Conformational flexibility of the oncogenic protein LMO2 primes the formation of the multi-protein transcription complex

Sewell, Helen; Tanaka, Tomoyuki; Omari, Kamel El; Mancini, Erika J.; Cruz, Ana Rita; Fernández-Fuentes, Narcís; Chambers, Jennifer S.; Rabbitts, Terence H.

doi:10.1038/srep03643

Cited by 17 publications

(35 citation statements)

References 69 publications

(99 reference statements)

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“…More striking is the observation that IBD is not bound by all three CDR loops, but lies alongside VH59 domain. This unusual antigen binding site is not unprecedented for VH complexes, and is similar to that observed for the complex between the anti-LMO2 VH576 and its LMO2 target 27 , where CDR3 is the only hypervariable loop involved, in addition to contacts within the VH framework amino acids. This is probably the result of the IAC screening procedure, where the VH59 protein sequence was derived from a diverse VH library with 14 amino acids of CDR3 randomized while CDR1 and CDR2 were not 16 .…”

Section: Discussionsupporting

confidence: 70%

Intracellular immunization against HIV infection with an intracellular antibody that mimics HIV integrase binding to the cellular LEDGF protein

Hannon

Cruz-Mignoni

Ptchelkine

et al. 2017

Sci Rep

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Preventing the protein-protein interaction of the cellular chromatin binding protein Lens Epithelium-Derived Growth Factor (LEDGF) and human immunodeficiency virus (HIV) integrase is an important possible strategy for anti-viral treatment for AIDS. We have used Intracellular Antibody Capture technology to isolate a single VH antibody domain that binds to LEDGF. The crystal structure of the LEDGF-VH complex reveals that the single domain antibody mimics the effect of binding of HIV integrase to LEDGF which is crucial for HIV propagation. CD4-expressing T cell lines were constructed to constitutively express the LEDGF-binding VH and these cells showed interference with HIV viral replication, assayed by virus capsid protein p24 production. Therefore, pre-conditioning cells to express antibody fragments confers effective intracellular immunization for preventing chronic viral replication and can be a way to prevent HIV spread in infected patients. This raises the prospect that intracellular immunization strategies that focus on cellular components of viral integrase protein interactions can be used to combat the problems associated with latent HIV virus re-emergence in patients. New genome editing development, such as using CRISPR/cas9, offer the prospect intracellularly immunized T cells in HIV+ patients.

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Section: Discussionsupporting

confidence: 70%

Intracellular immunization against HIV infection with an intracellular antibody that mimics HIV integrase binding to the cellular LEDGF protein

Hannon

Cruz-Mignoni

Ptchelkine

et al. 2017

Sci Rep

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“…These values likely reflect local dynamics; for example, E98 and G105, which lie in a loop and a β-turn, respectively, exhibit low S 2 values. Collectively these data may report intrinsic flexibility within LIM domains (e.g., [68] , [69] , [70] ).…”

Section: Resultsmentioning

confidence: 84%

The Structure of an LIM-Only Protein 4 (LMO4) and Deformed Epidermal Autoregulatory Factor-1 (DEAF1) Complex Reveals a Common Mode of Binding to LMO4

et al. 2014

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LIM-domain only protein 4 (LMO4) is a widely expressed protein with important roles in embryonic development and breast cancer. It has been reported to bind many partners, including the transcription factor Deformed epidermal autoregulatory factor-1 (DEAF1), with which LMO4 shares many biological parallels. We used yeast two-hybrid assays to show that DEAF1 binds both LIM domains of LMO4 and that DEAF1 binds the same face on LMO4 as two other LMO4-binding partners, namely LIM domain binding protein 1 (LDB1) and C-terminal binding protein interacting protein (CtIP/RBBP8). Mutagenic screening analysed by the same method, indicates that the key residues in the interaction lie in LMO4LIM2 and the N-terminal half of the LMO4-binding domain in DEAF1. We generated a stable LMO4LIM2-DEAF1 complex and determined the solution structure of that complex. Although the LMO4-binding domain from DEAF1 is intrinsically disordered, it becomes structured on binding. The structure confirms that LDB1, CtIP and DEAF1 all bind to the same face on LMO4. LMO4 appears to form a hub in protein-protein interaction networks, linking numerous pathways within cells. Competitive binding for LMO4 therefore most likely provides a level of regulation between those different pathways.

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“…The structure and conformational stabilization of LMO2 (green) when bound with LDB1-LID (purple) [ 15 ] is indicated in ( a ). When LMO2 (shown in blue in panel ( b )) is in complex with the anti-LMO2 VH (magenta), there is a conformational distortion, preventing nucleation of the LMO2-complex to the complex illustrated in ( d ) [ 49 ]. Superimposition of the normal LDB1- and VH-bound structures highlights the 23° contortion of the molecule when the anti-LMO2 VH is bound ( e ).…”

Section: Lmo2 Protein Structure and The Multimeric Dna-binding Complementioning

confidence: 99%

“…Superimposition of the normal LDB1- and VH-bound structures highlights the 23° contortion of the molecule when the anti-LMO2 VH is bound ( e ). The hinge region residue Phe88 (red), zinc atoms coordinated by the LIM-fingers (grey spheres) are indicated in both structures, drawn using UCSF Chimaera [ 14 ] from PDB accession codes 2XJY [ 15 ] and 4KFZ [ 49 ]. An in silico model of the structural effects on LMO2 induced by the peptide aptamer PA-207 is shown in ( c ).…”

Section: Lmo2 Protein Structure and The Multimeric Dna-binding Complementioning

confidence: 99%

“…The intracellular antibody fragments also abrogate the neoplastic effect of LMO2 in transgenic LMO2 cell transplantation assays [ 99 , 100 ] mediated by the disruption of the LMO2-complex by preventing LDB1 interaction [ 100 ]. The crystal structure of the LMO2 : VH complex [ 49 ], compared with that of LMO2-LDB1-LID fusion [ 15 ], demonstrates the mechanism. When the VH binds to LMO2, the latter adopts a distorted conformation around its hinge region ( figure 5 b , e ).…”

Section: Pre-clinical Macrodrugs Targeting the Lmo2 Protein Complexmentioning

confidence: 99%

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LMO2 at 25 years: a paradigm of chromosomal translocation proteins

Chambers

Rabbitts

2015

Open Biol.

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LMO2 was first discovered through proximity to frequently occurring chromosomal translocations in T cell acute lymphoblastic leukaemia (T-ALL). Subsequent studies on its role in tumours and in normal settings have highlighted LMO2 as an archetypical chromosomal translocation oncogene, activated by association with antigen receptor gene loci and a paradigm for translocation gene activation in T-ALL. The normal function of LMO2 in haematopoietic cell fate and angiogenesis suggests it is a master gene regulator exerting a dysfunctional control on differentiation following chromosomal translocations. Its importance in T cell neoplasia has been further emphasized by the recurrent findings of interstitial deletions of chromosome 11 near LMO2 and of LMO2 as a target of retroviral insertion gene activation during gene therapy trials for X chromosome-linked severe combined immuno-deficiency syndrome, both types of event leading to similar T cell leukaemia. The discovery of LMO2 in some B cell neoplasias and in some epithelial cancers suggests a more ubiquitous function as an oncogenic protein, and that the current development of novel inhibitors will be of great value in future cancer treatment. Further, the role of LMO2 in angiogenesis and in haematopoietic stem cells (HSCs) bodes well for targeting LMO2 in angiogenic disorders and in generating autologous induced HSCs for application in various clinical indications.

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Conformational flexibility of the oncogenic protein LMO2 primes the formation of the multi-protein transcription complex

Cited by 17 publications

References 69 publications

Intracellular immunization against HIV infection with an intracellular antibody that mimics HIV integrase binding to the cellular LEDGF protein

Intracellular immunization against HIV infection with an intracellular antibody that mimics HIV integrase binding to the cellular LEDGF protein

The Structure of an LIM-Only Protein 4 (LMO4) and Deformed Epidermal Autoregulatory Factor-1 (DEAF1) Complex Reveals a Common Mode of Binding to LMO4

LMO2 at 25 years: a paradigm of chromosomal translocation proteins

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