ABSTRACT
Metrosideros polymorpha, a dominant tree species in Hawaiian ecosystems, occupies a wide range of habitats. Complementary field and common-garden studies of M. polymorpha populations were conducted across an altitudinal gradient at two different substrate ages to ascertain if the large phenotypic variation of this species is determined by genetic differences or by phenotypic modifications resulting from environmental conditions. Several characteristics, including ecophysiological behavior and anatomical features, were largely induced by the environment. However, other characteristics, particularly leaf morphology, appeared to be mainly determined by genetic background. Common garden plants exhibited higher average rates of net assimilation (5.8 µmol CO2 m-2 s-1) and higher average stomatal conductance (0.18 mol H2O m-2 s-1) than their field counterparts (3.0 µmol CO2 m-2 s-1, and 0.13 mol H2O m-2 s-1 respectively). Foliar δ13C of most common-garden plants was similar among sites of origin with an average value of -26.9. In contrast, mean values of foliar δ13C in field plants increased substantially from -29.5 at low elevation to -24.8 at high elevation. Leaf mass per unit area increased significantly as a function of elevation in both field and common garden plants; however, the range of values was much narrower in common garden plants (211-308 g m-2 for common garden versus 107-407 g m-2 for field plants). Nitrogen content measured on a leaf area basis in common garden plants ranged from 1.4 g m-2 to 2.4 g m-2 and from 0.8 g m-2 to 2.5 g m-2 in field plants. Photosynthetic nitrogen use efficiency (PNUE) decreased 50% with increasing elevation in field plants and only 20% in plants from young substrates in the common garden. This was a result of higher rates of net CO2 assimilation in the common garden plants. Leaf tissue and cell layer thickness, and degree of leaf pubescence increased significantly with elevation in field plants, whereas in common garden plants, variation with elevation of origin was much narrower, or was entirely absent. Morphological characteristics such as leaf size, petiole length, and internode length decreased with increasing elevation in the field and were retained when grown in the common garden, suggesting a potential genetic basis for these traits. The combination of environmentally induced variability in physiological and anatomical characteristics and genetically determined variation in morphological traits allows Hawaiian M. polymorpha to attain and dominate an extremely wide ecological distribution not observed in other tree species.
ABSTRACT
Destruction of tropical forests has gained world-wide attention, and the associated depletion of biodiversity has become a growing concern. Almost simultaneously, forest decline and dieback in the developed countries on both sides of the North Atlantic has become an international worry. Industrial pollution has been implicated as the major cause, but the etiology of forest decline and dieback remains largely unresolved. Decline and dieback can also be related to biotic impoverishment in the sense of reduction of canopy species diversity, simplification of structural diversity and biological mining of soil nutrients. Thus, concern over the depletion of biodiversity is highly justified. It links tropical forest destruction to forest dieback in Europe in a way not yet widely realized. At the same time, it does not diminish tge equally justified concern about industrial pollution. A world-wide internationally coordinated research program is suggested which focuses on comparative, interdisciplinary studies in those countries where forest decline and dieback has surfaced as an unresolved problem.
ABSTRACT
The exotic nitrogen-fixing tree Myrica faya invades young volcanic sites where the growth of native plants is limited by a lack of nitrogen. Myrica quadruples the amount of nitrogen entering certain sites and increases the overall biological availability of nitrogen, thereby altering the nature of ecosystem development after volcanic eruptions.
