Evidence for paternal transmission and heteroplasmy in the mitochondrial genome of Silene vulgaris, a gynodioecious plant.

Gynodioecy refers to the co-occurrence of females and hermaphrodites in the same population. In many gynodioecious plants, sex is determined by an epistatic interaction between mitochondrial and nuclear genes, resulting in intragenomic evolutionary conflict, should the mitochondrial genome be maternally inherited. While maternal inheritance of the mitochondrial genome is common in angiosperms, few gynodioecious species have been studied. Here, the inheritance of the mitochondrial genes atpA and coxI was studied in 318 Silene vulgaris individuals distributed among 23 crosses. While maternal inheritance was indicated in 96% of the individuals studied, one or more individuals from each of four sib groups displayed a genotype that was identical to the father, or that did not match either parent. Given evidence that inheritance is not strictly maternal, it was hypothesized that some individuals could carry a mixture of maternally and paternally derived copies of the mitochondrial genome, a condition known as heteroplasmy. Since heteroplasmy might be difficult to detect should multiple versions of the mitochondrial genome co-occur in highly unequal copy number, a method was devised to amplify low-copy number forms of atpA differentially. Evidence for heteroplasmy was found in 23 of the 99 individuals studied, including cases in which the otherwise cryptic form of atpA matched the paternal genotype. The distribution of shared nucleotide sequence polymorphism among atpA haplotypes and the results of a population survey of the joint distribution of atpA and coxI haplotypes across individuals supports the hypothesis that heteroplasmy facilitates formation of novel mitochondrial genotypes by recombination.

Probing DNA polymerase fidelity mechanisms using time-resolved fluorescence anisotropy.

Prior to undergoing postsynthetic 3'-5' editing (proofreading), a defective DNA primer terminus must be transferred from the 5'-3' polymerase active site to a remote 3'-5' exonuclease site. To elucidate the mechanisms by which this occurs, we have used time-resolved fluorescence spectroscopy to study the interaction of dansyl-labeled DNA primer/templates with the Klenow fragment of Escherichia coli DNA polymerase I. The dansyl probe is positioned such that when the DNA substrate occupies the polymerase active site, the probe is solvent-exposed and possesses a short average fluorescence lifetime (4.7 ns) and extensive angular diffusion (42.5 degrees). Conversely, when the DNA substrate occupies the exonuclease active site, the probe becomes buried within the protein, resulting in an increase in the average lifetime (14.1 ns) and a decrease in the degree of angular diffusion (14.4 degrees ). If both polymerase and exonuclease binding modes are populated (lower limit approximately 5%), their markedly different fluorescence properties cause the anisotropy to decay with a characteristic "dip and rise" shape. Nonlinear least-squares analysis of these data recovers the ground-state mole fractions of exposed (x(e)) and buried (x(b)) probes, which are equivalent to the equilibrium proportions of the DNA substrate bound at the polymerase and exonuclease sites, respectively. The distribution between the polymerase and exonuclease binding modes is given by the equilibrium partitioning constant K(pe) (equal to x(b)/x(e)). The important determinants of the proofreading process can therefore be identified by changes made to either the protein or DNA that perturb the partitioning equilibrium and hence alter the magnitude of K(pe).

Seed provisioning in gynodioeciousSilene acaulis (Caryophyllaceae).

In gynodioecious species, which contain females and hermaphrodites, the outcrossed seeds of females have been found to outperform the outcrossed seeds of hermaphrodites, in spite of the fact that their seeds are not larger in mass. Females do not make pollen. Hence the nutrients that hermaphrodites allocate to pollen, such as nitrogen, might be allocated to seeds by the females, such that individual seeds from females are better provisioned than those from hermaphrodites. Alternatively, females might make more seeds, rather than better provisioned seeds. We tested the hypothesis that seeds from females would be better provisioned for the gynodioecious species Silene acaulis, by comparing seed mass, embryo/endosperm mass, nitrogen and phosphorus content, and energy content for outcrossed seeds from females and hermaphrodites produced in a natural population. We also measured the proportion of flowers that set fruit in both morphs. Seeds from the two sexual morphs were not found to differ significantly for any of the measures of seed provisioning, with seeds from females containing either nonsignificantly less or equivalent amounts of each of the measures as compared to hermaphrodites. However, females set a significantly higher proportion of their flowers to fruit, as compared to hermaphrodites. These results indicate that females do not provision individual seeds more than hermaphrodites in S. acaulis, and alternative hypotheses will need to be examined to explain the difference in the performance of the seeds from the two sexual morphs.

Thermodynamics of the interaction of the Escherichia coli regulatory protein TyrR with DNA studied by fluorescence spectroscopy.

Fluorescence quenching was used to study the site-specific binding of the Escherichia coli regulatory protein TyrR to a fluoresceinated oligonucleotide (9F30A/30B) containing a TyrR binding site. The equilibrium constant for the interaction (KL) was measured as a function of temperature and salt concentration in the presence and absence of ATPgammaS, a specific ligand for TyrR. Fluorescence titrations yielded a KL value of 1.20 x 10(7) M-1 at 20 degrees C, which was independent of the acceptor (9F30A/30B) concentration in the range 5-500 nM, indicating that the system exhibits true equilibrium binding. Clarke and Glew analysis of the temperature dependence of binding revealed a linear dependence of R ln KL on temperature in the absence of ATPgammaS. The thermodynamic parameters obtained at 20 degrees C (theta) were = -35.73 kJ mol-1, = 57.41 kJ mol-1, and = 93.14 kJ mol-1. Saturating levels of ATPgammaS (200 microM) strengthened binding at all temperatures and resulted in a nonlinear dependence of Rln KL on temperature. The thermodynamic parameters characterizing binding under these conditions were = -39.32 kJ mol-1, = 37.16 kJ mol-1, = 76.40 kJ mol-1, and = -1.03 kJ mol-1 K-1. Several conclusions were drawn from these data. First, binding is entropically driven at 20 degrees C in both the presence and absence of ATPgammaS. This can partly be accounted for by counterions released from the DNA upon TyrR binding; in the absence of ATPgammaS and divalent cations, the TyrR-9F30A/30B interaction results in the release of two to three potassium ions. Second, the more favorable value, and hence tighter binding observed in the presence of ATPgammaS, is primarily due to a decrease in (-20.3 kJ mol-1), which overcomes an unfavorable decrease in (-16.7 kJ mol-1). Third, the negative value obtained in the presence of ATPgammaS indicates that the binding of ATPgammaS favors a conformational change in TyrR upon binding to 9F30A/30B, yielding a more stable complex.

The effect of self-association on the interaction of the Escherichia coli regulatory protein TyrR with DNA.

The interaction of the Escherichia coli regulatory protein TyrR, with a 42 bp oligonucleotide (42A/42B) containing a centrally located recognition sequence (TyrR box), was examined by analytical ultracentrifugation. The stoichiometry of the binding of oligonucleotide to dimeric TyrR was determined by equilibrium centrifugation of a mixture of fluorescein-5-isothiocyanate-labelled 42A/42B (F-42A/42B) in the presence of an eightfold molar excess of TyrR. The molecular mass (M) of the labelled oligonucleotide was estimated as 148,000, indicating a 1:1 complex composed of oligonucleotide (M = 27,000) and TyrR dimer (M = 113,000). The association constant (Ko,d = 2.8(+/- 0.1) x 10(6) M-1) was determined by a global analysis of sedimentation data, collected at multiple wavelengths between 230 and 285 nm. The presence of 30 microM ATP gamma S enhanced the affinity of TyrR for DNA approximately 3.5-fold, (Ko,d = 9.9(+/- 0.3) x 10(6) M-1). The effect of dimer to hexamer self-association of TyrR on the binding of 42A/42B was also examined. Multiple wavelength sedimentation data fitted a model in which the oligonucleotide could bind to one site on the dimer (Ko,d = 9.9 x 10(6) M-1), and to either one or three sites on the hexamer (Ko,h) = 2.0(+/- 0.1) x 10(6) M-1 and 3.8(+/- 0.1) x 10(6) M-1, respectively). Competitive sedimentation equilibrium and fluorescence anisotropy titrations were performed under stoichiometric conditions to resolve the number of oligonucleotide binding sites per hexamer. In these experiments, 42A/42B was used as a competitor to displace F-42A/42B from the hexamer, which was found to bind the 42mer with a 1:1 stoichiometry. Our data support a model in which ATP increases the affinity of TyrR for the DNA recognition sequence, and tyrosine induced self-association of TyrR generates a hexameric species with a single binding site for the 42A/42B oligonucleotide.

The reaction of partners and families to significant neurological damage and the need for health team support.

The reaction of partners and families to significant neurological damage can be very negative and traumatic. We, as health professionals, need to examine our own attitudes and feelings toward the brain injured and their families and develop a health optimism toward their recovery. We also need to become sensitized to their need for our support, interest and understanding. Certainly, we owe the families our sensitivity, the installation of at least a glimmer of hope, if we expect them to have the courage and motivation to stand by and care for their brain injured loved ones.