Cdk5: Links to DNA damage

Comment on: Huang E, et al. Nat Cell Biol 2010; 12:563-71.     

Mammalian DNA methyltransferases: a structural perspective

The methylation of mammalian DNA, primarily at CpG dinucleotides, has long been recognized to play a major role in controlling gene expression, among other functions. Given their importance, it is surprising how many basic questions remain to be answered about the proteins responsible for this methylation and for coordination with the parallel chromatin-marking system that operates at the level of histone modification. This article reviews recent studies on, and discusses the resulting biochemical and structural insights into, the DNA nucleotide methyltransferase (Dnmt) proteins 1, 3a, 3a2, 3b, and 3L.     

Nonsequence-specific DNA recognition: a structural perspective

Chromosomal proteins that form essential architectural components of chromatin bind and bend DNA with an intrinsic low degree of sequence preference. Comparisons made between two recently determined structures of high mobility group (HMG) protein-DNA complexes and other nonsequence-specific protein-DNA complexes reveal the structural basis of this important mode of DNA binding.     

CedA is a novel Escherichia coli protein that activates the cell division inhibited by chromosomal DNA over-replication

We isolated and characterized a new gene related to the control of cell division regulation in Escherichia coli . At 30°C, the dnaAcos mutant causes over-replication of the chromosome, and colony formation is inhibited. We found that, at this temperature, the dnaAcos cells form filaments; therefore, septum formation is inhibited. This inhibition was independent of SfiA, an inhibitor of the septum-forming protein, FtsZ. To identify factors involved in this pathway of inhibition, we isolated seven multicopy suppressors for the cold-sensitive phenotype of the dnaAcos mutant. One of these proved to be a previously unknown gene, which we named cedA . This gene encoded a 12 kDa protein and resided at 38.9 min on the E. coli genome map. A multicopy supply of the cedA gene to the dnaAcos cells did not repress over-replication of the chromosome but did stimulate cell division of the host, the result being growth of cells with an abnormally elevated chromosomal copy number. Therefore, the expression level of the cedA gene seems to be important for inhibiting cell division of the dnaAcos mutant at 30°C. We propose that over-replication of the chromosome activates a pathway for inhibiting cell division and that the cedA gene modulates this division control. In the dnaA ⁺ background, cedA also seems to affect cell division.     

Cdk5: a new player at synapses

Cdk5 is a member of the cyclin-dependent kinase family. Unlike other conventional Cdks that are major regulators of eukaryotic cell cycle progression, Cdk5 displays diverse functions in neuronal as well as non-neuronal tissues. In particular, accumulating evidence points to the roles of this kinase in CNS development and other cellular processes. In this article, we summarize the functional roles of Cdk5 pertaining to the formation and functions of synapse, a specialized structure for the fundamental functions of neurons.     

Preventing re-replication of chromosomal DNA

To ensure its duplication, chromosomal DNA must be precisely duplicated in each cell cycle, with no sections left unreplicated, and no sections replicated more than once. Eukaryotic cells achieve this by dividing replication into two non-overlapping phases. During late mitosis and G1, replication origins are 'licensed' for replication by loading the minichromosome maintenance (Mcm) 2-7 proteins to form a pre-replicative complex. Mcm2-7 proteins are then essential for initiating and elongating replication forks during S phase. Recent data have provided biochemical and structural insight into the process of replication licensing and the mechanisms that regulate it during the cell cycle.     

Maize DNA polymerase alpha is phosphorylated by a PCNA-associated cyclin/Cdk complex: effect of benzyladenine

The activity of maize DNA polymerases 1 and 2 (delta and alpha-type enzymes, respectively) is stimulated during germination if embryo axes are imbibed in the presence of benzyladenine. In vivo, DNA pol 2 is a phosphorotein that appears to be maximally phosphorylated previous to the S phase start time (by 12 h of germination, Coello and Vázquez-Ramos 1995a). We find that, in vitro, a PCNA-associated cyclin/kinase activity isolated from maize axes acquires an increasing capacity to phosphorylate DNA pol 2 as germination advances; moreover, the PCNA-associated kinase isolated from BA-treated maize axes germinated at 3 h phosphorylates DNA pol 2 at the same level observed in samples of axes germinated for 13 h in the absence of exogenous BA. PCNA-associated kinase activity from BA-treated axes germinated at 13 h maximal using DNA pol 2 as substrate. However, there is no modification in DNA polymerase activity as a consequence of protein phosphorylation. Results are discussed in terms of their significance for cell cycle regulation during seed germination.     

Senescence associated with the over-replication of a mitochondrial retroplasmid in Neurospora crassa

Mitochondrial DNA rearrangements and deletions are a prevailing feature of filamentous fungal cultures that undergo senescence. In Neurospora spp., strains containing the Mauriceville and Varkud mitochondrial retroplasmids routinely senesce at elevated temperatures, a process that is initiated by the integration of variant forms of the plasmids into the mitochondrial genome. Here, we describe a strain that is phenotypically distinguishable from previously characterized senescent strains and show that senescence can occur in the absence of plasmid integration and associated alterations in mitochondrial DNA. The MS4416 strain contains a unique variant of the Mauriceville retroplasmid, and undergoes senescence at highly predictable frequencies at 37°, 25° and 18 °C. Decline in vegetative growth rate correlates with increased levels of the variant plasmid and alterations in the synthesis of mitochondrially encoded proteins, suggesting that plasmid over-replication interferes with mitochondrial translation. We also report the isolation of a mutant strain that escapes senescence yet still maintains high levels of the variant plasmid. Its ability to tolerate a growth-suppressive retroplasmid suggests that there are mechanisms in Neurospora which compensate for the deleterious effects that plasmid over-replication has on mitochondrial function. Received: 12 July 1999 / Accepted: 17 December 1999     

Homology in coding and non-coding DNA sequences: a parsimony perspective

Putative synapomorphy assessment (primary homology assessment) is distinct for DNA strings having a codon structure (hereafter, coding DNA) versus those lacking it (hereafter, non-coding DNA). The first requires the identification of a reading frame and of usually few in-frame insertions and deletions. In non-coding DNA, where length variation is much more common, putative synapomorphy assessment is considerably less straightforward and highly depends on the alignment method. Appreciating the existence of evolutionary constraints, alignments that consider patterns associated with specific putative evolutionary events are favored. Once the sequences have been aligned, the postulated putative evolutionary events need to be coded as an additional step. In order for the alignments and the alignment coding to be falsifiable, they should be carried out using justified and explicitly formulated criteria. Alternative coding methods for the most common patterns present in alignments of non-coding DNA are discussed here. Simpler putative synapomorphy assessment will not always correlate to more reliable phylogenetic information because simplicity does not necessarily correlate to the degree of homoplasy. The use of non-coding DNA can result in more laborious coding, but at the same time in more corroborated hypotheses, mirroring their accuracy for phylogenetic inference.     

DNA structure, nucleosome placement and chromatin remodelling: a perspective

A major question in chromatin biology is to what extent the sequence of DNA directly determines the genetic and chromatin organization of a eukaryotic genome? We consider two aspects to this question: the DNA sequence-specified positioning of nucleosomes and the determination of NDRs (nucleosome-depleted regions) or barriers. We argue that, in budding yeast, while DNA sequence-specified nucleosome positioning may contribute to positions flanking the regions lacking nucleosomes, DNA thermodynamic stability is a major component determinant of the genetic organization of this organism.     

A dual role of Cdk2 in DNA damage response

Once it was believed that Cdk2 was the master regulator of S phase entry. Gene knockout mouse studies of cell cycle regulators revealed that Cdk2 is dispensable for S phase initiation and progression whereby Cdk1 can compensate for the loss of Cdk2. Nevertheless, recent evidence indicates that Cdk2 is involved in cell cycle independent functions such as DNA damage repair. Whether these properties are unique to Cdk2 or also being compensated by other Cdks in the absence of Cdk2 is under extensive investigation. Here we review the emerging new role of Cdk2 in DNA damage repair and also discuss how the loss of Cdk2 impacts the G₁/S phase DNA damage checkpoint.