Expression of periplasmic chaperones in Salmonella Typhimurium reduces its viability in vivo.

The efficacy of live attenuated bacterial vectors is dependent upon the fine-tuning of a strain's immunogenicity and its virulence. Strains are often engineered to deliver heterologous antigens, but soluble expression of recombinant proteins can be troublesome. Therefore, secretion systems or chaperone proteins are routinely used to assist in attaining high levels of functional, soluble protein production. However, the effects of chaperone expression on the virulence of attenuated bacterial vectors have not been previously reported. In anticipation of utilizing periplasmic chaperone proteins to facilitate soluble production of immunomodulatory proteins in an attenuated strain of Salmonella Typhimurium, the production of the chaperones was tested for their effect on both culture growth and bacterial persistence in mouse tissues. Although no effect on growth of the bacteria was observed in vitro, the increased expression of the periplasmic chaperones resulted in over-attenuation of the Salmonella in vivo.

Soluble production of a biologically active single-chain antibody against murine PD-L1 in Escherichia coli.

Programmed death ligand 1 (PD-L1), is an important regulator of T-cell activation and has emerged as an important target for cancer immunotherapy. Single chain variable fragments (scFvs) have several desirable characteristics and are an attractive alternative to monoclonal antibodies for experimental or therapeutic purposes. Three chickens were immunized against murine PD-L1, and mRNA isolated from their spleens was used to generate an immunized immunoglobulin variable region library. Using splice-overlap extension PCR, variable region cDNAs were combined to generate full-length scFvs. M13 phage display of the resulting scFv library identified a functional scFv against PD-L1 (αPD-L1 scFv). The scFv was expressed as soluble protein in the periplasm and culture supernatant of recombinant Escherichia coli and purified with a 6×-His tag using immobile metal affinity chromatography. The dissociation constant of αPD-L1 scFv was determined to be 7.11×10(-10)M, and the scFv demonstrated inhibitory biological activity comparable to an antagonistic monoclonal antibody, providing an alternative agent for blocking PD-1/PD-L1 signaling.

Salmonella enterica Typhimurium engineered for nontoxic systemic colonization of autochthonous tumors.

Much of the bacterial anticancer therapy being developed relies on the ability of bacteria to specifically colonise tumours. Initial attempts to translate promising Salmonella enterica Typhimurium (S. Typhimurium) preclinical results to the clinical setting failed, primarily due to lack of tumour colonisation and the significant toxicities from systemically administered Gram-negative bacteria. To address the difference in results between preclinical experiments performed in mice with transplant tumours and clinical trials in human volunteers with autochthonous tumours, a genetically engineered mouse model of breast cancer (BALB-neuT) was utilised to develop a strain of virulence-attenuated S. Typhimurium capable of robust colonisation of autochthonous tumours. Several genes that code for bacterial surface molecules, responsible for signalling a toxic immune response against the bacteria, were mutated. The resulting S. Typhimurium strain, BCT2, allowed non-toxic intravenous administration of 3 × 106 colony forming units of bacteria in tumour-burdened mice when combined with a vascular disruption agent to induce intratumoral necrotic space and facilitate bacterial colonisation.

Virulence-attenuated Salmonella engineered to secrete immunomodulators reduce tumour growth and increase survival in an autochthonous mouse model of breast cancer.

The ultimate goal of bacterial based cancer therapy is to achieve non-toxic penetration and colonisation of the tumour microenvironment. To overcome this efficacy-limiting toxicity of anticancer immunotherapy, we have tested a therapy comprised of systemic delivery of a vascular disrupting agent to induce intratumoral necrotic space, cannabidiol to temporarily inhibit angiogenesis and acute inflammation, and a strain of Salmonella Typhimurium that was engineered for non-toxic colonisation and expression of immunomodulators within the tumour microenvironment. This combination treatment strategy was administered to transgenic mice burdened with autochthonous mammary gland tumours and demonstrated a statistically significant 64% slower tumour growth and a 25% increase in mean survival time compared to control animals without treatment. These experiments were accomplished with minimal toxicity as measured by less than 7% weight loss and a return to normal weight gain within three days following intravenous administration of the bacteria. Thus, non-toxic, robust colonisation of the microenvironment was achieved to produce a significant antitumor effect.

Hepatic expression of the SPOT 14 (S14) paralog S14-related (Mid1 interacting protein) is regulated by dietary carbohydrate.

The Spot 14 (S14) gene is rapidly up-regulated by signals that induce lipogenesis such as enhanced glucose metabolism and thyroid hormone administration. Previous studies in S14 null mice show that S14 is required for normal lipogenesis in the lactating mammary gland, but not the liver. We speculated that the lack of a hepatic phenotype was due to the expression of a compensatory gene. We recently reported that this gene is likely an S14 paralog that we named S14-Related (S14-R). S14-R is expressed in the liver, but not in the mammary gland. If S14-R compensates for the absence of S14 in the liver, we hypothesized that, like S14, S14-R expression should be glucose responsive. Here, we report that hepatic S14-R mRNA levels increase with high-carbohydrate feeding in mice or within 2 h of treating cultured hepatocytes with elevated glucose. A potential carbohydrate response element (ChoRE) was identified at position -458 of the S14-R promoter. Deletion of or point mutations within the putative S14-R ChoRE led to 50-95% inhibition of the glucose response. Gel-shift analysis revealed that the glucose-activated transcription complex carbohydrate responsive element-binding protein/Max-like protein X (Mlx) binds to the S14-R ChoRE. Finally, S14-R glucose induction is completely blocked when a dominant-negative form of Mlx is overexpressed in primary hepatocytes. In conclusion, our results indicate that the S14-R gene is a glucose-responsive target of carbohydrate responsive element-binding protein/Mlx and suggest that the S14-R protein is a compensatory factor, at least partially responsible for the normal liver lipogenesis observed in the S14 null mouse.

S14: insights from knockout mice.

Spot 14 (S14) is a protein whose mRNA is rapidly up-regulated by lipogenic stimuli including thyroid hormone and a high-carbohydrate diet. Previous investigation into the role of S14 suggested that it is involved in de novo lipogenesis. Knockout of the gene in mice has given further support to this hypothesis. The lack of S14 in different tissues resulted in varying phenotypic effects. In the lactating mammary gland, levels of lipogenesis, specifically the production of medium chain fatty acids, were decreased, whereas hepatic lipogenesis was not decreased. In fact, hepatic lipogenesis was increased, and the increase may be due to compensation by a paralog of S14 called S14-R. S14-R is expressed in the liver but not the mammary gland. Importantly, S14 knockout mice did not have reduced levels of lipogenic enzymes, implying that it does not affect the transcriptional rate of those enzymes. Instead, S14 may act in the cytoplasm to affect lipogenesis.

A phase I clinical study to evaluate safety of orally administered, genetically engineered Salmonella enterica serovar Typhimurium for canine osteosarcoma.

We conducted a prospective phase I study to evaluate safety of an orally administered Salmonella encoding IL-2 (SalpIL2) in combination with amputation and adjuvant doxorubicin for canine appendicular osteosarcoma. Efficacy was assessed as a secondary measure. The first dose of SalpIL2 was administered to 19 dogs on Day 0; amputation was done after 10 days with chemotherapy following 2 weeks later. SalpIL2 was administered concurrent with chemotherapy, for a total of five doses of doxorubicin and six doses of SalpIL2. There were six reportable events prior to chemotherapy, but none appeared due to SalpIL2. Dogs receiving SalpIL2 had significantly longer disease-free interval (DFI) than a comparison group of dogs treated with doxorubicin alone. Dogs treated using lower doses of SalpIL2 also had longer DFI than dogs treated using the highest SalpIL2 dose. The data indicate that SalpIL2 is safe and well tolerated, which supports additional testing to establish the potential for SalpIL2 as a novel form of adjuvant therapy for dogs with osteosarcoma.

Vasculature Disruption Enhances Bacterial Targeting of Autochthonous Tumors.

Attenuated Salmonella enterica serovar Typhimurium (S. Typhimurium) has been developed as a vector to deliver therapeutic agents to tumors. The potential of S. Typhimurium in cancer therapy is largely due to its reported propensity to accumulate at greater than 1,000-fold higher concentrations in tumors relative to healthy tissues. In this study, we compared bacterial colonization of tumors in a subcutaneous transplantation model with a more clinically relevant autochthonous tumor model. Following intravenous administration of attenuated S. Typhimurium strain SL3261, we observed approximately 10,000-fold less bacteria in autochthonous tumors that sporadically develop in transgenic BALB-neuT mice compared to tumors developed from subcutaneous transplantation of 4T1 murine breast cancer cells in BALB/c mice. Treatment of BALB-neuT mice with a vasculature-disrupting agent (VDA) prior to bacterial treatment caused necrosis of tumor tissue and significantly increased the bacterial targeting of autochthonous tumors by approximately 1,000-fold. These observations emphasize the importance of appropriate model selection in developing bacteria-based cancer therapies and demonstrate the potential of combining VDA pre-treatment with bacteria to facilitate targeting of clinically relevant tumors.

Antioxidant oils and Salmonella enterica Typhimurium reduce tumor in an experimental model of hepatic metastasis.

Fruit seeds high in antioxidants have been shown to have anticancer properties and enhance host protection against microbial infection. Recently we showed that a single oral dose of Salmonella enterica serovar Typhimurium expressing a truncated human interleukin-2 gene (SalpIL2) is avirulent, immunogenic, and reduces hepatic metastases through increased natural killer cell populations in mice. To determine whether antioxidant compounds enhance the antitumor effect seen in SalpIL2-treated animals, we assayed black cumin (BC), black raspberry (BR), and milk thistle (MT) seed oils for the ability to reduce experimental hepatic metastases in mice. In animals without tumor, BC and BR oil diets altered the kinetics of the splenic lymphocyte response to SalpIL2. Consistent with previous reports, BR and BC seed oils demonstrated independent antitumor properties and moderate adjuvant potential with SalpIL2. MT oil, however, inhibited the efficacy of SalpIL2 in our model. Based on these data, we conclude that a diet high in antioxidant oils promoted a more robust immune response to SalpIL2, thus enhancing its antitumor efficacy.

Gene repair and transposon-mediated gene therapy.

The main strategy of gene therapy has traditionally been focused on gene augmentation. This approach typically involves the introduction of an expression system designed to express a specific protein in the transfected cell. Both the basic and clinical sciences have generated enough information to suggest that gene therapy would eventually alter the fundamental practice of modern medicine. However, despite progress in the field, widespread clinical applications and success have not been achieved. The myriad deficiencies associated with gene augmentation have resulted in the development of alternative approaches to treat inherited and acquired genetic disorders. One, derived primarily from the pioneering work of homologous recombination, is gene repair. Simply stated, the process involves targeting the mutation in situ for gene correction and a return to normal gene function. Site-specific genetic repair has many advantages over augmentation although it too is associated with significant limitations. This review outlines the advantages and disadvantages of gene correction. In particular, we discuss technologies based on chimeric RNA/DNA oligonucleotides, single-stranded and triplex-forming oligonucleotides, and small fragment homologous replacement. While each of these approaches is different, they all share a number of common characteristics, including the need for efficient delivery of nucleic acids to the nucleus. In addition, we review the potential application of a novel and exciting nonviral gene augmentation strategy--the Sleeping Beauty transposon system.