Occurrence and identification of aster yellows related phytoplasma in Gladiolus in Poland

In 1996–1998 on Gladiolus plants cultivated in Poland severe symptoms were observed. The symptoms included chlorosis of the youngest leaves, yellowing and malformation of flower spices, flower discoloration and virescence. The affected corms kept in cold storage developed premature multiple sprouts weak and pale in color. Their root formation was strongly inhibited. Electron microscopy examination of the ultra-thin sections of the leaves and roots of diseased plants showed necrosis and collapsing of sieve tubes and companion cells, reduction of phloem and xylem strands as well as decrease of the number and diameter of xylem vessels. Numerous polymorphic bodies were observed in the phloem and parenchyma cells of affected gladioli. PCR amplification using universal phytoplasma primers rU3 and fU5 directed to ribosomal sequences and RFLP analysis of the amplified rDNA were used to identify the phytoplasma causing yellow disease in Poland. Specific product of about 880 bp was obtained, providing evidence of phytoplasma infection. RFLP analysis of the PCR product done with restriction enzyme AluI showed that the diseased gladioli were infected by phytoplasma very similar or identical with American aster yellows phytoplasma.     

Value of phloem necrosis in the diagnosis of potato leaf-roll

In plants infected with leaf-roll virus a type of phloem obliteration and necrosis occurs which is distinct from any abnormality produced by other pathogens or arising from physiological causes. The necrosis occurs in the primary phloem only of the bicollateral bundles. The affected tissue reacts with phloro-glucinol in HCI. It was present in all of 179 plants of 33 varieties showing secondary leaf-roll which were examined and was not found in any of 83 healthy plants of 20 varieties. The amount of necrosis varies in different plants. If the disease is severe, necrosis may extend to almost all parts of the plant except the stolon, tubers and roots. If the infection is mild it may be confined to a very few strands in two or three nodes near the base of the main stem. Phloem necrosis can always be found before leaf rolling is apparent.
In primary leaf-roll, slight necrosis can be found in the stem near the bases of the lowest rolled leaves and sometimes in the petioles.
A technique is suggested for the use of this symptom in diagnosis.     

HYPERPLASTIC PHLOEM IN SUGARBEET LEAVES INFECTED WITH THE BEET CURLY TOP VIRUS

Electron microscopy of sugarbeet leaves infected with the beet curly top virus confirmed earlier findings by light microscopy that the hyperplastic phloem consists mainly of sieve elements that are more or less abnormal in structure. Some parenchyma cells and occasional companion cells may be present. The hyperplastic phloem develops in the place of normal phloem and sometimes in the adjacent ground tissue and the xylem. The sieve elements vary in shape and may be haphazardly arranged. The protoplasts of the sieve elements have the usual characteristics of this type of cell. The sieve element plastids develop from chloroplasts if the hyperplasia occurs in chloroplast-containing parenchyma cells. The cell walls have sieve areas that often are less well differentiated than those of normal sieve elements. The hyperplastic growth in the phloem of curly top diseased plants is discussed with reference to plant tumors induced by certain other plant viruses.     

Aster Yellows Subgroup 16SrI‐C Phytoplasma in Rhododendron hybridum

Symptoms of unknown aetiology on Rhododendron hybridum cv. Cunningham's White were observed in the Czech Republic in 2010. The infected plant had malformed leaves, with irregular shaped edges, mosaic, leaf tip necrosis and multiple axillary shoots with smaller leaves. Transmission electron microscopy showed phytoplasma‐like bodies in phloem cells of the symptomatic plant. Phytoplasma presence was confirmed by polymerase chain reaction using phytoplasma‐specific, universal and group‐specific primer pairs. Restriction fragment length polymorphism analysis of 16S rDNA enabled classification of the detected phytoplasma into the aster yellows subgroup I‐C. Sequence analysis of the 16S‐23S ribosomal operon of the amplified phytoplasma genome from the infected rhododendron plant (1724 bp) confirmed the closest relationship with the Czech Echinacea purpurea phyllody phytoplasma. These data suggest Rhododendron hybridum is a new host for the aster yellows phytoplasma subgroup 16SrI‐C in the Czech Republic and worldwide.     

木立芦荟叶内维管束发育过程的研究

采用半薄切片和组织化学方法研究了木立芦荟（Aloe arhorescetzs）叶内维管束的发育过程,并着重于维管束鞘细胞和芦荟素细胞的来源及组织类型。结果表明：维管束由原形成层发育而来,但在分化原生韧皮部筛管时,其外侧仍保留一层原形成层细胞,以后分裂、增大成为特殊的大型薄壁细胞（芦荟素细胞）,芦荟索细胞啦属于韧皮部的一部分。而维管束鞘细胞则来源于基本分生组织,属于基本组织的范畴,与维管束不同源。     

Light- and Electron Microscopic Studies of Cherry Leaf Roll Virus (CLRV) on European Ash (Fraxinus excelsior L.)

Deformed leaves of CLRV-infected ash trees exhibited hyperplasia of mesophyll cells, multilayered palisade parenchyma, undulated lower epidermis, and meandering vascular bundles. The development of phloem and xylem cells was greatly inhibited. In tissues from chlorotic ringspots and line patterns, chloroplasts were highly inflated by starch grains and phloem necrosis could be observed. Plasmodesms in these tissues were dilated and revealed enhanced contrast. Fingerlike protrusions of polysaccharidic material enclosed the elongations of plasmodesms. Vesiculated paramural bodies were connected with altered plasmodesms. Virus-like particles could neither be observed in altered plasmodesms nor elsewere in the cytoplasm. Chloroplasts in infected tissues frequently were deformed as a result of cytoplasmic invaginations. The outer chloroplast membrane protruded into the cytoplasm at several locations. Thylakoid membranes were partly dilated.     

Cytology of beet yellows virus infection inTetragonia

Summary This paper is the second in the series dealing with the ultrastructure ofTetragonia expansa Murr. infected with the beet yellows virus. It considers the relation of the virus to the conducting cells in the phloem and the xylem. Virus particles occurred in mature sieve elements, their amount increasing as the infected leaf became older. In older leaves some sieve elements were completely blocked with virus. Virus particles were seen in pores of sieve plates, in plasmodesmata interconnecting sieve elements and parenchyma cells, and in those between parenchyma cells. Mature and immature tracheary elements also contained virus particles. Presence of inclusions composed of vesicles and virus in some immature tracheary elements may indicate that virus multiplies in these cells. No vesicles and no virus particles were discovered in immature sieve elements.This work was supported in part by National Science Foundation grant GB-5506.     

Studies of the mycoplasma-like organism (MLO) in spinach leaves affected by the aster yellows disease

Summary Mycoplasma-like organisms (MLO) were found in the phloem of spinach (Spinacia oleracea L.) leaves infected with the agent of aster yellows disease by means of the leafhopperMacrosteles fascifrons Stål. The MLOs occurred mainly in mature sieve elements but were recorded in occasional phloem parenchyma cells as well. The MLO showed the typical features of this organism. The majority were ovoid or spherical, some were irregular in form or elongated. The larger bodies were commonly accompanied by small bodies which appeared to originate from the larger by budding. Profiles suggesting binary fission and filamentous forms containing ovoid condensations of cytoplasm were present. The bounding membrane showed the typical trilaminate structure, and DNA-like fibrils were discernible in those MLOs that had an electron lucent central region. In the denser bodies the fibrils were obscured. The MLO ribosomes were distinctly smaller than those in the host cytoplasm. The MLOs were degenerating in phloem cells that were disorganizing and collapsing in response to the infection. Structures in host cells that may be confused with MLO are described.This work was supported by the National Science Foundation grant GB-35228 to K. E and by Hatch and California Statewide Critical Applied Research Funds to the Departmem of Cell Physiology, University of California, Berkeley, California. The authors thank ProfessorJulius H.Freitag for providing the original strains of the aster yellows agent.     

Comparative anatomy and systematics of Catasetinae (Orchidaceae)

Catasetinae consist of five genera of pseudobulbous Orchidaceae of the Neotropics. Anatomy is characterized by sunken, three-celled foliar hairs, mostly tetracytic stomatal apparatuses, superficial stomata, homogeneous mesophyll, foliar fibre bundles, collateral vascular bundles in a single row, xylem and phloem sclerenchyma associated with vascular bundles in leaves, conical, and rough-surfaced silica bodies adjacent to vascular bundle sclerenchyma; epidermal cells of pseudobulbs with heavily thickened outer walls, pseudobulb ground tissue of assimilatory and water-storage cells, scattered vascular bundles in pseudobulbs, and sclerenchyma and stegmata associated only with phloem of pseudobulbs; roots with thin-walled velamen cells and tenuous spirals of cell wall material, distinctive epivelamen cells, thin-walled exodermal cells and vascular tissue embedded in parenchyma. Except for mucilaginous idioblasts that occur in Mormodes and Cycnoches , there are few outstanding anatomical differences among the five genera. Thus, there are few anatomical characteristics of phylogenetic value. The monophyly of Catasetinae is supported by the presence of sunken foliar hairs. Our results support a close relationship between Clowesia and Catasetum , and between Mormodes and Cycnoches. Among the outgroups Pteroglossaspis is especially distinctive.     

Virus-like particles in phloem tissue of chervil (Anthriscus cerefolium) infected with carrot red leaf virus

Isometric virus-like particles c. 22–25 nm in diameter were found in ultrathin sections of chervil leaves infected with carrot red leaf virus (CRLV). The particles were confined to the phloem and occurred in less than 5% of the cells in the vascular bundles. They were commonest in companion cells, occurred frequently in sieve elements and were also found in phloem parenchyma cells. The observations support other evidence that CRLV should be classified in the luteovirus group.     

Sites of accumulation in excised Phloem and vascular tissues

Excised pieces of vascular bundle and phloem tissue were allowed to accumulate radioactive phosphate and sulfate, and were then sectioned and autoradiographed so as to detect the sites of accumulation. Special methods were needed to prevent any diffusion of the radioisotope. Some autoradiographs obtained are presented. In excised celery vascular bundles, the most radioactive area and hence the most actively accumulating tissue was the young secondary phloem at the sides of the bundle. In intact plants, the same tissue was the most active in translocating. In excised apple phloem there was some variation in behavior, but again the young secondary phloem was generally the most actively accumulating tissue. Accumulation activities of individual cells in the phloem and vascular tissue were compared. It appeared that all cell types, ray, phloem and xylem parenchyma, cambial cells and sieve tubes, accumulated at least 5 times more actively than did the cortical parenchyma cells. The sieve tubes were among the most actively accumulating cells present, accumulating 20 times more actively than the cortical parenchyma cells. It is concluded that accumulation processes have a primary role to play in the mechanism of phloem transport.     

Comparative cytopathology of Crinivirus infections in different plant hosts

We used transmission electron microscopy to compare the cytopathology induced in plants by five criniviruses (genus Crinivirus; Lettuce infectious yellows virus (LIYV), Cucurbit yellow stunting disorder virus (CYSDV), Tomato infectious chlorosis virus (TICV), Tomato chlorosis virus (ToCV) and Beet pseudo‐yellows virus (BPYV) (Hartono et al., 2003)). We also compared the patterns of infection for plants and mesophyll protoplasts infected by LIYV and Beet yellows virus (BYV), type members of genera Crinivirus and Closterovirus, respectively. The main cytopathological effects induced in plants by criniviruses were common in young leaves and included alterations of the chloroplasts and the presence of BYV‐type inclusion bodies in companion cells. Virus‐like particles were present in sieve tubes and vascular parenchyma cells as scattered particles, or in companion cells as large masses forming cross‐banded inclusions. Depending on the virus and the plant, it was possible to find virions or virus‐like particles out of the phloem cells, but only in cells of the bundle sheath. Virion‐like particles were never found outside of the vascular tissue. Accumulation of electron‐dense material at the plasmalemma was common for criniviruses, but only LIYV infections produced characteristic conical electron‐dense plasmalemma deposits (PDs). The LIYV‐induced PDs have a crystalline‐like structure and were found at the internal side of plasmalemma.     

Molecular and microscopical detection of aster yellows phytoplasma associated with infected parsnip

Typical phytoplasma yellows symptoms were observed in parsnip (Pastinaca sativa L.) plants grown around Edmonton, Alberta, Canada. Examination of ultrathin sections of leaf midribs by electron microscopy revealed numerous phytoplasma bodies localized in the phloem cells. DNA extracted from the infected leaves was amplified with a 16S rDNA universal primer pair P1/P6 giving the expected PCR product of 1.5 kb. The phytoplasma was confirmed as a member of the aster yellows (AY) group by amplification with the specific primer pair R16(1)/F1/R1 that was designed on the basis of AY phytoplasma 16S rDNA sequences. In the nested PCR assays, the expected DNA fragment of 1.1 kb was amplified with this specific primer set. Similar restriction patterns were found for the 1.1 kb PCR products of the phytoplasma isolated from parsnip and an AY phytoplasma control after digestion with restriction endonucleases AluI, HhaI, KpnI and RsaI. This is the first reported observation of aster yellows in parsnip in Canada.     

Relation of beet yellows virus to the phloem and to movement in the sieve tube

In minor veins of leaves of Beta vulgaris L. (sugar beet) yellows virus particles were found both in parenchyma cells and in mature sieve elements. In parenchyma cells the particles were usually confined to the cytoplasm, that is, they were absent from the vacuoles. In the sieve elements, which at maturity have no vacuoles, the particles were scattered throughout the cell. In dense aggregations the particles tended to assume an orderly arrangement in both parenchyma cells and sieve elements. Most of the sieve elements containing virus particles had mitochondria, plastids, endoplasmic reticulum, and plasma membrane normal for mature sieve elements. Some sieve elements, however, showed evidence of degeneration. Virus particles were present also in the pores of the sieve plates, the plasmodesmata connecting the sieve elements with parenchyma cells, and the plasmodesmata between parenchyma cells. The distribution of the virus particles in the phloem of Beta is compatible with the concept that plant viruses move through the phloem in the sieve tubes and that this movement is a passive transport by mass flow. The observations also indicate that the beet yellows virus moves from cell to cell and in the sieve tube in the form of complete particles, and that this movement may occur through sieve-plate pores in the sieve tube and through plasmodesmata elsewhere.     

Comparative vegetative anatomy and systematics of Vanilla (Orchidaceae)

Vanilla is a pantropical genus of green-stemmed vines bearing clasping (aerial) and absorbing (terrestrial) roots. Most vanillas bear normal, thick foliage leaves; others produce fugacious bracts. Seventeen species, including both types were studied. Foliage leaves of Vanilla are glabrous, have abaxial, tetracytic stomatal apparatuses, and a homogeneous mesophyll. Species may or may not have a uniseriate hypodermis. Crystals occur in the foliar epidermises of some species, but all species have crystalliferous idioblasts with raphides in the mesophyll. Vascular bundles in leaves are collateral and occur in a single series alternating large and small. Sclerenchyma may or may not be associated with the vascular bundles. Scale leaves may be crescent or C-shaped and usually have abaxial stomatal apparatuses. A hypodermis may or may not be present; the mesophyll contains raphide bundles in idioblasts. Vascular bundles are collateral and occur in a single row sometimes aligned close to the adaxial surface. They may or may not be associated with sclerenchyma. Stems of leafy vanillas show a sclerenchyma band separating cortex from ground tissue; stems of leafless vanillas do not show a sclerenchyma band. Ground tissue of the stem may consist solely of assimilatory cells or mixed assimilatory and water-storage cells. In some species centrally located assimilatory cells are surrounded by layers of water-storage cells. A uniseriate hypodermis is present in all stems. Sclerenchyma may completely surround the scattered collateral vascular bundles, occur only on the phloem side, or be absent. Both aerial and terrestrial roots are notable for their uniseriate velamen the cell walls of which may be unmarked or ornamented with anticlinal strips. Exodermis is uniseriate; the cells vary from barely thickened to strongly thickened. Only the outer and radial walls are thickened. Cortical cells of aerial roots generally have chloroplasts that are lacking from the same tissue of terrestrial roots. Raphide bundles occur in thin-walled cortical idioblasts. Endodermis and pericycle are uniseriate; pericycle cells are all ?-thickened opposite the phloem. Cells of the endodermis are either ?- or ∪-thickened opposite the phloem. Vascular tissue may be embedded in thin- or thick-walled sclerenchyma or in parenchyma. Metaxylem cells are always wider in terrestrial than in aerial roots of the same species. Pith cells are generally parenchymatous but sclerotic in a few species.     

盾叶薯蓣根状茎的发育解剖学和组织化学研究

盾叶薯蓣根状茎顶端的生长点由鳞片包被,其衍生细胞分化为原表皮、基本分生组织和散生的原形成层束,以后分化为表皮、基本组织和散生的维管束构成的初生结构。根状茎顶端下方的原表皮内存在初生增厚分生组织,其细胞不断向内分裂和其衍生细胞的体积增大使根状茎能够迅速增粗。分化完成的根状茎主要由周皮、基本组织和散生的维管束构成。周皮由木栓层、木栓形成层和栓内层组成;基本组织由薄壁细胞组成;维管束属于有限维管束。薯蓣皂甙主要存在于基本组织薄壁细胞中。原分生组织和原形成层不含薯蓣皂甙,维管束的木质部和韧皮部中的韧皮纤维也无薯蓣皂甙的分布,韧皮部的生活细胞和维管束鞘细胞有薯蓣皂甙的积累。近顶端的基本分生组织细胞内薯蓣皂甙不形成液滴,随着细胞分裂逐渐停止,细胞内开始形成含薯蓣皂甙的液滴,反映皂甙是在成熟细胞内积累。其中,有小型维管束分布的基本组织中薯蓣皂甙的积累与分布最丰富,两年生根状茎中薯蓣皂甙的含量比一年生的高。     

The Behaviour of Two Cell Populations in the Pericycle of Allium cepa, Pisum sativum, and Daucus carota During Early Lateral Root Development

The length of cells of the pericycle, endodermis and middlecortex not actively involved in lateral root primordia (LRP)development was measured in primary roots of Allium cepa, Pisumsativum and Daucus carota. The presence of two cell populationsin the pericycle was demonstrated in all three species. In Alliumcepa and Pisum sativum, pericyclic cells located opposite xylempoles were significantly shorter than cells lying opposite phloempoles. In both species, LRP originated opposite xylem poles.Our results, furthermore, strongly suggest that in regions ofthe root far from the apical meristem, numerous pericyclic cellsundergo transverse division both previous to and during LRPinitiation, decreasing in mean length throughout this period.In Daucus carota, LRP begin to form in pericyclic cells locatednext to the phloem poles, such cells were significantly shorterthan those opposite xylem poles, even in areas of the primaryroot located close to the root tip. Cells also appear to dividetransversely in regions far from the root tip in this species,leading to a conspicuous drop in the mean length of those cellslocated in portions of the pericycle destined to give rise toLRP. Two different cell populations can also be distinguishedin the endodermis of Allium cepa and Pisum sativum, althoughobservations were less conclusive in Daucus carota. In all threespecies, length of cortical cells was unaffected by their positionopposite xylem or phloem poles Allium cepa, carrot, cell division, cell length, Daucus carota, endodermis, lateral root development, onion, pea, pericycle, Pisum sativum     

Plasmodesmatal frequency in relation to short-distance transport and phloem loading in leaves of barley (Hordeum vulgare). Phloem is not loaded directly from the symplast

We investigated the phloem loading pathway in barley, by determining plasmodesmatal frequencies at the electron microscope level for both intermediate and small blade bundles of mature barley leaves. Lucifer yellow was injected intercellularly into bundle sheath, vascular parenchyma, and thin-walled sieve tubes. Passage of this symplastically transported dye was monitored with an epifluorescence microscope under blue light. Low plasmodesmatal frequencies endarch to the bundle sheath cells are relatively low for most interfaces terminating at the thin- and thick-walled sieve tubes within this C₃ species. Lack of connections between vascular parenchyma and sieve tubes, and low frequencies (0.5% plasmodesmata per μm cell wall interface) of connections between vascular parenchyma and companion cells, as well as the very low frequency of pore-plasmodesmatal connections between companion cells and sieve tubes in small bundles (0.2% plasmodesmata per μm cell wall interface), suggest that the companion cell-sieve tube complex is symplastically isolated from other vascular parenchyma cells in small bundles. The degree of cellular connectivity and the potential isolation of the companion cell-sieve tube complex was determined electrophysiologically, using an electrometer coupled to microcapillary electrodes. The less negative cell potential (average –52 mV) from mesophyll to the vascular parenchyma cells contrasted sharply with the more negative potential (–122.5 mV) recorded for the companion cell-thin-walled sieve tube complex. Although intercellular injection of lucifer yellow clearly demonstrated rapid (0.75 μm s^-1) longitudinal and radial transport in the bundle sheath-vascular parenchyma complex, as well as from the bundle sheath through transverse veins to adjacent longitudinal veins, we were neither able to detect nor present unequivocal evidence in support of the symplastic connectivity of the sieve tubes to the vascular parenchyma. Injection of the companion cell-sieve tube complex, did not demonstrate backward connectivity to the bundle sheath. We conclude that the low plasmodesmatal frequencies, coupled with a two-domain electropotential zonation configuration, and the negative transport experiments using lucifer yellow, precludes symplastic phloem loading in barley leaves.     

The phloem necrosis virus disease of tea in Ceylon; further characterization of necrosis in the leaf

Phloem necrosis due to the virus disease of that name in tea is fully described as it affects the leaf, on which diagnosis is chiefly based. Originating in the protophloem, it may extend inwards to the metaphloem and outwards to the pericycle, causing the breakdown and discoloration of the cells and their eventual death and obliteration, cell enlargement, and the production of new thin-walled cells by hyperplasia. The condition is termed 'true necrosis' to distinguish it from the non-pathogenic 'false necrosis', of unknown cause, which originates typically in the metaphloem but may have the same histological effects except for the absence of hyperplasia. In the petiole, the visual distinction between 'true' and 'false' necrosis on the basis of their position as seen in a transverse section of the bundle is relatively easy, and the continued use of this method of diagnosis is recommended. No such distinction can reliably be made in the midrib, where 'false' necrosis often occurs in the same position as 'true' necrosis, i.e. immediately within the pericycle. This is interpreted ontogenetically in terms of the smaller total width of the phloem in the midrib as compared with the petiole bundle; it effectively prevents the use of the midrib for diagnosis. The observations are discussed in terms of the inherent properties of the phloem, as affected by viruses and other agencies reported to have caused necrosis, among plants in general.     

牛膝根的结构发育与三萜皂苷积累的关系

应用植物解剖学、组织化学定位及植物化学技术,研究了不同发育时期牛膝根的结构特征与三帖皂苷积累的关系。结果表明:牛膝根的初生结构和次生结构类似于一般双子叶植物,其根的加粗主要是由于三生结构的发生和分化。第一圈额外形成层产生于次生韧皮部外侧的薄壁组织细胞和射线细胞,以后的每一圈由前一圈向外衍生的薄壁组织细胞产生。额外形成层无纺锤状原始细胞和射线原始细胞之分,在切向纵切面上呈叠生排列。三生维管束以离心方式排成整齐的同心环状,由薄壁结合组织将其彼此分开,其圈数与额外形成层的圈数是一致的,随着根的个体发育而不断增加。在根的初生结构中,三萜皂苷主要分布于中柱鞘、初生韧皮部及初生韧皮部和初生木质部之间的薄壁组织细胞内;在根的次生结构中,主要分布于次生韧皮部及栓内层的薄壁组织细胞内。当三生结构形成后,除次生韧皮部及栓内层细胞外,在额外形成层和三生维管束韧皮部细胞内均有皂苷类物质积累。三生结构在牛膝根中占主要地位,是三萜皂苷积累与分布的主要场所。在牛膝根的生长发育过程中,三萜皂苷元齐墩果酸的百分含量呈“S”型曲线增长,其根的增长、加粗、三生维管束圈数、三萜皂苷总量及根中干重的积累量都在出苗后约120天达到高峰,此时应为牛膝根的最佳采收期。