DNA aptamer selection for SARS-CoV-2 spike glycoprotein detection.

The rapid spread of SARS-CoV-2 infection throughout the world led to a global public health and economic crisis triggering an urgent need for the development of low-cost vaccines, therapies and high-throughput detection assays. In this work, we used a combination of Ideal-Filter Capillary Electrophoresis SELEX (IFCE-SELEX), Next Generation Sequencing (NGS) and binding assays to isolate and validate single-stranded DNA aptamers that can specifically recognize the SARS-CoV-2 Spike glycoprotein. Two selected non-competing DNA aptamers, C7 and C9 were successfully used as sensitive and specific biological recognition elements for the development of electrochemical and fluorescent aptasensors for the SARS-CoV-2 Spike glycoprotein with detection limits of 0.07 fM and 41.87 nM, respectively.

Choriodecidual leukocytes display a unique gene expression signature in spontaneous labor at term.

Prior to and during the process of human labor, maternal circulating leukocytes infiltrate the maternal-fetal interface (choriodecidua) and become activated resembling choriodecidual leukocytes. Since, there is no evidence comparing maternal circulating and choriodecidual leukocytes, herein, we characterized their transcriptome and explored the biological processes enriched in choriodecidual leukocytes. From women undergoing spontaneous term labor we isolated circulating and choriodecidual leukocytes, performed microarray analysis (n = 5) and qRT-PCR validation (n = 9) and interaction network analysis with up-regulated genes. We found 270 genes up-regulated and only 17 genes down-regulated in choriodecidual leukocytes compared to maternal circulating leukocytes. The most up-regulated genes were CCL18, GPNMB, SEPP1, FN1, RNASE1, SPP1, C1QC, and PLTP. The biological processes enriched in choriodecidual leukocytes were cell migration and regulation of immune response, chemotaxis, and humoral immune responses. Our results show striking differences between the transcriptome of choriodecidual and maternal circulating leukocytes. Choriodecidual leukocytes are enriched in immune mediators implicated in the spontaneous process of labor at term.

Amolimogene bepiplasmid, a DNA-based therapeutic encoding the E6 and E7 epitopes from HPV, for cervical and anal dysplasia.

MGI Pharma Biologics is developing amolimogene bepiplasmid as a potential therapy for HPV-associated diseases, including cervical dysplasia. Amolimogene bepiplasmid is a polymer-encapsulated DNA vaccine consisting of a plasmid expressing a chimeric peptide comprising immunogenic hybrid epitopes from HPV-16 and HPV-18 E6 and E7 proteins and an HLA-DRalpha intracellular trafficking peptide. In phase I and I/II clinical trials of ZYC-101 (the precursor of amolimogene bepiplasmid containing a single epitope from HPV-16 E7) in patients with cervical dysplasia and patients with anal dysplasia, ZYC-101 produced significant histological regression and was safe and well tolerated. Results from this trial led to a phase II clinical trial of amolimogene bepiplasmid in patients with cervical dysplasia. This phase II trial demonstrated that treatment with amolimogene bepiplasmid resolution of disease was not significantly superior to placebo except in the predefined group of women who were less than 25 years of age. A phase II/III clinical trial was ongoing at the time of publication examining amolimogene bepiplasmid in this patient population.

Effect of combined antisense oligodeoxynucleotides directed against the human papillomavirus type 16 on cervical carcinoma cells.

BACKGROUND: Cervical cancer is highly associated with human papillomavirus (HPV) E6 and E7 gene expression. We have previously reported two antisense oligodeoxynucleotides (AS-ODNs) directed against adjacent targets within the HPV-16 E6/E7 mRNA (419 and 434), each able to downregulate HPV-16 E6/E7 mRNA in vitro and in vivo and to specifically inhibit tumor cell growth in culture and animal models. METHODS: Towards potential clinical application and improved in vivo performance, we analyzed the effect of the combined treatment of 419-434 AS-ODNs on the anchorage independent growth (AIG) of HPV-16-positive cervical carcinoma cell lines. RESULTS: We found similar responses between combined 419-434 and individual AS-ODNs treatments in RNaseH assays, cell uptake, and in vivo degradation of HPV-16 E6/E7 transcripts. Moreover, the combined use of 419-434 AS-ODNs resulted in additive AIG inhibition of CaSki and SiHa cells, similar to that obtained with equivalent doses of the individual AS-ODNs. CONCLUSIONS: By using a combined treatment, it may be possible to overcome the potential mutations frequently reported within HPV-16 genome, thus improving the potential application of 419 and 434 AS-ODNs as a therapeutic alternative for cervical cancer.

Molecular approaches to cervical cancer therapy.

Cervical cancer is the second most common malignancy in women worldwide. Two HPV strains, HPV-16 and 18, occur in the 70% of untreated cancers. Expression of viral oncogenes E6 and E7 disrupt the cell cycle by interfering with p53 and p107(Rb). It is known that HPV infection is necessary but insufficient to cause malignancy. Furthermore, persistence of HPV-16 or 18 in women does not necessarily result in cancer. Persistence indicates the importance of other factors for malignant conversion of high-grade HPV infection. The multi-step cervical carcinogenesis process is amendable to molecular therapeutics such as therapeutic nucleic acids (TNAs). TNA-based therapies for cervical carcinoma include ribozymes, antisense oligonucleotides (AS-ODNs) and small interfering RNAs (siRNAs). In vitro experiments with TNAs successfully inhibited E6/E7 expression and caused induction of apoptosis and/or senescence in cervical carcinoma cells. Early ribozyme and AS-ODN approaches showed promise as therapeutic moieties for cervical cancer. Despite the very high in vitro efficiency of siRNA-based therapies they present the same issues that burdened clinical development of ribozymes and AS-ODNs. These issues include intracellular target accessibility, specificity and delivery. Ribozymes are useful for functional genomic studies including diagnosis. Moreover, AS-ODNs appear better suited for clinical protocols because recent advances in nucleic acid chemistry allow higher cell uptake with very low off-target effects leading to actual AS-ODNs clinical applications. By using combined treatments with multiple targets it will be possible to apply TNAs directly to the cancerous cervix to destroy viral RNA and obliterate the tumor.

A bacterial reporter system for the evaluation of antisense oligodeoxynucleotides directed against human papillomavirus type 16 (HPV-16).

BACKGROUND: Antisense oligodeoxynucleotides (AS-ODNs) are a promising alternative for the cure of many diseases because of their in vivo specificity and stability. However, AS-ODNs have a strong dependence on the target mRNA structure making necessary extensive in vivo testing. There is, therefore, a need to develop assays to rapidly evaluate in vivo ODN performance. METHODS: We report a simple and inexpensive bacterial reporter system for the rapid in vivo evaluation of AS-ODNs directed against human papillomavirus type 16 (HPV-16) based on the destruction of a chimeric CFP mRNA using the reported HPV-16 nt 410-445 target. RESULTS: In vitro RNaseH assays confirmed target RNA accessibility after AS-ODN treatment. Expression of CFP in Escherichia coli BL21(DE3) with pGST-TSd2-CFP plasmid containing HPV-16 nt 410-445 target linked to CFP was blocked by transformed antisense PS-ODNs but not by two different scrambled ODN controls. CONCLUSIONS: A correlation was observed between bacterial CFP downregulation with the HPV-16 E6/E7 mRNA downregulation and the inhibition of anchorage-independent growth of HPV-16 containing cells suggesting that inhibition of HPV-16 E6/E7 expression by AS-ODNs directed against 410-445 target in cervical tumor cells can be tested in bacterial models.

Isolation and characterization of an RNA aptamer for the HPV-16 E7 oncoprotein.

BACKGROUND AND AIMS: Cervical cancer is a common neoplastic disease affecting women worldwide. Expression of human papillomavirus type 16 (HPV-16) E6/E7 genes is frequently associated with cervical cancer, representing ideal targets for diagnostic and therapeutic strategies. Aptamers are oligonucleotide ligands capable of binding with high affinity and specificity to relevant markers in therapeutics and disease detection. The aim of the study was to isolate an RNA aptamer specific for the HPV-16 E7 protein. METHODS: Aptamers were selected from a randomized oligonucleotide library using a modified SELEX method and recombinant HPV-16 E7 protein. Isolated aptamers were cloned and sequenced for in silico analysis. Interaction and electromobility shift assays (EMSA) were performed to establish aptamer specificity and affinity for E7. RNase footprinting and serial deletions of the aptamer and the E7 protein were made to characterize the aptamer-protein complex. Sandwich slot-blot assays were used for K(D) determination. RESULTS: After several rounds of SELEX, an aptamer (G5α3N.4) exhibited specificity for E7 using cell-free and protein extracts. G5α3N.4 binding yielded a K(D) comparable to aptamers directed to other small targets. Enzymatic and genetic analysis of G5α3N.4 binding showed a secondary structure with two stem-loop domains joined by single-stranded region contacting E7 in a clamp-like manner. The G5α3N.4 aptamer also produced specific complexes in HPV-positive cervical carcinoma cells. CONCLUSIONS: The affinity and specificity of G5α3N.4 binding domains for the HPV-16 E7 protein may be used for the detection of papillomavirus infection and cervical cancer.

Cleavage of HPV-16 E6/E7 mRNA mediated by modified 10-23 deoxyribozymes.

Deoxyribozymes (DXZs) are small oligodeoxynucleotides capable of mediating phosphodiester bond cleavage of a target RNA in a sequence-specific manner. These molecules are a new generation of artificial catalytic nucleic acids currently used to silence many disease-related genes. The present study describes a DXZ (Dz1023-434) directed against the polycistronic mRNA from the E6 and E7 genes of human papillomavirus type 16 (HPV-16), the main etiological agent of cervical cancer. Dz1023-434 showed efficient cleavage against a bona fide antisense window at nt 410-445 within HPV-16 E6/E7 mRNA even in low [Mg(2+)] conditions. Using a genetic analysis as guidance, we introduced diverse chemical modifications within Dz1023-434 catalytic core to produce a stable locked nucleic acid (LNA)-modified DXZ (Dz434-LNA) with significant cleavage activity of full E6/E7 transcripts. Cell culture testing of Dz434-LNA produced a sharp decrement of E6/E7 mRNA levels in HPV-16-positive cells resulting in decreased proliferation and considerable cell death in a specific and dose-dependent manner. No significant effects were observed with inactive or scrambled control DXZs nor from using HPV-negative cells, suggesting catalysis-dependent effect and high specificity. The biological effects of Dz434-LNA suggest a potential use for the treatment of cervical cancer.

Nucleic acids as therapeutic agents.

Therapeutic nucleic acids (TNAs) and its precursors are applied to treat several pathologies and infections. TNA-based therapy has different rationales and mechanisms and can be classified into three main groups: 1) Therapeutic nucleotides and nucleosides; 2) Therapeutic oligonucleotides; and 3) Therapeutic polynucleotides. This review will focus in those TNAs that have reached clinical trials with anticancer and antiviral protocols, the two most common applications of TNAs. Although therapeutic nucleotides and nucleosides that interfere with nucleic acid metabolism and DNA polymerization have been successfully used as anticancer and antiviral drugs, they often produce toxic secondary effects related to dosage and continuous use. The use of oligonucleotides such as ribozyme and antisense oligodeoxynucleotides (AS-ODNs) showed promise as therapeutic moieties but faced several issues such as nuclease sensitivity, off-target effects and efficient delivery. Nevertheless, immunostimulatory oligodeoxynucleotides and AS-ODNs represent the most successful group of therapeutic oligonucleotides in the clinic. A newer group of therapeutic oligonucleotides, the aptamers, is rapidly advancing towards early detection and treatment alternatives the have reached the commercial interest. Despite the very high in vitro efficiency of small interfering RNAs (siRNAs) they present issues with intracellular target accessibility, specificity and delivery. DNA vaccines showed great promise, but they resulted in very poor responses in the clinic and further development is uncertain. Despite their many issues, the exquisite specificity and versatility of therapeutic oligonucleotides attracts a great deal of research and resources that will certainly convert them in the TNA of choice for treating cancer and viral diseases in the near future.

A triplex ribozyme expression system based on a single hairpin ribozyme.

Triplex ribozyme (RZ) configurations allow for the individual activity of trans-acting RZs in multiple expression cassettes (multiplex), thereby increasing target cleavage relative to conventionally expressed RZs. Although hairpin RZs have been advantageously compared to hammerhead RZs, their longer size and structural features complicated triplex design. We present a triplex expression system based on a single hairpin RZ with transcleavage capability and simple engineering. The system was tested in vitro using cis- and trans-cleavage kinetic assays against a known target RNA from HPV-16 E6/E7 mRNA. Single and multiplex triplex RZ constructs were more efficient in cleaving the target than tandem-cloned hairpin RZs, suggesting that the release of individual RZs enhanced trans-cleavage kinetics. Multiplex systems constructed with two different hairpin RZs resulted in better trans-cleavage compared to standard double-RZ constructs. In addition, the triplex RZ performed cis- and trans-cleavage in cervical cancer cells. The use of triplex configurations with multiplex RZs permit differential targeting of the same or different RNA, thus improving potential use against unstable targets. This prototype will provide the basis for the development of future RZ-based therapies and technologies.

Advances in the development of therapeutic nucleic acids against cervical cancer.

Cervical cancer is the second most common neoplastic disease affecting women worldwide. Basic, clinical and epidemiological analyses indicate that expression of high-risk human papillomaviruses (HPVs) E6/E7 genes is the primary cause of cervical cancer and represent ideal targets for the application of therapeutic nucleic acids (TNAs). Antisense oligodeoxyribonucleotides (AS-ODNs) and ribozymes (RZs) are the most effective TNAs able to inhibit in vivo tumour growth by eliminating HPV-16 and HPV-18 E6/E7 transcripts. Expression of multiple RZs directed against alternative target sites by triplex expression systems may result in the abrogation of highly variable HPVs. More recently, RNA interference (RNAi) gene knockdown phenomenon, induced by small interfering RNA (siRNA), has demonstrated its potential value as an effective TNA for cervical cancer. siRNA and aptamers as TNAs will have a place in the armament for cervical cancer. TNAs against cervical cancer is in a dynamic state, and clinical trials will define the TNAs in preventive and therapeutic roles to control tumour growth, debulk tumour mass, prevent metastasis and facilitate immune interaction.

Dystrophin Dp71 is required for neurite outgrowth in PC12 cells.

To determine the role of Dp71 in neuronal cells, we generated PC12 cell lines in which Dp71 protein levels were controlled by stable transfection with either antisense or sense constructs. Cells expressing the antisense Dp71 RNA (antisense-Dp71 cells) contained reduced amounts of the two endogenous Dp71 isoforms. Antisense-Dp71 cells exhibited a marked suppression of neurite outgrowth upon the induction with NGF or dibutyryl cyclic AMP. Early responses to NGF-induced neuronal differentiation, such as the cessation of cell division and the activation of ERK1/2 proteins, were normal in the antisense-Dp71 cells. On contrary, the induction of MAP2, a late differentiation marker, was disturbed in these cells. Additionally, the deficiency of Dp71 correlated with an altered expression of the dystrophin-associated protein complex (DAPC) members alpha and beta dystrobrevins. Our results indicate that normal expression of Dp71 is essential for neurite outgrowth in PC12 cells and constitute the first direct evidence implicating Dp71 in a neuronal function.

Virus y cáncer humano: genética molecular del cáncer cervicouterino / Virus and human carcinoma: molecular genetic and cervical carcinoma

El cáncer es un proceso multifactorial y con múltiples etapas. Los protooncogenes, antioncogenes y virus oncogénicos están involucrados en el desarrollo de diversas neoplasias. La expresión alterada de los protooncogenes (por mutaciones, rearreglos o amplificaciones), así como la cooperación entre ellos puede llevar a la célula a una estado transformado. Los genes p53 y RB codifican para dos proteínas antioncogénicas que regulan las decisiones celulares de proliferación o diferenciación. La ausencia de RB (pérdida de ambos alelos) lleva a la liberación de factores de transcripción. p53 en su forma mutada, favorece el crecimiento celular. El cáncer cervicouterino ejemplifica claramente la intervención de este tipo de factores en su desarrollo. Los papilomavirus humanos genitales (PVH) estan implicados en su etiología como iniciadores de la proliferación celular. La inactivación de las proteínas antioncogénicas p53 y p105 RB porparte de los oncogenes virales E6 y E7, respectivamente, mantiene el estado de divición celular continua. Adicionalmente, la participación de ooncogenes expresados en forma alterada (c-myc) y otros cofactores contribuyen a modificar los periodos de latencia y la gravedad de la enfermedad

Prevalence in two Mexican cities of human papilomavirus DNA sequences in cervical cancer

El cáncer cérvico uterino (CaCU) ocupa el 30 por ciento de todas las neoplasias de la mujer en México, resultando una de las principales causas de muerte por cáncer. En un estudio anterior en la ciudad de México, nuestro grupo reportó que sólo cinco de 16 muestras analizadas por transferencia Southern contenían secuencias virales integradas del papilomavirus humano tipo 16 (HPV16). En el presente trabajo, hemos extendido esta observación en un estudio comparativo de las ciudades de México, D!F!, y Monterrey, Nuevo León, incluyendo además otro tipo viral, el papilomavirus humano tipo 18 (HPV18), para determinar la frecuencia con la que se presentan en población mexicana los dos tipos de papilomavirus humanos más comunes en CaCU. Se determinó en primera instancia que la prevalencia de secuencias del HPV16 era similar en ambas poblaciones (4 de 14 para la ciudad de México y 6 de 23 para Monterrey); sin embargo, la presencia de secuencias de HPV18 fue aún más baja (una de 14 y una de 10, para las ciudades de México y Monterrey, respectivamente). En todos los tumores, las secuencias virales se encontraron integradas al genoma celular. Nuestros resultados muestran que existen una relativamente baja proporción de HPV16 Y 18 en tumores cervicales de población mexicana, sugiriendo que otros tipos de papilomavirus humanos o la presencia de un nuevo factor de riesgo (p.ej., activación de oncogenes) están involucrados en el desarrollo del CaCU en México.