Pms2 is a genetic enhancer of trinucleotide CAG.CTG repeat somatic mosaicism: implications for the mechanism of triplet repeat expansion

The expansion of CAG.CTG repeat sequences is the cause of several inherited human disorders. Longer alleles are associated with an earlier age of onset and more severe symptoms, and are highly unstable in the germline and soma with a marked tendency towards repeat length gains. Germinal expansions underlie anticipation; whereas age-dependent, tissue-specific, expansion-biased somatic instability probably contributes toward the progressive nature and tissue-specificity of the symptoms. The mechanism(s) of repeat instability is not known, but recent data have implicated mismatch-repair (MMR) gene mutS homologues in driving expansion. To gain further insight into the expansion mechanism, we have determined the levels of somatic mosaicism of a transgenic expanded CAG.CTG repeat in mice deficient for the Pms2 MMR gene. Pms2 is a MutL homologue that plays a critical role in the downstream processing of DNA mismatches. The rate of somatic expansion was reduced by approximately 50% in Pms2-null mice. A higher frequency of rare, but very large, deletions was also detected in these animals. No significant differences were observed between Pms2(+/+) and Pms2(+/-) mice, indicating that a single functional Pms2 allele is sufficient to generate normal levels of somatic mosaicism. These findings reveal that as well as MMR enzymes that directly bind mismatched DNA, proteins that are subsequently recruited to the complex also play a central role in the accumulation of repeat length changes. These data suggest that somatic expansion results not by replication slippage, single stranded annealing or simple MutS-mediated stabilization of secondary structures, but by inappropriate DNA MMR.     

Regional differences of somatic CAG repeat instability do not account for selective neuronal vulnerability in a knock-in mouse model of SCA1

Expression of unstable translated CAG repeats is the mutational mechanism in nine different neurodegenerative disorders. Although the products of genes harboring these repeats are widely expressed, a subset of neurons is vulnerable in each disease accounting for the different phenotypes. Somatic instability of the expanded CAG repeat has been implicated as a factor mediating the selective striatal neurodegeneration in Huntington disease. It remains unknown, however, whether such a mechanism contributes to the selective neurodegeneration in other polyglutamine diseases or not. To address this question, we investigated the pattern of CAG repeat instability in a knock-in mouse model of spinocerebellar ataxia type 1 (SCA1). Small pool PCR analysis on DNA from various neuronal and non-neuronal tissues revealed that somatic repeat instability was most remarkable in the striatum. In the two vulnerable tissues, cerebellum and spinal cord, there were substantial differences in the profiles of mosaicism. These results suggest that in SCA1 there is no clear causal relationship between the degree of somatic instability and selective neuronal vulnerability. The finding that somatic instability is most pronounced in the striatum of various knock-in models of polyglutamine diseases highlights the role of trans-acting tissue- or cell-specific factors in mediating the instability.     

Complex patterns of male germline instability and somatic mosaicism in myotonic dystrophy type 1

The genetic basis of myotonic dystrophy type 1 (DM1) is the expansion of a CTG repeat in the 3' untranslated region of DM1PK. Once into the disease range, the repeat becomes highly unstable and is biased toward expansion in both somatic and germline tissues. Intergenerational differences usually reveal an increase in allele length, concordant with the clinical anticipation characteristic of DM1, but there have also been cases with intergenerational contractions of the repeat length, accompanied by apparent anticipation. In order to gain a better understanding of this intergenerational behaviour, we have obtained semen samples from six DM males and used single molecule analyses to compare the allele distributions present in their sperm and blood with those of their offspring. We have confirmed that the male germline mutational pathway is distinct from that of the soma, but the extent of variation is highly variable from one individual to another and not obviously correlated with progenitor allele length. Nonetheless, in all cases the alleles present in the father's sperm overlap with those observed in their offspring. These data also provide further indications that the interpretation of intergenerational transmissions by standard analyses is frequently compromised by the masking of germline differences by age-dependent somatic expansion in the parent.     

Gametic but not somatic instability of CAG repeat length in Huntington''s disease.

Instability of a CAG repeat in 4p16.3 has been found in Huntington's disease (HD) chromosomes. Unlike a similar repeat in the fragile X syndrome, the expanded HD repeat showed no evidence of somatic instability in a comparison of blood, lymphoblast, and brain DNA from the same persons. Four pairs of monozygotic HD twins displayed identical CAG repeat lengths suggesting that repeat size is determined in gametogenesis. In contrast with the fragile X syndrome and with HD somatic tissue, mosaicism was readily detected as a diffuse spread of repeat lengths in DNA from HD sperm samples. Typically, the modal repeat size was larger in the sperm DNA than in corresponding lymphoblast DNA, with the greatest degree of gametic mosaicism coinciding with the longest somatic CAG repeats. These data indicate that the developmental timing of repeat instability appears to differ between HD and fragile X syndrome, and that the fundamental mechanisms leading to repeat expansion may therefore be distinct.     

Prion-like acceleration of a synucleinopathy in a transgenic mouse model

Our aim in this study was to investigate experimentally the possible in vivo transmission of a synucleinopathy, using a transgenic mouse model (TgM83) expressing the human A53T mutated α-synuclein. Brain homogenates from old TgM83 mice showing motor clinical signs due to the synucleinopathy and containing insoluble and phosphorylated (pSer129) α-synuclein were intracerebrally inoculated in young TgM83 mice. This triggered an early onset of characteristic motor clinical signs, compared with uninoculated TgM83 mice or to mice inoculated with a brain homogenate from a young, healthy TgM83 mouse. This early disease was associated with insoluble α-synuclein phosphorylated on Ser129, as already identified in old and sick uninoculated TgM83 transgenic mice. Although the molecular mechanisms remain to be determined, acceleration of the pathology following inoculation of mice expressing human mutated α-synuclein with tissues from mice affected by the synucleinopathy, could be consistent with "prion-like" propagation of the disease.     

Immunotherapy of cerebrovascular amyloidosis in a transgenic mouse model

Cerebrovascular amyloidosis is caused by amyloid accumulation in walls of blood vessel walls leading to hemorrhagic stroke and cognitive impairment. Transforming growth factor-β1 (TGF-β1) expression levels correlate with the degree of cerebrovascular amyloid deposition in Alzheimer's disease (AD) and TGF-β1 immunoreactivity in such cases is increased along the cerebral blood vessels. Here we show that a nasally administered proteosome-based adjuvant activates macrophages and decreases vascular amyloid in TGF-β1 mice. Animals were nasally treated with a proteosome-based adjuvant on a weekly basis for 3 months beginning at age 13 months. Using magnetic resonance imaging (MRI) we found that while control animals showed a significant cerebrovascular pathology, proteosome-based adjuvant prevents further brain damage and prevents pathological changes in the blood-brain barrier. Using an object recognition test and Y-maze, we found significant improvement in cognition in the treated group. Our findings support the potential use of a macrophage immunomodulator as a novel approach to reduce cerebrovascular amyloid, prevent microhemorrhage, and improve cognition.     

嗜酸性粒细胞增多症转基因小鼠模型的病理学观察

目的 研究过表达IL-5的嗜酸性粒细胞增多症转基因小鼠模型的生物学特性和病理学变化.方法 记录转基因小鼠的繁育情况,通过计数小鼠外周血中嗜酸性粒细胞的变化规律;观察嗜酸性粒细胞增多对器官损害的病理变化特征.结果 小鼠已成功繁育,外周血中嗜酸性粒细胞占白细胞数的比例持续增长到48周龄时的49.9±3.5%,脏器组织内出现嗜酸性粒细胞浸润和组织细胞变性、坏死等病理改变,出现体表被毛缺失和直肠脱垂现象.结论 小鼠体内高水平的IL-5能显著影响外周血内嗜酸性粒细胞的数目和比值,造成了肺脏、肝脏和脾脏等脏器的严重损坏.表明该小鼠是研究嗜酸性粒细胞增多症良好的转基因小鼠模型.     

Length-dependent gametic CAG repeat instability in the Huntington's disease knock-in mouse

The CAG repeats in the human Huntington's disease (HD) gene exhibit striking length-dependent intergenerational instability, typically small size increases or decreases of one to a few CAGs, but little variation in somatic tissues. In a subset of male transmissions, larger size increases occur to produce extreme HD alleles that display somatic instability and cause juvenile onset of the disorder. Initial efforts to reproduce these features in a mouse model transgenic for HD exon 1 with 48 CAG repeats revealed only mild intergenerational instability ( approximately 2% of meioses). A similar pattern was obtained when this repeat was inserted into exon 1 of the mouse Hdh gene. However, lengthening the repeats in Hdh to 90 and 109 units produced a graded increase in the mutation frequency to >70%, with instability being more evident in female transmissions. No large jumps in CAG length were detected in either male or female transmissions. Instead, size changes were modest increases and decreases, with expansions typically emanating from males and contractions from females. Limited CAG variation in the somatic tissues gave way to marked mosaicism in liver and striatum for the longest repeats in older mice. These results indicate that gametogenesis is the primary source of inherited instability in the Hdh knock-in mouse, as it is in man, but that the underlying repeat length-dependent mechanism, which may or may not be related in the two species, operates at higher CAG numbers. Moreover, the large CAG repeat increases seen in a subset of male HD transmissions are not reproduced in the mouse, suggesting that these arise by a different fundamental mechanism than the small size fluctuations that are frequent during gametogenesis in both species.      

High frequency of tissue-specific mosaicism in Turner syndrome patients

Interphase fluorescent studies of X chromosome aneuploidy in cultured and uncultured blood lymphocytes and oral mucosa epithelial cells using X centromere-specific DNA probe in addition to standard karyotype analysis were performed in 50 females with a clinical suspicion of Turner syndrome. All the patients were previously screened for the presence of 'hidden' Y chromosome mosaicism, using the primers DYZ3 and DYZ. The use of fluorescence in situ hybridization (FISH) analysis of interphase nuclei of tissues from different germ layers (lymphocytes from mesoderm and buccal epithelial cells from ectoderm) improves the accuracy of detection of low-level mosaicism. FISH studies on interphase nuclei revealed that 29% of patients with a pure form of monosomy X detected by metaphase analysis are, in fact, mosaics. The level of cells with the normal chromosomal constitution in lymphocytes of these cases as a rule was low, ranging from 3 to 18%, with an average of 7%. Two false-positive cases and one false-negative case of X monosomy mosaicism determined by standard cytogenetic approach were detected using FISH analysis. The majority of patients (92%) with mosaic form of Turner syndrome have considerable tissue-specific differences in levels of X aneuploidy. Our data indicate that in cases when mosaic aneuploidy with low-level frequency is questionable (approximately 10% and lower), the results of standard metaphase analysis should be supplemented with additional FISH studies of interphase nuclei. Tissue-specific differences in contents of different cell lines in the same patients point to the necessity of studying more than one tissue from each patient.     

Impaired angiogenesis in a transgenic mouse model of cerebral amyloidosis

Abeta peptides are naturally occurring peptides, which are thought to play a key role in the pathophysiology of Alzheimer's disease (AD). In AD cases, levels of soluble and insoluble Abeta peptides increase in the brain as well as in the cerebrovasculature, a phenomenon that does not occur in extra-cranial vessels. There are frequently anomalies in the cerebrovasculature in AD, and despite increases in several pro-angiogenic factors in AD brain, evidence for increased vascularity is lacking; in fact there is evidence to the contrary. It has also been recently shown that Abeta peptides may have profound anti-angiogenic effects in vitro and in vivo. We therefore investigated whether there is evidence for altered angiogenesis in the vasculature in a transgenic mouse model of Abeta amyloidosis (Tg APPsw line 2576). In vitro, the formation of capillary-like structures on a reconstituted extracellular matrix by endothelial cells isolated from Tg APPsw is impaired. Ex vivo, the sprouting of new capillaries from arterial explants (over expressing Abeta) isolated from 9-month-old Tg APPsw is reduced compared to arterial explants isolated from control littermates. In addition, Tg APPsw mice show a reduction in vascular density in the cortex and hippocampus compared to control littermates. Altogether, our data suggest that the over expression of APPsw in the vasculature may oppose angiogenesis.     

Metformin therapy in a transgenic mouse model of Huntington's disease

Huntington's disease (HD) is a hereditary neurodegenerative disease that leads to striatal degeneration and a severe movement disorder. We used a transgenic mouse model of HD (the R6/2 line with approximately 150 glutamine repeats) to test a new therapy for this disease. We treated HD mice with metformin, a widely used anti-diabetes drug, in the drinking water (0, 2 or 5mg/ml) starting at 5 weeks of age. Metformin treatment significantly prolonged the survival time of male HD mice at the 2mg/ml dose (20.1% increase in lifespan) without affecting fasting blood glucose levels. This dose of metformin also decreased hind limb clasping time in 11-week-old mice. The higher dose did not prolong survival, and neither dose of metformin was effective in female HD mice. Collectively, our results suggest that metformin may be worth further investigation in additional HD models.     

Instability of integrated hepatitis B virus DNA with inverted repeat structure in a transgenic mouse

We established four cell lines, from the liver cells of a transgenic mouse, constructed with hepatitis B virus DNA that had an inverted repeat structure. The integrated DNA patterns of the four established cell lines were different from one another and from the original pattern. These data show that the instability of integrated hepatitis B virus DNA would also occur in somatic cells during replication, apart from meiosis, which was previously reported.     

Early cerebrovascular inflammation in a transgenic mouse model of Alzheimer's disease

Amyloid plaques associated with Alzheimer's disease (AD) induce inflammatory responses associated with activated microglia and reactive astrocytes, which exacerbate neurodegeneration through release of inflammatory cytokines, reactive oxygen species, and other factors. Inflammation contributes to neurodegeneration at later stages of AD, but it may also play a role in early disease pathogenesis. We found that before plaque deposition, amyloid precursor protein (APP)/presenilin 1 (PSEN1) transgenic mice (PSAPP mice), a well-characterized model of AD, exhibit evidence of cerebrovascular inflammation. Expression of the endothelial cell-specific antigen MECA-32 (mouse endothelial cell antigen-32) was upregulated in the cerebrovasculature of young PSAPP mice (3 months old) and was similar to that observed in mice with experimental autoimmune encephalomyelitis, a model of multiple sclerosis characterized by neuroinflammation. MECA-32 is normally expressed in central and peripheral vasculature throughout development, but expression in the cerebrovasculature is downregulated on establishment of the blood-brain barrier (BBB). However, CNS inflammation triggers re-expression of MECA-32 in compromised cerebrovasculature. Our study indicates that MECA-32 may be a robust marker of cerebrovascular inflammation and compromised BBB integrity, triggered by soluble amyloid-β early in disease pathogenesis.     

Imaging corneal pathology in a transgenic mouse model using nonlinear microscopy

A transgenic mouse model with a Clim [co-factor of LIM (a combination of first letters of Lin-11 (C. elegans), ISL1 (rat), and Mec-3 (C. elegans) gene names) domain proteins] gene partially blocked in the epithelial compartment of its tissues is used to establish the sensitivity of intrinsic reflectance nonlinear optical microscopy (NLOM) to stromal and cellular perturbations in the cornea. Our results indicate dysplasia in the squamous epithelium, irregular collagen arrays in the stroma, and a compromised posterior endothelium in the corneas of these mice. As suggested by biochemical data, the collagen alterations are likely due to collagen III synthesis and deposition during healing and remodeling of transgenic mice corneal stromas. All of the topographic features seen in NLOM images of normal and aberrant corneas are confirmed by coregistration with histological sections. In this work, we also use ratiometric redox fluorometry based on two-photon excited cellular fluorescence from reduced nicotinamide adenine dinucleotide (NAD)(P)H and oxidized flavin adenine dinucleotide (FAD) to study mitochondrial energy metabolism. Employing this method, we detect higher metabolic activity in the endothelial layer of cornea compared to an epithelial layer located further away from the metabolites. The combination of two-photon excited fluorescence (TPF) with second harmonic generation (SHG) signals allows imaging to aid in understanding the relationship between alternation of specific genes and structural changes in cells and extracellular matrix.     

Lung tumourigenesis in a conditional Cul4A transgenic mouse model

Cullin4A (Cul4A) is a scaffold protein that assembles cullin–RING ubiquitin ligase (E3) complexes and regulates many cellular events, including cell survival, development, growth and cell cycle control. Our previous study suggested that Cul4A is oncogenic in vitro, but its oncogenic role in vivo has not been studied. Here, we used a Cul4A transgenic mouse model to study the potential oncogenic role of Cul4A in lung tumour development. After Cul4A over‐expression was induced in the lungs for 32 weeks, atypical epithelial cells were observed. After 40 weeks, lung tumours were visible and were characterized as grade I or II adenocarcinomas. Immunohistochemistry (IHC) revealed decreased levels of Cul4A‐associated proteins p21^CIP1 and tumour suppressor p19^ARF in the lung tumours, suggesting that Cul4A regulated their expression in these tumours. Increased levels of p27^KIP1 and p16^INK4a were also detected in these tumours. Moreover, the protein level of DNA replication licensing factor CDT1 was decreased. Genomic instability in the lung tumours was further analysed by the results from pericentrin protein expression and array comparative genomic hybridization analysis. Furthermore, knocking down Cul4A expression in lung cancer H2170 cells increased their sensitivity to the chemotherapy drug cisplatin in vitro, suggesting that Cul4A over‐expression is associated with cisplatin resistance in the cancer cells. Our findings indicate that Cul4A is oncogenic in vivo, and this Cul4A mouse model is a tool in understanding the mechanisms of Cul4A in human cancers and for testing experimental therapies targeting Cul4A. Published by John Wiley & Sons, Ltd     

Beneficial effects of quetiapine in a transgenic mouse model of Alzheimer's disease

Previous studies have suggested that quetiapine, an atypical antipsychotic drug, may have beneficial effects on cognitive impairment, and be a neuroprotectant in treating neurodegenerative diseases. In the present study, we investigated the effects of quetiapine on memory impairment and pathological changes in an amyloid precursor protein (APP)/presenilin-1 (PS-1) double transgenic mouse model of Alzheimer's disease (AD). Non-transgenic and transgenic mice were treated with quetiapine (0, 2.5, or 5mg/(kg day)) for 1, 4, and 7 months in drinking water from the age of 2 months. After 4 and 7 months of continuous quetiapine administration, memory impairment was prevented, and the number of beta-amyloid (Abeta) plaques decreased in the cortex and hippocampus of the transgenic mice. Quetiapine also decreased brain Abeta peptides, beta-secretase activity and expression, and the level of C99 (an APP C-terminal fragment following cleavage by beta-secretase) in the transgenic mice. Furthermore, quetiapine attenuated anxiety-like behavior, up-regulated cerebral Bcl-2 protein, and decreased cerebral nitrotyrosine in the transgenic mice. These findings suggest that quetiapine can alleviate cognitive impairment and pathological changes in an APP/PS1 double transgenic mouse model of AD, and further indicate that quetiapine may have preventive effects in the treatment of AD.     

Nucleosomal occupancy and CGG repeat expansion: a comparative analysis of triplet repeat region from mouse and human fragile X mental retardation gene 1

The expansion of CGG repeats in the 5′-untranslated region (5′UTR) of FMR1 gene is the molecular basis of fragile X syndrome in most of the patients. The nature of the flanking sequences in addition to the length and interruption pattern of repeats is predicted to influence CGG repeat instability in the FMR1 gene. We investigated nucleosome occupancy as a contributor to CGG repeat instability in a transgenic mouse model containing unstable (CGG)_26, from human FMR1 cloned downstream of nucleosome-excluding sequence. We observe that the transgene has an open chromatin structure compared to the stable endogenous mouse Fmr1 within the same nucleus. CGG repeats in mouse Fmr1 are flanked by nucleosomes unlike the repeats in the transgene in all the tissues examined. Further in vitro chromatin reconstitution experiments show that DNA fragment without the SV40ori/EPR (nucleosome-excluding sequence) forms more stable chromatin than the one containing it, despite having the same number of CGG repeats. The correlation between nucleosomal organisation of the FMR1 gene and CGG repeat instability was supported by significantly lower frequency of repeat expansion in mice containing an identical transgene without the SV40ori/EPR. Our studies demonstrate that flanking DNA sequences can influence repeat instability through modulation of nucleosome occupancy in the region.