Non-equilibrium structural dynamics of supercoiled DNA plasmids exhibits asymmetrical relaxation

Many cellular processes occur out of equilibrium. This includes site-specific unwinding in supercoiled DNA, which may play an important role in gene regulation. Here, we use the Convex Lens-induced Confinement (CLiC) single-molecule microscopy platform to study these processes with high-throughput and without artificial constraints on molecular structures or interactions. We use two model DNA plasmid systems, pFLIP-FUSE and pUC19, to study the dynamics of supercoiling-induced secondary structural transitions after perturbations away from equilibrium. We find that structural transitions can be slow, leading to long-lived structural states whose kinetics depend on the duration and direction of perturbation. Our findings highlight the importance of out-of-equilibrium studies when characterizing the complex structural dynamics of DNA and understanding the mechanisms of gene regulation.

Restoration of marine ecosystems: Understanding possible futures for optimal outcomes

Accelerating declines in the extent, quality and functioning of the world's marine ecosystems have generated an upsurge in focus on practical solutions, with ecosystem restoration becoming an increasingly attractive mitigation strategy for systems as diverse as coral reefs, mangroves and tidal flats. While restoration is popular because it promises positive outcomes and a return to something approaching unimpacted condition and functioning, it involves substantial public and private investment, both for the initial restoration activity and for on-going maintenance of the restored asset. This investment often affords one big chance to get things right before irretrievable damage is done. As a result, precise, well considered and accountable decision-making is needed to determine the specific focus for restoration, the scale of restoration, the location for deploying restoration activities, and indeed whether or not restoration is necessary or even possible. We explore the environmental/ecological considerations and constraints governing optimal decisions about the nature, location and prioritisation of restoration activities in marine ecosystems, and in particular the constraints on achieving understanding of possible futures and the likelihood of achieving them. We conclude that action must be informed by a context-specific understanding of the historical situation, the current situation, the constraints on change, the range of potential outcome scenarios, and the potential futures envisioned.

FUBP1 and FUBP2 enforce distinct epigenetic setpoints for MYC expression in primary single murine cells

Physiologically, MYC levels must be precisely set to faithfully amplify the transcriptome, but in cancer MYC is quantitatively misregulated. Here, we study the variation of MYC amongst single primary cells (B-cells and murine embryonic fibroblasts, MEFs) for the repercussions of variable cellular MYC-levels and setpoints. Because FUBPs have been proposed to be molecular “cruise controls” that constrain MYC expression, their role in determining basal or activated MYC-levels was also examined. Growing cells remember low and high-MYC setpoints through multiple cell divisions and are limited by the same expression ceiling even after modest MYC-activation. High MYC MEFs are enriched for mRNAs regulating inflammation and immunity. After strong stimulation, many cells break through the ceiling and intensify MYC expression. Lacking FUBPs, unstimulated MEFs express levels otherwise attained only with stimulation and sponsor MYC chromatin changes, revealed by chromatin marks. Thus, the FUBPs enforce epigenetic setpoints that restrict MYC expression.

Ying Zheng et al. characterize MYC gene and protein expression in single mammalian cells in response to various external signals. They find that individual cells show either high or low basal MYC expression setpoints, and that adherence to these setpoints as well as the magnitude of the response of MYC to stimulation, is controlled by FUBP1 and FUBP2.

Stakeholder engagement in the governance of marine migratory species: barriers and building blocks

Meaningful stakeholder engagement is important to collaborative decision-making and to effective polycentric governance, particularly when managing cross-scale environmental issues like those involving marine migratory species. In this paper, we explore the barriers to, and opportunities for, stakeholder involvement in the governance of threats to marine migratory species in eastern Australia, using semi-structured qualitative interviews and a focus group, as an example of the generic problem of managing migratory species within a large range state with multiple jurisdictions. Respondents identified several barriers to, and opportunities for, improved stakeholder involvement in the governance of marine migratory species, corresponding to 4 main themes: decision-making processes, information sharing, institutional structures, and participation processes. Respondents indicated that the governance system protecting marine turtles, dugongs, humpback whales, and non-threatened migratory shorebirds in eastern Australia would benefit from the introduction of new information pathways, reformed institutional structures (including environmental legislation), and improved participatory pathways for non-government stakeholders. Such changes could help harmonise the process of managing these species, leading to more effective conservation management throughout their range.

Comparison of penetrating and non-penetrating captive bolt in an alternative occipital approach in calves

The objective of this study was to describe the effect of penetrating or non-penetrating captive bolt using an occipital approach in 4–5 month old, Holstein steers weighing between 100–200 kg. Twelve calves were divided into two treatment groups; penetrating captive bolt (PCB; n = 6) and non-penetrating captive bolt (NPCB; n = 6). This sample size was chosen out of convenience and in conjunction with a separate study. Each calf was sedated with xylazine hydrochloride, then a captive-bolt device, outfitted with a standard penetrating bolt or a non-penetrating bolt, was placed flush on the dorsal midline of the cranium at the external occipital protuberance and aimed downward as though to intersect the intermandibular area. Following impact, indicators for loss of consciousness, such as respiration, righting response, corneal reflex, movement and vocalisation were recorded and characterised along with electrocardiogram and electroencephalogram recordings. After a 5-min observation period, all calves were administered potassium chloride. All calves experienced immediate and sustained loss of consciousness. The mean (± SEM) time to cessation of respiration was 60 (± 53.67) and 0 (± 0.0) s for PCB and NPCB, respectively. The mean time to cessation of convulsions was 310.4 (± 79.74) and 180.0 (± 60.24) s, respectively, and the mean number of convulsions was 2.75 (± 1.03) and 2.0 (± 0.837) for PCB and NPCB, respectively. Isoelectric EEG patterns were observed in 3/5 PCB and 3/4 NPCB with mean time to onset of isoelectric pattern in 69.0(± 52.24) and 113.5 (± 56.87) s. Both treatments induced a successful stun, which suggests these techniques are appropriate for humane euthanasia in calves of this age.

Our Environmental Value Orientations Influence How We Respond to Climate Change

People variably respond to global change in their beliefs, behaviors, and grief (associated with losses incurred). People that are less likely to believe in climate change, adopt pro-environmental behaviors, or report ecological grief are assumed to have different psycho-cultural orientations, and do not perceive changes in environmental condition or any impact upon themselves. We test these assumptions within the context of the Great Barrier Reef (GBR), a region currently experiencing significant climate change impacts in the form of coral reef bleaching and increasingly severe cyclones. We develop knowledge of environmental cultural services with the Environmental Schwartz Value Survey (ESVS) into four human value orientations that can explain individuals’ environmental beliefs and behaviors: biospheric (i.e., concern for environment), altruistic (i.e., concern for others, and intrinsic values), egoistic (i.e., concern for personal resources) and hedonic values (i.e., concern for pleasure, comfort, esthetic, and spirituality). Using face-to-face quantitative survey techniques, where 1,934 residents were asked to agree or disagree with a range of statements on a scale of 1–10, we investigate people’s (i) environmental values and value orientations, (ii) perceptions of environmental condition, and (iii) perceptions of impact on self. We show how they relate to the following climate change responses; (i) beliefs at a global and local scale, (ii) participation in pro-environmental behaviors, and (iii) levels of grief associated with ecological change, as measured by respective single survey questions. Results suggest that biospheric and altruistic values influenced all climate change responses. Egoistic values were only influential on grief responses. Perception of environmental change was important in influencing beliefs and grief, and perceptions of impact on self were only important in influencing beliefs. These results suggest that environmental managers could use people’s environmental value orientations to more effectively influence climate change responses toward environmental stewardship and sustainability. Communications that target or encourage altruism (through understanding and empathy), biospherism (through information on climate change impacts on the environment), and egoism (through emphasizing the benefits, health and wellbeing derived from a natural resource in good condition), could work.

Long-range correlations in the mechanics of small DNA circles under topological stress revealed by multi-scale simulation

It is well established that gene regulation can be achieved through activator and repressor proteins that bind to DNA and switch particular genes on or off, and that complex metabolic networks determine the levels of transcription of a given gene at a given time. Using three complementary computational techniques to study the sequence-dependence of DNA denaturation within DNA minicircles, we have observed that whenever the ends of the DNA are constrained, information can be transferred over long distances directly by the transmission of mechanical stress through the DNA itself, without any requirement for external signalling factors. Our models combine atomistic molecular dynamics (MD) with coarse-grained simulations and statistical mechanical calculations to span three distinct spatial resolutions and timescale regimes. While they give a consensus view of the non-locality of sequence-dependent denaturation in highly bent and supercoiled DNA loops, each also reveals a unique aspect of long-range informational transfer that occurs as a result of restraining the DNA within the closed loop of the minicircles.

Multifocal multiphoton excitation and time correlated single photon counting detection for 3-D fluorescence lifetime imaging

We report a multifocal multiphoton time-correlated single photon counting (TCSPC) fluorescence lifetime imaging (FLIM) microscope system that uses a 16 channel multi-anode PMT detector. Multiphoton excitation minimizes out-of-focus photobleaching, multifocal excitation reduces non-linear in-plane photobleaching effects and TCSPC electronics provide photon-efficient detection of the fluorescence decay profile. TCSPC detection is less prone to bleaching- and movement-induced artefacts compared to wide-field time-gated or frequency-domain FLIM. This microscope is therefore capable of acquiring 3-D FLIM images at significantly increased speeds compared to single beam multiphoton microscopy and we demonstrate this with live cells expressing a GFP tagged protein. We also apply this system to time-lapse FLIM of NAD(P)H autofluorescence in single live cells and report measurements on the change in the fluorescence decay profile following the application of a known metabolic inhibitor.

The positive aspects of stress: strain initiates domain decondensation (SIDD)

The conventional string-based bioinformatic methods of genomic sequence analysis are often insufficient to identify DNA regulatory elements, since many of these do not have a recognizable motif. Even in case a sequence pattern is known to be associated with an element it may only partially mediate its function. This suggests that properties not correlated with the details of base sequence contribute to regulation. One of these attributes is the DNA strand-separation potential, known as SIDD (stress-induced duplex destabilization) which facilitates the access of tracking proteins and the formation of local secondary structures. Using the type 1 interferon gene cluster as a paradigm, we demonstrate that the imprints in a SIDD profile coincide with chromatin domain borders and with DNAse I hypersensitive sites to which regulatory potential could be assigned. The approach permits the computer-guided identification of yet unknown, mostly remote sites and the design of artificial elements with predictable properties for multiple applications.

Correlations between scaffold/matrix attachment region (S/MAR) binding activity and DNA duplex destabilization energy

Scaffold or matrix-attachment regions (S/MARs) are thought to be involved in the organization of eukaryotic chromosomes and in the regulation of several DNA functions. Their characteristics are conserved between plants and humans, and a variety of biological activities have been associated with them. The identification of S/MARs within genomic sequences has proved to be unexpectedly difficult, as they do not appear to have consensus sequences or sequence motifs associated with them. We have shown that S/MARs do share a characteristic structural property, they have a markedly high predicted propensity to undergo strand separation when placed under negative superhelical tension. This result agrees with experimental observations, that S/MARs contain base-unpairing regions (BURs). Here, we perform a quantitative evaluation of the association between the ease of stress-induced DNA duplex destabilization (SIDD) and S/MAR binding activity. We first use synthetic oligomers to investigate how the arrangement of localized unpairing elements within a base-unpairing region affects S/MAR binding. The organizational properties found in this way are applied to the investigation of correlations between specific measures of stress-induced duplex destabilization and the binding properties of naturally occurring S/MARs. For this purpose, we analyze S/MAR and non-S/MAR elements that have been derived from the human genome or from the tobacco genome. We find that S/MARs exhibit long regions of extensive destabilization. Moreover, quantitative measures of the SIDD attributes of these fragments calculated under uniform conditions are found to correlate very highly (r2>0.8) with their experimentally measured S/MAR-binding strengths. These results suggest that duplex destabilization may be involved in the mechanisms by which S/MARs function. They suggest also that SIDD properties may be incorporated into an improved computational strategy to search genomic DNA sequences for sites having the necessary attributes to function as S/MARs, and even to estimate their relative binding strengths.

From DNA structure to gene expression: mediators of nuclear compartmentalization and dynamics

Eukaryotic genomes are functionally compartmentalized into chromatin domains by their attachment to a supporting structure that has traditionally been termed the nuclear matrix. Present evidence indicates the dynamics of this entity, which requires particular properties of the elements that mediate this kind of interaction. Above all, this is enabled by the so-called 'mass binding phenomenon' by which scaffold/matrix-attachment regions (S/MARs) reversibly associate with ubiquitous factors. Recent investigations and novel techniques have shown that these contacts can be altered by modulators as well as by specific interactions with the components of enhancers and locus control regions.

Computational and in vitro analysis of destabilized DNA regions in the interferon gene cluster: potential of predicting functional gene domains

Recent evidence adds support to a traditional concept according to which the eukaryotic nucleus is organized into functional domains by scaffold or matrix attachment regions (S/MARs). These regions have previously been predicted to have a high potential for stress-induced duplex destabilization (SIDD). Here we report the parallel results of binding (reassociation) and computational SIDD analyses for regions within the human interferon gene cluster on the short arm of chromosome 9 (9p22). To verify and further refine the biomathematical methods, we focus on a 10 kb region in the cluster with the pseudogene IFNWP18 and the interferon alpha genes IFNA10 and IFNA7. In a series of S/MAR binding assays, we investigate the promoter and termination regions and additional attachment sequences that were detected in the SIDD profile. The promoters of the IFNA10 and the IFNA7 genes have a moderate approximately 20% binding affinity to the nuclear matrix; the termination sequences show stronger association (70-80%) under our standardized conditions. No comparable destabilized elements were detected flanking the IFNWP18 pseudogene, suggesting that selective pressure acts on the physicochemical properties detected here. In extended, noncoding regions a striking periodicity is found of rather restricted SIDD minima with scaffold binding potential. By various criteria, the underlying sequences represent a new class of S/MARs, thought to be involved in a higher level organization of the genome. Together, these data emphasize the relevance of SIDD calculations as a valid approach for the localization of structural, regulatory, and coding regions in the eukaryotic genome.

Fatal connections: when DNA ends meet on the nuclear matrix

A damaged nucleus has long been regarded simply as a "bag of broken chromosomes," with the DNA free ends moving around and forming connections with randomly encountered partners. Recent evidence shows this picture to be fundamentally wrong. Chromosomes occupy specific nuclear domains within which only limited movement is possible. In a human diploid nucleus, 6.6 x 10(9) base pairs (bp) of DNA are compartmentalized into chromosomes in a way that allows stringent control of replication, differential gene expression, recombination and repair. Most of the chromatin is further organized into looped domains by the dynamic binding of tethered bases to a network of intranuclear proteins, the so-called nuclear scaffold or matrix. Thus, DNA movement is severely curtailed, which limits the number of sites where interchanges can occur. This intricate organizational arrangement may render the genome vulnerable to processes that interfere with DNA repair. Both lower and higher eukaryotic cells perform homologous recombination (HR) and illegitimate recombination (IR) as part of their survival strategies. The repair processes comprising IR must be understood in the context of DNA structural organization, which is fundamentally different in prokaryotic and eukaryotic genomes. In this paper we first review important cellular processes including recombination, DNA repair, and apoptosis, and describe the central elements involved. Then we review the different DNA targets of recombination, and present recent evidence implicating the nuclear matrix in processes which can induce either repair, translocation, deletion, or apoptosis. J. Cell. Biochem. Suppl. 35:3-22, 2000.

Transcriptional augmentation: modulation of gene expression by scaffold/matrix-attached regions (S/MAR elements)

For a long time S/MARs could only be characterized by the assays in vitro that led to their detection. Only recently a number of biological activities emerged that are common to most or all S/MARs that are detected by the classic procedures. This review focuses on the phenomenon of transcriptional augmentation that is found for genomically anchored or episomal genes and on a group of partially overlapping activities that are suited to maintain an episomal status. Further, it is attempted to correlate properties of the S/MAR-scaffold interaction with prominent or prototype protein binding partners.

Stress-induced duplex DNA destabilization in scaffold/matrix attachment regions

S/MARs are DNA elements 300 to several thousand base-pairs long, which are operationally defined by their affinity for the nuclear scaffold or matrix. S/MARs occur exclusively in eukaryotic genomes, where they mediate several functions. Because S/MARs do not have a clearcut consensus sequence, the characteristics that define their activity are thought to be structural. Ubiquitous S/MAR binding proteins have been identified, but to date no unique binding sequence or structural motif has been found. Here we show by computational analysis that S/MARs conform to a specific design whose essential attribute is the presence of stress-induced base-unpairing regions (BURs). Stress-induced destabilization (SIDD) profiles are calculated using a previously developed statistical mechanical procedure in which the superhelical deformation is partitioned between strand separation, twisting within denatured regions, and residual superhelicity. The results of these calculations show that BURs exhibit a succession of evenly spaced destabilized sites that would render part or all of the S/MAR sequence single stranded at sufficient superhelicity. These analyses are performed for a range of sequenced S/MAR elements from the borders of eukaryotic gene domains, from centromeres, and from positions where S/MARs are known to support the action of an enhancer. The results reported here are in excellent agreement with earlier in vitro chemical reactivity studies. This approach demonstrates the potential for computational analysis to predict the points of division of the eukaryotic genome into functional units (domains), and also to locate certain cis-regulatory sequences.

Hen's teeth and whale's feet: generalized characters and their compatibility

We propose a new model of computation for deriving phylogenetic trees based upon a generalization of qualitative characters. The model we propose is based upon recent experimental research in molecular biology. We show that the general case of determining perfect compatibility of generalized ordered characters is an NP-complete problem, but can be solved in polynomial time for a special case.

In vivo decay kinetic parameters of hammerhead ribozymes

Ribozymes offer a potentially important way to inactivate intracellular RNA from almost any gene whose nucleotide sequence is known. Recently, we found that hammerhead ribozymes directed against mRNA of tumour necrosis factor alpha (TNF alpha) and its derivatives, preferentially bind to a cellular protein(s). To better understand the effect of different 3'-terminal hairpins on ribozyme stability as well as their effect on the protein binding to the ribozyme, a mathematical treatment of the decay of three TNF alpha ribozymes that differed at their 3' ends was performed. One ribozyme contained a 3'-terminal hairpin derived from a transcription terminator of bacteriophage T7, another contained the same hairpin but modified to be highly enriched for G+C nucleotides, and a third lacked a hairpin. The TNF alpha ribozyme decay had two kinetic components. The slow component exhibited exponential decay with a half life of approximately 250 h in all cases. The 3'-terminal hairpin has no significant effect on this component. This slow phase accounted for 60-80% of ribozyme decay. The rapid phase also exhibited exponential decay. For this phase, a 3'-terminal hairpin roughly doubled the half-life (1.7-3.4). The slow phase of degradation was about three times faster for a ribozyme directed at the integrase mRNA of human immunodeficiency virus-1 than that seen with the TNF alpha ribozyme. Taken together, these results suggest that the ribozyme population is initially sensitive to degradation, with the presence of a hairpin provides some protection, and indicate that the addition of the hairpin to the ribozyme did not prevent the in vivo additional stabilizing effect of the protein(s).

An influenza virus containing nine different RNA segments

The packaging mechanism of segmented RNA viruses has not been well studied. Specifically, it has not been clear whether influenza A viruses package only eight RNA segments or whether virus particles contain more than eight segments. Using a newly developed ribonucleoprotein (RNP) transfection method, we engineered an influenza virus which must contain nine different RNA segments rather than the usual eight in order to survive under the experimental growth conditions. This result is compatible with a mechanism of packaging which allows influenza virus to encapsidate more than eight RNA segments. We also suggest that the virus packages its RNAs randomly and that this random packaging results in infectious viruses with the required ("right") complement of RNA segments.