A new expression vector facilitating production and functional analysis of scFv antibody fragments selected from Tomlinson I+J phagemid libraries.

Tomlinson I+J are synthetic phagemid human scFv libraries widely employed to obtain specific antibody fragments via a phage display method. The pIT2/HB2151 expression system proposed by the designers of the libraries has certain drawbacks which result in the lack of expression or low expression levels of numerous soluble scFvs. At the stage of scFv screening, this may lead to losing some excellent antibodies, which can be avoided but requires laborious and expensive work. Here we present a new, pET-30-based vector, which is compatible with Tomlinson libraries, retains all virtues of pIT2 used as a plasmid and eliminates all its flaws. We demonstrate that pET-scFv-T is frequently superior to pIT2 in terms of efficient scFv expression. Moreover, an amber suppressor bacterial strain, RosettaBlue(DE3)pLysS, transformed with the new vector, pET-scFv-T, coding for a number of scFvs, produces substantial amounts of functional, easy to purify recombinant antibody fragments, regardless of whether their coding sequences contain amber codons. Thus, pET-scFv-T/RosettaBlue(DE3)pLysS expression system seems to be a perfect tool for screening for the finest soluble scFvs selected from Tomlinson I+J, as well as from many other phagemid libraries.

Apoptins: selective anticancer agents.

Therapies that selectively target cancer cells for death have been the center of intense research recently. One potential therapy may involve apoptin proteins, which are able to induce apoptosis in cancer cells leaving normal cells unharmed. Apoptin was originally discovered in the Chicken anemia virus (CAV); however, human gyroviruses (HGyV) have recently been found that also harbor apoptin-like proteins. Although the cancer cell specific activity of these apoptins appears to be well conserved, the precise functions and mechanisms of action are yet to be fully elucidated. Strategies for both delivering apoptin to treat tumors and disseminating the protein inside the tumor body are now being developed, and have shown promise in preclinical animal studies.

Salmonella and cancer: from pathogens to therapeutics.

Bacterial cancer therapy is a concept more than 100 years old - yet, all things considered, it is still in early development. While the use of many passive therapeutics is hindered by the complexity of tumor biology, bacteria offer unique features that can overcome these limitations. Microbial metabolism, motility and sensitivity can lead to site-specific treatment, highly focused on the tumor and safe to other tissues. Activation of tumor-specific immunity is another important mechanism of such therapies. Several bacterial strains have been evaluated as cancer therapeutics so far, Salmonella Typhimurium being one of the most promising. S. Typhimurium and its derivatives have been used both as direct tumoricidal agents and as cancer vaccine vectors. VNP20009, an attenuated mutant of S. Typhimurium, shows significant native toxicity against murine tumors and was studied in a first-in-man phase I clinical trial for toxicity and anticancer activity. While proved to be safe in cancer patients, insufficient tumor colonization of VNP20009 was identified as a major limitation for further clinical development. Antibody-fragment-based targeting of cancer cells is one of the few approaches proposed to overcome this drawback.