Tuber physiology and properties of starch from tubers of transgenic potato plants with altered plastidic adenylate transporter activity.

We showed recently that antisense plants with decreased activity of the plastidic ATP/ADP-transporter protein exhibit drastically reduced levels of starch and a decreased amylose/amylopectin ratio, whereas sense plants with increased activity of the transporter possessed more starch than wild-type plants and an increased amylose/amylopectin ratio. In this paper we investigate the effect of altered plastidic ATP/ADP-transporter protein expression on primary metabolism and granule morphology in more detail. Tuber tissues from antisense and sense plants exhibited substantially increased respiratory activity compared with the wild type. Tubers from antisense plants contained markedly increased levels of free sugars, UDP-Glc, and hexose phosphates, whereas phosphoenolpyruvate, isocitrate, ATP, ADP, AMP, UTP, UDP, and inorganic pyrophosphate levels were slightly decreased. In contrast, tubers from sense plants revealed a slight increase in adenine and uridine nucleotides and in the levels of inorganic pyrophosphate, whereas no significant changes in the levels of soluble sugars and metabolites were observed. Antisense tubers contained 50% reduced levels of ADP-Glc, whereas sense tubers contained up to 2-fold increased levels of this sole precursor for starch biosynthesis. Microscopic examination of starch grain morphology revealed that the size of starch grains from antisense tubers was substantially smaller (50%) compared with the wild type. The large starch grains from sense tubers appeared of a more angular morphology, which differed to the more ellipsoid shape of wild type grains. The results suggest a close interaction between plastidial adenylate transport and starch biosynthesis, indicating that ADP-Glc pyrophosphorylase is ATP-limited in vivo and that changes in ADP-Glc concentration determine starch yield, as well as granule morphology. Possible factors linking starch synthesis and respiration are discussed.

Expression of a plastidic ATP/ADP transporter gene in Escherichia coli leads to a functional adenine nucleotide transport system in the bacterial cytoplasmic membrane.

Recently, a second type of eucaryotic adenine nucleotide transporter located in the inner envelope membrane of higher plants has been identified at the molecular level (Neuhaus, H. E., Thom, E., Möhlmann, T., Steup, M., and Kampfenkel, K. (1997) Plant J. 11, 73-82). Here we have analyzed the biochemical properties of this ATP/ADP transporter from Arabidopsis thaliana (AATP1, At). This analysis was carried out by expressing a cDNA encoding this carrier as a histidine-tagged chimeric protein heterologously in Escherichia coli. Isopropyl-1-thio-beta-D-galactopyranoside (IPTG)-induced E. coli cells were able to import radioactively labeled [alpha-32P]ATP. Uninduced E. coli cells did not import [alpha-32P]ATP. Further control experiments revealed that IPTG induction did not promote import of other phosphorylated or unphosphorylated metabolites into the bacterial cell indicating the specificity of [alpha-32P]ATP transport. [alpha-32P]ATP uptake into induced E. coli cells was linear with time for several minutes allowing for determination of kinetic constants. The apparent Km for ATP was 17 microM which is close to values reported on the authentic protein in isolated plastids. ADP was a strong competitive inhibitor of -alpha-32P-ATP uptake (Ki ADP 3.6 microM). Other metabolites like AMP, ADP glucose, UTP, UDP, NAD, and NADP did not influence [alpha-32P]ATP uptake. IPTG-induced E. coli cells preloaded with [alpha-32P]ATP exported radioactively labeled adenylates after exogenous addition of unlabeled ATP or ADP indicating a counter exchange mechanism of transport. The biochemical properties of the heterologously expressed AATP1 gene product demonstrated that the protein is functionally integrated in the cytoplasmic membrane of E. coli. This is the first report of the functional expression of a plant membrane protein in E. coli leading to new transport properties across the cytoplasmic membrane. The functional integration of a plant membrane protein in the cytoplasmic membrane of E. coli offers new possibilities for future studies of the structural and mechanistic properties of this transporter. Since IPTG induction allowed synthesis of a 67-kDa protein in E. coli, which was subsequently specifically enriched by metal-chelate chromatography, this procaryotic heterologous expression system might provide a suitable system for overproduction of membrane proteins of eucaryotic origin in the near future.