MicroRNA-145 regulates oncolytic herpes simplex virus-1 for selective killing of human non-small cell lung cancer cells.

BACKGROUND: Non-small cell lung cancer (NSCLC) is the leading cause of cancer-related mortality worldwide, and novel treatment modalities to improve the prognosis of patients with advanced disease are highly desirable. Oncolytic virotherapy is a promising approach for the treatment of advanced NSCLC. MicroRNAs (miRNAs) may be a factor in the regulation of tumor-specific viral replication. The purpose of this study was to investigate whether miRNA-145 regulated oncolytic herpes simplex virus-1 (HSV-1) can selectively kill NSCLC cells with reduced collateral damage to normal cells. METHODS: We incorporated 4 copies of miRNA-145 target sequences into the 3'-untranslated region of an HSV-1 essential viral gene, ICP27, to create AP27i145 amplicon viruses and tested their target specificity and toxicity on normal cells and lung cancer cells in vitro. RESULTS: miRNA-145 expression in normal cells was higher than that in NSCLC cells. AP27i145 replication was inversely correlated with the expression of miRNA-145 in infected cells. This oncolytic HSV-1 selectively reduced cell proliferation and prevented the colony formation of NSCLC cells. The combination of radiotherapy and AP27i145 infection was significantly more potent in killing cancer cells than each therapy alone. CONCLUSIONS: miRNA-145-regulated oncolytic HSV-1 is a promising agent for the treatment of NSCLC.

A novel sex-specific DNA marker in Columbidae birds.

That most Columbidae birds have no conspicuous sexual dimorphism often makes it difficult to identify their sex on the basis of external morphology. In the present study, we report a novel sex-specific DNA marker in Columbidae birds. DNA was extracted from one member of this bird group, Streptopelia orientalis (S. orientalis, oriental turtle dove), and used to identify a female-specific DNA marker using a random amplified polymorphic DNA (RAPD) fingerprinting. One hundred and sixty random primers were used for the RAPD-PCR reactions. When using the OPAV17 primer, a novel 902 bp sex-specific PCR product was amplified from known female birds. This fragment of DNA was cloned and sequenced. Two primers, TurSexOPAV17-F and TurSexOPAV17-R, were designed from the cloned sex-specific sequence, and were successfully used to amplify a 777 bp female-specific fragment using PCR from S. orientalis DNA. This sex-specific marker was also amplified from genomic DNA samples of two other female Columbidae, S. chinensis and Columba livia. Sequence analysis showed that this novel sex-specific marker was highly conserved amongst these three bird species. In contrast, the PCR product was not amplified from male DNA of these species, nor from either sex of the S. chinensis formosa birds. Therefore, we concluded that our novel marker can be used to rapidly and accurately identify the sex of birds from three species of Columbidae.

Female-specific DNA sequences in ostriches.

Ostrich absence of heteromorphic sex chromosomes, unique sequences or markers located in the ostrich W-chromosome. Random amplified polymorphic DNA (RAPD) fingerprinting was carried out to investigate the sex-specific DNA sequence for sexing in ostrich. One hundred and forty random primers were used for random amplified polymorphic DNA-polymerase chain reaction (RAPD-PCR). One of these primers, OPAJ-13, produced a sex-specific band only found in tested females, which was isolated and constructed into plasmids for nucleotide sequencing. A 760bp novel female-specific sequence was obtained. Two primers (OstSexOPAJ13-F and -R) were designed according to the cloned female sequence to amplify the female-specific fragment from genomic DNA of ostriches for sexing by PCR. The sex-specific band was represented in females but none were found in the males. This result showed that the sex of ostrich could be easily and effectively identified using the female-specific primers for PCR technique.

A novel molecular genetic marker for gender determination of pigeons.

The absence of conspicuous sexual dimorphism in pigeons often makes it difficult to determine their sex on the basis of external morphology. We identified a novel female-specific DNA marker in pigeons, presenting the possibility of pigeon gender determination using a PCR-based method. One-hundred and twenty random primers were used for RAPD fingerprinting in order to find any sex-specific fragments in pigeons. One of these primers, OPC-20, produced a female-specific band in the DNA fingerprints. This DNA fragment was isolated from the gel and inserted into a vector for nucleotide sequencing. A novel female-specific 732 bp sequence was obtained. A pair of primers (DoveOPC20F & R) was designed, based on the cloned sequence, for amplifying the female-specific band by PCR for pigeon gender determination. Sex-specific bands in the gel were observed in all females but not in males. The PCR products in the gel were then transferred onto nylon membranes and hybridized with a DIG-labeled probe of the cloned female-specific DNA fragment. Clear hybridization signals were found only in all of the female pigeons; the same result was obtained from dot blot hybridization. This demonstrates that the sex of pigeons can be accurately and rapidly identified by PCR.

Cloning of Taiwan water buffalo male-specific DNA sequence for sexing.

Random amplified polymorphic DNA (RAPD) fingerprinting was carried out to investigate the sex-specific DNA sequence for sexing in Taiwan water buffalos. One hundred and forty random primers were used for RAPD-PCR (polymerase chain reaction). One of these primers, OPC-16, produced a 321 bp fragment found only in tested males. This male-specific fragment was isolated and constructed into plasmids for nucleotide sequencing, a novel male-specific sequence was obtained. Two primers (BuSexOPC16-F and -R) were designed according to the cloned male-specific sequence to amplify the male-specific fragment using PCR for sexing. Sex-specific bands in the gel were represented in the males but none were found in the females when the Taiwan water buffalo genomic DNA samples were amplified with these two primers using PCR. The same results were also obtained from Taiwan yellow, Holstein, Angus, and Hereford cattle samples. This showed that the sex of these five breeds could be easily and effectively determined using the PCR technique.

Male-specific DNA sequences in pigs.

One hundred primers (Operon kits OPAA, OPAO, OPAV, OPC, and OPE series) were used for random amplified polymorphic DNA (RAPD) fingerprinting to determine male-specific fragments. Seventy-four percent of the primers yielded Yorkshire polymorphic fragments. One of these primers, OPAV-18, produced a novel 1098-bp DNA fragment found only in tested males. This male-specific fragment was isolated and constructed into plasmids for nucleotide sequencing. Two primers (5'-TTGCTCACGG TAGATAACAA GAGAG-3' and 5'-TTGCTCACGG ACCAGGTAGG GAATG-3') were designed according to the cloned male-specific sequence to amplify the male-specific band using polymerase chain reaction (PCR) for pig sexing. Sex-specific bands in the PCR gel products were represented in males but none were found in females when Yorkshire, Duroc, and Landrace genomic DNA samples were amplified with these two primers by PCR. The PCR products in the gel were transferred to nylon membranes and hybridized with a 32P-dCTP labeled probe of the cloned male-specific DNA fragment. There was a clear hybridization signal in samples from all of the male pigs, but not from those of female pigs. Male and female genomic DNA samples from these pigs were spotted onto nylon membranes and hybridized with the male-specific probe. The probe hybridized strongly to males only. A high degree of sequence homology was found among the novel male-specific DNA sequences in Yorkshire, Duroc and Landrace. The sex of these three breeds of pigs could be easily and effectively determined using these two primers.