Chemical, Biological, and Structural Properties of Stable Proteus L Forms and Their Parent Bacteria

Proteus L forms were disrupted by osmotic shock, and the sedimentable material present in the homogenate was further fragmented in a Sorvall pressure cell. The pressure cell was also used for disrupting normal Proteus cells. The homogenates obtained were fractionated by differential centrifugation. Purified endotoxins were isolated from the major fractions by phenol extraction. Material extracted with phenol from the membrane fraction of the L forms was about as toxic and pyrogenic on a weight basis as the typical enterobacterial endotoxins isolated from cell walls of normal bacteria. The yield of extract from L forms was about one-third of that from an equal weight of normal bacteria. No differences in the gross chemical composition of the phenol extracts from the L forms and the normal cells could be ascertained. A close serological relationship existed between extracts obtained from two L forms and their respective parent bacteria, but no such relationship was found in the case of the third L form studied and its parent bacterium. Diaminopimelic acid was not detected in the membranes of the L forms, but these membranes contained most of the succinic dehydrogenase of the organisms. Only small amounts of this enzyme were present in the wall fraction of normal bacteria. The data obtained suggest that precursors of the Proteus endotoxins are formed either in the soluble protoplasm of normal cells and L forms or at sites on the membrane from which they are readily liberated into the protoplasm, whereas the final steps of the synthesis of these toxins take place at the cytoplasmic membrane. In normal cells, much endotoxin is transported to and concentrated in the walls.     

Positional differentiation for development along the sporangiophore in <Emphasis Type="Italic">Phycomyces blakesleeanus</Emphasis>

 Small segments of Phycomyces sporangiophores regenerate various structures on incubation in a moist chamber. We tested the regeneration capacities of middle sporangiophore segments whose protoplasm had been totally or partially removed and replaced with protoplasm from various segments of a genetically different strain. The structures that were regenerated depended on the source of the injected protoplasm (sporangia of various sizes and segments from middle and basal parts of the sporangiophores), implying a positional differentiation of protoplasm along the sporangiophore axis. Protoplasm from various sources showed a high affinity; that is, they mixed successfully and led, in most cases, to the formation of heterokaryotic regenerating structures. The highest affinity was seen when mixing protoplasm from the middle segments of two different strains. Received: November 29, 2000 / Accepted: March 19, 2002     

Response of Xylem Ray Parenchyma Cells of Red Osier Dogwood (Cornus sericea L.) to Freezing Stress (Microscopic Evidence of Protoplasm Contraction)

Freezing behavior of wood tissue of red osier dogwood (Cornus sericea L.) cannot be explained by current concepts of freezing resistance. Previous studies indicated that water in wood tissue presumably froze extracellularly. However, it was observed that xylem ray parenchyma cells within these tissues could survive temperatures as low as -80[deg]C and the walls of these cells did not collapse during freezing (S.R. Malone and E.N. Ashworth [1991] Plant Physiol 95: 871-881). This observation was unexpected and is inconsistent with the current hypothesis of cell response during freezing. Hence, the objective of our study was to further examine the mechanism of freezing resistance of wood tissue of red osier dogwood. We studied freezing stress response of xylem ray parenchyma cells of red osier dogwood using freeze substitution and transmission electron microscopy. Wood samples were collected in winter, spring, and summer of 1992. Specimens were cooled from 0[deg]C to -60[deg]C at 5[deg]C/h. Freezing stress did not affect the structural organization of wood tissue. However, the xylem ray parenchyma cells showed two unique responses to a freezing stress: protoplasm contraction and protoplasm fragmentation. Protoplasm contraction was evident at all freezing temperatures and in tissues collected at different times of the year. Cells with fragmented protoplasm, however, were noticed only in tissues collected in spring and summer. Protoplasm contraction in winter tissue occurred without apparent damage to the protoplasm. In contrast, protoplasm contraction in spring and summer tissues was accompanied by substantial damage. No evidence of intracellular ice formation was observed in parenchyma cells exposed to freezing stress. Differences in protoplasm contraction and appearance of cells with fragmented protoplasm likely indicated seasonal changes in cold hardiness of the wood tissue of red osier dogwood. We speculate that the appearance of fragmented protoplasm may indicate that cells are being injured by an alternative mechanism in spring and summer.     

The Cell and Protoplasm as Container,Object, and Substance, 1835–1861

This article revisits the development of the protoplasm concept as it originally arose from critiques of the cell theory, and examines how the term “protoplasm” transformed from a botanical term of art in the 1840s to the so-called “living substance” and “the physical basis of life” two decades later. I show that there were two major shifts in biological materialism that needed to occur before protoplasm theory could be elevated to have equal status with cell theory in the nineteenth century. First, I argue that biologists had to accept that life could inhere in matter alone, regardless of form. Second, I argue that in the 1840s, ideas of what formless, biological matter was capable of dramatically changed: going from a “coagulation paradigm” (Pickstone, 1973) that had existed since Theophrastus, to a more robust conception of matter that was itself capable of movement and self-maintenance. In addition to revisiting Schleiden and Schwann’s original writings on cell theory, this article looks especially closely at Hugo von Mohl’s definition of the protoplasm concept in 1846, how it differed from his primordial utricle theory of cell structure two years earlier. This article draws on Lakoff and Johnson’s theory of “ontological metaphors” to show that the cell, primordial utricle, and protoplasm can be understood as material container, object, and substance, and that these overlapping distinctions help explain the chaotic and confusing early history of cell theory.     

猪苓菌核结晶及厚壁细胞的起源与发育

猪苓菌核的含晶细胞发生于菌丝中间或顶端,该细胞具有体积大、细胞质丰富等特点;结晶是由细胞质中的微小颗粒沉积于液泡中逐渐发育而成,液泡周围常有数量较多的线粒体分布,结晶发育至一定大小时细胞壁破裂释放出结晶,单个结晶在菌核中可聚集成大的棱状晶体。厚壁细胞产生于菌丝中间,与两端细胞以横隔膜相隔,细胞质收缩的同时胞壁加厚,厚壁细胞发育至仅留很小胞腔或完全被加厚物质充满时,可与相邻菌丝细胞分离;猪苓菌核厚壁细胞与有些真菌无性厚壁孢子的形成类同,但其大小不等在5～30μm之间。     

DISSIMILARITY OF INNER AND OUTER PROTOPLASMIC SURFACES IN VALONIA

The protoplasm of Valonia macrophysa forms a delicate layer, only a few microns in thickness, which contains numerous chloroplasts and nuclei. The outer surface is in contact with the cell wall, the inner with the vacuolar sap. As far as microscopic observation goes, these two surfaces seem alike; but measurements of potential difference indicate that they are decidedly different. We find that the chain sap | protoplasm | sap gives about 14.5 millivolts, the inner surface being positive to the outer. In order to explain this we may assume that the protoplasm consists of layers, the outer surface, X, differing from the inner surface, Y, and from the body of the protoplasm, W. We should then have the unsymmetrical chain sap | X | W | Y | sap which could produce an electromotive force. If the two surfaces of such a very thin layer of protoplasm can be different, it is of fundamental significance for the theory of the nature of living matter.     

Localization of crystals in diseased oats treated with uranyl acetate

Uranyl acetate, a suppressor of victorin-induced electrolyte leakage in oat leaves when applied together with, or before, victorin, also suppressed victorin-induced changes in ultra-structure. Uranyl crystallized in cell walls and near the plasmalemma of vascular cells, but was excluded from the protoplasm. Fewer crystals occurred near the plasmalemma when leaves were allowed to take up uranyl and victorin simultaneously than when uranyl alone was absorbed, but deposition in cell walls was similar in the two treatments. No differences in crystal distribution were found in uranyl-treated leaves which subsequently took up either water or victorin. The most striking effect of prolonged exposure to uranyl was increased vesicular activity in the protoplasm, formation of complex concentric membranes, and tonoplast damage. Following victorin treatment, uranyl post-treatment was ineffective in suppressing electrolyte leakage or preserving normal cellular ultrastructure. More severe ultrastructural damage was found in victorintreated leaves after uranyl post-treatments than after post-treatment with water, a result of victorin-induced damage which facilitates uranyl entry into the protoplasm.     

Sexual fusion of protoplasts in a marine green alga, Bryopsis plumosa

We isolated protoplasts from male and female gametophytes of a strictly dioecious strain of the coenocytic marine green alga Bryopsis plumosa. The protoplasts successfully developed into macrothalli. These in turn produced swimming cells, which appeared similar to biflagellated gametes even when the mixed protoplasts were comprised of protoplasm from male and female gametophytes. We found that swimming cell sizes depended on the male/female protoplasm ratio; macrothalli successfully produced swimming cells with male/female protoplasm ratios of 10:0; 9:1; 7:3; 5:5; 1:9; and 0:10. In male/female protoplasm ratios ranging from equal to strongly female biased (5:5; 3:7; 1:9), swimming cells exhibited normal behaviors of gametes and resultant zygotes, displaying positive and negative phototaxis, respectively. Negatively phototactic swimming cells were quadriflagellated and had two nuclei, apparently as a result of fusion, but never developed into microthalli. Thus, these swimming cells might lack functionality essential for normal gametes. Our findings suggested that natural monoecy observed in this genus did not originate from hybridization of protoplasm between the sexes.     

Antigens of Neisseria gonorrhoeae: Characterization by Gel Filtration, Complement Fixation, and Agar-Gel Diffusion of Antigens of Gonococcal Protoplasm

With the use of the agar-gel-diffusion and complement-fixation techniques, it was shown that protoplasm from different gonococcal isolates reacted with sera from some humans with a history of gonorrhea but did not react with "normal" human sera. The reactive antigen(s) could be partially separated from the other antigens by passing the gonococcal protoplasm through Sephadex G-200. The antigen(s) reacting in the gel-diffusion and complement-fixation tests appeared in the same fraction. On the basis of Sephadex gel filtration, the molecular weight of this antigen(s) is probably greater than 200,000.     

CONDUCTIVITY AND PERMEABILITY

An electrical current passing through a living plant flows partly through the cell wall and partly through the protoplasm. The relative amounts of these two portions of the current can be calculated. The outcome of such calculations shows that the conclusions drawn from the study of the resistance of the tissue as a whole apply also to the resistance of the protoplasm, and consequently to the permeability of the protoplasm to ions.     

淡黄绒泡菌和全白绒泡菌原生质流向的观察

显型原质团是绒泡菌目黏菌的营养生长阶段,其最明显的现象是往返原生质流,但一直并不清楚原生质流反向流动的原因。观察研究了淡黄绒泡菌和全白绒泡菌原质团中的原生质流,结果表明：由于菌脉中堵塞或是在原质团前缘尚未分化通道引起反向原生质流,从而引起原质团多方向生长使原质团前缘呈现扇面状。原生质流总的方向是扇面端,并完成原质团运动。     

The digestion of dandelion pollen by adult worker honeybees

ABSTRACT. The digestion of dandelion ( Taraxacum officinale ) pollen by adult worker honeybees ( Apis mellifera Linn.; Hymenoptera: Apidae) was initiated at the germination pores. 30 min after feeding, pollen had reached the anterior midgut and the germination pores had become swollen. This permitted further removal of protoplasm during the next 2 h of digestion as the pollen passed into the middle portion of the midgut. 3 h after feeding, pollen grains had reached the posterior midgut where some had ruptured to release both 'naked' protoplasm and masses of protoplasm but many remained intact or were only partially digested; undigested pollen grains passed unchanged to the rectum. The lipid-rich pollenkitt layer was removed from the exine during digestion. Our studies indicate that dandelion pollen was not utilized completely by honeybees.     

SOME PROPERTIES OF PROTOPLASMIC GELS : I. TENSION IN THE CHLOROPLAST OF SPIROGYRA

The chloroplast of Spirogyra is a long, spirally coiled ribbon which may contract to form a short, nearly straight rod. This happens under natural conditions and it can also be produced by a variety of inorganic salts and by some organic substances. It also occurs when the chloroplast is freed by centrifugal force from the clear peripheral protoplasm which is in contact with the cellulose wall. It would therefore seem that the chloroplast may be passively stretched by the action of the clear protoplasm and hence it contracts as soon as it is set free. This contraction happens in dead as well as in living cells. It would be of much interest to know how the protoplasm brings about the coiling of the chloroplast and how the chloroplast is set free by various reagents. Presumably they must penetrate the living protoplasm to produce the effects described. In one species partial contraction without detachment from the peripheral protoplasm can be brought about by lead acetate. This is reversible. Lead nitrate does not produce this result. The attack upon the problem is greatly facilitated by the study of dead cells. Thereby we reduce the number of variables but the chloroplast continues to react to certain chemical and physical agents in much the same manner as in the living cell and the solution surrounding it can be controlled as is not possible in the living cell. We must await further investigation to learn what plant and animal cells contain gels under tension and what functions they perform.     

Establishment of an Index to Appraise Cold-resistant Breeding for Citrus in Early Stage

Cold-resistance of citrus protoplasm and field plants in 5 different varieties was studied. The relative analysis between cold resistance of citrus protoplasts and that of field plants indicates that the cold resistance of citrus protoplasm can be considered as an index of cold resistance of field plants.     

The protoplasmic flow in the myxomycete plasmodium as revealed by a volumetric analysis

Summary The manner of the locomotion of the slime mold,Physarum polycephalum, was shown graphically using a double-chamber volumeter developed by the author. It enabled him to represent in undulating curves every detail of the way in which the slime mold moves on little by little by availing itself of the difference in transport-volume of the endoplasm produced at each repetition of the back and forth streaming.The curve showing the locomotion of the organism pointed out that more than 4 mm³ of protoplasm is sometimes shifted in a direction in one streaming duration. No close relationship is found between the streaming duration and the transport-volume of protoplasm. The intensity of the flow, which may be defined as the volume of protoplasm transported per unit time, can be obtained from the transport-volume curve through its graphical differentiation.     

The use of alizarin red S to detect and localize calcium in gametophyte cells of ferns

An aqueous solution of alizarin red S containing chloral hydrate both clears intact chlorophyllous gemma cells of Vittaria graminifolia and stains for protoplasmic calcium. Verification that the stain was protoplasmic rather than in the cell wall was shown by a positive reaction in extruded protoplasm. Similar staining was found in extruded protoplasm of Onoclea sensibilis spores. Differentiating gemma cells show localized protoplasmic accumulations of Ca2+ at sites where asymmetric cell divisions initiate the formation of rhizoids, antheridia or vegetative cells. The staining properties of the dye depend on careful control of pH and the addition of appropriate amounts of KCl to the mixture. Treatment of Onoclea spores and Vittaria gemmae with 100 mM EGTA for 30 min nearly abolishes staining of their extruded protoplasts and also of intact cells of gemmae. The use of alizarin red S with and without chloral hydrate demonstrates different pools of protoplasmic Ca2+. When Onoclea spores are ruptured to extrude the protoplasm, both dye mixtures stain a peripheral, granular protoplasmic component. However, the chloral hydrate-containing dye also reveals Ca2+ associated with small particulate protoplasmic components. Extruded protoplasm of gemma cells stains intensely with alizarin-chloral hydrate, but does not stain with alizarin lacking chloral hydrate.     

Twenty-four-hour induction of freezing and drought tolerance in plumules of winter rye seedlings by desiccation stress at room temperature in the dark

Exposure of seedlings of winter rye (Secale cereale L., cv. Puma) for 2 weeks or 24 hours to desiccation stress (40% relative humidity) at room temperature (21°C) in the dark induced degrees of freezing and drought tolerance in the plumules comparable to those produced by cold conditioning for 2 weeks at 3°C. The induction was associated with repression of growth and could not be produced in plumules excised from the seedlings indicating a requirement for translocation of nutrients from the endosperm. Rapid increase in osmotic pressure, soluble proteins, and phospholipids in plumules in association with the development of freezing and drought tolerance and the requirement of endosperm suggested diversion of nutrient from use in extension growth, to use in augmentation of protoplasm in plumule cells. Since cold acclimation slowed or arrested growth and is associated with augmentation of protoplasm, it is suggested that the common element in the induction of freezing tolerance by cold and drought is the necessity for producing a condition of augmented protoplasm and membranes in cells thus reinforcing a similar conclusion reached from seasonal studies on woody plants.     

ELECTROPHYSIOLOGICAL STUDIES ON NITELLA CELLS, WITH SPECIAL REFERENCE TO THE ELECTRIC RESISTANCE

Electrical properties of Nitella (Tolypella) cells were studied,with special reference to their electric resistance The resistanceof the protoplasm, as well as the potential of the inside ofthe cell, was measured by inserting capillary electrode intothe cell, which had been sealed with vaseline externally atthe middle so that the current across the protoplasm could bereadily determined. The characteristics of the rectification and impedance weremeasured The electric current was found to flow across the protoplasmiclayer more easily from the sap to the external water than inthe reverse direction. The resistance and the capacitance ofthe cell varied with the a.c frequencies used for the measurement Simultaneous measurements were made of the action potential,the action current, and the resistance change of the protoplasmin order to determine the relationship between them An intimateparallelism between the time courses of these three phenomenawas discovered. An attempt was made to interpret the resultsby taking into account the dissociation of ions in the protoplasm. ¹Present address: Japan Atomic Energy Research Institute, Tokai,Ibaraki Prefecture. (Received May 8, 1962; )     

The Use of Alizarin Red S To Detect and Localize Calcium in Gametophyte Cells of Ferns

An aqueous solution of alizarin red S containing chloral hydrate both clears intact chlorophyllous gemma cells of Vittaria graminifolia and stains for protoplasmic calcium. Verification that the stain was protoplasmic rather than in the cell wall was shown by a positive reaction in extruded protoplasm. Similar staining was found in extruded protoplasm of Onoclea sensibilis spores. Differentiating gemma cells show localized protoplasmic accumulations of Ca²⁺ at sites where asymmetric cell divisions initiate the formation of rhizoids, antheridia or vegetative cells. The staining properties of the dye depend on careful control of pH and the addition of appropriate amounts of KC1 to the mixture. Treatment of Onoclea spores and Vittaria gemmae with 100 mM EGTA for 30 min nearly abolishes staining of their extruded protoplasts and also of intact cells of gemmae. The use of alizarin red S with and without chloral hydrate demonstrates different pools of protoplasmic Ca²⁺. When Onoclea spores are ruptured to extrude the protoplasm, both dye mixtures stain a peripheral, granular protoplasmic component. However, the chloral hydrate-containing dye also reveals Ca²⁺ associated with small particulate protoplasmic components. Extruded protoplasm of gemma cells stains intensely with alizarin-chloral hydrate, but does not stain with alizarin lacking chloral hydrate.     

The role of water in protoplasmic permeability and in antagonism

The behavior of the cell depends to a large extent on the permeability of the outer non-aqueous surface layer of the protoplasm. This layer is immiscible with water but may be quite permeable to it. It seems possible that a reversible increase or decrease in permeability may be due to a corresponding increase or decrease in the water content of the non-aqueous surface layer. Irreversible increase in permeability need not be due primarily to increase in the water content of the surface layer but may be caused chiefly by changes in the protoplasm on which the surface layer rests. It may include desiccation, precipitation, and other alterations. An artificial cell is described in which the outer protoplasmic surface layer is represented by a layer of guaiacol on one side of which is a solution of KOH + KCl representing the external medium and on the other side is a solution of CO₂ representing the protoplasm. The K⁺ unites with guaiacol and diffuses across to the artificial protoplasm where its concentration becomes higher than in the external solution. The guaiacol molecule thus acts as a carrier molecule which transports K⁺ from the external medium across the protoplasmic surface. The outer part of the protoplasm may contain relatively few potassium ions so that the outwardly directed potential at the outer protoplasmic surface may be small but the inner part of the protoplasm may contain more potassium ions. This may happen when potassium enters in combination with carrier molecules which do not completely dissociate until they reach the vacuole. Injury and recovery from injury may be studied by measuring the movements of water into and out of the cell. Metabolism by producing CO₂ and other acids may lower the pH and cause local shrinkage of the protoplasm which may lead to protoplasmic motion. Antagonism between Na⁺ and Ca⁺⁺ appears to be due to the fact that in solutions of NaCl the surface layer takes up an excessive amount of water and this may be prevented by the addition of suitable amounts of CaCl₂. In Nitella the outer non-aqueous surface layer may be rendered irreversibly permeable by sharply bending the cell without permanent damage to the inner non-aqueous surface layer surrounding the vacuole. The formation of contractile vacuoles may be imitated in non-living systems. An extract of the sperm of the marine worm Nereis which contains a highly surface-active substance can cause the egg to divide. It seems possible that this substance may affect the surface layer of the egg and cause it to take up water. A surface-active substance has been found in all the seminal fluids examined including those of trout, rooster, bull, and man. Duponol which is highly surface-active causes the protoplasm of Spirogyra to take up water and finally dissolve but it can be restored to the gel state by treatment with Lugol solution (KI + I). The transition from gel to sol and back again can be repeated many times in succession. The behavior of water in the surface layer of the protoplasm presents important problems which deserve careful examination.