Cyclin B-cdk1 kinase stimulates ORC- and Cdc6-independent steps of semiconservative plasmid replication in yeast nuclear extracts.

Nuclear extracts from Saccharomyces cerevisiae cells synchronized in S phase support the semiconservative replication of supercoiled plasmids in vitro. We examined the dependence of this reaction on the prereplicative complex that assembles at yeast origins and on S-phase kinases that trigger initiation in vivo. We found that replication in nuclear extracts initiates independently of the origin recognition complex (ORC), Cdc6p, and an autonomously replicating sequence (ARS) consensus. Nonetheless, quantitative density gradient analysis showed that S- and M-phase nuclear extracts consistently promote semiconservative DNA replication more efficiently than G1-phase extracts. The observed semiconservative replication is compromised in S-phase nuclear extracts deficient for the Cdk1 kinase (Cdc28p) but not in extracts deficient for the Cdc7p kinase. In a cdc4-1 G1-phase extract, which accumulates high levels of the specific Clb-Cdk1 inhibitor p40(SIC1), very low levels of semiconservative DNA replication were detected. Recombinant Clb5-Cdc28 restores replication in a cdc28-4 S-phase extract yet fails to do so in the cdc4-1 G1-phase extract. In contrast, the addition of recombinant Xenopus CycB-Cdc2, which is not sensitive to inhibition by p40(SIC1), restores efficient replication to both extracts. Our results suggest that in addition to its well-characterized role in regulating the origin-specific prereplication complex, the Clb-Cdk1 complex modulates the efficiency of the replication machinery itself.

Semi-conservative replication in yeast nuclear extracts requires Dna2 helicase and supercoiled template.

We describe the preparation of nuclear extracts from yeast cells synchronised in S-phase that support the aphidicolin-sensitive, semi-conservative replication of primer-free, supercoiled plasmid in vitro. This is monitored by one and two-dimensional gel electrophoresis of replication intermediates that have incorporated [alpha-32P]dATP, by the conversion of methylated template DNA into a hemi-methylated or DpnI-resistant form, and by substitution of dTTP with the heavy derivative BrdUTP, which results in a shift in density corresponding to complete second strand synthesis. We demonstrate dependence on DNA pol delta and the pol alpha/primase complex, and are able to detect putative Okazaki fragments under ATP-limiting conditions. In contrast to the semi-conservative replication of supercoiled plasmid, linear or open-circular templates incorporate labelled nucleotides through repair synthesis that produces no significant density shift on CsCl gradients. Consistent with a true replication reaction we find that semi-conservative replication of plasmid DNA is stimulated in S-phase relative to G1-phase nuclear extracts, and is independent of the recombination-promoting factor Rad52p. Using this novel system we demonstrate that semi-conservative replication, but not polymerase activity per se, requires the activity of the DNA helicase encoded by DNA2.

Implants of polymer-encapsulated genetically modified cells releasing glial cell line-derived neurotrophic factor improve survival, growth, and function of fetal dopaminergic grafts.

Neural transplantation as an experimental therapy for Parkinsonian patients has been shown to be effective in several clinical trials. Further benefit, however, may be expected if the grafting is combined with a treatment of neurotrophic factors thus improving the survival and growth of grafted embryonic dopaminergic neurons. Continuous trophic support may be needed and therefore requires the long-term delivery of neurotrophic factors to the brain. We demonstrate here that the implantation of polymer-encapsulated cells genetically engineered to continuously secrete glial cell line-derived neurotrophic factor to the adult rat striatum improves dopaminergic graft survival and function. Near complete compensation of 6-hydroxydopamine-induced rotation was already achieved within 3 weeks postgrafting in rats that received glial cell line-derived neurotrophic factor-releasing capsules in addition to dopaminergic cell grafts of cultured tissue. Rats without trophic factor supply showed only little recovery at the same time point and sham grafted rats showed no recovery. The number of tyrosine hydroxylase-immunoreactive cells per graft was increased 2.6-fold in the presence of glial cell line-derived neurotrophic factor 6 weeks postgrafting. Similarly, tyrosine hydroxylase-immunoreactive fibers around the graft were increased by 53%. Moreover, these fibers showed a preferential growth towards the trophic factor-releasing capsule. Taken together, these results provide evidence that encapsulated genetically engineered cells are an effective means of long-term trophic factor supply into the adult rat brain and that the delivery of glial cell line-derived neurotrophic factor can sustain dopaminergic graft function and survival.

ORC-dependent and origin-specific initiation of DNA replication at defined foci in isolated yeast nuclei.

We describe an in vitro replication assay from yeast in which the addition of intact nuclei to an S-phase nuclear extract results in the incorporation of deoxynucleotides into genomic DNA at spatially discrete foci. When BrdUTP is substituted for dTTP, part of the newly synthesized DNA shifts to a density on CsCl gradients, indicative of semiconservative replication. Initiation occurs in an origin-specific manner and can be detected in G1- or S-phase nuclei, but not in G2-phase or mitotic nuclei. The S-phase extract contains a heat- and 6-DMAP-sensitive component necessary to promote replication in G1-phase nuclei. Replication of nuclear DNA is blocked at the restrictive temperature in an orc2-1 mutant, and the inactive Orc2p cannot be complemented in trans by an extract containing wild-type ORC. The initiation of DNA replication in cln-deficient nuclei blocked in G1 indicates that the ORC-dependent prereplication complex is formed before Start. This represents the first nonviral and nonembryonic replication system in which DNA replication initiates in an ORC-dependent and origin-specific manner in vitro.

Recombination of constant and variable modules alters DNA sequence recognition by type IC restriction-modification enzymes.

EcoR124 and EcoDXXI are allelic type I restriction-modification (R-M) systems whose specificity genes consist of common structural elements: two variable regions are separated by a constant, homologous region containing a number of repetitive sequence elements. In vitro recombination of variable and constant elements has led to fully active, hybrid R-M systems exhibiting new and predictable target site specificities. Methylation of synthetic DNA sequences with purified, hybrid modification methylases was used to confirm the proposed recognition sequences. The results clearly demonstrate the correlation between protein domains and target site specificity. Our data suggest that a bacterial population may switch the recognition sequences of its type I R-M system by single recombination events and thus is able to maintain a prokaryotic analogue of the immune system of variable specificity.