Keiko Kashiwagi

Multiple polyamine transport systems on the vacuolar membrane in yeast

We recently identified a gene (TPO1, YLL028w) that encodes a polyamine transport protein on the vacuolar membrane in yeast [Tomitori, Kashiwagi, Sakata, Kakinuma and Igarashi (1999) J. Biol. Chem. 274, 3265-3267]. Because the existence of one or more other genes for a polyamine transport protein on the vacuolar membrane was expected, we searched sequence databases for homologues of the protein encoded by TPO1. Membrane proteins encoded by the open reading frames YGR138c (TPO2), YPR156c (TPO3) and YOR273c (TPO4) were postulated to be polyamine transporters and, indeed, were subsequently shown to be polyamine transport proteins on the vacuolar membrane. Cells overexpressing these genes were resistant to polyamine toxicity and showed an increase in polyamine uptake activity and polyamine content in vacuoles. Furthermore, cells in which these genes were disrupted showed an increased sensitivity to polyamine toxicity and a decrease in polyamine uptake activity and polyamine content in vacuoles. Resistance to polyamine toxicity in cells overexpressing the genes was overcome by bafilomycin A(1), an inhibitor of the vacuolar H(+)-ATPase. Among the four polyamine transporters, those encoded by TPO2 and TPO3 were specific for spermine, whereas those encoded by TPO1 and TPO4 recognized spermidine and spermine. These results suggest that polyamine content in the cytoplasm of yeast is elaborately regulated by several polyamine transport systems in vacuoles. Furthermore, it was shown that Glu-207, Glu-324 (or Glu-323) and Glu-574 of TPO1 protein were important for the transport activity.

Identification of a gene for a polyamine transport protein in yeast.

Properties of a membrane protein encoded byYLL028w were examined using yeast cells transformed with the gene. The transformed cells became resistant to polyamine toxicity, and the resistance was overcome by bafilomycin A1, an inhibitor of vacuolar H+-ATPase. Although spermine uptake activity of the transformed cells was almost the same as that of wild type cells, the uptake activity of vacuolar membrane vesicles from the transformed cells was higher than that from wild type cells. The transformed cells became resistant to MGBG (methylglyoxal bis(guanylhydrazone)) and paraquat, but not Ni2+ and Co2+, suggesting that the protein encoded byYLL028w is a transport protein specific for polyamines. When the YLL028w gene was disrupted by inserting theHIS3 gene, the cells became sensitive to polyamines, and spermine uptake activity of the vacuolar membrane vesicles decreased significantly. The accumulated spermine in YLL028wgene-disrupted cells decreased greatly compared with that in wild type cells. The results indicate that a membrane protein encoded byYLL028w (TPO1) is a polyamine transport protein on the vacuolar membrane.

Properties of a polyamine transporter regulated by antizyme

The regulation of polyamine transport by antizyme, a protein that is involved in the rapid degradation of ornithine decarboxylase (ODC), was studied in FM3A mouse cells overproducing ODC. Both artificial (Z1) and natural antizymes not only inhibited polyamine uptake but also stimulated polyamine excretion. The properties of the polyamine transporter regulated by antizyme were characterized. The uptake of radiolabelled polyamines was inhibited by excess acetylpolyamines and a protonophore, CCCP (carbonyl cyanide m-chlorophenylhydrazone), whereas the excretion of radiolabelled polyamines was stimulated by unlabelled polyamines, acetylpolyamines and CCCP in the medium. Furthermore, it is shown that polyamines and acetylpolyamines are excreted from cells. On the basis of the results, it is discussed how antizyme regulates polyamine transport negatively.

Identification of the Putrescine Recognition Site on Polyamine Transport Protein PotE

The PotE protein can catalyze both uptake and excretion of putrescine. The K m values of putrescine for uptake and excretion are 1.8 and 73 μm, respectively. Uptake of putrescine is dependent on the membrane potential, whereas excretion involves putrescine-ornithine antiporter activity. Amino acids involved in both activities were identified using mutated PotE proteins. It was found that Cys62, Trp201, Trp292, and Tyr425 were strongly involved in both activities, and that Tyr92, Cys210, Cys285, and Cys286 were moderately involved in the activities. Mutations of Tyr78, Trp90, and Trp422 mainly affected uptake activity, and the K m values for putrescine uptake by these PotE mutants increased greatly, indicating that these amino acids are involved in the high affinity uptake of putrescine by PotE. Mutations of Lys301 and Tyr308 mainly affected excretion activity (putrescine-ornithine antiporter activity), and excretion by these mutants was not stimulated by ornithine, indicating that these amino acids are involved in the recognition of ornithine. It was found that the putrescine and ornithine recognition site on PotE is located at the cytoplasmic surface and the vestibule of the pore consisting of 12 transmembrane segments. Based on the results of competition experiments with various putrescine analogues and the disulfide cross-linking of PotE between cytoplasmic loops and the COOH terminus, a model of the putrescine recognition site on PotE consisting of the identified amino acids is presented.

Polyamine Stimulation of the Synthesis of Oligopeptide-binding Protein (OppA) INVOLVEMENT OF A STRUCTURAL CHANGE OF THE SHINE-DALGARNO SEQUENCE AND THE INITIATION CODON AUG IN OppA mRNA

We previously suggested that the degree of polyamine stimulation of oligopeptide-binding protein (OppA) synthesis is dependent on the secondary structure and position of the Shine-Dalgarno (SD) sequence of OppA mRNA. To study the structural change of OppA mRNA induced by polyamines and polyamine stimulation of initiation complex formation, four different 130-mer OppA mRNAs containing the initiation region were synthesized in vitro.The structural change of these mRNAs induced by polyamines was examined by measuring their sensitivity to RNase T1, specific for single-stranded RNA, and RNase V1, which recognizes double-stranded or stacked RNA. In parallel, the effect of spermidine on mRNA-dependent fMet-tRNA binding to ribosomes was examined. Our results indicate that the secondary structure of the SD sequence and initiation codon AUG is important for the efficiency of initiation complex formation and that spermidine relaxes the structure of the SD sequence and the initiation codon AUG. The existence of a GC-rich double-stranded region close to the SD sequence is important for spermidine stimulation of fMet-tRNA binding to ribosomes. Spermidine apparently binds to this GC-rich stem and causes a structural change of the SD sequence and the initiation codon, facilitating an interaction with 30 S ribosomal subunits.

Formation of a Complex Containing ATP, Mg2+, and Spermine STRUCTURAL EVIDENCE AND BIOLOGICAL SIGNIFICANCE

The conformation of ATP in the presence of Mg2+ and/or spermine was studied by 31P and 1H NMR, to clarify how polyamines interact with ATP. Spermine predominantly interacted with the β- and γ-phosphates of ATP in the presence of Mg2+. A conformational change of the β- and γ-phosphate of ATP with spermine could not be observed in the absence of Mg2+ by 31P NMR. It was found by1H NMR that the conformation of adenosine moiety of ATP was not influenced significantly by spermine. The binding of Mg2+ to ATP was slightly inhibited by spermine andvice versa. The results indicate that the binding sites of Mg2+ and spermine on ATP only partially overlap. The PotA protein, an ATP-dependent enzyme, was used as a model system to study the biological role of the ATP-Mg2+-spermine complex. The ATPase activity of PotA was greatly enhanced by spermine. Double reciprocal plots at several concentrations of spermine as an activator indicate that spermine interacts with ATP, but not with PotA. The activity of protein kinase A was also stimulated about 2-fold by spermine. The results suggest that a ternary complex of ATP-Mg2+-spermine may play an important role in some ATP-dependent reactions in vivo and in the physiological effects of endogenous polyamines.

Gene structure and chromosomal localization of mouse S-adenosylmethionine decarboxylase.

The structure of the mouse S-adenosylmethionine decarboxylase (AdoMetDC) gene has been determined. The mouse gene (AMD1) consisted of eight exons and seven introns, similar to the rat AdoMetDC gene, and was mapped to chromosome 10. The characteristics of AMD1 gene were as follows: (1) The region of the promoter necessary for maximal transcriptional activity was located about 400 nucleotides upstream of the transcriptional initiation point, and contained a TATA box and two GC boxes. The transcriptional activity of the promoter was nearly equal to that of the SV40 promoter. (2) Two polyadenylation signals for transcription were observed, and the larger AdoMetDC mRNA, which is the dominant form of mRNA, corresponded to mRNA that is generated using the second polyadenylation signal. (3) Using stable transfectants, we confirmed that the upstream open reading frame (uORF) in the 5-untranslated region (5-UTR) of AdoMetDC mRNA functioned as a negative regulatory element. Lower concentrations of polyamines affect both stimulation and inhibition of AdoMetDC synthesis, through the uORF in the mRNA, than affect general protein synthesis.