Visualizing the triheteromeric N-methyl-D-aspartate receptor subunit composition.

N-methyl-D-aspartate receptors (NMDARs) are one of three ligand-gated ionotropic channels that transduce the effects of neurotransmitter glutamate at excitatory synapses within the central nervous system. Their ability to influx Ca2+ into cells, unlike mature AMPA or kainate receptors, implicates them in a variety of processes ranging from synaptic plasticity to cell death. Many of the receptor's capabilities, including binding glutamate and regulating Ca2+ influx, have been attributed to their subunit composition, determined putatively using cell biology, electrophysiology and/or pharmacology. Here, we show that subunit composition of synaptic NMDARs can also be readily visualized in acute brain slices (rat) using highly specific antibodies directed against extracellular epitopes of the subunit proteins and high-resolution confocal microscopy. This has helped confirm the expression of triheteromeric t-NMDARs (containing GluN1, GluN2, and GluN3 subunits) at synapses for the first time and reconcile functional differences with diheteromeric d-NMDARs (containing GluN1 and GluN2 subunits) described previously. Even though structural information about individual receptors is still diffraction limited, fluorescently tagged receptor subunit puncta coalesce with precision at various magnifications and/or with the postsynaptic density (PSD-95) but not the presynaptic active zone marker Bassoon. These data are particularly relevant for identifying GluN3A-containing t-NMDARs that are highly Ca2+ permeable and whose expression at excitatory synapses renders neurons vulnerable to excitotoxicity and cell death. Imaging NMDAR subunit proteins at synapses not only offers firsthand insights into subunit composition to correlate function but may also help identify zones of vulnerability within brain structures underlying neurodegenerative diseases like Temporal Lobe Epilepsy.

Histone variants: The unsung guardians of the genome.

Histones H2A, H2B, H3, H4 and H1 are highly conserved, positively charged proteins which form a disc-shaped protein core around which genomic DNA is wrapped to form a nucleosome. Immediately following DNA synthesis, replication-dependent canonical histones help package the DNA into nucleosomes to form compact chromatin fibers that can fit within the confines of the cell nucleus. Histone variants, which vary from the canonical histones in their primary amino acid sequence and expression patterns, replace their canonical counterparts throughout the cell cycle in important biological processes such as transcription, replication, DNA repair and heterochromatin formation. DNA damage is a continual threat to genomic stability and cell survival. Unrepaired DNA lesions are either lethal or can promote mutations if the damaged cells escape programmed cell death due to apoptosis. In order to repair DNA damage, cells use multiple DNA repair pathways, all of which require the recruitment of a multiple DNA damage signaling and repair factors. In order for these repair factors to be recruited efficiently and function properly at sites of DNA damage, the local chromatin environment surrounding the DNA lesion is often altered. Cells are able to regulate chromatin structure in the vicinity of DNA lesions through the addition of posttranslational modifications on histones and DNA, as well as through histone variant incorporation or removal. Recruitment or removal of histone variants at sites of DNA damage can alter the local chromatin structure by destabilizing it and making it more accessible to repair factors. Alternatively, some histone variants and their modifications may also provide specific binding sites for the recruitment of various DNA repair factors, thereby influencing repair pathway choice or repair efficiency, or both. This review seeks to provide an overview of our current understanding of the roles played by histone variants in DNA repair, especially in mammalian cells.

Preparation of Cell Extracts by Cryogrinding in an Automated Freezer Mill.

The ease of genetic manipulation and the strong evolutionary conservation of eukaryotic cellular machinery in the budding yeast Saccharomyces cerevisiae has made it a pre-eminent genetic model organism. However, since efficient protein isolation depends upon optimal disruption of cells, the use of yeast for biochemical analysis of cellular proteins is hampered by its cell wall which is expensive to digest enzymatically (using lyticase or zymolyase), and difficult to disrupt mechanically (using a traditional bead beater, a French press or a coffee grinder) without causing heating of samples, which in turn causes protein denaturation and degradation. Although manual grinding of yeast cells under liquid nitrogen (LN2) using a mortar and pestle avoids overheating of samples, it is labor intensive and subject to variability in cell lysis between operators. For many years, we have been successfully preparing high quality yeast extracts using cryogrinding of cells in an automated freezer mill. The temperature of -196 °C achieved with the use of LN2 protects the biological material from degradation by proteases and nucleases, allowing the retrieval of intact proteins, nucleic acids and other macromolecules. Here we describe this technique in detail for budding yeast cells which involves first freezing a suspension of cells in a lysis buffer through its dropwise addition into LN2 to generate frozen droplets of cells known as "popcorn". This popcorn is then pulverized under LN2 in a freezer mill to generate a frozen "powdered" extract which is thawed slowly and clarified by centrifugation to remove insoluble debris. The resulting extracts are ready for downstream applications, such as protein or nucleic acid purification, proteomic analyses, or co-immunoprecipitation studies. This technique is widely applicable for cell extract preparation from a variety of microorganisms, plant and animal tissues, marine specimens including corals, as well as isolating DNA/RNA from forensic and permafrost fossil specimens.

Treatment of keloids with a single dose of low-energy superficial X-ray radiation to prevent recurrence after surgical excision: An in vitro and in vivo study.

BACKGROUND: Although keloids have been empirically treated with steroids and radiation, evidence-based radiation parameters for keloid therapy are lacking. OBJECTIVE: To determine evidence-based radiation parameters for blocking keloid fibroblast proliferation in vitro and apply them to patients. METHODS: The effects of various radiation parameters and steroids on cell proliferation, cell death, and collagen production in keloid explants and fibroblasts were evaluated with standard assays. Effective radiation parameters were then tested on patients. RESULTS: No differences were observed between the effects of 50 and 320 kV radiation or between single and fractionated radiation doses on keloid fibroblasts. A 3 Gy, 50 kV dose inhibited keloid fibroblast proliferation in culture, whereas 9 Gy completely blocked their outgrowth from explants by inducing multiple cell death pathways and reducing collagen levels. Thirteen of 14 keloids treated with a single 8 Gy, 50 kV dose of radiation did not recur, although 4 patients with 6 keloids were lost to follow-up. LIMITATIONS: Seventy-five percent of patients received steroids for pruritus, whereas approximately 25% of patients were lost to follow-up. CONCLUSIONS: A single 8 Gy dose of superficial 50 kV radiation delivered an average of 34 days after keloid excision maybe sufficient to minimize recurrence, including in individuals resistant to steroids. Higher radiation energies, doses, or fractions may be unnecessary for keloid therapy.

Zika Virus Infection Induces DNA Damage Response in Human Neural Progenitors That Enhances Viral Replication.

Zika virus (ZIKV) infection attenuates the growth of human neural progenitor cells (hNPCs). As these hNPCs generate the cortical neurons during early brain development, the ZIKV-mediated growth retardation potentially contributes to the neurodevelopmental defects of the congenital Zika syndrome. Here, we investigate the mechanism by which ZIKV manipulates the cell cycle in hNPCs and the functional consequence of cell cycle perturbation on the replication of ZIKV and related flaviviruses. We demonstrate that ZIKV, but not dengue virus (DENV), induces DNA double-strand breaks (DSBs), triggering the DNA damage response through the ATM/Chk2 signaling pathway while suppressing the ATR/Chk1 signaling pathway. Furthermore, ZIKV infection impedes the progression of cells through S phase, thereby preventing the completion of host DNA replication. Recapitulation of the S-phase arrest state with inhibitors led to an increase in ZIKV replication, but not of West Nile virus or DENV. Our data identify ZIKV's ability to induce DSBs and suppress host DNA replication, which results in a cellular environment favorable for its replication.IMPORTANCE Clinically, Zika virus (ZIKV) infection can lead to developmental defects in the cortex of the fetal brain. How ZIKV triggers this event in developing neural cells is not well understood at a molecular level and likely requires many contributing factors. ZIKV efficiently infects human neural progenitor cells (hNPCs) and leads to growth arrest of these cells, which are critical for brain development. Here, we demonstrate that infection with ZIKV, but not dengue virus, disrupts the cell cycle of hNPCs by halting DNA replication during S phase and inducing DNA damage. We further show that ZIKV infection activates the ATM/Chk2 checkpoint but prevents the activation of another checkpoint, the ATR/Chk1 pathway. These results unravel an intriguing mechanism by which an RNA virus interrupts host DNA replication. Finally, by mimicking virus-induced S-phase arrest, we show that ZIKV manipulates the cell cycle to benefit viral replication.

Colocalization of distinct NMDA receptor subtypes at excitatory synapses in the entorhinal cortex.

The subunit composition of N-methyl-d-aspartate receptors (NMDARs) at synaptic inputs onto a neuron can either vary or be uniform depending on the type of neuron and/or brain region. Excitatory pyramidal neurons in the frontal and somatosensory cortices (L5), for example, show pathway-specific differences in NMDAR subunit composition in contrast with the entorhinal cortex (L3), where we now show colocalization of NMDARs with distinct subunit compositions at individual synaptic inputs onto these neurons. Subunit composition was deduced electrophysiologically based on alterations of current-voltage relationship ( I-V) profiles, amplitudes, and decay kinetics of minimally evoked, pharmacologically isolated, NMDAR-mediated excitatory postsynaptic currents by known subunit-preferring antagonists. The I-Vs were outwardly rectifying in a majority of neurons assayed (~80%), indicating expression of GluN1/GluN2/GluN3-containing triheteromeric NMDARs ( t-NMDARs) and of the conventional type, reversing close to 0 mV with prominent regions of negative slope, in the rest of the neurons sampled (~20%), indicating expression of GluN1/GluN2-containing diheteromeric NMDARs ( d-NMDARs). Blocking t-NMDARs in neurons with outwardly rectifying I-Vs pharmacologically unmasked d-NMDARs, with all responses antagonized using D-AP5. Coimmunoprecipitation assays of membrane-bound protein complexes isolated from the medial entorhinal area using subunit-selective antibodies corroborated stoichiometry and together suggested the coexpression of t- and d-NMDARs at these synapses. Colocalization of functionally distinct NMDAR subtypes at individual synaptic inputs likely enhances the repertoire of pyramidal neurons for information processing and plasticity within the entorhinal cortex. NEW & NOTEWORTHY The subunit composition of a N-methyl-d-aspartate (NMDA) receptor, which dictates most aspects of its function, can vary between neurons in different brain regions and/or between synaptic inputs onto single neurons. Here we demonstrate colocalization of tri- and diheteromeric-NMDA receptors at the same/single synaptic input onto excitatory neurons in the entorhinal cortex. Synaptic colocalization of distinct NMDAR subtypes might endow entorhinal cortical neurons with the ability to encode distinct patterns of neuronal activity through single synapses.

Histone dosage regulates DNA damage sensitivity in a checkpoint-independent manner by the homologous recombination pathway.

In eukaryotes, multiple genes encode histone proteins that package genomic deoxyribonucleic acid (DNA) and regulate its accessibility. Because of their positive charge, 'free' (non-chromatin associated) histones can bind non-specifically to the negatively charged DNA and affect its metabolism, including DNA repair. We have investigated the effect of altering histone dosage on DNA repair in budding yeast. An increase in histone gene dosage resulted in enhanced DNA damage sensitivity, whereas deletion of a H3-H4 gene pair resulted in reduced levels of free H3 and H4 concomitant with resistance to DNA damaging agents, even in mutants defective in the DNA damage checkpoint. Studies involving the repair of a HO endonuclease-mediated DNA double-strand break (DSB) at the MAT locus show enhanced repair efficiency by the homologous recombination (HR) pathway on a reduction in histone dosage. Cells with reduced histone dosage experience greater histone loss around a DSB, whereas the recruitment of HR factors is concomitantly enhanced. Further, free histones compete with the HR machinery for binding to DNA and associate with certain HR factors, potentially interfering with HR-mediated repair. Our findings may have important implications for DNA repair, genomic stability, carcinogenesis and aging in human cells that have dozens of histone genes.

Novel E3 ubiquitin ligases that regulate histone protein levels in the budding yeast Saccharomyces cerevisiae.

Core histone proteins are essential for packaging the genomic DNA into chromatin in all eukaryotes. Since multiple genes encode these histone proteins, there is potential for generating more histones than what is required for chromatin assembly. The positively charged histones have a very high affinity for negatively charged molecules such as DNA, and any excess of histone proteins results in deleterious effects on genomic stability and cell viability. Hence, histone levels are known to be tightly regulated via transcriptional, posttranscriptional and posttranslational mechanisms. We have previously elucidated the posttranslational regulation of histone protein levels by the ubiquitin-proteasome pathway involving the E2 ubiquitin conjugating enzymes Ubc4/5 and the HECT (Homologous to E6-AP C-Terminus) domain containing E3 ligase Tom1 in the budding yeast. Here we report the identification of four additional E3 ligases containing the RING (Really Interesting New Gene) finger domains that are involved in the ubiquitylation and subsequent degradation of excess histones in yeast. These E3 ligases are Pep5, Snt2 as well as two previously uncharacterized Open Reading Frames (ORFs) YKR017C and YDR266C that we have named Hel1 and Hel2 (for Histone E3 Ligases) respectively. Mutants lacking these E3 ligases are sensitive to histone overexpression as they fail to degrade excess histones and accumulate high levels of endogenous histones on histone chaperones. Co-immunoprecipitation assays showed that these E3 ligases interact with the major E2 enzyme Ubc4 that is involved in the degradation related ubiquitylation of histones. Using mutagenesis we further demonstrate that the RING domains of Hel1, Hel2 and Snt2 are required for histone regulation. Lastly, mutants corresponding to Hel1, Hel2 and Pep5 are sensitive to replication inhibitors. Overall, our results highlight the importance of posttranslational histone regulatory mechanisms that employ multiple E3 ubiquitin ligases to ensure excess histone degradation and thus contribute to the maintenance of genomic stability.

Histone tyrosine phosphorylation comes of age.

Histones were discovered over a century ago and have since been found to be the most extensively posttranslationally modified proteins, although tyrosine phosphorylation of histones had remained elusive until recently. The year 2009 proved to be a landmark year for histone tyrosine (Y) phosphorylation as five research groups independently discovered this modification. Three groups describe phosphorylation of Y142 in the variant histone H2A.X, where it may be involved in the cellular decision making process to either undergo DNA repair or apoptosis in response to DNA damage. Further, one group suggests that phosphorylation of histone H3 on Y99 is crucial for its regulated proteolysis in yeast, while another found that Y41 phosphorylation modulates chromatin architecture and oncogenesis in mammalian cells. These pioneering studies provide the initial conceptual framework for further analyses of the diverse roles of tyrosine phosphorylation on different histones, with far reaching implications for human health and disease.

Excess histone levels mediate cytotoxicity via multiple mechanisms.

The accumulation of excess histone proteins in cells has deleterious consequences such as genomic instability in the form of excessive chromosome loss, enhanced sensitivity to DNA damaging agents and cytotoxicity. Hence, the synthesis of histone proteins is tightly regulated at multiple steps and transcriptional as well as posttranscriptional regulation of histone proteins is well established. Additionally, we have recently demonstrated that histone protein levels are regulated posttranslationally by the DNA damage checkpoint kinase Rad53 and ubiquitin-proteasome dependent proteolysis in the budding yeast. However, the underlying mechanism/s via which excess histones exert their deleterious effects in vivo are not clear. Here we have investigated the mechanistic basis for the deleterious effects of excess histones in budding yeast. We find that the presence of excess histones saturates certain histone modifying enzymes, potentially interfering with their activities. Additionally, excess histones appear to bind non-specifically to DNA as well as RNA, which can adversely affect their metabolism. Microarray analysis revealed that upon overexpression of histone gene pairs, about 240 genes were either up or downregulated by 2-fold or more. Overall, we present evidence that excess histones are likely to mediate their cytotoxic effects via multiple mechanisms that are primarily dependent on inappropriate electrostatic interactions between the positively charged histones and diverse negatively charged molecules in the cell. Our findings help explain the basis for the existence of multiple distinct mechanisms that contribute to the tight control of histone protein levels in cells and highlight their importance in maintaining genomic stability and cell viability.

The effects of repeated social defeat on long-term depressive-like behavior and short-term histone modifications in the hippocampus in male Sprague-Dawley rats.

RATIONALE: Social stress has been linked to several neuropsychiatric diseases, including depression, which is a debilitating disease that has genetic, environmental, and epigenetic underpinnings. OBJECTIVES: This study examined the effects of repeated social defeat on both depressive-like behaviors and histone acetylation in the hippocampus, amygdala, and dorsal prefrontal cortex of male Sprague-Dawley rats. MATERIALS AND METHODS: Subjects were exposed to four consecutive social defeats. Depressive-like behaviors were assayed in the sucrose preference, forced swim, contextual fear, and social approach and avoidance tests. Histone H3 and H4 acetylation in the hippocampus, amygdala, and prefrontal cortex were examined by Western blots under basal conditions and at several time points. We also investigated the potential involvement of N-methyl-D: -aspartic acid (NMDA) receptors and glucocorticoid receptors (GR) by injecting respective antagonists prior to each social defeat and examining their effect on histone acetylation in the hippocampus. RESULTS: Social defeat resulted in behavioral changes in the forced swim, social avoidance, and contextual fear tests nearly 6 weeks after defeat, with no change in sucrose preference. Additionally, histone H3 acetylation was increased in the hippocampus 30 min following the last defeat and was not blocked by antagonism of either NMDA or GR receptors. There were no changes in histone H4 acetylation. CONCLUSIONS: These results indicate that social defeat induces several long-lasting depressive-like behaviors in rats and induces a significant, short-lived increase in H3 acetylation in the hippocampus, although the underlying mechanism behind this change warrants further investigation.

FACT prevents the accumulation of free histones evicted from transcribed chromatin and a subsequent cell cycle delay in G1.

The FACT complex participates in chromatin assembly and disassembly during transcription elongation. The yeast mutants affected in the SPT16 gene, which encodes one of the FACT subunits, alter the expression of G1 cyclins and exhibit defects in the G1/S transition. Here we show that the dysfunction of chromatin reassembly factors, like FACT or Spt6, down-regulates the expression of the gene encoding the cyclin that modulates the G1 length (CLN3) in START by specifically triggering the repression of its promoter. The G1 delay undergone by spt16 mutants is not mediated by the DNA-damage checkpoint, although the mutation of RAD53, which is otherwise involved in histone degradation, enhances the cell-cycle defects of spt16-197. We reveal how FACT dysfunction triggers an accumulation of free histones evicted from transcribed chromatin. This accumulation is enhanced in a rad53 background and leads to a delay in G1. Consistently, we show that the overexpression of histones in wild-type cells down-regulates CLN3 in START and causes a delay in G1. Our work shows that chromatin reassembly factors are essential players in controlling the free histones potentially released from transcribed chromatin and describes a new cell cycle phenomenon that allows cells to respond to excess histones before starting DNA replication.

Histone levels are regulated by phosphorylation and ubiquitylation-dependent proteolysis.

Histone levels are tightly regulated to prevent harmful effects such as genomic instability and hypersensitivity to DNA-damaging agents due to the accumulation of these highly basic proteins when DNA replication slows down or stops. Although chromosomal histones are stable, excess (non-chromatin bound) histones are rapidly degraded in a Rad53 (radiation sensitive 53) kinase-dependent manner in Saccharomyces cerevisiae. Here we demonstrate that excess histones associate with Rad53 in vivo and seem to undergo modifications such as tyrosine phosphorylation and polyubiquitylation, before their proteolysis by the proteasome. We have identified the Tyr 99 residue of histone H3 as being critical for the efficient ubiquitylation and degradation of this histone. We have also identified the ubiquitin conjugating enzymes (E2) Ubc4 and Ubc5, as well as the ubiquitin ligase (E3) Tom1 (temperature dependent organization in mitotic nucleus 1), as enzymes involved in the ubiquitylation of excess histones. Regulated histone proteolysis has major implications for the maintenance of epigenetic marks on chromatin, genomic stability and the packaging of sperm DNA.

Generation and management of excess histones during the cell cycle.

Histones are essential proteins that package the DNA in all eukaryotes into chromosomes. However, histones can accumulate upon a decrease in DNA synthesis that occurs at the end of S-phase or following replication arrest. These positively charged histones can associate non-specifically with the negatively charged DNA and other cellular biomolecules, impairing their normal function. Hence, cells have evolved numerous strategies to limit the generation of excess histones and prevent deleterious effects due to their accumulation. Such strategies for histone regulation are discussed here, with particular emphasis on recent studies that implicate the DNA damage checkpoint kinases in the regulation of histone levels, especially in response to replication inhibition. We have also focused upon the recently discovered regulatory mechanism involving histone proteolysis in the budding yeast. Additionally, we speculate that cells may possess a surveillance mechanism for sensing histone levels, particularly in the G1 and S-phases of the cell cycle. Proper regulation of histone levels has major implications for the maintenance of epigenetic marks on chromatin, genomic stability and the packaging of sperm DNA.

The emergence of regulated histone proteolysis.

Proliferating cells need to synthesize large amounts of histones to rapidly package nascent DNA into nucleosomes. This is a challenging task for cells because changes in rates of DNA synthesis lead to an accumulation of excess histones, which interfere with many aspects of DNA metabolism. In addition, cells need to ensure that histone variants are incorporated at the correct chromosomal location. Recent discoveries have highlighted the importance of regulated histone proteolysis in preventing both the accumulation of excess histones and the mis-incorporation of histone variants at inappropriate loci.

Regulation of histone synthesis and nucleosome assembly.

Histone deposition onto nascent DNA is the first step in the process of chromatin assembly during DNA replication. The process of nucleosome assembly represents a daunting task for S-phase cells, partly because cells need to rapidly package nascent DNA into nucleosomes while avoiding the generation of excess histones. Consequently, cells have evolved a number of nucleosome assembly factors and regulatory mechanisms that collectively function to coordinate the rates of histone and DNA synthesis during both normal cell cycle progression and in response to conditions that interfere with DNA replication.

A Rad53 kinase-dependent surveillance mechanism that regulates histone protein levels in S. cerevisiae.

Rad53 and Mec1 are protein kinases required for DNA replication and recovery from DNA damage in Saccharomyces cerevisiae. Here, we show that rad53, but not mec1 mutants, are extremely sensitive to histone overexpression, as Rad53 is required for degradation of excess histones. Consequently, excess histones accumulate in rad53 mutants, resulting in slow growth, DNA damage sensitivity, and chromosome loss phenotypes that are significantly suppressed by a reduction in histone gene dosage. Rad53 monitors excess histones by associating with them in a dynamic complex that is modulated by its kinase activity. Our results argue that Rad53 contributes to genome stability independently of Mec1 by preventing the damaging effects of excess histones both during normal cell cycle progression and in response to DNA damage.