Design of chimaeric polymersomes.

We discuss the development of hierarchical polymer particles, or variegated polymersome composites, in which at least two different components are phase separated within one polymersome chimaera. We briefly discuss the present status in experimental polymersome research, and then discuss a speculative design strategy, based on mesoscopic simulations with a dynamical variant of polymer self-consistent field theory (Mesodyn). The main conclusion is that the counter-intuitive co-assembly of demixing block copolymers is the key in controlling hierarchical structures on a mesoscopic scale. This is the classical paradox of a chimaera: the constituents live in the same scaffold, but apart. Block copolymers beyond a certain length will always split the assembly, and without further precautions, polymer based chimaerae are intrinsically unstable. To this end, we propose the application of a branched block copolymer as composite compatibilizer, glueing the separate domains together, and thereby stabilizing the chimaeric polymersome.

Characterization of the gene encoding quinohaemoprotein ethanol dehydrogenase of Comamonas testosteroni.

The gene encoding quinohaemoprotein ethanol dehydrogenase type I (QH-EDHI) from Comamonas testosteroni has been cloned and sequenced. Comparison of the amino acid sequence deduced from this with that determined for the N-terminal amino acid stretch of purified QH-EDHI, suggests that the gene also contains a leader sequence of 31 residues. Based on this information, the molecular mass of the apo-enzyme, i.e. the enzyme without the cofactors pyrroloquinoline quinone (PQQ) and haem c, and without the Ca2+, appears to be 73 200 Da. Alignment of the deduced amino acid sequence to that of other PQQ-containing dehydrogenases showed that good similarity (up to 43% identity) exists with most of them. This also showed that the amino acid residues presumed to be involved in PQQ and Ca2+ binding and in the typical features of structure and catalysis of methanol dehydrogenase, are conserved at the same positions in QH-EDHI. The C-terminal part of the protein, containing the haem c, exhibited some similarity to cytochromes C553 from cyanobacteria and algae. Correct processing of the qhedh gene appeared to occur in Escherichia coli strain JM 109 in which the gene was placed under control of the lac promoter, as judged from a positive reaction with antibodies raised against authentic QH-EDHI, the size of the protein, the presence of haem c in it, and the specific activity value obtained after reconstitution with PQQ. The qhedh gene seems to form part of an operon which is organized in a way different from that of the genes required for methanol oxidation in methylotrophic bacteria.

Molecular cloning of the gene for the E1 alpha subunit of the pyruvate dehydrogenase complex from Saccharomyces cerevisiae.

The E1 alpha and E1 beta subunits of the pyruvate dehydrogenase complex from the yeast Saccharomyces cerevisiae were purified. Antibodies raised against these subunits were used to clone the corresponding genes from a genomic yeast DNA library in the expression vector lambda gt11. The gene encoding the E1 alpha subunit was unique and localized on a 1.7-kb HindIII fragment from chromosome V. The identify of the gene was confirmed in two ways. (a) Expression of the gene in Escherichia coli produced a protein that reacted with the anti-E1 alpha serum. (b) Gene replacement at the 1.7-kb HindIII fragment abolished both pyruvate dehydrogenase activity and the production of proteins reacting with anti-E1 alpha serum in haploid cells. In addition, the 1.7-kb HindIII fragment hybridized to a set of oligonucleotides derived from amino acid sequences from the N-terminal and central regions of the human E1 alpha peptide. We propose to call the gene encoding the E1 alpha subunit of the yeast pyruvate dehydrogenase complex PDA1. Screening of the lambda gt11 library using the anti-E1 beta serum resulted in the reisolation of the RAP1 gene, which was located on chromosome XIV.

Differential repair of UV damage in Saccharomyces cerevisiae.

Preferential repair of UV-induced damage is a phenomenon by which mammalian cells might enhance their survival. This paper presents the first evidence that preferential repair occurs in the lower eukaryote Saccharomyces cerevisiae. Moreover an unique approach is reported to compare identical sequences present on the same chromosome and only differing in expression. We determined the removal of pyrimidine dimers from two identical alpha-mating type loci and we were able to show that the active MAT alpha locus is repaired preferentially to the inactive HML alpha locus. In a sir-3 mutant, in which both loci are active this preference is not observed.

Regulation of the Escherichia coli excision repair gene uvrC. Overlap between the uvrC structural gene and the region coding for a 24 kD protein.

The UvrA, UvrB and UvrC proteins of E. coli are subunits of a DNA repair enzyme, the ABC exonuclease. In this paper we study the uvrC regulatory region. The uvrC structural gene is preceded by an open reading frame encoding a 24 kD protein. A uvrC promoter has been mapped within this gene. The transcription start of a second promoter located 5' of the 24 kD gene is mapped in vivo. We show that transcription from both promoters on the chromosome is not inducible by UV damage. The possible translation start codons of the UvrC and of the 24 kD protein are determined. Sequences encoding the N-terminal part of the UvrC protein overlap with sequences encoding the C-terminal part of the 24 kD protein. To examine a possible function of the 24 kD gene in repair, a 24 kD insertion mutant was created in the chromosome. The mutant however only slightly affects the UV sensitivity of the cell. Transcription of P3 alone provides sufficient UvrC protein for the normal repair of UV lesions.

Inducible DNA polymerase I synthesis in a UV hyper-resistant mutant of Escherichia coli.

A mutant of Escherichia coli which is more resistant to shortwave UV light than its wild-type parent strain and which can synthesise DNA polymerase I constitutively has been further analysed. It carries two mutational alleles which are located about 1.5 min apart and cotransducible by P1 with the argH locus. The two mutational alleles have been segregated and their analysis shows that one of them is responsible for UV hyper-resistance whereas the other mutation confers UV sensitivity. Recombinant plasmids carrying various sections of the polA regulatory region, linked to a galK gene, were introduced into the mutant strains. Analysis of galactokinase shows that the enzyme activity in the UV hyper-resistant mutant is increased. The results suggest that the synthesis of DNA polymerase I in E. coli is inducible.

In vitro study of the interaction of the LexA repressor and the UvrC protein with a uvrC regulatory region.

The in vitro interaction of the LexA repressor with a regulatory region of the uvrC gene has been studied by polyacrylamide gel electrophoresis. Although the uvrC promoter region shows some homology with the canonic LexA binding site, no specific binding of the repressor to this DNA sequence could be observed, but only a cooperative nonspecific binding. By the same technique we show that the UvrC protein does not bind specifically to this regulatory DNA sequence either, although the protein is able to bind nonspecifically and cooperatively to the double-stranded DNA fragment.

Regulation of the uvrC gene of Escherichia coli K12: localization and characterization of a damage-inducible promoter.

Operon fusion and S1 nuclease mapping have been employed to locate a putative uvrC promoter, which is situated approximately 200 bp ahead of the uvrC structural gene. The promoter sustains transcription towards the uvrC coding sequence and is inducible by DNA damaging agents. The inducibility is dependent on the Escherichia coli LexA and RecA functions. Examination of the DNA sequence in the promoter region reveals the presence of a sequence similar to the consensus of a SOS box. In contrast to the related uvrA and uvrB genes, uvrC gene expression is characterized by a delayed onset of induction after DNA damaging treatment. Furthermore, no induction is observed with nalidixic acid.

Effect of lexA and ssb genes, present on a uvrA recombinant plasmid, on the UV survival of Escherichia coli K-12.

The recombinant plasmid pJA01 contains, besides the uvrA gene, the genes lexA, ubiA and ssb. This plasmid does not fully complement a uvrA mutation in a Rec+ background. Plasmids which contain the uvrA and ssg genes, but not the lexA gene, show a higher but still only partial complementation. Full complementation achieved when the ssb gene us inactivated by insertion of Tn5. Furthermore, it appears that the presence of the ssb gene on a multicopy plasmid sensitizes wild-type cells to UV light. The effect of Ssb (single-strand DNA binding protein) overproduction on UV survival is discussed.

Use of transposons in cloning poorly selectable genes of Escherichia coli: cloning of uvrA and adjacent genes.

A transposon was introduced close to a poorly selectable gene. This gene could be cloned by using selection for the antibiotic resistance marker of the transposon.

Expression of the uvrB gene of Escherichia coli: in vitro construction of a pMB9 uvrB plasmid.

Bacteriophage lambdab2att2 [lambdab2cI857intam6(deltabioAB)bioFCD+uvrB+phr+] codes for a function(s) that confers UV resistance (Uvr+) and reactivation of irradiated phage (Hcr+) to an Uvr-Hcr-Escherichia coli strain. It was demonstrated that these functions are expressed under the control of bacterial regulatory elements located on lambdab2att2 DNA. The location of the E. coli uvrB gene on the DNA of this transducing phage was established by heteroduplex and restriction-enzyme analyses. Recombinant DNA molecules were constructed in vitro from plasmid pMB9 (Tcr), as the vector, and an EcoRI fragment (Eco-RI-F) of lambdab2att2 DNA. The resulting plasmid, designated pNP5, has a molecular weight of 5.1 X 10(6) and replicates in a relaxed fashion. Transformation of E. coli uvrB with plasmid pNP5 resulted in clones that are Uvr+ Tcr. Irradiation of bacteria transformed with plasmid pNP5 with low UV doses revealed a complete restoratation of the Uvr+ phenotype by the presence of the cloned EcoRI-F DNA, while only a partial restoration was observed after irradiation with high UV doses. Likewise, the Hcr+ character was also partially restored due to the presence of pNP5. No correlation was found between the acquired Uvr+, Hcr+ properties, and the presence of correndonuclease II activity in an extract of bacteria that harbor plasmid pNP5.

Comparison of the resA1 and polA1 mutations in isogenic strains of Escherichia coli K-12.

Strains carrying either the polA1 or resA1 mutation are deficient in DNA polymerase I, and the polA1 and resA1 mutations do not complement in merozygotes. The effect of these mutations in otherwise identical genetic backgrounds was studied: after ultraviolet irradiation both strains degrade their DNA more rapidly and more extensively than the wild-type strains. However, after X-ray irradiation the resA1 strain shows little DNA breakdown and repairs its single-strand breaks. In contrast, the polA1 strain degrades its DNA extensively, and single-strand breaks are not repaired. Moreover, the resA1 strain is capable of supporting the growth of a red(-) bacteriophage lambda, whereas the polA1 strain is not.