Loss of tau elicits axonal degeneration in a mouse model of Alzheimer's disease.

A central issue in the pathogenesis of tauopathy is the question of how tau protein dysfunction leads to neurodegeneration. We have previously demonstrated that the absence of tau protein is associated with destabilization of microtubules and impaired neurite outgrowth (Dawson et al., 2001; Rapoport et al., 2002). We now hypothesize that the absence of functional tau protein may render the central nervous system more vulnerable to secondary insults such as the overexpression of mutated beta amyloid precursor protein (APP) and traumatic brain injury. We therefore crossed tau knockout mice (Dawson et al., 2001) to mice overexpressing a mutated human APP (APP(670,671), A(sw)) (Hsiao et al., 1996) and created a mouse model (A(sw)/mTau(-/-)) that provides evidence that the loss of tau function causes degeneration of neuronal processes. The overexpression of APP(670,671) in tau knockout mice, elicits the extensive formation of axonal spheroids. While spheroids are only found associated with Abeta plaques in mice expressing APP(670,671) on an endogenous mouse tau background (Irizarry et al., 1997), A(sw)/mTau(-/-) mice have spheroids not only surrounding Abeta plaques but also in white matter tracks and in the neuropil. Plaque associated and neuropil dystrophic neurites and spheroids are prominent features of Alzheimer's disease (Masliah et al., 1993; Terry, 1996; Stokin et al., 2005), and our current data suggests that loss of tau function may lead to neurodegeneration.

NO synthase 2 (NOS2) deletion promotes multiple pathologies in a mouse model of Alzheimer's disease.

Alzheimer's disease is characterized by two primary pathological features: amyloid plaques and neurofibrillary tangles. The interconnection between amyloid and tau aggregates is of intense interest, but mouse models have yet to reveal a direct interrelationship. We now show that NO may be a key factor that connects amyloid and tau pathologies. Genetic removal of NO synthase 2 in mice expressing mutated amyloid precursor protein results in pathological hyperphosphorylation of mouse tau, its redistribution to the somatodendritic compartment in cortical and hippocampal neurons, and aggregate formation. Lack of NO synthase 2 in the amyloid precursor protein Swedish mutant mouse increased insoluble beta-amyloid peptide levels, neuronal degeneration, caspase-3 activation, and tau cleavage, suggesting that NO acts at a junction point between beta-amyloid peptides, caspase activation, and tau aggregation.

Microtubule treadmilling in vitro investigated by fluorescence speckle and confocal microscopy.

Whether polarized treadmilling is an intrinsic property of microtubules assembled from pure tubulin has been controversial. We have tested this possibility by imaging the polymerization dynamics of individual microtubules in samples assembled to steady-state in vitro from porcine brain tubulin, using a 2% glycerol buffer to reduce dynamic instability. Fluorescence speckled microtubules were bound to the cover-glass surface by kinesin motors, and the assembly dynamics of plus and minus ends were recorded with a spinning-disk confocal fluorescence microscopy system. At steady-state assembly, 19% of the observed microtubules (n = 89) achieved treadmilling in a plus-to-minus direction, 34% in a minus-to-plus direction, 37% grew at both ends, and 10% just shortened. For the population of measured microtubules, the distribution of lengths remained unchanged while a 20% loss of original and 27% gain of new polymer occurred over the 20-min period of observation. The lack of polarity in the observed treadmilling indicates that stochastic differences in dynamic instability between plus and minus ends are responsible for polymer turnover at steady-state assembly, not unidirectional treadmilling. A Monte Carlo simulation of plus and minus end dynamics using measured dynamic instability parameters reproduces our experimental results and the amount of steady-state polymer turnover reported by previous biochemical assays.

The complex dynamic network of microtubule and microfilament cytasters of the leech zygote.

The organization of the cytoskeleton in the early first interphase zygote and its involvement in organelle redistribution were studied in the glossiphoniid leech Theromyzon trizonare by confocal and electron microscopy, immunofluorescence, and time-lapse video imaging after microinjection of labeled tubulin and/or actin and loading with a mitotracker. The cytoskeleton consists of an inner or endoplasmic and an outer or ectoplasmic domain. The inner domain consists of a monaster whose fibers retract from the zygote periphery by the end of the early first interphase. The outer domain is built upon a network of microtubules and microfilaments cytasters. Short pulses of microinjected labeled actin or tubulin and Taxol treatment demonstrate that cytasters are centers of microtubule and microfilament nucleation. Immunostaining with anti-centrophilin, anti-BX-63, and anti-AH-6 indicates that the network of cytasters includes centrosomal antigens. Cytasters move in an orderly fashion at speeds of 0.5-2 micrometer/min, in an energy-dependent process retarded and finally blocked by the ATP analogue AMP-PNP and high concentrations of Taxol. Colliding cytasters fuse and form larger cytoskeletal nucleation centers. The leech zygote is a highly compartmentalized cell whose cytasters function as articulated components of a very dynamic cytoskeletal system engaged in bulk transportation of organelles during ooplasmic segregation.

Formation of polar cytoplasmic domains (teloplasms) in the leech egg is a three-step segregation process.

Segregation and proliferation of mitochondria, leading to formation of the teloplasms (pole plasms), were studied in eggs of the leech T. rude by immunocytochemistry, fluorescent time lapse video imaging, confocal and electron microscopy. The translocation of mitochondria was analyzed after loading the egg with either Rhodamine 123 or a Mitotracker. Mitochondrial proliferation was assessed after pulse labeling with BrdU. The involvement of the cytoskeleton in the segregation process was determined by drug action. The teloplasms form during the first interphase as consequence of a 3-step sequential process of mitochondrial redistribution throughout the egg cytoplasm. The first step is a microtubule dependent process of ectoplasm thickening due to centrifugal mitochondrial transportation from the neighboring endoplasm. During the second step mitochondria move in the plane of the ectoplasm to become concentrated at the wall of rings (polar rings) and bands of contraction. This process appears to mostly depend on actin. The furrowing pattern of the egg during this step can be modified by cold treatment and seems to be determined during oogenesis. During the third step the ectoplasm flows to either of the poles in conjunction with bipolar displacement of the polar rings and shortening of the contraction bands. This step depends on both microtubules and microfilaments. Mitochondria of first interphase eggs have three special features: (1) they move in clusters, (2) their movement depends on both microtubules and microfilaments and (3) they proliferate continuously. During the first interphase the polarized meiotic egg becomes a bipolar cell.

Formation and localization of cytoplasmic domains in leech and ascidian zygotes.

Leech and ascidian embryos are well suited for the study of certain developmental processes. Although leeches and ascidians belong to different bilateralia groups (protostomes and deuterostomes, respectively) they share important developmental features and, in particular, the determinate character of their embryogenesis. In both types of embryos this property is related to the presence of specific cytoplasmic domains that are selectively allocated to different blastomeres during cleavage. In this review leech and ascidian eggs and zygotes are compared in terms of the structure of these cytoplasmic domains and of the cellular mechanisms involved in their formation and localization. During meiosis the zygote of leeches and ascidians undergo stereotypic actin-dependent contraction movements related to both the emission of the polar bodies and the formation and relocalization of cytoplasmic domains. After completion of meiosis, during first interphase, monaster microtubules nucleated from the sperm-derived centrosome play a key role in pronuclear migration. In addition, these astral microtubules direct the relocalization of cytoplasmic domains and the translocation and accumulation of organelles in the interior of the zygote. Microtubules and microfilaments, on the other hand, are involved in cortical reorganizations and organelle translocations in both zygote species during interphase and cleavage divisions. In the case of leech zygotes, this process leads to formation of characteristic polar cytoplasmic domains called teloplasms. These domains are selectively inherited by teloblasts, precursor stem cells of ectodermal and mesodermal tissues in the leech embryo. In the ascidian zygote, the cytoplasmic movements observed during interphase and mitosis lead to relocalization of the bulk of a mitochondria-rich domain, called the myoplasm, along with an endoplasmic reticulum-rich domain towards the future posterior pole of the embryo. The myoplasm is inherited by a subset of posterior blastomeres committed to become the primary muscle cells of the ascidian tadpole.

[Percutaneous mitral valvuloplasty in 6 patients]. / Valvuloplastía mitral percutanea en 6 pacientes.

We performed a percutaneous mitral balloon valvuloplasty in 6 patients with severe mitral stenosis, aged 21 to 50 years. The mitral valve gradient decreased from 14.7 +/- 4.9 to 6.3 +/- 4.0 mmHg, p = 0.03. Mitral valve area increased in 5 patients (0.92 +/- 0.23 to 2.32 +/- 0.26 cm2, p = 0.04). One patient developed a transient cerebral ischemic attack without sequelae and mild mitral insufficiency. The diameter of the mitral annulus as measured by echocardiography was 48.5 +/- 8.1 mm, significantly larger than that reported in other series. The curvature of the transseptal needle was selected after an echocardiographic view of the inferior vena cava and atria from the subcostal window. This allowed a successful procedure in all patients regardless of cavity size.