Regeneration of the segment boundary in Oncopeltus

The segment boundary of Oncopeltus is a compartment border. It is also an element in the pattern of the abdomen, being marked by a groove in the surface of the cuticle and an abrupt change in the pigmentation of the cells. If the segment boundary is either burnt or extirpated, the surviving cells of the two neighbouring segments migrate into the wounded area and form a new segment boundary where they confront each other. Grafting experiments with genetically marked cells demonstrate that a boundary is regenerated wherever cells from remote locations in the anteroposterior axis of any segment are apposed; thus anterior and posterior cells from the same segment form an ectopic boundary when brought together, while cells from equivalent positions in two segments heal together without forming a boundary. We consider the segment boundary to be an element in a pattern which reiterates down the longitudinal axis of the body—whenever cells from different positions in this pattern are brought together intercalation occurs. The intercalation can either be within a segment (no boundary forms) or between segments (a boundary forms). The route of intercalation appears to be the shortest available, so that when the apposed cells are more than half a segment length apart a new boundary forms.     

A molecular mechanics investigation of RNA complexes. I. Ethidium intercalation in an HIV-1 TAR RNA sequence with an unpaired adenosine.

Nucleic acid complexes with ethidium intercalated into different sites in a segment of HIV-1 TAR RNA with an unpaired A base, along with corresponding complexes with a normal RNA sequence without an unpaired base were studied by molecular mechanics energy minimization methods. Different intercalation geometries as well as different orientations of the ethidium molecule in the intercalation sites were tested. A general binding affinity enhancement for the ethidium binding to the bulge sequence compared with the normal RNA segment was obtained. With the unpaired adenosine base stacked in the duplex, the binding site adjacent to the 3' side of the bulge was found to be the most energetically favorable binding site, and the intercalation site 5' to the bulge in the same sequence is much less favorable. Unique correlated backbone conformational changes on binding of ethidium to the intercalation site 3' to the bulge were found to relieve backbone strains caused by the stacking of the unpaired base into the helix. These backbone conformational changes present a plausible molecular basis for the experimentally observed ethidium binding preference in this bulge RNA segment (L.S. Ratmeyer, R. Vinayak, G. Zon and W.D. Wilson, J. Med. Chem. 35, 966, 1992).     

Crystal structure of the 2:1 complex between d(GAAGCTTC) and the anticancer drug actinomycin D.

The crystal structures of the 2:1 complex of the self-complementary DNA octamer d(GAAGCTTC) with actinomycin D has been determined at 3.0 A resolution. This is the first example of a crystal structure of a DNA-drug complex in which the drug intercalates into the middle of a relatively long DNA segment. The results finally confirmed the DNA-actinomycin intercalation model proposed by Sobell & co-workers in 1971. The DNA molecule adopts a severely distorted and slightly kinked B-DNA-like structure with an actinomycin D molecule intercalated in the middle sequence, GC. The two cyclic depsipeptides, which differ from each other in overall conformation, lie in the minor groove. The complex is further stabilized by forming base-peptide and chromophore-backbone hydrogen bonds. The DNA helix appears to be unwound by rotating one of the base-pairs at the intercalation site. This single base-pair unwinding motion generates a unique asymmetrically wound helix at the binding site of the drug, i.e. the helix is loosened at one end of the intercalation site and tightened at the other end. The large unwinding of the DNA by the drug intercalation is absorbed mostly in a few residues adjacent to the intercalation site. The asymmetrical twist of the DNA helix, the overall conformation of the two cyclic depsipeptides and their interaction mode with DNA are correlated to each other and rationally explained.     

JNK Signalling Controls Remodelling of the Segment Boundary through Cell Reprogramming during Drosophila Morphogenesis

Segments are fundamental units in animal development which are made of distinct cell lineages separated by boundaries. Although boundaries show limited plasticity during their formation for sharpening, cell lineages make compartments that become tightly restricted as development goes on. Here, we characterize a unique case of breaking of the segment boundary in late drosophila embryos. During dorsal closure, specific cells from anterior compartments cross the segment boundary and enter the adjacent posterior compartments. This cell mixing behaviour is driven by an anterior-to-posterior reprogramming mechanism involving de novo expression of the homeodomain protein Engrailed. Mixing is accompanied by stereotyped local cell intercalation, converting the segment boundary into a relaxation compartment important for tension-release during morphogenesis. This process of lineage switching and cell remodelling is controlled by JNK signalling. Our results reveal plasticity of segment boundaries during late morphogenesis and a role for JNK-dependent developmental reprogramming in this process.     

Engrailed gene expression in the abdominal segment of Oncopeltus: gradients and cell states in the insect segment

A monoclonal antibody that recognizes the product of the segmental gene, engrailed (en), of Drosophila has been used to analyse expression of the homologous gene of Oncopeltus. engrailed expression in the abdominal segment of larval Oncopeltus is confined to a narrow band of epidermal cells localized immediately anterior to the segment border. Expression varies in intensity during postembryonic development: no gene product is detectable in newly moulted larvae, but reappears soon after initiation of intermoult activities. One possible function of en in this system is revealed by a series of operations confronting cells from different anteroposterior levels in the segment. New segment borders are generated only when en-expressing cells confront cells from the anteriormost region of the segment. All other combinations result in intercalation of intermediate intrasegmental levels. It is therefore suggested that the most important function of en is the establishment of new, and presumably the maintenance of existing, segment borders.     

A double segment periodicity underlies segment generation in centipede development

The number of leg-bearing segments in centipedes varies extensively, between 15 and 191, and yet it is always odd. This suggests that segment generation in centipedes involves a stage with double segment periodicity and that evolutionary variation in segment number reflects the generation of these double segmental units. However, previous studies have revealed no trace of this. Here we report the expression of two genes, an odd-skipped related gene (odr1) and a caudal homolog, that serve as markers for early steps of segment formation in the geophilomorph centipede, Strigamia maritima. Dynamic expression of odr1 around the proctodaeum resolves into a series of concentric rings, revealing a pattern of double segment periodicity in overtly unsegmented tissue. Initially, the expression of the caudal homolog mirrors this double segment periodicity, but shortly before engrailed expression and overt segmentation, the intercalation of additional stripes generates a repeat with single segment periodicity. Our results provide the first clues about the causality of the unique and fascinating "all-odd" pattern of variation in centipede segment numbers and have implications for the evolution of the mechanisms of arthropod segmentation.     

Regulation of proximal-distal intercalation during limb regeneration in the axolotl (Ambystoma mexicanum)

Intercalation is the process whereby cells located at the boundary of a wound interact to stimulate proliferation and the restoration of the structures between the boundaries that were lost during wounding. Thus, intercalation is widely considered to be the mechanism of regeneration. When a salamander limb is amputated, the entire cascade of regeneration events is activated, and the missing limb segments and their boundaries (joints) as well as the structures within each segment are regenerated. Therefore, in an amputated limb it is not possible to distinguish between intersegmental regeneration (formation of new segments/joints) and intrasegmental regeneration (formation of structures within a given segment), and it is not possible to study the differential regulation of these two processes. We have used two models for regeneration that allow us to study these two processes independently, and report that inter- and intrasegmental regeneration are different processes regulated by different signaling pathways. New limb segments/joints can be regenerated from cells that dedifferentiate to form blastema cells in response to signaling that is mediated in part by fibroblast growth factor.     

Pattern regulation during the development of the dorsal abdomen in the flesh fly,Sarcophaga agryostoma

Summary In dipteran flies the adult abdominal epidermis is formed from small nests of diploid histoblast cells which spread out and replace the larval epidermis during metamorphosis. The pattern of nest outgrowth and fusion in Sarcophaga shows that the large dorsal hemitergite is normally formed by the two dorsal nests, the spiracle nest and part of the ventral nest (which also forms the hemisternite). By rotating the dorsal histoblast nests, we demonstrate that the adult segment border lies between the flexible intersegmental membrane (ISM) and the naked anterior strip of tergite, the acrotergite. Deletion of histoblast nests often results in a corresponding deletion of adult structures, accompanied by enlargement of adjacent structures within the segment and in neighbouring segments. Pattern formation is not strictly coupled to cell division (as in imaginal discs), since the nests remaining after an ablation, in spreading to fill vacant areas, generate more cells and larger structures than normal. Nest deletions can also result in regeneration, with remaining nests forming additional structures in the dorsal-ventral or anterior-posterior axis of the segment. The deletion of strips of anterior and intersegmental larval epidermis without histoblasts results in the formation of double-posterior duplications of the adult hemitergite. Although these operations damage adjacent histoblast nests, several features of the results suggest that the duplications arise from the interaction (after healing) of histoblasts with larval cells which they would not normally encounter, leading to the intercalation of histoblast cells bearing intervening anterior-posterior positional values. A similar process of intercalation may occur in normal development, as the histoblasts spread from their local origins across the larval epidermal sheet, replacing the larval cells to form the entire epidermis of the adult segment. Offprint requests to: V. French     

Control of intercalation is cell-autonomous in the notochord of Ciona intestinalis

Dishevelled signaling plays a critical role in the control of cell intercalation during convergent extension in vertebrates. This study presents evidence that Dishevelled serves a similar function in the Ciona notochord. Embryos transgenic for mutant Dishevelled fail to elongate their tails, and notochord cells fail to intercalate, though notochord cell fates are unaffected. Analysis of mosaic transgenics revealed that the effects of mutant Dishevelled on notochord intercalation are cell-autonomous in Ciona, though such defects have nonautonomous effects in Xenopus. Furthermore, our data indicate that notochord cell intercalation in Ciona does not require the progressive signals which coordinate cell intercalation in the Xenopus notochord, highlighting an important difference in how mediolateral cell intercalation is controlled in the two animals. Finally, this study establishes the Ciona embryo as an effective in vivo system for the study of the molecular control of morphogenetic cell movements in chordates.     

Intercalation conformations in single- and double-stranded nucleic acids

Two regions in the crystal structure of yeast phenylalanine tRNA, where single-stranded loops interact by intercalation, have been examined in detail. There are four examples of a nucleotide base from one loop intercalating between two sequential bases of another loop in these two regions. These four dinucleoside phosphate conformations serve as models for intercalation in single-stranded nucleic acids. Double-stranded DNA and RNA polymers were constructed by computer model building methods, which incorporated the dinucleoside phosphate conformations found in these single-stranded, intercalation regions in otherwise standard double-helices. The results suggest that it is unlikely that there is a unique intercalation geometry for either single- or double-stranded nucleic acids, but that nucleic acids may assume one of a variety of intercalation geometries which will best accommodate a particular intercalating agent for a particular base sequence.     

Structural limitations on the bifunctional intercalation of diacridines into DNA

An homologous series of diacridines containing two 9-aminoacridine chromophores linked via a simple methylene chain has been studied in order to investigate the minimum interchromophore separation required to permit bifunctional intercalation. Viscometric, sedimentation, and electric dichroism experiments show that compounds having one to four methylene groups in the linker are restricted to monofunctional intercalation, whereas the interaction becomes bifunctional when the chain length is increased to six carbons or more. The results indicate that bifunctional reaction occurs with an interchromophore distance not exceeding 8.8 A, implying that intercalation by these compounds is not subject to neighbor exclusion if the mode of binding is of the classical intercalation type.     

Sodium-23 and lithium-7 NMR spin-lattice relaxation measurements in the study intercalation in DNA.

Sodium-23 spin-lattice relaxation rate (the reciprocal relaxation time) measurements have been used to study the intercalation of 9-aminoacridine in calf thymus DNA. The results are analyzed by a two state model based on the counterion condensation theory and a theory for the quadrupolar relaxation of counterions in polyelectrolyte solutions. It is shown that change of the solvent from H2O to D2O has a negligible effect on the intercalation process. Furthermore, an attempt is made to analyze the dependence of the 7Li spin-lattice relation rate on intercalation of 9-aminoacridine in LiDNA. It is shown that both quadrupolar and dipolar mechanisms contribute to the bound 7Li relation rate, and that both these contributions are reduced upon intercalation of 9-aminoacridine.     

Tests of spool models for DNA packaging in phage lambda

Experiments are reported which bear on two spool models proposed for packaging the DNA of phage lambda. Both spool models fill an assumed spherical cavity with DNA wrapped in cylindrical or quasi-cylindrical layers composed of adjacent circular turns. In the curved-spool model, a single continuous segment of DNA, about 20% of the DNA length and probably located near the left end of the DNA, is in contact with the coat protein of the phage capsid. In the straight spool model, there are several DNA segments in contact with the capsid; they are concentrated in one half (probably the left half) of lambda DNA. We have identified the loci on the DNA which are in contact with the capsid by chemical crosslinking, induced by ultraviolet-irradiation of phage containing 5-bromodeoxyuridine in place of thymine.In an electron microscope experiment, phage are first lysed with EDTA, and then spread in a cytochrome c film by the formamide method. The disrupted capsid, which has the appearance of a phage ghost, serves as a marker showing where the DNA is crosslinked to the coat. The left end of the DNA is not distinguished from the right end, and so the map of DNA-capsid contacts is folded over on itself. Contacts are found nearly randomly over the entire map.In a second experiment, DNA from lysed, crosslinked phage is cut either with EcoRI or HindIII restriction endonucleases and the cut restriction fragments are labeled at their ends with ³²P. Density centrifugation in a CsCl gradient separates free DNA from restriction fragments crosslinked to protein. After digestion with proteinase k, the DNA fragments previously crosslinked to protein are identified by size after agarose gel electrophoresis. DNA fragments from all parts of the genome are found.These two experiments show that, if the DNA of each phage is packaged identically, then the curved-spool model is ruled out and the straight spool model is unlikely. Alternatively, the manner of packaging the DNA may vary from one phage to the next. These results agree with other recent experiments on λ DNA packaging by Hall & Schellman (1982a,b), and by Haas et al. (1982).A different experiment is also reported. The psoralen derivative aminomethyltrioxalen (AMT) is allowed to intercalate into λ phage and then the DNA strands are crosslinked by ultraviolet-irradiation after the rapid phase of AMT intercalation is complete. The DNA is subsequently denatured by glyoxal modification and spread for electron microscopy in a cytochrome c film by the formamide method. Sites of AMT crosslinking appear duplex; uncrosslinked regions appear as single-stranded loops. AMT is found to intercalate throughout the λ DNA. Patterns of reacted sites appear different from one DNA molecule to the next, and no consistent pattern can be found. More extensive intercalation occurs with the deletion mutant λb221 than with phage of wild-type DNA length, and free DNA shows much more reaction than the DNA inside either phage type. In order for intercalation to occur, the DNA helix must unwind and become further extended. This experiment shows that regions throughout the entire DNA molecule can unwind and be extended by intercalation, which is not confined to a single DNA segment or to segments in one half of the DNA molecule, as would be expected for the two spool models if only the DNA in contact with the capsid were accessible to the dye.     

Unravelling the distinct contribution of cell shape changes and cell intercalation to tissue morphogenesis: the case of the Drosophila trachea

Intercalation allows cells to exchange positions in a spatially oriented manner in an array of diverse processes, spanning convergent extension in embryonic gastrulation to the formation of tubular organs. However, given the co-occurrence of cell intercalation and changes in cell shape, it is sometimes difficult to ascertain their respective contribution to morphogenesis. A well-established model to analyse intercalation, particularly in tubular organs, is the Drosophila tracheal system. There, fibroblast growth factor (FGF) signalling at the tip of the dorsal branches generates a ‘pulling’ force believed to promote cell elongation and cell intercalation, which account for the final branch extension. Here, we used a variety of experimental conditions to study the contribution of cell elongation and cell intercalation to morphogenesis and analysed their mutual requirements. We provide evidence that cell intercalation does not require cell elongation and vice versa. We also show that the two cell behaviours are controlled by independent but simultaneous mechanisms, and that cell elongation is sufficient to account for full extension of the dorsal branch, while cell intercalation has a specific role in setting the diameter of this structure. Thus, rather than viewing changes in cell shape and cell intercalation as just redundant events that add robustness to a given morphogenetic process, we find that they can also act by contributing to different features of tissue architecture.     

Small molecule intercalation with double stranded DNA: implications for normal gene regulation and for predicting the biological efficacy and genotoxicity of drugs and other chemicals

The binding of small molecules to double stranded DNA including intercalation between base pairs has been a topic of research for over 40 years. For the most part, however, intercalation has been of marginal interest given the prevailing notion that binding of small molecules to protein receptors is largely responsible for governing biological function. This picture is now changing with the discovery of nuclear enzymes, e.g. topoisomerases that modulate intercalation of various compounds including certain antitumor drugs and genotoxins. While intercalators are classically flat, aromatic structures that can easily insert between base pairs, our laboratories reported in 1977 that a number of biologically active compounds with greater molecular thickness, e.g. steroid hormones, could fit stereospecifically between base pairs. The hypothesis was advanced that intercalation was a salient feature of the action of gene regulatory molecules. Two parallel lines of research were pursued: (1) development of technology to employ intercalation in the design of safe and effective chemicals, e.g. pharmaceuticals, nutraceuticals, agricultural chemicals; (2) exploration of intercalation in the mode of action of nuclear receptor proteins. Computer modeling demonstrated that degree of fit of certain small molecules into DNA intercalation sites correlated with degree of biological activity but not with strength of receptor binding. These findings led to computational tools including pharmacophores and search engines to design new drug candidates by predicting desirable and undesirable activities. The specific sequences in DNA into which ligands best intercalated were later found in the consensus sequences of genes activated by nuclear receptors implying intercalation was central to their mode of action. Recently, the orientation of ligands bound to nuclear receptors was found to match closely the spatial locations of ligands derived from intercalation into unwound gene sequences suggesting that nuclear receptors may be guiding ligands to DNA with remarkable precision. Based upon multiple lines of experimental evidence, we suggest that intercalation in double stranded DNA is a ubiquitous, natural process and a salient feature of the regulation of genes. If double stranded DNA is proven to be the ultimate target of genomic drug action, intercalation will emerge as a cornerstone of the future discovery of safe and effective pharmaceuticals.     

Interactions of molecules with nucleic acids. III. Steric and electrostatic energy contours for the principal intercalation sites,prerequisites for binding,and the exclusion of essential metabolites from intercalation

Based on steric and electrostatic considerations, the prerequisites for binding to DNA via the intercalation mechanism are proposed. Steric contour energy curves are presented to demonstrate the region inaccessible to an intercalant. They are calculated with a 6-n (n = 14) potential. This method is a soft potential analog of an excluded-volume approach. Electrostatic contours on the steric surface illustrate the relatively positive and negative regions of the binding site. The principal intercalation sites, predicted to fit into B-DNA via a tetramer-duplex unit, and the unconstrained dimer-duplex units, obtained in crystal structures, are examined. These contours illustrate the requirements of size, conformation, and net atomic charges necessary for intercalation and optimum binding. Based on the limited space available for intercalation by the presence of the backbone and the maximum base-pair separation of 8.25 Å, an Essential Metabolite Exclusion Hypothesis is presented.     

The influence of N-dialkyl and other cationic substituents on DNA intercalation and genotoxicity

DNA intercalation by small chemical molecules can result in frameshift mutagenesis and chromosomal breakage. With evidence mounting that broadly diverse structures are capable of intercalating between DNA base pairs, it becomes important to better define those structural features that enhance intercalation strength and those that confer genotoxicity particularly among those intercalators that do not have the classical planar tricyclic fused ring structure. A chemical substituent that is present on many pharmaceutical and other biologically active molecules is the N-dialkyl group. In the present study, we investigate if and how the presence of an aromatic N-dialkyl or other cationic group affects the genotoxicity and DNA intercalation ability of 26 selected acridines, phenothiazines, benzophenones, triphenylethylenes and other classes of molecules. The data were obtained from the literature, from experiments using a cell-based DNA intercalation assay, and from modeling studies using a three-dimensional computational DNA docking program. It is demonstrated that cationic substitution can enhance both genotoxicity and electrostatic interactions within a chemical/DNA intercalation complex.     

The role of side chains in the interaction of new antitumor pyrimidoacridinetriones with DNA: molecular dynamics simulations

Pyrimidoacridinetriones (PATs) are a new group of highly active antitumor compounds. It seems reasonable to assume that, like for some other acridine derivatives, intercalation into DNA is a necessary, however not a sufficient condition for antitumor activity of these compounds. Rational design of new compounds of this chemotype requires knowledge about the structure of the intercalation complex, as well as about interactions responsible for its stability. Computer simulation techniques such as molecular dynamics (MD) may provide valuable information about these problems. The results of MD simulations performed for three rationally selected PATs are presented in this paper. The compounds differ in the number and position of side chains. Each of the compounds was simulated in two systems: i) in water, and ii) in the intercalation complex with the dodecamer duplex d(GCGCGCGCGCGC)2. The orientation of the side chain in relation to the ring system is determined by the position of its attachment. Orientation of the ring system inside the intercalation cavity depends on the number and position of side chain(s). The conformations of the side chain(s) of all PATs studied in the intercalation complex were found to be very similar to those observed in water.