Maturation of Potassium-Stimulated Respiration in Rat Cerebral Cortical Slices

Abstract: Maximal dinitrophenol-stimulated respiration and K⁺-stimulated respiration were measured polarographically in cerebral cortical slices taken from rats aged 2–60 days. Increasing K⁺ concentrations produced an increase in respiration in slices from animals aged 15 days and older, but not in slices from animals aged 10 days and younger. Dinitrophenol-stimulated respiration, or the maximal respiratory capacity of the tissue, showed a similar increase between 10 and 15 days of age. At each age the maximal respiratory capacity was 6–8 ng at 0/mg protein min greater than the maximal K⁺-stimulated respiration.     

Relative Contribution of Cytochrome-mediated and Cyanide-resistant Electron Transport in Fresh and Aged Potato Slices

The respiration of fresh potato (Solanum tuberosum, var. Russet Burbank) slices is predominantly cyanide-sensitive whether in the presence or absence of uncoupler. By contrast, the wound-induced respiration which develops in thin slices with aging is cyanide-resistant, and in the presence of cyanide, sensitive to chlorobenzhydroxamic acid, a selective inhibitor of the cyanide-resistant respiration. Titration of the alternate path in coupled slices with chlorobenzhydroxamic acid, in the presence and absence of cyanide, shows that the contribution of the cyanide-resistant pathway to the wound-induced respiration is zero. Similar titrations with uncoupled slices reveal that the alternate path is engaged and utilized extensively.

The maximal capacity of the cytochrome path (V_cyt) has been estimated in fresh and aged slices in the presence of the uncoupler carbonyl-cyanide m-chlorophenyl hydrazone. It has been found that V_cyt of aged slices is but 30 to 40% higher than that of fresh slices. The results suggest that the bulk of the wound-induced respiration is mediated through the cytochrome pathway which exists in fresh slices in suppressed form, and which is fully expressed by slice aging. The engagement of the alternate path by uncouplers in aged slices is attributed to an increase in substrate mobilization, with the result that the electron transport capacity of the cytochrome chain is exceeded.

     

Metabolism of Red Beet Slices II. Effects of Aging

The rate of respiration of red beet slices increased 3- to 4-fold when the slices were aged in a moist atmosphere for 18 to 24 hours. The respiration of fresh slices was severely inhibited by 8 × 10⁻⁵ m HCN but as slices aged the sensitivity of respiration to HCN fell rapidly. The presence of HCN stimulated the respiration of slices after 8 to 12 hours of aging.     

Oxygen tension a determining factor in the respiration of potato disks of varying thickness

The effect of temperature on the respiration rate of potato tuber slices has been analyzed in terms of the Arrhenius equation. Freshly cut disks, irrespective of thickness, show a linear response to increasing temperature up to 30° with an activation energy (E) of approximately 12.0 Kcal. Aged disks less than 1.0 mm thick also give a linear response with E similar to that of fresh disks. With aged disks above 1.0 mm thick there is a loss of linearity above 20° and E falls to about 4.0 Kcal indicating that respiration becomes rate-limited by a diffusion process. This departure from linearity can be corrected by raising the oxygen tension or by subdivision of thick disks to give thin slices. It is concluded that the respiration of aged disks is rate-limited by oxygen deficiency and that the inverse relationship between respiration rate and disk thickness is in large part attributable to this factor.     

Comparison between Aging of Slices and Ethylene Treatment of Whole White Potato Tubers

Cyanide-resistant O(2) consumption can be stimulated by either treating whole white potato tubers (Norchip) with ethylene, in the presence of 100% O(2), or aging slices obtained from untreated potato tubers. A comparison of alternative pathway activity elicited by either treatment was undertaken. The proportion of electrons flowing through the alternative path in the presence of intermediate concentrations of KCN and at various concentrations of salicylhydroxamic acid was identical in both cases. However, the respiration of slices from ethylene-treated tubers was in every case stimulated by KCN, whereas the aged slices never exhibited this phenomenon. Furthermore, the metabolism of d-[U-(14)C]glucose was several hundred times greater in aged slices than in fresh slices from C(2)H(4)-treated tubers. These results, along with the respiratory kinetics of aged slices from ethylene-treated tubers, suggest that aged slices and fresh slices from ethylene-treated tubers are biochemically dissimilar.     

Studies on the Wound-Induced CN-Resistant Respiration in Potato Tuber Slices

The respiration of fresh potato slices was sensitive to CN-, and was not inhibited by m-CLAM in the presence or absence of CN-. By contrast, the wound-induced respiration of slices, incubated in air for 24 hours, was not only relatively resistant to CN-, but also markedly inhibited by m-CLAM in the presence or absence of CN-. When m-CLAM and CN- were added togather, the inhibitory effect was higher than that of them when used separately. The observations indicated that the alternate path is operative in aged potato slices. The data determined by the method of m-CLAM titration showed that the actual contribution of alternate path and cytochrome path in aged potato slices was approximately 28% and 54% of the total respiration respectively in the absence of CN-. When the cytochrome path was inhibited by CN-, the maximal capacity of alternate path (Valt was higher than the actual contribution of them (ρ·Valt). The increased contribution of alternate path in presence of CN- might be thought to indicate that there is a diversion of electron flux from the cytochrome path to the alternate path. When the respiratory flux of aged slices was reduced by treatment with iodoacetate and malonate, the proportions of respiration inhibited by CN- and m-CLAM respectively were not changed.     

Changes in properties of the inner mitochondrial membrane during mitochondrial biogenesis in aging sweet potato tissue slices in relation to the development of cyanide-insensitive respiration.

Protein and phospholipid of the inner mitochondrial membrane in sweet potato root tissue increased after a lag phase during aging of the sliced tissue. The protein, but not the phospholipid, from aged slices was more insoluble in a solution containing sodium deoxycholate and sodium cholate than that from fresh tissue. There were differences in polypeptide composition between deoxycholate-cholate-soluble and -insoluble fractions as determined by polyacrylamide-gel electorophoresis of membrane fragments in the presence of sodium dodecyl sulfate. However, no difference was observed between mitochondrial membranes from fresh and aged slices. When disrupted mitochondrial membrane was subjected to equilibrium density centrifugation, two bands were obtained from aged slices but only one band from fresh tissue. The lighter band from aged slices was indentical to the single band from fresh tissue. The denser band was very poor in phospholipid, and the protein was very insoluble in deoxycholate-cholate solution. The denser membrane fragments possessed a cyanide-insensitive respiratory chain whereas the lighter did not. It is proposed that the development of the cyanide-insensitive respiration in aging slices is related to the formation of phospholipid-deficient mitochondrial membrane.     

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.

     

Oxygen Electrode Measurements of Potato Slice Respiration at 0{degrees} C.

The use of the oxygen electrode in measuring the respirationrate of potato slices between o° C. and 27° C. is described.When slices are transferred from 27° C. to o° C. therespiration rate adjusts to the level characteristic of thelow temperature within 2 or 3 minutes. The slices have a highoxygen affinity and the respiration rate at o° C. is approximately10 per cent. of the rate at 24° C. in both freshly cut slicesand slices aged 24 hours, during which time respiration increasesfourfold.     

Membrane Lipid Breakdown in Relation to the Wound-induced and Cyanide-resistant Respiration in Tissue Slices: A COMPARATIVE STUDY

A study of a variety of bulky storage organs and fruits reveals that fresh slices fall into two categories with respect to their sensitivity to CN. Fresh slices in the first class are CN-sensitive, whereas slices of the second class are resistant to, and often stimulated by, CN. In tissue slices which are initially CN-sensitive, cutting initiates a burst of lipolytic activity. In CN-resistant fresh slices, there is no measurable lipid breakdown.Slicing evokes the wound-respiration which is 5- to 10-fold that of the parent organ. Slice aging, in turn, evokes a further 2- to 3-fold respiratory increase, the wound-induced respiration, whether fresh slice respiration is CN-sensitive or -resistant. Estimation of the contribution by the cytochrome and alternative paths shows that the wound respiration in both groups is mediated by the cytochrome path. On the other hand, the wound-induced respiration in the first class is cytochrome path mediated, whereas, in some members of the second group, both pathways are utilized. Uncouplers of oxidative phosphorylation elicit a CN-sensitive increment in fresh slices as great or greater than the wound-induced respiration. Accordingly, de novo synthesis of mitochondria is ruled out as an explanation of the latter.The integrity of endomembranes, perhaps including mitochondrial membranes, is seemingly a prerequisite for the operation of the alternative path, that is, alternative path activity is lost concomitantly with membrane lipid breakdown. The development of the wound-induced respiration is not co-extensive with the development of the CN-resistant path in all tissue slices. The fundamental process of aging appears to involve activation of pre-existing respiratory capacity.Fresh slices from whatever source fail to utilize exogenous (14)C-labeled glucose, whereas aged slices do so readily. A transport lesion is indicated, the healing of which does not depend on the development of the wound-induced respiration but does depend on fatty acid, and presumably membrane lipid, biosynthesis.     

丙酮酸对陈化马铃薯块茎切片线粒体抗氰呼吸的激活作用

用从陈化马铃薯切片纯化的线粒体进行实验发现：丙酮酸对总呼吸只有微弱的刺激作用,但可明显激活抗氰呼吸,并显著增强抗氰呼吸对总呼吸的贡献;丙酮酸对抗氰呼吸的激活作用可通过洗涤线粒体除去,重新加入丙酮酸又对抗氰呼吸产生激活作用;丙酮酸对抗氰呼吸的半最大激活浓度约为1．0mmol／L。上述结果表明丙酮酸对植物线粒体抗氰呼吸的激活作用可能具有普遍性。     

Ethylene and wound-induced cyanide-resistant respiration climaxes in potato: The synergistic role of CO2 and the selective role of lycorine

When treated with ethylene in O₂, conditioned potato (Solanum tuberosum L. cv. Russet Burbank) tubers – that is, tubers kept at room temperature for 10 days or more – yield slices that are CN^? resistant. Ten % CO₂ in the gas mixture not only synergizes the effect of ethylene, but replaces the need for conditioning as well. The response to CO₂ is more pronounced with increasing time from harvest. By contrast fresh slices from untreated tubers are CN^? sensitive, as are slices from tubers incubated in O₂ or O₂ plus CO₂. The suggestion is made that CN^? resistance is constitutive, and that treatment with ethylene/CO₂ in O₂ confers on potato tuber tissue a resistance to the extensive degradation of membrane phospholipids that normally attends slicing and leads to the loss of CN^? resistance. In this connection respiration inhibition by imidazole, an inhibitor of fatty acid α-oxidation, is extensive in slices of untreated tubers, and sharply diminished in slices of ethylene-treated tubers in proportion to their CN^? resistance. The coextensive rise of respiration rate and CN^? resistance in aged potato slices has led to the presumption that the CN^?-resistant path mediates the respiration climax. Accordingly the alkaloid, lycorine, has been considered to inhibit the development of CN^? resistance in aging potato slices because it curtails the wound-induced respiration. A comparison was carried out on the effect of lycorine on CN^?-sensitive and CN^?-resistant fresh slices – the latter obtained from ethylene/CO₂-treated tubers. Lycorine suppressed the development of the wound-induced respiration without restricting the development of CN^? resistance.     

内源乙烯对陈化马铃薯切片交替氧化酶表达的诱导作用

抗氰呼吸是植物线粒体区别于动物线粒体的主要功能特征之一,其本质是一条以交替氧化酶（ａｌｔｅｒｎａｔｉｖｅｏｘｉｄａｓｅ,ＡＯＸ）为末端氧化酶,被称为“交替途径”的呼吸电子传递链（ＭｃＩｎｔｏｓｈ１９９４）。该呼吸途径经常发生于产热植物开花、果实成熟、切片陈化、低温胁迫、机械损伤以及病原体侵染等一些较特殊的环境条件或生理过程中,并受乙烯等一些效应剂的诱导（Ｓｏｌｏｍｏｓ和Ｌａｔｉｅｓ１９７６,Ｄａｙ等１９７８,Ｇｕｄｅ和ｖａｎｄｅｒＰｌａｓ１９８５,Ｍａｒｉｓｓｅｎ等１９８６,Ｙｉｐ和Ｈｅｗ１９８…     

Relationship Between Endogenous Ethylene and the Development and Operation of the Alternative Respiratory Pathway in Aged Potato Tuber Slices

The relationship between endogenous ethylene and the development and the operation of the alternative respiration pathway in aged potato (Solanum tuberosum L. ) tuber slices were investigated. During the 24 h aging period under 30 ℃, along with the great increase of the total respiratory rate (Vt) of the slices, the alternative pathway capacity (Valt) developed continuously, and the Valt/Vt values kept increasing as well. Both the alternative pathway activity (ρValt) and its contribution to Vt(ρValt/Vt) also increased gradually before 12 h of aging, but kept constant from 12 h to 24 h. The time course of the endogenous ethylene production of the aged slices was similar to the changing trends of Valt and Valt/Vt, but different from those of ρValt and ρValt/Vt values. ACC and Cu2 + treatment which stimulated ethylene production of the aged slices enhanced their Valt and Valt/ Vt values, Co2 + and Ag+ treatment resulted in a decreased effect. However, all the above treat ments of ethylene-related agents could not alter the continuously decreasing trend of the ρ value of the alternative pathway of the aged slices. And their effects on ρValt and ρValt/Vt values were only observed before 12 h of aging. These results suggested that the endogenous ethylene was essential to the development of the capacity of alternative pathway, but could only slightly influence the operation of the activity of the alternative pathway in aged potato tuber slices.     

H2O2和水杨酸对陈化马铃薯切片交替呼吸途径影响的比较

外源5.0 mmol/L H2O2和0.1 mmol/L 水杨酸(salicylic acid, SA)处理均可明显提高陈化24 h的马铃薯切片的交替呼吸途径容量(Valt)及其与总呼吸的比值(Valt/Vt).应用交替氧化酶的单克隆抗体进行Western杂交的结果表明,H2O2和SA处理均可明显提高陈化马铃薯切片中交替氧化酶的表达水平.用氧同位素分辨法研究,结果表明:H2O2处理对陈化马铃薯切片中交替呼吸途径的实际运行没有影响,而SA处理对交替呼吸途径的实际运行具有明显的促进作用.上述结果表明,H2O2和SA对植物组织交替呼吸途径的影响存在差异,二者均可促进交替氧化酶的表达从而诱导交替呼吸途径容量的发生,但H2O2不影响其实际运行,而SA还可同时诱导其实际运行.     

Effect of Adenine Nucleotides on the Respiration of Carrot Root Slices

Sodium pyruvate and dinitrophenol stimulated O(2) uptake of freshly cut phloem parenchyma from carrot roots by 63 and 120% at optimal concentrations, indicating that production of pyruvate by glycolysis regulates over-all respiratory rate. Adding 0.5 to 6.7 mm Na(3)ADP and Na(3)ATP to slices rapidly stimulates respiration rate by 20 to 85%. The effect is greater at the lower end of this concentration range and is not due to change in pH or active cation uptake. It is suggested that treating tissue with both nucleotides stimulates pyruvate kinase, the rate-limiting step in respiration of freshly cut slices, by increasing the concentration of endogenous ADP. Adenosine diphosphate continued to stimulate O(2) uptake until the peak of induced respiration, but ATP inhibited respiration during development and decline of this peak. Absence of respiratory stimulation by NaH(2)PO(4) and of respiratory inhibition by added nucleosides confirms that inorganic phosphate is not a limiting factor of respiration in freshly cut slices. The stimulation of respiration rate of these slices by dinitrophenol is consistent with results from experiments in which ADP and ATP were applied to the tissue.     

Increase in the Number, G Protein Coupling, and Efficiency of Facilitatory Adenosine A2A Receptors in the Limbic Cortex, but not Striatum, of Aged Rats

Adenosine's effects result from a balanced activation of inhibitory A1 and facilitatory A2A receptors. Because in aged animals there is an increased number of A2A receptors, we now compared the efficiency of A2A receptors in cortical and striatal preparations of young adult (6-week-old) and aged (2-year-old) rats. In cortical, in contrast to striatal, membranes from aged rats, A2A receptors were more tightly coupled to G proteins, because 5'-guanylylimidodiphosphate (100 microM) increased by 321% the Ki of the A2A agonist CGS21680 as a displacer of binding of the A2A antagonist [3H]ZM241385 (1 nM), compared with a 112% increase in young rats. In cortical slices, CGS21680 (30-1,000 nM) was virtually devoid of effect on cyclic AMP accumulation in young rats but increased cyclic AMP accumulation with an EC50 of 153 nM in aged rats, whereas the efficiency of CGS21680 was similar in striatal slices of young and aged rats. CGS21680 (30 nM) was virtually devoid of effect on acetylcholine release from hippocampal CA1 slices of young rats but caused a 55% facilitation in aged rats. These results show that the number of A2A receptors, their coupling to G proteins, and their efficiency are enhanced in the limbic cortex of aged rats, suggesting a greater involvement of facilitation in adenosine responses.     

Alternative respiration and heat evolution in plants

The alternative respiratory pathway dissipates most of the chemical energy of respiratory substrates as heat. We have shown that this heat can be quantified by microcalorimetry and is a measure of alternative pathway activity in vivo. The alternative pathway is known to increase in aged potato (Solanum tuberosum) slices and in chill-stressed leaves. Aging of potato slices for 24 hours was accompanied by an almost fourfold increase in the rate of heat evolution. This heat increase was resistant to KCN but could be blocked by an alternative pathway inhibitor, salicylhydroxamic acid (SHAM). In cucumber (Cucumis sativus) leaves subjected to chilling stress (between 4 and 16°C), the rate of heat evolution was inversely related to temperature. As in aged potato slices, the increased rate of heat evolution in cucumber leaves was blocked by SHAM, but not by KCN. Nitrogen or the combination of SHAM and KCN blocked most of the heat evolution in both aged potato slices and chill-stressed cucumber leaves. Calorimetric measurements of the alternative pathway corresponded to respiration measurements performed using an oxygen electrode.     

Antimycin-insensitive Cytochrome-mediated Respiration in Fresh and Aged Potato Slices

The effect of antimycin A on the respiration of fresh potato (Solanum tuberosum var. Russet Burbank) slices has been determined in the presence and absence of m-chlorobenzhydroxamic acid (CLAM). Two antimycin-binding sites are indicated. At low concentrations antimycin alone inhibits respiration only slightly. When CLAM and low antimycin are added together, respiration is sharply inhibited, as in response to cyanide. High antimycin alone is as inhibitory as cyanide. The branch point to the alternate path is intact in fresh slices, as is the hydroxamate-sensitive component. The full alternate path is inoperative, however, as indicated by the sensitivity to cyanide. The data suggest an alternate path loop which bypasses the high affinity antimycin site and returns electrons to the cytochrome path. Antimycin at high concentrations prevents articulation of the loop with the cytochrome path.

The respiration of aged slices is not only markedly resistant to antimycin at high concentrations, but quite insensitive to CLAM in the presence of antimycin. A model is proposed which involves parallel paths within complex III of the cytochrome path, with one path bearing the high affinity, and the other the low affinity antimycin site. With slice aging the antimycin affinity of the latter site is even further reduced, providing a relatively antimycin-insensitive bypass to both the high affinity antimycin-sensitive cytochrome path, and the CLAM-sensitive alternate path. The alternate path loop in fresh slices is presumed to feed into the low affinity antimycin-sensitive arm of the cytochrome path.