Dual Benefit of Reduced Cx43 on Atherosclerosis in LDL Receptor-Deficient Mice

Paracrine cell-to-cell interactions are crucial events during atherogenesis, however, little is known on the role of gap junctional communication during this process. We recently demonstrated increased expression of Cx43 in intimal smooth muscle cells and in a subset of endothelial cells covering the shoulder of atherosclerotic plaques. The purpose of this study was to examine the role of Cx43 in the development of atherosclerosis in vivo. Atherosclerosis-susceptible LDL receptor-deficient (LDLR^?/?) mice were intercrossed with mice heterozygous for Cx43 (Cx43^+/?mice). Male mice with normal (Cx43^+/+LDLR^?/?) or reduced (Cx43^+/?LDLR^?/?) Cx43 level of 10 weeks old were fed a cholesterol-rich diet (1.25%) for 14 weeks. Both groups of mice showed similar increases in serum lipids and body weight. Interestingly, the progression of atherosclerosis was reduced by 50% (P < 0.01) in the thoraco-abdominal aorta and in the aortic roots of Cx43^+/?LDLR^?/?mice compared with Cx43^+/+LDLR^?/?littermate controls. In addition, atheroma in Cx43^+/?LDLR^?/?mice contained fewer inflammatory cells and exhibited thicker fibrous caps with more collagen and smooth muscle cells, important features associated, in human, with stable atherosclerotic lesions. Thus, reducing Cx43 expression in mice provides beneficial effects on both the progression and composition of the atherosclerotic lesions.     

Decreased Npc1 Gene Dosage in Mice Is Associated With Weight Gain

A recent genome‐wide association study has determined that the Niemann‐Pick C1 (NPC1) gene is associated with early‐onset and morbid adult obesity. However, what effects of the nonsynonymous variation in NPC1 on protein function result in weight gain remains unknown. The NPC1 heterozygous mouse model (Npc1^+/?), which expresses one‐half the normal amounts of functional Npc1 protein compared to the homozygous normal (Npc1^+/+) mouse, was used to determine whether decreased Npc1 gene dosage was associated with weight gain when fed either a low‐fat (10% kcal fat) or high‐fat (45% kcal fat) diet beginning at 4 weeks of age until 20 weeks of age. The results indicated that Npc1^+/? mice had significantly increased weight gain beginning at 13 weeks of age when fed a high‐fat diet, but not when fed a low‐fat diet, compared to the Npc1^+/+ mice fed the same diet. With respect to mice fed a high‐fat diet, the Npc1^+/? mice continued to have significantly increased weight gain to 30 weeks of age. At this age, the Npc1^+/? mice were found to have increased liver and inguinal adipose weights compared to the Npc1^+/+ mice. Therefore, decreased Npc1 gene dosage resulting in decreased Npc1 protein function, promoted weight gain in mice fed a high‐fat diet consistent with a gene–diet interaction.     

Progranulin haploinsufficiency causes biphasic social dominance abnormalities in the tube test

Loss‐of‐function mutations in progranulin (GRN) are a major autosomal dominant cause of frontotemporal dementia (FTD), a neurodegenerative disorder in which social behavior is disrupted. Progranulin‐insufficient mice, both Grn^+/? and Grn ^?/? , are used as models of FTD due to GRN mutations, with Grn^+/? mice mimicking the progranulin haploinsufficiency of FTD patients with GRN mutations. Grn^+/? mice have increased social dominance in the tube test at 6 months of age, although this phenotype has not been reported in Grn ^?/? mice. In this study, we investigated how the tube test phenotype of progranulin‐insufficient mice changes with age, determined its robustness under several testing conditions, and explored the associated cellular mechanisms. We observed biphasic social dominance abnormalities in Grn^+/? mice: at 6–8 months, Grn^+/? mice were more dominant than wild‐type littermates, while after 9 months of age, Grn^+/? mice were less dominant. In contrast, Grn ^?/? mice did not exhibit abnormal social dominance, suggesting that progranulin haploinsufficiency has distinct effects from complete progranulin deficiency. The biphasic tube test phenotype of Grn^+/? mice was associated with abnormal cellular signaling and neuronal morphology in the amygdala and prefrontal cortex. At 6–9 months, Grn^+/? mice exhibited increased mTORC2/Akt signaling in the amygdala and enhanced dendritic arbors in the basomedial amygdala, and at 9–16 months Grn^+/? mice exhibited diminished basal dendritic arbors in the prelimbic cortex. These data show a progressive change in tube test dominance in Grn^+/? mice and highlight potential underlying mechanisms by which progranulin insufficiency may disrupt social behavior.     

Impairment of insulin signalling in peripheral tissue fails to extend murine lifespan

Impaired insulin/IGF1 signalling has been shown to extend lifespan in model organisms ranging from yeast to mammals. Here we sought to determine the effect of targeted disruption of the insulin receptor (IR) in non‐neuronal tissues of adult mice on the lifespan. We induced hemizygous (PerIRKO^+/?) or homozygous (PerIRKO^?/?) disruption of the IR in peripheral tissue of 15‐weeks‐old mice using a tamoxifen‐inducible Cre transgenic mouse with only peripheral tissue expression, and subsequently monitored glucose metabolism, insulin signalling and spontaneous death rates over 4 years. Complete peripheral IR disruption resulted in a diabetic phenotype with increased blood glucose and plasma insulin levels in young mice. Although blood glucose levels returned to normal, and fat mass was reduced in aged PerIRKO^?/? mice, their lifespan was reduced. By contrast, heterozygous disruption had no effect on lifespan. This was despite young male PerIRKO^+/? mice showing reduced fat mass and mild increase in hepatic insulin sensitivity. In conflict with findings in metazoans like Caenorhabditis elegans and Drosophila melanogaster, our results suggest that heterozygous impairment of the insulin signalling limited to peripheral tissues of adult mice fails to extend lifespan despite increased systemic insulin sensitivity, while homozygous impairment shortens lifespan.     

Brain serotonin determines maternal behavior and offspring survival

Maternal care is an indispensable component of offspring survival and development in all mammals and necessary for reproductive success. Although brain areas regulating maternal behaviors are innervated by serotonergic afferents, very little is known about the role of this neurotransmitter in these behaviors. To evaluate the contribution of serotonin to maternal care, we used mice with a null mutation in the gene for tryptophan hydroxylase‐2 (TPH2), which results in a genetic depletion of brain serotonin, and tested them in a wide range of maternal behavior paradigms. We found that litters born to and reared by TPH2^?/? mothers showed decreased survival, lower weaning weights and increased cannibalization. In addition, TPH2^?/? mothers performed poorly in pup retrieval, huddling, nest construction and high‐arched back nursing. Aggression in TPH2^?/? dams was not triggered by lactation and was steadily high. Survival and weaning weight deficits of TPH2^?/? pups were rescued by cross‐fostering and in litters of mixed genotype (TPH2^?/? and TPH2^?/+). However, the maternal behaviors of TPH2^?/? dams did not improve when rearing either TPH2^+/+ pups or mixed‐genotype litters. In addition, TPH2^?/? pups significantly worsened the behavior of TPH2^+/+ dams with respect to cannibalism, weaning weight and latency to attack. Olfactory and auditory functions of TPH2^?/? females or anxiety‐like behaviors did not account for these maternal alterations as they were equal to their TPH2^+/+ counterparts. These findings illustrate a profound influence of brain serotonin on virtually all elements of maternal behavior and establish that TPH2^?/? pups can engender maladaptive mothering in dams of both genotypes.     

Evidence for chemically-induced structural gene mutations at the thymidine kinase locus in cultured L5178Y mouse lymphoma cells

L5178Y mouse lymphoma cells normally appear to possess two functional thymidine kinase alleles (TK^+/+). TK-deficient (TK^?/?) clonal lines can be derived from these cells by treatment with EMS or other mutagens. Mezger-Freed [12] has argued that such stable phenotypic variants do not arise as the result of gene mutations but instead represent epigenetic events such as normally occur during differentiation without any permanent gene alteration. If this be so, then rare TK^+/? revertants arising in TK^?/? cultures should possess TK enzyme identical with one of those present in the original TK^+/+ cells, since only depression of the TK gene is involved. Our studies show that this is not the case.Among the mutant TK enzymes analyzed in vitro (those from parental TK^+/? lines, each derived in turn from separate TK^?/? lines) differences were found in (1) solubility in saline; (2) solubility in3 M LiCl; (3) K_m′s; and (4) ATP-Mg²⁺ requirements. These findings were incompatible with a non-mutational model for the production of these stable variants and, in conjunction with reversion-rate data, they tended to favor either direct structural gene modifications or mutations affecting the expression of adult and fetal enzymes.     

Lifelong reduction in complex IV induces tissue‐specific metabolic effects but does not reduce lifespan or healthspan in mice

Loss of SURF1, a Complex IV assembly protein, was reported to increase lifespan in mice despite dramatically lower cytochrome oxidase (COX) activity. Consistent with this, our previous studies found advantageous changes in metabolism (reduced adiposity, increased insulin sensitivity, and mitochondrial biogenesis) in Surf1^?/? mice. The lack of deleterious phenotypes in Surf1^?/? mice is contrary to the hypothesis that mitochondrial dysfunction contributes to aging. We found only a modest (nonsignificant) extension of lifespan (7% median, 16% maximum) and no change in healthspan indices in Surf1^?/? vs. Surf1^+/+ mice despite substantial decreases in COX activity (22%–87% across tissues). Dietary restriction (DR) increased median lifespan in both Surf1^+/+ and Surf1^?/? mice (36% and 19%, respectively). We measured gene expression, metabolites, and targeted expression of key metabolic proteins in adipose tissue, liver, and brain in Surf1^+/+ and Surf1^?/? mice. Gene expression was differentially regulated in a tissue‐specific manner. Many proteins and metabolites are downregulated in Surf1^?/? adipose tissue and reversed by DR, while in brain, most metabolites that changed were elevated in Surf1^?/? mice. Finally, mitochondrial unfolded protein response (UPR^mt)‐associated proteins were not uniformly altered by age or genotype, suggesting the UPR^mt is not a key player in aging or in response to reduced COX activity. While the changes in gene expression and metabolism may represent compensatory responses to mitochondrial stress, the important outcome of this study is that lifespan and healthspan are not compromised in Surf1^?/? mice, suggesting that not all mitochondrial deficiencies are a critical determinant of lifespan.     

Enhanced axon outgrowth and improved long‐distance axon regeneration in sprouty2 deficient mice

Sprouty (Spry) proteins are negative feedback inhibitors of receptor tyrosine kinase signaling. Downregulation of Spry2 has been demonstrated to promote elongative axon growth of cultured peripheral and central neurons. Here, we analyzed Spry2 global knockout mice with respect to axon outgrowth in vitro and peripheral axon regeneration in vivo. Neurons dissociated from adult Spry2 deficient sensory ganglia revealed stronger extracellular signal‐regulated kinase activation and enhanced axon outgrowth. Prominent axon elongation was observed in heterozygous Spry2^+/? neuron cultures, whereas homozygous Spry2^?/? neurons predominantly exhibited a branching phenotype. Following sciatic nerve crush, Spry2^+/? mice recovered faster in motor but not sensory testing paradigms (Spry2^?/? mice did not tolerate anesthesia required for nerve surgery). We attribute the improvement in the rotarod test to higher numbers of myelinated fibers in the regenerating sciatic nerve, higher densities of motor endplates in hind limb muscles and increased levels of GAP‐43 mRNA, a downstream target of extracellular regulated kinase signaling. Conversely, homozygous Spry2^?/? mice revealed enhanced mechanosensory function (von Frey's test) that was accompanied by an increased innervation of the epidermis, elevated numbers of nonmyelinated axons and more IB4‐positive neurons in dorsal root ganglia. The present results corroborate the functional significance of receptor tyrosine kinase signaling inhibitors for axon outgrowth during development and nerve regeneration and propose Spry2 as a novel potential target for pharmacological inhibition to accelerate long‐distance axon regeneration in injured peripheral nerves. © 2014 Wiley Periodicals, Inc. Develop Neurobiol 75: 217–231, 2015     

Brain region‐specific immunolocalization of the lipolysis‐stimulated lipoprotein receptor (LSR) and altered cholesterol distribution in aged LSR+/− mice

Brain lipid homeostasis is important for maintenance of brain cell function and synaptic communications, and is intimately linked to age‐related cognitive decline. Because of the blood–brain barrier's limiting nature, this tissue relies on a complex system for the synthesis and receptor‐mediated uptake of lipids between the different networks of neurons and glial cells. Using immunofluorescence, we describe the region‐specific expression of the lipolysis‐stimulated lipoprotein receptor (LSR), in the mouse hippocampus, cerebellum Purkinje cells, the ependymal cell interface between brain parenchyma and cerebrospinal fluid, and the choroid plexus. Colocalization with cell‐specific markers revealed that LSR was expressed in neurons, but not astrocytes. Latency in arms of the Y‐maze exhibited by young heterozygote LSR^+/? mice was significantly different as compared to control LSR^+/+, and increased in older LSR^+/? mice. Filipin and Nile red staining revealed membrane cholesterol content accumulation accompanied by significantly altered distribution of LSR in the membrane, and decreased intracellular lipid droplets in the cerebellum and hippocampus of old LSR^+/? mice, as compared to control littermates as well as young LSR^+/? animals. These data therefore suggest a potential role of LSR in brain cholesterol distribution, which is particularly important in preserving neuronal integrity and thereby cognitive functions during aging.     

Not all water mazes are created equal: cyclin D2 knockout mice with constitutively suppressed adult hippocampal neurogenesis do show specific spatial learning deficits

Studies using the Morris water maze to assess hippocampal function in animals, in which adult hippocampal neurogenesis had been suppressed, have yielded seemingly contradictory results. Cyclin D2 knockout (Ccnd2^?/?) mice, for example, have constitutively suppressed adult hippocampal neurogenesis but had no overt phenotype in the water maze. In other paradigms, however, ablation of adult neurogenesis was associated with specific deficits in the water maze. Therefore, we hypothesized that the neurogenesis‐related phenotype might also become detectable in Ccnd2^?/? mice, if we used the exact setup and protocol that in our previous study had revealed deficits in mice with suppressed adult neurogenesis. Ccnd2^?/? mice indeed learned the task and developed a normal preference for the goal quadrant, but were significantly less precise for the exact goal position and were slower in acquiring efficient and spatially more precise search strategies. Upon goal reversal (when the hidden platform was moved to a new position) Ccnd2^?/? mice showed increased perseverance at the former platform location, implying that they were less flexible in updating the previously learned information. Both with respect to adult neurogenesis and behavioral performance, Ccnd2^+/? mice ranged between wild types and knockouts. Importantly, hippocampus‐dependent learning was not generally impaired by the mutation, but specifically functional aspects relying on precise and flexible encoding were affected. Whether ablation of adult neurogenesis causes a specific behavioral phenotype thus also depends on the actual task demands. The test parameters appear to be important variables influencing whether a task can pick up a contribution of adult neurogenesis to test performance.     

Impact of β-galactosidase mutations on the expression of the canine lysosomal multienzyme complex

β-galactosidase (GLB1) forms a functional lysosomal multienzyme complex with lysosomal protective protein (PPCA) and neuraminidase 1 (NEU1) which is important for its intracellular processing and activity. Mutations in the β-galactosidase gene cause the lysosomal storage disease G_M1-gangliosidosis. In order to identify additional molecular changes associated with the presence of β-galactosidase mutations, the expression of canine lysosomal multienzyme complex components in GLB1^+/+, GLB1^+/? and GLB1^?/? fibroblasts was investigated by quantitative RT-PCR, Western blot and enzymatic assays. Quantitative RT-PCR revealed differential regulation of total β-galactosidase, β-galactosidase variants and protective protein for β-galactosidase gene (PPGB) in GLB1^+/? and GLB1^?/? compared to GLB1^+/+ fibroblasts. Furthermore, it was shown that PPGB levels gradually increased with the number of mutant β-galactosidase alleles while no change in the NEU1 expression was observed. This is the first study that simultaneously examine the effect of GLB1^+/+, GLB1^+/? and GLB1^?/? genotypes on the expression of lysosomal multienzyme complex components. The findings reveal a possible adaptive process in GLB1 homozygous mutant and heterozygous individuals that could facilitate the design of efficient therapeutic strategies.     

Deficiency of apoptosis‐stimulating protein two of p53 ameliorates acute kidney injury induced by ischemia reperfusion in mice through upregulation of autophagy

Acute kidney injury (AKI) has become a common disorder with a high risk of morbidity and mortality, which remains major medical problem without reliable and effective therapeutic intervention. Apoptosis‐stimulating protein two of p53 (ASPP2) is a proapoptotic member that belongs to p53 binding protein family, which plays a key role in regulating apoptosis and cell growth. However, the role of ASPP2 in AKI has not been reported. To explore the role of ASPP2 in the progression of AKI, we prepared an AKI mouse model induced by ischaemia reperfusion (I/R) in wild‐type (ASPP2^+/+) mice and ASPP2 haploinsufficient (ASPP2^+/?) mice. The expression profile of ASPP2 were examined in wild‐type mice. The renal injury, inflammation response, cellular apoptosis and autophagic pathway was assessed in ASPP2^+/+ and ASPP2^+/? mice. The renal injury, inflammation response and cellular apoptosis was analysed in ASPP2^+/+ and ASPP2^+/? mice treated with 3‐methyladenine or vehicle. The expression profile of ASPP2 showed an increase at the early stage while a decrease at the late stage during renal injury. Compared with ASPP2^+/+ mice, ASPP2 deficiency protected mice against renal injury induced by I/R, which mainly exhibited in slighter histologic changes, lower levels of blood urea nitrogen and serum creatinine, and less apoptosis as well as inflammatory response. Furthermore, ASPP2 deficiency enhanced autophagic activity reflecting in the light chain 3‐II conversion and p62 degradation, while the inhibition of autophagy reversed the protective effect of ASPP2 deficiency on AKI. These data suggest that downregulation of ASPP2 can ameliorate AKI induced by I/R through activating autophagy, which may provide a novel therapeutic strage for AKI.     

Effect of exercise on bone and articular cartilage in heterozygous manganese superoxide dismutase (SOD2) deficient mice

Abstract

Reactive oxygen species (ROS) are involved in both bone and cartilage physiology and play an important role in the pathogenesis of osteoporosis and osteoarthritis. The present study investigated the effect of running exercise on bone and cartilage in heterozygous manganese superoxide dismutase (SOD2)-deficient mice. It was hypothesized that exercise might induce an increased production of ROS in these tissues. Heterozygous SOD2-deficient mice should exhibit an impaired capability to compensate, resulting in an increased oxidative stress in cartilage and bone. Thirteen female wild type and 20 SOD2^+/? mice (aged 16 weeks) were randomly assigned to a non-active wild type (SOD2^+/+Con, n = 7), a trained wild type (SOD2^+/+Run, n = 6), a non-active SOD2^+/? (SOD2^+/?Con, n = 9) and a trained SOD2^+/? (SOD2^+/?Run, n = 11) group. Training groups underwent running exercise on a treadmill for 8 weeks. In SOD2^+/? mice elevated levels of 15-F_2t-isoprostane and nitrotyrosine were detected in bone and articular cartilage compared to wild type littermates. In osteocytes the elevated levels of these molecules were found to be reduced after exercise while in chondrocytes they were increased by aerobic running exercise. The observed changes in oxidative and nitrosative stress did neither affect morphological, structural nor mechanical properties of both tissues. These results demonstrate that exercise might protect bone against oxidative stress in heterozygous SOD2-deficient mice.     

Atp1a3‐deficient heterozygous mice show lower rank in the hierarchy and altered social behavior

Atp1a3 is the Na‐pump alpha3 subunit gene expressed mainly in neurons of the brain. Atp1a3‐deficient heterozygous mice (Atp1a3^+/?) show altered neurotransmission and deficits of motor function after stress loading. To understand the function of Atp1a3 in a social hierarchy, we evaluated social behaviors (social interaction, aggression, social approach and social dominance) of Atp1a3^+/? and compared the rank and hierarchy structure between Atp1a3^+/? and wild‐type mice within a housing cage using the round‐robin tube test and barbering observations. Formation of a hierarchy decreases social conflict and promote social stability within the group. The hierarchical rank is a reflection of social dominance within a cage, which is heritable and can be regulated by specific genes in mice. Here we report: (1) The degree of social interaction but not aggression was lower in Atp1a3^+/? than wild‐type mice, and Atp1a3^+/? approached Atp1a3^+/? mice more frequently than wild type. (2) The frequency of barbering was lower in the Atp1a3^+/? group than in the wild‐type group, while no difference was observed in the mixed‐genotype housing condition. (3) Hierarchy formation was not different between Atp1a3^+/? and wild type. (4) Atp1a3^+/? showed a lower rank in the mixed‐genotype housing condition than that in the wild type, indicating that Atp1a3 regulates social dominance. In sum, Atp1a3^+/? showed unique social behavior characteristics of lower social interaction and preference to approach the same genotype mice and a lower ranking in the hierarchy.     

Lipid Composition of Whole Brain and Cerebellum in Hurler Syndrome (MPS IH) Mice

Hurler syndrome (MPS IH) is caused by a mutation in the gene encoding alpha-L-iduronidase (IDUA) and leads to the accumulation of partially degraded glycosaminoglycans (GAGs). Ganglioside content is known to increase secondary to GAG accumulation. Most studies in organisms with MPS IH have focused on changes in gangliosides GM3 and GM2, without the study of other lipids. We evaluated the total lipid distribution in the whole brain and cerebellum of MPS IH (Idua ^?/?) and control (Idua ^+/?) mice at 6 months and at 12 months of age. The content of total sialic acid and levels of gangliosides GM3, GM2, and GD3 were greater in the whole brains of Idua ^?/? mice then in Idua ^+/? mice at 12 months of age. No other significant lipid differences were found in either whole brain or in cerebellum at either age. The accumulation of ganglioside GD3 suggests that neurodegeneration occurs in the Idua ^?/? mouse brain, but not to the extent seen in human MPS IH brain.     

MMP-9 gene ablation mitigates hyperhomocystenemia-induced cognition and hearing dysfunction

Hyperhomocysteinemia (HHcy) is associated with cognitive decline and hearing loss due to vascular dysfunction. Although we have shown that HHcy-induced increased expression of matrix metalloproteinase-9 (MMP-9) is associated with cochlear pathology in cystathionine-β-synthase heterozygous (CBS^+/?) mice, it is still unclear whether MMP-9 contributes to functional deficit in cognition and hearing. Therefore, we hypothesize that HHcy-induced MMP-9 activation causes vascular, cerebral and cochlear remodeling resulting in diminished cognition and hearing. Wildtype (WT), CBS^+/?, MMP-9^?/? and CBS^+/?/MMP-9^?/? double knock-out (DKO) mice were genotyped and used. Doppler flowmetry of internal carotid artery (ICA) was performed for peak systolic velocity [PSV], pulsatility index [PI] and resistive index [RI]. Cognitive functions were assessed by Novel Object Recognition Test (NORT) and for cochlear function Auditory brainstem response (ABR) was elicited. Peak systolic velocity, pulsatility and resistive indices of ICA were decreased in CBS^+/? mice, indicating reduced perfusion. ABR threshold was increased and maximum ABR amplitude and NORT indices (recognition, discrimination) were decreased in CBS^+/? mice compared to WT and MMP-9^?/?. All these parameters were attenuated in DKO mice suggesting a significant role of MMP-9 in HHcy-induced vascular, neural and cochlear pathophysiology. Regression analysis of PSV with ABR and cognitive parameters revealed significant correlation (0.44–0.58). For the first time, MMP-9 has been correlated directly to functional deficits of brain and cochlea, and found to have a significant role. Our data suggests a dual pathology of HHcy occurring due to a decrease in blood supply (vasculo-neural and vasculo-cochlear) and direct tissue remodeling.