DNA recombination: the replication connection.

Chromosomal double-strand breaks (DSBs) arise after exposure to ionizing radiation or enzymatic cleavage, but especially during the process of DNA replication itself. Homologous recombination plays a critical role in repair of such DSBs. There has been significant progress in our understanding of two processes that occur in DSB repair: gene conversion and recombination-dependent DNA replication. Recent evidence suggests that gene conversion and break-induced replication are related processes that both begin with the establishment of a replication fork in which both leading- and lagging-strand synthesis occur. There has also been much progress in characterization of the biochemical roles of recombination proteins that are highly conserved from yeast to humans.     

DNA replication in Physarum polycephalum: characterization of replication products in vivo.

Synchronous plasmodia of Physarum polycephalum in DNA synthesis were pulse-labelled with [oH]- thymidine for time periods of 15 seconds up to 9 minutes, or given a 30 seconds pulse followed by chase periods of 9 minutes up to 6 hours. Sedimentation analysis in alkaline sucrose gradients revealed at least five species of single stranded DNA14 molecules in the pulse experiments. Co-sedimentation of [14C]-labelled phage-DNA gave relative S-values of 5-7, 13-15, 23-25, 30 and 33-35 for these DNA molecules, all of which can be chased into DNA of higher molecular weight.     

Human Y-chromatin : II. DNA replication

The DNA synthesis of the human Y-chromatin in its various morphological configurations was studied by labeling with tritiated thymidine (³H-TdR) and autoradiography. Continuous terminal and pulse labeling studies revealed that while condensed, the Y-body lagged in DNA synthesis behind the rest of the nucleus. The highest rate of incorporation of ³H-TdR by the Y-body occurred when it was dispersed. These observations are consistent with the replication characteristics of the Y chromosome as determined by conventional late labeling studies and strongly suggest that the Y-body uncoils at the time it replicates its DNA.     

DNA replication in Physarum polycephalum: bidirectional replication of DNA within replicons.

The direction of replication of DNA within replicons of Physarum polycephalum was studied by pulse-labelling with 5-bromouracil-deoxyriboside (BrdUrd) and 3H-adenosine deoxyriboside (dAdo), followed by ultraviolet- (UV) -photolysis and analysis of molecular weights of single strand DNA fragments on alkaline sucrose gradients. Newly made DNA within replicons at all stages of completion is split in two equal halves upon UV irradiation when BrdUrd was given at the time of initiation of DNA synthesis. This shows that replication within replicons of Physarum polycephalum starts at an origin located in the center of each unit, proceeding bidirectionally from this origin.     

Adenovirus origin of DNA replication: sequence requirements for replication in vitro.

The initiation of adenovirus DNA takes place at the termini of the viral genome and requires the presence of specific nucleotide sequence elements. To define the sequence organization of the viral origin, we tested a large number of deletion, insertion, and base substitution mutants for their ability to support initiation and replication in vitro. The data demonstrate that the origin consists of at least three functionally distinct domains, A, B, and C. Domain A (nucleotides 1 to 18) contains the minimal sequence sufficient for origin function. Domains B (nucleotides 19 to 40) and C (nucleotides 41 to 51) contain accessory sequences that significantly increase the activity of the minimal origin. The presence of domain B increases the efficiency of initiation by more than 10-fold in vitro, and the presence of domains B and C increases the efficiency of initiation by more than 30-fold. Mutations that alter the distance between the minimal origin and the accessory domains by one or two base pairs dramatically decrease initiation efficiency. This critical spacing requirement suggests that there are specific interactions between the factors that recognize the two regions.     

Studies on mammalian chromosome replication : III. Organization and replication of diplochromosomes

The process of DNA synthesis in normal and endoreduplicating mammalian cells are very similar. Both types of chromosomes are replicated in defined units termed chromosomal replicons, and in the same sequences along their lengths. The sister chromosomes of the diplochromosomes are replicated synchronously in identical patterns. The present observations suggest that organization and sequences of chromosome replication are genetically programmed.     

Parvovirus replication.

The members of the family Parvoviridae are among the smallest of the DNA viruses, with a linear single-stranded genome of about 5 kilobases. Currently the family is divided into three genera, two of which contain viruses of vertebrates and a third containing insect viruses. This review concentrates on the vertebrate viruses, with emphasis on recent advances in our insights into the molecular biology of viral replication. Traditionally the vertebrate viruses have been distinguished by the presence or absence of a requirement for a coinfection with a helper virus before productive infection can occur, hence the notion that the dependoviruses (adeno-associated viruses [AAV]) are defective. Recent data would suggest that not only is there a great deal of structural and genetic organizational similarity between the two types of vertebrate viruses, but also there is significant similarity in the molecular biology of productive replication. What differs is the physiological condition of the host cell that renders it permissive. Healthy dividing cells are permissive for productive replication by autonomous parvoviruses; such cells result in latent infection by dependoviruses. For a cell to become permissive for productive AAV replication, it must have been exposed to toxic conditions which activate a latent AAV genome. Such conditions can be caused by helper-virus infection or exposure to physical (UV light) or chemical (some carcinogens) agents. In this paper the molecular biology of replication is reviewed, with special emphasis on the role of the host and the consequences of viral infection for the host.     

Parvovirus replication.

The members of the family Parvoviridae are among the smallest of the DNA viruses, with a linear single-stranded genome of about 5 kilobases. Currently the family is divided into three genera, two of which contain viruses of vertebrates and a third containing insect viruses. This review concentrates on the vertebrate viruses, with emphasis on recent advances in our insights into the molecular biology of viral replication. Traditionally the vertebrate viruses have been distinguished by the presence or absence of a requirement for a coinfection with a helper virus before productive infection can occur, hence the notion that the dependoviruses (adeno-associated viruses [AAV]) are defective. Recent data would suggest that not only is there a great deal of structural and genetic organizational similarity between the two types of vertebrate viruses, but also there is significant similarity in the molecular biology of productive replication. What differs is the physiological condition of the host cell that renders it permissive. Healthy dividing cells are permissive for productive replication by autonomous parvoviruses; such cells result in latent infection by dependoviruses. For a cell to become permissive for productive AAV replication, it must have been exposed to toxic conditions which activate a latent AAV genome. Such conditions can be caused by helper-virus infection or exposure to physical (UV light) or chemical (some carcinogens) agents. In this paper the molecular biology of replication is reviewed, with special emphasis on the role of the host and the consequences of viral infection for the host.     

Complementary replication.

Differential equations for the kinetics of complementary replicating macromolecules in a flow reactor are derived. It is shown that such a model has many features in common with the differential equation for direct replication, the replicator equation. Two special cases of replication, and the influence of mutation on them, have been studied in detail. In the case of first-order mass action kinetics--the quasi-species model--complementary replication, like direct replication, exhibits an error threshold for the replication accuracy, below which the genetic information is lost. In turns out that the long-time behavior of many special cases of the second-order kinetics model can be described in terms of second-order replicator equations, although this is not possible in general.     

Chromatin replication.

Just as the faithful replication of DNA is an essential process for the cell, chromatin structures of active and inactive genes have to be copied accurately. Under certain circumstances, however, the activity pattern has to be changed in specific ways. Although analysis of specific aspects of these complex processes, by means of model systems, has led to their further elucidation, the mechanisms of chromatin replication in vivo are still controversial and far from being understood completely. Progress has been achieved in understanding: 1. The initiation of chromatin replication, indicating that a nucleosome-free origin is necessary for the initiation of replication; 2. The segregation of the parental nucleosomes, where convincing data support the model of random distribution of the parental nucleosomes to the daughter strands; and 3. The assembly of histones on the newly synthesized strands, where growing evidence is emerging for a two-step mechanism of nucleosome assembly, starting with the deposition of H3/H4 tetramers onto the DNA, followed by H2A/H2B dimers.     

Adenovirus type 2 DNA replication. II. Termini of DNA replication.

Complete, mature adenovirus type 2 DNA molecules were isolated from virus-infected HeLa cells, pulse-labeled at 20 h postinfection in [3H]thymidine pulses shorter than the time necessary for one round of viral DNA replication. After digestion with the restriction endonucleases Eco RI, Hpa I, and Hind III, a temporal order of synthesis of different regions of the viral genome was established from the relative specific radioactivities in the restriction enzyme fragments. A comparison with the physical order of these fragments revealed the existence of two termini of DNA replication towards both the molecular right and left ends, respectively, of the viral chromosome.     

Chromatin replication: Finding the right connection.

Nucleosomes are preferentially assembled on replicating DNA by chromatin assembly factor 1; recent studies have shown that replicated DNA is marked for assembly into chromatin by the replication-fork-associated protein PCNA.     

Functional analysis of minichromosome replication: bidirectional and unidirectional replication from the Escherichia coli replication origin, oriC.

Replicating molecules of minichromosomes pCM959 and pOC24 were analyzed by electron microscopy. Replication of pCM959 proceeded bidirectionally from the replication origin, oriC, in about 60% of the molecules; the rest of the molecules replicated unidirectionally in either direction. pOC24, in which deoxyribonucleic acid to the right (clockwise) of the oriC segment is deleted, seemed to replicate predominantly unidirectionally counterclockwise from oriC.     

RMPs: recombination/replication mediator proteins.

Enzymes for DNA replication and recombination need to gain access to single-stranded DNA (ssDNA) but ssDNA-binding proteins (SSBs) present an obstacle to the formation of enzyme-ssDNA replication and recombination complexes. A specialized class of SSBs, which we designate as recombination/replication mediator proteins (RMPs), promotes enzyme- ssDNA assembly by overcoming SSB inhibition. RMPs exhibit strong conservation of function across divergent species, and display species-specific interactions with SSB and enzymes to neutralize the SSB barrier to enzyme-ssDNA assembly.     

Ficellomycin and feldamycin; inhibitors of bacterial semiconservative DNA replication.

The two peptide-like antibiotics ficellomycin and feldamycin impair semiconservative DNA replication but not DNA repair synthesis in bacteria. Specifically both antibiotics cause the accumulation of a 34S DNA species in toluenized Escherichia coli cells which lacks the capability of being integrated into larger DNA pieces and eventually the complete bacterial chromosome. Novobiocin, a known inhibitor of replicative DNA synthesis, was investigated for comparative purposes. The action of this latter antibiotic differs from the ones exerted by ficellomycin and feldamycin in the novobiocin appears to block an event associated with the initiation of Okazaki fragments. The fact that novobiocin impairs DNA gyrase suggests that this enzyme plays an essential role during the initiation of Okazaki pieces.