Synthesis and biological evaluation of [18F]fluorovinpocetine, a potential PET radioligand for TSPO imaging.

Despite of various PET radioligands targeting the translocator protein TSPO 18-KDa are used for the investigations of neuroinflammatory conditions associated with neurological disorders, development of new TSPO radiotracers is still an active area of the researches with a major focus on the 18F-labelled radiotracers. Here, we report the radiochemical synthesis of [18F]vinpocetine, fluorinated analogue of previously reported TSPO radioligand, [11C]vinpocetine. Radiolabeling was achieved by [18F]fluoroethylation of apovincaminic acid with [18F]fluoroethyl bromide. [18F]vinpocetine was obtained in quantities >2.7 GBq in RCY of 13% (non-decay corrected), and molar activity >60 GBq/µmol within 95 min synthesis time. Preliminary PET studies in a cynomolgus monkey and metabolite studies by HPLC demonstrated similar results by [18F]vinpocetine as for [11C]vinpocetine, including high blood-brain barrier permeability, regional uptake pattern and fast washout from the NHP brain. These results demonstrate that [18F]fluorovinpocetine warrants further evaluation as an easier accessible alternative to [11C]vinpocetine.

Population dynamics of RNA viruses: the essential contribution of mutant spectra.

Cells and their viral and cellular parasites are genetically highly diverse, and their genomes contain signs of past and present variation and mobility. The great adaptive potential of viruses, conferred on them by high mutation rates and quasispecies dynamics, demands new strategies for viral disease prevention and control. This necessitates a more detailed knowledge of viral population structure and dynamics. Here we review studies with the important animal pathogen Foot-and-mouth disease virus (FMDV) that document modulating effects of the mutant spectra that compose viral populations. As a consequence of interactions within mutant spectra, enhanced mutagenesis may lead to viral extinction, and this is currently investigated as a new antiviral strategy, termed virus entry into error catastrophe.

Foot-and-mouth disease virus evolution: exploring pathways towards virus extinction.

Foot-and-mouth disease virus (FMDV) is genetically and phenotypically variable. As a typical RNA virus, FMDV follows a quasispecies dynamics, with the many biological implications of such a dynamics. Mutant spectra provide a reservoir of FMDV variants, and minority subpopulations may become dominant in response to environmental demands or as a result of statistical fluctuations in population size. Accumulation of mutations in the FMDV genome occurs upon subjecting viral populations to repeated bottleneck events and upon viral replication in the presence of mutagenic base or nucleoside analogs. During serial bottleneck passages, FMDV survive during extended rounds of replication maintaining low average relative fitness, despite linear accumulation of mutations in the consensus genomic sequence. The critical event is the occurrence of a low frequency of compensatory mutations. In contrast, upon replication in the presence of mutagens, the complexity of mutant spectra increases, apparently no compensatory mutations can express their fitness-enhancing potential, and the virus can cross an error threshold for maintenance of genetic information, resulting in virus extinction. Low relative fitness and low viral load favor FMDV extinction in cell culture. The comparison of the molecular basis of resistance to extinction upon bottleneck passage and extinction by enhanced mutagenesis is providing new insights in the understanding of quasispecies dynamics. Such a comparison is contributing to the development of new antiviral strategies based on the transition of viral replication into error catastrophe.

Variation in liposome binding among enteroviruses.

Liposome-binding properties of native virions and in vitro generated 135S particles of eight enteroviruses were studied. The temperature required for the structural transition from the native 160S virion to a 135S particle was virus-specific, ranging from +38 degrees C to more than +50 degrees C. While the 135S particles of poliovirus 1/Mahoney (PV1) and coxsackievirus A21 (CAV21) were capable of binding to liposomes, the other viruses showed minimal binding. Both of the viruses that bound to liposomes as 135S particles also bound as native virions. In addition, PV3/Sabin bound to liposomes as native virions but not as 135S particles, and the flotation patterns were different from those of PV1 and CAV21. The nonbinding viruses included coxsackieviruses A7, A9, A16, and B5, and enterovirus 68. The results follow the new classification of enteroviruses, as CAV21 is a member of the human enterovirus C species, which is genetically close to the poliovirus species.

Coxsackievirus A9 VP1 mutants with enhanced or hindered A particle formation and decreased infectivity.

We have studied coxsackievirus A9 (CAV9) mutants that each have a single amino acid substitution in the conserved 29-PALTAVETGHT-39 motif of VP1 and a reduced capacity to produce infectious progeny virus. After uncoating, all steps in the infection cycle occurred according to the same kinetics as and similar efficiency to the wild-type virus. However, the particle/infectious unit ratio in the progeny was significantly increased. The differences were apparently due to altered stability of the capsid: there were mutant viruses with enhanced or hindered uncoating, and both of these characteristics were found to reduce fitness under standard passaging conditions. At 32 degrees C the instable mutants had an advantage, while the wild-type and the most stable mutant grew poorly. When comparing the newly published CAV9 structure and the other enterovirus structures, we found that the PALTAVETGHT motif is always in exactly the same position, in a cavity formed by the 3 other capsid proteins, with the C terminus of VP4 between this motif and the RNA. In the 7 enterovirus structures determined to date, the most conserved residues of the studied motif have identical contacts to neighboring residues of VP2, VP3, and VP4. We conclude that (i) the mutations affect the uncoating step necessary for infection, resulting in an untimely or hindered externalization of the VP1 N terminus together with the VP4, and (ii) the reason for the studied motif being evolutionarily conserved is its role in maintaining an optimal balance between the protective stability and the functional flexibility of the capsid.

Effect of radiochemical purity of 99Tcm-Q12 on myocardial SPET image quality.

In myocardial perfusion SPET studies with 99Tcm-Q12, we observed that some patients had high liver uptake that interfered significantly in the assessment of the inferior wall. The aim of this study was to assess the effects of the radiochemical purity of 99Tcm-Q12 on liver uptake. Thirty-one patients undergoing routine myocardial infarction perfusion studies were evaluated. The radiochemical purity of 99Tcm-Q12 was determined using HPLC. Venous blood samples taken 50 min after injection of 99Tcm-Q12 during peak exercise were also analysed. Liver uptake was expressed as the liver-to-heart ratio. In addition, the SPET images were classified by two experienced nuclear medicine specialists into three groups representing high-quality images (n = 7), images with high general background activity (n = 13) and images with high liver and/or intestinal uptake (n = 11). The liver-to-heart ratio correlated inversely with the radiochemical purity of 99Tcm-Q12 (r = -0.65, P < 0.001) and unchanged 99Tcm-Q12 in plasma (r = -0.44, P < 0.02). The radiochemical purity of 99Tcm-Q12 was significantly lower in the group with high liver uptake (60.1 +/- 4.2%) than in the group with good-quality images (81.8 +/- 5.6%, P < 0.01) or with high background activity (82.3 +/- 2.5%, P < 0.01). In conclusion, the radiochemical purity of 99Tcm-Q12 has a significant inverse correlation with the liver-to-heart ratio; thus, the high radiochemical purity of 99Tcm-Q12 should be confirmed to prevent interference by liver uptake.

Modified base compositions at degenerate positions of a mutagenic oligonucleotide enhance randomness in site-saturation mutagenesis.

Site-saturation mutagenesis, using degenerate oligonucleotide primers, is a frequently used method in introducing various mutations in a selected target codon. Oligonucleotides that are synthesized using equimolar concentrations of nucleoside phosphoramidites (dA, dC, dG, dT) in the positions to be saturated, result in a mutant population that is biased towards the original nucleotides. We found that this bias could be eliminated by modifying the concentrations of nucleoside phosphoramidites during the oligonucleotide synthesis. We synthesized eight degenerate oligonucleotides to saturate eight different codons, and sequenced a total of 344 mutagenized codons. In six of these eight oligonucleotides, we reduced to varying extents the concentrations of those nucleotides in the target positions that would form base pairs with the template. From the data, we analyzed the effects of different base compositions in the oligonucleotides when mutagenizing different codons, the influence of the positions of mismatches, and the significance of different non-Watson-Crick base pairs. Based on these results, we suggest levels to which different phosphoramidites should be reduced when synthesizing oligonucleotides for site-saturation mutagenesis.

Selective cleavage by trypsin of the capsid protein VP1 of type 3 poliovirus results in improved sorting of cell bound virions.

A large proportion of host cell-bound virions of poliovirus type 1 strain Mahoney (PV1/M) is known to elute to the culture medium during incubation at 37 degrees C, and only a fraction of the virions remaining cell-associated will successfully uncoat and contribute to the new replication cycle. We found that while the proportion of inoculum type 3 poliovirus strain Saukett (PV3/S) bound to GMK cells was of the same order as that of PV1/M, the bound PV3/S virions uncoated much less efficiently, as judged by velocity sedimentation analysis of virion disintegration. Rather, the majority of the cell-associated PV3/S viruses remained apparently unaffected for several hours within an unidentified intracellular compartment. Incubation of PV3/S with intestinal trypsin is known to result in selective cleavage of the capsid protein VP1 and striking antigenic changes. Trypsin treatment of stock PV3/S preparations did not affect the infectivity titre or modify single-cycle progeny virus yields significantly. However, the fate of the cell-bound inoculum virus was profoundly altered. Trypsin-treated PV3/S virions (PV3/S-Try) attached to GMK cells less tightly than the untreated PV3/S virus or PV1/M, and a relatively larger proportion of the cell-bound virus eluted to the medium during subsequent incubation at 36 degrees C. However, the fraction of virions remaining cell-associated rapidly disintegrated suggesting efficient uncoating. In accordance with these observations, one step growth curves of PV3/S-Try in all cell lines tested showed lowered eclipse phase titres compared to those obtained with the untreated PV3/S inocula. Similar effects were also demonstrated for type 3 poliovirus strain Sabin while trypsin-sensitive strains of the other two serotypes of poliovirus remained unaffected in this sense. The putative biological significance of the altered sorting of cell-bound PV3/S-Try virions is not known. It might be related to the observations that sensitivity of type 3 poliovirus strains to trypsin is conserved in spite of the fact that the target site of trypsin action is flanked by highly variable motives in an immunodominant antigenic site.

UDP-galactose:lactosylceramide alpha-galactosyltransferase activity in human placenta.

The activity of UDP-Gal:LacCer galactosyltransferase in human placenta was studied by using crude homogenate and Triton CF-54 extract as the source of enzyme. Transfer of galactose to lactosylceramide was optimal in the presence of 0.1% Triton CF-54 and Mn2+ at pH 6.3, and the reaction product was susceptible to alpha-galactosidase.