Differences in the activity and distribution of peroxidases from three different portions of germinating Brassica oleracea seeds

Peroxidase (POD, EC 1.11.1.7) activity, cellular localization and isozyme patterns were investigated in the seed integument, cotyledon and embryo axis of Brassica oleracea cv. Cappuccio during pregermination and seedling growth. Seeds started to germinate after 24 h of imbibition. POD activity was localized in the pigmented layer of the integument and in procambial strands of the cotyledon and embryo axis in the first 24 h of imbibition. It was localized in the integumental cells of palisade, pigmented and aleurone layers and in epidermal, meristematic, procambial cells and xylem elements of the root and hypocotyl after 48 h of imbibition. POD activity increased during germination and early seedling growth: in the integument, it reached a maximum value after 72 h of imbibition, in the embryo axis and cotyledons, it increased up to 144 h of imbibition. The increase in peroxidase activity was accompanied by the appearance of new isozymes correlated with the development of seedling tissues. The isozyme profile was characterized by nine peroxidases: isoperoxidase of 50 kDa peculiar to integuments, that of 150 kDa to cotyledons and that of 82 kDa to the embryo axis. During pregerminative phase isozymes of 84 kDa were detected in the integument and cotyledons, of 48.5 kDa in the embryo axis. After germination, peroxidase activity and the complexity of the isozyme pattern increased, suggesting that they play a relevant role after rupture of the integument.     

Effects of ageing on peroxidase activity and localization in radish (Raphanus sativus L.) seeds

Peroxidase activity was assayed in crude extracts of integument, cotyledons and embryo axis of radish seeds, deteriorated under accelerated ageing conditions. Over five days of ageing, in which germination decreased from 100 to 52%, the enzyme activity in integument was higher than that in other seed parts, increasing in the first days of ageing and then decreasing sharply in extremely aged seeds. Polyacrylamide gel electrophoresis analysis showed four peroxidase isoenzymes with MM of 98, 52.5, 32.8 and 29.5 kDa in the embryo axis of unaged seeds, and only the 32.8 and 29.5 kDa MM isoforms in the integument and cotyledons. In these parts of the seed, only the 29.5 kDa MM isoenzyme increased in activity in early days of ageing and decreased there-after. In the embryo axis, the 29.5 kDa MM isoenzyme activity increased slowly in the first day of ageing, while the 98 and 52.5 kDa MM isoenzyme activities disappeared. A cytochemical localization of peroxidase activity in the various tissues showed that main differences between unaged and extremely aged seeds occurred in the embryo axis.     

Immunolocalization of the PmSUC1 sucrose transporter in Plantago major flowers and reporter-gene analyses of the PmSUC1 promoter suggest a role in sucrose release from the inner integument

This paper presents a detailed analysis of the PmSUC1 gene from plantago major, of its promoter activity in Arabidopsis, and of the tissue specific localization of the encoded protein in Plantago. PmSUC1 promoter activity was detected in the innermost layer of the inner integument (the endothel) of Arabidopsis plants expressing the gene of the green fluorescent protein (GFP) under the control of the PmSUC1 promoter. This promoter activity was confirmed with a PmSUC1-specific antiserum that identified the PmSUC1 protein in the endothel of Plantago and of Arabidopsis plants expressing the PmSUC1 gene under the control of its own promoter. PmSUC1 promoter activity and PmSUC1 protein were also detected in pollen grains during maturation inside the anthers and in pollen tubes during and after germination. These results demonstrate that PmSUC1 is involved in sucrose partitioning to the young embryo and to the developing pollen and growing pollen tube. In the innermost cell layer of the inner integument, a tissue that delivers nutrients to the endosperm and the embryo, PmSUC1 may catalyze the release of sucrose into the apoplast.     

Regulation of juvenile hormone esterase gene expression in the tobacco budworm (Heliothis virescens)

The tissue distribution, developmental control, and induction of juvenile hormone esterase (JHE) mRNA was examined in Heliothis virescens using an 800-base pair fragment of a JHE cDNA clone. Northern hybridization analysis of poly(A)+RNA from fat body and integument of fifth stadium larvae indicated the presence of a single JHE mRNA species having an estimated length of 3 kilobases. On Day 2 of the fifth stadium (L5D2), basal JHE mRNA levels were 3-fold higher in the integument than the fat body, which correlated with the higher specific activity of the enzyme in the integument at this time. However, JHE mRNA levels in the fat body on Day 4 of the fifth stadium were 9-fold higher than on Day 2, while mRNA levels in the integument remained the same. This endogenous increase in JHE mRNA and activity in the fat body occurred at the time of peak hemolymph JHE activity. JHE mRNA was not detected in third stadium larvae which have very low levels of JHE activity. Treatment of L5D2 larvae with the juvenile hormone mimic epofenonane resulted in a 7- and 14-fold increase in the level of JHE mRNA in the integument and fat body, respectively. The mRNA induced in both tissues was of the same estimated length as the constitutively expressed message. The data indicate that the developmental regulation and induction of JHE can occur at the level of mRNA. There is evidence that the fat body secretes more JHE than does the integument and could be the major source of hemolymph JHE.     

Alkaline phosphatase in the integument of Ceratitis capitata: Developmental profile and functional properties

Electrophoretic analysis of alkaline phosphatase from the integument during development, reveals two bands of enzyme activity. One corresponding to phosphatase activity during pupation and just prior to eclosion and the other during the middle of the pupal stages. On the contrary in the haemolymph there is one band on enzyme activity through all the developmental stages. The haemolymph alkaline phosphatase band does not comigrate with any integumental enzyme band. The developmental profile of the integumental alkaline phosphatase activity has also been compared to that of the haemolymph. It was found that the pattern of activity is completely different. In the integument, two peaks of enzyme activity were found: one just prior to pupation and the other during eclosion. These two peaks do not coincide to that of haemolymph alkaline phosphatase activity. The pH optimum for both enzyme forms of third instar larvae, although broad especially for haemolymph form, was clearly in the alkaline range, with a peak at pH 8.5–9.0. The two isozymes have different affinities for the substrate tyrosine-O-phosphate. Tyrosine-O-phosphate is the preferred substrate for the integumental enzyme form with a K_m of 0.4 mM. We suggest that alkaline phosphates from the integument is specific for the hydrolysis of tyrosine-O-phosphate.     

Histochemical characterization of esterases from three species of amphistomes

Esterase activity of Gigantocotyle explanatum, Ceylonocotyle scoliocoelium and Cotylophoron cotylophorum were localized histochemically in various regions associated with nutrition, viz, integument, pharynx, sucker and gastrodermis. The intensity of the reactions varied in the different regions of the same parasite and also from species to species. The distribution and relative activity of the esterases were investigated and the results reveal that the influence of inhibitors/activators on enzyme activity varied in the different regions. Based on the inhibitory effects it is inferred that carboxylesterases are distributed in the region of the integument, pharynx and gastrodermis, acetylesterases in the suckers and cholinesterase in the subtegumental cells and muscle of these three trematodes.     

Immunohistochemistry of active gibberellins and gibberellin-inducible alpha-amylase in developing seeds of morning glory

Gibberellins (GAs) in developing seeds of morning glory (Pharbitis nil) were quantified and localized by immunostaining. The starch grains began to be digested after the GA contents had increased and reached a plateau. Immunohistochemical staining with the antigibberellin A(1)-methyl ester-antiserum, which has high affinity to biologically active GAs, showed that GA(1) and/or GA(3) were localized around starch grains in the integument of developing young seeds, suggesting the participation of GA-inducible alpha-amylase in this digestion. We isolated an alpha-amylase cDNA (PnAmy1) that was expressed in the immature seeds, and using an antibody raised against recombinant protein, it was shown that PnAmy1 was expressed in the immature seeds. GA responsiveness of PnAmy1 was shown by treating the young fruits 9 d after anthesis with GA(3). RNA-blot and immunoblot analyses showed that PnAmy1 emerged soon after the rapid increase of GA(1/3). An immunohistochemical analysis of PnAmy1 showed that it, like the seed GA(1/3), was also localized around starch grains in the integument of developing young seeds. The localization of GA(1/3) in the integument coincident with the expression of PnAmy1 suggests that both function as part of a process to release sugars for translocation or for the further development of the seeds.     

棉铃虫幼虫加单氧酶活性的组织分布

棉铃虫（Ｈｅｌｉｃｏｖｅｒｐａ ａｒｍｉｇｅｒａ）６龄幼虫不同组织的加单氧酶活性的测定结果显示,对－硝基苯甲醚Ｏ－脱甲基酶主要分由于外来物质的入口部位,以中肠和脂肪体的活性较高,在前肠、后肠和马氏管等组织中有相对较低的活性,而在体壁和精巢中未检测到Ｏ－ 甲基作用。体壁表现一定的艾氏剂环氧化作用,但其活性不及中肠的１０％,内源性制剂被证明并非体壁低加单氧酶活性的主要原因。不同组织生物量的差异及其动态     

Juvenile hormone metabolism in the plasma,integument, midgut,fat body,and brain during the last instar of the tobacco hornworm,Manduca sexta (L.)

Juvenile hormone (JH) III esterase and JH III epoxide hydrolase activity was found in the integument, midgut, fat body, and brain during last instar development of the tobacco hornworm, Manduca sexta. JH esterase activity was primarily located in the cytosol in these tissues while the majority of the JH epoxide hydrolase activity was found in the microsomes. A prewandering (on day 3) and postwandering (on day 8) peak in plasma JH III esterase activity occurs in the last instar of gate I M. sexta. The JH esterase activity profile in integument, midgut, fat body, and brain followed a similar pattern to that of the plasma. The only exception to this was the absence of the postwandering, prepupal (on day 8) JH esterase peak in the fat body. The topical application of the juvenoid, (RS)-methoprene, failed to induce fat body JH esterase activity but increased activity in the plasma, integument, midgut, and brain in M. sexta prepupae. These results indicate that the source of plasma JH esterase activity is not always the fat body as previously hypothesized. The developmental profile of tissue JH epoxide hydrolase activity was also similar to that of JH esterase suggesting that both enzymes may be regulated partly by the same factors and that JH epoxide hydrolase may also have an important, previously unrecognized functional role in JH regulation and insect metamorphosis. Multiple isoelectric forms of tissue-specific JH esterases and JH epoxide hydrolases were found in integument, midgut, fat body, and brain. The JH esterases in these tissues had isoelectric points more acidic than that for plasma. Tissue α-naphthyl acetate esterase, developmental profiles, and inhibitor sensitivity to 3-(octylthio)-1,1,1-trifluoropropan-2-one differed significantly from that for JH esterase, suggesting that they represent different enzymes. ©1992 Wiley-Liss, Inc.     

ULTRACYTOCHEMICAL LOCALIZATION OF PLASMA MEMBRANE-ASSOCIATED PHOSPHATASE ACTIVITY IN DEVELOPING TOBACCO SEEDS

Plasma membrane-associated phosphatase activity was found in integumentary cells of developing tobacco ovules from the megaspore tetrad stage to seed maturity. Enzyme activity is greatest in the innermost layers of the integument from the mature megagametophyte stage on. The egg, zygote, and synergids almost totally lack plasma membrane-associated reaction product, while the antipodals show some activity at their chalazal ends. The endosperm has much plasma membrane-associated phosphatase activity in most of its cells during development, but it is primarily the outermost plasma membranes of the surface cells of the embryo that have associated reaction product. It is concluded that the plasma membrane-associated phosphatase activity is related to active transport of assimilates and that the integument is the most important site of active transport in the young ovule. After fertilization, in addition to the innermost layers of the integument, the endosperm and the outermost cells of the embryo become involved in active transport, which continues to seed maturity.     

Localization and General Properties of Developing Peach Seed Coat and Endosperm Peroxidase Isoenzymes

Changes of soluble and ionically bound peroxidase and indoleacetic acid (IAA) oxidase activities were followed during peach seed development. Soluble peroxidase activity was located mainly in the embryo plus endosperm tissue, whereas wall ionically bound activities were found predominantly in the integument tissue. The different peroxidase isoenzymes present in the extracts were characterized by polyacrylamide gel electrophoresis and isoelectric focusing; the main soluble isoenzyme of embryo plus endosperm tissue was an anionic isoperoxidase of R _F 0.07. Basic ionically bound isoenzymes were located only in the integument tissue, but two soluble anionic isoenzymes of R _F 0.23 and 0.51 were also present in this tissue. In parallel, peroxidase protein content was estimated specifically using polyclonal antibodies. The kinetic data and the changes of seed IAA oxidase activity during fruit development suggested that basic peroxidase isoenzymes from ionically bound extracts of integument might be involved in IAA degradation. Received September 11, 1997; accepted October 21, 1997     

保幼激素类似物及蜕皮甾类对亚洲玉米螟幼虫酚氧化酶活性的影响

分别用1 μg/头、0.1 μg/头和0.01 μg/头浓度的保幼激素类似物methoprene（蒙五一五）体外处理亚洲玉米螟5龄幼虫,测定幼虫体壁组织、血清和血细胞溶离物中酚氧化酶的活性。结果表明： 1 μg/头 methoprene处理组和0.1 μg/头处理组幼虫体壁组织中酚氧化酶活性与对照组相比有显著提高（P<0.01）,血清和血细胞溶离物中酚氧化酶活性也显著上升（P<0.01）。将含有20-羟基蜕皮酮的人工饲料饲喂亚洲玉米螟5龄幼虫,处理组幼虫体壁组织的酚氧化酶活性下降(P<0.05),血清和血细胞溶离物中的酚氧化酶活性均低于对照组 （P<0.01）。这些结果表明methoprene可以诱导亚洲玉米螟5龄幼虫体内酚氧化酶活性的上升,而20-羟基蜕皮酮则抑制了酚氧化酶的活性。     

21种杀虫剂和3种植物次生物质对杨扇舟蛾各组织谷胱甘肽S-转移酶的抑制作用

为了比较杨扇舟蛾Clostera anachoreta (Fabricius)各组织谷胱甘肽S 转移酶（GSTs）的差异,利用分光光度酶动力学的方法,研究了21种杀虫剂和3种植物次生物质对杨扇舟蛾4个组织（中肠、脂肪体、头部和体壁）GSTs活性的体外影响。结果表明:21种杀虫剂和3种植物次生物质对杨扇舟蛾4个组织GSTs活性的抑制作用不同。毒死蜱、氟虫腈、槲皮素和单宁酸对于杨扇舟蛾头GSTs活性抑制作用最强;槲皮素和单宁酸对中肠GSTs活性的抑制作用最强;单宁酸对脂肪体GSTs活性的抑制作用最强;辛硫磷、高效氯氟氰菊酯、溴氰菊酯和硫丹对皮GSTs活性的抑制作用最强。杨扇舟蛾4个组织GSTs对杀虫剂和植物次生物质敏感性存在的这种差异,可能是由于其在同工酶组成上的差异造成的。     

The entomopathogen Metarhizium anisopliae can modulate the secretion of lipolytic enzymes in response to different substrates including components of arthropod cuticle

The filamentous fungus Metarhizium anisopliae is a well-characterized, arthropod pathogen used in the biological control of arthropod pests. Studies on the regulation of enzymes related to host infection such as proteases and chitinases have been reported but little is known about regulation of lipolytic enzymes in this fungus. Here we present the effects of different carbon sources such as components of the arthropod cuticle on the secretion of lipolytic enzymes by M. anisopliae. Differences in the induction of lipolytic activity were observed between the several carbon sources tested. Higher activities of lipase or lipase/esterase were found in culture media containing the arthropod integument components chitin and cholesteryl stearate. Several bands of lipolytic activity were also detected in zymograms, thus suggesting an important set of lipolytic enzymes secreted by the fungus. These results show that the fungus can modulate the secretion of lipolytic activity in response to host integument components, thus reinforcing the potential role of these enzymes during M. anisopliae infection.     

The Ultracytochemical Localization of ATPase Activity in the Ovules of Antirrhinum majus L.

The ultracytochemical localization of ATPase activity was carried out by the method of lead precipitation in the ovules of Antirrhinum majus L. No ATPase activity is observed in the egg apparatus, but some in the polar nuclei, cytoplasm and plasma membrane of the central cell. Between the embryo sac wall and the cuticle surrounding it, there is a gap where some filamentand vesicle-like structures were demonstrated by conventional staining method, and much of ATPase activity is found there. At the chalaza of the ovule, a lot of ATPase particles are found irt the nuclei, plasma membranes and the thick and loose wall of the hypostase cells. The particles of ATPase in the hypostase and those in the gap surrounding embryo sac are continuously distributed through the intervals of the cuticle at the chalazal end of the embryo sac. Some of ATPase particles are found on the plasma membranes and plasmadesmata of integument ceils, noticeably much more in the nucleoplasm of the integumentary tapetum. According to the ATPase distribution pattern in the ovules, we suggest that the function of the integumentary tapetum and hypostase is secretion, and that the gap surrounding the embryo sac may be an apoplastic ehannal for nutrient flow into the embryo sac.     

The Arabidopsis SUPERMAN Gene Mediates Asymmetric Growth of the Outer Integument of Ovules

Arabidopsis superman (sup, also referred to as floral mutant10) mutants have previously been shown to have flowers with supernumerary stamens and reduced carpels as a result of ectopic expression of the floral homeotic gene APETALA3 (AP3). Here, we report that sup mutations also cause specific alterations in ovule development. Growth of the outer integument of wild-type ovules occurs almost exclusively on the abaxial side of the ovule, resulting in a bilaterally symmetrical hoodlike structure. In contrast, the outer integument of sup mutant ovules grows equally on all sides of the ovule, resulting in a nearly radially symmetrical tubular shape. Thus, one role of SUP is to suppress growth of the outer integument on the adaxial side of the ovule. Genetic analyses showed that the effects of sup mutations on ovule development are independent of the presence or absence of AP3 activity. Thus, SUP acts through different mechanisms in its early role in ensuring proper determination of carpel identity and in its later role in asymmetric suppression of outer integument growth.