Zihua Zeng

Using an RNA aptamer probe for flow cytometry detection of CD30-expressing lymphoma cells

Aptamers are small molecular ligands composed of short oligonucleotides that bind targets with high affinity. In contrast to antibodies, as synthetic oligonucleotides, aptamers have lower production costs and elicit no antigenic reactions. Therefore, aptamers are potential agents for disease diagnosis and treatment. In this study, we validate a fluorescently labeled RNA aptamer, which has been reported to bind specifically to mouse CD30 proteins in solution, for human CD30 protein recognition on intact cells. The aptamer probe was tested with cultured anaplastic large cell lymphoma and Hodgkins lymphoma cells that express high levels of CD30. Flow cytometry and fluorescence microscopy showed specific and sensitive binding of the aptamer probe to CD30-expressing lymphoma cells at low concentrations (0.3 nM). Studies performed on multiple cell lines and nuclear cells from healthy donors confirmed that the CD30 aptamer and anti-CD30 antibody, the standard clinical probe, recognized the same set of cells. The potential application of multicolor flow cytometry analysis using the CD30 aptamer probe and antibodies was also shown. In conclusion, the developed CD30 aptamer probe could act as a replacement and/or a supplement for antibodies in the diagnosis of the CD30-expressing lymphomas.

An ultra pH-sensitive and aptamer-equipped nanoscale drug-delivery system for selective killing of tumor cells

Nanotechnology has often been applied in the development of targeted drug-delivery systems for the treatment of cancer. An ideal nanoscale system for drug delivery should be able to selectively deliver and rapidly release the carried therapeutic drug(s) in cancer cells and, more importantly, not react to off-target cells so as to eliminate unwanted toxicity on normal tissues. To reach this goal, a selective chemotherapeutic is formulated using a hollow gold nanosphere (HAuNS) equipped with a biomarker-specific aptamer (Apt), and loaded with the chemotherapy drug doxorubicin (DOX). The formed Apt-HAuNS-Dox, approximately 42 nm in diameter, specifically binds to lymphoma tumor cells and does not react to control cells that do not express the biomarker. Through aptamer-mediated selective cell binding, the Apt-HAuNS-Dox is internalized exclusively into the targeted tumor cells, and then released the DOX intracellularly. Of note, although the formed Apt-HAuNS-Dox is stable under normal biological conditions (pH 7.4), it appears ultrasensitive to pH change and rapidly releases 80% of the loaded DOX within 2 h at pH 5.0, a condition seen in cell lysosomes. Functional assays using cell mixtures show that the Apt-HAuNS-Dox selectively kills lymphoma tumor cells, but has no effect on the growth of the off-target cells in the same cultures, indicating that this ultra pH-sensitive Apt-HAuNS-Dox can selectively treat cancer through specific aptamer guidance, and will have minimal side effects on normal tissue.

Using oligonucleotide aptamer probes for immunostaining of formalin-fixed and paraffin-embedded tissues

For tissue immunostaining, antibodies are currently the only clinically validated and commercially available probes. Aptamers, which belong to a class of small molecule ligands composed of short single-stranded oligonucleotides, have emerged as probes over the last several decades; however, their potential clinical value has not yet been fully explored. Using cultured cells and an RNA-based CD30 aptamer, we recently demonstrated that the synthetic aptamer is useful as a specific probe for flow cytometric detection of CD30-expressing lymphoma cells. In this study, we further validated the use of this aptamer probe for immunostaining of formalin-fixed and paraffin-embedded lymphoma tissues. Using CD30 antibody as a standard control, we demonstrated that the synthetic CD30 aptamer specifically recognized and immunostained tumor cells of classical Hodgkin lymphoma and anaplastic large cell lymphoma, but did not react with background cells within tumor sites. Notably, the CD30 aptamer probe optimally immunostained lymphoma cells with lower temperature antigen retrieval (37 vs 96°C for antibody) and shorter probing reaction times (20 vs 90 min for antibody) than typical antibody immunostaining protocols. In addition, the CD30 aptamer probe showed no nonspecific background staining of cell debris in necrotic tissue and exhibited no cross-reaction to tissues that do not express CD30, as confirmed by a standard CD30 antibody staining. Therefore, our findings indicate that the synthetic oligonucleotide CD30 aptamer can be used as a probe for immunostaining of fixed tissue sections for disease diagnosis.

Immunotherapy of CD30-expressing lymphoma using a highly stable ssDNA aptamer.

CD30 is highly expressed on Hodgkins lymphoma and anaplastic large cell lymphoma, making it an attractive target for therapy. We describe the generation of serum-stabilized ssDNA aptamers that bind CD30 via a hybrid SELEX methodology. The selected aptamer bound CD30 with high affinity and specificity. Further optimization of the aptamer led to a short, truncated variant with a 50-fold higher affinity than its longer counterpart. The multivalent aptamer was able to induce oligomerization of CD30 receptors and, in effect, activate downstream signaling, which led to apoptosis of ALCL cells. Immunotherapy using aptamer-based co-stimulation provides an alternative to antibodies, and has potential to transform cancer treatment.

Combination of an Aptamer Probe to CD4 and Antibodies for Multicolored Cell Phenotyping

Aptamers have emerged as a new class of small molecule ligands. These short, single-stranded oligonucleotides can be produced through simple chemical synthesis, making them easier and less costly to produce than antibodies. We synthesized an RNA aptamer probe specific for human CD4 using a reported sequence and investigated the potential use of this probe in cell phenotyping. Studies in cultured cells demonstrated that the synthetic CD4 aptamer had a nearly identical cell-binding specificity as the standard CD4 antibody. Fluorescent microscopy confirmed that the aptamer and antibody generated the same CD4 staining pattern in cells without competing with one another. Multicolored flow cytometry analysis revealed that the CD4 aptamer could be combined with antibodies to phenotype cells from bone marrow, lymph nodes, and pleural fluid, suggesting that the aptamer probe has value for clinical use.

A Cancer Cell-Activatable Aptamer-Reporter System for One-Step Assay of Circulating Tumor Cells

The current antibody-mediated numeration assays of circulating tumor cells (CTCs) require multiple steps and are time-consuming. To overcome these technical limitations, a cancer cell-activatable aptamer-reporter was formulated by conjugating a biomarker-specific aptamer sequence with paired fluorochrome-quencher molecules. In contrast to the antibody probes, the intact aptamer-reporter was optically silent in the absence of cells of interest. However, when used in an assay, the aptamer selectively targeted cancer cells through interaction with a specific surface biomarker, which triggered internalization of the aptamer-reporter and, subsequently, into cell lysosomes. Rapid lysosomal degradation of the aptamer-reporter resulted in separation of the paired fluorochrome-quencher molecules. The released fluorochrome emitted bright fluorescent signals exclusively within the targeted cancer cells, with no background noise in the assay. Thus, the assays could be completed in a single step within minutes. By using this one-step assay, CTCs in whole blood and marrow aspirate samples of patients with lymphoma tumors were selectively highlighted and rapidly detected with no off-target signals from background blood cells. The development of the cancer cell-activatable aptamer-reporter system allows for the possibility of a simple and robust point-of-care test for CTC detection, which is currently unavailable.

Specific and Sensitive Tumor Imaging Using Biostable Oligonucleotide Aptamer Probes

Although several imaging modalities are widely used for tumor imaging, none are tumor type-specific. Different types of cancer exhibit differential therapeutic responses, thus necessitating development of an imaging modality able to detect various tumor types with high specificity. To illustrate this point, CD30-specific oligonucleotide aptamer in vivo imaging probes were conjugated to the near-infrared IRD800CW reporter. Mice bearing xenografted CD30-positive or control CD30-negative lymphoma tumors on contralateral sides of the same mouse were developed. Following a systemic administration of aptamer probes, whole body imaging of tumor-bearing mice was performed. Imaging signal from tumor sites was analyzed and imaging specificity confirmed by tissue immunostaining. The in vivo biodistribution of aptamer probes was also evaluated. Whole body scans revealed that the RNA-based aptamer probes selectively highlighted CD30-expressing lymphoma tumors immediately after systemic administration, but did not react with control tumors in the same mouse. The resultant imaging signal lasted up to 1 hr and the aptamer probes were rapidly eliminated from the body through urinary and lower intestinal tracts. For more sensitive imaging, biostable CD30-specific ssDNA-based aptamer probes were also generated. Systemic administration of these probes also selectively highlighted the CD30-positive lymphoma tumors, with imaging signal detected 4-5 folds higher than that derived from control tumors in the same animal, and lasted for up to 24hr. This study demonstrates that oligonucleotide aptamer probes can provide tumor type-specific imaging with high sensitivity and a long-lasting signal, indicating their potential for clinical applications.

Transfecting the hard-to-transfect lymphoma/leukemia cells using a simple cationic polymer nanocomplex.

Although the development of gene delivery systems via non-viral-mediated methods is advancing rapidly, it remains a challenge to deliver plasmids into hard-to-transfect cells, such as lymphoma/leukemia cells. To develop an efficient transfection method, we formulated a simple nanocomplex by incorporating poly β-amino ester (PBAE) polymers with plasmid DNAs containing a GFP reporter gene. The formed PBAE-plasmid nanocomplexes are approximately 200nm in diameter and stable under physiological conditions, but become rapidly biodegradable when pH decreases <7.0. Cultured lymphoma/leukemia cells were used for transfection assays and resultant gene delivery rates were determined by quantifying GFP expression. Exposure of cells to the nanocomplexes composed of fractioned PBAE (>7kDa) resulted in GFP expression in 3% of cells, similar to that mediated by the standard Lipofectamine method. However, with polybrene pre-treatment, the nanocomplex could achieve GFP expression in up to 32% of lymphoma/leukemia cells, an 8-fold increase over that mediated by Lipofectamine. These findings demonstrated a simple, efficient method for in vitro gene delivery into hard-to-transfect cells. The nanocomplexes are biodegradable and have minimal cytotoxicity, suggesting the potential use for in vivo gene delivery.

Self‐Assembled Aptamer‐Nanomedicine for Targeted Chemotherapy and Gene Therapy

Chemotherapy is the mainstream treatment of anaplastic large cell lymphoma (ALCL). However, chemotherapy can cause severe adverse effects in patients because it is not ALCL-specific. In this study, a multifunctional aptamer-nanomedicine (Apt-NMed) achieving targeted chemotherapy and gene therapy of ALCL is developed. Apt-NMed is formulated by self-assembly of synthetic oligonucleotides containing CD30-specific aptamer and anaplastic lymphoma kinase (ALK)-specific siRNA followed by self-loading of the chemotherapeutic drug doxorubicin (DOX). Apt-NMed exhibits a well-defined nanostructure (diameter 59 mm) and stability in human serum. Under aptamer guidance, Apt-NMed specifically binds and internalizes targeted ALCL cells. Intracellular delivery of Apt-NMed triggers rapid DOX release for targeted ALCL chemotherapy and intracellular delivery of the ALK-specific siRNA induced ALK oncogene silencing, resulting in combined therapeutic effects. Animal model studies reveal that upon systemic administration, Apt-NMed specifically targets and selectively accumulates in ALCL tumor site, but does not react with off-target tumors in the same xenograft mouse. Importantly, Apt-NMed not only induces significantly higher inhibition in ALCL tumor growth, but also causes fewer or no side effects in treated mice compared to free DOX. Moreover, Apt-NMed treatment markedly improves the survival rate of treated mice, opening a new avenue for precision treatment of ALCL.

Aptamer internalization via endocytosis inducing s-phase arrest and priming maver-1 lymphoma cells for cytarabine chemotherapy

The goal of precision therapy is to efficiently treat cancer without side effects. Aptamers are a class of small ligands composed of single-stranded oligonucleotides that bind to their targets with high affinity and specificity. In this study, we identified an ssDNA aptamer specifically targeting Maver-1 lymphoma cells with high binding affinity (Kd = 70±8 pmol/L). Interestingly, cellular cycle studies revealed that exposure of Maver-1 cells to synthetic aptamers triggered S-phase arrest of 40% of the cells (vs. 18% baseline). Confocal microscopy confirmed specific cell binding of aptamers and the resultant endocytosis into Maver-1 cells. Subsequent functional assays validated the fact that aptamer internalization into targeted cells is a prerequisite for Maver-1 cell growth inhibition. Importantly, aptamer-induced S-phase arrest induced enhanced chemotherapeutic results involving cytarabine, which primarily kills lymphoma cells at S-phase. Combination treatments revealed that aptamer re-exposure considerably primed Maver-1 cells for cytarabine chemotherapy, thus achieving a synergistic killing effect by reaching cell death rates as high as 61% (vs. 13% or 14% induced by aptamer or cytarabine treatment alone). These findings demonstrated that aptamers do not only act as molecular ligands but can also function as biotherapeutic agents by inducing S-phase arrest of lymphoma cells. In addition, logical combination of aptamer and cytarabine treatments ushers the way to a unique approach in precision lymphoma chemotherapy.