A genetic model for the Prader-Willi syndrome and its implication for angelman syndrome

Summary Sporadic cases of Prader-Willi syndrome (PWS) are associated with the physical absence of the paternal Prader-Willi chromosome region (PWCR) by deletion 15q11–13, by segmental maternal heterodisomy or by chromosome rearrangements resulting in homozygosity for maternal PWCR. In isolated/familial cases, it is proposed that the expression of PWS depends on the functional absence caused by mutated gene(s) within the paternal PWCR. The same mutation on a maternally derived chromosome 15 is not able to express PWS. An epigenetic mechanism associated with the paternal meiosis is essential. In the Angelman syndrome (AS), inverse mechanisms are postulated. There is convincing evidence for specific PWS and AS genes or alleles within PWCR. This is compatible with the observations of interstitial chromosome deletions of the critical region in normal individuals or in probands with phenotypes other than PWS or AS. The new ideas of the model stated here are: (1) the proposed epigenetic mechanism in PWCR is obviously common in humans, but is usually of no phenotypic relevance; (2) interactions with specific chromosomal or gene mutations are required for the clinical expression of PWS or AS; (3) each factor alone is not able to produce an abnormal phenotype.     

A candidate mouse model for Hartnup Disorder deficient in neutral amino acid transport

The mutant mouse strain HPH2 (hyperphenylalaninemia) was isolated after N-ethyl-N-nitrosourea (ENU) mutagenesis on the basis of delayed plasma clearance of an injected load of phenylalanine. Animals homozygous for the recessive hph2 mutation excrete elevated concentrations of many of the neutral amino acids in the urine, while plasma concentrations of these amino acids are normal. In contrast, mutant homozygotes excrete normal levels of glucose and phosphorus. These data suggest an amino acid transport defect in the mutant, confirmed in a small reduction in normalized values of ¹⁴C-labeled glutamine uptake by kidney cortex brush border membrane vesicles (BBMV). The hyperaminoaciduria pattern is very similar to that of Hartnup Disorder, a human amino acid transport defect. A subset of Hartnup Disorder cases also show niacin deficiency symptoms, which are thought to be multifactorially determined. Similarly, the HPH2 mouse exhibits a niacin-reversible syndrome that is modified by diet and by genetic background. Thus, HPH2 provides a candidate mouse model for the study of Hartnup Disorder, an amino acid transport deficiency and a multifactorial disease in the human. Received: 16 May 1996 / Accepted: 25 September 1996     

Altered serotonin, dopamine and norepinepherine levels in 15q duplication and angelman syndrome mouse models

Childhood neurodevelopmental disorders like Angelman syndrome and autism may be the result of underlying defects in neuronal plasticity and ongoing problems with synaptic signaling. Some of these defects may be due to abnormal monoamine levels in different regions of the brain. Ube3a, a gene that causes Angelman syndrome (AS) when maternally deleted and is associated with autism when maternally duplicated has recently been shown to regulate monoamine synthesis in the Drosophila brain. Therefore, we examined monoamine levels in striatum, ventral midbrain, frontal cerebral cortex, cerebellar cortex and hippocampus in Ube3a deficient and Ube3a duplication animals. We found that serotonin (5HT), a monoamine affected in autism, was elevated in the striatum and cortex of AS mice. Dopamine levels were almost uniformly elevated compared to control littermates in the striatum, midbrain and frontal cortex regardless of genotype in Ube3a deficient and Ube3a duplication animals. In the duplication 15q autism mouse model, paternal but not maternal duplication animals showed a decrease in 5HT levels when compared to their wild type littermates, in accordance with previously published data. However, maternal duplication animals show no significant changes in 5HT levels throughout the brain. These abnormal monoamine levels could be responsible for many of the behavioral abnormalities observed in both AS and autism, but further investigation is required to determine if any of these changes are purely dependent on Ube3a levels in the brain.     

A mouse model for mucopolysaccharidosis type III A (Sanfilippo syndrome)

Mucopolysaccharidosis type III A (MPS III A, Sanfilippo syndrome) is a rare, autosomal recessive, lysosomal storage disease characterized by accumulation of heparan sulfate secondary to defective function of the lysosomal enzyme heparan N- sulfatase (sulfamidase). Here we describe a spontaneous mouse mutant that replicates many of the features found in MPS III A in children. Brain sections revealed neurons with distended lysosomes filled with membranous and floccular materials with some having a classical zebra body morphology. Storage materials were also present in lysosomes of cells of many other tissues, and these often stained positively with periodic-acid Schiff reagent. Affected mice usually died at 7-10 months of age exhibiting a distended bladder and hepatosplenomegaly. Heparan sulfate isolated from urine and brain had nonreducing end glucosamine- N -sulfate residues that were digested with recombinant human sulfamidase. Enzyme assays of liver and brain extracts revealed a dramatic reduction in sulfamidase activity. Other lysosomal hydrolases that degrade heparan sulfate or other glycans and glycosaminoglycans were either normal, or were somewhat increased in specific activity. The MPS III A mouse provides an excellent model for evaluating pathogenic mechanisms of disease and for testing treatment strategies, including enzyme or cell replacement and gene therapy.     

Molecular mechanism of angelman syndrome in two large families involves an imprinting mutation.

Patients with Angelman syndrome (AS) and Prader-Willi syndrome with mutations in the imprinting process have biparental inheritance but uniparental DNA methylation and gene expression throughout band 15q11-q13. In several of these patients, microdeletions upstream of the SNRPN gene have been identified, defining an imprinting center (IC) that has been hypothesized to control the imprint switch process in the female and male germlines. We have now identified two large families (AS-O and AS-F) segregating an AS imprinting mutation, including one family originally described in the first genetic linkage of AS to 15q11-q13. This demonstrates that this original linkage is for the 15q11-q13 IC. Affected patients in the AS families have either a 5.5- or a 15-kb microdeletion, one of which narrowed the shortest region of deletion overlap to 1.15 kb in all eight cases. This small region defines a component of the IC involved in AS (ie., the paternal-to-maternal switch element). The presence of an inherited imprinting mutation in multiple unaffected members of these two families, who are at risk for transmitting the mutation to affected children or children of their daughters, raises important genetic counseling issues.     

D-半乳糖诱导建立的小鼠多囊卵巢综合征模型

目的研究D-半乳糖诱导ICR中年雌性小鼠多囊卵巢综合征(PCOS)动物模型的卵巢形态学、性激素以及胰岛素水平变化,并探讨D-半乳糖引致小鼠PCOS的意义。方法以D-半乳糖腹腔注射20周龄ICR雌性小鼠8周,观察卵巢形态的变化,检测血糖值及动情周期排卵情况,并采用ELISA法测定血清胰岛素、雌二醇(E2)、促卵泡生长激素(FSH)、睾酮(T)水平。结果 D-半乳糖处理组小鼠的卵巢重量显著高于对照组(P<0.05),有80%(10/12)的单侧或双侧卵巢呈现多囊性扩张,卵巢闭锁增多及颗粒细胞层数减少,并表现为紊乱的动情周期,提示无排卵;与对照组比较,D-半乳糖组小鼠血清T、E2和空腹血糖水平明显升高(P<0.001),FSH水平下降(P<0.0001),空腹血胰岛素水平显著高于对照组(P<0.01),胰岛素敏感指数显著低于对照组(P<0.05)。结论使用D-半乳糖诱导小鼠PCOS模型,无论在影响血清性激素还是卵巢局部形态学改变方面都与临床表现相似,并存在胰岛素抵抗现象,符合PCOS的典型特征,可作为动物模型用于科学研究。     

A model for the oxygen-paradox in mouse cardiac muscle

1. Mouse ventricle strips provide a good model system for studying cellular damage in mammalian cardiac muscle. 2. Anoxia rapidly causes destruction of the myofilament apparatus that is characteristic of calcium-triggered damage in muscle cells, and it is suggested that anoxia promotes release of calcium from the mitochondria. 3. Oxygen exacerbates this damage which is independent of extracellular calcium; it is suggested that it initiates myofilament damage by activation at an intracellular site, probably the sarcoplasmic reticulum.     

A gene-targeted mouse model for chorea-acanthocytosis

Chorea-acanthocytosis (CHAC) is a hereditary neurodegenerative disorder with autosomal recessive transmission, in which selective degeneration of striatum has been reported in brain pathology. Clinically, CHAC shows Huntington's disease-like neuropsychiatric symptoms and red blood cell acanthocytosis. Recently, we identified the gene, CHAC, encoding a novel protein, chorein, in which a deletion mutation was found in Japanese families with CHAC. In the present study, we have identified the mouse CHAC cDNA sequence and the exon-intron structures of the gene and produced a CHAC model mouse introducing no. 60-61 exon deletion corresponding to a human disease mutation by a gene-targeting technique. The mice began to show acanthocytosis and motor disturbance in old age. In behavioral observations, locomotor activity was significantly decreased and the contact time at social interaction test was decreased significantly in the model mice. In the brain pathology, many apoptotic cells were observed in the striatum of the mutant mice. In neurochemical determinations, the dopamine metabolite, homovanillic acid, concentration decreased significantly in the portion including the midbrain of the mutant mice. These findings are consistent with the human results reported elsewhere and indicate that the CHAC model mice showed a mild phenotype with late adult onset. The CHAC model mouse therefore provides a good model system to study the human disease.     

A mouse model for β-thalassemia

A mutation that produces an absolute deficiency of normal β-major globin polypeptides has been recovered from a DBA/2J male mouse. Most mice homozygous for the deficiency survived to adulthood and reproduced but were smaller at birth than their littermates and demonstrated a hypochromic, microcytic anemia with severe anisocytosis, poikilocytosis, and reticulocytosis and the presence of inclusion bodies in a high proportion of circulating erythrocytes. Mice heterozygous for the deficiency demonstrated a mild reticulocytosis but were not clinically anemic. Analysis of globin chain synthesis in vitro by ³H-leucine incorporation revealed that β-globin synthesis was nearly normal (95%) in heterozygotes and about 75% of normal in deficiency homozygotes. Molecular characterization of the mutation by restriction analysis revealed a deletion of about 3.3 kb of DNA, including regulatory sequences and all coding blocks for β-major globin. Based on genetic and hematological criteria, mice homozygous for the mutant allele, designated Hbb^th-1, represent the first animal model of β-thalassemia (Cooley's anemia), a severe genetic disease of humans.     

A mouse model for cerebral babesiosis

Clinical symptoms and pathology observed in the cattle infected with Babesia bovis are quite similar to those of human cerebral malaria. Mechanisms involved in the pathogenesis of cerebral babesiosis, however, are still poorly understood because of the lack of a suitable experimental animal model. In this report, Masayoshi Tsuji and his colleagues describe B. bovis infection in severe combined immunodeficiency (SCID) mice, whose circulating red blood cells (RBCs) have been substituted with bovine RBCs (Bo-RBC-SCID mice). The infected mice not only develop a substantial level of parasitemia, but also show nerve symptoms and pathology similar to those observed in infected cattle.     

A mouse model for nonalcoholic steatohepatitis

Background

Nonalcoholic steatohepatitis (NASH) is a hepatic manifestation of the growing metabolic syndrome epidemic that could progress to cirrhosis. Animal models adequately mimicking this condition in humans are scanty.

Aim

The objective of our study was to investigate whether high-fat diets (HFD) with adequate methionine and choline levels can induce pathophysiological features typical of human NASH in C57BL/6J mice.

Methods

Forty C57BL/6J mice, divided into control and high-fat (HF) groups, were fed low-fat diet and HFD, ad libitum respectively for 20 weeks. At the end of 20 weeks, animals were sacrificed and assays were performed for blood biomarkers typical of human NASH. Adipose tissue depots were collected and liver samples were processed for histological examination.

Results

High-fat feeding led to increased triglyceride accumulation in the liver (8.9 μmol/100 mg liver tissue vs. 2.6 μmol/100 mg for control) and induced histopathological features of human NASH including hepatic steatosis, ballooning inflammation and fibrosis. Expressions of proteins and chemokines predominant in NASH including collagens I, III and IV and platelet derived growth factor (PDGF) A and B were significantly higher in animals fed the HFD. Liver enzymes alanine transaminase, aspartate transaminase and alkaline phosphatase were significantly (P<.05) elevated in the HF group compared to controls. Mice on HFD also developed hyperglycemia, hyperinsulinemia, hypoadiponectinemia along with elevated tumor necrosis factor α, resistin, leptin, free fatty acids, transforming growth factor β and malondialdehyde levels that characterize NASH in humans.

Conclusion

Long-term HF feeding with adequate methionine and choline can induce many of the pathophysiological features typical of human NASH in C57BL/6J mice.     

Adeno-associated virus-mediated rescue of the cognitive defects in a mouse model for Angelman syndrome

Angelman syndrome (AS), a genetic disorder occurring in approximately one in every 15,000 births, is characterized by severe mental retardation, seizures, difficulty speaking and ataxia. The gene responsible for AS was discovered to be UBE3A and encodes for E6-AP, an ubiquitin ligase. A unique feature of this gene is that it undergoes maternal imprinting in a neuron-specific manner. In the majority of AS cases, there is a mutation or deletion in the maternally inherited UBE3A gene, although other cases are the result of uniparental disomy or mismethylation of the maternal gene. While most human disorders characterized by severe mental retardation involve abnormalities in brain structure, no gross anatomical changes are associated with AS. However, we have determined that abnormal calcium/calmodulin-dependent protein kinase II (CaMKII) regulation is seen in the maternal UBE3A deletion AS mouse model and is responsible for the major phenotypes. Specifically, there is an increased αCaMKII phosphorylation at the autophosphorylation sites Thr(286) and Thr(305/306), resulting in an overall decrease in CaMKII activity. CaMKII is not produced until after birth, indicating that the deficits associated with AS are not the result of developmental abnormalities. The present studies are focused on exploring the potential to rescue the learning and memory deficits in the adult AS mouse model through the use of an adeno-associated virus (AAV) vector to increase neuronal UBE3A expression. These studies show that increasing the levels of E6-AP in the brain using an exogenous vector can improve the cognitive deficits associated with AS. Specifically, the associative learning deficit was ameliorated in the treated AS mice compared to the control AS mice, indicating that therapeutic intervention may be possible in older AS patients.     

A class III myosin expressed in the retina is a potential candidate for Bardet-Biedl syndrome

Class III myosins are actin-based motors with amino-terminal kinase domains. Expression of these motors is highly enhanced in retinal photoreceptors. As mutations in the gene encoding NINAC, a Drosophila melanogaster class III myosin, cause retinal degeneration, human homologs of this gene are potential candidates for human retinal disease. We have recently reported the cloning of MYO3A, a human myosin III expressed predominantly in the retina and retinal pigmented epithelium [1]. The map locus of MYO3A is close to, but does not overlap, that of human Usher's 1F [2]. Here we introduce a shorter class III myosin isoform, MYO3B, which is expressed in the retina, kidney, and testis. We describe the cDNA sequence, genomic organization, and splice variants of MYO3B expressed in the human retina. A product of 36 exons, MYO3B has several splice variants containing either one or two calmodulin binding (IQ) motifs in the neck domain and one of three predominant tail variations: a short tail ending just past the second IQ motif, or two alternatively spliced longer tails. MYO3B maps to 2q31.1-q31.2, a region that overlaps the locus for a Bardet-Biedl syndrome (BBS5) linked to markers at 2q31 [3].     

A new model for Hendra virus encephalitis in the mouse

Hendra virus (HeV) infection in humans is characterized by an influenza like illness, which may progress to pneumonia or encephalitis and lead to death. The pathogenesis of HeV infection is poorly understood, and the lack of a mouse model has limited the opportunities for pathogenetic research. In this project we reassessed the role of mice as an animal model for HeV infection and found that mice are susceptible to HeV infection after intranasal exposure, with aged mice reliably developing encephalitic disease. We propose an anterograde route of neuroinvasion to the brain, possibly along olfactory nerves. This is supported by evidence for the development of encephalitis in the absence of viremia and the sequential distribution of viral antigen along pathways of olfaction in the brain of intranasally challenged animals. In our studies mice developed transient lower respiratory tract infection without progressing to viremia and systemic vasculitis that is common to other animal models. These studies report a new animal model of HeV encephalitis that will allow more detailed studies of the neuropathogenesis of HeV infection, particularly the mode of viral spread and possible sequestration within the central nervous system; investigation of mechanisms that moderate the development of viremia and systemic disease; and inform the development of improved treatment options for human patients.     

Lung-restricted macrophage activation in the pearl mouse model of Hermansky-Pudlak syndrome

Pulmonary inflammation, abnormalities in alveolar type II cell and macrophage morphology, and pulmonary fibrosis are features of Hermansky-Pudlak Syndrome (HPS). We used the naturally occurring "pearl" HPS2 mouse model to investigate the mechanisms of lung inflammation observed in HPS. Although baseline bronchoalveolar lavage (BAL) cell counts and differentials were similar in pearl and strain-matched wild-type (WT) mice, elevated levels of proinflammatory (MIP1gamma) and counterregulatory (IL-12p40, soluble TNFr1/2) factors, but not TNF-alpha, were detected in BAL from pearl mice. After intranasal LPS challenge, BAL levels of TNF-alpha, MIP1alpha, KC, and MCP-1 were 2- to 3-fold greater in pearl than WT mice. At baseline, cultured pearl alveolar macrophages (AMs) had markedly increased production of inflammatory cytokines. Furthermore, pearl AMs had exaggerated TNF-alpha responses to TLR4, TLR2, and TLR3 ligands, as well as increased IFN-gamma/LPS-induced NO production. After 24 h in culture, pearl AM LPS responses reverted to WT levels, and pearl AMs were appropriately refractory to continuous LPS exposure. In contrast, cultured pearl peritoneal macrophages and peripheral blood monocytes did not produce TNF-alpha at baseline and had LPS responses which were no different from WT controls. Exposure of WT AMs to heat- and protease-labile components of pearl BAL, but not WT BAL, resulted in robust TNF-alpha secretion. Similar abnormalities were identified in AMs and BAL from another HPS model, pale ear HPS1 mice. We conclude that the lungs of HPS mice exhibit hyperresponsiveness to LPS and constitutive and organ-specific macrophage activation.