Alzheimer’s disease is the most common cause of dementia.Although increasing evidence suggests that disruptions in lipid metabolism are closely associated with the disease,the overall profile of lipid and sterol chan...Alzheimer’s disease is the most common cause of dementia.Although increasing evidence suggests that disruptions in lipid metabolism are closely associated with the disease,the overall profile of lipid and sterol changes that occur in the brain during Alzheimer’s disease remains unclear.In this study,we compared brain tissues extracted from 32-week-old male wild-type mice and 5×FAD transgenic Alzheimer’s disease model mice,which carry mutations in the amyloid precursor protein(APP)and presenilin 1(PS1)genes.Using untargeted lipidomics and sterolomics techniques,we investigated the metabolic profiles of lipids,with a focus on sterols specifically,in three brain regions:cerebellum,hippocampus,and olfactory bulb.Our results revealed significant alterations in various lipids,particularly in the hippocampus and olfactory bulb,suggesting changes in energy levels in these regions.Further pathway analysis indicated notable disruptions in key metabolic processes,particularly those related to fatty acids and cell membrane components.Additionally,we observed decreased expression of 15 genes involved in lipid and sterol regulation.Collectively,these findings provide new insights into how imbalances in lipid and sterol metabolism may contribute to the progression of Alzheimer’s disease,highlighting potential metabolic pathways involved in the development of this debilitating disease.展开更多
Realistic models for cancer research representing disease progression that commensurately respond to therapeutics consistent with clinical observation are the holy grail for pre-clinical research and screening.Althoug...Realistic models for cancer research representing disease progression that commensurately respond to therapeutics consistent with clinical observation are the holy grail for pre-clinical research and screening.Although such an ideal is elusive,well-characterized in vivo models facilitate our understanding of disease,progression,and therapeutic opportunities.Here,we characterize a commonly used syngeneic BALB/c mouse model of triple negative breast cancer(4T1)after establishing tumors in their flanks.Tumors developed at the subcutaneous injection site for all experimental mice and their volumes were monitored.We quantified a rare subset of breast cancer stemlike cells(CSCs),classified as CD44^(+)/CD24^(−)phenotypes in in vitro and ex vivo cell populations.Chromosome numbers in ex vivo metaphase cells were greater than cells cultured in vitro(89.4±3.4,range of 70-132 and 82.6±1.1,range of 70-128;respectively).Further,we observed different types of chromosome aberrations,including gap,deletion,exchange,interstitial deletion,terminal deletion,ring,dicentric,and Robertsonian translocations.For both sources of cells,the number of aberrations was dominated by deletions,terminal deletions,and Robertsonian translocations.Ex vivo cells exhibited greater prevalence of deletions and terminal deletions,whereas in vitro cells displayed more ring aberrations and Robertsonian translocations.In conclusion,we successfully characterized cancer cells from a syngeneic mouse model of breast cancer in terms of rare CSC proportion and a variety of chromosomal aberrations,which is useful for understanding tumor traits associated with cancer development and therapeutic action.The data act as a valuable resource for other studies using the 4T1 BALB/c model.展开更多
Background:In recent decades,the global incidence of dengue fever has been stead-ily increasing,with continuous geographical expansion.Researchers have successfully modeled most clinical symptoms of human dengue fever...Background:In recent decades,the global incidence of dengue fever has been stead-ily increasing,with continuous geographical expansion.Researchers have successfully modeled most clinical symptoms of human dengue fever using interferon type I(IFN-I)or combined IFN-I/II receptor knockout mice infected with dengue virus(DENV).However,this model requires further optimization to better support related studies.Methods:This study aimed to establish a stable dengue infection model by evaluating the effects of different genetic backgrounds and injection routes on DENV infection in interferon receptor knockout mice.We first infected various strains of interferon receptor-deficient mice with DENV and compared their susceptibility based on clini-cal symptoms,viremia levels,organ indices,histopathological findings,and vascular leakage markers.Subsequently,we selected the most susceptible strain to further investigate the impact of different injection methods on infection outcomes.Results:We found that BALB/c background mice with type 1 interferon recep-tor knockout(IFNAR)had the most obvious symptoms.Subsequently,we selected IFNAR−/−BALB/c mice to further explore the effects of different injection methods on dengue virus infection.The results showed that the intraperitoneal injection group had the most severe clinical symptoms,the longest duration of viremia,and the most obvious degree of organ damage.Conclusion:Through systematic screening and optimization,we established a robust animal model of dengue virus infection via intraperitoneal injection in IFNAR−/−BALB/c mice.This model offers a valuable tool for future dengue research.展开更多
Background:Humanized mouse models are essential for studying the human immune response and antibody development.However,conventional models show limited B cell maturation and antigen-specific humoral responses.To over...Background:Humanized mouse models are essential for studying the human immune response and antibody development.However,conventional models show limited B cell maturation and antigen-specific humoral responses.To overcome these limitations,we used the NOG-EXL mice expressing human interleukin 3(IL-3)and granulocyte-macrophage colony-stimulating factor(GM-CSF)to enhance myeloid and B-cell lineage differentiation.Methods:Human CD34^(+)hematopoietic stem cells(HSC)were transplanted into NOG-EXL mice to produce humanized immune systems.After immune cell reconstitution was confirmed across 12 weeks,the mice were immunized twice with inactivated severe fever with thrombocytopenia syndrome virus(SFTSV)antigens.Peripheral blood mononuclear cells and splenocytes were analyzed using multicolor flow cytometry to assess human immune cell subsets.Antigen-specific immunoglobulin G(IgG)production was quantified using enzyme-linked immunosorbent assay(ELISA),and virus-specific B cells were isolated using antigen-labeled recombinant protein probes.Results:Twelve weeks after transplantation of HSCs into NOG-EXL mice,they exhibited robust engraftment of human leukocytes,including T,B,and dendritic cells,compared to NOG mice.Unlike NOG mice,humanized NOG-EXL mice exhibited an increase in human IgG levels,indicating the production of human antibody responses to antigens.Humanized NOG-EXL mice were immunized twice every 2 weeks with inactivated SFTSV,and antigen-specific human antibodies against the virus were detected in the mouse sera by ELISA.Sera from SFTSV-immunized humanized mice demonstrated neutralizing activity against SFTSV,confirming the induction of functional virus-specific neutralizing antibodies.Antigen-binding IgG-positive human B cells were isolated from mouse splenocytes using recombinant protein probes.Conclusion:This model provides a valuable platform for evaluating humoral immunity and isolating B cells using high-affinity human monoclonal antibodies without genetic engineering.展开更多
Background:This study aims to explore the establishment of an animal model of car-diac injury induced by trimethylamine-N-oxide(TMAO),a metabolite secreted by gut microorganisms,and to investigate its application in m...Background:This study aims to explore the establishment of an animal model of car-diac injury induced by trimethylamine-N-oxide(TMAO),a metabolite secreted by gut microorganisms,and to investigate its application in moderate-intensity continuous training(MICT)intervention.Methods:C57BL6/J mice were randomly divided into four groups:normal mice(Nor,n=15);mice administered TMAO(TMAO,n=15);mice undergoing(Nor+MICT,n=15);mice undergoing(MICT)and administered TMAO(TMAO+MICT,n=15).Mice in the TMAO and TMAO+MICT groups received daily gavage of high-dose TMAO for 8 weeks,whereas those in the Nor+MICT and TMAO+MICT groups underwent MICT for 8 weeks(60 min per session,5 days per week,at 50%maximal running capacity).Cardiac function was evaluated using ultrasound,myocardial histology was examined using hematoxylin and eosin(HE)staining,and nuclear magnetic resonance(NMR)-based metabolomics was employed for multivariate statistical and metabolic pathway analyses.Results:Relative to the Nor group,TMAO-treated mice exhibited significant weight loss,elevated heart rate,and reduced ejection fraction and left ventricular fractional shortening,indicating cardiac impairment.Importantly,the TMAO+MICT group dem-onstrated significant improvements in these parameters compared to the TMAO group,alongside distinct alterations in myocardial metabolic profiles.TMAO altered five metabolic pathways relative to controls,whereas MICT induced significant changes in three pathways in TMAO-treated mice.Conclusion:Eight weeks of high-dose TMAO administration induced significant cardiac dysfunction in mice,which was effectively mitigated by MICT intervention.Consequently,this animal model serves as a valuable tool for investigating the mecha-nisms underlying the impact of MICT on cardiovascular diseases.展开更多
Age-related osteoporosis poses a significant challenge in musculoskeletal health;a condition characterized by reduced bone density and increased fracture susceptibility in older individuals necessitates a better under...Age-related osteoporosis poses a significant challenge in musculoskeletal health;a condition characterized by reduced bone density and increased fracture susceptibility in older individuals necessitates a better understanding of underlying molecular and cellular mechanisms.Emerging evidence suggests that osteocytes are the pivotal orchestrators of bone remodeling and represent novel therapeutic targets for age-related bone loss.Our study uses the prematurely aged PolgD257A/D257A(PolgA)mouse model to scrutinize age-and sex-related alterations in musculoskeletal health parameters(frailty,grip strength,gait data),bone and particularly the osteocyte lacuno-canalicular network(LCN).Moreover,a new quantitative in silico image analysis pipeline is used to evaluate the alterations in the osteocyte network with aging.Our findings underscore the pronounced degenerative changes in the musculoskeletal health parameters,bone,and osteocyte LCN in PolgA mice as early as 40 weeks,with more prominent alterations evident in aged males.Our findings suggest that the PolgA mouse model serves as a valuable model for studying the cellular mechanisms underlying age-related bone loss,given the comparable aging signs and age-related degeneration of the bone and the osteocyte network observed in naturally aging mice and elderly humans.展开更多
Alzheimer'sdisease(AD)isaprogressive neurodegenerative disorder characterized by cognitive impairment and distinct neuropathological features,including amyloid-βplaques,neurofibrillary tangles,and reactive astrog...Alzheimer'sdisease(AD)isaprogressive neurodegenerative disorder characterized by cognitive impairment and distinct neuropathological features,including amyloid-βplaques,neurofibrillary tangles,and reactive astrogliosis.Developing effective diagnostic,preventative,and therapeutic strategies for AD necessitates the establishment of animal models that accurately recapitulate the pathophysiological processes of the disease.Existing transgenic mouse models have significantly contributed to understanding AD pathology but often fail to replicate the complexity of human AD.Additionally,these models are limited in their ability to elucidate the interplay among amyloid-βplaques,neurofibrillary tangles,and reactive astrogliosis due to the absence of spatially and temporally specific genetic manipulation.In this study,we introduce a novel AD mouse model(APP/PS1-TauP301L-Adeno mice)designed to rapidly induce pathological symptoms and enhance understanding of AD mechanisms.Neurofibrillary tangles and severe reactive astrogliosis were induced by injecting AAVDJ-EF1a-hTauP301L-EGFP and Adeno-GFAP-GFP viruses into the hippocampi of 5-month-old APP/PS1 mice.Three months post-injection,these mice exhibited pronounced astrogliosis,substantial amyloid-βplaque accumulation,extensiveneurofibrillarytangles,accelerated neuronal loss,elevated astrocytic GABA levels,and significant spatial memory deficits.Notably,these pathological features were less severe in AAVTauP301L-expressing APP/PS1 mice without augmented reactive astrogliosis.These findings indicate an exacerbating role of severe reactive astrogliosis in amyloid-βplaque and neurofibrillary tangle-associated pathology.The APP/PS1-TauP301L-Adeno mouse model provides a valuable tool for advancing therapeutic research aimed at mitigating the progression of AD.展开更多
Background:The precise insertion of large DNA fragments(>3–5 kb)remains one of the key obstacles in establishment of genetically modified murine models.Methods:A 21 kb large DNA fragment containing three tandemly ...Background:The precise insertion of large DNA fragments(>3–5 kb)remains one of the key obstacles in establishment of genetically modified murine models.Methods:A 21 kb large DNA fragment containing three tandemly linked copies of the human HRAS gene was inserted into the genome of C57BL/6J mouse,generating a mouse model designated as KI.C57-ras(or named NF-h HRAS).Whole-genome sequencing and Sanger sequencing were utilized to it confirm precise insertion and copy number.The stability of transgene expression among different generations was verified from multiple aspects using by digital PCR,western blot and DNA sequencing.To assess tumor susceptibility in the mouse model,N-Nitroso-N-methylurea(MNU)was administered at a dosage of 75 mg/kg.Histopathological examinations were conducted using hematoxylin and eosin(H&E)staining.Results:The HRAS DNA fragment was inserted into mouse chromosome 15E1 site,locating between 80623202 bp and 80625020 bp.NF-h HRAS mice exhibited stable inheritance and displayed consistent phenotypes across individuals.Moreover,this mouse model exhibited a high susceptibility to carcinogens.Upon administration of MNU the earliest mortality onset was earlier than that of wild-type littermates(day 65 vs.day 78 for male and day 56 vs.day 84 for female).Notably,100%of the NF-h HRAS transgenic mice developed tumors,with approximately 84%of male NF-h HRAS mice exhibiting specific tumor types,such as squamous cell carcinoma or squamous cell papilloma,which was consistent with the previously reported carcinogenic rasH2 mouse model.The types of tumors and the target organs exhibited diversity in NFh HRAS mice,while the spontaneous tumor incidence remained low(1/50).Conclusions:The NF-h HRAS mice demonstrated excellent genetic stability,a reproducible phenotype,and high susceptibility to carcinogens,indicating their potential utility in non-clinical safety evaluations of drugs as per the S1B guidelines issued by the ICH(The International Council for Harmonization of Technical Requirements for Pharmaceuticals for Human Use).展开更多
Genetically engineered mouse(GEM)models are commonly used in biomedical research.Generating GEMs involve complex set of experimental procedures requiring sophisticated equipment and highly skilled technical staff.Beca...Genetically engineered mouse(GEM)models are commonly used in biomedical research.Generating GEMs involve complex set of experimental procedures requiring sophisticated equipment and highly skilled technical staff.Because of these reasons,most research institutes set up centralized core facilities where custom GEMs are created for research groups.Researchers,on the other hand,when they begin thinking about generating GEMs for their research,several questions arise in their minds.For example,what type of model(s)would be best useful for my research,how do I design them,what are the latest technologies and tools available for developing my model(s),and finally how to breed GEMs in my research.As there are several considerations and options in mouse designs,and as it is an expensive and time-consuming endeavor,careful planning upfront can ensure the highest chance of success.In this article,we provide brief answers to several frequently asked questions that arise when researchers begin thinking about generating mouse model(s)for their work.展开更多
Parkinson's disease,the most common movement disorder,has a strong neuroinflammatory aspect.This is evident by increased pro-inflammatory cytokines in the serum,and the presence of activated microglial cells,and i...Parkinson's disease,the most common movement disorder,has a strong neuroinflammatory aspect.This is evident by increased pro-inflammatory cytokines in the serum,and the presence of activated microglial cells,and inflammatory cytokines in the substantia nigra of post-mortem brains as well as cerebrospinal fluid of Parkinson's disease patients.The central and peripheral neuroinflammatory aspects of Parkinson's disease can be investigated in vivo via administration of the inflammagen lipopolysaccharide,a component of the cell wall of gram-negative bacteria.In this mini-review,we will critically evaluate different routes of lipopolysaccharide administration(including intranasal systemic and ste reotasic),their relevance to clinical Parkinson's disease as well as the recent findings in lipopolysaccharide mouse models.We will also share our own expe riences with systemic and intrastriatal lipopolysaccharide models in C57BL/6 mice and will discuss the usefulness of lipopolysaccharide mouse models for future research in the field.展开更多
Background:Most mutations in the COL6A3 gene lead to collagen VI-related myopathies.This is due to a reduced expression or mislocalization of the COL6A3 protein.Therefore,studying the consequence of knocking out the C...Background:Most mutations in the COL6A3 gene lead to collagen VI-related myopathies.This is due to a reduced expression or mislocalization of the COL6A3 protein.Therefore,studying the consequence of knocking out the Col6a3 gene in mouse models is relevant,but the Col6a3 mouse models reported so far do not entirely abolish COL6A3 protein expression.Methods:Here,we present the development,validation and preliminary phenotypic characterization of a novel CRISPR-based knockout mouse model targeting Col6a3 exon 3(Col6a3^(d3/d3)).Results:In this mouse model,Col6a3 mRNA is still expressed at a similar level to wild-type littermates,although the expected protein is undetectable by mass spectrometry.Histological analysis of Col6a3^(d3/d3)quadriceps revealed an abnormally high frequency of muscle cells with internally nucleated muscle cells,consistent with a myopathy phenotype.Interestingly,Col6a3^(d3/d3)mice are smaller in size,with their fat,muscle,and bone kept proportional compared to wild-type littermates.Conclusions:In summary,we performed the validation and preliminary phenotypic characterization of a novel Col6a3 knockout mouse model that could be further characterized and used to study COL6A3 biology and model collagen VI-associated diseases.展开更多
Substantial evidence points to the early onset of peripheral inflammation in the development of Parkinson's disease(PD),supporting the“body-first”hypothesis.However,there remains a notable absence of PD-specific...Substantial evidence points to the early onset of peripheral inflammation in the development of Parkinson's disease(PD),supporting the“body-first”hypothesis.However,there remains a notable absence of PD-specific animal models induced by inflammatory cytokines.This study introduces a novel mouse model of PD driven by the proinflammatory cytokine CXCL1,identified in our previous research.The involvement of CXCL1 in PD pathogenesis was validated using subacute and chronic MPTP-induced mouse models.Based on these findings,2-month-old C57BL/6J mice were intravenously administered CXCL1(20 ng/kg/day)for 2 weeks(5 days per week),successfully replicating motor deficits and pathological alterations in the substantia nigra observed in the chronic MPTP model.These results demonstrate the potential of CXCL1-induced inflammation as a mechanism for PD modeling.The model revealed activation of the PPAR signaling pathway in CXCL1-mediated neuronal damage by CXCL1.Linoleic acid,a PPAR-γactivator,significantly mitigated MPTPand CXCL1-induced toxicity and reduced serum CXCL1levels.In addition,the CXCL1-injected mouse model shortened the timeline for developing chronic PD mouse model to 2 weeks,offering an efficient platform for studying inflammation-driven processes in PD.The findings provide critical insights into the inflammatory mechanisms underlying PD and identify promising therapeutic targets for intervention.展开更多
Background:Spinocerebellar ataxia type 2(SCA2)is a neurodegenerative disease marked by significant clinical and genetic heterogeneity,primarily caused by expanded CAG mutations in the ATXN2 gene.The unstable expansion...Background:Spinocerebellar ataxia type 2(SCA2)is a neurodegenerative disease marked by significant clinical and genetic heterogeneity,primarily caused by expanded CAG mutations in the ATXN2 gene.The unstable expansion of CAG repeats disrupts the genetic stability of animal models,which is detrimental to disease research.Methods:In this study,we established a mouse model in which CAG repeats do not undergo microsatellite instability(MSI)across generations.A humanized ATXN2 cDNA with four CAA interruptions within 73 CAG expansions was inserted into the Rosa26 locus of C57BL/6J mice.A 23 CAG control mouse model was also generated to verify ATXN2 integration and expression.Results:In our model,the number of CAG repeats remained stable during transmission,with no CAG repeat expansion observed in 64 parent-to-offspring transmissions.Compared with SCA2-Q23 mice,SCA2-Q73 mice exhibited progressive motor impairment,reduced Purkinje cell count and volume(indicative of cell atrophy),and muscle atrophy.These observations in the mice suggest that the behavioral and neuropathological phenotypes may reflect the features of SCA2 patients.RNA-seq analysis of the gastrocnemius muscle in SCA2-Q73 mice showed significant changes in muscle differentiation and development gene expression at 56 weeks,with no significant differences at 16 weeks compared to SCA2-Q23 mice.The expression level of the Myf6 gene significantly changed in the muscles of aged mice.Conclusion:In summary,the establishment of this model not only provides a stable animal model for studying CAG transmission in SCA2 but also indicates that the lack of long-term neural stimulation leads to muscle atrophy.展开更多
Murine subarachnoid hemorrhage(SAH)induced using the filament perforation method is a useful in vivo experimental model to investigate the pathophysiological mechanisms in the brain underlying SAH.However,identifying ...Murine subarachnoid hemorrhage(SAH)induced using the filament perforation method is a useful in vivo experimental model to investigate the pathophysiological mechanisms in the brain underlying SAH.However,identifying mice with comorbid acute neurogenic pulmonary edema(NPE),a life-threatening systemic consequence often induced by SAH,in this model is difficult without histopathological investiga-tions.Herein,we present an imaging procedure involving dual-energy X-ray absorp-tiometry(DXA)to identify NPE in a murine model of SAH.We quantified the lung lean mass(LM)and compared the relationship between micro-computed tomography(CT)evidence of Hounsfield unit(HU)values and histopathological findings of PE.Of the 85 mice with successful induction of SAH by filament perforation,16(19%)had NPE,as verified by postmortem histology.The DXA-LM values correlate well with CT-HU levels(r=0.63,p<0.0001).Regarding the relationship between LM and HU in mice with post-SAH NPE,the LM was positively associated with HU values(r2=0.43;p=0.0056).A receiver operating characteristics curve of LM revealed a sensitivity of 87%and specificity of 57%for detecting PE,with a similar area under the curve as the HU(0.79±0.06 vs.0.84±0.07;p=0.21).These data suggest that confirming acute NPE using DXA-LM is a valuable method for selecting a clinically relevant murine NPE model that could be used in future experimental SAH studies.展开更多
Background:Rabies virus(RABV)-derived neuronal tracing tools are extensively applied in retrograde tracing due to their strict retrograde transsynaptic transfer property and low neurotoxicity.However,the RABV infectio...Background:Rabies virus(RABV)-derived neuronal tracing tools are extensively applied in retrograde tracing due to their strict retrograde transsynaptic transfer property and low neurotoxicity.However,the RABV infection and expression of fluorescence products would be gradually cleared while the infected neurons still survive,a phenomenon known as non-cytolytic immune clearance(NCLIC).This phenomenon introduced the risk of fluorescence loss and led to the omission of a subset of neurons that should be labeled,thereby interfering in the analysis of tracing results.Methods:To compensate for the fluorescence loss problem,in this study,we developed a novel marker footprints(MF)mouse,involving a Cre recombinase-dependent red fluorescent reporter system and systemic expression of glycoprotein(G)and ASLV-A receptor(TVA).Using this mouse model combined with the well-developed RABV-EnvA-ΔG-GFP-Cre viral tool,we developed a novel green-to-red spectral labeling strategy.Results:Neurons in the MF mouse could be co-labeled with green fluorescence from the very quick expression of the viral tool and with red fluorescence from the relatively slow expression of the neuron itself,so neurons undergoing NCLIC with green fluorescence loss could be relabeled red.Furthermore,newly infected neurons could be labeled green and other neurons could be labeled yellow due to the temporal expression difference between the two fluorescent proteins.Conclusions:This is the first polysynaptic retrograde tracing labeling strategy that could label neurons using spectral fluorescence colors with only one injection of the viral tool,enabling its application in recognizing the labeling sequence of neurons in brain regions and enhancing the spatiotemporal resolution of neuronal tracing.展开更多
Craniometaphyseal dysplasia(CMD),a rare craniotubular disorder,occurs in an autosomal dominant(AD)or autosomal recessive(AR)form.CMD is characterized by hyperostosis of craniofacial bones and metaphyseal flaring of lo...Craniometaphyseal dysplasia(CMD),a rare craniotubular disorder,occurs in an autosomal dominant(AD)or autosomal recessive(AR)form.CMD is characterized by hyperostosis of craniofacial bones and metaphyseal flaring of long bones.Many patients with CMD suffer from neurological symptoms.The pathogenesis of CMD is not fully understood.展开更多
Dear Editor,Crimean–Congo hemorrhagic fever(CCHF),caused by the CCHF virus(CCHFV),is a severe tick-borne illness with a wide geographical distribution,posing a significant threat with case fatality rates ranging from...Dear Editor,Crimean–Congo hemorrhagic fever(CCHF),caused by the CCHF virus(CCHFV),is a severe tick-borne illness with a wide geographical distribution,posing a significant threat with case fatality rates ranging from 5%to 70%(Hawman and Feldmann,2023).Due to the lack of approved vaccines and therapeutics,the World Health Organization(WHO)has listed CCHF as one of the priority diseases(Semper et al.,2024).CCHF initially presents as a nonspecific febrile illness,characterized by fever,malaise,myalgia,and nausea,which can rapidly progress to hemorrhagic disease.The hemorrhagic stage is particularly pronounced in severe cases,with rapid progression to disseminated intravascular coagulation(DIC),overt bleeding,kidney or liver failure,and shock(Frank et al.,2024).Up to date,there is an absence of a suitable animal model that can accurately mimic the coagulopathy and bleeding associated with CCHFV infection.Consequently,our understanding of the pathogenic mechanisms underlying these conditions remains limited(Rodriguez et al.,2022).展开更多
Background:The current understanding of diabetic kidney disease(DKD)has significant gaps regarding the underlying pathogenesis.In this study,we aimed to characterize the temporal progression of DKD using a state-of-th...Background:The current understanding of diabetic kidney disease(DKD)has significant gaps regarding the underlying pathogenesis.In this study,we aimed to characterize the temporal progression of DKD using a state-of-the-art mouse model of hypertension-accelerated disease,integrating kidney biomarker analysis,histopathology,and glomerular transcriptomic profiling.Methods:Female diabetic db/db mice received a single intravenous dose of adenoassociated virus-mediated renin overexpression(ReninAAV,week 5)and underwent uninephrectomy(UNx,week 4).db/db UNx-ReninAAV mice were terminated at weeks 1,4,8,and 12(n=7–8 per group).Female db/m mice were used as healthy controls.Study endpoints included plasma and urine biochemistry,glomerulosclerosis scoring,quantitative kidney histology,and RNA sequencing of glomeruli isolated using lasercapture microdissection.Results:db/db UNx-ReninAAV mice developed progressive albuminuria(from week 4)and glomerulosclerosis(from week 8).A pathway analysis of clustered gene regulations revealed broad glomerular transcriptome perturbations with signatures of increased extracellular matrix(ECM)turnover from week 8 and early onset of metabolic dysfunction.Markers of glomerular cell types and injury exhibited temporal regulation over the course of DKD,with early and sustained downregulation of endothelial markers,heterogeneous regulation of podocyte markers,and significant mesangial and parietal epithelial aberrations.Furthermore,the upregulation of cell injury markers confirmed progressive glomerular injury in the model.Conclusion:The db/db UNx-ReninAAV mouse model exhibits distinct temporal dynamics in glomerular cell markers,metabolic dysregulation,ECM remodeling,and injury.Together,these results highlight the utility of the db/db UNx-ReninAAV model as a relevant preclinical platform for studying progressive DKD.展开更多
Background:It is well recognized that developing new animal models,refining the existing mouse models,and thoroughly characterizing their features are essential for gaining a deeper understanding of rosacea pathogenes...Background:It is well recognized that developing new animal models,refining the existing mouse models,and thoroughly characterizing their features are essential for gaining a deeper understanding of rosacea pathogenesis and for advancing therapeutic strategies in this direction.Accordingly,we aimed to characterize the pathological features of a long-term LL-37-induced mouse model of rosacea and to compare the disease manifestations and pathophysiological characteristics between short-term and long-term LL-37-induced models.A key focus was to investigate differential gene expression and the underlying mechanisms of immune system dysregulation in these models.Methods:We comparatively assessed skin lesion manifestations,the extent of inflammatory infiltration,sebaceous gland alterations,fibrosis,and angiogenesis in both models.Assessments were performed using photographic documentation,hematoxylin-eosin(HE)staining,Van Gieson's(VG)staining,immunohistochemistry,and Western blotting.Furthermore,we employed RNA sequencing to analyze differential gene expression in mouse skin.The RNA sequencing data were validated using immunofluorescence staining and Western blotting,with a specific focus on gene variations and mechanisms related to immune system dysregulation.Results:Mice subjected to long-term LL-37 induction developed rosacea-like pathological features,including angiogenesis,thickened skin tissue,and sebaceous gland hypertrophy.In the short-term LL-37-induced model,immune dysregulation primarily involved the innate immune response.However,long-term LL-37 induction resulted in significant activation of both innate and adaptive immune responses.Conclusion:The long-term LL-37-induced mouse model offers a valuable animal model for the detailed investigation of the pathological mechanisms driving moderate-to-severe rosacea with prolonged disease duration.Importantly,this model provides a significant experimental foundation for exploring the potential role of immune system dysregulation in rosacea pathogenesis.展开更多
基金supported by the National Natural Science Foundation of China,Nos.82200784,32271311Qizhen Foundation,No.226‐2023‐00008(all to LH).
文摘Alzheimer’s disease is the most common cause of dementia.Although increasing evidence suggests that disruptions in lipid metabolism are closely associated with the disease,the overall profile of lipid and sterol changes that occur in the brain during Alzheimer’s disease remains unclear.In this study,we compared brain tissues extracted from 32-week-old male wild-type mice and 5×FAD transgenic Alzheimer’s disease model mice,which carry mutations in the amyloid precursor protein(APP)and presenilin 1(PS1)genes.Using untargeted lipidomics and sterolomics techniques,we investigated the metabolic profiles of lipids,with a focus on sterols specifically,in three brain regions:cerebellum,hippocampus,and olfactory bulb.Our results revealed significant alterations in various lipids,particularly in the hippocampus and olfactory bulb,suggesting changes in energy levels in these regions.Further pathway analysis indicated notable disruptions in key metabolic processes,particularly those related to fatty acids and cell membrane components.Additionally,we observed decreased expression of 15 genes involved in lipid and sterol regulation.Collectively,these findings provide new insights into how imbalances in lipid and sterol metabolism may contribute to the progression of Alzheimer’s disease,highlighting potential metabolic pathways involved in the development of this debilitating disease.
基金National Research,Development and Innovation Fund of the Ministry of Culture and Innovation under the National Laboratories Program(National Tumor Biology Laboratory,Grant/Award Number:2022-2.1.1-NL-2022-00010)Senior Research Fellowship from National Health and Medical Research Council of Australia,Grant/Award Number:1156693+1 种基金Hungarian Thematic Excellence Program,Grant/Award Number:TKP2021-EGA-44Tour de Cure,Pioneering Grant,Grant/Award Number:RSP-253-18/19。
文摘Realistic models for cancer research representing disease progression that commensurately respond to therapeutics consistent with clinical observation are the holy grail for pre-clinical research and screening.Although such an ideal is elusive,well-characterized in vivo models facilitate our understanding of disease,progression,and therapeutic opportunities.Here,we characterize a commonly used syngeneic BALB/c mouse model of triple negative breast cancer(4T1)after establishing tumors in their flanks.Tumors developed at the subcutaneous injection site for all experimental mice and their volumes were monitored.We quantified a rare subset of breast cancer stemlike cells(CSCs),classified as CD44^(+)/CD24^(−)phenotypes in in vitro and ex vivo cell populations.Chromosome numbers in ex vivo metaphase cells were greater than cells cultured in vitro(89.4±3.4,range of 70-132 and 82.6±1.1,range of 70-128;respectively).Further,we observed different types of chromosome aberrations,including gap,deletion,exchange,interstitial deletion,terminal deletion,ring,dicentric,and Robertsonian translocations.For both sources of cells,the number of aberrations was dominated by deletions,terminal deletions,and Robertsonian translocations.Ex vivo cells exhibited greater prevalence of deletions and terminal deletions,whereas in vitro cells displayed more ring aberrations and Robertsonian translocations.In conclusion,we successfully characterized cancer cells from a syngeneic mouse model of breast cancer in terms of rare CSC proportion and a variety of chromosomal aberrations,which is useful for understanding tumor traits associated with cancer development and therapeutic action.The data act as a valuable resource for other studies using the 4T1 BALB/c model.
基金Guangdong Province Medical Research Fund Project,Grant/Award Number:B2024112The Scientific Research Special Project of the Joint Construction Project of High-level Hospitals between Guangzhou University of Chinese Medicine and the Scientific Research Fund Project,Grant/Award Number:GZYZS2024G09+2 种基金Special Project of the Research Platform of Guangdong Provincial Department of Traditional Chinese Medicine,Grant/Award Number:20254040the Project of the Incubation Program for the Science and Technology Development of Chinese Medicine Guangdong Laboratory/Hengqin Laboratory,Grant/Award Number:HQL2024PZ043Guangdong Province Natural Science Foundation-Guangzhou-South China Joint Youth Fund Project,Grant/Award Number:2023A1515110849。
文摘Background:In recent decades,the global incidence of dengue fever has been stead-ily increasing,with continuous geographical expansion.Researchers have successfully modeled most clinical symptoms of human dengue fever using interferon type I(IFN-I)or combined IFN-I/II receptor knockout mice infected with dengue virus(DENV).However,this model requires further optimization to better support related studies.Methods:This study aimed to establish a stable dengue infection model by evaluating the effects of different genetic backgrounds and injection routes on DENV infection in interferon receptor knockout mice.We first infected various strains of interferon receptor-deficient mice with DENV and compared their susceptibility based on clini-cal symptoms,viremia levels,organ indices,histopathological findings,and vascular leakage markers.Subsequently,we selected the most susceptible strain to further investigate the impact of different injection methods on infection outcomes.Results:We found that BALB/c background mice with type 1 interferon recep-tor knockout(IFNAR)had the most obvious symptoms.Subsequently,we selected IFNAR−/−BALB/c mice to further explore the effects of different injection methods on dengue virus infection.The results showed that the intraperitoneal injection group had the most severe clinical symptoms,the longest duration of viremia,and the most obvious degree of organ damage.Conclusion:Through systematic screening and optimization,we established a robust animal model of dengue virus infection via intraperitoneal injection in IFNAR−/−BALB/c mice.This model offers a valuable tool for future dengue research.
基金The Korea Centers for Disease Control and Prevention,Grant/Award Number:2022-ER1701-00,2022-NI-041-02,2024-ER1702-00 and 2025-NI-014-00。
文摘Background:Humanized mouse models are essential for studying the human immune response and antibody development.However,conventional models show limited B cell maturation and antigen-specific humoral responses.To overcome these limitations,we used the NOG-EXL mice expressing human interleukin 3(IL-3)and granulocyte-macrophage colony-stimulating factor(GM-CSF)to enhance myeloid and B-cell lineage differentiation.Methods:Human CD34^(+)hematopoietic stem cells(HSC)were transplanted into NOG-EXL mice to produce humanized immune systems.After immune cell reconstitution was confirmed across 12 weeks,the mice were immunized twice with inactivated severe fever with thrombocytopenia syndrome virus(SFTSV)antigens.Peripheral blood mononuclear cells and splenocytes were analyzed using multicolor flow cytometry to assess human immune cell subsets.Antigen-specific immunoglobulin G(IgG)production was quantified using enzyme-linked immunosorbent assay(ELISA),and virus-specific B cells were isolated using antigen-labeled recombinant protein probes.Results:Twelve weeks after transplantation of HSCs into NOG-EXL mice,they exhibited robust engraftment of human leukocytes,including T,B,and dendritic cells,compared to NOG mice.Unlike NOG mice,humanized NOG-EXL mice exhibited an increase in human IgG levels,indicating the production of human antibody responses to antigens.Humanized NOG-EXL mice were immunized twice every 2 weeks with inactivated SFTSV,and antigen-specific human antibodies against the virus were detected in the mouse sera by ELISA.Sera from SFTSV-immunized humanized mice demonstrated neutralizing activity against SFTSV,confirming the induction of functional virus-specific neutralizing antibodies.Antigen-binding IgG-positive human B cells were isolated from mouse splenocytes using recombinant protein probes.Conclusion:This model provides a valuable platform for evaluating humoral immunity and isolating B cells using high-affinity human monoclonal antibodies without genetic engineering.
基金National Natural Science Foundation of China,Grant/Award Number:32271496China Fundamental Research Funds for the Central Universities(Bejing Sport University)Grant/Award Number:2024TZJK001。
文摘Background:This study aims to explore the establishment of an animal model of car-diac injury induced by trimethylamine-N-oxide(TMAO),a metabolite secreted by gut microorganisms,and to investigate its application in moderate-intensity continuous training(MICT)intervention.Methods:C57BL6/J mice were randomly divided into four groups:normal mice(Nor,n=15);mice administered TMAO(TMAO,n=15);mice undergoing(Nor+MICT,n=15);mice undergoing(MICT)and administered TMAO(TMAO+MICT,n=15).Mice in the TMAO and TMAO+MICT groups received daily gavage of high-dose TMAO for 8 weeks,whereas those in the Nor+MICT and TMAO+MICT groups underwent MICT for 8 weeks(60 min per session,5 days per week,at 50%maximal running capacity).Cardiac function was evaluated using ultrasound,myocardial histology was examined using hematoxylin and eosin(HE)staining,and nuclear magnetic resonance(NMR)-based metabolomics was employed for multivariate statistical and metabolic pathway analyses.Results:Relative to the Nor group,TMAO-treated mice exhibited significant weight loss,elevated heart rate,and reduced ejection fraction and left ventricular fractional shortening,indicating cardiac impairment.Importantly,the TMAO+MICT group dem-onstrated significant improvements in these parameters compared to the TMAO group,alongside distinct alterations in myocardial metabolic profiles.TMAO altered five metabolic pathways relative to controls,whereas MICT induced significant changes in three pathways in TMAO-treated mice.Conclusion:Eight weeks of high-dose TMAO administration induced significant cardiac dysfunction in mice,which was effectively mitigated by MICT intervention.Consequently,this animal model serves as a valuable tool for investigating the mecha-nisms underlying the impact of MICT on cardiovascular diseases.
基金the European Research Council(ERC Advanced MechAGE-ERC-2016-ADG-741883)the Swiss National Science Foundation(no.188522).
文摘Age-related osteoporosis poses a significant challenge in musculoskeletal health;a condition characterized by reduced bone density and increased fracture susceptibility in older individuals necessitates a better understanding of underlying molecular and cellular mechanisms.Emerging evidence suggests that osteocytes are the pivotal orchestrators of bone remodeling and represent novel therapeutic targets for age-related bone loss.Our study uses the prematurely aged PolgD257A/D257A(PolgA)mouse model to scrutinize age-and sex-related alterations in musculoskeletal health parameters(frailty,grip strength,gait data),bone and particularly the osteocyte lacuno-canalicular network(LCN).Moreover,a new quantitative in silico image analysis pipeline is used to evaluate the alterations in the osteocyte network with aging.Our findings underscore the pronounced degenerative changes in the musculoskeletal health parameters,bone,and osteocyte LCN in PolgA mice as early as 40 weeks,with more prominent alterations evident in aged males.Our findings suggest that the PolgA mouse model serves as a valuable model for studying the cellular mechanisms underlying age-related bone loss,given the comparable aging signs and age-related degeneration of the bone and the osteocyte network observed in naturally aging mice and elderly humans.
基金supported by the National Research Foundation of Korea (NRF)funded by the Ministry of Science,ICT&Future Planning (2022R1A2C2006229,2022R1A6A3A01086868)Korea Dementia Research Project through the Korea Dementia Research Center (KDRC)funded by the Ministry of Health&Welfare and Ministry of Science and ICT,Republic of Korea (RS-2024-00345328)KIST Institutional Grant (2E32851)。
文摘Alzheimer'sdisease(AD)isaprogressive neurodegenerative disorder characterized by cognitive impairment and distinct neuropathological features,including amyloid-βplaques,neurofibrillary tangles,and reactive astrogliosis.Developing effective diagnostic,preventative,and therapeutic strategies for AD necessitates the establishment of animal models that accurately recapitulate the pathophysiological processes of the disease.Existing transgenic mouse models have significantly contributed to understanding AD pathology but often fail to replicate the complexity of human AD.Additionally,these models are limited in their ability to elucidate the interplay among amyloid-βplaques,neurofibrillary tangles,and reactive astrogliosis due to the absence of spatially and temporally specific genetic manipulation.In this study,we introduce a novel AD mouse model(APP/PS1-TauP301L-Adeno mice)designed to rapidly induce pathological symptoms and enhance understanding of AD mechanisms.Neurofibrillary tangles and severe reactive astrogliosis were induced by injecting AAVDJ-EF1a-hTauP301L-EGFP and Adeno-GFAP-GFP viruses into the hippocampi of 5-month-old APP/PS1 mice.Three months post-injection,these mice exhibited pronounced astrogliosis,substantial amyloid-βplaque accumulation,extensiveneurofibrillarytangles,accelerated neuronal loss,elevated astrocytic GABA levels,and significant spatial memory deficits.Notably,these pathological features were less severe in AAVTauP301L-expressing APP/PS1 mice without augmented reactive astrogliosis.These findings indicate an exacerbating role of severe reactive astrogliosis in amyloid-βplaque and neurofibrillary tangle-associated pathology.The APP/PS1-TauP301L-Adeno mouse model provides a valuable tool for advancing therapeutic research aimed at mitigating the progression of AD.
基金National Key R&D Program of China,Grant/Award Number:2023YFC3402000National Institutes for Food and Drug Control,State Key Laboratory of Drug Regulatory Science,Grant/Award Number:2023SKLDRS0124。
文摘Background:The precise insertion of large DNA fragments(>3–5 kb)remains one of the key obstacles in establishment of genetically modified murine models.Methods:A 21 kb large DNA fragment containing three tandemly linked copies of the human HRAS gene was inserted into the genome of C57BL/6J mouse,generating a mouse model designated as KI.C57-ras(or named NF-h HRAS).Whole-genome sequencing and Sanger sequencing were utilized to it confirm precise insertion and copy number.The stability of transgene expression among different generations was verified from multiple aspects using by digital PCR,western blot and DNA sequencing.To assess tumor susceptibility in the mouse model,N-Nitroso-N-methylurea(MNU)was administered at a dosage of 75 mg/kg.Histopathological examinations were conducted using hematoxylin and eosin(H&E)staining.Results:The HRAS DNA fragment was inserted into mouse chromosome 15E1 site,locating between 80623202 bp and 80625020 bp.NF-h HRAS mice exhibited stable inheritance and displayed consistent phenotypes across individuals.Moreover,this mouse model exhibited a high susceptibility to carcinogens.Upon administration of MNU the earliest mortality onset was earlier than that of wild-type littermates(day 65 vs.day 78 for male and day 56 vs.day 84 for female).Notably,100%of the NF-h HRAS transgenic mice developed tumors,with approximately 84%of male NF-h HRAS mice exhibiting specific tumor types,such as squamous cell carcinoma or squamous cell papilloma,which was consistent with the previously reported carcinogenic rasH2 mouse model.The types of tumors and the target organs exhibited diversity in NFh HRAS mice,while the spontaneous tumor incidence remained low(1/50).Conclusions:The NF-h HRAS mice demonstrated excellent genetic stability,a reproducible phenotype,and high susceptibility to carcinogens,indicating their potential utility in non-clinical safety evaluations of drugs as per the S1B guidelines issued by the ICH(The International Council for Harmonization of Technical Requirements for Pharmaceuticals for Human Use).
基金We thank D.D.Meigs(University of Nebraska Medical Center)and Tonya Cejka(freelance English editor)for editing assistance.C.B.G.is funded by NIH grants R35HG010719,R21GM129559,R21AI143394 and R21DA046831.M.O.is funded by 2016–2017 Tokai University School of Medicine Project Research,the Research Aid from the Institute of Medical Sciences in Tokai University,Grant-in-Aid for Scientific Research(25290035)from MEXTa Grant-in-Aid for Challenging Exploratory Research(15K14371)from JSPS.
文摘Genetically engineered mouse(GEM)models are commonly used in biomedical research.Generating GEMs involve complex set of experimental procedures requiring sophisticated equipment and highly skilled technical staff.Because of these reasons,most research institutes set up centralized core facilities where custom GEMs are created for research groups.Researchers,on the other hand,when they begin thinking about generating GEMs for their research,several questions arise in their minds.For example,what type of model(s)would be best useful for my research,how do I design them,what are the latest technologies and tools available for developing my model(s),and finally how to breed GEMs in my research.As there are several considerations and options in mouse designs,and as it is an expensive and time-consuming endeavor,careful planning upfront can ensure the highest chance of success.In this article,we provide brief answers to several frequently asked questions that arise when researchers begin thinking about generating mouse model(s)for their work.
文摘Parkinson's disease,the most common movement disorder,has a strong neuroinflammatory aspect.This is evident by increased pro-inflammatory cytokines in the serum,and the presence of activated microglial cells,and inflammatory cytokines in the substantia nigra of post-mortem brains as well as cerebrospinal fluid of Parkinson's disease patients.The central and peripheral neuroinflammatory aspects of Parkinson's disease can be investigated in vivo via administration of the inflammagen lipopolysaccharide,a component of the cell wall of gram-negative bacteria.In this mini-review,we will critically evaluate different routes of lipopolysaccharide administration(including intranasal systemic and ste reotasic),their relevance to clinical Parkinson's disease as well as the recent findings in lipopolysaccharide mouse models.We will also share our own expe riences with systemic and intrastriatal lipopolysaccharide models in C57BL/6 mice and will discuss the usefulness of lipopolysaccharide mouse models for future research in the field.
文摘Background:Most mutations in the COL6A3 gene lead to collagen VI-related myopathies.This is due to a reduced expression or mislocalization of the COL6A3 protein.Therefore,studying the consequence of knocking out the Col6a3 gene in mouse models is relevant,but the Col6a3 mouse models reported so far do not entirely abolish COL6A3 protein expression.Methods:Here,we present the development,validation and preliminary phenotypic characterization of a novel CRISPR-based knockout mouse model targeting Col6a3 exon 3(Col6a3^(d3/d3)).Results:In this mouse model,Col6a3 mRNA is still expressed at a similar level to wild-type littermates,although the expected protein is undetectable by mass spectrometry.Histological analysis of Col6a3^(d3/d3)quadriceps revealed an abnormally high frequency of muscle cells with internally nucleated muscle cells,consistent with a myopathy phenotype.Interestingly,Col6a3^(d3/d3)mice are smaller in size,with their fat,muscle,and bone kept proportional compared to wild-type littermates.Conclusions:In summary,we performed the validation and preliminary phenotypic characterization of a novel Col6a3 knockout mouse model that could be further characterized and used to study COL6A3 biology and model collagen VI-associated diseases.
基金supported by the National Natural Science Foundation of China (32471049,32170984,32471188,32200802)Natural Science Foundation of Shandong Province (ZR2023QH110)。
文摘Substantial evidence points to the early onset of peripheral inflammation in the development of Parkinson's disease(PD),supporting the“body-first”hypothesis.However,there remains a notable absence of PD-specific animal models induced by inflammatory cytokines.This study introduces a novel mouse model of PD driven by the proinflammatory cytokine CXCL1,identified in our previous research.The involvement of CXCL1 in PD pathogenesis was validated using subacute and chronic MPTP-induced mouse models.Based on these findings,2-month-old C57BL/6J mice were intravenously administered CXCL1(20 ng/kg/day)for 2 weeks(5 days per week),successfully replicating motor deficits and pathological alterations in the substantia nigra observed in the chronic MPTP model.These results demonstrate the potential of CXCL1-induced inflammation as a mechanism for PD modeling.The model revealed activation of the PPAR signaling pathway in CXCL1-mediated neuronal damage by CXCL1.Linoleic acid,a PPAR-γactivator,significantly mitigated MPTPand CXCL1-induced toxicity and reduced serum CXCL1levels.In addition,the CXCL1-injected mouse model shortened the timeline for developing chronic PD mouse model to 2 weeks,offering an efficient platform for studying inflammation-driven processes in PD.The findings provide critical insights into the inflammatory mechanisms underlying PD and identify promising therapeutic targets for intervention.
基金CAMS Innovation Fund for Medical Sciences,Grant/Award Number:CIFMS,2021-I2M-1-024The Joint Fund for the Department of Science and Technology of Yunnan Province-Kunming Medical University,Grant/Award Number:202201AY070001-007+1 种基金Open Research Fund Project of Yunnan Provincial Key Laboratory of Pharmacology of Natural Medicines,Grant/Award Number:YKLPNP-G2403The Science and Technology Leading Talent Program of Yunnan Province,Grant/Award Number:202405AB350002。
文摘Background:Spinocerebellar ataxia type 2(SCA2)is a neurodegenerative disease marked by significant clinical and genetic heterogeneity,primarily caused by expanded CAG mutations in the ATXN2 gene.The unstable expansion of CAG repeats disrupts the genetic stability of animal models,which is detrimental to disease research.Methods:In this study,we established a mouse model in which CAG repeats do not undergo microsatellite instability(MSI)across generations.A humanized ATXN2 cDNA with four CAA interruptions within 73 CAG expansions was inserted into the Rosa26 locus of C57BL/6J mice.A 23 CAG control mouse model was also generated to verify ATXN2 integration and expression.Results:In our model,the number of CAG repeats remained stable during transmission,with no CAG repeat expansion observed in 64 parent-to-offspring transmissions.Compared with SCA2-Q23 mice,SCA2-Q73 mice exhibited progressive motor impairment,reduced Purkinje cell count and volume(indicative of cell atrophy),and muscle atrophy.These observations in the mice suggest that the behavioral and neuropathological phenotypes may reflect the features of SCA2 patients.RNA-seq analysis of the gastrocnemius muscle in SCA2-Q73 mice showed significant changes in muscle differentiation and development gene expression at 56 weeks,with no significant differences at 16 weeks compared to SCA2-Q23 mice.The expression level of the Myf6 gene significantly changed in the muscles of aged mice.Conclusion:In summary,the establishment of this model not only provides a stable animal model for studying CAG transmission in SCA2 but also indicates that the lack of long-term neural stimulation leads to muscle atrophy.
基金supported by the Grants-in-Aid for Scientific Research from Japan Society for the Promotion of Science KAKENHI 22K09110.
文摘Murine subarachnoid hemorrhage(SAH)induced using the filament perforation method is a useful in vivo experimental model to investigate the pathophysiological mechanisms in the brain underlying SAH.However,identifying mice with comorbid acute neurogenic pulmonary edema(NPE),a life-threatening systemic consequence often induced by SAH,in this model is difficult without histopathological investiga-tions.Herein,we present an imaging procedure involving dual-energy X-ray absorp-tiometry(DXA)to identify NPE in a murine model of SAH.We quantified the lung lean mass(LM)and compared the relationship between micro-computed tomography(CT)evidence of Hounsfield unit(HU)values and histopathological findings of PE.Of the 85 mice with successful induction of SAH by filament perforation,16(19%)had NPE,as verified by postmortem histology.The DXA-LM values correlate well with CT-HU levels(r=0.63,p<0.0001).Regarding the relationship between LM and HU in mice with post-SAH NPE,the LM was positively associated with HU values(r2=0.43;p=0.0056).A receiver operating characteristics curve of LM revealed a sensitivity of 87%and specificity of 57%for detecting PE,with a similar area under the curve as the HU(0.79±0.06 vs.0.84±0.07;p=0.21).These data suggest that confirming acute NPE using DXA-LM is a valuable method for selecting a clinically relevant murine NPE model that could be used in future experimental SAH studies.
基金Hubei Natural Science Foundation of China,Grant/Award Number:2024AFB593。
文摘Background:Rabies virus(RABV)-derived neuronal tracing tools are extensively applied in retrograde tracing due to their strict retrograde transsynaptic transfer property and low neurotoxicity.However,the RABV infection and expression of fluorescence products would be gradually cleared while the infected neurons still survive,a phenomenon known as non-cytolytic immune clearance(NCLIC).This phenomenon introduced the risk of fluorescence loss and led to the omission of a subset of neurons that should be labeled,thereby interfering in the analysis of tracing results.Methods:To compensate for the fluorescence loss problem,in this study,we developed a novel marker footprints(MF)mouse,involving a Cre recombinase-dependent red fluorescent reporter system and systemic expression of glycoprotein(G)and ASLV-A receptor(TVA).Using this mouse model combined with the well-developed RABV-EnvA-ΔG-GFP-Cre viral tool,we developed a novel green-to-red spectral labeling strategy.Results:Neurons in the MF mouse could be co-labeled with green fluorescence from the very quick expression of the viral tool and with red fluorescence from the relatively slow expression of the neuron itself,so neurons undergoing NCLIC with green fluorescence loss could be relabeled red.Furthermore,newly infected neurons could be labeled green and other neurons could be labeled yellow due to the temporal expression difference between the two fluorescent proteins.Conclusions:This is the first polysynaptic retrograde tracing labeling strategy that could label neurons using spectral fluorescence colors with only one injection of the viral tool,enabling its application in recognizing the labeling sequence of neurons in brain regions and enhancing the spatiotemporal resolution of neuronal tracing.
基金supported by NIH/NIDCR grant R01DE025664 to IPC.
文摘Craniometaphyseal dysplasia(CMD),a rare craniotubular disorder,occurs in an autosomal dominant(AD)or autosomal recessive(AR)form.CMD is characterized by hyperostosis of craniofacial bones and metaphyseal flaring of long bones.Many patients with CMD suffer from neurological symptoms.The pathogenesis of CMD is not fully understood.
基金supported in part by grants from the Strategic Priority Research Program of the Chinese Academy of Sciences(XDB0490000 to Z.H.)National Key Research and Development Program(2021YFF0702002 to J.L.,2022YFC2303300 to Z.H.,and 2023YFC2305900 to M.W.)+3 种基金“Youth Commando”project(2023QNTJ-02 TO J.L.)Key Project(2024JZZD-02 to Z.H.)of State Key Laboratory of Virology and BiosafetyWuhan Institute of Virology,the National Natural Science Foundation of China(U22A20336 to Z.H.and Y.Z.)Wuhan Natural Science Foundation(202404071010067 to M.W.and 202404071010068 to J.L.).
文摘Dear Editor,Crimean–Congo hemorrhagic fever(CCHF),caused by the CCHF virus(CCHFV),is a severe tick-borne illness with a wide geographical distribution,posing a significant threat with case fatality rates ranging from 5%to 70%(Hawman and Feldmann,2023).Due to the lack of approved vaccines and therapeutics,the World Health Organization(WHO)has listed CCHF as one of the priority diseases(Semper et al.,2024).CCHF initially presents as a nonspecific febrile illness,characterized by fever,malaise,myalgia,and nausea,which can rapidly progress to hemorrhagic disease.The hemorrhagic stage is particularly pronounced in severe cases,with rapid progression to disseminated intravascular coagulation(DIC),overt bleeding,kidney or liver failure,and shock(Frank et al.,2024).Up to date,there is an absence of a suitable animal model that can accurately mimic the coagulopathy and bleeding associated with CCHFV infection.Consequently,our understanding of the pathogenic mechanisms underlying these conditions remains limited(Rodriguez et al.,2022).
基金Supported by The Shanghai Municipal Natural Science Foundation,No.11ZR1405500the Shanghai Municipal Science and Technology Commission grant,No.13140902401
文摘AIM: To establish an orthotopic mouse model of pancreatic cancer that mimics the pathological features of exocrine pancreatic adenocarcinoma.
基金funding from the Innovation Fund Denmark(grant number 2040-00034B).
文摘Background:The current understanding of diabetic kidney disease(DKD)has significant gaps regarding the underlying pathogenesis.In this study,we aimed to characterize the temporal progression of DKD using a state-of-the-art mouse model of hypertension-accelerated disease,integrating kidney biomarker analysis,histopathology,and glomerular transcriptomic profiling.Methods:Female diabetic db/db mice received a single intravenous dose of adenoassociated virus-mediated renin overexpression(ReninAAV,week 5)and underwent uninephrectomy(UNx,week 4).db/db UNx-ReninAAV mice were terminated at weeks 1,4,8,and 12(n=7–8 per group).Female db/m mice were used as healthy controls.Study endpoints included plasma and urine biochemistry,glomerulosclerosis scoring,quantitative kidney histology,and RNA sequencing of glomeruli isolated using lasercapture microdissection.Results:db/db UNx-ReninAAV mice developed progressive albuminuria(from week 4)and glomerulosclerosis(from week 8).A pathway analysis of clustered gene regulations revealed broad glomerular transcriptome perturbations with signatures of increased extracellular matrix(ECM)turnover from week 8 and early onset of metabolic dysfunction.Markers of glomerular cell types and injury exhibited temporal regulation over the course of DKD,with early and sustained downregulation of endothelial markers,heterogeneous regulation of podocyte markers,and significant mesangial and parietal epithelial aberrations.Furthermore,the upregulation of cell injury markers confirmed progressive glomerular injury in the model.Conclusion:The db/db UNx-ReninAAV mouse model exhibits distinct temporal dynamics in glomerular cell markers,metabolic dysregulation,ECM remodeling,and injury.Together,these results highlight the utility of the db/db UNx-ReninAAV model as a relevant preclinical platform for studying progressive DKD.
基金The National Natural Science Foundation of China,Grant/Award Number:82204006Science and Technology Project of Hebei Education Department,Grant/Award Number:QN2022009+1 种基金Medical Science Research Project of Hebei,Grant/Award Number:20221534National Natural Science Foundation of Hebei Province,Grant/Award Number:H2024209038。
文摘Background:It is well recognized that developing new animal models,refining the existing mouse models,and thoroughly characterizing their features are essential for gaining a deeper understanding of rosacea pathogenesis and for advancing therapeutic strategies in this direction.Accordingly,we aimed to characterize the pathological features of a long-term LL-37-induced mouse model of rosacea and to compare the disease manifestations and pathophysiological characteristics between short-term and long-term LL-37-induced models.A key focus was to investigate differential gene expression and the underlying mechanisms of immune system dysregulation in these models.Methods:We comparatively assessed skin lesion manifestations,the extent of inflammatory infiltration,sebaceous gland alterations,fibrosis,and angiogenesis in both models.Assessments were performed using photographic documentation,hematoxylin-eosin(HE)staining,Van Gieson's(VG)staining,immunohistochemistry,and Western blotting.Furthermore,we employed RNA sequencing to analyze differential gene expression in mouse skin.The RNA sequencing data were validated using immunofluorescence staining and Western blotting,with a specific focus on gene variations and mechanisms related to immune system dysregulation.Results:Mice subjected to long-term LL-37 induction developed rosacea-like pathological features,including angiogenesis,thickened skin tissue,and sebaceous gland hypertrophy.In the short-term LL-37-induced model,immune dysregulation primarily involved the innate immune response.However,long-term LL-37 induction resulted in significant activation of both innate and adaptive immune responses.Conclusion:The long-term LL-37-induced mouse model offers a valuable animal model for the detailed investigation of the pathological mechanisms driving moderate-to-severe rosacea with prolonged disease duration.Importantly,this model provides a significant experimental foundation for exploring the potential role of immune system dysregulation in rosacea pathogenesis.
