Scanning Electron Microscopy (SEM) and Light Microscopy (LM)-based Palyno-morphological views of Solanaceae in Western Himalaya.

In this study, plants belonging to family Solanaceae growing in Western Himalaya region have been observed palynologically under Light Microscope and Scanning electron microscope. Present investigation comprises of 10 genera and 23 species, namely, Atropa acuminata, Capsicum decoraticus, Capsicum frutescens, Cestrum aurantiacum, Cestrum diurnum, Cestrum nocturnum, Datura alba, Datura innoxia, Datura stramonium, Hyoscymus niger, Lycopersicon esculentum, Nicotiana rustica, Nicotiana tabacum, Petunia alba, Petunia hybrida, Solanum erianthum, Solanum melongena, Solanum miniatum, Solanum pseudocapsicum, Solanum surratense, Solanum tuberosum, Withania coagulans, Withania somnifera. Solanaceae is a eurypalynous family. Grains are usually Tricolporate and Tetracolporate, radially symmetrical, isopolar, prolate-spheroidal to oblate-spheroidal to oblate-spheroidal to subprolate to per prolate or suboblate to oblate, size range: 8.55-72 µm, amb circular, semi-angular or subangular, aperture drop-type, labrum common-type, exine usually 2 µm thick, nexine 1-1.5 µm thick. Tectum usually psilate, sexine reticulate, granulate or striato-reticulate, with obscure pattern, sexine 1-2 µm thick, nexine 1-1.5 µm thick, and intine 0.5-1 µm thick. Most striking variation has been found in the shape class, aperture-type, and tectal surface. Based on these characters, taxonomic keys have been made for correct identification of members in Solanaceae. However, the grains of this family are usually tricolporate and have direct relationship with certain members of the family Scrophulariaceae. Palyno-morphological characters of family Solanaceae have been studied for the first time in Western Himalayan region of Pakistan. These palyno-morphological characters are significant for identification of the members of family Solanaceae.

A new commelinid monocot seed fossil from the early Eocene previously identified as Solanaceae.

PREMISE OF THE STUDY: Fossils provide minimum age estimates for extant lineages. Here we critically evaluate Cantisolanum daturoides Reid & Chandler and two other early putative seed fossils of Solanaceae, an economically important plant family in the Asteridae. METHODS: Three earliest seed fossil taxa of Solanaceae from the London Clay Formation (Cantisolanum daturoides) and the Poole and Branksome Sand Formations (Solanum arnense Chandler and Solanispermum reniforme Chandler) were studied using x-ray microcomputed tomography (MCT) and scanning electron microscopy (SEM). KEY RESULTS: The MCT scans of Cantisolanum daturoides revealed a high level of pyrite preservation at the cellular level. Cantisolanum daturoides can be clearly excluded from Solanaceae and has more affinities to the commelinid monocots based on a straight longitudinal axis, a prominent single layer of relatively thin-walled cells in the testa, and a clearly differentiated micropyle surrounded by radially elongated and inwardly curved testal cells. While the MCT scans show no internal preservation in Solanum arnense and Solanispermum reniforme, SEM images show the presence of several characteristics that allow the placement of these taxa at the stem node of Solanaceae. CONCLUSIONS: Cantisolanum daturoides is likely a member of commelinid monocots and not Solanaceae as previously suggested. The earliest fossil record of Solanaceae is revised to consist of fruit fossil with inflated calyces from the early Eocene of Patagonia (52 Ma) and fossilized seeds from the early to mid-Eocene of Europe (48-46 Ma). The new identity for Cantisolanum daturoides does not alter a late Cretaceous minimum age for commelinids.

Accumulation of acidic SK3 dehydrins in phloem cells of cold- and drought-stressed plants of the Solanaceae.

The role of acidic SK(n) dehydrins in stress tolerance of important crop and model species of the Solanaceae remains unknown. We have previously shown that the acidic SK3 dehydrin DHN24 from Solanum sogarandinum is constitutively expressed and its expression is associated with cold acclimation. Here we found that DHN24 is specifically localized to phloem cells of vegetative organs of non-acclimated plants. More precise localization of DHN24 revealed that it is primarily found in sieve elements (SEs) and companion cells (CCs) of roots and stems. In cold-acclimated plants, DHN24 is mainly present in all cell types of the phloem. Dhn24 transcripts are also predominantly localized to phloem cells of cold-acclimated stems. Immunoelectron microscopy localized DHN24 to the cytosol and close to organelle membranes of phloem cells, the lumen with phloem protein filaments, parietal cytoplasm of SEs and the nucleoplasm of some nuclei. Cell fractionation experiments revealed that DHN24 was detected in the cytosolic, nuclear and microsomal fractions. We also determined whether homologous members of the acidic subclass dehydrins from Capsicum annuum and Lycopersicon chilense share the characteristics of DHN24. We showed that they are also constitutively expressed, but their protein level is upregulated preferentially by drought stress. Immunofluorescent localization revealed that they are detected in SEs and CCs of unstressed plants and throughout the phloem in drought-stressed plants. These results suggest that one of the primary roles of DHN24 and its homologs may be the protection of the phloem region from adverse effects of abiotic stresses.

Plant hormones including ethylene are recruited in calyx inflation in Solanaceous plants.

Plant hormones direct many processes of floral and post-floral morphogenesis in Angiosperms. However, their role in shaping floral morphological novelties, such as inflated calyx syndrome (ICS) exhibited by a few genera of the Solanaceae, remains unknown. In Withania and Physalis, sepals resume growth after pollination and encapsulate the mature fruit to form a balloon-like structure, i.e. ICS. The epidermal cells of calyx show enlargement and lobation post-fertilization. Application of hormones to depistillated flower buds of Withania revealed that cytokinins and gibberellins mimic fertilization signals. The ICS development is a synchronous step with fruit development; both processes are under the control of more or less the same set of hormones, including cytokinins and gibberellic acids. Interestingly, inhibition of ethylene in the system is sufficient to yield inflated calyx in Withania. In contrast, Tubocapsicum, a closely related species and an evolutionary natural loss mutant of ICS - showed no response to applied hormones, and ethylene led to inflation of the receptacle indirectly. In addition to hormones, the expression of an MPF2-like MADS-box transcription factor in sepals is essential for ICS formation. Nevertheless, the interactions between MPF2-like genes and hormones are barely detectable at the transcript level. Our data provide insight into the role of hormones in generating floral morphological diversity during evolution.

Structural differences in chromosomes distinguish species in the tomato clade.

The tomato clade of Solanaceae is composed of 12 species that are all diploid with the same chromosome number and morphology. Species in the tomato clade are considered to have evolved primarily by genic changes rather than large-scale chromosomal rearrangements because pachytene chromosomes in F(1) hybrids synapse normally along their lengths and linkage maps of intra- and inter-specific hybrids are co-linear. However, small inversions have been reported between tomato and some of its wild relatives. Therefore, we reevaluated 5 F(1) hybrids using high-resolution, electron microscopic examination of pachytene chromosome (= synaptonemal complex) spreads to determine whether any minor structural changes had occurred among species in the tomato clade, which were not easily visible using light microscopic analysis of conventional chromosome squashes. Our study revealed a number of unexpected synaptic configurations such as mismatched kinetochores, inversion loops and reciprocal translocations. Most of these structural differences were in or close to heterochromatin that has comparatively few genes and little recombination, so they would be expected to have little effect on the evident colinearity of linkage maps, especially in euchromatin. However, these results demonstrate that substantial changes in chromosome structure have occurred among species within the tomato clade.

Genetic transformation of plastids of different Solanaceae species using tobacco cells as organelle hosts.

The plastid genome of angiosperms represents an attractive target for genetic manipulations. However plastid transformation of higher plants, especially of agriculturally valuable crops is an extremely difficult problem. Transformation protocols developed for tobacco 15 years ago failed to produce similar results with more than a handful of other species so far. We have analyzed plastid transformability of remote cytoplasmic hybrids (cybrids) that combine nuclei of tobacco, an easily transformable species, and plastids of some other, recalcitrant Solanaceae species. Here, we demonstrate that the plastids of five species of Solanaceae family, representing two subfamilies and three tribes, can be easily transformed if the plastids of these species are transferred into a cell of a transformable species (tobacco). The results can be considered to be an alternative approach to the development of plastid transformation technologies for recalcitrant species using a transformable intermediary ("clipboard") host.

[Consolidation of cytoskeleton during plant spindle formation. II. "Fused spindles"]. / Konsolidatsiia tsitoskeleta pri formirovanii veretena deleniia v rastitel'noi kletke. II. "Slivshiesia veretena".

Three mechanisms of fused spindle formation in meiosis of Solanacea have been described: 1) approach of daughter nuclei at prophase II; 2) fusion of perinuclear cytoskeleton systems at prophase II; 3) approach and fusion of prometaphase chaotic figures at prometaphase II. The process of fusion spindle formation appears to be complex and including several steps.

Structural and ultrastructural analysis of Solanum lycopersicoides protoplasts during diploid plant regeneration.

Light, fluorescence and electron microscopy were used to analyse the structural properties of protoplasts obtained from established suspension culture of Solanum lycopersicoides Dun, composed of meristematic cell aggregates. Four types of protoplasts were distinguished immediately after isolation: (1) mononuclear; (2) polynuclear, (3) anuclear and (4) homogeneous protoplasts. Only mononuclear protoplasts were capable of complete cell wall regeneration and mitotic division. Other types of protoplasts were eliminated during culture. Three phases were distinguished in the developing protoplast culture: (1) the elimination phase during which protoplasts damaged during isolation underwent complete degradation; (2) a phase of intense division during which both mitotic cell division and amitotic nuclear division took place; and (3) a stabilization phase leading to the formation of suspension culture. The cell suspension culture obtained from protoplasts was capable of regenerating diploid plants.

A proteinase inhibitor II of Solanum americanum is expressed in phloem.

Although proteinase inhibitor proteins are known to confer insect resistance in transgenic plants, their endogenous roles remain undefined. Here, we describe the expression of a proteinase inhibitor II (PIN2) protein from Solanum americanum in phloem of stems, roots and leaves suggesting a novel endogenous role for PIN2 in phloem. The phloem consists of parenchyma cells, sieve elements (SE), and companion cells (CC) which are in close association with SE. We isolated two cDNAs encoding PIN2, SaPIN2a and SaPIN2b, from a S. americanum cDNA library using a tomato PIN2 cDNA as hybridization probe. SaPIN2a shows 73.6% identity to SaPIN2b. Southern blot analysis confirmed that two genes occur in S. americanum. Northern blot analysis showed that both are wound-inducible and are expressed in flowers. Unlike SaPIN2b and other previously characterized plant PIN2 proteins, SaPlN2a is abundantly expressed in stems. In situ hybridization studies on stem sections showed that SaPIN2a mRNA is expressed in CC and some SE, likely the immature developing SE. of external and internal phloem. Western blot analysis using SaPIN2a-specific antibodies showed SaPIN2a accumulation in stems, leaf midribs and fruits. Immunohistochemical localization, using these antibodies, revealed SaPIN2a expression in external and internal phloem of stem. Immunoelectron microscopy of stem, root and leaf sections further localized SaPIN2a to the CC and predominantly to the SE, particularly the parietal cytoplasm adjacent to the cell wall, the lumen and the sieve-area pores. These results suggest that, other than a possible role in plant defense, SaPIN2a could be involved in regulating proteolysis in the SE.

Structures and expression patterns of two tropinone reductase genes from Hyoscyamus niger.

In the biosynthesis of tropane alkaloids, two tropinone reductases (TRs) catalyze reduction of tropinone to different stereoisomers, tropine and pseudotropine. Two TRs from Hyoscyamus niger have 64% of identical amino acids and hence a common evolutionary origin. In this study, genomic clones of TRs were isolated from H. niger. Their sequence comparison showed that although they have the same exon/intron organization, sequence similarity was restricted to the coding regions. In H. niger transgenic hairy roots, both TR promoters activated transcription of the reporter genes in endodermis and pericycle of the roots. A quantitative reporter assay and a nuclear run-on experiment indicated that the two genes are transcribed at a similar rate. The results indicate that although different activity levels have been observed for the TR enzymes in the H. niger root, the TR genes per se conserve similar tissue-specific expression pattern and transcriptional rate.

The 5S rRNA gene clusters have a defined orientation toward the nucleolus in Petunia hybrida and Crepis capillaris.

The 3D localization of the 5S ribosomal RNA genes was studied in cells of the cortex zone of roots in the plant species Petunia hybrida inbred line V26 and in Crepis capillaris. The analysis was carried out on interphase nuclei (both species) and on prophase nuclei (C. capillaris). The 5S ribosomal RNA genes were detected by fluorescence in-situ hybridization and 3D images were obtained by confocal scanning laser microscopy. In both plant species, the 5S ribosomal genes were localized at the short arm of chromosome 2, which, in both plants, also possesses a satellite at its end. Statistical and visual analysis of interphase nuclei showed that: (1) there is a preference for an association of the 5S rRNA gene clusters of the two homologous chromosomes, and (2) the 5S rRNA gene clusters in both species had a preserved spatial position within the interphase nucleus and they tended to be polarized with respect to their neighbouring cells (i.e. a relic telophase orientation). Moreover, tracing of the chromosomal segment between the 5S loci and the active NOR revealed that the homologous chromosomes during early/mid prophase were aligned and that they entered the nucleolus side by side, at least for these chromosome segments. We interpret our data to mean that location of 5S rRNA near the nucleolus favours their functioning in ribosome biogenesis.

The spatial localization of T-DNA insertions in petunia interphase nuclei: consequences for chromosome organization and transgene insertion sites.

In an earlier fluorescent in-situ hybridization (FISH) study on petunia (ten Hoopen et al. 1996), we found a considerable discrepancy between the genetic map and the physical map with respect to T-DNA insertions on metaphase chromosomes. For some transgenes we found a preference to integrate near the telomeres. Here, we studied the spatial position of transgenes in interphase nuclei by FISH and 3D-confocal microscopy to elucidate a possible structural preference for the nuclear localization of transgenes. Three transgenes located near telomeres on three different metaphase chromosomes showed a much more internal distribution in interphase root meristem than the telomeres, whereas a proximal transgene appeared to be distributed in a random fashion. The results point to local differences in chromatin compacting along a chromosome. These differences might explain a preference for T-DNA insertion in distal regions of the chromosome.

Ultrastructural effects of AAL-toxin TA from the fungus Alternaria alternata on black nightshade (Solanum nigrum L.) leaf discs and correlation with biochemical measures of toxicity.

Ultrastructural effects of AAL-toxin TA from Alternaria alternata on black nightshade (Solanum, nigrum L.) leaf discs and correlation with biochemical measures of toxicity. In black nightshade (Solanum nigrum L.) leaf discs floating in solutions of AAL-toxin TA (0.01-200 microM) under continuous light at 25 degrees C, electrolyte leakage, chlorophyll loss, autolysis, and photobleaching were observed within 24 h. Electrolyte leakage, measured by the conductivity increase in the culture medium, began after 12 h with 200 microM AAL-toxin T(A), but was observed after 24 h with 0.01 to 50 microM AAL-toxin T(A), when it ranged from 25%) to 63% of total releasable electrolytes, respectively. After 48 h incubation, leakage ranged from 39% to 79% of total for 0.01 to 200 microM AAL-toxin T(A), respectively, while chlorophyll loss ranged from 5% to 32% of total, respectively. Ultrastructural examination of black night-shade leaf discs floating in 10 microM AAL-toxin TA under continuous light at 25 degrees C revealed cytological damage beginning at 30 h, consistent with the time electrolyte leakage and chlorophyll reduction were observed. After 30 h incubation chloroplast starch grains were enlarged in control leaf discs, but not in AAL-toxin T(A)-treated discs, and the thylakoids of treated tissue contained structural abnormalities. After 36-48 h incubation with 10 microM AAL-toxin T(A), all tissues were destroyed with only cell walls, starch grains, and thylakoid fragments remaining. Toxicity was light-dependent, because leaf discs incubated with AAL-toxin T(A) in darkness for up to 72 h showed little phytotoxic damage. Within 6 h of exposure to > or =0.5 microM toxin, phytosphingosine and sphinganine in black nightshade leaf discs increased markedly, and continued to increase up to 24 h exposure. Thus, phy siological and ultrastructural changes occurred in parallel with disruption of sphingolipid synthesis, consistent with the hypothesis that AAL-toxin T(A) causes phytotoxicity by interrupting sphingolipid biosynthesis, thereby damaging cellular membranes.

Ultrastructural determination of the early stage of conversion from root primordia to shoot primordia in vitro cultures of Solanum lycopersicoides Dun.

The object of the research were in vitro cultures of root primordia and the early stage of conversion from root to shoot primordia cultures (ESCRS) of Solanum lycopersicoides Dun. The cell ultrastructure of both culture types was studied in order to determine processes underlying the root and shoot morphogenesis type. It was found that a change of a morphogenesis type occurs together with reorganization of aggregate structure and the cell ultrastructural organization. There were 4 zones detected in root primordia culture aggregates (the surface, the starch, the division and the differentiation zone) and 3 zones in ESCRS culture aggregates (the surface, the inner and the differentiation zone). The differences were observed also in storage substances accumulated in a culture (starch in root primordia cultures; proteins, lipids and starch in ESCRS ones).

Polyamine binding to proteins in oat and Petunia protoplasts.

Previous work (A Apelbaum et al. [1988] Plant Physiol 88: 996-998) has demonstrated binding of labeled spermidine (Spd) to a developmentally regulated 18 kilodalton protein in tobacco tissue cultures derived from thin surface layer explants. To assess the general importance of such Spd-protein complexes, we attempted bulk isolation from protoplasts of Petunia and oat (Avena sativa). In Petunia, as in tobacco, fed radioactive Spd is bound to protein, but in oat, Spd is first converted to 1,3,-diaminopropane (DAP), probably by polyamine oxidase action. In oat, binding of DAP to protein depends on age of donor leaf and conditions of illumination and temperature, and the extraction of the DAP-protein complex depends upon buffer and pH. The yield of the DAP-protein complex was maximized by extraction of frozen-thawed protoplasts with a pH 8.8 carbonate buffer containing SDS. Its molecular size, based on Sephacryl column fractionation of ammonium sulfate precipitated material, exceeded 45 kilodaltons. Bound Spd or DAP can be released from their complexes by the action of Pronase, but not DNAse, RNAse, or strong salt solutions, indicating covalent attachment to protein.