Kinetic mechanism of an aldehyde reductase of Saccharomyces cerevisiae that relieves toxicity of furfural and 5-hydroxymethylfurfural

An effective means of relieving the toxicity of furan aldehydes, furfural (FFA) and 5-hydroxymethylfurfural (HMF), on fermenting organisms is essential for achieving efficient fermentation of lignocellulosic biomass to ethanol and other products. Ari1p, an aldehyde reductase from Saccharomyces cerevisiae, has been shown to mitigate the toxicity of FFA and HMF by catalyzing the NADPH-dependent conversion to corresponding alcohols, furfuryl alcohol (FFOH) and 5-hydroxymethylfurfuryl alcohol (HMFOH). At pH 7.0 and 25°C, purified Ari1p catalyzes the NADPH-dependent reduction of substrates with the following values (k(cat) (s(-1)), k(cat)/K(m) (s(-1)mM(-1)), K(m) (mM)): FFA (23.3, 1.82, 12.8), HMF (4.08, 0.173, 23.6), and dl-glyceraldehyde (2.40, 0.0650, 37.0). When acting on HMF and dl-glyceraldehyde, the enzyme operates through an equilibrium ordered kinetic mechanism. In the physiological direction of the reaction, NADPH binds first and NADP(+) dissociates from the enzyme last, demonstrated by k(cat) of HMF and dl-glyceraldehyde that are independent of [NADPH] and (K(ia)(NADPH)/k(cat)) that extrapolate to zero at saturating HMF or dl-glyceraldehyde concentration. Microscopic kinetic parameters were determined for the HMF reaction (HMF+NADPH?HMFOH+NADP(+)), by applying steady-state, presteady-state, kinetic isotope effects, and dynamic modeling methods. Release of products, HMFOH and NADP(+), is 84% rate limiting to k(cat) in the forward direction. Equilibrium constants, [NADP(+)][FFOH]/[NADPH][FFA][H(+)]=5600×10(7)M(-1) and [NADP(+)][HMFOH]/[NADPH][HMF][H(+)]=4200×10(7)M(-1), favor the physiological direction mirrored by the slowness of hydride transfer in the non-physiological direction, NADP(+)-dependent oxidation of alcohols (k(cat) (s(-1)), k(cat)/K(m) (s(-1)mM(-1)), K(m) (mM)): FFOH (0.221, 0.00158, 140) and HMFOH (0.0105, 0.000104, 101).     

In situ dividing and phagocytosing retinal microglia express nestin, vimentin, and NG2 in vivo

Background

Following injury, microglia become activated with subsets expressing nestin as well as other neural markers. Moreover, cerebral microglia can give rise to neurons in vitro. In a previous study, we analysed the proliferation potential and nestin re-expression of retinal macroglial cells such as astrocytes and Müller cells after optic nerve (ON) lesion. However, we were unable to identify the majority of proliferative nestin⁺ cells. Thus, the present study evaluates expression of nestin and other neural markers in quiescent and proliferating microglia in naïve retina and following ON transection in adult rats in vivo.

Methodology/Principal Findings

For analysis of cell proliferation and cells fates, rats received BrdU injections. Microglia in retinal sections or isolated cells were characterized using immunofluorescence labeling with markers for microglia (e.g., Iba1, CD11b), cell proliferation, and neural cells (e.g., nestin, vimentin, NG2, GFAP, Doublecortin etc.). Cellular analyses were performed using confocal laser scanning microscopy. In the naïve adult rat retina, about 60% of resting ramified microglia expressed nestin. After ON transection, numbers of nestin⁺ microglia peaked to a maximum at 7 days, primarily due to in situ cell proliferation of exclusively nestin⁺ microglia. After 8 weeks, microglia numbers re-attained control levels, but 20% were still BrdU⁺ and nestin⁺, although no further local cell proliferation occurred. In addition, nestin⁺ microglia co-expressed vimentin and NG2, but not GFAP or neuronal markers. Fourteen days after injury and following retrograde labeling of retinal ganglion cells (RGCs) with Fluorogold (FG), nestin⁺NG2⁺ microglia were positive for the dye indicating an active involvement of a proliferating cell population in phagocytosing apoptotic retinal neurons.

Conclusions/Significance

The current study provides evidence that in adult rat retina, a specific resident population of microglia expresses proteins of immature neural cells that are involved in injury-induced cell proliferation and phagocytosis while transdifferentiation was not observed.     

Physiological ecology meets climate change

In this article, we pointed out that understanding the physiology of differential climate change effects on organisms is one of the many urgent challenges faced in ecology and evolutionary biology. We explore how physiological ecology can contribute to a holistic view of climate change impacts on organisms and ecosystems and their evolutionary responses. We suggest that theoretical and experimental efforts not only need to improve our understanding of thermal limits to organisms, but also to consider multiple stressors both on land and in the oceans. As an example, we discuss recent efforts to understand the effects of various global change drivers on aquatic ectotherms in the field that led to the development of the concept of oxygen and capacity limited thermal tolerance (OCLTT) as a framework integrating various drivers and linking organisational levels from ecosystem to organism, tissue, cell, and molecules. We suggest seven core objectives of a comprehensive research program comprising the interplay among physiological, ecological, and evolutionary approaches for both aquatic and terrestrial organisms. While studies of individual aspects are already underway in many laboratories worldwide, integration of these findings into conceptual frameworks is needed not only within one organism group such as animals but also across organism domains such as Archaea, Bacteria, and Eukarya. Indeed, development of unifying concepts is relevant for interpreting existing and future findings in a coherent way and for projecting the future ecological and evolutionary effects of climate change on functional biodiversity. We also suggest that OCLTT may in the end and from an evolutionary point of view, be able to explain the limited thermal tolerance of metazoans when compared to other organisms.     

Alphavirus Replicon DNA Expressing HIV Antigens Is an Excellent Prime for Boosting with Recombinant Modified Vaccinia Ankara (MVA) or with HIV gp140 Protein Antigen

Vaccination with DNA is an attractive strategy for induction of pathogen-specific T cells and antibodies. Studies in humans have shown that DNA vaccines are safe, but their immunogenicity needs further improvement. As a step towards this goal, we have previously demonstrated that immunogenicity is increased with the use of an alphavirus DNA-launched replicon (DREP) vector compared to conventional DNA vaccines. In this study, we investigated the effect of varying the dose and number of administrations of DREP when given as a prime prior to a heterologous boost with poxvirus vector (MVA) and/or HIV gp140 protein formulated in glucopyranosyl lipid A (GLA-AF) adjuvant. The DREP and MVA vaccine constructs encoded Env and a Gag-Pol-Nef fusion protein from HIV clade C. One to three administrations of 0.2 μg DREP induced lower HIV-specific T cell and IgG responses than the equivalent number of immunizations with 10 μg DREP. However, the two doses were equally efficient as a priming component in a heterologous prime-boost regimen. The magnitude of immune responses depended on the number of priming immunizations rather than the dose. A single low dose of DREP prior to a heterologous boost resulted in greatly increased immune responses compared to MVA or protein antigen alone, demonstrating that a mere 0.2 μg DREP was sufficient for priming immune responses. Following a DREP prime, T cell responses were expanded greatly by an MVA boost, and IgG responses were also expanded when boosted with protein antigen. When MVA and protein were administered simultaneously following multiple DREP primes, responses were slightly compromised compared to administering them sequentially. In conclusion, we have demonstrated efficient priming of HIV-specific T cell and IgG responses with a low dose of DREP, and shown that the priming effect depends on number of primes administered rather than dose.     

A new approximate whole boundary solution of the Lamm differential equation for the analysis of sedimentation velocity experiments

Sedimentation velocity is one of the best-suited physical methods for determining the size and shape of macromolecular substances or their complexes in the range from 1 to several thousand kDa. The moving boundary in sedimentation velocity runs can be described by the Lamm differential equation. Fitting of suitable model functions or solutions of the Lamm equation to the moving boundary is used to obtain directly sedimentation and diffusion coefficients, thus allowing quick determination of size, shape and other parameters of macromolecules. Here we present a new approximate whole boundary solution of the Lamm equation that simultaneously allows the specification of sedimentation and diffusion coefficients with deviations smaller than 1% from the expected values.     

Genomic convergence toward diploidy in Saccharomyces cerevisiae

Genome size, a fundamental aspect of any organism, is subject to a variety of mutational and selection pressures. We investigated genome size evolution in haploid, diploid, and tetraploid initially isogenic lines of the yeast Saccharomyces cerevisiae. Over the course of ~1,800 generations of mitotic division, we observed convergence toward diploid DNA content in all replicate lines. This convergence was observed in both unstressful and stressful environments, although the rate of convergence was dependent on initial ploidy and evolutionary environment. Comparative genomic hybridization with microarrays revealed nearly euploid DNA content by the end of the experiment. As the vegetative life cycle of S. cerevisiae is predominantly diploid, this experiment provides evidence that genome size evolution is constrained, with selection favouring the genomic content typical of the yeast's evolutionary past.     

HCMV-infection in a human arterial organ culture model: effects on cell proliferation and neointimal hyperplasia

Background

The impact of infections with the human cytomegalovirus (HCMV) for the development of atherosclerosis and restenosis is still unclear. Both a clear correlation and no correlation at all have been reported in clinical, mostly serological studies. In our study we employed a human non-injury ex vivo organ culture model to investigate the effect of an in vitro permissive HCMV-infection on cell proliferation and neointimal hyperplasia for a period of 56 days.

Results

During routine-nephrectomies parts of renal arteries from 71 patients were obtained and prepared as human organ cultures. Cell free HCMV infection was performed with the fibroblast adapted HCMV strain AD169, the endotheliotropic strain TB40E, and a clinical isolate (AN 365). After 3, 7, 14, 21, 28, 35, and 56 days in culture staining of HCMV-antigens was carried out and reactive cell proliferation and neointimal thickening were analysed. Successful HCMV-infection was accomplished with all three virus strains studied. During the first 21 days in organ culture no cell proliferation or neointimal hyperplasia was detected. At day 35 and day 56 moderate cell proliferation and neointimal hyperplasia was found both in HCMV-infected segments and mock infected controls. Neointimal hyperplasia in productively HCMV-infected segments was lower than in non infected at day 35 and day 56, but relatively higher after infection with the endotheliotropic TB40E in comparison with the two other strains.

Conclusion

The data do not support the hypothesis that HCMV-infection triggers restenosis via a stimulatory effect on cell proliferation and neointimal hyperplasia in comparison to non infected controls. Interestingly however, even after lytic infection, a virus strain specific difference was observed.     

Correlative Imaging of Fluorescent Proteins in Resin-Embedded Plant Material1

Fluorescent proteins (FPs) were developed for live-cell imaging and have revolutionized cell biology. However, not all plant tissues are accessible to live imaging using confocal microscopy, necessitating alternative approaches for protein localization. An example is the phloem, a tissue embedded deep within plant organs and sensitive to damage. To facilitate accurate localization of FPs within recalcitrant tissues, we developed a simple method for retaining FPs after resin embedding. This method is based on low-temperature fixation and dehydration, followed by embedding in London Resin White, and avoids the need for cryosections. We show that a palette of FPs can be localized in plant tissues while retaining good structural cell preservation, and that the polymerized block face can be counterstained with cell wall probes. Using this method we have been able to image green fluorescent protein-labeled plasmodesmata to a depth of more than 40 μm beneath the resin surface. Using correlative light and electron microscopy of the phloem, we were able to locate the same FP-labeled sieve elements in semithin and ultrathin sections. Sections were amenable to antibody labeling, and allowed a combination of confocal and superresolution imaging (three-dimensional-structured illumination microscopy) on the same cells. These correlative imaging methods should find several uses in plant cell biology.The localization of fluorescent proteins (FPs) in cells and tissues has become one of the major tools in cell biology (Tsien, 1998; Shaner et al., 2005). Advances in confocal microscopy have meant that many proteins can be tagged with appropriate fluorescent markers and tracked as they move within and between cells (Chapman et al., 2005). Additional approaches involving photobleaching and photoactivation of FPs have opened up new avenues for exploring protein dynamics and turnover within cells (Lippincott-Schwartz et al., 2003). However, not all cells are amenable to live-cell imaging, which in plants is usually restricted to surface cells such as the leaf epidermis. An example is the phloem. The delicate nature of sieve elements and companion cells, which are under substantial hydrostatic pressure, has made studies of the fine structure of these cells particularly difficult (Knoblauch and van Bel, 1998). Despite this, significant advances have been made in imaging the phloem through inventive use of imaging protocols that allow living sieve elements to be observed as they translocate assimilates (for review, see Knoblauch and Oparka, 2012). However, determining the precise localization of the plethora of proteins located within the sieve element (SE)-companion cell (CC) complex remains a technical challenge. The phloem is the conduit for long-distance movement of macromolecules in plants, including viral genomes. For several viruses, the entry into the SE-CC complex is a crucial step that determines the capacity for long-distance movement. Identifying the cell types within the phloem that restrict the movement of some viruses is technically challenging due to the small size of phloem cells and their location deep within plant organs (Nelson and van Bel, 1998).The problems associated with imaging proteins in phloem tissues prompted us to explore methods for retaining the fluorescence of tagged proteins within tissues not normally amenable to confocal imaging. Previously, we used superresolution imaging techniques on fixed phloem tissues sectioned on a Vibroslice, providing information on the association between a viral movement protein (MP) and plasmodesmata (PD) within the SE-CC complex (Fitzgibbon et al., 2010). However, we wished to explore the same cells using correlative light and electron microscopy (CLEM), necessitating the development of methods that would allow sequential imaging of cells using fluorescence microscopy and transmission electron microscopy (TEM). To this end, we developed a protocol that retains fluorescent proteins through aldehyde fixation and resin embedding.In the last 10 years there has been significant interest in imaging fluorescent proteins in semithin sections (for review, see Cortese et al., 2009). Luby-Phelps and colleagues (2003) first described a method for retaining GFP fluorescence after fixation and resin embedding, but their method has not seen widespread application. The advent of superresolution imaging techniques (for review, see Bell and Oparka, 2011) has stimulated considerable interest in this field as the retention of fluorescence in thin sections means that cells can be imaged using techniques such as photoactivation light microscopy and stochastic optical reconstruction microscopy, allowing a lateral resolution of less than 10 nm to be achieved (Subach et al., 2009; Xu et al., 2012). A number of studies have described CLEM on the same cells (Luby-Phelps et al., 2003; Betzig et al., 2006; Watanabe et al., 2011). Advances in this field were reviewed recently (Jahn et al., 2012; see contributions in Muller-Reichert and Verkade, 2012). For example, Pfeiffer et al. (2003) were able to image SEs and CCs using high-pressure freezing, followed by freeze substitution in acetone and resin embedding. They then used thick optical sections of the tissue to locate cells of interest, and these were subsequently imaged using TEM. However, there have been few attempts to retain FPs in resin-embedded plant tissues. Thompson and Wolniak (2008) described the retention of mCitrine fused to an SE-plasma membrane protein in glycol methacrylate sections. The fluorescent signal was stable using wide-field microscopy but bleached rapidly under the confocal microscope.To date, cryosections have been the preferred choice for CLEM in mammalian tissues (Watanabe et al., 2011). Recently, Lee et al. (2011) chemically fixed Arabidopsis (Arabidopsis thaliana) seedlings, cut 50-μm sections, and examined these with a confocal microscope. After confocal mapping the sections were embedded in resin and thin sectioned. These authors were able to locate the same PD pit fields using confocal and TEM, providing important information on the localization of a novel PD protein. As general rule, cryosectioning is a time-consuming process, and subcellular details may be obscured in cryosections because of poor tissue contrast (Watanabe et al., 2011). A major problem with imaging FPs in resin sections has been that GFP and its derivatives are quenched by the acidic, oxidizing conditions required for fixation, dehydration, and embedding of delicate specimens (Tsien, 1998; Keene et al., 2008). Recently, however, Watanabe et al. (2011) explored the retention of FPs in Caenorhabditis elegans cells after fixation by different aldehydes and embedding media. These authors tested a range of resins and found that Citrine and tandem dimer Eos (tdEos) could be retained in methacrylate plastic sections. This material was difficult to cut thinly (<70 nm) compared to epoxy-based resins, but the authors obtained valuable correlative images using stimulated emission depletion microscopy and photoactivation light microscopy followed by low-voltage scanning electron microscopy.Because the retention of fluorescent proteins may differ between plant and animal cells, we explored a number of approaches for retaining fluorescent proteins in resin. Using low-temperature conditions (<8°C) during fixation and dehydration, we could retain strong fluorescence prior to tissue embedding. We also explored different embedding media and found that tissue could be effectively polymerized in London Resin (LR) White while retaining sufficient fluorescence for confocal imaging. Using water-dipping lenses, we were able to detect fluorescent proteins in optical sections up to 40 μm below the surface of the block face. Ultrathin sections from the same blocks showed good structural preservation and allowed CLEM. Subsequently, we cut 1- to 2-μm sections and examined these using confocal microscopy and three-dimensional-structured illumination microscopy (3D-SIM). Sections could be counterstained with a number of conventional fluorophores and antibodies, allowing colocalization studies. These simple methods allow successive imaging of FPs with the light and electron microscope, combining the strengths of both imaging platforms. We believe this approach will have significant utility for tissues that are recalcitrant to conventional confocal imaging.