Golgi body motility in the plant cell cortex correlates with actin cytoskeleton organization.

The actin cytoskeleton is involved in the transport and positioning of Golgi bodies, but the actin-based processes that determine the positioning and motility behavior of Golgi bodies are not well understood. In this work, we have studied the relationship between Golgi body motility behavior and actin organization in intercalary growing root epidermal cells during different developmental stages. We show that in these cells two distinct actin configurations are present, depending on the developmental stage. In small cells of the early root elongation zone, fine filamentous actin (F-actin) occupies the whole cell, including the cortex. In larger cells in the late elongation zone that have almost completed cell elongation, actin filament bundles are interspersed with areas containing this fine F-actin and areas without F-actin. Golgi bodies in areas with the fine F-actin exhibit a non-directional, wiggling type of motility. Golgi bodies in areas containing actin filament bundles move up to 7 µm s⁻¹. Since the motility of Golgi bodies changes when they enter an area with a different actin configuration, we conclude that the type of movement depends on the actin organization and not on the individual organelle. Our results show that the positioning of Golgi bodies depends on the local actin organization.

Molecular and cellular actions of galantamine: clinical implications for treatment of organophosphorus poisoning.

There have been continued efforts to develop effective antidotal therapies against poisoning with organophosphorus (OP) compounds, including nerve agents and pesticides. We reported recently that galantamine, a drug used to treat Alzheimer's disease, administered before (up to 3 h) or soon after (up to 5 min) an exposure of guinea pigs to 1.5-2 x LD50 soman or sarin effectively counteracted the acute toxicity and lethality of the nerve agents provided that the animals were also post-treated with atropine. Here, we demonstrate that administered to guinea pigs at 30 min before or up to 15 min after an acute challenge with 1 x LD50 soman, galantamine (8 mg/kg, intramuscular) alone is sufficient to counteract the lethality and acute toxicity of the nerve agent. Evidence is also provided that 100% survival can be attained when the association of appropriate doses of galantamine and atropine is administered 30-45 min after the challenge of the guinea pigs with 1 x LD50 soman. Galantamine counteracts the neurodegeneration and the changes in the nicotinic cholinergic system that result from an acute exposure of guinea pigs to 1 x LD50 soman. The results presented herein corroborate that galantamine is an effective antidote against OP poisoning.

Effectiveness of donepezil, rivastigmine, and (+/-)huperzine A in counteracting the acute toxicity of organophosphorus nerve agents: comparison with galantamine.

Galantamine, a centrally acting cholinesterase (ChE) inhibitor and a nicotinic allosteric potentiating ligand used to treat Alzheimer's disease, is an effective and safe antidote against poisoning with nerve agents, including soman. Here, the effectiveness of galantamine was compared with that of the centrally active ChE inhibitors donepezil, rivastigmine, and (+/-)huperzine A as a pre- and/or post-treatment to counteract the acute toxicity of soman. In the first set of experiments, male prepubertal guinea pigs were treated intramuscularly with one of the test drugs and 30 min later challenged with 1.5 x LD(50) soman (42 microg/kg s.c.). All animals that were pretreated with galantamine (6-8 mg/kg), 3 mg/kg donepezil, 6 mg/kg rivastigmine, or 0.3 mg/kg (+/-)huperzine A survived the soman challenge, provided that they were also post-treated with atropine (10 mg/kg i.m.). However, only galantamine was well tolerated. In subsequent experiments, the effectiveness of specific treatment regimens using 8 mg/kg galantamine, 3 mg/kg donepezil, 6 mg/kg rivastigmine, or 0.3 mg/kg (+/-)huperzine A was compared in guinea pigs challenged with soman. In the absence of atropine, only galantamine worked as an effective and safe pretreatment in animals challenged with 1.0 x LD(50) soman. Galantamine was also the only drug to afford significant protection when given to guinea pigs after 1.0 x LD(50) soman. Finally, all test drugs except galantamine reduced the survival of the animals when administered 1 or 3 h after the challenge with 0.6 or 0.7 x LD(50) soman. Thus, galantamine emerges as a superior antidotal therapy against the toxicity of soman.

A comparison of 60, 70, and 90 kDa stress protein expression in normal rat NRK-52 and human HK-2 kidney cell lines following in vitro exposure to arsenite and cadmium alone or in combination.

Arsenite and cadmium are two potent nephrotoxicants and common Superfund site elements. These elements are included among the stress protein inducers, but information regarding relationships between toxicity produced by combinations of these agents to the stress protein response is lacking. In this study, the immortalized cell lines normal rat kidney NRK-52E and human kidney HK-2 were exposed in vitro to arsenite (As(3+)), cadmium (Cd(2+)), or to equimolar As(3+) plus Cd(2+) mixture combinations for 3 and 5 h over a concentration range of 0.1-100 microM. After a 12-h recovery period, cultured cells were then evaluated for expression of the 60, 70, and 90 kDa major stress protein families. Results indicated that expression of stress proteins varied depending on the species of kidney cells exposed, the exposure concentrations, and the length of exposure to each element on an individual basis and for combined mixtures. For the HK-2 kidney cell line, increased levels of the 70 kDa stress protein was observed for single and combined element exposures whereas there was no change or a decrease of stress proteins 60 and 90 kDa. Increased 70 kDa expression was observed for 10-microM doses of single elements and for a lower dose of 1 microM of the As plus Cd mixture at 3- and 5-h exposures. NRK-52 kidney cells exposed to equivalent doses of As(3+) and Cd(2+) alone or in combination showed increased levels of all stress proteins 60, 70, and 90 kDa. This increase was seen for 10 microM of the As plus Cd mixture at 3 h whereas for single element exposures, increased stress protein levels were generally observed for the 100-microM doses. At 5 h- exposure, 60 and 90 kDa levels increased for 10 microM of Cd(2+) and 60 kDa levels increased for 1 microM of As(3+). However, exposures to 10 microM of the As plus Cd mixture decreased 60 kDa protein expression to control levels at 5 h. For both kidney cell lines, there was a decrease in the stress protein expression levels for all three stress protein families for 100-microM doses of the mixture combination for 3- and 5-h exposures. These data indicate a dose- and combination-related correlation between depression of the stress protein response and the onset of overt cellular toxicity and/or cell death. The threshold for these changes was cell line specific.