Báo cáo khoa học: Regulation of maize lysine metabolism and endosperm protein synthesis by opaque and floury mutations potx

The activities of the enzymes lysine 2-oxo-glutate reductase and saccharopine dehydrogenase, both involved in lysine degradation in the maize endosperm were also determined and shown to

Regulation of maize lysine metabolism and endosperm protein

synthesis by opaque and floury mutations

Ricardo A Azevedo1, Catherine Damerval2, Jacques Landry3, Peter J Lea4, Cla´udia M Bellato5,

Lyndel W Meinhardt6, Martine Le Guilloux2, Sonia Delhaye3, Alejandro A Toro1, Salete A Gaziola1 and Bertha D A Berdejo1

1

Departamento de Gene´tica, Escola Superior de Agricultura Luiz de Queiroz, Universidade de Sa˜o Paulo, Sa˜o Paulo, Brazil;

2

Station de Ge´ne´tique Ve´ge´tale INRA/UPS/INA-PG/CNRS UMR 8120, La Ferme du Moulon, Gif-sur-Yvette;3INRA, Laboratoire

de Chimie Biologique, INA-PG, F78850 Thiverval-Grignon, France;4Department of Biological Sciences, University of Lancaster, Lancaster, UK;5Centro de Energia Nuclear na Agricultura, Universidade de Sa˜o Paulo, Sa˜o Paulo, Brazil; and6Departamento de Gene´tica e Evoluc¸a˜o, Universidade Estadual de Campinas, Campinas, Brazil

The capacity of two maize opaque endosperm mutants

(o1 and o2) and two floury (fl1 and fl2) to accumulate lysine

in the seed in relation to their wild type counterparts

Oh43+was examined The highest total lysine content was

3.78% in the o2 mutant and the lowest 1.87% in fl1, as

compared with the wild type (1.49%) For soluble lysine, o2

exhibited over a 700% increase, whilst for fl3 a 28% decrease

was encountered, as compared with the wild type In order to

understand the mechanisms causing these large variations in

both total and soluble lysine content, a quantitative and

qualitative study of the N constituents of the endosperm has

been carried out and data obtained for the total protein,

nonprotein N, soluble amino acids, albumins/globulins,

zeins and glutelins present in the seed of the mutants

Fol-lowing two-dimensional PAGE separation, a total of 35

different forms of zein polypeptides were detected and con-siderable differences were noted between the five different lines In addition, two enzymes of the aspartate biosynthetic pathway, aspartate kinase and homoserine dehydrogenase were analyzed with respect to feedback inhibition by lysine and threonine The activities of the enzymes lysine 2-oxo-glutate reductase and saccharopine dehydrogenase, both involved in lysine degradation in the maize endosperm were also determined and shown to be reduced several fold with the introduction of the o2, fl1 and fl2 mutations in the Oh43+inbred line, whereas wild-type activity levels were verified in the Oh43o1 mutant

Keywords: lysine metabolism; maize; storage proteins

Maize production is the highest of all crop plants and serves

as an important source of dietary protein for human and

livestock consumption However, the nutritional quality is

not adequate, due to the lack of the essential amino acids

lysine and tryptophan in the seed proteins [1]

Zeins, which account for 50–70% of the endosperm

proteins in maize seeds, have a characteristic amino acid

composition, being rich in glutamine and hydrophobic

amino acids, whilst being very poor in lysine and tryptophan

[2] Based on their solubility, genetic properties, and the

apparent molecular masses, zeins have been classified into a- (22 and 19 kDa), the most abundant, b- (14 kDa), c- (27 and 16 kDa) and d-zein (10 kDa) [3]

Four main strategies have been attempted in order to obtain plants with a high lysine seed content: plant breeding, characterization of naturally occurring mutants, induction

of biochemical mutants and the production of transgenic plants [4,5] Perhaps the most exciting result obtained during this research was the identification of the high-lysine opaque 2 (o2) maize mutant [6] Unfortunately, the high-lysine trait was negatively correlated with other agronomic characteristics, such as resistance to plant pathogens and yield [1] More recently, quality protein maize (QPM) varieties have been produced which maintain the high-lysine and high-tryptophan characteristics conditioned by the o2 mutation in a modified-vitreous endosperm, with favorable agronomic characteristics [7–9]

The amino acid lysine is derived from aspartate and the biosynthetic pathway involves the action of several strongly regulated enzymes [10] The enzyme aspartate kinase (AK;

EC 2.7.2.4), which converts aspartic acid into b-aspartyl phosphate, can exist in at least two distinct isoforms, one (or two) sensitive to lysine feedback inhibition and the other sensitive to threonine feedback inhibition, the latter being a bifunctional polypeptide with the threonine-sensitive homo-serine dehydrogenase isoenzyme (HSDH; EC 1.1.1.3) [11]

Correspondence to R A Azevedo, Departamento de Gene´tica, Escola

Superior de Agricultura Luiz de Queiroz, Universidade de Sa˜o Paulo,

Piracicaba CEP 13418–900, SP, Brazil.

Fax: +55 19 3433 6706, Tel.: +55 19 3429 4475,

E-mail: raazeved@esalq.usp.br

Abbreviations: AK, aspartate kinase; DHDPS, dihydrodipicolinate

synthase; HSDH, homoserine dehydrogenase; LOR, lysine

2-oxo-glutarate reductase; N, nitrogen; NPN, nonprotein nitrogen; PVPP,

insoluble polyvynylpyrrolidone; SDH, saccharopine dehydrogenase;

SAA, soluble amino acids.

Enzymes: AK (EC 2.7.2.4); HSDH (EC 1.1.1.3); LOR (EC 1.5.1.8);

SDH (EC 1.5.1.9); DHDPS (EC 4.2.1.52).

(Received 2 September 2003, accepted 22 October 2003)

The AK isoenzymes have been characterized at both the

biochemical and molecular level in several plant species

[4,5,10,12], and shown to be a major factor in the regulation

of the carbon flux through the aspartate pathway [4,10]

HSDH catalyses the conversion of aspartate semialdehyde

to homoserine in the presence of the coenzymes NADH or

NADPH and is present in plant species in two isoforms,

resistant and sensitive to threonine inhibition [10] The

first enzyme unique to lysine synthesis,

dihydrodipicoli-nate synthase (DHDPS; EC 4.2.1.52) has also been

exten-sively studied and characterized in plants catalyzing the

condensation of pyruvate and aspartate semialdehyde

into dihydrodipicolinic acid [4] DHDPS is also subject

to feedback inhibition by micromolar concentrations of

lysine [4]

Several mutants that overproduce and accumulate

threo-nine have been obtained by selection on media containing

amino acids or their analogues and this phenomenon has

been shown to be due to alteration in the feedback pattern of

the lysine-sensitive AK isoenzyme [4] However, in the case of

cereal seeds, the mutants failed to accumulate lysine in higher

concentration [10,13,14] The development of plant

formation techniques has allowed the production of

trans-genic plants expressing the enzymes of lysine biosynthesis

that are insensitive to feedback regulation analogous to the

biochemical mutants Again, most of the plants did not

exhibit significant accumulation of lysine in the seed [4,12]

Positive results were however, obtained with barley, canola

and soybean transgenic seeds in which dramatic increases in

the lysine content were observed [5,15]

Very little was known about lysine catabolism in plant

until recently [5,12,16] The first two enzymatic steps are

catalyzed by the bifunctional protein lysine 2-oxoglutarate

reductase–saccharopine dehydrogenase (LOR–SDH; EC

1.5.1.8 and EC 1.5.1.9, respectively) LOR–SDH protein

has been studied in some plant species [17–21] where the

activity was particularly high in the endosperm tissue in

cereal crops [17,18] The regulation of the LOR activity has

been shown to be complex, involving several distinct

mechanisms [5,12,16]

Recent studies have confirmed that in order to obtain

lysine overproduction in cereal seeds, manipulation of lysine

degradation is needed [5,12,16] This suggestion is supported

by five main points [5]: (a) The cereal mutants or transgenic

plants do not exhibit significant accumulation of lysine in

the seeds; (b) LOR–SDH activities are endosperm specific in

cereal crops only; (c) LOR–SDH activities are drastically

reduced in the high-lysine o2 maize mutant as compared

with the wild-type; (d) lysine catabolism intermediates

accumulate in the seeds of lysine overproducing plants of

soybean and canola, indicating reduced LOR–SDH

acti-vities; and (e) LOR–SDH activities are lower in legume

plants and rice, which is the cereal crop with the highest

concentration of lysine in the seed

The product of the o2 gene is specifically expressed in the

endosperm and the protein was shown to activate the

transcription of the 22 kDa a-zein [22] and 14 kDa b-zein

genes [23], together with the b-32 [24] and cyPPDK1 (one of

two cytosolic isoforms of pyruvate orthophosphate

dikin-ase) genes [25] Other possible direct or indirect target genes

of the o2 factor have been shown to belong to various

metabolic pathways [26–28] In the o2 mutant, LOR–SDH

mRNA and protein quantities were severely reduced (about 90%), and the expression pattern during grain development was markedly modified [29] The genomic sequence of the gene and its 5¢ regulatory regions revealed the presence of o2 boxes in the upstream promoter, confirming the hypothesis

of a transcriptional control of the Lor/Sdh gene by the o2 protein [16] These large effects suggest that o2 protein may play an important role in the developing grain, as a coordinator of the expression of storage protein, and nitrogen and carbon metabolism genes [30]

Although there is now plenty of information available about o2, information related to lysine metabolism for several other similar mutants that have been classified as high-lysine and exhibit the opaque phenotype are very scarce A comprehensive investigation into these mutants was initiated, with the aim of obtaining new insights into the regulation of lysine metabolism in maize During the course

of this work Hunter et al [31] published an analysis of some

of these mutants Our work now extends the studies of Hunter et al [31] and provides further insights into the complex but critical regulation of lysine accumulation within the maize seed, reporting for the first time the biochemical characterization of these mutants using pro-teomic and enzymological approaches

Experimental procedures

Maize mutants Seeds of the mutant genotypes opaque (o1 and o2) and floury (fl1 and fl2) and the respective wild type, Oh43 +, were kindly provided by the Maize Genetics Cooperation Seed Stock Center (Urbana, IL, USA) Plants of all genotypes were grown in the glasshouse at ESALQ-USP, Brazil and self-pollinated Maize ears were harvested

20 days after pollination (DAP) directly into liquid nitrogen and stored at) 80 C until used for enzyme extraction The experiments were repeated over three summer seasons (1999–2000, 2000–01 and 2001–02)

Preparation of endosperm samples Endosperms were isolated from mature grains previously soaked in water for 30 min by peeling off the outer tegument and excising the germ After freeze drying, the endosperms were ground to a powder using a ball mill

Fractionation of nitrogen (N) constituents The isolation of endosperm N constituents was undertaken

in duplicate as previously described by Landry et al [32]

Quantitation of N constituents For an accurate quantitation, the nonprotein nitrogen (NPN) and protein content were determined by the ninhydrin assay of a-amino N released after alkaline digestion (3MNaOH, 130C, 45 min) for the TCA, E1,2, E4 extracts [32] or acid digestion (6MHCl, 110C, 18 h) for the E3 extract and residues, according to Landry et al [33] Soluble amino acids (SAA) were quantitated by ninhydrin without previous digestion of the TCA extracts [32]

Amino acids analysis

Soluble amino acids from mature seeds were extracted and

analyzed exactly as described by Gaziola et al [9] As the

OPA-lysine derivative is rapidly degraded, a second analysis

was performed using a 15-min elution time Four replicates

were analyzed

Protein extraction and two-dimensional polyacrylamide

gel electrophoresis of zein polypeptides

The procedure for two-dimensional polyacrylamide gel

electrophoresis (2D-PAGE) analysis of zein isoforms

followed that published previously by Consoli and

Damer-val [34] Briefly, three sets of three mature kernels were

combined for each genotype and individually analyzed,

generating three independent replicates Embryos and

pericarp were manually excised, and the endosperms were

crushed in liquid nitrogen for each genotype The proteins

were resuspended in a urea-Triton X-100–2 ME buffer

Isoelectric focusing was performed in 10-cm long rod gels in

a pH gradient ranging from 5.5 to 8.5 Approximately

40 mg of total proteins were loaded on each gel The SDS

dimension was separated using a 14% acrylamide slab gel,

and staining was adapted from the colloidal Coomassie blue

method of Neuhoff et al [35] Images of the 2D patterns

were recorded and image analysis and spot detection were

carried out as described by Consoli and Damerval [34]

Specific zein protein extraction was previously used to

confirm the zein identity of the polypeptide spots visualized

in 2D gels [34]

Statistical analyses of zein isoform amounts

A previous analysis of colloidal Coomassie blue staining

intensity as a function of protein loading was carried out for

zein spots and it was demonstrated that for 86% of the

isoforms, a linear relationship was obtained [34] Differences

in total zein amounts loaded onto the gels were

compen-sated by scaling the raw integrated optical density of every

spot i in each gel j according to Consoli and Damerval [34]

One-way analysis of variance with the genotype as the

factor, were then performed for each spot on their scaled

integrated optical density, and a significant effect was

retained at P < 0.05

Enzymes partial purification and assays

All procedures were carried out at 4C unless stated

otherwise Four replicates each composed of five selected

maize ears, which were harvested (20 DAP), combined, and

mixed, were used for enzyme analysis

For the extraction of AK, frozen seeds were extracted in

five volumes of buffer A [50 mM Tris/HCl, 200 mMKCl,

0.1 mM phenylmethanesulfonyl fluoride, 0.1 mM EDTA,

1 mMdithiothreitol, 2 mM L-lysine, 2 mM L-threonine, 10%

(v/v) glycerol and 5% (w/v) insoluble polyvynylpyrrolidone

(PVPP), pH 7.4] The extract was filtered through three

layers of miracloth, and centrifuged at 16 000 g for 30 min

to remove the cellular debris Solid ammonium sulfate was

added slowly to 30% saturation with gently stirring for at

least 30 min The suspension was centrifuged at 16 000 g for

30 min and the supernatant subjected to a second ammo-nium sulfate precipitation at 60% saturation for 30 min with continuous stirring Precipitated protein was recovered

by centrifugation at 16 000 g for 30 min and the protein pellets were dissolved in a small volume of buffer B [25 mM Tris/HCl, 1 mM dithiothreitol, 0.1 mM L-lysine, 0.1 mM

L-threonine and 10% (v/v) glycerol, pH 7.4] The sample was loaded onto a Sephadex G25 column (2.5· 20 cm) equilibrated with five column volumes of buffer B and run under gravity The desalted sample was collected and assayed for AK activity

AK activity was assayed routinely in a final volume of

500 mL as described by Brennecke et al [28] Controls containing lysine and threonine were included to identify the isoenzymes sensitive to lysine and threonine Activity was expressed as nmolÆmin)1Æmg)1protein Four replications were carried out for each assay

For the extraction of HSDH, frozen seeds were extracted

in five volumes of buffer C [50 mMTris/HCl, 200 mMKCl, 0.1 mM phenylmethanesulfonyl fluoride, 1 mM EDTA,

3 mMdithiothreitol, 5 mM L-threonine, 10% (v/v) glycerol and 5% (w/v) PVPP, pH 7.5] The extract was filtered through three layers of miracloth, and centrifuged at

16 000 g for 30 min to remove completely cellular debris from the extract Solid ammonium sulfate was added slowly

to 30% saturation with gently stirring for at least 30 min The suspension was centrifuged at 16 000 g for 30 min and the supernatant subjected to a second ammonium sulfate precipitation at 60% saturation for 30 min with continuous stirring Precipitated protein was recovered by centrifuga-tion at 16 000 g for 30 min and the protein pellets were dissolved in a small volume of buffer D [25 mMTris/HCl,

1 mMEDTA, 1 mMdithiothreitol, 0.1 mM L-threonine and 10% (v/v) glycerol, pH 7.5] The sample was loaded onto a Sephadex G25 column (2.5· 20 cm) equilibrated with five column volumes of buffer D and run under gravity The desalted sample was collected and assayed for HSDH activity

HSDH activity was assayed routinely spectrophotomet-rically at 340 nm in a final volume of 1.1 mL at 30C as described by Azevedo et al [11] The effect of threonine on the HSDH activity was determined by the addition (10 mL

of a 1Msolution) of the amino acid to the assay mixture Activity was expressed as nmolÆmin)1Æmg)1protein Four replications were carried out for each assay

For the extraction of LOR–SDH, frozen seeds were extracted in five volumes of buffer E [100 mMpotassium phosphate, 50 mMKCl, 1 mMEDTA, 1 mMdithiothreitol, 0.1 mMphenylmethanesulfonyl fluoride, 10% (w/v) glycerol and 5% (w/v) PVPP, pH 7.0] The homogenate was first filtered through three layers of miracloth and then centri-fuged at 15 000 g for 30 min to remove cellular debris The supernatant was adjusted to 30% ammonium sulfate saturation by gently stirring for at least 30 min The suspension was centrifuged at 15 000 g for 30 min and the supernatant subjected to a second ammonium sulfate precipitation at 55% saturation for 30 min with continuous stirring After centrifugation at 15 000 g for 30 min, the sedimented proteins were dissolved in 10 mL of buffer E (minus phenylmethanesulfonyl fluoride and PVPP) The sample was then loaded onto a Sephadex G50 column (2.6· 20 cm) previously equilibrated with buffer F

[100 mMTris/HCl, 1 mMdithiothreitol, 1 mMEDTA and

10% (v/v) glycerol, pH 7.4] and run under gravity The

desalted sample was collected and assayed for LOR and

SDH activities

LOR activity was routinely assayed

spectrophotometri-cally in a 1 mL cuvette at 30C by following the change in

absorbance at 340 nm over a 15-min period, with

appro-priate adjustments for a lysine-free blank as described by

Gaziola et al [18] Activity was expressed as nmol NADPH

oxidizedÆmin)1Æmg)1protein Four replications were carried

out for each assay

SDH activity was measured spectrophometrically in a

1 mL cuvette by following the rate of substrate-dependent

reduction of NAD+to NADH monitored at 340 nm at

30C over a 15-min period, with appropriate adjustments

for a saccharopine-free blank as described by Gaziola

et al [18] Activity was expressed as nmol NAD+reducedÆ

min)1Æmg)1protein Four replications were carried out for

each assay

Protein determination

Protein concentrations of the samples were determined as

described by Bradford [36] using bovine serum albumin as

a standard

Results

Distribution patterns of N constituents

Table 1 provides data concerning the percentage

contri-bution of the main N constituents present in opaque (o),

floury (fl) and wild-type (+) endosperms The amounts of

SAA and NPN were of the same magnitude for the

wild-type inbred line and all mutants The albumins and

globulins of the mutants exhibited variable amounts,

ranging from a value similar to that of the wild-type

inbred line (Oh43fl1), to a value 3.5-fold higher (Oh43o2)

The same mutant genotypes also marked the boundaries

of variation of zein for the mutants, with the Oh43o2

endosperm being the poorest in zeins, whereas Oh43fl1

exhibited the highest amounts of zeins, but still lower than

that of the wild-type Oh43+ In general, the mutants had

protein distribution patterns varying between that of

Oh43fl1, similar to that of the wild type, and that of

Oh43o2 From these results it was possible to assess the importance of lysine-rich nonzeins with accuracy, because

of the quantitation of nonprotein N and the exhaustive extraction of zeins Thus, the ratio of the nonzein content

of the mutants compared with that of Oh43+varied from 1.2 to 1.5 for most mutants, whereas for Oh43o2, a ratio

of 2.6 was calculated

Soluble lysine concentration The Oh43o2 mutant exhibited the highest relative concen-tration of soluble lysine followed by the Oh43fl2 mutant, whereas the Oh43o1 mutant exhibited the lowest relative concentration of soluble lysine, but still higher than that of the wild-type counterpart (Table 1) The Oh43o2 mutant also exhibited the highest absolute concentration of soluble lysine (7.35 nmolÆmg)1dry weight) followed by the Oh43fl2 mutant (5.29 nmolÆmg)1dry weight), whereas the Oh43o1 mutant exhibited the lowest absolute concentration of soluble lysine (1.65 nmolÆmg)1dry weight), but still higher than that of the wild-type counterpart (0.82 nmolÆmg)1dry weight) However, the total SAA pool also varied among the genotypes, indicating clear differences between the mutations The total SAA pool was increased slightly following the introduction of the mutations o2, fl1 and fl2, but was reduced by 20% by the o1 mutation (Table 1), however, the relative soluble lysine concentrations were increased considerably following the introduction of each mutation (Table 1)

2D-page Thirty-five zein polypeptides were detected in wild type Oh43+and Oh43o1, Oh43o2, Oh43fl1 and Oh43fl2 mutants Four polypeptides were identified as c27 kDa zeins, 10 as a22 kDa zeins, 15 as a19 kDa zeins, two as b14 kDa zeins, two as c16 kDa zeins and two as d10 kDa zeins, according to their apparent molecular masses in the SDS dimension (Fig 1)

Between 20 and 31 zein isoforms were detected according

to the genotype (Table 2) The mutations decreased the number of zein isoforms detected on the 2D gels as compared with the wild-type, indicating a decrease in zein amount and diversity (Fig 2) The effect of each mutation

on the amount of every isoform was tested using analyses of

Table 1 Quantitation of N constituents Percentage contribution of N constituents present in opaque (o), floury (fl) and wild-type (Oh43+) endosperms Data expressed as percentage (± standard deviation) of endosperm total N N constituents: SAA, soluble amino acids; NPN, nonprotein N; A +G, albumins +globulins corresponding to E1,2 – NPN; non- zeins corresponding to glutelins (Glu) +albumins +globulins;

P, endosperm total proteins expressed as percentage of dry matter Soluble lysine is expressed as percentage of total soluble amino acids pool (± standard deviation) followed by the percentage increase in soluble lysine in relation to the wild type.

Genotypes

N constituents

Lysine % increase SAA NPN A+G Zeins Glu Non-zeins P% DM

Oh43+0.75 (0.07) 1.6 3.2 (0.28) 77.4 (1.8) 17.8 (1.0) 21.0 (0.6) 10.8 0.33 (0.02) –

Oh43o1 0.60 (0.07) 2.4 4.0 (0.20) 68.6 (0.4) 25.0 (0.7) 29.0 (0.5) 11.6 0.53 (0.02) 61 Oh43o2 0.95 (0.00) 2.9 11.1 (0.35) 41.5 (1.2) 44.5 (1.6) 55.6 (1.2) 8.7 2.70 (0.07) 718 Oh43fl1 0.82 (0.07) 1.9 3.7 (0.28) 71.9 (0.8) 22.5 (1.1) 26.2 (0.8) 12.8 0.83 (0.02) 151 Oh43fl2 0.94 (0.14) 2.7 6.7 (0.35) 64.8 (0.2) 25.8 (0.6) 32.5 (0.2) 11.2 1.46 (0.10) 342

variance on standardized spot volumes (see Methods) The

o2and fl2 mutations had large effects, as about 60% of the

isoforms differed in amount as compared with the wild type

Conversely, Oh43o1 and Oh43fl1 mutants exhibited zein

patterns and contents similar to those of their wild-type

counterpart, in agreement with the data of Table 1

The pattern of c27 kDa isoforms was the most strongly

affected by the fl2 mutation, as all the polypeptides

disappeared, in contrast, fl1 had little effect Among the

10 a22 kDa zein class isoforms, only one appeared in a

similar amount in all of the mutants and wild type (a22z2,

Fig 1, 2) The mutations generally decreased the amount of

the isoforms as compared with the wild type Among the 15

a19 kDa zein class isoforms, five were unaffected in the

mutants The Oh43fl2 mutant exhibited the strongest effect

on this zein class, altering the amount of nine isoforms,

amongst which, two occurred specifically in this mutant (e.g

a19z114, Fig 1, 2) The mutations fl2 and o2 had a parallel

effect on b14 kDa and d10 kDa zein isoforms, but the effect

of fl2 was less pronounced than that of o2 In all, the o2

mutation markedly altered the pattern of low molecular

mass zeins, as compared with the wild type

Lysine metabolism

In this study, the enzymes AK, HSDH, LOR and SDH

were extracted initially from the developing seeds (16, 20

and 24 DAP) of the wild type, which indicated that the

main peak of activity of AK (4.32, 7.91 and

3.10 nmolÆmin)1Æmg)1protein at 16, 20 and 24 DAP,

res-pectively), HSDH (5.24, 16.31 and 6.16 nmolÆmin)1Æmg)1

protein at 16, 20 and 24 DAP, respectively), LOR (2.05,

3.53 and 2.18 nmolÆmin)1Æmg)1protein at 16, 20 and 24 DAP, respectively) and SDH (2.37, 3.51 and 2.08 nmolÆ min)1Æmg)1protein at 16, 20 and 24 DAP, respectively) was

at 20 DAP The activities of the enzymes involved in lysine metabolism have been studied in maize endosperm, exhi-biting a peak of activity between 16 and 24 DAP depending

on the enzyme [9,28] In this study, the activities of the enzymes AK, HSDH, LOR and SDH were determined in extracts isolated from the wild-type 16, 20 and 24 DAP and the maximum activity for all enzymes was confirmed as 20 DAP Based on this peak of enzyme activity, all genotypes were subsequently analyzed at 20 DAP

The activity of AK varied considerably among all genotypes, ranging from 2.78 nmolÆmin)1Æmg)1protein in Oh43fl1)15.29 nmolÆmin)1Æmg)1protein in the Oh43fl2 (Table 3) The Oh43o1 and Oh43fl2 mutants exhibited higher activities (12 and 85%, respectively) when compared with the wild type, whereas the mutants Oh43o2 and Oh43fl1 exhibited lower activities (40 and 66%, respect-ively) The inhibition by lysine was shown to be reduced in all four mutants when compared with the wild type (60.8% inhibition), ranging from 28.9% in the Oh43fl1 mutant to 55.6% in the Oh43o1 mutant The inhibitory effect of threonine on AK activity was much lower when compared with the effect of lysine, resulting in 11.1% inhibition of AK activity in the wild type, 15.6% in the Oh43fl2 mutant and 3.34% in the Oh43fl1 mutant, whereas a slight stimulation

of AK activity was induced by threonine in the Oh43o2 mutant When both amino acids were added together, a more intense inhibitory effect was observed, with the wild-type Oh43+exhibiting the highest inhibitory effect (92.5%) and the Oh43fl1 the lowest (41.8%) (Table 3)

Fig 1 Two-dimensional separation of zein isoforms isolated from the endosperms of maize seeds in the Oh43 background, using isoelectric focusing and SDS/PAGE Wild-type Oh43+ key isoforms are indicated with black arrows The white arrow points to an isoform appearing specifically in the fl2 mutant Molecular masses and pH range are indicated along the gel.

The activity of HSDH varied considerably among all

genotypes, ranging from 17.4 nmolÆmin)1Æmg)1protein

in Oh43+to 38.4 nmolÆmin)1Æmg)1protein in Oh43o2

(Table 3) All mutants exhibited higher activities when

compared with the wild-type, with the Oh43o2 mutant

exhibiting a 2.2-fold higher HSDH activity The effect of

threonine was tested on HSDH activity, exhibiting an

inhibitory effect in the wild-type and Oh43o2, Oh43fl1 and

Oh43fl2 mutants, but stimulating HSDH activity in the

Oh43o1 mutant (Table 3)

Table 3 shows the activities of the enzymes LOR and

SDH, both involved in lysine degradation, which were also

measured for all genotypes Large variations were observed

for LOR activity, varying from 0.49 nmol NADPH

oxi-dized min)1Æmg)1protein in Oh43fl2)3.83 nmol NADPH

oxidized min)1Æmg)1protein in Oh43o1, which was even

higher than the activity in the wild type (3.50 nmol NADPH

oxidized min)1Æmg)1protein) (Table 3) The Oh43o2

mutant exhibited a sixfold reduction of LOR activity, a

reduction that was even higher (7.1-fold) in the Oh43fl2

mutant Reduction of LOR activity was also observed in the Oh43fl1 mutant (40% lower) when compared with the wild type, whereas in the Oh43o1 mutant the activity was slightly higher than the wild type Similar reductions in SDH activity along with LOR, were also induced by the o2, fl1 and fl2 mutations and thus the LOR/SDH ratio did not exhibit major variations

Discussion

The opaque and floury mutations and their respective wild-type (Oh43+) were obtained from the Maize Genetics Cooperation Seed Stock Center (USA) and cultivated in Brazil for three successive summer seasons Very little variation among the genotypes was observed for time of flowering indicating a similar developmental behavior, which would be expected as all mutants are in the same genetic background This also allowed the self-pollination and production of seeds for all genotypes The content of the various N constituents in the endosperm is dependent on

Table 2 Two dimensional separation of zeins isolated from maize endosperms Thirty-five zein isoforms were revealed Mean values of spot volumes are indicated Each isoform number is prefixed by the name of the zein class Statistical analyses were performed to test for significant differences in isoform amounts, and genotypes sharing a same letter did not differ significantly (a indicates an amount significantly greater than b).

c27z28 7009.92(a) 8712.80(a) 8342.94(a) 8406.33(a) 0 c27z21 29520.46(a) 10278.86(b) 0 16517.54(ab) 0 a22z4 51353.85(a) 50168.37(a) 41558.61(a) 60342.63(a) 0

a22z31 7140.23(a) 4266.46(a) 0 5461.84(a) 0 a22z3 26824.27(a) 24194.50(a) 4797.66(b) 24681.31(a) 25758.31(a) a22z2 26413.60(a) 32646.71(a) 26387.42(a) 32919.48(a) 28709.67(a) a22z18 9363.84(a) 6607.25(a) 0 7301.23(a) 0 a22z12 18884.57(a) 19780.78(a) 13033.15(a) 25436.17(a) 0

a22z11 23365.92(a) 18853.00(a) 0 23972.68(a) 19571.06(a) a22z1 81282.15(a) 73752.64(ab) 44042.71(b) 101923.68(a) 88989.89(a)

a19z9 51483.41(a) 43735.68(a) 50534.32(a) 42954.38(a) 52618.48(a) a19z8 25934.51(c) 18027.17(c) 72930.41(a) 33846.97(bc) 47679.73(b) a19z7 65109.57(a) 50561.34(a) 70261.18(a) 50230.13(a) 46370.74(a) a19z6 65917.49(a) 78276.12(a) 79297.66(a) 75690.34(a) 62619.74(a) a19z5 92886.09(a) 99287.19(a) 79080.27(a) 63968.14(a) 61067.52(a)

a19z30 7646.58(b) 0 17683.49(a) 6122.26(b) 0 a19z23 10831.41(b) 22279.91(a) 8024.70(b) 8822.52(b) 27136.28(a) a19z20 16394.55(a) 19023.76(a) 2706.90(b) 12926.97(a) 15690.45(a)

a19z17 19406.44(a) 20261.95(a) 10550.99(b) 19055.38(ab) 18178.69(ab)

a19z10 45064.00(a) 43462.53(a) 51245.73(a) 51198.85(a) 46990.69(a)

c16z13 31426.21(b) 37841.49(b) 118849.72(a) 44790.63(b) 23034.16(b) b14z33 7480.22(a) 7535.85(a) 0 6828.42(a) 0 b14z14 71467.31(ab) 83184.64(a) 39052.79(c) 73327.86(ab) 51025.04(bc) d10z16 43782.08(bc) 52390.91(bc) 109105.04(a) 27284.15(c) 75793.39(ab)

genetic and environmental factors With the view of

dissociating these two factors, the present results were

compared with data taken from the literature and

concern-ing the same genotypes, but cultivated at diverse locations:

Bergamo, Italy [37]; Orsay, France [32]; LaFayette, USA [38]; and Tucson, USA [31] Furthermore, for a better comparison, the genotypes were ranked according to an increasing content of zeins (Table 4): (a) Zein percentages

Fig 2 Mutants Oh43o1, Oh4 3o2, Oh4 3fl1 and Oh43fl2 The arrows point to the isoforms indicated on the wild-type gel (Fig 1).

Table 3 Determination of activity of enzymes involved in lysine metabolism AK specific activity (nmolÆmin)1Æmg protein)1), HSDH specific activity (nmolÆmin)1Æmg protein)1), LOR specific activity (nmol NADPH oxidizedÆmin)1Æmg protein)1) and SDH specific activity (nmol NAD + reducedÆmin)1Æmg protein)1) were determined in extracts of 20 DAP maize endosperms and following the addition of lysine (L) and/or threonine (T) Standard deviation (SD) values were all below 5% for the L, T and LT treatments.

Enzyme

Genotypes Oh43 +Oh43o1 Oh43o2 Oh43fl1 Oh43fl2 AK

Control (SD) 8.282 (0.314) 9.240 (0.371) 4.956 (0.121) 2.783 (0.120) 15.290 (0.414)

% inhibition by +5 m M L 60.8 55.6 42.2 28.9 37.5

% inhibition by +5 m M T 11.1 13.5 +4.73 a 3.34 15.6

% inhibition by +5 m M LT 92.5 78.3 83.2 41.8 49.5

HSDH

Control (SD) 17.4 (0.71) 27.6 (0.88) 38.4 (1.43) 19.8 (0.57) 21.0 (0.57)

% inhibition by +5 m M T 31.0 +26.1 25.0 6.1 17.1

LOR (SD) 3.505 (0.121) 3.830 (0.133) 0.590 (0.016) 2.115 (0.030) 0.490 (0.013) SDH (SD) 3.490 (0124) 3.050 (0.090) 0.705 (0.071) 1.870 (0.097) 0.890 (0.033)

a

Indicates activation of enzyme activity.

ranged from 28.7% (W64Ao2) to 77.5% (Oh43+) The

difference between the minimum and maximum percentages

was almost the same as that found by Balconi et al [39]

between Illinois low protein (40%) and Illinois high protein

(74.5%) genotypes, taking into account that these values are

slightly (5%) underestimated as E4 proteins were excluded

from zeins by the authors (b) The effect of environmental

conditions upon the content of zeins for a given genotype

can result in a discrepancy of 8–9% in the case of Oh43o2,

W22o2 and W22 +or be negligible in the case of Oh43fl2

or Oh43+ (c) For a given mutant gene the genetic

background can have a considerable impact upon the zein

content, however, this is not always the case as can be seen

with W64Ao1 and Oh43o1 (d) More generally, the gradual

increase in zein content would indicate a progressive change

in the relative proportions of soft and hard endosperms,

respectively, poor and rich in zeins Therefore, the effect of

one gene upon the distribution pattern of protein fractions

cannot be generalized from that found for only one genetic

background

The opaque and floury mutants used in this study have

been classified as high-lysine endosperm mutants, however,

such higher concentrations of lysine can be due to

altera-tions in the storage protein fracaltera-tions and/or in the

concen-tration of soluble lysine in the endosperm In previous

studies, the soluble lysine concentration has been shown to

be increased in the o2 maize mutant when compared with

the wild-type maize [9,30,31] Estimating the percentage of

lysine in true proteins by assuming the lysine content of

nonzeins is independent of genotype and equal to 7 g per

100 g of proteins, and based on the distribution of the

endosperm proteins, the mutants exhibited higher

concentrations of total lysine when compared with their

wild-type counterpart We have also observed a significant

variability in the absolute and relative soluble lysine

concentrations among the mutants analyzed The o2

mutation led to an increase in the total SAA pool and in

the soluble lysine concentration in the endosperm, confirm-ing the previous reports for this mutant [2,13,30,31], although such increases may vary depending on the genetic background to which the gene is introduced [30,31] In the other mutants, distinct responses were observed in relation

to lysine concentration, showing that the mutants Oh43fl1 and Oh43fl2, exhibited increases in total SAA and soluble lysine concentration, in a similar way to the Oh43o2 mutant, leading to higher lysine concentrations in the endosperm, but not to the same extent However the Oh43o1 mutant, exhibited a lower concentration of total SAA, but an increased concentration of relative and absolute contents of soluble lysine, which on balance indicates that the Oh43o1 mutant has a small significant increase (101%) in soluble lysine The results observed for the o1 mutation are similar

to that reported by Hunter et al [31], who observed an amino acid composition similar to the wild-type counter-part On the other hand, Balconi et al [39] reported an increased concentration of total lysine in the o1 mutant to the same extent as that for the o2 mutant In general, all mutants can be classified as high-lysine mutants, but the increases in lysine observed were not as great as that observed for the o2 mutation

Hunter et al [31] used one dimensional SDS/PAGE to compare qualitative and quantitative differences in zein patterns among a range of opaque mutants Except for o2, little effect of the mutations was observed The analysis was refined by immunoblotting with specific antisera, which demonstrated that in o2 there was a decreased amount a22 kDa, b14 kDa and d10 kDa isoforms, whereas in fl2 the a22 kDa zeins were reduced Using 2D electrophoresis,

we were able to observe complex patterns of alterations in the mutants as compared with the wild type The various isoforms detected are not due to artifacts during protein isolation and/or fractionation, but to genetic differences in charge and amino acid content [40] A given mutation can increase or decrease the relative amount of different isoforms belonging to the same class of zein, indicating very specific effects In the Oh43 background fl1 and o1 mutations had very little effect A similar low effect was also observed for o1 in the W64A background [31] The mutations o2 and fl2 had their largest effects on the a22 kDa and c27 kDa zeins, mostly decreasing the amount

of the isoforms present The effect of o2 on b14 kDa isoforms was consistent with a regulatory role of this transcriptional activator on these zein genes [23] In contrast

to Hunter et al [31], we found that o2 increased rather than decreased the relative amount of the d10 kDa isoforms This may be due to a specific effect of the background, as we used Oh43 while Hunter et al [31] used W64A A large background effect on the range of o2 effects had already been observed (e.g [34])

The enzymes of lysine metabolism have been studied and characterized in several plant species [10] As wild-type maize and the o2 mutant were the only sources of information in the literature as far as lysine metabolism is concerned, we have used them as controls for our analysis of the other mutants The data in Table 3 provide evidence that there is a wide variation in terms of AK activity, with several-fold variation in AK activity among the genotypes studied, which, in the case of the low rates in the Oh43o2 mutant, agreed with previous results published by other

Table 4 Zein and lysine determinations in distinct studies Percentage

of zein and protein lysine in maize seeds References: PS: present study;

Misra et al [38]; Di Fonzo et al [37]; Landry et al [32]; Hunter et al.

[31] Lysine percentage true proteins (estimated), values in parentheses

correspond to lysine percentage crude proteins (assayed).

Genotype Zeins Lysine percentage [Reference]

W64Ao2 28.7 3.8 31

Oh43o2 41.5 3.78 PS

Oh43o2 47.1 3.14 32

Oh43o2 49.3 (3.5) 38

W64Afl2 50.0 2.8 31

Oh43fl2 64.8 2.34 PS

W64Ao1 66.4 1.7 31

Oh43fl2 65.7 (2.3) 38

Oh43o1 68.6 2.08 PS

Oh43fl1 71.9 1.87 PS

Oh43+77.5 (1.6) 38

authors [9,28] Two mutants, Oh43o1 and Oh43fl2 exhibited

increases in AK activity, whereas the mutants Oh43o2

and Oh43fl1 exhibited a reduction in AK activity when

compared with their wild type, Oh43+ AK activity has

been shown to be determined by the action of at least two

separate isoenzymes, one that is sensitive to lysine inhibition

and the other sensitive to threonine inhibition [10]

Fur-thermore, in higher plants, the lysine-sensitive isoenzyme

normally accounts for 50–80% of the total AK activity,

with the exception of AK activity in coix endosperm, in

which the threonine-sensitive isoenzyme predominates [41]

Independent of the mutation, in the Oh43 genetic

back-ground, lysine produced the stronger inhibition of AK

activity, suggesting that the lysine-sensitive isoenzyme is

predominant in this genetic background and that such

distribution of isoenzymes activities is not affected by any of

the introduced mutations

Threonine inhibition of AK was low in all the lines, but

there was evidence of a further reduction, caused by the o2

and fl1 mutations However, lysine inhibition was reduced

in all the mutants when compared with the wild-type,

particularly in fl1 and fl2 The presence of AK activity more

insensitive to lysine and threonine inhibition was confirmed

when both amino acids were tested together, resulting in less

than 50% inhibition of the total AK activity in fl1 and fl2,

with lesser reductions being detected in the opaque mutants

Stimulation of HSDH activity by threonine was observed

for the Oh43o1 mutant, however, no major effects on AK

activity were observed in this mutant, which might indicate

a specific effect of the o1 gene on the HSDH domain of the

bifunctional polypeptide Apart from these results, HSDH

activity does not appear to be under any particular influence

from the mutations analyzed All the genotypes tested

exhibited variations for threonine inhibition, suggesting the

presence of both HSDH isoenzymes It has been suggested

that HSDH does not have a regulatory role in the

biosynthesis of lysine, although this enzyme shares the

same substrate (aspartate semialdehyde) with DHDPS,

which could eventually be a key point in determining

the flux of carbon through the pathway, leading to

threonine or lysine biosynthesis [10] Although a recent

study using transgenic Arabidopsis thaliana expressing

bacterial DHDPS and having knockout mutation for lysine

catabolism produced high increases in soluble lysine and

methionine [42], no evidence of an increase in soluble

methionine was detected in the opaque and floury mutants

analyzed in this work (data not shown)

Evidence has been obtained from biochemical and

molecular analyses that AK activity is possibly regulated

by the o2 gene [13], intensifying its effect on the total pool of

SAA and free threonine accumulation in maize endosperm

[13] Moreover, one of the genes encoding a lysine-sensitive

AK isoenzyme was linked to the o2 gene in chromosome 7

[13] Wang et al [43] also observed that AK activity varied

in its sensitivity to lysine inhibition, even between distinct

lines in which the o2 was introduced Furthermore, several

quantitative trait loci for SAA content have been identified,

one of them linked to another AK-HSDH encoding gene

[43] The analysis of o2 mutants has indicated that the

lysine-sensitive AK isoenzyme, but not the bifunctional

threonine-sensitive AK-HSDH isoenzyme, is affected by the

mutation [43]

The enzymes of lysine catabolism, LOR and SDH, were also analyzed in all genotypes and exhibited significant alteration in activity depending on the mutant LOR and SDH were initially identified as one bifunctional enzyme containing both enzyme domains [12,17,18], whilst later monofunctional LOR and SDH enzymes were identified [12] The results reported in the literature generally indicated that SDH activity is more stable than LOR activity [5] The dramatic sixfold reduction of LOR activity in the mutant Oh43o2 also confirmed the results observed for the effect of the o2 gene on LOR activity [9], which is due to a decreased mRNA and enzyme protein synthesis [29] SDH activity was also influenced by the o2 gene, exhibiting a 4.9-fold decrease in enzyme activity, which is a greater reduction when compared with previous work with this mutant [9] The reduction in LOR and SDH activities observed for the Oh43o2 mutant was also observed in Oh43fl1 and Oh43fl2 mutants, with the latter exhibiting a LOR activity even lower that of the Oh43o2 mutant (7.1-fold)

Our results suggest that the catabolism of lysine catalyzed

by the enzyme LOR, may be under the regulation of the opaque and floury mutations This is in addition to the biosynthetic enzymes AK and to a lesser extent HSDH discussed previously The way this pleiotropic regulation can take place may be different according to the mutation It has been shown in previous studies in which the LOR and SDH enzymes were isolated and characterized, that the LOR has an essential role in the regulation of lysine catabolism, as this enzyme is modulated by Ca2+, ionic strength and protein phosphorylation/dephosphorylation in several plant species [19,29,44,45], however, such modula-tion effects do not appear to influence SDH activity Pleiotropic regulation is also supported by the effect of the mutations on the storage proteins analyzed by 2D-PAGE

In parallel with their considerable effect on LOR and SDH activity, both o2 and fl2 induced large alterations in the synthesis pattern of a22 kDa and c27 kDa zeins Further-more, the Oh43o2 and Oh43fl2 mutants also exhibited higher concentrations of soluble lysine in the endosperm, not only based on its concentration, but accompanying the effect of each mutation on the concentration of the total pool of SAA

Curiously, the Oh43o1 mutant, which has been classi-fied as high-lysine, did not exhibit major effects on the catabolism of lysine in the endosperm, which suggests that the high lysine concentration cannot be explained by an altered lysine catabolism in this mutant Although there was a slight increase in the concentration of soluble lysine

in the Oh43o1 mutant when compared with the other mutants, the lysine degradation enzyme pattern as well as the AK activity, was shown to be at the same level of the wild-type counterpart Furthermore, Hunter et al [31] who also analyzed this mutant, but in a different genetic background, could not find any important effect of this mutation The mutants Oh43o1 and Oh43fl1 exhibited little effect either on the zein polypeptides or on LOR and SDH activities

The analysis of other mutations in the same phenotypic class as the o2 gene indicates that the mutations may strongly influence lysine metabolism and storage protein synthesis and accumulation in maize Many of the zein polypeptides have been shown to vary in these mutants and

a new range of studies must be carried out to determine the

precise molecular regulation of the synthesis of these

polypeptides by such mutations It is also clear that future

studies on the effect of these mutations should also be

carried out on the activity of the DHDPS enzyme, which has

been shown to be a key regulatory step in lysine biosynthesis

[5,10], but has only been tested in the o2 mutant so far [43]

Acknowledgements

This work was financed by grants to RAA from Fundac¸a˜o de Amparo

a` Pesquisa do Estado de Sa˜o Paulo, Brazil (FAPESP 98/12461–0 and

01/13904–8) and the British Council (RAA and PJL) The authors also

wish to thank the Conselho Nacional de Desenvolvimento Cientı´fico e

Tecnolo´gico (CNPq, Brazil) and FAPESP for the scholarships and

fellowships received, Professor L Sodek (UNICAMP) for the critical

reading of the manuscript, J Carmezzini for the growth of the

mutants, A Karime, M Garcia and F Mestrinelli for technical

assistance.

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