HV, Hsieh-Wilson LC. Loss of O-GlcNAc glycosylation in forebrain excitatory neurons induces neurodegeneration. Proc Natl Acad Sci U S A. (2016) 113(52):15120–5. doi: 10.1073/pnas.1606899113

PubMed Abstract | CrossRef Full Text | Google Scholar

70. Böhm J, Malfatti E, Oates E, Jones K, Brochier G, Boland A, et al. Novel ASCC1 mutations causing prenatal-onset muscle weakness with arthrogryposis and congenital bone fractures. J Med Genet. (2019) 56(9):617–21. doi: 10.1136/jmedgenet-2018-105390

CrossRef Full Text | Google Scholar

71. Meunier J, Villar-Quiles RN, Duband-Goulet I, Ferreiro A. Inherited defects of the ASC-1 Complex in congenital neuromuscular diseases. Int J Mol Sci. (2021) 22(11):6039–55. doi: 10.3390/ijms22116039

PubMed Abstract | CrossRef Full Text | Google Scholar

72. Rosano KK, Wegner DJ, Shinawi M, Baldridge D, Bucelli RC, Dahiya S, et al. Biallelic ASCC1 variants including a novel intronic variant result in expanded phenotypic spectrum of spinal muscular atrophy with congenital bone fractures 2 (SMABF2). Am J Med Genet A. (2021) 185(7):2190–7. doi: 10.1002/ajmg.a.62219

PubMed Abstract | CrossRef Full Text | Google Scholar

73. Dusl M, Moreno T, Munell F, Macaya A, Gratacòs M, Abicht A, et al. Congenital myasthenic syndrome caused by novel COL13A1 mutations. J Neurol. (2019) 266(5):1107–12. doi: 10.1007/s00415-019-09239-7

PubMed Abstract | CrossRef Full Text | Google Scholar

74. Kediha MI, Tazir M, Sternberg D, Eymard B, Alipacha L. Moderate phenotype of a congenital myasthenic syndrome type 19 caused by mutation of the COL13A1 gene: a case report. J Med Case Rep. (2022) 16(1):134. doi: 10.1186/s13256-022-03268-z

PubMed Abstract | CrossRef Full Text | Google Scholar

75. Rodríguez Cruz PM, Cossins J, Estephan EP, Munell F, Selby K, Hirano M, et al. The clinical spectrum of the congenital myasthenic syndrome resulting from COL13A1 mutations. Brain. (2019) 142(6):1547–60. doi: 10.1093/brain/awz107

CrossRef Full Text | Google Scholar

76. Dines JN, Golden-Grant K, LaCroix A, Muir AM, Cintrón DL, McWalter K, et al. TANGO2: expanding the clinical phenotype and spectrum of pathogenic variants. Genet Med. (2019) 21(3):601–7. doi: 10.1038/s41436-018-0137-y

PubMed Abstract | CrossRef Full Text | Google Scholar

77. Hoebeke C, Cano A, De Lonlay P, Chabrol B. Clinical phenotype associated with TANGO2 gene mutation. Arch Pediatr. (2021) 28(1):80–6. doi: 10.1016/j.arcped.2020.11.004

PubMed Abstract | CrossRef Full Text | Google Scholar

78. Miyake CY, Burrage L, Glinton K, Houck K, Hoyos-Martinez A, Graham B, et al. TANGO2 Deficiency. 2018 Jan 25 [updated 2023 Mar 9]. In: Adam MP, Mirzaa GM, Pagon RA, Wallace SE, Bean LJH, Gripp KW, Amemiya A, editors. GeneReviews® [Internet]. Seattle (WA): University of Washington, Seattle (1993–2023). PMID: 29369572

79. Schymick J, Leahy P, Cowan T, Ruzhnikov MRZ, Gates R, Fernandez L, et al. Variable clinical severity in TANGO2 deficiency: case series and literature review. Am J Med Genet A. (2022) 188(2):473–87. doi: 10.1002/ajmg.a.62543

PubMed Abstract | CrossRef Full Text | Google Scholar

80. Siokas V, Aloizou AM, Tsouris Z, Liampas I, Liakos P, Calina D, et al. ADORA2A Rs5760423 and CYP1A2 rs762551 polymorphisms as risk factors for Parkinson's disease. J Clin Med. (2021) 10(3. doi: 10.3390/jcm10030381

CrossRef Full Text | Google Scholar

81. Merighi S, Battistello E, Casetta I, Gragnaniello D, Poloni TE, Medici V, et al. Upregulation of cortical A2A adenosine receptors is reflected in platelets of patients with Alzheimer's disease. J Alzheimers Dis. (2021) 80(3):1105–17. doi: 10.3233/JAD-201437

PubMed Abstract | CrossRef Full Text | Google Scholar

82. Chandrasekera PC, McIntosh VJ, Cao FX, Lasley RD. Differential effects of adenosine A2a and A2b receptors on cardiac contractility. Am J Physiol Heart Circ Physiol. (2010) 299(6):H2082–9. doi: 10.1152/ajpheart.00511.2010

PubMed Abstract | CrossRef Full Text | Google Scholar

83. Yang JN, Chen JF, Fredholm BB. Physiological roles of A1 and A2A adenosine receptors in regulating heart rate, body temperature, and locomotion as revealed using knockout mice and caffeine. Am J Physiol Heart Circ Physiol. (2009) 296(4):H1141–9. doi: 10.1152/ajpheart.00754.2008

PubMed Abstract | CrossRef Full Text | Google Scholar

84. Özcan G, Özsu E, Şiklar Z, Çobanoğlu N. A rare cause of sleep-disordered breathing: ROHHAD syndrome. Front Pediatr. (2020) 8:573227. doi: 10.3389/fped.2020.573227

CrossRef Full Text | Google Scholar

85. Cai Z, Tu L, Guignabert C, Merkus D, Zhou Z. Purinergic dysfunction in pulmonary arterial hypertension. J Am Heart Assoc. (2020) 9(18):e017404. doi: 10.1161/JAHA.120.017404

PubMed Abstract | CrossRef Full Text | Google Scholar

86. Stowe RC, Afolabi-Brown O. Pulmonary hypertension and chronic hypoventilation in ROHHAD syndrome treated with average-volume assured pressure support. Pediatr Investig. (2019) 3(4):253–6. doi: 10.1002/ped4.12168

PubMed Abstract | CrossRef Full Text | Google Scholar

Keywords: autonomic dysfunction, neurogenetic syndromes, dental pulp stem cells, mRNA seq, genomics

Citation: Victor AK, Hedgecock T, Donaldson M, Johnson D, Rand CM, Weese-Mayer DE and Reiter LT (2023) Analysis and comparisons of gene expression changes in patient- derived neurons from ROHHAD, CCHS, and PWS. Front. Pediatr. 11:1090084. doi: 10.3389/fped.2023.1090084

Received: 4 November 2022; Accepted: 19 April 2023;
Published: 10 May 2023.

Edited by:

Alfredo Brusco, University of Turin, Italy

Reviewed by:

Andrea Angius, National Research Council (CNR), Italy
Marzia Rossato, University of Verona, Italy

© 2023 Victor, Hedgecock, Donaldson, Johnson, Rand, Weese-Mayer and Reiter. This is an open-access article distributed under the terms of the Creative Commons Attribution License (CC BY). The use, distribution or reproduction in other forums is permitted, provided the original author(s) and the copyright owner(s) are credited and that the original publication in this journal is cited, in accordance with accepted academic practice. No use, distribution or reproduction is permitted which does not comply with these terms.

*Correspondence: Lawrence T. Reiter lreiter@uthsc.edu

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