Genetic background modifies nuclear mutant huntingtin accumulation and HD CAG repeat instability in Huntington's disease knock-in mice

Genetically precise models of Huntington's disease (HD), Hdh CAG knock-in mice, are powerful systems in which phenotypes associated with expanded HD CAG repeats are studied. To dissect the genetic pathways that underlie such phenotypes, we have generated Hdh(Q111) knock-in mouse lines that are congenic for C57BL/6, FVB/N and 129Sv inbred genetic backgrounds and investigated four Hdh(Q111) phenotypes in these three genetic backgrounds: the intergenerational instability of the HD CAG repeat and the striatal-specific somatic HD CAG repeat expansion, nuclear mutant huntingtin accumulation and intranuclear inclusion formation. Our results reveal increased intergenerational and somatic instability of the HD CAG repeat in C57BL/6 and FVB/N backgrounds compared with the 129Sv background. The accumulation of nuclear mutant huntingtin and the formation of intranuclear inclusions were fastest in the C57BL/6 background, slowest in the 129Sv background and intermediate in the FVB/N background. Inbred strain-specific differences were independent of constitutive HD CAG repeat size and did not correlate with Hdh mRNA levels. These data provide evidence for genetic modifiers of both intergenerational HD CAG repeat instability and striatal-specific phenotypes. Different relative contributions of C57BL/6 and 129Sv genetic backgrounds to the onset of nuclear mutant huntingtin and somatic HD CAG repeat expansion predict that the initiation of each of these two phenotypes is modified by different genes. Our findings set the stage for defining disease-related genetic pathways that will ultimately provide insight into disease mechanism.     

Reduced brain volumes in mice expressing APP-Austrian mutation but not in mice expressing APP-Swedish-Austrian mutations

We previously described two transgenic mouse lines expressing sub-endogenous levels of the 'Austrian' APP-T714I mutation (driven by the prenatally active PDGF-beta promoter; APP-Au mice) and showing intraneuronal Abeta pathology and reduced brain volumes on MRI at 12 and 20 months of age. To further investigate whether reduced brain sizes were caused by neurodegeneration or a neurodevelopmental defect, we now measured brain volumes as early as postnatal day 10. At this age, a distinguishable reduction in brain volumes was absent, indicating that brain volume deficits in APP-Au mice are not caused by a neurodevelopmental defect. To further study the association between intraneuronal Abeta and reduced brain volumes, we further generated and analyzed an APP transgenic mouse model expressing both Austrian and Swedish (K670N/M671L) mutations (APP-SwAu mice). APP-Swedish mutation is known to lead to altered APP processing in the secretory pathway, precluding its later processing in endosomal-lysosomal compartments, the site of intraneuronal Abeta accumulation. Also, to have higher levels of transgene expression only after birth, a murine Thy-1 promoter was utilized for APP-SwAu mouse lines. Despite having five times higher transgene APP levels compared to APP-Au mice, APP-SwAu mice showed significantly lower intraneuronal Abeta levels in the absence of reduced brain volumes, suggesting that intraneuronal Abeta accumulation is related to reduced brain volumes in APP-Au mice. These data also provide a first in vivo indication of altered processing of APP-Swedish at sub-endogenous levels, an effect not observed in mouse models expressing the APP-Swedish mutation in high amounts.     

Characterization of neuron-specific huntingtin aggregates in human huntingtin knock-in mice

Huntington's disease (HD) is caused by a mutation causing expanded polyglutamine tracts in the N-terminal fragment of huntingtin. A pathological hallmark of HD is the formation of aggregates in the striatal neurons. Here we report that ageing human huntingtin knock-in mice expressing mutant human huntingtin contained neuronal huntingtin aggregates, as revealed by immunohistochemical analysis. In heterozygous knock-in mice with 77 CAG repeats, aggregates of N-terminal fragments of huntingtin were specifically formed in nuclei and neuropils in the striatal projection neurons, and in neuropils in their projection regions. This aggregate formation progressed depending on age, became interacted with proteolytic or chaperone proteins, and occurred most prominently in the nucleus accumbens. These mutant mice demonstrated abnormal aggressive behavior. In homozygous knock-in mice, heavy deposits of intranuclear and neuropil aggregates were detected, which extended to other regions; and characteristic large perikaryal aggregates were also found in the affected neurons. However, cell death was not observed among the striatal and affected neurons of these mutant mice. Our results indicate that the polyglutamine aggregates do not necessarily correlate with neuronal death. These human huntingtin knock-in mice should be useful to provide an effective therapeutic approach against HD.     

Premature death and neurologic abnormalities in transgenic mice expressing a mutant huntingtin exon-2 fragment

Huntington's disease (HD) is a fatal neurodegenerative disease characterized pathologically by aggregates composed of N-terminal fragments of the mutant form of the protein huntingtin (htt). The role of these N-terminal fragments in disease pathogenesis has been questioned based in part on studies in transgenic mice. In one important example, mice that express an N-terminal fragment of mutant htt terminating at the C-terminus of exon 2 (termed the Shortstop mouse) were reported to develop robust inclusion pathology without developing phenotypic abnormalities seen in the R6/2 or N171-82Q models of HD, which are also based on expression of mutant N-terminal htt fragments. To further explore the capacity of mutant exon-2 htt fragments to produce neurologic abnormalities (N-terminal 118 amino acids; N118), we generated transgenic mice expressing cDNA that encodes htt N118-82Q with the mouse prion promoter vector. In mice generated in this manner, we demonstrate robust inclusion pathology accompanied by early death and failure to gain weight. These phenotypes are the most robust abnormalities identified in the R6/2 and N171-82Q models. We conclude that the lack of an overt phenotype in the initial Shortstop mice cannot be completely explained by the properties of mutant htt N118 fragments.     

Transforming growth factor-beta 1 knockout mice. A mutation in one cytokine gene causes a dramatic inflammatory disease.

A monoclonal antibody (Ki-S1) has been raised that reacts with the nuclei of proliferating cells. The antigen recognized is resistant to formalin fixation and can be detected in frozen tissues as well as in routinely processed specimens. In immunohistochemistry, nuclear staining can be seen in those tissues and cellular compartments known to be actively proliferating. Peripheral blood lymphocytes are negative but show a strong increase in antigen expression after mitogen stimulation. Flow cytometric determination of DNA content and antigen expression revealed negativity of G0 cells and positivity of G1 to G2/M cells. A cytoplasmic co-reactivity, not associated with proliferation, was confined to Langerhans islands of the pancreas. The nuclear localized antigen has a molecular mass of 160 kd and therefore seems to be different from all other known immunohistochemical markers of proliferating cells. We conclude that the monoclonal antibody Ki-S1 might provide a useful tool for studying cell proliferation in situ under normal and pathological circumstances.     

Foot-and-mouth disease virus (FMDV) causes an acute disease that can be lethal for adult laboratory mice

Foot-and-mouth disease virus (FMDV) is a picornavirus that causes an acute vesicular disease of cloven-hoofed animals. This virus continues to be threat to livestock worldwide with outbreaks causing severe economic losses. However, very little is known about FMDV pathogenesis, partially due to the inconveniences of working with cattle and swine, the main natural hosts of the virus. Here we demonstrate that C57BL/6 and BALB/C adult mice are highly susceptible to FMDV infection when the virus is administered subcutaneously or intraperitoneally. The first clinical signs are ruffled fur, apathy, humped posture, and wasting, which are followed by neurological signs such as hind-limb paralysis. Within 2-3 days of disease onset, the animals die. Virus is found in all major organs, indicating a systemic infection. Mice developed microvesicles near the basal layer of the epithelium, event that precedes the vesiculation characteristics of FMD. In addition, a lymphoid depletion in spleen and thymus and severe lymphopenia is observed in the infected mice. When these mice were immunized with conventional inactivated FMDV vaccine, they were protected (100% of vaccinated animals) against challenge with a lethal dose of FMDV. The data indicate that this mouse model may facilitate the study of FMDV pathogenesis, and the development of new effective vaccines for FMD.     

Cholesterol biosynthesis pathway is disturbed in YAC128 mice and is modulated by huntingtin mutation

Our recent analyses of the cholesterol biosynthetic pathway in Huntington's disease (HD) cells, in the R6/2 huntingtin-fragment mouse model of HD as well as in human tissues have provided the first evidence of altered activity of this pathway in genetically identifiable HD samples. Here we report that these changes also occur in the full-length-huntingtin YAC128 (yeast artificial chromosome) mouse model, which shows a consistent reduction in the activity or levels of multiple components of the cholesterogenic pathway. We also show that this phenotype is progressive and is specific for the brain region most affected in HD. Mice over-expressing the wild-type protein with 18 CAG (YAC18 mice) show the opposite phenotype with higher activity of the cholesterol biosynthetic pathway compared with littermate mice. Finally, we report that plasma levels of cholesterol, its precursors and its brain-derived catabolite 24-S-hydroxycholesterol in YAC mice mirror brain biosynthetic levels supporting further investigation of their potential as peripheral biomarkers in HD.     

Electroconvulsive shock ameliorates disease processes and extends survival in huntingtin mutant mice

Huntington's disease (HD) is an inherited neurodegenerative disorder caused by expanded polyglutamine repeats in the huntingtin (Htt) protein. Mutant Htt may damage and kill striatal neurons by a mechanism involving reduced production of brain-derived neurotrophic factor (BDNF) and increased oxidative and metabolic stress. Because electroconvulsive shock (ECS) can stimulate the production of BDNF and protect neurons against stress, we determined whether ECS treatment would modify the disease process and provide a therapeutic benefit in a mouse model of HD. ECS (50 mA for 0.2 s) or sham treatment was administered once weekly to male N171-82Q Htt mutant mice beginning at 2 months of age. Endpoints measured included motor function, striatal and cortical pathology, and levels of protein chaperones and BDNF. ECS treatment delayed the onset of motor symptoms and body weight loss and extended the survival of HD mice. Striatal neurodegeneration was attenuated and levels of protein chaperones (Hsp70 and Hsp40) and BDNF were elevated in striatal neurons of ECS-treated compared with sham-treated HD mice. Our findings demonstrate that ECS can increase the resistance of neurons to mutant Htt resulting in improved functional outcome and extended survival. The potential of ECS as an intervention in subjects that inherit the mutant Htt gene merits further consideration.     

Plasmid expressing the influenza HA gene protects old mice from lethal challenge with influenza virus.

Virus-based influenza vaccines induce less protection in old compared to young subjects due, in part, to age-associated alterations in the immune response. This study shows that old mice produce a less diverse HI antibody response after immunization than adult mice. However, immunization of old and young mice with plasmids expressing the HA gene induced comparable clearance of influenza virus from the lungs and the same level of protection from a lethal challenge with live WSN influenza virus. Thus, genetic immunization may offer advantages for the elderly over virus-base vaccines.     

Homozygous loss-of-function mutation in ALMS1 causes the lethal disorder mitogenic cardiomyopathy in two siblings

BackgroundTwo siblings from consanguineous parents of Turkish descent presented with isolated dilated cardiomyopathy, leading to early death in infancy. The diagnosis of mitogenic cardiomyopathy was made histologically.Methods and resultsLinkage analysis combined with exome sequencing identified a homozygous deleterious mutation in the ALMS1 gene as the cause of this phenotype.ConclusionsAlström syndrome is characterized by a typically transient dilating cardiomyopathy in infancy, suggesting that mitogenic cardiomyopathy represents the extreme phenotype, resulting in demise before the other clinical symptoms become evident. This observation further illustrates the role of ALMS1 and cell cycle regulation.     

HD CAG repeat implicates a dominant property of huntingtin in mitochondrial energy metabolism

The 'expanded' HD CAG repeat that causes Huntington's disease (HD) encodes a polyglutamine tract in huntingtin, which first targets the death of medium-sized spiny striatal neurons. Mitochondrial energetics, related to N-methyl-d-aspartate (NMDA) Ca2+-signaling, has long been implicated in this neuronal specificity, implying an integral role for huntingtin in mitochondrial energy metabolism. As a genetic test of this hypothesis, we have looked for a relationship between the length of the HD CAG repeat, expressed in endogenous huntingtin, and mitochondrial ATP production. In STHdhQ111 knock-in striatal cells, a juvenile onset HD CAG repeat was associated with low mitochondrial ATP and decreased mitochondrial ADP-uptake. This metabolic inhibition was associated with enhanced Ca2+-influx through NMDA receptors, which when blocked resulted in increased cellular [ATP/ADP]. We then evaluated [ATP/ADP] in 40 human lymphoblastoid cell lines, bearing non-HD CAG lengths (9-34 units) or HD-causing alleles (35-70 units). This analysis revealed an inverse association with the longer of the two allelic HD CAG repeats in both the non-HD and HD ranges. Thus, the polyglutamine tract in huntingtin appears to regulate mitochondrial ADP-phosphorylation in a Ca2+-dependent process that fulfills the genetic criteria for the HD trigger of pathogenesis, and it thereby determines a fundamental biological parameter--cellular energy status, which may contribute to the exquisite vulnerability of striatal neurons in HD. Moreover, the evidence that this polymorphism can determine energy status in the non-HD range suggests that it should be tested as a potential physiological modifier in both health and disease.     

Fgfr3基因374点突变致软骨发育不全小鼠模型的建立与分析

目的建立模拟人成纤维细胞生长因子3型受体(fibroblastgrowthfactorreceptor3,Fgfr3)374号甘氨酸至精氨酸点突变小鼠模型并进行初步表型分析。方法应用双重PCR法及分子克隆技术构建小鼠Fgfr3-Gly374Arg点突变打靶载体,对胚胎干细胞(embryonicstemcells,ES细胞)进行打靶后,采用G418、Ganciclovir正负双向选择和Southern杂交对打靶ES细胞进行筛选,选发生正确同源重组的ES细胞进行胚泡显微注射,携带Neo基因的Fgfr3-Gly374Arg点突变鼠与EIIa-Cre转基因鼠杂交后,得到只含Fgfr3-Gly374Arg点突变鼠。用PCR法进行了基因型鉴定,并应用骨骼染色、组织学等技术对其表型进行了初步分析。结果Fgfr3-Gly374Arg点突变小鼠体小尾短、头大,前额圆凸,骨骺生长板区明显缩短、结构紊乱,肥大软骨细胞区也有明显减少。同时伴有多数雌性小鼠不孕、子宫、卵巢变小、乳腺发育不良等变化。结论成功地建立了模拟人Fgfr3-Gly374Arg点突变所致软骨发育不全的小鼠模型。     

A novel FAM20C mutation causes a rare form of neonatal lethal Raine syndrome

Raine syndrome is a rare, autosomal recessive, osteosclerotic bone dysplasia due to pathogenic variants in FAM20C. The clinical phenotype is characterized by generalized osteosclerosis affecting all bones, cerebral calcifications, and craniofacial dysmorphism. Most cases present during the neonatal period with early lethality due to pulmonary hypoplasia and respiratory compromise while only few affected individuals have been reported to survive into adulthood. FAM20C is a ubiquitously expressed protein kinase that contains five functional domains including a catalytic domain, a binding pocket for FAM20A and three distinct N‐glycosylation sites. We report a newborn infant with a history of prenatal onset fractures, generalized osteosclerosis, and craniofacial dysmorphism and early lethality. The clinical presentation was highly suggestive of Raine syndrome. A homozygous, novel missense variant in exon 5 of FAM20C (c.1007T>G; p.Met336Arg) was identified by targeted Sanger sequencing. Following in silico analysis and mapping of the variant on a three‐dimensional (3D) model of FAM20C it is predicted to be deleterious and to affect N‐glycosylation, protein folding, and subsequent secretion of FAM20C. In addition, we reviewed all published FAM20C mutations and observed that most pathogenic variants affect functional regions within the protein establishing evidence for an emerging genotype–phenotype correlation.     

H714Q mutation in Wilson disease is associated with late, neurological presentation.

Wilson disease is an autosomal recessive copper storage disease resulting from an inability of the liver to excrete copper. Patients can present at a young age, generally with symptoms of liver copper intoxication, or later on, generally with neurological symptoms. The gene for Wilson disease has recently been cloned. Five mutations have been described so far, but only one is found frequently, H714Q. We analysed 38 Dutch symptomatic Wilson disease patients for the H714Q mutation and correlated this finding with age and symptoms at presentation. Ten patients homozygous for the H714Q mutation presented at a mean age of 20.3 (SD 6.1) years, with either neurological symptoms or a Kayser-Fleischer ring. Six patients with a H714Q mutation in one chromosome and an unknown mutation in the other chromosome presented at a mean age of 17.8 (SD 5.8) years, with either neurological or hepatic symptoms. With the exception of one, all 22 patients with an uncharacterised mutation in both chromosomes presented with liver involvement, at a mean age of 9.9 (SD 2.4) years. The difference in age at presentation between the H714Q/H714Q group and the patients with an unknown mutation was highly significant (p < 0.0001). This suggests that the H714Q mutation represents a relatively mild mutation, possibly with some residual function in the copper transporting protein, resulting in a slower build up of copper.