The Phe-X-Glu DNA binding motif of MutS. The role of hydrogen bonding in mismatch recognition

The crystal structures of MutS protein from Thermus aquaticus and Escherichia coli in a complex with a mismatch-containing DNA duplex reveal that the Glu residue in a conserved Phe-X-Glu motif participates in a hydrogen-bonded contact with either an unpaired thymidine or the thymidine of a G-T base-base mismatch. Here, the role of hydrogen bonding in mismatch recognition by MutS is assessed. The relative affinities of MutS for DNA duplexes containing nonpolar shape mimics of A and T, 4-methylbenzimidazole (Z), and difluorotoluene (F), respectively, that lack hydrogen bonding donors and acceptors, are determined in gel mobility shift assays. The results provide support for an induced fit mode of mismatch binding in which duplexes destabilized by mismatches are preferred substrates for kinking by MutS. Hydrogen bonding between the O epsilon 2 group of Glu and the mismatched base contributes only marginally to mismatch recognition and is significantly less important than the aromatic ring stack with the conserved Phe residue. A MutS protein in which Ala is substituted for Glu(38) is shown to be defective for mismatch repair in vivo. DNA binding studies reveal a novel role for the conserved Glu residue in the establishment of mismatch discrimination by MutS.

Molecular mechanisms of DNA mismatch repair

DNA mismatch repair (MMR) safeguards the integrity of the genome. In its role in postreplicative repair, this repair pathway corrects base-base and insertion/deletion (I/D) mismatches that have escaped the proofreading function of replicative polymerases. In its absence, cells assume a mutator phenotype in which the rate of spontaneous mutation is greatly elevated. The discovery that defects in mismatch repair segregate with certain cancer predisposition syndromes highlights its essential role in mutation avoidance. Recently, three-dimensional structures of MutS, a key repair protein that recognizes mismatches, have been determined by X-ray crystallography. This article provides an overview of the structural features of MutS proteins and discusses how the structural data together with biochemical and genetic studies reveal new insights into the molecular mechanisms of mismatch repair.

Interaction of Escherichia coli MutS and MutL at a DNA Mismatch

MutS and MutL are both required to activate downstream events in DNA mismatch repair. We examined the rate of dissociation of MutS from a mismatch using linear heteroduplex DNAs or heteroduplexes blocked at one or both ends by four-way DNA junctions in the presence and absence of MutL. In the presence of ATP, dissociation of MutS from linear heteroduplexes or heteroduplexes blocked at only one end occurs within 15 s. When both duplex ends are blocked, MutS remains associated with the DNA in complexes with half-lives of 30 min. DNase I footprinting of MutS complexes is consistent with migration of MutS throughout the DNA duplex region. When MutL is present, it associates with MutS and prevents ATP-dependent migration away from the mismatch in a manner that is dependent on the length of the heteroduplex. The rate and extent of mismatch-provoked cleavage at hemimethylated GATC sites by MutH in the presence of MutS, MutL, and ATP are the same whether the mismatch and GATC sites are in cis or in trans. These results suggest that a MutS-MutL complex in the vicinity of a mismatch is involved in activating MutH.

Disruption of the helix-u-turn-helix motif of MutS protein: loss of subunit dimerization, mismatch binding and ATP hydrolysis

The DNA mismatch repair protein, MutS, is a dimeric protein that recognizes mismatched bases and has an intrinsic ATPase activity. Here, a series of Taq MutS proteins having C-terminal truncations in the vicinity of a highly conserved helix-u-turn-helix (HuH) motif are assessed for subunit oligomerization, ATPase activity and DNA mismatch binding. Those proteins containing an intact HuH region are dimers; those without the HuH region are predominantly monomers in solution. Steady-state kinetics of truncated but dimeric MutS proteins reveals only modest decreases in their ATPase activity compared to full-length protein. In contrast, disruption of the HuH region results in a greatly attenuated ATPase activity. In addition, only dimeric MutS proteins are proficient for mismatch binding. Finally, an analysis of the mismatch repair competency of truncated Escherichia coli MutS proteins in a rifampicin mutator assay confirms that the HuH region is critical for in vivo function. These findings indicate that dimerization is critical for both the ATPase and DNA mismatch binding activities of MutS, and corroborate several key features of the MutS structure recently deduced from X-ray crystallographic studies.

Composite active site of an ABC ATPase: MutS uses ATP to verify mismatch recognition and authorize DNA repair

The MutS protein initiates DNA mismatch repair by recognizing mispaired and unpaired bases embedded in duplex DNA and activating endo- and exonucleases to remove the mismatch. Members of the MutS family also possess a conserved ATPase activity that belongs to the ATP binding cassette (ABC) superfamily. Here we report the crystal structure of a ternary complex of MutS-DNA-ADP and assays of initiation of mismatch repair in conjunction with perturbation of the composite ATPase active site by mutagenesis. These studies indicate that MutS has to bind both ATP and the mismatch DNA simultaneously in order to activate the other mismatch repair proteins. We propose that the MutS ATPase activity plays a proofreading role in DNA mismatch repair, verification of mismatch recognition, and authorization of repair.

Antimicrobial effect of extracts from Chinese chive, cinnamon, and corni fructus

Extracts were prepared from Chinese chive (Allium tuberosum), cinnamon (Cinnamomum cassia), and corni fructus (Cornus officinalis) and used to evaluate their antimicrobial activity on common foodborne microorganisms, alone and in combination. The mixed extract, consisting of three extracts in equal volumes, showed an entire antimicrobial spectrum and had excellent stability to heat, pH, and storage. The mixed extract exhibited better inhibition on growth of Escherichia coli than potassium sorbate at 2-5 mg/mL. The mixed extract inhibited the growth of Pichia membranaefaciens at levels as low as 2 mg/mL. When the mixed extract was used in foods, the expected antimicrobial effect in orange juice, pork, and milk was observed. After gel filtration chromatography, each extract was partially purified into fractions, and one fraction in each extract showed enhanced antimicrobial activity. Overall, the mixed extract was of promising potential for incorporation into various food products for which a natural antimicrobial additive is desired.

Crystal structures of mismatch repair protein MutS and its complex with a substrate DNA

DNA mismatch repair is critical for increasing replication fidelity in organisms ranging from bacteria to humans. MutS protein, a member of the ABC ATPase superfamily, recognizes mispaired and unpaired bases in duplex DNA and initiates mismatch repair. Mutations in human MutS genes cause a predisposition to hereditary nonpolyposis colorectal cancer as well as sporadic tumours. Here we report the crystal structures of a MutS protein and a complex of MutS with a heteroduplex DNA containing an unpaired base. The structures reveal the general architecture of members of the MutS family, an induced-fit mechanism of recognition between four domains of a MutS dimer and a heteroduplex kinked at the mismatch, a composite ATPase active site composed of residues from both MutS subunits, and a transmitter region connecting the mismatch-binding and ATPase domains. The crystal structures also provide a molecular framework for understanding hereditary nonpolyposis colorectal cancer mutations and for postulating testable roles of MutS.

Requirement for Phe36 for DNA binding and mismatch repair by Escherichia coli MutS protein

The MutS family of DNA repair proteins recognizes base pair mismatches and insertion/deletion mismatches and targets them for repair in a strand-specific manner. Photocrosslinking and mutational studies previously identified a highly conserved Phe residue at the N-terminus of Thermus aquaticus MutS protein that is critical for mismatch recognition in vitro. Here, a mutant Escherichia coli MutS protein harboring a substitution of Ala for the corresponding Phe36 residue is assessed for proficiency in mismatch repair in vivo and DNA binding and ATP hydrolysis in vitro. The F36A protein is unable to restore mismatch repair proficiency to a mutS strain as judged by mutation to rifampicin or reversion of a specific point mutation in lacZ. The F36A protein is also severely deficient for binding to heteroduplexes containing an unpaired thymidine or a G:T mismatch although its intrinsic ATPase activity and subunit oligomerization are very similar to that of the wild-type MutS protein. Thus, the F36A mutation appears to confer a defect specific for recognition of insertion/deletion and base pair mismatches.

The effect of decreasing digital image resolution on teledermatology diagnosis

OBJECTIVE

To determine the effect of degraded digital image resolution (as viewed on a monitor) on the accuracy and confidence of dermatologic interpretation.

MATERIALS AND METHODS

Eight dermatologists interpreted 180 clinical cases divided into three Logical Competitor Sets (LCS) (pigmented lesions, non-pigmented lesions, and inflammatory dermatoses). Each case was digitized at three different resolutions. The images were randomized and divided into (9) 60-image sessions. The physicians were completely blinded concerning the image resolution. After 60 seconds per image, the viewer recorded a diagnosis and level of confidence. The resultant ROC curves compared the effect of LCS, level of clinical difficulty, and resolution of the digital image. One-way analysis of variance (ANOVA) compared the curves.

RESULTS

The areas beneath the ROC curves did not demonstrate any consistently significant difference between the digital image resolutions for all LCS and levels of difficulty. The only significant effect observed was amongst pigmented lesions (LCS-A) where the ROC curve area was significantly smaller in the easy images at high resolution compared to low and medium resolutions. For all other ROC curve comparisons within LCS-A, at all other levels of difficulty, as well as within the other LCS at all levels of difficulty, none of the differences was significant.

CONCLUSION

A 720 x 500 pixel image can be considered equivalent to a 1490 x 1000 pixel image for most store-and-forward teledermatology consultations.

A cruciform structural transition provides a molecular switch for chromosome structure and dynamics

The interaction between specific sites along a DNA molecule is often crucial for the regulation of genetic processes. However, mechanisms regulating the interaction of specific sites are unknown. We have used atomic force microscopy to demonstrate that the structural transition between cruciform conformations can act as a molecular switch to facilitate or prevent communication between distant regions in DNA. Cruciform structures exist in vivo and they are critically involved in the initiation of replication and the regulation of gene expression in different organisms. Therefore, structural transitions of the cruciform may play a key role in these processes.

Deletion of 150 kb in the minimal DiGeorge/velocardiofacial syndrome critical region in mouse

Deletions or rearrangements of human chromosome 22q11 lead to a variety of related clinical syndromes such as DiGeorge syndrome (DGS) and velo--cardiofacial syndrome (VCFS). In addition, patients with 22q11 deletions have an increased incidence of schizophrenia and several studies have mapped susceptibility loci for schizophrenia to this region. Human molecular genetic studies have so far failed to identify the crucial genes or disruption mechanisms that result in these disorders. We have used gene targeting in the mouse to delete a defined region within the conserved DGS critical region (DGCR) on mouse chromosome 16 to prospectively investigate the role of the mouse DGCR in 22q11 syndromes. The deletion spans a conserved portion ( approximately 150 kb) of the proximal region of the DGCR, containing at least seven genes ( Znf74l, Idd, Tsk1, Tsk2, Es2, Gscl and Ctp ). Mice heterozygous for this deletion display no findings of DGS/VCFS in either inbred or mixed backgrounds. However, heterozygous mice display an increase in prepulse inhibition of the startle response, a manifestation of sensorimotor gating that is reduced in humans with schizophrenia. Homozygous deleted mice die soon after implantation, demonstrating that the deleted region contains genes essential for early post-implantation embryonic development. These results suggest that heterozygous deletion of this portion of the DGCR is sufficient for sensorimotor gating abnormalities, but not sufficient to produce the common features of DGS/VCFS in the mouse.

Oligomerization of a MutS mismatch repair protein from Thermus aquaticus

The MutS DNA mismatch protein recognizes heteroduplex DNAs containing mispaired or unpaired bases. We have examined the oligomerization of a MutS protein from Thermus aquaticus that binds to heteroduplex DNAs at elevated temperatures. Analytical gel filtration, cross-linking of MutS protein with disuccinimidyl suberate, light scattering, and matrix-assisted laser desorption/ionization time-of-flight mass spectrometry establish that the Taq protein is largely a dimer in free solution. Analytical equilibrium sedimentation showed that the oligomerization of Taq MutS involves a dimer-tetramer equilibrium in which dimer predominates at concentrations below 10 microM. The DeltaG(0)(2-4) for the dimer to tetramer transition is approximately -6.9 +/- 0.1 kcal/mol of tetramer. Analytical gel filtration of native complexes and gel mobility shift assays of an maltose-binding protein-MutS fusion protein bound to a short, 37-base pair heteroduplex DNA reveal that the protein binds to DNA as a dimer with no change in oligomerization upon DNA binding.

Migration of a Holliday junction through a nucleosome directed by the E. coli RuvAB motor protein

Chromatin plays a critical role in regulating access to DNA by proteins that direct recombination and repair. The E. coli RuvAB protein complex promotes branch migration of the Holliday junction recombination intermediate. The ability of RuvAB to negotiate passage of the junction through nucleosomal DNA is examined. The model system involves the formation of a Holliday junction positioned upstream of a nucleosome. Unassisted, the junction is blocked by a histone octamer. In the presence of RuvAB and ATP, rapid branch migration through the nucleosome is observed. It results in disruption of the histone-DNA interactions leading to the removal of the octamer from the junction intermediate. These results suggest that eukaryotic DNA motor proteins analogous to RuvAB could function during recombination to promote branch migration through chromatin.

Branch migration through DNA sequence heterology

Branch migration of a DNA Holliday junction is a key step in genetic recombination. Previously, it was shown that a single base-pair heterology between two otherwise identical DNA sequences is a substantial barrier to passage of a Holliday junction during spontaneous branch migration. Here, we exploit this inhibitory effect of sequence heterology to estimate the step size of branch migration. We also devise a simulation of branch migration through mismatched base-pairs to arrive at the underlying molecular basis for the block to branch migration imposed by sequence heterology. Based on the observation that two adjacent sequence heterologies exert their effects on branch migration more or less independently, we conclude that the step size of branch migration is quite small, of the order of one or two base-pairs per migratory step. Comparison of branch migration experiments through a single base-pair heterology with simulations of a random walk through sequence heterology suggests that the inhibition of branch migration is largely attributable to a thermodynamic barrier arising from the formation of unpaired or mispaired bases in heteroduplex DNAs.

Changes in interstitial pressure and cross-sectional area of the cubital tunnel and of the ulnar nerve with flexion of the elbow. An experimental study in human cadavera

The purpose of this study was to determine the relationship between the ulnar nerve and the cubital tunnel during flexion of the elbow with use of magnetic resonance imaging and measurements of intraneural and extraneural interstitial pressure. Twenty specimens from human cadavera were studied with the elbow in positions of incremental flexion. With use of magnetic resonance imaging, cross-sectional images were made at each of three anatomical regions of the cubital tunnel: the medial epicondyle, deep to the cubital tunnel aponeurosis, and deep to the flexor carpi ulnaris muscle. The cross-sectional areas of the cubital tunnel and the ulnar nerve were calculated and compared for different positions of elbow flexion. Interstitial pressures were measured with use of ultrasonographic imaging to allow a minimally invasive method of placement of the pressure catheter, both within the cubital tunnel and four centimeters proximal to it, at 10-degree increments from 0 to 130 degrees of elbow flexion. As the elbow was moved from full extension to 135 degrees of flexion, the mean cross-sectional area of the three regions of the cubital tunnel decreased by 30, 39, and 41 per cent and the mean area of the ulnar nerve decreased by 33, 50, and 34 per cent. These changes were significant in all three regions of the cubital tunnel (p < 0.05). The greatest changes occurred in the region beneath the aponeurosis of the cubital tunnel with the elbow at 135 degrees of flexion. The mean intraneural pressure within the cubital tunnel was significantly higher than the mean extraneural pressure when the elbow was flexed 90, 100, 110, and 130 degrees (p < 0.05). With the elbow flexed 130 degrees, the mean intraneural pressure was 45 per cent higher than the mean extraneural pressure (p < 0.001). Similarly, with the elbow flexed 120 degrees or more, the mean intraneural pressure four centimeters proximal to the cubital tunnel was significantly higher than the mean extraneural pressure (p < 0.01). Relative to their lowest values, intraneural pressure increased at smaller angles of flexion than did extraneural pressure, both within the cubital tunnel and proximal to it. With the numbers available, we could not detect any significant difference in intraneural pressure measured, either at the level of the cubital tunnel or four centimeters proximal to it, after release of the aponeurotic roof of the cubital tunnel.

A histone octamer blocks branch migration of a Holliday junction

The Holliday junction is a key intermediate in genetic recombination. Here, we examine the effect of a nucleosome core on movement of the Holliday junction in vitro by spontaneous branch migration. Histone octamers consisting of H2A, H2B, H3, and H4 are reconstituted onto DNA duplexes containing an artificial nucleosome-positioning sequence consisting of a tandem array of an alternating AT-GC sequence motif. Characterization of the reconstituted branch migration substrates by micrococcal nuclease mapping and exonuclease III and hydroxyl radical footprinting reveal that 70% of the reconstituted octamers are positioned near the center of the substrate and the remaining 30% are located at the distal end, although in both cases some translational degeneracy is observed. Branch migration assays with the octamer-containing substrates reveal that the Holliday junction cannot migrate spontaneously through DNA organized into a nucleosomal core unless DNA-histone interactions are completely disrupted. Similar results are obtained with branch migration substrates containing an octamer positioned on a naturally occurring sequence derived from the yeast GLN3 locus. Digestion of Holliday junctions with T7 endonuclease I establishes that the junction is not trapped by the octamer but can branch migrate in regions free of histone octamers. Our findings suggest that migration of Holliday junctions during recombination and the recombinational repair of DNA damage requires proteins not only to accelerate the intrinsic rate of branch migration but also to facilitate the passage of the Holliday junction through a nucleosome.

Photocross-linking of the NH2-terminal region of Taq MutS protein to the major groove of a heteroduplex DNA

The MutS DNA mismatch repair protein recognizes heteroduplex DNAs containing mispaired or unpaired bases. To identify regions of MutS protein in close proximity to the heteroduplex DNA, we have utilized the photoactivated cross-linking moiety 5-iododeoxyuridine (5-IdUrd). Nucleoprotein complexes of Thermus aquaticus MutS protein bound to monosubstituted 5-IdUrd-containing heteroduplex DNAs were cross-linked with long-wavelength ultraviolet light. Positioning of the 5-IdUrd moiety at one of three positions within the DNA bulge, two nucleotides upstream or three nucleotides downstream of the unpaired base, resulted in an identical subset of cross-linked peptides as determined by proteolytic fingerprinting. The tryptic peptide cross-linked to an unpaired 5-IdUrd residue was determined by peptide sequencing to correspond to a highly conserved region spanning residues 25-49. Cross-linking to the bulge nucleotide occurred at Phe-39, indicating that this residue contacts, or is in close proximity to, the unpaired base of a heteroduplex DNA. Site-directed mutagenesis resulting in the substitution of Ala for Phe-39 reduced the affinity of the mutant protein for heteroduplex DNA by roughly 3 orders of magnitude, but had no apparent effect on its ability to dimerize, its thermostability, or its ATPase activity. These results implicate the region in the vicinity of Phe-39 as being crucial for heteroduplex DNA binding by Taq MutS protein.

Interaction of MutS protein with the major and minor grooves of a heteroduplex DNA

Thermus aquaticus MutS protein is a DNA mismatch repair protein that recognizes and binds to heteroduplex DNAs containing mispaired or unpaired bases. Using enzymatic and chemical probe methods, we have examined the binding of Taq MutS protein to a heteroduplex DNA having a single unpaired thymidine residue. DNase I footprinting identifies a symmetrical region of protection 24-28 nucleotides long centered on the unpaired base. Methylation protection and interference studies establish that Taq MutS protein makes contacts with the major groove of the heteroduplex in the immediate vicinity of the unpaired base. Hydroxyl radical and 1, 10-phenanthroline-copper footprinting experiments indicate that MutS also interacts with the minor groove near the unpaired base. Together with the identification of key phosphate groups detected by ethylation interference, these data reveal critical contact points residing in the major and minor grooves of the heteroduplex DNA.

Homologous recombination proteins in prokaryotes and eukaryotes

Genetic recombination is common to all forms of life and involves the exchange of DNA sequences between two chromosomes or DNA molecules. Such exchanges contribute to the generation of genetic diversity and the repair of damaged DNA. There are two major classes of recombination, site-specific recombination and general or homologous recombination. In homologous recombination the joining of the DNA duplexes exhibits a similar degree of precision or fidelity but, generally speaking, does not take place at specific sites. Since exchange can occur anywhere along the length of two homologous chromosomes, it follows that the proteins that catalyze homologous recombination are not sequence- or site-specific binding proteins. This review focuses on genetic and biochemical analyses of homologous recombination proteins that carry out conjugational recombination in E. coli and meiotic recombination in eukaryotes.

Identification and characterization of a thermostable MutS homolog from Thermus aquaticus

Recognition of mispaired or unpaired bases during DNA mismatch repair is carried out by the MutS protein family. Here, we describe the isolation and characterization of a thermostable MutS homolog from Thermus aquaticus YT-1. Sequencing of the mutS gene predicts an 89.3-kDa polypeptide sharing extensive amino acid sequence homology with MutS homologs from both prokaryotes and eukaryotes. Expression of the T. aquaticus mutS gene in Escherichia coli results in a dominant mutator phenotype. Initial biochemical characterization of the thermostable MutS protein, which was purified to apparent homogeneity, reveals two thermostable activities, an ATP hydrolysis activity in which ATP is hydrolyzed to ADP and Pi and a specific DNA mismatch binding activity with affinities for heteroduplex DNAs containing either an insertion/deletion of one base or a GT mismatch. The ATPase activity exhibits a temperature optimum of approximately 80 degrees C. Heteroduplex DNA binding by the T. aquaticus MutS protein requires Mg2+ and occurs over a broad temperature range from 0 degrees C to at least 70 degrees C. The thermostable MutS protein may be useful for further biochemical and structural studies of mismatch binding and for applications involving mutation detection.

A phase II trial of amonafide, caracemide, and homoharringtonine in the treatment of patients with advanced renal cell cancer

Forty-eight previously untreated, ambulatory patients with advanced or unresectable renal carcinoma were treated with either amonafide (17 patients), caracemide (17 patients), or homoharringtonine (14 patients). No objective responses were observed in any of the treatment cohorts. Amonafide and caracemide were well tolerated with no unexpected toxicities. One patient each died of pulmonary thromboembolism and sepsis with severe metabolic acidosis on the homoharringtonine arm. An additional 4 patients experienced grade 4 complications including myelosuppression, neurologic dysfunction, and respiratory failure. These severe and unexpected complications caused early termination of accrual to the homoharringtonine arm of the study. These agents have no activity in the treatment of advanced renal cell carcinoma.

Homologous recombination proteins in prokaryotes and eukaryotes

Genetic recombination is common to all forms of life and involves the exchange of DNA sequences between two chromosomes or DNA molecules. Such exchanges contribute to the generation of genetic diversity and the repair of damaged DNA. There are two major classes of recombination, site-specific recombination and general or homologous recombination. In homologous recombination the joining of the DNA duplexes exhibits a similar degree of precision or fidelity but, generally speaking, does not take place at specific sites. Since exchange can occur anywhere along the length of two homologous chromosomes, it follows that the proteins that catalyze homologous recombination are not sequence- or site-specific binding proteins. This review focuses on genetic and biochemical analyses of homologous recombination proteins that carry out conjugational recombination in E. coli and meiotic recombination in eukaryotes.

Insulin inhibits nuclear phosphatase activity: requirement for the C-terminal domain of the insulin receptor

Insulin's interaction with its receptor initiates a multitude of cellular effects on metabolism, growth, and differentiation. We recently described an insulin-mediated inhibition of nuclear protein phosphatase 2A (PP-2A), which is associated with an increase in phosphorylation of the transcription factor cAMP response element-binding protein. To clarify the role of nuclear PP-2A inhibition in the insulin signaling cascade, we examined the regulation of this phosphatase activity by insulin in Rat-1 fibroblasts overexpressing normal (HIRc) or mutant human insulin receptors (delta CT cells, deletion of a 43-amino acid C-terminal domain). The delta CT cells represent an excellent model of impaired metabolic and intact mitogenic action of insulin. Insulin inhibited nuclear PP-2A activity and enhanced cAMP response element-binding protein phosphorylation in HIRc cells, but not in delta CT cells. The delta CT cells exhibited normal ras activation and blunted mitogen-activating protein kinase phosphorylation and activation in response to insulin (16-fold in HIRc cells vs. 3-fold in delta CT cells), indicating that the mitogen-activating protein kinase pathway is important for the regulation of nuclear PP-2A activity by insulin. We conclude that insulin inhibits nuclear PP-2A activity, and that the carboxy-terminal domain of the insulin receptor is important for this effect.

A pivotal role for the structure of the Holliday junction in DNA branch migration

Branch migration of a DNA Holliday junction is a key step in genetic recombination that affects the extent of transfer of genetic information between homologous DNA sequences. We previously observed that the rate of spontaneous branch migration is exceedingly sensitive to metal ions and postulated that the structure of the cross-over point might be one critical determinant of the rate of branch migration. Other investigators have shown that in the presence of divalent metal ions like magnesium, the Holliday junction assumes a folded conformation in which base stacking is retained through the cross-over point. This base stacking is disrupted in the absence of magnesium. Here we measure the rate of branch migration as a function of Mg2+ concentration. The rate of branch migration increases dramatically at MgCl2 concentrations below 500 microM, with the steepest acceleration occurring between 300 and 100 microM MgCl2. This increase in the rate of branch migration coincides with the loss of base stacking in the four-way junction over this same interval of magnesium concentration, as measured by the susceptibility of junction residues to modification by osmium tetroxide and diethyl pyrocarbonate. We conclude that at physiological concentrations of intracellular Mg2+, base stacking in the Holliday junction constitutes one kinetic barrier to branch migration and that disruption of base stacking at the cross-over relieves this constraint.

Differential requirement for p21ras activation in the metabolic signaling by insulin

To evaluate the role of the "Ras pathway" in mediating metabolic signaling by insulin, we employed lovastatin to exhibit isoprenilation of Ras proteins in Rat-1 fibroblasts transfected with human insulin receptors (HIRc cells) and in differentiated 3T3-L1 adipocytes. Lovastatin blocked an ability of insulin to activate p21ras and mitogen-activated protein kinase. Lovastatin also significantly (p < 0.01) reduced insulin effects on thymidine incorporation and glucose incorporation into glycogen. Nevertheless, an effect of insulin on glucose uptake remained unaffected. It appears that in contrast to its mitogenic action and to its effect on glycogenesis, an effect of insulin on glucose uptake does not require p21ras activation.