Relação entre longevidade foliar, nitrogenio e compostos secundarios em folhas de leguminosas arboreas

Lima, Ana Lucia da Silva

04 July 2005

Orientadores: Marlene Aparecida Schiavinato, Claudia Baptista Haddad / Tese (doutorado) - Universidade Estadual de Campinas, Instituto de Biologia / Made available in DSpace on 2018-09-11T21:06:20Z (GMT). No. of bitstreams: 1 Lima_AnaLuciadaSilva_D.pdf: 355483 bytes, checksum: 9ce9e116731fc53ab23c70ac20c5cf48 (MD5) Previous issue date: 2005 / Resumo: A duração do ciclo de vida foliar determina características distintas nas folhas, que são relevantes para a sobrevivência da planta em diferentes habitats. Tem sido verificado que as espécies perenifólias apresentam mecanismos mais eficientes de conservação de nitrogênio (N) em relação às espécies decíduas. Esses mecanismos são: eficiência de reaproveitamento de nitrogênio (ERN), proficiência de reaproveitamento de nitrogênio (PRN) e eficiência do uso de nitrogênio (EUN). Segundo um dos paradigmas da ecologia vegetal, as espécies crescendo em ambientes oligotróficos têm maior eficiência de reaproveitamento de nutrientes em relação a espécies características de ambientes eutróficos. A PRN em espécies adaptadas a solos poço férteis é maior do que a de espécies de solos mais férteis. Plantas com longo ciclo de vida foliar possuem maior EUN do que plantas com folhas menos longevas e esta eficiência aumenta com o decréscimo da concentração de nutriente no solo. Espécies perenifólias apresentam maior longevidade foliar do que as decíduas e maior concentração de fenóis. Por outro lado, a concentração de taninos costuma ser maior nas folhas de espécies decíduas. É visto também que as espécies com folhas mais longevas possuem menor concentração de N total, menor concentração de compostos nitrogenados e maior massa foliar específica (MFE). O objetivo deste trabalho foi verificar se as observações encontradas na literatura, comparando espécies perenifólias e decíduas, aplicam-se também às espécies semidecíduas (Hymenaea courbaril - sem FSN e Lonchocarpus guilleminianus ¿ com FSN) e decíduas (Enterolobium contortisiliquum ¿ com FSN e Peltophorum dubium - sem FSN) encontrada em uma Mata Estacional Semidecídua remanescente da Mata Atlântica. As plantas foram cultivadas em casa de vegetação, em vasos contendo solo de local onde as espécies são encontradas na mata, enriquecido ou não com N. Plantas de H. courbaril e P. dubium também foram cultivadas em areia. Houve decréscimo na concentração de clorofila total com o avanço da idade foliar nas quatro espécies. As ERN, PRN e EUN decresceram com o aumento da concentração de N no solo. Espécies com FSN apresentaram menor ERN, PRN e EUN em relação às espécies sem FSN. Plantas cultivadas em areia tiveram maiores ERN, PRN e EUN. Os resultados mostraram uma relação inversa entre os parâmetros de ERN, PRN, EUN e presença de FSN e fertilidade do solo. Os resultados obtidos corroboram os da literatura, já que as espécies com folhas mais longevas apresentaram concentrações maiores de fenóis e maior MFE, menores de taninos, nitrato, proteínas, aminoácidos, clorofila e N total / Abstract: Depending on the leaf life span, the leaves show distinct characteristics, which are relevant to the survival of the plant in different habitats. It has been noticed that the evergreen species show more efficient mechanisms of Nitrogen (N) conservation. These mechanisms are related to N Resorption Efficiency (NRE), N Resorption Proficiency (NRP) and N Use Efficiency (NUE). According to one of the paradigms of plant ecology, species growing in oligotrophic environments are more efficient in nutrient resorption than species from eutrophic environments. It is well known that the NRP in species adapted to soils which are not very fertile, is higher than in species of fertile soils. Plants with long leaf life span have higher NUE than plants with shorter leaf life span and the NUE increases with the decrease of nutrient in the soil. Since the evergreen species present longer leaf life span than the deciduous, their leaves present higher concentration of phenolic compound. On the other hand, the concentration of tannins is usually higher in leaves of deciduous species. It is also known that the long leaf life species have lower concentration of nitrogen compounds and higher Specific Leaf Mass (SLM). The objective of this study was to verify if the observations found in literature, comparing evergreen species to deciduous species, are also applied to the semi deciduous species (Hymenaea courbaril - without SNF and Lonchocarpus guilleminianus ¿ with SNF) and deciduous species, (Enterolobium contortisiliquum ¿ with SNF and Peltophorum dubium - without SNF) of a semi deciduous tropical forest, remnant of the Atlantic Forest. The plants were grown in a greenhouse; in pots filled with soil from their natural environment, enriched or not with N. Plants of H. courbaril and P. dubium were also grown in sand. The results obtained confirm the observations cited in the literature, since the species with longer leaf life span presented higher SLM and concentrations of phenolic compounds, lower concentrations of tannins, nitrate, total proteins, total free amino acids, chlorophyll total), total N. There was a fall in the concentration of total chlorophyll with the advance of leaf age in the four species. The NRE, NRP and NUE decreased with the increase of N concentration in the soil. Species with SNF presented lower NRE, NRP and NUE if compared to species without SNF / Doutorado / Biologia Vegetal / Doutor em Biologia Vegetal

Leguminosa

Arvores fixadoras de nitrogênio

Nitrogênio - Reaproveitamento

Compostos nitrogênicos

Nitrogenase

Legumes

Nitrogen-fixing trees

Nitrogen resorption

Nitrogen compounds

Nitrogenase

INFLUENCE ON BIODIVERSITY ON CANOPY PROCESS IN A HARDWOOD PLANTATION FOREST ECOSYSTEM

Taylor M Nelson (10716447)

28 April 2021

Increased biodiversity generally enhances terrestrial ecosystem productivity. While niche-use efficiency is thought to drive the biodiversity-productivity relationship, the mechanisms within niche-use efficiency are not well understood. A potential mechanism for niche-use efficiency is nutrient-use efficiency. To measure nutrient-use efficiency, we calculated nitrogen-resorption efficiencies (NRE) because nitrogen is an important growth limiting nutrient for forest productivity. We used a plantation implemented as a full factorial design that included two levels of competition, implemented as different planting densities (one- and two-meter planting densities), and three diversity levels (monocultures, two-, and three-species plantings) that included three hardwood tree species (northern red oak (<i>Quercus rubra</i>), black cherry (<i>Prunus serotin</i><i>a</i>), and American chestnut (<i>Castanea dentata</i>). For our nitrogen-resorption efficiency data, we found that NRE increased as diversity and planting density decreased, but the magnitude of the response varied among species. This outcome suggests that while increased diversity likely provides a release from intra-specific competition, different combinations of species will play a critical role in shaping biodiversity-productivity relationships. Forest nutrient cycling can also be influenced by herbivory. To address the effects of forest diversity on herbivory rates, we monitored rates of foliar damage along with foliar nitrogen content. To measure foliar nitrogen content, we collected spectral data from early, midseason, and late season foliar samples. To assess foliar damage, we collected and imaged leaves from two canopy positions in order to measure late season foliar area and estimate pre damaged foliar area. We found that diversity and foliar nitrogen content have a positive relationship, and diversity does influence canopy damage but the effects vary among species and density. Upon further analysis, we found that foliar nitrogen content and canopy damage are correlated. Meaning individual trees showed a release from intraspecific competition, which lead to an increase in available nutrients and higher canopy quality, showing that stands with higher canopy quality experienced higher levels of damage.<br>

Invertebrate Biology

biodiversity-productivity relationship

niche-use efficiency

nitrogen resorption efficiency