Morphogenesis and fate of the residual body in human spermiogenesis

Summary In the human testis the formation of the residual body of the spermatid and its morphological changes during and after spermiation were studied by means of electron microscopy. The caudal cytoplasmic mass of the late spermatid contains a Golgi complex, mitochondria, annulate lamellae, a chromatoid body, flower-like structures, ribosomes, a few large vacuoles, myelin-like membrane profiles and sporadic lipid droplets. When, by detachment of the caudal cytoplasm from the free spermatozoon, the residual body is formed, the chromatoid body has disappeared; the mitochondria are clustered peripherally; the ribosomes appear as a single complex in contact with a large vacuole containing granular material; in place of the Golgi complex aggregations of vesicles are present. The lipid droplets remain unchanged. The residual bodies or their fragments are either extruded via the seminiferous tubular lumen into the excurrent ducts or they are engulfed by Sertoli cells where in the supranuclear region the successive steps of decomposition can be observed. The participation of the various constituents in the disintegration of the residual body is discussed. In contrast to other mammalian species, in man the sporadic lipid droplets seem to be of minor importance in the fate of the residual body.     

Temperature and growth-induced water potential

When the steins of dark-grown soybean [Glycine max (L.) Merr.] seedlings grew rapidly at favorable temperatures in saturating humidities, a water potential of about 0·2 MPa was induced by growth ($pS_o-$pS_w, where $pS_o is the water potential of the basal nonelongating tissue and $pS_w is the water potential of the elongating tissue). If this water potential was caused by high concentrations of solute in the apoplast, as has been proposed, lowering the temperature should have little effect on the potential. On the other hand, if the water potential was caused by apoplast tensions generated by growth, then the tensions should disappear as growth is inhibited by low temperatures. We observed that the growth-induced water potential became too small to detect when growth was inhibited by temperatures as low as 13—5 °C. The disappearance was observed as a rise in apoplast water potential using a thermocouple psychrometer for intact plants, a rise in cell turgor using a miniature pressure probe and a decrease in apoplast tensions using a pressure chamber. The disappearance was not caused by a loss of solute from the apoplast because the tensions fully accounted for the growth-induced water potential at all temperatures. The results are consistent with the lack of solute measured directly in the apoplast solutions at high temperatures (Nonami & Boyer 1987). Therefore, it was concluded that little solute was present in the apoplast at any temperature, and the growth-induced water potential was associated mostly with a tension that moved water from the xylem and into the surrounding cells to meet the demand of cell enlargement.     

Giant cells fromSaccharomyces uvarum grown after X-irradiation

Yeast cells, Saccharomyces uvarum, were irradiated with X-rays and grown in liquid suspension. Glucose as the only carbon source was limited to 12.5 mM. Under these conditions giant cells are formed. Cell number, glucose utilization, ethanol production and oxygen consumption are measured during the time of growth. The mean weight of single cells in the stationary phase increases up to 75 krad and is not due to an uptake of water. In irradiated cultures oxygen consumption and glucose utilization per cell are higher than in control cells. The data demonstrate that synthesis- and energy-metabolism during the formation of non-dividing, radiation-induced giant cells is increased.     

Potassium Loss from Stomatal Guard Cells at Low Water Potentials

The potassium content of guard cells and the resistance to viscousflow of air through the leaf were determined in sunflower (Helianthusannuus) subjected to low leaf water potentials under illuminatedconditions. In intact plants desiccated slowly by withholdingwater from the soil, large losses in guard cell K occurred asleaf water potentials decreased. Leaf viscous resistance increased,indicating stomatal closure. Similar results were obtained whendetached leaf segments were desiccated rapidly. Upon rehydrationof leaves, no stomatal opening was observed initially, despiteleaf water potentials at predesiccated levels. After severalhours, however, re-entry of K occurred and stomata became fullyopen. Turgid leaf segments floated on an ABA solution showedlosses of guard cell K and closure of stomata as rapidly andcompletely as those brought about by desiccation. It is concludedthat stomatal closure at low water potentials under illuminatedconditions is not controlled solely by water loss from the tissuebut involves the loss of osmoticum from the guard cells as well.This in turn decreases the turgor difference between the guardcells and the surrounding cells, and closing occurs.     

Automatic morphometric analysis of retrograde changes in the nucleus n. facialis at different ontogenetic stages in the rat

Summary The grey level index (= GLI) and the fresh volume were determined with the image analyser Micro-Videomat for the nucl. n. facialis after axotomy of the left n. facialis. The experiments were performed on 10 rats in different stages of ontogenesis. The GLI is a quantitative parameter which could be quickly obtained and which demonstrated quantitative changes during retrograde reaction in the respective centres. A decrease in the fresh volumes of the affected nucl. n. facialis could also be demonstrated. The meaning of GLI is discussed.Supported by Deutsche Forschungsgemeinschaft grants Kr 289/10 and Zi 192/1Dedicated to Prof. Dr. H. Leonhardt on the occasion of his 60th birthday