Analysis of hybridization between Eucalyptus pauciflora Sieber ex Spreng. and E. radiata Sieber ex DC. (Myrtaceae)

Eucalyptus is a large genus in which hybridization may produce populations which present taxonomic difficulties. A small group of plants, apparently morphologically intermediate between Eucalyptus pauciflora and E. radiata, was studied in an attempt to determine whether hybridization was occurring, and to investigate the use of different techniques of analysis (morphological, chemical and numerical). Taken as a whole, the data from adult and seedling morphology, flavonoid composition, and volatile oil composition of the plants studied prove that they are indeed hybrids between the two species of Eucalyptus; however, these data also indicate some interesting problems in the application of some of these techniques to this particular situation.     

How do species respond to climate change along an elevation gradient? A case study of the grey‐headed robin (Heteromyias albispecularis)

Climate is predicted to change rapidly in the current century, which may lead to shifts of species' ranges, reduced populations and extinctions. Predicting the responses of species abundance to climate change can provide valuable information to quantify climate change impacts and inform their management and conservation, but most studies have been limited to changes in habitat area due to a lack of abundance data. Here, we use generalized linear model and Bayesian information criteria to develop a predictive model based on the abundance of the grey‐headed robin (GHR) and the data of climatic environmental variables. The model is validated by leave‐one‐out cross‐validation and equivalence tests. The responses of GHR abundance, population size and habitat area by elevation are predicted under the current climate and 15 climate change scenarios. The model predicts that when temperature increases, abundance of GHR displays a positive response at high elevation, but a negative response at low elevation. High precipitation at the higher elevations is a limiting factor to GHR and any reduction in precipitation at high elevation creates a more suitable environment, leading to an increase in abundance of GHR, whereas changes in precipitation have little impact at low elevation. The loss of habitat is much more than would otherwise be assumed in response to climate change. Temperature increase is the predominant factor leading to habitat loss, whereas changes in precipitation play a secondary role. When climate changes, the species not only loses part of its habitat but also suffers a loss in its population size in the remaining habitat. Population size declines more than the habitat area under all considered climate change scenarios, which implies that the species might become extinct long before the complete loss of its habitat. This study suggests that some species might experience much more severe impacts from climate change than predicted from models of habitat area alone. Management policies based on predictions of habitat area decline using occurrence data need to be re‐evaluated and alternative measures need to be developed to conserve species in the face of rapid climate change.     

Non-autotrophic CO2 Fixation during Shoot Formation in Tobacco Callus

Non-autotrophic carbon fixation has been studied during growthof tobacco callus cultured in dark under shoot-forming (SF)and non-shoot-forming (NSF) conditions. The enzymes involvedin malate metabolism—phosphoenolpyruvate carboxylase,malic dehydrogenase, glutamic-oxalacetic transaminase, and malicenzyme—increased sharply during the first 4 d of cultureparticularly in SF tissue. The activities of the enzymes studiedwere considerably greater in SF than in NSF tissue. There wasa dramatic increase in malate content in SF tissue during thefirst 4 d of culture. Subsequently malate was rapidly depletedduring the time of organogenesis. In NSF tissue there was acontinuous build-up of malate content throughout the cultureperiod. We suggest that malate derived from dark fixation ofCO₂ plays differing roles in NSF (callus) and SF tissues. Inthe former, malate acts primarily as an osmotic solute regulating,at least in part, cell expansion between successive cell divisions.In shoot-forming tissue, on the other hand, malate preferentiallyprovides NADPH for reductive biosynthesis.     

Ethylene as an endogenous inhibitor of root regeneration in tomato leaf discs cultured in vitro

We examined ethylene effects on root regeneration in tomato leaf discs cultured in vitro. Applied ethylene or Ethephon did not stimulate rooting in the leaf discs. In the presence of indoleacetic acid. 5 × 10^-6M, these substances significantly inhibited root formation. Ethylene production (nl C₂H₄· (24 h)^-1. flask^-1) was positively correlated with increased IAA concentrations at various times during the culture period and, as a consequence, with the rooting response after 168 h. However, separate testing of equimolar concentrations of seven different auxins and auxin-like compounds showed no positive correlation between the rate of ethylene production and subsequent rooting response. Aeration of gas-tight flasks containing leaf discs and absorption of ethylene evolved from the discs by mercuric perchlorate in gas-tight flasks or pre-treatment of leaf discs with AgNO₃ significantly enhanced IAA induced root regeneration. Thus, these studies indicate that ethylene is not a rooting hormone per se. Furthermore, ethylene (whether applied externally or synthesized by the tissue) does not appear to account for the ability of auxin to stimulate rooting.     

Changes in water potential and its components during shoot formation in tobacco callus

Addition of plant growth regulators (5 nM NAA and 5μM BAP) to a defined basal medium stimulated adventitious bud formation of Douglas fir (Pseudotsuga menziesii [Mirb.] Franco) cotyledon explants in culture. Cytoplasmic soluble proteins synthesized during early stages of adventitious bud formation were analyzed by electrophoresis of ³H- and ¹⁴C-leucine labeled proteins on SDS polyacrylamide gels. Increased synthesis of low molecular weight proteins (16,000 to 20,000 daltons) was detected after 2 days in culture and reached a maximal level at day 4. When cotyledon explants cultured on bud medium for 2 days were transferred to callus medium (which suppressed adventitious bud formation), suppression of the synthesis of low molecular weight proteins was also observed, suggesting that these proteins may be associated with early stages of adventitious bud formation.     

Effects of Gibberellic Acid and Abscisic Acid on Shoot Formation in Tobacco Callus Cultures

Tobacco (Nicotiana tabacum L. cv. W. 38) callus grown on a shoot-forming medium was exposed to gibberellic acid (GA₃) and abscisic acid (ABA) for varying lengths of time and at different periods during culture. The results suggest that if the tissue accumulated sufficient GA₃ prior to the initiation of meristemoids and shoot primordia, repression of shoot formation occurred. This repression was not reversed by increasing the levels of auxin or cytokinin in the medium, but ABA could partially overcome the GA₃ repression of shoot formation.     

Osmotic Requirement for Shoot Formation in Tobacco Callus

Tobacco callus grown on medium containing 3% sucrose (w/v) shows optimum growth and produces the highest number of shoots; whereas cultures grown on medium with lower or higher sucrose levels show a reduced growth rate and capacity to form shoots. Cultures grown on a low sucrose containing medium produce a high number of shoots only if the medium is supplemented with mannitol to give the same water potential as that of the 3% sucrose medium. Mannitol cannot replace the sucrose requirement for growth. Increased levels of Bacto Agar, tricarboxylic acid cycle intermediates and amino acids added to the medium do not promote shoot formation or replace the carbohydrate requirement for that process. The success in partially replacing the sucrose requirement for shoot formation with mannitol supports the view that part of the tissue carbohydrate is acting in an osmoregulatory role. This finding is further interpreted in terms of the hypothesis of turgor-driven growth and cell expansion.     

Phylogenetic relationships of flesh flies in the subfamily Sarcophaginae based on three mtDNA fragments (Diptera: Sarcophagidae)

In an effort to improve our knowledge of the phylogenetic relationships among species and genera of the subfamily Sarcophaginae, we analysed data from three mitochondrial gene fragments. Sequence data for portions of the genes cytochrome oxidase I (COI), cytochrome oxidase II (COII) and dehydrogenase subunit 4 (ND4) were obtained from 43 species of Sarcophagidae representing 15 genera. We used a Bayesian approach to simultaneously choose how best to partition the data and which substitution model to apply to each partition. Phylogenetic relationships were inferred using Bayesian Inference and Maximum Likelihood methods. Our results are consistent with monophyly of the subfamily Sarcophaginae (posterior probability 1; bootstrap support 93%), as well as with monophyly of several genera within the Sarcophaginae (including Sarcophaga s.l.; posterior probability 1; bootstrap support 97%). We found support for a sister‐group relationship between Ravinia Robineau‐Desvoidy and Oxysarcodexia Townsend, which has been hypothesised by past authors on the basis of morphological similarities, although this was supported only in the Bayesian analyses (posterior probability 0. 81–0. 98), and for some novel supra‐generic clades. Contrary to a recent morphological hypothesis, we do not find Helicobia Coquillett to be nested within Sarcophaga Meigen; our data suggest, but do not strongly support, a hypothesis that Peckia Robineau‐Desvoidy is the sister group to Sarcophaga.