New methods for sensitive analysis with nanoelectrospray ionization mass spectrometry

Ek, Patrik

January 2010

In this thesis, new methods that address some current limitations in nanoelectrospray mass spectrometry (nESI-MS) analysis are presented. One of the major objectives is the potential gain in sensitivity that can be obtained when employing the proposed techniques. In the first part of this thesis, a new emitter, based on the generation of electrospray from a spray orifice with variable size, is presented. Electrospray is generated from an open gap between the edges of two individually mounted, pointed tips. The fabrication and evaluation of two different types of such emitters is presented; an ESI emitter fabricated from polyethylene terephtalate (Paper I), and a high-precision silicon device (Paper II). Both emitters were surface-treated in a selective way for an improved wetting of the gap and to confine the sample solution into the gap. In the second part of this thesis, different methods for improved sensitivity of nESI-MS analysis have been developed. In Paper III, a method for nESI-MS analysis from discrete sample volumes down to 1.5 nL is presented, using commercially available nESI needles. When analyzing attomole amounts of analyte in such a small volume of sample, an increased sensitivity was obtained, compared to when analyzing equal amounts in conventional nESI-MS analysis. To be able to analyze smaller sample volumes, needles with a narrower orifice and a higher flow resistance were needed. This triggered the development of a new method for fabrication of fused silica nESI needles (Paper IV). The fabrication is based on melting of a fused silica capillary by means of a rotating plasma, prior to pulling the capillary into a fine tip. Using the described technique, needles with sub-micrometer orifices could be fabricated. Such needles enabled the analysis of sample volumes down to 275 pL, and a further improvement of the sensitivity was obtained. In a final project (Paper V), nESI-MS was used to study the aggregation behavior of Aβ peptides, related to Alzheimer’s disease. An immunoprecipitation followed by nESI-MS was employed. This technique was also utilized to study the selectivity of the antibodies utilized. / QC 20101112

mass spectrometry

electrospray ionization

nanoelectrospray ionization

adjustable gap

emitter

miniaturization

improved sensitivity

nanoliter/picoliter sample volumes

Alzheimer’s disease

amyloid-beta (Aβ)

Analytical chemistry

Analytisk kemi

The combined role of amyloid precursor protein intracellular domain and amyloid-beta on synaptic transmission

Prozorov, Arsenii

08 1900

Ces dernières années, de nombreuses études ont prouvé que la protéine précurseur de l'amyloïde (APP) joue un rôle clé dans le processus de formation de la mémoire, le développement des connexions synaptiques et la régulation de la force synaptique. L’importance d’APP naît du fait que son clivage protéolytique produit le peptide bêta-amyloïde (Aβ), considéré comme l'un des facteurs cruciaux dans le développement de la maladie d'Alzheimer. Les recherches se sont donc concentrées sur Aβ plutôt que sur le domaine intracellulaire APP (APP-ICD). Récemment, il a été démontré qu’APP-ICD affecte l'induction de la plasticité synaptique, et Aβ à haute concentration est connu pour induire une dépression synaptique. Ici, nous montrons qu’APP-ICD et Aβ fonctionnent ensemble et induisent une dépression synaptique en modifiant la transmission synaptique par effet additif. L’activation de la caspase-3 clivant APP-ICD est nécessaire pour la dépression à long terme. Nous constatons que l’activation de la caspase-3 et son site de clivage d’APP-ICD, ainsi que le clivage d’APP par la gamma-sécrétase sont nécessaires à la dépression synaptique dépendante d’Aβ. La microglie assure la clairance d’Aβ et certains effets de plasticité. Nous démontrons qu’elle médie partiellement la dépression synaptique dépendante d’Aβ. Les mécanismes par lesquels APP-ICD et Aβ médient la dépression synaptique ne sont pas connus. Ici, nous discutons de pistes possibles pour la recherche future, notamment des changements dans l'homéostasie du calcium en tant que cible thérapeutique potentielle. Comprendre comment APP-ICD et Aβ travaillent ensemble pour induire une dépression synaptique aiderait à développer de meilleurs traitements pour la maladie d'Alzheimer. / In recent years, more and more evidence has proven that the amyloid precursor protein (APP) plays a key role in the process of memory formation, the development of synaptic connections, and the regulation of synaptic strength. APP rose to prominence since its proteolytic cleavage produces the amyloid-beta (Aβ) peptide, which is believed to be one of the crucial factors in the development of Alzheimer disease. Therefore, most of the research focused on Aβ, while APP intracellular domain (APP-ICD) received much less attention. In a recent study, APP-ICD was shown to affect the induction of synaptic plasticity, and Aβ at high concentration is known to induce synaptic depression. Here we show that APP-ICD works together with Aβ to induce synaptic depression, meaning they have an additive effect that changes synaptic transmission. Caspase-3 cleaves APP-ICD, and its activation is required for long-term depression. We found that the caspase-3 cleavage site of APP-ICD and caspase-3 activation are needed for Aβ-dependent synaptic depression. We also show that cleavage of APP by gamma-secretase is needed for the effect. Microglia mediate clearance of Aβ as well as some plasticity effects. We demonstrate that microglia partially mediate Aβ-dependent synaptic depression. The mechanisms of how APP-ICD and Aβ mediate synaptic depression are not known, here, we discuss possible avenues for future research, specifically changes in calcium homeostasis as a potential therapeutic target. Hence, understanding how APP-ICD and Aβ work together to induce synaptic depression would aid in developing better treatments for Alzheimer disease.

Maladie d'Alzheimer

Protéine précurseur de l'amyloïde

Bêta-amyloïde (Aβ)

Plasticité synaptique

Clivage de la caspase

Métaplasticité

Réserves de calcium intracellulaires

Microglie

Alzheimer disease

Amyloid Precursor Protein

Amyloid-beta (Aβ)

Aβ-dependent synaptic depression

Synaptic plasticity

Caspase cleavage

Metaplasticity

Intracellular calcium stores

Microglia