The origin of the savanna biome

Savannas are a major terrestrial biome, comprising of grasses with the C₄ photosynthetic pathway and trees with the C₃ type. This mixed grass–tree biome rapidly appeared on the ecological stage 8 million years ago with the near‐synchronous expansion of C₄ grasses around the world. We propose a new hypothesis for this global event based on a systems analysis that integrates recent advances in how fire influences cloud microphysics, climate and savanna ecology in a low carbon dioxide (CO₂) world. We show that fire accelerates forest loss and C₄ grassland expansion through multiple positive feedback loops that each promote drought and more fire. A low CO₂ atmosphere amplifies this cycle by limiting tree recruitment, allowing the ingress of C₄ grasses to greatly increase ecosystem flammability. Continued intensification of land use could enhance or moderate the network of feedbacks that have initiated, promoted and sustained savannas for millions of years. We suggest these alterations will overprint the effects of anthropogenic atmospheric change in coming decades.     

Interchromosomal exchange of genetic information between gene arrangements on the third chromosome of Drosophila pseudoobscura

During the last 60 years, the inversion polymorphism on the third chromosome of Drosophila pseudoobscura has become a case study of the evolution of linked blocks of genes, isolated from each other by the suppression of recombination in heterozygotes for different inversions. Due to its location within inverted regions in most gene arrangements, the amylase (Amy) gene region can be used to elucidate the molecular pattern of evolution in these inversions. We studied this region in the Tree Line phylad of gene arrangements, with regard to both restriction site polymorphisms (RSP) and nucleotide sequences. The analysis of restriction maps, encompassing 26 kb, corroborates the cytogenetic phylogeny established on the basis of inversion breakpoints. However, we found that the 2.7 kb of nucleotide sequences of the AmyI gene are identical in both Estes Park and Hidalgo arrangements, despite the fact that these inversions arose independently from Tree Line. These contrasting results suggest that a homogenizing force, most likely gene conversion, is able to bring about localized exchanges between otherwise isolated gene arrangements.      

Auxin and the Control of Ethylene Production during the Development and Senescence of Leaves and Fruits

The levels of endogenous IAA and the production of ethylenehave been followed during maturation and senescence in herbaceous(Phaseolus vulgaris, Ecballium elaterium) and deciduous (Prunusserrulata) leaves. Comparisons have been made with similar estimationsduring ripening of a herbaceous fruit. Ecballium elaterium.Whereas a correlation can be made between auxin content andethylene production in immature tissues, no such relationshipexists in senescing or ripening tissues where ethylene productionappears to be independent of the total endogenous auxin content.Both IAA and fusicoccin enhance ethylene production in developingleaves but fail to do so in senescent tissues. A mechanism forthe regulation of the rate of ethylene biosynthesis is described.This involves modifications in the release from a membrane-boundor membrane-enclosed compartment of cofactor(s) essential toone or more steps in the pathway. The mechanism accommodatesobserved normal and senescence-related rates of ethylene production.     

Chemical and structural changes of neurofilaments in transected rat sciatic nerve

The sequence of changes occurring in transected rat sciatic nerve was examined by electron microscopy and by sodium dodecyl sulfate (SDS) polyacrylamide disc gel electrophoresis. Representative segments of transected nerves were processed for ultrastructural examinations between 0 and 34 days after the transection of sciatic nerves immediately below the sacro-sciatic notch. The remainder of the transected nerves and the intact portions of sciatic nerves were desheathed and immediately homogenized in 1 percent SDS containing 8 M urea and 50 mM dithioerythritol. Solubilized proteins were analyzed on 12 percent gels at pH 8.3 in a discontinuous electrophoretic system. Initial changes were limited to the axons of transected nerve fibers and were characterized by the loss of microtubules and neurofilaments and their replacement by an amorphous floccular material. These changes became widespread between 24 and 48 h after transection. The disruption of neurofilaments during this interval occurred in parallel with a selective loss of 69,000, 150,000 and 200,000 mol wt proteins from nerve homogenates, thus corroborating the view that these proteins represent component subunits of mammalian neurofilaments. Furthermore, the selective changes of neurofilament proteins in transected nerves indicate their inherent lability and suggest their susceptibility to calcium-mediated alterations. Electrophoretic profiles of nerve proteins during the 4-34-day interval after nerve transection reflected the breakdown and removal of myelin, the proliferation of Schwann cells and the deposition of endoneurial collagen. A marked increase of intermediate-sized filaments within proliferating Schwann cell processes was not accompanied by the appearance of neurofilamentlike proteins in gels of nerve homogenates.     

Immunological and ultrastructural studies of neurofilaments isolated from rat peripheral nerve

Neurofilaments were isolated from desheathed and minced segments of rat peripheral nerve by osmotic shock into 0.01 M Tris-HCI buffer, pH 7.2. Freshly isolated neurofilaments were observed to undergo disassembly by progressive fragmentation upon exposure of dilute tissue extracts to this buffer. Low- and high-speed centrifugations of these tissue extracts separated membranous and particulate constituents and produced a progressive enrichment of 68,000-dalton polypeptide band in successive supernates, as determined by analyses of soluble proteins by SDS-polyacrylamide electrophoresis. The final high-speed supernatant fractions (S3) of nerve extracts, which were predominantly composed of 68,000-dalton polypeptide, were used to raise a specific experimental antisera in rabbits. Utilizing techniques of immune electron microscopy, experimental rabbit antisear was shown to contain antibodies against neurofilaments. Intact neurofilaments isolated from rat nerves and attached to carbon-coated grids became decorated when exposed to experimental rabbit antisera or purified gamma globulin (IgG) derivatives. The decoration of neurofilaments closely resembled the IgG coating seen in immune electron microscopy. Antibody absorption techniques were used to identify the biochemical constituency of neurofilamentous antigenic determinants. The decoration of neurofilament by experimental IgG was not altered by additions of tubulin or bovine serum albumin, but was prevented by additions of S3 fractions as well as the 68,000-dalton polypeptide of this fraction which was eluted and recovered from polyacrylamide gels. These findings are indicative that a 68,000-dalton polypeptide is a constituent subunit of rat peripheral nerve neurofilaments.     

Auxin and Ethylene Control of Growth in Seedlings of Zea mays L. and Avena sativa L

The effects of applied ethylene on the growth of coleoptilesand mesocotyls of etiolated monocot seedlings (oat and maize)have been compared with those on the epicotyl of a dicot seedling(the etiolated pea). Significant inhibition of elongation by ethylene (10 µll^–1for 24 h) was found in intact seedlings of all three species,but lateral expansion growth was observed only in the pea internodeand oat mesocotyl tissue. The sensitivity of the growth of seedlingparts to ethylene is in the decreasing order pea internode,oat coleoptile and oat mesocotyl, with maize exhibiting theleast growth response. Although excised segments of mesocotyland coleoptile or pea internode all exhibit enhanced elongationgrowth in IAA solutions (10^–6–2 ? 10^–5 moll^–1), no consistent effects were found in ethylene. Ethyleneproduction in segments was significantly enhanced by applicationof auxin (IAA, 10^–5 mol l^–6 or less) in all tissuesexcept those of the eat mesocotyl. Segments of maize show a slow rate of metabolism of applied[2-¹⁴C]IAA (30 per cent converted to other metabolites within9 h) and a high capacity for polar auxin transport. Ethylene(10 µl l^–1 for 24 h) has little effect on eitherof these processes. The oat has a smaller capacity for polartransport than maize and the rate ef metabolism of auxin isas fast as in the pea (90 per cent metabolized in 6 h). Althoughethylene pretreatment does not change the rate of auxin metabolismin oat, there is a marked reduction in auxin transport. It is proposed that the insensitivity of maize seedlings toethylene is related to the supply and persistence of auxin whichcould protect the seedling against the effects of applied orendogenously produced ethylene. Although the mesocotyl of oatis sensitive to applied ethylene it may be in part protectedagainst ethylene in vivo by the absence of an auxin-enhancedethylene production system. The results are discussed in relationto a model for the auxin and ethylene control of cell growthin the pea.