Hantaan virus infection causes an acute neurological disease that is fatal in adult laboratory mice

Hantaan virus, the etiological agent of Korean hemorrhagic fever, is transmitted to humans from persistently infected mice (Apodemus agrarius), which serve as the primary reservoir. Here we demonstrate that several strains of adult Mus musculus domesticus (C57BL/6, BALB/c, AKR/J, and SJL/J) were susceptible to Hantaan virus infection when infected intraperitoneally. First clinical signs were loss of weight, ruffled fur, and reduced activity, which were followed by neurological symptoms, such as paralyses and convulsions. Within 2 days of disease onset, the animals died of acute encephalitis. PCR analysis indicated a systemic infection with viral RNA present in all major organs. Immunohistochemical and in situ hybridization analyses of postmortem material detected viral antigen and RNA in the central nervous system (predominantly brain), liver, and spleen. In the central nervous system, viral antigen and RNA colocalized with perivascular infiltrations, the predominant pathological finding. To investigate the involvement of the interferon system in Hantaan virus pathogenesis, we infected alpha/beta interferon receptor knockout mice. These animals were more susceptible to Hantaan virus infection, indicating an important role of interferon-induced antiviral defense mechanisms in Hantaan virus pathogenesis. The present model may help to overcome shortcomings in the development of therapeutic and prophylactic measurements against hantavirus infections.     

Constitutive Expression of Interferon-Induced Human MxA Protein in Transgenic Tobacco Plants Does not Confer Resistance to a Variety of RNA Viruses

MxA is a key component in the interferon-induced antiviral defense in humans. After viral infections, MxA is rapidly induced and accumulates in the cytoplasm. The multiplication of many RNA viruses,including all bunyaviruses tested so far, is inhibited by MxA. These findings prompted us to express MxA in plants in an attempt to create resistance to tospoviruses. Here, we report the generation of transgenic tobacco plants that constitutively express MxA under the control of the 35S cauliflower mosaic virus promotor. Northern and western blot analysis confirmed the expression of MxA in several transgenic plant lines. MxA expression had no obvious detrimental effects on plant growth and fertility. However, challenge experiments with tomato spotted wilt virus, tomato chlorotic spot virus, and groundnut ringspot virus revealed no increased resistance of MxA-transgenic tobacco plants to tospovirus infections. Neither was the multiplicationof tobacco mosaic virus, cucumber mosaic virus and potato virus Y inhibited in MxA-transgenic plants. The results indicate that the expression of human MxA alone does not enhance virus resistance in planta.     

Escherichia coli exhibits a membrane-related response to a small arginine- and tryptophan-rich antimicrobial peptide

Since multiresistant bacterial strains are more widespread and the victim numbers steadily increase, it is very important to possess a broad bandwidth of antimicrobial substances. Antibiotics often feature membrane-associated effect mechanisms. So, we present a membrane proteomic approach to shed light on the cellular response of Escherichia coli as model organism to the hexapeptide MP196, which is arginine and tryptophan rich. Analyzing integral membrane proteins are still challenging, although various detection strategies have been developed in the past. In particular, membrane proteomics in bacteria have been conducted very little due to the special physical properties of these membrane proteins. To obtain more information on the cellular response of the new compound group of small peptides, the tryptophan- and arginine-rich hexapeptide MP196 was subject to a comprehensive quantitative membrane proteomic study on E. coli by means of metabolic labeling in combination with membrane lipid analyses. This study provides in total 767 protein identifications including 185 integral membrane proteins, from which 624 could be quantified. Among these proteins, 134 were differentially expressed. Thereby, functional groups such as amino acid and membrane biosynthesis were affected, stress response could be observed, and the lipid composition of the membrane was significantly altered. Especially, the strong upregulation of the envelope stress induced protein. Spy indicates membrane damage, as well as the downregulation of the mechano-sensitive channel MscL beside others. Finally, the exceptional downregulation of transport systems strengthens these findings.     

Noncanonical Modulation of the eIF2 Pathway Controls an Increase in Local Translation during Neural Wiring

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Corynebacterium glutamicum exhibits a membrane-related response to a small ferrocene-conjugated antimicrobial peptide

Multiresistant bacteria are becoming more and more widespread. It is therefore necessary to have new compound groups in hand, such as small cationic peptides, to cope with these challenges. In this work, we present a comprehensive approach by monitoring protein expression profiles in a Gram-positive bacterium (Corynebacterium glutamicum) to investigate the cellular response to such a compound, a ferrocene-conjugated arginine- and tryptophan-rich pentapeptide. To achieve this, a proteomic outline was performed where the compound-treated sample was compared with an untreated control. This study comprises more than 900 protein identifications, including numerous integral membrane proteins, and among these 185 differential expressions. Surprisingly, unregulated catalase and no elevated H₂O₂ levels demonstrate that no oxidative stress occurs after treatment with the iron-containing compound as a consequence of the potential Fenton reaction. A sufficient iron supply is evidenced by the iron-containing protein aconitase and SufB (the latter belongs to an iron–sulfur cluster assembly system) and decreased levels of ATP-binding-cassette-type cobalamin/Fe³⁺ siderophore transporters. The organometallic peptide antibiotic targets the cell membrane, which is evident by decreased levels of various integral membrane proteins, such as peptide permeases and transporters, and an altered lipid composition. Conversion to a more rigid cell membrane seems to be a relevant protective strategy of C. glutamicum against the ferrocene-conjugated antimicrobial peptide compound.     

K?rperliches Training bei mitochondrialen Erkrankungen

Exercise is a promising therapeutical option for the treatment of mitochondrial myopathies. Its efficacy and safety have been proven in various studies. In patients with mitochondrial myopathy, resistance training and aerobic exercise training lead to widely diversified effects: resistance training is thought to normalize the mitochondrial DNA (mtDNA) genotype in mature myofibers by enhancing the incorporation of satellite cells and thereby increasing the ratio of wild-type to mutant mtDNA (??gene shifting??). Aerobic exercise training induces mitochondrial biogenesis and helps breaking the vicious circle of low oxidative phosphorylation capacity, exercise intolerance, and progressive muscular deconditioning. Certain drugs act as inductors of mitochondrial biogenesis but their safety and efficacy in patients with mitochondrial myopathy have to be further investigated.     

Circadian and age-dependent expression patterns of GLUT2 and glucokinase in the pancreatic beta-cell of diabetic and nondiabetic rats.

Alterations in glucose sensing are well-known in both humans and animal models of non-insulin-dependent diabetes mellitus. However, the circadian- and age-dependent expression of glucose-sensing genes has not previously been investigated in vivo. In the present paper, we show a progressive loss of beta-cell GLUT2-mRNA and, by immunocytochemistry, a gain of soluble, cytoplasmic GLUT2-protein in Goto-Kakizaki rat islets. We report that GLUT2-mRNA shows significant diurnal variation, which is stronger in metabolically healthy rats. We also demonstrate the significant diurnal variation of glucokinase-mRNA, with higher levels in the pancreas of 6-week-old Goto-Kakizaki rats than in Wistar rats. This leads to a maximum glucose phosphorylation capacity in-phase with food intake, enhanced glucose-stimulated insulin secretion, and prevents postprandial hyperglycemia. Perfusion experiments showed a reduction in glucose-stimulated insulin secretion in Goto-Kakizaki rat islets with an impaired first phase. Hyperglycemia and hypoinsulinemia in newborn and up to 3-week-old Goto-Kakizaki rats are thus probably due to reduced pancreatic beta-cell content, reduced beta-cell insulin content and impaired glucose sensing. The de-compensation of the metabolic situation in 42-week-old Goto-Kakizaki rats is likely to be caused by beta-cell destruction accompanied by negligible accumulation of GLUT2 in the cell membrane and further reduction of glucokinase expression.     

Thermal conditioning improves quality and speed of keratinocyte sheet production for burn wound treatment

Background aimsCultured patient-specific keratinocyte sheets have been used clinically since the 1970s for the treatment of large severe burns. However, despite significant developments in recent years, successful and sustainable treatment is still a challenge. Reliable, high-quality grafts with faster availability and a flexible time window for transplantation are required to improve clinical outcomes.MethodsKeratinocytes are usually grown in vitro at 37°C. Given the large temperature differences in native skin tissue, the aim of the authors’ study was to investigate thermal conditioning of keratinocyte sheet production. Therefore, the influence of 31°C, 33°C and 37°C on cell expansion and differentiation in terms of proliferation and sheet formation efficacy was investigated. In addition, the thermal effect on the biological status and thus the quality of the graft was assessed on the basis of the release of wound healing-related biofactors in various stages of graft development.ResultsThe authors demonstrated that temperature is a decisive factor in the production of human keratinocyte sheets. By using specific temperature ranges, the authors have succeeded in optimizing the individual manufacturing steps. During the cell expansion phase, cultivation at 37°C was most effective. After 6 days of culture at 37°C, three times and six times higher numbers of viable cells were obtained compared with 33°C and 31°C. During the cell differentiation and sheet formation phase, however, the cells benefited from a mildly hypothermic temperature of 33°C. Keratinocytes showed increased differentiation potential and formed better epidermal structures, which led to faster biomechanical sheet stability at day 18. In addition, a cultivation temperature of 33°C resulted in a longer lasting and higher secretion of the investigated immunomodulatory, anti-inflammatory, angiogenic and pro-inflammatory biofactors.ConclusionsThese results show that by using specific temperature ranges, it is possible to accelerate the large-scale production of cultivated keratinocyte sheets while at the same time improving quality. Cultivated keratinocyte sheets are available as early as 18 days post-biopsy and at any time for 7 days thereafter, which increases the flexibility of the process for surgeons and patients alike. These findings will help to provide better clinical outcomes, with an increased take rate in severe burn patients.