Analysis of changes of insect-plant ratio-improvement of key-factor analysis for evaluating bottom-up effects in insect population dynamics

A revised key-factor analysis was presented for analyzing the temporal changes in the ratio of insect absolute number to plant resource. Ten data sets for 5 insect species were then analyzed. In this key-factor analysis, the key factor is defined as the factor contributing highly to between-year variation inR _r , the log rate of the inter-year change of the insect-plant ratio. The yearly change of plant resource was handled as a separate factor, expressed byr _pl , log ratio of plant resource in yearn to plant resource in yearn+1. The following was revealed: 1) In 7 of the 10 data sets examined,r _pl influenced variations ofR _r ; in particular in 3 casesr _pl was the main key factor. 2) Generation-to-generation fluctuations of absolute insect densities showed density dependence in 4 cases, while those of insect-plant ratios, in 8 cases. 3) The Royama model or a linear model, explained well the relationship between log insect-plant ratio (X _r ) andR _r and the relationship betweenX _r and log yearly change rate of absolute insect density (R _abs ). However, in the 7 cases in whichr _pl was a critical factor for variations ofR _r , with, increase ofX _r ,R _r showed a steeper, decrease around the equilibrium point (the point for whichR _r is 0) thanR _abs . This occurred becauser _pl tended to be negatively correlated withX _r . Consequently, in two casesX _r fluctuated cyclicly or chaotically although without the changes in plant resource, fluctuations ofX _r would be damped oscillations approaching equilibrium.     

The structural dependence of amino acid hydrophobicity parameters

Amino acid hydrophobicity parameters, G_hp log P (partition coefficient) values, free energies of solution, G_sol and hydration numbers, are well correlated by equations derived from the relationship O_X = Aα_X + Lσ_IX + Sν_X + I_iX + H₁n_HX + H₂n_nX + b₀ where O is the quantity correlated; X denotes the amino acid side chain; α is a polarizability parameter; σ_I, a localized electrical effect parameter; ν, a steric parameter; i, an indicator variable which accounts for an ionic X ; n_H and n_n the number of OH or NH bonds and of full nonbonding orbitals in X, respectively, and b₀ is the intercept. The equation is based on the assumption that Δ_hp log P and ΔG_sol are all functions of the difference in intermolecular forces between the amino acid and some medium, and the amino acid and water. The parameters were chosen to model the intermolecular forces of interest.Generally the most important factor is α_x. This is followed by ν, i, and n_H. Least important is σ_I. ΔG_sol depends on α, n_H and n_n. Hydration numbers depend on i, n_H and n_n. The hydrophobicity of amino acid side chains is the result of a preference for a nonpolar medium as a increases and for a polar medium as i, n_H and σ_I increase. It is quantitatively accounted for by the model, and no special “hydrophobic bond” need be involved. The results show that log P values for amino acids are composite quantities whose composition is variable.     

Development of water stress in kale leaves of different insertion levels

The mutual relationship between the water potential (γ _w ), its components, namely the osmotic potential (γ _s ) and the pressure potential (γ _p ), and the water saturation deficit (ΔW _sat ) were determined in the leaves of different insertion levels. During the water stress development in kale plants induced by decreasing soil moisture theγ _w decreased, parallely in all the leaves but the same decrease ofγ _q was accompanied by the highest decrease of theγ _p , probably due to the accumulation of osmotically active solutes, and the lowest decrease ofγ _p in the upper leaves and with the lowest decrease ofγ _s and the highest decrease ofγ _p in the lower leaves. Also the corresponding values of the ΔW _sat were always lower in the upper than in the middle and lower leaves. Thus the upper leaves wilted at more negative values ofγ _w than the other leaves. On the contrary, during the wilting of the cut off leaves the relationship betweenγ _w and ΔW _sat in the upper, middle and lower leaves was practically the same. The very slightly higher decrease ofγ _s in the upper leaves in comparison with the other leaves was compensated by a lower deerease of theirγ _p . These changes in the ratios ofγ _w ,γ _s ,γ _p and ΔW _sat with the leaf insertion levels enabled the preference of the upper leaves in retaining the necessary water supply during the wilting of plantsin situ.     

Genetic specifics of the breeding of cotton varieties with cleistogamous flowers

As a prerequisite to studying the genetics and breeding of chasmogamous and cleistogamous flowers, a preliminary experiment was performed to estimate the extent of cross-pollination in cotton varieties and hybrids. Vicinism estimates varied from 0.53 to 15.36%, i.e., the proportion of cross-pollination was relatively high, leading to a biological contamination. As a result of such contamination, genetic collection lines and varieties lose genetic homogeneity and become heterozygous and genetically heterogeneous. The genetic control of the flower type was studied in the Gossipium hirsutum L. × G. barbadense L. interspecific hybrids, and phenotypic segregation of the 3: 1 and 15: 1 types with monogenic (3: 1) and digenic (15: 1) differences of noncumulative polymerization was observed. The corresponding types of genotypic segregation were 1: 2: 1 (1Cg ₁ Cg ₁ cg ₂ cg ₂ : 2Cg ₁ cg ₁ cg ₂ cg ₂ : 1cg ₁ cg ₁ cg ₂ cg ₂ ) and 1: 2: 2: 4: 1: 2: 1: 2: 1 (1) Cg ₁ Cg ₁ Cg ₂ Cg ₂ -1; (2) Cg ₁ Cg ₁ cg ₂ cg ₂ -2; (3) Cg ₁ cg ₁ Cg ₂ Cg ₂ -2; (4) Cg ₁ cg ₁ Cg ₂ cg ₂-4; (5) Cg ₁ Cg ₁ cg ₂ cg ₂ -1; (6) Cg ₁ cg ₁ cg ₂ cg ₂ -2; (7) cg ₁ cg ₁ Cg ₂ Cg ₂-1; (8) cg ₁ cg ₁ Cg ₂ cg ₂ -2; (9) cg ₁ cg ₁ cg ₂ cg ₂ -1. Genotypes (1)–(8) had chasmogamous flowers, while double-recessive genotype (9) had cleistogamous flowers. Based on this, genotypes with individual phenotypic expression were identified in F2, and their correlation with the most important morphological, biological, and agricultural features was studied. Special attention was paid to the productivity of hybrid plants intended for use in breeding to obtain intensive varieties. The study made it possible to isolate forms, families, genetic collection lines, and varieties with isogenic or nonisogenic determination of these characters and chasmogamous and cleistogamous flowers of G. hirsutum L. and G. barbadense L. prototypes by using original methods to examine the two types of flowers; the methods do not have analogs in cotton breeding worldwide.     

Hydrophobic hydration processes thermal and chemical denaturation of proteins

The hydrophobic hydration processes have been analysed under the light of a mixture model of water that is assumed to be composed by clusters (W₅)_I, clusters (W₄)_II and free water molecules W_III. The hydrophobic hydration processes can be subdivided into two Classes A and B. In the processes of Class A, the transformation A(− ξ_wW_I → ξ_wW_II + ξ_wW_III + cavity) takes place, with expulsion from the bulk of ξ_w water molecules W_III, whereas in the processes of Class B the opposite transformation B(− ξ_wW_III − ξ_wW_II → ξ_wW_I − cavity) takes place, with condensation into the bulk of ξ_w water molecules W_III. The thermal equivalent dilution (TED) principle is exploited to determine the number ξ_w. The denaturation (unfolding) process belongs to Class A whereas folding (or renaturation) belongs to Class B. The enthalpy ΔH_den and entropy ΔS_den functions can be disaggregated in thermal and motive components, ΔH_den = ΔH_therm + ΔH_mot, and ΔS_den = ΔS_therm + ΔS_mot, respectively. The terms ΔH_therm and ΔS_therm are related to phase change of water molecules W_III, and give no contribution to free energy (ΔG_therm = 0). The motive functions refer to the process of cavity formation (Class A) or cavity reduction (Class B), respectively and are the only contributors to free energy ΔG_mot. The folded native protein is thermodynamically favoured (ΔG_fold ≡ ΔG_mot < 0) because of the outstanding contribution of the positive entropy term for cavity reduction, ΔS_red ? 0. The native protein can be brought to a stable denatured state (ΔG_den ≡ ΔG_mot < 0) by coupled reactions. Processes of protonation coupled to denaturation have been identified. In thermal denaturation by calorimetry, however, is the heat gradually supplied to the system that yields a change of phase of water W_III, with creation of cavity and negative entropy production, ΔS_for ? 0. The negative entropy change reduces and at last neutralises the positive entropy of folding. In molecular terms, this means the gradual disruption by cavity formation of the entropy-driven hydrophobic bonds that had been keeping the chains folded in the native protein. The action of the chemical denaturants is similar to that of heat, by modulating the equilibrium between W_I, W_II, and W_III toward cavity formation and negative entropy production. The salting-in effect produced by denaturants has been recognised as a hydrophobic hydration process belonging to Class A with cavity formation, whereas the salting-out effect produced by stabilisers belongs to Class B with cavity reduction.Some algorithms of denaturation thermodynamics are presented in the Appendices.     

New Mutational Variants of Neurospora Nadp-Specific Glutamate Dehydrogenase

The am locus of Neurospora codes for NADP-dependent glutamate dehydrogenase (GDH). Four new am mutants that produced mutationally altered GDH have been characterized. Mutant am₁₁₉ is a CRM-negative, complementing mutant that maps between am₂ and am₁. The other three mutants are CRM formers that produce varieties of GDH that can be activated by glutamate or succinate. The GDH of am₁₃₀ and am₁₃₁ is similar in terms of activation properties to that of am₃. The GDH of am₁₂₂ requires very high concentrations of dicarboxylate for activity. The mutation in am₁₃₀ maps between am₁₄ and am₂ and resulted in a replacement at residue 75 of the GDH (pro → ser). The mutation in am₁₂₂ maps near am₁₁ and apparently resulted in the replacement of the tryptophan residue at position 389 with an unknown amino acid. The mutation in am₁₃₁ maps between am₂ and am₁.     

The calculation of optical properties of cesium plasma under conditions of a pulse-periodic discharge

The calculations of the radiation spectrum, the color rendering index R _a , the color temperature T _c , and the color coordinates X _c and Y _c of cesium plasma radiation under the conditions characteristic for a pulse-periodic discharge in cesium are presented. The plasma pressure range of 30–1500 Torr and the range of temperatures on the axis of 3200–6000 K are considered. The color rendering index is shown to be R _a > 90 in the entire analyzed plasma parameter ranges. The color temperature of plasma radiation varies within a broad range of 2300–5500 K. The color coordinates of the cesium plasma radiation are close to the X _c and Y _c coordinates of a black body.     

Two-Electron Reactions S2QB → S0QB and S3QB → S1QB are Involved in Deactivation of Higher S States of the Oxygen-Evolving Complex of Photosystem II

The oxygen-evolving complex of Photosystem II cycles through five oxidation states (S₀-S₄), and dark incubation leads to 25% S₀ and 75% S₁. This distribution cannot be reached with charge recombination reactions between the higher S states and the electron acceptor Q_B⁻. We measured flash-induced oxygen evolution to understand how S₃ and S₂ are converted to lower S states when the electron required to reduce the manganese cluster does not come from Q_B⁻. Thylakoid samples preconditioned to make the concentration of the S₁ state 100% and to oxidize tyrosine Y_D were illuminated by one or two laser preflashes, and flash-induced oxygen evolution sequences were recorded at various time intervals after the preflashes. The distribution of the S states was calculated from the flash-induced oxygen evolution pattern using an extended Kok model. The results suggest that S₂ and S₃ are converted to lower S states via recombination from S₂Q_B⁻ and S₃Q_B⁻ and by a slow change of the state of oxygen-evolving complex from S₃ and S₂ to S₁ and S₀ in reactions with unspecified electron donors. The slow pathway appears to contain two-electron routes, S₂Q_B → S₀Q_B, and S₃Q_B → S₁Q_B. The two-electron reactions dominate in intact thylakoid preparations in the absence of chemical additives. The two-electron reaction was replaced by a one-electron-per-step pathway, S₃Q_B → S₂Q_B → S₁Q_B in PS II-enriched membrane fragments and in thylakoids measured in the presence of artificial electron acceptors. A catalase effect suggested that H₂O₂ acts as an electron donor for the reaction S₂Q_B → S₀Q_B but added H₂O₂ did not enhance this reaction.     

Isocitrate lyase from Pseudomonas indigofera: pH dependence of catalysis and binding of substrates and inhibitors.

The maximal velocity, V, for isocitrate cleavage by isocitrate lysase from Pseudomonas indigofera was dependent on two dissociable groups (pK_a's of 6.9 and 8.6). The pH dependence of the pK_i for succinate, a product of isocitrate cleavage, implied that a dissociable group (pK_a of 6.0) on the enzyme functions in binding succinate. The pK_i's for maleate and itaconate (succinate analogs) were similarly pH dependent. The pK_i for oxalate, an analog of glyoxylate which is also a product of isocitrate cleavage, was pH independent. In contrast the pK_i's of the four-carbon dicarboxylic acid inhibitors, fumarate and meso-tartrate, both of which affect the glyoxylate site, were dependent on a dissociable group on the enzyme-inhibitor complex. Comparison of the pH dependence of the pK_m for isocitrate and the pK_i for succinate (and succinate analogs) indicated that the binding of isocitrate was dependent on an acidic dissociable group on the enzyme (pK_a of 5.8). The pH dependence of the pK_i for homoisocitrate was similar. In addition the K_i for succinate and K_m for isocitrate were dependent upon Mg²⁺ concentration. Inhibition by phosphoenolpyruvate, which binds to the succinate site and may regulate isocitrate lyase from P. indigofera, was twice as pH dependent as that for succinate. Two dissociable groups, one on the enzyme (pK_a of 5.8) and one on phosphoenolpyruvate (pK_a of 6.35), contributed to the pH dependence observed with phosphoenolpyruvate.     

Glutamate-induced polymerization of tubulin: characteristics of the reaction and application to the large-scale purification of tubulin

The multiple attack model of the α-amylase mechanism has been analyzed. Theoretical rate coefficients dependent on the degree of polymerization of substrate (n) have been applied. They are: effectiveness of hydrolysis (y_n) which affects V values, and the average number of unitary movements (ζ_n) which affects K_m values. The model explains the dependence of V and K_m on the degree of polymerization of substrates with n values higher than the number of subsites in the enzyme binding site. Distribution of the degree of polymerization of hog pancreas α-amylase products (n_p) and average n_p value has been found experimentally and applied to calculate the maximal number of unitary movements (z) of the enzyme during the single enzyme-substrate meeting. V and K_m values of hog pancreas α-amylase for amylose and different branched substrates have been determined and discussed in terms of the multiple attack theory. Their dependence on theoretic y_n and ζ_n values has been found in support of the model.     

Identification and Characterisation of SFBs in Prunus mume

The gametophytic self-incompatibility system in Rosaceae is controlled by a single highly polymorphic gene complex, termed the S locus, which is comprised of tightly linked stylar-expressed gene, S-RNase, with a pollen-expressed gene. In this study, seven novel S haplotype-specific F-box protein genes, PmSFB ₁₀ to PmSFB ₁₆ in Prunus mume, have been identified and characterised. Similarities amongst the deduced amino acid sequences of these SFBs ranged from 73.2% to 90.9%. Comparisons of two trans-specific pairs of haplotypes, PmS ₁₁ with PspS _3-1 and PmS ₁₃ /ParS ₉ with PspS ₈ , indicated high degrees of polypeptide sequence identity. The deduced amino acid sequences of PmSFB ₁₁ and PspSFB _3-1 showed similarity scores of 99.1%. In addition, the deduced amino acid sequences of the corresponding S-RNases, PmS ₁₁ -RNase and PspS _3-1 -RNase exhibited a high similarity score of 99.0%. The similarity scores of the sequences physically positioned between S-RNase and SFB in the PmS ₁₁ haplotype and PspS _3-1 were 94.6%. The deduced amino acid sequence of PmSFB ₁₃ showed high similarity scores with those of PspSFB ₈ and ParSFB ₉ at 99.3% and 97.9%, respectively. At the deduced amino acid level, the similarity scores of the PmS ₁₃ -RNase with the PspS ₈ -RNase or the ParS ₉ -RNase were 99.0% or 99.1%, respectively. Moreover, the similarity score of the sequence separating S-RNase and SFB in PmS ₁₃ was 96.1% compared with that of the PspS ₈ haplotype and 99.0% compared with that of the ParS ₉ haplotype. Our results suggest that the S haplotypes in P. mume, P. armeniaca and P. spinosa may have a common ancestor.     

Distinct effects of the C-terminal octapeptide of cholecystokinin and of a cholera toxin pretreatment on the kinetics of rat pancreatic adenylate cyclase activity

(1) The kinetic parameters of rat pancreatic adenylate cyclase were evaluated, using GTP, p[NH]ppG or GTPγS as nucleotide activator, cholecystokinin as peptide hormone, and GDPβS and dibutyryl cyclic GMP as inhibitors of guanosine triphosphate and CCK-8, respectively. The time courses of activation and the degree of activation at steady state (E_A/E_TOT) were compatible with a simple two-state model of activation-deactivation based on a pseudo-monomolecular activation process (rate constant k₊₂, and a deactivation process (rate constant k_off) that included, depending on the activating nucleotide, the hydrolysis of GTP (rate constant k₂) and/or the dissociation of the intact nucleotide (rate constant k_?1), so that E_A/E_TOT = k₊₁/(k₊₁ + k₂ + k_?a). (2) The hormone CCK-8 increased the value of k₊₁ with GTP dose-dependently, from 0.2 to 10.9 min^?1. The value of k_?1 increased 0.01 to 0.3 min^?1 but the value of k₂ was unaltered at 7 min^?1, so that E_A/E_TOT increased 15-fold, from 4% to 61%. (3) A cholera toxin pretreatment at 30 μg/ml allowed also a large increase in E_A/E_TOT with GTP (up to 51%) but the underlying mechanism was different. It consisted of a 14-fold decrease in the k_off value of the GTP-activated enzyme (from 7 min^? to 0.5 min^?1) that corresponded to a reduction in GTPase activity. When testing the system with p[NH]ppG, two added effects of the cholera toxin pretreatment were observed: a 4-fold increase in the value of k₊₁ (from 0.2 to 0.8 min^?1) and the occurrence of a significant 0.3 min^?1 value for k_?1.     

Post-transcriptional regulation of catalase synthesis in rat liver and hepatoma: binding of inhibiting factor(s) with polyribosomes synthesizing catalase

Further studies were made on the actions of the inhibiting factor(s) (F_inh) and activating factor(s) (F_act) on catalase synthesis by polyribosomes of hepatoma and normal liver. The following results indicated that F_inh binds with polyribosomes synthesizing catalase. (1) The ribosomal wash of hepatoma, released by treating hepatoma polyribosomes with 0.8 M-KCl, contained F_inh, whereas a similar fraction from normal liver polyribosomes did not. (2) F_inh was not recovered in the ribosomal wash of hepatoma polyribosomes after the latter had been incubated with normal liver supernatant, which contains more F_act than F_inh. (3) The ribosomal wash of normal liver polyribosomes which had been incubated with hepatoma supernatant contained F_inh. This seems to be supported by the finding that in the presence of the supernatant of normal liver treated at pH 5, in which F_act has been inactivated, normal liver polyribosomes can synthesize catalase, whereas hepatoma polyribosomes cannot.F_inh from the supernatant fraction and from the ribosomal wash of hepatoma were indistinguishable in their behaviors on gel filtration on Sephadex G100 and column chromatography on DEAE-cellulose.The specific activities of F_inh recovered in the ribosomal wash fractions from hepatoma and normal liver after incubation with hepatoma supernatant were 100-fold that of F_inh in hepatoma supernatant.It is concluded from these results that catalase synthesis is controlled by F_inh and F_act as follows: F_inh depresses catalase synthesis by binding with polyribosomes synthesizing catalase. F_act restores the synthesis by interrupting the binding of F_inh with polyribosomes, or inactivating F_inh bound to polyribosomes.     

Inheritance and interactions of incompatibility alleles in the tetraploid sour cherry

Three progenies of sour cherry (Prunus cerasus) were analysed to correlate self-(in)compatibility status with S-RNase phenotype in this allotetraploid hybrid of sweet and ground cherry. Self-(in)compatibility was assessed in the field and by monitoring pollen tube growth after selfing. The S-RNase phenotypes were determined by isoelectric focusing of stylar proteins and staining for RNase activity and, for the parents, confirmed by PCR. Seedling phenotypes were generally consistent with disomic segregation of S-RNase alleles. The genetic arrangements of the parents were deduced to be ‘Köröser’ (self-incompatible) S ₁ S ₄ .S _B S _D , ‘Schattenmorelle’ (self-compatible) S ₆ S ₁₃ .S _B S _B , and clone 43.87 (self-compatible) S ₄ S ₁₃ .S _B S _B , where “.” separates the two homoeologous genomes. The presence of S ₄ and S ₆ alleles at the same locus led to self-incompatibility, whereas S ₁₃ and S _B at homoeologous loci led to self-compatibility. The failure of certain heteroallelic genotypes in the three crosses or in the self-incompatible seedlings indicates that S ₄ and S ₆ are dominant to S _B . However, the success of S ₁₃ S _B pollen on styles expressing corresponding S-RNases indicates competitive interaction or lack of pollen-S components. In general, the universal compatibility of S ₁₃ S _B pollen may explain the frequent occurrence of S ₁₃ and S _B together in sour cherry cultivars. Alleles S _B and S _D , that are presumed to derive from ground cherry, and S ₁₃ , presumably from sweet cherry, were sequenced. Our findings contribute to an understanding of inheritance of self-(in)compatibility, facilitate screening of progenies for self-compatibility and provide a basis for studying molecular interactions in heteroallelic pollen.     

Molecular typing of the self-incompatibility locus of Turkish sweet cherry genotypes reflects phylogenetic relationships among cherries and other Prunus species

Self-incompatibility of sweet cherry (Prunus avium L.) is controlled by the multiallelic S-locus. While many cultivars and wild accessions have been S-genotyped, only limited data are available on accessions native to the center of origin of this species. Therefore, this study was carried out to determine the S-genotype of 11 landrace cultivars and 17 local genotypes selected from populations growing wild at the Black Sea coast. Eleven sweet cherries (S ₁–S ₇, S ₁₀, and S ₁₂–S ₁₄) and some wild cherries (S ₁₇–S ₁₉, S _21/25, and S ₃₁) S-RNase alleles were detected. The results indicate that Turkish cultivars represent a broader gene pool as compared with international cultivars. A new (S ₃₇) and a doubtful allele (provisionally labelled as S _7m) as well as the sour cherry S ₃₄-allele were identified in sweet cherry. These data and others (SSR variants within the S ₁₃-RNase introns) confirmed that allele pools of sweet and sour cherries in the Black Sea region are overlapping. A new cross-incompatibility group, XLV (S ₂ S ₁₈), was also proposed. Allele-specific primers were designed for S ₁₇–S ₁₉, S _21/25, S ₃₄, and S ₃₇. A phylogenetic analysis of the cherry S ₃₁-RNase and its trans-specific sister alleles reliably mirrored the assumed length of the time period after the divergence of species in the subgenera Cerasus and Prunophora. Most variations (insertions/deletions and single-nucleotide polymorphisms) in the S-RNase gene were silent and, hence, have not been exposed to natural selection. The results are discussed from the aspects of S-allele evolution and phylogenetic relationships among cherries and other Prunus species.     

Effect of water activity on the mechanical glass transition and dynamical transition of bacteria

The purpose of this study was to clarify the glass-transition behavior of bacteria (Cronobacter sakazakii) as a function of water activity (a_w). From the water sorption isotherm (298 K) for C. sakazakii, monolayer water content and monolayer a_w were determined to be 0.0724 g/g-dry matter and 0.252, respectively. Mechanical relaxation was investigated at 298 K. In a higher a_w range of over 0.529, the degree of mechanical relaxation increased with an increase in a_w. From the effect of a_w on the degree of mechanical relaxation, the mechanical a_wc (a_w at which mechanical glass transition occurs at 298 K) was determined to be 0.667. Mean-square displacement of atoms in the bacteria was investigated by incoherent elastic neutron scattering. The mean-square displacement increased gradually with an increase in temperature depending on the a_w of samples. From the linear fitting, two or three dynamical transition temperatures (low, middle, and high T_ds) were determined at each a_w. The low-T_d values (142–158 K) were almost independent from a_w. There was a minor effect of a_w on the middle T_d (214–234 K) except for the anhydrous sample (261 K). The high T_d (252–322 K) largely increased with the decrease in a_w. From the a_w dependence of the high T_d, the dynamical a_wc was determined to be 0.675, which was almost equivalent to the mechanical a_wc. The high T_d was assumed to be the glass-transition temperature (T_g), and anhydrous T_g was estimated to be 409 K. In addition, molecular relaxation time (τ) of the bacteria was calculated as a function of a_w. From the result, it is suggested that the progress of metabolism in the bacterial system requires a lower τ than approximately 6 × 10^?5 s.     

Real-time monitoring of the cell agglutination process with a quartz crystal microbalance

The real-time monitoring of the agglutination process of human hepatic normal cells (L-02) at the quartz crystal microbalance (QCM) gold (Au) electrode was performed. Two lectins, concanavalin A (Con A) and wheat germ agglutinin (WGA), induced the cell agglutination, resulting in the different Δf₀ and ΔR₁ responses from those caused by the normal cell attachment and growth. The cell-Con A-cell aggregates had higher affinity for the Au substrate due to the excellent adsorption ability of Con A, which was revealed by increased Δf₀ and ΔR₁ shifts and the obvious mass effect of QCM. In contrast, the lower adsorption ability of cell-WGA-cell aggregates was related to the same characteristic of WGA, presenting the decreased Δf₀ and ΔR₁ responses and the time-extended adhesion phase. Parallel microscopic observation experiments were also carried out and exhibited comparable results. The Δf₀ responses during the processes of cell growth and cell agglutination were analyzed using the equations Δf₀=a₀+a₁e^-t/τ₁+a₂e^-t/τ₂+a₃e^-t/τ₃ and Δf₀=a₀+a₁e^-t/τ₁+a₂e^-t/τ₂, respectively. Furthermore, the current work proved that the QCM measurement technique based on cell agglutination was useful for discriminating hepatic normal cells (L-02) and hepatic cancer cells (Bel7402).     

Ionic Dependence of Reversal Voltage of the Light Response in Limulus Ventral Photoreceptors

The light-induced current as measured using a voltage clamp (holding voltage at resting potential) is attenuated when sodium ions in the bathing solution, Na_o, are replaced by Tris, choline, or Li or when NaCl is replaced by sucrose. After replacement of NaCl by sucrose, the reversal voltage, V_rev, for the light response becomes more negative. In this case, the slope of the V_rev vs. log Na_o near Na_o = 425 mM is approximately 55 mV/decade increase of Na_o (mean for 13 cells). The slope decreases at lower values of Na_o. Choline is not impermeant and partially substitutes for Na; the slope of V_rev vs. log Na_o is 20 mV/decade (mean for three cells). V_rev does not change when Na is replaced by Li. Decreases in the bath concentrations of Ca, Mg, Cl, or K do not affect V_rev. When Na_o = 212 mM, V_rev becomes more positive when K_o is increased. Thus, light induces a change in membrane permeability to Na and probably also to K.     

Potassium and the Recovery of Arterial Smooth Muscle after Cold Storage

The influence of K on the performance of vascular smooth muscle was studied by observing the mechanical performance of the muscle under conditions in which the magnitudes of [K_i] and of the [K_i]:[K_o] ratio varied in opposite directions. During prolonged storage at 4°C the artery strips lost K and their ability to respond to stimuli. Subsequently they were transferred to recovery solutions of various [K_o] at 38°C. The initial rate of K_i reaccumulation and steady state [K_i] were greater in solutions of higher [K_o]. Conversely for any time during recovery, the greater [K_o], the smaller the [K_i]:[K_o] ratio. When the strip was placed in the warm recovery solution it first contracted and then relaxed. The initial contraction was not relatable to [K_o] of the recovery solution but the subsequent relaxation was greater in rate and magnitude as [K_o] was greater. As the muscles recovered further they went into tonic contracture. As the [K_o] in the recovery solutions was greater these contractures occurred after shorter recovery times, and attained greater amplitude at a faster rate. Solution-switching experiments indicated a dependence of responses to electrical shocks on both the [K_i]:[K_o] ratio and [K_i]. Conclusions drawn were: (a) increased [K_i] increases contractility, (b) increased [K_i] increases the rate of relaxation, (c) excitability is decreased by too high or low a [K_i]: [K_o] ratio, and (d) the extent of tonic shortening depends on the [K_i]:[K_o] ratio.