Dual conformational recognition by Z-DNA binding protein is important for the B-Z transition process.

Left-handed Z-DNA is radically different from the most common right-handed B-DNA and can be stabilized by interactions with the Zα domain, which is found in a group of proteins, such as human ADAR1 and viral E3L proteins. It is well-known that most Zα domains bind to Z-DNA in a conformation-specific manner and induce rapid B-Z transition in physiological conditions. Although many structural and biochemical studies have identified the detailed interactions between the Zα domain and Z-DNA, little is known about the molecular basis of the B-Z transition process. In this study, we successfully converted the B-Z transition-defective Zα domain, vvZαE3L, into a B-Z converter by improving B-DNA binding ability, suggesting that B-DNA binding is involved in the B-Z transition. In addition, we engineered the canonical B-DNA binding protein GH5 into a Zα-like protein having both Z-DNA binding and B-Z transition activities by introducing Z-DNA interacting residues. Crystal structures of these mutants of vvZαE3L and GH5 complexed with Z-DNA confirmed the significance of conserved Z-DNA binding interactions. Altogether, our results provide molecular insight into how Zα domains obtain unusual conformational specificity and induce the B-Z transition.

NMR elucidation of reduced B-Z transition activity of PKZ protein kinase at high NaCl concentration.

A Z-DNA binding protein (ZBP)-containing protein kinase (PKZ) in fish species has an important role in the innate immune response. Previous structural studies of the Zα domain of the PKZ from Carassius auratus (caZαPKZ) showed that the protein initially binds to B-DNA and induces B-Z transition of double stranded DNA in a salt concentration-dependent manner. However, the significantly reduced B-Z transition activity of caZαPKZ at high salt concentration was not fully understood. In this study, we present the binding affinity of the protein for B-DNA and Z-DNA and characterize its extremely low B-Z transition activity at 250 mM NaCl. Our results emphasize that the B-DNA-bound form of caZαPKZ can be used as molecular ruler to measure the degree of B-Z transition.

Twisting right to left: A A mismatch in a CAG trinucleotide repeat overexpansion provokes left-handed Z-DNA conformation.

Conformational polymorphism of DNA is a major causative factor behind several incurable trinucleotide repeat expansion disorders that arise from overexpansion of trinucleotide repeats located in coding/non-coding regions of specific genes. Hairpin DNA structures that are formed due to overexpansion of CAG repeat lead to Huntington's disorder and spinocerebellar ataxias. Nonetheless, DNA hairpin stem structure that generally embraces B-form with canonical base pairs is poorly understood in the context of periodic noncanonical A…A mismatch as found in CAG repeat overexpansion. Molecular dynamics simulations on DNA hairpin stems containing A…A mismatches in a CAG repeat overexpansion show that A…A dictates local Z-form irrespective of starting glycosyl conformation, in sharp contrast to canonical DNA duplex. Transition from B-to-Z is due to the mechanistic effect that originates from its pronounced nonisostericity with flanking canonical base pairs facilitated by base extrusion, backbone and/or base flipping. Based on these structural insights we envisage that such an unusual DNA structure of the CAG hairpin stem may have a role in disease pathogenesis. As this is the first study that delineates the influence of a single A…A mismatch in reversing DNA helicity, it would further have an impact on understanding DNA mismatch repair.

Conformation-dependent DNA attraction.

Understanding how DNA molecules interact with other biomolecules is related to how they utilize their functions and is therefore critical for understanding their structure-function relationships. For a long time, the existence of Z-form DNA (a left-handed double helical version of DNA, instead of the common right-handed B-form) has puzzled the scientists, and the definitive biological significance of Z-DNA has not yet been clarified. In this study, the effects of DNA conformation in DNA-DNA interactions are explored by molecular dynamics simulations. Using umbrella sampling, we find that for both B- and Z-form DNA, surrounding Mg(2+) ions always exert themselves to screen the Coulomb repulsion between DNA phosphates, resulting in very weak attractive force. On the contrary, a tight and stable bound state is discovered for Z-DNA in the presence of Mg(2+) or Na(+), benefiting from their hydrophobic nature. Based on the contact surface and a dewetting process analysis, a two-stage binding process of Z-DNA is outlined: two Z-DNA first attract each other through charge screening and Mg(2+) bridges to phosphate groups in the same way as that of B-DNA, after which hydrophobic contacts of the deoxyribose groups are formed via a dewetting effect, resulting in stable attraction between two Z-DNA molecules. The highlighted hydrophobic nature of Z-DNA interaction from the current study may help to understand the biological functions of Z-DNA in gene transcription.

The crystallographic study of left-handed Z-DNA d(CGCGCG)2 and thermine complexes crystallized at various temperatures and at various concentration of cations.

In crystals of complexes of thermine and d(CGCGCG)2 molecules grown at 4, 10, and 20 degrees C, the numbers of thermine molecules connected to the DNA molecule were dependent on the temperature of the crystallization. Two molecules of thermine and one Mg2+ ion were connected to DNA molecule when thermine and d(CGCGCG)2 were co-crystallized at 4 and at 20 degrees C. When an increased concentration of magnesium and thermine molecules were co-crystallized with d(CGCGCG)2 molecules at 10 degrees C, three Mg2+ ions and only one thermine molecule were bound with a d(CGCGCG)2 molecule. The number of polyamines and of Mg2+ ions connected to DNA was dependent on the atomic values of the polyamine and of the metal ion. The binding of more Mg2+ ions occurred when the atomic value of Mg2+ exceeded that of the corresponding mono- or polyamine, and when the Mg2+ ion concentration was elevated. Furthermore, this study is the first documentation of a naturally occurring polyamine bound to the minor groove of DNA in a crystal structure.

Polyamines stabilize left-handed Z-DNA: using X-ray crystallographic analysis, we have found a new type of polyamine (PA) that stabilizes left-handed Z-DNA.

There are many great reports of polyamine stabilization of the Z-DNA by bridge conformation between neighboring, symmetry-related Z-DNA in the packing of crystals. However, polyamine binding to the minor groove of Z-DNA and stabilizing the Z-DNA structure has been rarely reported. We proved that the synthesized polyamines bind to the minor groove of Z-DNA and stabilize the conformation under various conditions, by X-ray crystallographic study. These polyamines consist of a polyamine nano wire structure. The modes of the polyamine interaction were changed under different conditions. It is the first example that the crystals consisted of metal free structure. This finding provides a basis for clarifying B-Z transition mechanics.

Solitary excitations in B-Z DNA transition: a theoretical and numerical study.

The molecular mechanism of B-Z DNA transition remains elusive since the elucidation of the left-handed Z-DNA structure using atomic resolution crystallographic study. Numerous proposals for the molecular mechanism have been advanced, but none has provided a satisfactory explanation for the process. A nonlinear DNA model is proposed which enables one to derive various hypothesized molecular mechanisms, namely the Harvey model, Zang and Olson model, and the stretched intermediate model, by imposing certain constraints and conditions on the model. These constraints raise the need to reevaluate experimental investigations on B-Z DNA transition.

Firing of transcription and compartmentalization of splicing factors in tomato radicle nuclei during germination(1).

BACKGROUND INFORMATION: Germination is a well-characterized process in which embryo cells of seeds experience a programmed transition from quiescence to proliferation. For this reason they constitute a very good system to analyse nuclear evolution from a dehydrated practically inactive state until the steady state of proliferation. We analysed the temporal and spatial organization of transcription and splicing factors in nuclei of tomato radicle cells during germination. To address this issue we performed in situ immunodetection of several markers of these processes: the Z-DNA stretches forming behind the active RNA polymerases, the splicing proteins U2B'' and Sm, and the trimethyl guanosin cap of small nuclear RNA. The concomitant structural changes of the different nuclear compartments were studied in meristematic nuclei by electron microscopy and high-resolution cytochemistry for DNA and ribonucleoproteins. RESULTS: In quiescent cells practically no Z-DNA stretches were detected and splicing components localized mainly to one or two Cajal bodies associated to the nucleolus. In early germination, a massive de-condensation of chromatin and nucleolar Z-DNA conformation stretches were first detected, followed by the relocation of scarce splicing components to the small interchromatin spaces. Nucleoplasmic Z-DNA stretches were not detected until 4 h of imbibition and were accompanied by an important increase of splicing components in this nuclear domain. Soon after the post-germination stage, transcription and splicing topology and nuclear organization in meristematic nuclei resemble those in steady state growing tomato roots. CONCLUSIONS: Our results demonstrate that, in tomato, dormant nuclei splicing factors are stored in nucleolar Cajal bodies. In early germination, RNA polymerase I transcription is first activated, whereas mRNA transcription is fired later and is accompanied by a massive de-condensation of chromatin and accumulation of splicing factors in the interchromatin domains. Nucleoplasmic Cajal bodies appear later in germination.

Interaction of the Zalpha domain of human ADAR1 with a negatively supercoiled plasmid visualized by atomic force microscopy.

Interest to the left-handed DNA conformation has been recently boosted by the findings that a number of proteins contain the Zalpha domain, which has been shown to specifically recognize Z-DNA. The biological function of Zalpha is presently unknown, but it has been suggested that it may specifically direct protein regions of Z-DNA induced by negative supercoiling in actively transcribing genes. Many studies, including a crystal structure in complex with Z-DNA, have focused on the human ADAR1 Zalpha domain in isolation. We have hypothesized that the recognition of a Z-DNA sequence by the Zalpha(ADAR1) domain is context specific, occurring under energetic conditions, which favor Z-DNA formation. To test this hypothesis, we have applied atomic force microscopy to image Zalpha(ADAR1) complexed with supercoiled plasmid DNAs. We have demonstrated that the Zalpha(ADAR1) binds specifically to Z-DNA and preferentially to d(CG)(n) inserts, which require less energy for Z-DNA induction compared to other sequences. A notable finding is that site-specific Zalpha binding to d(GC)(13) or d(GC)(2)C(GC)(10) inserts is observed when DNA supercoiling is insufficient to induce Z-DNA formation. These results indicate that Zalpha(ADAR1) binding facilities the B-to-Z transition and provides additional support to the model that Z-DNA binding proteins may regulate biological processes through structure-specific recognition.