Mouse models of triplet repeat diseases

Triplet repeat expansions were first discovered in 1991 and since then have been found to be the mutation underlying a range of neurodegenerative, neuromuscular, and cognitive disorders including fragile X syndrome, myotonic dystrophy, Friedreich's ataxia, and the polyglutamine disorders that include Huntington's disease. The repeats exert their detrimental effects through different molecular mechanisms dependent on whether they are located in coding or noncoding regions of the gene in question. During the past 10 yr, a wide range of strategies have been used to successfully establish mouse models for all of these disorders. This review presents an overview of these mouse models, discusses the insights into the molecular pathogenesis of these disorders that have been gained from their analysis and the strategies that are being used to uncover novel therapeutic options.     

Ribonuclease activities in rat sympathetic ganglia: Evidence for the presence of an endogenous inhibitor of alkaline ribonuclease

Using³H-labeled rat brain mature RNA as substrate, substantial ribonuclease activity was detected in homogenates of rat superior cervical ganglia with acidic (pH 5.5) and neutral (pH 7.0-7.5) optima. Very little activity could be measured at greater than pH 8. The acidic and neutral activities differed in the optimal conditions required for assay, and showed differential sensitivity to the sulfhydryl blocking agent, N-ethylmaleimide. Only the neutral activity was stimulated, optimally by 2 mM N-ethylmaleimide, and the magnitude of stimulation indicated that the contributing ribonucleases exist largely in a latent form in the ganglion. Ribonucleases in other tissues with neutral pH dependence, known usually as alkaline ribonucleases, are subject to an N-ethylmaleimide-sensitive endogenous inhibitor protein. The existence of a similar inhibitor in rat superior cervical ganglia was indicated by the latency of neutral ribonuclease activity and confirmed by observing the effect of a soluble fraction from the ganglia on the activity of pancreatic ribonuclease A.     

Mapping DNA sequences in a human X-chromosome deletion which extends across the region of the Duchenne muscular dystrophy mutation.

A somatic cell hybrid has been constructed and characterized using fibroblasts from a phenotypically normal woman who possesses an X chromosome with an interstitial deletion of the short arm. High-resolution banding indicates that the deleted segment is either Xp22.13-p11.4 or Xp22.11-p11.23. Southern blot hybridization to previously mapped DNA sequences confirms that the missing segment of the X chromosome is a deletion and not an interstitial translocation and supports the cytogenetic interpretation that the deletion extends proximal of Xp11.3 and therefore probably comprises Xp22.11-p11.23. Three further DNA sequences have been localized to the region of the deleted segment. The following order has been assigned to the seven probes used: Xpter-RC8-pXUT22-(OA1,C7,M2C)-L1.28-RD6 -Xcen.     

Postwildfire seeding to restore native vegetation and limit exotic annuals: an evaluation in juniper‐dominated sagebrush steppe

Reestablishment of perennial vegetation is often needed after wildfires to limit exotic species and restore ecosystem services. However, there is a growing body of evidence that questions if seeding after wildfires increases perennial vegetation and reduces exotic plants. The concern that seeding may not meet restoration goals is even more prevalent when native perennial vegetation is seeded after fire. We evaluated vegetation cover and density responses to broadcast seeding native perennial grasses and mountain big sagebrush (Artemisia tridentata Nutt. spp. vaseyana [Rydb.] Beetle) after wildfires in the western United States in six juniper (Juniperus occidentalis ssp. occidentalis Hook)‐dominated mountain big sagebrush communities for 3 years postfire. Seeding native perennial species compared to not seeding increased perennial grass and sagebrush cover and density. Perennial grass cover was 4.3 times greater in seeded compared to nonseeded areas. Sagebrush cover averaged 24 and less than 0.1% in seeded and nonseeded areas at the conclusion of the study, respectively. Seeding perennial species reduced exotic annual grass and annual forb cover and density. Exotic annual grass cover was 8.6 times greater in nonseeded compared to seeded areas 3 years postfire. Exotic annual grass cover increased over time in nonseeded areas but decreased in seeded areas by the third‐year postfire. Seeded areas were perennial‐dominated and nonseeded areas were annual‐dominated at the end of the study. Establishing perennial vegetation may be critical after wildfires in juniper‐dominated sagebrush steppe to prevent the development of annual‐dominated communities. Postwildfire seeding increased perennial vegetation and reduced exotic plants and justifies its use.     

Metakaryotic stem cell nuclei use pangenomic dsRNA/DNA intermediates in genome replication and segregation

Bell shaped nuclei of metakaryotic cells double their DNA content during and after symmetric and asymmetric amitotic fissions rather than in the separate, pre-mitotic S-phase of eukaryotic cells. A parsimonious hypothesis was tested that the two anti-parallel strands of each chromatid DNA helix were first segregated as ssDNA-containing complexes into sister nuclei then copied to recreate a dsDNA genome. Metakaryotic nuclei that were treated during amitosis with RNase A and stained with acridine orange or fluorescent antibody to ssDNA revealed large amounts of ssDNA. Without RNase treatment metakaryotic nuclei in amitosis stained strongly with an antibody complex specific to dsRNA/DNA. Images of amitotic figures co-stained with dsRNA/DNA antibody and DAPI indicated that the entire interphase dsDNA genome (B-form helices) was transformed into two dsRNA/DNA genomes (A-form helices) that were segregated in the daughter cell nuclei then retransformed into dsDNA. As this process segregates DNA strands of opposite polarity in sister cells it hypothetically offers a sequential switching mechanism within the diverging stem cell lineages of development.     

Pulmonary Abnormalities in Animal Models Due to Niemann-Pick Type C1 (NPC1) or C2 (NPC2) Disease

Niemann-Pick C (NPC) disease is due to loss of NPC1 or NPC2 protein function that is required for unesterified cholesterol transport from the endosomal/lysosomal compartment. Though lung involvement is a recognized characteristic of Niemann-Pick type C disease, the pathological features are not well understood. We investigated components of the surfactant system in both NPC1 mutant mice and felines and in NPC2 mutant mice near the end of their expected life span. Histological analysis of the NPC mutant mice demonstrated thickened septae and foamy macrophages/leukocytes. At the level of electron microscopy, NPC1-mutant type II cells had uncharacteristically larger lamellar bodies (LB, mean area 2-fold larger), while NPC2-mutant cells had predominantly smaller lamellar bodies (mean area 50% of normal) than wild type. Bronchoalveolar lavage from NPC1 and NPC2 mutant mice had an approx. 4-fold and 2.5-fold enrichment in phospholipid, respectively, and an approx. 9-fold and 35-fold enrichment in cholesterol, consistent with alveolar lipidosis. Phospholipid and cholesterol also were elevated in type II cell LBs and lung tissue while phospholipid degradation was reduced. Enrichment of surfactant protein-A in the lung and surfactant of the mutant mice was found. Immunocytochemical results showed that cholesterol accumulated in the LBs of the type II cells isolated from the affected mice. Alveolar macrophages from the NPC1 and NPC2 mutant mice were enlarged compared to those from wild type mice and were enriched in phospholipid and cholesterol. Pulmonary features of NPC1 mutant felines reflected the disease described in NPC1 mutant mice. Thus, with the exception of lamellar body size, the lung phenotype seen in the NPC1 and NPC2 mutant mice were similar. The lack of NPC1 and NPC2 proteins resulted in a disruption of the type II cell surfactant system contributing to pulmonary abnormalities.     

Development of a muscle actin specified by maternal and zygotic mRNA in ascidian embryos

In this investigation, we characterize the embryonic and adult actins and describe the embryonic expression of a muscle actin in the ascidian Styela. Two-dimensional polyacrylamide gel electrophoresis showed that embryos, tadpole larvae, and adult organs contain three major and two minor isoforms of actin. Two of the major isoforms, which are present in the mantle, branchial sac, alimentary tract, and gonads of adults and in eggs, embryos, and heads and tails of tadpoles, are likely to be cytoplasmic actins. The third major isoform, which was enriched in the mantle and branchial sac of adults and localized primarily in the tails of tadpoles, is a muscle actin. The muscle actin isoform was not detected in eggs and early embryos. Radioactivity incorporation studies showed that the cytoplasmic actins were synthesized throughout early development, but muscle actin synthesis was first detected between the 16- and 64-cell stages, 2-3 hr after fertilization. Two lines of evidence indicate that embryonic muscle actin synthesis is directed in part by maternal mRNA. First, poly(A)+ RNA isolated from unfertilized eggs directed the synthesis of muscle actin in an mRNA-dependent reticulocyte lysate. Second, muscle actin was synthesized in anucleate egg fragments. Arguments are also presented that muscle actin synthesis is not directed exclusively by maternal mRNA. It is concluded that embryonic and adult Styela exhibit actin heterogeneity, that one of the actin isoforms is a muscle actin, and that the muscle actin is synthesized during embryogenesis under the direction of maternal and zygotic mRNA.     

Molecular dynamics exposes α-helices in myelin basic protein

Molecular dynamics simulations of models of unmodified and deiminated MBP (myelin basic protein) have been performed on solvated structures with added counterions, for 10 ns using AMBER (assisted model building with energy refinement). The protein structures became extended, and a considerable number of -helical segments formed spontaneously. The degree of molecular extension was greater in the deiminated species, and the -helices were more transient. These structural disruptions may be operative in vivo during multiple sclerosis.Figure A model of the C1 isoform of myelin basic protein showing major -helical segments that were stable over the last 1 ns of a molecular dynamics simulation. The -helices are colored red, the -strands are colored yellow, the -turns are colored blue, and random coils are colored green     

Asymmetric hybridization in Nicotiana by fusion of irradiated protoplasts

Summary Mesophyll protoplasts of a kanamycin-resistant, nopaline-positive Nicotiana plumbaginifolia seed line were inactivated by -irradiation and electrically fused with unirradiated mesophyll protoplasts of N. tabacum. Hybrids were selected on kanamycin and regenerated. Genetic material from N. plumbaginifolia was detected in these plants by the following criteria: (1) morphology, (2) esterase isozyme profiles, and (3) the presence of nopaline in leaf extracts. All of the plants regenerated were morphologically more similar to N. tabacum than to N. plumbaginifolia, and many were indistinguishable from N. tabacum. It was found that 37 plants displayed one or two esterases characteristic of N. plumbaginifolia in addition to a full set of esterases from N. tabacum. Based on their esterases, we have classified these plants as somatic hybrids. However, irradiation has clearly reduced the amount of N. plumbaginifolia genetic material that they retain; 24 plants were found that had only N. tabacum esterases but that produced nopaline and were kanamycin resistant. Genomic DNA from several of these plants was probed by Southern blotting for the presence of the authentic neomycin phosphotransferase gene (kanamycin-resistance gene) — all were found to contain the gene. These plants were classified as asymmetric hybrids. Finally, 25 plants were regenerated that were kanamycin sensitive, negative for nopaline, and contained only N. tabacum esterases. All of the regenerated plants, including this final category, were male sterile. As transferring the N. plumbaginifolia cytoplasm to an N. tabacum nuclear background results in an alloplasmic form of male sterility, all of the plants regenerated in this study appear to be cybrids irrespective of their nuclear constitution. Chromosome analysis of the asymmetric hybrids showed that most of them contained one more chromosome than is normal for N. tabacum. The somatic hybrids examined all had several additional chromosomes. Although male sterile, the asymmetric hybrids were female fertile to varying degrees and were successfully backcrossed with N. tabacum. Analysis of the resultant F₁ progeny indicated that the kanamycin-resistance gene from N. plumbaginifolia is partially unstable during meiosis, as would be expected for factors inherited on an unpaired chromosome.Abbreviations Km ^r kanamycin resistant - Km ^s kamacysin sensitive - Nop ⁺ nopaline positive - Nop ^– nopaline negative