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Altered Ultrasonic Vocalization and Impaired Learning and Memory in Angelman Syndrome Mouse Model with a Large Maternal Deletion from Ube3a to Gabrb3

  • Yong-hui Jiang ,

    yong-hui.jiang@duke.edu

    Affiliations Department of Molecular and Human Genetics, Baylor College of Medicine, Houston, Texas, United States of America, Division of Medical Genetics, Department of Pediatrics and Neurobiology, Duke University School of Medicine, Durham, North Carolina, United States of America

  • Yanzhen Pan,

    Affiliation Department of Molecular and Human Genetics, Baylor College of Medicine, Houston, Texas, United States of America

  • Li Zhu,

    Affiliation Division of Medical Genetics, Department of Pediatrics and Neurobiology, Duke University School of Medicine, Durham, North Carolina, United States of America

  • Luis Landa,

    Affiliation Department of Molecular and Human Genetics, Baylor College of Medicine, Houston, Texas, United States of America

  • Jong Yoo,

    Affiliation Neurogenetics Laboratory of Department of Neurology, Baylor College of Medicine, Houston, Texas, United States of America

  • Corinne Spencer,

    Affiliation Department of Molecular and Human Genetics, Baylor College of Medicine, Houston, Texas, United States of America

  • Isabel Lorenzo,

    Affiliation Department of Molecular and Human Genetics, Baylor College of Medicine, Houston, Texas, United States of America

  • Murray Brilliant,

    Current address: Center for Human Genetics, Marshfield Clinic Research Foundation, Marshfield, Wisconsin, United States of America

    Affiliation Department of Pediatrics, University of Arizona Health Science Center, Tucson, Arizona, United States of America

  • Jeffrey Noebels,

    Affiliation Neurogenetics Laboratory of Department of Neurology, Baylor College of Medicine, Houston, Texas, United States of America

  • Arthur L. Beaudet

    Affiliation Department of Molecular and Human Genetics, Baylor College of Medicine, Houston, Texas, United States of America

Abstract

Angelman syndrome (AS) is a neurobehavioral disorder associated with mental retardation, absence of language development, characteristic electroencephalography (EEG) abnormalities and epilepsy, happy disposition, movement or balance disorders, and autistic behaviors. The molecular defects underlying AS are heterogeneous, including large maternal deletions of chromosome 15q11–q13 (70%), paternal uniparental disomy (UPD) of chromosome 15 (5%), imprinting mutations (rare), and mutations in the E6-AP ubiquitin ligase gene UBE3A (15%). Although patients with UBE3A mutations have a wide spectrum of neurological phenotypes, their features are usually milder than AS patients with deletions of 15q11–q13. Using a chromosomal engineering strategy, we generated mutant mice with a 1.6-Mb chromosomal deletion from Ube3a to Gabrb3, which inactivated the Ube3a and Gabrb3 genes and deleted the Atp10a gene. Homozygous deletion mutant mice died in the perinatal period due to a cleft palate resulting from the null mutation in Gabrb3 gene. Mice with a maternal deletion (m−/p+) were viable and did not have any obvious developmental defects. Expression analysis of the maternal and paternal deletion mice confirmed that the Ube3a gene is maternally expressed in brain, and showed that the Atp10a and Gabrb3 genes are biallelically expressed in all brain sub-regions studied. Maternal (m−/p+), but not paternal (m+/p−), deletion mice had increased spontaneous seizure activity and abnormal EEG. Extensive behavioral analyses revealed significant impairment in motor function, learning and memory tasks, and anxiety-related measures assayed in the light-dark box in maternal deletion but not paternal deletion mice. Ultrasonic vocalization (USV) recording in newborns revealed that maternal deletion pups emitted significantly more USVs than wild-type littermates. The increased USV in maternal deletion mice suggests abnormal signaling behavior between mothers and pups that may reflect abnormal communication behaviors in human AS patients. Thus, mutant mice with a maternal deletion from Ube3a to Gabrb3 provide an AS mouse model that is molecularly more similar to the contiguous gene deletion form of AS in humans than mice with Ube3a mutation alone. These mice will be valuable for future comparative studies to mice with maternal deficiency of Ube3a alone.

Introduction

Angelman syndrome (AS) is a neurodevelopmental disorder associated with severe mental retardation, absence of language development, characteristic EEG abnormalities and epilepsy, happy disposition, movement disorders, and autistic features [1]. The molecular defects underlying AS are heterogeneous. About 70% of AS patients have a large chromosomal deletion of 15q11–q13, exclusively of maternal origin. Paternal uniparental disomy (UPD) of chromosome 15 is found in ∼5% of AS patients. Mutations of the E6-AP ubiquitin ligase gene (UBE3A) on maternal chromosome 15 are found in about 15% of AS patients. Rarely, a microdeletion in the region designated as an imprinting center is also found in some cases of AS. The finding of loss-of-function mutations in the maternal UBE3A gene in patients with typical features of AS indicates that maternal deficiency for UBE3A is responsible for the major clinical manifestations [2], [3]. In addition, maternal, but not paternal, duplication of 15q11–q13 has been reported in about 1–2% of idiopathic autism spectrum disorder patients [4]. Recently, a small duplication covering from ATP10A to GABRB3 was reported in one autism patient [5]. At the molecular level, AS patients with a large chromosomal deletion of 15q11–q13 have deficiency of the maternally expressed UBE3A gene and possibly of ATP10A in brain, and they are haploinsufficient for many other genes with biallelic expression within the 6-Mb deleted interval. These biallelically expressed genes include the GABA receptor cluster of GABRB3, GABRG5, and GABAG3 telomeric of UBE3A, and CYFIP1, NIPA1, NIPA2, GCG5, WHCD1L1, and GOLGA8E at the centromeric end of the deletion in patients with a larger class I deletion [6], [7]. Reports have suggested that the ATP10A gene is maternally expressed in humans [8], [9]. One report found that ATP10A exhibits imprinted expression in brain but biallelic expression in non-neuronal tissues [9]. Another study reported imprinted expression of ATP10A in lymphoblasts as well as brains [8]. The most recent report found that ATP10A was expressed biallelically in brain in the majority of individuals examined while a small percentage exhibited variable monoallelic expression but not strictly maternal allele-specific. Monoallelic expression appeared to be favored by female gender [10]. Reports of imprinting status of the mouse ortholog of ATP10A were also not consistent. One report indicated that Atp10a is maternally expressed in hippocampus and olfactory bulb [11], while two other studies found that Atp10a is biallelically expressed in all tissues [12], [13]. Similarly, there were reports suggesting paternal, maternal, and biallelic expression of GABRB3 in humans and mice using different experimental designs [14], [15], [16]. A recent report also suggested greatly reduced levels of the Gabrb3 subunit in the brain of male mice with a maternally transmitted Gabrb3 mutation but not in male mice with paternal origin of the same mutation [17].

In humans, analyses of genotype and phenotype correlation among AS patients with different classes of molecular defects have been reported [18], [19]. These analyses have revealed that AS patients with large chromosome deletions of 15q11–q13 have more severe phenotypes than AS patients with UBE3A mutations, paternal UPD, and imprinting mutations. In addition, there were early reports suggesting that loss-of-function UBE3A mutations, paternal UPD of chromosome 15, or imprinting mutations in AS were associated with relatively milder epilepsy while AS patients with a deletion of chromosome 15q11–13 had more severe epilepsy [20]. However, other studies found no genotype-phenotype correlation for EEG abnormalities and epilepsy among AS patients with different genotypes [21], [22]. One caveat of these studies was the relative small sample size which might bias the results and conclusion.

We have previously characterized an AS model with a null mutation of the Ube3a gene. Mice with maternal deficiency of the Ube3a gene recapitulated the brain-specific imprinted expression [23], [24]. Mice inheriting the Ube3a mutation maternally, but not paternally, displayed phenotypes that resemble AS with abnormal EEG and seizure activity, motor dysfunction, and defects in contextual fear conditioning and hippocampal long-term potentiation (LTP). These findings, together with a report by others, indicate that mice with maternal deficiency of Ube3a are a valid model for human AS with mutations in the UBE3A gene [23], [25].

Here we report generation and characterization of mutant mice with a 1.6-Mb chromosomal deletion from Ube3a to Gabrb3. The chromosomal deletion was generated by a chromosome engineering technique using cre/loxP and two halves of a Hprt (hypoxanthine-guanine phosphoribosyl transferase) minigene as described previously [26], [27], [28]. The deletion disrupted both the Ube3a and Gabrb3 genes and also deleted the 1.6-Mb interval that contains the Atp10a gene. Analyses of maternal (m−/p+), paternal (m+/p−), and homozygous (m−/p−) deletion mice indicate that mice with a maternal deletion from Ube3a to Gabrb3 provide an AS mouse model that is molecularly more similar to the common contiguous deletion form of AS, and thus valuable for future comparative studies.

Results

Generation of mice with a chromosomal deletion from Ube3a to Gabrb3

We used the chromosomal engineering technique to generate mice with a large chromosomal deletion from Ube3a to Gabrb3 as described previously [28], [29] and in detail in the Methods section. A total of three 129SvEv embryonic stem (ES) cell clones (P11A8, P11B6, and P11H8) with a deletion from Ube3a to Gabrb3 were confirmed by DNA Southern analysis and injected into C57BL/6J blastocysts to obtain germline transmission. A total of 14 chimeric mice were produced. Germline transmission was obtained from ES cell clones P11A8 and P11B6 but not from P11H8. The Gabrb3 and Ube3a double targeted mutations without a deletion between them were also obtained in germline (data not shown). Mice with a deletion from Ube3a to Gabrb3 were identified by DNA genomic Southern analysis using genomic probes flanking and within the deletion interval as shown in the Figure 1E. Absence of signal in DNA Southern analysis using a probe hybridizing within the Atp10a gene indicated that the desired deletion was produced. A PCR-based mouse genotyping protocol was also developed for routine mouse colony management (data not shown). The estimated size of the deletion from Ube3a to Gabrb3 was 1.6-Mb (from 64846987 bp to 66527319 bp) based on the NCBI Build 37 assembly of mouse genome sequences (www.genome.ucsc.edu). Both the Ube3a and Gabrb3 genes were disrupted as shown in Figure 1D and confirmed by the RNA and protein analyses shown in Figure 2A and 2B using fetus with a homozygous deletion. Mice with a Ube3a single mutation have been characterized and reported previously [23]. Mice with a Gabrb3 single mutation and Ube3a and Gabrb3 double mutations produced from this experiment have not been fully characterized. However, Gabrb3 mutant mice with a different mutation have been reported previously by others [30]. Because of involvement of imprinting in the region, a specific breeding scheme diagramed in supplemental Figure S4 was followed to produce mice for experiments described below.

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Figure 1. Generation of mice with a deletion from Ube3a to Gabrb3 using chromosome engineering.

A. Genomic maps for Ube3a and Gabrb3 loci and design of targeting constructs (X, XbaI; H, HindIII; N, NotI; E, EcoRI; S, SacII; B, BamHI). The number in the rectangle indicates the exon number. B & C. Genomic DNA Southern analysis for Ube3a or Gabrb3 targeted ES cell clones using 5′-flanking probes and BamHI and HindIII restriction enzymes respectively. D. A genomic map from Ube3a to Gabrb3 and a scheme for chromosome engineering using half of Hprt and Cre/loxP strategy. The black bars indicate genomic probes used for DNA Southern analysis. E. Confirmation of a deletion from Ube3a to Gabrb3 by genomic DNA Southern analysis using probes shown in D. The probes P1 and P4 hybridize outside of the deleted interval and the probes P2, P3, and PD hybridize within the deleted interval. Four independent but indistinguishable ES cell clones (1–4, +/del) with a deletion were analyzed, and clone 5 (+ndel) was a Ube3a and Gabrb3 double targeted clone without a deletion. The DNA Southern analysis using the probe PD within the Atp10a gene showed no signal in the DNA from homozygous deletion (del/del or m−/p− in text) mice. “Co” was a control probe from the Snrpn gene that is outside of deleted region in chromosome 7.

https://doi.org/10.1371/journal.pone.0012278.g001

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Figure 2. Expression analysis of Ube3a, Atp10a, and Gabrb3.

A. Quantitative immunoblot analysis of Ube3a and Gabrb3 proteins in cerebellum. The m+/p+ is for wild-type, the m−/p+ is for maternal deletion, the m+/p− is for paternal deletion, and the m−/p− is for homozygous deletion fetus. The m+/p+ next to m−/p− was fetal brain tissue; others tissues were from adult mice. There was no detectable expression of Ube3a in m−/p+ and m−/p− mice indicating a null mutation in homozygotes and exclusively maternal expression of Ube3a. The expression of Ube3a in the m+/p− mice was similar to m+/p+ mice. The expression of Gabrb3 was reduced but readily detectable in m+/p− and m−/p− mice for both males and females compared to that of m+/p+ mice. The expression level of Gabrb3 normalized to β-actin is shown in 2B. The difference between m+/p+ and m−/p+, m+/p+ and m+/p− was significant (n = 5, p<0.01) but there was no significant difference between m−/p+ and m+/p− (n = 5, p>0.05). 2C–E. Expression analysis of Atp10a by regular and real-time RT-PCR analyses. The labels for genotype are the same as indicated in panel A. Data from regular RT-PCR analysis for Atp10a using RNA isolated from cerebral cortex are shown in 2C and from the cerebellum in 2D. The expression of Hprt was used as a control. The absence of RT-PCR product for Atp10a in the m−/p− fetus indicated a null mutation of Atp10a in mice with a deletion. The expression of Atp10a was detectable and not significantly different between m−/p+ and m+/p− mice. The expression of Atp10a normalized to β-actin by real-time RT-PCR analysis is shown in 2E. The level of expression of Atp10a in m−/p+ and m+/p− was significantly lower than that of m+/p+ both in males and females (n = 3, p<0.01) but there was no significant difference between m−/p+ and m+/p− (n = 3, p>0.05).

https://doi.org/10.1371/journal.pone.0012278.g002

Expression analysis of Ube3a, Atp10a, and Gabrb3 in mice with a deletion from Ube3a to Gabrb3

We examined the parental origin of expression for Ube3a, Gabrb3, and Atp10a in mice inheriting a paternal or maternal deletion by RNA or protein analysis. Tissues from homozygous deletion mice (m−/p−) were included in the analysis as controls. The expression of Gabrb3 and Ube3a was examined by quantitative immunoblot analysis while the expression of Atp10a was performed by regular and real-time RT-PCR analysis because a specific antibody against Atp10a was not available. Because of a report of gender differences in monoallelic expression of Gabrb3 in mice and ATP10A in humans [10], [17], we performed the expression analysis in both sexes of mice with a deletion from Ube3a to Gabrb3. Different brain regions, including hippocampus, cerebellum, and cerebral cortex, were dissected and compared to liver tissues to determine if there were tissue-specific differences. The data from all three brain regions were similar and only data from cerebellum are shown. As shown in Figure 2A, the protein level of Ube3a in m−/p+ mice was undetectable in cerebellum while the protein level of Ube3a in m+/p− mice was comparable to that in m+/p+ mice. The expression in the cerebral cortex of m−/p+ mice was similar to cerebellum and almost exclusively maternal (data not shown). The expression of Ube3a was readily detectable and similar in liver tissues among m−/p+, m+/p−, and m+/p+ mice which indicated biallelic expression of Ube3a in non-CNS tissues (data not shown). These data are consistent with the previous reports that Ube3a is maternally expressed in brain [23], [24] but the expression in the cerebral cortex was slightly different from the reports by RNA in situ in UPD and Ube3a mutant mice [23], [31]. The expression of Gabrb3 was also readily detectable in m−/p+, m+/p−, and m+/p+ mice in different brain regions in both males and females by quantitative immunoblot analysis as shown in Figure 2A. The level of Gabrb3 was 61.6±2.3% of wild-type in the m−/p+ mice and 62.5±2.1% of wild type in the m+/p− mice for both sexes together which is slightly higher than 50% as predicted for heterozygotes. The level of Gabrb3 in m+/p− and m−/p+ mice for males and females normalized to m+/p+ separately is summarized in Figure 2B. There was no significant difference between m+/p− and m−/p+ for males (n = 5, p = 0.75) or females (n = 5 and p = 0.29). There was no evidence for parental origin effect on the expression of Gabrb3 in the tissues examined. Similarly, expression of Atp10a was readily detectable by regular RT-PCR analysis in the cerebellum, cerebral cortex, hippocampus, and liver tissues of m−/p+ and m+/p− mice (Figure 2C and 2D, and data not shown for hippocampus and liver tissues). Among 8 (4 males and 4 females) m−/p+ and 7 m+/p− mice (4 females and 3 males) analyzed by RT-PCR, we did not observe the exclusively monoallelic expression of Atp10a in the cerebellum and hippocampus that was described in human brains [10]. To examine whether there was a quantitative or gender specific imprinting expression of Atp10a, we also performed real-time RT-PCR analysis for Atp10a in cerebellar tissues from m−/p+ and m+/p+ mice of both sexes. Expression of Atp10a normalized to the level of Gadph was 51.8±0.8% of wild type in m−/p+ male mice and 50.6±0.4% of wild type in m−/p+ male mice. There was no significant difference in the expression of Atp10a between male and female m−/p+ mice (p = 0.45, n = 3). These results indicate that the Atp10a gene is biallelically expressed in the tissues examined although the possibility of cell-type specific or developmental stage specific imprinting cannot be ruled out.

Perinatal lethality of mice with homozygous deletions from Ube3a to Gabrb3

Heterozygous mice inheriting a deletion of either paternal or maternal origin did not have any developmental defect. At 3 months of age, there was no difference in weight between m−/p+ (22.0±0.8 g) and m+/p+ mice (22.6±0.7 g) (p = 0.55), or between m+/p− (20.8±0.9 g) and m+/p+ mice (20.9±0.8 g) (p = 0.9). There was no apparent difference between m−/p+ and m+/p− mice by visual inspection. The lifespan of m−/p+ and m+/p− mice was similar to their m+/p+ littermates. Homozygous mutant mice with a deletion from Ube3a to Gabrb3 (m−/p−) were smaller at birth and most died within 1 to 3 days after birth due to a cleft palate and poor feeding (Figure 3A). At the weaning age, there was a significantly skewed distribution of genotypes from Mendelian inheritance (wild-type 20; heterozygotes 39; and homozygotes 2, p<0.001) because of perinatal lethality. We carefully examined each pup (n = 12) that died perinatally. Nine of 12 dead pups had a cleft palate, a representative example of which is shown in Figure 3C. No other obvious structural defects were found in pups with a homozygous deletion from Ube3a to Gabrb3. Functional defects such as poor feeding may be considered as the cause of perinatal death for pups without a cleft palate. Because it was reported previously that a homozygous null mutation of Gabrb3 caused cleft palate [30], we also generated mice with single homozygous Gabrb3 mutation for the purpose of comparison. A cleft palate was found in 6 out of 7 pups with a homozygous Gabrb3 mutation. Two mice with a homozygous deletion from Ube3a to Gabrb3 survived beyond the perinatal period but died at 24 and 28 days of age without a known cause. These two mice were ∼20% of smaller than their wild type littermates and without an apparent cleft palate. To determine whether embryonic lethality was associated with m−/p− mice, a total of 19 pups from three litters were dissected and genotyped at 16 days of gestational age. The distribution of genotypes was not significantly different from the expected Mendelian inheritance (wild-type 5; heterozygotes 10; and homozygotes 4, p>0.05). These data suggested that a homozygous deletion from Ube3a to Gabrb3 did not cause embryonic lethality and that the function of Atp10a is probably not critical for embryonic development.

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Figure 3. Perinatal lethality and cleft palate in newborn mice with a homozygous deletion from Ube3a to Gabrb3 (m−/p−).

A. Growth retardation of 2-day-old pup with a homozygous deletion from Ube3a to Gabrb3. B & C. Cleft palate in a pup with a homozygous deletion from Ube3a to Gabrb3. The black arrow points to the cleft palate in pup with a homozygous deletion (m−/p−).

https://doi.org/10.1371/journal.pone.0012278.g003

Spontaneous seizures and cortical discharges in mice with a maternal deletion from Ube3a to Gabrb3

Spontaneous visible tonic-clonic seizures were observed in 21.4% (6/28) of m−/p+ mice at 3–6 months of age but not in m+/p+ mice (n = 32) or m+/p− mice (n = 36) on the relatively homogenous C57BL/6J genetic background after more than 6 generations of backcrossing to C57BL/6J mice. The frequency of seizure activity in Ube3a to Gabrb3 maternal deletion mice was not different from that of maternal Ube3a deficiency alone (21%) previously reported [23]. To further characterize seizure activity, we performed chronic electroencephalographic (EEG) recordings for 3 m−/p+, 3 m+/p−, and 3 m+/p+ mice at 3–4 months of age. As shown in Figure 4, EEG in m−/p+ mice showed a pattern beginning with sudden isolated giant spike-wave discharges with no behavioral accompaniment, but then progressed to higher spike discharge frequencies, at which point the mice displayed sustained behavioral arrest and subtle myoclonic movements. These seizures lacked any tonic posturing or postictal phenomenology, and the mice rapidly resumed normal behavior (a sample video of recording is included in the supplementary data, Video S1). Frequent generalized cortical single interictal spike discharges were also present in m−/p+ mice (not shown). We also performed EEG recording in maternal Ube3a deficiency alone mice, and consistent with previous findings [23], an abnormal EEG was observed (data not shown). Electrographic seizures or discharges were not observed in m+/p− and m+/p+ mice during the recording.

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Figure 4. Abnormal EEG in mice with a maternal deletion from Ube3a to Gabrb3 (m−/p+).

Multielectrode continuous EEG tracing shows representative generalized rapid cortical spike seizure discharge in freely moving m−/p+ deletion mice. Top-bottom: temporal (T), parietal (P), and occipital leads (O) alternating between left (L) and right hemisphere (R) indicated as LT, RT, LP, RP, LO, and RO. The six panels in the top tracing were continued in the lower section. Single arrow indicates the onset of sudden isolated giant spike-wave discharges with no behavioral accompaniment, and double arrow marks progression to higher spike discharge frequencies.

https://doi.org/10.1371/journal.pone.0012278.g004

Behavioral analyses

We conducted a battery of behavioral tests for mice with a maternal or paternal deletion from Ube3a to Gabrb3. Mice used for behavioral tests were backcrossed to the C57BL/6J background for more than 6 generations as described in Methods section and diagramed in supplementary Figure S4. Behavioral tests included the following: open field, light dark, rotarod, prepulse inhibition (PPI), fear conditioning, Morris water maze, hot plate, and ultrasonic vocalization (USV) recording. Mice at age 8–10 weeks with a maternal deletion (m−/p+), paternal deletion (m+/p−), and their wild type (m+/p+) littermates were used for the tests. A total of 10 m−/p+ mice (5 males and 5 females) were compared to a total of 16 m+/p+ (7 males and 9 females), and 11 m+/p− mice (6 males and 5 females) were compared to 10 m+/p+ (5 males and 5 females). For USV recording, newborn pups of 6 day old were used for all genotypes. A total number of 18 m−/p+ pups (8 males and 10 females) and 17 m+/p+ (7 males and 10 females); and 27 m+/p− pups (12 males and 15 females) and 22 m+/p+ (12 males and 10 females) were analyzed. Mice used for USV recording were not used for other behavioral tests. Experimenters were blinded to the genotype during testing, and tested mice were re-genotyped after completion of testing. There was no significant difference between males and females for these tests. Therefore, the results were pooled for each test and described below.

Locomotor activity in the open-field

The open-field test was used to assess exploratory activity and anxiety-related responses in a novel arena. The travel distance during each testing block was similar for m−/p+ and m+/p− mice and their m+/p+ littermates (p = 0.12 for m−/p+ and p = 0.23 for m+/p−) (Figure S1A and S1B). There was no significant difference in total travel distance between m−/p+ mice and their m+/p+ littermates (Figure S1C; p = 0.4), and there were no differences in the center and total distance ratio (data not shown). Similarly, there was no difference in total travel distance between m+/p− mice and their m+/p+ littermates (Figure S1C, p = 0.42).

Light-dark exploration

The light–dark exploration test was also used to assess anxiety-related responses. The number of light-dark transitions was significantly lower in m−/p+ mice than in m+/p+ littermates (p = 0.003) but not significantly different between m+/p− mice and m+/p+ littermates (p = 0.8) (Figure 5A). In addition, m−/p+ mice stayed for a significantly longer time in the dark chamber than their m+/p+ littermates (p = 0.008) (Figure 5B). There was no significant difference for light dark transition (p = 0.25) and for the percentage of time stayed in dark (p = 0.32) between m+/p+ of maternal and paternal groups. But the difference between m−/p+ and m+/p− was significant (p = 0.006). These results suggest anxiety related behavior assayed by this task in m−/p+ mice when compared to their m+/p+ littermates.

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Figure 5. Abnormal light-dark exploration and impaired rotarod performance in mice with a maternal deletion from Ube3a to Gabrb3 (m−/p+) but not a paternal deletion (m+/p−).

A & B. Light-dark transition. The m−/p+ but not m+/p− mice showed a significantly lower number of light and dark transitions, shown in A (p = 0.003), and also spent significantly longer time in the dark chamber, shown in B (p = 0.008). There was no difference between m+/p+ of maternal and paternal group for both light-dark transition and percentage of time stayed in dark. C & D. Rotarod performance. The time that m−/p+ mice remained on the accelerating rotarod was significantly shorter than m+/p+ littermates for all trials, shown in C (p<0.0001). The overall performance of m+/p− mice was slightly worse than that of m+/p+ littermates, but the difference was not statistically significant, shown in D (p>0.05). * p<0.05.

https://doi.org/10.1371/journal.pone.0012278.g005

Rotarod test

There was no apparently abnormal gaits and weakness of limbs in the maternal and paternal deletion mice. We then used rotarod to study motor coordination and motor learning skills. As shown in Figure 5C, m−/p+ mice performed significantly worse on an accelerating rotarod than their m+/p+ littermates (p<0.0001). The performance of m+/p− mice was slightly worse than their m+/p+ littermates but the results were not statistically significant (Figure 5D, p = 0.06).

Hotplate

The hotplate test is an indicator of the sensitivity of animals to painful stimuli. The time to the first hind-limb response is shown in the Figure S1D. There was no significant difference between m−/p+ mice and m+/p+ littermates (p = 0.9). Similarly, there was no difference between m+/p− mice and their m+/p+ littermates (p = 0.46).

Prepulse inhibition (PPI)

As shown in Figure S2, there was no difference in maximal startle response between m−/p+ mice and their m+/p+ littermates or between m+/p− mice and their m+/p+ littermates. There was a trend towards increased PPI in m−/p+ mice, but the difference was not statistically significant (Figure S2B, p = 0.17). There was no significant difference between m+/p− mice and their m+/p+ littermates (Figure S2C; p = 0.75).

Impaired contextual fear learning in maternal deletion mice

Levels of freezing behavior for the contextual and auditory cued conditioning fear tests are shown in Figure 6; m−/p+ mice displayed a significantly lower level of freezing behavior in contextual fear conditioning than their m+/p+ littermates (p = 0.03). A significant difference was not observed between m+/p− and m+/p+ mice for contextual fear conditioning (p = 0.59) (Figure 6A). There was no significant difference in cued fear conditioning for either m−/p+ (p = 0.31) or m+/p− (p = 0.58) mice compared to that of their m+/p+ littermates (Figure 6B). These findings suggest that m−/p+ mice, but not m+/p− mice, have a selective impairment in fear conditioning that is associated with the context or environment where the shock occurred but not in cued fear conditioning.

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Figure 6. Impaired learning and memory task in mice with a maternal deletion from Ube3a to Gabrb3 (m−/p+).

A & B. Fear conditioning. The m−/p+ but not m+/p− mice showed significantly less freezing behavior in contextual fear conditioning (A) but not for cued fear conditioning. C to G. Morris water maze task. The m−/p+ but not m+/p− mice showed significantly longer escape latency than m+/p+ littermates (p<0.001 for m−/p+ and p>0.05 for m+/p−). In the probe trial, analysis of platform crossing found that m+/p+ mice displayed a significantly biased searching strategy, shown in E (p<0.001), while m−/p+ mice displayed a random searching strategy, shown in F (p>0.05). Post hoc analysis of m+/p+ mice revealed that the difference was significant only between quadrant 4 and 2 (p<0.01), and quadrant 4 and 3 (p<0.02). The labeling of each quadrant and location of the hidden platform is illustrated in G. * p<0.05.

https://doi.org/10.1371/journal.pone.0012278.g006

Spatial learning in the Morris water maze task

We performed the Morris water maze test to evaluate spatial learning and memory. As shown in Fig. 6C and 6D, both m−/p+ and m+/p− mice had very similar performances on day 1 of training which indicated the ability of swimming was comparable. However, m−/p+ mice, but not m+/p− deletion mice, took a significantly longer time to locate the hidden platform in subsequent trials (p<0.001 for m−/p+ and p = 0.8 for m+/p− mice). Probe trials were performed after the last trial to determine if a different strategy of searching for the hidden platform was used by mice with different genotypes. As shown in Figure 6E and 6F, m+/p+ mice displayed a spatially biased search pattern by making significantly more platform crossings in the target quadrant 4 (p<0.001); a similar spatially biased searching pattern was not observed in the m−/p+ mice (p = 0.58). Post hoc analysis for m+/p+ mice showed that the difference was significant only between quadrant 3 and quadrant 4 (p<0.02), and between quadrant 2 and quadrant 4 (p<0.01) (see Figure 6G). The m+/p− mice showed a searching pattern similar to m+/p+ mice (data not shown).

Ultrasonic vocalizations (USVs)

We recorded ultrasonic vocalizations (USVs) for pups at age of postnatal day 6, 8, 10, and 12 on three different beddings of clean, mother's, and stranger's. The number of USVs recorded during a period of five minutes for each day on different beddings was analyzed separately (Figure S3) and together (Figure 7). When data were analyzed separately on different days and beddings, it was noted that the USV production of m−/p+ pups was lower on day 6 of the clean bedding than other beddings but not statistically significant (p = 0.07). However, the USV production of m−/p+ pups increased on subsequent days and was significantly higher (p = 0.034) on day 12 when compared to those of m+/p+ pups (Figure S3). When the data on different beddings were analyzed regardless of days, there was an overall trend of increased USVs in m−/p+ pups compared to those of m+/p+ littermates in different beddings. The difference was statistically significant in the group recorded on the mother's bedding (p = 0.006), borderline in the clean bedding group (p = 0.046), but not significant in the stranger's bedding (p = 0.12) (Figure 7A). There were no significant differences between m+/p− and m+/p+ pups in different beddings (p = 0.25) (Figure 7B). When the data were analyzed on the different days regardless of beddings, there were significantly increased USVs in m−/p+ pups compared to their m+/p+ littermates (p = 0.011). Post hoc analysis revealed that the difference between m−/p+ and m+/p+ littermates was significant on day 10 (p = 0.02), borderline on day 12 (p = 0.05), but not significant on day 6 (p = 0.81). The three-way (genotype vs bedding vs day) mixed design ANOVA did not reveal significant interaction among them (p = 0.07). Similarly, two-way ANOVA did not reveal significant interaction between genotype and bedding (p = 0.15), and genotype and day (p = 0.29). There was no difference in USV production between m−/p+ and m+/p+ pups (p = 0.82), or between m+/p− and m+/p+ pups (p = 0.3) recorded on clean bedding in cold temperature on day 10 and day 12. These data indicated a normal stress response and capability to produce the USVs for both m−/p+ and m+/p− pups. Thus, the abnormal pattern of USV production observed in maternal deletion pups may suggest abnormal signaling or communication behaviors between mother and offspring.

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Figure 7. Increased ultrasonic vocalizations (USVs) of newborn pups with a maternal deletion (m−/p+) from Ube3a to Gabrb3.

A and B. Comparison of m−/p+ and m+/p− pups respectively to their m+/p+ littermates in different beddings. The m−/p+ pups emitted significantly more USVs than that of m+/p+ littermates at mother's bedding (p = 0.006) (2B) but not for m+/p− pups(2C, p>0.05). C. Comparison of USVs of m−/p+ to m+/p+ at different postnatal days. The m−/p+ pups emitted more USVs overall than m+/p+ mice but this was only statistically significantly on day 10 (p = 0.02) and day 12 (p = 0.05). The three-way (genotype X bedding X day) with mixed design ANOVA did not reveal significant interaction among them (p = 0.07). Similarly, two-way ANOVA did not reveal significant interactions between genotype and bedding (p = 0.15), and between genotype and day (p = 0.29). D. Comparison of USVs for m−/p+ and m+/p− pups recorded in clean bedding at low temperature (4–6°C) on day 10 and day 12. There was no significant difference between m−/p+ and their m+/p+ littermates (p = 0.82), or between m+/p− and their m+/p+ littermates (p = 0.3). * p<0.05.

https://doi.org/10.1371/journal.pone.0012278.g007

Discussion

Application of chromosome engineering strategy to model the human chromosome microdeletion syndromes

Using Cre/loxP and Hprt minigene chromosome engineering strategies, we have successfully generated and characterized mutant mice with a 1.6-Mb chromosomal deletion in mouse chromosome 7 corresponding to the critical region homologous to that deleted in human Angelman syndrome. With the application of array CGH (comparative genomic hybridization) in clinical genetics practice, an increasing number of new microdeletion syndromes are being characterized [32], [33], [34]. Together with several examples reported previously by us and others [28], [35], this report emphasizes the value of this strategy in dissecting the pathogenesis of human microdeletion syndromes using mouse models [29]. We have observed a workable frequency of Cre mediated recombination between two loxP sites that were 1.6-Mb apart, and others have reported similar frequencies in other chromosomal regions [36]. The challenge of this strategy is probably still related to the difficulty of obtaining germline transmission for targeted ES cells that are subjected to multiple electroporations during the procedure [28], [37], [38].

No evidence for allele-specific expression of the Atp10a and Gabrb3 genes in mice

We have shown that there was no detectable expression of Ube3a, Atp10A, and Gabrb3 in homozygous deletion mice by RT-PCR or immunoblot analysis, which indicated that the deletion resulted in null alleles for all three genes. The expression pattern of Ube3a in the cerebellum and hippocampus in maternal deletion mice was consistent with previous reports of exclusive maternal expression of Ube3a in these regions [23], [24]. We also observed that the expression in the cerebral cortex was almost exclusively maternal. This is slightly different from the previous report that the expression of Ube3a was predominantly maternal and region specific in the cerebral cortex by RNA in situ in UPD mice [23], [31]. The discrepancy could be due to the sensitivity of different techniques or different mutations analyzed. Using mice carrying a paternal or maternal deletion of Atp10a and Gabrb3, we were able to examine the parental origin of expression for Atp10a and Gabrb3 directly. Our analysis did not provide any evidence supporting exclusive maternal expression of Atp10a but indicated biallelic expression of Atp10a in the brain regions of mice examined by quantitative RNA expression analysis. This analysis also did not reveal monoallelic expression of Atp10a that was reported in a small fraction of human brains and associated with gender [10]. This is in agreement with two studies that found no imprinted expression in any tissue examined [12], [13] but differs from a third report suggesting predominant maternal expression of Atp10a in hippocampus and olfactory bulb in mice [11]. It is not immediately clear why the results from these studies are different. One possibility is the effect of mouse genetic background on imprinting, but this has not been fully investigated [39]. Our expression analysis of Atp10a was performed in mice with a relatively homogenous C57BL/6J genetic background that overlaps with, but is not the same as that used in the other studies. The technical limitations of the different methods used should also be considered. Our strategy of using Atp10a knockout mice was different from the other studies, which used strain-specific single nucleotide polymorphisms to determine the parental origin of expression, or studied in PWS imprinting center mutant mice. A limitation of our analysis is that we could not rule out a cell type-specific imprinting expression of Atp10a. In the future, expression analysis by RNA in situ hybridization or immunohistochemistry may help to determine if cell type-specific imprinting is associated with Atp10a expression. Similarly, our analysis did not reveal any evidence for a parental origin of expression for Gabrb3 but again the possibility of cell type or developmental stage specific expression cannot be completely ruled out.

The function of Atp10a gene

The function of Atp10a in mammals is unknown. Homozygous mice with a deletion from Ube3a to Gabrb3 died 1 to 3 days after birth and did not have any increased embryonic lethality or additional structural defects compared to mice with a null mutation of either Gabrb3 or Ube3a alone, or Gabrb3 and Ube3a double mutation without a deletion (Jiang and Beaudet, unpublished data). These observations suggest that the function of Atp10a is probably not essential during embryonic development. Studies of mice carrying a radiation-induced large deletion proximal to the 3′-end of Snrpn to the p locus that included Atp10a, indicated that Atp10a may have an important role in insulin resistance and glucose metabolism [40], [41]. However, no direct conclusion regarding the role of Atp10a could be made because the deletion is large and mice are haploinsufficient for many genes in addition to Atp10a. It would be interesting to perform the experiment described by Dhar et al. [40] to determine whether insulin resistance can also be found in mice with the Ube3a to Gabrb3 deletion. Additional studies of homozygous deletion mice and a careful comparison to mice with null mutations of Ube3a or Gabrb3 in the region may reveal the function of Atp10a, or it may be necessary to produce an Atp10a single knockout in order to ultimately understand the function of this gene.

Increased USVs in the maternal deletion mice

Ultrasonic vocalizations (USVs) in neonatal mice have been studied both as early communicative behavior between pups and mothers, and as a sign of response to environmental stress such as separation and cold temperature [42]. Recording of USVs has been increasingly used as a tool to analyze behavioral phenotypes of mouse models of neurodevelopmental disorders although interpretation of the findings remains a subject of debate [43]. Currently, there is no standardized protocol for recording USVs in the literature [44]. We followed a previously described protocol with minor modifications [45]. The rationale for recording USVs on different beddings was based on the fact that different odors may present important cues for social stress or isolation [42]. Recording in cold temperature was designed to evaluate the response to a known stress for USV production [46]. The protocol of recording on different days was based on the observation that the peak of USV production varied on different postnatal days and differed among different mouse genetic backgrounds [47]. From reviewing the limited reports of USVs recording in knockout mice in the literature, we anticipated the possibility that m−/p+ pups might have reduced USVs because of absence of language and autistic features in AS. Thus the finding of an overall increase in USVs in pups with a maternal deletion from Ube3a to Gabrb3 was somewhat unexpected but not surprised. The comparable rate of USVs between m+/p+ and m−/p+ mice at cold temperature suggested that m−/p+ pups had a normal response to cold stress. The significantly increased production of USVs in different beddings and on different days for m−/p+ pups may indicate increased anxiety and response to social isolation stress. However, this interpretation seems counterintuitive because the difference between m+/p+ and m−/p+ was most significant in the mother's bedding which was intended to be less stressful because of the maternal odor. Alternatively, the significant difference in USV production between m+/p+ and m−/p+ pups recorded in the mother's bedding may reflect impairment related to maternal attachment behaviors between mother and offspring. In the earlier reports, the characteristic happy disposition and friendly behaviors in AS patients were considered to be contextually inappropriate and not related to the environment stimuli [18]. It has also been reported that AS patients have significant autistic features and often meet the diagnosis of autism spectrum disorder through autism diagnostic evaluation [48], [49]. In contrast, other recent behavioral studies suggest that happy disposition like smiling and laughing behaviors in AS were influenced by environmental clues and different social settings [50], [51]. By carefully observing social behaviors among children with AS caused by a deletion of 15q11–q13, Oliver et al. reported that AS patients smiled more and evoked a higher level of adult attention than the control group in different settings [51]. They concluded that the excessive smiling and laughing behaviors seen in AS patients may indicate an increase in signaling behaviors. Thus, the observation of increased production of USVs in m−/p+ pups may suggest that increased USVs is analogous to the increased signaling behaviors observed in human AS. It should be noted that the human AS behavioral observation studies by Oliver et al. were carried out only in a small number of AS patients, all with a deletion of 15q11–q13 [51], [52]. An interesting question is whether AS patients with mutations in the UBE3A gene have the same behavioral profile related to smiling and laughing as those with a deletion of 15q11–q13. With the availability of AS mouse models with Ube3a mutation alone and a deletion from Ube3a to Gabrb3 in this report, a similar question can also be addressed in mice by recording USVs in both AS mouse models and making a direct comparison. In addition, recording the USVs in adult mice or using a different protocol in newborn pups is also desirable to further characterize this intriguing phenotype in future.

The value of recording and analyzing USVs to model human autistic behaviors has been increasingly recognized, although the interpretation of data and biological meaning of USVs in rodents in relation to human behaviors is still a subject of debate [44], [53]. Reduced USVs were reported in Foxp2 and Nlgn4 deficiency pups [54], [55], [56], [57]. These reports supported the value of this technique because a mutation in the FOXP2 gene was implicated in a large family with characteristic language disorder, and mutations in NLGN4 have been found in a few cases of autism spectrum disorders in humans [58], [59]. On the other hand, similar to maternal Ube3a to Gabrb3 deletion mice, increased USVs were reported in Mecp2 deficiency pups, a mouse model of Rett syndrome, in which autistic behavior is a major feature [60]. The reason for increased USV in the Rett syndrome mouse model was also not clear. There was a suggestion that the increased USVs may be related abnormal respiratory function, a symptom commonly observed in Rett syndrome patients [43]. Interestingly, significant overlapping clinical features between AS and Rett syndrome have long been documented [61]. Thus, the increased USVs in both AS and Rett syndrome mouse models may suggest a shared pathogenesis between these two disorders. In addition, increased USVs in newborn pups was also reported in mice of BTBR T+tf/J, tuberous sclerosis gene Tsc2 mutation, and paternal duplication of human 15q11–q13 region [62], [63], [64]. These observations suggest that increased USVs may be a common feature in mutant mice related to autism.

A mouse model for a contiguous gene deletion form of Angelman syndrome

Although the deletion from Ube3a to Gabrb3 is smaller than the typical 6-Mb deletion frequently found in human AS patients, the deleted interval in mice includes Ube3a, Atp10a, and Gabrb3 and covers a critical region of AS deletion. Haploinsufficiency of Atp10a and Gabrb3 has been suggested to account for differences in the phenotypes between patients with a point mutation in UBE3A and the large deletion form of AS. Thus, mice with a maternal deletion from Ube3a to Gabrb3 are molecularly more similar to the AS patients with a large maternal deletion of chromosome15q11–q13. Our extensive behavioral characterization of both maternal and paternal deletion mice supports that the maternal deletion mouse is a valid model for the contiguous gene deletion form of AS. The impairments in learning and memory tasks, including contextual fear conditioning and Morris water maze, were specific to maternal, but not paternal, deletion mice. Although both light-dark and open field tests were used to evaluate anxiety related behaviors, maternal deletion mice only displayed an impairment in light-dark task but not in open field test. This may suggest a selective deficit in anxiety related behavior in maternal deletion mice. Although maternal deletion mice have significant impairment in rotarod test, there was no difference for the travel distance and speed in open field test. This was not a surprise because these mice did not have apparent motor coordination problem and abnormal gaits. The abnormal behaviors specific to the maternal deletion mice are consistent with a brain-specific, maternal expression pattern for the Ube3a gene. Mice used for these behavioral tests were on a relatively homogenous C57BL/6J genetic background after more than 6 generations of backcrossing to C57BL/6J. This is generally acceptable for most behavioral tests in the transgenic mutant mice although additional backcrossing may result more homogenous genetic background on C57BL/6J [65]. It should also be noted that the genetic background of the region most closely linked to the deletion at the Ube3a anchor is likely to be 129 SvEv and not C57BL/6J, even after backcrossing. The genetic background of the region at the Gabrb3 anchor is C57BL/6J because the targeting construct for Gabrb3 was produced using a C57BL/6J genomic library. The different genetic backgrounds at the targeted loci may influence the expression of genes adjacent to the targeted region. While this is technically difficult to investigate, the influence of these different genetic backgrounds on observed behavioral differences between maternal deletion mice and wild type littermate controls is probably minimal. Behavioral data from mice with a maternal Ube3a to Gabrb3 deletion are mostly consistent with previous studies of Ube3a mutant mice, but the current study is more extensive as summarized in Table 1,[23], [25], [66]. Although mutations in the UBE3A gene cause typical AS in humans, it has been reported in some studies that the phenotypes such as seizures in AS patients with UBE3A mutations are milder than in AS patients with large deletions of 15q11–q13 [20], [21], [22]. In mice, we noticed that the frequency of observed seizure activity was not significantly different between deletion and Ube3a mutation mice [23]. However, these data should be interpreted with caution because the seizure phenotype, at best, is only semi-quantifiable in mice. More extensive studies with a novel design or technique are needed to compare the seizure phenotype between mice with a deletion and Ube3a mutation alone in order to make a meaningful conclusion. Similarly, mice with a deletion from Ube3a to Gabrb3 provide a unique tool to compare other behavioral impairments that observed in mice with Ube3a mutation alone. However, there are potential issues in designing such comparative studies, including that mice to be tested will have to be produced from two different breeding and tests may not be carried out at the same time in parallel because of the logistic support issues. Despite of these challenges, these studies are worth to pursue because they may help to elucidate the contribution of haploinsufficiency of Gabrb3 and Atp10a in the pathogenesis of AS and further shed light on the pathogenesis of human AS caused by different molecular defects.

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Table 1. Comparison of phenotypes in Angelman syndrome mouse models with different mutations.

https://doi.org/10.1371/journal.pone.0012278.t001

Materials and Methods

Ethics statement

All protocols involving animals in this work were approved by the Institutional Animal Care and Use Committee of Baylor College of Medicine and Duke University.

Targeting constructs for Ube3a and Gabrb3 genes

Two sets of overlapping lambda phage clones containing the Ube3a and Gabrb3 genes were isolated from a mouse 129/SvEv and C57BL/6J genomic library respectively. To place the loxP site at the Ube3a locus, a replacement-type targeting vector of Ube3a-pL13 was used to replace exon 2 of Ube3a with a cassette containing a loxP site, a neomycin selectable marker, and a 5′-half of the Hprt exon 1 and 2 minigene. To place another loxP site at the Gabrb3 locus, another replacement-type targeting vector of Gabrb3-pG12 was constructed to replace part of exon 1 and exon 2 of Gabrb3 with a cassette containing a loxP site, a puromycin selectable marker, and a 3′-half of the Hprt exon 3 to 9 minigene. The partial genomic and restriction enzyme map for the deleted interval between Ube3a and Gabrb3, and cassettes are shown in Figure 1A.

Generation of mice with a chromosomal deletion from Ube3a to Gabrb3

To generate the ES cells with a deletion from Ube3a to Gabrb3, the targeting construct for Gabrb3-pG12 was linearized with PvuI restriction enzyme and electroporated into 1×107 AB2.2 ES cells from the 129/SvEv strain as previously described [23]. Puromycin resistant colonies were picked after 7–8 days of selection. DNA from ES cells was analyzed by mini-Southern blot hybridization using both 5′- and 3′-flanking probes for the Gabrb3-pG12 construct to identify clones undergoing homologous recombination. The Gabrb3 targeted cells were expanded and used subsequently for targeting of the Ube3a gene. The Ube3a-pL13 construct linearized with NotI restriction was electroporated into the Gabrb3 targeted ES cell clones with the same procedure described except that neomycin was used for selection. The Gabrb3 and Ube3a double targeted ES cells were identified and subjected to electroporation with a Cre recombinase (pOG231) plasmid. HAT (hypoxanthine and thymine) selection was applied to select ES cells undergoing recombination between loxP sites to join the two halves of the Hprt minigene that conferred the HAT resistance. Abundant HAT-resistant clones were obtained from 2 out of 4 independent double-targeted ES clones, and these were further subjected to sib selection using puromycin or neomycin to determine the possible configuration of cis or trans recombination mediated by Cre recombinase. A total of 16 HAT resistant clones were sensitive to both puromycin and neomycin, indicating that the targeting was in cis and Cre-mediated recombination between loxP sites occurred as described previously [36]. ES cells with Gabrb3 targeted, Gabrb3 and Ube3a double-targeted, and a deletion from Gabrb3 to Ube3a were in injected into C57 BL/6J blastocysts for germline transmission.

Mouse breeding, genotyping, and backcrossing

Mice carrying the deletion from Ube3a to Gabrb3 were backcrossed to C57BL/6J for more than 6 generations. Because of genomic imprinting in the region, a specific breeding scheme (Figure S4) was followed to produce mice for molecular studies and behavioral tests. Heterozygous males were bred to wild type C57BL/6J females to produce heterozygotes with a paternal deletion from Ube3a to Gabrb3 (m+/p−) and wild type littermates (m+/p+). Heterozygous females were bred to wild type C57BL/6J males to produce heterozygotes with a maternal deletion from Ube3a to Gabrb3 (m−/p+) and wild type littermates (m+/p+). Because of a possible role of maternal factors in production of ultrasonic vocalization (USV) in offspring, newborn pups used for the USV recording were produced by using male or female heterozygotes that had a deletion paternally but not maternally. Homozygotes with a deletion from Ube3a to Gabrb3 (m−/p−) were produced by crossing heterozygous mice with a deletion. All experimentation and animal husbandry involving animals in this report have been conducted according to relevant national and international guidelines and under the animal protocols approved by IACUC at Duke University and Baylor College of Medicine. Genotyping was routinely doing by PCR based method using the following primer pairS: UB-R:5′ ATT AGA GGT GAT GAG GGT ATT GAG; UB-F:5′ CAT TGC AAA TCA AAG GTG TGT GGA; pL13:5′ TAC TTC CAT TTG TCA CGT CCT GCA C. PCR condition is as following: denaturation at 94°C for 45 seconds, annealing at 52°C for 45 seconds, and extension at 62°C for 45 seconds, for 35 cycles, and followed by a 5 min extension period at 72°C

RNA isolation and RNA expression analysis

Total RNA was isolated using the Trizol method as previously described [23]. For RT-PCR analysis, DNase I-treated total RNA was reverse transcribed with Superscript RNase H reverse transcriptase (Invitrogen, Carlsbad CA) using random hexamers for Atp10a. PCR was carried out in 50 µl reactions with cycling conditions of denaturation at 94°C for 45 seconds, annealing at 62°C for 45 seconds, and extension at 62°C for 45 seconds, for 35 cycles. The final cycle was followed by a 5 min extension period at 72°C. Primers were ATP10AF: 5′- CTTGTCTTCAGCAGGGAAAAG-3′ and ATP10R: 5′- AATGAGTAAACTGGTGTGGGT-3′. For real-time quantitative RT-PCR using LightCycler Hydrolysis probes, the primers used were ATP10aRealT-F: 5′-ATGAAATCAACCACCTGGG-3′ and ATP10aRealT-R: 5′-TTCAGGTTGGTCTCT CCAT-3′. The probe used was 5′ FAM-CGACTTTGTCCGTCTTTGCTGCAATG-BHQ-1 3′. Primers and probe for mouse β-actin were provided by Roche (Roche applied science, Germany). Real-time quantitative PCR was carried out using a LightCycler 480 Instrument (Roche Diagnostics, Germany) and LightCycler 480 RNA Master Hydrolysis Probes following manufacturer's recommendations. Two µl of the total RNA sample was used in a 20 µl PCR reaction containing 1x LightCycler 480 RNA master mix with an appropriate concentration of primers and probe. All samples and experiments were run in triplicate. Each PCR run also included 3 samples without RNA template as negative controls as well as a consistent triplicate calibrator comprising a mixture of multiple mouse cerebellum RNA as template. Mouse β-actin RNA expression was used as an internal reference to normalize the quantity of RNA input across samples for quantification analysis.

Western blot analysis

Mouse brain tissues were homogenized in NP40/SDS buffer (1% Nonidet P-40, 0.01% SDS, 0.1 M Tris-HCl, pH 7.2, and complete Protease Inhibitor Cocktail Tablet; Roche Applied Sciences, Indianapolis, IN) on ice with a pellet pestle. Following polyacryl amide gel electrophoresis, proteins were transferred to nitrocellulose membrane (Bio-Rad; Hercules, CA) at 4°C overnight. Incubations with antibodies were performed in TPBS-milk at 4°C overnight as follows: rabbit anti-human E6-AP diluted 1∶1,000 (BL447; Bethyl Labs, Montgomery, TX); mouse Gabrb3 diluted 1∶500 (LC-43101, Santa Cruz Biotec, Santan Cruz CA); and anti-mouse actin diluted 1∶500 (SC-1606, Santa Cruz Biotec. Santa Cruz, CA). The signals were detected by enhanced chemiluminescence (ECL, Amersham Life Science, Newark, NJ). The Image J software was used for quantification.

Chronic electroencephalographic (EEG) recordings

Paternal and maternal deletion mice and wild-type littermates (aged 3–4 months) were implanted for chronic EEG monitoring. Mice were anesthetized with Avertin (1.25% tribromoethanol/amyl alcohol solution, i.p.) using a dose of 0.02 ml/g. Teflon-coated silver wire electrodes (0.005 inch diameter) attached to a microminiature connector were implanted bilaterally into the subdural space over temporal, parietal, and occipital cortices. Digital EEG activity was monitored daily for up to two weeks during prolonged overnight and random 2 hr sample recordings (Stellate Systems, Harmonie software version 6.1b; Montreal Quebec, Canada). A digital video camera was used to simultaneously monitor behavior during the EEG recording periods. All recordings were carried out at least 24 hours after surgery on mice freely moving in the test cage.

Mouse behavioral testing

A battery of behavioral test was performed using a protocol previously described and used in behavioral core facilities at Baylor College of Medicine [23], [67], [68]. These tests include open field, light dark, rotarod, prepluse inhibition (PPI), fear conditioning, Morris water maze, hot plate, and ultrasonic vocalization recording (USVs). Mice were tested in the order listed except USVs for which a different set of mice were used. Mice were rested for one week between each test except only 1–3 days between open field and light dark and two to three weeks between fear conditioning and Morris water maze. The procedure and sequence of the tests, except of USVs recording, were previously described and validated [67], [68], [69]. A different set of newborn pups was used for the USVs recording and these pups were not be used for other behavioral tests. The protocol for USVs recording was based on a previous report with minor modifications [45]. A detailed description of each protocol is included in the supplementary data, Method S1.

Statistical analysis

Raw data from all behavioral tests were documented and tabulated in Microsoft excel. Statistical analyses were performed using Origin 8 software (http://www.originlab.com/) and SAS (www.sas.com) packages. For most behavioral data, analyses were performed by using one-way ANOVA. Two-way and three-way ANOVA with repeated measure was used as indicated. Post hoc analysis was also performed as indicated.

Supporting Information

Figure S1.

Open field and hot plate test. A, B, C: Results of open filed test. Travel distance per block for m−/p+ (A) and m+/p− (B), as well as total travel distance (C) of m−/p+ and m+/p− mice in open field test. D. Results of hot plate test.

https://doi.org/10.1371/journal.pone.0012278.s001

(0.02 MB PDF)

Figure S2.

Results of Pre-pulse inhibition in mice. No difference in maximal startle response between m−/p+ mice and their m+/p+ littermates or between m+/p− mice and their m+/p+ littermates.

https://doi.org/10.1371/journal.pone.0012278.s002

(0.01 MB PDF)

Figure S3.

The production of USVs of maternal deletion pups in different days and beddings.

https://doi.org/10.1371/journal.pone.0012278.s003

(0.02 MB PDF)

Figure S4.

Breeding of Ube3a and Gabrb3 deletion mice. Only F1 and F2 are diagrammed in figure. Mice and pups used for the experiments were from >F6 of backcrossing to C57BL/6J.

https://doi.org/10.1371/journal.pone.0012278.s004

(0.02 MB PDF)

Method S1.

Protocols for behavioral testing.

https://doi.org/10.1371/journal.pone.0012278.s005

(0.04 MB DOC)

Acknowledgments

We thank Allan Bradley for providing the reagents for chromosomal engineering. We also thank Jennifer Glodstein for critical reading the manuscript. We thank Chung-qin Deng for helping statistical analysis.

Author Contributions

Conceived and designed the experiments: YhJ ALB. Performed the experiments: YhJ YP LZ LL JY IL MHB JLN. Analyzed the data: YhJ YP LZ CMS MHB JLN ALB. Wrote the paper: YhJ.

References

  1. 1. Jiang Y, Lev-Lehman E, Bressler J, Tsai TF, Beaudet AL (1999) Genetics of Angelman syndrome. Am J Hum Genet 65: 1–6.
  2. 2. Matsuura T, Sutcliffe JS, Fang P, Galjaard RJ, Jiang YH, et al. (1997) De novo truncating mutations in E6-AP ubiquitin-protein ligase gene (UBE3A) in Angelman syndrome. Nat Genet 15: 74–77.
  3. 3. Kishino T, Lalande M, Wagstaff J (1997) UBE3A/E6-AP mutations cause Angelman syndrome. Nat Genet 15: 70–73.
  4. 4. Veenstra-Vanderweele J, Christian SL, Cook EH Jr (2004) Autism as a paradigmatic complex genetic disorder. Annu Rev Genomics Hum Genet 5: 379–405.
  5. 5. Weiss LA, Shen Y, Korn JM, Arking DE, Miller DT, et al. (2008) Association between microdeletion and microduplication at 16p11.2 and autism. N Engl J Med 358: 667–675.
  6. 6. Chai JH, Locke DP, Greally JM, Knoll JH, Ohta T, et al. (2003) Identification of four highly conserved genes between breakpoint hotspots BP1 and BP2 of the Prader-Willi/Angelman syndromes deletion region that have undergone evolutionary transposition mediated by flanking duplicons. Am J Hum Genet 73: 898–925.
  7. 7. Jiang YH, Wauki K, Liu Q, Bressler J, Pan Y, et al. (2008) Genomic analysis of the chromosome 15q11-q13 Prader-Willi syndrome region and characterization of transcripts for GOLGA8E and WHCD1L1 from the proximal breakpoint region. BMC Genomics 9: 50.
  8. 8. Meguro M, Kashiwagi A, Mitsuya K, Nakao M, Kondo I, et al. (2001) A novel maternally expressed gene, ATP10C, encodes a putative aminophospholipid translocase associated with Angelman syndrome. Nat Genet 28: 19–20.
  9. 9. Herzing LB, Kim SJ, Cook EH Jr, Ledbetter DH (2001) The human aminophospholipid-transporting ATPase gene ATP10C maps adjacent to UBE3A and exhibits similar imprinted expression. Am J Hum Genet 68: 1501–1505.
  10. 10. Hogart A, Patzel KA, LaSalle JM (2008) Gender influences monoallelic expression of ATP10A in human brain. Hum Genet 124: 235–242.
  11. 11. Kashiwagi A, Meguro M, Hoshiya H, Haruta M, Ishino F, et al. (2003) Predominant maternal expression of the mouse Atp10c in hippocampus and olfactory bulb. J Hum Genet 48: 194–198.
  12. 12. Kayashima T, Yamasaki K, Joh K, Yamada T, Ohta T, et al. (2003) Atp10a, the mouse ortholog of the human imprinted ATP10A gene, escapes genomic imprinting. Genomics 81: 644–647.
  13. 13. Dubose AJ, Johnstone KA, Smith EY, Hallett RA, Resnick JL (2009) Atp10a, a gene adjacent to the PWS/AS gene cluster, is not imprinted in mouse and is insensitive to the PWS-IC. Neurogenetics.
  14. 14. Meguro M, Mitsuya K, Sui H, Shigenami K, Kugoh H, et al. (1997) Evidence for uniparental, paternal expression of the human GABAA receptor subunit genes, using microcell-mediated chromosome transfer. Hum Mol Genet 6: 2127–2133.
  15. 15. Nicholls RD, Gottlieb W, Russell LB, Davda M, Horsthemke B, et al. (1993) Evaluation of potential models for imprinted and nonimprinted components of human chromosome 15q11-q13 syndromes by fine-structure homology mapping in the mouse. Proc Natl Acad Sci U S A 90: 2050–2054.
  16. 16. Hogart A, Nagarajan RP, Patzel KA, Yasui DH, Lasalle JM (2007) 15q11-13 GABAA receptor genes are normally biallelically expressed in brain yet are subject to epigenetic dysregulation in autism-spectrum disorders. Hum Mol Genet 16: 691–703.
  17. 17. Liljelund P, Handforth A, Homanics GE, Olsen RW (2005) GABAA receptor beta3 subunit gene-deficient heterozygous mice show parent-of-origin and gender-related differences in beta3 subunit levels, EEG, and behavior. Brain Res Dev Brain Res 157: 150–161.
  18. 18. Clayton-Smith J, Laan L (2003) Angelman syndrome: a review of the clinical and genetic aspects. J Med Genet 40: 87–95.
  19. 19. Lossie AC, Whitney MM, Amidon D, Dong HJ, Chen P, et al. (2001) Distinct phenotypes distinguish the molecular classes of Angelman syndrome. J Med Genet 38: 834–845.
  20. 20. Minassian BA, DeLorey TM, Olsen RW, Philippart M, Bronstein Y, et al. (1998) Angelman syndrome: correlations between epilepsy phenotypes and genotypes. Ann Neurol 43: 485–493.
  21. 21. Paprocka J, Jamroz E, Szwed-Bialozyt B, Jezela-Stanek A, Kopyta I, et al. (2007) Angelman syndrome revisited. Neurologist 13: 305–312.
  22. 22. Galvan-Manso M, Campistol J, Conill J, Sanmarti FX (2005) Analysis of the characteristics of epilepsy in 37 patients with the molecular diagnosis of Angelman syndrome. Epileptic Disord 7: 19–25.
  23. 23. Jiang YH, Armstrong D, Albrecht U, Atkins CM, Noebels JL, et al. (1998) Mutation of the Angelman ubiquitin ligase in mice causes increased cytoplasmic p53 and deficits of contextual learning and long-term potentiation. Neuron 21: 799–811.
  24. 24. Dindot SV, Antalffy BA, Bhattacharjee MB, Beaudet AL (2008) The Angelman syndrome ubiquitin ligase localizes to the synapse and nucleus, and maternal deficiency results in abnormal dendritic spine morphology. Hum Mol Genet 17: 111–118.
  25. 25. Miura K, Kishino T, Li E, Webber H, Dikkes P, et al. (2002) Neurobehavioral and electroencephalographic abnormalities in Ube3a maternal-deficient mice. Neurobiol Dis 9: 149–159.
  26. 26. Ramirez-Solis R, Liu P, Bradley A (1995) Chromosome engineering in mice. Nature 378: 720–724.
  27. 27. Yu Y, Bradley A (2001) Engineering chromosomal rearrangements in mice. Nat Rev Genet 2: 780–790.
  28. 28. Tsai TF, Jiang YH, Bressler J, Armstrong D, Beaudet AL (1999) Paternal deletion from Snrpn to Ube3a in the mouse causes hypotonia, growth retardation and partial lethality and provides evidence for a gene contributing to Prader-Willi syndrome. Hum Mol Genet 8: 1357–1364.
  29. 29. Bradley A, van der Weyden L (2005) Mouse: Chromosome Engineering for Modeling Human Disease. Annu Rev Genomics Hum Genet.
  30. 30. Homanics GE, DeLorey TM, Firestone LL, Quinlan JJ, Handforth A, et al. (1997) Mice devoid of gamma-aminobutyrate type A receptor beta3 subunit have epilepsy, cleft palate, and hypersensitive behavior. Proc Natl Acad Sci U S A 94: 4143–4148.
  31. 31. Albrecht U, Sutcliffe JS, Cattanach BM, Beechey CV, Armstrong D, et al. (1997) Imprinted expression of the murine Angelman syndrome gene, Ube3a, in hippocampal and Purkinje neurons. Nat Genet 17: 75–78.
  32. 32. Stankiewicz P, Beaudet AL (2007) Use of array CGH in the evaluation of dysmorphology, malformations, developmental delay, and idiopathic mental retardation. Curr Opin Genet Dev 17: 182–192.
  33. 33. Lee JA, Lupski JR (2006) Genomic rearrangements and gene copy-number alterations as a cause of nervous system disorders. Neuron 52: 103–121.
  34. 34. Lupski JR (2007) Genomic rearrangements and sporadic disease. Nat Genet 39: S43–47.
  35. 35. Walz K, Paylor R, Yan J, Bi W, Lupski JR (2006) Rai1 duplication causes physical and behavioral phenotypes in a mouse model of dup(17)(p11.2p11.2). J Clin Invest 116: 3035–3041.
  36. 36. Zheng B, Sage M, Sheppeard EA, Jurecic V, Bradley A (2000) Engineering mouse chromosomes with Cre-loxP: range, efficiency, and somatic applications. Mol Cell Biol 20: 648–655.
  37. 37. Nishijima I, Mills A, Qi Y, Mills M, Bradley A (2003) Two new balancer chromosomes on mouse chromosome 4 to facilitate functional annotation of human chromosome 1p. Genesis 36: 142–148.
  38. 38. Walz K, Caratini-Rivera S, Bi W, Fonseca P, Mansouri DL, et al. (2003) Modeling del(17)(p11.2p11.2) and dup(17)(p11.2p11.2) contiguous gene syndromes by chromosome engineering in mice: phenotypic consequences of gene dosage imbalance. Mol Cell Biol 23: 3646–3655.
  39. 39. Kayashima T, Ohta T, Niikawa N, Kishino T (2003) On the conflicting reports of imprinting status of mouse ATP10a in the adult brain: strain-background-dependent imprinting? J Hum Genet 48: 492–493; author reply 494.
  40. 40. Dhar MS, Yuan JS, Elliott SB, Sommardahl C (2006) A type IV P-type ATPase affects insulin-mediated glucose uptake in adipose tissue and skeletal muscle in mice. J Nutr Biochem 17: 811–820.
  41. 41. Dhar MS, Sommardahl CS, Kirkland T, Nelson S, Donnell R, et al. (2004) Mice heterozygous for Atp10c, a putative amphipath, represent a novel model of obesity and type 2 diabetes. J Nutr 134: 799–805.
  42. 42. Hofer MA, Shair HN, Brunelli SA (2002) Ultrasonic vocalizations in rat and mouse pups. Curr Protoc Neurosci Chapter 8: Unit 8 14.
  43. 43. Scattoni ML, Crawley J, Ricceri L (2008) Ultrasonic vocalizations: A tool for behavioural phenotyping of mouse models of neurodevelopmental disorders. Neurosci Biobehav Rev.
  44. 44. Hahn ME, Lavooy MJ (2005) A review of the methods of studies on infant ultrasound production and maternal retrieval in small rodents. Behav Genet 35: 31–52.
  45. 45. Moles A, Kieffer BL, D'Amato FR (2004) Deficit in attachment behavior in mice lacking the mu-opioid receptor gene. Science 304: 1983–1986.
  46. 46. Hahn ME, Schanz N (2002) The effects of cold, rotation, and genotype on the production of ultrasonic calls in infant mice. Behav Genet 32: 267–273.
  47. 47. Branchi I, Santucci D, Alleva E (2001) Ultrasonic vocalisation emitted by infant rodents: a tool for assessment of neurobehavioural development. Behav Brain Res 125: 49–56.
  48. 48. Peters SU, Beaudet AL, Madduri N, Bacino CA (2004) Autism in Angelman syndrome: implications for autism research. Clin Genet 66: 530–536.
  49. 49. Veltman MW, Craig EE, Bolton PF (2005) Autism spectrum disorders in Prader-Willi and Angelman syndromes: a systematic review. Psychiatr Genet 15: 243–254.
  50. 50. Horsler K, Oliver C (2006) Environmental influences on the behavioral phenotype of Angelman syndrome. Am J Ment Retard 111: 311–321.
  51. 51. Oliver C, Horsler K, Berg K, Bellamy G, Dick K, et al. (2007) Genomic imprinting and the expression of affect in Angelman syndrome: what's in the smile? J Child Psychol Psychiatry 48: 571–579.
  52. 52. Oliver C, Demetriades L, Hall S (2002) Effects of environmental events on smiling and laughing behavior in Angelman syndrome. Am J Ment Retard 107: 194–200.
  53. 53. Moy SS, Nadler JJ, Magnuson TR, Crawley JN (2006) Mouse models of autism spectrum disorders: the challenge for behavioral genetics. Am J Med Genet C Semin Med Genet 142: 40–51.
  54. 54. Shu W, Cho JY, Jiang Y, Zhang M, Weisz D, et al. (2005) Altered ultrasonic vocalization in mice with a disruption in the Foxp2 gene. Proc Natl Acad Sci U S A 102: 9643–9648.
  55. 55. Jamain S, Radyushkin K, Hammerschmidt K, Granon S, Boretius S, et al. (2008) Reduced social interaction and ultrasonic communication in a mouse model of monogenic heritable autism. Proc Natl Acad Sci U S A.
  56. 56. Fujita E, Tanabe Y, Shiota A, Ueda M, Suwa K, et al. (2008) Ultrasonic vocalization impairment of Foxp2 (R552H) knockin mice related to speech-language disorder and abnormality of Purkinje cells. Proc Natl Acad Sci U S A 105: 3117–3122.
  57. 57. Groszer M, Keays DA, Deacon RM, de Bono JP, Prasad-Mulcare S, et al. (2008) Impaired synaptic plasticity and motor learning in mice with a point mutation implicated in human speech deficits. Curr Biol 18: 354–362.
  58. 58. Lai CS, Fisher SE, Hurst JA, Vargha-Khadem F, Monaco AP (2001) A forkhead-domain gene is mutated in a severe speech and language disorder. Nature 413: 519–523.
  59. 59. Jamain S, Quach H, Betancur C, Rastam M, Colineaux C, et al. (2003) Mutations of the X-linked genes encoding neuroligins NLGN3 and NLGN4 are associated with autism. Nat Genet 34: 27–29.
  60. 60. Picker JD, Yang R, Ricceri L, Berger-Sweeney J (2006) An altered neonatal behavioral phenotype in Mecp2 mutant mice. Neuroreport 17: 541–544.
  61. 61. Jedele KB (2007) The overlapping spectrum of rett and angelman syndromes: a clinical review. Semin Pediatr Neurol 14: 108–117.
  62. 62. Scattoni ML, Gandhy SU, Ricceri L, Crawley JN (2008) Unusual repertoire of vocalizations in the BTBR T+tf/J mouse model of autism. PLoS One 3: e3067.
  63. 63. Nakatani J, Tamada K, Hatanaka F, Ise S, Ohta H, et al. (2009) Abnormal behavior in a chromosome-engineered mouse model for human 15q11-13 duplication seen in autism. Cell 137: 1235–1246.
  64. 64. Young DM, Schenk AK, Yang SB, Jan YN and Jan LY Altered ultrasonic vocalizations in a tuberous sclerosis mouse model of autism. Proc Natl Acad Sci U S A 107: 11074–11079.
  65. 65. Crawley JN (2008) Behavioral phenotyping strategies for mutant mice. Neuron 57: 809–818.
  66. 66. Heck DH, Zhao Y, Roy S, LeDoux MS, Reiter LT (2008) Analysis of cerebellar function in Ube3a-deficient mice reveals novel genotype-specific behaviors. Hum Mol Genet 17: 2181–2189.
  67. 67. Paylor R, Spencer CM, Yuva-Paylor LA, Pieke-Dahl S (2006) The use of behavioral test batteries, II: effect of test interval. Physiol Behav 87: 95–102.
  68. 68. Bi W, Yan J, Shi X, Yuva-Paylor LA, Antalffy BA, et al. (2007) Rai1 deficiency in mice causes learning impairment and motor dysfunction, whereas Rai1 heterozygous mice display minimal behavioral phenotypes. Hum Mol Genet 16: 1802–1813.
  69. 69. Shahbazian M, Young J, Yuva-Paylor L, Spencer C, Antalffy B, et al. (2002) Mice with truncated MeCP2 recapitulate many Rett syndrome features and display hyperacetylation of histone H3. Neuron 35: 243–254.
  70. 70. van Woerden GM, Harris KD, Hojjati MR, Gustin RM, Qiu S, et al. (2007) Rescue of neurological deficits in a mouse model for Angelman syndrome by reduction of alphaCaMKII inhibitory phosphorylation. Nat Neurosci.