The controlling factors limiting maximum body size of insects

The purpose of this study is to consider the controlling factors limiting maximum body size of insects. For this analysis, we set up and quantitatively verify the following working hypothesis: insect body sizes can be explained only by the historical changes in the oxygen supply. The present study focuses on the body size of the Protodonata and Odonata. The amount of oxygen needed and that of oxygen entering the insect body was calculated using allometric equations. The theoretical maximum sizes at each geologic time were estimated from palaeo‐atmospheric oxygen partial pressure and compared with the maximum size of known fossilized insects. The historical change in fossilized insect sizes was much larger than that in theoretical sizes. Additionally, from the Jurassic, despite an increase in the partial pressure of oxygen, which would theoretically increase maximum size, the maximum size of fossilized insects became smaller. These findings are inconsistent with the expectations of the working hypothesis. Oxygen supply is likely to partially limit the maximum size of insects with additional factors.     

Developmental morphology of the ovules of Amborella trichopoda (Amborellaceae) and Chloranthus serratus (Chloranthaceae)

The developmental morphology of the outer integument in the pendent orthotropous ovules of Amborella trichopoda (Amborellaceae) and Chloranthus serratus (Chloranthaceae) was studied. In both species the outer integument is semiannular at an early stage and becomes cup-shaped but dorsiventrally somewhat asymmetric at later stages. The outer integument, which is initiated first on the concave and lateral sides of the ovule, differs from that of the anatropous ovules of other basal families with the outer integument semiannular at an early stage or throughout development. The bilateral symmetry of the outer integument is shared by these orthotropous and anatropous ovules. The developmental pattern of the outer integument and ovule incurving characterize the ovule of the Amborellaceae and Chloranthaceae, which is not equivalent to typical orthotropous ovules of eudicots. A phylogenetic analysis of ovule characters in basal angiosperms suggests that anatropous ovules with cup-shaped outer integuments and orthotropous ovules were derived independently in several clades and that the ovules of Amborella and Chloranthus might also be derivative.     

THE GLYCEROL-ISOLATED MITOTIC APPARATUS: A RESPONSE TO PORCINE BRAIN TUBULIN AND INDUCTION OF CHROMOSOME MOTION

The birefringence of the MAs or spindles isolated from sea urchin eggs with the 1 M glycerol-isolation medium was stabilized when more than 0.5 mg/ml tubulin was contained in the medium. The addition of glycerol up to a final concentration of of 4 M strongly stabilized the MAs even in the absence of GTP and tubulin. The birefringence of the spindle and asters was not reduced even for the periods of several hours. The incorporation of heterogeneous tubulin into the isolated anaphase MAs was demonstrated by augmentation of the birefringence at the interzonal region as well as half spindles accompanied by enlargement of spindle and asters. In the anaphase MAs isolated in the absence of brain tubulin, chromosomes moved a short distance toward the poles upon addition of ATP, Mg²⁺ and 0.5 mg/ml tubulin. When the MAs were isolated in the presence of 0.5 mg/ml tubulin, the chromosomes moved in a more regular fashion to half the way to the poles accompanied by an increase in spindle length by 10 to 15%. GTP could not be substituted for ATP for inducing the motion. The chromosome motion of the isolated anaphase spindle was less significant than that of the isolated MA. Increasing tubulin concentration to 3 mg/ml, the chromosomes in the isolated MA separated at random by an unusual growth of the spindle. The stretch of the interzonal region by incorporating heterogeneous tubulin seemed to push the chromosomes apart abnormally. It was suggested that brain tubulin in a range of 0.5 mg/ml supports a tubulin-MA microtubule equilibrium favoring more regular motion of chromosomes in vitro .     

Developmental morphology of foliose shoots and seedlings of Dalzellia zeylanica (Podostemaceae) with special reference to their meristems

The developmental morphology of seedlings and shoots of Dalzellia zeylanica was examined with reference to the meristem in order to understand the dorsiventral, foliose shoot. In seedlings, no obvious primary shoot and no root are formed. Subsequent to disappearance of the vestigial primary shoot meristem, two shoot meristems are established in the axils of the cotyledons, one of which grows into a secondary shoot. Microtome and SEM examinations of mature plants show that the shoot meristem is complex, comprising three zones along the shoot margin. The organogenetic zone, equivalent to the shoot apical meristem, produces dorsal leaves proximally and much fewer marginal leaves distally. During development, the zone repeatedly changes into a dorsal zone, while a new organogenetic zone is formed in an area between developing marginal leaves, resulting in the alternation of the organogenetic and dorsal zones, which allowed development of the coenosomic structure of the shoot. The dorsal and ventral zones do not produce leaves, but contribute to shoot expansion. The ventral zone also forces the marginal leaves to shift to the lateral side of the shoot. The rosette with tufted leaves might be a modification of the short shoot (ramulus) of other Tristichoideae.  © 2004 The Linnean Society of London, Botanical Journal of the Linnean Society , 2004, 144 , 289–302.     

INDUCTION OF CHROMOSOME MOTION IN THE GLYCEROL-ISOLATED MITOTIC APPARATUS: NUCLEOTIDE SPECIFICITY AND EFFECTS OF ANTIDYNEIN AND MYOSIN SERA ON THE MOTION*

Chromosome motion in glycerol-isolated mitotic apparatus (MA) of sea urchin and starfish eggs was investigated with respect to nucleotide specificity and the effects of antisera against tryptic fragment (Fragment A) of flagellar dynein and starfish egg myosin. The motion was highly specific for ATP. GTP, ITP, CTP, UTP, and ADP caused no displacement of the chromosomes towards the poles. The anti-Fragment A serum completely inhibited chromosome motion in the MA of the sea urchin egg, while antiserum against starfish egg myosin as well as its γ-globulin fraction did not inhibit the motion in the isolated MA of the starfish egg, suggesting that chromosome motion depends upon dynein-microtubule but not upon myosin-actin interaction. In addition, colchicine completely suppressed the chromosome motion in vitro.     

THE MITOTIC APPARATUS ISOLATED IN GLYCEROL-CONTAINING MEDIUM

The mitotic apparatus of the sea urchin egg was isolated at 30°C in an isolation medium containing glycerol which is known to stabilize microtubules. After isolation in the 1 m glycerol-isolation medium, the mitotic apparatus was stabilized on addition of glycerol to a final concentration of 3 to 4 m. Without the addition, the chromosomes were disjoined from the spindle and the interzonal region between separating chromosomes was fragile resulting in separation of half spindles. Lowering the temperature of the isolation medium to 20°C or below, the isolation procedure allowed to isolate spindles. The isolated spindle behaved in a manner similar to the mitotic apparatus on the effect of glycerol concentration.
The glycerol-mitotic apparatus contained tubulin which was extractable with the isolation medium containing Ca ions or an organic mercurial. Tubulin was also extracted upon lowering the temperature to 0°C in the presence of GTP. Addition of KCl to a final concentration of 0.6 m immediately dispersed the mitotic apparatus. The extract revealed a colchicine binding of 0.001 mole per 105,000 × g of protein. The colchicine binding complex was found to have a molecular weight of 105,000. The DEAE Sephadex column chromatography of the KCl extract allowed to elute tubulin fraction which bound 0.1 mole colchicine per 105,000 × g of protein. The mitotic apparatus tubulin was shown to contain α and β subunits with mobilities quite identical with those of brain tubulin subunits. The molecular weights of the α and β subunits were 55,000 ± 1,000 and 51,000 ± 1,000, respectively.     

Early Leaf Development and Leaf Sheath Formation of Botrychium strictum and B. virginianum (Ophioglossaceae)

The morphogenesis of the leaf sheath was studied in Botrychiumstrictum and B. virginianum of subgenus Osmundopteris. In thetwo species, the leaf primordium is initiated on the lowestpart of a ridge which is formed by partial growth of the shootapex. The leaf primordium first grows to cover the shoot apexalmost entirely except for a slit-like opening. The openingis formed by the frontal rim of the growing leaf primordium,i.e. the leaf margin, and the rear part of the shoot apex. Asthe leaf grows, the leaf margin elongates and takes a reverseV-shape. On both lateral edges of the leaf margin, marginalgrowth occurs to form the lobes of the leaf sheath. Such marginalgrowth and a small amount of growth on the uppermost portionof the sheath is involved in the leaf sheath formation in B.cirginianum, while only marginal growth takes place in B. strictum.The leaf sheath of Botrychium virginianum, in comparison tothat of B. strictum, has a morphogenesis which is more similarto the completely covering leaf sheath of subgenera Botrychiumand Sceptridhim. Based on the morphogenesis of the leaf sheath,systematic relationships in subgenus Osmundopteris are discussed Botrychium virginianum, B. strictum, subgenus Osmundopteris, leaf ontogeny, leaf sheath formation, scanning electron microscopy, light microscopy