Involvement of phosphate carrier as a part of complex with ADP/ATP and aspartate/glutamate antiporters in palmitic acid-induced uncoupling in liver mitochondria

In liver mitochondria, the phosphate carrier is involved in protonophoric uncoupling effect of fatty acids together with ADP/ATP and aspartate/glutamate antiporters (Samartsev et al. 2003. Biochemistry (Moscow). 68, 618–629). Liver mitochondria depleted of endogenous oxidation substrates (exhausted mitochondria) have been used in the present work. In these mitochondria, like in the intact liver mitochondria, the specific inhibitor of ADP/ATP antiporter (carboxyatractylate) and the substrate of aspartate/glutamate antiporter (aspartate) suppress the uncoupling activity of palmitic acid. It is shown that in exhausted mitochondria the substrate of phosphate carrier (inorganic phosphate) and its nonspecific inhibitor mersalyl partially suppress palmitic acid-induced uncoupling due to decrease in the component of uncoupling activity sensitive to carboxyatractylate and aspartate. In the presence of inorganic phosphate or mersalyl, carboxyatractylate and aspartate added separately subsequent to palmitic acid do not suppress its uncoupling activity. They are effective only when added jointly. In the presence of thiourea or pyruvate, such effects of inorganic phosphate and mersalyl are not observed. It is supposed that in the presence of inorganic phosphate or mersalyl and under the condition of oxidation of critical SH-groups in mitochondria, the phosphate carrier, ADP/ATP antiporter, and aspartate/glutamate antiporter are involved in uncoupling function together with the general fatty acid pool as an uncoupling complex. The role of phosphate carrier in this complex may consist in facilitation of lateral transfer of the fatty acid molecules from one antiporter to another.     

Occurrence of Plant-Uncoupling Mitochondrial Protein (PUMP) in Diverse Organs and Tissues of Several Plants

The presence of plant-uncoupling mitochondrial protein (PUMP), previously described by Vercesi et al. (1995), was screened in mitochondria of various organs or tissues of several plant species. This was done functionally, by monitoring purine nucleotide-sensitive linoleic acid-induced uncoupling, or by Western blots. The following findings were established: (1) PUMP was found in most of the higher plants tested; (2) since ATP inhibition of linoleic acid-induced membrane potential decrease varied, PUMP content might differ in different plant tissues, as observed with mitochondria from maize roots, maize seeds, spinach leaves, wheat shoots, carrot roots, cauliflower, broccoli, maize shoots, turnip root, and potato calli. Western blots also indicated PUMP presence in oat shoots, carnation petals, onion bulbs, red beet root, green cabbage, and Sedum leaves. (3) PUMP was not detected in mushrooms. We conclude that PUMP is likely present in the mitochondria of organs and tissues of all higher plants.     

Mitochondria from Dipodascus (Endomyces) magnusii and Yarrowia lipolytica yeasts did not undergo a Ca2+-dependent permeability transition even under anaerobic conditions

In this study we used tightly-coupled mitochondria from Yarrowia lipolytica and Dipodascus (Endomyces) magnusii yeasts. The two yeast strains are good alternatives to Saccharomyces cerevisiae, being aerobes containing well-structured mitochondria (thus ensuring less structural limitation to observe their appreciable swelling) and fully competent respiratory chain with three invariantly functioning energy conservation points, including Complex I, that can be involved in induction of the canonical Ca²⁺/P_i-dependent mitochondrial permeability transition (mPTP pore) with an increased open probability when electron flux increases (Fontaine et al. J Biol Chem 273:25734–25740, 1998; Bernardi et al. FEBS J 273:2077–2099, 2006). High-amplitude swelling and collapse of the membrane potential were used as parameters for demonstrating pore opening. Previously (Kovaleva et al. J Bioenerg Biomembr 41:239–249, 2009; Kovaleva et al. Biochemistry (Moscow) 75:297–303, 2010) we have shown that mitochondria from Y. lipolytica and D. magnusii were very resistant to the Ca²⁺ overload combined with varying concentrations of P_i, palmitic acid, SH-reagents, carboxyatractyloside (an inhibitor of ADP/ATP translocator), as well as depletion of intramitochondrial adenine nucleotide pools, deenergization of mitochondria, and shifting to acidic pH values in the presence of high [P_i]. Here we subjected yeast mitochondria to other conditions known to induce an mPTP in animal and plant mitochondria, namely to Ca²⁺ overload under hypoxic conditions (anaerobiosis). We were unable to observe Ca²⁺-induced high permeability of the inner membrane of D. magnusii and Y. lipolytica yeast mitochondria under anaerobic conditions, thus suggesting that an mPTP-like pore, if it ever occurs in yeast mitochondria, is not coupled with the Ca²⁺ uptake. The results provide the first demonstration of ATP-dependent energization of yeast mitochondria under conditions of anaerobiosis.     

Plant Uncoupling Mitochondrial Protein Activity in Mitochondria Isolated from Tomatoes at Different Stages of Ripening

In the present study we have observed a higher state of coupling in respiring mitochondriaisolated from green as compared to red tomatoes (Lycopersicon esculentum, Mill.). Greentomato mitochondria produced a membrane potential () high enough to phosphorylate ADP,whereas in red tomato mitochondria, BSA and ATP were required to restore to the levelof that obtained with green tomato mitochondria. This supports the notion that such uncouplingin red tomato mitochondria is mediated by a plant uncoupling mitochondrial protein (PUMP;cf. Vercesi et al., 1995). Nevertheless, mitochondria from both green and red tomatoes exhibitedan ATP-sensitive linoleic acid (LA)-induced decrease providing evidence that PUMP isalso present in green tomatoes. Indeed, proteoliposomes containing reconstituted green or redtomato PUMP showed LA uniport and LA-induced H⁺ transport. It is suggested that the higherconcentration of free fatty acids (PUMP substrates) in red tomatoes could explain the lowercoupling state in mitochondria isolated from these fruits.     

Visualization of mitochondria and nuclei in living plant cells by the use of a potential-sensitive fluorescent dye

Abstract Cationic potential-sensitive dyes have previously been used to selectively stain mitochondria in living animal cells (Johnson, Walsh & Chen, 1980; Johnson et al., 1981). The present work demonstrates that the cyanine dye 3,3′-dihexyloxacarbocyanine iodide (DiOC₆(3)) can also be used as a mitochondrial stain in living plant cells. The stained mitochondria were easily visualized by fluorescence microscopy. The accumulation of DiOC₆(3) in mitochondria seemed to be potential-dependent since it was prevented by protonophores, valinomycin and inhibitors of electron transport. It was often observed that DiOC₆(3) also stained the nuclear membrane of some cells. This fluorescence, limited to the perinuclear region, was possibly due to a potential across one or both nuclear membranes, although it was not completely dissipated by any of the ionophores or inhibitors tested. Our observations demonstrate the usefulness of using DiOC₆(3) for studying relative membrane potentials of plant mitochondria and, perhaps, other organelles and membrane systems in living plant cells.     

Mitochondrial iron metabolism in plants: frataxin comes into play

Friedreich ataxia (FRDA), an autosomal recessive neurological dysfunction that severely impairs motor coordination and reduction of life expectancy in humans, is caused by a deficiency in frataxin, a nuclear-encoded mitochondrial protein. Recently, a frataxin ortholog has been identified in Arabidopsis thaliana, named AtFH, with a transit peptide for localization in mitochondria and 65% sequence identity with human frataxin (Busi et al. FEBS Lett 576:141–144, 2004). Complementation of S. cerevisiae mutant strain Δyfh1 deficient in frataxin with AtFH, proved that the plant isoform is a functional protein, able to restore normal respiration and growth rates in the mutant yeast (Busi et al. FEBS Lett 576:141–144, 2004). AtFH is localized in mitochondria as its animal counterparts (Busi et al. Plant J 48:873–882, 2006); it is expressed mainly in flowers and developing embryos and it is an essential protein, since the knocking out of AtFH gene causes arrest of embryo development at the globular stage (Vazzola et al. FEBS Lett 581:667–672, 2007). A T-DNA insertional A.thaliana mutant showing a greater than 50% reduction of AtFH protein content, named atfh-1, has impaired activity of two mitochondrial enzymes possessing [Fe-S] clusters: aconitase and succinate dehydrogenase (Busi et al. Plant J 48:873–882, 2006). The results obtained in the last ten years on animal systems can contribute, without any doubt, to the elucidation of the role of frataxin in plant mitochondria; however, mitochondria of photosynthetically active cells, differently from animal ones, are not the major source of Reactive Oxygen Species (ROS) which could suggest possible differences in function between plant and animal frataxin.     

A new type of mitochondrial mutation in Paramecium

Summary The mutant cl₁ of Paramecium previously described (Sainsard et al., 1974) differs from wild-type by a single recessive nuclear gene, cl ₁, and its mitochondria, M^cl, can be distinguished from wild-type mitochondria, M⁺, (Sainsard-Chanet, 1976). In order to determine the nature of the difference between M^cl and M⁺ mitochondria, the stability of the M^cl phenotype was studied. It was found that the M^cl character behaves like a mitochondrial mutation. Associated with a wild-type nucleus, M^cl mitochondria retain indefinitely their distinctive properties, i.e. compatibility with a cl ₁/cl ₁ nucleus and decrease of the cellular growth rate and cytochrome aa₃ content. Some properties of the cl₁ mutant which is in fact a double nuclear-mitochondrial mutant with the mitochondrial mutation partially suppressing the nuclear one are discussed.     

Effects of Desmin Gene Knockout on Mice Heart Mitochondria

In heart tissue from mice lacking the intermediate filament (IF) desmin, mitochondria show an abnormal shape and distribution (Thornell et al., 1997). In the present study we have isolated heart mitochondria from desmin null (D–/–) and control (D+/+) mice, and analyzed their composition by SDS–PAGE, immunoblotting, and enzyme measurements. We found both in vitro and in situ that the conventional kinesin, the microtubule-associated plus-end directed motor, was frequently associated with D+/+ heart mitochondria, but not with D–/– heart mitochondria, suggesting that the positioning of mitochondria in heart is a dynamic event involving the IF desmin, the molecular motor kinesin, and, most likely, the microtubules (MT) network. Furthermore, an increased capacity in energy production was found, as indicated by a threefold higher creatine kinase activity in heart mitochondria from D–/– compared to D+/+ mice. We also observed a significantly lower amount of cytochrome c in heart mitochondria from D–/– mice, and a relocalization of Bcl-2, which may indicate an apoptotic condition in the cell leading to the earlier reported pathological events, such as cardiomyocytes degeneration and calcinosis of the heart (Thornell et al., 1997).     

The mitochondrial tricarboxylate carrier

The tricarboxylate carrier has recently been purified from rat liver mitochondria by three distinct scientific groups using different methods. A 37–38-kDa protein has been prepared by silca gel 60 chromatography by our group (Claeys and Azzi, 1989; Glerumet al., 1990). The specific citrate transport activity of this preparation is not significantly different from that measured in mitochondria and it is inhibitable by 1,2,3-benzenetricarboxylic acid. Bisacciaet al. (1990) have reported the isolation of a 30-kDa protein by Celite 535 chromatography, and Kaplan's group (Kaplanet al., 1990) have isolated a 32.5-kDa protein by Matrex Orange, Matrex Blue, and Affi-Gel chromatography. Peptide mapping has failed to support any structural homologies between the 37–38-kDa and the 30–32.5-kD proteins. The 38-kD protein is N-terminally blocked. The peptides obtained by several cleavage procedures have been partially sequenced. Their sequence information has been used to obtain different cDNA clones by a dual approach, the polymerase chain reaction and screening of a ZAP cDNA library. The largest cDNA which could be isolated is 2,986 bp in length and contains a 1071-bp-long open reading frame and an unusually long 3 untranslated region, both of which have been completely sequenced. The protein sequence of the carrier from the first in-frame methionine is 322 amino acids in length and exhibits a molecular mass of 35,546. Comparison of the protein sequence to the sequences of the four members of the mitochondrial carrier protein family (ADP/ATP carrier, phosphate carrier, 2-oxoglutarate/malate carrier, and uncoupling protein) does not reveal significant similarity (cf. Walkeret al., 1987). A tripartite internal homology, which is a characteristic of these proteins, is not present in the sequence of the tricarboxylate carrier protein. The mRNA for the tricarboxylate carrier is expressed in rat liver and brain, but not in rat heart.     

Increase of membrane permeability of mitochondria isolated from water stress adapted potato cells

In order to gain some insight into mitochondria permeability under water stress, intact coupled mitochondria were isolated from water stress adapted potato cells and investigations were made of certain transport processes including the succinate/malate and ADP/ATP exchanges, the plant mitochondrial ATP-sensitive potassium channel (PmitoK_ATP) and the plant uncoupling mitochondrial protein (PUMP). The V _maxL values measured for succinate/malate and ADP/ATP carriers, as photometrically investigated, as well as the same values for the Pmito_ATP and the PUMP were found to increase; this suggested that mitochondria adaptation to water stress can cause an increase in the membrane permeability.     

Induction of a non-specific permeability transition in mitochondria from Yarrowia lipolytica and Dipodascus (Endomyces) magnusii yeasts

In this study we used tightly-coupled mitochondria from Yarrowia lipolytica and Dipodascus (Endomyces) magnusii yeasts, possessing a respiratory chain with the usual three points of energy conservation. High-amplitude swelling and collapse of the membrane potential were used as parameters for demonstrating induction of the mitochondrial permeability transition due to opening of a pore (mPTP). Mitochondria from Y. lipolytica, lacking a natural mitochondrial Ca²⁺ uptake pathway, and from D. magnusii, harboring a high-capacitive, regulated mitochondrial Ca²⁺ transport system (Bazhenova et al. J Biol Chem 273:4372–4377, 1998a; Bazhenova et al. Biochim Biophys Acta 1371:96–100, 1998b; Deryabina and Zvyagilskaya Biochemistry (Moscow) 65:1352–1356, 2000; Deryabina et al. J Biol Chem 276:47801–47806, 2001) were very resistant to Ca²⁺ overload. However, exposure of yeast mitochondria to 50–100 μM Ca²⁺ in the presence of the Ca²⁺ ionophore ETH129 induced collapse of the membrane potential, possibly due to activation of the fatty acid-dependent Ca²⁺/nH⁺-antiporter, with no classical mPTP induction. The absence of response in yeast mitochondria was not simply due to structural limitations, since large-amplitude swelling occurred in the presence of alamethicin, a hydrophobic, helical peptide, forming voltage-sensitive ion channels in lipid membranes. Ca²⁺- ETH129-induced activation of the Ca²⁺/H⁺-antiport system was inhibited and prevented by bovine serum albumin, and partially by inorganic phosphate and ATP. We subjected yeast mitochondria to other conditions known to induce the permeability transition in animal mitochondria, i.e., Ca²⁺ overload (in the presence of ETH129) combined with palmitic acid (Mironova et al. J Bioenerg Biomembr 33:319–331, 2001; Sultan and Sokolove Arch Biochem Biophys 386:37–51, 2001), SH-reagents, carboxyatractyloside (an inhibitor of the ADP/ATP translocator), depletion of intramitochondrial adenine nucleotide pools, deenergization of mitochondria, and shifting to acidic pH values in the presence of high phosphate concentrations. None of the above-mentioned substances or conditions induced a mPTP-like pore. It is thus evident that the permeability transition in yeast mitochondria is not coupled with Ca²⁺ uptake and is differently regulated compared to the mPTP of animal mitochondria.     

Neurotensin receptors: Binding properties,transduction pathways,and structure

Summary Neurotensin is a 13-amino acid peptide (pGlu-Leu-Tyr-Glu-Asn-Lys-Pro-Arg-Arg-Pro-Tyr-Ile-Leu) originally isolated from hypothalami (Carraway and Leeman, 1973) and later from intestines (Kitabgiet al., 1976) of bovine. The peptide is present throughout the animal kingdom, suggesting its participation to important processes basic to animal life (Carrawayet al., 1982). Neurotensin and its analogue neuromedin-N (Lys-Ile-Pro-Tyr-Ile-Leu) (Minaminoet al., 1984) are synthesized by a common precursor in mammalian brain (Kislauskiset al., 1988) and intestine (Dobneret al., 1987). The central and peripheral distribution and effects of neurotensin have been extensively studied. In the brain, neurotensin is exclusively found in nerve cells, fibers, and terminals (Uhlet al., 1979), whereas the majority of peripheral neurotensin is found in the endocrine N-cells located in the intestinal mucosa (Orciet al., 1976; Helmstaedteret al., 1977). Central or peripheral injections of neurotensin produce completely different pharmacological effects (Table I) indicating that the peptide does not cross the blood-brain barrier. Many of the effects of centrally administered neurotensin are similar to those of neuroleptics or can be antagonized by simultaneous administration of TRH (Table I). The recently discovered nonpeptide antagonist SR 48692 (Gullyet al., 1993) can inhibit several of the central and peripheral effects of neurotensin (Table I).Like many other neuropeptides, neurotensin is a messenger of intracellular communication working as a neurotransmitter or neuromodulator in the brain (Nemeroffet al., 1982) and as a local hormone in the periphery (Hirsch Fernstromet al., 1980). Thus, several pharmacological, morphological, and neurochemical data suggest that one of the functions of neurotensin in the brain is to regulate dopamine neurotransmission along the nigrostriatal and mesolimbic pathways (Quirion, 1983; Kitabgi, 1989). On the other hand, the likely role of neurotensin as a parahormone in the gastrointestinal tract has been well documented (Rosell and Rökaeus, 1981; Kitabgi, 1982).Both central and peripheral modes of action of neurotensin imply as a first step the recognition of the peptide by a specific receptor located on the plasma membrane of the target cell. Formation of the neurotensin-receptor complex is then translated inside the cell by a change in the activity of an intracellular enzyme. This paper describes the binding and structural properties of neurotensin receptors as well as the signal transduction pathways that are activated by the peptide in various target tissues and cells.     

Uncoupling activity of fatty acids in liver mitochondria in the presence of substrates of ADP/ATP- and aspartate/glutamate antiporters is increased under oxidative stress

It is shown that upon oxidation of succinate in the presence of rotenone and antioxidant Trolox (or pyruvate) in liver mitochondria of mature rats (9–12-month old) the respiration stimulated by palmitate is suppressed by ADP (the substrate of ADP/ATP-antiporter) and aspartate (the substrate of aspartate/glutamate antiporter). However, it was found that in the presence of the oxidative agent tert-butylhydroperoxide neither ADP nor aspartate is effective even at their joint action. In the presence of ADP and aspartate, uncoupling activity of palmitate is minimal, since the lipid peroxidation is inhibited by Trolox or pyruvate, and rises as the accumulation rate of conjugated dienes increases, reaching the maximal value at the oxidative stress caused by tert-butylhydroperoxide. In liver mitochondria of senile rats (22–26-month old) at high intensity of lipid peroxidation, ADP and aspartate do not affect the uncoupling activity of palmitate (Samartsev and Kozhina, 2008, Biochemistry (Mosc.), vol. 73, no. 7, pp. 783–790). Comparative studies have shown that in liver mitochondria of mature and senile rats at the similar accumulation rate of the conjugated dienes in the presence of ADP and aspartate, the uncoupling activity of palmitate reaches the same level relative to the maximal activity. We conclude that an enhancement of free radical reactions and lipid peroxidation in liver mitochondria can result in an increase of protonophore uncoupling activity of fatty acids with the involvement of ADP/ATP- and aspartate/glutamate antiporters due to the suppression of the ability of physiological substrates of these carriers of ADP and aspartate to inhibit the uncoupling process.     

Interaction of yeast mitochondria with fatty acids and mitochondria-targeted lipophilic cations

The effect of fatty acids and mitochondria-targeted lipophilic cations (SkQ1, SkQ3, MitoQ, and C₁₂TPP) on tightly-coupled mitochondria from yeasts Dipodascus (Endomyces) magnusii and Yarrowia lipolytica was investigated. Micromolar concentrations of saturated and unsaturated fatty acids were found to decrease the membrane potential, which was recovered almost totally by ATP and BSA. At low, micromolar concentrations, mitochondria-targeted lipophilic cations are “relatively weak, mild uncouplers”, at higher concentrations they inhibit respiration in state 3, and at much higher concentrations they induce swelling of mitochondria, possibly due to their prooxidant and detergent action. At very low, not uncoupling concentrations, mitochondria-targeted lipophilic cations profoundly promote (potentiate) the uncoupling effect of fatty acids. It is conceivable that the observed uncoupling effect of lipophilic cations can be, at least partially, due to their interactions with the endogenous pool of fatty acids.     

Influence of CSP 310 and CSP 310-like proteins from cereals on mitochondrial energetic activity and lipid peroxidation in vitro and in vivo

Background  

The development of chilling and freezing injury symptoms in plants is known to frequently coincide with peroxidation of free fatty acids. Mitochondria are one of the major sources of reactive oxygen species during cold stress. Recently it has been suggested that uncoupling of oxidation and phosphorylation in mitochondria during oxidative stress can decrease ROS formation by mitochondrial respiratory chain generation. At the same time, it is known that plant uncoupling mitochondrial protein (PUMP) and other UCP-like proteins are not the only uncoupling system in plant mitochondria. All plants have cyanide-resistant oxidase (AOX) whose activation causes an uncoupling of respiration and oxidative phosphorylation. Recently it has been found that in cereals, cold stress protein CSP 310 exists, and that this causes uncoupling of oxidation and phosphorylation in mitochondria.     

On the theory of the cardiovascular system

Most theoretical studies of the circulation have focussed on the transmission line properties of arteries. Only a small number of papers have dealt with the circulation as a closed (lumped) system with two pumps connected by the lesser and greater circulation (Beneken, inCirculatory Analog Computers, No. Holland Publ. Co., Amsterdam, 1963; Defares,et al., inCirculatory Analog Computers, No. Holland Publ. Co., Amsterdam, 1963; Grodins,Quart. Rev. of Biology,34, 93, 1959; Guyton,Cardiac Output and its Regulation, Saunders Publ. Co., New York, 1963). F. W. Cope's recent studies in this journal (Bull. Math. Biophysics,22, 19, 1960;23, 337, 1961;24, 137, 1962) deal with essentially the same questions, although here the circuit is not “closed”. We have attempted to extend the analysis of the areflex (closed) circulation. The complete study is reported elsewhere (Defares,et al., Acta Physiol, et Parmac. Neerl., 1963).     

Interactions between ellipticine derivatives and the mitochondrial respiratory chain

The interaction of monomeric and dimeric derivatives of ellipticine (a plant alkaloid) with plant mitochondria was studied by following electron transport and phosphorylative activities. It is shown that these compounds act as powerful inhibitors of the electron transfer in the terminal enzyme, i.e. cytochrome c oxidase, (presumably in the vicinity of cytochromes a-a₃) and exhibit uncoupling activities. The possibility of mitochondrial inner membrane being one of the sites of action of ellipticine derivatives is discussed in relation with their well-known pharmacological properties.     

In Phosphorylating <Emphasis Type="Italic">Acanthamoeba castellanii</Emphasis> Mitochondria the Sensitivity of Uncoupling Protein Activity to GTP Depends on the Redox State of Quinone

In isolated Acanthamoeba castellanii mitochondria respiring in state 3 with external NADH or succinate, the linoleic acid-induced purine nucleotide-sensitive uncoupling protein activity is able to uncouple oxidative phosphorylation. The linoleic acid-induced uncoupling can be inhibited by a purine nucleotide (GTP) when quinone (Q) is sufficiently oxidized, indicating that in A. castellanii mitochondria respiring in state 3, the sensitivity of uncoupling protein activity to GTP depends on the redox state of the membranous Q. Namely, the inhibition of the linoleic acid-induced uncoupling by GTP is not observed in uninhibited state 3 respiration as well as in state 3 respiration progressively inhibited by complex III inhibitors, i.e., when the rate of quinol (QH₂)-oxidizing pathway is decreased. On the contrary, the progressive decrease of state 3 respiration by declining respiratory substrate availability (by succinate uptake limitation or by decreasing external NADH concentration), i.e., when the rate of Q-reducing pathways is decreased, progressively leads to a full inhibitory effect of GTP. Moreover, in A. castellanii mitochondria isolated from cold-treated cells, where a higher uncoupling protein activity is observed, the inhibition of the linoleic acid-induced proton leak by GTP is revealed for the same low values of the Q reduction level.     

(Brady)Rhizobium-plant communications involved in infection and nodulation

Conclusion The interactions between(Brady)Rhizobium and legume plants involves many interesting problems. In the last ten years, there were remarkable experiments which have detected excreted flavonoid compounds at pmol levels from plant roots, which induce(Brady)Rhizobium nod gene expression (Long 1989, Nap and Bisseling 1990, Dénariéet al. 1992, Schlamanet al. 1992). The responses of rhizobial genes to the various kinds of chemical compound are different (Maxwellet al. 1989, Zaatet al. 1989, Davis and Johnston 1990, Hartwiget al. 1990, Hungriaet al. 1992). The resolution of pSym genes controlling those mechanisms makes way for the long-term goal of introducing nitrogen fixation ability into nonlegume plants. Recently, some experiments have shown thatRhizobium and other nitrogen fixing bacteria form nodule-like strutures on rice, barley or wheat (Al-Mallah 1989, Jinget al. 1990, Rolfe and Bender 1991). Some O₂ protection mechanism instead of leghemoglobin must be needed for nitrogen fixation byRhizobium or other N₂-fixing bacteria which have invaded in the nonlegume root tissue. The isolation of the plant mutants or preparation of transgenic plants capable of hyper-nodule formation having efficient nitrogen fixation ability may be major goals. For the attainment of these goals, transformation of a foreign genome (nif-ornod gene cassette) into the plant cell might be a good way to proceed (Barkeret al. 1990). It is also necessary to clarify the relationships between the level of relative endogenous plant hormones and the exchange of the differentiation of the root tissue to the nodule tissue. This phenomenon of redifferentiation of plant tissue by the results from(Brady)Rhizobium and legume communications will be an important approach likely to lead to solve the molecular basis of plant having “TOTIPOTENCY”.