|
1. |
Lectins, lectin genes, and their role in plant defense. |
|
The Plant cell,
Volume 3,
Issue 1,
1991,
Page 1-9
M J Chrispeels,
N V Raikhel,
Preview
|
PDF (811KB)
|
|
ISSN:1040-4651
DOI:10.1105/tpc.3.1.1
出版商:American Society of Plant Biologists
年代:1991
数据来源: ASPB
|
2. |
Ammonia-regulated expression of a soybean gene encoding cytosolic glutamine synthetase in transgenic Lotus corniculatus. |
|
The Plant cell,
Volume 3,
Issue 1,
1991,
Page 11-22
G H Miao,
B Hirel,
M C Marsolier,
R W Ridge,
D P Verma,
Preview
|
PDF (2557KB)
|
|
摘要:
A full-length cDNA clone encoding cytosolic glutamine synthetase (GS), expressed in roots and root nodules of soybean, was isolated by direct complementation of an Escherichia coli gln A- mutant. This sequence is induced in roots by the availability of ammonia. A 3.5-kilobase promoter fragment of a genomic clone (lambda GS15) corresponding to this cDNA was isolated and fused with a reporter [beta-glucuronidase (GUS)] gene. The GS-GUS fusion was introduced into a legume (Lotus corniculatus) and a nonlegume (tobacco) plant by way of Agrobacterium-mediated transformations. This chimeric gene was found to be expressed in a root-specific manner in both tobacco and L. corniculatus, the expression being restricted to the growing root apices and the vascular bundles of the mature root. Treatment with ammonia increased the expression of this chimeric gene in the legume background (i.e., L. corniculatus); however, no induction was observed in tobacco roots. Histochemical localization of GUS activity in ammonia-treated transgenic L. corniculatus roots showed a uniform distribution across all cell types. These data suggest that the tissue specificity of the soybean cytosolic GS gene is conserved in both tobacco and L. corniculatus; however, in the latter case, this gene is ammonia inducible. Furthermore, the ammonia-enhanced GS gene expression in L. corniculatus is due to an increase in transcription. That this gene is directly regulated by externally supplied or symbiotically fixed nitrogen is also evident from the expression of GS-GUS in the infection zone, including the uninfected cells, and the inner cortex of transgenic L. corniculatus nodules, where a flux of ammonia is encountered by this tissue. The lack of expression of GS-GUS in the outer cortex of the nodules suggests that ammonia may not be able to diffuse outside the endodermis.
ISSN:1040-4651
出版商:American Society of Plant Biologists
年代:1991
数据来源: ASPB
|
3. |
Tissue-Specific Expression of Cell Wall Proteins in Developing Soybean Tissues. |
|
The Plant cell,
Volume 3,
Issue 1,
1991,
Page 23-37
Z. H. Ye,
J. E. Varner,
Preview
|
PDF (6206KB)
|
|
摘要:
Cell wall hydroxyproline-rich glycoproteins (HRGPs) and glycine-rich proteins (GRPs) were examined at the protein and at the mRNA levels in developing soybean tissues by tissue print immunoblots and RNA blots. In young soybean stems, HRGPs are expressed most heavily in cambium cells, in a few layers of cortex cells surrounding primary phloem, and in some parenchyma cells around the primary xylem, whereas GRPs are highly expressed in the primary xylem and also in the primary phloem. In older soybean stems, HRGP genes are expressed exclusively in cambium cells and GRP genes are most heavily expressed in newly differentiated secondary xylem cells. Similar expression patterns of HRGPs and of GRPs were found in soybean petioles, seedcoats, and young hypocotyls, and also in bean petioles and stems. HRGPs and GRPs become insolubilized in soybean stem cell walls. Three major HRGP mRNAs and two major GRP mRNAs accumulate in soybean stems. Soluble HRGPs are abundant in young hypocotyl apical regions and young root apical regions, whereas in hypocotyl and root mature regions, soluble HRGPs are found only in a few layers of cortex cells surrounding the vascular bundles. GRPs are specifically localized in primary xylem cell walls of young root. These results show that the gene expression of HRGPs and GRPs is developmentally regulated in a tissue-specific manner. In soybean tissues, HRGPs are most heavily expressed in meristematic cells and in some of those cells that may be under stress, whereas GRPs are expressed in all cells that are or are going to be lignified.
ISSN:1040-4651
DOI:10.1105/tpc.3.1.23
出版商:American Society of Plant Biologists
年代:1991
数据来源: ASPB
|
4. |
Regulation and manipulation of flavonoid gene expression in anthers of petunia: the molecular basis of the Po mutation. |
|
The Plant cell,
Volume 3,
Issue 1,
1991,
Page 39-48
A J van Tunen,
L A Mur,
K Recourt,
A G Gerats,
J N Mol,
Preview
|
PDF (2819KB)
|
|
摘要:
Molecular mechanisms governing development of the male reproductive organs of flowers, the anthers, are largely unknown. In this article, we report on the investigation of the molecular basis of a mutation involving the expression of a gene encoding the flavonoid biosynthesis enzyme chalcone flavanone isomerase (CHI) in anthers of petunia. In petunia, the gene Po regulates the expression of CHI in anthers: PoPo petunia lines contain CHI enzyme activity in petals and anthers, whereas popo lines contain the CHI enzyme only in petals but not in anthers. As a result of the Po mutation, the substrate of CHI accumulates and therefore the pollen of a popo line are yellow or greenish. The genome of petunia contains two chi genes, chiA and chiB. In a restriction fragment length polymorphism analysis, a 100% linkage was observed between Po and chiA. This result suggested that Po is identical to chiA and that Po is not a regulatory gene of chiA. Introduction of a chiA gene isolated from a PoPo line into a popo line resulted in a complementation of the mutation that was directly visible because the pollen color shifted from yellow to white. This proved that chiA and Po are identical. Because chiA encodes a functional CHI enzyme in flower petals of a popo line, we propose that the Po mutation is a mutation in the regulatory region of chiA abolishing chiA promoter activity in anthers but not in corollas. This change in anther color is a fine illustration of how floral pigmentation can be manipulated in a predictable way and suggests the use of CHI as a visible marker.
ISSN:1040-4651
出版商:American Society of Plant Biologists
年代:1991
数据来源: ASPB
|
5. |
Identification of Pseudomonas syringae pathogens of Arabidopsis and a bacterial locus determining avirulence on both Arabidopsis and soybean. |
|
The Plant cell,
Volume 3,
Issue 1,
1991,
Page 49-59
M C Whalen,
R W Innes,
A F Bent,
B J Staskawicz,
Preview
|
PDF (1894KB)
|
|
摘要:
To develop a model system for molecular genetic analysis of plant-pathogen interactions, we studied the interaction between Arabidopsis thaliana and the bacterial pathogen Pseudomonas syringae pv tomato (Pst). Pst strains were found to be virulent or avirulent on specific Arabidopsis ecotypes, and single ecotypes were resistant to some Pst strains and susceptible to others. In many plant-pathogen interactions, disease resistance is controlled by the simultaneous presence of single plant resistance genes and single pathogen avirulence genes. Therefore, we tested whether avirulence genes in Pst controlled induction of resistance in Arabidopsis. Cosmids that determine avirulence were isolated from Pst genomic libraries, and the Pst avirulence locus avrRpt2 was defined. This allowed us to construct pathogens that differed only by the presence or absence of a single putative avirulence gene. We found that Arabidopsis ecotype Col-0 was susceptible to Pst strain DC3000 but resistant to the same strain carrying avrRpt2, suggesting that a single locus in Col-0 determines resistance. As a first step toward genetically mapping the postulated resistance locus, an ecotype susceptible to infection by DC3000 carrying avrRpt2 was identified. The avrRpt2 locus from Pst was also moved into virulent strains of the soybean pathogen P. syringae pv glycinea to test whether this locus could determine avirulence on soybean. The resulting strains induced a resistant response in a cultivar-specific manner, suggesting that similar resistance mechanisms may function in Arabidopsis and soybean.
ISSN:1040-4651
DOI:10.1105/tpc.3.1.49
出版商:American Society of Plant Biologists
年代:1991
数据来源: ASPB
|
6. |
Induction of Arabidopsis defense genes by virulent and avirulent Pseudomonas syringae strains and by a cloned avirulence gene. |
|
The Plant cell,
Volume 3,
Issue 1,
1991,
Page 61-72
X Dong,
M Mindrinos,
K R Davis,
F M Ausubel,
Preview
|
PDF (2070KB)
|
|
摘要:
We developed a model system to study the signal transduction pathways leading to the activation of Arabidopsis thaliana genes involved in the defense against pathogen attack. Here we describe the identification and characterization of virulent and avirulent Pseudomonas syringae strains that elicit disease or resistance symptoms when infiltrated into Arabidopsis leaves. The virulent and avirulent strains were characterized by determining growth of the pathogen in Arabidopsis leaves and by measuring accumulation of mRNA corresponding to Arabidopsis phenylalanine ammonia-lyase (PAL), beta-1,3-glucanase (BG), and chalcone synthase (CHS) genes in infected leaves. The virulent strain, P. syringae pv maculicola ES4326, multiplied 10(5)-fold in Arabidopsis leaves and strongly elicited BG1, BG2, and BG3 mRNA accumulation but had only a modest effect on PAL mRNA accumulation. In contrast, the avirulent strain, P. syringae pv tomato MM1065, multiplied less than 10-fold in leaves and had only a minimal effect on BG1, BG2, and BG3 mRNA accumulation, but it induced PAL mRNA accumulation. No accumulation of CHS mRNA was found with either ES4326 or MM1065. We also describe the cloning of a putative avirulence (avr) gene from the avirulent strain MM1065 that caused the virulent strain ES4326 to grow less well in leaves and to strongly elicit PAL but not BG1 and BG3 mRNA accumulation. These results suggest that the Arabidopsis PAL and BG genes may be activated by distinct signal transduction pathways and show that differences in plant gene induction by virulent and avirulent strains can be attributed to a cloned presumptive avr gene.
ISSN:1040-4651
DOI:10.1105/tpc.3.1.61
出版商:American Society of Plant Biologists
年代:1991
数据来源: ASPB
|
7. |
The tnpA and tnpD gene products of the Spm element are required for transposition in tobacco. |
|
The Plant cell,
Volume 3,
Issue 1,
1991,
Page 73-85
P Masson,
M Strem,
N Fedoroff,
Preview
|
PDF (1773KB)
|
|
摘要:
The maize Suppressor-mutator (Spm) element encodes four alternatively spliced transcripts designated tnpA, tnpB, tnpC, and tnpD. tnpA and tnpB are monocistronic, whereas tnpC and tnpD are dicistronic, and the protein-coding sequences of each transcript overlap extensively with those of one or more of the other transcripts. We have analyzed the role of the Spm-encoded gene products in element transposition by using cDNAs with a single open reading frame to (1) complement Spm elements with frameshift mutations and (2) complement each other in a tobacco transposition assay. We report that whereas the tnpA and tnpD gene products are essential for transposition, the tnpB and tnpC gene products are not. We have analyzed the structure of empty donor sites, new insertion sites, and potential transposition intermediates. We discuss the implications of our findings for the mechanism of Spm transposition.
ISSN:1040-4651
DOI:10.1105/tpc.3.1.73
出版商:American Society of Plant Biologists
年代:1991
数据来源: ASPB
|
8. |
Macrostructure of the tomato telomeres. |
|
The Plant cell,
Volume 3,
Issue 1,
1991,
Page 87-94
M W Ganal,
N L Lapitan,
S D Tanksley,
Preview
|
PDF (2069KB)
|
|
摘要:
The macrostructure of the tomato telomeres has been investigated by in situ hybridization, genomic sequencing, and pulsed-field gel electrophoresis. In situ hybridizations with a cloned telomeric sequence from Arabidopsis thaliana indicated that the telomeric repeat of tomato cross-hybridizes with that of Arabidopsis and is located at all telomeres. Bal31 digestion kinetics confirmed that the tomato telomeric repeat represents the outermost DNA sequence of each tomato chromosome. Genomic sequencing of enriched tomato telomeric sequences, using primers derived from the Arabidopsis sequence, revealed that the consensus sequence of the tomato telomeric repeat is TT(T/A)AGGG compared with the Arabidopsis consensus sequence of TTTAGGG. Furthermore, as shown by pulsed-field gel electrophoresis, the telomeric repeat of tomato is separated by not more than a few hundred kilobases from a previously described 162-base pair satellite DNA repeat of tomato (TGR I) at 20 of the 24 telomeres. Together, these sequences are found in the heterochromatic terminal knob observed in pachytene chromosomes. Therefore, these two repeats determine the structure of 20 of the 24 tomato chromosome ends over approximately 2% of the total chromosome length.
ISSN:1040-4651
出版商:American Society of Plant Biologists
年代:1991
数据来源: ASPB
|
9. |
DNA Fingerprinting with a Dispersed Repeated Sequence Resolves Pathotype Diversity in the Rice Blast Fungus. |
|
The Plant cell,
Volume 3,
Issue 1,
1991,
Page 95-102
M. Levy,
J. Romao,
M. A. Marchetti,
J. E. Hamer,
Preview
|
PDF (1952KB)
|
|
摘要:
The poor definition of pathotype variation in the rice blast fungus has historically handicapped strategies for reducing blast disease damage to the world's rice crop. We have employed a probe for a dispersed repeated DNA sequence called MGR [Hamer et al. (1989). Proc. Natl. Acad. Sci. USA 86, 9981-9985] to construct genotype-specific, EcoRl restriction fragment length profiles (MGR-DNA fingerprints) from United States field isolates of this fungus. By using a blind-test design, we demonstrated that MGR-DNA fingerprints distinguished the major pathotypes in the United States, accurately identified the pathotypes of isolates collected over a 30-year period, and defined the organization of clonal lineages within and among pathotype groups. These results resolved a lingering controversy regarding rice blast pathotype stability and illustrated new opportunities for tracking the population dynamics and evolution of this important crop pathogen.
ISSN:1040-4651
DOI:10.1105/tpc.3.1.95
出版商:American Society of Plant Biologists
年代:1991
数据来源: ASPB
|
10. |
CORRECTION |
|
The Plant cell,
Volume 3,
Issue 1,
1991,
Page 103-103
J. Nash,
K. R. Luehrsen,
V. Walbot,
Preview
|
PDF (253KB)
|
|
ISSN:1040-4651
DOI:10.1105/tpc.3.1.103
出版商:American Society of Plant Biologists
年代:1991
数据来源: ASPB
|
|