Protein kinases and multidrug resistance

The role of protein kinases in the multidrug resistance phenotype of cancer cell lines is discussed with an emphasis on protein kinase C and protein kinase A. Evidence that P-glycoprotein is phosphorylated by these kinases is summarised and the relationship between P-glycoprotein phosphorylation and the multidrug-resistant phenotype discussed. Results showing that protein kinase C, particularly the alpha subspecies, is overexpressed in many MDR cell lines are described: this common but by no means universal finding seems to be drug- and cell line-dependent and in only in a few cases is there a direct correlation between protein kinase C activity and multidrug resistance. From co-immunoprecipitation results it is suggested that P-glycoprotein is a specific protein kinase C receptor, as well as being a substrate. Revertant experiments provide conflicting results as to a direct relationship between expression of P-glycoprotein and protein kinase C. Evidence that protein kinase A influences P-glycoprotein expression at the gene level is well documented and the mechanisms by which this occurs are becoming clarified. Results on the relationship between protein kinase C and multidrug resistance using many inhibitors and phorbol esters are difficult to interpret because such compounds bind to P-glycoprotein. In spite of huge effort, a direct involvement of protein kinase C in regulating multidrug resistance has not yet been firmly established. However, evidence that PKC regulates a Pgp-independent mechanism of drug resistance is accumulating. This revised version was published online in August 2006 with corrections to the Cover Date.     

Alternative and cytochrome pathway respiration during shoot bud formation in cultured Pinus radiata cotyledons

Respiration rates for excised cotyledons of Pinus radiata cultured in the presence (shoot-forming) and absence (non-shoot-forming) of N⁶-benzyladenine (BA) over a 21-day period were measured using a Clark-type oxygen electrode. The capacities and activities of cytochrome and alternative pathways of respiration were determined from titrations with KCN (1-10 m M ) and salicylhydroxamic acid (2–20 m M ) individually and in combination. Respiration accounted for by alternative (AP) and cytochrome (CP) pathways varied with both culture treatment and age in culture. Rates of total respiration, CP respiration and AP activity rose concurrent with key developmental events of shoot bud formation. The greatest AP capacity was measured at day 3 in shoot-forming tissue. In contrast, for cotyledons cultured under non-shoot-forming conditions, no AP activity was observed after day 3 despite relatively constant AP capacity throughout the culture period. Although initial increases in cotyledon respiration during the culture period may be related to wounding and introduction to a tissue culture environment, later differences in respiratory patterns between shoot-forming and non-shoot-forming cotyledons appear to be associated with the cytokinin-induced developmental changes which give rise to shoot primordia in cultured radiata pine cotyledons.     

The effect of the gaseous state on bud induction and shoot multiplication in vitro in eastern white cedar

The effect of vessel type and the gaseous phase on the morphogenic response of Thuja occidentalis L. explants in vitro was studied. Explants were cultured in container types that varied in their degree of gas exchange. Traps for ethylene and CO₂ were employed. During shoot bud induction from embryonic explants, the number and elongation of shoot buds improved significantly when gastight, serum-capped flasks were used compared to the foam bung-capped flasks or the regularly used Petri dishes. Elimination of the two gases from the headspace of the flasks either singly or together reduced shoot bud induction and especially elongation of shoots. A similar response was seen during axillary bud development from cultured shoots. Ethylene and CO₂ accumulation promoted development and elongation of axillary shoots. An increase in the zeatin concentration in the medium produced a greater number of axillary shoots and higher levels of ethylene in the culture vessels. Removal of CO₂ caused gradual death of the shoots, while removal of ethylene alone reduced axillary shoot lengths significantly. Inclusion of aminoethoxyvinylglycine in the medium combined with ethylene traps produced an effect similar to the use of ethylene traps alone.     

Paclobutrazol Protects Wheat Seedlings from Heat and Paraquat Injury. Is Detoxification of Active Oxygen Involved?

Paclobutrazol (PBZ), a member of the triazole family, protectedwheat (Triticum aestivum L.) seedlings from injury due to heat(50°C for 2.5 h) and paraquat (2 mM). Both stresses inducedphotoinhibition, loss of fresh weight and membrane integrity,suggesting the possible involvement of toxic oxygen species.This study tested the hypothesis that PBZ-induced protectionfrom stress is in part mediated by enhanced detoxification ofactive oxygen. The results support this hypothesis since PBZstimulated a 16, 32 and 21% increase in the activities of superoxidedismutase, ascorbate peroxidase (AP), and glutathione reductase(GR), on a fresh weight basis. The increased activities of APand GR were maintained to a higher degree than their correspondingcontrols after exposure to both heat and paraquat stress. Ascorbateand glutathione pools were l4 and 8% higher respectively inthe PBZ-treated wheat than in the controls. Within the cytoplasm,PBZ increased the activities of catalase (45%) and guaiacolperoxidase (29%) on a fresh weight basis and these higher activities,over the controls, were conserved after stress. It is suggestedthat the damage caused by two different stresses, heat and paraquat,is in part due to increased generation of active oxygen andthat PBZ protects plants by maintaining increased antioxidantenzyme activity. (Received May 10, 1993; Accepted October 29, 1993)     

Vessel-diameter distribution in roots of grapevines (Vitis vinifera L. cv. Shiraz)

The distribution frequency patterns of diameter of xylem vessels and percentage of total predicted axial conductances were studied in 190-day and 212-day-old main roots of grapevine (Vitis vinifera L. cv. Shiraz) grown under well-watered and stressed conditions. The protoxylem were the first to mature and were responsible for most of the theoretical conductance in root segments between the tip and 2.5 cm from the tip. Some large xylem vessels retained cross walls and protoplasm up to 22.5 cm from the tip. Statistical tests using the Kolmogorov-Smirnov two sample test showed that the pattern of distribution frequency of xylem vessels classified in different diameter classes varied with distance from the root tip. The distribution frequency of xylem vessels was similar in both well-watered and stressed plants from the tip up to 15 cm from the tip. At distances further from the tip the distribution frequency of xylem vessels of well-watered plants was significantly different from that of stressed plants, with the former having more larger vessels than the latter. The pattern of vessel distribution frequency was different from that of percent total axial conductance (K_h) predicted with fewer large vessels carrying most of the axial flow.     

Induction of Enzymes Associated with Lysigenous Aerenchyma Formation in Roots of Zea mays during Hypoxia or Nitrogen Starvation

Either hypoxia, which stimulates ethylene biosynthesis, or temporary N starvation, which depresses ethylene production, leads to formation of aerenchyma in maize (Zea mays L.) adventitious roots by extensive lysis of cortical cells. We studied the activity of enzymes closely involved in either ethylene formation (1-amino-cyclopropane-1-carboxylic acid synthase [ACC synthase]) or cell-wall dissolution (cellulase). Activity of ACC synthase was stimulated in the apical zone of intact roots by hypoxia, but not by anoxia or N starvation. However, N starvation, as well as hypoxia, did enhance cellulase activity in the apical zone, but not in the older zones of the same roots. Cellulase activity did not increase during hypoxia or N starvation in the presence of aminoethoxyvinylglycine, an inhibitor of ACC synthase, but this inhibition of cellulase induction was reversed during simultaneous exposure to exogenous ethylene. Together these results indicate both the role of ethylene in signaling cell lysis in response to two distinct environmental factors and the significance of hypoxia rather than anoxia in stimulation of ethylene biosynthesis in maize roots.     

PRODUCTION OF HYALINE HAIRS BY INTERTIDAL SPECIES OF FUCUS (FUCALES) AND THEIR ROLE IN PHOSPHATE UPTAKE1

A field study to determine the precise times of year at which three intertidal species of Fucus start to produce hyaline hairs and cease producing such hairs was conducted on the Isle of Man, U.K. Hairs were first observed during February, and within 6 days of their initial appearance, all tagged plants of all species at all tidal heights on the shore possessed hairs. Hair production continued until the beginning of October, at which time Fucus plants growing at the lowest stations (+ 3.0 m) had glabrous apical growth. Hair production continued later into the year for plants growing higher on the shore, and it was not until mid-November that glabrous apical growth was observed in all plants. Phosphate uptake rates of pilose (hairy) and glabrous (hairless) apical sections were measured in November 1988 for F. spiralis L. and in January 1989 for F. spiralis and F. serratus L., at phosphate concentrations ranging from 0.8 μM (ambient seawater) to 9.0 μM. In ambient seawater, pilose plants of F. spiralis removed phosphate 2–3 times faster than glabrous plants, whereas the uptake rates of pilose plants of F. serratus were about 50% greater than those of glabrous plants. The differences between uptake rates of pilose and glabrous plants of both species were smaller or nonsignificant at higher phosphate concentrations. The field and laboratory data are consistent with the hypothesis that hairs are formed in Fucus as a response to increased nutrient demand and that hairs facilitate the uptake of nutrients from seawater at concentrations typical of natural situations.     

Establishment of willow cuttings grown in porous membrane root envelopes

Small diameter fine, fibrous roots of willow are exceedingly difficult to remove from most soils. Where field retrieval of entire plants including clean roots may be important, porous membrane rooting envelopes are a method of choice.Purple osier willow (Salix purpurea L.) stem cuttings (clone SP3) were field rooted in buried porous membrane envelopes permeable to water and nutrients. Ramets were grown for two and four months, then separated into component parts for dry weight analysis.At two months, cuttings grown in rooting envelopes were no different in shoot dry weight than plants grown in clay pots or in soil. Tests indicated that rooting envelopes may be reused at least once without affecting shoot or total plant dry weight. Likewise, membrane pore sizes of 0.45, 1.2 and 3 m did not affect SP3 dry weight in four month tests. The importance of matching plant material and experiment duration to envelope size was illustrated by the limitation of growth by envelope edges at four months compared to two months.     

Response of stomatal resistance and photosynthesis to night temperature in Populus deltoides

Summary Ramets from stem cuttings of three populations of Populus deltoides Bartr. from Wisconsin, Illinois, and Louisiana representing a latitudinal gradient were grown in pots outdoors at Urbana, Illinois and brought indoors for growth chamber studies. Leaf resistance and photosynthetic response to low night temperatures of 4° and 10° C were determined relative to 20° C controls for plants measured over one growing season. Plants from Louisiana, where nights are warm, reacted to cool nights of 4° and 10° C by opening their stomata slower upon illumination the following day than those from farther north where nights are cooler. The optimum night temperature for rate of opening was lower in the Wisconsin population than in populations from farther south. The Wisconsin population showed more ideal homeostasis of photosynthesis at different temperatures than the southern population which exhibited greater plasticity. No seasonal differences in these relationships were apparent other than at the time of leaf senescence.As plants approached senescence, which occurred earliest in the Wisconsin population, leaf resistance increased and photosynthesis declined, but stomata still retained their functional ability to respond to changes in night temperature. The change in leaf resistance, noted in the Wisconsin population, was related more to closure of lower-leaf surface stomata than upper. Only the Louisiana population had significantly more stomata on the lower than upper leaf surface.