Spontaneous muscle action potentials fail to develop without fetal-type acetylcholine receptors

In mammals, two combinations of muscle nicotinic acetylcholine receptors (AChRs) are used: α₂βγδ (γ-AChR) or α₂βδ (-AChR). After birth, γ-AChRs are replaced by -AChRs (γ/-switch). The two receptors have different conductances and open times. During perinatal period, the long open time γ-AChRs generate random myofiber action potentials from uniquantal miniature end-plate potentials (mEPPs). -AChRs are suitable for strong adult muscle activities. Since the effect of the γ/-switch on neuromuscular development was unclear, despite the many differences in channel characteristics, we carried out this study to generate γ-subunit-deficient mice. Homozygotes born alive survived for 2 days in a stable condition, and were able to move their forelimbs. Endplate AChRs included -subunits, and muscle fibers had multiple neuromuscular junctions. Both pre- and postsynapses were abnormal and spontaneous action potentials generated from mEPPs were totally absent. Results suggest a requirement for γ-AChRs in mediating synaptically-induced action potential activity critical for neuromuscular development.     

The alpha-galactosyl derivatives of ganglioside GD(1b) are essential for the organization of lipid rafts in RBL-2H3 mast cells

Gangliosides are complex glycosphingolipids that are important in many biological processes. The present study investigated the role of gangliosides in the organization of lipid rafts in RBL-2H3 mast cells and in the modulation of mast cell degranulation via FcRI. The role of gangliosides was examined using two ganglioside deficient cell lines (B6A4A2III-E5 and B6A4C1III-D1) as well as the parent cell line (RBL-2H3). All three cell lines examined express FcRI, Lyn, Syk and LAT. However, only in RBL-2H3 cells were FcRI, LAT and α-galactosyl derivatives of ganglioside GD_1b mobilized to lipid raft domains following FcRI stimulation. The inhibition of glycosphingolipid synthesis in RBL-2H3 cells also resulted in a decrease in the release of β-hexosaminidase activity after FcRI activation. The two mutant cell lines have a reduced release of β-hexosaminidase activity after FcRI stimulation, but not after exposure to calcium ionophore. These results indicate that the α-galactosyl derivatives of ganglioside GD_1b are important in the initial events of FcRI signaling upstream of Ca²⁺ influx. Since the initial signaling events occur in lipid rafts and in the mutant cell lines the rafts are disorganized, these results also suggest that these gangliosides contribute to the correct assembly of lipid rafts and are essential for mast cell activation via FcRI.     

Protein kinase C-α negatively regulates EGF-induced PLC- activity through direct phosphorylation

Phospholipase C- is a PLC isozyme that contains a CDC25 homology domain and a pair of RA domains in addition to a conserved PLC catalytic domain. PLC- is activated by both growth factors and GPCR ligands in a distinct manner. Growth factors such as EGF stimulate PLC- in an RA2 domain-dependent manner through Ras and Rap. On the other hand, several GPCR ligands that are linked with Ga₁₂ or Ga₁₃ can activate PLC- by associating with GTP-RhoA. GTP-RhoA binds with the region in the PLC- Y domain. Gs-linked ligands such as PGE1 and adrenaline stimulate PLC- by cAMP-dependent activation of Epac and Rap2B. PLC- is important for cardiac development and function. In addition, several lines of evidence indicate that PLC- promotes cell growth in an activity-dependent or -independent manner. In particular, PLC--dependent suppression of EGF receptor downregulation contributes to its growth promoting activity. Proper regulation of PLC- activity is essential for preventing tumor formation. Our previous report indicated that EGF-dependent ubiquitination of PLC- is required for the control of PLC--dependent cell growth. Recently, we found that PLC- is phosphorylated by growth factor stimulation, and this is another mechanism of the negative regulation. PLC- is phosphorylated by PKC-α upon stimulation with growth factors such as EGF and PDGF. The EGF-induced phosphorylation of PLC- was abolished by PKC inhibitors and by the expression of the dominant negative mutant of PKC-α. Furthermore, PKC-α was found to phosphorylate PLC- directly in vitro, suggesting that PLC- is a substrate of PKC-α in cells. In addition, PLC- was co-immunoprecipitated with PKC-α in an EGF-dependent manner. Immunocytochemical studies showed that PLC- co-localized with PKC-α in the plasma membrane after EGF stimulation. In addition, inhibition of PKC activity enhanced PLC--mediated PIP₂ hydrolysis, suggesting that PKC-α negatively regulates PLC- activity. Taken together, these results suggest for the first time that PLC- is regulated by PKC-α-dependent phosphorylation.     

Accessibility of DNA polymerases to repair synthesis during nucleotide excision repair in yeast cell-free extracts

Nucleotide excision repair (NER) removes a variety of DNA lesions. Using a yeast cell-free repair system, we have analyzed the repair synthesis step of NER. NER was proficient in yeast mutant cell-free extracts lacking DNA polymerases (Pol) β, ζ or η. Base excision repair was also proficient without Polβ. Repair synthesis of NER was not affected by thermal inactivation of the temperature-sensitive mutant Polα (pol1-17), but was reduced after thermal inactivation of the temperature-sensitive mutant Polδ (pol3-1) or Pol (pol2-18). Residual repair synthesis was observed in pol3-1 and pol2-18 mutant extracts, suggesting a repair deficiency rather than a complete repair defect. Deficient NER in pol3-1 and pol2-18 mutant extracts was specifically complemented by purified yeast Polδ and Pol, respectively. Deleting the polymerase catalytic domain of Pol (pol2-16) also led to a deficient repair synthesis during NER, which was complemented by purified yeast Pol, but not by purified yeast Polη. These results suggest that efficient repair synthesis of yeast NER requires both Polδ and Pol in vitro, and that the low fidelity Polη is not accessible to repair synthesis during NER.     

In Vivo Protein Interactions within the Escherichia coli DNA Polymerase III Core

The mechanisms that control the fidelity of DNA replication are being investigated by a number of approaches, including detailed kinetic and structural studies. Important tools in these studies are mutant versions of DNA polymerases that affect the fidelity of DNA replication. It has been suggested that proper interactions within the core of DNA polymerase III (Pol III) of Escherichia coli could be essential for maintaining the optimal fidelity of DNA replication (H. Maki and A. Kornberg, Proc. Natl. Acad. Sci. USA 84:4389–4392, 1987). We have been particularly interested in elucidating the physiological role of the interactions between the DnaE (α subunit [possessing DNA polymerase activity]) and DnaQ ( subunit [possessing 3′→5′ exonucleolytic proofreading activity]) proteins. In an attempt to achieve this goal, we have used the Saccharomyces cerevisiae two-hybrid system to analyze specific in vivo protein interactions. In this report, we demonstrate interactions between the DnaE and DnaQ proteins and between the DnaQ and HolE (θ subunit) proteins. We also tested the interactions of the wild-type DnaE and HolE proteins with three well-known mutant forms of DnaQ (MutD5, DnaQ926, and DnaQ49), each of which leads to a strong mutator phenotype. Our results show that the mutD5 and dnaQ926 mutations do not affect the subunit-α subunit and subunit-θ subunit interactions. However, the dnaQ49 mutation greatly reduces the strength of interaction of the subunit with both the α and the θ subunits. Thus, the mutator phenotype of dnaQ49 may be the result of an altered conformation of the protein, which leads to altered interactions within the Pol III core.     

Casein kinase I δ/ɛ phosphorylates topoisomerase IIα at serine-1106 and modulates DNA cleavage activity

We previously reported that phosphorylation of topoisomerase (topo) IIα at serine-1106 (Ser-1106) regulates enzyme activity and sensitivity to topo II-targeted drugs. In this study we demonstrate that phosphorylation of Ser-1106, which is flanked by acidic amino acids, is regulated in vivo by casein kinase (CK) Iδ and/or CKI, but not by CKII. The CKI inhibitors, CKI-7 and IC261, reduced Ser-1106 phosphorylation and decreased formation of etoposide-stabilized topo II–DNA cleavable complex. In contrast, the CKII inhibitor, 5,6-dichlorobenzimidazole riboside, did not affect etoposide-stabilized topo II–DNA cleavable complex formation. Since, IC261 specifically targets the Ca²⁺-regulated isozymes, CKIδ and CKI, we examined the effect of down-regulating these enzymes on Ser-1106 phosphorylation. Down-regulation of these isozymes with targeted si-RNAs led to hypophosphorylation of the Ser-1106 containing peptide. However, si-RNA-mediated down-regulation of CKIIα and α′ did not alter Ser-1106 phosphorylation. Furthermore, reduced phosphorylation of Ser-1106, observed in HRR25 (CKIδ/ homologous gene)-deleted Saccharomyces cerevisiae cells transformed with human topo IIα, was enhanced following expression of human CKI. Down-regulation of CKIδ and CKI also led to reduced formation of etoposide stabilized topo II–DNA cleavable complex. These results provide strong support for an essential role of CKIδ/ in phosphorylating Ser-1106 in human topo IIα and in regulating enzyme function.     

Macroporous poly(glycidyl methacrylate-co-ethylene glycol dimethacrylate) resins—Versatile immobilization supports for biocatalysts

Crosslinked macroporous hydrophilic poly(glycidyl methacrylate-co-ethylene glycol dimethacrylate)s [abbreviated poly(GMA-co-EGDMA)] with identical chemical structure (60% of glycidyl methacrylate) but with varied average pore sizes (from 30 to 560 nm), specific surface areas (from 13.2 to 106.0 m²/g), specific volumes (from 0.755 to 1.191 cm³/g) and particle sizes (less than 100–650 μm) were synthesized via suspension polymerization. The influence of the resin properties on the loading of Candida antarctica lipase B (Cal-B) during immobilization and on the hydrolytic (hydrolysis of para-nitrophenyl acetate) and synthetic (ring-opening polymerization of -caprolactone) activity of the immobilized Cal-B were studied. Immobilization of Cal-B was performed at different temperatures and pH values. Cal-B immobilized at 30 °C and pH 6.8 was leading to increased activities. By decreasing the resin diameter: (i) the amount of Cal-B adsorbed onto the resin decreases, (ii) the conversion of para-nitrophenyl acetate increases (hydrolytic activity) and (iii) the conversion of -caprolactone and the molecular weight of the synthesized poly--caprolactone increases (synthetic activity). Varying the porosity parameters results in different hydrolytic and synthetic activities. Pore sizes of all synthesized resins (from 30 to 560 nm) are big enough to overcome diffusion limitations. Therefore increasing the pore size of the resins resulted in a large increase in the hydrolytic and synthetic activity. Increasing the specific surface area resulted in an increase of activities, as the result of alleviated substrate approach to the immobilized enzyme zones. The obtained results were compared to results from dried Cal-B powder and Novozyme 435. Resin with particle size less than 100 μm and pore size 48 nm had much higher hydrolytic activity than both dried Cal-B powder and Novozyme 435. Nearly similar trends were observed for the synthetic activity.Via the DMSO leaching technique we could show that about 80% of Cal-B was covalently attached to the macroporous resin.     

The regulation of glycine transporter GLYT1 is mainly mediated by protein kinase Calpha in C6 glioma cells

Glycine has been shown to possess important functions as a bidirectional neurotransmitter. At synaptic clefts, the concentration of glycine is tightly regulated by the uptake of glycine released from nerve terminals into glial cells by the transporter GLYT1. It has been recently demonstrated that protein kinase C (PKC) mediates the downregulation of GLYT1 activity in several cell systems. However, it remains to be elucidated which subtypes of PKC might be important in the regulation of GLYT1 activity. In this study, we attempted to make clear the mechanism of the phorbol 12-myristate 13-acetate (PMA)-suppressed uptake of glycine in C6 glioma cells which have the native expression of GLYT1. In C6 cells, the expression of PKCα, PKCδ, and PKC of the PMA-activated subtypes was detected. The PMA-suppressed action was fully reversed by the removal of both extracellular and intracellular Ca²⁺. Furthermore, the inhibitory effects of PMA or thymeleatoxin (THX), which is a selective activator of conventional PKC (cPKC), were blocked by the downregulation of all PKCs expressed in C6 cells by long-term incubation with THX, or pretreatment with GF109203X or Gö6983, which are broad inhibitors of PKC, or Gö6976, a selective inhibitor of cPKC. On the other hand, treatment of C6 cells with ingenol, a selective activator of novel PKCs, especially PKCδ and PKC, did not affect the transport of glycine. Silencing of PKCδ expression by using RNA interference or pretreatment with the inhibitor peptide for PKC had no effect on the PMA-suppressed uptake of glycine. Together, these results suggest PKCα to be a crucial factor in the regulation of glycine transport in C6 cells.     

Phylogenetic Diversity of Bacterial and Archaeal Communities in the Anoxic Zone of the Cariaco Basin

Microbial community samples were collected from the anoxic zone of the Cariaco Basin at depths of 320, 500, and 1,310 m on a November 1996 cruise and were used to construct 16S ribosomal DNA libraries. Of 60 nonchimeric sequences in the 320-m library, 56 belonged to the subdivision of the Proteobacteria (-Proteobacteria) and 53 were closely related to ectosymbionts of Rimicaris exoculata and Alvinella pompejana, which are referred to here as epsilon symbiont relatives (ESR). The 500-m library contained sequences affiliated with the fibrobacteria, the Flexibacter-Cytophaga-Bacteroides division, the division Verrucomicrobia, the division Proteobacteria, and the OP3 candidate division. The Proteobacteria included members of the γ, δ, and new candidate subdivisions, and γ-proteobacterial sequences were dominant (25.6%) among the proteobacterial sequences. As in the 320-m library, the majority of the -proteobacteria belonged to the ESR group. The genus Fibrobacter and its relatives were the second largest group in the library (23.6%), followed by the δ-proteobacteria and the -proteobacteria. The 1,310-m library had the greatest diversity; 59 nonchimeric clones in the library contained 30 unique sequences belonging to the planctomycetes, the fibrobacteria, the Flexibacter-Cytophaga-Bacteroides division, the Proteobacteria, and the OP3 and OP8 candidate divisions. The proteobacteria included members of new candidate subdivisions and the β, γ, δ, and -subdivisions. ESR sequences were still present in the 1,310-m library but in a much lower proportion (8.5%). One archaeal sequence was present in the 500-m library (2% of all microorganisms in the library), and eight archaeal sequences were present in the 1,310-m library (13.6%). All archaeal sequences fell into two groups; two clones in the 1,310-m library belonged to the kingdom Crenarchaeota and the remaining sequences in both libraries belonged to the kingdom Euryarchaeota. The latter group appears to be related to the Eel-TA1f2 sequence, which belongs to an archaeon suggested to be able to oxidize methane anaerobically. Based on phylogenetic inferences and measurements of dark CO₂ fixation, we hypothesized that (i) the ESR are autotrophic anaerobic sulfide oxidizers, (ii) sulfate reduction and fermentative metabolism may be carried out by a large number of bacteria in the 500- and 1,310-m libraries, and (iii) members of the Euryarchaeota found in relatively large numbers in the 1,310-m library may be involved in anaerobic methane oxidation. Overall, the composition of microbial communities from the Cariaco Basin resembles the compositions of communities from several anaerobic sediments, supporting the hypothesis that the Cariaco Basin water column is similar to anaerobic sediments.     

Dual regulation of the cardiac L-type calcium channel in L6 cells by protein kinase C

The role of protein kinase C (PKC) in the regulation of cardiac L-type Ca²⁺ channel activity (LCC) was investigated in L6 rat neonatal myoblasts. Depolarization of fura-2 loaded cells with 140 mM KCl activated a Ba²⁺ influx pathway that was blocked by nifedipine and stimulated by (−) Bay K 8644. At least two splice variants of the α_1C subunit of the cardiac LCC were identified by PCR; the α_1S subunit of the skeletal muscle LCC was not detected. Peptides that specifically inhibit translocation of the novel, Ca²⁺-independent δ and PKC isozymes reduced Ba²⁺ influx by 27% and 19%, respectively, whereas a corresponding peptide directed against translocation of classical PKC α had no effect. Ingenol 3,20-dibenzoate, an agent reported to selectively activate novel PKCs, increased Ba²⁺ uptake by 31% while ethanol, a PKC agonist, enhanced uptake by 38%. In contrast, selective activation of classical PKCs with thymeleatoxin or an agonist peptide reduced Ba²⁺ influx by 23–33%. Ba²⁺ influx was reduced by 30–40% when cells were treated with either a PKC inhibitor (Gö 6983, bisindolylmaleimide) or the PKC activator phorbol-12-myristate-13-acetate. We propose that novel, Ca²⁺-insensitive PKC(s) enhance cardiac Ca²⁺ channel activity in L6 cells under basal conditions while activation of the classical, Ca²⁺-sensitive PKC(s) inhibits channel activity. These findings provide the first evidence that different PKC isozymes exert class-specific opposing effects on cardiac L-type Ca²⁺ channel activity in L6 myoblasts.     

Stable Isotope Fractionation Caused by Glycyl Radical Enzymes during Bacterial Degradation of Aromatic Compounds

Stable isotope fractionation was studied during the degradation of m-xylene, o-xylene, m-cresol, and p-cresol with two pure cultures of sulfate-reducing bacteria. Degradation of all four compounds is initiated by a fumarate addition reaction by a glycyl radical enzyme, analogous to the well-studied benzylsuccinate synthase reaction in toluene degradation. The extent of stable carbon isotope fractionation caused by these radical-type reactions was between enrichment factors () of −1.5 and −3.9‰, which is in the same order of magnitude as data provided before for anaerobic toluene degradation. Based on our results, an analysis of isotope fractionation should be applicable for the evaluation of in situ bioremediation of all contaminants degraded by glycyl radical enzyme mechanisms that are smaller than 14 carbon atoms. In order to compare carbon isotope fractionations upon the degradation of various substrates whose numbers of carbon atoms differ, intrinsic (_intrinsic) were calculated. A comparison of _intrinsic at the single carbon atoms of the molecule where the benzylsuccinate synthase reaction took place with compound-specific elucidated that both varied on average to the same extent. Despite variations during the degradation of different substrates, the range of found for glycyl radical reactions was reasonably narrow to propose that rough estimates of biodegradation in situ might be given by using an average if no fractionation factor is available for single compounds.     

The effect of hormone therapy on olfactory sensitivity is dependent on apolipoprotein E genotype

Patients with Alzheimer's disease (AD) show a deficit in olfactory threshold sensitivity. The Apolipoprotein E (ApoE) 4 allele is associated with increased risk of AD and earlier symptom onset. Hormone therapy (HT) may exert neuroprotective effects on brain areas affected by AD. The current study investigated the effect of HT on performance on an olfactory threshold test in 4 positive and 4 negative non-hysterectomized, non-demented, elderly females and AD patients. Among the non-demented participants, 4 positive females who had received HT performed 1) significantly better than those without HT, and 2) at levels similar to those of 4 negative females. In contrast, those without HT who were 4 positive performed significantly worse than those who were 4 negative. HT had no effect on performance in AD patients regardless of 4 status. These results suggest that HT may offer protection against loss of olfactory function in 4 positive individuals in preclinical stages of AD. Future research is warranted in order to investigate further the neuroprotective role of HT on sensory and cognitive functions in non-demented aging individuals.     

Lysine-2,3-Aminomutase and β-Lysine Acetyltransferase Genes of Methanogenic Archaea Are Salt Induced and Are Essential for the Biosynthesis of Nɛ-Acetyl-β-Lysine and Growth at High Salinity

The compatible solute N-acetyl-β-lysine is unique to methanogenic archaea and is produced under salt stress only. However, the molecular basis for the salt-dependent regulation of N-acetyl-β-lysine formation is unknown. Genes potentially encoding lysine-2,3-aminomutase (ablA) and β-lysine acetyltransferase (ablB), which are assumed to catalyze N-acetyl-β-lysine formation from α-lysine, were identified on the chromosomes of the methanogenic archaea Methanosarcina mazei Gö1, Methanosarcina acetivorans, Methanosarcina barkeri, Methanococcus jannaschii, and Methanococcus maripaludis. The order of the two genes was identical in the five organisms, and the deduced proteins were very similar, indicating a high degree of conservation of structure and function. Northern blot analysis revealed that the two genes are organized in an operon (termed the abl operon) in M. mazei Gö1. Expression of the abl operon was strictly salt dependent. The abl operon was deleted in the genetically tractable M. maripaludis. Δabl mutants of M. maripaludis no longer produced N-acetyl-β-lysine and were incapable of growth at high salt concentrations, indicating that the abl operon is essential for N-acetyl-β-lysine synthesis. These experiments revealed the first genes involved in the biosynthesis of compatible solutes in methanogens.

     

Molecular modeling of substrate selectivity of Candida antarctica lipase B and Candida rugosa lipase towards c9, t11- and t10, c12-conjugated linoleic acid

Molecular modeling was used to clarify the mechanism of the selectivity of Candida antarctica lipase B and Candida rugosa lipase towards cis9, trans11 (c9, t11-) and trans10, cis12 (t10, c12-) conjugated linoleic acid. Hydrogen bonds network, substrate conformation, binding affinity and water molecules in the binding site were analyzed. Substrate conformation and binding affinity were not correlated with the experimental results of the substrate selectivity. On the contrary, better enzyme preference towards a substrate was correlated with two stronger hydrogen bonds (His-NH-O_a and His-NH-Ser-O_γ) and less water molecules between the substrate the binding pocket. Possible explanation of these was discussed.     

Activation of Protein Kinase C Triggers Its Ubiquitination and Degradation

Treatment of cells with tumor-promoting phorbol esters results in the activation but then depletion of phorbol ester-responsive protein kinase C (PKC) isoforms. The ubiquitin-proteasome pathway has been implicated in regulating the levels of many cellular proteins, including those involved in cell cycle control. We report here that in 3Y1 rat fibroblasts, proteasome inhibitors prevent the depletion of PKC isoforms α, δ, and in response to the tumor-promoting phorbol ester 12-O-tetradecanoylphorbol-13-acetate (TPA). Proteasome inhibitors also blocked the tumor-promoting effects of TPA on 3Y1 cells overexpressing c-Src, which results from the depletion of PKC δ. Consistent with the involvement of the ubiquitin-proteasome pathway in the degradation of PKC isoforms, ubiquitinated PKC α, δ, and were detected within 30 min of TPA treatment. Diacylglycerol, the physiological activator of PKC, also stimulated ubiquitination and degradation of PKC, suggesting that ubiquitination is a physiological response to PKC activation. Compounds that inhibit activation of PKC prevented both TPA- and diacylglycerol-induced PKC depletion and ubiquitination. Moreover, a kinase-dead ATP-binding mutant of PKC α could not be depleted by TPA treatment. These data are consistent with a suicide model whereby activation of PKC triggers its own degradation via the ubiquitin-proteasome pathway.     

Host-Symbiont Relationships in Hydrothermal Vent Gastropods of the Genus Alviniconcha from the Southwest Pacific

Hydrothermal vent gastropods of the genus Alviniconcha are unique among metazoans in their ability to derive their nutrition from chemoautotrophic γ- and -proteobacterial endosymbionts. Although host-symbiont relationships in Alviniconcha gastropods from the Central Indian Ridge in the Indian Ocean and the Mariana Trough in the Western Pacific have been studied extensively, host-symbiont relationships in Alviniconcha gastropods from the Southwest Pacific remain largely unknown. Phylogenetic analysis using mitochondrial cytochrome c oxidase subunit I gene sequences of host gastropods from the Manus, North Fiji, and Lau Back-Arc Basins in the Southwest Pacific has revealed a new host lineage in a Alviniconcha gastropod from the Lau Basin and the occurrence of the host lineage Alviniconcha sp. type 2 in the Manus Basin. Based on 16S rRNA gene sequences of bacterial endosymbionts, two γ-proteobacterial lineages and one -proteobacterial lineage were identified in the present study. The carbon isotopic compositions of the biomass and fatty acids of the gastropod tissues suggest that the γ- and -proteobacterial endosymbionts mediate the Calvin-Benson cycle and the reductive tricarboxylic acid cycle, respectively, for their chemoautotrophic growth. Coupling of the host and symbiont lineages from the three Southwest Pacific basins revealed that each of the Alviniconcha lineages harbors different bacterial endosymbionts belonging to either the γ- or -Proteobacteria. The host specificity exhibited in symbiont selection provides support for the recognition of each of the host lineages as a distinct species. The results from the present study also suggest the possibility that Alviniconcha sp. types 1 and 2 separately inhabit hydrothermal vent sites approximately 120 m apart in the North Fiji Basin and 500 m apart in the Manus Basin.     

Dominant Microbial Populations in Limestone-Corroding Stream Biofilms, Frasassi Cave System, Italy

Waters from an extensive sulfide-rich aquifer emerge in the Frasassi cave system, where they mix with oxygen-rich percolating water and cave air over a large surface area. The actively forming cave complex hosts a microbial community, including conspicuous white biofilms coating surfaces in cave streams, that is isolated from surface sources of C and N. Two distinct biofilm morphologies were observed in the streams over a 4-year period. Bacterial 16S rDNA libraries were constructed from samples of each biofilm type collected from Grotta Sulfurea in 2002. β-, γ-, δ-, and -proteobacteria in sulfur-cycling clades accounted for ≥75% of clones in both biofilms. Sulfate-reducing and sulfur-disproportionating δ-proteobacterial sequences in the clone libraries were abundant and diverse (34% of phylotypes). Biofilm samples of both types were later collected at the same location and at an additional sample site in Ramo Sulfureo and examined, using fluorescence in situ hybridization (FISH). The biomass of all six stream biofilms was dominated by filamentous γ-proteobacteria with Beggiatoa-like and/or Thiothrix-like cells containing abundant sulfur inclusions. The biomass of -proteobacteria detected using FISH was consistently small, ranging from 0 to less than 15% of the total biomass. Our results suggest that S cycling within the stream biofilms is an important feature of the cave biogeochemistry. Such cycling represents positive biological feedback to sulfuric acid speleogenesis and related processes that create subsurface porosity in carbonate rocks.     

Regulatory links between PLC enzymes and Ras superfamily GTPases: Signalling via PLC

A growing body of work implies that links between PLC isoforms, in particular PLC, and small G-proteins from Ras superfamily could be important in regulation of a number of cellular processes. Through successful use of biochemistry and structural biology, several interactions have been characterized providing some ideas about the regulatory mechanisms. A number of signalling pathways have also been suggested that could involve direct interaction of Ras and Rho GTPases with PLC. Importantly, several studies combining cell biology and genetics have provided new insights into functions of PLC and highlighted the importance of this approach to extend further and consolidate currently incomplete picture regarding its roles in development and disease.     

Protein and drug interactions in the minor groove of DNA

Interactions between proteins, drugs, water and B-DNA minor groove have been analyzed in crystal structures of 60 protein–DNA and 14 drug–DNA complexes. It was found that only purine N3, pyrimidine O2, guanine N2 and deoxyribose O4′ are involved in the interactions, and that contacts to N3 and O2 are most frequent and more polar than contacts to O4′. Many protein contacts are mediated by water, possibly to increase the DNA effective surface. Fewer water-mediated contacts are observed in drug complexes. The distributions of ligands around N3 are significantly more compact than around O2, and distributions of water molecules are the most compact. Distributions around O4′ are more diffuse than for the base atoms but most distributions still have just one binding site. Ligands bind to N3 and O2 atoms in analogous positions, and simultaneous binding to N3 and N2 in guanines is extremely rare. Contacts with two consecutive nucleotides are much more frequent than base–sugar contacts within one nucleotide. The probable reason for this is the large energy of deformation of hydrogen bonds for the one nucleotide motif. Contacts of Arg, the most frequent amino acid ligand, are stereochemically indistinguishable from the binding of the remaining amino acids except asparagine (Asn) and phenylalanine (Phe). Asn and Phe bind in distinct ways, mostly to a deformed DNA, as in the complexes of TATA-box binding proteins. DNA deformation concentrates on dinucleotide regions with a distinct deformation of the δ and backbone torsion angles for the Asn and δ, , ζ and χ for the Phe-contacted regions.     

Drosophila and vertebrate casein kinase Idelta exhibits evolutionary conservation of circadian function

Mutations lowering the kinase activity of Drosophila Doubletime (DBT) and vertebrate casein kinase I/δ (CKI/δ) produce long-period, short-period, and arrhythmic circadian rhythms. Since most ckI short-period mutants have been isolated in mammals, while the long-period mutants have been found mostly in Drosophila, lowered kinase activity may have opposite consequences in flies and vertebrates, because of differences between the kinases or their circadian mechanisms. However, the results of this article establish that the Drosophila dbt mutations have similar effects on period (PER) protein phosphorylation by the fly and vertebrate enzymes in vitro and that Drosophila DBT has an inhibitory C-terminal domain and exhibits autophosphorylation, as does vertebrate CKI/δ. Moreover, expression of either Drosophila DBT or the vertebrate CKIδ kinase carrying the Drosophila dbt^S or vertebrate tau mutations in all circadian cells leads to short-period circadian rhythms. By contrast, vertebrate CKIδ carrying the dbt^L mutation does not lengthen circadian rhythms, while Drosophila DBT^L does. Different effects of the dbt^S and tau mutations on the oscillations of PER phosphorylation suggest that the mutations shorten the circadian period differently. The results demonstrate a high degree of evolutionary conservation of fly and vertebrate CKIδ and of the functions affected by their period-shortening mutations.