Patterned cocrystal monolayers self-assemble on HOPG in contact with solutions containing complementary pairs of 1,5-chain-substituted anthracene derivatives. Monolayer unit cells containing three or four molecules and spanning 9-11 nm are generated. The monolayers consist of alternating aromatic and aliphatic columns. The designs and dimensions of the cocrystal patterns (unit cells) are determined by (i) the preferred packing alignment of identical length side chains, (ii) the selectivity of each side chain for neighboring chains, (iii) the identities of the two side chains on each anthracene, and (iv) the 2D-chirality of 1,5-substituted anthracenes. The aliphatic columns form by interdigitation of identical length side chains arrayed in an antiparallel alignment, with the nth heavy atom of one side chain in registration with the (omega+2-n)th heavy atom of two adjacent chains ((omega <--> 2) packing). Adjacent side chains are attached, alternately, to anthracenes in one of the two flanking aromatic columns. The preference for (omega <--> 2) packing optimizes side-chain van der Waals interactions. The composition and fidelity of patterning in the cocrystal monolayers requires an additional source of "molecular recognition" in addition to side-chain length. Dipolar interactions, both attractive and repulsive, between ether groups in neighboring, (omega <--> 2) packed side chains, constitute a second recognition element needed for cocrystal self-assembly.
The virally encoded site-specific recombinase Int collaborates with its accessory DNA bending proteins IHF, Xis, and Fis to assemble two distinct, very large, nucleoprotein complexes that carry out either integrative or excisive recombination along regulated and essentially unidirectional pathways. The core of each complex consists of a tetramer of Integrase protein (Int), which is a heterobivalent DNA binding protein that binds and bridges a core-type DNA site (where strand cleavage and ligation are executed), and a distal arm-type site, that is brought within range by one or more DNA bending proteins. The recent determination of the patterns of these Int bridges has made it possible to think realistically about the global architecture of the recombinogenic complexes. Here, we combined the previously determined Int bridging patterns with in-gel FRET experiments and in silico modeling to characterize and differentiate the two 400-kDa multiprotein Holiday junction recombination intermediates formed during λ integration and excision. The results lead to architectural models that explain how integration and excision are regulated in λ site-specific recombination. Our confidence in the basic features of these architectures is based on the redundancy and self-consistency of the underlying data from two very different experimental approaches to establish bridging interactions, a set of strategic intracomplex distances from FRET experiments, and the model's ability to explain key aspects of the integrative and excisive recombination pathways, such as topological changes, the mechanism of capturing attB, and the features of asymmetry and flexibility within the complexes.regulation of directionality | topology | recombinogenic architectures | molecular machines H igh-precision DNA transactions responsible for a variety of fundamental processes are typically promoted and modulated by large multiprotein machines that use cooperative interactions and involve DNA bending and/or wrapping. One well-studied example is the tightly regulated and highly directional site-specific recombination by which bacteriophage λ inserts and excises its DNA into and out of the Escherichia coli host chromosome, using the phage attP and the bacterial attB DNA sequences for integration and the resulting junction sequences, attL and attR, for excision. These reactions are catalyzed by the phage-encoded Integrase protein (Int), the founding member of the tyrosine recombinase family of site-specific recombinases (1). In addition to mediating integration and excision of viral genomes, members of this family function in a variety of other cellular processes including chromosome segregation, gene regulation, and conjugative transposition (2).Int has three well-characterized domains: an N-terminal DNA-binding domain (NTD), a central core-binding domain (CB), and a C-terminal catalytic domain (CAT). The CB and CAT domains (referred to here as the CTD) are together responsible for binding to the core-type DNA sequences where strand exchange and ligation t...
A strategy for controlling relative placements of molecules within multicomponent monolayers at the solution-HOPG interface is demonstrated. The monolayers assemble from complementary pairs of 1,5-bis-alkyldiether-anthracenes bearing self-repelling side chains. Each diether side chain suffers repulsive dipolar interactions if it adsorbs next to an identical side chain in the morphology normally assumed by 1,5-bis-substituted-anthracene monolayers. Complementary side-chain pairs experience attractive dipolar interactions when adsorbed as neighbors in the normal morphology monolayer. The repulsive and attractive forces spontaneously drive formation of a patterned monolayer at the solution-HOPG interface. Each molecule adsorbs in its own row, sandwiched between two rows of the complementary anthracene. These studies demonstrate the viability of using weak dipolar interactions to control molecular placement and monolayer morphology and to pattern multicomponent monolayers.
The site-specific recombinase encoded by bacteriophage λ [λ Integrase (Int)] is responsible for integrating and excising the viral chromosome into and out of the chromosome of its Escherichia coli host. In contrast to the other well-studied and highly exploited tyrosine recombinase family members, such as Cre and Flp, Int carries out a reaction that is highly directional, tightly regulated, and depends on an ensemble of accessory DNA bending proteins acting on 240 bp of DNA encoding 16 protein binding sites. This additional complexity enables two pathways, integrative and excisive recombination, whose opposite, and effectively irreversible, directions are dictated by different physiological and environmental signals. Int recombinase is a heterobivalent DNA binding protein that binds via its small amino-terminal domain to high affinity arm-type DNA sites and via its large, compound carboxyl-terminal domain to core-type DNA sites, where DNA cleavage and ligation are executed. Each of the four Int protomers, within a multiprotein 400-kDa recombinogenic complex, is thought to bind and, with the aid of DNA bending proteins, bridge one arm-and one core-type DNA site. Despite a wealth of genetic, biochemical, and functional information generated by many laboratories over the last 50 y, it has not been possible to decipher the patterns of Int bridges, an essential step in understanding the architectures responsible for regulated directionality of recombination. We used site-directed chemical cross-linking of Int in trapped Holliday junction recombination intermediates and recombination reactions with chimeric recombinases, to identify the unique and monogamous patterns of Int bridges for integrative and excisive recombination.site-specific recombination | regulation of directionality | recombinogenic architectures | molecular machines
The molecular machinery responsible for DNA expression, recombination, and compaction has been difficult to visualize as functionally complete entities due to their combinatorial and structural complexity. We report here the structure of the intact functional assembly responsible for regulating and executing a site-specific DNA recombination reaction. The assembly is a 240-bp Holliday junction (HJ) bound specifically by 11 protein subunits. This higher-order complex is a key intermediate in the tightly regulated pathway for the excision of bacteriophage λ viral DNA out of the E. coli host chromosome, an extensively studied paradigmatic model system for the regulated rearrangement of DNA. Our results provide a structural basis for pre-existing data describing the excisive and integrative recombination pathways, and they help explain their regulation.DOI: http://dx.doi.org/10.7554/eLife.14313.001
Scanning tunneling microscopy (STM) is used to determine the 2-D unit cell parameters of monolayers self-assembled by twelve symmetrical, 1,5-bis(linear aliphatic ether side chain) anthracenes at the solution-graphite interface. The standard morphology assembled by 1,5-bis(alkyloxymethyl) anthracenes consists of single-lamella domains containing columns of anthracene cores alternating with columns of interdigitated, aliphatic side chains. Adjacent side chains within the aliphatic columns adsorb in antiparallel orientations. The terminal methyl (omega-position) of each side chain lies in registration with the 2-positions of its two neighboring chains ((omega <--> 2)-packing). Anthracenes with diether side chains can generate repulsive or attractive dipole-dipole interactions between proximate ethers of adjacent aliphatic chains. Anthracenes bearing even length side chains with oxygens at the 2- and omega-1 positions or at the 3- and omega-2 positions do not assemble (omega <--> 2)-packed monolayers. Repulsive dipolar interactions between ethers in adjacent side chains raise the energy of (omega <--> 2) morphologies. These "self-repulsive" side chains drive assembly of (omega <--> l)- or (omega <--> 3)-packed morphologies, which enjoy stabilizing dipolar interactions between ethers in adjacent side chains. In stark contrast, anthracenes bearing odd length diether side chains assemble (omega <--> 2)-packed morphologies, regardless of whether adjacent chains suffer zero, one, or two sets of proximate dipole-dipole repulsions. The intrinsic energy gap from (omega <--> 2)- to non-(omega <--> 2)-packed morphologies of odd length side chain anthracenes is, apparently, larger than for even length side chain anthracenes. Overall, the twelve compounds self-assemble seven different morphologies. Distinguishing morphologies, understanding polymorphism within the monolayers, and evaluating the morphological consequences of side chain dipolar interactions is facilitated by viewing the monolayers as assemblies of 1-D, molecular tapes.
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