Bacteriophage P1 Bof protein is an indirect positive effector of transcription of the phage bac-1 ban gene in some circumstances and a direct negative effector in other circumstances

Previous genetic studies have suggested that the Bof protein of bacteriophage P1 can act as both a negative and a positive regulator of phage gene expression: in bof-1 prophages, the ref gene and a putative phage ssb gene are derepressed, but expression of an operator-semiconstitutive variant of the phage ban gene (bac-1) is markedly reduced. An explanation of this apparent duality is suggested by recent reports that Bof is a corepressor of genes that are regulated by the phage C1 repressor, including the autoregulated c1 gene itself. Here we show, by means of operon fusions to lacZ, that the balance points between Bof-mediated decreases in c1 expression and Bof-mediated increases in C1 efficacy are different among various C1-regulated genes. Thus, expression of Bof by P1 prophages affects some genes (e.g., bac-1 ban) positively, and others (e.g., ref) negatively. Even at bac-1 ban, where the positive indirect effect of Bof is physiologically dominant, Bof can be seen to act as a corepressor if C1 is supplied from a nonautoregulated (ptac-c1) source, eliminating the effect of Bof on C1 synthesis.     

The Bof protein of bacteriophage P1 exerts its modulating function by formation of a ternary complex with operator DNA and C1 repressor.

Bacteriophage P1 encodes several regulatory elements for the lytic or lysogenic response, which are located in the immC, immI, and immT regions. Their products are the C1 repressor of lytic functions with the C1 inactivator protein Coi, the C4 repressor of antirepressor synthesis and the modulator protein Bof, respectively. We have studied in vitro the interaction of the components of the immC and immT regions with C1-controlled operators using highly purified Bof, C1, and Coi proteins. Bof protein (M(r) = 9,800) does not interact with C1 repressor alone, but as shown by DNA mobility shift experiments, in the presence of C1 repressor Bof binds to all operators tested by forming a C1.Bof-operator DNA ternary complex. The effect of this complex formation was studied in more detail with the operator of the c1 gene. Here, Bof only marginally alters the C1 repressor footprint at Op99a,b, but nevertheless considerably influences the repressibility of the operator.promoter element: (i) the autoregulated c1 mRNA synthesis is further down-regulated and (ii) the ability of Coi protein to dissociate the C1.operator DNA complex is strongly inhibited. We suggest that Bof protein functions by modulating C1 repression of many widely dispersed operators on the prophage genome.     

The P gene of human parainfluenza virus type 1 encodes P and C proteins but not a cysteine-rich V protein.

The nucleotide sequence of the P gene of human parainfluenza virus type 1 (PIV1) was determined from cloned cDNA copies of the mRNA. By analogy with the gene organization of Sendai virus, two open reading frames in the mRNA sense of the gene were identified as coding sequences for the P protein (568 amino acids with an estimated molecular weight of 64,655) and the C protein (204 amino acids with an estimated molecular weight of 24,108). Comparison of the deduced amino acid sequences of the P and C proteins of PIV1 with those of Sendai virus showed a high degree of homology. However, a sequence for the cysteine-rich V protein, which was considered a common feature of other paramyxoviruses, was interrupted by the presence of multiple stop codons. The sequence analysis of three P-gene-specific cDNA clones generated from genomic RNA by polymerase chain reaction and one additional clone generated from mRNA confirmed that the coding sequence for the cysteine-rich region is silent in the PIV1 gene and thus is not translated into protein. Two potential editing sites with the consensus sequence 3'UUYUCCC were found in the PIV1 P gene at positions 564 to 570 and 1430 to 1436. However, examination of the PIV1 mRNA population by a primer extension method indicated that neither of these sites is utilized. These results indicate that the PIV1 P gene has a coding strategy different from those of other paramyxovirus P genes.     

Down-regulation of vimentin gene expression during myogenesis is controlled by a 5'-flanking sequence

During myogenesis, the intermediate filament proteins vimentin and desmin are differentially expressed. While desmin levels increase dramatically, vimentin mRNA levels decrease substantially. Here, we show that transfected whole- and mini-vimentin-coding genes (Vim) are expressed in fibroblasts (mouse L cells) and down-regulated during muscle cell differentiation in culture. Functional assays with 5'-end Vim::cat constructs demonstrate that this repression is controlled by a 5'-element (nt -321 to -160). This region is distinct from Vim promoter elements (nt -160 to +71) which do not contribute to vimentin's down-regulation during myogenesis.     

Nucleotide sequence of a type II DNA topoisomerase gene. Bacteriophage T4 gene 39.

T4 DNA topoisomerase is a type II enzyme and is thought to be required for normal T4 DNA replication T4 gene 39 codes for the largest of the three subunits of T4 DNA topoisomerase. I have determined the nucleotide sequence of a region of 2568 nucleotides of T4 DNA which includes gene 39. The location of the gene was established by the identification of the first fifteen amino acids in the large open reading frame in the DNA sequence as those found at the amino-terminus of the purified 39-protein. The coding region of gene 39 has 1560 bases, and it is followed by two in-frame stop codons. The gene is preceded by a typical Shine-Dalgarno sequence as well as possible promoter sequences for E. coli RNA polymerase. T4 39-protein consists of 520 amino acids, and it has a calculated molecular weight of 58,478. By comparing the amino acid sequences, T4 39-protein is found to share homology with the gyrB subunit of DNA gyrase. This suggests that these topoisomerase subunits may be equivalent functionally. Some of the characteristics of the 39-protein and its structural features predicted from the DNA sequence data are discussed.     

The nfkb1 promoter is controlled by proteins of the Ets family.

The gene encoding NFKB1 is autoregulated, responding to NF-kappa B/Rel activation through NF-kappa B binding sites in its promoter, which also contains putative sites for Ets proteins. One of the Ets sites, which we refer to as EBS4, is located next to an NF-kappa B/Rel binding site, kB3, which is absolutely required for activity of the promoter in Jurkat T cells in response to activation by phorbol 12-myristate 13-acetate (PMA), PMA/ionomycin, or the Tax protein from human T cell leukemia virus type I. We show that EBS4 is, required for the full response of the nfkb1 promoter to PMA or PMA/ionomycin in Jurkat cells. EBS4 is bound by Ets-1, Elf-1, and other species. Overexpression of Ets-1 augments the response to PMA/ionomycin and this is reduced by mutation of EBS4. Elf-1 has less effect in conjunction with PMA/ionomycin, but by itself activates the promoter 12-fold. This activation is only partly affected by mutation of EBS4, and a mutant promoter that binds Ets-1, but not Elf-1, at the EBS4 site responds to PMA/ionomycin as efficiently as the wild-type. Ets proteins may be responsible for fine-tuning the activity of the nfkb1 gene in a cell-type-specific manner.     

C1 inhibitor gene sequence facilitates frameshift mutations.

Mutations disrupting the function or production of C1 inhibitor cause the disease hereditary angioneurotic edema. Patient mutations identified an imperfect inverted repeat sequence that was postulated to play a mechanistic role in the mutations. To test this hypothesis, the inverted repeat was cloned into the chloramphenicol acetyltransferase gene in pBR325 and its mutation rate was studied in four bacterial strains. These strains were selected to assay the effects of recombination and superhelical tension on mutation frequency. Mutations that revert bacteria to chloramphenicol resistance (Cmr) were scored. Both pairs of isogenic strains had reversion frequencies of approximately 10(-8). These rare reversion events in bacteria were most often a frameshift that involved the imperfect inverted repeat with a deletion or a tandem duplication, an event very similar to the human mutations. Increased DNA superhelical tension, which would be expected to enhance cruciform extrusion, did not accentuate mutagenesis. This finding suggests that the imperfect inverted repeat may form a stem-loop structure in the single-stranded DNA created by the duplex DNA melting prior to replication. Models explaining the slippage can be drawn using the lagging strand of the replication fork. In this model, the formation of a stem-loop structure is responsible for bringing the end of the deletion or duplication into close proximity.     

Induction of P1 Prophage and Superinfection by Bacteriophage T1

Induction of the resident prophage did not permit restricted phage T1 to replicate freely in P1-lysogenic hosts. A few induced cells did become infectible.     

C1 repressor of phage P1 is inactivated by noncovalent binding of P1 Coi protein.

The temperate phage P1 encodes two genes whose products antagonize the action of the phage's C1 repressor of lytic functions, namely a distantly linked antirepressor gene, ant, and a closely linked c1 inactivator gene, coi. Starting with an inducible coi-recombinant plasmid, Coi protein was overproduced and purified to near homogeneity. By using a DNA mobility shift assay we demonstrate that Coi protein inhibits the operator binding of the C1 repressors of the closely related P1 and P7 phages. Coi protein (Mr = 7,600) exerts its C1-inactivating function by forming a complex with the C1 repressor (Mr = 32,500) at a molar ratio of about 1:1, as shown by density gradient centrifugation and gel filtration. C1 repressor and Coi protein are recovered in active form from the complex, suggesting that noncovalent interactions are the sole requirements for complex formation. The interplay of repressor and antagonists operating in the life cycle of P1 is discussed.     

Species-specific uptake of DNA by gonococci is mediated by a 10-base-pair sequence.

Piliated Neisseria gonorrhoeae are known to be transformed less readily if transforming DNA competes with DNA containing the 10-bp sequence GCCGTCTGAA. It has been postulated that the 10-bp sequence is a recognition sequence which is required for efficient DNA uptake. We show that the presence of various forms of this 10-bp sequence results in increased uptake of double-stranded DNA into a DNase-resistant state and allows genetic transformation by an otherwise nontransformable plasmid.     

GLH-1, the C. elegans P granule protein, is controlled by the JNK KGB-1 and by the COP9 subunit CSN-5

The GLHs (germline RNA helicases) are constitutive components of the germline-specific P granules in the nematode Caenorhabditis elegans and are essential for fertility, yet how GLH proteins are regulated remains unknown. KGB-1 and CSN-5 are both GLH binding partners, previously identified by two-hybrid interactions. KGB-1 is a MAP kinase in the Jun N-terminal kinase (JNK) subfamily, whereas CSN-5 is a subunit of the COP9 signalosome. Intriguingly, although loss of either KGB-1 or CSN-5 results in sterility, their phenotypes are strikingly different. Whereas csn-5 RNA interference (RNAi) results in under-proliferated germlines, similar to glh-1/glh-4(RNAi), the kgb-1(um3) loss-of-function mutant exhibits germline over-proliferation. When kgb-1(um3) mutants are compared with wild-type C. elegans, GLH-1 protein levels are as much as 6-fold elevated and the organization of GLH-1 in P granules is grossly disrupted. A series of additional in vivo and in vitro tests indicates that KGB-1 and CSN-5 regulate GLH-1 levels, with GLH-1 targeted for proteosomal degradation by KGB-1 and stabilized by CSN-5. We propose the ;good cop: bad cop' team of CSN-5 and KGB-1 imposes a balance on GLH-1 levels, resulting in germline homeostasis. In addition, both KGB-1 and CSN-5 bind Vasa, a Drosophila germ granule component; therefore, similar regulatory mechanisms might be conserved from worms to flies.     

Recruitment of cortexillin into the cleavage furrow is controlled by Rac1 and IQGAP-related proteins.

Cytokinesis in eukaryotic organisms is under the control of small GTP-binding proteins, although the underlying molecular mechanisms are not fully understood. Cortexillins are actin-binding proteins whose activity is crucial for cytokinesis in Dictyostelium. Here we show that the IQGAP-related and Rac1-binding protein DGAP1 specifically interacts with the C-terminal, actin-bundling domain of cortexillin I. Like cortexillin I, DGAP1 is enriched in the cortex of interphase cells and translocates to the cleavage furrow during cytokinesis. The activated form of the small GTPase Rac1A recruits DGAP1 into a quaternary complex with cortexillin I and II. In DGAP1(-) mutants, a complex can still be formed with a second IQGAP-related protein, GAPA. The simultaneous elimination of DGAP1 and GAPA, however, prevents complex formation and localization of the cortexillins to the cleavage furrow. This leads to a severe defect in cytokinesis, which is similar to that found in cortexillin I/II double-null mutants. Our observations define a novel and functionally significant signaling pathway that is required for cytokinesis.