LeProT1, a transporter for proline, glycine betaine, and gamma-amino butyric acid in tomato pollen

During maturation, pollen undergoes a period of dehydration accompanied by the accumulation of compatible solutes. Solute import across the pollen plasma membrane, which occurs via proteinaceous transporters, is required to support pollen development and also for subsequent germination and pollen tube growth. Analysis of the free amino acid composition of various tissues in tomato revealed that the proline content in flowers was 60 times higher than in any other organ analyzed. Within the floral organs, proline was confined predominantly to pollen, where it represented >70% of total free amino acids. Uptake experiments demonstrated that mature as well as germinated pollen rapidly take up proline. To identify proline transporters in tomato pollen, we isolated genes homologous to Arabidopsis proline transporters. LeProT1 was specifically expressed both in mature and germinating pollen, as demonstrated by RNA in situ hybridization. Expression in a yeast mutant demonstrated that LeProT1 transports proline and gamma-amino butyric acid with low affinity and glycine betaine with high affinity. Direct uptake and competition studies demonstrate that LeProT1 constitutes a general transporter for compatible solutes.     

文冠果可孕花与不孕花发育过程的比较研究简

利用半薄切片和透射电镜技术对文冠果可孕花和不孕花的发育过程进行观察和比较。结果显示：(1)小孢子发育初期,两种类型花花药形态无明显差别;小孢子发育双核期,可孕花花药内壁纤维层细胞壁带状加厚,无唇细胞形成。而不孕花花药同侧两个花粉囊之间唇细胞正在分化;小孢子发育成熟期,不孕花花药唇细胞完全形成;散粉期,不孕花花药开裂呈双心形,而可孕花花药则不能开裂散粉。(2)可孕花雌蕊子房内有两室,柱头细胞排列紧密,柱头逐渐发育成圆球形,周围密布乳突细胞,具中空花柱道;不孕花雌蕊柱头停止发育,无中空花柱道,子房室变小,胚囊发育退化。(3)不孕花花药绒毡层中含大量蛋白体,小泡以及乌氏体等细胞器,发育后期绒毡层解体。而可孕花花药绒毡层中细胞器和营养物质积累均较少,发育后期绒毡层解体不完全。(4)可孕花花药内花粉粒细胞壁连续无萌发孔,细胞内含物较少。不孕花花药内花粉出现3个向内凹陷的萌发孔,且花粉内含有大量造粉质体和脂类物质。     

Amino acid transport by prosthecae of Asticcacaulis biprosthecum: evidence for a broad-range transport system

Prosthecae purified from cells of Asticcaulis biprosthecum possess active transport systems that transport all 20 amino acids tested. Using ascorbate-reduced phenazine methosulphate in the presence of oxygen, all 20 amino acids are accumulated against a concentration gradient by isolated prosthecae. Results of experiments testing the inhibition of transport of one amino acid by another, and of experiments testing the exchange of exogenous amino acids with those preloaded in prosthecae, along with characteristics of mutants defective in amino acid transport, suggest the presence in prosthecae of three amino acid transport systems. One, the general or G system, transports at least 18 of the 20 amino acids tested. Another system, referred to as the proline or P system, transports seven amino acids (including proline) that are also transported by the G system. The third system transports only glutamate and aspartate, and is referred to as the acidic amino acid transport system or A system.     

The amino acid transport systems of the autotrophically grown green alga Chlorella

The kinetic analysis of l-amino acid uptake by the green alga Chlorella revealed at least seven different uptake systems to be present in cells grown autotrophically with nitrate as nitrogen source. There is a ‘general system’ which transports most neutral and acidic amino acids, a system for short-chain neutral amino acids including proline, a system for basic amino acids including histidine, a special system for acidic amino acids, and specific systems for methionine, glutamine and threonine. The ‘general system’ is possibly the same as that which can be stimulated by incubation of cells in glucose plus ammonium (Sauer, N. (1984) Planta 161, 425–431). The incubation of Chlorella in glucose induces the increased synthesis of six amino acid uptake systems, namely the above-mentioned system for short-chain neutral amino acids, a threonine system, a methionine system, and a glutamine system. These results indicate that the uptake of l-amino acids by the green alga Chlorella is as complex as in other free-living organisms such as bacteria or yeast. The small number of amino acid uptake systems found in cells of higher plants, i.e. two or three, seems therefore to be a consequence of integration of the cells in a tissue supplying a relatively constant environment, and not a consequence of autotrophic growth on mineral carbon and mineral nitrogen.     

Low and high affinity amino acid H+-cotransporters for cellular import of neutral and charged amino acids

Amides and acidic amino acids represent the major long distance transport forms of organic nitrogen. Six amino acid permeases (AAPs) from Arabidopsis mediating transport of a wide spectrum of amino acids were isolated. AAPs are distantly related to plasma membrane amino acid transport systems N and A and to vesicular transporters such as VGAT from mammals. A detailed comparison of the properties by electrophysiology after heterologous expression in Xenopus oocytes shows that, although capable of recognizing and transporting a wide spectrum of amino acids, individual AAPs differ with respect to specificity. Apparent substrate affinities are influenced by structure and net charge and vary by three orders of magnitude. AAPs mediate cotransport of neutral amino acids with one proton. Uncharged forms of acidic and basic amino acids are cotransported with one proton. Since all AAPs are differentially expressed, different tissues may be supplied with a different spectrum of amino acids. AAP3 and AAP5 are the only transporters mediating efficient transport of the basic amino acids. In vivo competition shows that the capability to transport basic amino acids in planta might be overruled by excess amides and acidic amino acids in the apoplasm. With the exception of AAP6, AAPs do not recognize aspartate; only AAP6 has an affinity for aspartate in the physiologically relevant range. This property is due to an overall higher affinity of AAP6 for neutral and acidic amino acids. Thus AAP6 may serve a different role either in cooperating with the lower affinity systems to acquire amino acids in the low concentration range, as a system responsible for aspartate transport or as an uptake system from the xylem. In agreement, a yeast mutant deficient in acidic amino acid uptake at low aspartate concentrations was complemented only by AAP6. Taken together, the AAPs transport neutral, acidic and cationic amino acids, including the major transport forms, i.e. glutamine, asparagine and glutamate. Increasing proton concentrations strongly activate transport of amino acids. Thus the actual apoplasmic concentration of amino acids and the pH will determine what is transported in vivo, i.e. major amino acids such as glutamine, asparagine, and glutamate will be mobilized preferentially.     

ANT1, an aromatic and neutral amino acid transporter in Arabidopsis

A new amino acid transporter was identified from the Arabidopsis expressed sequence tag cDNAs by expressing the cDNA in a yeast amino acid transport mutant. Transport analysis of the expressed protein in yeast showed that it transports aromatic and neutral amino acids, as well as arginine. This transporter (ANT1, aromatic and neutral transporter) also transports indole-3-acetic acid and 2,4-dichlorophenoxyacetic acid. The cDNA is 1.6 kb in length with an open reading frame that codes for a protein with 432 amino acids and a calculated molecular mass of 50 kD. Hydropathy analysis showed ANT1 is an integral membrane protein with 11 putative membrane-spanning domains. Southern analysis and a BLAST search of the Arabidopsis genome database suggests that ANT1 is part of a small gene family containing at least five members. Phylogenetic comparisons with other known amino acid transporters in plants suggests that ANT1 represents a new class of amino acid transporter. RNA gel-blot analysis showed that this transporter is expressed in all organs with highest abundance in flowers and cauline leaves.     

Molecular cloning of mouse amino acid transport system B0, a neutral amino acid transporter related to Hartnup disorder

Resorption of amino acids in kidney and intestine is mediated by transporters, which prefer groups of amino acids with similar physico-chemical properties. It is generally assumed that most neutral amino acids are transported across the apical membrane of epithelial cells by system B(0). Here we have characterized a novel member of the Na(+)-dependent neurotransmitter transporter family (B(0)AT1) isolated from mouse kidney, which shows all properties of system B(0). Flux experiments showed that the transporter is Na(+)-dependent, electrogenic, and actively transports most neutral amino acids but not anionic or cationic amino acids. Superfusion of mB(0)AT1-expressing oocytes with neutral amino acids generated inward currents, which were proportional to the fluxes observed with labeled amino acids. In situ hybridization showed strong expression in intestinal microvilli and in the proximal tubule of the kidney. Expression of mouse B(0)AT1 was restricted to kidney, intestine, and skin. It is generally assumed that mutations of the system B(0) transporter underlie autosomal recessive Hartnup disorder. In support of this notion mB(0)AT1 is located on mouse chromosome 13 in a region syntenic to human chromosome 5p15, the locus of Hartnup disorder. Thus, the human homologue of this transporter is an excellent functional and positional candidate for Hartnup disorder.     

Cloning of an amino acid transporter with functional characteristics and tissue expression pattern identical to that of system A

We report here on the cloning and functional characterization of the protein responsible for the system A amino acid transport activity that is known to be expressed in most mammalian tissues. This transporter, designated ATA2 for amino acid transporter A2, was cloned from rat skeletal muscle. It is distinct from the neuron-specific glutamine transporter (GlnT/ATA1). Rat ATA2 consists of 504 amino acids and bears significant homology to GlnT/ATA1 and system N (SN1). ATA2-specific mRNA is ubiquitously expressed in rat tissues. When expressed in mammalian cells, ATA2 mediates Na(+)-dependent transport of alpha-(methylamino)isobutyric acid, a specific model substrate for system A. The transporter is specific for neutral amino acids. It is pH-sensitive and Li(+)-intolerant. The Na(+):amino acid stoichiometry is 1:1. When expressed in Xenopus laevis oocytes, transport of neutral amino acids via ATA2 is associated with inward currents. The substrate-induced current is Na(+)-dependent and pH-sensitive. The amino acid transport system A is particularly known for its adaptive and hormonal regulation, and therefore the successful cloning of the protein responsible for this transport activity represents a significant step toward understanding the function and expression of this transporter in various physiological and pathological states.     

An investigation of the role of the anther tapetum during microspore development using genetic cell ablation

The effects on anther development of a fusion of the Arabidopsis anther-specific apg gene promoter to a ribonuclease (barnase) in transgenic tobacco plants were examined. Contrary to expectations, viable pollen grains were produced by these plants despite the demonstration that ribonuclease expression in the microspores and tapetum caused targeted cell ablation. Transformed plants were reduced in male fertility due to ablation of a proportion of pollen dependent on apg-barnase locus number. Plants were otherwise phenotypically normal and fully female fertile, confirming the anther-specific nature of the apg promoter. In microspores inheriting an apg-barnase locus following meiosis, loss of cell viability, as judged by fluorescein diacetate staining, occurred during mid to late microspore development. Microspores not inheriting a transgene went on to mature into viable pollen grains. Premature degeneration of the tapetum was also observed as a result of apg-barnase expression, but this did not appear to disrupt the subsequent microspore and pollen developmental programmes. This was substantiated by observations of microspore development in plants in which the tapetum was rescued from ablation by crossing in a second transgene encoding a tapetum-specific inhibitor of the ribonuclease. It was determined that tapetum cell disruption occurs at the early to mid uninucleate microspore stage in apg-barnase transformants. The data presented show that after this point in microspore development the tapetum is no longer essential for the production of viable pollen in tobacco.     

Free amino acids of Nicotiana alata anthers during development in vivo

The variation of free amino acids in anthers and pollen of Nicotiana alata Link et Otto has been examined during pollen development in vivo. The purpose was to find clues for optimizing an in vitro medium for cultivation of haploid plantlets from N. alata pollen. The quantitatively most important amino acids were proline, glutamic acid/glutamine, alanine and aspartic acid/asparagine. These exhibited similar patterns of variation during pollen development: first maximum (0.5 to 1.7 μmol per flower) at mitosis, then decrease during early binucleate stage (0.6 to 2.0 m mol per flower). Other amino acids were found in much smaller quantities (max 0.25 μmol per flower).     

A trial to determine D-amino acids in tissue proteins of mice

Summary Eleven neutral amino acids and two acidic amino acids in tissue proteins of mouse kidney, liver and brain were analyzed for the presence of D-enantiomers. The proteins were hydrolyzed with HCl for 6 h. Of the thirteen amino acids investigated, the presence of D-enantiomers of serine, alanine, proline, aspartate and glutamate (including asparagine and glutamine) was shown in the hydrolysates. However, the level of D-enantiomers were not significantly higher than that of 6-h hydrolysate of serum albumin examined as a control protein. Serum albumin was shown to contain no D-amino acid residues.     

An anther-specific lipid transfer protein gene in sugar beet: its expression is strongly reduced in male-sterile plants with Owen cytoplasm

Differential screening of a sugar beet (normal cytoplasm line TK81-O) cDNA library made with anther tissues of various stages resulted in the isolation of a clone (#74-29) that hybridized to flower bud RNA but did not hybridize to RNA of vegetative organs. The clone contained an open reading frame (ORF) (designated bvLTP-1 ) that encoded a putative lipid transfer protein. We also identified a second copy ( bvLTP-2 ) of the gene. In situ hybridization analysis demonstrated that expression of bvLTP-1 was confined to the tapetal cells of the anthers at the young microspore stage. Flower bud RNA was prepared from male-sterile sugar beet with Owen cytoplasm and fertility-restored plants and used for northern hybridization with the bvLTP-1 probe. Interestingly, bvLTP-1 was found to be expressed in the flower buds from the restored plants producing 30% or more stainable pollen, but not in the flower buds from completely sterile or poorly fertility-restored plants. These results lead us to suppose that the expression of bvLTP-1 is strongly reduced in the tapetum in response to mitochondrial dysfunction and subsequent physiological changes caused by the Owen cytoplasm.     

水稻雄性半不育突变体的细胞学观察

TP-2是由水稻品种台北309自然突变的雄性半不育突变体。解剖小花后观察发现,突变体花药细长,干瘪,白色透明状,雌蕊正常。花粉活力检测结果表明:突变体水稻平均花粉粒活力率为57.599%,1个花粉囊里的花粉粒平均有436粒;正常材料台北309水稻平均花粉活力率为94.177%,1个花粉囊里的花粉粒有798粒。组织切片观察发现:突变体水稻从小孢子母细胞发育到减数分裂结束,和正常株相比较在形态上无显著差异,小孢子形成初期出现异常,绒毡层快速消融,小孢子在其发育过程中因得不到营养不能正常发育,产生的小孢子干瘪,呈不规则状,同时部分小孢子产生破裂消融现象,绒毡层不能正常降解可能是导致TP-2水稻小孢子异常发育的主要原因。通过以上观察,对进一步揭示TP-2突变体的不育机制提供了基本资料,对该材料的组配奠定了基础。     

Cloning and expression of amino acid transporters from broad bean

This work describes the isolation of a full-length (VfAAP2) and three partial amino acid transporter genes (VfAAPa, VfAAPb, VfAAPc) from broad bean (Vicia faba L.). The function of VfAAP2 was tested by heterologous expression in a yeast mutant deficient in proline uptake. VfAAP2 mediates proton-dependent proline uptake with an apparent K_m of about 1 mM. Analysis of substrate specificity by competition experiments showed that aromatic amino acids, neutral aliphatic acids and L-citrulline are the best competitors, whereas basic amino acids do not compete with proline. Northern analysis indicates that all VfAAPs exhibit different patterns of expression. VfAAP2 is most strongly expressed in the stem and at a lower level in sink leaves and pods. VfAAPa, VfAAPb and VfAAPc are most strongly expressed in the flowers, but their expression in the other organs varies.     

小盐芥小孢子发生和雄配子体发育研究

在显微水平上研究了小盐芥的小孢子发生及雄配子体发育过程,以及不同阶段与花蕾外部形态的相关性.本实验报道的小孢子发生及雄配子体发育的研究结果表明:雄蕊为四强雄蕊,每个花药具4个花粉囊.小孢子母细胞减数分裂属同时型,小孢子在四分体中的排列方式属四面体型.成熟花粉粒属3-细胞型,有3个萌发沟.花粉囊壁发育属双子叶型,由4层细胞构成——表皮、药室内壁、中层和绒毡层.绒毡层为腺质绒毡层.植株花蕾肉眼可见时,雄性孢原细胞开始分化.花蕾露白即蕾长1.1~1.7 mm时,形成成熟的雄配子体,即3-细胞花粉粒.     

AAP1 transports uncharged amino acids into roots of Arabidopsis

Amino acids are available to plants in some soils in significant amounts, and plants frequently make use of these nitrogen sources. The goal of this study was to identify transporters involved in the uptake of amino acids into root cells. Based on the fact that high concentrations of amino acids inhibit plant growth, we hypothesized that mutants tolerating toxic levels of amino acids might be deficient in the uptake of amino acids from the environment. To test this hypothesis, we employed a forward genetic screen for Arabidopsis thaliana mutants tolerating toxic concentrations of amino acids in the media. We identified an Arabidopsis mutant that is deficient in the amino acid permease 1 (AAP1, At1g58360) and resistant to 10 mm phenylalanine and a range of other amino acids. The transporter was localized to the plasma membrane of root epidermal cells, root hairs, and throughout the root tip of Arabidopsis. Feeding experiments with [(14)C]-labeled neutral, acidic and basic amino acids showed significantly reduced uptake of amino acids in the mutant, underscoring that increased tolerance of aap1 to high levels of amino acids is coupled with reduced uptake by the root. The growth and uptake studies identified glutamate, histidine and neutral amino acids, including phenylalanine, as physiological substrates for AAP1, whereas aspartate, lysine and arginine are not. We also demonstrate that AAP1 imports amino acids into root cells when these are supplied at ecologically relevant concentrations. Together, our data indicate an important role of AAP1 for efficient use of nitrogen sources present in the rhizosphere.     

西瓜小孢子囊发育及雄配子体发生的观察

西瓜(Citrullus lanatus)小孢子囊的孢原细胞出现在雄花原基出现后4—6天,孢原细胞数目推测只有一列;初生造孢细胞经过2—3次分裂,形成次生造孢细胞。开花前7—8天,小孢子囊发育健全,小孢子母细胞进入减数分裂期。同一花药不同花粉囊相同一药室,花粉母细胞减数分裂和小孢子的发育,并不是高度同步的。绒毡层为异型细胞,腺质绒毡层。雄配子体的发育开始于开花前6—7天,充分成熟的西瓜花粉已分裂为三细胞花粉。