Analysis of an Arabidopsis thaliana protein family, structurally related to cytochromes b561 and potentially involved in catecholamine biochemistry in plants

Cytochromes b561 (cyts b561) constitute a family of eukaryotic membrane proteins, catalysing ascorbate (Asc)-mediated trans-membrane electron transport, and hence likely involved in Asc regeneration. A class of proteins (DoH-CB) has been identified in plants and animals, containing the cyt b561 electron-transport domain (CB), combined with the catecholamine-binding regulatory domain of dopamine-beta-hydroxylase (DoH). A mammalian DoH-CB protein was previously reported to function as a cell-derived growth factor receptor (SDR2). We have performed an in silico analysis on DoH-CB proteins from Arabidopsis thaliana and demonstrate that structural features of both CB and DoH domains are well conserved. The combination of both domains may have evolved from a functional interaction between a cyt b561 and a DoH-containing protein, illustrating the so-called "Rosetta Stone" evolutionary principle, and this hypothesis is supported by sequence comparisons. DoH-CB proteins form a newly identified group of proteins, likely to play a key role in catecholamine action in plants. It is suggested that these proteins may function as trans-membrane electron shuttles, possibly regulated by catecholamines. The role and action of catecholamines in plants is poorly documented, but it is clear that they are involved in many aspects of growth and development. Whether the DoH-CB proteins functionally interact with Asc, as is the case for cyts b561, remains to be determined.     

Two β-tubulin genes,TUB1 and TUB8, of Arabidopsis exhibit largely nonoverlapping patterns of expression

Chimeric reporter genes were used to investigate the patterns of expression of two -tubulin genes, TUB1 and TUB8, in Arabidopsis thaliana. The TUB1 chimeric gene was preferentially expressed in epidermal and cortical cells of primary roots, whereas the TUB8 chimeric gene was preferentially expressed in the endodermal and phloem cells of primary roots and in the vascular tissues of leaves, stems, and flowers of transgenic plants.     

5个毛果杨PtrZFP基因的鉴定和表达分析

ZFP转录因子是植物中的一类具有指环结构域的转录因子。从毛果杨中鉴定出5条ZFP基因（命名为PtrZFP1-5）,对其特性和表达模式进行了分析,以期初步了解这些基因是否能对胁迫做出应答。对PtrZFP1-5基因进行生物学分析,进一步利用qRT-PCR技术分析NaCl、PEG₆₀₀₀和ABA胁迫处理后毛果杨根、茎和叶中5条基因的表达情况。PtrZFP1-5基因编码蛋白氨基酸残基数为258~338 aa,编码蛋白的分子量为27.7~37.3 kDa,理论等电点为4.87~8.61,5个基因不均等的分布在毛果杨基因组的3条染色体上。qRT-PCR结果显示,0.2 mol·L^-1 NaCl、15%（w/v）PEG6000和100 μmol·L^-1 ABA胁迫处理后,5个PtrZFP基因在毛果杨根、茎和叶中的表达模式明显不同。PtrZFP1基因在3种胁迫后毛果杨中均被明显的上调表达;PtrZFP2基因在盐、渗透和ABA胁迫处理后,叶中的表达都明显被抑制;PtrZFP3基因受到干旱胁迫时在根中的响应最为明显;而叶和茎中,表达量在大部分胁迫的大部分时间点无明显改变。PtrZFP4基因也能在根和茎中对干旱胁迫做出明显应答。PtrZFP5基因在经受盐和ABA胁迫后,在叶中的表达受到明显抑制。PtrZFP1-5这5个基因至少能在一种器官中对一种胁迫处理做出应答,但参与的胁迫应答类型和机制可能不同。     

Tissue and cellular phosphorus storage during development of phosphorus toxicity in Hakea prostrata (Proteaceae)

Storage of phosphorus (P) in stem tissue is important in Mediterranean Proteaceae, because proteoid root growth and P uptake is greatest during winter, whereas shoot growth occurs mostly in summer. This has prompted the present investigation of the P distribution amongst roots, stems, and leaves of Hakea prostrata R.Br. (Proteaceae) when grown in nutrient solutions at ten P-supply rates. Glasshouse experiments were carried out during both winter and summer months. For plants grown in the low-P range (0, 0.3, 1.2, 3.0, or 6.0 micromol d(-1)) the root [P] was > stem and leaf [P]. In contrast, leaf [P] > stem and root [P] for plants grown in the high-P range (6.0, 30, 60, 150, or 300 micromol P d(-1)). At the highest P-supply rates, the capacity for P storage in stems and roots appears to have been exceeded, and leaf [P] thereafter increased dramatically to approximately 10 mg P g(-1) dry mass. This high leaf [P] was coincident with foliar symptoms of P toxicity which were similar to those described for many other species, including non-Proteaceae. The published values (tissue [P]) at which P toxicity occurs in a range of species are summarized. X-ray microanalysis of frozen, full-hydrated leaves revealed that the [P] in vacuoles of epidermal, palisade and bundle-sheath cells were in the mM range when plants were grown at low P-supply, even though very low leaf [P] was measured in bulk leaf samples. At higher P-supply rates, P accumulated in vacuoles of palisade cells which were associated with decreased photosynthetic rates.     

Tissue-specific expression of a gene encoding a cell wall-localized lipid transfer protein from Arabidopsis.

Nonspecific lipid transfer proteins (LTPs) from plants are characterized by their ability to stimulate phospholipid transfer between membranes in vitro. However, because these proteins are generally located outside of the plasma membrane, it is unlikely that they have a similar role in vivo. As a step toward identifying the function of these proteins, one of several LTP genes from Arabidoposis has been cloned and the expression pattern of the gene has been examined by analysis of the tissue specificity of beta-glucuronidase (GUS) activity in transgenic plants containing LTP promoter-GUS fusions and by in situ mRNA localization. The LTP1 promoter was active early in development in protoderm cells of embryos, vascular tissues, lignified tips of cotyledons, shoot meristem, and stipules. In adult plants, the gene was expressed in epidermal cells of young leaves and the stem. In flowers, expression was observed in the epidermis of all developing influorescence and flower organ primordia, the epidermis of the siliques and the outer ovule wall, the stigma, petal tips, and floral nectaries of mature flowers, and the petal/sepal abscission zone of mature siliques. The presence of GUS activity in guard cells, lateral roots, pollen grains, leaf vascular tissue, and internal cells of stipules and nectaries was not confirmed by in situ hybridizations, supporting previous observations that suggest that the reporter gene is subject to artifactual expression. These results are consistent with a role for the LTP1 gene product in some aspect of secretion or deposition of lipophilic substances in the cell walls of expanding epidermal cells and certain secretory tissues. The LTP1 promoter region contained sequences homologous to putative regulatory elements of genes in the phenylpropanoid biosynthetic pathway, suggesting that the expression of the LTP1 gene may be regulated by the same or similar mechanisms as genes in the phenylpropanoid pathway.     

A wound-inducible tobacco peroxidase gene expresses preferentially in the vascular system

A tobacco peroxidase gene tpoxN1 was reported to be expressed within 1 h after wounding in leaves [Hiraga et al. (2000a) Plant Cell Physiol. 41: 165]. We describe here further results on the wound-induced tpoxN1 expression. The quick tpoxN1 induction occurred preferentially in stems and petioles, but was negligible in leaf blades even 8 h after wounding. Induced GUS activity was also detected rapidly after wounding in the stem of transgenic tobacco plants carrying the tpoxN1 promoter::GUS fusion gene, localized mainly in the vascular systems where it was maintained this level for 14 d or more. Strong GUS activity was also found in the petiole and veinlet as well as the epidermal tissue in the stem. Treatment of known inducers for wound-responsive genes such as jasmonate, 1-aminocyclopropane-1-carboxylate, spermine, phytohormones and other stress treatments did not enhance wound-induced tpoxN1 gene expression in stems at all, but rather repressed it in some cases. Studies using metabolic inhibitors suggested that phosphorylation and dephosphorylation of proteins together with de novo protein synthesis are likely to be involved in the wound-induced tpoxN1 expression as well as some other wound-responsive genes. Thus, tpoxN1 is a unique wound-inducible and possible wound-healing gene which is rapidly expressed being maintained for a long time in veins via an unknown wound-signaling pathway(s).     

Expression of the Fusarium resistance gene I-2 colocalizes with the site of fungal containment

The tomato resistance gene I-2 is one of at least six members of a gene family that are expressed at low levels in the roots, stems and leaves of young tomato plants. Plants transformed with constructs containing a functional I-2 promoter fused to the beta-glucuronidase (GUS) reporter gene were used in detailed expression studies. Highest GUS activity was found in stems of young tomato plants. Histochemical analysis revealed that the I-2 promoter drives expression of the reporter gene in vascular tissue of fruits, leaves, stems and mature roots. In younger roots, expression was most abundant at the base of lateral root primordia. Microscopical analysis of young tomato plants revealed expression in tissue surrounding the xylem vessels. We show that in resistant plants, fungal growth into this region of the vascular tissue is prevented, suggesting a correlation with the I-2-mediated resistance response.     

pH-induced alteration and oxidative destruction of heme in purified chromaffin granule cytochrome b(561): implications for the oxidative stress in catecholaminergic neurons

The transmembrane hemoprotein, cytochrome b(561) (b(561)), in the neuroendocrine secretory vesicles is shown to shuttle electrons from the cytosolic ascorbate (Asc) to the intravesicular matrix to provide reducing equivalents for the dopamine beta-monooxygenase (DbetaM) reaction. Intravesicular Asc may also play a role in relieving catecholamine-induced oxidative stress in catecholaminergic neurons. In the present study, we have examined the alteration of purified oxidized b(561) (b(561,ox)) under mild alkaline conditions to probe the structural and functional characteristics of the protein, using UV-vis and EPR spectroscopic and kinetic techniques. Our results show that low spin heme in oxidized b(561) (b(561,ox)) readily transforms to an altered high spin form and then slowly to an Asc nonreducible form, in a pH-, temperature-, and time-dependent manner, which can be described by single-exponential rate equations, A(t) = A(o)(1- e (-kt)) and A(t) = A(o)e(-kt), respectively. More than half of the Asc nonreducible altered b(561) could be converted back to the native b(561) by pH adjustment followed by dithionite reduction, suggesting the reversibility of the process. The heme center of the transformed Asc nonreducible protein is completely bleached instantaneously by dithionite in the presence of atmospheric oxygen, which appears to be mediated by molecular oxygen and/or hydrogen peroxide. These results demonstrate that the heme centers of the protein are susceptible to the pH-induced alteration and oxidative destruction, raising some questions regarding the proposed one alkaline labile, two-heme model of b(561) [Tsubaki, M.; Nakayama, M.; Okuyama, E.; Ichikawa, Y. (1997) J. Biol. Chem. 272, 23206-23210]. The pH-induced alteration and the destruction of heme under oxidative conditions may play a significant role in the amplification of oxidative stress in catecholaminergic neurons.