Background: The role of the neurotrophin regulated polypeptide, VGF, has been investigated in a rat spared injury model of neuropathic pain. This peptide has been shown to be associated with synaptic strengthening and learning in the hippocampus and while it is known that VGFmRNA is upregulated in dorsal root ganglia following peripheral nerve injury, the role of this VGF peptide in neuropathic pain has yet to be investigated.
Βeta-thalassemia, is a hemoglobinopathy characterized by reduced beta-globin chain synthesis, leading to imbalanced globin chain production, ineffective erythropoiesis and anemia. Increasing gamma-globin gene expression is a promising therapeutic approach as it reduces this imbalance by combining with the excess alpha globin chains and producing fetal hemoglobin (HbF). Furthermore, increased iron absorption and repeated blood transfusions lead to iron overload and tissue damage secondary to reactive oxygen species. Compounds exhibiting both antioxidant and HbF inducing activities are, therefore, highly desirable therapeutic agents. Resveratrol, a natural phytoalexin, combines these two activities but is also cytotoxic. Nine hydroxystilbenic resveratrol derivatives were synthesized in an attempt to identify compounds that retain the HbF-inducing and antioxidant activities of resveratrol but exhibit reduced cytotoxicity. Three derivatives (P1, P4 and P11) exhibited similar hemoglobin-inducing properties to resveratrol in K562 cells, however, only P11 showed reduced cytotoxicity. All three derivatives demonstrated variable HbF-inducing activity in primary erythroid progenitor cells from healthy donors. Resveratrol and P11 increased HbF induction significantly, with P11 having the highest activity. Additionally, P4 significantly increased progenitor numbers. A combinatorial treatment in K562 cells using resveratrol and decitabine resulted in a statistically significant increase in hemoglobin-inducing activity only above the level shown by resveratrol alone.
In 1993, we described an English family with beta-thalassaemia that was not linked to the beta-globin locus. Whole genome sequence analyses revealed potential causative mutations in 15 different genes, of which 4 were consistently and uniquely associated with the phenotype in all 7 affected family members, also confirmed by genetic linkage analysis. Of the 4 genes, which are present in a centromeric region of chromosome 1, ASH1L was proposed as causative through functional mRNA knock-down and chromatin-immunoprecipitation studies in human erythroid progenitor cells. Our data suggest a putative role for ASH1L (Trithorax protein) in the regulation of globin genes.
Reactivation of γ-globin is considered a promising approach for the treatment of β-thalassemia and sickle cell disease. Therapeutic induction of γ-globin expression, however, is fraught with lack of suitable therapeutic targets. The aim of this study was to investigate the effects that treatment with decitabine has on the proteome of human primary erythroid cells from healthy and thalassemic volunteers, as a means of identifying new potential pharmacological targets. Decitabine is a known γ-globin inducer, which is not, however, safe enough for clinical use. A proteomic approach utilizing isobaric tags for relative and absolute quantitation (iTRAQ) analysis, in combination with high-pH reverse phase peptide fractionation followed by liquid chromatography-tandem mass spectrometry (LC-MS/MS), was employed to investigate the effects of decitabine treatment. Bioinformatics analysis making use of the Database for Annotation, Visualization and Integrated Discovery (DAVID) was employed for functional annotation of the 192 differentially expressed proteins identified. The data are available via ProteomeXchange with identifier PXD006889. The proteins fall into various biological pathways, such as the NF-κB signaling pathway, and into many functional categories including regulation of cell proliferation, transcription factor and DNA binding, protein stabilization, chromatin modification and organization, and oxidative stress proteins.
BACKGROUND: We have previously described a unique English family with beta-thalassemia trait which was not linked to the β-globin gene locus (Thein, Wood, Wickramasinghe, & Galvin, 1993). This suggested involvement of a trans-acting factor required for full activation of the β-globin gene locus. Such a factor is likely to be a modulator of disease severity in sickle cell disease and beta-thalassemia which could provide insights for novel therapeutic targets in the beta-globinopathies. RESULTS: We applied whole genome scan (WGS) to 2 affected and 2 unaffected subjects of the English family. The familial segregation suggested a dominant transmission mode; WGS identified 15 genes as potentially causative to the phenotype, with four genes located on chromosome 1, four on chromosome 3, three on chromosome 20, and one on chromosome 6, chromosome 8, chromosome 10 and chromosome 19. Sanger sequence analysis on 23 family members spanning three generations, including the 4 individuals that were subjected to WGS, revealed that the 15 variants were not artefacts of the WGS and that all variants were present in the 2 affected but not in the 2 unaffected individuals. Furthermore we found that 4 of the 15 variants were consistently and uniquely present in all 9 affected but absent in the unaffected family members. We performed association linkage analysis using the 15 markers in the whole family, and confirmed that the phenotype was closely linked to the 4 genes that were inherited as a block spanning the centromere on chromosome 1. We concluded that the region containing these 4 genes most likely harbours the mutation causing the phenotype. Among the 4 candidate genes, 2 were not expressed in erythroid cells, but the other 2 - one encoding an integral membrane protein (LRIG2) and the other one encoding a methyl transferase (ASH1L)- were expressed in erythroid cells. Functional studies for these two genes were performed on primary human erythroid progenitor cells (hEPCs) in culture. In following the kinetics of the 2 candidates during differentiation of hEPCs, we observed that the expression of ASH1L increased at later stages of differentiation, where LRIG2 displayed a less dramatic change of expression. Moreover, ASH1L has previously been found to occupy transcribed chromatin domains and methylate histone tails in vitro (Gregory et al., 2007; Miyazaki et al., 2013; Tanaka et al., 2011). In undifferentiated mouse embryonic stem cells there is no ASH1L recruitment to the β-globin gene locus but upon erythroid differentiation the protein is recruited to the transcribed portion of the gene (Gregory et al., 2007). This suggests an involvement of ASH1L in beta-globin activation in erythroid lineages. We used shRNA lentiviruses to generate knock-down (KD) of ASH1L and obtained over 65-75% KD of the gene. In hEPCs treated with the shRNA lentivirus, we observed a slight decrease in beta-globin expression compared to the control hEPCs. The α/β-globin and α/(β+γ) globin ratios were also affected by the gene knock-down. ChIP-qPCR was performed to assess the enrichment of the ASH1L protein at β-globin promoter region. The results show that enrichment of ASH1L at the β-globin promoter correlates with the β-globin expression in cells. CONCLUSIONS: These results suggest that ASH1L is responsible for the phenotype observed in the English family and act in differentiating hEPCs as a trans-acting factor for full beta-globin gene activation. Further ChIP analysis to assess the binding of the protein to the beta-globin locus during hEPCs differentiation and under KD condition will provide us with a better understanding of the influence of the methyl transferase on β-globin activation. The replication of the patient mutation in vitro using CRISPR technology will provide the model to study fully the impact of the mutation on the phenotype described in the original paper. These findings could provide new insights for therapeutic targets for beta-globinopathies. Disclosures No relevant conflicts of interest to declare.
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