Erythroid Krüppel-like factor (EKLF) is active in primitive and definitive erythroid cells and is required for the function of 5'HS3 of the beta-globin locus control region.

Disruption of the gene for transcription factor EKLF (erythroid Krüppel-like factor) results in fatal anaemia caused by severely reduced expression of the adult beta-globin gene, while other erythroid-specific genes, including the embryonic epsilon- and fetal gamma-globin genes, are expressed normally. Thus, EKLF is thought to be a stage-specific factor acting through the CACC box in the beta-gene promoter, even though it is already present in embryonic red cells. Here, we show that a beta-globin gene linked directly to the locus control region (LCR) is expressed at embryonic stages, and that this is only modestly reduced in EKLF-/- embryos. Thus, embryonic beta-globin expression is not intrinsically dependent on EKLF. To investigate whether EKLF functions in the locus control region, we analysed the expression of LCR-driven lacZ reporters. This shows that EKLF is not required for reporter activation by the complete LCR. However, embryonic expression of reporters driven by 5'HS3 of the LCR requires EKLF. This suggests that EKLF interacts directly with the CACC motifs in 5'HS3 and demonstrates that EKLF is also a transcriptional activator in embryonic erythropoiesis. Finally, we show that overexpression of EKLF results in an earlier switch from gamma- to beta-globin expression. Adult mice with the EKLF transgene have reduced platelet counts, suggesting that EKLF levels affect the balance between the megakaryocytic and erythroid lineages. Interestingly, the EKLF transgene rescues the lethal phenotype of EKLF null mice, setting the stage for future studies aimed at the analysis of the EKLF protein and its role in beta-globin gene activation.

The role of EKLF in human beta-globin gene competition.

We have investigated the role of erythroid Kruppel-like factor (EKLF) in expression of the human beta-globin genes in compound EKLF knockout/human beta-locus transgenic mice. EKLF affects only the adult mouse beta-globin genes in homozygous knockout mice; heterozygous mice are unaffected. Here we show that EKLF knockout mice express the human epsilon and gamma-globin genes normally in embryonic red cells. However, fetal liver erythropoiesis, which is marked by a period of gamma- and beta-gene competition in which the genes are alternately transcribed, exhibits an altered ratio of gamma- to beta-gene transcription. EKLF heterozygous fetal livers display a decrease in the number of transcriptionally active beta genes with a reciprocal increase in the number of transcriptionally active gamma genes. beta-Gene transcription is absent in homozygous knockout fetuses with coincident changes in chromatin structure at the beta promoter. There is a further increase in the number of transcriptionally active gamma genes and accompanying gamma gene promoter chromatin alterations. These results indicate that EKLF plays a major role in gamma- and beta-gene competition and suggest that EKLF is important in stabilizing the interaction between the Locus Control Region and the beta-globin gene. In addition, these findings provide further evidence that developmental modulation of globin gene expression within individual cells is accomplished by altering the frequency and/or duration of transcriptional periods of a gene rather than changing the rate of transcription.

Defective haematopoiesis in fetal liver resulting from inactivation of the EKLF gene.

Erythroid Krüppel-like factor (EKLF) was originally isolated from erythroid cell RNA by differential screening and shown to be erythroid-specific, although a low level of EKLF was found in mast cell lines. EKLF contains three zinc-fingers homologous to those found in the Krüppel family of transcription factors. Because it binds the sequence CCACACCCT, EKLF may affect erythroid development as a result of its ability to bind to the CAC box in the promoter of the beta-globin gene. Mutation of this element leads to reduced beta-globin expression and it appears to mediate the effect of the globin locus control region on the promoter. Here we inactivate the EKLF gene through insertion of a lacZ reporter gene by homologous recombination in embryonic stem (ES) cells. Heterozygous EKLF+/- mice show that the reporter gene is expressed in a developmentally specific manner in all types of erythroblasts in the fetal liver and adult bone marrow. Homozygous EKLF-/- mice appear normal during the embryonic stage of haematopoiesis in the yolk sac, but develop a fatal anaemia during early fetal life when haematopoiesis has switched to the fetal liver. Enucleated erythrocytes are formed but these do not contain the proper amount of haemoglobin. We conclude that the transcription factor EKLF is essential for the final steps of definitive erythropoiesis in fetal liver.

Requirement for an A-tract structure at the binding site of phage phi 29 transcriptional activator.

The Bacillus subtilis phage phi 29 transcriptional activator, protein p4, binds to the 5'-AACT-TTTT-15 base-pair spacer-AAAATGTT-3' inverted repeat. In this communication, we study the influence in protein p4 binding of the DNA helical structure within the protein p4 recognition sequences, 5'-AAAATAG-3'. Protein p4 could efficiently bind to a modified target in which the A-tracts had been changed into T-tracts (a different sequence with a similar structure). Binding was lost when the structure of the binding site was modified by an interrupting C residue. The results suggest that the DNA helical structure of the A-tracts is critical for p4 binding. Two models are described that would explain how protein p4 recognized its target sequences on the DNA.

Bacteriophage Nf DNA region controlling late transcription: structural and functional homology with bacteriophage phi 29.

The putative region for the control of late transcription of the Bacillus subtilis phage Nf has been identified by DNA sequence homology with the equivalent region of the evolutionary related phage phi 29. A similar arrangement of early and late promoters has been detected in the two phages, suggesting that viral transcription could be regulated in a similar way at late times of the infection. Transcription of late genes requires the presence of a viral early protein, gpF in phage Nf and p4 in phage phi 29, being the latter known to bind to a DNA region located upstream from the phage phi 29 late promoter. We have identified a DNA region located upstream from the putative late promoter of phage Nf that is probably involved in binding protein gpF. Furthermore, we show that the phage phi 29 protein p4 is able to bind to this region and activate transcription from the phage Nf putative late promoter. Sequence alignment has also revealed the existence of significant internal homology between the two early promoters contained in this region of each phage.

The main early and late promoters of Bacillus subtilis phage phi 29 form unstable open complexes with sigma A-RNA polymerase that are stabilized by DNA supercoiling.

Most Escherichia coli promoters studied so far form stable open complexes with sigma 70-RNA polymerase which have relatively long half-lives and, therefore, are resistant to a competitor challenge. A few exceptions are nevertheless known. The analysis of a number of promoters in Bacillus subtilis has suggested that the instability of open complexes formed by the vegetative sigma A-RNA polymerase may be a more general phenomenon than in Escherichia coli. We show that the main early and late promoters from the Bacillus subtilis phage phi 29 form unstable open complexes that are stabilized either by the formation of the first phosphodiester bond between the initiating nucleoside triphosphates or by DNA supercoiling. The functional characteristics of these two strong promoters suggest that they are not optimized for a tight and stable RNA polymerase binding. Their high activity is probably the consequence of the efficiency of further steps leading to the formation of an elongation complex.

Phage phi 29 regulatory protein p4 stabilizes the binding of the RNA polymerase to the late promoter in a process involving direct protein-protein contacts.

Transcription from the late promoter, PA3, of Bacillus subtilis phage phi 29 is activated by the viral regulatory protein p4. A kinetic analysis of the activation process has revealed that the role of protein p4 is to stabilize the binding of RNA polymerase to the promoter as a closed complex without significantly affecting further steps of the initiation process. Electrophoretic band-shift assays performed with a DNA fragment spanning only the protein p4 binding site showed that RNA polymerase could efficiently retard the complex formed by protein p4 bound to the DNA. Similarly, when a DNA fragment containing only the RNA polymerase-binding region of PA3 was used, p4 greatly stimulated the binding of RNA polymerase to the DNA. These results strongly suggest that p4 and RNA polymerase contact each other at the PA3 promoter. In the light of current knowledge of the p4 activation mechanism, we propose that direct contacts between the two proteins participate in the activation process.

In vitro and in vivo analysis of transcription within the replication region of plasmid pIP501.

Derivatives of the conjugative streptococcal plasmid pIP501 replicate stably in Bacillus subtilis. The region essential for replication of pIP501 has been narrowed down to a 2.2 kb DNA segment, the sequence of which has been determined. This region comprises two genes, copR and repR, proposed to be involved in copy control and replication. By in vitro and in vivo transcriptional analysis we characterized three active promoters, pI, pII and pIII within this region. A putative fourth promoter (pIV) was neither active in vitro nor in vivo. We showed that copR is transcribed from promoter pI while the repR gene is transcribed from promoter pII located just downstream of copR. The pII transcript encompasses a 329 nucleotide (nt) long leader sequence. A counter transcript that was complementary to a major part of this leader was found to originate from a third promoter pIII. The secondary structure of the counter transcript revealed several stem-loop regions. A regulatory function for this antisense RNA in the control of repR expression is proposed. Comparative analysis of the replication regions of pAM beta 1 and pSM19035 suggested a similar organization of transcriptional units, suggesting that an antisense RNA is produced by these plasmids also.

Identification of the sequences recognized by phage phi 29 transcriptional activator: possible interaction between the activator and the RNA polymerase.

Expression of Bacillus subtilis phage phi 29 late genes requires the transcriptional activator protein p4. This activator binds to a region of the late A3 promoter spanning nucleotides -56 to -102 relative to the transcription start site, generating a strong bending Tin the DNA. In this work the target sequences recognized by protein p4 in the phage phi 29 late A3 promoter have been characterized. The binding of protein p4 to derivatives of the late A3 promoter harbouring deletions in the protein p4 binding site has been studied. When protein p4 recognition sequences were altered, the activator could only bind to the promoter in the presence of RNA polymerase. This strong cooperativity in the binding of protein p4 and RNA polymerase to the promoter suggests the presence of direct protein-protein contacts between them.