Abstract
Long-range associations between enhancers and their target gene promoters have been shown to play critical roles in executing genome function. Recent variations of chromosome capture technology have revealed a comprehensive view of intra- and interchromosomal contacts between specific genomic sites. The locus control region of the β-globin genes (β-LCR) is a super-enhancer that is capable of activating all of the β-like globin genes within the locus in cis through physical interaction by forming DNA loops. CTCF helps to mediate loop formation between LCR-HS5 and 3’HS1 in the human β-globin locus, in this way thought to contribute to the formation of a “chromatin hub”. The β-globin locus is also in close physical proximity to other erythrocyte-specific genes located long distances away on the same chromosome. In this case, erythrocyte-specific genes gather together at a shared “transcription factory” for co-transcription. Theoretically, enhancers could also activate target gene promoters at the identical loci, yet on different chromosomes in trans, a phenomenon originally described as transvection in Drosophilla. Although close physical proximity has been reported for the β-LCR and the β-like globin genes when integrated at the mouse homologous loci in trans, their structural and functional interactions were found to be rare, possibly because of a lack of suitable regulatory elements that might facilitate such trans interactions. Therefore, we re-evaluated presumptive transvection-like enhancer-promoter communication by introducing CTCF binding sites and erythrocyte-specific transcription units into both LCR-enhancer and β-promoter alleles, each inserted into the mouse ROSA26 locus on separate chromosomes. Following cross-mating of mice to place the two mutant loci at the identical chromosomal position and into active chromation in trans, their transcriptional output was evaluated. The results demonstrate that there was no significant functional association between the LCR and the β-globin gene in trans even in this idealized experimental context.
Highlights
Gene expression is tightly regulated by DNA cis elements and their binding trans-factors, in which specific enhancer-promoter communications play a pivotal role
To gain insight into possible interchromosomal gene regulatory mechanisms, Noordermeer et al employed the human β-globin locus control region (LCR) enhancer and human β-globin promoter as regulatory elements to test for functional consequences of placing them separately at corresponding cis locations on homologous chromosomes in mice [38], since these regulatory elements represent one of the most robust and most thoroughly examined enhancer-promoter pairs capable of interacting with each other over extremely long distances [10]
Despite their clear affinity in the native chromatin configuration, they showed no transvection-like interaction when integrated into the Rad23a gene locus where many housekeeping genes reside
Summary
Gene expression is tightly regulated by DNA cis elements and their binding trans-factors, in which specific enhancer-promoter communications play a pivotal role. It has been reported that genes with similar transcriptional specificity migrate into transcription factories in the nucleus that are rich in transcription factors engaged in the expression of those genes [10,11,12]. According to this mechanism, two distinct genome regions carrying genes with the same expression pattern should meet at the shared foci for cotranscription
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