Compartmentation of glutamate metabolism in brain. Evidence for the existence of two different tricarboxylic acid cycles in brain

1. (14)C from [1-(14)C]glucose injected intraperitoneally into mice is incorporated into glutamate, aspartate and glutamine in the brain to a much greater extent than (14)C from [2-(14)C]glucose. This difference for [1-(14)C]glucose and [2-(14)C]glucose increases with time. The amount of (14)C in C-1 of glutamate increases steadily with time with both precursors. It is suggested that a large part of the glutamate and aspartate pools in brain are in close contact with intermediates of a fast-turning tricarboxylic acid cycle. 2. (14)C from [1-(14)C]acetate and [2-(14)C]acetate is incorporated to a much larger extent into glutamine than into glutamate. An examination of the time-course of (14)C incorporated into glutamine and glutamate reveals that glutamine is not formed from the glutamate pool, labelled extensively by glucose, but from a small glutamate pool. This small glutamate pool is not derived from an intermediate of a fast-turning tricarboxylic acid cycle. 3. It is proposed that two different tricarboxylic acid cycles exist in brain.     

Analysis of inhibitors of bacteriophage T4 DNA polymerase.

Bacteriophage T4 DNA polymerase was inhibited by butylphenyl nucleotides, aphidicolin and pyrophosphate analogs, but with lower sensitivities than other members of the B family DNA polymerases. The nucleotides N2-(p-n-butylphenyl)dGTP (BuPdGTP) and 2-(p-n-butylanilino)dATP (BuAdATP) inhibited T4 DNA polymerase with competitive Ki values of 0.82 and 0.54 microM with respect to dGTP and dATP, respectively. The same compounds were more potent inhibitors in truncated assays lacking the competitor dNTP, displaying apparent Ki values of 0.001 and 0.0016 microM, respectively. BuPdGTP was a substrate for T4 DNA polymerase, and the resulting 3'-BuPdG-primer:template was bound strongly by the enzyme. Each of the non-substrate derivatives, BuPdGDP and BuPdGMPCH2PP, inhibited T4 DNA polymerase with similar potencies in both the truncated and variable competitor assays. These results indicate that BuPdGTP inhibits T4 DNA polymerase by distinct mechanisms depending upon the assay conditions. Reversible competitive inhibition predominates in the presence of dGTP, and incorporation in the absence of dGTP leads to potent inhibition by the modified primer:template. The implications of these findings for the use of these inhibitors in the study of B family DNA polymerases is discussed.     

Genetic Evidence for Two Protein Domains and a Potential New Activity in Bacteriophage T4 DNA Polymerase

Intragenic complementation was detected within the bacteriophage T4 DNA polymerase gene. Complementation was observed between specific amino (N)-terminal, temperature-sensitive (ts) mutator mutants and more carboxy (C)-terminal mutants lacking DNA polymerase polymerizing functions. Protein sequences surrounding N-terminal mutation sites are similar to sequences found in Escherichia coli ribonuclease H (RNase H) and in the 5'----3' exonuclease domain of E. coli DNA polymerase I. These observations suggest that T4 DNA polymerase, like E. coli DNA polymerase I, contains a discrete N-terminal domain.     

Structure-function studies of the bacteriophage T4 DNA polymerase. Isolation of a novel suppressor mutant

We describe here our first attempt in using suppressor mutations to study structure-function relationships of the bacteriophage T4 DNA polymerase. One intragenic suppressor mutation, J5(43) degrees, was isolated that suppresses the temperature sensitivity but not the mutator activity of tsM19, a DNA polymerase mutant. Thus, the substituted amino acid induced by the tsM19 lesion decreases DNA polymerase fidelity, even if the temperature sensitivity has been corrected by a second amino acid substitution in the DNA polymerase polypeptide. The isolation, mapping and characterization of the J5(43) degrees mutation as well as the purification and characterization of the tsM19-J5(43) degrees mutant DNA polymerase are presented. The suppressor isolation procedure has general applicability for the selection of suppressor mutations of other T4 DNA polymerase mutator mutants.     

In vitro selection of sequence contexts which enhance bypass of abasic sites and tetrahydrofuran by T4 DNA polymerase holoenzyme

The influence of sequence context on the ability of DNA polymerase to bypass sites of base loss was addressed using an in vitro selection system. Oligonucleotides containing either an aldehydic abasic site or tetrahydrofuran surrounded by four randomized bases on both the 5' and 3' sides were used as templates for synthesis by phage T4 DNA polymerase holoenzyme proficient or deficient in the 3'-->5' proofreading exonuclease activity. Successful bypass products were purified, subcloned and the sequences of approximately 100 subclones were determined for each of the four polymerase/lesion combinations tested. Between 7 and 19 % of the bypass products contained deletions of one to three nucleotides in the randomized region. In bypass products not containing deletions, biases for and against certain nucleotides were readily noticeable across the entire randomized region. Template strands from successful bypass products of abasic sites had a high frequency of T in most of the randomized positions, while those from bypass products of tetrahydrofuran had a high frequency of G at the positions immediately to the 3' and 5' side of the lesion. Consensus sequences were shared by successful bypass products of the same lesion but not between bypass products of the two lesions. The consensus sequence for efficient bypass of tetrahydrofuran was over-represented in several frames relative to the lesion. T4 DNA polymerase inserted A opposite abasic sites 63 % of the time in the presence of proofreading and 79 % of the time in its absence, followed by G>T>C, while the insertion of A opposite tetrahydrofuran ranged between 93 % and 100 % in the presence and absence of proofreading, respectively. Finally, sequence context influenced the choice of nucleotide inserted opposite abasic sites and consensus sequences which favored the incorporation of nucleotides other than A were defined.     

Progress towards single-molecule DNA sequencing: a one color demonstration

Single molecules of fluorescently labeled nucleotides were detected during the cleavage of individual DNA fragments by a processive exonuclease. In these experiments, multiple (10-100) strands of DNA with tetramethyl rhodamine labeled dUMP (TMR-dUMP) incorporated into the sequence were anchored in flow upstream of the detection region of an ultra sensitive flow cytometer. A dilute solution of Exonuclease I passed over the microspheres. When an exonuclease attached to a strand, processive digestion of that strand began. The liberated, labeled bases flowed through the detection region and were detected at high efficiency at the single-molecule level by laser-induced fluorescence. The digestion of a single strand of DNA by a single exonuclease was discernable in these experiments. This result demonstrates the feasibility of single-molecule DNA sequencing. In addition, these experiments point to a new and practical means of arriving at a consensus sequence by individually reading out identical sequences on multiple fragments.     

DNA polymerase proofreading: Multiple roles maintain genome stability

DNA polymerase proofreading is a spell-checking activity that enables DNA polymerases to remove newly made nucleotide incorporation errors from the primer terminus before further primer extension and also prevents translesion synthesis. DNA polymerase proofreading improves replication fidelity ∼ 100-fold, which is required by many organisms to prevent unacceptably high, life threatening mutation loads. DNA polymerase proofreading has been studied by geneticists and biochemists for > 35 years. A historical perspective and the basic features of DNA polymerase proofreading are described here, but the goal of this review is to present recent advances in the elucidation of the proofreading pathway and to describe roles of DNA polymerase proofreading beyond mismatch correction that are also important for maintaining genome stability.     

<Emphasis Type="Italic">Pseudomonas aeruginosa</Emphasis> inhibits <Emphasis Type="Italic">in-vitro Candida</Emphasis> biofilm development

Background  

Elucidation of the communal behavior of microbes in mixed species biofilms may have a major impact on understanding infectious diseases and for the therapeutics. Although, the structure and the properties of monospecies biofilms and their role in disease have been extensively studied during the last decade, the interactions within mixed biofilms consisting of bacteria and fungi such as Candida spp. have not been illustrated in depth. Hence, the aim of this study was to evaluate the interspecies interactions of Pseudomonas aeruginosa and six different species of Candida comprising C. albicans, C. glabrata, C. krusei, C. tropicalis, C. parapsilosis, and C. dubliniensis in dual species biofilm development.