The chick oviduct in tissue culture. I. Initial characterization of growing primary oviduct tissue cultures

A simple three-enzyme treatment of collagenase, dispase and hyaluronidase on finely minced chick oviduct yields clumps of 50-150 cells. These cells attach to collagen-treated dishes and survive in culture for at least 2 weeks without subculturing. Oviduct cell cultures can also be induced to grow. Estradiol or epidermal growth factor (EGF) induce a 40% increase in cells in 4 days when cultures are grown in serum levels that do not support growth. Serum from estrogen-stimulated chicks promotes rapid cellular proliferation (doubling times of 1-2 days). Sera from estrogen withdrawn chicks, laying hen or horse do not support as rapid proliferation. The oviduct growth-promoting factors in serum from estrogen-stimulated chicks are not steroids or fibroblast growth factors (FGF). Removal of steroids from these sera by charcoal treatment or delipidization does not decrease the rate of growth. The addition of 1-100 nM estradiol does not increase a serum's ability to promote growth. Purified FGF or platelet-derived growth factor (PDGF) do not induce oviduct proliferation. These results were reproduced in oviduct cell cultures started from estrogen-stimulated and withdrawn chicks as well as laying hens. Thus the factors in serum from estrogen-stimulated chicks that promote rapid oviduct growth are induced by estrogen treatments in vivo, but do not seem to be only steroids.     

The selection and uses of plant tissue cultures resistant to toxic compounds

Beginning in 1970, in vitro selection for resistance to various toxic compounds has produced many plant cell lines useful for studying biochemical pathways, altering overall cell metabolism and growth, and regenerating plants with desirable traits. Some toxin-resistant lines have been used to elucidate the genetic and biochemical mechanisms plant cells use to adapt, including gene amplification. Other resistance traits have been used for the selection of protoplast fusion hybrids or to develop selectable markers for nuclear or plastid transformation through cloning the corresponding genes and promoters.     

Quantitative selection of denitrifying bacteria in continuous cultures and requirement for organic carbon. I. Starch

A mixed population of bacteria from bottom sludge of nitrogen wastewater reservoir was incubated in continuous culture in medium containing 1000 mg nitrate nitrogen/l and starch. Maximal efficiency of denitrification was 5 mg N/l/h. Marked changes in participation of denitrifying bacteria (16-76%) among total number of bacteria was observed, this being dependent on the ratio of starch concentration (CS) to nitrogen concentration (CN) in the medium. The optimal CS/CN ratio ensuring highest participation of denitrifying bacteria was 3.2. The amount of starch required for the denitrification of a defined quantity of nitrogen is negatively correlated (r = -0.98) with the frequency of the occurrence of denitrifying bacteria (XD) and is: CS = (5.53-0.028XD) CN. The denitrifying bacteria in continuous culture were dominated, depending on CS/CN ratio and flow rate of medium, by Alcaligenes faecalis, Paracoccus denitrificans or Pseudomonas mendocina, that is species unable to hydrolyse starch.     

Bioconversion of naturally occurring precursors and related synthetic compounds using plant cell cultures.

The nearly unlimited enzymatic potential of cultured plant cells can basically be employed for bioconversion purposes. Plant enzymes are able to catalyze regio- and stereospecific reactions and can therefore be applied to the production of compounds of pharmaceutical interest. Naturally occurring as well as related synthetic compounds may be used as precursors. A review of the current status of such bioconversions is given. It includes the performance of bioconversions by freely suspended and immobilized plant cells or enzyme preparations. In addition, the kinetic aspects of immobilized plant cells are discussed. Special attention is paid to the bioconversion of poorly or water insoluble precursors. Finally, a model scheme for the development of a commercially available drug, produced by bioconversion, and perspectives are discussed.     

Studies on plant tissue cultures I. Relationship between inocula sizes and growth of calluses in liquid culture

1. 1. It was observed that lag of growth was longer in small inoculathan in large inocula using tobacco callus in liquid culture.
2. 2. These different growth responses between small and largeinocula were dependent on the ratio of inoculum to culture medium.
3. 3. The same result was obtained in a strain of carrot rootcallus.But the growth lag was very short in the carrot callus,whichwas subcultured for the shortest period among the 4 strainsused, even in small inocula. On the other hand, both small andlarge inocula of the strain, which were subcultured for thelongest period among the 4 strains, did not grow at all duringthe culture period; the longer the period of subculturing, thelonger the lag of growth.
4. 4. The longer lag of small inoculain tobacco callus was recoveredby gibberellin A₃ in the presenceof the acidic fraction ofcarrot root extract or vitamins suchas pyridoxine and thiamine.

(Received December 11, 1967; )     

Freeze-fracture analysis of phloem structure in plant tissue cultures. I. The sieve element reticulum

During the differentiation of phloem sieve elements, the endoplasmic reticulum undergoes unique modifications to form the sieve element reticulum (SER) which persists in mature, functioning sieve tubes. Cisternae of the SER lack ribosomes and are restricted to the periphery of the sieve element at late stages of development. Some of the SER is seen as single cisternae that are in close contact with the sieve element plasma membrane. Thin sections and freeze-fracture images of sieve elements formed in tissue cultures demonstrate that the SER consists of both single cisternae and regions of stacked cisternae at some stages of maturity. The unstacked regions of the SER are continuous with the cisternae of the stacked regions. In freeze-fracture images the single cisternae adjacent to the plasma membrane are seen to be fenestrated and the openings allow continuity between the plasma membrane and the cell lumen. It is concluded that the interface between the SER and the plasma membrane of the sieve element serves to allow membrane functions such as proton efflux, proton-sucrose cotransport and compensating movements of ions to occur in a microenvironment that is separated from the moving translocation stream in the sieve element lumen. Passage of water and translocated solutes from the plasma membrane or the SER/PM interface to the interior of the cell is enhanced by the openings in the fenestrated regions of the SER. It is suggested tha the SER may also play a role in channeling ATP from mitochondria associated with the SER to the proton-pumping ATPase in the plasma membrane and that the SER may function in the uptake and release of potassium ions in the sieve element.