Research Note Involvement of the superoxide dismutase enzyme in the mycorrhization process Justo Arines, Antonio Vilarino and José M. Palma Arines, J., Vilarino, A'. & Palma, J. M. 2 1994. Involvement of the superoxide dismutase enzyme in the mycorrhization process. Agricultural Science in Fin- land 3: 303-307. ('lnstituto de Investigaciones Agrobiolögicas de Galicia (CSIC), Apdo 122, 15080-Santiago de Compostela, Spain and, 2 Estaci6n Experimental del Zaidm (CSIC), Apdo 419, 18080-Granada, Spain.) The survivability and quality of micropropagated plants can be improved through mycorrhization. We consider that mycorrhization is important in supporting plants under stress conditions. The mechanism is not fully understood, but it seems that the enzymes involved in alleviating stress are important factors. We therefore studied superoxide dismutase (SOD; EC 1.15.1.1) isozymes. Insight is provided into the generation of superoxide radicals (SORs) and the detoxification role of SOD isozymes. Examples of how the expression of this enzyme changes in symbi- otic processes are also given. Key words: activated oxygen species, arbuscular mycorrhizal fungi, isozymes, oxi- dative stress, pathogenesis, superoxide radical Introduction Arbuscular mycorrhizal fungi (AMF) are known to be able to colonize the roots of most vascular plants and, under natural conditions, to provide a partnership with a complex system of extraradi- cal hyphae. This extraradical system contributes to the uptake of water and nutrients and creates a modified rhizosphere favourable for plant pro- tection in stress situations (Sylvia and Williams 1992). This is appreciated by mycorrhizologists, but not by all plant growers, who still do not realize that when cuttings are introduced into the soil the rooted plants become mycorrhizal, and their establishment and growth in the field are thus improved. The technique of ‘ in-vitro ’ micropropagation is of special interest in plant propagation. Exper- iments made using this technique have shown that inoculation of recently rooted plants at the weaning stage improves the survival of the plants because they are much better able to withstand stress in a changing habitat. Growth differences between mycorrhizal and non-mycorrhizal Pru- nus cemsifera are very large (Fortuna et al. 1992), confirming the importance of mycorrhiza inoculation of micropropagated plants. Mycorrhiza appears to play a key role in improving the ‘ex- vitro' development of micropropagated Avocado plants (Azcon-Aguilar et al. 1992) and the sur- vival of micropropagated Anthyllis cytisoides (Salamanca et al. 1992). Moreover, the accli- matization phase has been reduced to eight weeks following mycorrhization with Anthyllis (Sala- manca et al. 1992). As there is some degree of specificity in the mycorrhization of micropropa- gated pineapple plants (Guillemin et al. 1992), 303 Agricultural Science in Finland 3 (1994) Research Note the growth effects are not always comparable because conditions for establishing the symbiot- ic change within plant and fungus species vary. This is probably a consequence of intrinsic fac- tors and should be further investigated. The in- volvement of various enzymes was recently re- viewed by Gianinazzi (1991). Enzymes participating in detoxification of su- peroxide radicals (SORs) are important during stress situations (Tsang et al. 1991). We, there- fore, consider it necessary to study the extent of superoxide dismutase (SOD) involvement in the mycorrhization process. Overview of stress-causing oxygen derivatives Although oxygen is an essential element for life, its presence in living organisms implies that some metabolic by-products can also be formed in the cellular niche. In the presence of an adequate electron donor and slight energy activation, the reactive form of the SOR (O, ) is produced. There- after, and under acidic conditions, the presence of electron donors leads to generation of the per- oxide anion, the hydroxyl radical and, finally, water (Elstner 1987). All these oxygen-activat- ed forms can be detoxified by different compounds usually present in the cell, the mechanisms cho- sen being dependent on the particular situation and cellular location. Biologically, the most dangerous by-product is the hydroxyl radical because of its high reactivi- ty with chemical bonds, which causes oxidation and cleavage of the unsaturated bonds in mem- brane lipids termed lipid peroxidation. Hydroxyl radicals are formed in living beings by a metal- catalized Haber-Weiss reaction, where H 2 0 2 and 0 2 are precursors. Furthermore, the production of H 20 2 is also partially dependent on either an enzyme-dependent or an enzyme-independent dis- mutation of the SOR. The oxidative stress gener- ated by these radicals within the cell can be coun- teracted by both enzymatic and non-enzymatic mechanisms. Superoxide radicals and their dismutation Superoxide radicals are biologically generated during both mitochondrial respiration and photo- synthesis. The steady-state level of SORs in in- tact mitochondria, where SOD is present, is esti- mated to be about 10" 11 to KT 12 M. In washed mitochondria from which SODs are removed, SORs are estimated to account for about 4% of total oxygen. These radicals are usually generat- ed in mitochondria, chloroplasts, the microsomal fraction, nuclei (Hassan and Scandalios 1990) and peroxisomes (Del Rio et al. 1992). Almost all aerobic living organisms are pro- tected against the damaging action of SORs by superoxide dismutases, metalloenzymes which catalyze the conversion of O, to H,O, and 0,, H 2 0 2 being then metabolized by catalase and/or peroxidases. Three types of SOD have been char- acterized on the basis of the metal accompanying the protein: CuZn-SOD, Mn-SOD and Fe-SOD. CuZn-SOD is the most abundant in eukaryotic organisms and is mainly located in the cytosol and in chloroplasts, whereas Mn-SOD is usually located in mitochondria and in peroxisomes. Fe- SOD was initially found in prokaryotes, but has recently been detected in chloroplasts and in plant peroxisomes. There is little difference between organisms with regard to CuZn-SODs, and their amino acid sequences show a high degree of sim- ilarity (homodimer with 32 kDa MW). Mn-SODs are mainly tetrameric with 75-95 kDa MW in most organisms, and are phyllogenetically relat- ed to Fe-SODs. Role of superoxide dismutases in symbiotic systems In addition to their normal activity in plants, SODs are also associated with stress situations. The reg- ulation of SODs in plants exposed to environ- mental stress has been studied by Tsang et al. (1991) by determining the presence of mRNA coding for different SODs in Nicotiana under dif- ferent stress conditions (light, temperature, Para- 304 Agricultural Science in Finland 3 (1994) Research Note quat). Their conclusion was that oxidative stress was a component of environmental stress. They demonstrated that with exposure to Paraquat, the chloroplastic Fe-SOD mRNA increased and that it was not a general reflection of other photosyn- thetic components. This finding suggests that the Fe-SOD gene expression is controlled by the ox- idative stress itself, and is not part of a global response. Further, in mitochondrial Mn-SOD and cytosolic CuZn-SOD, the abundance of mRNA is also increased. Therefore, it is likely that, al- though SORs are generated within a specific com- partment, the damage can affect other compart- ments of the cell. Of particular interest was the finding that under illuminated conditions spray- ing leaves with 5 x 10~5 M Paraquat increased the quantity of Fe-SODchl, Mn-SODmit and CuZn- SODcyt mRNAs about 40, 30 and 15-fold, re- spectively. Light itself caused an increase in SODs because SORs are generated primarily by the leak- age of electrons from photosystem I and from ferredoxin. An interesting study has recently suggested that, in pathogenic situations, the expression of induc- ible SODs is related to resistance or susceptibili- ty to rust in coffee plants (Daza et al. 1993). Coffee leaves resistant to infection by the rust Hemileia vastatrix show a different SOD pattern, with two extra CuZn-SODs. This hypothesis is supported by the fact that two different coffee plant cultivars, which are resistant to infection by Hemileia vastatrix, share the same SOD pat- tern. A different strategy is adopted by some Pha- seolus vulgaris cultivars, which are resistant to Uromyces phaseoli (Buonario et al. 1987). An increase in SOD activity has been detected in susceptible and resistant plants, with selective stimulation of SOD activity taking place: the man- ganese-enzyme in the susceptible cultivar and the cuprozinc-enzyme in the hypersensitive cultivars. Thus an increase in the Mn enzyme seems to be more closely related to the biotrophic phase of parasitism in the host cell, but an increase in the CuZn enzyme to the necrotic process associated with hypersensitivity (Buonario et al. 1987). The first reference to SODs in symbiotic sys- tems was by Becana et al. (1989) in their study of free-living bacteria, bacteroids and nodules of different legumes with Rhizobium or Bradyrhizo- bium. Different patterns were found in each case. With Rhizobium, the transformation into bacter- oids induced the expression of a new Mn-SOD. In our laboratory we recently studied the Tri- folium pmtense-Glomus mosseae system (Palma et al. 1993). G. mosseae spores contained only one CuZn-SOD (G.m. CuZn-SOD); the non-my- corrhizal root had one Mn-SOD (Mn-SOD I) and two CuZn-SODs (CuZn-SOD 1 and CuZn-SOD II). However, the mycorrhizal root had six SOD isozymes; besides the plant SODs indicated above, another Mn-SOD (Mn-SOD II) and two new CuZn-SODs (G.m. CuZn-SOD and mycCuZn- SOD) were detected. We propose that mycCuZn- SOD and Mn-SOD II were induced by the sym- biosis, although we could not determine the ori- gin of these SODs. Furthermore, the activity of CuZn-SOD I, which appeared in both kinds of root, was strongly increased after mycorrhization. Five isozymes were also detected in nodules of red clover: the three plant SODs plus two new Mn-SODs (nodMn-SOD and Mn-SOD II). nod- Mn-SOD was exclusively expressed in nodules, whereas nodule Mn-SOD II behaved like the Mn- SOD II found in mycorrhizal roots, and we pos- tulate that it may be a uniform response of the plant to colonization by a foreign organism. We think that in red clover, both symbioses induced the expression of new SOD isozymes, suggesting that activated oxygen species must be implicated in the symbiosis. This was not the case for the Pisum sativum-Glomus mosseae symbiosis. No new isozymes were detected in mycorrhizal roots, but total activity was higher, the extra activity being accounted for by a CuZn-SOD (Arines et al. 1994). Thus the symbiosis implies higher ac- tivity in SODs, as do other stress situations, per- haps because of the higher cellular activity asso- ciated with this process. Results obtained by Buonario et al. (1987) and Daza et al. (1993) show that various strate- gies may be adopted in the interaction between pathogens and plants. In mycorrhizal symbiosis, we have found that new isozymes are expressed in T. pratense-G. mosseae but not in P. sativum- 305 Agricultural Science in Finland 3 (1994) Agricultural Science in Finland 3 (1994) G. mosseae. The difference may be related to the different efficiency of the symbiosis in the two plants: a higher efficiency in the colonization per- centage was obtained with red clover, suggesting that the expression of new isozymes may allow the plant to cope with the excess SORs generated during the entrance of a foreign organism. How- ever, in peas, in which a lower percentage colo- nization was determined, the plants’ own SOD activity may be sufficient without inducing new isozymes. We consider that the activity of SODs is affected directly or indirectly by mycorrhiza- tion, although, as happens in plant-pathogen re- lationships, different strategies may be followed. Further research is needed to understand the im- portance of SOD in mycorrhization. References Arises, J., Quintela, M., Vilarino, A. & Palma, J. M. 1994. Protein patterns and superoxide dismutase activ- ity in non-mycorrhizal and arbuscular mycorrhizal Pis- uin sativum L, plants. Plant and Soil (in press). Azcon-Aguilar, C., Barcelö, A., Vidal, M. T. & de la Vina, G. 1992. Further studies on the influence of mycorrhizas on growth and development of microprop- agated avocado plants. Agronomic 12; 837-840. Becana, M., Paris, F.J., Sandalio, L.M. & del Rfo, L.A. 1989. Isoenzymes of superoxide dismutase in nodules of Phaseolus vulgaris L., Pisum sativum L., and Vigna unguiculata (L.) Walp. Plant Physiololy 90: 1286-1292. Buonario, R,, della Torre, G. & Montalbini, P. 1987. Soluble superoxide dismutase (SOD) in susceptible and resistant host-parasite complexes of Phaseolus vulgaris and Uromyces phaseoli. Physiological and Molecular Plant Pathology 31: 173-184. Daza, M.C., Sandalio, L.M., Quijano-Rico, M. & del Rfo, L.A. 1993. Isoenzyme pattern of superoxide dis- mutase in coffee leaves from cultivars susceptible and resistant to the rust Hemileia vastatrix. Journal of Plant Physiology 141: 521-526. Del Rio, L. A., Sandalio, L. M., Palma, J. M., Bueno, P. & Corpas, F. J. 1992. Metabolism of oxygen radicals in peroxisomes and cellular implications. Free Radi- cals in Biology and Medicine 13: 557-580. Elstner, E.F. 1987. Metabolism of activated oxygen spe- cies. In: Stumpf, P.K. & Conn, E.E. (eds.). The Bio- chemistry of Plants; A comprehensive treatise, Vol, 11, Academic Press, London, p. 253-315. Fortuna, P., Citernesi, S., Morini, S., Giovannetti, M. & Loreti, F. 1992. Infectivity and effectiveness of different species of arbuscular mycorrhizal fungi in micropropagated plants of MrS 2/5 plum rootstock. Agronomic 12: 825-829. Gianinazzi, S, 1991. Vesicular-arbuscular (endo-) mycor- rhizas: cellular, biochemical and genetic aspects. Agri- culture, Ecosystems and Environment 35: 105-119. Guillemin, J.P., Gianinazzi, S. & Trouvelot, A. 1992. Screening of arbuscular endomycorrhizal fungi for es- tablishment of micropropagated pineapple plants. Agronomie 12: 831-836. Hassan, H.M. & Scandalios, J.G, 1990. Superoxide dis- mutases in aerobic organisms. In: Stress Responses in Plants: Adaptation and Acclimation Mechanisms, Wi- ley-Liss, Inc. p. 175-199. Palma, J.M., Longa, M.A., del Rfo, L.A. & Arines, J. 1993. Superoxide dismutase in vesicular arbuscular- mycorrhizal red clover plants. Physiologia Plantarum 87:77-83. Salamanca, C.P., Herrera, M.A. & Barea, J.M. 1992. Mycorrhizal inoculation of micropropagated woody leg- umes used in revegetation programmes for desertified Mediterranean ecosystems, Agronomie 12: 869-872. Sylvia, D. & Williams, S.E. 1992. Vesicular-arbuscular mycorrhizae and environmental stress. In: Bethlenfal- vay, G.J. & Lindeman, R.G. (eds.). Mycorrhizae in Sustainable Agriculture. ASA Special Publication No. 54, Madison, p. 101-124. Tsang, W.T., Bowler, C., Herouart, D,, Van Camp, W,, Villarroel, R., Gentello, C., Van Montagu, M. & Inzé, D. 1991. Differential regulation of superoxide dismutases in plants exposed to environmental stress. The Plant Cell 3: 783-792. Manuscript received January 1994 306 Research Note SELOSTUS Superoksidi-dismutaasientsyymin merkitys mykorritsan muodostuksessa Justo Arines 1, Antonio Vilardmo 1 ja José M. Palma 2 1 Instituto de Investigaciones Agrobiolögicas de Galicia (CSIC), Espanja ja 2 Estaciön Experimental del Zaidin (CSIC), Espanja Mykorritsan avulla voidaan lisätä mikrolisättyjen kasvien eloonjäämistä ja parantaa kasvien laatua. Tiedetään, että mykorritsa auttaa merkittävästi kasveja vaikeissa olosuh- teissa, Tämän ilmiön mekanismia ei täysin tunneta, mutta kasvien stressiä lievittävillä entsyymeillä näyttää olevan siinä tärkeä merkitys. Tästä syystä tutkimme superoksidi- dismutaasientsyymejä (SOD; EC 1.15.1.1). Superoksidi- radikaalien (SOR) syntymistä ja SOD-isotsyymien merki- tystä detoksifikaatiossa selvitettiin myös yksityiskohtai- sesti. Myös esimerkkejä näiden entsyymien ilmenemisen muuttumisesta symbioottisissa tapahtumissa on annettu. 307 Agricultural Science in Finland 3 (1994)Research Note