The steady-state kinetic mechanism of ATP hydrolysis catalyzed by membrane-bound (Na+ + K+)-ATPase from ox brain IV. Rate constant determination

The expressions for the kinetic constants corresponding to the steady state model for hydrolysis of ATP catalyzed by (Na⁺ + K⁺)-ATPase proposed recently are analyzed with the object of determining the rate constants. The theoretical background for the necessary procedures is described. The results of this analysis are: (1) A small class (four) of rate constants are determined directly by the previously published values of the kinetic constants. (2) For a somewhat larger class of rate constants upper and lower bounds may be established. For several rate constants the upper and lower bounds differ by less than a factor 1.6 (for the ‘(Na⁺ + K⁺)-enzyme’, i.e. the enzyme activity with K⁺ and millimolar substrate concentration) and 1.2 (for the ‘Na⁺-enzyme’, i.e. the activity at micromolar substrate concentrations). (3) Experiments on inhibition by K⁺ of the Na⁺-enzyme at various Mg²⁺ concentrations are reported and analyzed. With the additional assumption that the rate constants governing the addition to ATP of Mg²⁺ is independent of whether or not ATP is bound to an enzyme molecule, a set of consistent values for all the 23 rate constants in the mechanism may be obtained. (4) The values of some rate constants lend further support to the contention discussed in a previous paper that the enzyme hydrolyzes ATP along two kinetically distinct pathways, depending on the presence of K⁺ and on the concentration of substrate, without the necessity of having more than one active substrate site per enzyme unit at any time. (5) The results show that while the two enzyme forms, the ‘Na⁺-enzyme’ E₁ and the “K⁺-enzyme” E₂K, add substrate with (second order) rate constants of the same order of magnitude (differing only by a factor of four in favor of the former), the rate constants for the reverse processes differ by a factor of 100, being largest for the K⁺-enzyme. This is the main reason for the large difference in the Michaelis constants for the two forms reported previously. (6) Compatibility of the model with the well-known rapid dephosphorylation of the phosphorylated enzyme in the presence of K⁺ requires the presence, at non-zero steady state concentration, of an enzyme-potassium-phosphate intermediate, which is acid labile and is therefore not detected as a phosphorylated enzyme using conventional methods.     

Chromosomal locations of two DNA segments that flank ribosomal insertion-like sequences in Drosophila: Flanking sequences are mobile elements

We report the chromosomal locations of two repetitive DNA sequences that flank ribosomal insertion-like sequences in Drosophila melanogaster. The chromocentric region of D. melanogaster contains many copies of sequences that are homologous to type 1 ribosomal insertions. These insertion-like elements are interspersed with other DNA segments that we call flanking sequences. Two distinct flanking sequences derived from the same cloned DNA molecule pDmI 101, the HindIII fragments 101E and 101F, were studied. Whole genome Southern blots with DNA from the D. melanogaster stocks Oregon R (P2), gt-1, and gt-X11 showed complex restriction patterns that differed substantially between the three stocks. This and other data show that flanking sequences are members of diverged repetitive sequence families. In situ hybridization to salivary gland chromosomes of gt-1 and gt-X11 showed that both sequences are homologous to the chromocenter and to about 5 to 8 (101E) or 25 to 30 (101F) euchromatic sites in each stock. Most, if not all, of these sites differed in gt-1 and gt-X11. Both 101E and 101F are homologous to the chromocenter and very few euchromatic bands in D. simulans, but 101F is homologous to numerous bands in D. mauritiana. We conclude that the flanking sequences represented by 101E and 101F are mobile elements within the genome of Drosophila. These two sequences differ in several structural features from mobile DNA elements previously described in this organism.We dedicate this paper to Professor W. Beermann at the occasion of his 60th birthday     

Patterns of ribosomal DNA spacer lengths are inherited

The non-transcribed spacer regions in Xenopus laevis ribosomal DNA vary in length, even within a single nucleolar organizer. The pattern of spacer lengths is sufficiently different from one nucleolar organizer to another to allow the pattern to be used as a genetic marker. We have analyzed the spacer patterns of rDNA² from a total of 50 progeny from three separate matings. Spacer patterns were inherited with no detectable change in all but two cases. The reproducibility of the patterns among siblings and their stable inheritance between generations rule out sudden mechanisms for gene evolution, such as the master-slave model, and support more gradual mechanisms.Two animals out of 50 showed marked changes in their rDNA spacer patterns. It is not possible at present to decide which of several possible mechanisms were responsible for the observed changes.     

Are fire,soil fertility and toxicity,water availability,plant functional diversity,and litter decomposition related in a Neotropical savanna?

Understanding how biodiversity and ecosystem functioning respond to changes in the environment is fundamental to the maintenance of ecosystem function. In realistic scenarios, the biodiversity-ecosystem functioning path may account for only a small share of all factors determining ecosystem function. Here, we investigated the strength to which variations in environmental characteristics in a Neotropical savanna affected functional diversity and decomposition. We sought an integrative approach, testing a number of pairwise hypotheses about how the environment, biodiversity, and functioning were linked. We used structural equation modelling to connect fire frequency, soil fertility, exchangeable Al, water availability, functional diversity of woody plants, tree density, tree height, and litter decomposition rates in a causal chain. We found significant effects of soil nutrients, water availability, and Al on functional diversity and litter decomposition. Fire did not have a significant direct effect on functional diversity or litter decomposition. However, fire was connected to both variables through soil fertility. Functional diversity did not influence rates of litter decomposition. The mediated effects that emerged from pairwise interactions are encouraging not only for predicting the functional consequences of changes in environmental variables and biodiversity, but also to caution against predictions based on only environmental or only biodiversity change.     

N-terminal region of Saccharomyces cerevisiae eRF3 is essential for the functioning of the eRF1/eRF3 complex beyond translation termination

Background  

Termination of translation in eukaryotes requires two release factors, eRF1, which recognizes all three nonsense codons and facilitates release of the nascent polypeptide chain, and eRF3 stimulating translation termination in a GTP-depended manner. eRF3 from different organisms possess a highly conservative C region (eRF3C), which is responsible for the function in translation termination, and almost always contain the N-terminal extension, which is inessential and vary both in structure and length. In the yeast Saccharomyces cerevisiae the N-terminal region of eRF3 is responsible for conversion of this protein into the aggregated and functionally inactive prion form.     

Insulation of the chicken beta-globin chromosomal domain from a chromatin-condensing protein,MENT

Active genes are insulated from developmentally regulated chromatin condensation in terminally differentiated cells. We mapped the topography of a terminal stage-specific chromatin-condensing protein, MENT, across the active chicken beta-globin domain. We observed two sharp transitions of MENT concentration coinciding with the beta-globin boundary elements. The MENT distribution profile was opposite to that of acetylated core histones but correlated with that of histone H3 dimethylated at lysine 9 (H3me2K9). Ectopic MENT expression in NIH 3T3 cells caused a large-scale and specific remodeling of chromatin marked by H3me2K9. MENT colocalized with H3me2K9 both in chicken erythrocytes and NIH 3T3 cells. Mutational analysis of MENT and experiments with deacetylase inhibitors revealed the essential role of the reaction center loop domain and an inhibitory affect of histone hyperacetylation on the MENT-induced chromatin remodeling in vivo. In vitro, the elimination of the histone H3 N-terminal peptide containing lysine 9 by trypsin blocked chromatin self-association by MENT, while reconstitution with dimethylated but not acetylated N-terminal domain of histone H3 specifically restored chromatin self-association by MENT. We suggest that histone H3 modification at lysine 9 directly regulates chromatin condensation by recruiting MENT to chromatin in a fashion that is spatially constrained from active genes by gene boundary elements and histone hyperacetylation.     

DNA polymerase lambda from calf thymus preferentially replicates damaged DNA

A new gene (POLL), has been identified encoding the novel DNA polymerase lambda and mapped to mouse chromosome 19 and at human chromosome 10. DNA polymerase lambda contains all the critical residues involved in DNA binding, nucleotide binding, nucleotide selection, and catalysis of DNA polymerization and has been assigned to family X based on sequence homology with polymerase beta, lambda, mu, and terminal deoxynucleotidyltransferase. Here we describe a purification of DNA polymerase lambda from calf thymus that preferentially can replicate damaged DNA. By testing polymerase activity on non-damaged and damaged DNA, DNA polymerase lambda was purified trough five chromatographic steps to near homogeneity and identified as a 67-kDa polypeptide that cross-reacted with monoclonal antibodies against DNA polymerase beta and polyclonal antibodies against DNA polymerase lambda. DNA polymerase lambda had no detectable nuclease activities and, in contrast to DNA polymerase beta, was aphidicolin-sensitive. DNA polymerase lambda was a 6-fold more accurate enzyme in an M13mp2 forward mutation assay and 5-fold more accurate in an M13mp2T90 reversion system than human recombinant DNA polymerase beta. The biochemical properties of the calf thymus DNA polymerase lambda, described here for the first time, are discussed in relationship to the proposed role for this DNA polymerase in vivo.