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排序方式: 共有133条查询结果,搜索用时 15 毫秒
31.
M. J. M. Smulders E. T. W. M. van de Ven A. F. Croes G. J. Wullems 《Journal of Plant Growth Regulation》1990,9(1-3):27-34
1-Naphthaleneacetic acid (1-NAA), required for in vitro flower bud formation, was taken up by pedicel explants of tobacco (Nicotiana tabacum L.) in large amounts and rapidly metabolized into various conjugates. These conjugates have been tentatively identified in four thin-layer Chromatographic systems using authentic standards as references. The major metabolite formed during the first hours of culture comigrated with 1-NAA-glucoside (1-NAGlu). From the 6th hour on, most 1-NAA had been converted into a yet unidentified metabolite. 1-NAglu was an intermediate in the formation of this metabolite. After 24 h, 1-NAA-aspartate (1-NAAsp) became the second major metabolite. The increase in 1-NAAsp formation was induced by 1-NAA. The inactive analog 2-naphthaleneacetic acid (2-NAA) was metabolized similar to 1-NAA, but was unable to increase the formation of the aspartate conjugate. When explants were fed labeled 1-NAGlu, 1-NAAsp or the major unidentified metabolite, radioactivity became associated with free 1-NAA and all major conjugates, indicating interconversion of conjugates and breakdown to free 1-NAA. A regulatory role of conjugation in maintaining a particular level of free 1-NAA in the tissue is proposed herein. 相似文献
32.
The regulation of methylamine and formaldehyde metabolism in Arthrobacter P1 was investigated in carbonlimited continuous cultures. To avoid toxic effects of higher formaldehyde concentrations, formaldehyde-limited cultures were established in smooth substrate transitions from choline-limitation. Evidence was obtained that the synthesis of enzymes involved in the conversion of methylamine into formaldehyde and in formaldehyde fixation is induced sequentially in this organism. Compared to growth with methylamine the molar growth yield on formaldehyde was approximately 30% higher. This difference is mainly due to the expenditure of energy for the uptake of methylamine from the medium.The addition of a pulse of a heterotrophic substrate, glucose or acetate, to C1 substrate-limited continuous cultures resulted in relief of carbon limitation and transient synthesis of increasing amounts of cell material. Concomitantly, a significant decrease in the specific activities of hexulose phosphate synthase was observed. However, the total activity of hexulose phosphate synthase in these cultures remained clearly in excess of that required to fix the formaldehyde that became available in time. The observed strong decrease in the specific activities of this RuMP cycle enzyme strongly suggests that its synthesis is controlled via catabolite repression exerted by the metabolism of heterotrophic substrates.Abbreviations HPS
3-Hexulose-6-phosphate synthase
- HPI
3-hexulose-6-phosphate isomerase
- RuMP
ribulose monophosphate 相似文献
33.
34.
35.
M. J. M. Smulders A. Kemp G. W. M. Barendse A. F. Croes G. J. Wullems 《Physiologia plantarum》1990,78(2):167-172
The effect of ethytene on in vitro flower bud formation in thin-layer explants from tobacco pendicels ( Nicotiana tabacum L. cv. Samsun) was studied Endogenous ethylene production was stimulated by l-minocyclopropanc-l-carhoxylic acid (ACT), and inhibited by aminoethoxyviny lglycine (AVG). resulting in higher and lower ethylene accumulation. respectively. In the presence of an elevated ethylene concentration, the number of flower buds formed after 7 days of culture in explants was increased, compared with the control. Treatment with AVG or with AgNO3 which blocks ethylene action resulted in decreased bud numbers after 7 days of culture. A different effect of ethylene was visible after 14 days of culture, when regeneration was complete. Treatment with AgNO3 led to more bud regeneration, and increasing ethylene concentrations to lower bud numbers. The endogenous production of ethylene was enhanced by high concentrations of 1-naphthaleneacetic acid (NAA).
The inhibitory effect of applied ethylene was almost 100% in explants cultured at low concentrations of NAA (below 1 μ M ). but hardly visible at high concentrations (4.5 μ M ). As a consequence, the optimal NAA concentration shifted to a higher value in the presence of ethylene. These results are interpreted as a reduction in tissue sensitivity to auxin and in regenerative capability by ethylene. The effect of ethylene on auxin action is not exerted at the level of hormone concentration. Neither NAA uptake nor conversion to conjugates was effected by ethylene. 相似文献
The inhibitory effect of applied ethylene was almost 100% in explants cultured at low concentrations of NAA (below 1 μ M ). but hardly visible at high concentrations (4.5 μ M ). As a consequence, the optimal NAA concentration shifted to a higher value in the presence of ethylene. These results are interpreted as a reduction in tissue sensitivity to auxin and in regenerative capability by ethylene. The effect of ethylene on auxin action is not exerted at the level of hormone concentration. Neither NAA uptake nor conversion to conjugates was effected by ethylene. 相似文献
36.
G. W. M. Barendse A. F. Croes M. Bosveld W. M. van der Krieken G. J. Wullems 《Journal of Plant Growth Regulation》1987,6(4):193-200
In vitro flower bud initiation and development depend on the presence of two hormones in the culture medium—auxin (NAA) and cytokinin (BAP). The uptake of both NAA and BAP by the explants was shown to be proportional to the concentrations supplied in the medium over a period of 4 days after the onset of culture. However, when supplied at equal concentrations for 24 h, the NAA uptake was up to 10-fold higher than the BAP uptake. Both hormones are rapidly metabolized by the explants. Nevertheless, the concentrations of free hormones inside the explants appeared to be high and in the case of NAA exceeded the concentration in the medium by more than 1 order of magnitude within 24 h. Apparently flower bud initiation in tobacco explants requires relatively high concentrations free NAA and BAP in the tissue maintained by a continuous supply in the medium. There are at present no indications that the products of hormone metabolism are directly involved in bud formation. 相似文献
37.
38.
Purification and cDNA Cloning of Isochorismate Synthase from
Elicited Cell Cultures of Catharanthus roseus
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Léon J.P. van Tegelen Paolo R.H. Moreno Anton F. Croes Robert Verpoorte George J. Wullems 《Plant physiology》1999,119(2):705-712
Isochorismate is an important
metabolite formed at the end of the shikimate pathway, which is
involved in the synthesis of both primary and secondary metabolites. It
is synthesized from chorismate in a reaction catalyzed by the enzyme
isochorismate synthase (ICS; EC 5.4.99.6). We have purified ICS to
homogeneity from elicited Catharanthus roseus cell
cultures. Two isoforms with an apparent molecular mass of 64 kD were
purified and characterized. The Km values
for chorismate were 558 and 319 μm for isoforms I and II,
respectively. The isoforms were not inhibited by aromatic amino acids
and required Mg2+ for enzyme activity. Polymerase chain
reaction on a cDNA library from elicited C. roseus cells
with a degenerated primer based on the sequence of an internal peptide
from isoform II resulted in an amplification product that was used to
screen the cDNA library. This led to the first isolation, to our
knowledge, of a plant ICS cDNA. The cDNA encodes a protein of 64 kD
with an N-terminal chloroplast-targeting signal. The deduced amino acid
sequence shares homology with bacterial ICS and also with anthranilate
synthases from plants. Southern analysis indicates the existence of
only one ICS gene in C. roseus.The shikimate pathway is a major pathway in primary and secondary
plant metabolism (Herrmann, 1995). It provides chorismate for the
synthesis of the aromatic amino acids Phe, Tyr, and Trp, which are used
in protein biosynthesis, but also serves as a precursor for a wide
variety of aromatic substances (Herrmann, 1995; Weaver and Hermann,
1997; Fig. Fig.1a).1a). Chorismate is also the starting point of a biosynthetic
pathway leading to phylloquinones (vitamin K1)
and anthraquinones (Poulsen and Verpoorte, 1991). The first committed
step in this pathway is the conversion of chorismate into
isochorismate, which is catalyzed by ICS (Poulsen and Verpoorte, 1991;
Fig. Fig.1b).1b). Its substrate, chorismate, plays a pivotal role in the
synthesis of shikimate-pathway-derived compounds, and its distribution
over the various pathways is expected to be tightly regulated. Elicited
cell cultures of Catharanthus roseus provide an example of
the partitioning of chorismate. Concurrently, these cultures produce
both Trp-derived indole alkaloids and DHBA (Moreno et al., 1994). In
bacteria DHBA is synthesized from isochorismate (Young et al.,
1969). Elicitation of C. roseus cell cultures with a fungal
extract induces not only several enzymes of the indole alkaloid
biosynthetic pathway (Pasquali et al., 1992) but also ICS
(Moreno et al., 1994). Information concerning the expression and
biochemical characteristics of the enzymes that compete for available
chorismate (ICS, CM, and AS) may help us to understand the regulation
of the distribution of this precursor over the various pathways. Such
information is already available for CM (Eberhard et al., 1996) and AS
(Poulsen et al., 1993; Bohlmann et al., 1995) but not for ICS.
Figure 1a, Position of ICS in the plant metabolism. SA,
Salicylic acid, OSB, o-succinylbenzoic acid. b, Reaction
catalyzed by ICS.Isochorismate plays an important role in bacterial and plant metabolism
as a precursor of o-succinylbenzoic acid, an intermediate in
the biosynthesis of menaquinones (vitamin K2)
(Weische and Leistner, 1985) and phylloquinones (vitamin
K1; Poulsen and Verpoorte, 1991). In bacteria
isochorismate is also a precursor of siderophores such as
DHBA (Young et al., 1969), enterobactin (Walsh et
al., 1990), amonabactin (Barghouthi et al., 1991), and salicylic acid
(Serino et al., 1995). Although evidence from tobacco would indicate
that salicylic acid in plants is derived from Phe via benzoic acid
(Yalpani et al., 1993; Lee et al., 1995; Coquoz et al., 1998), it
cannot be excluded that it is also synthesized from isochorismate. In
the secondary metabolism of higher plants, isochorismate is a precursor
for the biosynthesis of anthraquinones (Inoue et al., 1984; Sieweke and
Leistner, 1992), naphthoquinones (Müller and Leistner, 1978),
catalpalactone (Inouye et al., 1975), and certain alkaloids in orchids
(Leete and Bodem, 1976).ICS was first extracted and partially purified from crude extracts of
Aerobacter aerogenes (Young and Gibson, 1969). Later, ICS
activity was detected in protein extracts of cell cultures from plants
of the Rubiaceae, Celastraceae, and Apocynaceae families (Ledüc
et al., 1991; Poulsen et al., 1991; Poulsen and Verpoorte, 1992). Genes
encoding ICS have been cloned from bacteria such as Escherichia
coli (Ozenberger et al., 1989), Pseudomonas aeruginosa
(Serino et al., 1995), Aeromonas hydrophila (Barghouthi et
al., 1991), Flavobacterium K3–15
(Schaaf et al., 1993), Hemophilus influenzae
(Fleischmann et al., 1995), and Bacillus subtilis
(Rowland and Taber, 1996). Both E. coli and B.
subtilis have two distinct ICS genes; one is involved in
siderophore biosynthesis and the other is involved in menaquinone
production (Daruwala et al., 1996, 1997; Müller et al., 1996;
Rowland and Taber, 1996). The biochemical properties of the two ICS
enzymes from E. coli are different (Daruwala et al., 1997;
Liu et al., 1990). Sequence analysis has revealed that the bacterial
ICS enzymes share homology with the chorismate-utilizing
enzymes AS and p-aminobenzoate synthase, suggesting that
they share a common evolutionary origin (Ozenberger et al.,
1989).Much biochemical and molecular data concerning the shikimate pathway in
plants have accumulated in recent years (Schmid and Amrhein, 1995;
Weaver and Hermann, 1997), but relatively little work has been done on
ICS from higher plants. The enzyme has been partially purified from
Galium mollugo cell cultures (Ledüc et al., 1991,
1997), but purification of the ICS protein to homogeneity has remained
elusive, probably because of instability of the enzyme.Our interests focus on the role of ICS in the regulation of chorismate
partitioning over the various pathways. Furthermore, we studied ICS in
C. roseus to gain insight into the biosynthesis of DHBA in
higher plants (Moreno et al., 1994). In this paper we report the first
purification, to our knowledge, of ICS to homogeneity from a plant
source and the cloning of the corresponding cDNA. 相似文献
39.
40.
Opdam FJ Kamps G Croes H van Bokhoven H Ginsel LA Fransen JA 《European journal of cell biology》2000,79(5):308-316
Rab proteins belong to a subfamily of small GTP-binding protein genes of the Ras superfamily and play an important role in intracellular vesicular targeting. The presence of members of this protein family was examined in Caco-2 cells by a PCR-based strategy. Twenty-five different partial cDNA sequences were isolated, including 18 Rab protein family members. Seven novel human sequences, representing Rab2B, Rab6A', Rab6B, Rab10, Rab19B, Rab21 and Rab22A, were identified. For one clone, encoding Rab21, full-length cDNA was isolated from a Caco-2 cDNA library. Northern blot analysis showed a ubiquitous expression pattern of Rab21. To study Rab21 protein expression in Caco-2 cells, polyclonal antibodies were raised against GST-Rab21 fusion protein and characterised. The antibodies recognised Rab21 as a protein of approximately 25 kDa. Interestingly, the protein shows a general ER-like staining in nonpolarised Caco-2 cells in contrast to an apically located vesicle-like staining in polarised Caco-2 cells. Furthermore, immunohistochemical staining on human jejunal tissue showed a predominant expression of Rab21 in the epithelial cell layer with high expression levels in the apical region, whereas stem cells in the crypts were negative. We therefore suggest an alternative role for Rab21 in the regulation of vesicular transport in polarised intestinal epithelial cells. 相似文献