Non-human primate models in drug addiction deserve more attention

Dear Editor, The process of relapse involves firm or aberrant memories of environmental cues associated with drug craving or addiction. To date, it is not known where these memories are stored in the brain, what kinds of regulatory biological factors or molecules are involved, nor why it is so difficult to stop addiction psychologically. Currently, rodent animal models, such as the self-administration and conditioning place preference / aversion paradigm are still widely used in the studies of drug withdrawal syndromes or drug-associate memories. However, the differences between humans and rodents--particularly in terms of genetics, and pathology and pharmacology--have significantly limited the application of further studies on this topic. Essentially, rodents lack the longterm or life-time memories humans possess and lose their drug-associated memory only after a few weeks of withdrawal.

Characteristics of a primate model of focal motor cortical seizures suitable for preclinical testing of therapies like DBS

Background and objective: Generating and characterizing primate models of epileptic seizures are important for understanding pathophysiology of diseases and establishing preclinical efficacy of novel therapies like Deep Brain Stimulation. A focal motor epilepsy model is described here. Method: Seizures were obtained after intracortical penicillin injection into the motor strip through a cannula in two awake monkeys and electrocorticograms were recorded by epidural screws. Seizures were analyzed and compared for number, average duration of each seizure and total duration of ictal activity. Pharmaco-resistance for antiepileptic drug was tested by administration of Diazepam during seizures. Results: A motor status with seizures mimicking those seen in Kojevnikov’s syndrome was easily generated several minutes after penicillin injection and lasted 24 h on an average. The model thus characterized appears stable and consistent. There is no significant variation between experiments in individual primate as well as between two specimens. Diazepam though reduced the total duration of seizures, failed to abolish behavioural seizures. Conclusion: This model represents a good alternative model for preclinical research aiming at testing novel therapies because seizures are obtained on demand, last up to 24 h after a single penicillin injection, are stable and resistant to Diazepam.

Nonhuman primate models of focal cerebral ischemia

Rodents have been widely used in the production of cerebral ischemia models. However, successful therapies have been proven on experimental rodent stroke model, and they have often failed to be effective when tested clinically. Therefore, nonhuman primates were recommended as the ideal alternatives, owing to their similarities with the human cerebrovascular system, brain metabolism, grey to white matter ratio and even their rich behavioral repertoire. The present review is a thorough summary of ten methods that establish nonhuman primate models of focal cerebral ischemia; electrocoagulation, endothelin-1-induced occlusion, microvascular clip occlusion, autologous blood clot embolization, balloon inflation, microcatheter embolization, coil embolization, surgical suture embolization, suture, and photochemical induction methods. This review addresses the advantages and disadvantages of each method, as well as precautions for each model, compared nonhuman primates with rodents, different species of nonhuman primates and different modeling methods. Finally it discusses various factors that need to be considered when modelling and the method of evaluation after modelling. These are critical for understanding their respective strengths and weaknesses and underlie the selection of the optimum model.

How can we establish animal models of HIV-associated lymphoma?

Human immunodeficiency virus(HIV)infection is strongly associated with a height-ened incidence of lymphomas.To mirror the natural course of human HIV infection,animal models have been developed.These models serve as valuable tools to inves-tigate disease pathobiology,assess antiretroviral and immunomodulatory drugs,ex-plore viral reservoirs,and develop eradication strategies.However,there are currently no validated in vivo models of HIV-associated lymphoma(HAL),hampering progress in this crucial domain,and scant attention has been given to developing animal models dedicated to studying HAL,despite their pivotal role in advancing knowledge.This re-view provides a comprehensive overview of the existing animal models of HAL,which may enhance our understanding of the underlying pathogenesis and approaches for malignancies linked to HIV infection.

Meeting report:the 4^(th) symposium on animal models of non-human primates in Kunming,Yunnan,China

From 2 to 4 November, 2016, the 4th Symposium on Animal Models of Non-Human Primates （NHP） was held in Kunming, Yunnan, China. This meeting was organized by the Key Laboratory of Animal Models and Human Disease Mechanisms of the Chinese Academy of Sciences （CAS） ＆ Yunnan Province Kunming Primate Research Center （KPRC）, Zoological Research, and Kunming Institute of Zoology （KIZ）, CAS.

Establishment of AIDS Animal Model with SIVmac239 Infected Chinese Rhesus Monkey

In the present research,two Chinese rhesus monkeys were inoculated intravenously with 5000 TCID50 of SIVmac239. The changes in the numbers of CD4+ T lymphocyte in peripheral blood,plasma viral loads,proviral DNA and humoral antibodies against virus were periodically monitored during 121 days. At the early stage of infection,proviral DNA had been detected in PBMCs,and infectious SIVmac239 virus had been isolated from PBMCs. At the same period,the numbers of CD4+ T lymphocytes were significantly decreased,and maintained at low level during the 121-day period of infection. Plasma viral loads reached the peak at week 2 post-inoculation and kept at a steady state subsequently. Moreover,antibodies against viral proteins were detected from plasma. All the results showed that the two Chinese rhesus monkeys had been infected with SIVmac239 successfully. This animal model can be applied for further AIDS researches.

Generation of nonhuman primate retinitis pigmentosa model by in situ knockout of RHO in rhesus macaque retina

Retinitis pigmentosa(RP)is a form of inherited retinal degenerative diseases that ultimately involves the macula,which is present in primates but not in the rodents.Therefore,creating nonhuman primate(NHP)models of RP is of critical importance to study its mechanism of pathogenesis and to evaluate potential therapeutic options in the future.Here we applied adeno-associated virus(AAV)-delivered CRISPR/SaCas9 technology to knockout the RHO gene in the retinae of the adult rhesus macaque(Macaca mulatta)to investigate the hypothesis whether non-germline mutation of the RHO gene is sufficient to recapitulate RP.Through a series of studies,we were able to demonstrate successful somatic editing of the RHO gene and reduced RHO protein expression.More importantly,the mutant macaque retinae displayed clinical RP phenotypes,including photoreceptor degeneration,retinal thinning,abnormal rod subcellular structures,and reduced photoresponse.Therefore,we suggest somatic editing of the RHO gene is able to phenocopy RP,and the reduced time span in generating NHP mutant accelerates RP research and expands the utility of NHP model for human disease study.

Delayed severe cytokine storm and immune cell infiltration in SARS-CoV-2-infected aged Chinese rhesus macaques

As of June 2020, Coronavirus Disease 2019(COVID-19) has killed an estimated 440 000 people worldwide, 74% of whom were aged ≥65 years,making age the most significant risk factor for death caused by severe acute respiratory syndrome coronavirus 2(SARS-CoV-2) infection. To examine the effect of age on death, we established a SARSCoV-2 infection model in Chinese rhesus macaques(Macaca mulatta) of varied ages. Results indicated that infected young macaques manifested impaired respiratory function, active viral replication, severe lung damage, and infiltration of CD11b^+ and CD8^+ cells in lungs at one-week post infection(wpi), but also recovered rapidly at 2 wpi. In contrast, aged macaques demonstrated delayed immune responses with a more severe cytokine storm, increased infiltration of CD11b^+ cells, and persistent infiltration of CD8^+ cells in the lungs at 2 wpi. In addition,peripheral blood T cells from aged macaques showed greater inflammation and chemotaxis, but weaker antiviral functions than that in cells from young macaques. Thus, the delayed but more severe cytokine storm and higher immune cell infiltration may explain the poorer prognosis of older aged patients suffering SARS-CoV-2 infection.

The 3rd Symposium on Animal Models of Primates——The Application of Non-Human Primates to Basic Research and Translational Medicine

In order to understand the fundamental questions of the biology of life and to duplicate the pathogenesis of human diseases, animal models using different experimental animals, such as rodents, Drosophila, Caenorhabditis elegans, and zebrafish, have been established and used widely for many decades. The controllability of environmental conditions, the high reproducibility, the ease of scale and the comparability of results, as well as the ability to use different standards for ethical protocols, all make an animal model the ideal tool for carrying out studies on human diseases and the development of novel pharmaceuticals and new therapies （Xue et al., 2014）. An ideal animal model should reflect the complete spectra of a specific human disease, with similar features on the following key issues： （1） genetic basis; （2） anatomy and physiology; （3） pathological response（s） and underlying mechanism（s）; （4） phenotypic endpoints as clinical studies; （5） responsiveness to known drugs with clinical efficacy; and （6） prediction of clinical efficacy （McGonigle and Ruggeri, 2014）.

Recent Advances in Animal Models of Zika Virus Infection

An infection by Zika virus(ZIKV), a mosquito-borne flavivirus, broke out in South American regions in 2015, and recently showed a tendency of spreading to North America and even worldwide. ZIKV was first detected in 1947 and only 14 human infection cases were reported until 2007. This virus was previously observed to cause only mild flu-like symptoms.However, recent ZIKV infections might be responsible for the increasing cases of neurological disorders such as GuillainBarre′ syndrome and congenital defects, including newborn microcephaly. Therefore, researchers have established several animal models to study ZIKV transmission and pathogenesis, and test therapeutic candidates. This review mainly summarizes the reported animal models of ZIKV infection, including mice and non-human primates.

Induction of core symptoms of autism spectrum disorder by in vivo CRISPR/Cas9-based gene editing in the brain of adolescent rhesus monkeys

Although CRISPR/Cas9-mediated gene editing is widely applied to mimic human disorders,whether acute manipulation of disease-causing genes in the brain leads to behavioral abnormalities in non-human primates remains to be determined.Here we induced genetic mutations in MECP2,a critical gene linked to Rett syndrome(RTT)and autism spectrum disorders(ASD),in the hippocampus(DG and CA1–4)of adolescent rhesus monkeys(Macaca mulatta)in vivo via adeno-associated virus(AAV)-delivered Staphylococcus aureus Cas9 with small guide RNAs(sg RNAs)targeting MECP2.In comparison to monkeys injected with AAV-Sa Cas9 alone(n=4),numerous autistic-like behavioral abnormalities were identified in the AAV-Sa Cas9-sg MECP2-injected monkeys(n=7),including social interaction deficits,abnormal sleep patterns,insensitivity to aversive stimuli,abnormal hand motions,and defective social reward behaviors.Furthermore,some aspects of ASD and RTT,such as stereotypic behaviors,did not appear in the MECP2 gene-edited monkeys,suggesting that different brain areas likely contribute to distinct ASD symptoms.This study showed that acute manipulation of disease-causing genes via in vivo gene editing directly led to behavioral changes in adolescent primates,paving the way for the rapid generation of genetically engineered non-human primate models for neurobiological studies and therapeutic development.

Pathogenic analysis of coxsackievirus A10 in rhesus macaques

Coxsackievirus A10(CV-A10)is one of the etiological agents associated with hand,foot and mouth disease(HFMD)and also causes a variety of illnesses in humans,including pneumonia,and myocarditis.Different people,particularly young children,may have different immunological responses to infection.Current CV-A10 infection animal models provide only a rudimentary understanding of the pathogenesis and effects of this virus.The characteristics of CV-A10 infection,replication,and shedding in humans remain unknown.In this study,rhesus macaques were infected by CV-A10 via respiratory or digestive route to mimic the HFMD in humans.The clinical symptoms,viral shedding,inflammatory response and pathologic changes were investigated in acute infection(1–11 day post infection)and recovery period(12–180 day post infection).All infected rhesus macaques during acute infection showed obvious viremia and clinical symptoms which were comparable to those observed in humans.Substantial inflammatory pathological damages were observed in multi-organs,including the lung,heart,liver,and kidney.During the acute period,all rhesus macaques displayed clinical signs,viral shedding,normalization of serum cytokines,and increased serum neutralizing antibodies,whereas inflammatory factors caused some animals to develop severe hyperglycemia during the recovery period.In addition,there were no significant differences between respiratory and digestive tract infected animals.Overall,all data presented suggest that the rhesus macaques provide the first non-human primate animal model for investigating CV-A10 pathophysiology and assessing the development of potential human therapies.