Selection of aptamers using ß-1,3-glucan recognition protein-tagged proteins and curdlan beads.

RNA aptamersare nucleic acids that are obtained using the systematic evolution of ligands by exponential enrichment (SELEX) method. When using conventional selection methods to immobilize target proteins on matrix beads using protein tags, sequences are obtained that bind not only to the target proteins but also to the protein tags and matrix beads. In this study, we performed SELEX using ß-1,3-glucan recognition protein (GRP)-tags and curdlan beads to immobilize the acute myeloid leukaemia 1 (AML1) Runt domain (RD) and analysed the enrichment of aptamers using high-throughput sequencing. Comparison of aptamer enrichment using the GRP-tag and His-tag suggested that aptamers were enriched using the GRP-tag as well as using the His-tag. Furthermore, surface plasmon resonance analysis revealed that the aptamer did not bind to the GRP-tag and that the conjugation of the GRP-tag to RD weakened the interaction between the aptamer and RD. The GRP-tag could have acted as a competitor to reduce weakly bound RNAs. Therefore, the affinity system of the GRP-tagged proteins and curdlan beads is suitable for obtaining specific aptamers using SELEX.

UBC9 inhibits myeloid differentiation in collaboration with AML1-MTG8.

The chimeric oncogene AML1-MTG8 (RUNX1-RUNX1T1) is generated in t(8;21) acute myeloid leukemia (AML). Here, we report a novel interaction of MTG8/RUNX1T1/ETO with UBC9/UBE2I. AML1-MTG8 protein also interacted with UBC9, suggesting a role in leukemogenesis. Overexpression of UBC9 in Kasumi-1 attenuated myeloid differentiation induced by all-trans retinoic acid, G-CSF, and GM-CSF (AGGM), which was judged by suppression of CD11b. In addition, the UBC9 inhibitor 2-D08 accelerated myeloid differentiation induced by AGGM in two t(8;21) AML cell lines, Kasumi-1 and SKNO-1. These data suggest that UBC9 may play a role in leukemogenesis in t(8;21) AML by working with AML1-MTG8 to suppress myeloid differentiation. Therefore, UBC9 may be a good target for new differentiation therapy against t(8;21) AML.

A G-quadruplex-forming RNA aptamer binds to the MTG8 TAFH domain and dissociates the leukemic AML1-MTG8 fusion protein from DNA.

MTG8 (RUNX1T1) is a fusion partner of AML1 (RUNX1) in the leukemic chromosome translocation t(8;21). The AML1-MTG8 fusion gene encodes a chimeric transcription factor. One of the highly conserved domains of MTG8 is TAFH which possesses homology with human TAF4 [TATA-box binding protein-associated factor]. To obtain specific inhibitors of the AML1-MTG8 fusion protein, we isolated RNA aptamers against the MTG8 TAFH domain using systematic evolution of ligands by exponential enrichment. All TAF aptamers contained guanine-rich sequences. Analyses of a TAF aptamer by NMR, CD, and mutagenesis revealed that it forms a parallel G-quadruplex structure in the presence of K+ . Furthermore, the aptamer could bind to the AML1-MTG8 fusion protein and dissociate the AML1-MTG8/DNA complex, suggesting that it can inhibit the dominant negative effects of AML1-MTG8 against normal AML1 function and serve as a potential therapeutic agent for leukemia.

Characterisation of an aptamer against the Runt domain of AML1 (RUNX1) by NMR and mutational analyses.

Since the invention of systematic evolution of ligands by exponential enrichment, many short oligonucleotides (or aptamers) have been reported that can bind to a wide range of target molecules with high affinity and specificity. Previously, we reported an RNA aptamer that shows high affinity to the Runt domain (RD) of the AML1 protein, a transcription factor with roles in haematopoiesis and immune function. From kinetic and thermodynamic studies, it was suggested that the aptamer recognises a large surface area of the RD, using numerous weak interactions. In this study, we identified the secondary structure by nuclear magnetic resonance spectroscopy and performed a mutational study to reveal the residue critical for binding to the RD. It was suggested that the large contact area was formed by a DNA-mimicking motif and a multibranched loop, which confers the high affinity and specificity of binding.

Conjugation of two RNA aptamers improves binding affinity to AML1 Runt domain.

To develop a high-affinity aptamer against AML1 Runt domain, two aptamers were conjugated based on their structural information. The newly designed aptamer Apt14 was generated by the conjugation of two RNA aptamers (Apt1 and Apt4) obtained by SELEX against AML1 Runt domain, resulting in improvement in its binding performance. The residues of AML1 Runt domain in contact with Apt14 were predicted in silico and confirmed by mutation and NMR analyses. It was suggested that the conjugated internal loop renders additional contacts and is responsible for the enhancement in the binding affinity. Conjugation of two aptamers that bind to different sites of the target protein is a facile and robust strategy to develop an aptamer with higher performance.

NMR monitoring of the SELEX process to confirm enrichment of structured RNA.

RNA aptamers are RNA molecules that bind to a target molecule with high affinity and specificity using uniquely-folded tertiary structures. RNA aptamers are selected from an RNA pool typically comprising up to 1015 different sequences generated by iterative steps of selection and amplification known as Systematic Evolution of Ligands by EXponential enrichment (SELEX). Over several rounds of SELEX, the diversity of the RNA pool decreases and the aptamers are enriched. Hence, monitoring of the enrichment of these RNA pools is critical for the successful selection of aptamers, and several methods for monitoring them have been developed. In this study, we measured one-dimensional imino proton NMR spectra of RNA pools during SELEX. The spectrum of the initial RNA pool indicates that the RNAs adopt tertiary structures. The structural diversity of the RNA pools was shown to depend highly on the design of the primer-binding sequence. Furthermore, we demonstrate that enrichment of RNA aptamers can be monitored using NMR. The RNA pools can be recovered from the NMR tube after measurement of NMR spectra. We also can monitor target binding in the NMR tubes. Thus, we propose using NMR to monitor the enrichment of structured aptamers during the SELEX process.

Kinetic and Thermodynamic Analyses of Interaction between a High-Affinity RNA Aptamer and Its Target Protein.

AML1 (RUNX1) protein is an essential transcription factor involved in the development of hematopoietic cells. Several genetic aberrations that disrupt the function of AML1 have been frequently observed in human leukemia. AML1 contains a DNA-binding domain known as the Runt domain (RD), which recognizes the RD-binding double-stranded DNA element of target genes. In this study, we identified high-affinity RNA aptamers that bind to RD by systematic evolution of ligands by exponential enrichment. The binding assay using surface plasmon resonance indicated that a shortened aptamer retained the ability to bind to RD when 1 M potassium acetate was used. A thermodynamic study using isothermal titration calorimetry (ITC) showed that the aptamer-RD interaction is driven by a large enthalpy change, and its unfavorable entropy change is compensated by a favorable enthalpy change. Furthermore, the binding heat capacity change was identified from the ITC data at various temperatures. The aptamer binding showed a large negative heat capacity change, which suggests that a large apolar surface is buried upon such binding. Thus, we proposed that the aptamer binds to RD with long-range electrostatic force in the early stage of the association and then changes its conformation and recognizes a large surface area of RD. These findings about the biophysics of aptamer binding should be useful for understanding the mechanism of RNA-protein interaction and optimizing and modifying RNA aptamers.

Solution structure of a DNA mimicking motif of an RNA aptamer against transcription factor AML1 Runt domain.

AML1/RUNX1 is an essential transcription factor involved in the differentiation of hematopoietic cells. AML1 binds to the Runt-binding double-stranded DNA element (RDE) of target genes through its N-terminal Runt domain. In a previous study, we obtained RNA aptamers against the AML1 Runt domain by systematic evolution of ligands by exponential enrichment and revealed that RNA aptamers exhibit higher affinity for the Runt domain than that for RDE and possess the 5'-GCGMGNN-3' and 5'-N'N'CCAC-3' conserved motif (M: A or C; N and N' form Watson-Crick base pairs) that is important for Runt domain binding. In this study, to understand the structural basis of recognition of the Runt domain by the aptamer motif, the solution structure of a 22-mer RNA was determined using nuclear magnetic resonance. The motif contains the AH(+)-C mismatch and base triple and adopts an unusual backbone structure. Structural analysis of the aptamer motif indicated that the aptamer binds to the Runt domain by mimicking the RDE sequence and structure. Our data should enhance the understanding of the structural basis of DNA mimicry by RNA molecules.

The Runt domain of AML1 (RUNX1) binds a sequence-conserved RNA motif that mimics a DNA element.

AML1 (RUNX1) is a key transcription factor for hematopoiesis that binds to the Runt-binding double-stranded DNA element (RDE) of target genes through its N-terminal Runt domain. Aberrations in the AML1 gene are frequently found in human leukemia. To better understand AML1 and its potential utility for diagnosis and therapy, we obtained RNA aptamers that bind specifically to the AML1 Runt domain. Enzymatic probing and NMR analyses revealed that Apt1-S, which is a truncated variant of one of the aptamers, has a CACG tetraloop and two stem regions separated by an internal loop. All the isolated aptamers were found to contain the conserved sequence motif 5'-NNCCAC-3' and 5'-GCGMGN'N'-3' (M:A or C; N and N' form Watson-Crick base pairs). The motif contains one AC mismatch and one base bulged out. Mutational analysis of Apt1-S showed that three guanines of the motif are important for Runt binding as are the three guanines of RDE, which are directly recognized by three arginine residues of the Runt domain. Mutational analyses of the Runt domain revealed that the amino acid residues used for Apt1-S binding were similar to those used for RDE binding. Furthermore, the aptamer competed with RDE for binding to the Runt domain in vitro. These results demonstrated that the Runt domain of the AML1 protein binds to the motif of the aptamer that mimics DNA. Our findings should provide new insights into RNA function and utility in both basic and applied sciences.

RNA aptamers targeting the carboxyl terminus of KRAS oncoprotein generated by an improved SELEX with isothermal RNA amplification.

Mutations in the KRAS gene occur frequently in various human tumors and are known to lead to malignant transformation. We isolated RNA aptamers targeting activated mutant KRAS proteins using an improved SELEX method by isothermal RNA amplification. RNA aptamers were selected against mutant KRAS (G12V) proteins, as well as a biotinylated 15-amino-acid peptide from the carboxyl terminal of KRAS that contains a farnesylation site. All the selected RNA aptamers bound to the basic carboxy-terminal region of KRAS protein and the highest K(D) value was 2.3 microM. By an in vitro scintillation proximity assay, we demonstrated that KRAS aptamers inhibited farnesylation moderately. From these aptamers, we determined a consensus sequence (U)CCAAGCAC(AC) that, when concatamerized, exhibited higher binding affinity to the carboxy-terminal region of KRAS protein. Further improvement of binding affinity between aptamers and KRAS protein might provide a new therapeutic approach for activated mutant KRAS proteins.

Characterization of a novel oncogenic K-ras mutation in colon cancer.

Activating mutations of RAS are frequently observed in subsets of human cancers, indicating that RAS activation is involved in tumorigenesis. Here, we identified and characterized a novel G to T transversion mutation of the K-ras gene at the third position of codon 19 (TTG) which substituted phenylalanine for leucine in 3 primary colon carcinomas. Biological and biochemical activity was examined using transformed NIH3T3 cells expressing mutant or wild-type K-ras. Transformants harboring the K-ras mutation at codon 19 showed proliferative capacity under serum-starved conditions, less contact inhibition, anchorage-independent growth, tumorigenicity in nude mice and elevation of active Ras-GTP levels. These results indicated that this novel mutation possesses high oncogenic activity.

MYND-less splice variants of AML1-MTG8 (RUNX1-CBFA2T1) are expressed in leukemia with t(8;21).

The AML1-MTG8 fusion gene is generated by chromosome translocation t(8;21), which is frequently observed in acute myeloid leukemia. The fusion gene produces a chimeric transcription factor that suppresses the expression of AML1-target genes via the MTG8 part of the chimeric protein, which is thought to be the primary cause of leukemia. The C-terminal region of MTG8 contains the MYND domain, represented by highly conserved zinc-finger-like protein motifs, and is known to interact with corepressor proteins. We found that, instead of the MYND domain, an alternative last exon of MTG8 encoding 27 amino acids in-frame is expressed naturally in human adult testis and in several leukemia cell lines. This type of alternative splicing also occurred in the AML1-MTG8 fusion gene at high levels in leukemia cell lines with t(8;21), as well as in blast cells of leukemia patients with t(8;21). The variant proteins of both MTG8 and AML1-MTG8 reduced transcriptional repressor activity in a mammalian two-hybrid assay. However, mixed expression of these variants with wild-type MTG8 recovered their repressor activity, suggesting that these variants also act as repressors in vivo where wild-type MTG8 and other family members exist in abundance. On the other hand, the MYND-less variants acquired a higher affinity for binding to MTG8 and formed a multimer, whereas the wild-type protein forms a dimer. Thus, expression of the MYND-less variants by the dysregulation of splicing machinery, which stimulates the oligomerization of fusion proteins in leukemia cells, may enhance malignant conversion of hematopoietic cells.

Discrimination of target by siRNA: designing of AML1-MTG8 fusion mRNA-specific siRNA sequences.

AML1-MTG8 is a chimeric transcription factor produced by t(8;21) chromosome translocation and causes AML. AML1-MTG8 acts as a dominant negative effector on normal AML1 protein, a key transcriptional regulator of hematopoietic differentiation, but its precise mechanism is not known. To analyze the function of AML1-MTG8 in leukemic cells and to explore the possibility of AML1-MTG8-targeted therapy, we designed nine small interfering RNAs (siRNAs) targeting a 25-nucleotide region spanning the fusion point of AML1 and MTG8. Two different siRNAs (AM2 and AM4) significantly reduced AML1-MTG8 expression from a transfected reporter plasmid at both the mRNA and protein levels. Both siRNAs did not reduce AML1b expression, but AM2 siRNA showed slightly reducing activity against MTG8b mRNA that is 86% homologous to the corresponded region of AML1-MTG8 mRNA. Moreover, using a cationic lipid reagent, the siRNAs were efficiently introduced into leukemia cell lines with t(8;21), SKNO-1 (30-40%) and Kasumi-1 (60-70%) cells, and reduced specifically the endogenous AML1-MTG8 expression. The siRNAs reduced neither the wild type AML1 in Kasumi-1 cells nor wild type MTG8b in human erythroblastic leukemia (HEL) cells. These results indicated that the two siRNAs are highly specific for the fusion mRNA. The knockdown of AML1-MTG8 in Kasumi-1 cells resulted in the activation of p14(ARF) promoter activity and increased the expression of integrin alphaIIb, whose expression is related to megakaryocytic differentiation. However, the knockdown of AML1-MTG8 in Kasumi-1 cells did not inhibit the cell growth, suggesting that the siRNA-mediated knockdown of AML1-MTG8 is useful for the functional analysis of the gene, but it alone might not be sufficient for gene therapy of the leukemia.

Altered expression profiles of microRNAs during TPA-induced differentiation of HL-60 cells.

MicroRNAs (miRNAs) are highly conserved small non-coding RNAs that regulate gene expression through translational repression by base-pairing with partially complementary mRNAs. The expression of a set of miRNAs is known to be regulated developmentally and spatially, and is involved in differentiation or cell proliferation in several organisms. However, the expression profiles of human miRNAs during cell differentiation remain largely unknown. In an effort to expand our knowledge of human miRNAs, we investigated miRNAs during 12-O-tetradecanoylphorbol-13-acetate (TPA)-induced differentiation of human leukemia cells (HL-60) into monocyte/macrophage-like cells. Several hundred RNAs ranging from 18 to 26 nucleotides were isolated from HL-60 cells with or without TPA-induction, and subsequently characterized by sequencing, database searching, and expression profiling. By removing non-miRNA sequences, we found three novel and 38 known miRNAs expressed in HL-60 cells. These miRNAs could be further classified into subsets of miRNAs that responded differently following TPA induction, either being up-regulated or down-regulated, suggesting the importance of regulated gene expression via miRNAs in the differentiation of HL-60 cells.