Defining the EM-signature of successful cell-transfection.

In this report, we describe the architecture of Lipofectamine 2000 and 3000 transfection- reagents, as they appear inside of transfected cells, using classical transmission electron microscopy (EM). We also demonstrate that they provoke consistent structural changes after they have entered cells, changes that not only provide new insights into the mechanism of action of these particular transfection-reagents, but also provide a convenient and robust method for identifying by EM which cells in any culture have been successfully transfected. This also provides clues to the mechanism(s) of their toxic effects, when they are applied in excess. We demonstrate that after being bulk-endocytosed by cells, the cationic spheroids of Lipofectamine remain intact throughout the entire time of culturing, but escape from their endosomes and penetrate directly into the cytoplasm of the cell. In so doing, they provoke a stereotypical recruitment and rearrangement of endoplasmic reticulum (ER), and they ultimately end up escaping into the cytoplasm and forming unique 'inclusion-bodies.' Once free in the cytoplasm, they also invariably develop dense and uniform coatings of cytoplasmic ribosomes on their surfaces, and finally, they become surrounded by 'annulate' lamellae' of the ER. In the end, these annulate-lamellar enclosures become the ultrastructural 'signatures' of these inclusion-bodies, and serve to positively and definitively identify all cells that have been effectively transfected. Importantly, these new EM-observations define several new and unique properties of these classical Lipofectamines, and allow them to be discriminated from other lipoidal or particulate transfection-reagents, which we find do not physically break out of endosomes or end up in inclusion bodies, and in fact, provoke absolutely none of these 'signature' cytoplasmic reactions.

Introducing a mammalian nerve-muscle preparation ideal for physiology and microscopy, the transverse auricular muscle in the ear of the mouse.

A new mammalian neuromuscular preparation is introduced for physiology and microscopy of all sorts: the intrinsic muscle of the mouse ear. The great utility of this preparation is demonstrated by illustrating how it has permitted us to develop a wholly new technique for staining muscle T-tubules, the critical conductive-elements in muscle. This involves sequential immersion in dilute solutions of osmium and ferrocyanide, then tannic acid, and then uranyl acetate, all of which totally blackens the T-tubules but leaves the muscle pale, thereby revealing that the T-tubules in mouse ear-muscles become severely distorted in several pathological conditions. These include certain mouse-models of muscular dystrophy (specifically, dysferlin-mutations), certain mutations of muscle cytoskeletal proteins (specifically, beta-tubulin mutations), and also in denervation-fibrillation, as observed in mouse ears maintained with in vitro tissue-culture conditions. These observations permit us to generate the hypothesis that T-tubules are the "Achilles' heel" in several adult-onset muscular dystrophies, due to their unique susceptibility to damage via muscle lattice-dislocations. These new observations strongly encourage further in-depth studies of ear-muscle architecture, in the many available mouse-models of various devastating human muscle-diseases. Finally, we demonstrate that the delicate and defined physical characteristics of this 'new' mammalian muscle are ideal for ultrastructural study, and thereby facilitate the imaging of synaptic vesicle membrane recycling in mammalian neuromuscular junctions, a topic that is critical to myasthenia gravis and related diseases, but which has, until now, completely eluded electron microscopic analysis. This article is part of a Special Issue entitled: Honoring Ricardo Miledi - outstanding neuroscientist of XX-XXI centuries.

A modified silver technique (de Olmos stain) for assessment of neuronal and axonal degeneration.

Silver impregnation histological techniques yield excellent visualization of degenerating neurons and their processes in animal models of neurological diseases. These methods also provide a particularly valuable complement to current immunocytochemical techniques for recognition of axon injury in the setting of brain or spinal cord trauma, ischemia, or neurodegenerative diseases. Despite their utility, silver methods are not commonly used because of complex preparation requirements and inconsistent results obtained by inexperienced histologists. This chapter details a modification of the de Olmos amino-cupric-silver protocol, which has been adapted for efficient processing of large numbers of mouse or rat brains. One author (T.I.T.) has used this method for several years to identify degenerating neurons in adult and neonatal rodent brains. A detailed protocol is provided, with attention to the most critical variables in tissue fixation and solution preparation. Examples are shown of axon injury in the rat brain after focal ischemia.

Potential of ketamine and midazolam, individually or in combination, to induce apoptotic neurodegeneration in the infant mouse brain.

Recently, it was reported that anesthetizing infant rats for 6 h with a combination of anesthetic drugs (midazolam, nitrous oxide, isoflurane) caused widespread apoptotic neurodegeneration in the developing brain, followed by lifelong cognitive deficits. It has also been reported that ketamine triggers neuroapoptosis in the infant rat brain if administered repeatedly over a period of 9 h. The question arises whether less extreme exposure to anesthetic drugs can also trigger neuroapoptosis in the developing brain. To address this question we administered ketamine, midazolam or ketamine plus midazolam subcutaneously at various doses to infant mice and evaluated the rate of neuroapoptosis in various brain regions following either saline or these various drug treatments. Each drug was administered as a single one-time injection in a dose range that would be considered subanesthetic, and the brains were evaluated by unbiased stereology methods 5 h following drug treatment. Neuroapoptosis was detected by immunohistochemical staining for activated caspase-3. It was found that either ketamine or midazolam caused a dose-dependent, statistically significant increase in the rate of neuroapoptosis, and the two drugs combined caused a greater increase than either drug alone. The apoptotic nature of the neurodegenerative reaction was confirmed by electron microscopy. We conclude that relatively mild exposure to ketamine, midazolam or a combination of these drugs can trigger apoptotic neurodegeneration in the developing mouse brain.

Apoptotic neurodegeneration induced by ethanol in neonatal mice is associated with profound learning/memory deficits in juveniles followed by progressive functional recovery in adults.

Administration of ethanol to rodents during the synaptogenesis period induces extensive apoptotic neurodegeneration in the developing brain. This neurotoxicity may explain the reduced brain mass and neurobehavioral disturbances in human Fetal Alcohol Syndrome (FAS). Here, we report binge-like exposure of infant mice to ethanol on a single postnatal day triggered apoptotic death of neurons from diencephalic structures that comprise an extended hippocampal circuit important for spatial learning and memory. The ethanol exposure paradigm yielding these neuronal losses caused profound impairments in spatial learning and memory at 1 month of age. This impairment was significantly attenuated during subsequent development, indicating recovery of function. Recovery was not associated with increased neurogenesis, suggesting plastic reorganization of neuronal networks compensated for early neuronal losses. We hypothesize that neuroapoptotic damage in homologous regions of human brain underlies cognitive deficits in FAS and the human brain of FAS victims has a similar capacity to effect functional recovery.

Excitotoxic versus apoptotic mechanisms of neuronal cell death in perinatal hypoxia/ischemia.

Hypoxic/ischemic (H/I) neuronal degeneration in the developing central nervous system (CNS) is mediated by an excitotoxic mechanism, and it has also been reported that an apoptosis mechanism is involved. However, there is much disagreement regarding how excitotoxic and apoptotic cell death processes relate to one another. Some authors believe that an excitotoxic stimulus directly triggers apoptotic cell death, but this interpretation is largely speculative at the present time. Our findings support the interpretation that excitotoxic and apoptotic neurodegeneration are two separate and distinct cell death processes that can be distinguished from one another by ultrastructural evaluation. Here we review evidence supporting this interpretation, including evidence that H/I in the developing CNS triggers two separate waves of neurodegeneration, the first being excitotoxic and the second being apoptotic. The first (excitotoxic) wave destroys neurons that would normally provide synaptic inputs or synaptic targets for the neurons that die in the second (apoptotic) wave. Since neurons, during the developmental period of synaptogenesis, are programmed to commit suicide if they fail to achieve normal connectivity, this explains why neuroapoptosis occurs following H/I in the developing CNS. However, it does not support the interpretation that H/I directly triggers apoptotic neurodegeneration. Rather, it documents that H/I directly triggers excitotoxic neurodegeneration, and apoptotic neurodegeneration ensues subsequently as the natural response of developing neurons to a specific kind of deprivation - loss of the ability to form normal synaptic connections.

Ethanol-induced apoptosis in the developing visual system during synaptogenesis.

PURPOSE: Ethanol is known to have deleterious effects on the human fetal nervous system (fetal alcohol syndrome), including components of the visual system, but only modest progress has been made in understanding these effects. The authors have recently demonstrated that, during the period of synaptogenesis, a single episode of ethanol intoxication lasting for several hours triggers a massive wave of apoptotic neurodegeneration in several regions of the developing rat or mouse forebrain. The present study was undertaken to determine to what extent the developing visual system is vulnerable to the apoptogenic effects of ethanol. METHODS: Infant rats and mice at ages from birth to 21 days were treated subcutaneously with a single dose of ethanol or with two doses, 2 hours apart, on a single day. Blood alcohol levels were determined, and the retinas and visual centers in the brain were examined by light and electronmicroscopy at various times from 4 to 24 hours after treatment. RESULTS: Retinal ganglion cells and neurons in the lateral geniculate nucleus, superior colliculus, and visual cortex were all highly susceptible to ethanol's apoptogenic action, the period of peak sensitivity being postnatal days 1 to 4 for ganglion cells and 4 to 7 for the other visual neurons. A transient elevation of blood alcohol to approximately 120 mg/dL was sufficient to activate the cell death program in visual neurons. CONCLUSIONS: During synaptogenesis, a single ethanol intoxication episode triggers apoptotic cell death of neurons at all levels of the visual system from retina to the visual cortex.

Ethanol-induced apoptotic neurodegeneration in the developing C57BL/6 mouse brain.

Recent studies have shown that administration of ethanol to infant rats during the synaptogenesis period (first 2 weeks after birth), triggers extensive apoptotic neurodegeneration throughout many regions of the developing brain. While synaptogenesis is largely a postnatal phenomenon in rats, it occurs prenatally (last trimester of pregnancy) in humans. Recent evidence strongly supports the interpretation that ethanol exerts its apoptogenic action by a dual mechanism--blockade of NMDA glutamate receptors and hyperactivation of GABA(A) receptors. These findings in immature rats represent a significant advance in the fetal alcohol research field, in that previous in vivo animal studies had not demonstrated an apoptogenic action of ethanol, had not documented ethanol-induced cell loss from more than a very few brain regions and had not provided penetrating insight into the mechanisms underlying ethanol's neurotoxic action. To add to the mechanistic insights recently gained, it would be desirable to examine gene-regulated aspects of ethanol-induced apoptotic neurodegeneration, using genetically altered strains of mice. The feasibility of such research must first be established by demonstrating that appropriate mouse strains are sensitive to this neurotoxic mechanism. In the present study, we demonstrate that mice of the C57BL/6 strain, a strain frequently used in transgenic and gene deletion research, are exquisitely sensitive to the mechanism by which ethanol induces apoptotic neurodegeneration during the synaptogenesis period of development.

Ethanol-induced caspase-3 activation in the in vivo developing mouse brain.

Recently several methods have been described for triggering extensive apoptotic neurodegeneration in the developing in vivo mammalian brain. These methods include treatment with drugs that block NMDA glutamate receptors, drugs that promote GABA(A) neurotransmission, or treatment with ethanol, which has both NMDA antagonist and GABAmimetic properties. A single intoxication episode induced by any of these agents is sufficient to cause widespread neurodegeneration throughout many brain regions. The cell death process transpires rapidly from early to late stages within several hours. As the neurons die, they become TUNEL positive and show, by both light and electron microscopy, all of the classical morphological characteristics of apoptosis. In the present study, using immunocytochemical methods, we document that ethanol intoxication of 7-day-old infant mice causes a widespread pattern of caspase-3 activation corresponding to the pattern of apoptotic neurodegeneration that is occurring simultaneously.