Structural appearance of linker histone H1/siRNA complexes

Efficient non-viral vectors for the in vivo siRNA transfer are still being searched for. Comparing the differences of the structural appearance of siRNA and pDNA one would assume differences in the assembling behaviour between these polyanions when using polycationic vectors such as nuclear proteins...

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Bibliographic Details
Published in:Molecular biology reports 2009-05, Vol.36 (5), p.1083-1093
Main Authors: Haberland, Annekathrin, Zaitsev, Sergei, Waldöfner, Norbert, Erdmann, Bettina, Böttger, Michael, Henke, Wolfgang
Format: Article
Language:English
Subjects:
Absorption
Animal Anatomy
Animal Biochemistry
Animals
Binding sites
Biomedical and Life Sciences
Cattle
DNA - metabolism
DNA - ultrastructure
Electron microscopy
Electrophoretic Mobility Shift Assay
Ethidium
Ethidium bromide
Expression vectors
Fluorescence
Gels
Genetic linkage
Histology
Histone H1
Histones - chemistry
Life Sciences
Light
Light scattering
Molecular biology
Morphology
Particle Size
Plasmids - metabolism
Plasmids - ultrastructure
Polyanions
polylysine
Polylysine - metabolism
Protein Binding
Protein Structure, Tertiary
Ribonucleic acid
RNA
RNA, Small Interfering - chemistry
RNA, Small Interfering - ultrastructure
Salts
Scattering, Radiation
Serum
siRNA
Ultracentrifugation
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Summary:Efficient non-viral vectors for the in vivo siRNA transfer are still being searched for. Comparing the differences of the structural appearance of siRNA and pDNA one would assume differences in the assembling behaviour between these polyanions when using polycationic vectors such as nuclear proteins. The spontaneous assembly of nuclear proteins such as histone H1 (H1) with pDNA as polyanion which has intensively been investigated over the last decade, showed a particulate structure of the resulting complexes. For an efficient in vivo use small almost monomolecular structures are searched for. Using siRNA as the polyanion might enforce this structural prerequisite lacking unwanted aggregation processes, exploiting the molecular size of siRNA. We therefore investigated the structure of H1/siRNA complexes. Five commonly used methods characterizing the resulting assemblies such as retardation gels, static and dynamic light scattering, reduction of ethidium bromide fluorescence, analytical ultracentrifugation, and electron microscopy were used. From analytical ultracentrifugation we learned that under physiological salt conditions the siRNA-H1 binding was not cooperative, even though the gel analysis showed disproportionation which would be an indication for a cooperative binding mode. H1 formed very small and stable complexes with siRNA at a molar ratio of 1:1 and 1:2. In order to find out if the observed structural appearance of the H1/siRNA complexes is due to unspecific charge effects only or to special features of H1, polylysine was included in the study. Low molecular weight polylysine (K₁₆) showed also non-cooperative binding with siRNA.
ISSN:0301-4851
1573-4978
DOI:10.1007/s11033-008-9282-8