Synthesis of new Aβ-ligands useful in diagnosis of Alzheimer's disease

Alzheimer’s disease is a chronic progressive neurodegenerative disease and is the most common form of dementia (estimated 50−60% of all cases), associated with loss of memory (in particular episodic memory), cognitive decline, and behavioural and physical disability, ultimately leading to death. Alzheimer’s disease is a complex disease, mostly occurring sporadically with no apparent inheritance and being the age the main risk factor. The production and accumulation of amyloid-beta peptide in the central nervous system is a key event in the development of Alzheimer’s disease. This project is devoted to the synthesis of amyloid-beta ligands, fluorophores and blood brain barrier-transporters for diagnosis and therapy of Alzheimer’s disease. Different amyloid-beta ligands will be synthesized and their ability to interact with amyloid-beta plaques will be studied with nuclear magnetic resonance techniques and a process of lead optimization will be performed. Many natural and synthetic compounds able to interact as amyloid-beta ligands have been identified. Among them, a set of small molecules in which aromatic moieties seem to play a key role to inhibit amyloid-beta aggregation, in particular heteroaromatic polycyclic compounds such as tetracyclines. Nevertheless tetracyclines suffer from chemical instability, low water solubility and possess, in this contest, undesired anti-bacterial activity. In order to overcome these limitations, one of our goals is to synthesize tetracyclines analogues bearing a polycyclic structure with improved chemical stability and water solubility, possibly lacking antibacterial activity but conserving the ability to interact with amyloid-beta peptides. Known tetracyclines have in common a fourth cycle without an aromatic character and with different functionalisations. We aim to synthesize derivatives in which this cycle is represented by a sugar moiety, thus bearing different derivatisable positions or create derivatives in which we will increase or decrease the number of fused rings. In order to generate a potential drug-tool candidate, these molecules should also possess the correct chemical-physical characteristics. The glycidic moiety, not being directly involved in the binding, it assures further possible derivatizations, such as conjugation to others molecular entities (nanoparticles, polymeric supports, etc.), and functionalization with chemical groups able to modulate the hydro/lipophilicity. In order to be useful such compounds should perform their action within the brain, therefore they have to be able to cross the blood brain barrier, and to be somehow detected for diagnostic purposes.

Aß biology and its contribution to Alzheimer's disease

A doença de Alzheimer (DA) é uma desordem neurodegenerativa progressiva patologicamente caracterizada pela presença de placas de amilóide (placas senis) insolúveis e também pela presença de tranças neurofibrilhares,formadas pela proteína Tau hiperfosforiladada. O principal constituinte das placas senis é o peptídeo beta-amilóide (Ab), que deriva do processamento proteolítico da proteína precursora de amilóide de Alzheimer (APP). Embora Ab exista como um agregado pouco solúvel nas placas senis, ele é secretado pelas células como uma molécula solúvel. O Ab “per se” pode afectar o metabolismo da APP. Alguns autores sugerem que o Ab exerce o seu efeito alterando o processamento ou catabolismo da APP, outros sugerem que ele também induz a transcrição da APP, onde aumentando os níveis da APP pode estar a contribuir para a sua própria produção (mecanismo de “feedback” positivo). Assim sendo, torna-se difícil consolidar todas estas observações e identificar as potenciais funções fisiológicas do Ab “in vivo”, ou as consequências da sua produção. Neste trabalho caracterizaram-se os efeitos do Ab no metabolismo da APP. Os nossos estudos revelaram que um dos mecanismos induzidos pelo Ab é a acumulação intracelular do fragmento neuroprotector sAPP (isAPPa) em estruturas com características vesiculares associadas ao citosqueleto. Estudos adicionais em culturas primárias revelaram que o Ab estava a exercer o seu efeito ao nível da secreção vesicular, provavelmente interferindo com o transporte de APP/sAPP ao longo da rede do citosqueleto. Esta hipótese é sustentada pelo facto do Ab estar a afectar a estabilidade e a polimerização de proteínas envolvidas na dinâmica do citosqueleto. Contrariamente a publicações anteriores o Ab não induziu a transcrição da APP, na verdade em culturas primárias neuronais foi observado uma diminuição nos níveis de expressão da APP. Isto foi acompanhado por um aumento nos fragmentos C-terminais da APP (CTFs) e uma diminuição na localização nuclear do seu domínio intracelular (AICD), sugerindo alterações na sinalização nuclear da APP. O Ab pode afectar outras vias de sinalização, particularmente alterando o balanço entre as actividades das proteínas cinases e fosfatases, o que pode ter consequências para o desenvolvimento da doença. Os dados obtidos indicam que o Ab é capaz de inibir a actividade da proteína fosfatase1, a sua importância numa perspectiva de futuras terapias é discutida. Devido à relevância da agregação do Ab para a sua toxicidade, a formação de complexos com proteínas que promovem a sua desagregação/degradação e o seu efeito no processamento da APP foi avaliado. Na presença destes complexos observou-se uma reversão da acumulação isAPP, demonstrando o potencial terapêutico destas proteínas como moduladores do metabolismo da APP. Este trabalho permitiu compreender melhor os mecanismos envolvidos nos efeitos do Ab no processamento da APP e descobrir algumas moléculas que podem ser relevantes numa perspectiva de diagnóstico e terapia na DA.

The role of cellular prion protein in Alzheimer’s disease

Alzheimer’s disease (AD) is the most prevalent age-related neurodegenerative disease that leads to cognitive impairment and dementia. The major defined pathological hallmark of AD is the accumulation of amyloid beta (Aβ), a neurotoxic peptide, derived from beta and gamma-secretase cleavage of the amyloid precursor protein (APP). It has been described that cellular prion protein (PrPC) plays a role in the pathogenesis of Alzheimer disease. Although, the role of PrPC is still unclear, previous studies showed contradictious results. To elucidate this issue, the main objective of the present study is to investigate the influence of a knockout of the PRNP gene in 5XFAD mice, 5xFAD mice exhibited 5 mutations related to familial Alzheimer disease. These mice show an Aβ1-42 accumulation and an increased neuronal loss during aging. To create a bi-transgenic 5xFAD mice were crossed with Prnp0/0 Zurich 1 mice (prion protein knockout mice). We subjected two transgenic mice (5xFAD and Prnp0/05xFAD) at different ages (3, 9 and 12 months of age) to a battery of task to evaluate cognitive and motoric deficits and a biochemical analysis (ELISA, western blot and immunohistochemistry) to investigate the regulation and potential involvement of downstream signaling proteins in the Aβ induced toxicity process dependent of the PrPC concentration. The study revealed that the deficits induced by Aβ mediated toxicity appeared earlier in 5xFAD mice (9 months of age) than in Prnp0/05xFAD (12 months of age). Investigating the amount of amyloid beta in 5xFAD mice we observed a PrPC dependent regulation in 9 month-old animals of Aβ1−40 but not of the toxic form Aβ1−42. We did not found in Prnp0/05xFAD mice the up-regulation of P-Fyn, Fyn or Cav-1 as we found in 5xFAD mice. This suggests an important role of PrPC in Alzheimer’s disease as a promoter of toxic effect of Aβ oligomers. Our results may suggest the loss of PrPC delays the toxicity of amyloid beta. In conclusion, our data support a role of PrPC as a mediator of Aβ toxicity in AD by promoting early onset of disease.

Optimization of a multielectrode array (MEA)-based approach to study the impact of Aβ on the SH-SY5Y cell line

The human brain stores, integrates, and transmits information recurring to millions of neurons, interconnected by countless synapses. Though neurons communicate through chemical signaling, information is coded and conducted in the form of electrical signals. Neuroelectrophysiology focus on the study of this type of signaling. Both intra and extracellular approaches are used in research, but none holds as much potential in high-throughput screening and drug discovery, as extracellular recordings using multielectrode arrays (MEAs). MEAs measure neuronal activity, both in vitro and in vivo. Their key advantage is the capability to record electrical activity at multiple sites simultaneously. Alzheimer’s disease (AD) is the most common neurodegenerative disease and one of the leading causes of death worldwide. It is characterized by neurofibrillar tangles and aggregates of amyloid-β (Aβ) peptides, which lead to the loss of synapses and ultimately neuronal death. Currently, there is no cure and the drugs available can only delay its progression. In vitro MEA assays enable rapid screening of neuroprotective and neuroharming compounds. Therefore, MEA recordings are of great use in both AD basic and clinical research. The main aim of this thesis was to optimize the formation of SH-SY5Y neuronal networks on MEAs. These can be extremely useful for facilities that do not have access to primary neuronal cultures, but can also save resources and facilitate obtaining faster high-throughput results to those that do. Adhesion-mediating compounds proved to impact cell morphology, viability and exhibition of spontaneous electrical activity. Moreover, SH-SY5Y cells were successfully differentiated and demonstrated acute effects on neuronal function after Aβ addition. This effect on electrical signaling was dependent on Aβ oligomers concentration. The results here presented allow us to conclude that the SH-SY5Y cell line can be successfully differentiated in properly coated MEAs and be used for assessing acute Aβ effects on neuronal signaling.