Effects of clinorotation and microgravity on sweet clover columella cells treated with cytochalasin D

The cytoskeleton of columella cells is believed to be involved in maintaining the developmental polarity of cells observed as a reproducible positioning of cellular organelles. It is also implicated in the transduction of gravitropic signals. Roots of sweet clover ( Melilotus alba L.) seedlings were treated with a microfilament disrupter, cytochalasin D, on a slowly rotating horizontal clinostat (2 rpm). Electron micrographs of treated columella cells revealed several ultrastructural effects including repositioning of the nucleus and the amyloplasts and the formation of endoplasmic reticulum (ER) whorls. However, experiments performed during fast clinorotation (55 rpm) showed an accumulation (but no whorling) of a disorganized ER network at the proximal and distal pole and a random distribution of the amyloplasts. Therefore, formation of whorls depends upon the speed of clinorotation, and the overall impact of cytochalasin D suggests the necessity of microfilaments in organelle positioning. Interestingly, a similar drug treatment performed in microgravity aboard the US Space Shuttle Endeavour (STS-54, January 1993) caused a displacement of ER membranes and amyloplasts away from the distal plasma membrane. In the present study, we discuss the role of microfilaments in maintaining columella cell polarity and the utility of clinostats to simulate microgravity.     

Cortical microtubules in sweet clover columella cells developed in microgravity

Electron micrographs of columella cells from sweet clover seedlings grown and fixed in microgravity revealed longitudinal and cross sectioned cortical microtubules. This is the first report demonstrating the presence and stability of this network in plants in microgravity.     

An AU-rich element in the 3' untranslated region of the spinach chloroplast petD gene participates in sequence-specific RNA-protein complex formation.

In chloroplasts, the 3' untranslated regions of most mRNAs contain a stem-loop-forming inverted repeat (IR) sequence that is required for mRNA stability and correct 3'-end formation. The IR regions of several mRNAs are also known to bind chloroplast proteins, as judged from in vitro gel mobility shift and UV cross-linking assays, and these RNA-protein interactions may be involved in the regulation of chloroplast mRNA processing and/or stability. Here we describe in detail the RNA and protein components that are involved in 3' IR-containing RNA (3' IR-RNA)-protein complex formation for the spinach chloroplast petD gene, which encodes subunit IV of the cytochrome b6/f complex. We show that the complex contains 55-, 41-, and 29-kDa RNA-binding proteins (ribonucleoproteins [RNPs]). These proteins together protect a 90-nucleotide segment of RNA from RNase T1 digestion; this RNA contains the IR and downstream flanking sequences. Competition experiments using 3' IR-RNAs from the psbA or rbcL gene demonstrate that the RNPs have a strong specificity for the petD sequence. Site-directed mutagenesis was carried out to define the RNA sequence elements required for complex formation. These studies identified an 8-nucleotide AU-rich sequence downstream of the IR; mutations within this sequence had moderate to severe effects on RNA-protein complex formation. Although other similar sequences are present in the petD 3' untranslated region, only a single copy, which we have termed box II, appears to be essential for in vitro protein binding. In addition, the IR itself is necessary for optimal complex formation. These two sequence elements together with an RNP complex may direct correct 3'-end processing and/or influence the stability of petD mRNA in chloroplasts.     

Interferon-γ exerts its negative regulatory effect primarily on the earliest stages of murine erythroid progenitor cell development

Interferon-γ (INFγ) has been shown to suppress erythropoiesis and perhaps to contribute to the anemia of chronic disease. In this study we demonstrated that the concentration of INFγ required to suppress murine burst forming unit-erythroid (BFU-E) growth was significantly less than that required to suppress colony forming unit-erythroid (CFU-E) growth. INFγ acted at the most primitive step in erythroid progenitor cell differentiation and proliferation, as inhibition was maximal when added at the time of BFU-E culture initiation. Inhibition was progressively less if INF-γ addition was delayed after culture initiation. The effects of INFγ on BFU-E did not require the presence of interleukin-1α (IL-1α), tumor necrosis factor-α (TNFα), or granulocyte macrophage colony stimulating factor (GM-CSF), as its effects were not neutralized by monoclonal antibodies against IL-1α, TNFα, or GM-CSF. This applied whether INFγ was added to culture with individual antibodies or with a combination of all three antibodies. INFγ was not required for IL-1α- or TNFα-induced suppression of BFU-E, as their effects were not neutralized by a monoclonal anti-INFγ antibody. In contrast, GM-CSF—induced suppression of BFU-E was negated by the simultaneous addition of anti-INFγ. We have previously shown that the addition of TNFα does not suppress BFU-E growth in cultures from marrow depleted of macrophages. Suppression did occur, however, if a small concentration of INFγ that does not inhibit and increasing concentrations of TNFα were added to culture, suggesting a synergistic effect between INFγ and TNFα. These observations suggest that INFγ is a potent direct inhibitor of erythroid colony growth in vitro. It exerts its negative regulatory effect primarily on the earliest stages of erythroid progenitor cell differentiation and proliferation, as much higher doses are required to suppress late erythroid cell development. INFγ is also involved in GM-CSF—induced inhibition of BFU-E colony growth. © 1995 Wiley-Liss, Inc.

1 This artilce is a US Government work and, as such, is in the public domain in the United States of America.

     

Regression of hypoxic hypertension-induced changes in the elastic laminae of rat pulmonary arteries

Liu, S. Q. Regression of hypoxic hypertension-inducedchanges in the elastic laminae of rat pulmonary arteries.J. Appl. Physiol. 82(5):1677-1684, 1997.The elastic laminae of the pulmonary arteries(PAs) undergo a progressive structural change in hypoxic hypertension.This study focused on the reversibility of altered PA elastic laminaeof the rat due to hypoxic hypertension. The structure andcross-sectional area of the PA medial elastic laminae were examined byusing electron-microscopic and image-analytic approaches duringrecovery from 12 h and 10 days of hypoxic hypertension. At 12 h ofhypoxic hypertension, the elastic laminae, which appeared homogeneousin normal control animals, were reorganized into structures composed ofrandomly oriented filaments, with an increase in the cross-sectionalarea of 70%. At 10 days of hypoxic hypertension, the elastic laminaeappeared homogeneous in structure and normal in cross-sectional areadespite continuous exposure to hypoxia. During recovery from 12 h ofhypoxic hypertension, the medial elastic laminae regained theirhomogeneous structure and normal cross-sectional area afterday 2. During recovery from 10 days ofhypoxic hypertension, the medial elastic laminae changed from homogeneous to filamentous structures, with a progressively altered cross-sectional area that increased by 89% from recoveryday 0 to day10 and returned to the normal level onday 30. These changes were associatedwith alterations in the PA wall tensile stress. These results indicatedthat structural changes in the PA elastic laminae were reversible andthat the regression process depended on the duration of exposure tohypoxia, the state of the elastic laminae, and possibly the tensilestress level in the PA wall.

     

An increase in nitric oxide produced by rat peritoneal neutrophils is not involved in cell apoptosis

Polymorphonuclear neutrophils (PMN) obtained from carrageenin-stimulated peritoneal cavities of rats, but not blood PMN, spontaneously produced nitric oxide (NO) when incubated in vitro. Incubation of the cells with the NO synthase inhibitors, L-imino-ethyl-L-ornithine (L-NIO) or N(G)-monomethyl-L-arginine (L-NMMA), inhibited NO production. This inhibition could be reversed by L-arginine. Incubation of PMN with lipopolysaccharide (LPS) failed to enhance NO production. Pretreatment of the rats with dexamethasone (DEXA) prior to carrageenin injection or incubation of PMN with the glucocorticoid in vitro partially inhibited the spontaneous release of NO. On the other hand, when PMN obtained from DEXA pretreated rats were incubated in vitro with DEXA, NO synthase activity and hence NO generation were almost abolished. A similar inhibition was also observed following the addition of L-NIO or cycloheximide to cultures of carrageenin-elicited PMN. The NO production by PMN did not appear to be related to cell viability or apoptosis. Indeed, neither the blockade of NO generation by L-NIO nor the incubation of the neutrophils with a NO donor, S-nitroso-acetylpenicillamine (SNAP) modified the pattern of LDH release or DNA fragmentation. In summary, it appears that PMN migration triggers a continuous NO synthesis, and that NO produced by these cells is not related to their apoptosis.     

Synthesis and degradation of aflatoxins by Aspergillus parasiticus. II. Comparative toxicity and mutagenicity of aflatoxin B1 and its autolytic breakdown products

A crude mycelial protein extract from a 16-day-old culture of A. parasiticus, on purification, lost 50% of its ability to degrade aflatoxin B1. The addition of hydrogen peroxide increased this activity to 97% of that of the crude extract. Ducklings dosed orally with aflatoxin extracts from 14- and 20-day-old cultures containing 46 micrograms or more of aflatoxin B1 developed enlarged livers, haemorrhaged and died in less than 10 days, giving and LD50 of 17.5 and 17.1 micrograms aflatoxin B1 per 50 g body weight respectively for each extract. When pure aflatoxin B1 was mixed with either the crude or purified mycelial protein extract the aflatoxin B1 level was decreased by 29% as was the toxicity of the mixture. The main breakdown product of aflatoxin B1 was isolated and was shown to have an RF value of 0.34, was non-fluorescent, and was non-toxic for ducklings at oral doses as high as 400 micrograms per 50 g body weight. The mutagenic effect of aflatoxin B1 on Salmonella typhimurium was relative to its concentration. The main breakdown product of aflatoxin B1 was non-mutagenic.