Developmental study onHypolepis punctata (Thunb.) Mett.

The third petiolar bud ofHypolepis punctata appears on the basiscopic lateral side of the petiole above the fairly developed first petiolar bud. This investigation clarified the fact that the third bud is formed neither by the activity of the meristem of the first bud nor by the meristem directly detached from the shoot apical meristem, but is initiated in the cells involved in the abaxial basal part of the elevated portion of the leaf primordium. Thus the third bud is of phyllogenous origin. This investigation further revealed that the cells to initiate the third bud are originally located in the abaxial side of the leaf apical cell complex like the cells to initiate the first bud, but are not incorporated into the meristem of the first. After the first, second and third petiolar buds have been initiated, they are carried up into fairly high regions on the petiolar base by the intercalary growth which occurs in the leaf base below the insertion level of the first and the second buds.     

Genetic and developmental evidence for a repressed genital primordium in Drosophila melanogaster

Agametic, a maternal-effect mutation, causes the absence of germ cells in approximately 40% of the gonads of flies derived from homozygous females. The nature of the deficiency in the eggs produced by these flies was examined. Ultrastructural abnormalities were seen in the polar granules of some eggs shortly after fertilization. Although a normal number of pole cells form, some are abnormal with degenerating polar granules and nuclear bodies and they contain myeloid bodies. The pole cells reach the gonads and at 14 hr of development all the gonads contain germ cells. However, in 40% of the gonads the germ cells become necrotic and disappear. Thus, the source of agametic gonads in the adult is embryonic death of pole cells in some gonads. To test whether this gonadal death is an autonomous deficiency of the mutant pole cells, mosaic pole cell populations were produced by reciprocal pole cell transplantation. In both types of transplants, the mutant pole cells died autonomously. In eight instances gonads containing only donor pole cells were obtained. Since mutant pole cells die when wild-type pole cells normally begin dividing, we suggest that the lesion affects the ability of these mutant pole cells to reenter the cell cycle.     

Modulation of auxin-binding proteins in cell suspensions

Summary Cultured cell lines from carrot (Daucus carota L.) with little or no embryogenic potential were examined for the auxin-binding capacity of their membranes. The lines belonged to different classes: (a) wild-type lines kept in culture for different periods (the longer the period, the lower being their embryogenic potential); (b) variants, isolated after mutagenesis, showing normal growth but a lack of embryogenic response; (c) auxin-resistant lines, isolated as colonies on solid media containing 45 M 2,4-d; (d) a previously described tumorous line (E9) isolated because of its resistance to hypomethylating drugs. All of these lines showed alterations in auxin-induced, auxin-binding capacity (modulation), i.e. in the non-embryogenic lines the addition of auxin increased the auxinbinding capacity to a very small degree, or removal of the hormone did not produce the proper decrease in that capacity, or both defects could be simultaneously present. Both types of defects were shown to be correctable: after treatments designed to increase the amplitude of modulation, embryogenic capacity was restored in a number of lines.     

Developmental variation in copper,zinc and metallothionein mRNA in brindled mutant and nutritionally copper deficient mice

The concentrations of copper, zinc and metallothionein-I (MT-I) mRNA were determined in the liver, kidney and brain of the brindled mutant mouse from birth until the time of death. Despite accumulation of copper in the kidney of the mutant, MT-I mRNA concentrations were normal. There was no difference between the MT-I mRNA in the brain of mutant and normal in the first 10 days of life, but after day 10 metallothionein mRNA levels were increased in the mutant. The concentration of copper was very low in the liver of the mutant, and on day 6 after birth the metallothionein mRNA was also reduced by about 50%. This reduction was not seen in copper-deficient 6-day-old pups, despite very low hepatic copper levels. This suggests that the lower hepatic MT-I mRNA in the day 6 brindled mouse was not simply due to the reduction in hepatic copper and also that hepatic copper is not regulating metallothionein gene expression the liver of neonatal mice. After day 12 hepatic MT-I mRNA levels were elevated in mutant and in copper deficient mice, both of which die at 14 to 16 days. These increases and the increase in brain MT-I mRNA in older mutant mice are likely to be caused by stress. Overall the results support the conclusions that the brindled mutation does not cause a constitutive activation of the metallothionein genes, and that the differences in metallothionein mRNA between mutant and normal are most probably secondary consequences of the mutation.     

Quantitative staging of embryonic development of the tobacco hawkmoth,Manduca sexta

Summary A complete timetable of embryonic development of the tobacco hawkmoth,Manduca sexta (Lepidoptera: Sphingidae), is presented. Using living embryos, 20 developmental stages from oviposition to hatching are described with respect to their morphological and physiological maturation. This staging series provides a simple method to identify the stage ofManduca development during all phases of embryogenesis.     

Δ1-11-oxa-11-deoxycortisol: A new antiglucocorticoid with activity in vivo

A new steroid-like compound, Δ¹-11-oxa-11-deoxycortisol, was tested in a one-week growth suppression, thymus suppression and adrenal weight suppression bioassay for possible glucocorticoid antagonist activity in $\text{vivo}$. We hypothesized that this compound would have antiglucocorticoid activity based on previous studies of 11-deoxycortisol and Δ^1,9(11)-11-deoxycortisol, which were optimal glucocorticoid antagonists $\text{in vivo}$ in adrenalectomized rats, but which lost antiglucocorticoid activity in intact animals, apparently due to adrenal 11β-hydroxylation. Thus, Δ¹-11-oxa-11-deoxycortisol, a compound which cannot undergo llβ-hydroxylation, was synthesized and tested as an antiglucocorticoid. This analog had an affinity for the rat thymus glucocorticoid receptor similar to that of its parent compounds (Ki 0.9-3.1×10^?7M). A dose of 1 $\text{mg}\text{rat}$ antagonized the effect of 15μg of dexamethasone in the growth suppression assay (p<0.05) and in the thymus suppression assay (p<0.06), but did not antagonize dexamethasone-induced adrenal weight suppression. Δ¹-11-oxa-11-deoxycortisol did not exhibit glucocorticoid activity in any of the three assays. These data suggest that Δ¹-11-oxa-11-deoxycortisol may be a pure competitive antagonist of dexamethasone.     

Genetics of the peroxidase isoenzymes in Petunia

Summary Three electrophoretic variants of the peroxidase b isoenzymes in Petunia have been found. The encoding gene prxB is shown to be located on chromosome I by its linkage with the gene Hfl. Analysis of prxB heterozygotes showed a gradual increase of the electrophoretic mobility of all three PRXb allozymes during development and differential expression in enzyme activity of three prxB alleles. The location of prxB on chromosome I was confirmed by an allelic dosage effect in trisomies I, trisomie segregation and the construction of trisomies I with triple-banded PRXb phenotype. From telotrisomic analysis it was concluded that prxB and Hfl are located on the same arm of chromosome I. The unexpected linkage of prxB and Hfl with the gene Fl in one of the crosses was suggested to be caused by a translocation in line SI, involving the gene Fl.     

Developmental studies on the leaf and the extra-axillary bud ofHistiopteris incisa

Anatomical and developmental studies have been made ofHistiopteris incisa in order to obtain a reasonable interpretation of the so-called extra-axillary bud. Single, or rarely two extra-axillary buds arise on the lateral side of the petiolar base. The branch trace appears to depart from the basiscopic margin of the leaf trace. At the earliest stage of the leaf initiation, the leaf apical cell is cut off in one of the prismatic cells of the shoot apical meristem. The leaf apical cell, then, cuts off segments successively to form a well-defined group of derivatives. On the other hand, a well-recognized cell group called “outer neighboring cell group”,onc, is found adjacent to the abaxial boundary of the derivatives of the leaf apical cell. This group of cells does not originate directly in the mother cell of the leaf apical cell. The primordium of the extra-axillary bud is always initiated in the superficial pillar-shaped cell layer ofonc. The leaf primordium may consist of two parts, the distal part derived from the leaf apical cell and the basal part from the adjacent cells includingonc. These facts suggest that the extra-axillary bud is of foliar nature. This study was partly supported by a Grant-in-Aid for Encouragement of Young Scientists by the Ministry of Education of Japan; no. 374222 in 1978.     

Infloreszenz- und Blütenentwicklung bei der KugeldistelEchinops exaltatus (Asteraceae)

InEchinops the flowers are surrounded by several scales and initiated in an acropetal and spiral succession on a cone-like inflorescence axis (Figs. 1–6). The floral organs originate in the following sequence: petals—stamens—carpels—pappus. The petals arise from a meristematic rim and therefore are already interconnected when they arise as primordia. This sympetalous zone remains rather inconspicuous for a long period, but eventually, the elongated corolla tube is formed through intercalary growth in a ring zone. Thereby, the stamens are moved upwards and form ledges on the corolla tube (Fig. 34). In the inferior ovary the usual zones of the typical angiospermous gynoecium can be distinguished, namely a synascidiate, symplicate and hemisymplicate zone. The ovule is borne on carpellary tissue.