Histone segregation on replicating chromatin

We have reinvestigated the mode of segregation of preexisting histones onto replicating chromosomes. Since our previous data have indicated that only histones H3 and H4 do not appear to move from their association with the DNA strand with which they are bound until the next round of replication, we have concentrated our attention on these two histones. The strategy we have employed involved density labeling of DNA and radiolabeling of the histones of interest. Subsequently, we followed the association of histones and DNA during further rounds of DNA replication. One can make predictions concerning the nature of the association between specific histones and particular DNA strands depending on the mode of deposition. The results have confirmed our previous findings that histones segregate randomly. The possibility that such a result is a consequence of turnover of radiolabel in non-histone proteins and subsequent reutilization for histone synthesis has been tested directly. This process appears to be occurring to only a very limited extent. The implications of these conclusions for chromatin structure and gene control are discussed.     

DNA methylation in plants: relationship to small RNAs and histone modifications, and functions in transposon inactivation

DNA methylation is a type of epigenetic marking that strongly influences chromatin structure and gene expression in plants and mammals. Over the past decade, DNA methylation has been intensively investigated in order to elucidate its control mechanisms. These studies have shown that small RNAs are involved in the induction of DNA methylation, that there is a relationship between DNA methylation and histone methylation, and that the base excision repair pathway has an important role in DNA demethylation. Some aspects of DNA methylation have also been shown to be shared with mammals, suggesting that the regulatory pathways are, in part at least, evolutionarily conserved. Considerable progress has been made in elucidating the mechanisms that control DNA methylation; however, many aspects of the mechanisms that read the information encoded by DNA methylation and mediate this into downstream regulation remain uncertain, although some candidate proteins have been identified. DNA methylation has a vital role in the inactivation of transposons, suggesting that DNA methylation is a key factor in the evolution and adaptation of plants.     

C2 from Beet curly top virus meddles with the cell cycle: A novel function for an old pathogenicity factor

Geminiviruses are ssDNA plant viruses that infect a wide range of crops. Since geminiviruses often infect terminally differentiated cells, they must induce cell cycle re-entry in order to replicate; until recently, only two viral proteins, the replication-associated protein Rep and the curtoviral pathogenicity factor C4, had been assigned a role in the restoration of cell competency. In a recent work, we demonstrated that C2 from Beet curly top virus activates the expression of host genes involved in DNA replication and/or control of the G2/M transition in a manner consistent with cell cycle re-entry. As expected, expression of BCTV C2 results in enhanced replication of DNA viruses. We conclude that BCTV C2 acts as a re-activator of the cell cycle in infected cells, enhancing the DNA replication competency and providing a cell environment favorable for replication of geminiviruses. Potential mechanisms for this novel function are discussed in light of our findings.KEYWORDS: Geminivirus, BCTV, curtovirus, C2, cell cycle, replication     

Involvement of Nucleotide Excision and Mismatch Repair Mechanisms in Double Strand Break Repair

Living organisms are constantly threatened by environmental DNA-damaging agents, including UV and ionizing radiation (IR). Repair of various forms of DNA damage caused by IR is normally thought to follow lesion-specific repair pathways with distinct enzymatic machinery. DNA double strand break is one of the most serious kinds of damage induced by IR, which is repaired through double strand break (DSB) repair mechanisms, including homologous recombination (HR) and non-homologous end joining (NHEJ). However, recent studies have presented increasing evidence that various DNA repair pathways are not separated, but well interlinked. It has been suggested that non-DSB repair mechanisms, such as Nucleotide Excision Repair (NER), Mismatch Repair (MMR) and cell cycle regulation, are highly involved in DSB repairs. These findings revealed previously unrecognized roles of various non-DSB repair genes and indicated that a successful DSB repair requires both DSB repair mechanisms and non-DSB repair systems. One of our recent studies found that suppressed expression of non-DSB repair genes, such as XPA, RPA and MLH1, influenced the yield of IR induced micronuclei formation and/or chromosome aberrations, suggesting that these genes are highly involved in DSB repair and DSB-related cell cycle arrest, which reveals new roles for these gene products in the DNA repair network. In this review, we summarize current progress on the function of non-DSB repair-related proteins, especially those that participate in NER and MMR pathways, and their influence on DSB repair. In addition, we present our developing view that the DSB repair mechanisms are more complex and are regulated by not only the well known HR/NHEJ pathways, but also a systematically coordinated cellular network.Key Words: Ionizing radiation (IR), DNA damage, DSB repair, NER, MMR and cell cycle.     

Agrobacterium T-DNA integration: molecules and models

Genetic transformation mediated by Agrobacterium involves the transfer of a DNA molecule (T-DNA) from the bacterium to the eukaryotic host cell, and its integration into the host genome. Whereas extensive work has revealed the biological mechanisms governing the production, Agrobacterium-to-plant cell transport and nuclear import of the Agrobacterium T-DNA, the integration step remains largely unexplored, although several different T-DNA integration mechanisms have been suggested. Recent genetic and functional studies have revealed the importance of host proteins involved in DNA repair and maintenance for T-DNA integration. In this article, we review our understanding of the specific function of these proteins and propose a detailed model for integration.     

Chorion gene amplification in Drosophila: A model for metazoan origins of DNA replication and S-phase control.

The mechanisms controlling duplication of the metazoan genome are only beginning to be understood. It is still unclear what organization of DNA sequences constitutes a chromosomal origin of DNA replication, and the regulation of origin activity during the cell cycle has not been fully revealed. We review recent results that indicate that chorion gene amplification in follicle cells of the Drosophila ovary is a model for investigating metazoan replication. Evaluation of cis sequence organization and function suggests that chorion loci share attributes with other replicons and provides insights into metazoan origin structure. Moreover, recent results indicate that chorion origins respond to S-phase control, but escape mechanisms that inhibit other origins from firing more than once in a cell cycle. Several identified genes that mediate amplification are critical for the cell cycle control of replication initiation. It is likely that further genetic screens for mutations that disrupt amplification will identify the cadre of proteins associated with origins and the regulatory pathways that control their activity. Furthermore, the recent development of methods to detect amplification in situ has uncovered new aspects of its developmental control. Examining this control will reveal links between developmental pathways and the cell cycle machinery. Visualization of amplifying chorion genes with high resolution also represents an opportunity to evaluate the influence of nuclear and chromosome structure on origin activity. The study of chorion amplification in Drosophila, therefore, provides great potential for the genetic and molecular dissection of metazoan replication.     

Clusterin and DNA repair: a new function in cancer for a key player in apoptosis and cell cycle control

The glycoprotein clusterin (CLU), has two known isoforms generated in human cells. A nuclear form of CLU protein (nCLU) is pro-apoptotic, while a secretory form (sCLU) is pro-survival. Both forms are implicated in various cell functions, including DNA repair, cell cycle regulation, and apoptotic cell death. CLU expression has been associated with tumorigenesis and the progression of various malignancies. In response to DNA damage, cell survival can be enhanced by activation of DNA repair mechanisms, while simultaneously stimulating energy-expensive cell cycle checkpoints that delay the cell cycle progression to allow more time for DNA repair. This review summarizes our current understanding of the role of clusterin in DNA repair, apoptosis, and cell cycle control and the relevance.     

Cell size and the initiation of DNA replication in bacteria

In eukaryotes, DNA replication is coupled to the cell cycle through the actions of cyclin-dependent kinases and associated factors. In bacteria, the prevailing view, based primarily from work in Escherichia coli, is that growth-dependent accumulation of the highly conserved initiator, DnaA, triggers initiation. However, the timing of initiation is unchanged in Bacillus subtilis mutants that are ~30% smaller than wild-type cells, indicating that achievement of a particular cell size is not obligatory for initiation. Prompted by this finding, we re-examined the link between cell size and initiation in both E. coli and B. subtilis. Although changes in DNA replication have been shown to alter both E. coli and B. subtilis cell size, the converse (the effect of cell size on DNA replication) has not been explored. Here, we report that the mechanisms responsible for coordinating DNA replication with cell size vary between these two model organisms. In contrast to B. subtilis, small E. coli mutants delayed replication initiation until they achieved the size at which wild-type cells initiate. Modest increases in DnaA alleviated the delay, supporting the view that growth-dependent accumulation of DnaA is the trigger for replication initiation in E. coli. Significantly, although small E. coli and B. subtilis cells both maintained wild-type concentration of DnaA, only the E. coli mutants failed to initiate on time. Thus, rather than the concentration, the total amount of DnaA appears to be more important for initiation timing in E. coli. The difference in behavior of the two bacteria appears to lie in the mechanisms that control the activity of DnaA.     

<Emphasis Type="Italic">Ab ovo or de novo?</Emphasis> Mechanisms of centriole duplication

The centrosome, an organelle comprising centrioles and associated pericentriolar material, is the major microtubule organizing center in animal cells. For the cell to form a bipolar mitotic spindle and ensure proper chromosome segregation at the end of each cell cycle, it is paramount that the cell contains two and only two centrosomes. Because the number of centrosomes in the cell is determined by the number of centrioles, cells have evolved elaborate mechanisms to control centriole biogenesis and to tightly coordinate this process with DNA replication. Here we review key proteins involved in centriole assembly, compare two major modes of centriole biogenesis, and discuss the mechanisms that ensure stringency of centriole number.     

Meiotic restitution in amphihaploids in the tribe Triticeae

In haploid and diploid organisms of the plant kingdom, meiotic division of diploid cells proceeds in two consecutive stages, with DNA replicating only once. In amphihaploids (interspecific or intergeneric hybrids), where homologs are absent, the reduction of the chromosome number does not occur, meiosis is abnormal, and the plants are sterile. Gamete viability in F₁ hybrids is ensured by a single division when chromosomes are separated into sister chromatids in either the first or the second division. Such gametes ensure partial fertility of amphihaploids, thereby facilitating their survival and stabilization of the polygenome. The frequency of the formation of viable gametes varies from a few cases to 98.8% in different anthers of the hybrids. Here, studies on the cytological mechanisms and genetic control of chromosome unreduction or restitution in different amphihaploids of the tribe Triticeae are reviewed. The current notions on the control of formation of restitution nuclei based on the principles of a prolonged metaphase I and different types of meiocytes. The main terms used for systematization of restitution mechanisms are first-division restitution (FDR), single-division meiosis (SDM), and unreductional meiotic cell division (UMCD). It has been assumed that archesporial cells of wide hybrids may have two cell division programs, the meiotic and the mitoyic ones The possible approaches to the analysis of the genetic control of chromosome restitution in amphihaploids are discussed.     

p53-mediated transcriptional regulation and activation of the actin cytoskeleton regulatory RhoC to LIMK2 signaling pathway promotes cell survival

The central arbiter of cell fate in response to DNA damage is p53, which regulates the expression of genes involved in cell cycle arrest, survival and apoptosis. Although many responses initiated by DNA damage have been characterized, the role of actin cytoskeleton regulators is largely unknown. We now show that RhoC and LIM kinase 2 (LIMK2) are direct p53 target genes induced by genotoxic agents. Although RhoC and LIMK2 have well-established roles in actin cytoskeleton regulation, our results indicate that activation of LIMK2 also has a pro-survival function following DNA damage. LIMK inhibition by siRNA-mediated knockdown or selective pharmacological blockade sensitized cells to radio- or chemotherapy, such that treatments that were sub-lethal when administered singly resulted in cell death when combined with LIMK inhibition. Our findings suggest that combining LIMK inhibitors with genotoxic therapies could be more efficacious than single-agent administration, and highlight a novel connection between actin cytoskeleton regulators and DNA damage-induced cell survival mechanisms.     

Agents that elevate cAMP stimulate DNA fragmentation in thymocytes

Increases in the cAMP level are often inhibitory in mature T lymphocytes and may be involved in the development of tolerance to self Ag. In this report, agents inducing an increase in the cAMP level by independent mechanisms were found to stimulate DNA fragmentation, characteristic of a suicide program known as apoptosis, in isolated thymocytes. Data obtained with cAMP analogs known to act synergistically to stimulate protein kinase A suggested that the latter directly mediated endonuclease activation. Agents previously shown to stimulate protein kinase C and to inhibit Ca2(+)-dependent, TCR-mediated thymocyte apoptosis, including IL-1, also blocked both DNA fragmentation and cell death in response to cAMP, suggesting interactions ("cross-talk") between the two protein kinase systems. As it has been proposed that apoptosis mediates negative cell selection in the thymus, our results indicate that cAMP may play a role in the development of functional mature T lymphocytes.     

Regulation of DNA repair throughout the cell cycle

The repair of DNA lesions that occur endogenously or in response to diverse genotoxic stresses is indispensable for genome integrity. DNA lesions activate checkpoint pathways that regulate specific DNA-repair mechanisms in the different phases of the cell cycle. Checkpoint-arrested cells resume cell-cycle progression once damage has been repaired, whereas cells with unrepairable DNA lesions undergo permanent cell-cycle arrest or apoptosis. Recent studies have provided insights into the mechanisms that contribute to DNA repair in specific cell-cycle phases and have highlighted the mechanisms that ensure cell-cycle progression or arrest in normal and cancerous cells.     

Temporal organization of replication in DNA fibers of mammalian cells

The extent of coordinate control over the multiple initiation events in DNA replication has been investigated in three mammalian cell lines by DNA fiber autoradiography. Quantitative estimates have been obtained of the degree of synchrony among initiations occurring on stretches of DNA. Synchrony decreases markedly with increasing distance between initiation sites in MDBK (bovine) and L929 (mouse) cells, but only slightly in muntjac cells. Possible control mechanisms for the initiation process are discussed.     

Changes in DNA repair during aging

DNA is a precious molecule. It encodes vital information about cellular content and function. There are only two copies of each chromosome in the cell, and once the sequence is lost no replacement is possible. The irreplaceable nature of the DNA sets it apart from other cellular molecules, and makes it a critical target for age-related deterioration. To prevent DNA damage cells have evolved elaborate DNA repair machinery. Paradoxically, DNA repair can itself be subject to age-related changes and deterioration. In this review we will discuss the changes in efficiency of mismatch repair (MMR), base excision repair (BER), nucleotide excision repair (NER) and double-strand break (DSB) repair systems during aging, and potential changes in DSB repair pathway usage that occur with age. Mutations in DNA repair genes and premature aging phenotypes they cause have been reviewed extensively elsewhere, therefore the focus of this review is on the comparison of DNA repair mechanisms in young versus old.     

Genomic Instability in Cancer

One of the fundamental challenges facing the cell is to accurately copy its genetic material to daughter cells. When this process goes awry, genomic instability ensues in which genetic alterations ranging from nucleotide changes to chromosomal translocations and aneuploidy occur. Organisms have developed multiple mechanisms that can be classified into two major classes to ensure the fidelity of DNA replication. The first class includes mechanisms that prevent premature initiation of DNA replication and ensure that the genome is fully replicated once and only once during each division cycle. These include cyclin-dependent kinase (CDK)-dependent mechanisms and CDK-independent mechanisms. Although CDK-dependent mechanisms are largely conserved in eukaryotes, higher eukaryotes have evolved additional mechanisms that seem to play a larger role in preventing aberrant DNA replication and genome instability. The second class ensures that cells are able to respond to various cues that continuously threaten the integrity of the genome by initiating DNA-damage-dependent “checkpoints” and coordinating DNA damage repair mechanisms. Defects in the ability to safeguard against aberrant DNA replication and to respond to DNA damage contribute to genomic instability and the development of human malignancy. In this article, we summarize our current knowledge of how genomic instability arises, with a particular emphasis on how the DNA replication process can give rise to such instability.In eukaryotes, DNA replication initiates from hundreds of thousands of replication sites, termed origins of DNA replication (Leonard and Méchali 2013). Not only do cells need to initiate and terminate DNA replication at the right time during S phase, they must do so only once, at each of these replication origins, during each division cycle (Machida et al. 2005). Mechanisms that govern the initiation of DNA replication in eukaryotes are described in full detail in Bell and Kaguni (2013) and Tanaka and Araki (2013), whereas those that regulate DNA replication are described in Siddiqui et al. (2013) and Zielke et al. (2013). Rhind and Gilbert’s (2013) work is dedicated to the mechanisms that control the timing of DNA replication. Here we focus on the mechanisms that prevent aberrant DNA replication.Perturbations in DNA replication present cells with significant challenges. On one hand, incomplete genome duplication leads to cell inviability or, if cells survive, to aneuploidy. On the other hand, failure to restrict origin firing to once per replication origin per cell cycle, leads to overreplication. Reinitiation of DNA replication from the same origins of replication before the completion of S phase, commonly referred to as rereplication, is often associated with genome instability owing to the accumulation of replication intermediates, collapsed replication forks, and chromosomal breakages. In addition, defects in cytokinesis or mitotic regulation may lead to the complete reduplication of the genome. This latter process is reminiscent of endoreduplication, a physiological process that occurs in many metazoans during normal development and is characterized by multiple, discrete, and complete rounds of S phases without intervening mitosis. Finally, reinitiation of DNA replication from specific genomic loci is thought to be responsible for gene amplifications but the mechanisms underlying gene amplification are poorly understood.How do these various mechanisms of genomic instability relate to cancer? An increase of copy number of chromosomes or genes allows cells to overexpress certain genes or mutate the extra copies to acquire growth, survival, or metastasis advantage. Equally important is the excessive DNA damage that is associated with these problems in DNA replication. When a cell attempts to segregate an underreplicated chromosome between two daughter cells, the result is often broken chromosomes and aneuploidy. Conversely, overreplication is marked by excessive DNA damage from collapsed replication forks. The repair processes are not perfect and so any increase in DNA damage leads to increased mutagenesis, and thus activation of oncogenes or inactivation of tumor suppressor genes, fueling malignant transformation and progression.