Two distinct ferredoxins from Rhodobacter capsulatus: complete amino acid sequences and molecular evolution

Two distinct ferredoxins were purified from Rhodobacter capsulatus SB1003. Their complete amino acid sequences were determined by a combination of protease digestion, BrCN cleavage and Edman degradation. Ferredoxins I and II were composed of 64 and 111 amino acids, respectively, with molecular weights of 6,728 and 12,549 excluding iron and sulfur atoms. Both contained two Cys clusters in their amino acid sequences. The first cluster of ferredoxin I and the second cluster of ferredoxin II had a sequence, CxxCxxCxxxCP, in common with the ferredoxins found in Clostridia. The second cluster of ferredoxin I had a sequence, CxxCxxxxxxxxCxxxCM, with extra amino acids between the second and third Cys, which has been reported for other photosynthetic bacterial ferredoxins and putative ferredoxins (nif-gene products) from nitrogen-fixing bacteria, and with a unique occurrence of Met. The first cluster of ferredoxin II had a CxxCxxxxCxxxCP sequence, with two additional amino acids between the second and third Cys, a characteristics feature of Azotobacter-[3Fe-4S] [4Fe-4S]-ferredoxin. Ferredoxin II was also similar to Azotobacter-type ferredoxins with an extended carboxyl (C-) terminal sequence compared to the common Clostridium-type. The evolutionary relationship of the two together with a putative one recently found to be encoded in nifENXQ region in this bacterium [Moreno-Vivian et al. (1989) J. Bacteriol. 171, 2591-2598] is discussed.     

The electron transport to nitrogenase in Mycobacterium flavum

1. Two ferredoxin-type iron-sulfur proteins have been isolated from Mycobacterium flavum 301 grown under nitrogen-fixing, iron-sufficient conditions. No flavodoxin was observed. 2. These ferredoxins are apparently soluble: they were present in the supernatant fraction after disrupting by decompression. Only small amounts were present in particulate fractions. 3. The two ferredoxins were separated by chromatography on DEAE-cellulose, Sephadex or electrophoresis. 4. Both ferredoxins mediated the transfer of electrons from illuminated spinach chloroplasts to a nitrogenase preparation to reduce acetylene. Ferredoxin II was specifically about five times more active than ferredoxin I. Ferredoxin II was also active in the photosynthetic NADP+-reduction whereas ferredoxin I was not. 5. Both ferredoxins were reversibly reduced by either sodium dithionite, illuminated spinach chloroplasts or hydrogen plus hydrogenase from Clostridium pasteurianum. 6. Attempts to determine the primary electron donor for nitrogen fixation in Mycobacterium flavum were unsuccessful. Acetylene reduction in Mycobacterium extracts was obtained only with sodium dithionite or illuminated spinach chloroplasts as electron donors. The reduction of the electron carrier (e.g. ferredoxin) rather than the transfer of electrons from the reduced carrier to nitrogenase was rate-limiting.     

Iron-sulphur cluster composition and redox properties of two ferredoxins from Desulfovibrio desulfuricans Norway strain

Two ferredoxins from Desulfovibrio desulfuricans, Norway Strain, were investigated by EPR spectroscopy. Ferredoxin I appears to be a conventional [4Fe-4S]2+;1+ ferredoxin, with a midpoint reduction potential of -374 mV at pH 8. Ferredoxin II when reduced, at first showed a more complex spectrum, indicating an interaction between two [4Fe-4S] clusters, and probably, has two clusters per protein subunit. Upon reductive titration ferredoxin II changed to give a spectrum in which no intercluster interaction was seen. The midpoint potentials of the native and modified ferredoxin at pH 8 were estimated to be -500 and -440 mV, respectively.     

Structure of the extracellular ferredoxin from Rhodospirillum rubrum: close similarity to clostridial ferredoxins

The amino acid sequence of an [8Fe-8S] ferredoxin isolated from the culture medium of Rhodospirillum rubrum, a photosynthetic purple non-sulfur bacterium, was determined by a combination of various conventional procedures. The sequence was A-Y-K-I-E-E-T-C-I-S-C-G-A-C-A-A-E-C-P-V-N-A-I-E-Q-G-D-T-I-F-V-V-N-A-D-T-C-I-D-C - G-N-C-A-N-V-C-P-V-G-A-P-V-A-E (55 amino acid residues). It lacked methionine, leucine, histidine, arginine, and tryptophan. The molecular weight was calculated to be 5,568 excluding iron and sulfur atoms. The distribution of 8 cysteine residues was exactly the same as that of clostridial-type ferredoxin, suggesting retention of the duplication of the bacterial ancestral ferredoxin gene. The extracellular ferredoxin of R. rubrum was compared with other ferredoxins observed in closely related photosynthetic bacteria and the evolutionary significance of this ferredoxin is discussed.     

Isolation and characterization of a rubredoxin and two ferredoxins from Desulfovibrio africanus

Rubredoxin and two distinct ferredoxins have been purified from Desulfovibrio africanus. The rubredoxin has a molecular weight of 6000 while the ferredoxins appear to be dimers of identical subunits of approximately 6000 to 7000 molecular weight. Rubredoxin contains one iron atom, no acid-labile sulfide and four cysteine residues per molecule. Its absorbance ratio A₂₇₈/A₄₉₀ is 2.23 and its amino acid composition is characterized by the absence of leucine and a preponderance of acidic amino acids.

The two ferredoxins, designated I and II, are readily separated on DEAE-cellulose. The amino acid compositions of ferredoxins I and II show them to be different protein species; the greater number of acidic amino acid residues in ferredoxin I than in ferredoxin II appears to account for separation based on electronic charge. Both ferredoxins contain four iron atoms, four acid-labile sulfur groups and either four (ferredoxin II) or six (ferredoxin I) cysteine residues per molecule. Spectra of the two ferredoxins differ from those of ferredoxins of other Desulfovibrio species by exhibiting a pronounced absorption peak at 283 nm consistent with an unusual high content of aromatic residues. The A₃₈₅/A₂₈₃ absorbance ratio of ferredoxins I and II are 0.56 and 0.62, respectively.

The N-terminal sequencing data of the two ferredoxins clearly indicate that ferredoxins I and II are different protein species. However, the two proteins exhibit a high degree of homology.

The physiological activity of ferredoxins I and II appears to be similar as far as the electron transfer in the phosphoroclastic reaction is concerned.     

Iron-sulphur cluster composition and redox properties of two ferredoxins from Desulfovibrio desulfuricans Norway strain

Two ferredoxins from Desulfovibrio desulfuricans, Norway Strain, were investigated by EPR spectroscopy. Ferredoxin I appears to be a conventional [4Fe-4S]^2+;1+ ferredoxin, with a midpoint reduction potential of ?374 mV at pH 8. Ferredoxin II when reduced, at first showed a more complex spectrum, indicating an interaction between two [4Fe-4S] clusters, and probably, has two clusters per protein subunit. Upon reductive titration ferredoxin II changed to give a spectrum in which no intercluster interaction was seen. The midpoint potentials of the native and modified ferredoxin at pH 8 were estimated to be ?500 and ?440 mV, respectively.     

Electron transfer mechanism and interaction studies between cytochrome C3 and ferredoxin

Ferredoxin, cytochrome c3 and hydrogenase are specific partners of the sulfate reduction pathway of Desulfovibrio desulfuricans Norway and might be exemplary for electron exchange mechanism studies. Cytochrome c3 contains four low redox potential haems for 13 000 molecular weight. Two ferredoxins isolated from the same bacteria are dimers of 6 000 molecular weight per subunit (Ferredoxin I: one (4 Fe-4S) cluster per subunit, ferredoxin II: two (4 Fe-4 S) clusters per subunit). The amino acid sequence of ferredoxin I is reported and compared to the ferredoxin II sequence. The structural characteristics of ferredoxins and cytochrome c3 should allow a discussion on the nature of the interaction. 1H-NMR spectra of ferredoxin I and cytochrome c3 in the absence and presence of ferredoxin are presented.     

Isolation and characterization of a rubredoxin and two ferredoxins from Desulfovibrio africanus

Rubredoxin and two distinct ferredoxins have been purified from Desulfovibrio africanus. The rubredoxin has a molecular weight of 6000 while the ferredoxins appear to be dimers of identical subunits of approximately 6000 to 7000 molecular weight. Rubredoxin contains one iron atom, no acid-labile sulfide and four cysteine residues per molecule. Its absorbance ratio A278/A490 is 2.23 and its amino acid composition is characterized by the absence of leucine and a preponderance of acidic amino acids. The two ferredoxins, designated I and II, are readily separated on DEAE-cellulose. The amino acid compositions of ferredoxins I and II show them to be different protein species; the greater number of acidic amino acid residues in ferredoxin I than in ferredoxin II appears to account for separation based on electronic charge. Both ferredoxins contain four iron atoms, four acid-labile residues per molecule. Spectra of the two ferredoxins differ from those of ferredoxins of other Desulfovibrio species by exhibiting a pronounced absorption peak at 283 nm consistent with an unusual high content of aromatic residues. The A385/A283 absorbance ratio of ferredoxins I and II are 0.56 and 0.62, respectively. The N-terminal sequencing data of the two ferredoxins clearly indicate that ferredoxins I and II are different protein species. However, the two proteins exhibit a high degree of homology.     

Characterization of ferredoxin, flavodoxin, and rubredoxin from Clostridium formicoaceticum grown in media with high and low iron contents

Ferredoxin, flavodoxin, and rubredoxin were purified to homogeneity from Clostridium formicoaceticum and characterized. Variation of the iron concentration of the growth medium caused substantial changes in the concentrations of ferredoxin and flavodoxin but not of rubredoxin. The ferredoxin has a molecular weight of 6,000 and is a four iron-four sulfur protein with eight cysteine residues. The spectrum is similar to that of other ferredoxins. The molar extinction coefficients are 22.6 X 10(3) and 17.6 X 10(3) at 280 and 390 nm, respectively. From 100 g wet weight of cells grown with 3.6 microM iron and with 40 microM iron, 5 and 20 mg offerredoxin were isolated, respectively. The molecular weight of rubredoxin is 5,800 and it contains one iron and four cysteines. The UV-visible absorption spectrum is dissimilar to those of other rubredoxins in that the 373 nm absorption peak is quite symmetric, lacking the characteristic 350-nm shoulder found in other rubredoxins. The flavodoxin is a 14,500-molecular-weight protein which contains 1 mol of flavin mononucleotide per mol of protein. It forms a stable, blue semiquinone upon light irradiation in the presence of EDTA or during enzymatic reduction. When cells were grown in low-iron medium, flavodoxin constituted at least 2% of the soluble cell protein; however, it was not detected in extracts of cells grown in high-iron medium. The rubredoxin and ferredoxin expressed during growth in low-iron and high-iron media are identical as judged by iron, inorganic sulfide, and amino acid analysis, as well as light absorption spectroscopy.     

Properties and regulation of synthesis of two ferredoxins from Rhodopseudomonas capsulata

Two ferredoxins from nitrogen-fixing cells of the phototrophic bacterium Rhodopseudomonas capsulata, strain B10, are purified to a homogeneous state and characterized. The molecular mass of ferredoxin I is about 12 kDa and that of ferredoxin II, 18 kDa. Ferredoxin I contains 8 Fe²⁺ and 8 S^2?; ferredoxin II has 4 Fe²⁺ and 4 S^2? per molecule. The redox potential of ferredoxin I is about ?270 mV and that of ferredoxin II ?419 mV. Ferredoxin I is more labile to the action of O₂, O^?₂, H₂O₂ and heating. The ferredoxins are also different in their absorption and EPR spectra, amino acid composition and electron-transfer activity to Rps. capsulata nitrogenase: both C₂H₂ reduction and H₂ evolution by Rps. capsulata nitrogenase proceed faster in the presence of ferredoxin I than in case of ferredoxin II. Synthesis of ferredoxin I takes place only in Rps. capsulata nitrogen-fixing cells grown in light under anaerobic conditions whereas ferredoxin II formation does not depend on the source of nitrogen or the growth medium, though the amount of ferredoxin II varies with the growth conditions. Its highest level has been found in the cells grown in lactate-limited medium in the presence of CO₂ and light or in the presence of glutamate in darkness under anaerobic conditions.     

Purification and some properties of a 2Fe ferredoxin in Pseudomonas ovalis

A [2Fe-2S] ferredoxin was found in Pseudomonas ovalis which was grown in a medium supplemented with glucose and ammonium sulfate. The molecular weight of the 2Fe ferredoxin was estimated to be 13,000. It contained 2.2 gramatoms of non-heme iron and 2.3 gramatoms of acid-labile sulfur per mole protein. The absorption and circular dichroism spectra were characteristic of those of [2Fe-2S] type ferredoxins, especially adrenodoxin and putidaredoxin. The electron paramagnetic resonance spectrum of the reduced protein showed an axial symmetry (g = 2.020, g = 1.939). The amino acid composition was determined.     

NMR studies of Azotobacter vinelandii and Pseudomonas putida seven-iron ferredoxins. Direct assignment of beta-cysteinyl carbon NMR resonances and further proton NMR assignments of cysteinyl and aromatic resonances.

Ferredoxins are proteins which contain iron and inorganic sulfide and are capable of electron transport. They are found in a wide range of organisms, from anaerobic bacteria, to plants and mammals. Although NMR spectroscopy has been used to study ferredoxins since the 1970s, little important structural or biochemical information has resulted from these investigations. The major difficulty has been the effect of the paramagnetic iron-sulfur clusters on the peptide resonances, hindering nuclear Overhauser effect (NOE) studies and causing broad line widths. These effects are most pronounced on resonances arising from the nuclei closest to the iron-sulfur center. Unfortunately, these are likely to be the most interesting nuclei, as they report the events and geometry in the vicinity of the active sites. In this paper, the first direct assignment of beta-cysteinyl 13C resonances for any iron-sulfur protein is reported for the spectrum of Pseudomonas putida ferredoxin. These resonances are of special significance, as they arise from the atoms on the protein closest to the iron centers, with the exception of the directly bound cysteinyl sulfur atoms. In addition, cysteinyl and ring system 1H NMR resonance assignments are made for the spectra of P. putida ferredoxin and Azotobacter vinelandii ferredoxin I.     

Two plant-type ferredoxins from a blue-green alga, Nostoc verrucosum.

Two plant-type ferredoxins were isolated and purified from a blue-green alga, Nostoc verrucosum. They were separable by chromatography on a DEAE-cellulose column. The slow-moving band was designated ferredoxin I (Fd I) and the fast-moving band was ferredoxin II (Fd II). The ratio of the yield of ferredoxins I and II was about 1 : 0.84. Both ferredoxins had absorption spectra similar to those of plant-type ferredoxins. Two atoms of non-heme iron and two of labile sulfur were found per mol of both ferredoxin I and ferredoxin II. Their molecular weights were identical and estimated to be about 18 000 by a gel filtration method. The biochemical activities of these Nostoc ferredoxins were studied: the NADP photoreduction activity on one hand and the NADP-cytochrome c reductase activity on the other.     

Comparison of the properties of two hydrogenases from the photosynthetic bacterium Chromatium vinosum

Chromatium vinosum hydrogenases I and II were purified to specific activities of 9.6 and 28.0 units/mg protein, respectively. They have the same isoelectric point (pI = 4.1), and their visible spectra are typical of iron-sulfur proteins. Hydrogenase II in general was more stable than hydrogenase I. Both enzymes lost their activities slowly during storage in air, and this inactivation was more apparent in preparations of hydrogenase I. Bovine serum albumin helped to stabilize hydrogenase I against thermal and storage inactivation. The pH optima of H2-evolution activity of hydrogenases I and II were 7.4 and 5.4, respectively. Neither enzyme was able to evolve H2 from reduced ferredoxins as the sole electron carrier, but ferredoxins had an effect on the activity with methyl viologen as carrier to hydrogenase I. None of the natural compounds tested was able to serve as a physiological donor for H2 production. Hydrogenase I was more susceptible than hydrogenase II to inhibition by heavy metal ions and other enzyme inhibitors. Both enzymes were reversibly inhibited by CO with Ki values of 12 and 6 Torr for hydrogenase I and II, respectively. Hydrogenase I was more sensitive to denaturation by urea and guanidinium chloride while hydrogenase II was more susceptible to sodium dodecyl sulfate. Both enzymes were rapidly and irreversibly inactivated by dimethyl sulfoxide. Hydrogenase I evolved H2 from methyl viologen and ferredoxin photoreduced by chloroplasts. The enzymes differed in their iron and acid-labile sulfur contents.     

Isolation and characterization of an Fe,-S8 ferredoxin (ferredoxin II) from Clostridium thermoaceticum.

A second ferredoxin protein was isolated from the thermophilic anaerobic bacterium Clostridium thermoaceticum and termed ferredoxin II. This ferredoxin was found to contain 7.9 +/- 0.3 iron atoms and 7.4 +/- 0.4 acid-labile sulfur atoms per mol of protein. Extrusion studies of the iron-sulfur centers showed the presence of two [Fe4-S4] centers per mol of protein and accounted for all of the iron present. The absorption spectrum was characterized by maxima at 390 nm (epsilon 390 = 30,400 M-1cm-1) and 280 nm (epsilon 280 = 41.400 M-1 cm-1) and by a shoulder at 300 nm. The ration of the absorbance of the pure protein at 390 nm to the absorbance at 280 nm was 0.74. Electron paramagnetic resonance data showed a weak signal in the oxidized state, and the reduced ferredoxin exhibited a spectrum typical of [Fe4-S4] clusters. Double integration of the reduced spectra showed that two electrons were necessary for the complete reduction of ferredoxin II. Amino histidine, and 1 arginine, and a molecular weight of 6,748 for the native protein. The ferredoxin is stable under anaerobic conditions for 60 min at 70 degrees C. The average oxidation-reduction potential for the two [Fe4-S4] centers was measured as -365 mV.     

Two plant-type ferredoxins from a blue-green alga, Nostoc verrucosum

Two plant-type ferredoxins were isolated and purified from a blue-green alga, Nostoc verrucosum. They were separable by chromatography on a DEAE-cellulose column. The slow-moving band was designated ferredoxin I (Fd I) and the fast-moving band was ferredoxin II (Fd II). The ratio of the yield of ferredoxins I and II was about 1:0.84. Both ferredoxins had absorption spectra similar to those of plant-type ferredoxins. Two atoms of non-heme iron and two of labile sulfur were found per mol of both ferredoxin I and ferredoxin II. Their molecular weights were identical and estimated to be about 18 000 by a gel filtration method. The biochemical activities of these Nostoc ferredoxins were studied: the NADP photoreduction activity on one hand and the NADP-cytochrome c reductase activity on the other.     

Ferredoxin and Ferredoxin-NADP Reductase from Photosynthetic and Nonphotosynthetic Tissues of Tomato

Ferredoxin and ferredoxin-NADP⁺ oxidoreductase (FNR) were purified from leaves, roots, and red and green pericarp of tomato (Lycopersicon esculentum, cv VFNT and cv Momotaro). Four different ferredoxins were identified on the basis of N-terminal amino acid sequence and charge. Ferredoxins I and II were the most prevalent forms in leaves and green pericarp, and ferredoxin III was the most prevalent in roots. Red pericarp of the VFNT cv yielded variable amounts of ferredoxins II and III plus a unique form, ferredoxin IV. Red pericarp of the Momotaro cv contained ferredoxins I, II, and IV. This represents the first demonstration of ferredoxin in a chromoplast-containing tissue. There were no major differences among the tomato ferredoxins in absorption spectrum or cytochrome c reduction activity. Two forms of FNR were present in tomato as judged by anion exchange chromatography and by sodium dodecyl sulfate-polyacrylamide gel electrophoresis. FNR II had a lower apparent relative molecular weight, a slightly altered absorption spectrum, and a lower specific activity for cytochrome c reduction than FNR I. FNR II could be a partially degraded form of FNR I. The FNRs from the different tissues of tomato plants all showed diaphorase activity, with FNR II being more active than FNR I. The presence of ferredoxin and FNR in heterotrophic tissues of tomato is consistent with the existence of a nonphotosynthetic ferredoxin/FNR redox pathway to support the function of ferredoxin-dependent enzymes.     

The protein responsible for center A/B in spinach photosystem I: isolation with iron-sulfur cluster(s) and complete sequence analysis

The 9 kDa polypeptide from spinach photosystem I (PS I) complex was isolated with iron-sulfur cluster(s) by an n-butanol extraction procedure under anaerobic conditions. The polypeptide was soluble in a saline solution and contained non-heme irons and inorganic sulfides. The absorption spectrum of this iron-sulfur protein was very similar to those of bacterial-type ferredoxins. The amino acid sequence of the polypeptide was determined by using a combination of gas-phase sequencer and conventional procedures. It was composed of 80 amino acid residues giving a molecular weight of 8,894, excluding iron and sulfur atoms. The sequence showed the typical distribution of cysteine residues found in bacterial-type ferredoxins and was highly homologous (91% homology) to that deduced from the chloroplast gene, frxA, of liverwort, Marchantia polymorpha. The 9 kDa polypeptide is considered to be the iron-sulfur protein responsible for the electron transfer reaction in PS I from center X to [2Fe-2S] ferredoxin, namely a polypeptide with center(s) A and/or B in PS I complex. It is noteworthy that the 9 kDa polypeptide was rather hydrophilic and a little basic in terms of the primary structure. A three-dimensional structure was simulated on the basis of the tertiary structure of Peptococcus aerogenes [8Fe-8S] ferredoxin, and the portions in the molecule probably involved in contacting membranes or other polypeptides were indicated. The phylogenetic implications of the structure of the present polypeptide as compared with those of several bacterial-type ferredoxins are discussed.     

Spectroscopic and functional properties of novel 2[4Fe-4S] cluster-containing ferredoxins from the green sulfur bacterium Chlorobium tepidum

Two distinct ferredoxins, Fd I and Fd II, were isolated and purified to homogeneity from photoautotrophically grown Chlorobium tepidum, a moderately thermophilic green sulfur bacterium that assimilates carbon dioxide by the reductive tricarboxylic acid cycle. Both ferredoxins serve a crucial role as electron donors for reductive carboxylation, catalyzed by a key enzyme of this pathway, pyruvate synthase/pyruvate ferredoxin oxidoreductase. The reduction potentials of Fd I and Fd II were determined by cyclic voltammetry to be -514 and -584 mV, respectively, which are more electronegative than any previously studied Fds in which two [4Fe-4S] clusters display a single transition. Further spectroscopic studies indicated that the CD spectrum of oxidized Fd I closely resembled that of Fd II; however, both spectra appeared to be unique relative to ferredoxins studied previously. Double integration of the EPR signal of the two Fds yielded approximately approximately 2.0 spins per molecule, compatible with the idea that C. tepidum Fd I and Fd II accept 2 electrons upon reduction. These results suggest that the C. tepidum Fd I and Fd II polypeptides each contain two bound [4Fe-4S] clusters. C. tepidum Fd I and Fd II are novel 2[4Fe-4S] Fds, which were shown previously to function as biological electron donors or acceptors for C. tepidum pyruvate synthase/pyruvate ferredoxin oxidoreductase (Yoon, K.-S., Hille, R., Hemann, C. F., and Tabita, F. R. (1999) J. Biol. Chem. 274, 29772-29778). Kinetic measurements indicated that Fd I had approximately 2.3-fold higher affinity than Fd II. The results of amino acid sequence alignments, molecular modeling, oxidation-reduction potentials, and spectral properties strongly indicate that the C. tepidum Fds are chimeras of both clostridial-type and chromatium-type Fds, suggesting that the two Fds are likely intermediates in the evolutional development of 2[4Fe-4S] clusters compared with the well described clostridial and chromatium types.     

Comparative studies on two ferredoxins from the cyanobacterium Nostoc strain MAC.

Two ferredoxins were isolated from the cyanobacterium Nostoc strain MAC grown autotrophically in the light or heterotrophically in the dark. In either case approximately three times as much ferredoxin I as ferredoxin II was obtained. Both ferredoxins had absorption maxima at 276, 282 (shoulder), 330, 423 and 465 nm in the oxidized state, and each possessed a single 2 Fe-2S active centre. Their isoelectric points were approx. 3.2. The midpoint redox potentials of the ferredoxins differed markedly; that of ferredoxin I was --350mV and that of ferredoxin II was --445mV, at pH 8.0. The midpoint potential of ferredoxin II was unusual in being pH dependent. Ferredoxin I was most active in supporting NADP+ photoreduction by chloroplasts, whereas ferredoxin II was somewhat more active in pyruvate decarboxylation by the phosphoroclastic system of Clostridum pasteurianum. Though the molecular weights of the ferredoxins determined by ultracentrifugation were the same within experimetnal error, the amino acid compositions showed marked differences. The N-terminal amino acid sequences of ferredoxins I and II were determined by means of an automatic sequencer. There are 11--12 differences between the sequences of the first 32 residues. It appears that the two ferredoxins have evolved separately to fulfil different roles in the organism.