Identification and characterization of a chicken alpha-globin enhancer.

We identify and describe the properties of an enhancer within the chicken alpha-globin gene cluster. This cluster consists of one gene (pi) expressed only in primitive erythrocytes and two (alpha A and alpha D) expressed in both primitive and definitive cell lineages. The genes are linked together in the order 5'-pi-alpha D-alpha A-3' and occupy a region about 10 kilobase pairs long. The enhancer is located at the 3' end of the cluster, about 750 base pairs 3' to the alpha A translation stop site. When assayed by transfection into either primitive or definitive primary chicken erythrocytes, this element stimulated expression from plasmids containing the alpha D- or alpha A-globulin gene promoters. Except for sites in the alpha-globin promoters, no other stimulatory activity was observed in DNA taken from other regions of the alpha-globin locus. Moderate resolution DNase I hypersensitivity studies as well as DNase I footprinting revealed three regions of protein binding, each containing a similar core DNA sequence within the enhancer element. Gel mobility shift studies demonstrated that all three regions bind the recently identified erythrocyte-specific factor, EryfI, which has binding sites in the regulatory regions of all chicken globin genes. Our data suggest that the enhancer we have identified may act in vivo only on the alpha A gene; expression of the alpha D gene is affected by another EryfI site located in the alpha D promoter. Such a mechanism would be consistent with the observed relative abundances of alpha A- and alpha D-globin in vivo. The simplicity of these regulatory elements may reflect the limited repertoire of expression of these genes during development.     

B-lymphocyte targeting of gene expression in transgenic mice with the immunoglobulin heavy-chain enhancer.

A hybrid gene containing rabbit beta-globin structural sequences (-9 to +1650), and a chicken conalbumin gene promoter (+62 to -102) in the place of the beta-globin promoter (upstream from -9), was inactive in 5 different transgenic mouse line. Adding the mouse immunoglobulin heavy-chain (IgH) enhancer to this construction specifically stimulated expression in B-cells. These results show that IgH enhancer is specifically active in B-cells. Expression of the hybrid gene was low compared to the endogenous immunoglobulin heavy and light-chain genes. Substituting the mouse immunoglobulin kappa light-chain gene (Ig kappa) promoter (+4 to -800) for the heterologous conalbumin promoter was not sufficient to restore gene expression to level of the endogenous genes. In addition to the reproducible B cell expression, we also found inheritable unexpected expression in certain tissues, which varied from line to line.     

Identification of enhancer sequences 3' of the rabbit Ig kappa L chain loci

The rabbit is useful for studies of Ig L chain gene expression because of a great disparity in expression of two isotypic forms of the kappa L chain. Normally, K1 is expressed at high levels and K2 is almost silent; expression of K2 increases in mutant or experimentally allotype-suppressed animals. The reasons for the preferential utilization of the K1 isotype have not been fully elucidated. We were interested in looking for second enhancers 3' of the C kappa genes because the absence of a 3' enhancer in the K2 locus could explain the preferential utilization of the K1 isotype. However, we found a strong region of enhancer activity about 7 kb downstream of the C kappa 2 gene. Sequences in this region are highly conserved between rabbit, man, and mouse. There also appears to be a homologous 3' enhancer region in the rabbit K1 locus. We also confirmed earlier reports that the rabbit K1 intron enhancer is inactive in transient transfections into mouse B cells but find that the same construct has low but significant activity in a human B cell line. In a comparable construct the K2 intron enhancer is without activity suggesting possible differential activity of the intronic enhancers.     

Regulation of the rat alpha-fetoprotein gene expression in liver. Both the promoter region and an enhancer element are liver-specific and negatively modulated by dexamethasone.

Cis-acting elements involved in the control of rat alpha-fetoprotein gene expression in the liver and its modulation by glucocorticoid hormones were detected after transfection of chloramphenicol acetyltransferase constructs and their transient expression into two hepatoma cell lines. The proximal promoter region (-324 to -15) was found to contain all the information necessary for tissue-specific expression. It is also involved in the negative gene modulation by glucocorticoids and includes an activating regulatory domain allowing efficient expression in the HepG2 cells. Three regions within 7 kilobase pairs of the 5' extragenic sequences are capable of stimulating the chloramphenicol acetyltransferase activity driven by the alpha-fetoprotein promoter sequence. One of these regions, at about -2.5 kilobase pairs, contains a short indivisible 170-base pair DNA element that fulfills all the criteria of a tissue-specific enhancer, i.e. orientation and position independence, as well as cell-specific stimulation of gene expression driven by a homologous or heterologous promoter. The enhancing properties of this element are totally abolished by glucocorticoids. DNase I footprinting experiments indicate that several rat liver nuclear proteins interact with this enhancer element.     

Characterization of cDNA and genomic sequences corresponding to an embryonic myosin heavy chain

We report here the isolation and characterization of cDNA and genomic sequences corresponding to a rat embryonic myosin heavy chain (MHC) protein. This gene, which is present as a single copy in the rat genome, comprises about 25 kilobase pairs of DNA and contains approximately 80% intronic sequences. The embryonic MHC gene belongs to a highly conserved multigene family, and exhibits a high degree of nucleotide and amino acid sequence conservation with other sarcomeric MHC genes from nematode to man. S1 nuclease mapping experiments using cDNA and genomic probes show that this MHC gene is transiently expressed during skeletal muscle development. Its mRNA is detected in fetal skeletal muscle during early development and persists up to 2 weeks after birth with the overlapping expression of neonatal and adult skeletal MHC mRNAs. However, this MHC is not expressed in the adult skeletal muscle with the exception of extraocular muscle fibers. The transient expression during muscle development of the isoform produced by this gene and its sequential replacement by other MHCs raises interesting questions about the mechanism controlling MHC isozyme transitions and the physiological significance of the individual MHCs in muscle fibers.     

Different E-box regulatory sequences are functionally distinct when placed within the context of the troponin I enhancer.

Basic helix-loop-helix (bHLH) regulatory proteins are known to bind to a single DNA consensus sequence referred to as an E-box. The E-box is present in the regulatory elements of many developmentally controlled genes, including most muscle-specific genes such as troponin I (TnI). Although the E-box consensus is minimally defined as CANNTG, the adjacent nucleotides of functional E-boxes are variable for genes regulated by the bHLH proteins. In order to examine how E-box regulatory regions containing different internal and flanking nucleotides function when placed within the context of a single regulatory element, the E-box region (14 bp) present within the TnI enhancer was substituted with the corresponding E-box sequences derived from the muscle-specific M-creatine kinase (MCK) and cardiac alpha-actin regulatory elements as well as from the immunoglobulin kappa (Ig kappa) enhancer. Within the TnI enhancer, the E-box sequence derived from cardiac alpha-actin was inactive whereas the corresponding sequence from the MCK right E-box efficiently restored wild-type enhancer activity in muscle cells. Intermediate levels of gene activity were observed for TnI enhancers containing E-boxes derived from the MCK left E-box site or from the Ig kappa E2 E-box. DNA binding studies of MyoD:E12 protein complexes with each substituted TnI enhancer confirmed that DNA binding activity in vitro mimics the relative strength of the enhancers in vivo. These studies demonstrate that the specific nucleotide composition of individual E-boxes, which are contained within the regulatory elements of most if not all muscle-specific genes, contributes to the complex regulatory mechanisms governing bHLH-mediated gene expression.     

Structural analysis of a rabbit immunoglobulin kappa 2 J-C locus reveals multiple deletions.

We previously reported that domestic rabbits harbor at least two DNA sequences that hybridize strongly to immunoglobulin kappa C region probes in Southern blots. One of these was cloned from a domestic b4 rabbit and identified as the gene for the nominal b4 allotype kappa chain which is expressed at high levels. We now have cloned (from a b4 rabbit) the other homologous sequence and find that it encodes a kappa chain nearly identical to the kappa 2 chain of "bas" rabbits, which is not normally expressed at detectable levels in domestic rabbits. Sequence analysis of this kappa 2 chain reveals a J kappa -C kappa locus with no obvious coding sequence defects that could explain its low expression. However, several base changes in a putative enhancer region as well as deletions (totalling about 1.5 kb) in the J-C intron might be related to low expression. The comparison between these two kappa genes raises questions about the selective pressures operating during the evolution of this gene system.     

Adult chicken alpha-globin gene expression in transfected QT6 quail cells: evidence for a negative regulatory element in the alpha D gene region.

The chicken adult alpha-globin genes, alpha A and alpha D, are closely linked in chromosomal DNA and are coordinately expressed in vivo in an approximate 3:1 ratio, respectively. When subcloned DNAs containing one or the other gene are stably transfected into QT6 quail fibroblasts, the alpha A-globin gene is expressed at measurable RNA levels, but the alpha D gene is not. The alpha A gene expression can be considerably increased by the presence of a linked Rous sarcoma virus long terminal repeat enhancer, but that of the alpha D gene remains undetectable. Transfection with subclones containing both genes, either in cis or in trans, leads to considerably reduced alpha A RNA levels and still no observable alpha D gene expression. Transfection with deleted subclones suggests that maximal expression levels in this system require the alpha A-globin gene promoter, as opposed to that of the alpha D gene, but that such expression is greatly reduced by one or more DNA sequences which lie approximately 2,000 base pairs upstream of the alpha A gene, within the body of the alpha D gene.     

Alpha-tropomyosin gene organization. Alternative splicing of duplicated isotype-specific exons accounts for the production of smooth and striated muscle isoforms

We have previously isolated and characterized cloned complementary DNAs (cDNAs) for striated and smooth muscle alpha-tropomyosin. The sequences of these cDNA clones suggested that these two isoforms were encoded by the same gene. Here, we have determined the complete structure of the alpha-tropomyosin (alpha-TM) gene, establishing that a single gene, with a sequence complexity of 28 kilobase pairs, is split into 12 exons and produces the smooth and striated muscle alpha-TM mRNA isoforms by alternative splicing of a minimum of five exchangeable isotype-specific exons. The elucidation of the intron/exon organization of alpha-TM suggests that this gene evolved from an ancestral gene encoding a 21-aa protein that might represent the primordial actin binding domain. Sequence comparison between the pairs of exons coding for the "isotype switch regions" and among the corresponding regions of tropomyosin genes in a variety of species ranging from insects to mammals, suggests that the alternatively spliced exons are very old and might have arisen before the radiation of the arthropods, more than 600 million years ago. Additionally, the examination of the intronic sequences has uncovered potential alternative intramolecular secondary structures (hairpin-loop structures) which might be involved in the tissue-specific expression of the duplicated and mutually exclusive alpha-TM isotype-specific exons.