Shuanglin Xiang

Short hairpin RNA–expressing bacteria elicit RNA interference in mammals

RNA-interference (RNAi) is a potent mechanism, conserved from plants to humans for specific silencing of genes, which holds promise for functional genomics and gene-targeted therapies. Here we show that bacteria engineered to produce a short hairpin RNA (shRNA) targeting a mammalian gene induce trans-kingdom RNAi in vitro and in vivo. Nonpathogenic Escherichia coli were engineered to transcribe shRNAs from a plasmid containing the invasin gene Inv and the listeriolysin O gene HlyA, which encode two bacterial factors needed for successful transfer of the shRNAs into mammalian cells. Upon oral or intravenous administration, E. coli encoding shRNA against CTNNB1 (catenin β-1) induce significant gene silencing in the intestinal epithelium and in human colon cancer xenografts in mice. These results provide an example of trans-kingdom RNAi in higher organisms and suggest the potential of bacteria-mediated RNAi for functional genomics, therapeutic target validation and development of clinically compatible RNAi-based therapies.

Delivery of RNA Interference

Over the last few years, RNA Interference (RNAi), a naturally occurring mechanism of gene regulation conserved in plant and mammalian cells, has opened numerous novel opportunities for basic research across the field of biology. While RNAi has helped accelerate discovery and understanding of gene functions, it also has great potential as a therapeutic and potentially prophylactic modality. Challenging diseases failing conventional therapeutics could become treatable by specific silencing of key pathogenic genes. More specifically, therapeutic targets previously deemed “undruggable” by small molecules, are now coming within reach of RNAi based therapy. For RNAi to be effective and elicit gene silencing response, the double-stranded RNA molecules must be delivered to the target cell. Unfortunately, delivery of these RNA duplexes has been challenging, halting rapid development of RNAi-based therapies. In this review we present current advancements in the field of siRNA delivery methods, including the pros and cons of each method.

Induction of cancer cell stemness by chemotherapy

Recent studies indicate that cancer stem cells (CSCs) exist in most hematological and solid tumors. CSCs are characterized by their ability to self-renew and their capacity to differentiate into the multitude of cells that comprise the tumor mass. Moreover, these cells have been shown to be intrinsically resistant to conventional anticancer therapies. Despite their fundamental role in cancer pathogenesis, the cellular origin of CSCs remains highly controversial. The aim of this study was to examine whether heterogeneous cancer cells can acquire stem cell-like properties in response to chemotherapy. We demonstrate that carboplatin can induce the self-renewal (spherogenesis) and pluripotency (Sox2 and Oct3/4 expression) of hepatocellular carcinoma (HCC) cells grown under stem cell culture conditions. Moreover, we show that non-CSC cells, obtained by side population flow cytometric sorting using Hoechst 33342, can acquire stem-like properties after exposure to carboplatin. Finally, we show that knockdown of Sox2 and Oct3/4 gene expression in HCC cells can reduce carboplatin-mediated increases in sphere formation and increase cellular sensitivity to chemotherapy. Taken together, our data indicate that bulk cancer cells may be an important source of CSCs during tumor development, and that targeting Sox2 and/or Oct3/4 may be a promising approach for targeting CSCs in clinical cancer treatment.

Genomic instability in precancerous lesions before inactivation of tumor suppressors p53 and APC in patients

The etiology and significance of genomic instability (GIN), a hallmark of human cancers, remains controversial. The paradigm that inactivation of tumor suppressors (e.g. p53 or adenomatous polyposis coli (APC) genes) leads to GIN is largely based on experiments in vitro and in animal models. It remains unclear whether GIN is a cause or a result of cancer, particularly in patients. Precancerous Barrett’s esophagus (BE) provides a clinical model to investigate GIN in cancer progression. We analyzed specimens from endoscopic biopsies or esophagectomies in patients with BE (10 cases), BE-associated esophageal adenocarcinoma (10 cases), or with normal gastro-esophageal junction (5 cases). Chromosomal enumeration probe Cep 7, 11, 12, 17 and 18 were detected by fluorescence in situ hybridization (FISH). Expression of p53 and APC were determined by immunohistochemistry. Increased p53 expression, a measurement of p53 mutations, was observed in BE with high grade dysplasia (HGD) and in BE-associated esophageal cancer (EC). The expression of wild type APC was decreased in BE with HGD and in advanced EC. Chromosomal abnormalities were found in all EC samples. Numeric changes of chromosome 7, 11 and 12 were observed in BE in 14%, 64% and 43% of cases, respectively. Aneusomy of chromosome 11 and 12 were found in ME and in BE without dysplasia, in the presence of normal expression pattern of p53 and APC. Our results suggest that GIN is an early event that occurs at precancerous stages prior to changes in tumor suppressor genes (p53 and APC) in BE-associated tumorigenesis in patients, suggesting that GIN may serve as a causative link between chronic inflammation and cancer.

In Vitro and In Vivo Gene Silencing by TransKingdom RNAi (tkRNAi)

RNA interference (RNAi) is a potent and specific mechanism for eliminating the mRNA of specific genes. This gene silencing mechanism occurs naturally and is highly conserved from plants to human cells, holding promise for functional genomics and for revolutionizing medicine due to its unlimited potential to treat genetic, epigenetic, and infectious disease. However, efforts to unleash the enormous potential of RNAi have met with significant challenges. Delivery is problematic because short interfering RNAs (siRNA) are negatively charged polymers that inefficiently enter cells and undergo rapid enzymatic degradation in vivo. In addition, the synthesis of siRNAs is expensive for long-term research and therapeutic applications. Recently, we have shown that nonpathogenic bacteria can be engineered to activate RNAi in mammalian cells (TransKingdom RNA interference; tkRNAi). This new approach offers several advantages and has significant implications. First, this method allows the establishment of a long-term stable gene silencing system in the laboratory against genes of interests in vitro and in vivo, and enables high-throughput functional genomics screening in mammalian systems. RNAi libraries can be constructed, stored, reproduced, amplified, and used with the help of E. coli as currently done with gene cloning. Second, this technology provides a clinically compatible way to achieve RNAi for therapeutic applications due to the proven clinical safety ofnonpathogenic bacteria as a gene carrier, tkRNAi also eliminates the siRNA manufacture issue, and may circumvent or mitigate host interferon-like responses since siRNA is produced intracellularly.

Cequent Pharmaceuticals, Inc.: the biological pitcher for RNAi therapeutics.

Cequent Pharmaceuticals, Inc. is a recently established biopharmaceutical company that aims to develop clinically compatible therapies based on RNAi, a potent gene-silencing mechanism discovered in 1998. The companys proprietary technology, transkingdom RNAi (tkRNAi), uses nonpathogenic bacteria to produce and deliver shRNA into target cells to induce RNAi. Our initial focus is on the development of a tkRNAi-based therapy for familial adenatomous polyposis, an inherited form of colon cancer. Cequents first tkRNAi-based drug for familial adenatomous polyposis, CEQ501, is currently in advanced preclinical testing. As part of its ongoing activities, Cequent plans to develop additional tkRNAi-based products for indications within and outside the GI tract. Our overall goal is to establish tkRNAi as a platform for developing a wide range of RNAi-based therapies.

TransKingdom RNA interference : a bacterial approach to challenges in RNAi therapy and delivery

Abstract Since its discovery in 1998 RNA interference (RNAi), a potent and highly selective gene silencing mechanism, has revolutionized the field of biological science. The ability of RNAi to specifically down-regulate the expression of any cellular protein has had a profound impact on the study of gene function in vitro. This property of RNAi also holds great promise for in vivo functional genomics and interventions against a wide spectrum of diseases, especially those with “undruggable” therapeutic targets. Despite the enormous potential of RNAi for medicine, development of in vivo applications has met with significant problems, particularly in terms of delivery. For effective gene silencing to occur, silencing RNA must reach the cytoplasm of the target cell. Consequently, various strategies using chemically modified siRNA, liposomes, nanoparticles and viral vectors are being developed to deliver silencing RNA. These approaches, however, can be expensive and in many cases they lack target cell specificity or clinical compatibility. Recently, we have shown that RNAi can be activated in vitro and in vivo by non-pathogenic bacteria engineered to manufacture