Estudos anatômicos, ultra-estruturais e bioquímicos da síndrome Kranz em folhas de duas espécies de Gomphrena L. (Amaranthaceae) / Anatomical, ultrastructural and biochemical surveys in leaves to two Gomphrena L. species (Amaranthaceae)

Natalia Paganotti Antonucci

10 March 2010

A síndrome Kranz é um conjunto de características anatômicas, ultra-estruturais e bioquímicas que culminam na realização da fotossíntese C4. Tal síndrome apresenta grande diversidade dentre as Angiospermas, tornando-se conveniente seu estudo em todos os níveis acima citados para a completa caracterização da mesma. No presente trabalho foi investigada a síndrome Kranz de Gomphrena arborescens e G. scapigera (Amaranthaceae) com ênfase na origem ontogenética da bainha Kranz, na descrição ultra-estrutural e na confirmação bioquímica sobre o tipo de fotossíntese C4. O desenvolvimento foliar dessas espécies indica que a bainha Kranz é originada da camada mais interna do mesofilo, a endoderme foliar. Uma discussão sobre os termos presentes na literatura para a descrição dessa bainha, todos eles focados em sua função na fotossíntese C4, demonstra a importância de se utilizar termos que informem a origem ontogenética dessa bainha, como endoderme e periciclo. Na análise ultra-estrutural, foram identificados possíveis fatores que interferem na fotossíntese de ambas as espécies, como o espessamento e a composição da parede da bainha Kranz, o posicionamento centrípeto dos cloroplastos e a presença de retículo periférico nos mesmos. Embora a análise bioquímica tenha resultado em informações ainda não conclusivas, o dimorfismo dos cloroplastos sugere a realização da fotossíntese C4 do tipo NADP-ME. O presente trabalho, de uma forma geral, contribui ao conhecimento da síndrome Kranz dentre as Amaranthaceae s.s., um grupo em que a ultra-estrutura e a bioquímica ainda são pouco conhecidas, e ressalta a importância dos estudos anatômicos, principalmente com enfoque ontogenético, para o melhor conhecimento da diversidade da síndrome Kranz dentre as Angiospermas. / The Kranz syndrome is a set of anatomical, ultrastructural and biochemical features that culminate in the C4 photosynthesis. This syndrome has a huge diversity among Angiosperms, so it became suitable to survey all the levels above cited for its complete characterization. In the present work the Kranz syndrome of Gomphrena arborescens and G. scapigera (Amaranthaceae) is studied, with emphasis on the ontogenetic origin of the Kranz sheath, on the ultrastructural description, and on the biochemical confirmation about the C4 photosynthesis kind. The foliar development of these species shows that the Kranz sheath is originated from the inner layer of the mesophyll, the foliar endodermis. A discussion about the literature terms used to describe the Kranz sheath, all of them referring to the function of this layer in C4 photosynthesis, demonstrates the importance of using terms that inform the ontogenetic origin of this layer, such as endodermis and perycicle. The ultrastructural analysis identified possible factors that interfere on the C4 photosynthesis of both species, such as wall thickening and composition of Kranz sheath cells, the centripetal position of chloroplasts and the peripheral reticulum in chloroplasts. Although biochemical analysis has resulted in no conclusive information, the chloroplast dimorphism suggests the NADP-ME C4 photosynthesis. This work, in a general way, contributes to the knowledge of the Kranz syndrome among Amaranthaceae s.s., a group that has the ultrastructure and the biochemistry of C4 photosynthesis poorly known. It also draws attention to the importance of anatomical surveys concerning the ontogenetic origin of Kranz sheath for a better understanding on the diversity of Kranz syndrome among Angiosperms.

Anatomia Kranz

Bainha do feixe

Cloroplasto

Endoderme

Fotossíntese C4

Bundle sheath

C4 photosynthesis

Chloroplast

Endodermis

Kranz anatomy

Caractérisation d'un nouveau membre du complexe d'élongation des acides gras chez Arabidopsis thaliana : intéractions métaboliques et régulation développementale / Very long chain fatty acid elongation complex in Arabidopsis thaliana : metabolic interaction and developmental regulation

Morineau, Céline

16 December 2014

Les acides gras à très longues chaine (VLCFA) sont essentiels dans le développement, particulièrement dans les mécanismes de trafic vésiculaires, de différenciation et division cellulaire. Cependant, le rôle de ces VLCFA dans ces différents processus chez les plantes n’est pas encore bien compris. Afin d’identifier de nouveaux acteurs associés à la biosynthèse ou la fonction des VLCFA, un crible suppresseur multicopies a été réalisé dans un mutant d’élongation des VLCFA de levure. La perte de l’activité déshydratase PHS1 chez la levure et de PASTICCINO2 chez les plantes perturbe la croissance et induit des défauts de cytokinèse. La PROTEIN TYROSIN PHOSPHATASE-LIKE (PTPLA) historiquement caractérisée comme une déshydratase inactive est capable de restaurer les défauts de croissance et d’élongation de phs1 mais non de pas2. PTPLA interagit avec plusieurs membres du complexe élongase dans le RE et son absence conduit à l’accumulation 3-hydroxyacyl-CoA, signature des déshydratases impliquées dans l’élongation des acides gras. Cependant, la perte de PTPLA conduit à une augmentation des VLCFA, probablement dépendante de PAS2 montrant que PTPLA serait un répresseur potentiel de l’élongation. Les deux déshydratases ont des profils d’expression divergents dans la racine. PAS2 est majoritairement exprimé dans l’endoderme tandis que PTPLA s’exprime uniquement dans les tissus vasculaires et le péricycle. La comparaison de l’expression ectopique de PAS2 et PTPLA dans leur tissus respectif confirme l’existence de deux complexe élongase indépendant associé à PAS2 ou PTPLA et interagissant de manière non cellule autonome. Les cytokinines pourraient constituer le signal entre les deux complexes élongase du fait que la biosynthèse de ces hormones est réprimée par les VLCFA. Les VLCFA répriment ainsi l'expression d'IPT3 dans les racines comme observées pour la partie apicale. Les cytokinines semblent aussi réguler la teneur en VLCFA dans la racine suggérant la présence de boucles de rétrocontrôles entre ces hormones et les VLCFA / Very long chain fatty acids (VLCFA) are involved in plant development and particularly in several cellular processes such as membrane trafficking, cell division and cell differentiation. However, the precise role of VLCFA in these different cellular processes is still poorly understood in plants. In order to identify new factors associated with the biosynthesis or function of VLCFA, a yeast multicopy suppressor screen was carried out in a yeast mutant strain defective for fatty acid elongation. Loss of function of the elongase dehydratase PHS1 in yeast and PASTICCINO2 in plants prevents growth and induces cytokinesis defects. PROTEIN TYROSIN PHOSPHATASE-LIKE (PTPLA) previously characterized as an inactive dehydratase was able to restore yeast phs1 growth and VLCFA elongation but not the plant pas2 defects. PTPLA interacted with elongase members in the ER and its absence induced the accumulation of 3-hydroxyacyl-CoA as expected from a dehydratase involved in fatty acid (FA) elongation. However, loss of PTPLA function led to increased VLCFA levels, effect that was dependent of the presence of PAS2 indicating that PTPLA activity repressed FA elongation. The two dehydratases have specific expression profiles in the root with PAS2, mostly restricted in the endodermis, while PTPLA was confined in the vascular tissue and pericycle cells. Comparative ectopic expression of PTPLA and PAS2 in their respective domains confirmed the existence of two independent elongase complexes comprising PAS2 or PTPLA that were functionally interacting in a non-cell autonomous manner. A putative regulating signal could involve cytokinins that were described to be regulated by VLCFA. VLCFA were indeed found to repress IPT3 expression in roots like in leaves. Cytokinins were also found to regulate VLCFA levels suggesting the existence of regulatory feedback loops between cytokinins and VLCFA

PTPLA

Endoderme

Tissus vasculaires

Signal non cellule autonome

Very long chain fatty acids (VLCFA

PTPLA

Endodermis

Vascular tissues

, non-cell autonomous signal.

The Role of the Actin Cytoskeleton in Gravity Signal Transduction of Hypocotyls of Arabidopsis thaliana

Palmieri, Maria

14 August 2006

No description available.

Gravitropism

Arabidopsis

plant physiology

curvature

latrunculin B

BDM

growth

curvature

spaceflight

microgravity

signal transduction

gravity perception

amyloplast

statolith

tensegrity

actin tether

vacuole

endodermis

statocyte

Cellular Mechanisms of Gravitropism in ARG1 (Altered Response to Gravity) Mutants of <i>Arabidopsis Thaliana</i>

Kumar, Neela Shiva

12 August 2008

No description available.

Botany

actin cytoskeleton

Arabidopsis

columella cells

electron microscopy

endodermis

endomembrane system

gravitropism

gravity perception

immunocytochemical

plastid movement

signal transduction

statocytes

Cellular mechanisms of gravitropism in ARG1 (altered response to gravity) mutants of Arabidopsis thaliana

Kumar, Neela Shiva.

January 2008

Thesis (Ph. D.)--Miami University, Dept. of Botany, 2008. / Title from second page of PDF document. Includes bibliographical references.

Mechanismy reakce exodermis na dostupnost živin v prostředí / Mechanisms of exodermal response to nutrient availability in the environment

Gargoš, Ondřej

January 2021

in English The apoplastic barriers of the root (endodermis and exodermis) represent an important regulatory mechanism for the uptake of water and nutrients from the environment, ensuring its selectivity. In addition, both layers respond to stress factors by altering its rate and degree of cell wall modification, which affects the transport properties of the root and represents adaptive plants to high heterogeneity of the soil environment. Apoplastic barriers also respond to the availability of mineral nutrients. This issue has recently been intensively studied and a number of ambiguities persist. Interestingly, the deficiency of some mineral nutrients stimulates the differentiation of barriers, while the deficiency of other mineral nutrients delays the differentiation. In addition, different plant species react differently to the deficiency of the same element. Another interesting aspect is the fact that the reaction of the endodermis and exodermis is localized and takes place mainly in that part of the root system which is directly exposed to the stress factor. This phenomenon has been observed with cadmium toxicity, but more recently with local nutrient deficiencies (nitrogen and potassium) in Zea mays. This diploma thesis deals with the functional significance of localized enhancing or delaying...