Chloramphenicol Induced Changes in Some Respiratory Characteristics of Potato Tuber Callus

Chloramphenicol (CAP), an inhibitor of the mitochondrial proteinsynthesis inhibits callus induction and subsequent growth ofpotato tuber tissue discs. Tissue respiration increase did notoccur in the presence of CAP. Both with and without CAP theinitially CN^–-sensitive tissue becomes totally CN^–-resistantin 1–2 weeks. CAP blocks the development of mitcohondrial cytochrome oxidase.A gradual decrease in the activities of cytochrome oxidase andof cytochrome pathway-mediated mitochondrial respiration isfound in CAP-tissue. The mitochondrial alternative pathway whichis absent in mitochondria from freshly sliced tissue developsduring incubation both in the absence and presence of CAP. Thealternative pathway is only operative in uninhibited state IIIrespiration in mitochondria from CAP-tissue. Cycloheximide, an inhibitor of the cytoplasmic protein synthesisinhibits the developments of the alternative pathway and ofthe cytochrome pathway. Alcohol dehydrogenase activity increasestenfold in the tissue during two weeks of incubation on mediawith and without CAP. Alcohol production in the tissue did nottake place in the controls nor in the CAP-treated tissue. (Received April 18, 1981; Accepted July 17, 1981)     

Alternative pathway respiration in vivo of potato tuber callus grown at various temperatures

During incubation of potato tuber discs ( Solanum tuberosum L. cv. Bintje) on a callus-inducing medium at 28°C, a high capacity of in vivo alternative pathway respiration develops (75% of uninhibited respiration is azide-resistant). When callus induction takes place at 8°C, only 45% of respiration is resistant to azide. In the lag phase of growth the activity of alternative pathway is low. during the exponential growth phase the activity reaches its maximal rate. This in vivo activity is of the same size at both culture temperatures. As a consequence a greater part of alternative pathway capacity is operating in uninhibited respiration during growth at low temperatures.     

Influence of growth temperature on respiratory characteristics of mitochondria from callus-forming potato tuber discs

The uninhibited respiration of mitochondria, isolated from potato tuber discs (Solanum tuberosum L. cv. Bintje) incubated on a callus-inducing medium at 28°C, is higher than that of mitochondria from tissue incubated at 8°C. This respiration is composed of a CN-sensitive and a CN-resistant part. The capacity of the CN-resistant alternative oxidase pathway is larger in mitochondria from 28°C tissue than in mitochondria from 8°C tissue (35% and 8% of uninhibited respiration, respectively). The alternative pathway is operative both in mitochondria from 28°C tissue and 8°C tissue.

The observed difference in uninhibited respiration, is not only caused by lower values of respiration via the alternative pathway in mitochondria from 8°C tissue, but also by lower values of respiration via the cytochrome pathway.

A positive correlation has been demonstrated between the incubation temperature (ranging from 4-37°C) and the relative capacity of respiration via alternative pathway in the mitochondria. Induction of alternative pathway is not directly correlated with growth (in terms of increase in fresh weight) of the potato tuber discs.

     

绿豆线粒体呼吸链在不同电子传递途径中的电子漏

绿豆线粒体的呼喊链在氧化不同义莪时有不同的呼吸速率和电子漏速率,但是Ｏ２＾－／Ｏ２比值较稳定。呼吸链部位Ⅱ的抑制剂抗霉素Ａ对α－酮茂二酸、琥珀酸及苹果本工物时的电子漏速率和Ｏ２＾－／Ｏ２比值都明显的促进作用,说明电子漏发生的位点可能在抗纱Ａ的抑制点之前。呼吸链在氧化外源ＮＡＤＨ时,线料体所产生的地氰化物、鱼藤酮、抗弱Ａ及ＳＨＡＭ都不敏感,而对钙离子的螯合剂ＥＧＴＡ显著敏感。因此,依赖于钙离子的ＮＡ     

The regulation of respiration and growth of potato tuber callus by endogenous ethylene. Suppression of ethylene action by 2,5-norbornadiene

The growth (fresh and dry weight increase) of potato tuber ( Solanum tuberosum L. cv. Bintje) callus discs was stimulated by incubation in air with 500 ppm 2,5-norbornadiene (NBD, a competitive inhibitor of ethylene action) and inhibited by incubation in air with 4 000 ppm NBD. Ethylene formation by the callus was stimulated by NBD. The development of the alternative pathway, measured in isolated mitochondria was inhibited by NBD in a concentration-dependent way. The alternative pathway capacity, measured in vivo, was inhibited by 4 000 ppm NBD, but not by 500 ppm. Uninhibited in vivo respiration, which consists of cytochrome path activity and alternative path activity, was stimulated by the treatment with 500 ppm NBD. The main contribution to this stimulation was made by the cytochrome pathway. In 4 000 ppm NBD-treated callus, uninhibited respiration seemed to be unaffected as a consequence of an inhibited cytochrome path activity, which was compensated by a stimulated alternative path activity. Both in 500 and 4 OIK) ppm NBD-treated callus the alternative path activity in vivo was stimulated.
The regulatory role for endogenous ethylene in potato tuber callus is discussed in relation to: 1) The induction of respiratory pathways, 2) the supply of reduction equivalents in vivo and 3) growth.     

Regulation of the activity of the alternative oxidase in callus forming discs from potato tubers

Callus-forming discs from potato tubers lose 80% of their starch during one month of incubation on nutrient medium containing either 0, 3 or 6% (w/v) sucrose. The content of soluble sugar in the discs varies from 5 mg (incubated without sucrose) to 22 mg (on 3% sucrose) and 40 mg (on 6% sucrose) per g fresh weight. The activity of the cytochrome pathway (V_cyt) increases during the first week of incubation on all media. Thereafter V_cyt decreases again on 0% sucrose medium, while it remains constant on 3 and 6% sucrose media. Alternative pathway capacity (V_alt), absent in freshly sliced tissue, shows a sharp increase during the first days of incubation, independent of the sucrose concentration in the medium. This capacity further increases during prolonged incubation on 3 and 6% sucrose but decreases on 0% sucrose. The in vivo activity of the alternative pathway (the participation in uninhibited respiration, ?V_alt) varies with the sucrose concentration and with the culture time. In tissue incubated for 2-3 weeks on 6% sucrose as much as 45% of the electrons are transfered to oxygen via the alternative pathway. In this tissue the factor Q (the part of the alternative pathway capacity that is operative) is about 0.8, while in tissue incubated on 0 and 3% sucrose media p generally does not exceed 0.5. When chloramphenicol, an inhibitor of mitochondrial protein synthesis, is added to the medium together with 3% sucrose, the increase in V_yet does not occur, while the induction of V_alt during the first week of incubation is the same as without chloramphenicol. A greater part of the alternative pathway capacity becomes operative in this tissue, leading to values of Q of almost 1 after prolonged incubation. Apparently, incubation on high sugar medium leads to extra participation in respiration of the energetically inefficient alternative oxidase pathway Excess sugar leads to wasteful respiration suggesting that the alternative oxidase functions as an ‘energy overflow’.     

Functional expression of plant alternative oxidase decreases antimycin A-induced reactive oxygen species production in human cells

Alternative oxidase (AOX) plays a pivotal role in cyanide-resistance respiration in the mitochondria of plants, fungi and some protists. Here we show that AOX from thermogenic skunk cabbage successfully conferred cyanide resistance to human cells. In galactose medium, HeLa cells with mitochondria-targeted AOX proteins were found to have significantly less reactive oxygen species production in response to antimycin-A exposure, a specific inhibitor of respiratory complex III. These results suggest that skunk cabbage AOX can be used to create an alternative respiration pathway, which might be important for therapy against various mitochondrial diseases.     

Respiration and Alternative Oxidase in Corn Seedling Tissues during Germination at Different Temperatures

Respiration rates of Zea mays L. seedling tissues grown at 30 and 14°C were measured at 25°C at different stages of seedling growth. Accumulation of heat units was used to define the developmental stages to compare respiration between the two temperatures. At both temperatures, respiration rates of most tissues were highest at the youngest stages, then declined with age. Respiration rates of mesocotyl tissue were the most responsive to temperature, being nearly twofold higher when grown at 14 compared to 30°C. Alternative pathway respiration increased concomitantly with respiration and was higher in mesocotyls grown in the cold. When seedlings were started at 30 then transferred to 14°C, the increase in alternative pathway respiration due to cold was not observed unless the seedlings were transferred before 2 days of growth. Seedlings transferred to 14°C after growth at 30°C for 2 days had the same alternative oxidase capacity as seedlings grown at 30°C. Seedlings grown at 14°C for 10 to 12 days, then transferred to 30°C, lost alternative pathway respiratory capacity over a period of 2 to 3 days. Western blots of mitochondrial proteins indicated that this loss of capacity was due to a loss of the alternative oxidase protein. Some in vitro characteristics of mitochondria were determined. The temperature optimum for measurement of alternative oxidase capacity was 15 to 20°C. At 41°C, very little alternative oxidase was measured, i.e., the mitochondrial oxygen uptake was almost completely sensitive to cyanide. This inactivation at 41°C was reversible. After incubation at 41°C, the alternative oxidase capacity measured at 25°C was the similar to when it was measured at that temperature directly. Isolated mitochondria lost alternative oxidase capacity at the same rate when incubated at 41°C as they did when incubated at 25°C. Increasing the supply of electrons to isolated mitochondria increased the degree of engagement of the alternative pathway, whereas lower temperature decreased the degree of engagement. Lower temperatures did not increase the degree of engagement of the pathway in intact tissues. We interpret these observations to indicate that the greater capacity of alternative oxidase in cold-grown seedlings is a consequence of development at these low temperatures which results in elevated respiration rates. Low temperature itself does not cause greater capacity or engagement of the alternative oxidase in mitochondria that have developed under warm temperatures. Our hypothesis would be that the low growth temperatures require the seedlings to have a higher respiration rate for some reason, e.g., to prevent the accumulation of a toxic metabolite, and that the alternative pathway functions in that respiration.     

Lower growth temperature increases alternative pathway capacity and alternative oxidase protein in tobacco

Suspension cells of NT1 tobacco (Nicotiana tabacum L. cv bright yellow) have been used to study the effect of growth temperature on the CN-resistant, salicylhydroxamic acid-sensitive alternative pathway of respiration. Mitochondria isolated from cells maintained at 30°C had a low capacity to oxidize succinate via the alternative pathway, whereas mitochondria isolated from cells 24 h after transfer to 18°C displayed, on average, a 5-fold increase in this capacity (from 7 to 32 nanoatoms oxygen per milligram protein per minute). This represented an increase in alternative pathway capacity from 18 to 45% of the total capacity of electron transport. This increased capacity was lost upon transfer of cells back to 30°C. A monoclonal antibody to the terminal oxidase of the alternative pathway (the alternative oxidase) from Sauromatum guttatum (T.E. Elthon, R.L. Nickels, L. McIntosh [1989] Plant Physiology 89: 1311-1317) recognized a 35-kilodalton mitochondrial protein in tobacco. There was an excellent correlation between the capacity of the alternative path in isolated tobacco mitochondria and the levels of this 35-kilodalton alternative oxidase protein. Cycloheximide could inhibit both the increased level of the 35-kilodalton alternative oxidase protein and the increased alternative pathway capacity normally seen upon transfer to 18°C. We conclude that transfer of tobacco cells to the lower temperature increases the capacity of the alternative pathway due, at least in part, to de novo synthesis of the 35-kilodalton alternative oxidase protein.     

Coordinate regulation of cytochrome and alternative pathway respiration in tobacco

In suspension cells of NT1 tobacco (Nicotiana tabacum L. cv bright yellow), inhibition of the cytochrome pathway of respiration with antimycin A induced a large increase in the capacity of the alternative pathway over a period of approximately 12 h, as confirmed in both whole cells and isolated mitochondria. The increase in alternative pathway capacity required de novo RNA and protein synthesis and correlated closely with the increase of a 35-kD alternative oxidase protein. When the cytochrome pathway of intact cells was inhibited by antimycin A, respiration proceeded exclusively through the alternative pathway, reached rates significantly higher than before antimycin A addition, and was not stimulated by p-trifluoromethoxycarbonylcyanide (FCCP). When inhibition of the cytochrome pathway was relieved, alternative pathway capacity and the level of the 35-kD alternative oxidase protein declined. Respiration rate also declined and could once again be stimulated by FCCP. These observations show that the capacities of the mitochondrial electron transport pathways can be regulated in a coordinate fashion.     

Modulation of the Access of Exogenous NAD(P)H to the Alternative Pathway in Potato Tuber Callus Mitochondria with Triton X-100

Alternative oxidase activity in potato tuber (Solanum tuberosum L. cv Bintje) callus mitochondria with exogenous NAD(P)H as substrate is inhibited by low concentrations of the detergent Triton X-100. Alternative oxidase activity with succinate or malate as substrate is not affected by these low concentrations of Triton X-100. Cytochrome pathway activity was not influenced under these conditions, neither with endogenous nor with exogenous substrate. Washing of Triton X-100-treated mitochondria did partially restore both uninhibited and CN-resistant NADH oxidation, indicating that under these conditions Triton X-100 does not permanently remove major components from the mitochondrial membrane. Apparently, it is possible to manipulate mitochondria in such a way that the access of exogenous NADH to the alternative pathway is blocked while access to the cytochrome pathway is uninhibited. It is suggested that membrane conditions have a regulatory function (possibly via influencing the diffusion path) in the oxidation of exogenous NADH via the alternative pathway.     

The dual role of oxygen in avocado fruit respiration: Kinetic analysis and computer modelling of diffusion-affected respiratory oxygen isotherms

Abstract. Oxygen plays a dual role in affecting the rate of respiration of avocado fruit ( Persea americana Mill, cv. Hass). The respiration rate v. oxygen concentration curve for steady state avocado fruit respiration is biphasic. The curve becomes monophasic, however, when measured under conditions of rapidly changing oxygen concentration in a closed circulating system. The results are interpreted as indicating that oxygen at relatively high concentrations modulates respiration independent of its interaction with the terminal oxidase—presumably cytochrome oxidase.
A computer model is presented which takes into account the effect of diffusion barriers on the kinetics of oxygen utilization as a function of concentration in avocado fruit. The model is used to make predictions concerning the apparent K _m of the terminal oxidase or oxidases in avocado fruit. It is concluded that the apparent K _m of the terminal oxidase of uninhibited avocado fruit is that of cytochrome oxidase, and that the alternative, cyanide-resistant oxidase of avocado fruit does not contribute appreciably to the uninhibited respiration of preclimacteric or climacteric avocado fruit.     

Molecular Genetic Alteration of Plant Respiration (Silencing and Overexpression of Alternative Oxidase in Transgenic Tobacco)

The alternative oxidase (AOX) of plant mitochondria is encoded by the nuclear gene Aox1. Sense and antisense DNA constructs of Nicotiana tabacum Aox1 were introduced into tobacco, and transgenic plants with both increased and decreased levels of mitochondrial AOX protein were identified. Suspension cells derived from wild-type and transgenic plants were grown in heterotrophic batch culture. Transgenic cells with increased AOX protein had an increased capacity for cyanide-resistant, salicylhydroxamic acid-sensitive respiration compared to wild-type cells, whereas transgenic cells with decreased AOX protein had a decreased capacity for such respiration. Thus, genetic alteration of the level of AOX protein was sufficient to alter the capacity for electron transport through the alternative pathway. Under our standard growth conditions, "antisense" cells with dramatically reduced levels of AOX protein had growth and respiration rates similar to the wild type. However, whereas wild-type cells were able to grow under conditions that severely suppressed cytochrome pathway activity, antisense cells could not survive this treatment. This suggests that a critical function of AOX may be to support respiration when the cytochrome pathway is impaired. The much higher level of AOX protein in "sense" cells compared to the wild type did not appreciably alter the steady-state partitioning of electrons between the cytochrome path and the alternative pathway in vivo, suggesting that this partitioning may be subject to additional regulatory factors.     

Cyanide-resistant Respiration in Fresh and Aged Sweet Potato Slices

The respiration of fresh sweet potato (Ipomoea batatas) slices is resistant to, and often stimulated by, cyanide and antimycin A. m-Chlorobenzhydroxamic acid (CLAM), a selective inhibitor of the alternate path, inhibits respiration in the presence of cyanide and has a limited inhibitory effect in the presence of antimycin A. Thus, a partial bypass of the antimycinsensitive site is indicated. Respiration rises 2-fold at best with slice aging, the increment being cytochrome-mediated. The cyanide-resistant pathway contributes neither to coupled fresh slice respiration nor to the induced respiration in the absence of inhibitors of the cytochrome path. In the presence of uncoupler, however, the alternate path is engaged both in fresh and aged slices. V_cyt, the maximal capacity of the cytochrome path, remains essentially the same with slice aging, whereas V_alt decreases from 20 to 60 per cent. The induced respiration is readily accommodated by the potential cytochrome path capacity of fresh slices, which is realized on aging. Accordingly, there is no need to invoke mitochondrial proliferation in explanation of the development of the induced respiration. The engagement of the alternate path in response to uncoupler reflects substrate mobilization to a degree that substrate oxidation exceeds the electron transport capacity of the cytochrome path.

Fresh slices do not utilize exogenous substrates, whereas aged slices do so readily. Cerulenin, a specific inhibitor of fatty acid synthesis, prevents the development of the induced respiration as well as the capacity to oxidize exogenous substrates. It is suggested that lipid, and ultimately membrane, biosynthesis is central to the development of the induced respiration and the ability to use exogenous substrates, much as in potato.

     

Endogenous ethylene formation and the development of the alternative pathway in potato tuber discs

Callus-forming discs from potato ( Solanum tuberosum L. cv. Bintje) tubers grown on a nutrient medium containing an auxin and a cytokinin show both a higher ethylene formation and a higher capacity of the mitochondrial alternative pathway than nongrowing discs (on the same medium without auxin and cytokinin). Addition of 1-ami-nocyclopropane-1-carboxylic acid (ACC) to the nutrient medium of non-growing discs results in an enhancement of the ethylene formation as well as the alternative pathway capacity. In callus-forming tissue, the levels of both these parameters can be suppressed by adding aminoethoxyvinylglycine (AVG) to the nutrient medium without affecting growth. The effects on state 3-respiration of ACC (increase) and AVG (decrease) are relatively small. These results suggest that the alternative pathway capacity is controlled to a considerable extent by the endogenous ethylene formation of the tissues.     

Influence of osmotic stress on the respiration of potato tuber callus

Potato tuber ( Solanum tuberosum L. cv. Bintje) callus shows a decrease in fresh weight and an increase in dry weight upon transfer to nutrient medium supplemented with 0.3 or 0.5 M mannitol. The osmolarity of the intracellular fluid increases simultaneously. Probably mannitol is taken up from the medium till the osmolarity of the tissue is in equilibrium with that of the medium. After osmotic adaptation, on a medium with 0.5 M mannitol, growth is negligible, although the tissue retains its viability.
Respiration increases upon transfer to medium with extra mannitol, especially when expressed on a fresh weight basis. On this basis cytochrome and alternative pathway capacities do not change appreciably. The respiratory increase is exclusively caused by an increased engagement of the alternative pathway. The participation of this pathway in uninhibited respiration increases from about 10 to 90% upon transfer to medium with extra mannitol. The increase in respiration is partly correlated with the decrease in fresh weight upon transfer. Per disc, the capacities of the cytochrome and alternative pathway decline. Yet, total respiration per disc significantly increases due to the increased participation of the alternative pathway. This results in an almost equal ATP-production per disc before and after transfer. We suggest, that the alternative pathway functions as a reserve capacity in potato callus, which is switched on when ATP-production coupled to the cytochrome pathway is impaired.     

The regulation of respiration in cell suspensions of Petunia hybrida, studied by inhibiting mitochondrial protein synthesis with chloramphenicol

When Petunia hybrida L. cv. Rosy Morn Fertile suspension cells were inoculated in fresh medium with chloramphenicol (CAP), the activity of cytochrome C oxidase (EC 1. 9. 3. 1), and the respiration via the cytochrome pathway of isolated mitochondria decreased, while in untreated cells these parameters more than doubled in 2–3 days. However, the in vivo respiratory activity of the cytochrome pathway of CAP-treated cells showed a similar course in time as that of untreated cells, even in the presence of an uncoupler, a large rise during the first 2–3 days followed by a decline. This leads to the conclusion that the respiration via the cytochrome pathway, even when measured in the presence of an uncoupler, is not the capacity of this pathway. Furthermore, the results suggest that, although new-synthesis of proteins occurs directly after in-oculation, a large overcapacity must be present of cytochrome pathway elements (at least of those that are mitochondrial encoded). CAP had little effect on the uninhibited respiration and the cyanide-resistant, alternative pathway of the Petunia cells. However, the engagement of the alternative pathway (in the presence or absence of uncoupler) was increased in CAP-treated cells, especially after day 3 of the batch cycle, possibly as an effect of higher sugar degradation in combination with substrate phosphorylation to compensate the loss of ATP-synthesizing ability of the cytochrome pathway. It will be discussed that in general one should be careful using the term 'capacity' for the respiratory pathways.     

Ascorbic acid is a key participant during the interactions between chloroplasts and mitochondria to optimize photosynthesis and protect against photoinhibition

The possible role of L-ascorbate (AsA) as a biochemical signal during the interactions between photosynthesis and respiration was examined in leaf discs of Arabidopsis thaliana. AsA content was either decreased as in AsA-deficient vtc1 mutants or increased by treatment with L-galactono-1, 4-lactone (L-GalL, a precursor of AsA; EC 1.3.2.3). In mutants, photosynthesis was extremely sensitive to both antimycin A (inhibitor of the cytochrome c oxidase pathway [COX pathway]) and salicylhydroxamic acid (SHAM, inhibitor of the alternative pathway [AOX pathway]), particularly at high light conditions. Mitochondrial inhibitors lowered the ratio of reduced AsA to total AsA, at high light, indicating oxidative stress in leaf discs. Elevation of AsA by L-GalL decreased the sensitivity of photosynthesis at high light to antimycin A or SHAM, sustained photosynthesis at supraoptimal light and relieved the extent of photoinhibition. High ratios of reduced AsA to total AsA in L-GalL-treated leaf discs suggests that L-GalL lowers oxidative stress. The protection by L-GalL of photosynthesis against the mitochondrial inhibitors and photoinhibition was quite pronounced in vtc1 mutants. Our results suggest that the levels and redox state of AsA modify the pattern of modulation of photosynthesis by mitochondrial metabolism. The extent of the AOX pathway as a percentage of the total respiration in Arabidopsis mesophyll protoplasts was much higher in vtc1 than in wild type. We suggest that the role of AsA becomes pronounced at high light and/or when the AOX pathway is inhibited. While acknowledging the importance of the COX pathway, we hypothesize that AsA and the AOX pathway may complement each other to protect photosynthesis against photoinhibition.