Overexpression of endonuclease III protects Escherichia coli mutants defective in alkylation repair against lethal effects of methylmethanesulphonate

Endonuclease III of Escherichia coli is normally involved in the repair of oxidative DNA damage. Here, we have investigated a possible role of EndoIII in the repair of alkylation damage because of its structural similarity to the alkylation repair enzyme 3-methyladenine DNA glycosylase II. It was found that overproduction of EndoIII partially relieved the alkylation sensitivity of alkA mutant cells. Site-directed mutagenesis to make the active site of EndoIII more similar to AlkA (K120W) had an adverse effect on the complementation and the mutant protein apparently inhibited repair by competing for the substrate without base release. These results suggest that EndoIII might replace AlkA in some aspect of alkylation repair, although high expression levels are needed to produce this effect.     

Elimination of extrachromosomal c-myc genes by hydroxyurea induces apoptosis

Hydroxyurea (HU) increases extrachromosomal DNA elimination in tumor cell lines. The c-myc oncogene is one of the many relevant amplified genes contained within the extrachromosomal DNA compartment. Spontaneous loss of amplified copies of c-myc induces terminal differentiation and apoptosis in the human HL-60 leukemia cell lines. In the present study, we evaluate HU's ability to induce apoptosis by eliminating extrachromosomally located c-myc oncogene in human tumor cell lines. The consequences of eliminating extrachromosomal DNA by HU were explored in two different cell lines using the TdT assay and acridine orange/ethidium bromide labeling. COLO 320 clone 3 and COLO 320 clone 21 cell lines contain the same number of amplified copies of c-myc oncogene, but located respectively on extrachromosomal DNA, and intrachromosomally in homogeneously staining regions. HU induced apoptosis in the COLO 320 clone 3 cell line by a time and concentration dependent mechanism but could not induce apoptosis in the COLO 320 clone 21 cell line. These results suggested that HU-induced apoptosis in COLO 320 cell lines depends on elimination of extrachromosomal amplified copies of the c-myc oncogene. The ability of HU to eliminate extrachromosomally amplified copies of the c-myc oncogene and to induce apoptosis should be considered when targeting malignancies with amplification of the c-myc oncogene in an extrachromosomal site.     

Myocardialization of the cardiac outflow tract.

During development, the single-circuited cardiac tube transforms into a double-circuited four-chambered heart by a complex process of remodeling, differential growth, and septation. In this process the endocardial cushion tissues of the atrioventricular junction and outflow tract (OFT) play a crucial role as they contribute to the mesenchymal components of the developing septa and valves in the developing heart. After fusion, the endocardial ridges in the proximal portion of the OFT initially form a mesenchymal outlet septum. In the adult heart, however, this outlet septum is basically a muscular structure. Hence, the mesenchyme of the proximal outlet septum has to be replaced by cardiomyocytes. We have dubbed this process "myocardialization." Our immunohistochemical analysis of staged chicken hearts demonstrates that myocardialization takes place by ingrowth of existing myocardium into the mesenchymal outlet septum. Compared to other events in cardiac septation, it is a relatively late process, being initialized around stage H/H28 and being basically completed around stage H/H38. To unravel the molecular mechanisms that are responsible for the induction and regulation of myocardialization, an in vitro culture system in which myocardialization could be mimicked and manipulated was developed. Using this in vitro myocardialization assay it was observed that under the standard culture conditions (i) whole OFT explants from stage H/H20 and younger did not spontaneously myocardialize the collagen matrix, (ii) explants from stage H/H21 and older spontaneously formed extensive myocardial networks, (iii) the myocardium of the OFT could be induced to myocardialize and was therefore "myocardialization-competent" at all stages tested (H/H16-30), (iv) myocardialization was induced by factors produced by, most likely, the nonmyocardial component of the outflow tract, (v) at none of the embryonic stages analyzed was ventricular myocardium myocardialization-competent, and finally, (vi) ventricular myocardium did not produce factors capable of supporting myocardialization.     

Making more heart muscle

Postnatally, heart muscle cells almost completely lose their ability to divide, which makes their loss after trauma irreversible. Potential repair by cell grafting or mobilizing endogenous cells is of particular interest for possible treatments for heart disease, where the poor capacity for cardiomyocyte proliferation probably contributes to the irreversibility of heart failure. Knowledge of the molecular mechanisms that underly formation of heart muscle cells might provide opportunities to repair the diseased heart by induction of (trans) differentiation of endogenous or exogenous cells into heart muscle cells. We briefly review the molecular mechanisms involved in early development of the linear heart tube by differentiation of mesodermal cells into heart muscle cells. Because the initial heart tube does not comprise all the cardiac compartments present in the adult heart, heart muscle cells are added to the distal borders of the tube and within the tube. At both distal borders, mesodermal cell are recruited into the cardiac lineage and, within the heart tube, muscular septa are formed. In this review, the relative late additions of heart muscle cells to the linear heart tube are described and the potential underlying molecular mechanisms are discussed.     

Transcellular and paracellular elements of salt chemosensation in toad skin

Dehydrated toads absorb water by pressing a specialized (seat patch) area of the skin to moist surfaces. This behavior, the water absorption response (WR), is preceded by periods of more limited skin contact (seat patch down, SPD) in which the suitability of the rehydration source is evaluated. WR and SPD behaviors were suppressed on 250 mM NaCl and 200 mM KCl solutions. Ten micromolar amiloride partially restored SPD and WR on NaCl solutions. The addition of 5 mM La(3+) also partially restored the initiation of WR and this effect was additive to the effect of amiloride, suggesting transcellular and paracellular pathways exist in parallel. Similarly, 5 mM La(3+) partially restored the initiation of WR on KCl solutions, to levels comparable to those with K(+)gluconate, suggesting a paracellular pathway for detection of K(+). Hyperosmotic (250 mM) NaCl solutions bathing the mucosal surface rapidly and reversibly increased the paracellular conductance of isolated skin and this increase was partially inhibited by 5 mM La(3+). These results suggest that the regulation of tight junctions has a chemosensory role in toad skin.     

Camptothecin analogs with bulky, hydrophobic substituents at the 7-position via a Grignard reaction

By developing a new synthetic procedure for introduction of side chains onto the camptothecin ring system, we were able to achieve the preparation of a number of analogs bearing bulky, hydrophobic groups directly attached to the 7-position. These include 7-tert-butylcamptothecin, 7-benzylcamptothecin and the corresponding 10,11-methylenedioxycamptothecins. This method involves the reaction of an appropriate orthoaminobenzonitrile with various Grignard reagents to give the corresponding orthoaminoketones. Friedlander condensation of the latter with the key tricyclic ketone leads to 7-substituted camptothecin analogs. We report the activity of these compounds as topoisomerase I poisons and their ability to inhibit growth of selected tumor cell lines.     

Photo-CIDNP 13C magic angle spinning NMR on bacterial reaction centres: exploring the electronic structure of the special pair and its surroundings

Photochemically induced dynamic nuclear polarisation (photo-CIDNP) in intact bacterial reaction centres has been observed by 13C-solid state NMR under continuous illumination with white light. Strong intensity enhancement of 13C NMR signals of the aromatic rings allows probing the electronic ground state of the two BChl cofactors of the special pair at the molecular scale with atomic selectivity. Differences between the two BChl cofactors are discussed. Several aliphatic 13C atoms of cofactors, as well as 13C atoms of the imidazole ring of histidine residue(s), show nuclear-spin polarisation to the same extent as the aromatic nuclei of the cofactors. Mechanisms and applications of polarisation transfer are discussed.     

B-branch electron transfer in reaction centers of Rhodobacter sphaeroides assessed with site-directed mutagenesis

Mutants of Rhodobacter (Rba.) sphaeroides are described which were designed to study electron transfer along the so-called B-branch of reaction center (RC) cofactors. Combining the mutation L(M214)H, which results in the incorporation of a bacteriochlorophyll, β, for H_A [Kirmaier et al. (1991) Science 251: 922–927] with two mutations, G(M203)D and Y(M210)W, near B_A, we have created a double and a triple mutant with long lifetimes of the excited state P^* of the primary donor P, viz. 80 and 160 ps at room temperature, respectively. The yield of P⁺Q_A ⁻ formation in these mutants is reduced to 50 and 30%, respectively, of that in wildtype RCs. For both mutants, the quantum yield of P⁺H_B ⁻ formation was less than 10%, in contrast to the 15% B-branch electron transfer demonstrated in RCs of a similar mutant of Rba. capsulatus with a P^* lifetime of 15 ps [Heller et al. (1995) Science 269: 940–945]. We conclude that the lifetime of P^* is not a governing factor in switching to B-branch electron transfer. The direct photoreduction of the secondary quinone, Q_B, was studied with a triple mutant combining the G(M203)D, L(M214)H and A(M260)W mutations. In this triple mutant Q_A does not bind to the reaction center [Ridge et al. (1999) Photosynth Res 59: 9–26]. It is shown that B-branch electron transfer leading to P⁺Q_B ⁻ formation occurs to a minor extent at both room temperature and at cryogenic temperatures (about 3% following a saturating laser flash at 20 K). In contrast, in wildtype RCs P⁺Q_B ⁻ formation involves the A-branch and does not occur at all at cryogenic temperatures. Attempts to accumulate the P⁺Q_B ⁻ state under continuous illumination were not successful. Charge recombination of P⁺Q_B ⁻ formed by B-branch electron transfer in the new mutant is much faster (seconds) than has been previously reported for charge recombination of P⁺Q_B ⁻ trapped in wildtype RCs (10⁵ s) [Kleinfeld et al. (1984b) Biochemistry 23: 5780–5786]. This difference is discussed in light of the different binding sites for Q_B and Q_B ⁻ that recently have been found by X-ray crystallography at cryogenic temperatures [Stowell et al. (1997) Science 276: 812–816]. We present the first low-temperature absorption difference spectrum due to P⁺Q_B ⁻. This revised version was published online in June 2006 with corrections to the Cover Date.