Reformulation of a thermostable broadly protective recombinant vaccine against human papilloma virus

The causal relationship between Human Papilloma Virus (HPV) infection and cervical cancer has motivated the development, and further improvement, of prophylactic vaccines against this virus. 70% of cervical cancers, 80% of which in low-resources countries, are associated to HPV16 and HPV18 infection, with 13 additional HPV types, classified as high-risk, responsible for the remaining 30% of tumors. Current vaccines, Cervarix® (GlaxoSmithKline) and Gardasil®(Merk), are based on virus-like particles (VLP) obtained by self-assembly of the major capsid protein L1. Despite their undisputable immunogenicity and safety, the fact that protection afforded by these vaccines is largely limited to the cognate serotypes included in the vaccine (HPV 16 and 18, plus five additional viral types incorporated into a newly licensed nonavalent vaccine) along with high production costs and reduced thermal stability, are pushing the development of 2nd generation HPV vaccines based on minor capsid protein L2. The increase in protection broadness afforded by the use of L2 cross-neutralizing epitopes, plus a marked reduction of production costs due to bacterial expression of the antigens and a considerable increase in thermal stability could strongly enhance vaccine distribution and usage in low-resource countries. Previous studies from our group identified three tandem repeats of the L2 aa. 20-38 peptide as a strongly immunogenic epitope if exposed on the scaffold protein thioredoxin (Trx). The aim of this thesis work is the improvement of the Trx-L2 vaccine formulation with regard to cross-protection and thermostability, in order to identify an antigen suitable for a phase I clinical trial. By testing Trx from different microorganisms, we selected P. furiosus thioredoxin (PfTrx) as the optimal scaffold because of its sustained peptide epitope constraining capacity and striking thermal stability (24 hours at 100°C). Alternative production systems, such as secretory Trx-L2 expression in the yeast P. pastoris, have also been set-up and evaluated as possible means to further increase production yields, with a concomitant reduction of production costs. Limitations in immune-responsiveness caused by MHC class II polymorphisms –as observed, for example, in different mouse strains- have been overcome by introducing promiscuous T-helper (Th) epitopes, e.g., PADRE (Pan DR Epitope), at both ends of PfTrx. This allowed us to obtain fairly strong immune responses even in mice (C57BL/6) normally unresponsive to the basic Trx-L2 vaccine. Cross-protection was not increased, however. I thus designed, produced and tested a novel multi-epitope formulation consisting of 8 and 11 L2(20-38) epitopes derived from different HPV types, tandemly joined into a single thioredoxin molecule (“concatemers”). To try to further increase immunogenicity, I also fused our 8X and 11X PfTrx-L2 concatemers to the N-terminus of an engineered complement-binding protein (C4bp), capable to spontaneously assemble into ordered hepatmeric structures, previously validated as a molecular adjuvant. Fusion to C4bp indeed improved antigen presentation, with a fairly significant increase in both immunogenicity and cross-protection. Another important issue I addressed, is the reduction of vaccine doses/treatment, which can be achieved by increasing immunogenicity, while also allowing for a delayed release of the antigen. I obtained preliminary, yet quite encouraging results in this direction with the use of a novel, solid-phase vaccine formulation, consisting of the basic PfTrx-L2 vaccine and its C4bp fusion derivative adsorbed to mesoporus silica-rods (MSR).

Microenvironment and microvascular wall modulate cancer cell progression

Tumour progression is a complex process that frequently brings to cancer metastasis, the first cause of poor prognosis of cancer affected patients. Metastasis are generated by cells escaped from a primary mass and able to enter in the circulation, survive and proliferate in a new, distant site of the organism. To reach all these goal, many different phenomena had occur within both the cancer cells and the surrounding microenvironment. In the first part of this thesis, the focus was pointed on the metastatic potential of a leiomyosarcoma cell model. The studied cancer cells demonstrated a strong invasive capacity of the ECM in vitro, principally by production of matrix metalloproteinases 2 and 9, and robust pro-angiogenic activity in the chick CAM model, that facilitate its dissemination through same chick embryo internal organs. This study, with the title “MMPs and angiogenesis affect the metastatic potential of a human vulvar leiomyosarcoma cell line”, is presented in the published form. In the second part of this work, the emphasis was given to the microvascular element of the tumour microenvironment and specifically to the perivascular pericytes. These are intriguing cells due to their uncertain involvement in the biology of cancer. It is not clear how pericytes change within the tumour microenvironment and which is their contribute during the tumour dissemination. After the characterization of the chosen pericytic cell model, an in vitro study of the interaction between pericytes and different cancer cell lines where performed. Indirect and direct cell-cell interaction as well as movement of cancer cells in presence of pericytes conditioned media was analysed, in order to investigate the reciprocal influence of pericytes and tumour cells in the context of cancer progression.