Inhibitors of endogenous proteinases in the seeds of Scots pine, Pinus sylvestris

Extracts of resting pine seeds inhibited the proteinase activities present in extracts of endosperms of germinating seeds (hydrolysis of haemoglobin at pH 3.7 and hydrolysis of casein at pH 5.4 and 7.0). Heating the extracts of resting seeds at 60°C destroyed their own proteinase activity but their proteinase inhibitor activity decreased by only 25 to 30%. Some properties of the inhibitor(s) were studied using extracts treated at 60°C. The inhibitor activities were non-dialysable. the inhibition increased linearly with increasing inhibitor concentration up to 80% of total proteinase activity, and the maximal inhibition was 80% at pH 3.7. 90% at pH 5.4. and 97% at pH 7.0. The extracts of resting seeds did not inhibit the pepsin-like acid pine proteinase that accounts for a minor part of the proteolytic activity of endosperm extracts at pH 3.7. Neither did they have any effect on the acid pine carboxypeptidase or trypsin and chymotrypsin. Fresh extracts of endosperms of germinating seeds contained relatively high proteinase activity (assayed directly) and moderate inhibitor activity (assayed after treatment at 60°C). When fresh extracts were dialysed at 50°C for 48 h their proteinase activities increased considerably while the corresponding inhibitor activities disappeared. It is concluded that the decrease of inhibitors during dialysis is due to enzymatic inactivation and that the corresponding increase of proteinase activities is at least partly due to the destruction of the inhibitors.     

Proteolytic Activities in x Haynaldoticum sardoum Seeds of Different Ages

Carboxypeptidase, aminopeptidase and proteinase activities weremeasured in endosperms from dry and germinating x Haynaldoticumsardoum naturally aged seeds. Carboxypeptidase activity, presentin dry seeds, decreased slightly during germination and remainednearly unchanged during the storage period. Aminopeptidase activityincreased during germination in younger seeds, but decreasedin non-viable seeds. Proteinase activity was absent in dry seeds,increased during germination in younger seeds and disappearedin the older ones. Proteinase activity was not recovered in old endosperms followingtransplantation of young embryos, and was recovered only toa very small extent in young endosperms following transplantationof old embryos. Young endosperms onto which young embryos hadbeen transplanted gave maximum recovery of enzyme activity,although this was lower than in young intact seeds. These results suggest that the reduced or delayed availabilityof nutrients to the embryo axis is not the only factor causingthe failure of seeds to germinate, the ageing process beinga progressive phenomenon affecting both embryo and endosperm. x Haynaldoticum sardoum, Denti de cani, seed ageing, proteolytic activities, embryo-transplantation     

Localization and Activity of Naphthylamidases in Germinating Seeds of Scots Pine, Pinus sylvestris

Extracts prepared from endosperms of germinating seeds of Scots pine, Pinus sylvestris L., rapidly hydrolysed the β-naphthylamides of L-phenylalanine and L-leucine optimally at pH 6.5 and that of L-arginine at pH 7.7. Disc electrophoresis followed by activity staining showed that the activities were due to two naphthylamidases (aminopeptidases) with different substrate specificities. Seeds were allowed to germinate at 20°C on agar gel in the dark and the activities on the three substrates were assayed from separated endosperms and seedlings at various stages of germination. The activities in the endosperm of resting seeds were relatively high and they remained unchanged throughout the period of reserve protein mobilization (seedling length up to 50 mm), after which they began to decrease. The activities of the naphthylamidases are rather small compared with those of the two alkaline peptidases of pine, contributing about 17% of the total amino-peptidase activity in the endosperm of germinating seeds. The total aminopeptidase activity is sufficient to account for the rate of storage protein mobilization during germination. In the seedlings the naphthylamidase activities (per seedling) increased continuously during germination, and activities per g dry weight were higher than those in the endosperm.     

Asparaginyl endopeptidase during maturation and germination of durum wheat

Asparaginyl-endopeptidase activity was detected in endosperms of maturing and germinating wheat seeds. The highest activity was found during maturation before the maximal accumulation of storage proteins. The enzyme activity then decreased in the dry seeds and increased again during germination. The increase of activity during germination required the presence of the embryo. In fact, the activity found in detached endosperms was lower than that found in attached ones. The localization at tissue level of the enzyme reveals differences between maturation and germination: the enzyme was about equally located in the aleurone layer and starchy endosperm during maturation, but solely in the aleurone layer during germination. The asparaginyl enzymes from maturing and germinating seeds had many similar properties, such as pH optimum, pH stability, thermal stability and sensitivity to thiol reagents and to thiol compounds. The results suggest that asparaginyl endopeptidases may be involved in the modification of proproteins of storage proteins during seed maturation and in the degradation of storage proteins deposited in the aleurone layer during germination.     

Proteinase activities in resting and germinating seeds of Scots pine, Pinus sylvestris

Resting seeds of Scots pine contained a moderate amount of acid proteinase activity, about 90% of which was inhibited by pepstatin A and about 10% by p-hydroxymer-curibenzoate. In gel chromatography on Sephacryl S-200 the proteinase activity showed a complex elution pattern with poorly separated peaks at positions corresponding to mol. wts. 100,000 and 30,000 and several shoulders. The results suggested that pine proteinases I and II, which are the main proteinases in the endosperms of germinating seeds (Salmia 1981: Physiol. Plant. 51: 253–258), were not present in the resting seeds.—Seedling extracts showed a low level of acid proteinase activity, which separated into several peaks in chromatography on Sephacryl S-200. As none of the peaks had the catalytic properties of proteinase I or II, it seems that these endospermal enzymes are also lacking in the seedling tissues.—In the endosperms of germinating seeds the activity of the pepstatin-sensitive acid proteinase(s) remained at a constant level throughout the period of reserve protein mobilization (lasting up to the stage when the length of dark-grown seedlings was 60 mm). Proteinases I and II were absent from resting seeds, showed a small increase up to the 20-mm stage, and then increased rapidly up to the 60-mm stage.—Resting embryos contained relatively higher acid proteinase activity than resting endosperms, and again about 90% of it was inhibited by pepstatin A and about 10% by p-hy-droxymercuribenzoate. During germination the former activity decreased, the latter activity remained at approximately the same level, and the activity of the other acid proteinases increased continuously with the growth of the seedling.—It is concluded that the pepstatin-sensitive proteinase(s), which is not affected by endogenous proteinase inhibitors, plays a central role in the initiation of reserve protein mobilization in both the embryo and the endosperm. Proteinases I and II, on the other hand, seem to account for the greater part of reserve protein breakdown in the main protein storage tissue, the endosperm.     

Fractionation of the proteinases present in the endosperm of germinating seed of Scots pine, Pinus sylvestris

When fresh extracts of endosperms separated from germinating seeds of Scots pine were dialysed at 5°C, proteinase activity on haemoglobin at pH 3.7 showed only a small initial increase, proteinase activities on casein at pH 5.4 and at pH 7.0 increased several-fold, and all the corresponding inhibitor activities disappeared (Salmia and Mikola 1980, Physiol. Plant. 48: 126–130). To find out what happens during dialysis, both fresh and dialysed extracts were fractionated by gel chromatography on Sephacryl S-200. – The fresh extracts had a major proteinase peak (mol. wt. 42,000) with high activity at pH 3.7 and moderate activities at pH 5.4 and 7.0 (pine proteinase I) and a smaller peak (mol. wt. 30,000) with high activity at pH 5.4 and 7.0 and smaller activity at pH 3.7 (pine proteinase II). In dialysed extracts the situation was reversed: the peak of proteinase I was very small while the peak of proteinase II was very high. Apparently, proteinase I is largely inactivated during dialysis while the activity of proteinase II increases, at least partly due to destruction of inhibitors. – The two enzymes were -SH proteinases, as they were completely inhibited by p -hydroxymercuribenzoate; both of them were also inhibited by the endogenous proteinase inhibitors of resting pine seeds. Besides these enzymes, the endosperm extracts contained pepsin-like acid proteinase activity, which is not affected by the endogenous inhibitors. This enzyme activity was largely inactivated during dialysis.     

Occurrence of proteolytic inhibitors in various tissues of barley

Summary The three groups of proteolytic inhibitors present in resting barley grains, namely, trypsin inhibitors, Aspergillus-proteinase inhibitors, and inhibitors of endogenous proteinases, occur in both the embryo and the two endosperm tissues. There are pronounced quantitative differences, however. The three inhibitor activities in the embryo are, respectively, 6-, 0.1-, and 6-fold of those in the endosperm.During germination at 20° all inhibitor activities disappear from the endosperms in 4–5 days. Young rootlets and coleoptiles contain inhibitors of trypsin and Aspergillus proteinase, but these disappear after 4–5 days' germination. However, the trypsin inhibitor content per seedlings remains roughly constant through the whole period. The Aspergillus-proteinase inhibitors, in contrast, exhibit a pronounced increase of activity per seedling.No inhibitor activities were detected in leaves and roots at later stages of growth.The trypsin inhibitor which we have earlier purified from resting grains occurs exclusively in the two endospermal tissues and is immunologically entirely different from the trypsin inhibitors present in embryos and young seedlings.     

Proteinase activities in quiescent and germinating seeds of xHaynaldoticum sardoum

Breakdown of gliadin during germination of xHaynaldoticum sardoum Meletti et Onnis seeds is correlated with the appearance in the endosperms of a proteinase activity, which is absent in the quiescent seed. This activity is optimal at pH 4 and has a maximum stability at pH 4–5. Gel filtration of proteinase activity extracted from quiescent seeds indicates a molecular weight of 60–100 kDa. The proteinase can hydrolyze hemoglobin but not gliadin and is inhibited by pepstatin A and, to a lower extent, by p -chloromercuribenzoic acid (p-CMB). Gel filtrations of crude extracts from germinating seeds reveal two peaks (molecular weight 66 and 21 kDa) of activity against hemoglobin and a shoulder and a peak (molecular weight 21 kDa) of activity on gliadin. The first peak of activity against hemoglobin is inhibited by pepstatin A and p-CMB; the second one is inhibited by p-CMB and leupeptin. As for the gliadin-eluted activity the shoulder is mainly inhibited by pepstatin A and p-CMB, whereas the peak is inhibited by p-CMB and leupeptin. Estimations of the ratios of total nitrogen to α-amino nitrogen, suggest that the enzyme preparations mainly contain proteinases. It is concluded that the proteinases present in the quiescent seeds of xH. sardoum , in particular aspartic proteinases (EC 3.4.23), could play a role as initiator endoproteases or participate in the digestion of modified proteins during the mobilization of reserve proteins. The cysteine proteinases (EC 3.4.22) appearing during the germination seem to account for the hydrolysis of the most abundant class of protein reserves, the prolamins.     

Degradation of the endosperm cell walls of Lactuca sativa L., cv. grand rapids in relation to the mobilisation of proteins and the production of hydrolytic enzymes in the axis,cotyledons and endosperm

The timing of changes in total nitrogen and soluble amino nitrogen content, and in the activities of proteinase (pH 7.0), isocitrate lyase, catalase, phytase, phosphatase (pH 5.0), -galactosidase and -mannosidase were studied in extracts from the cotyledons, axis and endosperms of germinating and germinated light-promoted lettuce seeds. The largest amount of total nitrogen (2.7% seed dry weight) occurs within the cotyledons, as storage protein. As this decreases the total nitrogen content of the axis increases and the soluble amino nitrogen in the cotyledons and axis increases. Proteinase activity in the cotyledons increases coincidentally with the depletion of total nitrogen therein. Enzymes for phytate mobilisation and for gluconeogenesis of hydrolysed lipids increase in activity in the cotyledons as the appropriate stored reserves decline. Beta-mannosidase, an enzyme involved in the hydrolysis of oligo-mannans released by the action of endo--mannase on mannan reserves in the endosperm, arises within the cotyledons. This indicates that complete hydrolysis of mannans to the monomer does not occur within the endosperm. Mobilisation of all cotyledon reserves occurs after the endosperm has been degraded, providing further evidence that the endosperm is an early source of food reserves for the growing embryo.Abbreviations HEPES N-2-hydroxyethylpiperazine-N-2-ethanesulphonic acid - EDTA ethylenediamine tetraacetic acid disodium salt - TCA trichloroacetic acid Part 2 of a series, of which the first was published in Planta 139, 1–8 (1978)     

Localization and Activity of a Carboxypeptidase in Germinating Seeds of Scots Pine, Pinus sylvestris

Extracts prepared from the endosperm of germinating seeds of Scots pine, Pinus sylvestris L., hydrolysed two typical carboxypeptidase substrates, Z-Phe-Ala and Z-Phe-Phe, with pH optima at 4.2 and 5.0. The activities were completely destroyed by diisopropylfluorophosphate. Identical heat inactivation curves and elution patterns in gel chromatography on Sephadex G-200 suggest that the two activities are due to a single enzyme. In resting seeds very low carboxypeptidase activity was present in both the endosperm and the embryo. During germination on agar gel at 20°C in the dark the activities, expressed as enzyme units per seed, increased in the seedling and particularly in the endosperm up to the stage when the reserves of the endosperm were completely depleted. The time of rapid increase of activity in the endosperm did not coincide with the onset of storage protein mobilization. On the contrary, the major part of the increase occurred after the bulk of endosperm nitrogen had already been transferred to the seedling. The results suggest that the carboxypeptidase does not play a major role in the mobilization of storage proteins in germinating pine seeds. On the other hand, it probably functions in the proteolytic reactions associated with the senescence of the reserve-depleted endosperm.     

Cadmium elevates level of protein, amino acids and alters activity of proteolytic enzymes in germinating rice seeds

When seeds of two rice cvs. Ratna and Jaya were germinated under increasing levels of cadmium nitrate (0, 100 and 500 μM) in the medium, a marked decrease in germination percentage was observed with Cd treatments, as compared to controls. There was more absorbed Cd in embryo axes than in endosperms. More uptake resulted with increasing Cd levels in the growth medium in embryo axes. In both rice cultivars, during a germination period of 0 – 120 h, an increased level of protein as well as free amino acids was noted in Cd treatments. Protease activity in general decreased in both embryo axes as well as endosperms due to Cd treatment. In vitro studies showed an enhancement in protease activity in Cd treatments at low Cd levels (50–100 μM), whereas concentrations above this caused inhibition in enzyme activity. Under 500 μM Cd treatments in vivo there was about 30 to 50 percent decline in leucine aminopeptidase (LAP) activity in endosperms, however, carboxypeptidase activity showed a marked increase in endosperms beyond 24 h under Cd treatments. In embryo axes of germinating seeds there was always a decline in peptidase activities, under the influence of cadmium. The leucine amino peptidase and protease activity were always greater in embryo axes in cv. Ratna than cv. Jaya. However, the carboxypeptidase activity was higher in Jaya when compared to Ratna in endosperms under Cd treatments. The results suggest possible suppression of protease and peptidase activities due to Cd treatments in germinating rice seeds leading to altered levels of protein and amino acids.     

Characterization of asparaginyl endopeptidase activity in endosperm of developing and germinating castor oil seeds

A spectrophotometric assay was devised to characterize the asparaginyl (Asn) endopeptidase activity from the endosperm of castor oil seeds. (Ricinus communis L. var. Baker 296). The assay measures the release of p-nitroaniline from the hydrolysis of benzoyl-l-Asn-p-nitroanilide. Assay sensitivity was improved through diazotization of the reaction product with N(]-napthy])-ethylenediamine dihydrochloride: diazotized p-nitroaniline was determined spectrophotometrically at 548 nm (?₅₄₈= 1.64 × 10^?1M^?1 cm^?2). By using this assay. Asn endopeptidase activity was detected in endosperm extracts of developing, mature and germinating castor seeds. Comparison of the Asn endopeptidase activities of developing and germinating castor endosperms revealed that they: 1) have identical pH-activity profiles with optimal activity occuring at pH 5.4: 2) are heat-labile proteins displaying comparable thermal stability profiles, and 3) are activated and inhibited by dithiothreitol and thiol modifying reagents, respectively. Thus, the Asn endopeptidases of developing and germinating castor seeds are very similar, if not identical, cysteine proteases. The most significant increase in the activity of endosperm Asn endopeptidase occurs during the full coryledon to maturation stage of seed development, this period coincides with the most active phase of reserve protein accumulation by ripening castor oil seeds. Asn endopeptidase activity of fully mature (dry) castor seeds was about 2-fold lower than that of muturation stage ripening castor oil seed. Asn endopeptidase activity showed a slight reduction over the inicial 2-day period following seed imbibition, and then rapidly decreased over the next several days of germination. The results are compatible with the proposal that Asn endopeptidase functions both to process storage preproteins following their import into protein bodies of developing seeds, as well as to participate in the mobilization of storage proteins during the early phase of seed germination.     

Characterization of the Proteinases Present in Germinating Seeds of Scots Pine, Pinus sylvestris

Methods were developed to determine proteinase activity in germinating seeds of Scots pine. The assays were based on the liberation of TCA-soluble peptides from haemoglobin at pH 3.7 and from casein at pH 5.4 and pH 7.0; the reaction products were determined by the Lowry method. — Endosperms separated from seeds at the time of rapid storage protein mobilization (seedling length between 20 and 50 mm) showed high proteinase activities in all three assays. Experiments with different inhibitors suggested that at least four enzymes were involved. One of the enzymes resembled mammalian and microbial pepsin-like acid proteinases: the pH optimum was 3.7 and the enzyme was inhibited by pepstatin.—The proteinase activities in the endosperms were high enough to account for the mobilization of the reserve proteins during germination. Moreover the activities at pH 3.7.5.4. and 7.0 in the endosperms were 10-, 25-, and 50-fold the corresponding activities in the growing seedlings (a “reference” tissue). Consequently, it seems that both the acid and neutral proteinases take part in the mobilization of storage proteins in the germinating seed.     

Increased hexokinase levels in endosperm of mutant maize

Hexokinase activity was measured in endosperms of shrunken-2 (sh₂) and starchy maize. Initial increases in hexokinase were observed for developing endosperms of both genotypes, and the enzyme declined in both as the seeds matured. A higher level of hexokinase was observed in developing sh₂ than in starchy endosperm. This difference persisted throughout maturation and occurred also in germinating seeds. Soluble hexokinase activity per endosperm continued to increase in sh₂ for about 8 days (22–30 days after pollination) after the enzyme in starchy endosperm had attained maximum activity and begun to decline. Hexokinase was predominantly soluble in both genotypes so the differences observed are not due to altered distribution of enzyme between particulate and soluble fractions.     

Phosphoenolpyruvate carboxylase activity and concentration in the endosperm of developing and germinating castor oil seeds

Monospecific polyclonal antibodies against maize leaf phosphoenolpyruvate carboxylase (PEPC, EC 4.1.1.31) were utilized to examine the subunit composition and developmental profile of endosperm PEPC in developing and germinating castor oil seeds (Ricinus communis L. cv Baker 296). PEPC from developing endosperm consists of a single type of 100-kilodalton subunit, whereas the enzyme from 2- to 5-day germinated endosperm appears to contain equal proportions of immunologically related 103- and 108-kilodalton subunits. The maximal activity of PEPC in developing endosperms (2.67 micromoles oxaloacetate produced per minute per gram fresh weight) is approximately 20-fold and threefold greater than that of fully mature (dry seed) and germinating endosperms, respectively. The most significant increase in the activity and concentration of endosperm PEPC occurs during the middle cotyledon to full cotyledon stage of seed development; this period coincides with the most active phase of storage oil accumulation by ripening castor oil seeds. The data are compatible with the recent proposal (RG Smith, DA Gauthier, DT Dennis, DH Turpin [1992] Plant Physiol 1233-1238) that PEPC plays a fundamental role in vivo in the cytosolic production of an important substrate (malate) for fatty acid biosynthesis by developing castor oil seed leucoplasts. Immediately following seed imbibition, PEPC activity and concentration increase in parallel, with the greatest levels attained by the third day of germination. It is suggested that during this early phase of seed germination PEPC has a critical function to build up cellular dicarboxylic acid pools required to initiate significant activities of both the tricarboxylic acid and glyoxylate cycles.     

Endopeptidases of Triticale Seeds

The changes in endopeptidase activity in different parts of germinating triticale cv. Malno were investigated. Haemoglobin, gliadin, azocasein and azoalbumin were used as substrates. During the first day of germination the activity of haemoglobin hydrolyzing endopeptidases predominated while after the second day, mainly in the endosperm, a rapid increase in endopeptidases activity preferring gliadin hydrolysis was observed. In all the investigated tissues azocaseinolytic activities increased with the successive days of germination. Similar changes were observed using azoalbumin with one exception: in the embryo axis this activity decreased with the progression of germination. Separation of endopeptidases on the DEAE Sepharose CL-6B reveals three activity peaks in extract from dry seeds and four peaks in extract from 3 d germinated seeds. The obtained peaks differed in substrate specificity and in sensitivities to class-specific inhibitors.     

Two Additional Phosphorylases in Developing Maize Seeds

Two additional phosphorylases (III and IV) have been detected in developing seeds of maize. Phosphorylase IV is found only in the embryo (with scutellum). It is also present in the embryo of the germinating seed where its activity is 90-fold greater than the activity in the developing embryo 22 days after pollination. Phosphorylase IV is eluted from a DEAE-cellulose column in the same fraction as phosphorylase I of the endosperm, and the 2 enzymes are similar in many respects. Phosphorylase IV is distinguished from phosphorylase I by electrophoretic mobility, by pH optimum, and because its properties are not affected by the shrunken-4 mutation.Phosphorylase III is found both in the endosperms and embryos of developing seeds. Activity for this enzyme is not detected in crude homogenates nor eluates from a DEAE-cellulose column apparently because it complexes with a non-dialyzable, heat-labile inhibitor. High activity is found after protamine sulfate fractionation. Phosphorylase III is bound to protamine sulfate and is then removed by washing with 0.3 m phosphate buffer. Phosphorylase III activity in the endosperm is not detectable 8 days after pollination but is present 12 days after pollination. Phosphorylase III differs from phosphorylases I, II, and IV in several respects-pH optimum, pH-independent ATP inhibition, time of appearance in the endosperm, and because purine and pyrimidine nucleotides are equally inhibitory. In common with phosphorylase II, phosphorylase III apparently does not require a primer to initiate the synthesis of an amylose-like polymer.     

Protein Body Degradation in the Starchy Endosperm of Germinating Sorghum

Taylor, J. R. N., Novellie, L. and Liebenberg, N. v. d. W. 1985.Protein body degradation in the starchy endosperm of germinatingsorghum.—J. exp. Bot. 36: 1287–1295. Transmission electron micrographs of starchy endosperms of germinatingsorghum indicate that the protein bodies are degraded predominantlyby progressive hydrolysis of prolamin from their surface. Theappearance of holes within partially degraded protein bodiesindicates that some internal hydrolysis also takes place. Chemicalanalyses of protein bodies isolated at different stages duringgermination showed that their amino acid composition and electrophoreticpattern remained relatively unchanged during hydrolysis. Theend result of protein body degradation was that the organellescompletely disappeared leaving empty starchy endosperm cells.The protein bodies did not swell prior to or during degradation.This mode of protein body degradation differs from that in germinatingdicotyledonous seeds and in the aleurone layer and embryo ofcereal seeds but was identical to the mode of prolamin proteinbody degradation in the starchy endosperm of germinating riceseeds. Key words: Sorghum bicolor, protein body degradation, prolamin     

Purification and partial characteristic of a major gliadin-degrading cysteine endopeptidase from germinating triticale seeds

The endopeptidase of the highest electrophoretic mobility was the main endopeptidase hydrolyzing gliadin in the endosperm of germinated triticale (X Triticosecale Wittm.) grains after three days of imbibition. Activity of this endopeptidase, named EP8 starts to be detectable after two days of imbibition. The appearance of its activity in the endosperm on a second day of imbibition may suggest that EP8 is synthesized in aleurone during germination and/or secreted into the starchy endosperm as an inactive polypeptide during grains development and then activated. EP8 was isolated from the endosperm of germinating triticale seeds and purified 257-fold using ammonium sulphate, ion exchange chromatography on DEAE Sepharose CL-6B and gel filtration on Sephadex G-100. The enzyme was totally inhibited by E-64—class-specific cysteine proteinases inhibitor and activated by thiol compounds. Molecular weight estimated by SDS-PAGE was 39.5 kDa. The optimum pH for the hydrolysis of gliadin was 4.2 and for hemoglobin 5.2. High activity of EP8 against wheat gliadin in vitro suggests that this cysteine endopeptidase plays a major role in the mobilization of storage proteins in the endosperm of germinating triticale grains.     

The Hydrolysis of Endosperm Protein in Zea mays

Degradation of the major storage proteins in maize endosperm, zein and glutelin, begins during the 2nd day of germination. The protein most abundant in the mature endosperm is degraded most rapidly. The patterns of protein loss are essentially similar in germinating seeds and excised endosperms. Cycloheximide, added at the beginning of the incubation period, prevents the development of α-amylase and protease activities and the disappearance of starch and protein reserves. Late additions (70 hours) of cycloheximide still inhibit the increase in hydrolase activity but have no effect on the hydrolysis of storage reserves. The results indicate that the hydrolytic enzymes are synthesized de novo in the maize endosperm.