Day 0 neonate fibroblast cells were treated with 5-azacytidine followed by RNA/DNA fluorescence in situ hybridization (FISH) to ascertain the affect of CpG hypomethylation on the allelic expression profile of IGF2 in M. domestica. Both treated and control cells were subjected to RNA FISH to determine mono-vs biallelic expression status, followed by DNA FISH as an internal hyrbidization control. Only those cells containing two DNA FISH signals were scored for RNA FISH (Figure 1A–C). Untreated neonate cells showed zero RNA signals in 11.1% of cells (Figure 1A), one RNA signal in 77.7% of cells (Figure 1B), and two RNA signals in 11.1% of cells, confirming the imprinted status of IGF2 (Figure 1D). Cells treated with 5-azacytidine showed a significant (p < 0.001) shift to biallelic expression, with 14.3% of cells containing no RNA signal, 10.7% containing one RNA signal and 75% of cells containing 2 RNA FISH signals (Figure 1C,D). We have previously shown that only the paternal allele of IGF2 is transcriptionally active in neonatal opossums 4. The detection of two RNA FISH signals in treated neonatal fibroblasts, therefore, indicates that the normally silent maternal allele has been activated by the loss of cytosine methylation.

Slightly greater than 22 kilobases of DNA sequence encompassing the M. domestica IGF2 gene was assembled from sequencing of a 14 kb lambda clone and from subcloning and sequencing regions of a BAC clone (223O16, pCC1BAC) 19. A northern blot of RNA extracted from whole neonate tissue was hybridized to a cDNA probe encompassing the protein coding portion of the M. domestica IGF2 gene. A single transcript of approximately 5 kb was detected (data not shown). To determine the 5' extent of the transcript and identify the promoter for the gene we performed 5' RACE using oligonucleotide primers seated in the first protein coding exon. 5' RACE of neonatal RNA generated a single product that revealed a 95 base pair non-coding exon situated ~5 kilobases upstream of the start codon in the first protein coding exon of IGF2 (Figure 2A). In mouse and human, multiple transcripts for IGF2 have been detected with specific spatiotemporal expression profiles that result from differential promoter usage and alternative splicing of noncoding exons upstream of the three conserved protein coding exons. The single band detected by northern analysis and the single 5' RACE product, both from whole neonatal RNA, suggest that opossum neonates express only one IGF2 transcript isotype from one promoter. The 5' flanking region of the noncoding exon identified by 5' RACE was analyzed by PROSCAN 20 and was predicted with high confidence to be a promoter (promoter score = 73.63).

We next determined if features of the M. domestica IGF2 locus, including the region encompassing the 5' noncoding exon and the predicted promoter, show conservation among marsupial clades and between marsupials and eutherians. Pairwise alignments using a 100 base pair sliding window were performed in VISTA 21 utilizing the genomic sequences of IGF2 from M. domestica, Macropus eugenii (tammar wallaby) and Homo sapiens (Figure 2B,C). Conservation was extremely high (>80%) between all three species within the three protein coding exons. In addition, a segment of approximately 600 base pairs, encompassing the 5' noncoding exon and upstream flanking sequence showed >85% identity between opossum and tammar wallaby and >50% identity between opossum and human. Didelphids (including Monodelphis and Didelphis) and Macropodids (including Macropus) last shared a common ancestor ~85 MYA, while estimates for the most recent common ancestor for human and M. domestica are ~145 MYA 1. Given these deep phylogenetic branches, sequences containing high homology between these disparate species may be indicative of functional conservation and represent potential targets for further epigenetic analyses.

Several CpG isochores and CpG enriched regions were predicted within the assembled sequence contig using CpG Plot 22. A CpG enriched region was found upstream and within the third coding exon (region VI, Figure 2A) corresponding to DMR2 in mice, which is paternally methylated and known to be important in maintaining high levels of transcription of Igf2 from the paternal allele 16. Bisulphite sequencing of this CpG enriched region encompassing 750 base pairs in M. domestica revealed no differential methylation (Figure 3A).

No sequence cognates of mouse Igf2 DMR0 or DMR1 were identified. Nevertheless, bisulfite sequencing and methylation-sensitive Southern analyses were performed on the CpG enriched regions found upstream of the first exon (regions I and II, Figure 3A,B), within the first intron (region IV, Figure 3B) and flanking the second exon (region V, Figure 3A). Like region VI, region V is fully methylated on both alleles, while regions I, II and IV are unmethylated on both alleles.

Region III includes the first exon and approximately 500 base pairs of its immediate 5' flank. Apart from the predicted promoter, this region is composed of extremely low complexity DNA sequence: the upstream half of which is comprised of interspersed strings of G's or A's two to six bases in length, while the downstream half is comprised of similarly short strings of C's and T's. The character of the sequence in this region precludes both the ability to design primers for bisulphite sequencing, which requires high complexity sequence to compensate for the conversion of C's to U's by deamination, as well as the utilization of methylation sensitive restriction enzymes for Southern analysis to detect differential CpG methylation. Therefore, we designed a methylation-sensitive restriction digest/quantitative real-time PCR assay to examine select CpG residues in the vicinity of the predicted promoter. The quantitative real-time assay detects 50% methylation (99.9% confidence limits) within Region III (Figure 3C). Furthermore, the 50% methylation of Region III is lost upon 5-azacytidine treatment of cells. Sequence polymorphisms that might distinguish parental copies of Region III were not found among the available stocks of M. domestica, therefore it is formally possible that the CpGs in this region are randomly methylated. However, the precise 50% methylation (within 0.1% error) of Region III despite full methylation or unmethylation of CpGs in surrounding regions, and the activation of the maternal allele of IGF2 concurrent with the loss of methylation of Region III in 5-azacytidine treated neonatal fibroblasts, strongly suggest that Region III comprises an allele-specific DMR essential to PSGE of IGF2 in opossums.

When sequence obtained from the 5' region of the M. domestica IGF2 gene was input into the bioinformatics program MAR-Wiz 23, a region within the first intron just downstream of the 5' noncoding exon was predicted to be a Matrix Attachment Region (92% average strength) (Figure 2A). FISH using a 5 kilobase probe containing the predicted MAR sequence showed two signals exclusively in the nuclear matrix rather than in the loop region of nuclear halos (Figure 4), confirming the presence of an active MAR in the 5' region of this gene in opossum.

Primary cultures of fibroblast cells were established from (Day 0) neonates.

Neonate tissues were treated with 500 units Collagenase type 3 (Worthington Biochemical), in 35 mm Petri dishes containing complete marsupial media 33. Tissues were excised with a scalpel blade and incubated 18–24 hours at 37°C. Disaggregated cells were then transferred to 15 mL Falcon tubes and centrifuged to collect cells and rinsed with sterile PBS to remove remaining Collagenase. Cells were further disaggregated with a 1 mL syringe capped with a 21G needle, transferred to flasks (25 cm²) and grown to confluency at 35°C in complete marsupial media. Optimal 5-azacytidine treatment recovery time was determined empirically. Four flasks (25 cm²) with cells at ~60% confluency were treated with 20 uM 5-azacytidine in complete marsupial media for 24 hours followed by 24, 48, 72 and 96 hours of recovery, respectively. DNA was isolated from each flask and 1 μg was digested with HpaII overnight. The recovery time of 48 hours contained cells showing the greatest decrease in CpG methylation and was subsequently chosen for further analyses (data not shown).

Igf2 probe was derived from 5 kb of intronic sequence 5' of the first noncoding exon. The subclone was generated from M. domestica IGF2 BAC DNA clone # 223O16, pCC1BAC 34 from the VMRC18 library (CHORI) digested with EcoR I and Bgl II and ligated into pBluescript^® KS+ (Stratagene). Plasmid DNA (1 μg) was labeled with dig-11-dUTP using the Dig High Prime (Roche) Kit for RNA FISH and with biotin-16-dUTP with the Biotin High Prime (Roche) Kit for DNA FISH, both according to manufacturer's instructions. Probe DNA was precipitated with 10 μg salmon sperm DNA, 10 μg tRNA, 20 μg sonicated M. domestica genomic DNA and 2 volumes -20°C ethanol for 30 minutes at -80°C. Following centrifugation for 20 minutes, hybridization cocktail DNA was resuspended in 17 μl of 100% deionized formamide and 17 μl 2 X hybridization mix 35. Hybridization cocktail DNA was denatured at 70°C for 10 minutes and incubated at 37°C for 30 minutes to allow blocking of repeat sequences in the probe DNA.

Day 0 neonate fibroblast cells were plated on a Dual Chamber slide in DMEM media supplemented with 10% FBS and non-essential amino acids overnight at 35°C. Once the cells were at ~60% confluency, one of the two wells for each slide was treated with 5-azacytidine (20 uM) for 24 hrs, while the control well was treated with media alone. After 24 hours of treatment, both wells were rinsed with PBS and treated with media for 48 hours of recovery at 35°C. Following recovery, slides were processed in cytoskeletal buffer for 2.5 minutes, followed by formaldehyde fixation and 2 × 70% ethanol rinses according to 36.

Following overnight hybridization at 37°C under a 22 × 50 mm coverslip across both the treated and control wells, slides were washed in 50%formamide/2 × SSC at 45°C for 3 washes of 5 minutes each followed by 1 × SSC (prewarmed to 60°C) at 45°C for 3 washes of 5 minutes each. Detection using anti-dig-rhodamine was performed according to 37. Cells were counterstained with DAPI, mounted in antifade and viewed on a Leica DM6000B equipped with a DFC350FX CCD camera and analyzed on a CW4000 Cytogenetics Image Analysis Workstation. Once positive hybridization signals were visually confirmed, the slide was rinsed in PBS to remove the coverslip and antifade solution and was subsequently processed for DNA FISH. The slide was treated with RNAse A (0.1 mg/mL RNAse A in 2 × SSC). Following chromosome denaturation in 70%formamide/2 × SSC at 70°C for 2 minutes the slide was dehydrated in ice cold 70%, 90% and 100% ethanol.

DNA FISH probe (1 μg biotin labeled DNA) was precipitated according to RNA FISH (above). The DNA FISH hybridization cocktail was denatured and pre-annealed and applied to the slide as above. FISH washes were performed as above followed by detection with anti-biotin FITC Avidin Fluorescein (Vector Laboratories).

Hybridization signals were scored for a minimum of 25 cells per well 38. Only cells containing two positive DNA hybridization signals were scored for use in statistical analyses. Chi tests were performed to determine whether the observed peak signal distribution of hybridization signals within the treated well was significantly different than the peak signal distribution of the control sample.

A Monodelphis domestica genomic library constructed in Lamda FIX^®II/XhoI (Stratagene, according to the manufacturer's protocol) was screened using a probe generated from amplification of genomic DNA from a male M. domestica liver with primers designed from an alignment of the 3' untranslated region (UTR) of several species 4. Subclones were generated by restriction digests with BamH I, EcoR I, Not I, and Sac II and ligation into pBluescript^® II KS+ vector (Stratagene). Additional sequence was obtained by screening the VMRC-18 M. domestica genomic library ordered from BACPAC Resources (Children's Hospital Oakland Research Institute, Oakland, CA) using the same 3' UTR probe. BAC DNA was prepared using a QIAGEN™ Plasmid Midi Kit following manufacturer's instructions. Sequencing was accomplished by primer walking using BigDye Chemistry (Applied Biosystems), according to the manufacture's protocol. Regions of repeats or secondary structure were subcloned after Pst I digestion into pBluescript^® KS+, then sequenced using 400 ng DNA, 2.3 μL of 5× buffer, 5% DMSO (final concentration), 1 M Betaine (final concentration), 2 μL BigDye Terminator v3.1, dGTP BigDye Terminator v3.0 (Applied Biosystems), 3.2 picomoles primer, and MilliQ water to 20 μL. The reaction was run for 30 cycles at 95°C for 15 sec., 50°C for 5 sec., and 60°C for 2 min.

The 5' untranslated exon sequence was captured by RACE using the BD SMART™ RACE cDNA Amplification Kit. The procedure was done as described by the manufacturer using 1 ug of total RNA, a reverse gene specific primer (5': GACGCTTGGCCTCTCTGAT) in the primary PCR, and a reverse nested gene specific primer (5: CGGGGAATCTGGGGAAGTTGTCC). The resulting amplicon was cloned into the pCR^® II Topo^® vector and sequenced.

The full 22 kb from M. domestica IGF2 and Macropus eugenii (BAC MEKBa-346C2, gi: CR925759) were analyzed in VISTA 21 using a 100 bp sliding window. Sequence identity greater than 70% over 100 bp was scored. The homologous segment of human IGF2 (UCSC Genome Browser: hsa chr11:2107400-2125903) was used in pairwise VISTA alignments to identify conserved portions within a 100 bp sliding window with greater than 50% identity.

CpG islands were predicted by the program CpG Plot with input analyzed using an observed/expected ratio of 0.6 and a window length of 200 bp 22. Either bisulfite sequencing or southern analysis was conducted on CpG islands to evaluate the presence of differential methylation. Bisulfite sequencing was performed on neonate liver DNA. Briefly, 4 μg of DNA extracted from a Day 0 neonate was treated with bisulfite reagents using the EZ DNA Methylation Kit (Zymo Research) as per manufacturer's instructions. Four microliters of treated DNA was then amplified using 100 ng forward and reverse primers designed in MethPrimer 34 (see Additional file 1) in a 35 cycle protocol consisting of 94°C for 1 min., 55°C for 30 sec., and 72°C for 30 sec. The PCR products were ligated into pCR^® II Topo^® vector (Invitrogen) and multiple sublcones sequenced. Sequences were aligned with Clustal X and analyzed in Meth Tools 39.

Two CpG islands (I and IV, Figure 2B) were not amenable to primer design due to the presence of repeats, and were thus analyzed by southern analyses. For CpG island I, 10 μg of genomic DNA was digested with PstI in conjunction with either Msp I or Hpa II to allow for the detection of a <1 kb band encompassing the boundary of this island. The probe was generated by amplification of DNA from forward (5': GCTTCATCGACTTCAGGCTG) and reverse (5': CTCAGTGGGGAGCTCTCCA) primers. For CpG island IV, 10 μg of genomic DNA from a Day 0 neonate was digested with EcoR I and Xmn I in conjunction with either Msp I or Hpa II to allow for the detection of a <1 kb band encompassing the boundary of this island. The probe was generated by amplification of DNA from forward (5': AAAGTCCGCAAGGGGATG) and reverse (5': CCCCCTTCAGTCCTCTCTCT) primers. In both assays, a shift, or lack thereof, in the size of the hybridizing fragments in the HpaII digests indicates the methylation status of the respective targeted CpGs.

Quantitative PCR (QPCR) of the region just upstream of the 5' noncoding exon (CpG island III) was performed using Biorad Sybr Green on Biorad iCycler machine as previously described 40. Briefly, 2 μg genomic DNA isolated from non-treated and 5-azacytidine treated neonate cells was digested overnight at 37°C in separate reactions with either 40 Units of EcoRI (an enzyme targeting sites outside of the PCR target region), HpaII (methylation sensitive) or MspI (methylation insensitive) and subsequently cleaned using Microcon YM-100s according to the manufacturer's protocol. Primers spanning one CCGG (HpaII/MspI) targeting the CpG island III (see Additional file 1) amplified 50 ng of gDNA (undigested gDNA, EcoRI digested gDNA, HpaII digested gDNA and MspI digested gDNA) from either non-treated or 5-azacytidine treated cells with the following cycling conditions: 95°C for 15 sec, 63°C for 45 seconds in 40 total cycles. EcoRI digested DNA was analyzed by QPCR to verify there was no effect on amplification efficiency due to post-digestion processing (data not shown). MspI digested DNA was analyzed by QPCR to verify there was complete digestion of HpaII/MspI sites regardless of methylation (no amplification detected, data not shown). The reference PCR product targeted the first coding exon and contained no restriction sites (see Additional file 1). Reactions were assembled in triplicate and normalized against the reference as in 41.

Sequence obtained from BAC and lambda clones were input into the MAR-Wiz program v 1.5 23 for analysis of potential matrix attachment regions. Halo preparation was performed by culturing fibroblast cells from M. domestica day 0 neonates as above. Nuclear halos were then prepared by the methods of 42 with the exception that dehydration following halo formation consisted of 10%, 30%, 70%, 90%, and 100% ethanol, and slides were fixed in methanol/acetic-acid (3:1) for 1 hour, then baked for 1 hour. The slide was treated with RNase A (0.1 mg/mL in 2 × SSC) for 1 hour and denatured in 70% formamide/2 × SSC at 70°C for 2 minutes prior to hybridization, then serially dehydrated at -20°C in 70%, 90%, and 100% ethanol and allowed to dry.

The in situ hybridization experiments were carried out with prepared halos using the 5 kb sublcone as above. Random priming with DIG-High Prime (Roche), DNA FISH probe preparation, hybridization and post-hybridization washes were performed as above for RNA-DNA FISH.