Correct Hox gene expression established independently of position in Caenorhabditis elegans.

The Hox genes are expressed in a conserved sequence of spatial domains along the anteroposterior (A/P) body axes of many organisms. In Drosophila, position-specific signals located along the A/P axis establish the pattern of Hox gene expression. In the nematode Caenorhabditis elegans, it is not known how the pattern of Hox gene expression is established. C. elegans uses lineal control mechanisms and local cell interactions to specify early blastomere identities. However, many cells expressing the same Hox gene are unrelated by lineage, suggesting that, as in Drosophila, domains of Hox gene expression may be defined by cell-extrinsic A/P positional signals. To test this, we have investigated whether posterior mesodermal and ectodermal cells will express their normal posterior Hox gene when they are mispositioned in the anterior. Surprisingly, we find that correct Hox gene expression does not depend on cell position, but is highly correlated with cell lineage. Thus, although the most striking feature of Hox gene expression is its positional specificity, in C. elegans the pattern is achieved, at least in part, by a lineage-specific control system that operates without regard to A/P position.

Expression of the homeotic gene mab-5 during Caenorhabditis elegans embryogenesis.

mab-5 is a member of a complex of homeobox-containing genes evolutionarily related to the Antennapedia and bithorax complexes of Drosophila melanogaster. Like the homeotic genes in Drosophila, mab-5 is required in a particular region along the anterior-posterior body axis, and acts during postembryonic development to give cells in this region their characteristic identities. We have used a mab-5-lacZ fusion integrated into the C. elegans genome to study the posterior-specific expression of mab-5 during embryogenesis. The mab-5-lacZ fusion was expressed in the posterior of the embryo by 180 minutes after the first cleavage, indicating that the mechanisms responsible for the position-specific expression of mab-5-lacZ act at a relatively early stage of embryogenesis. In embryos homozygous for mutations in the par genes, which disrupt segregation of factors during early cleavages, expression of mab-5-lacZ was no longer localized to the posterior. This suggests that posterior-specific expression of mab-5 depends on the appropriate segregation of developmental factors during early embryogenesis. After extrusion of any blastomere of the four-cell embryo, descendants of the remaining three cells could still express the mab-5-lacZ fusion. In these partial embryos, however, the fusion was often expressed in cells scattered throughout the embryo, suggesting that cell-cell interactions and/or proper positioning of early blastomeres are required for mab-5 expression to be localized to the posterior.

Development of RNA polymerase-promoter contacts during open complex formation.

We have charted the movements of E sigma 32 RNA polymerase at the heat-shock promoter PgroE throughout open complex formation, using hydroxyl radical footprinting. In combination with methylation protection and DNase I experiments, these data suggest the following model for open complex formation. E sigma 32 initially anchors itself in the upstream region of the promoter forming the first closed complex, RPC1; in this complex the enzyme makes backbone contacts in the -35 region of the promoter that are maintained throughout open complex formation. An isomerization follows resulting in a second closed complex, RPC2; in this complex the enzyme makes base-specific and backbone contacts in the -10 region that are almost identical to those found in the open complex. Thus, at the groE promoter, upstream contacts are established in RPC1 and downstream contacts in RPC2. A similar pattern of backbone contacts was obtained for E sigma 32 bound in the open complex at two additional heat-shock promoters, suggesting that the overall topology of holoenzyme in the open complex is similar regardless of sequence variations in the promoter.

Interaction of Escherichia coli RNA polymerase holoenzyme containing sigma 32 with heat shock promoters. DNase I footprinting and methylation protection.

The DNase I protection pattern of E sigma 32 was assayed on three heat shock promoters, the E sigma 32 promoter for the groESL operon, P2 of the dnaKJ operon, and rpoD PHS, the E sigma 32 promoter upstream from rpoD. E sigma 32 protected each of these promoters from DNase I digestion from around -60 to around +20. Protection from dimethyl sulfate methylation was assayed at the groE promoter. E sigma 32 binding altered the sensitivity to methylation of bases in the vicinity of both the -10 and -35 regions. The DNase I footprints for the E sigma 32 promoters were very similar to the DNase I footprint of E sigma 70 on the lacUV5 promoter. After analyzing the DNase I footprints by taking into account the contacts predicted to be made by DNase I, it appeared that E sigma 32, like E sigma 70, contacts the DNA primarily on one face of the helix in the -35 region and on both faces in the -10 region.

Intermediates in the formation of the open complex by RNA polymerase holoenzyme containing the sigma factor sigma 32 at the groE promoter.

The interaction of E sigma 32 with the groE promoter at temperatures between 0 degrees C and 37 degrees C was studied using DNase I footprinting and dimethyl sulfate methylation. Three distinct complexes were observed. At 0 degrees C E sigma 32 fully protected sequences between -60 and -5 from DNase I digestion on the top (non-template) strand of the promoter. At 16 degrees C the majority of the E sigma 32 promoter complexes had a DNase I footprint almost identical with that seen at 37 degrees C, protecting the DNA from about -60 to +20; however, little DNA strand separation had occurred, and the changes in sensitivity of guanine residues to dimethyl sulfate methylation caused by E sigma 32 differed from those seen at 37 degrees C. DNA strand separation, and changes in the pattern of protections from and enhancements of methylation by dimethyl sulfate to those characteristic of the open complex, occurred at temperatures between 16 degrees C and 27 degrees C. It is plausible to assume that these temperature-dependent isomerizations are analogous to the time-dependent sequence of intermediates on the pathway to open complex formation at 37 degrees C. Therefore we propose that the formation of an open complex by E sigma 32 at the groE promoter involves three classes of steps: E sigma 32 initially binds to the promoter in a closed complex (RPC1) in which the enzyme interacts with a smaller region of the DNA than in the open complex. E sigma 32 then isomerizes to form a second closed complex (RPC2) in which the enzyme interacts with the same region of the DNA as in the open complex. Finally, a process of local DNA denaturation (strand opening) leads to formation of the open complex (RPO).

Consensus sequence for Escherichia coli heat shock gene promoters.

We have identified promoters for the Escherichia coli heat shock operons dnaK and groE and the gene encoding heat shock protein C62.5. Transcription from each promoter is heat-inducible in vivo, and each is recognized in vitro by RNA polymerase containing sigma 32, the sigma factor encoded by rpoH (htpR) but not by RNA polymerase containing sigma 70. We compared the sequences of the heat shock promoters and propose a consensus promoter sequence, having T-N-t-C-N-C-c-C-T-T-G-A-A in the -35 region and C-C-C-C-A-T-t-T-a in the -10 region. These sequences differ from the consensus sequence recognized by holoenzyme containing sigma 70, the major sigma in E. coli. We suggest that the accumulated consensus sequences of promoters recognized by alternate forms of holoenzyme are compatible with a model in which sigma recognizes only the -10 region of the promoter.

DNA methylation affecting the expression of murine leukemia proviruses.

The endogenous, vertically transmitted proviral DNAs of the ecotropic murine leukemia virus in AKR embryo fibroblasts were found to be hypermethylated relative to exogenous AKR murine leukemia virus proviral DNAs acquired by infection of the same cells. The hypermethylated state of the endogenous AKR murine leukemia virus proviruses in these cells correlated with the failure to express AKR murine leukemia virus and the lack of infectivity of cellular DNA. Induction of the endogenous AKR murine leukemia virus proviruses with the methylation antagonist 5-azacytidine suggested a causal connection between DNA methylation and provirus expression. Also found to be relatively hypermethylated and noninfectious were three of six Moloney murine leukemia virus proviral DNAs in an unusual clone of infected rat cells. Recombinant DNA clones which derived from a methylated, noninfectious Moloney provirus of this cell line were found to be highly active upon transfection, suggesting that a potentially active proviral genome can be rendered inactive by cellular DNA methylation. In contrast, in vitro methylation with the bacterial methylases MHpaII and MHhaI only slightly reduced the infectivity of the biologically active cloned proviral DNA. Recombinant DNA clones which derived from a second Moloney provirus of this cell line were noninfectious. An in vitro recombination method was utilized in mapping studies to show that this lack of infectivity was governed by mechanisms other than methylation.

Most of the murine leukemia virus sequences in the DNA of NIH/swiss mice consist of two closely related proviruses, each repeated several times.

The structure of the endogenous murine leukemia virus (MuLV) sequences of NIH/Swiss mice was analyzed by restriction endonuclease digestion, gel electrophoresis, and hybridization to an MuLV nucleic acid probe. Digestion of mouse DNA with certain restriction endonucleases revealed two classes of fragments. A large number of fragments (about 30) were present at a relatively low concentration, indicating that each derived from a sequence present once in the mouse genome. A smaller number of fragments (one to five) were present at a much higher concentration and must have resulted from sequences present multiple times in the mouse genome. These results indicated that the endogenous MuLV sequences represent a family of dispersed repetitive sequences. Hybridization of these same digested mouse DNAs to nucleic acid probes representing different portions of the MuLV genome allowed construction of a map of the sites where restriction endonucleases cleave the endogenous MuLV sequences. Several independent recombinant DNA clones of endogenous MuLV sequences have been isolated from C3H mice (Roblin et al., J. Virol. 43:113-126, 1982). Analysis of these sequences shows that they have the structure of MuLV proviruses. The sites at which restriction endonucleases cleave within these proviruses appeared to be similar or identical to the sites at which these nucleases cleaved within the MuLV sequences of NIH/Swiss mice. This identity was confirmed by parallel electrophoresis. We conclude that the apparently complex pattern of endogenous MuLV sequences of NIH/Swiss mice consists largely of only two kinds of provirus, each repeated multiple times at dispersed sites in the mouse genome.

Identification of a phosphoprotein specifically induced by the transforming DNA of rat neuroblastomas.

DNAs from nitrosoethylurea-induced rat neuroblastomas transform NIH/3T3 mouse fibroblasts in a transfection assay. DNAs of such transformed cells can be used in a subsequent cycle of transfection to generate secondary foci that contain virtually no foreign genetic material besides the sequences carrying the rat neuroblastoma transforming function. These secondary neuroblastoma transfectants were injected into young mice and grew out into fibrosarcomas. Sera from these mice were examined for reactivity with any proteins which were induced specifically by the neuroblastoma transforming sequence. These sera precipitate a polypeptide of about 185,000 daltons from 35S-methionine-labeled cell lysates of the rat neuroblastoma cells that served as DNA donors and in all transfection-derived primary and secondary foci. This protein is present in high levels in all neuroblastoma transfectant clones, but was not detectable in a variety of other transformed cells. Antisera were prepared from mice bearing tumors induced by transformed cells derived by transfection of DNAs from various tumor cell types unrelated to rat neuroblastoma. These antisera failed to immunoprecipitate the 185,000 dalton protein. These data indicate that the synthesis of the 185,000 dalton protein is specifically induced by the neuroblastoma transforming sequence. The protein may be encoded by the transforming sequence and may mediate transformation in this chemically induced tumor.

Three different human tumor cell lines contain different oncogenes.

We have obtained foci of transformed mouse cells after transfection of human DNA from colon and bladder carcinoma cell lines and a promyelocytic leukemia cell line. These foci can be shown to contain a large number of human DNA sequences by use of highly repetitive human DNA sequence probes. Cell DNA from primary foci can be used in a subsequent cycle of transfection resulting in secondary foci that contain relatively little human DNA. Secondary foci appear to contain only the human sequences proximal to those responsible for the transformed phenotype. A set of characteristic DNA restriction fragments is found in common among secondary foci derived from each tumor cell line DNA. Comparison of the common DNA fragments found in secondary foci derived from three different human tumor cell lines indicates that these three cell lines contain three different transforming genes.