Skip to main content Accessibility help

We use cookies to distinguish you from other users and to provide you with a better experience on our websites. Close this message to accept cookies or find out how to manage your cookie settings.

Close cookie message
×
Hostname: page-component-8448b6f56d-tj2md Total loading time: 0 Render date: 2024-04-23T12:31:47.701Z Has data issue: false hasContentIssue false

7 - Microcebus murinus – a unique primate for modeling human brain disorders, including Alzheimer's disease and bovine spongiform encephalopathy

from Part II - Methods for studying captive and wild cheirogaleids

Published online by Cambridge University Press:  05 March 2016

By
Jean-Michel Verdier  and
Nadine Mestre-Francés
Edited by
Shawn M. Lehman ,
Ute Radespiel  and
Elke Zimmermann
Jean-Michel Verdier
Affiliation:
Université de Montpellier, Paris, France
Nadine Mestre-Francés
Affiliation:
Université de Montpellier, Paris, France
Shawn M. Lehman
Affiliation:
University of Toronto
Ute Radespiel
Affiliation:
University of Veterinary Medicine Hannover, Foundation
Elke Zimmermann
Affiliation:
University of Veterinary Medicine Hannover, Foundation
Get access

Summary

Introduction

The continuing increase in life expectancy in the developed world is one of humanity's greatest successes. However, the rising number of older people will have economic and societal consequences, as well as major effects on the occurrence of age-related diseases, especially neurodegenerative disorders such as Alzheimer's disease (AD). Combating AD is one of the most important medical, societal, and economical challenges (Lo et al., 2014). On February 3, 2009, the European Parliament adopted a written declaration on the priorities for fighting AD (No. 80/2008). This action plan was designed to promote research into the causes, prevention, and treatment of this disease.

Unfortunately, despite intensive research, the pathogenetic mechanisms and risk factors of AD are still poorly understood, and no effective treatments are available. One of the reasons underlying the lack of successful AD therapies is the lack of a relevant animal model, despite the large variety of models that have been created (reviewed in Woodruff-Pak, 2008). Transgenic mice are the major animal model for AD studies (Chin, 2011). They have been proven valuable for modeling various aspects of AD neuropathology, such as amyloid-β(Aβ) deposits, neuritic plaques, gliosis, synaptic alterations, and signs of neurodegeneration, as well as associated cognitive changes (McGowan et al., 2006; Kitazawa et al., 2012). Despite these similarities, there are important neuropathological and behavioral differences between these transgenic mouse models and AD in humans. Furthermore, experimental findings and conclusions are highly dependent on model systems and even animal strains, making it difficult to transfer findings to the human condition. Introducing a mutated human gene into a mouse does not necessarily trigger the cascade of events encountered in human disease (Langui et al., 2007). Regarding AD, clinical trials have been stopped because of the death of several patients due to encephalopathies (Robinson et al., 2004). Indeed, due to high social pressures, the results obtained in transgenic mice have been rapidly and directly translated into human treatments. The subsequent disappointing results demonstrated that observations in these transgenic models cannot necessarily be extrapolated to humans. There are several key criteria to increase the validity of a model, including requiring:

  1. (1)similar symptoms as observed in clinical manifestations;

  2. (2)similar underlying biology; and

  3. (3)a responsiveness to measure clinically effective therapeutic drugs by assessing true readouts.

Type
Chapter
Information
The Dwarf and Mouse Lemurs of Madagascar
Biology, Behavior and Conservation Biogeography of the Cheirogaleidae
 , pp. 161 - 173
Publisher: Cambridge University Press
Print publication year: 2016

Access options

Get access to the full version of this content by using one of the access options below. (Log in options will check for institutional or personal access. Content may require purchase if you do not have access.)

References

Rassoul, R Abdel, Alves, S, Pantesco, V, et al. 2010. Distinct transcriptome expression of the temporal cortex of the primate Microcebus murinus during brain aging versus Alzheimer's disease-like pathology. PloS One 5(9):e12770.Google Scholar
Apetrei, C, Pandrea, I, Mellors, JW. 2012. Nonhuman primate models for HIV cure research. PLoS Pathogens 8:e1002892.Google Scholar
Aujard, F, Nemoz-Bertholet, F. 2004. Response to urinary volatiles and chemosensory function decline with age in a prosimian primate. Physiology and Behavior 81:639–644.Google Scholar
Baker, HF, Ridley, RM, Wells, GA. 1993. Experimental transmission of BSE and scrapie to the common marmoset. Veterinary Record 132:403–406.Google Scholar
Baker, HF, Ridley, RM, Wells, GA, Ironside, JW. 1998. Prion protein immunohistochemical staining in the brains of monkeys with transmissible spongiform encephalopathy. Neuropathology and Applied Neurobiology 24:476–486.Google Scholar
Ballatore, C, Lee, VM, Trojanowski, JQ. 2007. Tau-mediated neurodegeneration in Alzheimer's disease and related disorders. Nature Reviews: Neuroscience 8:663–672.Google Scholar
Barone, E, Mancuso, C, Domenico, F Di, et al. 2012. Biliverdin reductase-A: a novel drug target for atorvastatin in a dog pre-clinical model of Alzheimer disease. Journal of Neurochemistry 120:135–146.Google Scholar
Beltran, WA, Vanore, M, Ollivet, F, et al. 2007. Ocular findings in two colonies of gray mouse lemurs (Microcebus murinus). Veterinary Ophthalmology 10:43–49.Google Scholar
Bons, N, Jallageas, V, Silhol, S, et al. 1995. Immunocytochemical characterization of Tau proteins during cerebral aging of the lemurian primate Microcebus murinus. Comptes Rendus de l'Académie des Sciences Série III: Sciences de la Vie 318:741–747.Google Scholar
Buccafusco, JJ. 2008. Estimation of working memory in macaques for studying drugs for the treatment of cognitive disorders. Journal of Alzheimer's Disease 15:709–720.Google Scholar
Bystron, I, Rakic, P, Molnar, Z, Blakemore, C. 2006. The first neurons of the human cerebral cortex. Nature Neuroscience 9:880–886.Google Scholar
Casalone, C, Zanusso, G, Acutis, P, et al. 2004. Identification of a second bovine amyloidotic spongiform encephalopathy: molecular similarities with sporadic Creutzfeldt–Jakob disease. Proceedings of the National Academy of Sciences of the United States of America 101:3065–3070.Google Scholar
Chin, J. 2011. Selecting a mouse model of Alzheimer's disease. Methods in Molecular Biology 670:169–189.Google Scholar
Contreras, JL, Smyth, CA, Curiel, DT, Eckhoff, DE. 2004. Nonhuman primate models in type 1 diabetes research. ILAR Journal 45:334–342.Google Scholar
Cotman, CW, Head, E. 2008. The canine (dog) model of human aging and disease: dietary, environmental and immunotherapy approaches. Journal of Alzheimer's Disease 15:685–707.Google Scholar
Dehay, C, Kennedy, H. 2007. Cell-cycle control and cortical development. Nature Reviews: Neuroscience 8:438–450.Google Scholar
Delacourte, A, Sautiere, PE, Wattez, A, et al. 1995. Biochemical characterization of Tau proteins during cerebral aging of the lemurian primate Microcebus murinus. Comptes Rendus de l'Académie des Sciences Série III: Sciences de la Vie 318:85–89.Google Scholar
Dhenain, M, Chenu, E, Hisley, CK, Aujard, F, Volk, A. 2003. Regional atrophy in the brain of lissencephalic mouse lemur primates: measurement by automatic histogram-based segmentation of MR images. Magnetic Resonance in Medicine 50:984–992.Google Scholar
Dudas, S, Yang, J, Graham, C, et al. 2010. Molecular, biochemical and genetic characteristics of BSE in Canada. PLoS ONE 5:e10638.Google Scholar
Frost, JL, Le, KX, Cynis, H, et al. 2013. Pyroglutamate-3 amyloid-beta deposition in the brains of humans, non-human primates, canines, and Alzheimer disease-like transgenic mouse models. American Journal of Pathology 183:369–381.Google Scholar
Garcia-Cabezas, MA, Martinez-Sanchez, P, Sanchez-Gonzalez, MA, Garzon, M, Cavada, C. 2009. Dopamine innervation in the thalamus: monkey versus rat. Cerebral Cortex 19:424–434.Google Scholar
Gilman, S, Koller, M, Black, RS, et al. 2005. Clinical effects of Abeta immunization (AN1792) in patients with AD in an interrupted trial. Neurology 64:1553–1562.Google Scholar
Grundke-Iqbal, I, Iqbal, K, Tung, YC, et al. 1986. Abnormal phosphorylation of the microtubule-associated protein tau (tau) in Alzheimer cytoskeletal pathology. Proceedings of the National Academy of Sciences of the United States of America 83:4913–4917.Google Scholar
Hagiwara, K, Yamakawa, Y, Sato, Y, et al. 2007. Accumulation of mono-glycosylated form-rich, plaque-forming PrPSc in the second atypical bovine spongiform encephalopathy case in Japan. Japanese Journal of Infectious Diseases 60:305–308.Google Scholar
Head, E, Pop, V, Vasilevko, V, et al. 2008. A two-year study with fibrillar beta-amyloid (Abeta) immunization in aged canines: effects on cognitive function and brain Abeta. Journal of Neuroscience 28:3555–3566.Google Scholar
Heydecke, H, Schwibbe, M, Kaumanns, W. 1986. Studies on social behaviour of aging rhesus monkeys (Macaca mulatta). Primate Report 15:41–59.Google Scholar
Jacobs, JG, Langeveld, JP, Biacabe, AG, et al. 2007. Molecular discrimination of atypical bovine spongiform encephalopathy strains from a geographical region spanning a wide area in Europe. Journal of Clinical Microbiology 45:1821–1829.Google Scholar
Janecka, JE, Miller, W, Pringle, TH, et al. 2007. Molecular and genomic data identify the closest living relative of primates. Science 318:792–794.Google Scholar
Joly, M, Deputte, B, Verdier, JM. 2006. Age effect on olfactory discrimination in a non-human primate, Microcebus murinus. Neurobiology of Aging 27:1045–1049.Google Scholar
Joly, M, Ammersdörfer, S, Schmidtke, D, et al. 2014. Touchscreen-based cognitive tasks reveal age-related impairment in a primate aging model, the grey mouse lemur (Microcebus murinus). PLoS One 9(10):e109393.Google Scholar
Joseph-Mathurin, N, Dorieux, O, Trouche, SG, et al. 2013. Amyloid beta immunization worsens iron deposits in the choroid plexus and cerebral microbleeds. Neurobiology of Aging 34:2613–2622.Google Scholar
Kang, J, Lemaire, HG, Unterbeck, A, et al. 1987. The precursor of Alzheimer's disease amyloid A4 protein resembles a cell-surface receptor. Nature 325:733–736.Google Scholar
Kitazawa, M, Medeiros, R, Laferla, FM. 2012. Transgenic mouse models of Alzheimer disease: developing a better model as a tool for therapeutic interventions. Current Pharmaceutical Design 18:1131–1147.Google Scholar
Kraska, A, Dorieux, O, Picq, JL, et al. 2011. Age-associated cerebral atrophy in mouse lemur primates. Neurobiology of Aging 32:894–906.Google Scholar
Langui, D, Lachapelle, F, Duyckaerts, C. 2007. Animal models of neurodegenerative diseases. Médecine Sciences 23:180–186.Google Scholar
Languille, S, Blanc, S, Blin, O, et al. 2012. The grey mouse lemur: a non-human primate model for ageing studies. Ageing Research Review 11:150–162.Google Scholar
Lasmezas, CI, Fournier, JG, Nouvel, V, et al. 2001. Adaptation of the bovine spongiform encephalopathy agent to primates and comparison with Creutzfeldt–Jakob disease: implications for human health. Proceedings of the National Academy of Sciences of the United States of America 98:4142–4147.Google Scholar
Lasmezas, CI, Comoy, E, Hawkins, S, et al. 2005. Risk of oral infection with bovine spongiform encephalopathy agent in primates. Lancet 365:781–783.Google Scholar
Lemere, CA, Beierschmitt, A, Iglesias, M, et al. 2004. Alzheimer's disease abeta vaccine reduces central nervous system abeta levels in a non-human primate, the Caribbean vervet. American Journal of Pathology 165:283–297.Google Scholar
Lo, AW, Ho, C, Cummings, J, Kosik, KS. 2014. Parallel discovery of Alzheimer's therapeutics. Science Translational Medicine 6:241–245.Google Scholar
McGowan, E, Eriksen, J, Hutton, M. 2006. A decade of modeling Alzheimer's disease in transgenic mice. Trends in Genetics 22:281–289.Google Scholar
Mestre-Francés, N, Keller, E, Calenda, A, et al. 2000. Immunohistochemical analysis of cerebral cortical and vascular lesions in the primate Microcebus murinus reveal distinct amyloid beta1–42 and beta1–40 immunoreactivity profiles. Neurobiology of Disease 7:1–8.Google Scholar
Mestre-Francés, N, Nicot, S, Rouland, S, et al. 2012. Oral transmission of L-type bovine spongiform encephalopathy in primate model. Emerging Infectious Diseases 18:142–145.Google Scholar
Morrison, JH, Hof, PR. 1997. Life and death of neurons in the aging brain. Science 278:412–419.Google Scholar
Nemoz-Bertholet, F, Aujard, F. 2003. Physical activity and balance performance as a function of age in a prosimian primate (Microcebus murinus). Experimental Gerontology 38:407–414.Google Scholar
Ono, F, Tase, N, Kurosawa, A, et al. 2011. Atypical L-type bovine spongiform encephalopathy (L-BSE) transmission to cynomolgus macaques, a non-human primate. Japan Journal of Infectious Disease 64:81–84.Google Scholar
Orgogozo, JM, Gilman, S, Dartigues, JF, et al. 2003. Subacute meningoencephalitis in a subset of patients with AD after Abeta42 immunization. Neurology 61:46–54.Google Scholar
Perret, M. 1997. Change in photoperiodic cycle affects life span in a prosimian primate (Microcebus murinus). Journal of Biological Rhythms 12:136–145.Google Scholar
Picq, JL. 1992. Aging and social behaviour in captivity in Microcebus murinus. Folia Primatologica 59:217–220.Google Scholar
Picq, JL. 2007. Aging affects executive functions and memory in mouse lemur primates. Experimental Gerontology 42:223–232.Google Scholar
Picq, JL, Dhenain, M. 1998. Reaction to new objects in young and aged grey mouse lemurs (Microcebus murinus). The Quarterly Journal of Experimental Psychology 51B:337–348.Google Scholar
Picq, JL, Aujard, F, Volk, A, Dhenain, M. 2012. Age-related cerebral atrophy in nonhuman primates predicts cognitive impairments. Neurobiology of Aging 33:1096–1109.Google Scholar
Radespiel, U. 2000. Sociality in the gray mouse lemur (Microcebus murinus) in northwestern Madagascar. American Journal of Primatology 51:21–40.Google Scholar
Rathbun, WB, Holleschau, AM. 1992. The effects of age on glutathione synthesis enzymes in lenses of Old World simians and prosimians. Current Eye Research 11:601–607.Google Scholar
Robine, JM, Herrmann, FR, Arai, Y, et al. 2012. Exploring the impact of climate on human longevity. Experimental Gerontology 47:660–671.Google Scholar
Robinson, SR, Bishop, GM, Lee, HG, Munch, G. 2004. Lessons from the AN 1792 Alzheimer vaccine: lest we forget. Neurobiology of Aging 25:609–615.Google Scholar
Sanchez-Gonzalez, MA, Garcia-Cabezas, MA, Rico, B, Cavada, C. 2005. The primate thalamus is a key target for brain dopamine. Journal of Neuroscience 25:6076–6083.Google Scholar
Schenk, D, Barbour, R, Dunn, W, et al. 1999. Immunization with amyloid-beta attenuates Alzheimer-disease-like pathology in the PDAPP mouse. Nature 400:173–177.Google Scholar
Shen, YT. 2010. Primate models for cardiovascular drug research and development. Current Opinion in Investigational Drugs 11:1025–1029.Google Scholar
Sigurdsson, EM, Scholtzova, H, Mehta, PD, Frangione, B, Wisniewski, T. 2001. Immunization with a nontoxic/nonfibrillar amyloid-beta homologous peptide reduces Alzheimer's disease-associated pathology in transgenic mice. American Journal of Pathology 159:439–447.Google Scholar
Sterling, EJ, Radespiel, U. 2000. Advances in studies of sociality in nocturnal prosimians. American Journal of Primatology 51:1–2.Google Scholar
Stone, J, Johnston, E. 1981. The topography of primate retina: a study of the human, bushbaby, and new- and old-world monkeys. Journal of Comparative Neurology 196:205–223.Google Scholar
Sutcliffe, J, Hutcheson, D. 2012. Perspectives on the non-human primate touch-screen self ordered spatial search paradigm. In Spink, AJ, Grieco, F, Krips, OE, et al. (eds.), Proceedings of Measuring Behavior, August 28–31, 2012. Utrecht, The Netherlands.
Torrent, J, Soukkarieh, C, Lenaers, G, et al. 2010. Microcebus murinus retina: a new model to assess prion-related neurotoxicity in primates. Neurobiology of Disease 39:211–220.Google Scholar
Trouche, SG, Asuni, A, Rouland, S, et al. 2009. Antibody response and plasma Abeta1–40 levels in young Microcebus murinus primates immunized with Abeta1–42 and its derivatives. Vaccine 27:957–964.Google Scholar
Trouche, SG, Maurice, T, Rouland, S, Verdier, JM, Mestre-Francés, N. 2010. The three-panel runway maze adapted to Microcebus murinus reveals age-related differences in memory and perseverance performances. Neurobiology of Learning and Memory 94:100–106.Google Scholar
Someren, EJ Van, Lek, RF Riemersma-Van Der. 2007. Live to the rhythm, slave to the rhythm. Sleep Medicine Reviews 11:465–484.Google Scholar
Wagner, JE, Kavanagh, K, Ward, GM, et al. 2006. Old world nonhuman primate models of type 2 diabetes mellitus. ILAR Journal 47:259–271.Google Scholar
Woodruff-Pak, DS. 2008. Animal models of Alzheimer's disease: therapeutic implications. Journal of Alzheimer's Disease 15:507–521.Google Scholar
Yutzy, B, Holznagel, E, Coulibaly, C, et al. 2007. Time-course studies of 14-3-3 protein isoforms in cerebrospinal fluid and brain of primates after oral or intracerebral infection with bovine spongiform encephalopathy agent. Journal of General Virology 88:3469–3478.Google Scholar

Save book to Kindle

To save this book to your Kindle, first ensure coreplatform@cambridge.org is added to your Approved Personal Document E-mail List under your Personal Document Settings on the Manage Your Content and Devices page of your Amazon account. Then enter the ‘name’ part of your Kindle email address below. Find out more about saving to your Kindle.

Note you can select to save to either the @free.kindle.com or @kindle.com variations. ‘@free.kindle.com’ emails are free but can only be saved to your device when it is connected to wi-fi. ‘@kindle.com’ emails can be delivered even when you are not connected to wi-fi, but note that service fees apply.

Find out more about the Kindle Personal Document Service.

Available formats
×

Save book to Dropbox

To save content items to your account, please confirm that you agree to abide by our usage policies. If this is the first time you use this feature, you will be asked to authorise Cambridge Core to connect with your account. Find out more about saving content to Dropbox.

Available formats
×

Save book to Google Drive

To save content items to your account, please confirm that you agree to abide by our usage policies. If this is the first time you use this feature, you will be asked to authorise Cambridge Core to connect with your account. Find out more about saving content to Google Drive.

Available formats
×