α-Thalassemia resulting from a negative chromosomal position effect

To date, all of the chromosomal deletions that cause -thalassemia remove the structural  genes and/or their regulatory element (HS –40). A unique deletion occurs in a single family that juxtaposes a region that normally lies approximately 18-kilobase downstream of the human  cluster, next to a structurally normal -globin gene, and silences its expression. During development, the CpG island associated with the -globin promoter in the rearranged chromosome becomes densely methylated and insensitive to endonucleases, demonstrating that the normal chromatin structure around the -globin gene is perturbed by this mutation and that the gene is inactivated by a negative chromosomal position effect. These findings highlight the importance of the chromosomal environment in regulating globin gene expression.

α-Thalassemia resulting from a negative chromosomal position effect

To date, all of the chromosomal deletions that cause -thalassemia remove the structural  genes and/or their regulatory element (HS –40). A unique deletion occurs in a single family that juxtaposes a region that normally lies approximately 18-kilobase downstream of the human  cluster, next to a structurally normal -globin gene, and silences its expression. During development, the CpG island associated with the -globin promoter in the rearranged chromosome becomes densely methylated and insensitive to endonucleases, demonstrating that the normal chromatin structure around the -globin gene is perturbed by this mutation and that the gene is inactivated by a negative chromosomal position effect. These findings highlight the importance of the chromosomal environment in regulating globin gene expression.

Tissue- and stage-specific activation of an endogenous provirus after transcription through its integration site in the opposite orientation.

Endogenous proviruses of the Moloney murine leukemia retrovirus (Mo-MuLV) are transcriptionally blocked in early embryos and in general remain silent even when the tissues have become permissive to the expression of newly integrated copies. Eventually, activation in presumably very few cells initiates rapid superinfection leading to viremia and leukemia, but the processes leading to provirus activation are unknown. Differences in the onset and development of viremia between several mouse strains carrying an endogenous Mo-MuLV (Mov lines) are attributed to a chromosomal position effect, but neither cell type nor stage of provirus activation is known for any strain. We have now monitored the appearance of viral transcripts and particles in the Mov13 strain, which carries the Mo-MuLV provirus in inverted orientation in the first intron of a collagen gene (Col1a1) with well-characterized transcriptional activity. We report obligatory tissue- and stage-specific virus activation in osteoblasts and odontoblasts. The significance of this activation pattern is indicated by the fact that of the great variety of cells expressing the wild-type collagen gene, only these two cell types can also transcribe the mutant allele including its viral insert. We propose that this transcription of the proviral genome, albeit in the opposite direction, leads to the activation of the viral promoter.

Expression of a foreign gene in a line of transgenic mice is modulated by a chromosomal position effect.

Unusual aberrant expression of a foreign gene in a particular transgenic mouse line is often attributed to chromosomal position effect, although proof of this is lacking. An alternative explanation is that expression has been modified by the arrangement of multiple copies of the foreign gene at the insertion site or by mutation or gene rearrangement. We have distinguished between these explanations in the case of one particular transgenic line by recovering the aberrantly expressed foreign DNA and reintroducing it into the mouse genome to produce secondary transgenic mice. The expression pattern of the gene in the secondary transgenic mice was normal, showing that this case of aberrant expression is due to a chromosomal position effect.