Asexual reproduction,regeneration, and somatic embryogenesis in the planarian Dugesia tigrina (Turbellaria)

In reviewing recent research published in Russian on regeneration and asexual reproduction, the following morphogenetic processes in the planarian Dugesia tigrina are considered: 1) regeneration of lost parts of the body; 2) regeneration of the whole worm from fragments of the body, either by normal regeneration when the inital polarity of the fragment is retained or by somatic embryogenesis when one or more new axes of polarity arise; 3) somatic embryogenesis, or development of individuals from somatic cells; 4) hypermorphosis, or the presence of more than the usual number of organs or body parts, a process that can be interpreted in terms of somatic embryogenesis; and 5) asexual reproduction. Some morphological, biochemical, and physiological studies of the division zone in D. tigrina demonstrate peculiarities of a local breakdown of integrative functions, a breakdown which in turn causes division of the individual to take place at this zone; timing of division is controlled by the organism as an integrated whole.     

Developmental profiles of three embryo-lethal maize mutants lacking leaf primordia: ptd*-1130, cp*-1418, and bno*-747B

The defective kernel (dek) mutants of maize are altered in both their embryo and endosperm development. Earlier studies have indicated that some of the dek mutants are unable to form shoot apical meristems or leaf primoirda. We have examined three embryo lethal dek mutants of this type, ptd*-1130, cp*-1418, and bno*-747B, to obtain a developmental profile for each. Allelism tests show that these three mutants are not allelic. Embryos were examined in early, mid-, and late kernel development as well as at kernel maturity by dissection and sectioning procedures and also at kernel maturity by scanning electron microscopy. All three mutants lag behind normal embryos in their rate of development. Embryos of ptd*-1130 reached the transition stage by early kernel development and progressed no further but underwent cell enlargement and necrosis during late kernel development. Embryos of cp*-1418 reached an early coleoptilar stage by midkernel development. They subsequently increased in size but did not form any leaf primordia. At kernel maturity, they no longer had a shoot apical meristem but often had a well formed root meristem. They appeared to remain healthy and did not become necrotic. Embryos of bno*747B reached the early coleoptilar stage by early kernel development but progressed no further. By kernel maturity, they had grown into masses of irregularly shaped embryonic tissue that no longer resembled any normal embryo stage but were not necrotic. None of these three mutants responded to attempts to support continued embryo development when cultured, but all three mutants formed callus on N6 and MS media supplemented with 2,4-D. These results indicate that these mutants are all uniformly blocked at specific stages early in embryonic development, have different subsequent developmental fates, and represent three different genes performing unique functions that are essential for embryogenesis.     

Establishment and maintenance of friable,embryogenic maize callus and the involvement of L-proline

Friable, embryogenic maize (Zea mays L.), inbred line A188, callus was established and maintained for more than one year without apparent loss of friability or embryogenic potential. Embryoid development was abundant in these cultures and plants were easily regenerated. Frequencies of friable-callus initiation and somatic-embryoid formation increased linearly with addition to N6 medium (C.C. Chu et al. 1975, Sci. Sin. [Peking] 18, 659–668) of up to 25 mM L-proline. Proline additions up to 9 mM to MS medium (inorganic elements of T. Murashige and F. Skoog 1962, Physiol. Plant. 15, 473–497, plus 0.5 mg 1^-1 thiamine hydrochloride and 150 mg 1^-1 L-asparagine monohydrate) did not stimulate embryoid formation. A major part of the difference between MS and N6 media could be attributed to their respective inorganic nitrogen components. L-Glutamine was not a satisfactory substitute for L-proline. Of 111 regenerated plants grown to maturity from three independent friable, embryogenic cell lines ranging in age from three to seven months, only four plants were abnormal based on morphology and pollen sterility. Seed was produced by 77% of the regenerated plants.Abbreviations 2,4-D 2,4-dichlorophenoxyacetic acid - MS medium containing inorganic elements of Murashige and Skoog (1962), plus 0.5 ml 1^-1 thiamine hydrochloride and 150 mg 1^-1 L-asparagine monohydrate - N6 medium of Chu et al. (1975) Paper No. 13,904, Scientific Journal Series Minnesota Agricultural Experiment Station     

Ultrastructural studies on plastids of generative and vegetative cells inLiliaceae 3. Plastid distribution during the pollen development inGasteria verrucosa (Mill.) Duval

Summary This paper describes the development of pollen grains ofGasteria verrucosa from the late microspore to the mature two-cellular pollen grain. Ultrastructural changes and the distribution of plastids as a result of the first pollen mitosis have been investigated using light and electron microscopy. The microspores as well as the generative and the vegetative cell contain mitochondria and other cytoplasmic organelles during all of the observed developmental stages. In contrast, the generative cell and the vegetative cell show a different plastid content. Plastids are randomly distributed within the microspores before pollen mitosis. During the prophase of the first pollen mitosis the plastids become clustered at the proximal pole of the microspore. The dividing nucleus of the microspore is located at the distal pole of the microspore. Therefore, the plastids are not equally distributed into both the generative and the vegetative cell. The possible reasons for the polarization of plastids within the microspore are briefly discussed. The lack of plastids in the generative cell causes a maternal inheritance of plastids inGasteria verrucosa.     

The spatial association of the sperm cells and vegetative nucleus in the pollen grain ofBrassica

Summary In mature viable pollen ofBrassica oleracea, the pair of sperm cells and the nucleus of the vegetative cell are linked to form a structured unit we term the male germ unit. The sperm cells are held within a common periplasm and have no cell walls. Each sperm cell has a central globular body containing the nucleus surrounded by several evaginations which provide the means for linkage between them. One sperm cell, usually that closest to the nucleus of the vegetative cell contains most of mitochondria profiles (plastids are absent). This sperm cell appears to be linked by its protoplasmic evaginations to the envelope of the vegetative nucleus. The role of this unit in interactions with the female gametic complex is considered.     

Quantitative ultrastructural analysis of barley sperm

Summary Complete serial ultrathin sections of seven sperm pairs, computer-assisted measurements of cell, nuclear and organelle surface areas and volumes, and three-dimensional imagery were used to demonstrate that a process of cytoplasm and organelle elimination occurs during sperm maturation in barley. The number of mitochondria per sperm cell is reduced by 50%; sperm cell surface area and volume are reduced by 30% and 51% respectively. Mean volume and surface area per mitochondrion are significantly less in mature sperms. No examples of mitochondrial fusion or degeneration were observed within sperm cells. These data, along with observations of plasma membrane apposition and vesiculation within cytoplasmic extensions containing mitochondria, support the proposition that cytoplasm and organelle loss results primarily from the formation of cytoplasmic projections that are subsequently discarded from the sperm cell body. Comparisons of the quantitative data, including the number of mitochondria, indicate that differences between sperm cells of a pair are absent to very slight. Spatial organization within the pollen grain is such that the mature sperms, as well as the sperms and vegetative nucleus, are not in close proximity.     

Long term regeneration by somatic embryogenesis in barley (Hordeum vulgare L.) tissue cultures derived from apical meristem explants

Callus cultures were initiated from apical meristem explants of one to four-week-old aseptically-grown barley (Hordeum vulgare L. cv. Atlas 57) plants. Embryogenic callus and plants were produced in three separate experiments; the cultures have retained regenerative capacity for three years after initiation. Our results demonstrate that explants other than immature embryos are embryogenically competent in barley and that regeneration occurs by both somatic embryogenesis and organogenesis.