Effect of arteriovenous flow reversal on blood flow and metabolism in a skin flap

Twelve pig buttock island flaps (10 X 10 cm) were studied for 6 hours after arteriovenous flow reversal at the level of the pedicle. Follow-up was 48 hours. Blood pressure, Po2, pH, and lactate were measured in flap arteries and veins. Oxygen consumption was calculated. Data indicated true flow reversal. Blood pressure and Po2 in flap veins increased to systemic arterial levels. Outflow was provided by the arterial system, demonstrating venous pressure and Po2 values. Lactate increased significantly (1.8 +/- 0.5 to 4.0 +/- 2.3 mmol/liter), while pH dropped from 7.43 +/- 0.03 to 7.11 +/- 0.02. Oxygen consumption remained below baseline. In four flaps thrombosis occurred within 6 hours; no flap survived 48 hours. The results of this study do not encourage clinical application of the concept of flow reversal.     

Characterization of a parallel-stranded DNA hairpin

Recently we have shown that synthetic DNA containing homooligomeric A-T base pairs can form a parallel-stranded intramolecular hairpin structure [van de Sande et al. (1988) Science (Washington, D.C.) 241, 551-557]. In the present study, we have employed NMR and optical spectroscopy to investigate the structure of the parallel-stranded (PS) DNA hairpin 3'-d(T)8C4(A)8-3' and the related antiparallel (APS) hairpin 5'-d(T)8C4(A)8-3'. The parallel orientation of the strands in the PS oligonucleotide is achieved by introducing a 5'-5' phosphodiester linkage in the hairpin loop. Ultraviolet spectroscopic and fluorescence data of drug binding are consistent with the formation of PS and APS structures, respectively, in these two hairpins. Vacuum circular dichroism measurements in combination with theoretical CD calculations indicate that the PS structure forms a right-handed helix. 31P NMR measurements indicate that the conformation of the phosphodiester backbone of the PS structure is not drastically different from that of the APS control. The presence of slowly exchanging imino protons at 14 ppm and the observation of nuclear Overhauser enhancement between imino protons and the AH-2 protons demonstrate that similar base pairing and base stacking between T and A residues occur in both hairpins. However, the small chemical shift dispersion observed in proton NMR spectra of the PS hairpin suggests that the stem of this hairpin is more regular than that of the APS hairpin. On the basis of NOESY measurements, we find that the orientation of the bases is in the anti region and that the sugar puckering is in the 2'-endo range.(ABSTRACT TRUNCATED AT 250 WORDS)     

Perturbation of DNA hairpins containing the EcoRI recognition site by hairpin loops of varying size and composition: physical (NMR and UV) and enzymatic (EcoRI) studies.

We have investigated loop-induced structural perturbation of the stem structure in hairpins d(GAATTCXnGAATTC) (X = A, T and n = 3, 4, 5 and 6) that contain an EcoRI restriction site in close proximity to the hairpin loop. Oligonucleotides containing either a T3 or a A3 loop were not hydrolyzed by the restriction enzyme and also showed only weak binding to EcoRI in the absence of the cofactor Mg2+. In contrast, hairpins with larger loops are hydrolyzed by the enzyme at the scission site next to the loop although the substrate with a A4 loop is significantly more resistant than the oligonucleotide containing a T4 loop. The hairpin structures with 3 loop residues were found to be thermally most stable while larger hairpin loops resulted in structures with lower melting temperatures. The T-loop hairpins are thermally more stable than the hairpins containing the same number of A residues in the loop. As judged from proton NMR spectroscopy and the thermodynamic data, the base pair closest to the hairpin loop did form in all cases studied. The hairpin loops did, however, affect the conformation of the stem structure of the hairpins. From 31P and 1H NMR spectroscopy we conclude that the perturbation of the stem structure is stronger for smaller hairpin loops and that the extent of the perturbation is limited to 2-3 base pairs for hairpins with T3 or A4 loops. Our results demonstrate that hairpin loops modulate the conformation of the stem residues close to the loop and that this in turn reduces the substrate activity for DNA sequence specific proteins.     

Characterization of two allelic forms of Neurospora crassa laccase. Amino- and carboxyl-terminal processing of a precursor

The complete structures of the laccase genes isolated from two different Neurospora crassa wild-type strains are described. The genes were cloned by screening partial genomic DNA libraries with a nick-translated laccase-specified 1.36-kilobase SalI fragment (Germann, U. A., and Lerch, K. (1986) Proc. Natl. Acad. Sci. U.S.A. 83, 8854-8858) as a hybridization probe. Nucleotide sequence analysis revealed the presence of two different allelic forms. They conform to the same structural organization, but show an overall divergence of 5.3% which is mainly the result of point mutations in the nontranslated regions. The coding parts are interrupted by a short intron. The encoded proteins differ in 12 out of 619 amino acid residues. A comparison of the primary structure deduced from the nucleotide sequence of the gene with a protein chemical analysis of the two terminal cyanogen bromide fragments of extracellular N. crassa laccase revealed that the enzyme is synthesized as a precursor. The precursor protein exceeds the mature protein by 49 amino acids at its amino terminus and by 13 amino acids at its carboxyl terminus, thus indicating a complex maturation pathway. The possible involvement of amino-terminal processing in secretion and of carboxyl-terminal processing in activation of the enzyme is discussed.     

Expression of a multidrug resistance-adenosine deaminase fusion gene

A novel fusion gene has been created in which the expression of a dominant selectable marker, the human multidrug resistance gene, is directly linked to the expression of human adenosine deaminase cDNA. The chimeric gene was inserted between the long terminal repeats of a Harvey murine sarcoma virus expression vector and used to transfect drug-sensitive human KB carcinoma cells. Transfectants were selected in increasing concentrations of colchicine and found to contain multiple copies of the intact fusion gene, which is stably and efficiently expressed. A membrane-associated 210-kDa human P-glycoprotein-adenosine deaminase fusion protein is synthesized which retains function of the multidrug transporter and also exhibits adenosine deaminase activity. The data indicate that the human multidrug resistance gene may be used as a dominant selectable marker to introduce other genes in the form of gene fusions into cultured cells.     

Effects of phosphorylation of P-glycoprotein on multidrug resistance

Cells expressing elevated levels of the membrane phosphoprotein P-glycoprotein exhibit a multidrug resistance phenotype. Studies involving protein kinase activators and inhibitors have implied that covalent modification of P-glycoprotein by phosphorylation may modulate its biological activity as a multidrug transporter. Most of these reagents, however, have additional mechanisms of action and may alter drug accumulation within multidrug resistant cells independent of, or in addition to their effects on the state of phosphorylation of P-glycoprotein. The protein kinase(s) responsible for P-glycoprotein phosphorylation has(ve) not been unambiguously identified, although several possible candidates have been suggested. Recent biochemical analyses demonstrate that the major sites of phosphorylation are clustered within the linker region that connects the two homologous halves of P-glycoprotein. Mutational analyses have been initiated to confirm this finding. Preliminary data obtained from phosphorylation- and dephosphorylation-defective mutants suggest that phosphorylation of P-glycoprotein is not essential to confer multidrug resistance.     

Expression of the human multidrug transporter in insect cells by a recombinant baculovirus

The plasma membrane associated human multidrug resistance (MDR1) gene product, known as the 170-kDa P-glycoprotein or the multidrug transporter, acts as an ATP-dependent efflux pump for various cytotoxic agents. We expressed recombinant human multidrug transporter in a baculovirus expression system to obtain large quantities and further investigate its structure and mechanism of action. MDR1 cDNA was inserted into the genome of the Autographa californica nuclear polyhedrosis virus under the control of the polyhedrin promoter. Spodoptera frugiperda insect cells synthesized high levels of recombinant multidrug transporter 2-3 days after infection. The transporter was localized by immunocytochemical methods on the external surface of the plasma membranes, in the Golgi apparatus, and within the nuclear envelope. The human multidrug transporter expressed in insect cells is not susceptible to endoglycosidase F treatment and has a lower apparent molecular weight of 140,000, corresponding to the nonglycosylated precursor of its authentic counterpart expressed in multidrug-resistant cells. Labeling experiments showed that the recombinant multidrug transporter is phosphorylated and can be photoaffinity labeled by [3H]-azidopine, presumably at the same two sites as the native protein. Various drugs and reversing agents (e.g., daunomycin greater than verapamil greater than vinblastine approximately vincristine) compete with the [3H]azidopine binding reaction when added in excess, indicating that the recombinant human multidrug transporter expressed in insect cells is functionally similar to its authentic counterpart.     

Length-dependent formation of parallel-stranded DNA in alternating AT segments

Parallel-stranded DNA can be formed from alternating AT segments and is not restricted exclusively to homooligomeric AT sequences. DNA oligonucleotides 3'-d(AT)nxC4(AT)n-3' (where x indicates the location of the 5'-5' phosphodiester linkage) form parallel-stranded hairpin structures at micromolar strand concentration for n = 4 or 5 but not for n = 6, 7. The spectral properties of the parallel-stranded structures are similar to those of the hairpin structures containing homooligomeric AT stems. However, parallel-stranded structures formed in alternating AT segments are significantly less stable than either their corresponding antiparallel control or the homooligomeric parallel AT hairpins as evidenced by their lower helix-coil transition enthalpy, melting temperature, and stability constant. This results in a remarkable polymorphism which is most pronounced for 3'-d(AT)5xC4(AT)5-3'. This oligonucleotide can exist as a parallel-stranded hairpin, coil, or concatameric antiparallel structure(s), depending on temperature and strand concentration. These results suggest simple guidelines for the design of parallel-stranded DNA. In addition, we present a model for the assessment of the stability of parallel-stranded duplex structures formed from AT base pairs based on their sequence.     

Physical mapping and cloning of RAD56

Here we report the physical mapping of the rad56-1 mutation to the NAT3 gene, which encodes the catalytic subunit of the NatB N-terminal acetyltransferase in Saccharomyces cerevisiae. Mutation of RAD56 causes sensitivity to X-rays, methyl methanesulfonate, zeocin, camptothecin and hydroxyurea, but not to UV light, suggesting that N-terminal acetylation of specific DNA repair proteins is important for efficient DNA repair.     

Homooligomeric dA·dU and dA·dT Sequences in Parallel and Antiparallel Strand Orientation: Consequence of the 5-methyl Groups on Stability,Structure and Interaction with the Minor Groove Binding Drug HOECHST 33258

Abstract

Oligodeoxyribonucleotides containing dA·dU base combinations were shown to form parallel stranded DNA. CD spectra and hyperchromicity profiles provide evidence that the structure is very similar to that of a related parallel stranded dA·oligomer. Thermal denaturation studies show that these parallel dAdU sequences are significantly less stable than their dA·analogues in either antiparallel or parallel stranded orientations. The stabilizing effect of the 5- methyl group is similar for parallel and antiparallel sequences. The minor groove binding drug Hoechst 33258 binds with similar affinity to APS dA·and APS dA·dU sequences. However, binding to the PS dA·hairpin is significantly impaired as a consequence of the different groove dimensions and the presence of thymine methyl groups at the binding site. This results in an 8.6 kJmoF reduced free energy of binding for the PS dA·sequence. Replacement of the bulky methyl group with a hydrogen (ie. T -> U) results in significantly stronger Hoechst 33258 binding to the parallel dA·dU sequences with a penalty of only 4.1 kJmol^?1. Our data demonstrate that although Hoechst 33258 detects the altered groove, it is still able to bind a PS duplex containing dA·dU base pairs with high affinity, despite the large structural differences from its regular binding site in APS DNA.