Binding of a liver-specific factor to the human albumin gene promoter and enhancer.

A segment of 1,022 base pairs (bp) of the 5'-flanking region of the human albumin gene, fused to a reporter gene, directs hepatoma-specific transcription. Three functionally distinct regions have been defined by deletion analysis: (i) a negative element located between bp -673 and -486, (ii) an enhancer essential for efficient albumin transcription located between bp -486 and -221, and (iii) a promoter spanning a region highly conserved throughout evolution. Protein-binding studies have demonstrated that a liver trans-acting factor which interacts with the enhancer region is the well-characterized transcription factor LF-B1, which binds to promoters of several liver-specific genes. A synthetic oligodeoxynucleotide containing the LF-B1-binding site is sufficient to act as a tissue-specific transcriptional enhancer when placed in front of the albumin promoter. The fact that the same binding site functions in both an enhancer and a promoter suggests that these two elements influence the initiation of transcription through similar mechanisms.

Two distinct factors interact with the promoter regions of several liver-specific genes.

A segment of the human alpha 1-antitrypsin (alpha 1AT) 5'-flanking region comprising nucleotides -137 to -37 from the start of transcription is sufficient to drive liver-specific transcription from the homologous alpha 1AT promoter and from the heterologous SV40 promoter. In this paper we characterize two proteins, LF-A1 and LF-B1, whose ability to bind wild-type and mutant alpha 1AT promoter segments correlates with the ability of these segments to activate transcription in vivo. DNase I protection and methylation interference analysis reveals that LF-A1 recognizes sequences present in the regulatory region of the human alpha 1-antitrypsin, apolipoprotein A1 and haptoglobin-related genes. These sequences share a common 5' TGG/A A/C CC 3' motif. LF-B1 binds to the palindrome 5' TGGTTAAT/ATTCACCA 3' which is present in the human alpha 1-antitrypsin gene between positions -78 and -62 from the start of transcription. LF-B1 also recognizes a related sequence present in the human albumin gene between -66 and -50. These results suggest that LF-A1 and LF-B1 are common positive trans-acting factors which are required for the expression of several genes in the hepatocyte.

The transcription factor LF-A1 interacts with a bipartite recognition sequence in the promoter regions of several liver-specific genes.

The transcription factors LF-A1 and LF-B1 are required for the cell-specific expression of the human alpha 1-antitrypsin gene in hepatocytes. We report here the purification and preliminary characterization of LF-A1. This protein, purified to homogeneity from calf liver nuclei by site-specific DNA affinity chromatography and reverse-phase HPLC, has a molecular mass of 40 kDa. Binding sites of LF-A1 are present in the promoter regions of several genes expressed in the liver (alpha 1-antitrypsin, apolipoproteins A1, B1, A4 and pyruvate kinase). Interestingly, the binding site of LF-A1 is bipartite and consists of two short sequence motifs (consensus: TGGACT/CT/C and TGGCCC) separated by a variable 'spacer' region. Insertion or deletion of 1-4 nucleotides in the 'spacer' region of the site in the alpha 1-antitrypsin promoter does not abolish DNA binding.

Structure and sequence of the Drosophila zeste gene.

The zeste gene of Drosophila affects the expression of other genes in a manner that depends on the homologous pairing of the chromosomes bearing the target gene. Zeste mediates transvection effects, the ability of one gene to control the expression of its homologous copy on another chromosome. We have determined the structure of the zeste gene and several mutants bearing partial deletions and the sequence of the z+, z1, zop6 and z11G3 alleles. The predicted zeste protein has an unusual structure including runs of Gln, Ala and alternating Gln Ala. Contrary to expectations the z1, zop6 and z11G3 mutations can each be attributed to single amino acid changes. The analysis of the mutants suggests that the zeste gene product is required for normal expression of at least some genes and we argue that za mutants may have residual function.

Self-cloning in the cyanobacterium Anacystis nidulans R2: fate of a cloned gene after reintroduction.

Functional analysis of cloned genes often makes use of complementation after introducing these genes into cells of a mutant strain. Problems with this self-cloning step in the cyanobacterium Anacystis nidulans R2 have been encountered, which were mainly due to recombinational instability of gene and vector after transformation. Therefore, conditions determining the exchange of material between chromosome, insert and plasmids were studied to achieve the necessary stability. The fate of plasmid pME1, containing a wild-type methionine gene from A. nidulans R2, was investigated after its introduction into a Tn901-induced methionine mutant strain as recipient, so that the mutant chromosomal gene could be distinguished from the plasmid-borne wild-type copy. Two different recipients were constructed, one containing and one lacking the resident plasmid pCH1, which is a derivative of the indigenous small plasmid pUH24. When using the pCH1-free strain and with combined selection for both wild-type gene and vector, the original configuration of the genes in chromosome and vector was retained in the majority of the transformed cells, while the remaining transformants were reciprocal recombinants; under conditions of single selection mainly nonreciprocal recombination or loss of the vector was observed. When the recipient strain contained pCH1 additional recombinational events took place. The results show that under appropriate conditions a chromosomal gene cloned on a plasmid vector can be stably maintained in a majority of the transformants, thus making self-cloning experiments feasible in A. nidulans R2. On the other hand, the introduction of foreign DNA into the chromosome can be achieved by deliberately exploiting recombination between chromosome and plasmid.

Cis- and trans-acting elements responsible for the cell-specific expression of the human alpha 1-antitrypsin gene.

The 5' flanking region of the human alpha 1-antitrypsin (alpha 1-AT) gene contains cis-acting signals for liver-specific expression and, when fused to a reporter gene, is able to drive the expression of this gene specifically in liver cells. Here we report the results of a functional dissection of the alpha 1-AT regulatory region. The expression of the bacterial chloramphenicol-transacetylase (CAT) gene, fused to a set of alpha 1-AT 5' flanking regions shortened by progressive deletions or mutated by base pair substitutions, has been compared by transfection in HepG2 (hepatocyte) and HeLa (non-hepatocyte) human cell lines. A minimal tissue-specific element has been identified between the nucleotides -137 and -37 (from the transcriptional start site). This DNA segment activates the heterologous SV40 promoter in hepatoma cell lines but not in HeLa cells. This element contains at least two regions referred to as the A (-125/-100) and B (-84/-70) domains, both essential for transcription. There are at least two other regulatory domains located upstream of the 'minimal element'; the most active of these is located between positions -261 and -210 from the cap site. These upstream elements activate the heterologous SV40 early promoter both in hepatoma cell lines and in HeLa cells. Upon fractionation of rat liver nuclear extracts two proteins have been identified, alpha 1TF-A and alpha 1TF-B, which bind specifically to the A and B domains respectively. Transcriptionally inactive A and B domain mutants are not able to bind these proteins.