Identification of mRNA splicing factors as the endothelial receptor for carbohydrate-dependent lung colonization of cancer cells

Hatakeyama, Shingo; Sato, Kazuhiro; Nakayama, Jun; Akama, Tomoya O.; Wong, Shuk-Man Annie; Kawashima, Hiroto; Zhang, Jianing; Smith, David F.; Οhyama, Chikara; Fukuda, Minoru; Fukuda, Michiko N.

doi:10.1073/pnas.0810110106

Cited by 40 publications

(40 citation statements)

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“…Because I-peptide targets normal lung through pre-mRNA splicing factor and it is likely targets the tumor vasculature through Anxa1 (12) (Fig. S1A), we looked for a peptide sequence specifically targeting tumor but not normal lung vasculature.…”

Section: Resultsmentioning

confidence: 99%

“…However, sialyl Lewis X-dependent B16FT-IIIM colonization occurred in E-selectin/P-selectin doubly-deficient mutant mice, and I-peptide inhibited that colonization, suggesting the presence of a yet unknown I-peptide receptor distinct from E-or P-selectins (11). We then isolated the putative receptor by I-peptide affinity chromatography and subjected it to proteomic analysis, which identified the I-peptide receptor as a pre-mRNA splicing factor (12). During these experiments, we found unexpectedly that I-peptide binds to a 15 kDa fragment of annexin 1 (Anxa1) (12).…”

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confidence: 99%

“…We then isolated the putative receptor by I-peptide affinity chromatography and subjected it to proteomic analysis, which identified the I-peptide receptor as a pre-mRNA splicing factor (12). During these experiments, we found unexpectedly that I-peptide binds to a 15 kDa fragment of annexin 1 (Anxa1) (12).…”

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confidence: 99%

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Targeted drug delivery to tumor vasculature by a carbohydrate mimetic peptide

Hatakeyama

Sato

Shibata

et al. 2011

Proc. Natl. Acad. Sci. U.S.A.

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Although numerous carbohydrates play significant roles in mammalian cells, carbohydrate-based drug discovery has not been explored due to the technical difficulty of chemically synthesizing complex carbohydrate structures. Previously, we identified a series of carbohydrate mimetic peptides and found that a 7-mer peptide, designated I-peptide, inhibits hematogenous carbohydrate-dependent cancer cell colonization. During analysis of the endothelial surface receptor for I-peptide, we found that I-peptide bound to annexin 1 (Anxa1). Because Anxa1 is a highly specific tumor vasculature surface marker, we hypothesized that an I-peptide-like peptide could target anticancer drugs to the tumor vasculature. This study identifies IFLLWQR peptide, designated IF7, as homing to tumors. When synthetic IF7 peptide was conjugated to fluorescent Alexa 488 (A488) and injected intravenously into tumor-bearing mice, IF7-A488 targeted tumors within minutes. IF7 conjugated to the potent anticancer drug SN-38 and injected intravenously into nude mice carrying human colon HCT116 tumors efficiently suppressed tumor growth at low dosages with no apparent side effects. These results suggest that IF7 serves as an efficient drug delivery vehicle by targeting Anxa1 expressed on the surface of tumor vasculature. Given its extremely specific tumor-targeting activity, IF7 may represent a clinically relevant vehicle for anticancer drugs.angiogenesis | carbohydrate binding protein | geldanamycin | phage display | chemiluminescence

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Section: Resultsmentioning

confidence: 99%

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confidence: 99%

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Targeted drug delivery to tumor vasculature by a carbohydrate mimetic peptide

Hatakeyama

Sato

Shibata

et al. 2011

Proc. Natl. Acad. Sci. U.S.A.

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“…In animals, SRs are known to perform many other diverse functions in the nucleus as well as in the cytoplasm, including mRNA transport, localization, translation, and decay, as well as in genome stability and microRNA biogenesis (Twyffels et al, 2011). Interestingly, some SRs in animals are present at the cell surface and exhibit carbohydratebinding activity (Hatakeyama et al, 2009). The SR proteins are major regulators of CS and AS Long and Caceres, 2009;.…”

Section: Sr Proteinsmentioning

confidence: 99%

Localization and Dynamics of Nuclear Speckles in Plants

et al. 2011

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The generation of mature mRNAs from most genes (about 80%-90%) in autotrophic eukaryotes requires the removal of noncoding sequences (introns) and splicing of the coding regions (exons; Labadorf et al., 2010). During splicing in some precursor messenger RNAs (pre-mRNAs), the same splice sites are always used, referred to as constitutive splicing (CS), resulting in a single transcript from a gene. However, from many pre-mRNAs, multiple mature mRNAs are generated from a single gene by alternative splicing (AS), where different combinations of splice sites are used. Both CS and AS are critical to the proper expression of intron-containing genes. Recent transcriptome-wide analysis of AS using high-throughput sequencing indicates that pre-mRNAs from up to 42% of introncontaining genes in Arabidopsis (Arabidopsis thaliana; Filichkin et al., 2010) and about 48% in rice (Oryza sativa; Lu et al., 2010) are alternatively spliced, whereas about 95% of human genes are alternatively spliced (Pan et al., 2008). In addition to pre-mRNAs, some primary microRNAs (pri-miRNAs) are also subject to CS and AS (Hirsch et al., 2006;Szarzynska et al., 2009;Mica et al., 2010). AS increases the protein-coding capacity of a genome and generates functionally different proteins from the same gene (Reddy, 2007). AS results in protein isoforms with loss or gain of function and altered subcellular localization, protein stability, and/or posttranslational modifications. Furthermore, AS plays an important role in gene regulation through regulated unproductive splicing and translation, leading to RNA degradation by mRNA surveillance mechanisms, differential recruitment of mRNAs to ribosomes, or translatability of splice variants (Kurihara et al., 2009;Licatalosi and Darnell, 2010;Palusa and Reddy, 2010). Numerous spliceosomal proteins either promote or suppress splicing by interacting with splicing regulatory elements on the pre-mRNAs. In recent years, the localization and dynamics of some splicing regulators in plants have been analyzed using a variety of approaches. This review summarizes the current status of research in this area, with emphasis on RNAbinding proteins (RBPs) that are involved in splicing regulation, discusses open questions, and presents some approaches to address these questions. SPLICING REGULATORSpre-mRNAs splicing takes place cotranscriptionally in the spliceosome, a large multicomponent complex composed of small nuclear RNAs (snRNAs) and about 170 proteins, many of which are involved in the regulation of splicing (Wahl et al., 2009;Valadkhan and Jaladat, 2010). The composition of the human and yeast spliceosome has been analyzed in great detail (Wahl et al., 2009); however, information on plant splicing has been scarce, as no in vitro assembly of a functional plant spliceosome has been possible to date. A detailed search for Arabidopsis orthologs of the human spliceosome proteome revealed that most splicing factors are present in the Arabidopsis genome, indicating a similar complexity (Barta et al., 2011). Interestingly, m...

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“…The biopanning technique has been shown to be a powerful tool for identifying specific ligands on target organs and tumors, as it enables forced evolution of very high-affinity targeting peptides through rounds of selection of living libraries of peptides presented on the surface of the bacteriophage particle (9)(10)(11)(12). This technique has classically been used to iteratively produce peptides binding purified cell surface markers (13,14), cultured cell lines (15,16), or tumor-bearing animals (17)(18)(19). We utilized a peptide-presenting bacteriophage library on the basis of a combinatorial library of random peptide 12mers fused to a minor coat protein pIII of the M13 bacteriophage containing approximately 2.7 Â 10 9 different sequences, and different peptides selective for the target cells were identified with successive rounds of biopanning.…”

Section: Introductionmentioning

confidence: 99%

COP35, a Cholangiocarcinoma-Binding Oligopeptide, Interacts with the Clathrin Heavy Chain Accompanied by GRP78

Kitahara

Masumoto

Parker

et al. 2011

Molecular Cancer Research

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Cholangiocarcinoma (CCA) is a common carcinoma of the liver, and the majority of patients with CCA have a poor prognosis due to the lack of effective nonsurgical therapies in addition to its rapid progression and inoperability at the time of diagnosis. The development of novel nonsurgical therapeutics that efficiently target CCA could significantly improve the prognosis for patients presenting with CCA. Here, we describe the iterative production and characterization of a novel peptide, designated COP35 (CCA-binding oligopeptide 35), which binds selectively to human CCA, identified by bacteriophage biopanning using the intrahepatic CCA cell line RBE and the normal cholangiocyte cell line MMNK-1. COP35 was found to augment the growth inhibitory effects of 5-fluorouracil (5-FU) against RBE cells. Utilizing pull-down assay and liquid chromatography, we identify the clathrin heavy chain accompanied by GRP78/BiP as a COP35-binding partner. In summary, we identify COP35 as a possible candidate for peptide-targeted therapies for CCA. Mol Cancer Res; 9(6); 688-701. Ó2011 AACR.

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Identification of mRNA splicing factors as the endothelial receptor for carbohydrate-dependent lung colonization of cancer cells

Cited by 40 publications

References 42 publications

Targeted drug delivery to tumor vasculature by a carbohydrate mimetic peptide

Targeted drug delivery to tumor vasculature by a carbohydrate mimetic peptide

Localization and Dynamics of Nuclear Speckles in Plants

COP35, a Cholangiocarcinoma-Binding Oligopeptide, Interacts with the Clathrin Heavy Chain Accompanied by GRP78

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