Trypanosoma brucei: loss of variable antigens during transformation from bloodstream to procyclic forms in vitro.

The loss of variable antigen from Trypansoma brucei during transformation from the bloodstream to the procyclic form in vitro has been monitored by agglutination and immunofluorescence reactions using antisera against both forms. Maximum agglutination of transforming trypanosomes with anti-culture form sera was obtained in 36–48 hr coinciding with loss of the surface coat as seen by electron microscopy. Agglutination with antisera against homologous bloodstream forms, however, reached a constant minimum but still positive level after 7–9 days: absorption of such antisera with culture or heterologous bloodstream forms reduced this period of persistent agglutinability to 72–84 hr, suggesting that the sera contained antibodies to “common” (surface membrane) antigens which became exposed when the surface coat was lost during transformation. The indirect immunofluorescence reaction provided a direct correlation of loss of antigen with loss of coat. The majority of trypanosomes lost detectable variable antigen by 36–48 hr, but a few flagellates, morphologically resembling bloodstream forms, retained the coat and capacity for labeling up to 84 hr; the numbers of such persistent bloodstream forms were shown to be sufficient to give a positive agglutination reaction for the population as a whole up to this time. Variable antigen appeared to be lost by dilution over the entire trypanosome surface rather than in patches or caps and the relevance of this observation to the process of antigenic variation is discussed.     

Volatile transport in frozen aqueous solutions. II. Influence of system parameters

Frozen aqueous butanol solutions are evaluated for the influence of sample preparation and equilibration conditions on the loss of butanol.It is shown that an increase of equilibration temperature results in increased butanol loss, both water independent and water dependent. The freezing rate will influence the equilibration retention level, with faster freezing resulting in smaller butanol loss. An increase in butanol concentration gave the same percentage of butanol loss, i.e., the amount of butanol lost was directly proportional to the initial concentration.     

The tardigrade cuticle II. Evidence for a dehydration-dependent permeability barrier in the intracuticle

Tardigrades weighed during desiccation in high or low humidities show a short period of rapid transpiration followed by an abrupt decline in transpiration which virtually arrests water loss. The amount of water retained following this 'permeability slump' is greater at low rates of desiccation but the slump is not a metabolic phenomenon, being reproducible in dead or narcotised animals. Tardigrades rinsed in hot chloroform (62 degrees C) for 5 hr still show the characteristic permeability decline when desiccated in 80% RH. However, 25hr rinsing in hot chloroform apparently obliterates the slump. Estimates of the bound water content of tardigrades by DSC show that this can account for the dehydrated masses of these chloroform-rinsed animals and that all free water is probably transpired. Lipid analysis of the 25 hr chloroform extracts by GC-MS reveals several lipid classes, predominantly free fatty acids (C(12)-C(18)); these are not detectable in the 5 hr extracts. Control rinsing in hot water has no apparent effect on the permeability slump. TEM tracer studies with lanthanum show the lipid-rich intracuticle to serve as a transpiration barrier in dehydrated animals but not in fully hydrated specimens. There is thus strong support for the role of intracuticular lipids in effecting the permeability slump. A model to explain this phenomenon on the basis of lipid phase changes is postulated.     

Evaporative water loss, corporal temperature and the distribution of sympatric fiddler crabs (Uca) from south Texas

Desiccation and thermal stress are among the primary factors limiting terrestriality in crustaceans. Water loss was estimated as weight change in five sympatric species of Uca from south Texas for periods up to 7 hr in dry air. Simultaneously, corporal temperature was measured with a thermocouple placed under the carapace. To estimate integumental permeability to water, 115 mm2 portions of dorsal carapace were glued to U-shaped tubes containing a crab Ringer's solution. These were exposed to dry air and water permeability was estimated from weight change. In whole-animal studies, most rapid weight loss occurred in the first 5 min of exposure to dry air as the body temperature fell below ambient (25 degrees C) in all species. The three most terrestrial species exhibited significant survival over more aquatic congeners after prolonged desiccation. The greatest rate of water loss was observed in Uca subcylindrica which lost 22.9+/-3.0% body weight. Uca panacea and Uca spinicarpa lost 14.1+/-1.6% and 18.5+/-1.8%, respectively. Based on blood osmolarity changes, Uca longisignalis and Uca rapax were more resistant to water loss than Uca subcylindrica under these conditions. Water loss from sections of the dorsal carapace were highest in Uca spinicarpa (10.4 mg/hr/cm2) and Uca longisignalis (8.9 mg/ hr/cm2). Uca subcylindrica and Uca panacea were intermediate (4.5 and 4.2 mg/hr/cm2) while Uca rapax expressed the lowest value (2.9 mg/hr/cm2). These observations support the notion that water loss can effectively lower body temperature in fiddler crabs. However, an inverse relationship between terrestriality and integumental permeability was not evident in these sympatric congeners. Ultimately a balance between physiological and behavioral mechanisms must be achieved for adaptation to the semi-arid habitats in south Texas.     

Loss of cell constituents from hepatocytes on centrifugation.

In studies of the metabolism of isolated hepatocytes, it is often necessary to measure the concentrations of cell constituents both in cells and medium. When hepatocytes are separated in the special tubes of Hems, Lund & Krebs (1975) (Biochem. J. 150, 47--50), they lose much glucose, urea and Na+, whereas there is no loss of K+, glutamate, aspartate and adenine nucleotides. Cell water is also lost, as measured by the distribution of 3H2O. This loss is mainly due to an exchange of cell water with the aqueous solution in the stems of the tubes through which the cells pass on centrifugation. In general, substances are lost only when the intracellular concentration is equal to, or lower than, the extracellular concentration. Probably solutes are lost because they travel with the water unidirectionally out of the cell. A loss of solute does not occur when the cells are centrifuged in conical tubes with a layer of silicone oil between the cell suspension and the deproteinizing layer. The reasons for the loss occurring in the special separation tubes are discussed.     

Cell-surface glycosaminoglycans: Turnover in cultured human embryo fibroblasts (IMR-90)

As constituents of both extracellular matrix and the cell surface, glycosaminoglycans are in a strategic position to influence several basic cell features. The localization and turnover of glycosaminoglycans was investigated in cultured normal human embryo fibroblasts of lung origin (IMR-90). Attention was directed particularly toward that compartment of the culture which could be released by gentle proteloysis (trypsin, 0.1 mg/ml, 15 min) and is considered to represent the cell surface. In the presence of Na₂SO₄, sulfated glycosaminoglycans (S-GAGs) of the cell surface were labeled rapidly, but within 30 min some ³⁵S-GAG appeared in the extracellular medium. The intracellular pool of S-GAGs labeled during a 10-min period was lost during the first hr of chase with a half-life of 18 min, compared with 16 hr for S-GAGs labeled over a 48-hr period. Pulse-labeled S-GAGs of the surface turned over with an initial half-life of 60 min, compared with 7 hr for surface material labeled over a 48-hr period. These rapid movements of the early chase period were followed by similar movement at a much slower rate. The results are consistent with a model in which most of the S-GAGs synthesized in the cell move rapidly to the surface. The surface GAGs are then released immediately to the medium or accumulate at the membrane to be shed more slowly at a later time or to be degraded. The S-GAG which left the cell layer most rapidly during chase was dermatan sulfate, while heparan sulfate made up an increasing percentage of the cell layer as chase progressed. These cultures produce a fibrillar matrix of fibronectin, but the kinetics of this study suggest that the S-GAGs of the surface are membrane-bound, and an extracellular glycosaminoglycan matrix does not form.     

Control of desmosome formation in aggregating embryonic chick cells

Corneal epithelial cells have been used to study cell surface changes during cell aggregation. Tissue was taken from developmental stages in which desmosomes were forming rapidly. When corneal cells are dispersed, adjacent desmosome plaques are separated and single plaques are left on the cell surface. As cells aggregate, changes in the frequency of single plaques or of full desmosomes (double plaques) per micrometer of cell surface cross section can be followed. Single plaques are lost from the surface by endocytosis. Quantitative studies show a loss of single plaques beginning in the first hour of culture and formation of double plaques at 2 to 3 hr. In cells treated with cytochalasin B or D, single plaques are not lost during the first 2 hr and double plaques form with a higher frequency. Formation of double plaques is suppressed by actinomycin D, cycloheximide, and dinitrophenol. Thus desmosome formation requires de novo protein synthesis. In addition, inhibition of cell surface turnover by drugs which modify the cytoskeleton will enhance the rate at which desmosomes form.     

The pelagic and benthic phases of post-metamorphic Munida gregaria (Fabricius) (Decapoda,Anomura)

Some post-metamorphic individuals of Munida gregaria (Fabricius) are permanent members of the benthos while others spend at least part of their time in the water column. These two types of individual are distinct, both morphologically and in the composition of the body. Pelagic specimens have a low density throughout the moult cycle, brought about by a high water content, and low ash and calcium contents. Benthic individuals have this low density for only the first few days post-moult. Normally the pelagic habit is retained only during the first summer as post-larvae but on occasions it is extended over the whole year. In captivity specimens collected at the surface quickly settle on the bottom of the tanks and do not reappear at the surface. The strong positive phototactic response, seen when the animals are collected from the surface, is lost in the first few weeks and the low density persists only until they moult.     

Efficient butanol production under aerobic conditions by coculture of Clostridium acetobutylicum and Nesterenkonia sp. strain F

Clostridium acetobutylicum is widely used for the microbial production of butanol in a process known as acetone–butanol–ethanol (ABE) fermentation. However, this process suffers from several disadvantages including high oxygen sensitivity of the bacterium which makes the process complicated and necessitate oxygen elimination in the culture medium. Nesterenkonia sp. strain F has attracted interests as the only known non-Clostridia microorganism with inherent capability of butanol production even in the presence of oxygen. This bacterium is not delimited by oxygen sensitivity, a challenge in butanol biosynthesis, but the butanol titer was far below Clostridia. In this study, Nesterenkonia sp. strain F was cocultivated with C. acetobutylicum to form a powerful “coculture” for butanol production thereby eliminating the need for oxygen removal before fermentation. The response surface method was used for obtaining optimal inoculation amount/time and media formulation. The highest yield, 0.31 g/g ABE (13.6 g/L butanol), was obtained by a coculture initiated with 1.5 mg/L Nesterenkonia sp. strain F and inoculated with 15 mg/L C. acetobutylicum after 1.5 hr in a medium containing 67 g/L glucose, 2.2 g/L yeast extract, 4 g/L peptone, and 1.4% (vol/vol) P2 solution. After butanol toxicity assessment, where Nesterenkonia sp. strain F showed no butanol toxicity, the coculture was implemented in a 2 L fermenter with continual aeration leading to 20 g/L ABE.     

Ascaris sp.: water loss during desiccation of embryonating eggs

The ability of embryonating eggs of Ascaris lumbricoides to avoid desiccation by reducing the loss of water through the egg shell was investigated. When exposed to desiccation the eggs lost water at a rate dependent upon the relative humidity and ambient temperature, eventually resulting in the collapse of the eggs and the death of the enclosed embryo. The eggs are small with a large surface to volume ratio. A low permeability to gaseous exchange thus restricts water loss while still ensuring an adequate supply of oxygen for embryonic development. Relative humidity did not appear to affect the rate of development. In eggs exposed to desiccation at various constant temperatures, the rate of water loss increased as an exponential function of increasing temperature. When eggs were exposed to various temperatures before exposure to desiccation at 22 C, the rate of water loss increased as a function of increasing pretreatment temperature. After exposure to 63–65 C, the ability of the egg shell to slow down the loss of water was destroyed. These phenomena suggest that there is not a simple “critical” or “transition” temperature, but a gradual melting of the complex mixture of components forming the lipid layer.     

Low cell surface hydrophobicity is one of the key factors for high butanol tolerance of Lactic acid bacteria

Highly butanol‐tolerant strains have always been attractive because of their potential as microbial hosts for butanol production. However, due to the amphiphilic nature of 1‐butanol as a solvent, the relationship between the cell surface hydrophobicity and butanol resistance remained ambiguous to date. In this work, the quantitatively estimated cell surface hydrophobicity of 74 Lactic acid bacteria strains were juxtaposed to their tolerance to various butanol concentrations. The obtained results revealed that the strains’ hydrophobicity was inversely proportional to their butanol tolerance. All highly butanol‐resistant strains were hydrophilic (cell surface hydrophobicity<1%), whereas the more hydrophobic the strains were, the more sensitive to butanol they were. Furthermore, cultivation at increasing butanol concentrations showed a clear tendency to decrease the level of hydrophobicity in all tested organisms, thus suggesting possible adaptation mechanisms. Purposeful reduction of cell surface hydrophobicity (by removal of S‐layer proteins from the cell envelope) also led to an increase of butanol resistance. Since the results covered 23 different Lactic acid bacteria species of seven genera, it could be concluded that regardless of the species, the lower degree of cells’ hydrophobicity clearly correlates with the higher level of butanol tolerance.     

The Retention of Water-soluble Compounds during Freeze-Substitution and Microautoradiography

Freeze-substitution and Epon embedment were quantitatively evaluated for their effectiveness in retaining water-soluble metabolites in plant tissues. Roughly 99% of the 80% (v/v) ethanol-extractable radioactivity in photosynthetically labeled soybean leaf discs and in petiole fragments containing translocated ¹⁴C was retained during freeze-substitution in acetone or propylene oxide and embedment in Epon. Substantially more activity was lost from ¹⁴C-sucrose-infiltrated pith blocks, but most or all of this loss came from the block surface. The procedure was effective for a sucrose concentration as low as 0.004%. Sections floated on water retained most of their ¹⁴C-sucrose, and high resolution autoradiographs could easily be prepared without resorting to dry procedures. Embedded ¹⁴C-sucrose was apparently chemically unreactive, since there was no loss of radioactivity when sections were stained with the periodic acid-Schiff reagent, nor did the embedded sucrose show staining.     

Nondestructive analysis of senescence in mesophyll cells by spectral resolution of protein synthesis-dependent pigment metabolism

* Over 6 d of dark-induced senescence, leaf segments of wild-type Lolium temulentum lost > 96% chlorophyll a + b; leaves from plants containing a staygreen mutation introgressed from Festuca pratensis, which has a lesion in the senescence-associated fragmentation of pigment-proteolipid complexes, retained over 43% of total chlorophyll over the same period. * Mutant segments preferentially retained thylakoid membrane proteins (exemplified by LHCP II) but lost other cellular proteins at the same rate as wild-type tissue. The protein synthesis inhibitor D-MDMP inhibited chlorophyll degradation and partially prevented protein loss in both genotypes, but tissues treated with the ineffective L-stereoisomer were indistinguishable from water controls. * Principal-components analysis of leaf reflectance spectra distinguished between genotypes, time points and D-MDMP treatments, showing the disruption of pigment metabolism during senescence brought about by the staygreen mutation, by inhibition of protein synthesis and by combinations of the two factors. * The build-up of oxidized, dephytylated and phaeo-derivatives of chl a during senescence of staygreen tissue was prevented by D-MDMP and associated with characteristic difference spectra when senescent mutant tissue was compared with wild-type or inhibitor-treated samples. The suitability of senescence as a subject for systems biology approaches is discussed.     

Turnover and shedding of Ia antigens by murine spleen cells in culture.

Lactoperoxidase-catalyzed radioiodination was used to examine the metabolic fate of surface Ia antigens on murine spleen cells in culture. Ia antigens, detected predominately on splenic B lymphocytes, were lost from the cultured cells with biphasic kinetics: a 4 to 6 hr rapid phase, t 1/2 = 5 hr followed by slow release through 20 hr, t 1/2 = 30 hr. The rapid loss of Ia antigens observed was abolished by both harsh iodination conditions and nonphysiologic incubation conditions. The rapid decline in Ia activity was shown to be due to shedding of intact Ia antigens from the cell and to predominant release of IA subregion-coded proteins. Release of Ia antigens from the cell was accomplished by replacement at the cell surface, and thus reflected net membrane Ia turnover. Ia shedding was shown to be extremely temperature dependent, reflecting both a comparatively high activation enthalpy and entropy requirement for turnover.     

GLUCOCORTICOID-INDUCED ALTERATION OF THE SURFACE MEMBRANE OF CULTURED HEPATOMA CELLS

Glucocorticoids induce an alteration of the surface of hepatoma tissue culture (HTC) cells as expressed by changes in cell electrophoretic, antigenic, and adhesive properties. The alteration is assayed by the increased adhesiveness of induced cells for a glass surface. The induction process has a lag period of about 3 hr and attains a plateau level after 24–30 hr when 50–80% of the steroid-treated cells are firmly adhered. Less than 10% of untreated cells adhere under the same conditions. Induction is inhibited by actinomycin D and cycloheximide, demonstrates both pH and temperature dependence, and responds to changes in steroid concentration and structure. By contrast, the attachment per se of preinduced cells is not affected by inhibitors of RNA and protein synthesis, fluctuations of temperature and pH, and the presence or absence of the hormone. When the induction process is reversed by removal of steroid or addition of actinomycin D, preinduced adhesiveness is lost with a half-life of 13–24 hr, but in the presence of cycloheximide the loss is accelerated (t_1/2 3–5.5 hr). These results suggest that glucocorticoids induce the biosynthesis of a protein which either modifies the cell surface (an enzyme) or is incorporated into surface structures (structural protein).     

Water loss from aerially exposed mussels

The valve activity and water loss from aerially exposed Mytilus edulis L. and Modiolus modiolus (L.) have been investigated in a series of laboratory experiments. Mytilus is capable of maintaining long periods of complete, or almost complete, valve closure when exposed in air, and this allows the retention of water in the mantle cavity and protects the tissues from evaporative water loss. Over periods of three days or more the amount of water lost from emersed Mytilus was found to be less than that retained in the mantle cavity at the beginning of exposure, suggesting that during normal periods of exposure the tissues are never directly subject to water loss. In contrast, Modiolus shows periods of gaping during which water loss is rapid due to drainage from the mantle cavity and evaporation from the tissues. The exposure of the tissues to air that results from gaping, makes the water loss susceptible to environmental influences of which wind was found to be the factor which caused the greatest increase in water loss and, as a consequence, an important factor in causing death through dehydration. The different abilities of Mytilus edulis and Modiolus modiolus to control water loss may be related to their intertidal distributions.     

Maturation-associated loss and incomplete de novo synthesis of the transferrin receptor in peripheral sheep reticulocytes: response to heme and iron

Hemin, but not iron, in the culture medium stimulates the maturation-associated loss of the transferrin receptor from sheep reticulocytes (t1/2 for loss approximately 6 hr) and its appearance in a population of externalized vesicles. A similar pattern is seen with nucleoside binding (a measure of the nucleoside transporter), where hemin increases the loss of binding activity from the cells during culture, concomitant with an increase in nucleoside binding in the externalized vesicles. Sheep reticulocytes retain the ability to synthesize the transferrin receptor, but the 35S-labeled receptors are not detected in released vesicles. Whereas hemin stimulates the loss of 35S-labeled transferrin receptors from the cell (t1/2 for loss approximately 20 hr), nonheme iron is more effective than heme. This difference in response of native and 35S-labeled receptor to hemin and iron supplements appears to be related to the differences in the two classes of receptors. Although the 35S-labeled receptor binds transferrin and both native and 35S-labeled peptides comigrate after chemical deglycosylation, the 35S-receptor is approximately 2 kD smaller than the native receptor and fails to acquire its complete size even when chased for up to 24 hr. Moreover, the 35S-labeled receptor is not expressed at the cell surface, but is retained in a nonrecycling compartment, where it is insensitive to digestion by trypsin at both 0 degrees C and 37 degrees C.     

THE INTERACTION OF SOLUBLE HORSERADISH PEROXIDASE WITH MOUSE PERITONEAL MACROPHAGES IN VITRO

The in vitro interaction of soluble horseradish peroxidase (HRP) with homogeneous mono layers of mouse macrophages has been studied using sensitive biochemical and cytochemical techniques. The compartmentalization of HRP in extracellular and intracellular sites has been quantitatively evaluated. A significant fraction is bound to a serum-derived layer, which coats the surface of culture vessels and may be removed by appropriate washes. Macrophages interiorize HRP as a solute in pinocytic vesicles without appreciable binding of the glycoprotein to the plasma membrane. Uptake is directly proportional to the concentration of HRP in the culture medium. 1 x 10⁶ cells ingest 0.0025% of the administered load per hr over a wide range of concentrations. Cytochemically, all demonstrable HRP is sequestered within the endocytic vesicles and secondary lysosomes of the vacuolar apparatus. After uptake, the enzymatic activity of HRP is inactivated exponentially with a half-life of 7–9 hr, until enzyme is no longer detectable. When macrophages have pinocytosed trace-labeled HRP-¹²⁵I, cell-associated isotope disappears with a t ½ of 20–30 hr and they release monoiodotyrosine-¹²⁵I into the culture medium. We were unable to obtain evidence that significant amounts of HRP (>2%) can be exocytosed after uptake, can exist intact on the cell surface, or can be digested extracellularly. It is difficult to reconcile these observations with several of the postulated mechanisms whereby macrophages are thought to play a prominent role in the induction of an immune response.     

The influence of water velocity on the downstream movement of alevins and fry of brown trout, Salmo trutta L.

Trout eggs were planted in four experimental stream channels, each channel being run at a different but constant discharge. Survival of the eggs to hatching was low and apparently unrelated to surface water velocity. However, movement of young trout out of channels was affected by water velocity, the higher the velocity the greater the proportion of trout that were lost. Virtually all fry moved out of a channel with a mean surface water velocity of 0.73 m s⁻¹. The rate of loss was not constant over the experiment but increased as the young trout entered the free-feeding stage. At the end of the experiment loss of fry, after abrupt increases in discharge, was demonstrated in the lower velocity channels.     

Trypanosoma brucei: morphometric changes and loss of infectivity during transformation of bloodstream forms to procyclic culture forms in vitro.

The transformation of Trypanosoma brucei bloodstream forms to procyclic culture forms in the semidefined medium SDM-77 has been studied by light microscopy and quantitative electron microscopy. Stumpy and intermediate forms are able to transform to culture forms whereas slender forms die after approximately 24 hr. The surface coat and infectivity for the mammalian host are lost after 72 hr. Morphometrical analysis of the cells during transformation process revealed: (1) The cytoplasm and the cell surface increased significantly; (2) the volume density of the mitochondrion increased twofold and the surface density of the inner mitochondrial membrane increased threefold; (3) the volume density of the glycosomes remained about constant; (4) the volume density of the lipid inclusions increased up to 72 hr, probably as a result of the complete oxidation of glucose. Transformation as observed by light microscopy was completed in 72 hr. However, quantitative electron microscopy revealed that establishment of the culture form was incomplete even after 11 days.