Phosphorylation of fibrinogen by casein kinase 1

Casein kinase 1 phosphorylated human fibrinogen, in a reaction that did not use GTP as phosphoryl donor and was neither stimulated by cyclic AMP or Ca2+, nor inhibited by the cyclic AMP-dependent protein kinase inhibitor protein. Maximal incorporation averaged 4 mol of phosphate per mol of fibrinogen, most of it in the largest CNBr-fragment of the alpha-chain. Phosphoamino acid analysis revealed that phosphorylation occurred only at seryl residues. The phosphorylation of fibrinogen by casein kinase 1 was reverted by alkaline phosphatase.     

Contrasting levels of genetic diversity between the common, self-compatible Liparis kumokiri and rare, self-incompatible Liparis makinoana (Orchidaceae) in South Korea

Levels of allozyme variation and intrapopulation spatial genetic structure of the two terrestrial clonal orchids Liparis kumokiri , a self-compatible relatively common species, and L. makinoana , a self-incompatible rare species, were examined for 17 ( N  = 1875) and four ( N  = 425) populations, respectively, in South Korea. Populations of L. makinoana harboured high levels of genetic variation ( H _e = 0.319) across 15 loci. In contrast, L. kumokiri exhibited a complete lack of allozyme variation ( H _e = 0.000). Considering the lack of genetic variability, it is suggested that current populations of L. kumokiri in South Korea originated from a genetically depauperate ancestral population. For L. makinoana , a significant deficit of heterozygosity (mean F _IS = 0.198) was found in population samples excluding clonal ramets, suggesting that pollen dispersal is localized, generating biparental inbreeding. The significant fine-scale genetic structuring (≤ 2 m) found in a previous study, in addition to the moderate levels of population differentiation ( F _ST = 0.107) and the significant relationship between genetic and geographical distances ( r  = 0.680) found here, suggests a leptokurtic distribution of seed dispersal for L. makinoana . Although populations of L. makinoana harbour high levels of genetic variation, they are affected by a recent genetic bottleneck. This information suggests that genetic drift and limited gene flow could be the main evolutionary forces for speciation of a species-rich genus such as Liparis .  © 2007 The Linnean Society of London, Botanical Journal of the Linnean Society , 2007, 153 , 41–48.     

A quantitative analysis of the effect of nucleotides and the M domain on the association equilibrium of ClpB

ClpB is a hexameric molecular chaperone that, together with the DnaK system, has the ability to disaggregate stress-denatured proteins. The hexamer is a highly dynamic complex, able to reshuffle subunits. To further characterize the biological implications of the ClpB oligomerization state, the association equilibrium of the wild-type (wt) protein and of two deletion mutants, which lack part or the whole M domain, was quantitatively analyzed under different experimental conditions, using several biophysical [analytical ultracentrifugation, composition-gradient (CG) static light scattering, and circular dichroism] and biochemical (ATPase and chaperone activity) methods. We have found that (i) ClpB self-associates from monomers to form hexamers and higher-order oligomers that have been tentatively assigned to dodecamers, (ii) oligomer dissociation is not accompanied by modifications of the protein secondary structure, (iii) the M domain is engaged in intersubunit interactions that stabilize the protein hexamer, and (iv) the nucleotide-induced rearrangement of ClpB affects the protein oligomeric core, in addition to the proposed radial extension of the M domain. The difference in the stability of the ATP- and ADP-bound states [ΔΔG(ATP-ADP) = -10 kJ/mol] might explain how nucleotide exchange promotes the conformational change of the protein particle that drives its functional cycle.     

Co‐operational PCR Coupled with Dot Blot Hybridization for the Detection of Phaeomoniella chlamydospora on Infected Grapevine Wood

The technique consisting of the co‐operational PCR coupled with dot blot hybridization and posterior colorimetric visualization was developed for the detection of Phaeomoniella chlamydospora, one of the major pathogenic fungi involved in the Petri disease of grapevine. A partial region of the fungal rDNA including the internal transcribed spacer (ITS) region was amplified through co‐operational PCR for P. chlamydospora and 17 additional grapevine‐associated fungi included in the genera Botryosphaeria, Cryptovalsa, Cylindrocarpon, Dematophora, Diplodia, Dothiorella, Eutypa, Fomitiporia, Lasiodiplodia, Neofusicoccum, Phaeoacremonium, Phomopsis and Stereum, by using the primer pairs NSA3/NLC2 (external pair) and NSI1/NLB4 (inner pair). A specific probe (Pch2D) targeting the ITS2 region in the rDNA was developed for the detection of P. chlamydospora. Dot blot hybridizations carried out with the PCR products showed the specificity of the probe. Results indicated that Pch2D only hybridized with DNA amplicons of P. chlamydospora isolates, thus proving the specific detection of this fungus, while the 17 remaining species tested for the Pch2D probe resulted in negative results. Sensitivity of the technique was established below 0.1 pg of genomic DNA. This technique was further validated using artificially inoculated grapevine cuttings with P. chlamydospora. The efficacy of detection was established at 80% after two independent blind assays.     

Effects of dimethylsulfoxide on the ultrastructure of fixed cells

It has been reported that the use of dimethylsulfoxide (DMSO) as a solvent for fixatives enhances preservation of cellular ultrastructure. By contrast, we have shown that DMSO alters the ultrastructural integrity of glutaraldehyde fixed cells. The cell membrane, nuclear envelope, endoplasmic reticulum, ribosomes, microtubules and intracytoplasmic organelles are most susceptible to the action of DMSO. We hypothesize that DMSO exerts intracellular alterations via its interaction with remnant interfacial water in fixed cells. DMSO-induced alterations of these and related cellular components may result in the formation of artefactual structures and networks. Thus, it appears that DMSO containing glutaraldehyde neither accelerates fixation nor enhances stabilization of cellular ultrastructure. For these reasons, addition of DMSO to fixatives is not recommended.     

Binding to protein surfaces by supramolecular multivalent scaffolds

Multivalency plays a pivotal role in biological recognition, particularly at protein-protein and protein-carbohydrate interaction sites. Scaffolds of diverse structure, flexibility, and valency are gaining increasing biomedical importance in the development of artificial multivalent ligands for these interfaces. Relevant examples range from small C(4) symmetric calix[4]arenes and porphyrin ligands, which may achieve nanomolar affinity for protein surfaces of pharmaceutical interest, to large-sized dendrimers that provide promising adherence-inhibition for toxins and other relevant lectins. In addition, highly flexible supramolecular platforms like rotaxanes and polymers have been proposed as challenging alternatives to more rigid designs. Finally, nanoparticles are being exploited for this aim as they present important advantages from the biological and synthetic points of view.