Chromatin Dynamics of the mouse β-globin locus

textabstractLately it has become more clear that (subtle) changes in 3D organization of chromatin can either trigger transcription or silence genes or gene clusters. It has also been postulated that due to changes in chromatin structure, a change in chromatin accessibility of transcription factors (TF) to TF binding sites also becomes an important factor to the gene’s activation status. Both such changes have been ascribed to the mouse ?- haemoglobin gene cluster as a trigger to activate globin expression in the erythroid cell lineage. Early models speculated a scanning, random activation or a looping mechanism to activate globin transcription. The chromatin conformation capture (3C) technique has shown that there is a molecular interaction between various DNAse I hypersensitive (HS) sites that are located up- and downstream of the ?-globin gene cluster, the HS sites of the Locus Control Region (LCR) and the promoter by means of a dynamic looping mechanism. The clustering of the HS sites of the LCR and the up- and down- stream HS sites results in the formation of a so called Active Chromatin Hub (ACH) which is depending on at least two erythoid TF: EKLF and GATA-1. The long range interactions between the outlying HS -84/-85, -62/-60 and the 3’HS1 are depending on the presence of CTCF, a TF that is thought to play an important role in long range chromatin interactions across the whole genome. Prior to gene activation, cells of the early erythroid lineage (progenitors) already show a presence of an ACH, which is not found in non-erythroid cells. The final chromatin 3D structure consist of four major loops sizing 25- 38Kb and two minor loops within the LCR sizing 4.5 and 12Kb. To confirm this looping hypothesis (based on 3C technology) we used an in situ hybridization approach to visualize and, after image restoration, quantitatively measure the 3D conformational changes that take place within the locus in erythroid cells before and after differentiation. Globin gene activation is depending on long distance looping of the up- and downstream HS sites and the ?-major promotor to the LCR, resulting in a complex 3D chromatin structure. By staining the m?- globin loci with fluorescence labeled sequence specific probes followed by high-resolution 3D imaging and 3D volume rendering of the deconvolved images, the loci reveal changes in the geometric size and shape properties when cells are differentiated into a active globin transcribing cell. An almost 2x decrease in volume was measured, which was mostly due to a reduction of the longest length measured. This can be explained by a change in loop formation. The almost 70Kb loop between the LCR and the 3’HS1 is folded into two loops of 34 and 35Kb upon interaction of the promotor to the ACH to activate transcription. The limited decrease in volume and length when the locus was probed with an additional 5’ and 3’ end region is surprising. The 5’ end is actively participating in the looping process that stabilizes the ACH. However, the 3’ end has (until now) not been seen to be participate in ACH formation or any complex looping mechanism for globin gene activation. As this part of the locus seems to be the most un-dynamic, it could be the dominating factor that influences the fluorescent signal emitting from the probed DNA region and therefore cloud subtle changes in the chromatin folding mechanism of gene activation. Next to the dynamic chromatin folding process that is occurring between the HS-85/84 and the 3’HS1, a stretch of “rigid” DNA can prevent a DNA region containing activated genes to stay at the edge of a chromosome territory and possibly prevent a close proximity to the silencing effect of (spreading) heterochromatin. An increase in lateral and axial resolution like the 3D Structural Illumination Microscope (SIM) provides, could help solve the problem of detecting subtle 3D changes in chromatin structure. And in the near future will reveal many more details of 3D chromatin organization of not only the m?-globin locus but of many other intra-cellular processes.