Lysozyme gene activity in chicken macrophages is controlled by positive and negative regulatory elements.

The chicken lysozyme gene is constitutively active in macrophages and under the control of steroid hormones in the oviduct. To investigate which DNA elements are involved in the control of its expression in macrophages we performed transient DNA transfer experiments with two different types of plasmids: 5'-deletion mutants of the upstream region of the chicken lysozyme gene and different fragments from this area in front of the thymidine kinase promoter (herpes simplex virus), each placed in front of the CAT (chloramphenicol acetyl transferase) coding sequence. Two enhancers (E-2.7 kb and E-0.2 kb) were characterized. They are active in macrophages, but not in chicken fibroblasts. Furthermore a negative element (N-2.4 kb) was identified, which is active in fibroblasts and promyelocytes, but not in mature macrophages. The combined action of all three elements contributes to the observed lysozyme gene activities: no activity in fibroblasts, moderate activity in promyelocytes and high activity in mature macrophages.     

Organization, sequence and nuclease hypersensitivity of repetitive elements flanking the chicken apoVLDLII gene: extended sequence similarity to elements flanking the chicken vitellogenin gene.

Analysis of nuclease hypersensitivity of regions flanking the estrogen-dependent, chicken apoVLDLII gene has revealed an hepatic, DNaseI hypersensitive site whose sensitivity is influenced by both the developmental stage and sex of the bird. The site is located 3.0kb upstream from the gene, in a block of middle repetitive elements. Contact hybridization studies indicate that the block consists of contiguous copies of two elements with reiteration frequencies of 500-1000 and 10,000-30,000 copies per haploid genome. Sequencing of 1.8kb spanning the repeats has revealed that the higher frequency element is a member of the CR1 family. The adjacent lower frequency repeat can also be found next to another member of the CR1 family located in the 3' flanking region of the vitellogenin gene. The hypersensitive site has been mapped to one of the two most highly conserved regions of the CR1 element. This region displays homology with a silencer sequence recently identified in a CR1 element flanking the chicken lysozyme gene.     

Modular structure of a chicken lysozyme silencer: involvement of an unusual thyroid hormone receptor binding site

Silencer elements, by analogy to enhancer elements, function independently of their position and orientation. We show that the chicken lysozyme silencer S-2.4 kb has many other characteristics in common with enhancer elements. The silencer is comprised of modules that independently repress gene activity--repression being increased synergistically when different or identical modules are combined. Repression is effective both on a complete and on a minimal promoter consisting of a TATA box only. One silencer module is bound in vitro by a 75-93 kd protein, termed NeP1; the other can be bound either by the product of the oncogene v-erbA or by the thyroid hormone receptor. This erbA binding site is unusual in that the palindromic sequence is inverted.     

Dissection of the locus control function located on the chicken lysozyme gene domain in transgenic mice.

The entire chicken lysozyme gene locus including all known cis-regulatory sequences and the 5' and 3' matrix attachment sites defining the borders of the DNase I sensitive chromatin domain, is expressed at a high level and independent of its chromosomal position in macrophages of transgenic mice. It was concluded that the lysozyme gene locus carries a locus control function. We analysed several cis-regulatory deletion mutants to investigate their influence on tissue specificity and level of expression. Position independent expression of the gene is lost whenever one of the upstream tissue specific enhancer regions is deleted, although tissue specific expression is usually retained. Deletion of the domain border fragments has no influence on copy number dependency of expression. However, without these regions an increased incidence of ectopic expression is observed. This suggests that the domain border fragments may help to suppress transgene expression in inappropriate tissues. We conclude, that position independent expression of the lysozyme gene is not controlled by a single specific region of the locus but is the result of the concerted action of several tissue specific upstream regulatory DNA elements with the promoter.     

Tissue specific and position independent expression of the complete gene domain for chicken lysozyme in transgenic mice.

A 21.5 kb DNA fragment carrying the entire chicken lysozyme gene locus was introduced into the germ line of mice. The fragment contains the transcribed region plus 11.5 kb 5'-flanking and 5.5 kb 3'-flanking sequences including all known cis-regulatory elements and the 5' and 3' attachment elements (A-elements) which define the borders of the DNase I sensitive chromatin domain. All sequences which adopt a DNase I hypersensitive chromatin conformation in vivo are present on the construct. Seven founder mice were analysed. All of these expressed chicken lysozyme RNA at high levels specifically in macrophages, as is the case in the donor species. Expression levels are dependent on the copy number of integrated genes indicating that a complete gene locus, as defined by its chromatin structure, functions as an independent regulatory unit when introduced into a heterologous genome.