An Examination of the Refractometric Method for Determining the Water Potential of Plant Tissues

Some sources of error in refractometric determinations of waterpotential are examined and methods of correcting for them oravoiding them are discussed, as well as their relevance to Shardakov’s(Schlieren) method. The sources of the exudation from cut tissues,which causes a rise in the refractive index of water and affectsthat of solutions, are investigated. The exudation consistsmainly of sap released from cut and damaged cells. The amountof sap exuded is independent of the concentration of the externalsolution. A method of estimating the extent of the error thusincurred in water potential determinations is described. Errorarising also from the admixture of cell-wall water to the referencesolutions, lowering their effective concentration, and othersources of error are briefly described. A method of eliminating the curvature in graphs of change ofrefractive index plotted against molarity is suggested. Themethod permits the data from all concentrations to be used indetermining the null point for water exchange, instead of thosenear to the null point only.     

The Derivation of the Cell Wall Elasticity Function from the Cell Turgor Potential

An equation is derived expressing average turgor pressure ofa leaf (_p) as a function of relative water content (RWC). Basedon this derivation, the relationships of the bulk elastic modulus(_v) and both RWC and _p, are formulated and discussed. The bulkelastic modulus (_v) becomes zero for _p = 0, that is at the turgorloss point for the leaf. At full water saturation the valueof ev is proportional to the water saturation turgor potential_p(max). The factor relating _P and _v (structure coefficient ,Burstrom, Uhrstr?m and Olausson, 1970) changes only very littlefor values of _p, which are not too close to zero. An exampleis given for the calculation from experimental data of the turgorpressure function, the structure coefficient function, and the_v function. Key words: Cell wall, Turgor pressure, Bulk elastic modulus     

Regulators of Cell Division in Plant Tissues

The cytokinins, 6-benzylaminopurine and kinetin, markedly enhanced the yield of both free and membrane-bound 80S ribosomes per unit weight of radish (Raphanus sativus) cotyledon tissue. The response was observed only after the induction of growth by cytokinin; during the lag period preceding cytokinin-induced growth, ribosome yields from both control and cytokinin-treated cotyledons were below detectable levels. Mannitol depressed both growth and ribosome yield to the same degree. The enhanced ribosome yield appeared to be an indirect effect of cytokinin and was probably a consequence of cytokinin-induced growth. The effect of 6-benzylaminopurine on ribosome yield was not reflected in enhanced levels of cytoplasmic ribosomal RNA, while recently synthesized ribosomes were found to be more readily recovered from cytokinin-treated tissue than from control tissue. It was concluded that cytokinin-enhanced ribosome yield resulted from enhanced ribosome recovery or extractability and that ribosome yield is an unreliable indication of ribosome level in plant tissue.     

Regulators of Cell Division in Plant Tissues

Procedures were devised for purification of the cytokinins in the milk of mature coconuts (Cocos nucifera fruits). One cytokinin isolated in crystalline form was unequivocally identified as 9-β-D-ribofuranosylzeatin. This compound appeared to account for a large proportion of the cytokinin activity in n-butanol extracts of coconut milk. The activity which was not extracted by n-butanol was largely due to unidentified compounds which could be partially purified by adsorption onto and elution from charcoal.     

High Resolution Imaging of Plant Tissues10

Connelly, A., Lohman, J. A. B., Loughman, B. C., Quiquampoix,H. and Ratcliffe, R. G. 1987. High resolution imaging of planttissues by NMR.—J. exp. Bot. 38: 1713–1723. NMR images of living plant tissues were recorded at a ¹H frequencyof 200 MHz using a high resolution imaging technique that gavean in-plane pixel resolution of 50 µm x 50 µm orbetter. Images with interpretable contrast were obtained fromgerminating seeds, the roots of seedlings and the stems of youngplants. The expected structural features of these tissues werereadily observed including, in Mn²⁺ loaded tissue, the xylemvessels of maize root sections. Preliminary experiments on H₂O-D₂Oexchange in maize roots, on the uptake of Mn²⁺ by maize rootsand on the germination of seeds in situ demonstrate that thenon-invasive method of NMR mini-imaging has the potential tocomplement existing techniques for physiological investigationsin plant tissues. Key words: NMR imaging, water content, ion uptake     

Microanalysis of Plant Cell Wall Polysaccharides

Oligosaccharide Mass Profiling （OLIMP） allows a fast and sensitive assessment of cell wall polymer structure when coupled with Matrix Assisted Laser Desorption Ionisation Time Of Flight Mass Spectrometry （MALDI-TOF MS）. The short time required for sample preparation and analysis makes possible the study of a wide range of plant organs, revealing a high degree of heterogeneity in the substitution pattern of wall polymers such as the cross-linking glycan xyloglucan and the pectic polysaccharide homogalacturonan. The high sensitivity of MALDI-TOF allows the use of small amounts of samples, thus making it possible to investigate the wall structure of single cell types when material is collected by such methods as laser micro-dissection. As an example, the analysis of the xyloglucan structure in the leaf cell types outer epidermis layer, entire epidermis cell layer, palisade mesophyll cells, and vascular bundles were investigated. OLIMP is amenable to in situ wall analysis, where wall polymers are analyzed on unprepared plant tissue itself without first isolating cell walls. In addition, OLIMP enables analysis of wall polymers in Golgi-enriched fractions, the location of nascent matrix polysaccharide biosynthesis, enabling separation of the processes of wall biosynthesis versus post-deposition apoplastic metabolism. These new tools will make possible a semi-quantitative analysis of the cell wall at an unprecedented level.     

植物原生质体的细胞壁再生

细胞壁作为植物细胞重要的组成部分,在决定细胞形状、维持机械支撑、吸收养分等方面发挥重要功能.因此,揭示植物细胞壁合成的调控机制具有重大的生物学意义.基于植物组织水平研究细胞壁的生物合成具有难以控制时间尺度、观察空间狭小等局限性.原生质体作为去除细胞壁的单个细胞是研究细胞壁再生的理想系统.在过去的几十年里报道了大量关于植...     

Tissue-Specific Expression of Cell Wall Proteins in Developing Soybean Tissues

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.     

Phase Separation of Plant Cell Wall Polysaccharides and Its Implications for Cell Wall Assembly

Concentrated binary mixtures of polymers in solution commonly exhibit immiscibility, resolving into two separate phases each of which is enriched in one polymer. The plant cell wall is a concentrated polymer assembly, and phase separation of the constituent polymers could make an important contribution to its structural organization and functional properties. However, to our knowledge, there have been no published reports of the phase behavior of cell wall polymers, and this phenomenon is not included in current cell wall models. We fractionated cell walls purified from the pericarp of unripe tomatoes (Lycopersicon esculentum) by extraction with cyclohexane diamine tetraacetic acid (CDTA), Na2CO3, and KOH and examined the behavior of concentrated mixtures. Several different combinations of fractions exhibited phase separation. Analysis of coexisting phases demonstrated the immiscibility of the esterified, relatively unbranched pectic polysaccharide extracted by CDTA and a highly branched, de-esterified pectic polysaccharide present in the 0.5 N KOH extract. Some evidence for phase separation of the CDTA extract and hemicellulosic polymers was also found. We believe that phase separation is likely to be a factor in the assembly of pectic polysaccharides in the cell wall and could, for example, provide the basis for explaining the formation of the middle lamella.     

Measurement of the Water Potential of Intact Plant Tissues1

A modified design of a thermocouple psychrometer is describedwhich utilizes the Peltier effect for producing an exceedinglysmall wet-bulb thermometer. The thermocouple assembly has beenreduced to miniature dimensions and the thermocouple chamberconsists of a silver cylinder (volume 0.06 cm³) whose base isformed by the material under observation. This makes it possibleto measure water potentials over limited surfaces of intactplant tissues, e.g. germinating pea seeds (Pisum sativum L.).The apparatus is capable of measuring water potentials downto a magnitude of about –6,000 joules/kg.³     

Estimation of the Anion-Exchange Capacity of the Cell Wall of Nitella flexilis

Diffusion potentials in KCI and triphenyl phosphonium chloride(TPP) solutions have been measured across an isolated cell wallof Nitella flexilis either after pretreatment by difluoronitrobenzene(DFNB), a compound which reacts with the protein amino groups,or after alkalization of the external solutions. In both cases,it appears that the cationic transport numbers are enhancedwith respect to the controls. These data suggest that the maineffect of the two treatments was to deprive the wall of positivecharges carried by protonized amino groups. The changes in t_Kwere used to roughly estimate the anion-exchange capacity ofthe wall.     

一种植物细胞壁松驰蛋白: 膨胀素

在植物细胞的生长过程中 ,多糖和蛋白质分泌到细胞壁里层 ,并形成具有一定机械强度的网络 ,这个网络是能伸展的 ,除非细胞停止生长。在细胞的生长过程中 ,一种细胞壁蛋白—膨胀素首次被鉴定出来具有使细胞壁的多糖网络疏松的能力 ,从而使膨压驱动的细胞扩大。膨胀素由两个多基因家族即α -膨胀素和 β -膨胀素多基因家族编码 ,每种基因的表达具有部位和细胞类型的特异性 ,但最新的研究也表明拟南芥中的膨胀素可以分为三个亚家族。越来越多的膨胀素基因从各种植物中鉴定出来 ,系统分析显示它们可能从一个共同的祖先基因进化而来。膨胀素的作用机理研究的还不是很清楚 ,但因为它们具有特别的功能 ,因此展现出良好的工业化应用前景。     

615小鼠ES细胞集落的分离及初步鉴定

目的　分离和培养 6 15小鼠的ES细胞集落 ,为建系打下基础。方法　以PMEF为饲养层分离 6 15小鼠的ES细胞集落 ,进行无饲养层培养 ,并对其进行初步鉴定。结果　ES细胞集落的出现率和传代成功率为 2 2 6 %和 0 94 % ,其ALP染色阳性 ,具有稳定的二倍体核型 ,可自发分化为多种类型的细胞。结论　成功分离和培养了6 15小鼠的ES细胞集落     

Effect of Alfalfa Wilts on the Hydroxyproline Content in Cell Wall

The Hyp content was studied in cell wall of alfalfa susceptible and resistant strains on the 3rd, the 7th and on the 14th day after inoculation with Verticillium albo-atrum or Corynebacterium michiganense pv. insidiosum. The changes of Hyp content after inoculation with both pathogens were markedly expressed in alfalfa roots. Resistant plants of R 337 strain responded to inoculation with V. albo-atrum or C. michiganense pv. insidiosum by the decrease of Hyp content mainly on the 3rd and on the 7th day. On the 14th day after inoculation Hyp content practically did not differ from that of the control. Susceptible plants of S 354 and S 321 srains responded to inoculation with wilt pathogens by the slight decrease of Hyp content at the 3rd day after inoculation. A significant increase of Hyp content was found on the 7th and mainly on the 14th day after inoculation in comparison with control plants. The cell wall Hyp content was also determined with 7 R-strains and 7 S-strains at 120 days after inoculation with both pathogens. In each R and S strain two categories of plants were used for chemical analyses: Wilt-free plants (0 to 1 classes) and diseased, wilted plants (2 to 6 classes). In the resistant alfalfa strains no differences in Hyp content between the wilt-free and diseased plants were found. In the susceptible alfalfa strains the Hyp content was significantly higher in roots of diseased plants comparing with the wilt-free ones. Only negligible changes in Hyp content were registered in the overground parts of all inoculated alfalfa strains.     

Use of the Plant Defense Protein Osmotin To Identify Fusarium oxysporum Genes That Control Cell Wall Properties

Fusarium oxysporum is the causative agent of fungal wilt disease in a variety of crops. The capacity of a fungal pathogen such as F. oxysporum f. sp. nicotianae to establish infection on its tobacco (Nicotiana tabacum) host depends in part on its capacity to evade the toxicity of tobacco defense proteins, such as osmotin. Fusarium genes that control resistance to osmotin would therefore reflect coevolutionary pressures and include genes that control mutual recognition, avoidance, and detoxification. We identified FOR (Fusarium Osmotin Resistance) genes on the basis of their ability to confer osmotin resistance to an osmotin-sensitive strain of Saccharomyces cerevisiae. FOR1 encodes a putative cell wall glycoprotein. FOR2 encodes the structural gene for glutamine:fructose-6-phosphate amidotransferase, the first and rate-limiting step in the biosynthesis of hexosamine and cell wall chitin. FOR3 encodes a homolog of SSD1, which controls cell wall composition, longevity, and virulence in S. cerevisiae. A for3 null mutation increased osmotin sensitivity of conidia and hyphae of F. oxysporum f. sp. nicotianae and also reduced cell wall β-1,3-glucan content. Together our findings show that conserved fungal genes that determine cell wall properties play a crucial role in regulating fungal susceptibility to the plant defense protein osmotin.Studies of plant-pathogen interactions strongly suggest that under the pressure to survive, plants and pathogens continuously react to one another''s defense arsenal and evolve to overcome these defenses (13). Plants recognize pathogen-associated molecular patterns, such as fungal cell wall fragments composed of chitin, glucans, oligosaccharides, or glycoprotein peptides (32). It has been established that pathogens evolved effector proteins to avoid plant surveillance mechanisms that recognize pathogen-associated molecular patterns and this in turn led to the evolution of plant surveillance mechanisms that recognize pathogen-specific effector proteins. All pathogen recognition mechanisms induce intracellular signaling that culminates in the synthesis of factors, such as antimicrobial plant proteins, that help in limiting the severity of infection (74). The antimicrobial proteins are therefore among the ultimate effectors of plant defense. There is evidence of recognition between plant antimicrobial proteins and pathogen-specific molecules (74). Therefore, pathogen mechanisms of resistance to the antimicrobial proteins and the antimicrobial proteins themselves must have coevolved. Consequently, we postulated that a screen for fungal genes that alter the sensitivity of a phytopathogen to an antifungal protein of the host plant (that is, a cognate plant defense effector) would lead to identification of genes involved in controlling pathogenicity, in controlling access of the antifungal protein to its target fungal molecules (such as genes controlling cell surface composition), and in controlling detoxification mechanisms.The plant antifungal protein selected to test this hypothesis was osmotin. Osmotin is an antifungal protein that is overexpressed in and secreted by salt-adapted cultured tobacco (Nicotiana tabacum) cells (63). It is a member of a family of ubiquitous plant proteins, referred to as plant pathogenesis-related proteins of family 5 (PR-5), that are implicated in defense against fungi (74). Osmotin gene and protein expression is induced by biotic stresses, and overexpression of osmotin delays development of disease symptoms in transgenic plants (41, 42, 43, 84). The genetic bases of the susceptibility and resistance of Saccharomyces cerevisiae to osmotin have been explored in our laboratory (49, 50). The results show that specific interactions of osmotin with the plasma membrane are responsible for cell death signaling. However, because the cell wall governs access of osmotin to the plasma membrane, differences in cell wall composition largely account for the differential osmotin sensitivity of various S. cerevisiae strains, and specific cell wall components play a significant role in modulating osmotin toxicity (30, 31, 49, 50, 81, 82). These studies in the model nonpathogenic fungus, S. cerevisiae, support our hypothesis that a screen for genes that alter the sensitivity of a phytopathogenic fungus to an antifungal defense effector protein of the host plant will uncover genes involved in controlling access of the antifungal protein to its target fungal molecules.Osmotin, like other plant defense antifungal proteins, has specific but broad-spectrum antifungal activity (74). One of the most osmotin-sensitive phytopathogenic fungi is Fusarium oxysporum. F. oxysporum is an ascomycete fungus, like S. cerevisiae, and has been touted as an appropriate multihost model for studying fungal virulence (53). It is a soilborne plant pathogen of economic significance, because it causes vascular wilt disease on a large variety of crop plants and produces toxic food contaminants (17, 58). In humans it also causes skin, nail, and eye disease that can become serious or life-threatening illnesses in immunocompromised patients (52, 69). F. oxysporum f. sp. lycopersici, F. oxysporum f. sp. nicotianae, and F. oxysporum f. sp. meloni, like S. cerevisiae, are quite sensitive to osmotin (1, 51; M. L. Narasimhan, unpublished data). Furthermore, it was recently shown that overexpression in F. oxysporum f. sp. nicotianae of an S. cerevisiae cell wall glycoprotein that increases the osmotin resistance of S. cerevisiae also increases the osmotin resistance of the plant pathogen and its virulence on tobacco, the osmotin-producing host plant (51). This suggested that osmotin resistance mechanisms may be conserved between S. cerevisiae and F. oxysporum and that S. cerevisiae could be used as a tool to uncover F. oxysporum genes that control osmotin sensitivity or resistance.In the current study, we expressed an F. oxysporum f. sp. nicotianae cDNA library in the osmotin-sensitive S. cerevisiae strain BWG1-7a and selected genes for their ability to increase osmotin tolerance. We report here the identification and characterization of three FOR (Fusarium Osmotin Resistance) genes that affect the cell wall in S. cerevisiae. The product of FOR1 has homology with a putative cell surface glycoprotein; FOR2 encodes glutamine:fructose-6-phosphate amidotransferase (GFAT), an enzyme that catalyzes the first step in the biosynthetic pathway leading to amino sugar-containing macromolecules, such as glycoproteins and chitin (64); and FOR3 has high homology with S. cerevisiae SSD1, a gene that controls cell wall composition and virulence (31, 78). FOR2 and FOR3 are the functional equivalents of the corresponding S. cerevisiae genes. Our parallel analysis using two model fungi verifies the notion that cell wall proteins play a critical role in determining the sensitivity/resistance of fungi to osmotin. In addition, these results implicate that the tobacco defense protein, osmotin, can serve as an effective/useful tool in identifying genes that control cell wall composition not only in a model fungus, such as S. cerevisiae, but also in phytopathogenic fungi, such as F. oxysporum.     

Cell Wall Composition and Ruminant Digestibility of Various Maize Tissues Across Development

Maize stover, including stalks, leaves, and cobs, has potential utility as a cellulosic biofeedstock. Understanding how total stover ethanol potential is affected by the proportion and quality of major plant components would facilitate the genetic improvement of stover quality and inform decisions regarding which plant parts should be targeted for harvesting. Our objectives were to determine how the proportion and composition of plant components affected ethanol potential and whether there are early season predictors of stover quality at maturity. Twenty-three hybrids were evaluated including 20 from a factorial mating design between five silage inbred lines and four commercial inbreds and a brown-midrib3, a Leafy1, and a commercial grain hybrid checks. Plants were harvested and dissected into component parts at developmental stages vegetative 3, vegetative 12, reproductive 3, and reproductive 6 (R6). Tissues were evaluated for acid detergent fiber (ADF), neutral detergent fiber (NDF), and NDF digestibility (NDFD). Stalk was the largest fraction of whole plant dry matter (46.2%) and had the lowest NDFD (3,750 g/kg) at R6. No relationship was found between stalk ADF at early developmental stages and whole plant ADF at R6, suggesting that quality at early developmental stages is not indicative of quality at physiological maturity. Differences were observed among hybrids for ADF and NDF for most plant parts evaluated. Hybrid-by-developmental stage and hybrid-by-plant part interactions were statistically significant. This indicates that there is minimal opportunity to identify superior hybrids for biofuel production based on the proportion of total biomass represented by a plant part and its quality at early developmental stages. Maximum conversion efficiency is attained when leaves are harvested compared to other tissue types at physiological maturity.     

Staining Raw and Cooked Apple Tissues for Study of Cell Wall Structure

Permanent preparations were made of paraffin sections from raw and cooked apple tissues stained with microchemical color reagents for pectins and pentosans. Sections stained with ruthenium red to show pectins were dehydrated and covered in balsam, and sections stained with diphenylene diamine acetate (DDA) to show pentosans were washed with water and covered in Clearcol.

Cooking was accomplished by steaming cubed histological samples. Both raw and steamed specimens were fixed in FAA in a vacuum chamber, dehydrated and cleared in tertiary butyl alcohol, and embedded in paraffin. Paraffin sections first fixed to slides with Haupt's adhesive were further stabilized by immersing in a 1% celloidin solution after dissolving the paraffin.

Ruthenium oxychloride flakes were dissolved in a Coplin jar of water containing 2 drops of ammonium hydroxide. Rehydrated sections were stained in ruthenium red 30 minutes and rinsed in water. Three methods of further preparation follow: (1) Flood sections with 10% gum arabic; drain and air-dry thoroughly; immerse in xylene 5 minutes; cover in balsam. (2) Drain and air-dry sections; if desired, counterstain dry sections with Johansen's fast green solution; immerse in xylene; cover in balsam. (3) Dehydrate by dipping in 70%, 95%, and absolute ethyl alcohol; immerse in xylene; cover in balsam.

DDA was made by heating 15 g. of benzidine in 150 ml. of glacial acetic acid and 450 ml. of water until dissolved, then adding water to make 750 ml. of solution. Rehydrated sections were stained 4 hours in DDA, washed, stained 5 minutes in Congo red (Congo red, 5 g.; NaOH, 5 g.; water, 100 ml.), washed, and covered in Clearcol.

An Autotechnicon was used for dehydration, clearing, infiltration, deparaffinizing sections, and staining. Procedures that necessarily remained manual were fixation in a vacuum chamber, and all operations that followed staining.

Ruthenium red, though the best available indicator for pectins, may not be specific for these substances. DDA and ruthenium red stained identical structures in hypodermis and cortex. DDA also stained cuticle, hence was more useful than ruthenium red for delineating that portion. DDA sections were better for photomicrography, and for measuring thickness of cell walls. Neither stain prevented the study of cell walls in polarized light.