CONICET | Buscador de Institutos y Recursos Humanos

Phytomonas cells (Phytomonas Jma) isolated from the latex of Jatropha macrantha were assayed for amino acid, hexose and polyamine transport. Results showed high transport rates for glucose and fructose (193 and 128 pmol min1 107 cells, respectively) and lower, but significant rates, for proline, arginine, cysteine and glutamate (between 1.7 and 5.8 pmol min1 107 cells). Minor transport activities were observed for serine, glycine and aspartate (<1 pmol min1 107 cells). Amino acid transport processes do not seem to be regulated by starvation or during the growth phases. Polyamine transport was also evaluated showing a clear preference for spermidine over putrescine (3.4 and 0.4 pmol min1 107 cells, respectively). This work represents the first report on metabolite transport in phytomonads. phytomonads. phytomonads. by starvation or during the growth phases. Polyamine transport was also evaluated showing a clear preference for spermidine over putrescine (3.4 and 0.4 pmol min1 107 cells, respectively). This work represents the first report on metabolite transport in phytomonads. phytomonads. phytomonads. by starvation or during the growth phases. Polyamine transport was also evaluated showing a clear preference for spermidine over putrescine (3.4 and 0.4 pmol min1 107 cells, respectively). This work represents the first report on metabolite transport in phytomonads. phytomonads. phytomonads. were observed for serine, glycine and aspartate (<1 pmol min1 107 cells). Amino acid transport processes do not seem to be regulated by starvation or during the growth phases. Polyamine transport was also evaluated showing a clear preference for spermidine over putrescine (3.4 and 0.4 pmol min1 107 cells, respectively). This work represents the first report on metabolite transport in phytomonads. phytomonads. phytomonads. by starvation or during the growth phases. Polyamine transport was also evaluated showing a clear preference for spermidine over putrescine (3.4 and 0.4 pmol min1 107 cells, respectively). This work represents the first report on metabolite transport in phytomonads. phytomonads. phytomonads. by starvation or during the growth phases. Polyamine transport was also evaluated showing a clear preference for spermidine over putrescine (3.4 and 0.4 pmol min1 107 cells, respectively). This work represents the first report on metabolite transport in phytomonads. phytomonads. phytomonads. were observed for serine, glycine and aspartate (<1 pmol min1 107 cells). Amino acid transport processes do not seem to be regulated by starvation or during the growth phases. Polyamine transport was also evaluated showing a clear preference for spermidine over putrescine (3.4 and 0.4 pmol min1 107 cells, respectively). This work represents the first report on metabolite transport in phytomonads. phytomonads. phytomonads. by starvation or during the growth phases. Polyamine transport was also evaluated showing a clear preference for spermidine over putrescine (3.4 and 0.4 pmol min1 107 cells, respectively). This work represents the first report on metabolite transport in phytomonads. phytomonads. phytomonads. by starvation or during the growth phases. Polyamine transport was also evaluated showing a clear preference for spermidine over putrescine (3.4 and 0.4 pmol min1 107 cells, respectively). This work represents the first report on metabolite transport in phytomonads. phytomonads. phytomonads. significant rates, for proline, arginine, cysteine and glutamate (between 1.7 and 5.8 pmol min1 107 cells). Minor transport activities were observed for serine, glycine and aspartate (<1 pmol min1 107 cells). Amino acid transport processes do not seem to be regulated by starvation or during the growth phases. Polyamine transport was also evaluated showing a clear preference for spermidine over putrescine (3.4 and 0.4 pmol min1 107 cells, respectively). This work represents the first report on metabolite transport in phytomonads. phytomonads. phytomonads. by starvation or during the growth phases. Polyamine transport was also evaluated showing a clear preference for spermidine over putrescine (3.4 and 0.4 pmol min1 107 cells, respectively). This work represents the first report on metabolite transport in phytomonads. phytomonads. phytomonads. by starvation or during the growth phases. Polyamine transport was also evaluated showing a clear preference for spermidine over putrescine (3.4 and 0.4 pmol min1 107 cells, respectively). This work represents the first report on metabolite transport in phytomonads. phytomonads. phytomonads. were observed for serine, glycine and aspartate (<1 pmol min1 107 cells). Amino acid transport processes do not seem to be regulated by starvation or during the growth phases. Polyamine transport was also evaluated showing a clear preference for spermidine over putrescine (3.4 and 0.4 pmol min1 107 cells, respectively). This work represents the first report on metabolite transport in phytomonads. phytomonads. phytomonads. by starvation or during the growth phases. Polyamine transport was also evaluated showing a clear preference for spermidine over putrescine (3.4 and 0.4 pmol min1 107 cells, respectively). This work represents the first report on metabolite transport in phytomonads. phytomonads. phytomonads. by starvation or during the growth phases. Polyamine transport was also evaluated showing a clear preference for spermidine over putrescine (3.4 and 0.4 pmol min1 107 cells, respectively). This work represents the first report on metabolite transport in phytomonads. phytomonads. phytomonads. were observed for serine, glycine and aspartate (<1 pmol min1 107 cells). Amino acid transport processes do not seem to be regulated by starvation or during the growth phases. Polyamine transport was also evaluated showing a clear preference for spermidine over putrescine (3.4 and 0.4 pmol min1 107 cells, respectively). This work represents the first report on metabolite transport in phytomonads. phytomonads. phytomonads. by starvation or during the growth phases. Polyamine transport was also evaluated showing a clear preference for spermidine over putrescine (3.4 and 0.4 pmol min1 107 cells, respectively). This work represents the first report on metabolite transport in phytomonads. phytomonads. phytomonads. by starvation or during the growth phases. Polyamine transport was also evaluated showing a clear preference for spermidine over putrescine (3.4 and 0.4 pmol min1 107 cells, respectively). This work represents the first report on metabolite transport in phytomonads. phytomonads. phytomonads. significant rates, for proline, arginine, cysteine and glutamate (between 1.7 and 5.8 pmol min1 107 cells). Minor transport activities were observed for serine, glycine and aspartate (<1 pmol min1 107 cells). Amino acid transport processes do not seem to be regulated by starvation or during the growth phases. Polyamine transport was also evaluated showing a clear preference for spermidine over putrescine (3.4 and 0.4 pmol min1 107 cells, respectively). This work represents the first report on metabolite transport in phytomonads. phytomonads. phytomonads. by starvation or during the growth phases. Polyamine transport was also evaluated showing a clear preference for spermidine over putrescine (3.4 and 0.4 pmol min1 107 cells, respectively). This work represents the first report on metabolite transport in phytomonads. phytomonads. phytomonads. by starvation or during the growth phases. Polyamine transport was also evaluated showing a clear preference for spermidine over putrescine (3.4 and 0.4 pmol min1 107 cells, respectively). This work represents the first report on metabolite transport in phytomonads. phytomonads. phytomonads. were observed for serine, glycine and aspartate (<1 pmol min1 107 cells). Amino acid transport processes do not seem to be regulated by starvation or during the growth phases. Polyamine transport was also evaluated showing a clear preference for spermidine over putrescine (3.4 and 0.4 pmol min1 107 cells, respectively). This work represents the first report on metabolite transport in phytomonads. phytomonads. phytomonads. by starvation or during the growth phases. Polyamine transport was also evaluated showing a clear preference for spermidine over putrescine (3.4 and 0.4 pmol min1 107 cells, respectively). This work represents the first report on metabolite transport in phytomonads. phytomonads. phytomonads. by starvation or during the growth phases. Polyamine transport was also evaluated showing a clear preference for spermidine over putrescine (3.4 and 0.4 pmol min1 107 cells, respectively). This work represents the first report on metabolite transport in phytomonads. phytomonads. phytomonads. were observed for serine, glycine and aspartate (<1 pmol min1 107 cells). Amino acid transport processes do not seem to be regulated by starvation or during the growth phases. Polyamine transport was also evaluated showing a clear preference for spermidine over putrescine (3.4 and 0.4 pmol min1 107 cells, respectively). This work represents the first report on metabolite transport in phytomonads. phytomonads. phytomonads. by starvation or during the growth phases. Polyamine transport was also evaluated showing a clear preference for spermidine over putrescine (3.4 and 0.4 pmol min1 107 cells, respectively). This work represents the first report on metabolite transport in phytomonads. phytomonads. phytomonads. by starvation or during the growth phases. Polyamine transport was also evaluated showing a clear preference for spermidine over putrescine (3.4 and 0.4 pmol min1 107 cells, respectively). This work represents the first report on metabolite transport in phytomonads. phytomonads. phytomonads. transport. Results showed high transport rates for glucose and fructose (193 and 128 pmol min1 107 cells, respectively) and lower, but significant rates, for proline, arginine, cysteine and glutamate (between 1.7 and 5.8 pmol min1 107 cells). Minor transport activities were observed for serine, glycine and aspartate (<1 pmol min1 107 cells). Amino acid transport processes do not seem to be regulated by starvation or during the growth phases. Polyamine transport was also evaluated showing a clear preference for spermidine over putrescine (3.4 and 0.4 pmol min1 107 cells, respectively). This work represents the first report on metabolite transport in phytomonads. phytomonads. phytomonads. by starvation or during the growth phases. Polyamine transport was also evaluated showing a clear preference for spermidine over putrescine (3.4 and 0.4 pmol min1 107 cells, respectively). This work represents the first report on metabolite transport in phytomonads. phytomonads. phytomonads. by starvation or during the growth phases. Polyamine transport was also evaluated showing a clear preference for spermidine over putrescine (3.4 and 0.4 pmol min1 107 cells, respectively). This work represents the first report on metabolite transport in phytomonads. phytomonads. phytomonads. were observed for serine, glycine and aspartate (<1 pmol min1 107 cells). Amino acid transport processes do not seem to be regulated by starvation or during the growth phases. Polyamine transport was also evaluated showing a clear preference for spermidine over putrescine (3.4 and 0.4 pmol min1 107 cells, respectively). This work represents the first report on metabolite transport in phytomonads. phytomonads. phytomonads. by starvation or during the growth phases. Polyamine transport was also evaluated showing a clear preference for spermidine over putrescine (3.4 and 0.4 pmol min1 107 cells, respectively). This work represents the first report on metabolite transport in phytomonads. phytomonads. phytomonads. by starvation or during the growth phases. Polyamine transport was also evaluated showing a clear preference for spermidine over putrescine (3.4 and 0.4 pmol min1 107 cells, respectively). This work represents the first report on metabolite transport in phytomonads. phytomonads. phytomonads. were observed for serine, glycine and aspartate (<1 pmol min1 107 cells). Amino acid transport processes do not seem to be regulated by starvation or during the growth phases. Polyamine transport was also evaluated showing a clear preference for spermidine over putrescine (3.4 and 0.4 pmol min1 107 cells, respectively). This work represents the first report on metabolite transport in phytomonads. phytomonads. phytomonads. by starvation or during the growth phases. Polyamine transport was also evaluated showing a clear preference for spermidine over putrescine (3.4 and 0.4 pmol min1 107 cells, respectively). This work represents the first report on metabolite transport in phytomonads. phytomonads. phytomonads. by starvation or during the growth phases. Polyamine transport was also evaluated showing a clear preference for spermidine over putrescine (3.4 and 0.4 pmol min1 107 cells, respectively). This work represents the first report on metabolite transport in phytomonads. phytomonads. phytomonads. significant rates, for proline, arginine, cysteine and glutamate (between 1.7 and 5.8 pmol min1 107 cells). Minor transport activities were observed for serine, glycine and aspartate (<1 pmol min1 107 cells). Amino acid transport processes do not seem to be regulated by starvation or during the growth phases. Polyamine transport was also evaluated showing a clear preference for spermidine over putrescine (3.4 and 0.4 pmol min1 107 cells, respectively). This work represents the first report on metabolite transport in phytomonads. phytomonads. phytomonads. by starvation or during the growth phases. Polyamine transport was also evaluated showing a clear preference for spermidine over putrescine (3.4 and 0.4 pmol min1 107 cells, respectively). This work represents the first report on metabolite transport in phytomonads. phytomonads. phytomonads. by starvation or during the growth phases. Polyamine transport was also evaluated showing a clear preference for spermidine over putrescine (3.4 and 0.4 pmol min1 107 cells, respectively). This work represents the first report on metabolite transport in phytomonads. phytomonads. phytomonads. were observed for serine, glycine and aspartate (<1 pmol min1 107 cells). Amino acid transport processes do not seem to be regulated by starvation or during the growth phases. Polyamine transport was also evaluated showing a clear preference for spermidine over putrescine (3.4 and 0.4 pmol min1 107 cells, respectively). This work represents the first report on metabolite transport in phytomonads. phytomonads. phytomonads. by starvation or during the growth phases. Polyamine transport was also evaluated showing a clear preference for spermidine over putrescine (3.4 and 0.4 pmol min1 107 cells, respectively). This work represents the first report on metabolite transport in phytomonads. phytomonads. phytomonads. by starvation or during the growth phases. Polyamine transport was also evaluated showing a clear preference for spermidine over putrescine (3.4 and 0.4 pmol min1 107 cells, respectively). This work represents the first report on metabolite transport in phytomonads. phytomonads. phytomonads. were observed for serine, glycine and aspartate (<1 pmol min1 107 cells). Amino acid transport processes do not seem to be regulated by starvation or during the growth phases. Polyamine transport was also evaluated showing a clear preference for spermidine over putrescine (3.4 and 0.4 pmol min1 107 cells, respectively). This work represents the first report on metabolite transport in phytomonads. phytomonads. phytomonads. by starvation or during the growth phases. Polyamine transport was also evaluated showing a clear preference for spermidine over putrescine (3.4 and 0.4 pmol min1 107 cells, respectively). This work represents the first report on metabolite transport in phytomonads. phytomonads. phytomonads. by starvation or during the growth phases. Polyamine transport was also evaluated showing a clear preference for spermidine over putrescine (3.4 and 0.4 pmol min1 107 cells, respectively). This work represents the first report on metabolite transport in phytomonads. phytomonads. phytomonads. significant rates, for proline, arginine, cysteine and glutamate (between 1.7 and 5.8 pmol min1 107 cells). Minor transport activities were observed for serine, glycine and aspartate (<1 pmol min1 107 cells). Amino acid transport processes do not seem to be regulated by starvation or during the growth phases. Polyamine transport was also evaluated showing a clear preference for spermidine over putrescine (3.4 and 0.4 pmol min1 107 cells, respectively). This work represents the first report on metabolite transport in phytomonads. phytomonads. phytomonads. by starvation or during the growth phases. Polyamine transport was also evaluated showing a clear preference for spermidine over putrescine (3.4 and 0.4 pmol min1 107 cells, respectively). This work represents the first report on metabolite transport in phytomonads. phytomonads. phytomonads. by starvation or during the growth phases. Polyamine transport was also evaluated showing a clear preference for spermidine over putrescine (3.4 and 0.4 pmol min1 107 cells, respectively). This work represents the first report on metabolite transport in phytomonads. phytomonads. phytomonads. were observed for serine, glycine and aspartate (<1 pmol min1 107 cells). Amino acid transport processes do not seem to be regulated by starvation or during the growth phases. Polyamine transport was also evaluated showing a clear preference for spermidine over putrescine (3.4 and 0.4 pmol min1 107 cells, respectively). This work represents the first report on metabolite transport in phytomonads. phytomonads. phytomonads. by starvation or during the growth phases. Polyamine transport was also evaluated showing a clear preference for spermidine over putrescine (3.4 and 0.4 pmol min1 107 cells, respectively). This work represents the first report on metabolite transport in phytomonads. phytomonads. phytomonads. by starvation or during the growth phases. Polyamine transport was also evaluated showing a clear preference for spermidine over putrescine (3.4 and 0.4 pmol min1 107 cells, respectively). This work represents the first report on metabolite transport in phytomonads. phytomonads. phytomonads. were observed for serine, glycine and aspartate (<1 pmol min1 107 cells). Amino acid transport processes do not seem to be regulated by starvation or during the growth phases. Polyamine transport was also evaluated showing a clear preference for spermidine over putrescine (3.4 and 0.4 pmol min1 107 cells, respectively). This work represents the first report on metabolite transport in phytomonads. phytomonads. phytomonads. by starvation or during the growth phases. Polyamine transport was also evaluated showing a clear preference for spermidine over putrescine (3.4 and 0.4 pmol min1 107 cells, respectively). This work represents the first report on metabolite transport in phytomonads. phytomonads. phytomonads. by starvation or during the growth phases. Polyamine transport was also evaluated showing a clear preference for spermidine over putrescine (3.4 and 0.4 pmol min1 107 cells, respectively). This work represents the first report on metabolite transport in phytomonads. phytomonads. phytomonads. transport. Results showed high transport rates for glucose and fructose (193 and 128 pmol min1 107 cells, respectively) and lower, but significant rates, for proline, arginine, cysteine and glutamate (between 1.7 and 5.8 pmol min1 107 cells). Minor transport activities were observed for serine, glycine and aspartate (<1 pmol min1 107 cells). Amino acid transport processes do not seem to be regulated by starvation or during the growth phases. Polyamine transport was also evaluated showing a clear preference for spermidine over putrescine (3.4 and 0.4 pmol min1 107 cells, respectively). This work represents the first report on metabolite transport in phytomonads. phytomonads. phytomonads. by starvation or during the growth phases. Polyamine transport was also evaluated showing a clear preference for spermidine over putrescine (3.4 and 0.4 pmol min1 107 cells, respectively). This work represents the first report on metabolite transport in phytomonads. phytomonads. phytomonads. by starvation or during the growth phases. Polyamine transport was also evaluated showing a clear preference for spermidine over putrescine (3.4 and 0.4 pmol min1 107 cells, respectively). This work represents the first report on metabolite transport in phytomonads. phytomonads. phytomonads. were observed for serine, glycine and aspartate (<1 pmol min1 107 cells). Amino acid transport processes do not seem to be regulated by starvation or during the growth phases. Polyamine transport was also evaluated showing a clear preference for spermidine over putrescine (3.4 and 0.4 pmol min1 107 cells, respectively). This work represents the first report on metabolite transport in phytomonads. phytomonads. phytomonads. by starvation or during the growth phases. Polyamine transport was also evaluated showing a clear preference for spermidine over putrescine (3.4 and 0.4 pmol min1 107 cells, respectively). This work represents the first report on metabolite transport in phytomonads. phytomonads. phytomonads. by starvation or during the growth phases. Polyamine transport was also evaluated showing a clear preference for spermidine over putrescine (3.4 and 0.4 pmol min1 107 cells, respectively). This work represents the first report on metabolite transport in phytomonads. phytomonads. phytomonads. were observed for serine, glycine and aspartate (<1 pmol min1 107 cells). Amino acid transport processes do not seem to be regulated by starvation or during the growth phases. Polyamine transport was also evaluated showing a clear preference for spermidine over putrescine (3.4 and 0.4 pmol min1 107 cells, respectively). This work represents the first report on metabolite transport in phytomonads. phytomonads. phytomonads. by starvation or during the growth phases. Polyamine transport was also evaluated showing a clear preference for spermidine over putrescine (3.4 and 0.4 pmol min1 107 cells, respectively). This work represents the first report on metabolite transport in phytomonads. phytomonads. phytomonads. by starvation or during the growth phases. Polyamine transport was also evaluated showing a clear preference for spermidine over putrescine (3.4 and 0.4 pmol min1 107 cells, respectively). This work represents the first report on metabolite transport in phytomonads. phytomonads. phytomonads. significant rates, for proline, arginine, cysteine and glutamate (between 1.7 and 5.8 pmol min1 107 cells). Minor transport activities were observed for serine, glycine and aspartate (<1 pmol min1 107 cells). Amino acid transport processes do not seem to be regulated by starvation or during the growth phases. Polyamine transport was also evaluated showing a clear preference for spermidine over putrescine (3.4 and 0.4 pmol min1 107 cells, respectively). This work represents the first report on metabolite transport in phytomonads. phytomonads. phytomonads. by starvation or during the growth phases. Polyamine transport was also evaluated showing a clear preference for spermidine over putrescine (3.4 and 0.4 pmol min1 107 cells, respectively). This work represents the first report on metabolite transport in phytomonads. phytomonads. phytomonads. by starvation or during the growth phases. Polyamine transport was also evaluated showing a clear preference for spermidine over putrescine (3.4 and 0.4 pmol min1 107 cells, respectively). This work represents the first report on metabolite transport in phytomonads. phytomonads. phytomonads. were observed for serine, glycine and aspartate (<1 pmol min1 107 cells). Amino acid transport processes do not seem to be regulated by starvation or during the growth phases. Polyamine transport was also evaluated showing a clear preference for spermidine over putrescine (3.4 and 0.4 pmol min1 107 cells, respectively). This work represents the first report on metabolite transport in phytomonads. phytomonads. phytomonads. by starvation or during the growth phases. Polyamine transport was also evaluated showing a clear preference for spermidine over putrescine (3.4 and 0.4 pmol min1 107 cells, respectively). This work represents the first report on metabolite transport in phytomonads. phytomonads. phytomonads. by starvation or during the growth phases. Polyamine transport was also evaluated showing a clear preference for spermidine over putrescine (3.4 and 0.4 pmol min1 107 cells, respectively). This work represents the first report on metabolite transport in phytomonads. phytomonads. phytomonads. were observed for serine, glycine and aspartate (<1 pmol min1 107 cells). Amino acid transport processes do not seem to be regulated by starvation or during the growth phases. Polyamine transport was also evaluated showing a clear preference for spermidine over putrescine (3.4 and 0.4 pmol min1 107 cells, respectively). This work represents the first report on metabolite transport in phytomonads. phytomonads. phytomonads. by starvation or during the growth phases. Polyamine transport was also evaluated showing a clear preference for spermidine over putrescine (3.4 and 0.4 pmol min1 107 cells, respectively). This work represents the first report on metabolite transport in phytomonads. phytomonads. phytomonads. by starvation or during the growth phases. Polyamine transport was also evaluated showing a clear preference for spermidine over putrescine (3.4 and 0.4 pmol min1 107 cells, respectively). This work represents the first report on metabolite transport in phytomonads. phytomonads. phytomonads. significant rates, for proline, arginine, cysteine and glutamate (between 1.7 and 5.8 pmol min1 107 cells). Minor transport activities were observed for serine, glycine and aspartate (<1 pmol min1 107 cells). Amino acid transport processes do not seem to be regulated by starvation or during the growth phases. Polyamine transport was also evaluated showing a clear preference for spermidine over putrescine (3.4 and 0.4 pmol min1 107 cells, respectively). This work represents the first report on metabolite transport in phytomonads. phytomonads. phytomonads. by starvation or during the growth phases. Polyamine transport was also evaluated showing a clear preference for spermidine over putrescine (3.4 and 0.4 pmol min1 107 cells, respectively). This work represents the first report on metabolite transport in phytomonads. phytomonads. phytomonads. by starvation or during the growth phases. Polyamine transport was also evaluated showing a clear preference for spermidine over putrescine (3.4 and 0.4 pmol min1 107 cells, respectively). This work represents the first report on metabolite transport in phytomonads. phytomonads. phytomonads. were observed for serine, glycine and aspartate (<1 pmol min1 107 cells). Amino acid transport processes do not seem to be regulated by starvation or during the growth phases. Polyamine transport was also evaluated showing a clear preference for spermidine over putrescine (3.4 and 0.4 pmol min1 107 cells, respectively). This work represents the first report on metabolite transport in phytomonads. phytomonads. phytomonads. by starvation or during the growth phases. Polyamine transport was also evaluated showing a clear preference for spermidine over putrescine (3.4 and 0.4 pmol min1 107 cells, respectively). This work represents the first report on metabolite transport in phytomonads. phytomonads. phytomonads. by starvation or during the growth phases. Polyamine transport was also evaluated showing a clear preference for spermidine over putrescine (3.4 and 0.4 pmol min1 107 cells, respectively). This work represents the first report on metabolite transport in phytomonads. phytomonads. phytomonads. were observed for serine, glycine and aspartate (<1 pmol min1 107 cells). Amino acid transport processes do not seem to be regulated by starvation or during the growth phases. Polyamine transport was also evaluated showing a clear preference for spermidine over putrescine (3.4 and 0.4 pmol min1 107 cells, respectively). This work represents the first report on metabolite transport in phytomonads. phytomonads. phytomonads. by starvation or during the growth phases. Polyamine transport was also evaluated showing a clear preference for spermidine over putrescine (3.4 and 0.4 pmol min1 107 cells, respectively). This work represents the first report on metabolite transport in phytomonads. phytomonads. phytomonads. by starvation or during the growth phases. Polyamine transport was also evaluated showing a clear preference for spermidine over putrescine (3.4 and 0.4 pmol min1 107 cells, respectively). This work represents the first report on metabolite transport in phytomonads. phytomonads. phytomonads. cells (Phytomonas Jma) isolated from the latex of Jatropha macrantha were assayed for amino acid, hexose and polyamine transport. Results showed high transport rates for glucose and fructose (193 and 128 pmol min1 107 cells, respectively) and lower, but significant rates, for proline, arginine, cysteine and glutamate (between 1.7 and 5.8 pmol min1 107 cells). Minor transport activities were observed for serine, glycine and aspartate (<1 pmol min1 107 cells). Amino acid transport processes do not seem to be regulated by starvation or during the growth phases. Polyamine transport was also evaluated showing a clear preference for spermidine over putrescine (3.4 and 0.4 pmol min1 107 cells, respectively). This work represents the first report on metabolite transport in phytomonads. phytomonads. phytomonads. by starvation or during the growth phases. Polyamine transport was also evaluated showing a clear preference for spermidine over putrescine (3.4 and 0.4 pmol min1 107 cells, respectively). This work represents the first report on metabolite transport in phytomonads. phytomonads. phytomonads. by starvation or during the growth phases. Polyamine transport was also evaluated showing a clear preference for spermidine over putrescine (3.4 and 0.4 pmol min1 107 cells, respectively). This work represents the first report on metabolite transport in phytomonads. phytomonads. phytomonads. were observed for serine, glycine and aspartate (<1 pmol min1 107 cells). Amino acid transport processes do not seem to be regulated by starvation or during the growth phases. Polyamine transport was also evaluated showing a clear preference for spermidine over putrescine (3.4 and 0.4 pmol min1 107 cells, respectively). This work represents the first report on metabolite transport in phytomonads. phytomonads. phytomonads. by starvation or during the growth phases. Polyamine transport was also evaluated showing a clear preference for spermidine over putrescine (3.4 and 0.4 pmol min1 107 cells, respectively). This work represents the first report on metabolite transport in phytomonads. phytomonads. phytomonads. by starvation or during the growth phases. Polyamine transport was also evaluated showing a clear preference for spermidine over putrescine (3.4 and 0.4 pmol min1 107 cells, respectively). This work represents the first report on metabolite transport in phytomonads. phytomonads. phytomonads. were observed for serine, glycine and aspartate (<1 pmol min1 107 cells). Amino acid transport processes do not seem to be regulated by starvation or during the growth phases. Polyamine transport was also evaluated showing a clear preference for spermidine over putrescine (3.4 and 0.4 pmol min1 107 cells, respectively). This work represents the first report on metabolite transpo