Lysosomal trafficking in rat cardiac myocytes

By immunolabeling of cryosections, we have characterized in rat cardiac myocytes the cation-independent mannose-6-phosphate receptor (MPR), a lysosomal membrane glycoprotein, lgp120, and a lysosomal enzyme, MEP (homologous to cathepsin L). Most of the MPR label was located in large membrane-filled structures (MPR structures) in large clusters of mitochondria adjacent to but distinct from the Golgi complex. Lpg120 and MEP showed typical lysosomal localization throughout the cell, often associated with regions that appeared to contain autophagosome-like structures. In addition, MEP and lgp120 co-localized within MPR structures. MEP and MPR were localized inside the lumen of MPR structures. MPR was associated mostly with inner membranes, whereas lgp120 was predominantly bound to the outer limiting membrane. MPR, lgp120, and MEP were not detected in Golgi stacks, but some labeling was seen in the putative TGN. Our data suggest that the MPR structures are prelysosomes involved in lysosomal enzyme targeting in rat cardiac myocytes.     

Fate of Nodule-Specific Polysaccharide Produced by Bradyrhizobium japonicum Bacteroids

A polysaccharide produced by Bradyrhizobium japonicum bacteroids in nodules (NPS) on soybean (Glycine max [L.] Merr.) roots is different in composition and structure from the extracellular polysaccharide produced in culture by this organism. Isogenic strains either capable or incapable of NPS synthesis supported similar rates of plant growth and nitrogenase activity, indicating that polysaccharide deposition was not detrimental. The possibility that NPS may have some protective or nutritional role for bacteroids was considered. Analysis of disintegrating nodules over periods of 1 to 3 months indicated greater recovery of viable bacteria from NPS+ nodules prior to the breakdown of NPS. During and after the breakdown of NPS, the decline in viable bacteria was similar for NPS+ and NPS- strains. Bacteroid destruction in senescing nodules may be accelerated by exposure to proteolytic enzymes in host cytoplasm; however, highly purified NPS had no significant effect on the in vitro activity of partially purified proteases, so protection of bacteroids via this mechanism is unlikely. B. japonicum USDA 438 did not utilize NPS as a carbon source for growth in liquid culture. In vitro assays of NPS depolymerase activity in cultured bacteria and bacteroids were negative using a variety of strains, all of which contained extracellular polysaccharide depolymerase. It seems highly unlikely that B. japonicum can utilize the polysaccharide it synthesizes in nodules, and NPS breakdown in senescing nodules is probably caused by saprophytic fungi.     

Transformation of carbon tetrachloride under sulfate reducing conditions

The removal of carbon tetrachloride under sulfate reducing conditions was studied in an an aerobic packed-bed reactor. Carbon tetrachloride, up to a concentration of 30 μM, was completely converted. Chloroform and dichloromethane were the main transformation products, but part of the carbon tetrachloride was also completely dechlorinated to unknown products. Gram-positive sulfate-reducing bacteria were involved in the reductive dechlorination of carbon tetrachloride to chloroform and dichloromethane since both molybdate, an inhibitor of sulfate reduction, and vancomycin, an inhibitor of gram-positive bacteria completely inhibited carbon tetrachloride transformation. Carbon tetrachloride transformation by these bacteria was a cometabolic process and depended on the input of an electron donor and electron acceptor (sulfate). The rate of carbon tetrachloride transformation by sulfate reducing bacteria depended on the type of electron donor present. A transformation rate of 5.1 nmol·ml^-1·h^-1 was found with ethanol as electron donor. At carbon tetrachloride concentrations higher than18 μM, sulfate reduction and reductive dechlorination of carbon tetrachloride decreased and complete inhibition was observed at a carbon tetrachloride concentration of 56.6 μM. It is not clear what type of microorganisms were involved in the observed partial complete dechlorination of carbon tetrachloride. Sulfate reducing bacteria probably did not play a role since inhibition of these bacteria with molybdate had no effect on the complete dechlorination of carbon tetrachloride. This revised version was published online in August 2006 with corrections to the Cover Date.     

Uptake and Metabolism of Carbohydrates by Bradyrhizobium japonicum Bacteroids

Bradyrhizobium japonicum bacteroids were isolated anaerobically and were supplied with ¹⁴C-labeled trehalose, sucrose, UDP-glucose, glucose, or fructose under low O₂ (2% in the gas phase). Uptake and conversion of ¹⁴C to CO₂ were measured at intervals up to 90 minutes. Of the five compounds studied, UDP-glucose was most rapidly absorbed but it was very slowly metabolized. Trehalose was the sugar most rapidly converted to CO₂, and fructose was respired at a rate at least double that of glucose. Sucrose and glucose were converted to CO₂ at a very low but measurable rate (<0.1 nanomoles per milligram protein per hour). Carbon Number 1 of glucose appeared in CO₂ at a rate 30 times greater than the conversion of carbon Number 6 to CO₂, indicating high activity of the pentose phosphate pathway. Enzymes of the Entner-Doudoroff pathway were not detected in bacteroids, but very low activities of sucrose synthase and phosphofructokinase were demonstrated. Although metabolism of sugars by B. japonicum bacteroids was clearly demonstrated, the rate of sugar uptake was only 1/30 to 1/50 the rate of succinate uptake. The overall results support the view that, although bacteroids metabolize sugars, the rates are very low and are inadequate to support nitrogenase.     

Ion and water shifts produced by ammonium chloride in high K and low K red cells

The effect of ammonium chloride on the cellular Na⁺, K⁺ and water has been examined in human and horse (high K), cow (medium K) and cat (low K) red cells. It was found that high K red cells, especially those of the horse, gained water an Na⁺, whereas the net movement of K⁺ was negligible. There was a correlation between the increase of cellular Na⁺ concentration and of the packed red cell volume. In contrast, the packed cell volume of low K red cells increased slightly or not at all, and Na⁺ ions leaked out from the cells. The high K cells had a lower Cl^? concentration and higher buffer capacity than the low K cells. The results obtained with the medium K (cow) cells usually lay between those of the other two cell types. In all the cases both the plasma and cell pH decreased resulting from the addition of ammonium chloride. The mechanism of movements of water and Na⁺ ions in high K cells remained unsolved, but the response of low K cells to ammonium chloride was near that of a cation exchange resin.     

Attachment of Lactobacillus casei strain GG to human colon carcinoma cell line Caco-2: comparison with other dairy strains

The degree of adhesion of Lactobacillus casei strain GG to human Caco-2 cell line was investigated. Assessment of adhesion was compared to the adhesion of enterotoxigenic human Escherichia coli strain H 10407 and enterotoxigenic bovine E. coli strain B44 (non-adhesive). Freeze-dried Lactobacillus GG or samples from dairy products had medium to strong binding to the Caco-2 cell line. Lactobacillus acidophilus (NCFB 1748) and L. bulgaricus showed no adhesion to the cell line while four tested Bifidobacterium strains had no or very weak adhesion to the Caco-2 cell line.     

Phytoplankton primary production in a eutrophic cooling water pond

The seasonal variation of phytoplankton photosynthesis was measured with ¹⁴C-method in a warmed ice-free pond in central Finland. Simultaneously with in situ measurements the photosynthesis was also measured in an incubator with different water temperatures and constant light (ca. 16 W m^–2). The total annual photosynthesis was 57.2 C m^–2 a^–1. The portion of the winter and spring production of the annual photosynthesis was 18.4%, that of the autumn production ws 17.4%. Thus 64.3% of the total annual phytoplankton photosynthesis occurred in the three summer months. The range of the daily integrated photosynthesis per unit area was 1.9—563 mg C m^–2d^–1. The photosynthetic rate per unit chlorophyll a varied in situ from 0.94 to 33.1 mg C (mg chl. a)^–1 d^–1. The highest value was measured in the beginning of July and the lowest in mid-January. The photosynthetic rate increased in situ exponentially with increasing water temperature. In the incubator the highest photosynthetic rate values were also found in July and August (at+20 °C) when the phytoplankton population was increasing and the minimum values occurred after every diatom maximum both in spring and autumn. Light was a limiting factor for photosynthesis from September to Mid-January, low water temperature was a limiting factor from late January through May. The efficiency of the photosynthesis varied between 0.1 and 0.7% of P.A.R. According to the incubator experiments the Q₁₀ values for the photosynthesis were 2.45 and 2.44 for the winter population between 1 and 10° C and for the summer population between 5 and 15° C, respectively, but the Q₁₀ values decrease at the higher temperatures. The main effect of the warm effluents on the yearly photosynthesis was the increase of production in spring months due to the lack of ice cover. However, the increase of total annual phytoplankton photosynthesis was only ca. 10–15%, because the water temperature was during the spring months below 10° C.     

The Sec15 protein responds to the function of the GTP binding protein, Sec4, to control vesicular traffic in yeast

SEC15 function is required at a late stage of the yeast secretory pathway. Duplication of the gene encoding the ras-like, GTP-binding protein, Sec4, can suppress the partial loss of function resulting from the sec15-l mutation, but cannot suppress disruption of sec15. Analysis of the SEC15 gene predicts a hydrophilic protein product of 105 kD. Anti-Sec15 antibody recognizes a protein of 116-kD apparent molecular mass which is associated with a microsomal fraction of yeast in a strongly pH dependent fashion. Overproduction of Sec15 protein interferes with the secretory pathway, resulting in the formation of a cluster of secretory vesicles, and a patch of Sec15 protein revealed by immunofluorescence. The sec4-8 and sec2-4l mutations, but not mutations in other SEC genes, prevent formation of the Sec15 protein patch. We propose that Sec15 protein responds to the function of the Sec4 protein to control vesicular traffic.