Demonstration of the presence of an inducibleβ-lactamase inAzospirillum lipoferum

Azospirillum lipoferum is a soil microorganism that has been shown to be resistant to penicillins. It has been suggested that resistance is due to the presence of a -lactamase activity, but no conclusive evidence has been reported. The incubation of benzylpenicillin, or nitrocephin with either wholeAzospirillum cells or cell-free extracts was accompanied, by hydrolysis of the -lactam ring of the antibiotics. Such hydrolytic activity exhibited Michaelis and Menten-like kinetics. The enzyme was produced at a low, basal level that was increased approximately 50 times by the addition of benzylpenicillin, an increase that was completely blocked by chloramphenicol or rifampicin.     

Noncompaction of the Ventricular Myocardium Is Associated with a De Novo Mutation in the β-Myosin Heavy Chain Gene

Noncompaction of the ventricular myocardium (NVM) is the morphological hallmark of a rare familial or sporadic unclassified heart disease of heterogeneous origin. NVM results presumably from a congenital developmental error and has been traced back to single point mutations in various genes. The objective of this study was to determine the underlying genetic defect in a large German family suffering from NVM. Twenty four family members were clinically assessed using advanced imaging techniques. For molecular characterization, a genome-wide linkage analysis was undertaken and the disease locus was mapped to chromosome 14ptel-14q12. Subsequently, two genes of the disease interval, MYH6 and MYH7 (encoding the α- and β-myosin heavy chain, respectively) were sequenced, leading to the identification of a previously unknown de novo missense mutation, c.842G>C, in the gene MYH7. The mutation affects a highly conserved amino acid in the myosin subfragment-1 (R281T). In silico simulations suggest that the mutation R281T prevents the formation of a salt bridge between residues R281 and D325, thereby destabilizing the myosin head. The mutation was exclusively present in morphologically affected family members. A few members of the family displayed NVM in combination with other heart defects, such as dislocation of the tricuspid valve (Ebstein''s anomaly, EA) and atrial septal defect (ASD). A high degree of clinical variability was observed, ranging from the absence of symptoms in childhood to cardiac death in the third decade of life. The data presented in this report provide first evidence that a mutation in a sarcomeric protein can cause noncompaction of the ventricular myocardium.     

Dynamic Properties of an Inositol 1,4,5-Trisphosphate– and Thapsigargin-insensitive Calcium Pool in Mammalian Cell Lines

The functional characteristics of a nonacidic, inositol 1,4,5-trisphosphate– and thapsigargin-insensitive Ca²⁺ pool have been characterized in mammalian cells derived from the rat pituitary gland (GH3, GC, and GH3B6), the adrenal tissue (PC12), and mast cells (RBL-1). This Ca²⁺ pool is released into the cytoplasm by the Ca²⁺ ionophores ionomycin or A23187 after the discharge of the inositol 1,4,5-trisphosphate–sensitive store with an agonist coupled to phospholipase C activation and/or thapsigargin. The amount of Ca²⁺ trapped within this pool increased significantly after a prolonged elevation of intracellular Ca²⁺ concentration elicited by activation of Ca²⁺ influx. This pool was affected neither by caffeine-ryanodine nor by mitochondrial uncouplers. Probing mitochondrial Ca²⁺ with recombinant aequorin confirmed that this pool did not coincide with mitochondria, whereas its homogeneous distribution across the cytosol, as revealed by confocal microscopy, and its insensitivity to brefeldin A make localization within the Golgi complex unlikely. A proton gradient as the driving mechanism for Ca²⁺ uptake was excluded since ionomycin is inefficient in releasing Ca²⁺ from acidic pools and Ca²⁺ accumulation/release in/from this store was unaffected by monensin or NH₄Cl, drugs known to collapse organelle acidic pH gradients. Ca²⁺ sequestration inside this pool, thus, may occur through a low-affinity, high-capacity Ca²⁺–ATPase system, which is, however, distinct from classical endosarcoplasmic reticulum Ca²⁺–ATPases. The cytological nature and functional role of this Ca²⁺ storage compartment are discussed.The cytosolic free Ca²⁺ concentration ([Ca²⁺]_i)¹ of eukaryotic cells rests in the range of 50–200 nM, i.e., at a very low level, if compared to the Ca²⁺ concentration of physiological media (2 mM). However, the total cellular Ca²⁺ content is closer to this latter value (1–3 mmol/l of cell water). In other words, eukaryotic cells sequester large amounts of Ca²⁺ mainly by uptake inside intracellular Ca²⁺ stores (∼90%) (for reviews see Pozzan et al., 1994; Clapham, 1995).The complexity of intracellular Ca²⁺ stores has been intensively investigated in recent years (for reviews see Meldolesi et al., 1990; Pozzan et al., 1994; Simpson et al., 1995). Attention has been focused mainly on Ca²⁺ stores that are highly dynamic because of their ability to rapidly take up and release Ca²⁺. Ca²⁺ sequestration into these pools depends on Ca²⁺–ATPases, known as sarco/endoplasmic reticulum Ca²⁺–ATPases (SERCAs) (Burk et al., 1989; Bobe et al., 1994; Wuytack et al., 1994). All the SERCA isoforms share the property of being selectively inhibited by thapsigargin (Tg), a tumor-promoting sesquiterpene lactone (Lytton et al., 1991). Tg acts with both high affinity, at nanomolar concentrations, and high specificity, with virtually no effect on the Ca²⁺– or Na⁺/K⁺– ATPase of the plasmalemma.Other drugs, such as 2,5-di(tert-butyl)-1,4-benzohydroquinone (tBHQ) and cyclopiazonic acid (CA), also block SERCAs, albeit with a significantly lower affinity (Mason et al., 1991). Ca²⁺ release, on the other hand, depends mainly on two types of Ca²⁺ release channels named inositol 1,4,5-trisphosphate (InsP₃) and ryanodine receptors (for reviews see Mikoshiba, 1993; Sorrentino and Volpe, 1993; Ehrlich, 1995). These channels are expressed in variable proportions in different cell types and couple extracellular stimuli to the release of Ca²⁺, with possible ensuing generation of Ca²⁺ waves and spikes (for reviews see Amundson and Clapham, 1993; Taylor, 1994; Bootman and Berridge, 1995). The relationship between these types of Ca²⁺-release channels is still largely debated. The ryanodine-sensitive channel is also activated by caffeine, and ryanodine- and caffeine-sensitive stores are generally regarded to comprise the same pool (Zacchetti et al., 1991; Barry and Cheek, 1994; but also see Giannini et al., 1992; McNulty and Taylor, 1993).In the vast majority of cell types so far investigated, the InsP₃- (and/or the ryanodine-) sensitive stores almost completely overlap with those sensitive to Tg (Zacchetti et al., 1991; Gamberucci et al., 1995) and are thus referred to also as Tg-sensitive Ca²⁺ pools. From the cytological point of view, the InsP₃-/Tg-sensitive Ca²⁺ pool is identified with the ER or with a subfraction of it (Hashimoto et al., 1988).The complexity of the relationships between the InsP₃- and ryanodine/caffeine-sensitive stores does not cover the entire issue of intracellular Ca²⁺ pool heterogeneity. Other types of Ca²⁺ pools are known to exist, the size of which varies considerably among different cell types. These latter Ca²⁺ stores account for roughly half of all sequestered Ca²⁺ (Chandra et al., 1991; Fasolato et al., 1991; Shorte et al., 1991; Bastianutto et al., 1995; Mery et al., 1996). They have been identified through the increase in [Ca²⁺]_i upon application of Ca²⁺ ionophores, after depletion of the Tgsensitive pool with a combination, or a sequence, of InsP₃generating agonists, Tg, and caffeine. These residual Tginsensitive pools appear rather heterogeneous in terms of cytological identity and pharmacological sensitivity. Part of these pools shows an acidic lumenal pH and is discharged only by a combination of a Ca²⁺ ionophore and of agents that collapse internal acidic pH gradients (such as monensin and NH₄Cl). ⁴⁵Ca²⁺ labeling of Tg-insensitive pools is slower than that of the Tg-sensitive store, and, for this reason, they have been generally indicated as slowly exchanging Ca²⁺ pools (Fasolato et al., 1991). As far as their identification is concerned, the acidic pool seems largely identifiable with secretory compartments and lysosomes, while very little is known yet about the rest of the Tg-insensitive store.Here we demonstrate that a nonacidic, InsP₃- and Tg- insensitive Ca²⁺ pool rapidly accumulates large amounts of Ca²⁺ when high and sustained increases of [Ca²⁺]_i are induced by opening of voltage- or store-operated Ca²⁺ channels. This Ca²⁺ storage compartment is insensitive to mitochondrial uncouplers and appears diffusely distributed in the cell cytosol. The possibility is discussed that this low-affinity, high-capacity Ca²⁺ pool represents a previously unidentified subcompartment of the ER expressing a Tg-insensitive Ca²⁺–ATPase.     

Up Regulation of cystathione γ lyase and Hydrogen Sulphide in the Myocardium Inhibits the Progression of Isoproterenol–Caffeine Induced Left Ventricular Hypertrophy in Wistar Kyoto Rats

Hydrogen sulphide (H₂S) is an emerging molecule in many cardiovascular complications but its role in left ventricular hypertrophy (LVH) is unknown. The present study explored the effect of exogenous H₂S administration in the regression of LVH by modulating oxidative stress, arterial stiffness and expression of cystathione γ lyase (CSE) in the myocardium. Animals were divided into four groups: Control, LVH, Control-H₂S and LVH-H₂S. LVH was induced by administering isoprenaline (5mg/kg, every 72 hours, S/C) and caffeine in drinking water (62mg/L) for 2 weeks. Intraperitoneal NaHS, 56μM/kg/day for 5 weeks, was given as an H₂S donor. Myocardial expression of Cystathione γ lyase (CSE) mRNA was quantified using real time polymerase chain reaction (qPCR).There was a 3 fold reduction in the expression of myocardial CSE mRNA in LVH but it was up regulated by 7 and 4 fold in the Control-H₂S and LVH-H₂S myocardium, respectively. Systolic blood pressure, mean arterial pressure, pulse wave velocity were reduced (all P<0.05) in LVH-H₂S when compared to the LVH group. Heart, LV weight, myocardial thickness were reduced while LV internal diameter was increased (all P<0.05) in the LVH-H₂S when compared to the LVH group. Exogenous administration of H₂S in LVH increased superoxide dismutase, glutathione and total antioxidant capacity but significantly reduced (all P<0.05) plasma malanodialdehyde in the LVH-H₂S compared to the LVH group. The renal cortical blood perfusion increased by 40% in LVH-H₂S as compared to the LVH group. Exogenous administration of H₂S suppressed the progression of LVH which was associated with an up regulation of myocardial CSE mRNA/ H₂S and a reduction in pulse wave velocity with a blunting of systemic hemodynamic. This CSE/H₂S pathway exhibits an antihypertrophic role by antagonizing the hypertrophic actions of angiotensin II(Ang II) and noradrenaline (NA) but attenuates oxidative stress and improves pulse wave velocity which helps to suppress LVH. Exogenous administration of H₂S augmented the reduced renal cortical blood perfusion in the LVH state.     

Repair of DNA–Protein Cross-links in Mammalian Cells

DNA–protein cross-links are generated by both endogenous and exogenous DNA damaging agents, as intermediates during normal DNA metabolism, and during abortive base excision repair. Cross-links are relatively common lesions that are lethal when they block progression of DNA polymerases. DNA–protein cross-links may be broadly categorized into four groups by the DNA and protein chemistries near the cross-link and by the source of the cross-link: DNA–protein cross-links may be found (1) in nicked DNA at the 3' end of one strand (topo I), (2) in nicked DNA at the 5' end of one strand (pol beta), (3) at the 5' ends of both strands adjacent to nicks in close proximity (topo II; Spo 11), and (4) in one strand of duplex DNA (UV irradiation; bifunctional carcinogens and chemotherapeutic agents). Repair mechanisms are reasonably well-defined for groups 1 and 3, and suggested for groups 2 and 4. Our work is focused on the recognition and removal of DNA–protein cross-links in duplex DNA (group 4).     

On Mechanism of “Konjac”mannan Metabolism in Gastrointestinal Bacteria in Relation to Nutrition

On the gastrointestinal bacteria related to nutrition, there have been many important publications. Recently, the present author has attempted further researches on Aerobacter mannanolyticus suzu-II, a strain in the type cultures collected by N. Inoue in this laboratory from human gastrointestinal tract, and the enzyme specificity was studied. The isolation of the “Konjac”mannan decomposing enzyme preparation was completely successful, and effects of carbon and nitrogen sources in Koser’s citrate medium on the enzyme formation were also confirmed. In the present paper, the results are described.     

Demonstration of cross-reacting material in Tay–Sachs disease

Antibodies against placental hexosaminidase A and kidney alpha-subunits were raised in rabbits after cross-linking the antigens with glutaraldehyde. Anti-(alpha(n)-subunit) antiserum (anti-alpha(n)) precipitated hexosaminidase A but not hexosaminidase B, whereas anti-(hexosaminidase A) antiserum precipitated both hexosaminidases A and B. Specific anti-(hexosaminidase A) antiserum was prepared by absorbing antiserum with hexosaminidase B. Both anti-alpha(n) and anti-(hexosaminidase A) antisera precipitated the CR (cross-reacting) material from eight unrelated patients with Tay-Sachs disease. Immunotitration, immunoelectrophoresis, double-immunodiffusion and radial-immunodiffusion techniques were used to demonstrate the presence of CR material. The CR-material-antibody complex was enzymically inactive. Antiserum raised against kidney or placental hexosaminidase A, without cross-linking with glutaraldehyde, failed to precipitate the CR material, implying that treatment of the protein with glutaraldehyde exposes antigenic determinants that are hidden in the native protein. Since anti-(hexosaminidase B) antiserum did not precipitate the CR material during the immunoelectrophoresis of Tay-Sachs liver extracts, it is suggested that altered alpha-subunits do not combine with beta-subunits. By using immunotitration we have demonstrated the competition between the hexosaminidase B-free Tay-Sachs liver extract and hexosaminidase A for the common binding sites on monospecific anti-(cross-linked hexosaminidase A) antiserum. The amount of CR material in the liver samples from seven cases of Tay-Sachs desease was found to be in the same range as theoretically calculated alpha-subunits in normal liver samples. Similar results were obtained by the radial-immunodiffusion studies. The present studies therefore suggest that Tay-Sachs disease is caused by a structural-gene mutation.     

Demonstration of 2n spermatids in carriers of the “sex reversed” factor in the mouse by feulgen cytophotometry

Summary The Sex Reversed factor (Sxr) leads to development of XX males. The condition is transmitted by XY-Sxr males. The testes of XY-Sxr carriers are characterized by patches of defective spermatogenesis with meiotic failure and appearance of extraordinary large spermatids. In the present study DNA content of the large spermatids is determined by Feulgen DNA measurement using a scanning cytophotometer. The large spermatids in XY-Sxr testes are shown to be 2n.This study is dedicated to Prof. Dr. W. Graumann on occasion of his 65th birthday     

Similar Endothelial Glycocalyx Structures in Microvessels from a Range of Mammalian Tissues: Evidence for a Common Filtering Mechanism?

The glycocalyx or endocapillary layer on the luminal surface of microvessels has a major role in the exclusion of macromolecules from the underlying endothelial cells. Current structural evidence in the capillaries of frog mesentery indicates a regularity in the structure of the glycocalyx, with a center-to-center fiber spacing of 20 nm and a fiber width of 12 nm, which might explain the observed macromolecular filtering properties. In this study, we used electron micrographs of tissues prepared using perfusion fixation and tannic acid treatment. The digitized images were analyzed using autocorrelation to find common spacings and to establish whether similar structures, hence mechanisms, are present in the microvessel glycocalyces of a variety of mammalian tissues. Continuous glycocalyx layers in mammalian microvessels of choroid, renal tubules, glomerulus, and psoas muscle all showed similar lateral spacings at ∼19.5 nm (possibly in a quasitetragonal lattice) and longer spacings above 100 nm. Individual glycocalyx tufts above fenestrations in the first three of these tissues and also in stomach fundus and jejunum showed evidence for similar short-range structural regularity, but with more disorder. The fiber diameter was estimated as 18.8 (± 0.2) nm, but we believe this is an overestimate because of the staining method used. The implications of these findings are discussed.     

Mechanism of selection of side-chain rotamers in α-helices

In this study, a possible mechanism of selection of side-chain rotamers based on the rotamer distributions in known coiled-coil proteins is suggested. According to this mechanism, interhelical hydrophobic, polar, and packing interactions bring alpha-helices closer to each other and this effect squeezes side chains out of the helix-helix interface. As a result, in dimeric coiled coils and long alpha-alpha-hairpins where alpha-helices are packed in a face-to-face manner, most side chains occupying the a-positions have t-rotamers and those in the d-positions g(-)-rotamers. In tetramers, where alpha-helices are packed side-by-side, most side chains in the a-positions adopt g(-)-rotamers and those in the d-positions t-rotamers.     

A Functional Study of Single Mammalian CNS “Synaptic Bouton”

Single CNS neurons could be dissociated with adherent functional synaptic boutons without using any enzyme, namely when preparing a “synaptic bouton.” This allows experimenters to investigate the effects of presynaptic modulators of synaptic transmission with unprecedented case and accuracy. Moreover, a single bouton can be visualized using fluorescent markers and can also be focally stimulated with electrical pulses. In this communication, high voltage-dependent Ca²⁺ channels of nerve endings, as one of experimental examples using the “synaptic bouton” preparation, are described. Ca²⁺ channels belonging to different subtypes, which trigger GABA release from nerve terminals (boutons) projecting to rat hippocampal CA1 pyramidal neurons, were studied. GABA-ergic evoked inhibitory postsynaptic currents (eIPSCs) were recorded; these currents were evoked by focal stimulation of single boutons in mechanically dissociated neurons and by stimulation of a nerve bundle in slice preparations. Nilvadipine, an L-type Ca²⁺ channel blocker, completely inhibited eIPSCs evoked by stimulation of single boutons but exerted no effect on eIPSCs evoked by low-frequency stimulation of the nerve bundle. Nilvadipine did, however, prevent potentiation of the eIPSC amplitude following high-frequency stimulation of the nerve bundles in slice preparations. ω-Conotoxin-GVIA, an N-type Ca²⁺ channel blocker, and ω-Agatoxin-IVA, a P/Q-type Ca²⁺ channel blocker, completely inhibited the eIPSCs in 33.3 and 83.3% of the recordings from single boutons, respectively. In response to low-frequency nerve bundle stimulation in the slice preparation, both ω-Conotoxin-GVIA and ω-Agatoxin-IVA partially reduced the amplitude of eIPSC, and the residual component could be abolished by Cd²⁺. From these results, the following hypotheses could be drawn. (i) The distribution of P/Q- and N-type Ca²⁺ channels at a single bouton is nonuniform; (ii) when a focal stimulation is applied to a single bouton, L-type Ca²⁺ channels play a significant role in generation of action potentials, which subsequently activate P/Q- and N-type Ca²⁺ channels at GABA release sites; and (iii) action potentials conducted through axons in the slice preparation are sufficient to depolarize the bouton membrane, even when L-type Ca²⁺ channels are suppressed. Neirofiziologiya/Neurophysiology, Vol. 37, No. 2, pp. 181–183, March–April, 2005.     

Is Sequence Heterochrony an Important Evolutionary Mechanism in Mammals?

It is postulated widely that changes in developmental timing (i.e., heterochrony) represent a major mechanism of evolutionary change. However, it is only with recent methodological advances that changes in the order in which development proceeds (sequence heterochrony) can be identified and quantified. We apply these techniques to examine whether heterochrony in the early embryonic (organogenetic) period has played an important role in the diversification of mammals. Although we find clear instances of sequence heterochrony in mammals, particularly between eutherians and marsupials, the majority of mammalian lineages that we could examine (those within the major clades Euarchontoglires and Laurasiatheria) show few or no heterochronic changes in the 116 events examined (e.g., Artiodactyla, Euarchonta, Fereuungulata, Glires, Primates, Rodentia). This is in contrast with the timing shifts reported between and within other tetrapod clades. Our results suggest that sequence heterochrony in embryonic stages has not been a major feature of mammalian evolution. This might be because mammals, and perhaps amniotes in general, develop for an extended time in a protected environment, which could shield the embryos from strong diversifying selection. Our results are also consistent with the view that mammal embryos are subject to special developmental constraints. Therefore, other mechanisms explaining the diversity of extant mammals must be sought.