ON PROPAGATION OF CORTICLA FACTOR AND CYTOPLASMIC FACTOR PARTICIPATING IN CLEAVAGE FURROW FORMATION OF THE NEWT'S EGG*

From Cynops pyrrhogaster eggs just after the start of the first cleavage, a fragment of cortical layer with a small entire cleavage furrow was cut out. In the fragment, the cortex had already acquired susceptibility to and the subcortical cytoplasm had already accquired inducibility for furrow formation. The fragment was transplanted to the animal hemisphere of uncleaved fertilized eggs or eggs immediately after the onset of the first cleavage, from which a portion of the host cortex was removed. Observation was made on division of the graft, and on propagation of the cortical susceptibility and the cytoplasmic inducibility of the graft onto the host egg. The transplant divided succesively on the host egg in many cases, but the furrow of the graft never advanced to the surface of the host egg. Neither the cortical factor nor the cytoplasmic factor was transmitted across the graft to the recipient egg.     

CHANGES OF THE MEMBRANE POTENTIAL AT THE TIME OF FERTILIZATION IN THE SEA URCHIN EGG WITH SPECIAL REFERENCE TO THE FERTILIZATION-WAVE

An experimental device was developed from the work of U ehara and S ugiyama (1969), in order to study the electrical phenomena accompanying the fertilization-wave in the sea urchin egg.
The change in membrane potential upon fertilization consists of 2 peaks (I to et al. , 1970), being preceded by a shoulder. The shoulder appears within the "latent period" (A llen and G riffin , 1958), and the 2 peaks correspond to the breakdown of the cortical granules and the formation of the fertilization membrane.
When the equatorial region of the egg surface was exposed to a detergent-sea water, the breakdown of the cortical granules and the formation of the fertilization membrane are induced only in this ring-shaped area. Sperm is then added to one of the polar regions. The fertilization-wave, starting from the point of sperm-entry, propagates across the detergent-treated region, and the membrane is formed on the whole egg surface. During such an experiment, changes of the membrane potential in the detergent-treated region were measured. 1 to 3 sudden transient depolarizations appear, followed by a delayed small depolarization. It is presumed that the initial depolarization corresponds to the fertilization-wave. The pattern of the potential change at normal fertilization may be explained by complexity of the cortical change, and the initial depolarizing shoulder is considered to correspond to the fertilization-wave, which is isolated by the above-mentioned device.     

Mutation in the Structural Gene for Diphtheria Toxin carried by Temperate Phage β

Corynebacterium diphtheriae strains lyso-genic for phage β are able to produce diphtheria toxin. This article describes evidence suggesting that the toxin structural gene is part of the phage genome.     

CORTICAL AND SUBCORTICAL CHANGES PRECEDING FURROW FORMATION IN THE CLEAVAGE OF NEWT EGGS

In the first cleavage of the egg of the newt, Cynops(Triturus) pyrrhogaster, some sort of preparation for the furrow formation in the cortical and subcortical cytoplasm precedes the advancing tip of the cleavage furrow. This is shown by the following facts: (1) Incisions made close to the tip of the cleavage furrow do not stop the progress of furrowing, allowing the furrow to cross the incisions and appear on the farther sides, while incisions made far enough from the furrow tip always prevent the further travelling of the furrow, (2) Displacement of the subcortical cytoplasm ahead of the furrow by rubbing with a hair loop makes the furrow bend corresponding to the width of the rubbed area, and (3) Transplantation of the subcortical material of the furrow tip to lateral parts in the same egg causes a depression in the overlying cortex at the transplanted position. The linear extension of the prepared area for the furrow formation is the longest in the animal hemisphere and it decreases in gradient towards the vegetal pole.     

EXPERIMENTAL STUDIES ON THE SITE OF PROPAGATION OF THE FERTILIZATION-WAVE IN THE SEA URCHIN EGG

Although the fertilization-wave in the sea urchin egg is generally considered to propagate over the egg surface, there has been no definite evidence to show the site of propagation. The possibility that the wave passes through the endoplasm, not over the egg surface, has not been denied.
A drop of paraffin was injected into an egg, so that the endoplasm was divided into 2 parts by the paraffin drop, the 2 parts being connected only by the egg cortex. When spermatozoa were added to one side of the egg, the fertilization membrane was formed first on this part of the egg and then on the opposite part. This indicates that the egg surface or the egg cortex is the site of propagation of the fertilization-wave and the endoplasm has no direct influence on the propagation.     

Development of microsatellite markers for the drywood termite Incisitermes minor (Hagen)

Ten polymorphic microsatellite markers were developed in the drywood termite Incisitermes minor (Hagen) by using a genomic DNA extracted from the heads of workers. The microsatellite markers obtained in this study produced between two and seven alleles per locus. The observed and expected heterozygosities among the 10 markers ranged from 0.16 to 0.83 and from 0.43 to 0.84, respectively. These markers were shown to be good molecular tools for identification of the genetic structure and parentage assessment in I. minor.     

Ion gradients in xylem exudate and guttation fluid related to tissue ion levels along primary leaves of barley

The concentration of ions in plant cells and tissues is an essential factor in determining physiological function. In the present study, we established that concentration gradients of mobile ions exist in both xylem exudates and tissues within a barley (Hordeum vulgare) primary leaf. For K⁺ and NO₃^?, ion concentrations generally decreased from the leaf base to the tip in both xylem exudates and tissues. Ion gradients were also found for Pi and Cl^? in the xylem. The hydathode strongly absorbed Pi and re‐translocated it to the rest of the plant, whereas Cl^? was extruded. The ion concentration gradients developed early during leaf growth, increased as the tissue aged and remained under both high and low transpiration conditions. Measurement of the expression profiles of Pi, K⁺ and NO₃^? transporters along the longitudinal axis of the leaf revealed that some transporters are more expressed at the hydathode, but for most transporters, there was no significant variation along the leaf. The mechanisms by which longitudinal ion gradients develop in leaves and their physiological functions are discussed.