Strategies to Rescue the Consequences of Inducible Arginase-1 Deficiency in Mice

Arginase-1 catalyzes the conversion of arginine to ornithine and urea, which is the final step of the urea cycle used to remove excess ammonia from the body. Arginase-1 deficiency leads to hyperargininemia in mice and man with severe lethal consequences in the former and progressive neurological impairment to varying degrees in the latter. In a tamoxifen-induced arginase-1 deficient mouse model, mice succumb to the enzyme deficiency within 2 weeks after inducing the knockout and retain <2 % enzyme in the liver. Standard clinical care regimens for arginase-1 deficiency (low-protein diet, the nitrogen-scavenging drug sodium phenylbutyrate, ornithine supplementation) either failed to extend lifespan (ornithine) or only minimally prolonged lifespan (maximum 8 days with low-protein diet and drug). A conditional, tamoxifen-inducible arginase-1 transgenic mouse strain expressing the enzyme from the Rosa26 locus modestly extended lifespan of neonatal mice, but not that of 4-week old mice, when crossed to the inducible arginase-1 knockout mouse strain. Delivery of an arginase-1/enhanced green fluorescent fusion construct by adeno-associated viral delivery (rh10 serotype with a strong cytomegalovirus-chicken β-actin hybrid promoter) rescued about 30% of male mice with lifespan prolongation to at least 6 months, extensive hepatic expression and restoration of significant enzyme activity in liver. In contrast, a vector of the AAV8 serotype driven by the thyroxine-binding globulin promoter led to weaker liver expression and did not rescue arginase-1 deficient mice to any great extent. Since the induced arginase-1 deficient mouse model displays a much more severe phenotype when compared to human arginase-1 deficiency, these studies reveal that it may be feasible with gene therapy strategies to correct the various manifestations of the disorder and they provide optimism for future clinical studies.     

Historical Invasion Records Can Be Misleading: Genetic Evidence for Multiple Introductions of Invasive Raccoons (Procyon lotor) in Germany

Biological invasions provide excellent study systems to understand evolutionary, genetic and ecological processes during range expansions. There is strong evidence for positive effects of high propagule pressure and the associated higher genetic diversity on invasion success, but some species have become invasive despite small founder numbers. The raccoon (Procyon lotor) is often considered as a typical example for such a successful invasion resulting from a small number of founders. The species’ largest non-native population in Germany is commonly assumed to stem from a small number of founders and two separate founding events in the 1930s and 1940s. In the present study we analyzed 407 raccoons at 20 microsatellite loci sampled from the invasive range in Western Europe to test if these assumptions are correct. Contrary to the expectations, different genetic clustering methods detected evidence for at least four independent introduction events that gave rise to genetically differentiated subpopulations. Further smaller clusters were either artifacts or resulted from founder events at the range margin and recent release of captive individuals. We also found genetic evidence for on-going introductions of individuals. Furthermore a novel randomization process was used to determine the potential range of founder population size that would suffice to capture all the alleles present in a cluster. Our results falsify the assumption that this species has become widespread and abundant despite being genetically depauperate and show that historical records of species introductions may be misleading.     

Molecular cytogenetics of tragelaphine and alcelaphine interspecies hybrids: hybridization,introgression and speciation in some African antelope

Hybridization can occur naturally among diverging lineages as part of the evolutionary process leading to complete reproductive isolation, or it can result from range shifts and habitat alteration through global warming and/or other anthropogenic influences. Here we report a molecular cytogenetic investigation of hybridization between taxonomically distinct species of the Alcelaphini (Alcelaphus buselaphus 2n = 40 × Damaliscus lunatus 2n = 36) and the Tragelaphini (Tragelaphus strepsiceros 2n = 31/32 × Tragelaphus angasii 2n = 55/56). Cross-species fluorescence in situ hybridization provides unequivocal evidence of the scale of karyotypic difference distinguishing parental species. The findings suggest that although hybrid meiosis of the former cross would necessitate the formation of a chain of seven, a ring of four and one trivalent, the progeny follow Haldane''s rule showing F₁ male sterility and female fertility. The tragelaphine F₁ hybrid, a male, was similarly sterile and, given the 11 trivalents and chain of five anticipated in its meiosis, not unexpectedly so. We discuss these findings within the context of the broader evolutionary significance of hybridization in African antelope, and reflect on what these hold for our views of antelope species and their conservation.     

Cytoskeletal Components Define Protein Location to Membrane Microdomains

The plasma membrane is an important compartment that undergoes dynamic changes in composition upon external or internal stimuli. The dynamic subcompartmentation of proteins in ordered low-density (DRM) and disordered high-density (DSM) membrane phases is hypothesized to require interactions with cytoskeletal components. Here, we systematically analyzed the effects of actin or tubulin disruption on the distribution of proteins between membrane density phases. We used a proteomic screen to identify candidate proteins with altered submembrane location, followed by biochemical or cell biological characterization in Arabidopsis thaliana. We found that several proteins, such as plasma membrane ATPases, receptor kinases, or remorins resulted in a differential distribution between membrane density phases upon cytoskeletal disruption. Moreover, in most cases, contrasting effects were observed: Disruption of actin filaments largely led to a redistribution of proteins from DRM to DSM membrane fractions while disruption of tubulins resulted in general depletion of proteins from the membranes. We conclude that actin filaments are necessary for dynamic movement of proteins between different membrane phases and that microtubules are not necessarily important for formation of microdomains as such, but rather they may control the protein amount present in the membrane phases.Living cells need borders and molecular compartments for biochemical reactions and storage of metabolites. The plasma membrane therefore is a prerequisite for the evolution of different life forms. It consists of a phospholipid bilayer into which proteins and special lipid species such as sterols, sphingolipids, and glycolipids are inserted. The first complex model of plasma membrane was proposed in 1972 by Jonathan Singer and Garth Nicolson (1), replacing the concept of the plasma membrane as a strict protein–lipid–protein sandwich that was generally accepted until then. In Singer and Nicolson''s model, the cell membrane is a two-dimensionally oriented viscous solution in which the membrane constituents are orientated in the most thermodynamically favorable manner, hiding hydrophobic hydrocarbon chains inside the lipid bilayer and exposing polar and ionic groups to the aqueous phase. This fluid mosaic model also implied that membrane proteins as well as lipid components are distributed in a homogeneous lipid bilayer at long range, but they can form specific aggregates and phases at short range, which were also termed “lipid rafts” or membrane microdomains.Over the past 30 years, it has become evident that the plasma membrane is not such a homogeneous structure as it was initially proposed. We now know that the lipid bilayer is asymmetric (2) and that the free diffusion of membrane proteins is restricted by their interactions with intracellular and extracellular components (3). More recently, Simons and Ikonen suggested that large ordered phases, enriched with cholesterol and sphingolipids, emerge within the plasma membrane and that they function as platforms for enrichment of certain proteins while excluding others (4). This current membrane model suggests that the mixture of sterols and polar lipids within the plasma membrane can appear in two distinct phases: liquid disordered (L_d) and liquid ordered (L_o) phase (5). In this view, the so-called membrane microdomains are considered to be part of the L_o phase. Based on work on model membranes, it is suggested that lateral segregation of components into L_d and L_o phases occurs spontaneously (6) with the self-associating properties between sterols and highly saturated hydrocarbon chains of phopsho- and sphingolipids as the main driving force (7). Additionally, it is suggested that also specific lipid-protein and protein-protein interactions are essential for the formations of membrane domains as well as for stabilization of smaller nanodomains which subsequently may cause formation of larger platforms. In contrast to the animal cells, in plants these membrane microdomains seem to be rather immobile (8), possibly due to their attachment to the outer cell wall. More recently, it became obvious that membrane microdomains within a single cell are highly diverse and of different compositions (9). Generally, in the plant model, organisms'' plasma membrane microdomains turned out to be important in plant defense (10, 11), cell polarity (12, 13), and general signaling properties of the plasma membrane (14, 15).The cytoskeleton was identified as an essential cellular component with important roles in membrane topography, bordering, trafficking, and organelle movement (16). Single particle tracking in mammalian cells revealed that the transferrin receptor and macroglobulin receptor demonstrate normal Brownian diffusion but only within a specific membrane compartment (17). Two hypothetical models were proposed in order to explain this phenomenon (supplemental Fig. 1). Direct interactions between transmembrane proteins and cytoskeleton are suggested to creates a barrier, called “fence,” where cytosolic parts of transmembrane proteins collides with cytoskeletal components, limiting their diffusion to certain areas. These molecules can jump over the “fence” to a neighboring compartment, possibly due to the dynamic nature of the interaction of membrane proteins and cytoskeleton, where they are again temporally trapped (17). This phenomenon was recently described also in A. thaliana where the interplay between membrane microdomains and microtubules plays a role in secondary cell wall formation (reviewed in (18)). The second model assumes, additionally, that particular transmembrane proteins are anchored to and lined up along cytoskeleton and act as “pickets” to arrest free diffusion of other membrane components, including nontransmembrane proteins, within the enclosed compartment (19).For plants, the composition of these sterol-rich membranes phases was analyzed in several biochemical studies (14, 20–22). Thereby, low-density preparations of plasma membrane fractions after treatment with nonionic detergents (DRM¹ fractions) were considered as a biochemical representation enriched in cellular membrane ordered phases or microdomains. Proteomic studies in mammalian cells consistently reported that the DRM fraction is highly enriched with several cytoskeletal proteins such as actin, tubulin, myosin, dynamin, actinin, and supervillin (23–25). Additionally, the level of phosphatidylinositol 4,5-bisphosphate (PI(4,5)P2), a lipid connecting the plasma membrane to actin filaments, was also significantly elevated in DRM preparations (26). Treatment with microtubule and actin depolymerizing agent results in drastic loss of many signaling proteins from these DRM fractions prepared from adult rat cardiac myocytes (27) or human embryonic retinal cells (28).Based on this knowledge, we propose two hypothetical models for the relationship between cytoskeleton and membrane microdomains for plant cells: (i) Actin filaments and microtubules could be important in the membrane phase separation or formation of the membrane microdomains themselves. In this case, disruption of the cytoskeleton would cause a lack of phase segregation in the plasma membrane. (ii) The cytoskeleton is only important for the incorporation of specific protein into the sterol-enriched regions but not for the general formation of these phase separations. This view implies that phase separations or membrane microdomains would still be present after cytoskeleton disruption but their protein composition can be different. Another possible scenario is (iii) that cytoskeletal elements serve as anchors for membrane microdomains at particular position in the plasma membrane, so the absence of these anchors would cause the increased mobility of microdomains (supplemental Fig. 1).The primary aim of this study was to characterize the interplay between cytoskeletal components and different membrane phases (microdomains) in A. thaliana suspension cell cultures. To reach this goal, biochemical and proteomic approaches were combined with confocal microscopy and activity assays measuring the influence of actin or tubulin disruption on the composition, localization, and biochemical properties of the sterol-enriched membrane microdomains. Thereby, for biochemical analyses, low-density detergent-resistant membrane fractions are analyzed as containing cellular sterol-rich membrane compartments.     

Criteria Used in Clinical Practice to Guide Immunosuppressive Treatment in Patients with Primary Sclerosing Cholangitis

Background & Aims

Current guidelines recommend immunosuppressive treatment (IT) in patients with primary sclerosing cholangitis (PSC) and elevated aminotransferase levels more than five times the upper limit of normal and elevated serum IgG-levels above twice the upper limit of normal. Since there is no evidence to support this recommendation, we aimed to assess the criteria that guided clinicians in clinical practice to initiate IT in patients with previously diagnosed PSC.

Methods

This is a retrospective analysis of 196 PSC patients from seven German hepatology centers, of whom 36 patients had received IT solely for their liver disease during the course of PSC. Analyses were carried out using methods for competing risks.

Results

A simplified autoimmune hepatitis (AIH) score >5 (HR of 36, p<0.0001) and a modified histological activity index (mHAI) greater than 3/18 points (HR 3.6, p = 0.0274) were associated with the initiation of IT during the course of PSC. Of note, PSC patients who subsequently received IT differed already at the time of PSC diagnosis from those patients, who did not receive IT during follow-up: they presented with increased levels of IgG (p = 0.004) and more frequently had clinical signs of cirrhosis (p = 0.0002).

Conclusions

This is the first study which investigates the parameters associated with IT in patients with PSC in clinical practice. A simplified AIH score >5 and a mHAI score >3, suggesting concomitant features of AIH, influenced the decision to introduce IT during the course of PSC. In German clinical practice, the cutoffs used to guide IT may be lower than recommended by current guidelines.     

SnAvi – a new tandem tag for high-affinity protein-complex purification

Systematic tandem-affinity-purification (TAP) of protein complexes was tremendously successful in yeast and has changed the general concept of how we understand protein function in eukaryotic cells. The transfer of this method to other model organisms has been difficult and may require specific adaptations. We were especially interested to establish a cell-type-specific TAP system for Caenorhabditis elegans, a model animal well suited to high-throughput analysis, proteomics and systems biology. By combining the high-affinity interaction between in vivo biotinylated target-proteins and streptavidin with the usage of a newly identified epitope of the publicly shared SB1 monoclonal antibody we created a novel in vivo fluorescent tag, the SnAvi-Tag. We show the versatile application of the SnAvi-Tag in Escherichia coli, vertebrate cells and in C. elegans for tandem affinity purification of protein complexes, western blotting and also for the in vivo sub-cellular localization of labelled proteins.     

Identification of protein stability determinants in chloroplasts

Although chloroplast protein stability has long been recognised as a major level of post‐translational regulation in photosynthesis and gene expression, the factors determining protein stability in plastids are largely unknown. Here, we have identified stability determinants in vivo by producing plants with transgenic chloroplasts that express a reporter protein whose N‐ and C‐termini were systematically modified. We found that major stability determinants are located in the N‐terminus. Moreover, testing of all 20 amino acids in the position after the initiator methionine revealed strong differences in protein stability and indicated an important role of the penultimate N‐terminal amino acid residue in determining the protein half life. We propose that the stability of plastid proteins is largely determined by three factors: (i) the action of methionine aminopeptidase (the enzyme that removes the initiator methionine and exposes the penultimate N‐terminal amino acid residue), (ii) an N‐end rule‐like protein degradation pathway, and (iii) additional sequence determinants in the N‐terminal region.     

Cre-mediated seed-specific transgene excision in tobacco

Here we report the production of marker-free transgenic plants expressing phenolic compounds with high pharmacological value. Our strategy consisted in simultaneous delivery of lox-target and cre-containing constructs into the plant genome by cotransformation. In the Cre-vector, the cre recombinase gene was controlled by a seed-specific napin promoter. In the lox-target construct the selectable bar gene was placed between two lox sites in direct orientation, while a napin promoter driven vstI gene was inserted outside of the lox sites. Upon seed-specific cre induction the bar expression cassette was excised from the tobacco genome. Genetic and molecular analysis of T1 progeny plants indicated DNA excision in all 10 transgenic lines tested. RP-HPLC analysis demonstrated that the expression of the vstI gene resulted in accumulation of trans-resveratrol and its glycosylated derivative piceid in seeds of all marker free lines. These findings indicate that the seed-specific marker gene excision did not interfere with the expression of the gene of interest. Our data demonstrated the feasi of a developmentally controlled cre gene to mediate site-specific excision in tobacco very efficiently.     

The new HNO donor, 1-nitrosocyclohexyl acetate, increases contractile force in normal and β-adrenergically desensitized ventricular myocytes

Haplotype, which is the sequence of SNPs in a specific chromosome, plays an important role in disease association studies. However, current sequencing techniques can detect the presence of SNP sites, but they cannot tell which copy of a pair of chromosomes the alleles belong to. Moreover, sequencing errors that occurred in sequencing SNP fragments make it difficult to determine a pair of haplotypes from SNP fragments. To help overcome this difficulty, the haplotype assembly problem is defined from the viewpoint of computation, and several models are suggested to tackle this problem. However, there are no freely available web-based tools to overcome this problem as far as we are aware. In this paper, we present a web-based application based on the genetic algorithm, named HapAssembler, for assembling a pair of haplotypes from SNP fragments. Numerical results on real biological data show that the correct rate of the proposed application in this paper is greater than 95% in most cases. HapAssembler is freely available at http://alex.chonnam.ac.kr/~drminor/hapHome.htm. Users can choose any model among four models for their purpose and determine haplotypes from their input data.