Distribution of intrapleural and intravenous Corynebacterium parvum in humans; 99mTc−, and 131I-labeled bacteria

Summary The distribution of Corynebacterium parvum labeled with ¹³¹iodine or ^99mtechnetium was studied in 17 patients with bronchogenic carcinoma. The labeled bacteria were given intravenously or intrapleurally and monitored by whole-body gamma tracking and samples of blood and urine. Even though the rate of physical decay is quite different for ¹³¹iodine and ^99mtechnetium, the tracking time of labeled bacteria was limited to 24 h after injection for both radioactive isotopes. Technetium labeling was preferred because of greater imaging resolution and less radiation dose to the patient. Following intravenous administration, labeled C. parvum was found predominantly in the liver and spleen, and in a lesser amount in the lung. Radioactivity was confined to the pleural cavity after intrapleural injection. These results suggest the combined intravenous and intrapleural route of adjuvant immunosupportive agents such as C. parvum for operable lung cancer patients.     

Regeneration of Fertile Barley Plants from Mechanically Isolated Protoplasts of the Fertilized Egg Cell

A simple procedure is described for the mechanical isolation of protoplasts of unfertilized and fertilized barley egg cells from dissected ovules. Viable protoplasts were isolated from ~75% of the dissected ovules. Unfertilized protoplasts did not divide, whereas almost all fertilized protoplasts developed into microcalli. These degenerated when grown in medium only. When cocultivated with barley microspores undergoing microspore embryogenesis, the protoplasts of the fertilized egg cells developed into embryo-like structures that gave rise to fully fertile plants. On average, 75% of cocultivated protoplasts of fertilized egg cells developed into embryo-like structures. Fully fertile plants were regenerated from ~50% of the embryo-like structures. The isolation-regeneration techniques may be largely genotype independent, because similar frequencies were obtained in two different barley varieties with very different performance in anther and microspore culture. Protoplasts of unfertilized and fertilized eggs of wheat were isolated by the same procedure, and a fully fertile wheat plant was regenerated by cocultivation with barley microspores.     

Improved microRNA quantification in total RNA from clinical samples

microRNAs are small regulatory RNAs that are currently emerging as new biomarkers for cancer and other diseases. In order for biomarkers to be useful in clinical settings, they should be accurately and reliably detected in clinical samples such as formalin fixed paraffin embedded (FFPE) sections and blood serum or plasma. These types of samples represent a challenge in terms of microRNA quantification. A newly developed method for microRNA qPCR using Locked Nucleic Acid (LNA?)-enhanced primers enables accurate and reproducible quantification of microRNAs in scarce clinical samples. Here we show that LNA?-based microRNA qPCR enables biomarker screening using very low amounts of total RNA from FFPE samples and the results are compared to microarray analysis data. We also present evidence that the addition of a small carrier RNA prior to total RNA extraction, improves microRNA quantification in blood plasma and laser capture microdissected (LCM) sections of FFPE samples.     

Nitrogen transfer in the interface between the symbionts in pea root nodules

Transport mechanisms for transfer of nitrogen from the bacteroid side across the symbiosome membrane of pea (Pisum sativum L.) root nodules were identified by the use of energised bacteroid side-out symbiosome membrane vesicles. Such membrane vesicles were used to study a mechanism with high capacity for transport of ammonium and another mechanism capable of transporting aspartate. Both transport mechanisms are voltage driven and the rate of transport relates positively to the magnitude of the imposed membrane potentials. Competition for transport between ammonium and aspartate was not observed. The ammonium transporter has been identified as a voltage-driven channel whereas the symbiosome membrane aspartate transporter appears to be a H⁺/aspartate symport. The results suggest that nitrogen transfer between the symbionts in pea root nodules involves transfer of amino acids as well as ammonium. In the symbiosome subfraction, which represents the interface between the symbionts, specific aspartate aminotransferase activity was more than four times as high as in the bacteroid cytosol. This finding supports a hypothesis that transamination cycles operating between the symbionts may constitute a component of the transfer of nitrogen between the symbionts.     

Identification of a Transport Mechanism for NH4+ in the Symbiosome Membrane of Pea Root Nodules

Symbiosome membrane vesicles, facing bacteroid-side-out, were purified from pea (Pisum sativum L.) root nodules and used to study NH4+ transport across the membrane by recording vesicle uptake of the NH4+ analog [14C]methylamine (MA). Membrane potentials ([delta][psi]) were imposed on the vesicles using K+ concentration gradients and valinomycin, and the size of the imposed [delta][psi] was determined by measuring vesicle uptake of [14C]tetraphenylphosphonium. Vesicle uptake of MA was driven by a negative [delta][psi] and was stimulated by a low extravesicular pH. Protonophore-induced collapse of the pH gradient indicated that uptake of MA was not related to the presence of a pH gradient. The MA-uptake mechanism appeared to have a large capacity for transport, and saturation was not observed at MA concentrations in the range of 25 [mu]M to 150 mM. MA uptake could be inhibited by NH4+, which indicates that NH4+ and MA compete for the same uptake mechanism. The observed fluxes suggest that voltage-driven channels are operating in the symbiosome membrane and that these are capable of transporting NH4+ at high rates from the bacteroid side of the membrane to the plant cytosol. The pH of the symbiosome space is likely to be involved in regulation of the flux.     

Isolation and culture of barley megasporocyte protoplasts

An efficient technique has been developed for the isolation of barley megasporocyte protoplasts at early meiotic prophase. Ovules were dissected out of ovaries under aseptic conditions, subjected to a brief enzymatic digestion, and then transferred to a modified Kao medium with 90 g/l sucrose and 20 mM CaCl₂. A small incision was made with a scalpel through the softened epidermal cell layer of the nucellus and the megasporocyte could then be liberated into the medium by applying gentle pressure on the nucellus. The megasporocyte appeared to be completely devoid of a wall and changed its in situ pyriform shape to completely spherical when extruded into the medium. Four to nine protoplasts could typically be isolated per spike. Protoplasts cultured in medium degenerated after a few days. Viability was dramatically improved if protoplasts were co-cultivated with barley microspores undergoing microspore embryogenesis. More than half of the protoplasts were still alive after 6 days of culture, and in some cases they survived more than 12 days of culture. Fluorescence microscopy of the cultured protoplasts stained with 4,6-diamidino-2-phenylindole (DAPI) or aniline blue revealed that the protoplasts remained uninuclear and reformed their callose wall.     

Regeneration of the barley zygote in ovule culture

An ovule culture technique has been established for barley that allows the regeneration of plants from zygotes. An average of 1.3 plantlets per ovule could be regenerated from more than 60% of the cultured ovules and about 75% of the regenerated plantlets developed into normal, fertile plants. The same regeneration frequencies were obtained in intact ovules and in ovules where the two integuments had been removed from the micropylar region. Unfertilized ovules and ovules where the fertilized eggs had been destroyed by a microinjection needle did not give rise to embryo-like structures. Plants could be regenerated from the zygote at the same frequency at developmental stages from immediately after fertilization until the formation of bicellular embryos. This tissue culture system appeared to be largely independent of genotype since similar regeneration frequencies were obtained in two different barley cultivars, Igri and Alexis, that in anther and microspore culture behave differently. The same technique has also been applied successfully in the wheat cultivar Walter.