The Expression Pattern of the Tonoplast Intrinsic Protein gamma-TIP in Arabidopsis thaliana Is Correlated with Cell Enlargement

The vacuolar membrane (tonoplast) contains an abundant intrinsic protein with six membrane-spanning domains that is encoded by a small gene family. Different isoforms of tonoplast intrinsic protein (TIP) are expressed in different tissues or as a result of specific signals. Using promoter-β-glucuronidase (GUS) fusions and in situ hybridization, we have examined the expression of γ-TIP in Arabidopsis thaliana. GUS staining of plants transformed with promoter-GUS fusions showed that γ-TIP gene expression is high in recently formed tissues of young roots. In the shoot, γ-TIP gene expression was highest in the vascular bundles of stems and petioles, as well as in the stipules and in the receptacle of the flower. No GUS activity was detected in root or shoot meristems or in older tissues, suggesting temporal control of γ-TIP gene expression associated with cell elongation and/or differentiation. In situ hybridization carried out with whole seedlings confirmed that in root tips, γ-TIP mRNA was present only in the zone of cell elongation just behind the apical meristem. In seedling shoots, mRNA abundance was also found to be correlated with cell expansion. These results indicate that γ-TIP may be expressed primarily at the time when the large central vacuoles are being formed during cell enlargement.     

Molecular identification and expression of heat shock cognate 70 (HSC70) in the Pacific white shrimp Litopenaeus vannamei

Heat shock protein 70s (HSP70s) are fundamental chaperone proteins that are indispensable to most living organisms. In order to investigate the function of HSP70 and heat shock response in shrimp, a heat shock cognate (HSC70) gene of the white shrimp (Litopenaeus vannamei), containing a 1959-bp open reading frame, was cloned and characterized. The amino acid sequence, 71.5 kDa of molecular weight, shares 80-99.6% homology with 12 diverse species' HSP70s and HSC70s. In fact, some segments of the eukaryotic HSC70 sequence, such as ATP/GTP-binding site, cytoplasmic HSP70 C-terminal sequence, and GGMP/GAP repeats, are also found in the putative shrimp HSC70. Moreover, multi-tissue RT-PCR was performed to assay the basal expressions of HSC70 in the heart, gill, hepatopancreas, stomach, gut, and muscle. The results demonstrate that the basal expressions of HSC70 in theses organs are similar to that of beta-actin. Furthermore, quantitative real-time experiments showed that HSC70 was up-regulated in hepatopancreas (4.6-fold), stomach (5.9-fold), gut (2.6-fold), and muscle (3.5-fold) but not in the heart (1.7-fold) and gill (1.6-fold) after 2 h of heat shock. Nevertheless, the HSC70 was found to be highly expressed in the heart and gill following 6 h of heat shock. This suggests that HSC70 in white shrimp possess both short-term and long-term responses to heat shock stress, indicating this HSC70 may be a heat-dependent HSC70 member. Finally, we constructed an expression vector to generate HSC70 in Escherichia coli BL21, which displayed immune cross-reactivity with mouse HSP70 antibody. In conclusion, the identification and expression of white shrimp HSC70 gene present useful data for studying the molecular mechanism of heat shock response and the effect of heat shock proteins in shrimps' cytoprotection.     

Apical and lateral shoot apex-specific expression is conferred by promoter of the seed storage protein β-phaseolin gene

A previous analysis with deletion mutants of the native -phaseolin gene demonstrated that removal of a negative element 5 upstream of–107 permitted phaseolin expression in stem cortex and secondary root (Burowet al., 1992). Here we employed the -glucuronidase (GUS) reporter gene to visualize, by histochemical staining, the cell type-specificity of phaseolin expression in stem and root, and to understand further the spatial control of the -phaseolin gene. The 782 bp 5 upstream promoter and its deletion mutants were fused to the GUS gene, and these chimaeric genes were used to transform tobacco. Histochemical staining for GUS activity demonstrated that phaseolin promoters truncated downstream of –227 conferred cell-type specific expression in internal/external phloem and protoxylem of mature stem. Surprisingly, GUS staining was prominent in both apical and lateral shoot apices of plants that contain the full-length –782 promoter and mutant promoters deleted up to –64. GUS expression was extended to all cell types of shoot tips, including epidermis, cortex, vasculature, procambium and pith. Expression in vasculature of petioles was limited to plants with promoters truncated to –106 and –64. The current results are in agreement with our previous findings with the native phaseolin gene: that the major positive element (–295/–228) is sufficient for seed-specific late-temporal expression of the phaseolin gene. We conclude that the 5 upstream sequence of the -phaseolin gene directs spatially- and temporally-controlled gene expression in developing seeds during the reproductive phase, but also confers expression in shoot apices during the vegetative phase of plant development.     

Immunolocalization of cinnamyl alcohol dehydrogenase 2 (CAD 2) indicates a good correlation with cell-specific activity of CAD 2 promoter in transgenic poplar shoots

Cinnamyl alcohol dehydrogenase 2 (CAD 2) localization and the cell-specific activity of the eucalyptus CAD 2 promoter were investigated by CAD 2 immunogold localization and promoter β-glucuronidase (GUS) histochemistry in apical and mature parts of stable transformed poplar (Populus tremula × P. alba) stems. Both CAD 2 protein and GUS activity were found to be confined in the same types of cells in the shoot apices, particularly in the determined meristematic cells in leaf axils and shell zones, procambium and developing tracheids. Within mature stems, CAD 2 and GUS were also identified in cambium and in fully or partially lignified cells derived from it (young xylem, developing phloem fibres, chambered parenchyma cells around phloem). Additionally, GUS activity was found in the scale leaves of apical shoot buds and in the roots (namely in the procambium, cambium, phellogen, young xylem, pericycle) of transformed plants. By employing immunogold cytochemistry, CAD 2 was shown to be localized in the cytoplasm within cambial, ray and young xylem cells in stems, the gold particles being randomly attached to endoplasmic reticulum and Golgi-derived vesicles. These results support a crucial role for CAD 2 in lignification and indicate a new role for this enzyme in branching events within the shoot apex and during lateral root formation. Received: 24 April 1997 / Accepted: 17 July 1997     

Differential regulation of HSC70, HSP70, HSP90 alpha, and HSP90 beta mRNA expression by mitogen activation and heat shock in human lymphocytes

A subset of heat shock proteins, HSP90 alpha, HSP90 beta, and a member of the HSP70 family, HSC70, shows enhanced synthesis following mitogenic activation as well as heat shock in human peripheral blood mononuclear cells. In this study, we have examined expression of mRNA for these proteins, including the major 70-kDa heat shock protein, HSP70, in mononuclear cells following either heat shock or mitogenic activation with phytohemagglutinin (PHA), ionomycin, and the phorbol ester, tetradecanoyl phorbol acetate. The results demonstrate that the kinetics of mRNA expression of these four genes generally parallel the kinetics of enhanced protein synthesis seen following either heat shock or mitogen activation and provide clear evidence that mitogen-induced synthesis of HSC70 and HSP90 is due to increased mRNA levels and not simply to enhanced translation of preexisting mRNA. Although most previous studies have focused on cell cycle regulation of HSP70 mRNA, we found that HSP70 mRNA was only slightly and transiently induced by PHA activation, while HSC70 is the predominant 70-kDa heat shock protein homologue induced by mitogens. Similarly, HSP90 alpha appears more inducible by heat shock than mitogens while the opposite is true for HSP90 beta. These results suggest that, although HSP70 and HSC70 have been shown to contain similar promoter regions, additional regulatory mechanisms which result in differential expression to a given stimulus must exist. They clearly demonstrate that human lymphocytes are an important model system for determining mechanisms for regulation of heat shock protein synthesis in unstressed cells. Finally, based on kinetics of mRNA expression, the results are consistent with the hypothesis that HSC70 and HSP90 gene expression are driven by an IL-2/IL-2 receptor-dependent pathway in human T cells.     

Molecular identification and expression of heat shock cognate 70 (<Emphasis Type="Italic">HSC</Emphasis>70) in the pacific white shrimp <Emphasis Type="Italic">Litopenaeus vannamei</Emphasis>

Heat shock protein 70s (HSP70s) are fundamental chaperone proteins that are indispensable to most living organisms. In order to investigate the function of HSP70 and heat shock response in shrimp, a heat shock cognate (HSC70) gene of the white shrimp (Litopenaeus vannamei), containing a 1959-bp open reading frame, was cloned and characterized. The amino acid sequence, 71.5 kDa of molecular weight, shares 80–99.6% homology with 12 diverse species’ HSP70s and HSC70s. In fact, some segments of the eukaryotic HSC70 sequence, such as ATP/GTP-binding site, cytoplasmic HSP70 C-terminal sequence, and GGMP/GAP repeats, are also found in the putative shrimp HSC70. Moreover, multitissue RT-PCR was performed to assay the basal expressions of HSC70 in the heart, gill, hepatopancreas, stomach, gut, and muscle. The results demonstrate that the basal expressions of HSC70 in theses organs are similar to that of β-actin. Furthermore, quantitative real-time experiments showed that HSC70 was upregulated in hepatopancreas (4.6-fold), stomach (5.9-fold), gut (2.6-fold), and muscle (3.5-fold) but not in the heart (1.7-fold) and gill (1.6-fold) after 2 h of heat shock. Nevertheless, the HSC70 was found to be highly expressed in the heart and gill following 6 h of heat shock. This suggests that HSC70 in white shrimp possess both short-term and long-term responses to heat shock stress, indicating this HSC70 may be a heat-dependent HSC70 member. Finally, we constructed an expression vector to generate HSC70 in Escherichia coli BL21, which displayed immune cross-reactivity with mouse HSP70 antibody. In conclusion, the identification and expression of the white shrimp HSC70 gene present useful data for studying the molecular mechanism of heat shock response and the effect of heat shock proteins in shrimps’ cytoprotection. Published in Russian in Molekulyarnaya Biologiya, 2008, Vol. 42, No. 2, pp. 265–274. The text was submitted by the authors in English.     

Increased expression of co-chaperone HOP with HSP90 and HSC70 and complex formation in human colonic carcinoma

Co-chaperone HOP (also called stress-inducible protein 1) is a co-chaperone that interacts with the cytosolic 70-kDa heat shock protein (HSP70) and 90-kDa heat shock protein (HSP90) families using different tetratricopeptide repeat domains. HOP plays crucial roles in the productive folding of substrate proteins by controlling the chaperone activities of HSP70 and HSP90. Here, we examined the levels of HOP, HSC70 (cognate of HSP70, also called HSP73), and HSP90 in the tumor tissues from colon cancer patients, in comparison with the non-tumor tissues from the same patients. Expression level of HOP was significantly increased in the tumor tissues (68% of patients, n = 19). Levels of HSC70 and HSP90 were also increased in the tumor tissues (95% and 74% of patients, respectively), and the HOP level was highly correlated with those of HSP90 (r = 0.77, p < 0.001) and HSC70 (r = 0.68, p < 0.01). Immunoprecipitation experiments indicated that HOP complexes with HSC70 or HSP90 in the tumor tissues. These data are consistent with increased formation of co-chaperone complexes in colon tumor specimens compared to adjacent normal tissue and could reflect a role for HOP in this process.     

Quantitative RT-PCR analysis and immunohistochemical localization of HSP70 in sea bass Dicentrarchus labrax exposed to transport stress

In aquaculture, fish are exposed to stressful conditions, which cause an increased synthesis of heat shock proteins (HSPs) at the cellular level. In this work we considered the expression of the constitutive and inducible forms of HSP70 as an indicator of stress caused by transport, during development of the sea bass (Dicentrarchus labrax), a teleost fish of high value for aquaculture. Qualitative RT-PCR analysis revealed expression of inducible HSP70 gene in larvae and fry (25, 40 and 80 days) as well as in adult tissues (liver, brain, muscle, gills, kidney, gonads, heart, spleen and skin) of both control and stressed animals. Expression of inducible HSP70 mRNA examined in different adult tissues by Real-Time PCR, was significantly higher in skin and skeletal muscle of stressed animals than in controls. Immunolocalization of inducible and constitutive forms of heat shock protein 70 (HSP70 and HSC70), reported here for the first time, demonstrated an ubiquitous distribution of HSC70 protein in several tissues of both stressed and control animals (at all stages), while inducible HSP70 protein was found only in skeletal muscle of stressed animals. In all stressed animals, regardless of their developmental stage, cortisol levels were higher than in control animals.     

Resistance to Water Transport in Shoots of Vitis vinifera L. : Relation to Growth at Low Water Potential

Apparent resistances to water transport in the liquid phase were determined from measurements of soil, root, basal shoot internode, shoot apex, and leaf water potentials and water flux in Vitis vinifera (cv White Riesling) during soil drying. Predawn water potential differences (ΔΨ) in the shoots accounted for 20% of the total ΔΨ between the soil and the shoot apex when plants were well-watered but increased to about 90% when shoot growth ceased. The ΔΨ from soil to root was essentially constant during this period. At low water potential, the ΔΨ in the shoot was persistent when transpiration was low (predawn) or completely prevented (plant bagging). The apparent hydraulic resistance between the basal shoot internode and most rapidly expanding leaf (or shoot apex) increased several-fold when water was withheld. Leaf and internode expansion both exhibited high sensitivity to increasing hydraulic resistance. Measurements of pneumatic resistance to air flow through frozen internode segments indicated progressive vapor-filling of vessels as soil drying progressed. From these observations and others in the literature, it was suggested that embolization may be a common occurrence and play an important role in the inhibition of shoot growth at moderate water deficits.     

The Arabidopsis 1-Aminocyclopropane-1-Carboxylate Synthase Gene 1 Is Expressed during Early Development

The temporal and spatial expression of one member of the Arabidopsis 1-aminocyclopropane-1-carboxylate (ACC) synthase gene family (ACS1) was analyzed using a promoter-[beta]-glucuronidase fusion. The expression of ACS1 is under developmental control both in shoot and root. High expression was observed in young tissues and was switched off in mature tissues. ACS1 promoter activity was strongly correlated with lateral root formation. Dark-grown seedlings exhibited a different expression pattern from light-grown ones. The ACC content and the in vivo activity of ACC oxidase were determined. ACC content correlated with ACS1 gene activity. ACC oxidase activity was demonstrated in young Arabidopsis seedlings. Thus, the ACC formed can be converted into ethylene. In addition, ethylene production of immature leaves was fourfold higher compared to that of mature leaves. The possible involvement of ACS1 in influencing plant growth and development is discussed.     

Developmental and environmental regulation of tissue- and cell-specific expression for a pea protein farnesyltransferase gene in transgenic plants

Farnesylation mediates membrane targeting and in vivo activities of several key regulatory proteins such as Ras and Ras-related GTPases and protein kinases in yeast and mammals, and is implicated in cell cycle control and abscisic acid (ABA) signaling in plants. In this study, the developmental expression of a pea protein farnesyl-transferase (FTase) gene was examined using transgenic expression of the β-glucuronidase (GUS) gene fused to a 3.2 kb 5′ upstream sequence of the gene encoding the pea FTase β subunit. Coordinate expression of the GUS transgene and endogenous tobacco FTase β subunit gene in tobacco cell lines suggests that the 3.2 kb region contains the key FTase promoter elements. In transgenic tobacco plants, GUS expression is most prominent in meristematic tissues such as root tips, lateral root primordia and the shoot apex, supporting a role for FTase in the control of the cell cycle in plants. GUS activity was also detected in mature embryos and imbibed embryos, in accordance with a role for FTase in ABA signaling that modulates seed dormancy and germination. In addition, GUS activity was detected in regions that border two organs, e.g. junctions between stems and leaf petioles, cotyledons and hypocotyls, roots and hypocotyls, and primary and secondary roots. GUS is expressed in phloem complexes that are adjacent to actively growing tissues such as young leaves, roots of light-grown seedlings, and hypocotyls of dark-grown seedlings. Both light and sugar (e.g. sucrose) treatments repressed GUS expression in dark-grown seedlings. These expression patterns suggest a potential involvement of FTase in the regulation of nutrient allocation into actively growing tissues.     

A Cytosolic Relay of Heat Shock Proteins HSP70-1A and HSP90β Monitors the Folding Trajectory of the Serotonin Transporter

Mutations in the C terminus of the serotonin transporter (SERT) disrupt folding and export from the endoplasmic reticulum. Here we examined the hypothesis that a cytosolic heat shock protein relay was recruited to the C terminus to assist folding of SERT. This conjecture was verified by the following observations. (i) The proximal portion of the SERT C terminus conforms to a canonical binding site for DnaK/heat shock protein of 70 kDa (HSP70). A peptide covering this segment stimulated ATPase activity of purified HSP70-1A. (ii) A GST fusion protein comprising the C terminus of SERT pulled down HSP70-1A. The interaction between HSP70-1A and SERT was visualized in live cells by Förster resonance energy transfer: it was restricted to endoplasmic reticulum-resident transporters and enhanced by an inhibitor that traps HSP70-1A in its closed state. (iv) Co-immunoprecipitation confirmed complex formation of SERT with HSP70-1A and HSP90β. Consistent with an HSP relay, co-chaperones (e.g. HSC70-HSP90-organizing protein) were co-immunoprecipitated with the stalled mutants SERT-R607A/I608A and SERT-P601A/G602A. (v) Depletion of HSP90β by siRNA or its inhibition increased the cell surface expression of wild type SERT and SERT-F604Q. In contrast, SERT-R607A/I608A and SERT-P601A/G602A were only rendered susceptible to inhibition of HSP70 and HSP90 by concomitant pharmacochaperoning with noribogaine. (vi) In JAR cells, inhibition of HSP90 also increased the levels of SERT, indicating that endogenously expressed transporter was also susceptible to control by HSP90β. These findings support the concept that the folding trajectory of SERT is sampled by a cytoplasmic chaperone relay.     

黄颡鱼HSC70基因及其组织表达分析

热休克蛋白70（HSP70）与生物体的抗胁迫能力密切相关。本文采用RACE (Rapid amplification of cDNA ends) 技术,从黄颡鱼Pelteobagrus fulvidraco克隆到一种组成型热休克蛋白（HSC70）基因及其cDNA。该cDNA全长2245bp,包括5′非编码区82bp,3′非编码区225bp,开放阅读框(ORF) 1938bp,编码645个氨基酸组成的蛋白质。黄颡鱼HSC70基因含有8个内含子,与人、鼠、虹鳟和花斑溪鳉的HSC70基因内含子数目相同,位置相似。其中,最长内含子（873bp）位于5′端非编码区,其余内含子（长度在80－251bp之间不等）均在编码区以内。黄颡鱼HSC70基因编码的氨基酸序列与南方鲶的相似度最高,达96.13%,与欧洲银鲫和团头鲂的相似度分别为94.45%和94.14%。RT-PCR检测显示,正常情况下黄颡鱼HSC70在血细胞、心脏、肝、头肾、脾、鳃、肌肉和脑中均有表达,但表达量在鳃中最高,肌肉中最低;统计结果显示,热激后HSC70在血细胞、肝、头肾和脑中的表达量显著上升(p<0.05),而在其余组织中热激前后的表达差异不显著(p>0.05)。     

The 5'-leader of tobacco mosaic virus promotes translation through enhanced recruitment of eIF4F

The 5′-leader sequence (called Ω) of tobacco mosaic virus (TMV) functions as a translational enhancer in plants. A poly(CAA) region within Ω is responsible for the translation enhancement and serves as a binding site for the heat shock protein, HSP101, which is required for the translational enhancement. Genetic analysis of the HSP101-mediated enhancement of translation from Ω-containing mRNA suggested that two eukaryotic initiation factors (eIFs), i.e. eIF4G and eIF3, were necessary. In this study, the functional interaction between Ω and other RNA elements known to participate in the recruitment of eIF4G, i.e. the 5′-cap and the poly(A) tail, was examined. Ω exhibited functional overlap with the 5′-cap and the poly(A) tail but not with the native TMV 3′-UTR which contains an independent translational enhancer. Consistent with the role of HSP101 in mediating the translational function of Ω, the enhancement afforded by Ω increased following a heat shock, which elevates expression of HSP101. The use of a fractionated translation lysate revealed that of the two eIF4F proteins present in plants, eIF4F was specifically required for the activity of Ω. The data suggest that Ω is functionally similar to a 5′-cap and a poly(A) tail in that it serves to recruit eIF4F in order to enhance translation from an mRNA.