Mexical plant phenology: is it similar to Mediterranean communities?

The sclerophyllous, evergreen vegetation found in Mexico under tropical climate is named 'Mexical' (MEX) and presents many traits that have been thought to converge under a Mediterranean climate. Flowering phenology is strongly similar across Mediterranean-type ecosystems (MTEs) and this paper investigates MEX plant phenology in this context. The common history of the vegetation and the differences in the climatic conditions experienced by MEX and MTE taxa provide an ideal scenario to infer the relative importance of natural selection and historical constraints in the phenological response of plants to climatic conditions. This study has involved collecting field and bibliographic data on flowering phenology of MEX communities to detect (1) similarities at the community level between MTEs and MEX, (2) similarities between Tertiary and Quaternary taxa in MTEs and MEX, and (3) similarities between congeneric taxa from MEX and MTEs (taxa sharing a common ancestor but having evolved under different climates). Flowering in MEX does not occur mainly in spring, as in MTEs, but in summer, suggesting a response that maximizes water use in the rainy season. Flowering phenology of MEX species differed from their MTE congeneric species, suggesting that even though a common ancestor is shared, environmental pressures have led to different phenological responses in MEX and MTE plants. The flowering season for species that originated in the Tertiary and Quaternary did not differ in MEX, as expected, because of climatic uniformity along the whole time line. In MTEs, flowering differences between Tertiary and Quaternary species were not congruent, suggesting that the balance between the historical constraints and the selective force of the Mediterranean climate is different among the three MTEs, and a particular explanation is needed for each. © 2002 The Linnean Society of London, Botanical Journal of the Linnean Society , 2002, 138 , 297–303.     

Treefall gaps required for establishment,but not survival,of invasive Rubus phoenicolasius in deciduous forest,Maryland, USA

Although plant invasions are often associated with disturbance, localized disturbances can promote invasion either by: (i) creating sites where individuals establish; or (ii) enabling an invader to colonize the entire stand. The former is expected when both establishment and survival to reproductive age require disturbed conditions, whereas the latter should occur in systems when either establishment or survival are limited to disturbed sites. We investigated the role of localized disturbance, specifically treefalls, in the invasion of the Asian Rubus phoenicolasius in a deciduous forest in Maryland, USA. We investigated the density and demography of R. phoenicolasius in treefall gaps of various sizes, but identical age to non‐gap areas, using Classification and Regression Tree (CART) analyses to identify the most important predictors. To explore how the demography of established individuals responds to disturbed versus undisturbed conditions, we carried out a garden experiment with three different levels of shade (5, 12 and 22% full sun). We found vegetative and sexual reproduction, and seedling establishment, to be limited to large gaps in an old stand, but not in a stand in an earlier age of succession. However, in the garden experiment, established plants were able to survive and grow under all shade treatments. These findings indicate that R. phoenicolasius requires disturbances such as treefalls to establish in forests, but established plants will survive canopy closure, leading to stand‐wide invasion. Managers should be able to prevent invasion, however, by inspecting large gaps for new recruits every 3 years.     

Movement of Ions and Electrogenesis in Higher Plant Cells

During the past 10 years considerable information has accumulatedon the electrochemical relationships of higher plant cells duringtransport of mineral ions. Using the Nernst equation as a criterion,none of eight ions (K⁺, Na⁺, Ca⁺⁺, Mg⁺⁺, NO₃^–, Cl^–,H₂PO₄^–, and SO₄^–) is in a passive equilibrium. Na⁺,Ca⁺⁺, and Mg⁺⁺ are subject to an exclusion mechanism, and allof the anions appear to be pumped inwardly. K⁺ apparently approachesan electrochemical balance under certain conditions but probablyis actively accumulated. Compartmental analyses giving estimatesof amounts in the cytoplasm and vacuole and of unidirectionalfluxes permit application of the Ussing flux-ratio equation.The criterion in oat coleoptile cells suggests that at the plasmalemmaNa⁺ is pumped out while K⁺ and Cl^– are pumped in. K⁺ andCl^– appear to be coupled in active transport across thetonoplast into the vacuole. Good evidence has been found thatthe cell's electropotential arises from an electrogenic pump:CN^– (cyanide) and DNP (dinitrophenol) reversibly blockthe potential and ionic transport; cell potentials are higherthan can be accounted for by diffusion; the responses of respirationand potential to the concentration of CN^– are nearly parallel;and CN^– inhibited tissue approaches a fit to the Goldmanconstant field equation. Future objectives should be identificationof the ion, or ions, subject to the electrogenic pump and discoveryof the immediate energy source.