Modeling chromosomal translocations using conditional alleles to recapitulate initiating events in human leukemias.

Recurrent reciprocal chromosomal translocations are present in more than 50% of leukemias. A deeper understanding of how they affect cancer initiation is essential for evaluating the origins of cancer and the potential for therapy based on the translocation products. Mouse models of chromosomal translocations are required for this. Here we summarize three methodologies developed in our laboratory to model chromosomal translocations (knock-in, translocator, and invertor methods). We have used these models to study leukemias caused by fusions of the mixed lineage leukemia (MLL) gene and the Ews-ERG fusion gene to evaluate oncogenicity and elucidate some general principles about translocation products. We show that MLL fusions have the capacity to cause hematopoietic tumors only if expressed in permissive cells and that the Mll-Enl fusion can cause lineage reassignment if the chromosomal translocation occurs in lineage noncommitted progenitors. The leukemia-initiating cells generated by Mll fusions or by Ews-ERG fusion can be committed cells within the hematopoietic pathway. Our translocation mimic models are applicable to any human reciprocal chromosomal translocation.

The invertor knock-in conditional chromosomal translocation mimic.

Knock-in models of tumor-specific chromosomal translocations can generate lethal mutations. To circumvent this, a new conditional gene fusion model has been developed (invertor mice) and exemplified with the Ews-ERG fusion oncogene. An ERG segment, flanked by loxP sites, was knocked in to an intron of the Ews gene but in an inverted transcription orientation and lineage-specific Ews-ERG fusion created by Cre-mediated inversion. This invertor method is a completely conditional approach, applicable to any gene fusion, to emulate effects of translocations found in human cancers.

Intracellular antibodies and challenges facing their use as therapeutic agents.

A key feature of antibodies is their ability to bind antigens with high specificity and affinity. This has led to the concept of intracellular antibodies (intrabodies), designed to mimic antibody-antigen binding, but inside cells. Antibody fragments comprising the antigen-binding variable domains are convenient formats for intrabodies, potentially allowing for intracellular functionality. Intrabodies are promising tools, capable of interfering with a wide range of molecular targets in various intracellular compartments. However, many significant challenges remain to be overcome before intrabodies can be useful therapeutic agents. Although major progress has been made in the design and selection of intrabodies, new developments and advances are needed to allow their efficient delivery and expression for treatment of human diseases.

Single domain intracellular antibodies: a minimal fragment for direct in vivo selection of antigen-specific intrabodies.

There is a major need in target validation and therapeutic applications for molecules that can interfere with protein function inside cells. Intracellular antibodies (intrabodies) can bind to specific targets in cells but isolation of intrabodies is currently difficult. Intrabodies are normally single chain Fv fragments comprising variable domains of the immunoglobulin heavy (VH) and light chains (VL). We now demonstrate that single VH domains have excellent intracellular properties of solubility, stability and expression within the cells of higher organisms and can exhibit specific antigen recognition in vivo. We have used this intracellular single variable domain (IDab) format, based on a previously characterised intrabody consensus scaffold, to generate diverse intrabody libraries for direct in vivo screening. IDabs were isolated using two distinct antigens and affinities of isolated IDabs ranged between 20 nM and 200 nM. Moreover, IDabs selected for binding to the RAS protein could inhibit RAS-dependent oncogenic transformation of NIH3T3 cells. The IDab format is therefore ideal for in vivo intrabody use. This approach to intrabodies obviates the need for phage antibody libraries, avoids the requirement for production of antigen in vitro and allows for direct selection of intrabodies in vivo.

De novo production of diverse intracellular antibody libraries.

Many therapeutic targets are intracellular proteins and molecules designed to interact with them must effectively bind to their target inside the cell. Intracellular antibodies (intrabodies) recognise and bind to proteins in cells and various methods have been developed to produce such molecules. Intracellular antibody capture (IAC) is based on a genetic screening approach and is a facile methodology with which effective intracellular antibodies can be obtained. During the development of the IAC technology, consensus immunoglobulin variable frameworks were identified which can form the basis of intrabody libraries for direct screening. In this paper, we describe the de novo synthesis of intrabody libraries based on the IAC consensus sequence. The procedure comprises in vitro production of a single antibody gene fragment from oligonucleotides and diversification of CDRs of the immunoglobulin variable domain by mutagenic PCR. Completely de novo intrabody libraries can be rapidly generated in vitro by these approaches. As an example, a single immunoglobulin VH domain intrabody library was screened directly in yeast with an oncogenic BCR-ABL antigen bait and distinct antigen binders were isolated illustrating the functional utility of the library. This second generation IAC approach (IAC2) has many practical advantages, in particular the ability to isolate intrabodies by direct genetic selection, which obviates the need for in vitro production of antigen for pre-selection of antibody fragments.

Intracellular antibody capture technology: application to selection of intracellular antibodies recognising the BCR-ABL oncogenic protein.

The expression of antibodies inside cells to ablate protein function has the potential for disease therapy and for target validation in functional genomics. However, due to inefficient expression or folding, only a few antibodies or antibody fragments, usually as single-chain Fv antibody fragments (scFv), bind their antigens in an intracellular environment. We have established a genetic-selection technology (intracellular antibody capture, IAC) to facilitate the isolation of functional intracellular scFv from a diverse repertoire. This approach comprises an in vitro library screen with scFv-expressing bacteriophage, employing bacterially expressed antigen, followed by a yeast in vivo antibody-antigen interaction screen of the sub-library of in vitro scFv antigen-binders. Accordingly, we have isolated panels of scFv that bind intracellularly to the BCR or the ABL parts of the BCR-ABL oncogenic protein. Sequence analysis of the intracellular antibody scFv panels revealed a sequence conservation indicating an intracellular antibody consensus for both VH and VL, which could form the basis for the de novo synthesis of intracellular antibody libraries to be used with intracellular antibody-capture technology.