Genetic organization of the polymorphic equine alpha globin locus and sequence of the BII alpha 1 gene.

The equine alpha globin gene complex comprises two functional alpha genes and an alpha-like pseudogene arranged in the order 5'-alpha 2-(5kb)-alpha 1-(3kb)-psi alpha-3'. A single (embryonic) zeta-like sequence lies within a 12 kb region 5' to the alpha 2 gene. We have determined the sequence of the alpha 1 gene of the BII haplotype, one of two most common haplotypes (the other being BI) which encode alpha globins with either Tyr (BI) or Phe (BII) at codon 24 in both linked alpha genes. In BI and BII the non-allelic alpha 2 and alpha 1 genes respectively code for Gln or Lys at codon 60, thus accounting for the 4 alpha globin types seen in BI/BII heterozygotes. Genomic restriction enzyme maps of the BII alpha complex (24Phe/60Lys,Gln) and the allelic BI (24Tyr/60Lys,Gln) are identical to each other, and to those of a rarer normal haplotype, A, which encodes only alpha 24Tyr/60Gln globin, and a low expression mutant of BII which encodes only 24Phe/60Lys globin. These two latter haplotypes must therefore have a linked pair of alpha genes, as in BI and BII, but with identical coding properties, and it is suggested that this has arisen by gene conversion.     

Establishing the structure of anthracyclinones produced by Streptomyces griseoruber

Streptomyces grisoruber strain 1618-306 produces three types of anthracycline antibiotics, derivatives of epsilon-pyrromycinone (methyl (7S, 9R, 10R)-9-ethyl-5,7,8,9,10,12-hexahydro-1,4,6,7,9-pentahydroxy-5,12-di oxo-10- naphthacenecarboxylate), epsilon-1-hydroxyauramycinone and epsilon-1-hydroxysulfurmycinone, differing in C-9 substituent in D ring of anthracyclines (Et, Met or CH2COCH3, respectively). Besides 7-O-glycosides of these aglycones, complex of antibiotics contains corresponding 7-deoxy- and 7,8,9,10-bisanhydroanthracyclinones.     

Gene conversions in the horse alpha-globin gene complex

The sequences of the linked alpha 2- and alpha 1-globin genes of the equine BI and BII haplotypes are greater than 99% identical within a 1.2-kb region extending from approximately 75 bp upstream of the putative cap site to a point approximately 150 bp 3' to the poly A addition signal. Differences between the alpha 2 and alpha 1 genes that are common to both haplotypes indicate that a major gene conversion occurred approximately 12 Myr ago and that this has been followed by shorter, more localized, conversions. Interhaplotype (allelic) comparisons at the alpha loci suggest that the BI and BII haplotypes have probably existed independently greater than or equal to 0.5 Myr and that the alpha 1 genes may have undergone a recent interchromosomal gene conversion.      

DNA fine structure and dynamics in crystals and in solution: the impact of BI/BII backbone conformations

Sugar-phosphate backbone conformations are an important structural element for a complete understanding of specific recognition in nucleic acid-protein interactions. They can be involved both in early stages of target discrimination and in structural adaptation upon binding. In the first part of this study, we have analyzed high-resolution structures of double-stranded B-DNA either isolated or bound to proteins, and explored the impact of both the standard BI and the unusual BII phosphate backbone conformations on neighboring sugar puckers and on selected helical parameters. Correlations are found to be similar for free and bound DNA, and in both categories, the possible facing backbone conformations (BI.BI, BI.BII, and BII.BII) define well-characterized substates in the B-DNA conformational space. Notably, BII.BII steps are characterized by specific, and sequence-independent, structural effects involving reduced standard deviations for almost all conformational parameters. In the second part of this work, we analyze four 10 ns molecular dynamics simulations in explicit solvent on the DNA targets of NF-kappaB and bovine papillomavirus E2 proteins, highlighting the multiplicity of backbone dynamical behavior. These results show sequence effects on the percentages of BI and BII conformers, the preferential state of facing backbones, the occurrence of coupled transitions. The backbone states can consequently be seen as a mechanism for transmitting information from the bases to the phosphate groups and thus for modulating the overall structural properties of the target DNA.     

M.TaqI facilitates the base flipping via an unusual DNA backbone conformation

MD simulations have been carried out to understand the dynamical behavior of the DNA substrate of the Thermus aquaticus DNA methyltransferase (M.TaqI) in the methylation process at N6 of adenine. As starting structures, an x-ray structure of M.TaqI in complex with DNA and cofactor analogue (PDB code: 1G 38) and free decamer d(GTTCGATGTC)(2) were taken. The x-ray structure shows two consecutive BII substates that are not observed in the free decamer. These consecutive BII substates are also observed during our simulation. Additionally, their facing backbones adopt the same conformations. These double facing BII substates are stable during the last 9 ns of the trajectories and result in a stretched DNA structure. On the other hand, protein-DNA contacts on 5' and 3' phosphodiester groups of the partner thymine of flipped adenine have changed. The sugar and phosphate parts of thymine have moved further into the empty space left by the flipping base without the influence of protein. Furthermore, readily high populated BII substates at the GpA step of palindromic tetrad TCGA rather than CpG step are observed in the free decamer. On the contrary, the BI substate at the GpA step is observed on the flipped adenine strand. A restrained MD simulation, reproducing the BI/BII pattern in the complex, demonstrated the influence of the unusual backbone conformation on the dynamical behavior of the target base. This finding along with the increased nearby interstrand phosphate distance is supportive to the N6-methylation mechanism.     

Sequence preference for BI/BII conformations in DNA: MD and crystal structure data analysis

Deciphering sequence information from sugar-phosphate backbone is finely tuned through the conformational substates of DNA. BII conformation, one of the conformational substates of B-DNA, is known to play a key role in DNA-protein recognition. BI and BII are identified by the epsilon-zeta difference, which is negative in BI and positive in BII. Our analysis of MD and crystal structures shows that BII conformation is sequence specific and dinucleotides GC, CG, CA, TG, TA show high preference to take up BII conformation, while TT, TC, CT, CC dinucleotides rarely take up this conformation. Significant changes were observed in the dinucleotide parameters viz. twist, roll, and slide for the steps having BII conformation. Interestingly, the magnitude of variation in the dinucleotide parameters is seen to depend mainly on two factors, the magnitude of epsilon-zeta difference and the presence or absence of BII conformation in the second strand, across the WC base-paired dinucleotide step. Based on these two factors, the conformational substate of a dinucleotide step can be further classified as BI.BI (BI conformation in both strands), BI.BII (BI conformation in one strand and BII conformation in the other), and BII.BII (BII conformation in both strands). The occurrence of BII in both strands was found to be quite rare and thus, it can be concluded that BI.BI and BI.BII hybrid steps are more favorable than a BII.BII step. In conformity with the sequence preference seen for dinucleotides in each strand, BII.BII combination of backbone conformation was observed only for GC, CG, CA, and TG containing dinucleotide steps. We further classified BII.BII step as strong BII and weak BII depending on the magnitude of the average epsilon-zeta difference. The dinucleotide steps which belong to the category of strong BII, have large twist, high positive slide and negative roll values, while those in the weak BII group have roll, twist, and slide values similar to that of hybrid BI.BII steps. This conformational property could be contributing to the groove opening/closing and thus can modulate protein-DNA interaction.     

Interaction specificity of violamycin BI and BII with DNA using the hyperchromic spectra method

Interaction specificity of the anthracycline antibiotics violamycin BI and violamycin BII in respect to A.T and G.C pairs was investigated. For comparison denaturation of complexes with A.T and G.C specific ligands distamycin A and actinomycin D are presented. Making use of the least squares hyperchromic spectra measured in the course of thermal denaturation were partitioned into the components corresponding to the melting of A.T and G.C base pairs and dissociation of ligand. The mutual dependence of AT and GC denaturation allows one to draw conclusions about specificity of interaction. In case of both violamycins only slight preference of interaction with AT-rich regions was detected. The dissociation of violamycin BII in the latest stage of thermal denaturation was found to be cooperative.     

Unexpected BII conformer substate population in unoriented hydrated films of the d(CGCGAATTCGCG)2 dodecamer and of native B-DNA from salmon testes.

Conformational substates of B-DNA had been observed so far in synthetic oligonucleotides but not in naturally occurring highly polymeric B-DNA. Our low-temperature experiments show that native B-DNA from salmon testes and the d(CGCGAATTCGCG)2 dodecamer have the same BI and BII substates. Nonequilibrium distribution of conformer population was generated by quenching hydrated unoriented films to 200 K, and isothermal structural relaxation toward equilibrium by interconversion of substates was followed by Fourier transform infrared spectroscopy. BI interconverts into BII on isothermal relaxation at 200 K, whereas on slow cooling from ambient temperature, BII interconverts into BI. Our estimation of the dodecamer's BI-to-BII conformer substate population by curve resolution of the symmetrical stretching vibration of the ionic phosphate is 2.4 +/- 0.5 to 1 at 200 K, and it is 1.3 +/- 0.5 to 1 between 270 and 290 K. Pronounced spectral changes upon BI-to-BII interconversion are consistent with base destacking coupled with migration of water from ionic phosphate toward the phosphodiester and sugar moieties. Nonspecific interaction of proteins with the DNA backbone could become specific by induced-fit-type interactions with either BI or BII backbone conformations. This suggests that the BI-to-BII substate interconversion could be a major contributor to the protein recognition process.     

Flexibility of the B-DNA backbone: effects of local and neighbouring sequences on pyrimidine-purine steps.

The structurally correlated dihedral angles epsilon and zeta are known for their large variability within the B-DNA backbone. We have used molecular modelling to study both energetic and mechanical features of these variations which can produce BI/BII transitions. Calculations were carried out on DNA oligomers containing either YpR or RpY dinucleotides steps within various sequence environments. The results indicate that CpA and CpG steps favour the BI/BII transition more than TpA or any RpY step. The stacking energy and its intra- and inter-strand components explain these effects. Analysis of neighbouring base pairs reveals that BI/BII transitions of CpG and CpA are easiest within (Y)n(R)n sequences. These can also induce a large vibrational amplitude for TpA steps within the BI conformation.     

BII nucleotides in the B and C forms of natural-sequence polymeric DNA: A new model for the C form of DNA

A combination of solid-state (31)P and (13)C NMR, X-ray diffraction, and model building is used to show that the B and C forms of fibrous macromolecular DNA consist of two distinct nucleotide conformations, which correspond closely to the BI and BII nucleotide conformations known from oligonucleotide crystals. The proportion of the BII conformation is higher in the C form than in the B form. We show structural models for a 10(1) double helix involving BI nucleotides and a 9(1) double helix involving BII nucleotides. The 10(1) BI model is similar to a previous model of B-form DNA, while the 9(1) BII model is novel. The BII model has a very deep and narrow minor groove, a shallow and wide major groove, and highly inclined bases. This work shows that the B to C transition in fibers corresponds to BI to BII conformational changes of the individual nucleotides.     

Isolation and characterization of DNA-dependent RNA polymerase A, B and C from rat brain nuclei

Abstract— DNA-dependent RNA polymerase activities were solubilized from the brain nuclei of young rats. Six forms of RNA polymerases were distinguished on DEAE-Sephadex A-25 chromatography and designated A, BI, BII, CI, CII, and Oil by their sensitivities to α-amanitin. CII enzyme was shown to derive from CIII enzyme by serine-protease digestion. CI enzyme was also suggested to be a product of a proteolytic process. Using a DNA template, enzyme A was completely resistant to α-amanitin; BI and BII enzymes were equally sensitive to this toxin (50% inhibition at 0.006 μg/ml); while C enzymes showed intermediate sensitivity (50% inhibition at 30 μg/ml). When poly[d(A-T)] was used as a template, α-amanitin sensitivities were altered in A, CI, CII, and CIII enzymes without any change in the BII enzyme. CI, CII and CIII enzymes were greatly stimulated by poly[d(A-T)], whereas A and BII enzymes were only slightly stimulated. All six forms of RNA polymerases were extensively characterized with respect to their ammonium sulphate optima, effects of divalent metal ions, template requirements and pH optima, using DNA and poly[d(A-T)] as templates. The results show new findings in several properties and supply basic data for discussion and future studies on RNA metabolism of the brain.     

Tricholongins BI and BII, 19-residue peptaibols from Trichoderma longibrachiatum. Solution structure from two-dimensional NMR spectroscopy

Two nonadecapeptides, tricholongins BI and BII, which display antifungal and antibacterial activities, have been isolated from in vitro cultures of the fungus Trichoderma longibrachiatum. The peptides were separated by reversed-phase HPLC; their amino acid compositions were determined by gas chromatography and their sequences by positive-ion fast-atom-bombardment mass spectrometry and high-field NMR. These linear peptides, containing mainly hydrophobic L-amino acids, 8-9 2-aminoisobutyric acid residues and exhibiting an acetylated N-terminal residue and an amino alcohol C-terminal leucinol belong to the peptaibol class. The methanol solution structure of tricholongins BI and BII has been investigated using both one- and two-dimensional NMR techniques. The total 1H-NMR and 13C-NMR assignments are given. By a combination of the 3JNH,C alpha H coupling constant values, temperature coefficients of the NH and CO groups, amide hydrogen/deuterium-exchange rate measurements and NOE data, a secondary structure for tricholongins in solution has been proposed. Both peptides adopt a similar alpha-helical conformation with a hinge around Pro13 resulting from two 3(10) bonds. The results suggest that the N-terminus contains mixed alpha/3(10) bonds. The membrane permeability modifications induced by tricholongins have been assayed by the use of liposomes composed of egg phosphatidylcholine with 20-30% cholesterol. The peptide-induced leakage of an entrapped fluorescent probe has been followed by fluorescence spectroscopy. In a concentration range of 0.13-0.31 microM, tricholongins induce the leakage of 50% of the entrapped material in 20 min.     

DNA-binding proteins in cells and membrane blebs of Neisseria gonorrhoeae.

Naturally elaborated membrane bleb fractions BI and BII of Neisseria gonorrhoeae contain both linear and circular DNAs. Because little is known about the interactions between DNA and blebs, studies were initiated to identify specific proteins that bind DNA in elaborated membrane blebs. Western immunoblots of whole-cell and bleb proteins from transformation-competent and DNA-uptake-deficient (dud) mutants were probed with single- or double-stranded gonococcal DNA, pBR322, or synthetic DNA oligomers containing intact or altered gonococcal transformation uptake sequences. The specificity and sensitivity of a nonradioactive DNA-binding protein assay was evaluated, and the assay was used to visualize DNA-protein complexes on the blots. The complexes were then characterized by molecular mass, DNA-binding specificity, and expression in bleb fractions. The assay effectively detected blotted DNA-binding proteins. At least 17 gonococcal DNA-binding proteins were identified; unique subsets occurred in BI and BII. Certain DNA-binding proteins had varied affinities for single- and double-stranded DNA, and the intact transformation uptake sequence competitively displaced the altered sequence from a BI protein at 11 kilodaltons (kDa). A dud mutant, strain FA660, lacked DNA-binding activity at the 11-kDa protein in BI. The segregation of DNA-binding proteins within BI and BII correlates with their distinct protein profiles and suggests that these vesicles may play different roles. Although the DNA-binding proteins expressed in BII may influence the nuclease-resistant export of plasmids within BII vesicles, the BI 11-kDa protein may bind transforming DNA.     

Determination of the structure of the main component of an antibiotic complex produced by Streptomyces griseolus 182]

In the programme for screening antibiotics with antifungal and immunosuppressing activity a culture of Streptomyces griseolus 182 was isolated. The culture produced a complex of oligomycin structure antibiotics. Individual components of the complex were isolated by HPLC. The complex was shown to contain three components at a ratio of 80:15:5. The findings were compared with the physico-chemical characteristics of the described antibiotics. On the basis of the analysis it was concluded that fraction 2 of the antibiotic complex 182 could be oligomycin A. A detailed comparative investigation of oligomycin A and component 2 with HPLC, FMR, IR spectroscopy and mass spectrometry revealed their identity. The other two components were shown to be oligomycins B and C.     

Viruses infecting a warm water picoeukaryote shed light on spatial co-occurrence dynamics of marine viruses and their hosts

The marine picoeukaryote Bathycoccus prasinos has been considered a cosmopolitan alga, although recent studies indicate two ecotypes exist, Clade BI (B. prasinos) and Clade BII. Viruses that infect Bathycoccus Clade BI are known (BpVs), but not that infect BII. We isolated three dsDNA prasinoviruses from the Sargasso Sea against Clade BII isolate RCC716. The BII-Vs do not infect BI, and two (BII-V2 and BII-V3) have larger genomes (~210 kb) than BI-Viruses and BII-V1. BII-Vs share ~90% of their proteins, and between 65% to 83% of their proteins with sequenced BpVs. Phylogenomic reconstructions and PolB analyses establish close-relatedness of BII-V2 and BII-V3, yet BII-V2 has 10-fold higher infectivity and induces greater mortality on host isolate RCC716. BII-V1 is more distant, has a shorter latent period, and infects both available BII isolates, RCC716 and RCC715, while BII-V2 and BII-V3 do not exhibit productive infection of the latter in our experiments. Global metagenome analyses show Clade BI and BII algal relative abundances correlate positively with their respective viruses. The distributions delineate BI/BpVs as occupying lower temperature mesotrophic and coastal systems, whereas BII/BII-Vs occupy warmer temperature, higher salinity ecosystems. Accordingly, with molecular diagnostic support, we name Clade BII Bathycoccus calidus sp. nov. and propose that molecular diversity within this new species likely connects to the differentiated host-virus dynamics observed in our time course experiments. Overall, the tightly linked biogeography of Bathycoccus host and virus clades observed herein supports species-level host specificity, with strain-level variations in infection parameters.Subject terms: Microbial biooceanography, Phylogenetics     

Chemical characteristics of the antibiotic, memomycin (LIA-0775)

By its physico-chemical and biological properties memomycin was classified as belonging to the group of hydrostatin-nifimycin. Memomycin contained ester (or lactone) and amide, 7 C-methyl and 10-12 acetylating groups. Oxidation of the antibiotic with an excess of alkaline permanganate solution revealed the presence of an unbroken chain consisting at least of 8 methylen groups in the carbon skeleton of memomycin. Acid hydrolysis revealed no sugars and ninhidrine-positive components. Memomycin differed from the antibiotics close to nifimycin mainly in the UV-spectra. It differed from hydrostatin, muzarine, rinamycin and azalomycin by a complete set of physico-chemical properties and biological spectrum. On the basis of these data memomycin may be considered an original antibiotic.     

Chiral phosphorothioate analogues of B-DNA. The crystal structure of Rp-d[Gp(S)CpGp(S)CpGp(S)C]

The compound Rp-d[Gp(S)CpGp(S)CpGp(S)C], an analogue of the deoxyoligomer d(G-C)3, crystallizes in space group P2(1)2(1)2(1) with a = 34.90 A, b = 39.15 A and c = 20.64 A. The structure, which is not isomorphous with any previously determined deoxyoligonucleotide, was refined to an R factor of 14.5% at a resolution of 2.17 A, with 72 solvent molecules located. The two strands of the asymmetric unit form a right-handed double helix, which is a new example of a B-DNA conformation and brings to light an important and overlooked component of flexibility of the double helix. This flexibility is manifest in the alternation of the backbone conformation between two states, defined by the adjacent torsion angles epsilon and zeta, trans . gauche-(BI) and gauche-. trans (BII). BI is characteristic of classical of B-DNA and has an average C(1') to C(1') separation of 4.5 A. The corresponding separation for BII is 5.3 A. Each state is associated with a distinct phosphate orientation where the plane of the PO2 (or POS) group is alternately near horizontal or vertical with respect to the helix axis. The BI and BII conformations are out of phase on the two strands. As a consequence, on one strand purine-pyrimidine stacking is better than pyrimidine-purine, while the converse holds for the other strand. At each base-pair step, good and bad stacking alternate across the helix axis. The pattern of alternation is regular in the context of a fundamental dinucleotide repeat. Re-examination of the B-DNA dodecamer d(C-G-C-G-A-A-T-T-C-G-C-G) shows that the C-G-C-G regions contain the BI and BII conformations, and the associated dual phosphate orientation and asymmetric base stacking. Different mechanisms are used in the two structures to avoid clashes between guanine residues on opposite strands, a combination of lateral slide, tilt and helical twist in the present structure, and base roll, tilt and longitudinal slide (Calladine rules) in the dodecamer. The flexibility of the phosphate orientations demonstrated in this structure is important, since it offers a structural basis for protein-nucleic acid recognition.     

Isolation of polypeptide chains with heme from the extracellular hemoglobin of Amphitrite ornata (Polychaeta, Annelida)

From the extracellular hemoglobin of Amphitrite ornata four constituent polypeptide chains containing heme and designated AI, AII, BI and BII according to the elution order were obtained by DE52-cellulose ion-exchange chromatography with dithiothreitol (DTT) as a reducing reagent. The NH2-terminal sequences for the chains are AI, Asp-Ser-Asn-Ala; AII, Glu-Tyr-Thr; BI, Asp-Phe-Asn-Thr; and BII, Asp-Ser-Glu. Each of the isolated chains showed spectra similar to those of vertebrate hemoglobins, and they bound oxygen reversibly. Acid urea polyacrylamide gel electrophoresis separated four bands, corresponding to the isolated chain, from the intact extracellular hemoglobin reduced with DTT. These results and our failure to detect an appreciable amount of non-heme protein suggest that the extracellular hemoglobin of A. ornata is composed of four polypeptide chains, each containing a heme.     

Daunomycin intercalation stabilizes distinct backbone conformations of DNA

Daunomycin is a widely used antibiotic of the anthracycline family. In the present study we reveal the structural properties and important intercalator-DNA interactions by means of molecular dynamics. As most of the X-ray structures of DNA-daunomycin intercalated complexes are short hexamers or octamers of DNA with two drug molecules per doublehelix we calculated a self complementary 14-mer oligodeoxyribonucleotide duplex d(CGCGCGATCGCGCG)2 in the B-form with two putative intercalation sites at the 5'-CGA-3' step on both strands. Consequently we are able to look at the structure of a 1:1 complex and exclude crystal packing effects normally encountered in most of the X-ray crystallographic studies conducted so far. We performed different 10 to 20 ns long molecular dynamics simulations of the uncomplexed DNA structure, the DNA-daunomycin complex and a 1:2 complex of DNA-daunomycin where the two intercalator molecules are stacked into the two opposing 5'-CGA-3' steps. Thereby--in contrast to X-ray structures--a comparison of a complex of only one with a complex of two intercalators per doublehelix is possible. The chromophore of daunomycin is intercalated between the 5'-CG-3' bases while the daunosamine sugar moiety is placed in the minor groove. We observe a flexibility of the dihedral angle at the glycosidic bond, leading to three different positions of the ammonium group responsible for important contacts in the minor groove. Furthermore a distinct pattern of BI and BII around the intercalation site is induced and stabilized. This indicates a transfer of changes in the DNA geometry caused by intercalation to the DNA backbone.