Bubble dynamics in DNA

The formation of local denaturation zones (bubbles) in double-stranded DNA is an important example for conformational changes of biological macromolecules. We study the dynamics of bubble formation in terms of a Fokker-Planck equation for the probability density to find a bubble of size n base pairs at time t, on the basis of the free energy in the Poland-Scheraga model. Characteristic bubble closing and opening times can be determined from the corresponding first passage time problem, and are sensitive to the specific parameters entering the model. A multistate unzipping model with constant rates recently applied to DNA breathing dynamics [G. Altan-Bonnet et al, Phys. Rev. Lett. 90, 138101 (2003)] emerges as a limiting case.Comment: 9 pages, 2 figure

The Influence of Dormitory Architecture On Resident Behavior

Peer Reviewedhttp://deepblue.lib.umich.edu/bitstream/2027.42/66943/2/10.1177_001391657300500402.pd

Beyond quantitative and qualitative traits: three telling cases in the life sciences

This paper challenges the common assumption that some phenotypic traits are quantitative while others are qualitative. The distinction between these two kinds of traits is widely influential in biological and biomedical research as well as in scientific education and communication. This is probably due to both historical and epistemological reasons. However, the quantitative/qualitative distinction involves a variety of simplifications on the genetic causes of phenotypic variability and on the development of complex traits. Here, I examine three cases from the life sciences that show inconsistencies in the distinction: Mendelian traits (dwarfism and pigmentation in plant and animal models), Mendelian diseases (phenylketonuria), and polygenic mental disorders (schizophrenia). I show that these traits can be framed both quantitatively and qualitatively depending, for instance, on the methods through which they are investigated and on specific epistemic purposes (e.g., clinical diagnosis versus causal explanation). This suggests that the received view of quantitative and qualitative traits has a limited heuristic power—limited to some local contexts or to the specific methodologies adopted. Throughout the paper, I provide directions for framing phenotypes beyond the quantitative/qualitative distinction. I conclude by pointing at the necessity of developing a principled characterisation of what phenotypic traits, in general, are

Bacteriophage T4 unf (=alc) gene function is required for late replication in the presence of plasmid pR386

The bacteriophage T4 unf gene, known to be involved in the arrest of transcription from cytosine-containing DNA, is unessential except in Escherichia coli strains containing plasmid pR386. Comparative genetic and biochemical analyses of parameters of unf+ and unf- phage growth in host cells isogenic except for the presence or absence of plasmid pR386 have shown that unf gene function is required for late phage DNA synthesis in the presence of the plasmid. Shutoff of host DNA, RNA, and protein syntheses, degradation of host DNA, adsorption, injection, and early phage DNA, RNA, and protein syntheses all occurred with normal or near-normal kinetics in unf- infections, even in the presence of the plasmid. The switch from early to late protein synthesis occurred in plasmid pR386-containing cells infected with unf+ or unf- phage. However, this switchover was slow in both cases and may be slower in unf- infections than in unf+ infections. Net incorporation of [3H]thymidine terminated at about 30 min after infection of pR386-containing cells with unf- phage at 30 degrees C. Alkaline sucrose gradient studies of the intracellular pools of replicative DNA in unf-infected plasmid pR386-containing cells indicated that this DNA is not detectably nickel or cleaved at the time that DNA synthesis aborts. The addition of chloramphenicol subsequent to early enzyme synthesis prevented the arrest of DNA synthesis in plasmid-containing cells infected with unf-phage.</jats:p

Mechanism of Inhibition of Deoxyribonucleic Acid Synthesis in <i>Escherichia coli</i> by Hydroxyurea

The effects of hydroxyurea on Escherichia coli B/5 physiology (increases in cell mass, number of viable cells, and deoxyribonucleic acid [DNA], RNA, and protein concentrations) were studied in an attempt to find a concentration that completely inhibits DNA synthesis and increase in number of viable cells but has little or no effect on other metabolic processes. These conditions were the most closely approached at an hydroxyurea concentration of 0.026 to 0.033 m . A concentration of 0.026 or 0.033 m was used in subsequent experiments to study the site(s) of inhibition of DNA synthesis in E. coli B/5 by hydroxyurea. Hydroxyurea at a concentration of 10 −2 m was found to inhibit ribonucleoside diphosphate reductase activity completely in crude extracts of E. coli . The synthesis of deoxyribonucleotides was greatly reduced when E. coli cells were grown in the presence of 0.033 m hydroxyurea. Studies on the acid-soluble DNA precursor pools showed that hydroxyurea causes a decrease in the concentration of deoxyribonucleoside diphosphates and deoxyribonucleoside triphosphates and an increase in the total concentration of ribonucleotides. Sucrose density gradient sedimentation of DNA from cells treated with 0.026 m hydroxyurea for 30 min indicated that at this concentration hydroxyurea induces no detectable single- or double-strand breaks. In addition, both replicative and repair syntheses of DNA were found to occur normally in toluene-treated cells in the presence of relatively high concentrations of hydroxyurea. Pulse-chase studies showed that deoxyribonucleotides synthesized prior to the addition of hydroxyurea to cells are utilized normally for DNA synthesis in the presence of hydroxyurea. On the basis of these observations, we have concluded that the primary, if not the only, site of inhibition of DNA synthesis in E. coli B/5 by low concentrations of hydroxyurea is the inhibition of the enzyme ribonucleoside diphosphate reductase. </jats:p

Plasmid pR386 renders Escherichia coli cells restrictive to the growth of bacteriophage T4 unf mutants

The introduction of the F1 incompatibility group plasmid pR386 Tc into several common laboratory strains of Escherichia coli rendered them restrictive to the growth of bacteriophage T4 unf mutants, which are defective in unfolding the host genome. The growth inhibition was temperature dependent. The single mutant unf39 x 5 exhibited an efficiency of plating of less than 10(-8) at 27 degrees C. However, at 37 degrees C, complete growth inhibition occurred only when host DNA degradation was also absent.</jats:p