The nanoparticulate Quillaja saponin KGI exerts anti-proliferative effects by down-regulation of cell cycle molecules in U937 and HL-60 human leukemia cells.

Cancer cells are characterized by uncontrolled replication involving loss of control of cyclin dependent kinases (CDKs) and cyclins, and by abolished differentiation. In this study we introduce KGI, which is a nanoparticle with a Quillaja saponin as an active molecule. By the use of RNA array analysis and confirmation at the protein level, we show that KGI affects myeloid leukemia cells (in particular, the U937 monoblast cancer cell) by the following mechanisms: (A) ceasing cell replication via proteasome degradation, (B) down-regulation of key molecules at check points between G1/S and G2/M phases, (C) reduction of thymidine kinase activity, followed by (D) exit to differentiation and production of interleukin-8 (IL-8), eventually leading to apoptosis.

The Nanoparticulate Quillaja Saponin BBE is selectively active towards renal cell carcinoma.

Aim: To characterize the cytotoxic effect of BBE, the particulate of desacyl-saponin, in model systems of solid tumours.

Materials And Methods: Cytotoxic activity of BBE was investigated in solid human tumour cell lines, in tumour cells from patients with renal cell carcinoma, in normal human renal cells and in peripheral blood mononuclear cells. The BBE mode of cell death was assessed in vitro.

Nanoparticulate Quillaja saponin induces apoptosis in human leukemia cell lines with a high therapeutic index.

Saponin fractions of Quillaja saponaria Molina (QS) have cytotoxic activity against cancer cells in vitro, but are too toxic to be useful in the clinic. The toxic effect was abolished by converting QS fractions into stable nanoparticles through the binding of QS to cholesterol. Two fractions of QS were selected for particle formation, one with an acyl-chain (ASAP) was used to form killing and growth-inhibiting (KGI) particles, and the other without the acyl-chain (DSAP) was used to formulate blocking and balancing effect (BBE) particles.

Binary AdEasy vector systems designed for Tet-ON or Tet-OFF regulated control of transgene expression.

Here, we describe the construction of a set of binary adenovirus vectors encoding for a tetracycline-regulatable expression cassette and the Tet-ON or the Tet-OFF transcriptional activator proteins from a single viral chromosome. The rabies virus glycoprotein was cloned into the E1 region and the tetracycline activator proteins were inserted in both orientation in place of the E3 region. To further restrict background transcription, we also introduced a Lac repressor protein based roadblock to transcription elongation.

Suppression of RNA interference by adenovirus virus-associated RNA.

We show that human adenovirus inhibits RNA interference (RNAi) at late times of infection by suppressing the activity of two key enzyme systems involved, Dicer and RNA-induced silencing complex (RISC). To define the mechanisms by which adenovirus blocks RNAi, we used a panel of mutant adenoviruses defective in virus-associated (VA) RNA expression. The results show that the virus-associated RNAs, VA RNAI and VA RNAII, function as suppressors of RNAi by interfering with the activity of Dicer.

Unscheduled expression of capsid protein IIIa results in defects in adenovirus major late mRNA and protein expression.

Adenovirus gene expression is to a large extent regulated at the level of alternative RNA splicing. For example, in the major late region 1 (L1) unit, a common 5' splice site can be joined to two alternative 3' splice sites, resulting in the formation of the so-called 52,55K (proximal 3' splice site) or the IIIa (distal 3' splice site) mRNAs. Whereas, the 52,55K mRNA is expressed both early and late during infection, the IIIa mRNA is strictly confined to the late phase of the infectious cycle.