Mammal responses to matrix development intensity

The landscape matrix is increasingly being recognized as important to biodiversity conservation. The nature of the matrix impacts the persistence of species in human‐modified landscapes through its pervasive influence on adjacent habitat and through the habitat value of the matrix itself. However, previous studies have not isolated the effects of the matrix from the effects of other aspects of landscape modification, such as habitat loss and fragmentation, and much remains to be understood about the independent impact of the matrix on wildlife. We investigated the effects of the matrix on mammal abundance and landscape use in south‐east Queensland, Australia. Mammals were surveyed in patch ‘core’, patch ‘edge’ and ‘matrix’ landscape elements along a rural–suburban gradient of matrix development intensity quantified by a weighted road‐length metric, which was significantly correlated with housing density, while controlling for potentially confounding patch and landscape attributes. Response to increasing matrix development intensity was highly species‐specific. Several native species declined in abundance; however, others were more resilient to moderate levels of matrix intensity, one species increased in abundance, and at least one species appeared unaffected by matrix intensity. Native species richness peaked at moderate levels of matrix development intensity. Exotic species richness and feral predators increased with matrix intensity and were negatively correlated with native species. Species response to matrix intensity appeared related to their use of edge or matrix habitat. An ability to use the matrix per se, however, may not translate into an ability to persist in a landscape where development substantially reduces the habitat or movement value of the matrix.     

The Micronuclear Gene Encoding β-Telomere Binding Protein in Oxytricha nova

ABSTRACT The micronuclear version of the gene encoding β-telomere binding protein (β-TBP) in Oxytricha nova has been sequenced and compared to the macronuclear β-TBP gene, previously described. The micronuclear gene contains three AT-rich internal eliminated sequences (IES) of 37, 40, and 43 bp and four macronuclear destined sequences (MDS). The IES interrupt the gene once near the 5′ end of the coding region and twice in the 3′ trailer downstream from the TGA stop codon. The sequences of the micronuclear and macronuclear genes are colinear. Thus, the micronuclear β-TBP gene is not scrambled, which contrasts with the highly scrambled state among the 14 MDS in the micronuclear α;-TBP gene.     

Investigation of Effects of Plant Growth Regulators on Liposome Fluidity and Permeability

Naturally occurring plant growth regulators gibberellic acid (GA), indole-3-acetic acid (IAA), abscisic acid (ABA), ethylene and other growth regulating compounds such as 5-methyl-7-chloro-4-ethoxycarbonylmethoxy-2,1,3-benzothiadiazole (TH) and 2,4 dichlorophenoxyacetic acid (2,4-D), had no effect on the partition behavior of a piperidine based spin label in liposomes composed of pure or mixed phospholipids or a phospholipid-sterol mixture. Although no effect on fluidity was observed, TH significantly increased the initial rate of swelling of soybean lecithin-sitosterol liposomes in isotonic glycerol. IAA and ethylene did not influence this rate but ABA, GA and 2,4-D inhibited the initial rate of swelling. Lipid composition of liposomes determined the extent and direction of the effects on swelling rates. The observed swelling behavior was, therefore, not related to fluidity of the bulk membrane lipids but was due, instead, to modification of the access of glycerol to the phospholipid bilayer surface or, alternatively, to the creation of polar channels into the liposomes.     

Neurogenic pacemakers in the legs of Opiliones

ABSTRACT. After autotomy, the legs of all the species of Opiliones examined, and of a Kenyan Pholcid spider, twitched spontaneously at the femoro-patellar and tibio-basitarsal joints, for periods of up to an hour. These joints lack extensor muscles, extension being achieved at the femoro-patellar joint probably by haemolymph pressure, but at the tibio-basitarsal joint of Opiliones by a cuticular spring which can extend the joint fully. Comparable twitching activity could be evoked without autotomy if the central nervous system was burnt, or by asphyxiation. Electromyograms from the femur or tibia of an isolated twitching leg showed regular motor bursts which accompanied flexions, and sensory activity during extension. Forced movements of the joints did not perturb the rhythm of the motor bursts. An isolated proximal half of a femur could still generate the same bursting pattern whereas no other region showed this activity after its isolation. Bursts recorded in the tibia were shown to be dependent on the integrity of the femur. By stimulation of the femur with 1 -ms current pulses it was possible to reset the rhythm. Stimulation with 1-s pulses caused an acceleration or inhibition of the rhythm according to the direction of the current. Spontaneous bursts could be evoked in silent isolated legs, or in intact quiescent legs, by similar 1-s current pulses. It is postulated that the femur contains independent neurogenic pacemakers which are activated by injury current from the damaged leg nerve; they produce regular bursts of motor impulses without the interplay of proprioceptive loops, and are responsible for the movements observed.     

Physiological factors affecting the rapid decrease in protein assimilation efficiency by a caterpillar on newly‐mature tree leaves

Lymantria dispar L. caterpillars have a decreased ability to assimilate protein from mature leaves of red oak (Quercus rubra) compared with young, expanding leaves. The present study determines whether the drop in protein assimilation efficiency (PAE) occurs during the rapid phase of leaf maturation. Several mechanisms that might account for decreased PAE are also examined: mature leaf tissues could resist being chewed efficiently, protein in mature leaf tissues could become difficult to extract, and other nutrients in mature leaves might become growth limiting. The entire seasonal decrease in PAE occurs rapidly (in less than 2 weeks), when the leaves finished expanding. The maturation process is characterized by increased levels of fibre and decreased levels of water but no significant changes in the levels of protein or carbohydrates. Despite increased fibre in mature leaves, they are not chewed into larger food particles than are immature leaves. Carbohydrate assimilation efficiencies remain high on mature leaves, and signs of limiting water levels in larvae of L. dispar on mature leaves are not observed. The most important finding in the present study is the decreased extractability of protein in food particles from mature leaves, which plays a major role in explaining the rapid decrease in PAE. It is hypothesized that structural changes in cell walls during the rapid process of leaf maturation decrease protein extractability, which, in turn, greatly decreases the nutritional quality of mature oak leaves for caterpillars. The results of the present study therefore suggest a general mechanism to help explain the widely documented decrease in the nutritional quality of the mature leaves of many tree species for herbivorous insects.