Role of homotropic association of luteinizing hormone receptors in hormone mediated signaling

2012 Spring.Includes bibliographical references.G protein-coupled receptors (GPCR) are plasma membrane receptors involved in signal transduction and are an important target for drug discovery. Luteinizing hormone receptors (LHR) are GPCRs found on the reproductive organs of both males and females and promote spermatogenesis and ovulation. Understanding how these protein receptors function on the plasma membrane will lead to better understanding of the mammalian reproduction system and other GPCR systems. Studies in the past suggested that these receptors oligomerize after hormone binding, but recent studies performed with LHRs suggest that these receptors maybe constitutively oligomerized in the endoplasmic reticulum and on the plasma membrane. However, these experiments were performed on receptors expressed by transient transfection and using bioluminescence resonance energy transfer (BRET). These methods have potential weaknesses. Transient transfections typically yield a fraction of cells with very high receptor expression and BRET measurements are strongly weighted towards those cells. Hence, this overall approach may have yielded misleading results. Fluorescence energy transfer (FRET) is a similar technique to BRET but has advantages such as allowing imaging examination of single cells. Using FRET, LHR oligomerization was evaluated on cells treated with human chorionic gonadotropin (hCG) or deglycosylated-hCG, hormones which activate and inhibit the receptor function, respectively. FRET measurements demonstrated that, on the surfaces of transiently transfected cells, LHRs exhibit substantial intermolecular FRET which is very slightly increased by hCG treatment and very slightly reduced by exposure to DG-hCG. Closer examination of these data showed that all observed FRET depended linearly on receptor expression and approach zero at low expression levels. This suggests that FRET between LHR on these transiently-transfected cells may arise from inter-molecular proximity induced non-specifically by high receptor surface concentrations. To evaluate the receptor density on cells flow cytometry was used. Flow cytometry revealed that transiently-transfected LHRs are expressed over a broad range of surface densities, including very high expression levels. Using a mathematical model, the FRET efficiencies expected for various receptor surface densities were calculated. These calculations suggest that expression levels observed cytometrically could cause substantial amounts of FRET from molecular crowding and, particularly if the receptors are additionally concentrated in lipid rafts, most of the observed FRET signal could be attributed to non-specific concentration effects

Immuno Magnetic Thermosensitive Liposomes For Cancer Therapy

The present work describes the encapsulation of the drug doxorubicin (DOX) in immuno paramagnetic thermosensitive liposomes. DOX is the most common chemotherapeutic agent for the treatment of a variety of carcinomas. However, the pure drug has high cytotoxicity and therefore requires a targeted and biocompatible delivery system. The introduction includes concepts, modalities, and functionalities of the project. First, a detailed description of the cell type (triple-negative breast cancer) is given. Furthermore, the importance of liposomal doxorubicin is explained and the current state of research is shown. The importance of modification to achieve thermosensitive properties and the procedure for co-encapsulation with Gd chelate to achieve paramagnetic properties is also discussed. In addition, the first part describes the surface modification with ADAM8 antibodies, which leads to improved targeting. The second part of the thesis covers the different materials and methods used in this paper. The production of the liposomes LipTS, LipTS-GD, LipTS-GD-CY, LipTS-GD-CY-MAB and the loading of DOX using an ammonium sulfate gradient method were described in detail. The results part deals with the physicochemical characterization using dynamic light scattering and laser Doppler velocimetry, which confirmed a uniform monodisperse distribution of the liposomes. These properties facilitate the approach of liposomes to target cancer cells. The influence of lipid composition of liposomes, co-encapsulation with Gd chelate and surface modification of liposomes was evaluated and described accordingly. The size and structure of the individual liposomal formulations were determined by atomic force microscopy and transmission electron microscopy. Morphological examination of the liposomes confirmed agreement with the sizes obtained by dynamic light scattering. Temperature-dependent AFM images showed an intact liposome structure at 37 °C, whereas heating by UHF-MRI led to a lipid film indicating the destruction of the lipid bilayer. Furthermore, TEM images showed the morphological properties of the liposomes and gave a more precise indication of how Gd-chelate accumulates within the liposomes. Liposomes with Gd-chelate showed well-separated vesicles, suggesting that Gd- chelate is deposited in the lipid bilayer of the liposomes. Gd was encapsulated in the hydrophilic core whereas chelate was extended into the lipid bilayer. By differential scanning calorimetry and drug release, the heat-sensitive functionality of the liposomes could be determined. Liposomes showed a beginning of phase transition temperature at about 38 °C, which can be achieved by UHF-MRI exposure. The maximum phase transition temperature in the case of LipTS-GD and LipTS-GD-CY-MAB was 42 °C and 40 °C, respectively. A proof of concept study for the thermosensitive properties of liposomes and a time-dependent DOX release profile in hyperthermia was performed. Gd-chelate is encapsulated in both LipTS-GD and LipTS-GD-CY-MAB and led to paramagnetic properties of the liposomes. This facilitates imaging mediated DOX delivery and diagnosis of the solid tumor and metastatic cells. The change in relaxation rate R1 of liposomes was quantified before and after heating above Tm (T> Tm). The relaxivity of the liposomes was obtained from the adapted slope of the relaxation rate against the Gd concentration. Remarkably, the relaxation rate and relaxivity increased after heating the liposomes above Tm (T> Tm), suggesting that the liposomes opened, released Gd chelate, and the exchange of water molecules became faster and more practicable. Toxicity studies describe the different mechanisms for induced DOX toxicity. The increased cytotoxic effect at elevated temperatures showed that the induced toxicity is thermally dependent, i.e. DOX was released from the liposomes. The high viability of the cells at 37 °C indicates that the liposomes were intact at normal physiological temperatures. Under UHF-MRI treatment, cell toxicity due to elevated temperature was observed. The cellular uptake of liposomes under UHF-MRI was followed by a confocal laser scanning microscope. An increase in fluorescence intensity was observed after UHF-MRI exposure. The study of the uptake pathway showed that the majority of liposomes were mainly uptake by clathrin-mediated endocytosis. In addition, the liposomes were modified with anti-ADAM8 antibodies (MAB 1031) to allow targeted delivery. The cellular binding capabilities of surface-modified and non-modified liposomes were tested on cells that had ADAM8 overexpression and on ADAM8 knockdown cells. Surface-modified liposomes showed a significant increase in binding ability, indicating significant targeting against cells that overexpress ADAM8 on their surface. In addition, cells with knockdown ADAM8 could not bind a significant amount of modified liposomes. The biocompatibility of liposomes was assessed using a hemolysis test, which showed neglected hemolytic potential and an activated thromboplastin time (aPTT), where liposomes showed minimal interference with blood clotting. Hemocompatibility studies may help to understand the correlation between in vitro and in vivo. The chorioallantois model was used in ovo to evaluate systematic biocompatibility in an alternative animal model. In the toxicity test, liposomes were injected intravenously into the chicken embryo. The liposomes showed a neglectable harmful effect on embryo survival. While free DOX has a detrimental effect on the survival of chicken embryos, this confirms the safety profile of liposomes compared to free DOX. LipTS-GD-CY-MAB were injected into the vascular system of the chicken embryo on egg development day 11 and scanned under UHF-MRI to evaluate the magnetic properties of the liposomes in a biological system with T2-weighted images (3D). The liposomal formulation had distinct magnetic properties under UHF MRI and the chick survived the scan. In summary, immunomagnetic heat-sensitive liposomes are a novel drug for the treatment of TNBC. It is used both for the diagnosis and therapy of solid and metastasizing tumors without side effects on the neighboring tissue. Furthermore, a tumor in the CAM model will be established. Thereafter, the selective targeting of the liposomes will be visualized and quantitated using fluorescence and UHF-MRI. Liposomes are yet to be tested on mice as a xenograft triple-negative breast cancer model, in which further investigation on the effect of DOX-LipTS-GD-CY-MAB is evaluated. On one hand, the liposomes will be evaluated regarding their targetability and their selective binding. On the other hand, the triggered release of DOX from the liposomes after UHF-MRI exposure will be quantitated, as well as evaluate the DOX-Liposomes therapeutic effect on the tumor

Advances in dual-energy computed tomography imaging of radiological properties

Dual-energy computed tomography (DECT) has shown great potential in the reduction of uncertainties of proton ranges and low energy photon cross section estimation used in radiation therapy planning. The work presented herein investigated three contributions for advancing DECT applications. 1) A linear and separable two-parameter DECT, the basis vector model (BVM) was used to estimate proton stopping power. Compared to other nonlinear two-parameter models in the literature, the BVM model shows a comparable accuracy achieved for typical human tissues. This model outperforms other nonlinear models in estimations of linear attenuation coefficients. This is the first study to clearly illustrate the advantages of linear model not only in accurately mapping radiological quantities for radiation therapy, but also in providing a unique model for accurate linear forward projection modelling, which is needed by the statistical iterative reconstruction (SIR) and other advanced DECT reconstruction algorithms. 2) Accurate DECT requires knowledge of x-ray beam properties. Using the Birch-Marshall1 model and beam hardening correction coefficients encoded in a CT scanner’s sinogram header files, an efficient and accurate way to estimate the x-ray spectrum is proposed. The merits of the proposed technique lie in requiring no physical transmission measurement after a one-time calibration against an independently measured spectrum. This technique can also be used in monitoring the aging of x-ray CT tubes. 3) An iterative filtered back projection with anatomical constraint (iFBP-AC) algorithm was also implemented on a digital phantom to evaluate its ability in mitigating beam hardening effects and supporting accurate material decomposition for in vivo imaging of photon cross section and proton stopping power. Compared to iFBP without constraints, both algorithms demonstrate high efficiency of convergence. For an idealized digital phantom, similar accuracy was observed under a noiseless situation. With clinically achievable noise level added to the sinograms, iFBP-AC greatly outperforms iFBP in prediction of photon linear attenuation at low energy, i.e., 28 keV. The estimated mean errors of iFBP and iFBP-AC for cortical bone are 1% and 0.7%, respectively; the standard deviations are 0.6% and 5%, respectively. The achieved accuracy of iFBP-AC shows robustness versus contrast level. Similar mean errors are maintained for muscle tissue. The standard deviation achieved by iFBP-AC is 1.2%. In contrast, the standard deviation yielded by iFBP is about 20.2%. The algorithm of iFBP-AC shows potential application of quantitative measurement of DECT. The contributions in this thesis aim to improve the clinical performance of DECT

Cholesterol levels affect the performance of aunps-decorated thermo-sensitive liposomes as nanocarriers for controlled doxorubicin delivery

Stimulus-responsive liposomes (L) for triggering drug release to the target site are particularly useful in cancer therapy. This research was focused on the evaluation of the effects of cholesterol levels in the performance of gold nanoparticles (AuNPs)-functionalized L for controlled doxorubicin (D) delivery. Their interfacial and morphological properties, drug release behavior against temperature changes and cytotoxic activity against breast and ovarian cancer cells were studied. Langmuir isotherms were performed to identify the most stable combination of lipid components. Two mole fractions of cholesterol (3.35 mol% and 40 mol%, L1 and L2 series, respectively) were evaluated. Thin-film hydration and transmembrane pH-gradient methods were used for preparing the L and for D loading, respectively. The cationic surface of L allowed the anchoring of negatively charged AuNPs by electrostatic interactions, even inducing a shift in the zeta potential of the L2 series. L exhibited nanometric sizes and spherical shape. The higher the proportion of cholesterol, the higher the drug loading. D was released in a controlled manner by diffusion-controlled mechanisms, and the proportions of cholesterol and temperature of release media influenced its release profiles. D-encapsulated L preserved its antiproliferative activity against cancer cells. The developed liposomal formulations exhibit promising properties for cancer treatment and potential for hyperthermia therapy.Ministerio de Ciencia e Innovación CTQ2014- 57515-C2-

Miniaturized Fluorescence Biosensor for Studying Neuronal Events

When developing new techniques to analyze neuro-chemical microenvironments, it is important to realize the incredible variability in the cellular content and the response to stimulation between cells and within a single cell. Conventional analysis techniques yield an average result to describe the content and function of cells. This approach often misses important information since the onset of pathological conditions is always initiated in a small number of cells. New minimally invasive single cell analysis techniques are required for single cell studies in order to gain new insights and understanding of cells\u27 functions. The objective of my Ph.D. study was to fabricate, characterize, and apply submicrometric fluorescence sensors for the analysis of neuron cells. This dissertation will report the fabrication of miniaturized fluorescence sensors for Ca2+, pH and Zn2+ analysis. In the first approach, liposomes (phospholipid vesicles) were used as miniaturized containers for fluorescent sensing reagents. Liposome-based fluorescence sensing technology offers several advantages over commonly used fluorescence sensing techniques including high spatial resolution, protection of the sensing dye from quenchers and high biocompatibility. However, liposome based sensors were found to be unstable in the cellular environment. The second approach was to synthesize submicrometric particle-based fluorescence sensors named lipobeads to replace the fluorescent liposomes in cellular studies. Lipobeads are polystyrene particles that are coated with a phospholipid membrane. One unique advantage of fluorescent sensing lipobeads is the ability to immobilize hydrophobic indicator molecules in the phospholipid membrane. This enables the use of these indicators in aqueous media since the lipobeads are fully water miscible. The lipobeads also proved to be highly biocompatible in cellular studies. This is attributed to their phospholipid bilayer membrane, which is similar in structure to cell membranes. The dissertation will describe the analytical properties of fluorescence sensing lipobeads and their application in studying zinc ion release and pH changes near neuron cells under physiological conditions, conditions of neuronal injury and stress and acidic cortical spreading depression during stroke like conditions

Multimodal nanoparticles for quantitative imaging

The scope of this thesis is research related to applications of nanoparticles in quantitative preclinical imaging. Nanoparticles are a versatile platform that can interact with biological systems at many different length scales and can furthermore be rendered visible for basically any medical imaging technique by modification with appropriate contrast providing moieties. Thus, nanoparticles can be used as a new class of contrast agents for basically all imaging modalities, e.g. as long circulating blood pool agents in CT, or as MRI contrast agents. Vice versa, non-invasive imaging techniques can be used to for example follow the biodistribution of nanoparticles in vivo and apply nanoparticles as a tool to investigate biological processes related to disease processes. Dual modal imaging applying multifunctional and dual-labeled nanoparticles offer new approaches to quantitative imaging, giving new insights into technology development on one side and biological read-outs on the other. For instance, quantification of biological processes that lie at the basis in the development of disease may lead to earlier detection and better disease diagnosis and treatment. Results and concepts presented in this thesis have high impact on therapeutic application of nanoparticles, for example when they are used as drug delivery systems. Imaging can provide valuable information on drug delivery and biodistribution in a quantitative manner, which may help in development of new therapeutic strategies. Nanoparticles are promising structures for quantitative imaging. Its surface can be utilized to attach almost any desirable molecule. Nanoparticles are relatively large in size (typically 10-200 nm) and can for instance accommodate a high payload of contrast agent per particle on its surface or inside the particle, thereby increasing the signal/particle by five orders of magnitude. In addition, also multiple imaging probes for different imaging modalities can be incorporated providing a double read-out. For the understanding of biological processes, targeting ligands such as antibodies, proteins and peptides can be attached to its surface. Despite the wide variety of possibilities with nanoparticles, they have hardly been studies for quantitative imaging purposes. Therefore, the aim of the research described in this thesis was to explore and develop several nanoparticles for quantitative imaging by using existing or newly developed imaging techniques. Chapter 1 gives a general introduction in the field of nanoparticles for quantitative imaging. Several imaging techniques are described such as CT, Spectral CT, SPECT and MRI, and how nanoparticles can play an important role in research. Chapter 2 describes the development of a novel nanoparticulate CT contrast agent. Several amphiphilic molecules were investigated in this chapter in the combination with different iodinated oils for their influence on the size stability of the nanoparticles. In Chapter 3, the dose dependent biodistribution of the nanoparticles is investigated as well as strategies to vary the biodistribution. The effect of a co-injection with liposomes and soy bean oil emulsions was investigated using CT, SPECT and ¿-counting. The final optimized blood pool CT contrast agent from chapter 2 and 3 can be used for qualitative imaging in CT as well as in quantitative imaging in Spectral CT. Chapter 4 describes the very first use of this novel imaging technique Spectral CT in quantitative imaging. For this, the nanoparticles of chapter 2 were extended to a multimodal nanoparticulate contrast agent for CT, Spectral CT and SPECT. Spectral CT quantification was compared to quantification using SPECT and ICP-MS to demonstrate the correlations and accuracy of the techniques. In Chapter 5, the development is described of a dual-isotope SPECT imaging protocol as a tool for pre-clinical testing of new molecular imaging tracers. New molecular targeting probes are consistently investigated as a tool to enable target specific binding of nanoparticles to cellular surfaces of interest. Dual-isotope SPECT can be used in which the biodistribution of two different ligands labelled with two different radionuclides can be studied in the same animal, thereby excluding experimental and physiological inter-animal variations. The developed dual-isotope protocol was tested using a known angiogenesis specific ligand (cRGD peptide) in comparison to a potential non-specific control (cRAD peptide). Chapter 6 describes the use of a multimodal radiolabeled paramagnetic liposomal contrast agent that allows simultaneous imaging with SPECT and MRI. A double read-out is then possible and demonstrates the additional advantages of the combination of the two techniques. SPECT can for instance quantify the nanoparticle concentration and MRI can spatially localize the nanoparticle. The combination however gives an indirect read-out of the water exchange, which in return reveals insights in biological processes and environments. Chapter 7 describes a study that investigates the use of nanoparticles in the quantitative imaging technique fluorine MRI. The use of gadolinium-complexes as signal modulating ingredients into the nanoparticle formulation has emerged as a promising approach towards improvement of the fluorine signal. Paramagnetic lipids based on gadolinium complexes can be incorporated to increase the 19F MR signal per particle. Here, 3 different paramagnetic lipids were investigated on its influence at five different field strengths. This furthermore also provides important insights in the dependency of the magnetic field on fluorine signal intensity. The final Chapter 8 describes the future perspectives of the use of multimodal nanoparticles for quantitative imaging

Cyclic peptide-poly(HPMA) nanotubes as drug delivery vectors : in vitro assessment, pharmacokinetics and biodistribution

Size and shape have progressively appeared as some of the key factors influencing the properties of nanosized drug delivery systems. In particular, elongated materials are thought to interact differently with cells and therefore may allow alterations of in vivo fate without changes in chemical composition. A challenge, however, remains the creation of stable self-assembled materials with anisotropic shape for delivery applications that still feature the ability to disassemble, avoiding organ accumulation and facilitating clearance from the system. In this context, we report on cyclic peptide-polymer conjugates that self-assemble into supramolecular nanotubes, as confirmed by SANS and SLS. Their behaviour ex and in vivo was studied: the nanostructures are non-toxic up to a concentration of 0.5 g L and cell uptake studies revealed that the pathway of entry was energy-dependent. Pharmacokinetic studies following intravenous injection of the peptide-polymer conjugates and a control polymer to rats showed that the larger size of the nanotubes formed by the conjugates reduced renal clearance and elongated systemic circulation. Importantly, the ability to slowly disassemble into small units allowed effective clearance of the conjugates and reduced organ accumulation, making these materials interesting candidates in the search for effective drug carriers

Miniaturized Fluorescence Biosensor for Studying Neuronal Events

When developing new techniques to analyze neuro-chemical microenvironments, it is important to realize the incredible variability in the cellular content and the response to stimulation between cells and within a single cell. Conventional analysis techniques yield an average result to describe the content and function of cells. This approach often misses important information since the onset of pathological conditions is always initiated in a small number of cells. New minimally invasive single cell analysis techniques are required for single cell studies in order to gain new insights and understanding of cells\u27 functions. The objective of my Ph.D. study was to fabricate, characterize, and apply submicrometric fluorescence sensors for the analysis of neuron cells. This dissertation will report the fabrication of miniaturized fluorescence sensors for Ca2+, pH and Zn2+ analysis. In the first approach, liposomes (phospholipid vesicles) were used as miniaturized containers for fluorescent sensing reagents. Liposome-based fluorescence sensing technology offers several advantages over commonly used fluorescence sensing techniques including high spatial resolution, protection of the sensing dye from quenchers and high biocompatibility. However, liposome based sensors were found to be unstable in the cellular environment. The second approach was to synthesize submicrometric particle-based fluorescence sensors named lipobeads to replace the fluorescent liposomes in cellular studies. Lipobeads are polystyrene particles that are coated with a phospholipid membrane. One unique advantage of fluorescent sensing lipobeads is the ability to immobilize hydrophobic indicator molecules in the phospholipid membrane. This enables the use of these indicators in aqueous media since the lipobeads are fully water miscible. The lipobeads also proved to be highly biocompatible in cellular studies. This is attributed to their phospholipid bilayer membrane, which is similar in structure to cell membranes. The dissertation will describe the analytical properties of fluorescence sensing lipobeads and their application in studying zinc ion release and pH changes near neuron cells under physiological conditions, conditions of neuronal injury and stress and acidic cortical spreading depression during stroke like conditions