Human myocardial Na,K-ATPase concentration in heart failure

The Na,K-ATPase is of major importance for active ion transport across the sarcolemma and thus for electrical as well as contractile function of the myocardium. Furthermore, it is receptor for digitalis glycosides. In human studies of the regulatory aspects of myocardial Na,K-ATPase concentration a major problem has been to obtain tissue samples. Methodological accomplishments in quantification of myocardial Na,K-ATPase using vanadate facilitated ³H-ouabain binding to intact samples have, however, made it possible to obtain reliable measurements on human myocardial necropsies obtained at autopsy as well as on biopsies of a wet weight of only 1–2 mg obtained during heart catheterisation. However, access to the ultimately, normal, vital myocardial tissue has come from the heart transplantation programs, through which myocardial samples from cardiovascular healthy organ donors have become available. In the present paper we evaluate the various values reported for normal human myocardial Na,K-ATPase concentration, its regulation in heart disease and the association with digitalization. Normal myocardial Na,K-ATPase concentration level is found to be 700 pmol/g wet weight. No major variations were found between or within the walls of the heart ventricles. During the first few years of life a marked decrease in myocardial Na,K-ATPase concentration is followed by a stable level obtained in early adulthood and normally maintained throughout life. In patients with enlarged cardiac x-ray silhouette a significant positive, linear correlation between left ventricular ejection fraction (EF) and Na,K-ATPase concentration was established. A maximum reduction in Na,K-ATPase concentration of 89% was obtained when EF was reduced to 20%. Generally, heart failure associated with heart dilatation, myocardial hypertrophy as well as ischaemic heart disease is associated with reductions in myocardial Na,K-ATPase concentration of around 25%. During digoxin treatment of heart failure patients a further reduction in functional myocardial Na,K-ATPase concentration of 15% has been found. Thus, the total reduction in functional myocardial Na,K-ATPase concentration in digitalised heart failure patients may well be of the magnitude 40%. In conclusion, it has become possible to quantify human myocardial Na,K-ATPase in health and disease. Revealed reductions are in heart failure of importance for contractile function, generation of arrhythmia and for digoxin treatment.     

Analysis of functional domain organization in DNA topoisomerase II from humans and Saccharomyces cerevisiae.

The functional domain structure of human DNA topoisomerase IIalpha and Saccharomyces cerevisiae DNA topoisomerase II was studied by investigating the abilities of insertion and deletion mutant enzymes to support mitotic growth and catalyze transitions in DNA topology in vitro. Alignment of the human topoisomerase IIalpha and S. cerevisiae topoisomerase II sequences defined 13 conserved regions separated by less conserved or differently spaced sequences. The spatial tolerance of the spacer regions was addressed by insertion of linkers. The importance of the conserved regions was assessed through deletion of individual domains. We found that the exact spacing between most of the conserved domains is noncritical, as insertions in the spacer regions were tolerated with no influence on complementation ability. All conserved domains, however, are essential for sustained mitotic growth of S. cerevisiae and for enzymatic activity in vitro. A series of topoisomerase II carboxy-terminal truncations were investigated with respect to the ability to support viability, cellular localization, and enzymatic properties. The analysis showed that the divergent carboxy-terminal region of human topoisomerase IIalpha is dispensable for catalytic activity but contains elements that specifically locate the protein to the nucleus.     

Characterization of an altered DNA catalysis of a camptothecin-resistant eukaryotic topoisomerase I.

We investigated topoisomerase I activity at a specific camptothecin-enhanced cleavage site by use of a partly double-stranded DNA substrate. The cleavage site belongs to a group of DNA topoisomerase I sites which is only efficiently cleaved by wild-type topoisomerase I (topo I-wt) in the presence of camptothecin. With a mutated camptothecin-resistant form of topoisomerase I (topo I-K5) previous attempts to reveal cleavage activity at this site have failed. On this basis it was questioned whether the mutant enzyme has an altered DNA sequence recognition or a changed rate of catalysis at the site. Utilizing a newly developed assay system we demonstrate that topo I-K5 not only recognizes and binds to the strongly camptothecin-enhanced cleavage site but also has considerable cleavage/religation activity at this particular DNA site. Thus, topo I-K5 has a 10-fold higher rate of catalysis and a 10-fold higher affinity for DNA relative to topo I-wt. Our data indicate that the higher cleavage/religation activity of topo I-K5 is a result of improved DNA binding and a concomitant shift in the equilibrium between cleavage and religation towards the religation step. Thus, a recently identified point mutation which characterizes the camptothecin-resistant topo I-K5 has altered the enzymatic catalysis without disturbing the DNA sequence specificity of the enzyme.     

(Na + K)-ATPase activity of crude homogenates of rat skeletal muscle as estimated from their K-dependent 3-O-methylfluorescein phosphatase activity

A highly sensitive fluorimetric assay using 3-O-methylfluorescein phosphate as substrate was used in the determination of K⁺-dependent phosphatase activity in preparations of rat skeletal muscle. The gastrocnemius muscle was chosen because of mixed fibre composition. Crude, detergent treated homogenate was used so as to avoid loss of activity during purification. K⁺-dependent phosphatase activities in the range 0.19–0.37 μmol · (g wet weight)⁻¹ · min⁻¹ were obtained, the value decreasing with age and K⁺-deficiency. Complete inhibition of the K⁺-dependent phosphatase was obtained with 10⁻³ M ouabain. Using a KSCN-extracted muscle enzyme the intimate relation between K⁺-dependent phosphatase activity and (Na⁺ + K⁺)-activated ATP hydrolysis could be demonstrated. A molecular activity of 620 min⁻¹ was estimated from simultaneous determination of K⁺-dependent phosphatase activity and [³H]ouabain binding capacity using the partially purified enzyme preparation. The corresponding enzyme concentration in the crude homogenates was calculated and corresponded well with the number of [³H]ouabain binding sites measured in intact muscles or biopsies hereof.     

UPTAKE OF GLUCOSE ANALOGUES BY RAT BRAIN CORTEX SLICES: Na+-INDEPENDENT MEMBRANE TRANSPORT

Abstract— The glucose analogues 3-O-methyl-D-glucose and α-methyl-D-glucoside were not metabolized in brain tissue.
The uptake of these two sugars into the intracellular compartment of brain cortex slices was investigated using media with normal and low Na⁺ concentration (replacement of all NaCl with choline Cl). The cellular transport was not Na⁺-dependent. The transport mechanism clearly distinguished between the two sugars in both normal and low Na⁺ media.     

Complete genome sequence of Desulfocapsa sulfexigens,a marine deltaproteobacterium specialized in disproportionating inorganic sulfur compounds

Desulfocapsa sulfexigens SB164P1 (DSM 10523) belongs to the deltaproteobacterial family Desulfobulbaceae and is one of two validly described members of its genus. This strain was selected for genome sequencing, because it is the first marine bacterium reported to thrive on the disproportionation of elemental sulfur, a process with a unresolved enzymatic pathway in which elemental sulfur serves both as electron donor and electron acceptor. Furthermore, in contrast to its phylogenetically closest relatives, which are dissimilatory sulfate-reducers, D. sulfexigens is unable to grow by sulfate reduction and appears metabolically specialized in growing by disproportionating elemental sulfur, sulfite or thiosulfate with CO₂ as the sole carbon source. The genome of D. sulfexigens contains the set of genes that is required for nitrogen fixation. In an acetylene assay it could be shown that the strain reduces acetylene to ethylene, which is indicative for N-fixation. The circular chromosome of D. sulfexigens SB164P1 comprises 3,986,761 bp and harbors 3,551 protein-coding genes of which 78% have a predicted function based on auto-annotation. The chromosome furthermore encodes 46 tRNA genes and 3 rRNA operons.     

Personality may influence reactivity to stress

Background  

Possible mechanisms behind psychophysiological hyperreactivity may be located at a cognitive-emotional level. Several personality traits have been associated with increased cardiovascular reactivity. Subjects with white coat hypertension, which may constitute a kind of hyperreactivity, are found to suppress their emotions and adapt to the surroundings to a larger extent than controls.     

N-losses and energy use in a scenario for conversion to organic farming

The aims of organic farming include the recycling of nutrients and organic matter and the minimisation of the environmental impact of agriculture. Reduced nitrogen (N)-losses and energy (E)-use are therefore fundamental objectives of conversion to organic farming. However, the case is not straightforward, and different scenarios for conversion to organic farming might lead to reduced or increased N-losses and E-use. This paper presents a scenario tool that uses a Geographical Information System in association with models for crop rotations, fertilisation practices, N-losses, and E-uses. The scenario tool has been developed within the multidisciplinary research project Land Use and Landscape Development Illustrated with Scenarios (ARLAS). A pilot scenario was carried out, where predicted changes in N-losses and E-uses following conversion to organic farming in areas with special interests in clean groundwater were compared. The N-surplus and E-use were on average reduced by 10 and 54%, respectively. However, these reductions following the predicted changes in crop rotations, livestock densities, and fertilisation practices were not large enough to ensure a statistically significant reduction at the 95% level. We therefore recommend further research in how conversion to organic farming or other changes in the agricultural practice might help to reduce N-surpluses and E-uses. In that context, the presented scenario tool would be useful.     

Dynamics of human DNA topoisomerases IIalpha and IIbeta in living cells

DNA topoisomerase (topo) II catalyses topological genomic changes essential for many DNA metabolic processes. It is also regarded as a structural component of the nuclear matrix in interphase and the mitotic chromosome scaffold. Mammals have two isoforms (alpha and beta) with similar properties in vitro. Here, we investigated their properties in living and proliferating cells, stably expressing biofluorescent chimera of the human isozymes. Topo IIalpha and IIbeta behaved similarly in interphase but differently in mitosis, where only topo IIalpha was chromosome associated to a major part. During interphase, both isozymes joined in nucleolar reassembly and accumulated in nucleoli, which seemed not to involve catalytic DNA turnover because treatment with teniposide (stabilizing covalent catalytic DNA intermediates of topo II) relocated the bulk of the enzymes from the nucleoli to nucleoplasmic granules. Photobleaching revealed that the entire complement of both isozymes was completely mobile and free to exchange between nuclear subcompartments in interphase. In chromosomes, topo IIalpha was also completely mobile and had a uniform distribution. However, hypotonic cell lysis triggered an axial pattern. These observations suggest that topo II is not an immobile, structural component of the chromosomal scaffold or the interphase karyoskeleton, but rather a dynamic interaction partner of such structures.