The first exon of the rat aldolase C gene is essential for restoring the chromatin structure in transgenic mice

BLG-e1 - a novel regulatory element in the distal region of the beta-lactoglobulin gene promoter

beta-Lactoglobulin (BLG) is a major ruminant milk protein. A regulatory element, termed BLG-e1, was defined in the distal region of the ovine BLG gene promoter. This 299-bp element lacks the established cis-regulatory sequences that affect milk-protein gene expression. Nevertheless, it alters the binding of downstream BLG sequences to histone H4 and the sensitivity of the histone-DNA complexes to trichostatin A treatment. In mammary cells cultured under favorable lactogenic conditions, BLG-e1 acts as a potent, position-independent silencer of BLG/luciferase expression, and similarly affects the promoter activity of the mouse whey acidic protein gene. Intragenic sequences upstream of BLG exon 2 reverse the silencing effect of BLG-e1 in vitro and in transgenic mice.

Purkinje cell expression of the mouse aldolase C gene in transgenic mice is directed by an upstream regulatory element

We have sought to understand the regulation of the expression pattern of aldolase C (Zebrin II) in cerebellar Purkinje cells. Normally, aldolase C is expressed in a series of sagittal stripes of Purkinje cells interrupted by stripes of little or no expression. Genomic aldolase C:LacZ fusion genes with 1.8 kb of sequence 5' to the transcription start site drive CNS expression of LacZ only in astrocytes and cells of the pia mater. If the 5' portion of the transgene is extended to a full 5.0 kb, expression is reliably observed in Purkinje cells, yet none of the astrocyte expression is lost. We broke the additional 3.0 kb into 1.0 kb fragments and tested each for Purkinje cell enhancer activity when appended to the original 1.8 kb construct. We show that the 886 bp region from nucleotide -2796 to -3682 (relative to the start of transcription) contains virtually all of the Purkinje cell enhancer activity. However, neither the full 5.0 kb nor the 886 bp region directed a striped expression pattern, as is seen for the endogenous gene. Taken together, our study localizes a Purkinje cell enhancer to a small 5' region of the aldolase C gene and illustrates that the element(s) responsible for the normal anatomically complex pattern of aldolase C expression are separate from those conferring cell-type specificity. The relationship of these findings to previous work in other laboratories is discussed.

Critical regulatory domains in intron 2 of a porcine sarcomeric myosin heavy chain gene

The porcine sarcomeric fast 2a myosin heavy chain (MyHC) gene was previously found to require a region extending 3' from the transcriptional start site for high levels of expression. Here we established the existence of two novel opposing regulatory domains in intron 2. A positive regulatory element, defined to a 75bp region, resembles a TATA-less intronic promoter, with a consensus transcription initiation element. It can up-regulate its endogenous or a heterologous muscle promoter in a position specific manner, and on its own drive a reporter gene. In tandem with it is a dominant negative regulatory element, localised to a 81bp region, which can down-regulate its native gene and a heterologous muscle promoter. Bandshift and DNase I footprinting assays demonstrated that specific nuclear factors bound to both regulatory elements are distinctly different. Both elements appear to have no counterpart in intron 2 of the porcine fast 2x and 2b MyHC genes. Taken together, we demonstrate for the first time that a 5'-end terminal intron of a sarcomeric MyHC gene contains two critical regulatory domains, which may be involved in the complexity of temporo-spatial expression.

Upstream elements involved in vivo in activation of the brain-specific rat aldolase C gene. Role of binding sites for POU and winged helix proteins

The rat aldolase C gene encodes a glycolytic enzyme strongly expressed in adult brain. We previously reported that a 115-base pair (bp) promoter fragment was able to ensure the brain-specific expression of the chloramphenicol acetyltransferase (CAT) reporter gene in transgenic mice, but only at a low level (Thomas, M., Makeh, I., Briand, P., Kahn, A., and Skala, H. (1993) Eur. J. Biochem. 218, 143-151). Here we show that in vivo activation of this promoter at a high level requires cooperation between an upstream 0.6-kilobase pair (kb) fragment and far upstream sequences. In the 0.6-kb region, a 28-bp DNA element is shown to include overlapping in vitro binding sites for POU domain regulatory proteins and for the Winged Helix hepatocyte nuclear factor-3beta factor. An hepatocyte nuclear factor-3beta-binding site previously described in the short proximal promoter fragment is also shown to interact in vitro with POU proteins, although with a lower affinity than the 28-bp motif. Additional binding sites for POU factors were detected in the upstream 0.6-kb sequences. Progressive deletion in this region resulted in decreased expression levels of the transgenes in mice, suggesting synergistic interactions between these multiple POU-binding sites. We propose that DNA elements characterized by a dual binding specificity for both POU domain and Winged Helix transcription factors could play an essential role in the brain-specific expression of the aldolase C gene and other neuronal genes.