Trends in adjuvant development for vaccines: DAMPs and PAMPs as potential new adjuvants

Aluminum salts have been widely used in vaccine formulations and, after their introduction more than 80 years ago, only few vaccine formulations using new adjuvants were developed in the last two decades. Recent advances in the understanding of how innate mechanisms influence the adaptive immunity opened up the possibility for the development of new adjuvants in a more rational design. The purpose of this review is to discuss the recent advances in this field regarding the attempts to determine the molecular basis and the general mechanisms underlying the development of new adjuvants, with particular emphasis on the activation of receptors of innate immune recognition. One can anticipate that the use of these novel adjuvants will also provide a window of opportunities for the development of new vaccines.

Mechanisms of cell transformation induced by polyomavirus

Polyomavirus is a DNA tumor virus that induces a variety of tumors in mice. Its genome encodes three proteins, namely large T (LT), middle T (MT), and small T (ST) antigens, that have been implicated in cell transformation and tumorigenesis. LT is associated with cell immortalization, whereas MT plays an essential role in cell transformation by binding to and activating several cytoplasmic proteins that participate in growth factor-induced mitogenic signal transduction to the nucleus. The use of different MT mutants has led to the identification of MT-binding proteins as well as analysis of their importance during cell transformation. Studying the molecular mechanisms of cell transformation by MT has contributed to a better understanding of cell cycle regulation and growth control

Polyomavirus-induced malignant transformation: comparative analysis of wild type and mutant middles T-overexpressing cell lines

Polyomavirus, a DNA tumor virus, expresses three viral oncoproteins (large, middle and small T antigens), causes malignant transformation in cell culture and induces multiple tumors in vivo. The middle T (MT) antigen seems to play an essential role in transformation and tumori-genicity. The observation that MT-overexpressing cell lines are able to grow in the absence of PDGF (platelet-derived growth factor) led several laboratories to study the mechanism underlying MT-induced growth deregulation and the signal transduction pathway used by this viral oncoprotein. A number of cellular proteins were shown to be common to both the normal PDGF mitogenic pathway and the MT transforming pathway. The expression of some PDGF primary response genes (fos, jun, myc, JE, KC) was shown to be rendered constitutive by MT overexpression. Using MT mutants, important domains for binding and activation of cytoplasmic proteins were mapped. Wild type and mutant MT cell lines are used in our laboratory to analyze the expression and activity of the PDGF early response genes during cell transformation and correlate them with activation of specific cytoplasmic proteins. In addition to abrogating the PDGF requirement for growth, activation of cellular proteins caused by MT results in cell lines that have an altered morphology and are able to form colonies in agarose. These changes may be due to alterations in connexin 43 and other cell surface proteins.

Molecular genetic approach to cell proliferation control and neoplasia

A number of gene products involved in the control of cell proliferation fall into one of two classes: oncogenes and tumor suppressor genes. The same gene products have also been associated with malignant growth (tumors) caused by radiation, chemicals and tumor viruses. Here we describe our attempts to elucidate the molecular mechanisms underlying polyomavirus-induced cell transformation and the anti-tumor activity of glucocorticoid hormones. Wild type and mutant polyomavirus middle T (MT) overexpressing cell lines, generated with retroviral vector constructs, were used to investigate the role played by peptide growth factor primary response genes (fos, jun, myc, JE, KC) in viral transformation and to map the transduction pathway of the mitogenic signal of MT. Overexpression of MT leads to increased AP-1 (Fos/Jun) transcriptional complex activity. Transformation defective mutant analysis allowed the identification of sites in the MT molecule that are crucial for this activity. Two different approaches were used to investigate the molecular basis for glucocorticoids anti-tumor activity, namely: blind cloning of cDNAs and analysis of growth control genes in C6 glioma cell variants that are either hypersensitive (C6/ST1) or unresponsive to glucocorticoids (C6/P7). Four different glucocorticoid-regulated cDNA sequences were isolated using differential hybridization. A number of differentially expressed sequences were isolated from glucocorticoid-treated C6/ST1 cells by differential display (DDRT-PCR) and are currently being characterized. Expression of known growth control genes in C6/ST1 cells allowed the identification of important candidates for glucocorticoid hormone targets.