Auristatin PYE, a novel synthetic derivative of dolastatin 10, is highly effective in human colon tumour models

Shnyder, Steven, Cooper, Patricia A., Millington, Nicola J., Pettit, G.R., Bibby, Michael C.

January 2007

No / Despite promising early data, the natural product dolastatin 10 has not been successful as a single agent in phase II clinical trials. Herein the mechanism of action and efficacy of a synthetic analogue, auristatin PYE, was investigated in 2 human colon adenocarcinoma models, DLD-1 and COLO 205. In vivo efficacy was assessed in subcutaneous xenografts following intravenous administration. Mechanistic studies investigated effects of auristatin PYE on microtubule disruption using immunocytochemistry, whilst cell cycle effects were studied using flow cytometry. Possible effects on tumour functional blood vasculature were assessed in tumour-bearing mice. Auristatin PYE was less potent in vitro than dolastatin 10, but was significantly more effective (p<0.01) in vivo against both tumours. Significant effects on tumour blood vasculature were seen, with optimal shutdown at 6-h post-treatment. Extensive necrosis became more evident over time after treatment. Auristatin PYE caused severe disruption of normal microtubule structure at concentrations and times comparable with the IC50 data, and also instigated a G2/M cell cycle block. Auristatin PYE was more effective in the DLD-1 and COLO 205 models than dolastatin 10, with anti-tumour effects mediated through vascular shutdown. These data suggest that auristatin PYE has good potential as an anti-cancer agent.

Dolastatin

Pye

Tumour

Human colon

Colon tumour

Tumour model

Microtubule

Synthetic derivative

Blood vasculature

Effect of murine cytomegalovirus infection on haematopoiesis and myeloid cell differentiation and function

Khong, Andrea

January 2008

Cytomegalovirus (CMV) is a ubiquitous pathogen affecting over 95% of the world’s population. While infection is typically asymptomatic in healthy individuals, the virus persists life-long in its host and can be reactivated following withdrawal of immune control. As such, it remains a serious clinical concern in individuals who are immunocompromised, such as newborns and neonates, transplant and/or chemotherapy recipients, and HIV/AIDS patients. CMV also has the ability to cause immunosuppression, the mechanisms of which include defective antigen presentation to T cells and interference with haematopoiesis in the bone marrow (BM). Due to strict species specificity, murine CMV (MCMV) provides a relevant model for the study of CMV modulation of the immune system in vivo in its natural host. The type I interferons (IFNs) represent a major family of cytokines involved in the early response to MCMV infection. Their anti-viral activity and regulation of NK cell activation and cytotoxicity are of significant interest in the context of MCMV infection, as genetic resistance to MCMV is mediated by the ability of Ly49H+ NK cells to directly recognise and lyse infected cells. Chapter 2 comprises an analysis of acute MCMV infection in the absence of type I IFN activity. These studies were conducted in IFNAR1 and IFNAR2 deficient mice, which lack components of the type I IFN receptor. Data obtained from these studies confirmed the essential requirement for type I IFN in controlling viral titres, promoting expansion of splenic Ly49H+ NK cells, and inducing early activation of NK cell cytotoxicity. In addition, our data depicted an accumulation of infected myeloid cells in the absence of effective NK cell-mediated control. This was paralleled by a significant increase in the level of serum TNF-a and IFN-¿, an effect which in some cases has been linked to serious pathological disease. Thus, the data described in this chapter provide an insight into the consequences arising from delayed NK cell responses to MCMV infection in the absence of type I IFN. vii Type I IFN can also potentially affect BM haematopoiesis. BM atrophy and impairment of myelopoiesis are serious consequences of CMV infection. During acute MCMV infection we consistently observed a profound loss of splenic dendritic cells (DCs) in BALB/c mice. Since all DC subsets are derived from BM haematopoietic progenitor cells, the possibility that MCMV might interfere with BM haematopoiesis and DC differentiation was explored. Chapters 3 and 4 describe the impact of acute MCMV infection on BM progenitors, with particular emphasis on the differentiation capabilities of these cells in ex vivo culture systems. Chapter 3 focuses on the effect of MCMV infection on BM cellularity and frequency of specific BM progenitor populations. A thorough analysis of contributing factors, such as viral infection of BM cells, involvement of type I and II IFNs, progenitor cell trafficking and NK cell activity in the BM compartment, was conducted. Our results showed that a severe loss of BM cellularity occurs in MCMV-infected mice. Furthermore, when BM cells from MCMV-infected mice were cultured ex vivo in granulocyte macrophage-colony stimulating factor (GM-CSF), there was an impairment in their ability to differentiate into DCs.

Cytomegalovirus infections

Cytomegaloviruses

Dendritic cells

Hematopoiesis

Immune response -- Molecular aspects

Immunosuppressive agents

Interferon

Tumour model

Cytokine response

Dendritic cells

Murine cytomegalovirus

Targeted Drug Delivery to Breast Cancer using Polymeric Nanoparticle Micelles

Ho, Karyn

13 December 2012

Broad distribution and activity limit the utility of anti-cancer compounds by causing unacceptable systemic toxicity and narrow therapeutic indices. To improve tumour accumulation, drug-loaded macromolecular assemblies have been designed to replace conventional surfactant-based formulations. Their nanoscale size enhances tumour accumulation via hyperpermeable vasculature and reduced lymphatic drainage. Incorporating targeting ligands introduces cell specificity through receptor-specific binding and uptake, enabling drugs to reach intracellular targets. In this work, the targeting properties of polymer nanoparticle micelles of poly(2-methyl-2-carboxytrimethylene carbonate-co-D,L-lactide)-graft-poly(ethylene glycol)-furan (poly(TMCC-co-LA)-g-PEG) were verified using in vitro and in vivo models of breast cancer. To select a relevant mouse model, the vascular and lymphovascular properties of two tumour xenograft models were compared. Greater accumulation of a model nanocarrier was observed in orthotopic mammary fat pad (MFP) tumours than size matched ectopic subcutaneous tumours, suggesting that the organ environment influenced the underlying pathophysiology. Immunostaining revealed greater vascular thickness, density and size, and thinner basement membranes in MFP tumours, likely contributing to greater blood perfusion and vascular permeability. Based on these observations, MFP tumour-bearing mice were used to characterize the pharmacokinetics and biodistribution of a taxol drug, docetaxel, encapsulated in poly(TMCC-co-LA)-g-PEG nanoparticles. The nanoparticle formulation demonstrated longer docetaxel circulation in plasma compared to the conventional surfactant-based formulation. As a result, greater docetaxel retention was uniquely measured in tumour tissue, extending exposure of tumour cells to the active compound and suggesting potential for increased anti-cancer efficacy. Furthermore, active targeting of antibody-modified nanoparticles to live cells was shown to be selective and receptor-specific. Binding isotherms were used to quantify the impact of antibody density on binding strength. The equilibrium binding constant increased linearly with the average number of antibodies per particle, which is consistent with a single antibody-antigen interaction per particle. This mechanistic understanding enables binding behaviour to be adjusted in a predictive manner and guides rational nanoparticle design. These studies validate poly(TMCC-co-LA)-g-PEG nanoparticles as a platform for targeted delivery to cancer on both a tissue and cellular level, forming a compelling justification for further pre-clinical evaluation of this system for safety and efficacy in vivo.

Drug delivery

Cancer

Chemotherapy

Anti-cancer therapy

Polymeric nanoparticles

Nanoparticle micelles

Pharmacokinetics

Biodistribution

Live cell binding

Tumour xenograft models

Tumour pathophysiology

Orthotopic tumour model

Nanoparticle targeting

Passive targeting

Active targeting

Formulations

Antibody targeting

Breast cancer

0541

0542

Targeted Drug Delivery to Breast Cancer using Polymeric Nanoparticle Micelles

Ho, Karyn

13 December 2012

Broad distribution and activity limit the utility of anti-cancer compounds by causing unacceptable systemic toxicity and narrow therapeutic indices. To improve tumour accumulation, drug-loaded macromolecular assemblies have been designed to replace conventional surfactant-based formulations. Their nanoscale size enhances tumour accumulation via hyperpermeable vasculature and reduced lymphatic drainage. Incorporating targeting ligands introduces cell specificity through receptor-specific binding and uptake, enabling drugs to reach intracellular targets. In this work, the targeting properties of polymer nanoparticle micelles of poly(2-methyl-2-carboxytrimethylene carbonate-co-D,L-lactide)-graft-poly(ethylene glycol)-furan (poly(TMCC-co-LA)-g-PEG) were verified using in vitro and in vivo models of breast cancer. To select a relevant mouse model, the vascular and lymphovascular properties of two tumour xenograft models were compared. Greater accumulation of a model nanocarrier was observed in orthotopic mammary fat pad (MFP) tumours than size matched ectopic subcutaneous tumours, suggesting that the organ environment influenced the underlying pathophysiology. Immunostaining revealed greater vascular thickness, density and size, and thinner basement membranes in MFP tumours, likely contributing to greater blood perfusion and vascular permeability. Based on these observations, MFP tumour-bearing mice were used to characterize the pharmacokinetics and biodistribution of a taxol drug, docetaxel, encapsulated in poly(TMCC-co-LA)-g-PEG nanoparticles. The nanoparticle formulation demonstrated longer docetaxel circulation in plasma compared to the conventional surfactant-based formulation. As a result, greater docetaxel retention was uniquely measured in tumour tissue, extending exposure of tumour cells to the active compound and suggesting potential for increased anti-cancer efficacy. Furthermore, active targeting of antibody-modified nanoparticles to live cells was shown to be selective and receptor-specific. Binding isotherms were used to quantify the impact of antibody density on binding strength. The equilibrium binding constant increased linearly with the average number of antibodies per particle, which is consistent with a single antibody-antigen interaction per particle. This mechanistic understanding enables binding behaviour to be adjusted in a predictive manner and guides rational nanoparticle design. These studies validate poly(TMCC-co-LA)-g-PEG nanoparticles as a platform for targeted delivery to cancer on both a tissue and cellular level, forming a compelling justification for further pre-clinical evaluation of this system for safety and efficacy in vivo.

Drug delivery

Cancer

Chemotherapy

Anti-cancer therapy

Polymeric nanoparticles

Nanoparticle micelles

Pharmacokinetics

Biodistribution

Live cell binding

Tumour xenograft models

Tumour pathophysiology

Orthotopic tumour model

Nanoparticle targeting

Passive targeting

Active targeting

Formulations

Antibody targeting

Breast cancer

0541

0542

Die Wirkung des kompetitiven Gastrin-releasing peptide-(GRP-) -Antagonisten RC 3095 auf das Wachstumsverhalten im Modell experimentell induzierter orthotoper Nierenzellkarzinome – Analyse mittels Volumencomputertomographie (VCT) / The Impact of the Competitive Gastrin-Releasing Peptide (GRP) Antagonist RC 3095 on Growth Behaviour in the Model of Experimentally Induced Orthotopic Renal Cell Carcinoma – Analysis Based on Volumetric Computed Tomography (VCT)

Koskinas, Nikolaos

18 October 2017

No description available.

610

Development of advanced three-dimensional tumour models for anti-cancer drug testing

Wan, Xiao

January 2014

Animal testing is still the common method to test the efficacy of new drugs, but tissue engineered in vitro models are becoming more acceptable for replacing and reducing animal testing in anti-cancer drug screening by developing in vitro three-dimensional (3D) tumour models for anti-cancer drug testing. In this study, three-dimensional (3D) culture methods were developed to mimic the tumour microenvironment. 3D culturing is to seed, maintain and expand cultured cells in three-dimensional space, in contrast to the traditional two-dimensional (2D) method in which the cells attach to the bottom of culture containers as monolayers. To mimic the intercellular interplay for tumour study, cell co-culture was applied. In this thesis, perfusion culture showed a better homeostasis for 3D tumour model growth over 17 days, with a more controllable working platform and a more reliable response-dose correlation for data interpretation. In the Matrigel sandwich system, the co-culture of breast cancer cells and endothelial cells demonstrated the morphology featuring a vascular network and tumour structures, with the thickness of the three-dimensional structure around 100µm and tubule length 200-400 µm, and maintained for 10 days. The comparisons studies between Matrigel sandwich and other methods suggest that though not fully characterised, Matrigel is still a valuable scaffold choice for developing co-culture 3D tumour model. Finally, the combination of perfusion and co-culture showed the potential of applying this model in angiogenesis assay, with a drug response profile combining cell viability and morphology to mimic in vivo tumour physiology.

616.99