Characterizing clearance of helper adenovirus by a clinical rAAV1 manufacturing process.

Recombinant adeno-associated viral vectors (rAAV) are being developed as gene therapy delivery vehicles and as genetic vaccines, and some of the most scaleable manufacturing methods for rAAV use live adenovirus to induce production. One aspect of establishing safety of rAAV products is therefore demonstrating adequate and reliable clearance of this helper virus by the vector purification process. The ICH Q5A regulatory guidance on viral safety provides recommendations for process design and characterization of viral clearance for recombinant proteins, and these principles were adapted to a rAAV serotype 1 purification process for clinical vectors. Specific objectives were to achieve overall adenovirus clearance factors significantly greater than input levels by using orthogonal separation and inactivation methods, and to segregate adenovirus from downstream operations by positioning a robust clearance step early in the process. Analytical tools for process development and characterization addressed problematic in-process samples, and a viral clearance validation study was performed using adenovirus and two non-specific model viruses. Overall clearance factors determined were >23 LRV for adenovirus, 11 LRV for BVDV, and >23 LRV for AMuLV.     

Differential mobilization of blubber fatty acids in lactating Weddell seals: evidence for selective use

A major source of energy during lactation in mammals is provided through the mobilization of blubber fatty acids (FAs). We investigated the extent to which FAs were mobilized to support both maternal metabolic requirements and milk production in the Weddell seal and how this was reflected in the FA composition of the pup's blubber at the end of lactation (EL). FA composition of postpartum female blubber was similar in the 2 yr of study (2002 and 2003) but differed markedly by EL. Pup blubber FAs (at EL) were also different between years and did not match that of the mother's milk or blubber. Milk FA composition changed during lactation, which may have been a reflection of an increase in pup energy demands at different stages of development. In addition, there was evidence of feeding by some females during lactation, with higher levels of some FAs in the milk than in the blubber. Our results indicate that differential mobilization of FAs occurred in lactating Weddell seals and that this was related to total body lipid stores at postpartum. Furthermore, growing pups did not store FAs unmodified, providing evidence that selective use does occur and also that using FA composition to elucidate dietary sources may be problematic in growing individuals.     

The role of vicariance vs. dispersal in shaping genetic patterns in ocellated lizard species in the western Mediterranean

The schism between North Africa and Southern Europe caused by the opening of the Strait of Gibraltar and the consequent refilling of the Mediterranean basin at the end of Messinian salinity crisis (MSC), 5.33 million years ago, has been advocated as the main event shaping biogeographical patterns in the western Mediterranean as exemplified by the distribution of species and subspecies and genetic variation within the ocellated lizard group. To reassess the role of the MSC, partial sequences of three mitochondrial DNA genes (cytochrome b , 12S and 16S ribosomal RNA) and two nuclear genes (β-fibrinogen and C-mos) from species of the ocellated lizard group were analysed. Three alternative hypotheses were tested: that divergence was initiated (i) by post-MSC vicariance as the basin filled, (ii) when separate populations established either side of the strait by pre-MSC overseas dispersal, and (iii) by post-MSC overseas dispersal. The pattern and level of divergence detected clearly refute the post-MSC vicariance hypothesis, and support a model of divergence initiated by earlier overseas dispersal. Indeed, our best estimate is that the basal Euro-African divergence predates the MSC event by several million years. The estimated divergence times among the populations in former Miocene Mediterranean islands, the current Betic and Rifian mountains, from adjacent mainland populations suggest overseas dispersal for the former and overland dispersal, or perhaps vicariance, for the latter. These results suggest that the MSC may have played a much less important role in shaping the current western Mediterranean biogeographical patterns than might have been anticipated from the dramatic nature of the episode.     

Long-Term Trends in Faunal Recolonization After Bauxite Mining in the Jarrah Forest of Southwestern Australia

Abstract Fauna serve a key role in many forest ecological processes. Despite this, few studies have considered long‐term faunal recolonization after mining and rehabilitation of forest ecosystems. In the jarrah forest of southwestern Australia, permanent fauna monitoring sites have been established in bauxite mined areas rehabilitated in 1990 and in a range of representative unmined forest control sites. At each site mammals, birds, reptiles, and ants were surveyed in 1992, 1995, and 1998. The aims of the monitoring were to develop a better understanding of faunal recolonization trends, to produce recommendations for promoting fauna return, and to consider which techniques and fauna groups are best suited for monitoring recolonization. The results showed that successional trends varied between fauna groups. Generalist foraging mammals recolonized rapidly, whereas small predators took longer. Feral mice were initially abundant and then declined. Birds gradually recolonized, and after 8 years bird communities were very similar to those in unmined forest sites. Reptile species took longer, and after 8 years numbers of species remained lower than in unmined forests. Species richness and diversity of ants in 8‐year‐old rehabilitation were comparable with those of unmined forest in some rehabilitated sites but were lower in others. The composition of ant communities was still different from that of unmined sites. Ant species that only use disturbed forest declined rapidly in abundance as rehabilitation aged. The results suggest that although the rates of faunal recolonization will vary, with time most or all mammal, bird, reptile, and ant species should inhabit rehabilitated bauxite mines. The densities of many are likely to be similar to those in unmined forest, but for others it is too early to know whether this will be the case. Techniques for promoting fauna return are discussed. This study demonstrates that no single fauna group is suitable for use as an overall “indicator” of faunal recolonization; different fauna species and groups reflect different aspects of faunal succession.     

Genomewide association study for susceptibility genes contributing to familial Parkinson disease

Five genes have been identified that contribute to Mendelian forms of Parkinson disease (PD); however, mutations have been found in fewer than 5% of patients, suggesting that additional genes contribute to disease risk. Unlike previous studies that focused primarily on sporadic PD, we have performed the first genomewide association study (GWAS) in familial PD. Genotyping was performed with the Illumina HumanCNV370Duo array in 857 familial PD cases and 867 controls. A logistic model was employed to test for association under additive and recessive modes of inheritance after adjusting for gender and age. No result met genomewide significance based on a conservative Bonferroni correction. The strongest association result was with SNPs in the GAK/DGKQ region on chromosome 4 (additive model: p = 3.4 × 10⁻⁶; OR = 1.69). Consistent evidence of association was also observed to the chromosomal regions containing SNCA (additive model: p = 5.5 × 10⁻⁵; OR = 1.35) and MAPT (recessive model: p = 2.0 × 10⁻⁵; OR = 0.56). Both of these genes have been implicated previously in PD susceptibility; however, neither was identified in previous GWAS studies of PD. Meta-analysis was performed using data from a previous case–control GWAS, and yielded improved p values for several regions, including GAK/DGKQ (additive model: p = 2.5 × 10⁻⁷) and the MAPT region (recessive model: p = 9.8 × 10⁻⁶; additive model: p = 4.8 × 10⁻⁵). These data suggest the identification of new susceptibility alleles for PD in the GAK/DGKQ region, and also provide further support for the role of SNCA and MAPT in PD susceptibility. Electronic supplementary material  The online version of this article (doi:) contains supplementary material, which is available to authorized users. N. Pankratz and J. B. Wilk are joint first authors.     

Improved Sugar Conversion and Ethanol Yield for Forage Sorghum (Sorghum bicolor L. Moench) Lines with Reduced Lignin Contents

Lignin is known to impede conversion of lignocellulose into ethanol. In this study, forage sorghum plants carrying brown midrib (bmr) mutations, which reduce lignin contents, were evaluated as bioenergy feedstocks. The near-isogenic lines evaluated were: wild type, bmr-6, bmr-12, and bmr-6 bmr-12 double mutant. The bmr-6 and bmr-12 mutations were equally efficient at reducing lignin contents (by 13% and 15%, respectively), and the effects were additive (27%) for the double mutant. Reducing lignin content was highly beneficial for improving biomass conversion yields. Sorghum biomass samples were pretreated with dilute acid and recovered solids washed and hydrolyzed with cellulase to liberate glucose. Glucose yields for the sorghum biomass were improved by 27%, 23%, and 34% for bmr-6, bmr-12, and the double mutant, respectively, compared to wild type. Sorghum biomass was also pretreated with dilute acid followed by co-treatment with cellulases and Saccharomyces cerevisiae for simultaneous saccharification and fermentation (SSF) into ethanol. Conversion of cellulose to ethanol for dilute-acid pretreated sorghum biomass was improved by 22%, 21%, and 43% for bmr-6, bmr-12, and the double mutant compared to wild type, respectively. Electron microscopy of dilute-acid treated samples showed an increased number of lignin globules in double-mutant tissues as compared to the wild-type, suggesting the lignin had become more pliable. The mutations were also effective for improving ethanol yields when the (degrained) sorghum was pretreated with dilute alkali instead of dilute acid. Following pretreatment with dilute ammonium hydroxide and SSF, ethanol conversion yields were 116 and 130 mg ethanol/g dry biomass for the double-mutant samples and 98 and 113 mg/g for the wild-type samples.     

Widespread Phosphorylation of Histone H2AX by Species C Adenovirus Infection Requires Viral DNA Replication

Adenovirus infection activates cellular DNA damage response and repair pathways. Viral proteins that are synthesized before viral DNA replication prevent recognition of viral genomes as a substrate for DNA repair by targeting members of the sensor complex composed of Mre11/Rad50/NBS1 for degradation and relocalization, as well as targeting the effector protein DNA ligase IV. Despite inactivation of these cellular sensor and effector proteins, infection results in high levels of histone 2AX phosphorylation, or γH2AX. Although phosphorylated H2AX is a characteristic marker of double-stranded DNA breaks, this modification was widely distributed throughout the nucleus of infected cells and was coincident with the bulk of cellular DNA. H2AX phosphorylation occurred after the onset of viral DNA replication and after the degradation of Mre11. Experiments with inhibitors of the serine-threonine kinases ataxia telangiectasia mutated (ATM), AT- and Rad3-related (ATR), and DNA protein kinase (DNA-PK), the kinases responsible for H2AX phosphorylation, indicate that H2AX may be phosphorylated by ATR during a wild-type adenovirus infection, with some contribution from ATM and DNA-PK. Viral DNA replication appears to be the stimulus for this phosphorylation event, since infection with a nonreplicating virus did not elicit phosphorylation of H2AX. Infected cells also responded to high levels of input viral DNA by localized phosphorylation of H2AX. These results are consistent with a model in which adenovirus-infected cells sense and respond to both incoming viral DNA and viral DNA replication.Cellular DNA damage response pathways protect and preserve the integrity of the genome. These pathways, which are activated in response to various forms of DNA damage, involve a number of proteins that participate in both DNA repair and cell cycle progression (62). The serine-threonine kinases ataxia telangiectasia mutated (ATM), AT- and Rad3-related (ATR), and DNA protein kinase (DNA-PK) are activated in response to distinct types of damage. The ATM pathway is activated primarily by double-stranded DNA breaks (4, 30). DNA-PK acts in conjunction with the DNA ligase IV/XRCC4 complex to mediate the ligation of double-stranded breaks through nonhomologous end joining (34). The ATR pathway can be activated in response to a wide range of genotoxic stresses, such as base or nucleotide excision, double-stranded breaks, or single-stranded breaks. Activation of ATR is generally thought to occur via the recognition of single-stranded tracks of DNA (63). Each of these pathways leads to the phosphorylation and activation of a number of cellular proteins such as the variant histone H2AX, checkpoint kinases 1 and 2 (Chk1 and Chk2), and Nijmegen break syndrome protein 1 (NBS1), among others (62). Signals transmitted by a cascade of phosphorylation events result in cell cycle arrest and the accumulation of repair protein complexes at sites of DNA damage.Upon recognition of a double-stranded DNA break by the cell, H2AX is phosphorylated on an extended C-terminal tail at serine 139 by the phosphatidylinositol 3-kinase (PI3K)-related kinases ATM, ATR, and DNA-PK (9, 41, 44, 58). Considered one of the earliest indications of a double-stranded DNA break, phosphorylated H2AX (γH2AX) acts as a scaffolding protein to which a number of DNA repair factors can dock to facilitate repair of the damaged DNA (36, 42, 53). Areas of phosphorylated H2AX, termed γH2AX foci, are enriched for proteins involved in both homologous recombination and nonhomologous end joining, such as NBS1, BRCA1 (42), and Mdc1 (24, 50).Although adenovirus is able to activate both ATM and ATR pathways (11), adenoviral proteins limit the extent and consequences of signaling through these pathways. The E1B-55K and E4orf6 proteins form an E3 ubiquitin ligase with the cellular proteins Cullin-5, elongins B and C, and Rbx1 (28, 43). This complex targets key cellular proteins involved in cellular response to DNA damage, including p53 (28, 43), Mre11 (51), and DNA ligase IV (3). The E4orf3 gene product targets cellular proteins central to both the cellular DNA damage response and the antiviral response. The E4orf3 protein of species C adenoviruses alters the localization of Mre11/Rad50/NBS1 (MRN) complex members within the nucleus to prevent association with centers of viral DNA replication and to ensure efficient viral DNA replication (17, 18, 52). In addition, these three viral early proteins direct members of the MRN complex (2, 35) and the single-stranded DNA-binding protein 2 (20) to cytoplasmic aggresomes, where these sequestered proteins are effectively inactivated. These viral activities, along with the inactivation of DNA-PK by E4orf3 and E4orf6 gene products (7), appear to prevent recognition of viral genomes by the MRN complex and prevent ligation of these genomes through nonhomologous end joining. In cells infected with a virus with E4 deleted, Mre11 physically binds to viral DNA in an NBS1-dependent manner and may prevent efficient genome replication (37). The overlapping means by which adenovirus disables the MRN complex and prevents DNA damage repair serves to illustrate the importance of this activity for a productive adenovirus infection. However, despite having DNA damage signaling and DNA repair pathways dismantled, adenovirus-infected cells exhibit some characteristic changes associated with DNA damage signaling events, such as the phosphorylation of H2AX (6, 15). Thus, it appears that adenovirus effectively inhibits DNA repair activity but may not fully suppress the early events of DNA damage signaling.The focus of the present study was to elucidate the activation of DNA damage signaling pathways revealed by phosphorylation of the variant histone H2AX during wild-type adenovirus infection and to determine what stage of the virus life cycle leads to this activation. We demonstrate that infected cells respond to viral genome replication with high levels of H2AX phosphorylation throughout the cell nucleus. This phosphorylation event is not localized to viral replication centers and does not appear to be concurrent with cellular double-stranded DNA breaks; rather, H2AX phosphorylation occurs coincident with the bulk of cellular chromatin. H2AX phosphorylation follows viral DNA replication and reaches peak levels after the degradation of the Mre11. In addition, we observed that infected cells can respond to both the presence of incoming viral genomes and genome replication by initiating H2AX phosphorylation.     

Direct Regulation of Prokaryotic Kir Channel by Cholesterol

Our earlier studies have shown that channel activity of Kir2 subfamily of inward rectifiers is strongly suppressed by the elevation of cellular cholesterol. The goal of this study is to determine whether cholesterol suppresses Kir channels directly. To achieve this goal, purified prokaryotic Kir (KirBac1.1) channels were incorporated into liposomes of defined lipid composition, and channel activity was assayed by ⁸⁶Rb⁺ uptake. Our results show that ⁸⁶Rb⁺ flux through KirBac1.1 is strongly inhibited by cholesterol. Incorporation of 5% (mass cholesterol/phospholipid) cholesterol into the liposome suppresses ⁸⁶Rb⁺ flux by >50%, and activity is completely inhibited at 12–15%. However, epicholesterol, a stereoisomer of cholesterol with similar physical properties, has significantly less effect on KirBac-mediated ⁸⁶Rb⁺ uptake than cholesterol. Furthermore, analysis of multiple sterols suggests that cholesterol-induced inhibition of KirBac1.1 channels is mediated by specific interactions rather than by changes in the physical properties of the lipid bilayer. In contrast to the inhibition of KirBac1.1 activity, cholesterol had no effect on the activity of reconstituted KscA channels (at up to 250 μg/mg of phospholipid). Taken together, these observations demonstrate that cholesterol suppresses Kir channels in a pure protein-lipid environment and suggest that the interaction is direct and specific.Inwardly rectifying potassium channels (Kir) are known to play critical roles in the regulation of multiple cellular functions including membrane excitability, heart rate, and vascular tone (1–3). Kir channels are classified into seven subfamilies (Kir1–7) identified by distinct biophysical properties and sensitivities to different regulators (2). Our earlier studies have shown that Kir2 channels, one of the major subfamilies of Kir that are responsible for maintaining membrane potential in a variety of cell types, are strongly suppressed by the elevation of membrane cholesterol (4, 5). Cholesterol-induced suppression of Kir2 was first observed in aortic endothelial cells (4), in which resting K⁺ conductance is dominated by Kir2.1 and Kir2.2 channels (6), and then when channels were heterologously expressed in Chinese hamster ovary cells (5, 7). Furthermore, the same effect was observed ex vivo in endothelial cells and bone marrow-derived progenitor cells isolated from hypercholesterolemic pigs (8, 9).In terms of the mechanism, the first insights came from comparing the effects of cholesterol and of its chiral analogue, epicholesterol. Although the two sterols are known to have almost identical effects on the biophysical properties of the lipid bilayer (10, 11), their impact on Kir activity is completely different; partial substitution of endogenous cholesterol with epicholesterol resulted in significant increase in Kir current in endothelial cells (4). These observations suggest that specific sterol-protein interactions may be involved in the cholesterol sensitivity of Kir2 channels. However, in the complex environment of the plasma membrane, cholesterol may interact not only with the channels themselves but also with other proteins, which in turn may regulate the activity of the channels. In the cellular environment, therefore, it is impossible to discriminate between direct channel-cholesterol interactions and indirect effects. Moreover, it is impossible to define the actual concentrations of cholesterol in any given membrane compartment. To quantitatively test direct cholesterol-protein interactions, it is necessary to examine sensitivity of pure Kir channels to membrane cholesterol in a membrane of defined lipid composition. To date, only the cytoplasmic domains of several mammalian Kir channels have been purified (Kir2.1, Kir3.1, and Kir3.2) (12–15). We therefore concentrate in this study on the effect of cholesterol on two bacterial K⁺ channels that differ in the level of their homology to mammalian Kir channels, KirBac1.1 and KcsA. KirBac channels have high sequence homology with mammalian Kirs (e.g. 52% homology between KirBac1.1 and Kir2.1; see Fig. 7A) and have now been extensively used as structural models of mammalian Kir channels (3, 16, 17). The sequence similarity between KcsA and mammalian K channels lies mainly in the transmembrane domain (18). The overall sequence homology of KcsA to mammalian Kir channels is relatively low (e.g. 22% homology between KcsA and Kir2.1; see Fig. 7A), with an entirely different cytoplasmic domain structure.Open in a separate windowFIGURE 7.Cholesterol has no effect on KcsA-mediated ⁸⁶Rb⁺ uptake. A, time courses of ⁸⁶Rb⁺ uptake into liposomes reconstituted with 50 μg of cholesterol/mg of PL and as compared with liposomes containing no cholesterol (control). Both batches of liposomes contained 5 μg of KcsA/mg of PL. Blank liposomes contain no protein. The points represent averages of three independent experiments (means ± S.D.). B, normalized time courses of ⁸⁶Rb⁺ uptake in liposomes incorporating 50, 150, and 250 μg of cholesterol/mg of PL. C, maximal uptake of ⁸⁶Rb⁺ after 240 s in liposomes containing 10, 25, 50, 100, 150, 200, and 250 μg of cholesterol/mg of PL normalized to control (means ± S.D. of 3–5 independent experiments; *, p < 0.05). DPM, disintegrations per minute.Here we show that, similarly to Kir2 channels, prokaryotic Kir channels incorporated into liposomes are strongly suppressed by an increase in membrane cholesterol. Furthermore, the sensitivity of prokaryotic Kir to cholesterol is stereo-selective to cholesterol optical analogues. In contrast, KscA channels are insensitive to membrane cholesterol. These observations suggest that cholesterol directly suppresses Kir channels.