Team:Warsaw/Project/detailed

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Detailed research project

Contents

Introduction

Fig 1. The overview of the system.
Fig 1. The overview of the system. Gene regulatory network is composed of three modules: invasion operon, endosome detection operon and cytoplasmic operon. Invasion and cytoplasmic operon are bistable switches regulated by endosome detection operon.

This project attempts to create E. coli strain capable of entering the eukaryotic cells by means of controlled expression of invasin gene from Yersinia sp. together with internalinA gene from Listeria monocytogenes st. EDG-e. This leads to internalization of the bacteria into the phagosome of the host cell. To escape the endosome we will apply bacterial hemolysin (listeriolysin) from Listeria monocytogenes. The coordination of protein expression is based on switching the E. coli cells between four physiological states: growth in the medium, ability to enter mammalian cells, presence in the phagosome, and escape from the phagosome into the cytoplasm. (Fig1.). Two component system PhoP/PhoQ from Salmonella enterica ser. typhimurium LT2 will be used to detect the states. It activates PhoP dependent promoters in the endosomal environment (low pH, low metal ions concentration). Each of the states will be stabilised by two feedback loops based on natural regulatory systems. System is composed of three synthetic operons [18].

Invasion operon

Fig 2. The overview of the invasion operon.
Fig 2. The overview of the invasion operon. It is based on a lacI/cI bistable switch. After thermal activation (42°C) the expression of genes that enable invasion of mammalian cells is activated. The invasion operon is composed of lacI – lactose operon repressor, llo – hemolysin from Listeria monocytogenes, inv – invasin from Yersinia sp., phoQ/phoP two component system detecting endosomal conditions from Salmonella typhimurium, GFP – Green Fluorescent Protein from Aqueora victoria. Proteins are fused with LVA sequence which provides quick proteolytic degradation.

The invasion operon includes lacI– lactose operon repressor, llo – hemolysin from Listeria monocytogenes (listeriolysin), inv – invasin from Yersinia sp., PhoP/PhoQ two component system that detects endosomal conditions from Salmonella typhimurium, GFP – green fluorescent protein. (Fig.2.). These genes are under the control of bacteriophage promoter (PR) that is repressed by cI protein. The second part of the operon is gene cIts that encodes for thermosensitive version of the cI repressor protein from phage λ. It is under the control of lactose promoter (Plac). This λ system of promoters and regulatory genes creates two mutually exclusive negative feedback loops and is dubbed the bistable switch [19]. It has two states depending on conditions within the cell. cI protein binds the PR promoter inhibiting its activity and expression of the invasion operon genes. cIts protein is inactivated by high temperature 42°C it allows the expression of invasion operon that codes for lacI. lacI stops gene expression from the Plac promoter ( the expression of cI protein). IPTG that binds and inactivates lacI can be used to switch on the expression from Plac promoter. Another way to control the operon is in trans expression of cI or lacI genes. Activated invasion operon causes internalisation of bacteria by mammalian cells. It also detects endosomal localisation using PhoP/PhoQ system. Expression of green fluorescence protein allows observation of the process using confocal microscopy.

Endosome detection operon

Fig 3. Overview of endosomal detection operon.
Fig 3. Overview of endosomal detection operon. It is composed of cro – antirepressor from phage λ, tetR – repressor of tetracycline resistance operon, cI – repressor from phage λ and cfp – Cyan Fluorescent Protein.

Low endosomal pH and low concentration of metal ions lead to decrease the likelihood of transmembrane receptor kinase phoQ binding its ligands – divalent cations. This enables the phosphorylation of phoP by phoQ. Phosphorylated phoP activates the gene expression from MgtC promoter leading to production of proteins encoded by endosome detection operon. cI protein inactivates the invasion operon. TetR protein activates cytoplasmic operon. Not all genes encoded by cytoplasmic operon are expressed in endosome, due to the presence of cro box sequence, which binds cro protein thus stopping the trancription Cro protein is encoded by endosome detection operon. After bacterium escapes into cytoplasm the endosome detection operon genes are no longer expressed, since phoP is not phosphorylated in cytoplasmic conditions. The process can be monitored using CFP fluorescence protein.

The cytoplasmic operon.

Fig 4. Overview of endosomal detection operon.
Fig 4. Overview of endosomal detection operon. It is composed of YFP – Yellow Fluorescent Protein, tetR – repressor of a tetracycline resistance operon, cro box regulatory sequence from phage and λ desired genes and genes specific for desired function of bacterial strain. In this case p53 – apoptosis inducer.

Cytoplasmic operon, like the invasion operon, is a bistable switch. The regulatory elements are: synthetic promoter inhibited by TetR, promoter inhibited by araC, araC protein (inactivated by L-arabinose) and TetR protein (repressor of tetracycline resistance gene inactivated by tetracycline). [18] This switch controls genes expressed in the cytoplasm. Cro box confines the gene expression to the cytoplasm only. Cro protein bound to it stops the transcription while the endosome detection operon is expressed. The yellow florescence protein is expressed to allow detection of the cytoplasmic operon activity. The set of genes in the cytoplasmic operon depends on the desired functionality of bacterial strain. In case of antitumor therapy could be the p53 protein with mitochondrial leader sequence. In the strain capable of conjugation with mitochondria cytoplasmic operon will control genes responsible for the conjugation process.

The mechanism of proposed regulatory system.

In the growth medium (at 37 °C) the expression of all genetic circuits is inactive. After temperature increases to 42°C the system is activated by thermal degradation of cIts. Genes from invasion operon are transcribed. They maintain their own expression, initiate internalisation of E. coli by mammalian cells and enable escape from endosome. When bacterial cell is inside the endosome the endosome detection module is activated by PhoP/PhoQ system. In trans expression of regulatory genes cI and tetR deactivates invasion operon and activates cytoplasmic operon. However its genes are not expressed as long as bacterial cell is inside endosome due to cro protein activity. When bacterium escapes from the endosome, the transcription from endosome detection operon is repressed and cytoplasmic operon genes are expressed.

Conjugation with mitochondria.

To locate the copy of the mitochondrial genome into bacterial cell the pBACrNESd plasmid will be used. It is built basing the Bacterial Artificial Chromosome. Replication origin (ori R6K), kanamycin resistance gen (kanR) and replication complex genes (repE, parA, parC) from pBACrNESd plasmid will be fused with origin of transfer (oriTF) from natural conjugative F plasmid. Unique restriction site will be introduced into the mitochondrial genome by PCR reaction and the described construct will be inserted into mitochondrion. To enable conjugation proteins encoded on RP4 plasmid (Tc, MuKm, Tn7) will be placed in the cytoplasmic operon. These genes are responsible for pillus formation and transport of single stranded DNA. The cell with this system will conjugate with any structure surround by lipid bilayer. We will prepare mitochondrial DNA deficient cells using a previously described procedure [2]. The occurrence of conjugation will be confirmed by PCR reaction specific for sequences added to mitochondrial DNA. The origin of the DNA will be determined by analysis of restriction patterns. The expression of mitochondrial genes will be confirmed by semi-quantitative PCR [2].

Secretion of p53 into the cytoplasm

To efficiently transport p53 to the eukaryotic cells the endogenic E. coli secretion system responsible for secretion of hemolysin by uropathogenic strains will be used. It is composed of three transport proteins HlyB, HlyD and TolC [10]. TolC is present in the genome of the lab strain derived from K12 strain. To ensure efficient secretion hlyB and hlyD have to be introduced into the genome and proapoptotic protein has to be fused with 60 amino acid long C-terminal sequence of hemolysin. [5].

Directing bacterial proteins to mammalian mitochondria.

One of the nescessary objectives is to direct a fraction of secreted proteins into the mitochondrion. This will be achieved by fusion of mitochondrial leader sequence from human protein Cox1 to the N-terminus of proteins. It has been shown that 40 amino acids long N-terminal sequence is enough for effective transport of Cox1 across the mitochondrial membrane. First the efficiency of the process will be assessed by detection of Red Fluorescent Protein with confocal microscopy. The red fluorescence should be visible in the mitochondria of the cells invaded by bacteria expressing RFP fused with the mitochondrial leader sequence. Then the ability to induce apoptosis by mitochondrially directed p53 will be investigated. Apoptosis induction will be confirmed by flow cytometry [8]. In addition we will use confocal microscopy to monitor the process. In both cases cells will be stained with propidium iodide and annexin V.

Error proofing and disposing of the run down bacteria

During the course of planing we have given much thought to the issue of error proofing. When the project will be finalised we'll be dealing with a potentially dangerous microbe, capable of entering eukaryotic cells. This forced us develop a method of emergency killing the bacteria at any given time, a so called "kill switch". We chose to use a toxin/antitoxin system (MazF/MazE for example) in which both proteins are produced at equal levels. The antitoxin will be expressed from a promoter that is easily inhibited by small size particles capable of penetrating inside the cell. If at any moment we decide to terminate the treatment the introduction of such a particle to the blood stream will cause the bacterium to halt the production of the antitoxin thus effectively killing itself.

The other problem we have faced was what to do with the bacteria that have already completed their task. If such a bacterium finds itself absorbed by a white blood cell along with the apoptosomes it might start inducing apoptosis to its new host. Our solution to that problem was inspired by the Team Waterloo's 2008 project. The cytoplasmic operon could be supplemented with an additional endonucleolitic enzyme, one that would dispose of every unnecessary peace of DNA including bacteria's genome and previous operons. Such a vessel could only carry out the one final step (be it protein secretion or conjugation) over and over again until it depletes all its resources becoming eventually digested by either the host cell or along with the apoptotic remnants.