Identification of potential key genes associated with osteosarcoma based on integrated bioinformatics analyses

Due to high rates of metastasis and poor clinical outcomes for patients, it is important to study the pathomechanisms of osteosarcoma. However, due to the fact that osteosarcoma shows significant interindividual variation and high heterogeneity, the identification of differentially expressed genes (DEGs) at the population level cannot answer many important questions related to osteosarcoma tumorigenesis. Therefore, a new strategy to identify dysregulated genes in osteosarcoma samples is required. The aim of this study was to improve our understanding of osteosarcoma pathogenesis by identifying genes with universal aberrant expression in osteosarcoma samples. Because the relative expression ordering of genes is stable in normal bone tissues but is disrupted in osteosarcoma tissues, we used the RankComp algorithm to identify DEGs in normal and osteosarcoma tissue samples. We then calculated the dysregulation frequency for each gene. Genes with deregulation frequencies above 80% were deemed to be universal DEGs. Next, coexpression, pathway enrichment, and protein-protein interaction network analyses were performed to characterize the functions of these genes. From 188 samples of osteosarcoma obtained from four datasets measured on different platforms, 51 universal DEGs were identified, including 4 universally upregulated genes and 47 universally downregulated genes. Genes that were differentially coexpressed with these universal DEGs were found to be enriched in 46 cancer-related pathways. In addition, functional and network analyses showed that genes with high dysregulation frequencies were involved in cancer-related functions. Thus, the commonly aberrant genes identified in osteosarcoma tissues may be important targets for osteosarcoma diagnosis and therapy.     

Resveratrol inhibits hepatocellular carcinoma progression driven by hepatic stellate cells by targeting Gli-1

A disintegrin and metalloproteinase 17 (ADAM17) is highly expressed in various tumours and affects tumour progression. In this study, ADAM17 expression in 60 gastric cancer and 20 normal gastric mucosal tissues was assessed using immunohistochemistry. ADAM17 expression was higher in gastric cancer tissues than in normal gastric mucosal tissues (P < 0.0005). A significant relationship was identified between ADAM17 expression and the depth of tumour invasion, metastasis, and carcinoma stage. Furthermore, the effects of ADAM17 knockdown on the proliferation, cell invasion, and apoptosis of human gastric carcinoma cells (SGC-7901) were determined. SGC-7901 cells were transfected with ADAM17-shRNA, and cell proliferation and migration were assessed using CCK-8 and transwell assays, respectively, to evaluate the role of ADAM17 in tumour proliferation and invasion. Furthermore, the EGFR signalling pathway, the cell membrane receptor-bound TNF-α level, and apoptosis were evaluated by western blotting and flow cytometry. The inhibition of cell proliferation and invasion was observed in the ADAM17 knockdown cells, which was associated with modulation of the EGFR signalling pathway. Apoptosis was increased, and TNF-α signalling was attenuated in the ADAM17 knockdown cells. Our study demonstrated that ADAM17 over-expression in gastric cancer tissues was closely associated with tumour proliferation, invasion, and apoptosis.     

Structural and expressional analysis of the <Emphasis Type="Italic">B-hordein</Emphasis> genes in Tibetan hull-less barley

The B-hordein gene family was analyzed from two Tibetan hull-less barley cultivars Z09 and Z26 (Hordeum vulgare subsp. vulgare). Fourteen B-hordein genes, designated BZ09-2 to BZ09-5 (from Z09) and BZ26-1 to BZ26-10 (from Z26), were sequenced. Seven of them, similar to a previously reported BZ09-1 from Z09, were predicted to encode putative active proteins each with a signal peptide, a repetitive domain, and a C-terminal region; seven of them were predicted to be pseudogenes. The B-hordein gene family was analyzed using all known representatives of B-hordein sequences and two most similar LMW-GSs of Triticum aestivum. Alignment of these seven putative proteins with known B-hordeins and two most similar LMW-GSs of T. aestivum revealed that they shared a common motif. A large variation was observed between numbers of repeat units of predicted B-hordeins of Z26 and Z09. Phylogenetic analysis revealed that all BZ26 clones were clustered in a subgroup, and BZ09-1 formed another subgroup by itself in the putative eight active genes. In addition, six 5′-upstream regulatory sequences of the B-hordein genes were isolated from the two accessions by a single oligonucleotide nested PCR, and several different mutations were identified in the cis-acting element GLM and two distinctive sequences (Z09P-2 and Z26P-3). Phylogenetic analysis of 5′-upstream regulatory regions of the B-hordein genes showed that members from the same accession were clustered together except for two distinct members. Quantitative real time PCR analysis indicated distinct expression levels of B-hordein genes in four developing stages of developing grains in two accessions. These findings suggest B-hordein genes have intrinsic differences between accessions, and this knowledge will be useful for incorporating the B-hordeins protein in barley breeding programs.     

Virus-induced silencing of genes encoding LEA protein in Tibetan hulless barley (Hordeum vulgare ssp. vulgare) and their relationship to drought tolerance

Expression of the late embryogenesis abundant (LEA) gene is usually associated with plant response to dehydration. In this study, a drought-tolerant genotype was screened from 48 accessions of Tibetan hulless barley (Hordeum vulgare ssp. vulgare). By using virus-induced gene silencing, the influence of two LEA genes (HVA1 and Dhn6) on drought tolerance of Tibetan hulless barley was investigated. Results of quantitative real-time PCR indicated that the relative expression levels of HVA1 and Dhn6 in silenced plants were significantly reduced compared with control plants. Both HVA1-silenced and Dhn6-silenced plants showed a consequently lower survival rate than control plants under drought stress. However, only HVA1-silenced plants exhibited a significantly higher water loss rate (WLR). These results suggested that HVA1 and Dhn6 might participate in adaptive responses to water deficit in different ways. Vegetative growth of HVA1-silenced plants was significantly retarded even under optimal growth conditions, and their biomass accumulation was also much lower than that of the controls. These results indicate that HVA1 might play a role in vegetative growth of Tibetan hulless barley.