Histone H3 and H4 Ubiquitylation by the CUL4-DDB-ROC1 Ubiquitin Ligase Facilitates Cellular Response to DNA Damage

Chromatin structure following UV-induced DNA damage-repair or death?

In eukaryotes, DNA is compacted into a complex structure known as chromatin. The unravelling of DNA is a crucial step in DNA repair, replication, transcription and recombination as this allows access to DNA for these processes. Failure to package DNA into the nucleosome, the individual unit of chromatin, can lead to genomic instability, driving a cell into apoptosis, senescence, or cellular proliferation. Ultraviolet (UV) radiation damage causes destabilisation of chromatin integrity. UV irradiation induces DNA damage such as photolesions and subjects the chromatin to substantial rearrangements, causing the arrest of transcription forks and cell cycle arrest. Highly conserved processes known as nucleotide and base excision repair (NER and BER) then begin to repair these lesions. However, if DNA repair fails, the cell may be forced into apoptosis. The modification of various histones as well as nucleosome remodelling via ATP-dependent chromatin remodelling complexes are required not only to repair these UV-induced DNA lesions, but also for apoptosis signalling. Histone modifications and nucleosome remodelling in response to UV also lead to the recruitment of various repair and pro-apoptotic proteins. Thus, the way in which a cell responds to UV irradiation via these modifications is important in determining its fate. Failure of these DNA damage response steps can lead to cellular proliferation and oncogenic development, causing skin cancer, hence these chromatin changes are critical for a proper response to UV-induced injury.

Regulation of nucleotide excision repair by UV-DDB: prioritization of damage recognition to internucleosomal DNA

This study reveals the molecular mechanism by which the nucleotide excision repair protein DDB2 prioritises excision of UV-induced DNA lesions in the nucleosome landscape.

How tightly packed chromatin is thoroughly inspected for DNA damage is one of the fundamental unanswered questions in biology. In particular, the effective excision of carcinogenic lesions caused by the ultraviolet (UV) radiation of sunlight depends on UV-damaged DNA-binding protein (UV-DDB), but the mechanism by which this DDB1-DDB2 heterodimer stimulates DNA repair remained enigmatic. We hypothesized that a distinctive function of this unique sensor is to coordinate damage recognition in the nucleosome repeat landscape of chromatin. Therefore, the nucleosomes of human cells have been dissected by micrococcal nuclease, thus revealing, to our knowledge for the first time, that UV-DDB associates preferentially with lesions in hypersensitive, hence, highly accessible internucleosomal sites joining the core particles. Surprisingly, the accompanying CUL4A ubiquitin ligase activity is necessary to retain the xeroderma pigmentosum group C (XPC) partner at such internucleosomal repair hotspots that undergo very fast excision kinetics. This CUL4A complex thereby counteracts an unexpected affinity of XPC for core particles that are less permissive than hypersensitive sites to downstream repair subunits. That UV-DDB also adopts a ubiquitin-independent function is evidenced by domain mapping and in situ protein dynamics studies, revealing direct but transient interactions that promote a thermodynamically unfavorable β-hairpin insertion of XPC into substrate DNA. We conclude that the evolutionary advent of UV-DDB correlates with the need for a spatiotemporal organizer of XPC positioning in higher eukaryotic chromatin.

Like all molecules in living organisms, DNA undergoes spontaneous decay and is constantly under attack by endogenous and environmental agents. Unlike other molecules, however, DNA—the blueprint of heredity—cannot be re-created de novo; it can only be copied. The original blueprint must therefore remain pristine. All kinds of DNA damage pose a health hazard. DNA lesions induced by the ultraviolet (UV) component of sunlight, for example, can lead to skin aging and skin cancer. A repair process known as nucleotide excision repair (NER) is dedicated to correcting this UV damage. Although the enzymatic steps of this repair process are known in detail, we still do not understand how it copes with the native situation in the cell, where the DNA is tightly wrapped around protein spools called nucleosomes. Our study has revealed the molecular mechanism by which an enigmatic component of NER called UV-DDB stimulates excision of UV-induced lesions in the landscape of nucleosome-packaged DNA in human skin cells. In particular, we describe how this accessory protein prioritizes, in space and time, which UV lesions in packaged DNA to target for repair by NER complexes, thus optimizing the repair process.

Multiple DNA damage recognition factors involved in mammalian nucleotide excision repair

The nucleotide excision repair (NER) subpathway operating throughout the mammalian genome is a versatile DNA repair system that can remove a wide variety of helix-distorting base lesions. This system contributes to prevention of blockage of DNA replication by the lesions, thereby suppressing mutagenesis and carcinogenesis. Therefore, it is of fundamental significance to understand how the huge genome can be surveyed for occurrence of a small number of lesions. Recent studies have revealed that this difficult task seems to be accomplished through sequential actions of multiple DNA damage recognition factors, including UV-DDB, XPC, and TFIIH. Notably, these factors adopt completely different strategies to recognize DNA damage. XPC detects disruption and/or destabilization of the base pairing, which ensures a broad spectrum of substrate specificity for global genome NER. In contrast, UV-DDB directly recognizes particular types of lesions, such as UV-induced photoproducts, thereby vitally recruiting XPC as well as further extending the substrate specificity. After DNA binding by XPC, moreover, the helicase activity associated with TFIIH scans a DNA strand to make a final search for the presence of aberrant chemical modifications of DNA. The combination of these different strategies makes a crucial contribution to simultaneously achieving efficiency, accuracy, and versatility of the entire repair system.

V(D)J recombination: mechanisms of initiation

V(D)J recombination assembles immunoglobulin and T cell receptor genes during lymphocyte development through a series of carefully orchestrated DNA breakage and rejoining events. DNA cleavage requires a series of protein-DNA complexes containing the RAG1 and RAG2 proteins and recombination signals that flank the recombining gene segments. In this review, we discuss recent advances in our understanding of the function and domain organization of the RAG proteins, the composition and structure of RAG-DNA complexes, and the pathways that lead to the formation of these complexes. We also consider the functional significance of RAG-mediated histone recognition and ubiquitin ligase activities, and the role played by RAG in ensuring proper repair of DNA breaks made during V(D)J recombination. Finally, we propose a model for the formation of RAG-DNA complexes that involves anchoring of RAG1 at the recombination signal nonamer and RAG2-dependent surveillance of adjoining DNA for suitable spacer and heptamer sequences.

Nucleotide Excision Repair in Caenorhabditis elegans

Nucleotide excision repair (NER) plays an essential role in many organisms across life domains to preserve and faithfully transmit DNA to the next generation. In humans, NER is essential to prevent DNA damage-induced mutation accumulation and cell death leading to cancer and aging. NER is a versatile DNA repair pathway that repairs many types of DNA damage which distort the DNA helix, such as those induced by solar UV light. A detailed molecular model of the NER pathway has emerged from in vitro and live cell experiments, particularly using model systems such as bacteria, yeast, and mammalian cell cultures. In recent years, the versatility of the nematode C. elegans to study DNA damage response (DDR) mechanisms including NER has become increasingly clear. In particular, C. elegans seems to be a convenient tool to study NER during the UV response in vivo, to analyze this process in the context of a developing and multicellular organism, and to perform genetic screening. Here, we will discuss current knowledge gained from the use of C. elegans to study NER and the response to UV-induced DNA damage.

Chromatin and the DNA damage response: the cancer connection

The integrity of the human genome is constantly threatened by genotoxic agents that cause DNA damage. Inefficient or inaccurate repair of DNA lesions triggers genome instability and can lead to cancer development or even cell death. Cells counteract the adverse effects of DNA lesions by activating the DNA damage response (DDR), which entails a coordinated series of events that regulates cell cycle progression and repair of DNA lesions. Efficient DNA repair in living cells is complicated by the packaging of genomic DNA into a condensed, often inaccessible structure called chromatin. Cells utilize post-translational histone modifications and ATP-dependent chromatin remodeling to modulate chromatin structure and increase the accessibility of the repair machinery to lesions embedded in chromatin. Here we review and discuss our current knowledge and recent advances on DNA damage-induced chromatin changes and their implications for the mammalian DNA damage response, genome stability and carcinogenesis. Exploiting our improving understanding of how modulators of chromatin structure orchestrate the DDR may provide new avenues to improve cancer management.

Cullin 4B protein ubiquitin ligase targets peroxiredoxin III for degradation

Cullin 4B (CUL4B) is a scaffold protein that assembles cullin-RING ubiquitin ligase (E3) complexes. Recent studies have revealed that germ-line mutations in CUL4B can cause mental retardation, short stature, and many other abnormalities in humans. Identifying specific CUL4B substrates will help to better understand the physiological functions of CUL4B. Here, we report the identification of peroxiredoxin III (PrxIII) as a novel substrate of the CUL4B ubiquitin ligase complex. Two-dimensional gel electrophoresis coupled with mass spectrometry showed that PrxIII was among the proteins up-regulated in cells after RNAi-mediated CUL4B depletion. The impaired degradation of PrxIII observed in CUL4B knockdown cells was confirmed by Western blot. We further demonstrated that DDB1 and ROC1 in the DDB1-CUL4B-ROC1 complex are also indispensable for the proteolysis of PrxIII. In addition, the degradation of PrxIII is independent of CUL4A, a cullin family member closely related to CUL4B. In vitro and in vivo ubiquitination assays revealed that CUL4B promoted the polyubiquitination of PrxIII. Furthermore, we observed a significant decrease in cellular reactive oxygen species (ROS) production in CUL4B-silenced cells, which was associated with increased resistance to hypoxia and H(2)O(2)-induced apoptosis. These findings are discussed with regard to the known function of PrxIII as a ROS scavenger and the high endogenous ROS levels required for neural stem cell proliferation. Together, our study has identified a specific target substrate of CUL4B ubiquitin ligase that may have significant implications for the pathogenesis observed in patients with mutations in CUL4B.

Nucleotide excision repair in chromatin: damage removal at the drop of a HAT

In an earlier review of our understanding of the mechanism of nucleotide excision repair (NER) we examined the process with respect to how it occurs in chromatin [1]. We described how much of our mechanistic understanding of NER was derived from biochemical studies that analysed the repair reaction in DNA substrates not representative of that which exists in the living cell. We pointed out that our efforts to understand how NER operates in chromatin had been hampered in part because of the well-known inhibition of NER that occurs when DNA is assembled into nucleosomes and used as the substrate to examine the repair reaction in vitro. Despite this technical bottleneck, we summarized the biochemical, genetic and cell-based studies which have provided insights into the molecular mechanism of NER in the cellular context. More recently, we revisited the topic of how UV induced DNA damage is repaired in chromatin. In this review we examined the commonly held view that depicts a struggle in which the DNA repair machinery battles to overcome the inhibitory effect of chromatin during the repair process. We suggested that in this interpretation of events, the DNA repair mechanisms might be described as 'tilting at windmills': fighting an imaginary foe [2]. We surmised that this scenario was overly simplistic, and we described an emerging picture in which the DNA repair process and chromatin remodeling were mechanistically linked and were in fact functioning cooperatively to organize the efficient removal of DNA damage from the genome. Here we discuss the latest findings, which contribute to the idea that DNA damage induced changes to chromatin represent an important way in which the DNA repair process is initiated and organized throughout the genome to promote the efficient removal of damage in response to UV radiation.

Regulation of the DNA Damage Response to DSBs by Post-Translational Modifications

Damage to the genetic material can affect cellular function in many ways. Therefore, maintenance of the genetic integrity is of primary importance for all cells. Upon DNA damage, cells respond immediately with proliferation arrest and repair of the lesion or apoptosis. All these consequences require recognition of the lesion and transduction of the information to effector systems. The accomplishment of DNA repair, but also of cell cycle arrest and apoptosis furthermore requires protein-protein interactions and the formation of larger protein complexes. More recent research shows that the formation of many of these aggregates depends on post-translational modifications. In this article, we have summarized the different cellular events in response to a DNA double strand break, the most severe lesion of the DNA.

Gene expression profile in cultured human umbilical vein endothelial cells exposed to a 300 mT static magnetic field

In a previous investigation we reported that exposure to a moderate (300 mT) static magnetic field (SMF) causes transient DNA damage and promotes mitochondrial biogenesis in human umbilical vein endothelial cells (HUVECs). To better understand the response of HUVECs to the 300 mT SMF, a high-quality subtracted cDNA library representative of genes induced in cells after 4 h of static magnetic exposure was constructed. The global gene expression profile showed that several genes were induced after the SMF exposure. The characterized clones are involved in cell metabolism, energy, cell growth/division, transcription, protein synthesis, destination and storage, membrane injury, DNA damage/repair, and oxidative stress response. Quantitative real-time polymerase chain reaction (qRT-PCR) experiments were performed at 4 and 24 h on four selected genes. Their expression profiles suggest that HUVEC's response to SMF exposure is transient. Furthermore, compared to control cells, an up-regulation of several genes involved in cell growth and division was observed. This up-regulation is likely to be the cause of the slight, but significant, increase in cell proliferation at 12 h post-treatment. These results provide additional support to the notion that SMFs may be harmless to human health, and could support the rationale for their possible use in medical treatments.

Determinants and dynamics of genome accessibility

In eukaryotes, all DNA-templated reactions occur in the context of chromatin. Nucleosome packaging inherently restricts DNA accessibility for regulatory proteins but also provides an opportunity to regulate DNA-based processes through modulating nucleosome positions and local chromatin structure. Recent advances in genome-scale methods are yielding increasingly detailed profiles of the genomic distribution of nucleosomes, their modifications and their modifiers. The picture now emerging is one in which the dynamic control of genome accessibility is governed by contributions from DNA sequence, ATP-dependent chromatin remodelling and nucleosome modifications. Here we discuss the interplay of these processes by reviewing our current understanding of how chromatin access contributes to the regulation of transcription, replication and repair.

Enzymatic assays for assessing histone deubiquitylation activity

While the post-translational modification of histones by the addition of ubiquitin was discovered decades ago, it has only recently been appreciated that the dynamic regulation of histone ubiquitylation patterns is an important mechanism for controlling a variety of biological processes. The processes include transcription, the recognition and repair of genomic damage and DNA replication, among others. Enzymes that catalyze the addition of ubiquitin to histones, such as the polycomb family, have been well-studied. In contrast, the enzymes that remove ubiquitin from histones are less well understood. The assay strategies described here provide a platform for the thorough in vitro and in vivo analysis of histone deubiquitylation. In some cases, these poorly characterized enzymes are likely to provide new opportunities for therapeutic targeting and a detailed understanding of their biochemical and biological activities is a prerequisite to these clinical advances.

Purification of histone ubiquitin ligases from HeLa cells

Posttranslational histone modifications play an important role in regulating chromatin based nuclear processes including transcription. Of these modifications, histone ubiquitination is among the least understood. Histone ubiquitination predominately targets histones H2A and H2B. While ubiquitination of H2B is evolutionarily conserved from budding yeast to mammals, ubiquitination of H2A has not been detected in budding yeast, worms, or plants. Until recently, studies of histone ubiquitination lagged far behind the study of other histone modifications, largely because antibodies specific for ubiquitinated histones are difficult to generate. Despite this obstacle, the identification of the enzymatic machineries involved in histone ubiquitination, together with the successful use of a combination of genetic and immunoblot approaches to detect ubiquitinated histones, have helped to reveal important regulatory roles for this modification in transcriptional initiation and elongation, cell cycle progression, and DNA damage response. With the aid of the recently developed ubiquitinated histone-specific antibodies, an intriguing link between histone ubiquitination and cancer development has been established. While the enzymes involved in H2B ubiquitination were identified first in budding yeast and subsequently in higher organisms based on gene homology, the identification of the enzymatic machineries involved in H2A ubiquitination largely depended on a biochemical purification approach. The unbiased search for ubiquitin ligases targeting histones also led to the identification of a H3 and H4 ubiquitin ligase. Here we detail a protocol for the biochemical approach to identify histone ubiquitin ligase(s) from HeLa cells. Similar approaches have been successfully used to identify histone methyltransferases, histone demethylases, chromatin remodeling factors, and general transcription factors. So long as an in vitro enzymatic assay can be established, the approach we describe can be easily adapted to identify other histone and non-histone modifying enzymes.

Mms1 and Mms22 stabilize the replisome during replication stress

A mechanism is shown by which Mms1 and Mms22 promote DNA replication in the presence of replication stress: they stabilize the replisome at stalled replication forks.

Mms1 and Mms22 form a Cul4^Ddb1-like E3 ubiquitin ligase with the cullin Rtt101. In this complex, Rtt101 is bound to the substrate-specific adaptor Mms22 through a linker protein, Mms1. Although the Rtt101^Mms1/Mms22 ubiquitin ligase is important in promoting replication through damaged templates, how it does so has yet to be determined. Here we show that mms1Δ and mms22Δ cells fail to properly regulate DNA replication fork progression when replication stress is present and are defective in recovery from replication fork stress. Consistent with a role in promoting DNA replication, we find that Mms1 is enriched at sites where replication forks have stalled and that this localization requires the known binding partners of Mms1—Rtt101 and Mms22. Mms1 and Mms22 stabilize the replisome during replication stress, as binding of the fork-pausing complex components Mrc1 and Csm3, and DNA polymerase ε, at stalled replication forks is decreased in mms1Δ and mms22Δ. Taken together, these data indicate that Mms1 and Mms22 are important for maintaining the integrity of the replisome when DNA replication forks are slowed by hydroxyurea and thereby promote efficient recovery from replication stress.

Detecting UV-lesions in the genome: The modular CRL4 ubiquitin ligase does it best!

The DDB1-DDB2-CUL4-RBX1 complex serves as the primary detection device for UV-induced lesions in the genome. It simultaneously functions as a CUL4 type E3 ubiquitin ligase. We review the current understanding of this dual function ubiquitin ligase and damage detection complex. The DDB2 damage binding module is merely one of a large family of possible DDB1-CUL4 associated factors (DCAF), most of which are substrate receptors for other DDB1-CUL4 complexes. DDB2 and the Cockayne-syndrome A protein (CSA) function in nucleotide excision repair, whereas the remaining receptors operate in a wide range of other biological pathways. We will examine the modular architecture of DDB1-CUL4 in complex with DDB2, CSA and CDT2 focusing on shared architectural, targeting and regulatory principles.

COP9 signalosome function in the DDR

The COP9 signalosome (CSN) is a platform for protein communication in eukaryotic cells. It has an intrinsic metalloprotease that removes the ubiquitin (Ub)-like protein Nedd8 from cullins. CSN-mediated deneddylation regulates culling-RING Ub ligases (CRLs) and controls ubiquitination of proteins involved in DNA damage response (DDR). CSN forms complexes with CRLs containing cullin 4 (CRL4s) which act on chromatin playing crucial roles in DNA repair, checkpoint control and chromatin remodeling. Furthermore, via associated kinases the CSN controls the stability of DDR effectors such as p53 and p27 and thereby the DDR outcome. DDR is a protection against cancer and deregulation of CSN function causes cancer making it an attractive pharmacological target. Here we review current knowledge on CSN function in DDR.

Cul4A is essential for spermatogenesis and male fertility

The mammalian Cul4 genes, Cul4A and Cul4B, encode the scaffold components of the cullin-based E3 ubiquitin ligases. The two Cul4 genes are functionally redundant. Recent study indicated that mice expressing a truncated CUL4A that fails to interact with its functional partner ROC1 exhibit no developmental phenotype. We generated a Cul4A-/- strain lacking exons 4-8 that does not express any detectable truncated protein. In this strain, the male mice are infertile and exhibit severe deficiencies in spermatogenesis. The primary spermatocytes are deficient in progression through late prophase I, a time point when expression of the X-linked Cul4B gene is silenced due to meiotic sex chromosome inactivation. Testes of the Cul4A-/- mice exhibit extensive apoptosis. Interestingly, the pachytene spermatocytes exhibit persistent double stranded breaks, suggesting a deficiency in homologous recombination. Also, we find that CUL4A localizes to the double stranded breaks generated in pre-pachytene spermatocytes. The observations identify a novel function of CUL4A in meiotic recombination and demonstrate an essential role of CUL4A in spermatogenesis.

Structure and function of WD40 domain proteins

The WD40 domain exhibits a β-propeller architecture, often comprising seven blades. The WD40 domain is one of the most abundant domains and also among the top interacting domains in eukaryotic genomes. In this review, we will discuss the identification, definition and architecture of the WD40 domains. WD40 domain proteins are involved in a large variety of cellular processes, in which WD40 domains function as a protein-protein or protein-DNA interaction platform. WD40 domain mediates molecular recognition events mainly through the smaller top surface, but also through the bottom surface and sides. So far, no WD40 domain has been found to display enzymatic activity. We will also discuss the different binding modes exhibited by the large versatile family of WD40 domain proteins. In the last part of this review, we will discuss how post-translational modifications are recognized by WD40 domain proteins.

Genotoxic stress and DNA repair in plants: emerging functions and tools for improving crop productivity

Crop productivity is strictly related to genome stability, an essential requisite for optimal plant growth/development. Genotoxic agents (e.g., chemical agents, radiations) can cause both chemical and structural damage to DNA. In some cases, they severely affect the integrity of plant genome by inducing base oxidation, which interferes with the basal processes of replication and transcription, eventually leading to cell death. The cell response to oxidative stress includes several DNA repair pathways, which are activated to remove the damaged bases and other lesions. Information concerning DNA repair in plants is still limited, although results from gene profiling and mutant analysis suggest possible differences in repair mechanisms between plants and other eukaryotes. The present review focuses on the base- and nucleotide excision repair (BER, NER) pathways, which operate according to the most common DNA repair rule (excision of damaged bases and replacement by the correct nucleotide), highlighting the most recent findings in plants. An update on DNA repair in organelles, chloroplasts and mitochondria is also provided. Finally, it is generally acknowledged that DNA repair plays a critical role during seed imbibition, preserving seed vigor. Despite this, only a limited number of studies, described here, dedicated to seeds are currently available.

The conserved factor DE-ETIOLATED 1 cooperates with CUL4-DDB1DDB2 to maintain genome integrity upon UV stress

Plants and many other eukaryotes can make use of two major pathways to cope with mutagenic effects of light, photoreactivation and nucleotide excision repair (NER). While photoreactivation allows direct repair by photolyase enzymes using light energy, NER requires a stepwise mechanism with several protein complexes acting at the levels of lesion detection, DNA incision and resynthesis. Here we investigated the involvement in NER of DE-ETIOLATED 1 (DET1), an evolutionarily conserved factor that associates with components of the ubiquitylation machinery in plants and mammals and acts as a negative repressor of light-driven photomorphogenic development in Arabidopsis. Evidence is provided that plant DET1 acts with CULLIN4-based ubiquitin E3 ligase, and that appropriate dosage of DET1 protein is necessary for efficient removal of UV photoproducts through the NER pathway. Moreover, DET1 is required for CULLIN4-dependent targeted degradation of the UV-lesion recognition factor DDB2. Finally, DET1 protein is degraded concomitantly with DDB2 upon UV irradiation in a CUL4-dependent mechanism. Altogether, these data suggest that DET1 and DDB2 cooperate during the excision repair process.

Epigenetic regulation by nuclear receptors

Nuclear receptors (NRs) represent a vital class of ligand-activated transcription factors responsible for coordinately regulating the expression of genes involved in numerous biological processes. Transcriptional regulation by NRs is conducted through interactions with multiple coactivator or corepressor complexes that modify the chromatin environment to facilitate or inhibit RNA polymerase II binding and transcription initiation. In recent years, studies have identified specific biological roles for cofactors mediating NR signaling through epigenetic modifications such as acetylation and methylation of histones. Intriguingly, genome-wide analysis of NR and cofactor localization has both confirmed findings from single-gene studies and revealed new insights into the relationships between NRs, cofactors and target genes in determining gene expression. Here, we review recent developments in the understanding of epigenetic regulation by NRs across the genome within the context of the well-established background of cofactor complexes and their roles in histone modification.

Dynamic recruitment of licensing factor Cdt1 to sites of DNA damage

For genomic integrity to be maintained, the cell cycle and DNA damage responses must be linked. Cdt1, a G1-specific cell-cycle factor, is targeted for proteolysis by the Cul4-Ddb1(Cdt2) ubiquitin ligase following DNA damage. Using a laser nanosurgery microscope to generate spatially restricted DNA damage within the living cell nucleus, we show that Cdt1 is recruited onto damaged sites in G1 phase cells, within seconds of DNA damage induction. PCNA, Cdt2, Cul4, DDB1 and p21(Cip1) also accumulate rapidly to damaged sites. Cdt1 recruitment is PCNA-dependent, whereas PCNA and Cdt2 recruitment are independent of Cdt1. Fitting of fluorescence recovery after photobleaching profiles to an analytic reaction-diffusion model shows that Cdt1 and p21(Cip1) exhibit highly dynamic binding at the site of damage, whereas PCNA appears immobile. Cdt2 exhibits both a rapidly exchanging and an apparently immobile subpopulation. Our data suggest that PCNA provides an immobile binding interface for dynamic Cdt1 interactions at the site of damage, which leads to rapid Cdt1 recruitment to damaged DNA, preceding Cdt1 degradation.

MSI4/FVE interacts with CUL4-DDB1 and a PRC2-like complex to control epigenetic regulation of flowering time in Arabidopsis

Flowering at the right time is crucial to ensure successful plant reproduction and seed yield and is dependent on both environmental and endogenous parameters. Among the different pathways that impinge on flowering, the autonomous pathway promotes floral transition independently of day length through the repression of the central flowering repressor flowering locus C (FLC). FLC blocks floral transition by repressing flowering time integrators such as flowering locus T (FT). MSI4/FVE is a key regulator of the autonomous pathway that reduces FLC expression. Here we report that the MSI4 protein is a DDB1 and CUL4-associated factor that represses FLC expression through its association with a CLF-Polycomb Repressive Complex 2 (PRC2) in Arabidopsis. Thus, the lack of MSI4 or decreased CUL4 activity reduces H3K27 trimethylation on FLC, but also on its downstream target FT, resulting in increased expression of both genes. Moreover, CUL4 interacts with FLC chromatin in an MSI4-dependant manner, and the interaction between MSI4 and CUL4-DDB1 is necessary for the epigenetic repression of FLC. Overall our work provides evidence for a unique functional interaction between the cullin-RING ubiquitin ligase (CUL4-DDB1(MSI4)) and a CLF-PRC2 complex in the regulation of flowering timing in Arabidopsis.

The RAG1 V(D)J recombinase/ubiquitin ligase promotes ubiquitylation of acetylated, phosphorylated histone 3.3

Histone variant H3.3 is associated with transcriptionally active chromatin and accumulates at loci undergoing preparation for V(D)J recombination, a DNA rearrangement required for the assembly of antigen receptors and development of B and T lymphocytes. Here we demonstrate that the RAG1 V(D)J recombinase protein promotes ubiquitylation of H3.3 that has been heavily acetylated and phosphorylated on serine 31 (acetyl-H3.3 S31p). A fragment of RAG1 promoted formation of a mono-ubiquitylated H3 product that was identified using mass spectrometry as ubiquitylated acetyl-H3.3 S31p. H3 was ubiquitylated at multiple lysine residues, and correspondingly, di-, tri- and higher-order ubiquitylated products were detected at low levels. Ubiquitylation was dependent on an intact RAG1 RING finger/ubiquitin ligase domain and required additional regions of the RAG1 amino terminus that are likely to interact with H3. Acetylated residues within the H3 amino terminal tail were also required. Purified, recombinant H3.1 and H3.3 were not good substrates, suggesting that post-translational modifications enhance recognition by RAG1. A complex including damage-DNA binding protein has also been shown to ubiquitylate H3 in response to UV treatment, suggesting the H3 ubiquitylation may be a common step in multiple DNA repair pathways.

The Arabidopsis CUL4-DDB1 complex interacts with MSI1 and is required to maintain MEDEA parental imprinting

Protein ubiquitylation regulates a broad variety of biological processes in all eukaryotes. Recent work identified a novel class of cullin-containing ubiquitin ligases (E3s) composed of CUL4, DDB1, and one WD40 protein, believed to act as a substrate receptor. Strikingly, CUL4-based E3 ligases (CRL4s) have important functions at the chromatin level, including responses to DNA damage in metazoans and plants and, in fission yeast, in heterochromatin silencing. Among putative CRL4 receptors we identified MULTICOPY SUPPRESSOR OF IRA1 (MSI1), which belongs to an evolutionary conserved protein family. MSI1-like proteins contribute to different protein complexes, including the epigenetic regulatory Polycomb repressive complex 2 (PRC2). Here, we provide evidence that Arabidopsis MSI1 physically interacts with DDB1A and is part of a multimeric protein complex including CUL4. CUL4 and DDB1 loss-of-function lead to embryo lethality. Interestingly, as in fis class mutants, cul4 mutants exhibit autonomous endosperm initiation and loss of parental imprinting of MEDEA, a target gene of the Arabidopsis PRC2 complex. In addition, after pollination both MEDEA transcript and protein accumulate in a cul4 mutant background. Overall, our work provides the first evidence of a physical and functional link between a CRL4 E3 ligase and a PRC2 complex, thus indicating a novel role of ubiquitylation in the repression of gene expression.

Interactions of transcription factors with chromatin

Sequence-specific transcription factors (TFs) play a central role in regulating transcription initiation by directing the recruitment and activity of the general transcription machinery and accessory factors. It is now well established that many of the effects exerted by TFs in eukaryotes are mediated through interactions with a host of coregulators that modify the chromatin state, resulting in a more open (in case of activation) or closed conformation (in case of repression). The relationship between TFs and chromatin is a two-way street, however, as chromatin can in turn influence the recognition and binding of target sequences by TFs. The aim of this chapter is to highlight how this dynamic interplay between TF-directed remodelling of chromatin and chromatin-adjusted targeting of TF binding determines where and how transcription is initiated, and to what degree it is productive.

Regulation of DNA repair by ubiquitylation

Cellular DNA repair is a frontline system that is responsible for maintaining genome integrity and thus preventing premature aging and cancer by repairing DNA lesions and strand breaks caused by endogenous and exogenous mutagens. However, it is also the principal cellular system in cancer cells that counteracts the killing effect of the major cancer treatments, e.g. chemotherapy and ionizing radiation. Although it is clear that an individual's DNA repair capacity varies, the mechanisms involved in the regulation of repair systems that are responsible for such variations are only just emerging. This knowledge gap is impeding the finding of new cancer therapy targets and the development of novel treatment strategies. In recent years the vital role of post-translational modifications of DNA repair proteins, including ubiquitylation and phosphorylation, has been uncovered. This review will cover recent progress in our understanding of the role of ubiquitylation in the regulation of DNA repair.

Characterization of the Dictyostelium homolog of chromatin binding protein DET1 suggests a conserved pathway regulating cell type specification and developmental plasticity

DET1 (De-etiolated 1) is a chromatin binding protein involved in developmental regulation in both plants and animals. DET1 is largely restricted to multicellular eukaryotes, and here we report the characterization of a DET1 homolog from the social amoeba Dictyostelium discoideum. As in other species, Dictyostelium DET1 is nuclear localized. In contrast to other species, where it is an essential protein, loss of DET1 is nonlethal in Dictyostelium, although viability is significantly reduced. The phenotype of the det1(-) mutant is highly pleiotropic and results in a large degree of heterogeneity in developmental parameters. Loss of DET1 results in delayed and abnormal development with enlarged aggregation territories. Mutant slugs displayed cell type patterning with a bias toward the prestalk pathway. A number of DET1-interacting proteins are conserved in Dictyostelium, and the apparently conserved role of DET1 in regulatory pathways involving the bZIP transcription factors DimB, c-Jun, and HY5 suggests a highly conserved mechanism regulating development in multicellular eukaryotes. While the mechanism by which DET1 functions is unclear, it appears that it has a key role in regulation of developmental plasticity and integration of information on environmental conditions into the developmental program of an organism.

Mass spectrometric analysis of lysine ubiquitylation reveals promiscuity at site level

The covalent attachment of ubiquitin to proteins regulates numerous processes in eukaryotic cells. Here we report the identification of 753 unique lysine ubiquitylation sites on 471 proteins using higher-energy collisional dissociation on the LTQ Orbitrap Velos. In total 5756 putative ubiquitin substrates were identified. Lysine residues targeted by the ubiquitin-ligase system show no unique sequence feature. Surface accessible lysine residues located in ordered secondary regions, surrounded by smaller and positively charged amino acids are preferred sites of ubiquitylation. Lysine ubiquitylation shows promiscuity at the site level, as evidenced by low evolutionary conservation of ubiquitylation sites across eukaryotic species. Among lysine modifications a significant overlap (20%) between ubiquitylation and acetylation at site level highlights extensive competitive crosstalk among these modifications. This site-specific crosstalk is not prevalent among cell cycle ubiquitylations. Between SUMOylation and ubiquitylation the preferred interaction is through mixed-chain conjugation. Overall these data provide novel insights into the site-specific selection and regulatory function of lysine ubiquitylation.

The Ino80 chromatin-remodeling complex restores chromatin structure during UV DNA damage repair

Ino80 facilitates restoration of nucleosome structure during NER-mediated repair of UV-induced lesions.

Chromatin structure is modulated during deoxyribonucleic acid excision repair, but how this is achieved is unclear. Loss of the yeast Ino80 chromatin-remodeling complex (Ino80-C) moderately sensitizes cells to ultraviolet (UV) light. In this paper, we show that INO80 acts in the same genetic pathway as nucleotide excision repair (NER) and that the Ino80-C contributes to efficient UV photoproduct removal in a region of high nucleosome occupancy. Moreover, Ino80 interacts with the early NER damage recognition complex Rad4–Rad23 and is recruited to chromatin by Rad4 in a UV damage–dependent manner. Using a modified chromatin immunoprecipitation assay, we find that chromatin disruption during UV lesion repair is normal, whereas the restoration of nucleosome structure is defective in ino80 mutant cells. Collectively, our work suggests that Ino80 is recruited to sites of UV lesion repair through interactions with the NER apparatus and is required for the restoration of chromatin structure after repair.

Hepatocyte-specific deletion of DDB1 induces liver regeneration and tumorigenesis

Etiologic risk factors for hepatocellular carcinoma can be involved in the transformation process by directly targeting intracellular signaling pathways or by indirectly stimulating chronic cycles of hepatocyte destruction and regeneration. However, the contribution of these two routes to hepatocarcinogenesis has not been determined, partly because of the difficulty in distinguishing damaged and regenerated hepatocytes. Here we report that induced deletion of the damaged DNA binding protein 1 (DDB1) abrogates the self-renewing capacity of hepatocytes, resulting in compensatory proliferation of DDB1-expressing hepatocytes. Constitutive stimulation of this regeneration process leads to development of hepatocellular carcinoma, which surprisingly contains no disruption of the DDB1 gene, indicating a cell-nonautonomous role of DDB1 inactivation in tumor initiation. Our results suggest that viruses and hepatoxins may cause liver tumors by simply driving hepatocyte turnover without directly targeting cancer cells.

Open, repair and close again: chromatin dynamics and the response to UV-induced DNA damage

Due to its link with human pathologies, including cancer, the mechanism of Nucleotide Excision Repair (NER) has been extensively studied. Most of the pathway and players have been defined using in vitro reconstitution experiments. However, in vivo, the NER machinery must deal with the presence of organized chromatin, which in some regions, such as heterochromatin, is highly condensed but still susceptible to DNA damage. A series of events involving different chromatin-remodeling factors and histone-modifying enzymes target chromatin regions that contain DNA lesions. CPDs change the structure of the nucleosome, allowing access to factors that can recognize the lesion. Next, DDB1-DDB2 protein complexes, which mono-ubiquitinate histones H2A, H3, and H4, recognize nucleosomes containing DNA lesions. The ubiquitinated nucleosome facilitates the recruitment of ATP-dependent chromatin-remodeling factors and the XPC-HR23B-Centrin 2 complex to the target region. Different ATP-dependent chromatin-remodeling factors, such as SWI/SNF and INO80, have been identified as having roles in the UV irradiation response prior to the action of the NER machinery. Subsequently, remodeling of the nucleosome allows enzymatic reactions by histone-modifying factors that may acetylate, methylate or demethylate specific histone residues. Intriguingly, some of these histone modifications are dependent on p53. These histone modifications and the remodeling of the nucleosome allow the entrance of TFIIH, XPC and other NER factors that remove the damaged strand; then, gap-filling DNA synthesis and ligation reactions are carried out after excision of the oligonucleotide with the lesion. Finally, after DNA repair, the initial chromatin structure has to be reestablished. Therefore, factors that modulate chromatin dynamics contribute to the NER mechanism, and they are significant in the future design of treatments for human pathologies related to genome instability and the appearance of drug-resistant tumors.

RNAi-based screening identifies the Mms22L-Nfkbil2 complex as a novel regulator of DNA replication in human cells

Cullin 4 (Cul4)-based ubiquitin ligases emerged as critical regulators of DNA replication and repair. Over 50 Cul4-specific adaptors (DNA damage-binding 1 (Ddb1)-Cul4-associated factors; DCAFs) have been identified and are thought to assemble functionally distinct Cul4 complexes. Using a live-cell imaging-based RNAi screen, we analysed the function of DCAFs and Cul4-linked proteins, and identified specific subsets required for progression through G1 and S phase. We discovered C6orf167/Mms22-like protein (Mms22L) as a putative human orthologue of budding yeast Mms22, which, together with cullin Rtt101, regulates genome stability by promoting DNA replication through natural pause sites and damaged templates. Loss of Mms22L function in human cells results in S phase-dependent genomic instability characterised by spontaneous double-strand breaks and DNA damage checkpoint activation. Unlike yeast Mms22, human Mms22L does not stably bind to Cul4, but is degraded in a Cul4-dependent manner and upon replication stress. Mms22L physically and functionally interacts with the scaffold-like protein Nfkbil2 that co-purifies with histones, several chromatin remodelling and DNA replication/repair factors. Together, our results strongly suggest that the Mms22L-Nfkbil2 complex contributes to genome stability by regulating the chromatin state at stalled replication forks.

De novo DNA methyltransferase DNMT3b interacts with NEDD8-modified proteins

DNA methylation and histone modifications play an important role in transcription regulation. In cancer cells, many promoters become aberrantly methylated through the activity of the de novo DNA methyltransferases DNMT3a and DNMT3b and acquire repressive chromatin marks. NEDD8 is a ubiquitin-like protein modifier that is conjugated to target proteins, such as cullins, to regulate their activity, and cullin 4A (CUL4A) in its NEDD8-modified form is essential for repressive chromatin formation. We found that DNMT3b associates with NEDD8-modified proteins. Whereas DNMT3b interacts directly in vitro with NEDD8, conjugation of NEDD8 to target proteins enhances this interaction in vivo. DNMT3b immunoprecipitated two major bands of endogenously NEDDylated proteins at the size of NEDDylated cullins, and indeed DNMT3b interacted with CUL1, CUL2, CUL3, CUL4A, and CUL5. Moreover, DNMT3b preferentially immunoprecipitated the NEDDylated form of endogenous CUL4A. NEDD8 enhanced DNMT3b-dependent DNA methylation. Chromatin immunoprecipitation assays suggest that DNMT3b recruits CUL4A and NEDD8 to chromatin, whereas deletion of Dnmt3b reduces the association of CUL4A and NEDD8 at a repressed promoter in a cancer cell line.

Histone modifications and cancer

It is now widely recognized that epigenetic events are important mechanisms underlying cancer development and progression. Epigenetic information in chromatin includes covalent modifications (such as acetylation, methylation, phosphorylation, and ubiquitination) of core nucleosomal proteins (histones). A recent progress in the field of histone modifications and chromatin research has tremendously enhanced our understanding of the mechanisms underlying the control of key physiological and pathological processes. Histone modifications and other epigenetic mechanisms appear to work together in establishing and maintaining gene activity states, thus regulating a wide range of cellular processes. Different histone modifications themselves act in a coordinated and orderly fashion to regulate cellular processes such as gene transcription, DNA replication, and DNA repair. Interest in histone modifications has further grown over the last decade with the discovery and characterization of a large number of histone-modifying molecules and protein complexes. Alterations in the function of histone-modifying complexes are believed to disrupt the pattern and levels of histone marks and consequently deregulate the control of chromatin-based processes, ultimately leading to oncogenic transformation and the development of cancer. Consistent with this notion, aberrant patterns of histone modifications have been associated with a large number of human malignancies. In this chapter, we discuss recent advances in our understanding of the mechanisms controlling the establishment and maintenance of histone marks and how disruptions of these chromatin-based mechanisms contribute to tumorigenesis. We also suggest how these advances may facilitate the development of novel strategies to prevent, diagnose, and treat human malignancies.

Temporal and spatial regulatory functions of the V(D)J recombinase

In developing lymphocytes, V(D)J recombination is subject to tight spatial and temporal regulation. An emerging body of evidence indicates that some of these constraints, particularly with respect to locus specificity and cell cycle phase, are enforced by regulatory cues that converge directly on the RAG proteins themselves. Active chromatin is bound by RAG-2 through a specific histone modification that may serve the recombinase as an allosteric activator as well as a docking site. RAG-1 possesses intrinsic histone ubiquitin ligase activity, suggesting that the recombinase not only responds to chromatin modification but is itself able to modify chromatin. The cyclin A/Cdk2 component of the cell cycle clock triggers periodic destruction of RAG-2, thereby restricting V(D)J recombination to the G0/G1 cell cycle phases. These examples illustrate that the RAG proteins, in addition to their direct actions on DNA, are able to detect and respond to intracellular signals, thereby coordinating recombinase activity with intracellular processes such as cell division and transcription.

INO80 chromatin remodeling complex promotes the removal of UV lesions by the nucleotide excision repair pathway

The creation of accessible DNA in the context of chromatin is a key step in many DNA functions. To reveal how ATP-dependent chromatin remodeling activities impact DNA repair, we constructed mammalian genetic models for the INO80 chromatin remodeling complex and investigated the impact of loss of INO80 function on the repair of UV-induced photo lesions. We showed that deletion of two core components of the INO80 complex, INO80 and ARP5, significantly hampered cellular removal of UV-induced photo lesions but had no significant impact on the transcription of nucleotide excision repair (NER) factors. Loss of INO80 abolished the assembly of NER factors, suggesting that prior chromatin relaxation is important for the NER incision process. Ino80 and Arp5 are enriched to UV-damaged DNA in an NER-incision-independent fashion, suggesting that recruitment of the remodeling activity likely takes place during the initial stage of damage recognition. These results demonstrate a critical role of INO80 in creating DNA accessibility for the NER pathway and provide direct evidence that repair of UV lesions and perhaps most bulky adduct lesions requires chromatin reconfiguration.

DCAF26, an adaptor protein of Cul4-based E3, is essential for DNA methylation in Neurospora crassa

DNA methylation is involved in gene silencing and genome stability in organisms from fungi to mammals. Genetic studies in Neurospora crassa previously showed that the CUL4-DDB1 E3 ubiquitin ligase regulates DNA methylation via histone H3K9 trimethylation. However, the substrate-specific adaptors of this ligase that are involved in the process were not known. Here, we show that, among the 16 DDB1- and Cul4-associated factors (DCAFs) encoded in the N. crassa genome, three interacted strongly with CUL4-DDB1 complexes. DNA methylation analyses of dcaf knockout mutants revealed that dcaf26 was required for all of the DNA methylation that we observed. In addition, histone H3K9 trimethylation was also eliminated in dcaf26^KO mutants. Based on the finding that DCAF26 associates with DDB1 and the histone methyltransferase DIM-5, we propose that DCAF26 protein is the major adaptor subunit of the Cul4-DDB1-DCAF26 complex, which recruits DIM-5 to DNA regions to initiate H3K9 trimethylation and DNA methylation in N. crassa.

DNA associates with histones to form chromatin in eukaryotes. Epigenetics refers to DNA and histone modifications in chromatin that persist from one cell generation to the next, controlling gene expression and genome stability. These epigenetic changes are crucial for the development and differentiation of the various cell types in eukaryotes. In this study, we identified DCAF26 as a crucial regulator of DNA methylation. Inactivation of this gene in N. crassa resulted in loss of both DNA methylation and histone H3K9 trimethylation. We found that the resulting severe defects in the development and growth of dcaf26 mutants were similar to those found in cul4, ddb1, and dim-5 mutants, suggesting that these four genes function in the same pathway. Furthermore, we showed that DCAF26 functioned as an adaptor protein for the Cullin4-DDB1 complex to recruit the histone methyltransferase DIM-5 and regulate trimethylation of histone H3K9, which marks DNA for methylation. Our results reveal important roles for DCAF26 in H3K9 trimethylation and DNA methylation in N. crassa and suggest a conserved mechanism for DNA methylation in eukaryotic organisms.

Navigating the nucleotide excision repair threshold

Nucleotide excision repair (NER) is the primary DNA repair pathway that removes helix-distorting DNA strand damage induced by ultraviolet light irradiation or chemical carcinogens to ensure genome integrity. While the core NER proteins that carry out damage recognition, excision, and repair reactions have been identified and extensively characterized, and the NER pathway has been reconstituted in vitro, the regulatory pathways that govern the threshold levels of NER have not been fully elucidated. This mini-review focuses on recently discovered transcriptional and post-translational mechanisms that specify the capacity of NER, and suggests the potential implications of modulating NER activity in cancer prevention and therapeutic intervention.

Chromatin dynamics mediated by histone modifiers and histone chaperones in postreplicative recombination

Eukaryotic chromatin is regulated by chromatin factors such as histone modification enzymes, chromatin remodeling complexes and histone chaperones in a variety of DNA-dependent reactions. Among these reactions, transcription in the chromatin context is well studied. On the other hand, how other DNA-dependent reactions, including postreplicative homologous recombination, are regulated in the chromatin context remains elusive. Here, histone H3 Lys56 acetylation, mediated by the histone acetyltransferase Rtt109 and the histone chaperone Cia1/Asf1, is shown to be required for postreplicative sister chromatid recombination. This recombination did not occur in the cia1/asf1-V94R mutant, which lacks histone binding and histone chaperone activities and which cannot promote the histone acetyltransferase activity of Rtt109. A defect in another histone chaperone, CAF-1, led to an increase in acetylated H3-K56 (H3-K56-Ac)-dependent postreplicative recombination. Some DNA lesions recognized by the putative ubiquitin ligase complex Rtt101-Mms1-Mms22, which is reported to act downstream of the H3-K56-Ac signaling pathway, seem to be increased in CAF-1 defective cells. Taken together, these data provide the framework for a postreplicative recombination mechanism controlled by histone modifiers and histone chaperones in multiple ways.

Low-dose radiation-induced responses: focusing on epigenetic regulation

PURPOSE

With the widespread use of ionising radiation, the risks of low-dose radiation have been increasingly highlighted for special attention. This review introduces the potential role of epigenetic elements in the regulation of the effects of low-dose radiation.

MATERIALS AND METHODS

The related literature has been analysed according to the topics of DNA methylation, histone modifications, chromatin remodelling and non-coding RNA modulation in low-dose radiation responses.

RESULTS

DNA methylation and radiation can reciprocally regulate effects, especially in the low-dose radiation area. The relationship between histone methylation and radiation mainly exists in the high-dose radiation area; histone deacetylase inhibitors show a promising application to enhance radiation sensitivity, both in the low-dose and high-dose areas; phosphorylated histone 2 AX (H2AX) shows a low sensitivity with 1-15 Gy irradiation as compared with lower dose radiation; and histone ubiquitination plays an important role in DNA damage repair mechanisms. Moreover, chromatin remodelling has an integral role in the repair of DNA double-strand breaks and the response of chromatin to ionising radiation. Finally, the effect of radiation on microRNA expression seems to vary according to cell type, radiation dose, and post-irradiation time point.

CONCLUSION

Small advances have been made in the understanding of epigenetic regulation of low-dose radiation responses. Many questions and blind spots deserve to be investigated. Many new epigenetic elements will be identified in low-dose radiation responses, which may give new insights into the mechanisms of radiation response and their exploitation in radiotherapy.

Drosophila p53 is required to increase the levels of the dKDM4B demethylase after UV-induced DNA damage to demethylate histone H3 lysine 9

Chromatin undergoes a variety of changes in response to UV-induced DNA damage, including histone acetylation. In human and Drosophila cells, this response is affected by mutations in the tumor suppressor p53. In this work, we report that there is a global decrease in trimethylated Lys-9 in histone H3 (H3K9me3) in salivary gland cells in wild type flies in response to UV irradiation. In contrast, flies with mutations in the Dmp53 gene have reduced basal levels of H3K9me3, which are then increased after UV irradiation. The reduction of H3K9me3 in response to DNA damage occurs preferentially in heterochromatin. Our experiments demonstrate that UV irradiation enhances the levels of Lys-9 demethylase (dKDM4B) transcript and protein in wild type flies, but not in Dmp53 mutant flies. Dmp53 binds to a DNA element in the dKdm4B gene as a response to UV irradiation. Furthermore, heterozygous mutants for the dKdm4B gene are more sensitive to UV irradiation; they are deficient in the removal of cyclobutane-pyrimidine dimers, and the decrease of H3K9me3 levels following DNA damage is not observed in dKdm4B mutant flies. We propose that in response to UV irradiation, Dmp53 enhances the expression of the dKDM4B histone demethylase, which demethylates H3K9me3 preferentially in heterochromatin regions. This mechanism appears to be essential for the proper function of the nucleotide excision repair system.

The functions of the HIV1 protein Vpr and its action through the DCAF1.DDB1.Cullin4 ubiquitin ligase

Among the proteins encoded by human and simian immunodeficiency viruses (HIV and SIV) at least three, Vif, Vpu and Vpr, subvert cellular ubiquitin ligases to block the action of anti-viral defenses. This review focuses on Vpr and its HIV2/SIV counterparts, Vpx and Vpr, which all engage the DDB1.Cullin4 ubiquitin ligase complex through the DCAF1 adaptor protein. Here, we discuss the multiple functions that have been linked to Vpr expression and summarize the current knowledge on the role of the ubiquitin ligase complex in carrying out a subset of these activities.

Cullins and cancer

The cullin family of ubiquitin ligases can potentially assemble hundreds of RING-type E3 complexes (CRLs) by utilizing different substrate receptors that share common interaction domains. Cullin receptors dictate substrate specificity, and cullin-mediated substrate degradation controls a wide range of cellular processes, including proliferation, differentiation, and apoptosis. Dysregulation of cullin activity has been shown to contribute to oncogenesis through the accumulation of oncoproteins or the excessive degradation of tumor suppressors. In this review, we will discuss cullin complexes and their substrates, the regulatory pathways that affect cullin activity, and the mechanisms by which cullins may facilitate or inhibit carcinogenesis.

Roles of Vpr and Vpx in modulating the virus-host cell relationship

The human and simian immunodeficiency viruses contain small open reading frames known as vpr and vpx. These genes encode proteins that are highly related both at the amino acid level and functionally, although key differences do exist. This review describes the main functions ascribed to Vpr and Vpx in the context of both viral replication and modulation of host cell biology.