High-frequency transfer of cloned herpes simplex virus type 1 sequences to mammalian cells by protoplast fusion.

The protoplast fusion technique of Schaffner (W. Schaffner, Proc. Natl. Acad. Sci. U.S.A. 77:2163-2167, 1980) has been adapted to introduce cloned herpes simplex virus genes into cultured mammalian cells. The technique involves digesting bacterial cell walls with lysozyme to produce protoplasts and then fusing the protoplasts to mammalian cells by treatment with polyethylene glycol. For monitoring transfer, protoplasts were labeled with the fluorescent dye fluorescein isothiocyanate before fusion. After fusion, greater than 50% of the mammalian cells were fluorescent, demonstrating that bacterial material was transferred with high frequency. Transfer of plasmid pBR325 occurred at frequencies of 1 to 2%, as measured by in situ hybridization. Fusion transfer of a chimeric plasmid consisting of the herpes simplex virus type 1 (strain KOS) EcoRI fragment F in pBR325 resulted in expression of some viral genomic sequences in about 5% of the mammalian cells, as detected by indirect immunofluorescence. One Ltk- cell in 300 to 500 was transformed to the TK+ phenotype after fusion with protoplasts carrying the chimeric plasmid pX1, which consists of pBR322 and the BamHI fragment coding for the herpes simplex virus type 1 thymidine kinase gene.     

Detection of linkage for heterogeneous disorders by using multipoint linkage analysis.

We have compared the efficiency of the lod score test which assumes heterogeneity (lod2) to the standard lod score test which assumes homogeneity (lod1) when three-point linkage analysis is used in successive map intervals. If it is assumed that a gene located midway between two linked marker loci is responsible for a proportion of disease cases, then the lod1 test loses power relative to the lod2 test, as the proportion of linked families decreases, as the flanking markers are more closely linked, and as more map intervals are tested. Moreover, when multipoint analysis is used, linkage for a disease gene is more likely to be incorrectly excluded from a complete and dense linkage map if true genetic heterogeneity is ignored. We thus conclude that, in general, the lod2 linkage test is more efficient for detecting a true linkage when a complete genetic marker map is screened for a heterogeneous disorder.     

The regulation of growth in the mesonephric kidney of adult Xenopus laevis by an endogenous inhibitor of proliferation.

The effect of dorsal lymph sac implanted tissue fragments, of a 100,000g kidney supernatant, and of various kidney-derived ultrafiltrate fractions on the percentage of DNA synthesizing cells in the mesonephric kidney of Xenopus laevis following partial unilateral nephrectomy was investigated autoradiographically. Using Amicon filters with cut-off values of MW 50,000 and 10,000, three ultrafiltrate fractions were obtained: a fraction containing molecules of MW 50,000 and less, a fraction containing molecules of MW 10,000 and less, and one containing molecules in the range of MW 10,000 to 50,000. The ultrafiltrates containing molecules of less than 10,000 MW were found to depress DNA synthetic activity on the sixth postoperative day by 30 to 40%, while the fraction containing molecules between MW 10,000 and 50,000 showed no significant effect. It has been concluded that an endogenous inhibitor of proliferation, with the attributes of a chalone, is present in the fraction of less than 10,000 MW. The loss of inhibitor action following Pronase treatment of the ultrafiltrate suggests that the inhibitor substance may be a protein or polypeptide, or that such constituent may be the carrier for the active agent. Since a depression in DNA synthetic activity of 60% was obtained in normal adult mesonephric kidneys following the injection of the ultrafiltrate, it is concluded that both compensatory growth and reparative growth in the kidney of Xenopus laevis are regulated by a G₁ kidney chalone of less than 10,000 MW.     

DNA synthesis during larval development and compensatory growth in the mesonephros of Xenopus laevis.

Autoradiography following tritiated thymidine administration to Xenopus laevis tadpoles of stages 45–48 of larval development has revealed that, as the cells of the mesonephric kidney differentiate during organogenesis, there is a marked decrease in the percentage of cells synthesizing DNA (from 100% at stage 45 to less than 9% at stage 48). In the adult this figure is of the order of 0.1%. This reduced DNA synthetic activity was found to take place in the cells of both the proximal and distal tubules of the nephrons. Special mucous cells which serve as markers of distal tubules were not observed to synthesize DNA after the onset of their differentiation at stage 48 of larval development.Through the partial extirpation of tissue in one kidney of adult Xenopus laevis males, DNA synthesis was reactivated in differentiated cells. The increased DNA synthetic activity following partial unilateral nephrectomy was found to be maximal after 6 days of recovery when 19% of cells synthesize DNA. This increased DNA synthetic activity was found to occur only in the cells of the distal tubules, both mucous and nonmucous cells, while the cells of the proximal tubules did not respond to this reactivation.The apparent inability of proximal tubule cells to synthesize DNA following partial unilateral nephrectomy is discussed.     

Differential expression of interferon responsive genes in rodent models of transmissible spongiform encephalopathy disease

Background

Alzheimer's disease (AD) is characterized by a decline in cognitive function and accumulation of amyloid-β peptide (Aβ) in extracellular plaques. Mutations in amyloid precursor protein (APP) and presenilins alter APP metabolism resulting in accumulation of Aβ42, a peptide essential for the formation of amyloid deposits and proposed to initiate the cascade leading to AD. However, the role of Aβ40, the more prevalent Aβ peptide secreted by cells and a major component of cerebral Aβ deposits, is less clear. In this study, virally-mediated gene transfer was used to selectively increase hippocampal levels of human Aβ42 and Aβ40 in adult Wistar rats, allowing examination of the contribution of each to the cognitive deficits and pathology seen in AD.

Results

Adeno-associated viral (AAV) vectors encoding BRI-Aβ cDNAs were generated resulting in high-level hippocampal expression and secretion of the specific encoded Aβ peptide. As a comparison the effect of AAV-mediated overexpression of APPsw was also examined. Animals were tested for development of learning and memory deficits (open field, Morris water maze, passive avoidance, novel object recognition) three months after infusion of AAV. A range of impairments was found, with the most pronounced deficits observed in animals co-injected with both AAV-BRI-Aβ40 and AAV-BRI-Aβ42. Brain tissue was analyzed by ELISA and immunohistochemistry to quantify levels of detergent soluble and insoluble Aβ peptides. BRI-Aβ42 and the combination of BRI-Aβ40+42 overexpression resulted in elevated levels of detergent-insoluble Aβ. No significant increase in detergent-insoluble Aβ was seen in the rats expressing APPsw or BRI-Aβ40. No pathological features were noted in any rats, except the AAV-BRI-Aβ42 rats which showed focal, amorphous, Thioflavin-negative Aβ42 deposits.

Conclusion

The results show that AAV-mediated gene transfer is a valuable tool to model aspects of AD pathology in vivo, and demonstrate that whilst expression of Aβ42 alone is sufficient to initiate Aβ deposition, both Aβ40 and Aβ42 may contribute to cognitive deficits.     

Molecular basis of isoform-specific micro-conotoxin block of cardiac,skeletal muscle,and brain Na+ channels

mu-Conotoxins (mu-CTXs) block skeletal muscle Na(+) channels with an affinity 1-2 orders of magnitude higher than cardiac and brain Na(+) channels. Although a number of conserved pore residues are recognized as critical determinants of mu-CTX block, the molecular basis of isoform-specific toxin sensitivity remains unresolved. Sequence comparison of the domain II (DII) S5-S6 loops of rat skeletal muscle (mu1, Na(v)1.4), human heart (hh1, Na(v)1.5), and rat brain (rb1, Na(v)1.1) Na(+) channels reveals substantial divergence in their N-terminal S5-P linkers even though the P-S6 and C-terminal P segments are almost identical. We used Na(v)1.4 as the backbone and systematically converted these DII S5-P isoform variants to the corresponding residues in Na(v)1.1 and Na(v)1.5. The Na(v)1.4-->Na(v)1.5 variant substitutions V724R, C725S, A728S, D730S, and C731S (Na(v)1.4 numbering) reduced block of Na(v)1.4 by 4-, 86-, 12-, 185-, and 55-fold respectively, rendering the skeletal muscle isoform more "cardiac-like." Conversely, an Na(v)1.5--> Na(v)1.4 chimeric construct in which the Na(v)1.4 DII S5-P linker replaces the analogous segment in Na(v)1.5 showed enhanced mu-CTX block. However, these variant determinants are conserved between Na(v)1.1 and Na(v)1.4 and thus cannot explain their different sensitivities to mu-CTX. Comparison of their sequences reveals two variants at Na(v)1.4 positions 729 and 732: Ser and Asn in Na(v)1.4 compared with Thr and Lys in Na(v)1.1, respectively. The double mutation S729T/N732K rendered Na(v)1.4 more "brain-like" (30-fold downward arrow in block), and the converse mutation T925S/K928N in Na(v)1.1 reproduced the high affinity blocking phenotype of Na(v)1.4. We conclude that the DII S5-P linker, although lying outside the conventional ion-conducting pore, plays a prominent role in mu-CTX binding, thus shaping isoform-specific toxin sensitivity.     

Potentiation of rat brain sodium channel currents by PKA in Xenopus oocytes involves the I-II linker

Functional modulation of voltage-gated sodium channelsaffects the electrical excitability of neurons. Protein kinase A (PKA) can decrease sodium currents by phosphorylation at consensus sites inthe cytoplasmic I-II linker. Once the sites are phosphorylated, however, additional PKA activity can increase sodium currents by anunknown mechanism. When the PKA sites were eliminated by substitutionsof alanine for serine, peak sodium current amplitudes were increased by20-80% when PKA was activated in Xenopus oocytes eitherby stimulation of a coexpressed ₂-adrenergic receptor orby perfusion with reagents that increase cAMP. Potentiation requiredthe I-II linker of the brain channel, in that a chimeric channel inwhich the brain linker was replaced with the comparable linker from theskeletal muscle channel did not demonstrate potentiation. Using aseries of chimeric and deleted channels, we demonstrate thatpotentiation is not dependent on any single region of the linker andthat the extent of potentiation varies depending on the total lengthand the residues throughout the linker. These data are consistent withthe hypothesis that potentiation by PKA is an indirect processinvolving phosphorylation of an accessory protein that interacts withthe I-II linker of the sodium channel.