https://orcid.org/0000-0002-9154-952X
Figures
Abstract
Lateral Meningocele Syndrome (LMS), a disorder associated with NOTCH3 pathogenic variants, presents with neurological, craniofacial and skeletal abnormalities. Mouse models of the disease exhibit osteopenia that is ameliorated by the administration of Notch3 antisense oligonucleotides (ASO) targeting either Notch3 or the Notch3 mutation. To determine the consequences of LMS pathogenic variants in human cells and whether they can be targeted by ASOs, induced pluripotent NCRM1 and NCRM5 stem (iPS) cells harboring a NOTCH36692-93insC insertion were created. Parental iPSCs, NOTCH36692-93insC and isogenic controls, free of chromosomal aberrations as determined by human CytoSNP850 array, were cultured under conditions of neural crest, mesenchymal and osteogenic cell differentiation. The expected cell phenotype was confirmed by surface markers and a decline in OCT3/4 and NANOG mRNA. NOTCH36692-93insC cells displayed enhanced expression of Notch target genes HES1, HEY1, 2 and L demonstrating a NOTCH3 gain-of-function. There was enhanced osteogenesis in NOTCH36692-93insC cells as evidenced by increased mineralized nodule formation and ALPL, BGLAP and BSP expression. ASOs targeting NOTCH3 decreased both NOTCH3 wild type and NOTCH36692-93insC mutant mRNA by 40% in mesenchymal and 90% in osteogenic cells. ASOs targeting the NOTCH3 insertion decreased NOTCH36692-93insC by 70–80% in mesenchymal cells and by 45–55% in osteogenic cells and NOTCH3 mRNA by 15–30% and 20–40%, respectively. In conclusion, a NOTCH3 pathogenic variant causes a modest increase in osteoblastogenesis in human iPS cells in vitro and NOTCH3 and NOTCH3 mutant specific ASOs downregulate NOTCH3 transcripts associated with LMS.
Citation: Canalis E, Yu J, Schilling L, Jafar-nejad P, Carrer M (2025) A NOTCH3 pathogenic variant influences osteogenesis and can be targeted by antisense oligonucleotides in induced pluripotent stem cells. PLoS ONE 20(1): e0316644. https://doi.org/10.1371/journal.pone.0316644
Editor: Md Shaifur Rahman, AERE: Atomic Energy Research Establishment, BANGLADESH
Received: May 29, 2024; Accepted: December 15, 2024; Published: January 3, 2025
Copyright: © 2025 Canalis et al. This is an open access article distributed under the terms of the Creative Commons Attribution License, which permits unrestricted use, distribution, and reproduction in any medium, provided the original author and source are credited.
Data Availability: All relevant data are within the manuscript.
Funding: This work was supported by the National Institute of Arthritis and Musculoskeletal and Skin Diseases (NIAMS) [AR076747 (EC) and AR072987 (EC)]. The content is solely the responsibility of the authors and does not necessarily represent the official views of the National Institutes of Health. he funders had no role in study design, data collection and analysis, decision to publish, or preparation of the manuscript.
Competing interests: PJ and MC are paid employees of Ionis Pharmaceuticals. Please note that the synthesis and applications of antisense oligonucleotides may be covered by patent(s) filed by Ionis Pharmaceuticals. Individuals wanting to obtain antisense oligonucleotides from Ionis Pharmaceuticals are required to contact Ionis Pharmaceuticals directly. This does not alter our adherence to PLOS ONE policies on sharing data and materials.” as detailed in http://journals.plos.org/plosone/s/competing-interests
Abbreviations: The abbreviations used are ASO, antisense oligonucleotides; bp, base pair; cEt, constrained ethyl; DMEM, Dulbecco’s modified Eagle’s medium; FACS, fluorescence activated cell sorting; GSKi, glycogen synthase inhibitor; iPS, induced pluripotent stem; LMS, Lateral Meningocele Syndrome; MSC, mesenchymal cells; MOE, methoxyethyl; NCRM, NIH control reference line; NRR, negative regulatory region; NC, neural crest; NICD, NOTCH3 intracellular domain; PCR, polymerase chain reaction; PEST, proline (P)-, glutamic acid (E)-, serine (S)-, threonine (T)-rich; qRT-PCR, quantitative reverse transcription-polymerase chain reaction; RANKL, receptor activator of NF-κB ligand; sg, single guide; TGF, transforming growth factor
Introduction
Lehman Syndrome or Lateral Meningocele Syndrome (LMS) (OMIM 130720) is a rare and devastating disorder characterized by meningoceles and numerous skeletal manifestations, including craniofacial developmental defects, short stature, scoliosis and osteopenia [1–3]. The syndrome is associated with mutations, insertions or short deletions in exon 33 of NOTCH3 upstream of the proline (P)-, glutamic acid (E)-, serine (S)-, threonine (T)-rich (PEST) domain [4, 5]. The mutations lead to the premature termination of a protein product lacking sequences required for the ubiquitination and degradation of the NOTCH3 intracellular domain (NICD) so that the protein is stable and a gain-of-NOTCH3 function ensues. The inheritance of the disorder is autosomal dominant although de novo heterozygous mutations may occur [2]. The incidence of LMS is unknown and less than 100 cases have been reported. Treatment for this genetic disorder affecting the skeleton is not available.
LMS is one of many disorders that are associated with specific gene mutations that present with devastating clinical manifestations [6, 7]. Unfortunately, there is no practical or effective intervention that corrects the genetic abnormality, leading to the unsuccessful management of subjects afflicted by these disorders. Gene editing has been proposed to correct mutations in mice and humans [8, 9]. However, gene editing is not readily available for therapeutic intervention, and ethical concerns have been raised regarding genome editing in human embryos [10–12]. A specific tissue could be targeted with vectors with preferential affinity for the tissue affected to replace the mutant DNA with repaired DNA, an approach that also has been challenging [13].
Antisense oligonucleotides (ASO) are a novel and potential therapeutic approach to downregulate wild type and mutant transcripts. ASOs have been successful in the targeting and downregulation of mutant genes in the liver, central and peripheral nervous system and retina [14–20]. ASOs are synthetic single-stranded nucleic acids that by binding to target mRNA by Watson-Crick pairing they cause the degradation of mRNA by RNase H [21, 22]. As such, ASOs are of potential value in conditions where a gain-of-function exists since gene downregulation could correct the functional outcome. Previously, we demonstrated the effectiveness of ASOs targeting either wild type or mutant Notch3 in mice and skeletal cells from mice harboring a Notch3 mutation resulting in a gain-of-function analogous to the one observed in LMS [23, 24].
An attractive application of induced pluripotent stem (iPS) cell technology is that it allows the isolation of patient-derived cells that carry the genetic alterations associated with specific disorders or the creation of stocks of established iPS cell lines harboring specific mutations. iPS cells provide an experimental system not only to study the pathogenesis of the disease but also to devise therapeutic strategies [25]. Although the mutations present in individuals with LMS are in exon 33 of NOTCH3, not every family line harbors the same mutation, and this is often the case with monogenic disorders [4]. Therefore, ASOs targeting each mutation would need to be designed and tested for their effectiveness in downregulating the NOTCH3 mutant transcript. This would require ample supply of cells from afflicted individuals so that ASOs specific to the pathogenic variant can be tested to document efficacy. A practical approach is the establishment of stocks of iPS cells from affected individuals or the introduction of specific mutations in stocks of iPS cells to be tested for ASO effectiveness on mutant transcript downregulation and cellular behavior.
The intent of the current study was to create and establish iPS cell lines harboring a NOTCH3 pathogenic variant found in LMS and define their cellular behavior and differentiation to the osteogenic lineage. In addition, ASOs targeting either the wild type or NOTCH3 pathogenic variant were tested to determine their effectiveness in downregulating NOTCH3.
Materials and methods
Induced pluripotent stem (iPS) cells
NIH control reference line (NCRM)1 and NCRM5 were generated by the NIH Regenerative Medicine Program and obtained through RUCDR Infinite Biologics (Piscataway, NJ) [26]. NCRM1 and NCRM5 cells are derived from male CD14+ cord blood by episomal integration and are well-characterized pluripotent cells devoid of chromosomal structural aberrations.
Human NOTCH3 mutant iPS cells were created at the University of Connecticut Cell and Engineering Core (Farmington, CT). To introduce the NOTCH36692-93insC insertion into NOTCH3, the databases http://www.rgenome.net and https://chopchop.cbu.uib.no were utilized to evaluate potential single guide (sg)RNAs. NOTCH3 sgRNA 5’-AGAGGTCAAGGCCAGGACTA-3’ was selected because of its high score with minimum off-target effects. This guide RNA targets the intron upstream of exon 33 containing the mutation and was cloned into pSpCas9(BB)-2A-Puro (PX459v2, Addgene 62988, Watertown, MA). Homology arms flanking a neomycin selection cassette flanked by loxP sites were cloned into a targeting vector so that the guide RNA sequence would be split by the cassette to prevent further DNA cleavage following the targeting of the 3’ homology arm contained either in the NOTCH36692-93insC mutant or the wild type sequence to be targeted (Fig 1). NCRM1 and NCRM5 iPS cells were nucleofected using a Lonza 4d Nucleofector and primary kit P3 following manufacturer’s protocols (Lonza, Basel, Switzerland). Cells were grown and clones established, and genomic DNA was screened for vector-targeting and positive clones were analyzed by DNA sequencing to determine genotype and the presence or absence of the NOTCH36692-93insC insertion. Depending on the breakpoint occurring during homologous directed repair, cells could harbor the mutation, if the breakpoint was at the end of the homology arm or harbor a wild type allele if the breakpoint occurred at the insertion site. Clones were transfected with a Cre-IRES-PuroR vector (Addgene 30205) to delete the neomycin selection cassette and loxP recombination verified by polymerase chain reaction (PCR). Homozygous, and heterozygous clones and wild type isogenic controls were obtained. Absence of genetic aberrations was verified using the Infinium CytoSNP-850K v1.3 BeadChip microarray (Illumina; San Diego, CA) at the University of Connecticut Center for Genome Innovation (Storrs, CT) in accordance with manufacturer’s instructions. Parental NCRM1 and NOTCH3 mutant and isogenic control NCRM1 cells harbored a 602.9 kilobase gain in chromosome 20 Band 20q11.21-20q11.21 position 29, 804, 293–30, 407, 232.
In Panel A, NCRM1 and NCRM5 cells were nucleofected with pSPCas9(BB)-2A-Puro to deliver Cas9 and the targeting vector, containing the NOTCH36692-93insC insertion depicted above in Band C or isogenic control. The neo selection cassette (in A) was deleted following nucleofection of Cre-IRES-PuroR. Breakpoints in homologous directed repair in the homology arm (C) would include the mutation and breakpoint in the insertion (B) would create a wild type allele. In Panel B, DNA sequencing of Notch36692-93insC homozygous and heterozygous mutant and NOTCH3 isogenic control NCRM1 and NCRM5 iPS cells.
iPS cell culture and in vitro osteogenesis
NCRM1 and NCRM5 iPS cells with and without the NOTCH36692-93insC insertion were seeded on matrigel-coated plates (STEMCELL Technologies, Vancouver, Canada or Geltrex, Waltham, MA) and cultured in mTeSR Plus (STEMCELL Technologies) medium at 37°C in a 5% CO2 atmosphere and manually passaged twice a week with the aid of a 28-gauge needle using an enzyme-free cell dissociation solution at 37°C and streaked through the well for colony formation [26–28]. For neural crest differentiation, cells were cultured on laminin-521 (Thermo Fisher, Waltham, MA) for 6 days and the culture medium was replaced twice a week with basal STEMdiff™ APEL™ differentiation medium (STEMCELL Technologies) supplemented with 5 μM glycogen synthase inhibitor (GSKi) (CHIR992021, Stemgent, Lexington, MA) and 10 μM transforming growth factor (TGF)β inhibitor (SB431542, Sigma-Aldrich, St. Louis, MO) (Fig 2) [27, 28]. Cells were detached by adding Stempro Accutase (Thermo Fisher) and selected for CD34−KDR−CD271+PDGFRa− surface markers by fluorescence activated cell sorting (FACS) [29]. Following sorting, cells were plated at a 1–2 x 106 cells/10 cm2 density on laminin-521 (Thermo Fisher) coated dishes in the presence of STEMdiff™ APEL™ Medium, 10 μM TGFβ inhibitor, 10 μM Rho kinase (ROCK) inhibitor (Y-27632, STEMCELL Technologies) and antibiotic-antimycotic cocktail (Thermo Fisher) for 24 h. To induce mesenchymal cell differentiation, cells were cultured for one week on laminin-521 coated plates and for one week on Cell Bind coated plates (Thermo Fisher) in MSC NutriStem XF medium (Sartorius, Gottingen, Germany) [28]. Mesenchymal cell differentiation was verified by the presence of CD44+CD73+CD105+CD31−CD45− surface markers by flow cytometry.
iPS cells were cultured in STEMdiff™ APEL™ medium in the presence of GSK and TGFβ inhibitors, selected for KDR−CD34−CD271+PDGFRa− by FACS and cultured in the presence of ROCK and TGFβ inhibitors for 24 h. Cells were transferred to Laminin-521 and Cell Bind coated plates in the presence of NutriStem XF medium for 2 weeks and osteogenic culture conditions for 4 weeks. Panel A shows the cell differentiation scheme. Panels B and C show the neural crest cells and surface markers following FACS. Panel D shows mesenchymal cells and surface markers determined by flow cytometry and Panel E shows mineralized nodules stained with alizarin red following osteogenesis. Bars in the right corner of images in B and E represent 500 μm, and in D 200 μm.
To induce osteogenic differentiation, mesenchymal cells were grown to confluence on Cell Bind coated plates in NutriStem XF medium and switched to Dulbecco’s modified Eagle’s medium (DMEM) (Thermo Fisher), 10% fetal bovine serum (Atlanta Biologicals, Laurenceville, GA), 100 nM dexamethasone, 50 ng/ml ascorbic acid, 10 mM β-glycerophosphate (all from Sigma-Aldrich) [30]. Medium was replaced twice a week and cells were cultured for up to 4 weeks. To determine the presence of mineralized nodules, cultured cells were fixed and stained with alizarin red at various times during the culture period.
NOTCH3 antisense oligonucleotides (ASO)
ASOs targeting the NOTCH3 or the NOTCH36692-93insC mutant pre-mRNA and a non-targeting control ASO that does not hybridize to any specific mRNA in the human or mouse transcriptome sequence were designed and synthesized by Ionis Pharmaceuticals (Carlsbad, CA). The ASO targeting human NOTCH3 has a central segment of eight DNA nucleotides flanked on each side by five nucleotides with 2′-O-(2-methoxyethyl) (MOE) ribose sugar modifications, and contains phosphodiester or phosphorothioate backbone linkages [31]. The ASOs targeting NOTCH36692-93insC have a central segment of ten DNA nucleotides flanked on each side by three nucleotides with 2′4′-constrained 2′-O-ethyl (cEt) modifications and contain phosphorothioate backbone linkages. NOTCH3 mutant or control ASOs at various doses and periods of time were added directly to mesenchymal cells before and after they were exposed to culture medium under osteogenic conditions for 2 weeks as indicated in text and legends.
Quantitative reverse transcription-polymerase chain reaction (qRT-PCR)
Cellular RNA was extracted with the RNeasy kit (Qiagen, Valencia, CA), following manufacturer’s protocols [32–35]. The iScript RT-PCR kit (BioRad, Hercules, CA) was used to reverse transcribe equal amounts of RNA which was then amplified in the presence of specific primers (IDT) (Table 1) with the SsoAdvanced Universal SYBR Green Supermix or the iQ SYBR Green Supermix (BioRad) at 60°C for 35 cycles. Transcript copy number was estimated by comparison with serial dilutions of cDNA of the genes examined obtained from Thermo Fisher Scientific or Dharmacon (Lafayette, CO). In experiments designed with the intent to determine an effect on NOTCH36692-93insC transcripts by an ASO, fluorescent tagged products were used to conduct RT-PCR. Moloney murine leukemia virus reverse transcriptase was used to reverse transcribe total RNA and NOTCH3 cDNA was amplified by qPCR in the presence of SsoAdvanced Universal Probes Supermix (BioRad), NOTCH3 and NOTCH3 mutant primers and HEX labeled NOTCH3 and FAM labeled NOTCH36692-93insC probes (BioRad) for 10 secs at 95°C followed by 30 secs at 60°C and repeated for 45 cycles [36]. Copy number of NOTCH3 or NOTCH36692-93insC was estimated by comparison to a serial dilution of a 100 to 200 base pair (bp) synthetic DNA fragment (IDT) harboring (or not) the 6692-93insC in the NOTCH3 locus cloned into pcDNA3.1(-) (Thermo Fisher) by isothermal single reaction assembly using reagents available commercially (New England BioLabs, Ipswich, MA) [37]. Transcripts are expressed as copy number corrected for HPRT expression.
GenBank accession numbers identify transcript recognized by primer pairs.
Statistics
Data are expressed as means ± SD and as individual sample values of technical replicates. Statistical significant differences were determined by either unpaired t test for pairwise comparisons or by two-way analysis of variance for multiple comparisons with Holm Šidák post-hoc analysis employing the GraphPad Prism version 10.2.0 for Windows 10 (GraphPad Software, San Diego, CA).
Results
Creation of NOTCH36692-93insC mutant cells
CRISPR/Cas9 technology was used to introduce a single base pair insertion at c.6692_93insC in NOTCH3 in both NCRM1 and NCRM5 cells. The insertion predicts a premature termination upstream of the PEST domain of NOTCH3 duplicating the pathogenic variant found in a subject afflicted by LMS and functionally replicated in the Notch3em1Ecan mouse mutant [38, 39]. NCRM1 and NCRM5 cells homozygous and heterozygous for the c.6692_93insC were obtained and verified by DNA sequencing and stocks created to be used for testing (Fig 1). Isogenic controls and heterozygous and homozygous NOTCH36692-93insC cells retained genomic stability and were absent of chromosomal aberrations as determined by the human CytoSNP-850 array.
NCRM1 and NCRM5 cells differentiate into mesenchymal and osteogenic cells in vitro
Parental NCRM1 and NCRM5 cells were cultured in STEMdiff™ APEL™ medium in the presence of GSK and TGFβ inhibitors to direct their differentiation to cells of the neural crest [28, 29]. Cells were selected for the neural crest markers CD34−KDR−CD271+PDGFRa- by FACS and grown further on Laminin-521 and Cell Bind coated plates to induce mesenchymal cell differentiation (Fig 2). Mesenchymal cells were identified by the absence of CD45 and CD31 surface markers and the detection of CD44+CD73+CD105+ by flow cytometry and were transferred to osteogenic medium for differentiation [28, 40]. The pluripotent cell gene markers OCT3/4 and NANOG were detected in parental iPS cells but were virtually undetectable in neural crest and mesenchymal cells verifying loss of pluripotency and evidence of cell differentiation (Fig 3A). Following differentiation, NCRM1 and NCRM5 neural crest cells expressed GSC and SOX10 and mesenchymal cells expressed FOXC2 transcripts (Fig 3A) [29, 41–43]. The NOTCH36692-93insC pathogenic variant did not alter the differentiation of either NCRM1 or NCRM5 cells to neural crest or mesenchymal cells (Fig 3B). Culture of mesenchymal cells under osteogenic conditions induced their differentiation toward osteoblasts and formed mineralized nodules (Figs 2 and 4) and expressed ALPL, BGLAP, RUNX2 and low levels of SP7, genes associated with osteoblasts. RUNX2 declined and ALPL increased as the culture progressed over a 4-week period (Fig 4). ACP5, an osteoclast gene marker, was detected during the initial phase of the culture and declined during osteoblast differentiation. NOTCH1, NOTCH2 and NOTCH3, but not NOTCH4, transcripts were detected in NCRM1 and NCRM5 cells during osteogenic differentiation.
iPS cells were cultured it STEMdiff™ APEL™ medium in the presence of GSK and TGFβ inhibitors, selected for KDR−CD34−CD271+PDGFRa− by FACS and cultured in the presence of ROCK and TGFβ inhibitors for 24 h. Cells were transferred to Laminin-521 and Cell Bind coated plates in the presence of NutriStem XF medium for 2 weeks. Panel A shows pluripotent cell gene markers OCT3/4 and NANOG, neural crest gene markers GSC and SOX10 and mesenchymal cell marker FOXC2 mRNA expressed as copy number corrected for HPRT in undifferentiated parental NCRM1 (white bars) and NCRM5 (black bars) iPS cells, neural crest and mesenchymal cells (MSC). Panel B shows mesenchymal cell surface markers determined by flow cytometry of NCRM1 and NCRM5 parental cells (left) and iPS cells harboring a NOTCH36692-93insC insertion and isogenic controls following neural crest and mesenchymal cell differentiation. Individual values are shown, and bars and ranges represent means ± SD; n = 4 technical replicates.
NCRM1 (white bars) and NCRM5 (black bars) iPS cells were cultured to induce neural crest and mesenchymal cell differentiation as described in Figs 2 and 3 and transferred to osteogenic medium for 4 weeks. In Panel A, SP7, RUNX2, ALPL, BGLAP, ACP5, NOTCH1, NOTCH2 and NOTCH3 mRNA levels were determined at the indicated times. Transcript levels are expressed as copy number following correction for HPRT copy number. Individual values are shown, and bars and ranges represent means ± SD; n = 4 technical replicates. In Panel B, mineralized nodules stained with alizarin red obtained after 4 weeks of culture in osteogenic medium. Bars in the right corner represent 200 μm. NOTCH4 was not detected.
NOTCH36692-93insC pathogenic variant causes a modest enhancement of osteoblastogenesis in vitro
To determine the impact of the NOTCH36692-93insC insertion on osteoblast cell differentiation, homozygous NCRM1 (Fig 5) and NCRM5 (Fig 6) cells for the insertion and isogenic controls were cultured under osteogenic conditions. NOTCH3 mRNA was detected in control and mutant cells throughout the culture since the RT-PCR could not discriminate a single 6692-93insC. NOTCH36692-93insC transcripts were detected only in iPS cells harboring the pathogenic variant allele and as expected, the level of expression was higher in homozygous than in heterozygous NOTCH36692-93insC clones (not shown). NOTCH36692-93insC cells expressed higher levels of HEY1, HEY2 and HEYL transcripts than isogenic controls during the first 2 weeks of culture in NCRM1 and throughout the culture period in NCRM5 mutant cells demonstrating that the NOTCH3 insertion resulted in a gain-of-Notch function (Figs 5 and 6). Accordingly, there was a short-lived induction of ALPL and BGLAP in NCRM1 mutant cells (Fig 5) and a more sustained increased expression of ALPL and BSP in NCRM5 cells harboring the NOTCH36692-93insC insertion compared to isogenic controls (Fig 6). There was greater formation of mineralized nodules in NOTCH36692-93insC NCRM1 and NCRM5 cells than in isogenic control cells (Figs 5 and 6). WNT1 was not detected in either wild type or NOTCH36692_93insC, NCRM1 or NCRM5 iPS cells.
iPS cells harboring a NOTCH36692_93insC insertion in both alleles (INS/INS, black bars) and isogenic controls (WT/WT white bars) were cultured under conditions that induce neural crest and mesenchymal cell differentiation and transferred to osteogenic medium for 4 weeks. In Panel A, NOTCH3, NOTCH36692_93insC, HES1, HEY1, HEY2, HEYL, ALPL and BGLAP mRNA levels were determined at the indicated times. Transcript levels are expressed as copy number following correction for HPRT copy number. Individual values are shown, and bars and ranges represent means ± SD; n = 4 technical replicates. In Panel B, mineralized nodules stained with alizarin red after 3 weeks of culture in osteogenic medium. Bars in the right corner represent 200 μm. *Significantly different between NOTCH36692_93insC and control cells by ANOVA, p < 0.05.
iPS cells harboring a NOTCH36692_93insC insertion in both alleles (INS/INS, black bars) and isogenic controls (WT/WT, white bars) were cultured under conditions that induce neural crest and mesenchymal cell differentiation and transferred to osteogenic medium for 4 weeks. In Panel A, NOTCH3 (in isogenic controls), NOTCH36692_93insC (in NOTCH3 mutant iPS cells), HES1, HEY1, HEY2, HEYL, ALPL, BGLAP and BSP mRNA levels were determined at the indicated times. Transcript levels are expressed as copy number following correction for HPRT copy number. Individual values are shown, and bars and ranges represent means ± SD; n = 4 technical replicates. In Panel B, mineralized nodules stained with alizarin red obtained following 3 and 4 weeks of culture in osteogenic medium. Bars in the right corner represent 200 μm. *Significantly different between NOTCH36692_93insC and control cells by ANOVA, p < 0.05.
NOTCH3 ASOs downregulate NOTCH3 expression in mesenchymal and osteogenic cells
To determine the effect of NOTCH3 ASOs in control and NOTCH36692-93insC cells, ASOs targeting NOTCH3 and the NOTCH36692-93insC pre-mRNA were designed and synthesized (Fig 7). The effect of NOTCH3 ASOs was tested initially in undifferentiated iPS NOTCH36692-93insC and isogenic control cells, but neither the addition of NOTCH3 nor NOTCH3 mutant ASOs to the culture medium downregulated NOTCH3 or NOTCH36692-93insC transcripts, possibly because of limited ASO internalization by undifferentiated iPS cells (not shown). In subsequent experiments, NOTCH3 and NOTCH3 mutant ASOs were tested in mesenchymal and following culture under osteogenic conditions for 2 weeks (osteogenic cells). NOTCH3 ASOs added to the culture medium at 20 and 50 μM for 72 h downregulated NOTCH3 and NOTCH36692-93insC transcripts to an equal extent (30–40%) in mesenchymal and ~90% in osteogenic cells (Fig 8). The addition of one of the 10 ASOs designed to target mutant NOTCH3 to the culture medium of mesenchymal cells downregulated NOTCH36692-93insC mRNA and downregulated NOTCH3 wild type mRNA modestly indicating specificity for the NOTCH3 insertion (Fig 8). The NOTCH3 mutant ASO at 10 μM and 20 μM downregulated NOTCH36692-93insC by 70–80% in mesenchymal cells and by 44–55% in osteogenic cells. The effect was more pronounced for NOTCH36692-93insC than for NOTCH3 wild type mRNA, which was downregulated by 15–30% in mesenchymal cells and 20–40% in osteogenic cells. As expected, the NOTCH36692-93insC transcript was not detected in control wild type cells. To verify the activity of NOTCH3 ASOs, they were tested for their effects on canonical targets of Notch signaling in osteogenic cells. HEY1, HEY2, and HEYL mRNA expression was increased in NOTCH36692-93insC cells, and the effect was reversed by the ASO targeting NOTCH3 at 50 μM and the ASO targeting NOTCH36692-93insC at 20 μM (Fig 9). However, some of these changes did not reach statistical significance due to a small sample size (n = 3) and variability. The results suggest a reversal of the enhanced signal activation observed in LMS mutant cells.
Green lines represent the site targeted by each ASO. The colored letter represents the NOTCH36692_93insC insertion harbored by mutant cells compared to wild type human NOTCH3. The wild type human NOTCH3 pre-mRNA sequence is depicted at the top of the figure.
Control and NOTCH3 ASOs targeting NOTCH3 or the NOTCH36692_93insC insertion were tested for their effects on NOTCH3 and NOTCH36692_93insC mRNA expression in NCRM1 mesenchymal cells before (left) and following the exposure to osteogenic medium for 14 days (right). NOTCH3 and NOTCH36692_93insC mRNA levels were obtained 72 h after the addition of control, NOTCH3 or NOTCH3 mutant ASOs at the indicated concentrations to the culture medium. Transcript levels are expressed as NOTCH3 (upper panels) and NOTCH36692-93insC (lower panels) copy number following correction for HPRT copy number. Individual values are shown, and bars and ranges represent means ± SD n = 3 technical replicates. *Significantly different between NOTCH3 ASO or mutant NOTCH3 ASO and control ASO by unpaired t test, p < 0.05.
Control and NOTCH3 ASOs targeting NOTCH3 (N3) at 50 μM or the NOTCH36692_93insC insertion (mN3) at 20 μM were tested for their effects on HEY1, HEY2 and HEYL mRNA expression in NCRM1 mesenchymal cells exposed to osteogenic conditions for 2 weeks 72 h after ASO addition to the culture. Control ASO was added at the same concentration. Transcript levels are expressed as HEY1, HEY2 and HEYL copy number following correction for HPRT copy number following treatment with NOTCH3 (upper panel) or NOTCH3 mutant ASO (lower panel). Individual values are shown, and bars and ranges represent means ± SD; n = 3 technical replicates. Bars and p values indicate significant differences between NOTCH36692_93insC and control cells, and between NOTCH3 ASO or mutant NOTCH3 ASO and control ASO by ANOVA.
Discussion
The present studies were conducted to determine whether a NOTCH3 pathogenic variant found in LMS or Lehman Syndrome had a phenotypic impact on mesenchymal and osteogenic cell differentiation. In addition, the work tested whether NOTCH3 and its pathogenic variant could be downregulated in human cells in vitro by the administration of ASOs. The current findings confirm in human iPS cells that a pathogenic variant harbored in LMS results in a gain-of-Notch function as evidenced by increased expression of the canonical target genes HES1, HEY1, HEY2 and HEYL. The results confirm observations reported in mouse models of LMS termed Notch3em1Ecan that presented with a NOTCH3 gain-of-function and osteopenia secondary to an increase in receptor activator of NF-κB ligand (RANKL) in cells of the osteoblast lineage [38]. The number and function of osteoblasts was not affected in Notch3em1Ecan mice and in vitro experiments did not reveal either enhanced or suppressed osteoblastogenesis. In contrast to these findings, iPS cells harboring an LMS pathogenic variant exhibited a modest enhancement in osteogenesis as evidenced by an increase in mineralized nodule formation and select gene markers associated with the osteoblast phenotype. The effect was more evident and sustained in NCRM5 than in NCRM1 cells harboring the NOTCH3 pathogenic variant, but the reasons for the difference were not explored. NCRM1 cells harbor a 602.9 kilobase gain in chromosome 20 Band 20q11.21-20q11.21 position 29, 804, 293–30, 407, 232 although whether this could influence their phenotype is unknown. The modest discrepancy between human and mouse cells might be related to different culture models since the cells from Notch3em1Ecan mice were studied in primary cultures following the isolation of relatively mature cells of the osteoblast lineage [38]. It is possible that the outcome observed in iPS cells is due to an effect of NOTCH3 in an immature, less differentiated cell or to the fact that often the effects of Notch are cell-context dependent.
The current work also was undertaken to determine whether ASOs could be developed to target and downregulate a NOTCH3 pathogenic variant in iPS cells. One of the ASOs tested downregulated the NOTCH36692-93insC with a more modest effect on wild type NOTCH3 transcripts in mesenchymal and osteogenic cell cultures indicating a degree of specificity. In addition, ASOs targeting either wild type or mutant NOTCH3 alleles decreased the induction of canonical Notch target genes observed in NOTCH36692-93insC cells. Although some of the changes did not achieve statistical significance due to a small sample size, the results would suggest at least a partial reversal of the NOTCH3 gain-of-function observed in cells harboring the LMS pathogenic variant and provide evidence of a biological effect. It was not possible to test the long-term effects of NOTCH3 ASOs on the osteogenic phenotype of NOTCH36692-93insC cells because the phenotype was modest and the prolonged exposure of cells to the ASO resulted in cellular toxicity.
Various approaches have been reported to downregulate signaling by Notch receptors. However, often they lack specificity to Notch activity or to a specific Notch receptor. Antibodies targeting the negative regulatory region (NRR) of Notch prove to be an exception and in previous work, we demonstrated that anti-NOTCH2 NRR and anti-NOTCH3 NRR antibodies reverse skeletal phenotypic manifestations of Notch2tm1.1Ecan, a mouse model of Hajdu Cheney Syndrome (HCS) and of Notch3em1Ecan, a mouse model of LMS [44, 45]. A limitation of anti-Notch NRR antibodies is the fact that they do not discriminate between the wild type and mutant forms of the receptor and by causing a substantial downregulation of Notch signaling their administration may result in gastrointestinal toxicity.
Previously, we have shown the in vitro and in vivo ability of Notch2 ASOs to downregulate Notch2 expression and as a result improve the osteopenia of mice harboring a Notch2 gain-of-function mutation found in HCS [46]. We also reported that ASOs targeting either Notch3 or Notch3 mutants replicating the pathogenic variant of LMS, inhibit Notch3 mRNA and improve the cortical osteopenia found in Notch3em1Ecan mice [23, 24]. The present work confirms the feasibility of the approach and extends the findings to a human, albeit in vitro, model.
There are limitations in the present work. Phenotypic alterations of experimental and control iPS cells and testing of ASOs were conducted in vitro for markers of osteogenesis and no assays were conducted to verify bone formation in vivo [47]. The enhancement of osteoblastogenesis by the NOTCH3 LMS pathogenic variant was modest. The phenotypic impact of the NOTCH36692-93insC variant and the effects of Notch3 ASOs were assessed in cells of the osteoblast lineage and not in the myeloid/osteoclast lineage because NOTCH3 is not expressed in this lineage either in human or murine cells and NOTCH3 does not have direct effects on osteoclastogenesis [6, 39]. Indeed, NOTCH1 and NOTCH2 transcripts are detected in iPS cells differentiating toward the myeloid/osteoclast lineage whereas low/undetectable levels of NOTCH3 and NOTCH4 are found (Canalis, et al., unpublished observations). Because only iPS cells derived from umbilical blood of male subjects were studied, one should not extrapolate the results observed to iPS cells derived from female individuals or iPS cells from other sources.
In conclusion, a NOTCH3 pathogenic variant found in LMS causes a modest enhancement of osteogenesis in iPS cells in vitro, and ASOs can be used to target and downregulate NOTCH3 and an LMS pathogenic variant in human iPS cells.
Acknowledgments
The authors thank Drs. Pamela Robey and Fahad Kidwai for helpful advice, Magda Mocarska and Emily Denker for technical assistance, Mary Yurczak for secretarial support, and Emily Denker for creating figures for the manuscript.
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