The Drosophila P-element KP repressor protein dimerizes and interacts with multiple sites on P-element DNA.

Drosophila P elements are mobile DNA elements that encode an 87-kDa transposase enzyme and transpositional repressor proteins. One of these repressor proteins is the 207-amino-acid KP protein which is encoded by a naturally occurring P element with an internal deletion. To study the molecular mechanisms by which KP represses transposition, the protein was expressed, purified, and characterized. We show that the KP protein binds to multiple sites on the ends of P-element DNA, unlike the full-length transposase protein. These sites include the high-affinity transposase binding site, an 11-bp transpositional enhancer, and, at the highest concentrations tested, the terminal 31-hp inverted repeats. The DNA binding domain was localized to the N-terminal 98 amino acids and contains a CCHC sequence, a potential metal binding motif. We also demonstrate that the KP repressor protein can dimerize and contains two protein-protein interaction regions and that this dimerization is essential for high-affinity DNA binding.     

Regulation of P-element transposase activity in Drosophila melanogaster by hobo transgenes that contain KP elements

Fusions between the Drosophila hsp70 promoter and three different incomplete P elements, KP, SP, and BP1, were inserted into the Drosophila genome by means of hobo transformation vectors and the resulting transgenic stocks were tested for repression of P-element transposase activity. Only the H(hsp/KP) transgenes repressed transposase activity, and the degree of repression was comparable to that of a naturally occurring KP element. The KP transgenes repressed transposase activity both with and without heat-shock treatments. Both the KP element and H(hsp/KP) transgenes repressed the transposase activity encoded by the modified P element in the P(ry(+), Delta2-3)99B transgene more effectively than that encoded by the complete P element in the H(hsp/CP)2 transgene even though the P(ry(+), Delta2-3)99B transgene was the stronger transposase source. Repression of both transposase sources appeared to be due to a zygotic effect of the KP element or transgene. There was no evidence for repression by a strictly maternal effect; nor was there any evidence for enhancement of KP repression by the joint maternal transmission of H(hsp/KP) and H(hsp/CP) transgenes. These results are consistent with the idea that KP-mediated repression of P-element activity involves a KP-repressor polypeptide that is not maternally transmitted and that KP-mediated repression is not strengthened by the 66-kD repressor produced by complete P elements through alternate splicing of their RNA.     

Three-partner conversion induced by the P-element transposase in Drosophila melanogaster

Conversion of one P-derived transposon into another has already been shown to occur with a measurable frequency. However, the mechanism responsible for such replacements has remained controversial. We previously proposed a mechanism involving three partners. We assumed that after excision of the P-element inserted at the target site, the double-strand break was repaired using, first, the homologous P sequences on the sister chromatid, and second, a remote template, the donor P-derived transposon. However, two other mechanisms have been proposed. The first involves two partners only, the broken end and the remote template, while the second involves transposition of the donor into the target P-element, followed by a double recombination event. Here we describe the conversion of a defective P-element using as a remote template an enhancer-trap element that is itself unable to transpose because it lacks 21 bp at its 5' end. This result makes it possible to exclude the possibility that this conversion event occurred after transposition. The new allele was molecularly and genetically characterized. The occurrence of a polymorphism at position 33 of the P-element sequence and of an imperfect copy of the template on the 3' side of the converted transposon confirmed that the sister chromatid was absolutely necessary as a partner for repair. Our results show that targeting of a marked P-element is possible, even when this element is unable to transpose. This provides a means of improving recovery of conversion events by eliminating unwanted transpositions catalyzed by the P transposase.     

Bound Lac repressor protein differentially inhibits the unwinding reactions catalyzed by DNA helicases.

A partial duplex DNA substrate containing the Lac repressor binding site, within the duplex region, was constructed to examine the effect of bound Lac repressor on the unwinding reaction catalyzed by several DNA helicases. The substrate contained 90 base pairs of double-stranded DNA and, in the absence of Lac repressor, was effectively unwound by each of the seven helicases tested. The unwinding reactions catalyzed by Escherichia coli Rep protein, bacteriophage T4 Dda protein and E. coli DNA helicase I were not inhibited by the presence of bound Lac repressor. Both SV40 T antigen and E. coli helicase II were partially inhibited by bound repressor at the highest repressor concentrations tested. The helicase reactions catalyzed by E. coli DnaB protein and helicase IV were substantially inhibited by the presence of bound protein. When the length of the duplex region was increased to 323 base pairs the inhibition spectrum caused by bound Lac repressor on the unwinding reactions catalyzed by DnaB protein, helicase I and helicase II was essentially the same as that observed using the shorter partial duplex molecule. Inhibition of the unwinding reaction was due to the presence of bound Lac repressor as evidenced by the substantially weaker inhibition of helicase IV by Lac repressor in the presence of IPTG. In addition, we have shown that Rep protein displaces the bound repressor protein during the course of an unwinding reaction.     

A hobo transgene that encodes the P-element transposase in Drosophila melanogaster: autoregulation and cytotype control of transposase activity

Drosophila were genetically transformed with a hobo transgene that contains a terminally truncated but otherwise complete P element fused to the promoter from the Drosophila hsp70 gene. Insertions of this H(hsp/CP) transgene on either of the major autosomes produced the P transposase in both the male and female germlines, but not in the soma. Heat-shock treatments significantly increased transposase activity in the female germline; in the male germline, these treatments had little effect. The transposase activity of two insertions of the H(hsp/CP) transgene was not significantly greater than their separate activities, and one insertion of this transgene reduced the transposase activity of P(ry(+), Delta2-3)99B, a stable P transgene, in the germline as well as in the soma. These observations suggest that, through alternate splicing, the H(hsp/CP) transgene produces a repressor that feeds back negatively to regulate transposase expression or function in both the somatic and germline tissues. The H(hsp/CP) transgenes are able to induce gonadal dysgenesis when the transposase they encode has P-element targets to attack. However, this ability and the ability to induce P-element excisions are repressed by the P cytotype, a chromosomal/cytoplasmic state that regulates P elements in the germline.     

Lac repressor purification without inactivation of DNA binding activity.

A procedure has been developed which eliminates the commonly observed inactivation of the DNA binding activity of the lac repressor during purification. The operator binding activity of the repressor obtained by this method is 100 +/- 10%. The repressor can be stored frozen indefinitely without losing its affinity for DNA.     

Adenovirus-specific DNA-binding protein inhibits the hydrolysis of DNA by DNase in vitro.

The adenovirus-specific DNA-binding protein was isolated from adenovirus type 5-infected KB cells and shown to possess DNase inhibitor activity. The protein decreased the rate of hydrolysis of single-strand DNA proportionately to its concentration in the reaction. Two peaks of activity were obtained upon sedimentation in a glycerol gradient, probably corresponding to the two major adenovirus-specific polypeptides in the preparation (molecular weights, 72,000 and 44,000). The DNase inhibitor activity of the adenovirus DNA-binding protein was distinguishable from that of the cellular DNA-binding protein, which we have described previously (K, Nass and G. D. Frenkel, J. Biol. Chem. 254:3407-3410, 1979), by its pattern of sedimentation and by the effect of temperature on the two activities. For the adenovirus DNA-binding protein, the ratio of DNase inhibitor activity at 43 degrees C to that at 30 degrees C was approximately 14, whereas for the cellular protein this ratio was less than 3. The DNase inhibitor activity with the temperature coefficient of 14 was absent from cells infected with adenovirus type 5 ts125 at 40 degrees C. DNase inhibition is a simple, sensitive, quantitative method for assay of the adenovirus DNA-binding protein.     

DNA binding protein dbpA binds Cdk5 and inhibits its activity

Progress in the cell cycle is governed by the activity of cyclin dependent kinases (Cdks). Unlike other Cdks, the Cdk5 catalytic subunit is found mostly in differentiated neurons. Interestingly, the only known protein that activates Cdk5 (i.e. p35) is expressed solely in the brain. It has been suggested that, besides its requirement in neuronal differentiation, Cdk5 activity is induced during myogenesis. However, it is not clear how this activity is regulated in the pathway that leads proliferative cells to differentiation. In order to find if there exists any Cdk5-interacting protein, the yeast two-hybrid system was used to screen a HeLa cDNA library. We have determined that a C-terminal 172 amino acid domain of the DNA binding protein, dbpA, binds to Cdk5. Biochemical analyses reveal that this fragment (dbpA(Cdelta)) strongly inhibits p35-activated Cdk5 kinase. The protein also interacts with Cdk4 and inhibits the Cdk4/cyclin D1 enzyme. Surprisingly, dbpA(Cdelta) does not bind Cdk2 in the two-hybrid assay nor does it inhibit Cdk2 activated by cyclin A. It could be that dbpA's ability to inhibit Cdk5 and Cdk4 reflects an apparent cross-talk between distinct signal transduction pathways controlled by dbpA on the one hand and Cdk5 or Cdk4 on the other.     

Glycine insertion in the hinge region of lactose repressor protein alters DNA binding.

Amino acid alterations were designed at the C terminus of the hinge segment (amino acids approximately 51-59) that links two functional domains within lactose repressor protein (LacI). Gly was introduced between Gly(58) and Lys(59) to generate Gly(58+1); Gln(60) was changed to Gly or Pro, and up to three additional glycines were inserted following Gln(60) --> Gly. All mutant proteins exhibited purification behavior, CD spectra, assembly state, and inducer binding properties similar to wild-type LacI and only small differences in trypsin proteolysis patterns. In contrast, significant differences were observed in DNA binding properties. Gly(58+1) exhibited a decrease of approximately 100-fold in affinity for O(1) operator, and sequential Gly insertion C-terminal to Gln(60) --> Gly resulted in progressively decreased affinity for O(1) operator, approaching nonspecific levels for insertion of >/=2 glycines. Where sufficient affinity for O(1) operator existed, decreased binding to O(1) in the presence of inducer indicated no disruption in the allosteric response for these proteins. Collectively, these results indicate that flexibility and/or spacing between the core and N-terminal domains did not significantly affect folding or assembly, but these alterations in the hinge domain profoundly altered affinity of the lactose repressor protein for its wild-type target sequence.     

Biochemical characterization of a SET and transposase fusion protein, Metnase: its DNA binding and DNA cleavage activity

Metnase (SETMAR) is a SET and transposase fusion protein that promotes in vivo end joining activity and mediates genomic integration of foreign DNA. Recent studies showed that Metnase retained most of the transposase activities, including 5'-terminal inverted repeat (TIR)-specific binding and assembly of a paired end complex, and cleavage of the 5'-end of the TIR element. Here we show that R432 within the helix-turn-helix motif is critical for sequence-specific recognition, as the R432A mutation abolishes its TIR-specific DNA binding activity. Metnase possesses a unique DNA nicking and/or endonuclease activity that mediates cleavage of duplex DNA in the absence of the TIR sequence. While the HTH motif is essential for the Metnase-TIR interaction, it is not required for its DNA cleavage activity. The DDE-like motif is crucial for its DNA cleavage action as a point mutation at this motif (D483A) abolished its DNA cleavage activity. Together, our results suggest that Metnase's DNA cleavage activity, unlike those of other eukaryotic transposases, is not coupled to its sequence-specific DNA binding.     

DNA binding activities of the Caenorhabditis elegans Tc3 transposase.

Tc3 is a member of the Tc1/mariner family of transposable elements. All these elements have terminal inverted repeats, encode related transposases and insert exclusively into TA dinucleotides. We have studied the DNA binding properties of Tc3 transposase and found that an N-terminal domain of 65 amino acids binds specifically to two regions within the 462 bp Tc3 inverted repeat; one region is located at the end of the inverted repeat, the other is located approximately 180 bp from the end. Methylation interference experiments indicate that this N-terminal DNA binding domain of the Tc3 transposase interacts with nucleotides on one face of the DNA helix over adjacent major and minor grooves.     

a1 protein alters the DNA binding specificity of alpha 2 repressor

The alpha 2 protein of S. cerevisiae, the product of the MAT alpha 2 gene, represses a set of cell-type-specific genes (the a-specific genes) by binding to an operator sequence upstream of each gene. We demonstrate that a second yeast regulatory protein, a1, the product of the MATa1 gene, can alter the binding specificity of alpha 2 so that it no longer recognizes the a-specific gene operator, but instead acquires the ability to recognize a different operator sequence found upstream of haploid-specific genes. Thus, under the influence of a1, alpha 2 can repress haploid-specific genes. An alpha cell expresses alpha 2 but not a1, so that alpha 2 turns off only the a-specific genes. An a/alpha cell makes both a1 and alpha 2, in a ratio that ensures that alpha 2 is distributed between two distinct binding modes: the alpha 2 binding mode and the a1-alpha 2 binding mode. Thus in an a/alpha cell, alpha 2 represses two distinct classes of genes.     

A deoxyribonucleic acid binding protein from KB cells which inhibits deoxyribonuclease activity on single-stranded DNA.

A deoxyribonuclease inhibitor has been purified from KB cells by chromatography on single-stranded DNA-cellulose. Polyacrylamide gel electrophoresis showed the purified preparation to contain two major polypeptides in sodium dodecyl sulfate, with molecular weights of 72,000 and 65,000, but only one major band (with a molecular weight of approximately 140,000) after electrophoresis under nondenaturing conditions. The protein inhibits the hydrolysis of single-stranded DNA by KB DNase, DNase I, DNase II, and nuclease S1, but has no effect on the hydrolysis of double-stranded DNA by these enzymes. The inhibitor causes a reduction in the rate of hydrolysis of DNA by the deoxyribonuclease, probably by reducing the effective concentration of substrate.     

A sequence-specific single-strand DNA binding protein that contacts repressor sequences in the human GM-CSF promoter.

NF-GMb is a nuclear factor that binds to the proximal promoter of the human granulocyte-macrophage colony stimulating factor (GM-CSF) gene. NF-GMb has a subunit molecular weight of 22 kDa, is constitutively expressed in embryonic fibroblasts and binds to sequences within the adjacent CK-1 and CK-2 elements (CK-1/CK-2 region), located at approximately -100 in the GM-CSF gene promoter. These elements are conserved in haemopoietic growth factor (HGF) genes. NF-GMb binding requires the presence of repeated 5'CAGG3' sequences that overlap the binding sites for positive activators. Surprisingly, NF-GMb was found to bind solely to single-strand DNA, namely the non-coding strand of the GM-CSF CK-1/CK-2 region. NF-GMb may belong to a family of single-strand DNA binding (ssdb) proteins that have 5'CAGG3' sequences within their binding sites. Functional analysis of the proximal GM-CSF promoter revealed that sequences in the -114 to -79 region of the promoter containing the NF-GMb binding sites had no intrinsic activity in fibroblasts but could, however, repress tumour necrosis factor-alpha (TNF-alpha) inducible expression directed by downstream promoter sequences (-65 to -31). Subsequent mutation analysis showed that sequences involved in repression correlated with those required for NF-GMb binding.     

Cytotype control of Drosophila P element transposition: the 66 kd protein is a repressor of transposase activity

Drosophila P transposable elements encode two proteins, an 87 kd transposase protein and a 66 kd protein that has been hypothesized to repress transposition. We have made germline transformants carrying modified P element derivatives that encode only the 66 kd protein and shown that these elements repress transposase activity in both the germline and the soma. The position of these elements in the genome quantitatively affected their ability to negatively regulate transposase and to express the 66 kd protein. Single 66 kd element-containing strains did not exhibit the maternal inheritance of P cytotype characteristic of P strains. However, we demonstrated that a true P strain produced higher levels of the 66 kd protein during oogenesis than single 66 kd P elements. Thus, the expression of the 66 kd repressor during oogenesis may be a major determinant of the maternal effect of P cytotype.