A Comparison of Alpha‐amylases From the Latex of Three Selected Species of Euphorbia (Euphorbiaceae)

Biesboer, David D.; Mahlberg, Paul G.

doi:10.1002/j.1537-2197.1981.tb07793.x

Cited by 10 publications

(5 citation statements)

References 20 publications

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“…Bark beetles, for example, attack host trees en masse, thereby overwhelming the defensive response of their canals (Cates andAlexander 1982, Birch 1984). Besides vulnerability to behavioral deactivation, canal-borne defenses pose a second problem: when injured, they release large volumes of fluids, which are lost to the plant (although many canals have plugging agents to minimize drainage; Cronshaw et al 1973, Buttery and Boatman 1976, Biesboer and Mahlberg 1981.…”

Section: Discussionmentioning

confidence: 99%

Deactivation of Plant Defense: Correspondence Between Insect Behavior and Secretory Canal Architecture

Dussourd¹,

Denno²

1991

Ecology

155

158

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JSTOR is a not-for-profit service that helps scholars, researchers, and students discover, use, and build upon a wide range of content in a trusted digital archive. We use information technology and tools to increase productivity and facilitate new forms of scholarship. For more information about JSTOR, please contact support@jstor.org.. Ecological Society of America is collaborating with JSTOR to digitize, preserve and extend access to Ecology.Abstract. To determine if the arrangement of secretary canals in leaves affects foraging by folivorous insects, we examined the behaviors of 33 species found on diverse canalbearing plants. Insect behaviors were categorized into three principal classes: vein cutting, trenching, and neither behavior. Canal architectures were ascertained by damaging leaves with standardized tests and measuring the secretary response.Our observations document a precise correspondence between herbivore behavior and canal morphology. Vein-cutting insects occur on plants with arborescent canals (resin canals in Anacardiaceae and nonarticulated laticifers in Apocynaceae, Asclepiadaceae, and Moraceae). By severing the secretary canals in leaf veins, insects prevent the flow of secretion to distal branches of the canals. Trenching insects, in contrast, are found on plants with net-like canal systems (anastomosing articulated laticifers in Asteraceae and Caricaceae, and exuding phloem in Cucurbitaceae). To eliminate secretion outflow from these plants, the insects must transect all strands of the network by cutting a trench. The secretary canals of the Convolvulaceae (nonanastomosing articulated laticifers) differ from the preceding categories in being restricted primarily to the major leaf veins. The behavior of herbivores on this family is also distinct: all feed between the major veins without prior vein cutting or trenching.Thus, insects employ the same behavior on similar canal architectures, even when their host plants otherwise differ in taxonomy, secondary chemistry, and canal type. The occurrence of vein-cutting and trenching behaviors in multiple lineages of insects that include caterpillars, beetles, and katydids indicates that the behaviors have evolved repeatedly, apparently through convergence. Our comparative analysis supports the view that these preingestive behaviors function specifically to deactivate defensive canal systems.

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Section: Discussionmentioning

confidence: 99%

Deactivation of Plant Defense: Correspondence Between Insect Behavior and Secretory Canal Architecture

Dussourd¹,

Denno²

1991

Ecology

155

158

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“…Starch accumulated in the laticifer throughout its period of growth, but apparent net starch degradation did not subsequently occur. In previous studies of laticifer starch of other Euphorbia species, no diurnal rhythm or net starch degradation in darkness was observed in contrast with that occurring in photosynthetic cells, nor was starch degraded during flowering or fruit formation (Biesboer and Mahlberg, 1978). Thus, laticifer starch does not appear to serve a storage function under any of these conditions.…”

Section: Analysis Of Latex Triterpenoids-« Triterpe-mentioning

confidence: 73%

Latex and Laticifer Starch Content of Developing Leaves of Euphorbia Pulcherrima

Spilatro

Mahlberg

1986

American J of Botany

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Laticifer starch accumulation was compared to laticifer growth for developing leaves of Euphorbia pulcherrima Willd. (poinsettia). Measurements of the laticifer-specific triterpenol, cyc1oartenol, in latex and in whole leaf extracts were used to calculate the total latex volume in leaves of different developmental stages. Latex volume and starch concentration in the latex were used to determine totallaticifer starch and to compare laticifer growth and starch synthesis. Young leaves contained the highest latex and laticifer starch contents on dry wt and leaf area bases. In older expanding leaves, laticifer growth produced an increase in total latex volume accompanied by an increase in totallaticifer starch. Laticifer growth and starch accumulation stopped upon cessation of leaf expansion. Starch concentration was similar in latex from all leaves, but differed between plant organs. Thus, laticifer starch accumulation correlated with laticifer growth, but mobilization of the starch out of the laticifer was not observed in old or senescent leaves. This is evidence that laticifer starch grains function within the laticifer independently of degradation or export to other cell types.

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“…The actual composition of E. esula latex starch granules was not determined; however, based on the blue-black color produced by iodine staining, it would appear that the amylose/amylopectin ratio is not unusual. Amylose content of latex starch granules from E. marginata, E. tirucalli, and E. heterophylla was determined and found to range from 18 to 20%, which is considered typical for most nonwaxy starches (2).…”

Section: Discussionmentioning

confidence: 99%

“…It has been suggested that they stem the flow of latex from nonarticulated laticifers when plant parts are damaged (2). What remains to be determined is why a constitutive system, which encumbers 20 to 40%…”

Section: Discussionmentioning

confidence: 99%

No Latex Starch Utilization in Euphorbia esula L.

Nissen¹,

Foley²

1986

Plant Physiol.

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Utilization of leaf, stem, root, and latex starch was monitored in Euphorbia esula L. plants. Leaf, stem, and 20-20-20). Cone-tainer grown plants used in the light starvation study were pruned of all top growth, transferred to a growth chamber, and allowed to regrow for 4 weeks. The growth chamber was set at a constant temperature of 25°C and 16 h photoperiod with incandescent and fluorescent lights providing a photo flux density of 150E m 2 -s-'. Amylase activity was determined from latex samples taken from 1-to 2-year old E. esula growing in polyvinyl chloride pipe under greenhouse conditions. Each

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A Comparison of Alpha‐amylases From the Latex of Three Selected Species of Euphorbia (Euphorbiaceae)

Cited by 10 publications

References 20 publications

Deactivation of Plant Defense: Correspondence Between Insect Behavior and Secretory Canal Architecture

Deactivation of Plant Defense: Correspondence Between Insect Behavior and Secretory Canal Architecture

Latex and Laticifer Starch Content of Developing Leaves of Euphorbia Pulcherrima

No Latex Starch Utilization in Euphorbia esula L.

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