Identification of an enhancer and an alternative promoter in the first intron of the alpha-fetoprotein gene.

In this study we have characterized a positive regulatory region located in the first intron of the alpha-fetoprotein (AFP) gene. We show that the enhancer activity of the region depends on a 44 bp sequence centered on a CACCC motif. The sequence is the target of the two zinc fingers transcription factors BKLF and YY1. The introduction of a mutation destroying the CACCC box impairs the binding of BKLF but improves that of YY1. Moreover, the mutated sequence behaves as a negative control element, suggesting that BKLF behaves as a positive factor and that YY1 is a negative one. We also demonstrate the existence of a novel, tissue-specific AFP mRNA isoform present in the yolk sac and fetal liver which initiates from an alternative promoter located approximately 100 bp downstream of the enhancer element. The transcriptional start site controlled by this new promoter (called P2), was mapped to 66 bp downstream of a TATA box. A putative AUG translation site in-frame with exon 2 of the classical gene was found 295 bp downstream of the transcription start site. Like the traditional AFP promoter (P1), the P2 promoter is active in the yolk sac and fetal liver. Embryonic stem cells with an AFP knock-in gene containing either the P2 promoter or deleted for it were isolated and comparative analysis of embryonic bodies derived from these cells suggests that the P2 promoter contributes to early expression of the AFP gene.

Direct selection cloning vectors adapted to the genetic analysis of gram-negative bacteria and their plasmids.

A range of specific and unusual biological pathways are found in Gram-negative bacteria. It is possible to express the genes involved in these processes in Escherichia coli, however, some genes prove lethal when cloned into high copy number vectors in common usage. Conversely, various genetic functions remain silent in E. coli and require to be transferred into their original host for expression and subsequent analysis. To facilitate the cloning and the characterisation of bacterial genes, we have constructed CcdB 'positive-selection' vectors that possess one or more of the following properties: (i) low or medium copy number; (ii) narrow or broad replication host range; (iii) conjugational mobilisation. In this communication, we illustrate the use of these new cloning tools and analyse the CcdB toxicity in different bacterial species.

Positive-selection vectors using the F plasmid ccdB killer gene.

Plasmids pKIL18/19 are positive-selection cloning vectors containing an active cytotoxic ccdB gene under the control of the lacP promoter. They are derivatives of high-copy-number pUC18/19 plasmids in which the ccdB killer gene has been fused in phase downstream from the lacP MCS18 and MCS19 multiple cloning sites. When an Escherichia coli wild-type gyrA+ strain is transformed by such vectors, the ccdB gene product blocks bacterial growth. However, if ccdB is inactivated by insertion of a foreign DNA fragment, this recombinant plasmid no longer interferes with host viability. The positive selection of recombinant clones is highly efficient and bench manipulations are simplified to the utmost: E. coli transformants are plated on rich medium and only cells containing recombinant plasmids give rise to colonies. The CcdB protein is a potent poison of gyrase and the gyrA462 mutation confers total resistance to CcdB [Bernard and Couturier, J. Mol. Biol. 226 (1992) 735-745]. Therefore, pKIL18/19 vectors can be amplified and prepared in large quantities in a gyrA462 host. Like pUC vectors, pKIL vectors are designed for general cloning/sequencing procedures.

Bifunctional lacZ alpha-ccdB genes for selective cloning of PCR products.

The use of PCR-amplified DNA-fragments is a classical approach to generate recombinant DNA. To facilitate the cloning of PCR products, we have constructed two new pKIL vectors that allow selection of recombinants. The multiple cloning sites (MCS) of these plasmids contain two adjacent Aspel sites and a unique HindII site. Cleavage of these vectors with Aspel produce linearized molecules with a single thymidine nucleotide at the 3' ends allowing TA cloning of Taq-amplified fragments. On the other hand, cleavage with HindII can be used for the cloning of blunt-ended PCR products generated by other DNA polymerases. The LacZ alpha-CcdB fusion protein produced by these plasmids has retained both the CcdB killer activity and the ability to alpha-complement the truncated LacZ delta M15. This bifunctionality allowed us to show that small PCR products (< 1000 bp) that do not disrupt lacZ alpha efficiently do inactivate CcdB, which demonstrates that the CcdB-based selection is well adapted for cloning of PCR products, especially for small size fragments.

Positive selection vectors to generate fused genes for the expression of his-tagged proteins.

Epitope tagging simplifies detection, characterization and purification of proteins. Gene fusion to combine the coding region of a well-characterized epitope with the coding region for a protein of interest generally requires several subcloning steps. Alternatively, a PCR strategy can be used to generate such a chimeric gene. In addition to its simplicity, this approach allows one to limit the size of the multiple cloning sites present in conventional expression vectors, thus reducing the introduction of artifactual amino-acid sequences into the fused protein. In this communication, we describe new vectors that allow PCR cloning and selection of chimeric genes coding for N- or C-terminal His-tagged proteins. These vectors are based on the control of cell death CcdB direct selection technology and are well adapted to the cloning of blunt-ended PCR products that were generated by using thermostable polymerases that provide proofreading activity.

New positive selection system based on the parD (kis/kid) system of the R1 plasmid.

The use of vectors that are designed to allow positive selection of recombinants facilitates cloning experiments in E. coli. Using kid, a lethal gene of the R1 plasmid parD locus, we generated pKID vectors leading to high selective efficiency of recombinants (greater than 90%). The E. coli bacterial host used to propagate these vectors produces the Kis protein, the natural antagonist of Kid. This new positive-selection system exhibits the same efficiency as the original ccdB-based selection vectors, pKIL (4). We also show that the ccdB and kid systems are independent. This property increases the potential of plasmidic poison-antidote systems for genetic applications and opens the door to a generation of new vectors containing the two selection systems.

Negative regulation of the alpha-foetoprotein gene in fibroblasts: identification and characterization of cis and trans elements.

The alpha-foetoprotein (AFP) gene is extinguished in hybrids formed between hepatoma cells (expressing cells) and fibroblasts (non-expressing cells). Transfection experiments with constructions containing segments from the promoter region of the AFP-gene, placed upstream of an ubiquitously expressed promoter (the Herpes virus thymidine kinase gene promoter), showed that the AFP gene-derived sequence contains at least one negative element active in fibroblasts (while this sequence behaves as an enhancer in hepatoma cells). We identified such a fibroblast negative region, localized between nucleotide positions -80 to -38 (FNE1). Gel retardation experiments showed that FNE1 specifically binds fibroblast nuclear proteins, generating three complexes. The sequence from -57 to -43 was shown to be responsible for both the formation of these complexes and the negative activity of FNE1. These results suggest that the binding of nuclear factors to the AFP promoter region contributes to silencing the AFP gene in non-expressing cells, such as fibroblasts, and thus to establishing lineage-specific expression of the AFP gene.

Nucleotide sequence and replication characteristics of RepHI1B: a replicon specific to the IncHI1 plasmids.

The IncHI1 plasmids are multireplicon plasmids. They contain at least three autoreplicative regions, one of which is closely related to the RepFIA replicon of F. Two other IncHI1-specific replicons, RepHI1A and RepHI1B, have been recently isolated and mapped on the R27 (IncHI1) genome (P. Gabant, P. Newnham, D. Taylor, and M. Couturier, J. Bacteriol. 175, 7697-7701, 1993). In the present work, the DNA sequence of RepHI1B was determined. It reveals DNA repeats of 17 base pairs located upstream and downstream from a gene coding for a 32 kilodalton protein (RepA) required for replication. Interestingly, RepA presents significant homology with other Rep proteins encoded by plasmids belonging to different incompatibility groups: P1 (IncY), Rts1 (IncT), RepFIB (IncFI) and RepHI1A (IncHI1). All these results provide strong evidence that the RepHI1B replicon of the IncHI1 subgroup belongs to the group of plasmids which control their copy number by an iteron mechanism.

Cloning and characterization of the Inc A/C plasmid RA1 replicon.

The Inc A/C plasmids, like Inc P and Inc Q plasmids, have a broad host range. However, their maintenance functions remain to be studied. An autoreplicative region of 2.79 kb named RepA/C, able to replicate both in the family Enterobacteriaceae and in Pseudomonas spp., was isolated and sequenced. The stability, copy number, and incompatibility expression of this replicon were determined. RepA/C and a nonautoreplicative fragment of 16 kb of this replicon were used as probes and showed specific hybridizations with the Inc P3-A/C plasmids from Pseudomonas spp. and members of the Enterobacteriaceae. These probes could be used as tools for identification of the plasmids of this epidemiologically important Inc group.

Molecular analysis of RepHI1B, a replicon specific to IncHI1 plasmids.

RepHI1B is one of the replicons that is specific to IncHI1 multireplicon plasmids. Its general organization resembles that of several replicons that control their copy number by an iteron mechanism. The RepHI1B replicon (2.4 kb) contains: (i) an 882 bp repA gene coding for a 32 kDa replication protein (RepA), sharing significant similarity with the initiator proteins of other replicons belonging to various incompatibility (Inc) groups, including P1 (IncY), Rts1 (IncT), RepFIB (IncFI), and RepHI1A (IncHI1); (ii) two sets of 17 bp DNA repeats (iterons), one upstream and one downstream from repA. By complementation testing, we identified the replication origin (ori) of RepHI1B in a 223 bp locus upstream from repA. By primer extension we mapped two promoters of repA (Pr1 and Pr2) in the ori sequence. We used repA::lacZ transcriptional fusions to study regulation of the repA gene. This analysis showed that repA is transcriptionally autoregulated. Gel mobility shift assays demonstrated that RepA binds specifically to the origin and to iterons overlapping the Pr1 and Pr2 promoters. A G to A transition at nucleotide position 13 of the iteron located in Pr2 (repeat 5) drastically decreases autoregulation of repA by inhibiting binding of RepA.

Isolation and location on the R27 map of two replicons and an incompatibility determinant specific for IncHI1 plasmids.

Two replicons were isolated independently from different IncHI1 plasmids. One was isolated from R27, and a second was isolated from pIP522. We demonstrate, by DNA-DNA hybridization experiments, that these maintenance regions are different and that they are specific to, and carried by, all IncHI1 plasmids tested. In view of this specificity we decided to designate the replicon isolated from R27 as RepHI1A and the replicon isolated from pIP522 as RepHI1B. These two autoreplicative regions are not related to a third replicon present in all IncHI1 plasmids that bears homology with RepFIA and that expresses the characteristic incompatibility of IncHI1 subgroup plasmids toward F factor (D. Saul, D. Lane, and P. L. Bergquist, Mol. Microbiol. 2:219-225, 1988; D. E. Taylor, R. W. Hedges, and P. L. Bergquist, J. Gen. Microbiol. 131:1523-1530, 1985). These results demonstrate that all IncHI1 plasmids tested contain at least three replicons. An incompatibility (Inc) region that hybridizes specifically to all the IncHI1 plasmids was previously isolated (M. Couturier, F. Bex, P. L. Bergquist, and W. K. Maas, Microbiol. Rev. 52:375-395, 1988). Although this Inc locus is not located in an autoreplicative region of IncHI1 plasmids, we observed that this locus stabilizes a low-copy-number replicon. This Inc locus is probably a component of an active partition locus involved in the maintenance of IncHI1 plasmids. The nucleotide sequence of the Inc region contains direct repeats of 31 bp. In addition, this incompatibility determinant hybridizes specifically with IncHI1 plasmids but expresses incompatibility toward plasmids of both IncHI subgroups (IncHI1 and IncHI2). In this communication, we present the mapping of these maintenance elements on the R27 genome.

Molecular analysis of the replication elements of the broad-host-range RepA/C replicon.

RepA/C is a replicon specific to the IncA/C incompatibility group of plasmids and was isolated recently from plasmid RA1. The sequence of this autoreplicative region was established; it contains 13 repeats, suggesting that the replicon uses iterons to control its copy number. The sequence contains two ORFs, one potentially coding for a 33-kDa protein (ORF1) and a second potentially coding for a 14-kDa protein (ORF2) (Llanes et al., 1994b). In this work, using an in vitro transcription/translation system, we detected a polypeptide whose size corresponded well to that of the deduced product of ORF1. Deletion and insertion mutation analysis showed that ORF1 is essential for replication; it encodes an initiator protein (called RepA). ORF2 was not essential for replication in Escherichia coli and its function remains to be determined. Using complementation experiments, the replication origin (ori) of RepA/C was defined. The ori was located in a 600-bp fragment downstream from repA, containing 10 direct repeats. To study the control of repA expression, a transcriptional fusion PrepA::lacZ was constructed. Its analysis showed that repA is transcriptionally autoregulated as are most repA genes of replicons controlled by iterons.

Identification of KLF13 and KLF14 (SP6), novel members of the SP/XKLF transcription factor family.

Using the sequence of the SP1 zinc-finger DNA-binding domain as a probe to screen a mouse EST database, we identified two novel members of the SP/XKLF transcription factor family, KLF13 and KLF14. The mouse Klf13 cDNA (1310 bp in length) contains a single open reading frame of 288 amino acids with a DNA-binding domain closely related to that of the human RFLAT-1 protein and a putative transactivator N-terminal domain rich in proline and alanine residues. The mouse Klf13 gene seems to be the homologue of the human RFLAT1 gene. The mouse Klf14 sequence is homologous to a human genomic sequence from chromosome 17 that is believed to code for a protein with three zinc fingers at the end of its C-terminal domain. Using reverse transcription-polymerase chain reaction, we showed ubiquitous expression of Klf13 and Klf14 in adult mice. A third member of this family was also identified in a human EST database; this sequence was found to be identical to KLF11 (TIEG2), recently identified by Cook et al. (1998, J. Biol. Chem. 273: 25929-25936). The corresponding mouse cDNA was isolated and sequenced. The three genes were localized in the human and the rat: chromosomes 15 (human KLF13), 17q21.3-q22 (human KLF14; HGMW-approved symbol SP6), and 2p25 (human KLF11) and chromosomes 1q31-q32 (rat Klf13), 10q31-q32.1 (rat Klf14) (SP6), and 6q16-q21 (rat Klf11).

Rat Chromosome 2: assignment of the genes encoding cyclin B1, interleukin 6 signal transducer, and proprotein convertase 1 to the Mcs1-containing region and identification of new microsatellite markers.

The rat Chromosome (Chr) 2 harbors several genes controlling tumor growth or development, blood pressure, and non-insulin-dependent diabetes mellitus. We report that the region (2q1) containing the mammary susceptibility cancer gene Mcs1 also harbors the genes encoding cyclin B1, interleukin 6 signal transducer (gp130), and proprotein convertase 1. We also generated 13 new anonymous microsatellite markers from Chr 2-sorted DNA. These markers, as well as a microsatellite marker in the cyclin B1 gene, were genetically mapped in combination with known markers. A cyclin B1-related gene was also cytogenetically assigned to rat Chr 11q22-q23.