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991.
Thomas R. H. B��ch Dominik Heling Ellen Damm Thomas Gudermann Andreas Breit 《The Journal of biological chemistry》2009,284(39):26411-26420
Melanocortin-4 receptor (MC4R)-induced anorexigenic signaling in the hypothalamus controls body weight and energy homeostasis. So far, MC4R-induced signaling has been exclusively attributed to its coupling to Gs proteins. In line with this monogamous G protein coupling profile, most MC4R mutants isolated from obese individuals showed a reduced ability to activate Gs. However, some mutants displayed enhanced Gs coupling, suggesting that signaling pathways independent of Gs may be involved in MC4R-mediated anorexigenic signaling. Here we report that the Gs signaling-deficient MC4R-D90N mutant activates G proteins in a pertussis toxin-sensitive manner, indicating that this mutant is able to selectively interact with Gi/o proteins. Analyzing a hypothalamic cell line (GT1-7 cells), we observed activation of pertussis toxin-sensitive G proteins by the wild-type MC4R as well, reflecting multiple coupling of the MC4R to Gs and Gi/o proteins in an endogenous cell system. Surprisingly, the agouti-related protein, which has been classified as a MC4R antagonist, selectively activates Gi/o signaling in GT1-7 cells. Thus, the agouti-related protein antagonizes melanocortin-dependent Gs activation not only by competitive antagonism but additionally by initiating Gi/o protein-induced signaling as a biased agonist.The melanocortin system has been shown to play a pivotal role in food intake and energy homeostasis. Therefore, dysfunction of the melanocortin system inevitably leads to an obese phenotype in mammals. Accordingly, targeted disruption of the melanocortin-4 receptor (MC4R)2 gene in mice causes an obesity-diabetes syndrome characterized by hyperphagia, hyperinsulinemia, and hyperglycemia (1). The importance of MC4R signaling in the regulation of human metabolism has been highlighted by the finding that mutations in the MC4R gene are the most frequent monogenic cause of severe obesity (2–7).Signaling pathways involved in MC4R-mediated regulation of energy homeostasis have been attributed to its coupling to Gs proteins and the resulting activation of the protein kinase A pathway (8, 9). Agouti and agouti-related protein (AGRP) are the only known endogenously occurring neuropeptides that block GPCR activity and are, therefore, classified as MCR antagonists. AGRP has been shown to block melanocortin signaling at MC3R and MC4R subtypes (10). In addition, it has been proposed that AGRP decreases basal as well as forskolin-promoted adenylyl cyclase activity, thus also acting as an inverse agonist on basal MCR activity (11). However, recent studies revealed that the effects of AGRP on appetite control are independent of melanocortin signaling (12, 13). For example, in mice deficient of the melanocortin precursor proopiomelanocortin starvation after AGRP neuron ablation is independent of melanocortin signaling (13). Thus, the orexigenic effects induced by AGRP appear to be mediated in a melanocortin-independent manner by a so far unknown mechanism.Interestingly, the aforementioned MC4R mutants isolated from obese patients exerted inconsistent effects on Gs signaling. For example, the MC4R-G181D or -S94R mutants showed a loss-of-function phenotype, whereas the MC4R-P78L or -R165W variants exhibited reduced function, whereas other mutants (MC4R-G253S, -I317T, -I251L) showed no functional alterations. Even more surprisingly, some mutants (MC4R-S127L, -P230L) constitutively increased Gs-dependent adenylyl cyclase activity (5). Therefore, no clear correlation could be drawn between the cellular phenotype resulting from these mutations and obesity observed in vivo.Melanocortin-independent actions of AGRP and non-uniform effects of obesity-associated mutations on Gs signaling suggest that the MC4R receptor may interact with G proteins other than Gs. The D90N mutation of the MC4R has also been associated with severe early onset obesity (14). This MC4R variant binds melanocortins with unchanged high affinity, but agonist binding does not initiate Gs signaling (14). Thus, the D90N variant represents an excellent tool to analyze putative Gs-independent signaling pathways of the MC4R.Directly measuring incorporation of GTPγ35S, we show herein that the wild-type MC4R and the MC4R-D90N mutant activate pertussis toxin (PTX)-sensitive Gi/o proteins. Multiple coupling of the MC4R to Gs and Gi/o proteins in HEK293 cells is reflected by cAMP accumulation, as treatment of cells with PTX significantly increased melanocortin-induced cAMP accumulation, indicative of simultaneous activation of adenylyl cyclase stimulating and inhibiting pathways. Using a hypothalamic cell line (GT1-7 cells) endogenously expressing MC4R, we demonstrate PTX-sensitive melanocortin-induced GTPγ35S incorporation and an increase in MC4R-mediated cAMP accumulation in response to toxin treatment. In addition, we show that AGRP, assumed to be an antagonist of the MC4R, promotes PTX-sensitive signaling in GT1-7 cells and, thus, exhibits biased agonistic actions on MC4R in hypothalamic cells. These data may explain melanocortin-independent AGRP signaling and define the MC4R as an interface integrating anorexigenic and orexigenic signaling depending on the stimulus received. 相似文献
992.
993.
Denise A. Berti Cain Morano Lilian C. Russo Leandro M. Castro Fernanda M. Cunha Xin Zhang Juan Sironi Cl��cio F. Klitzke Emer S. Ferro Lloyd D. Fricker 《The Journal of biological chemistry》2009,284(21):14105-14116
Thimet oligopeptidase (EC 3.4.24.15; EP24.15) is an intracellular enzyme
that has been proposed to metabolize peptides within cells, thereby affecting
antigen presentation and G protein-coupled receptor signal transduction.
However, only a small number of intracellular substrates of EP24.15 have been
reported previously. Here we have identified over 100 peptides in human
embryonic kidney 293 (HEK293) cells that are derived from intracellular
proteins; many but not all of these peptides are substrates or products of
EP24.15. First, cellular peptides were extracted from HEK293 cells and
incubated in vitro with purified EP24.15. Then the peptides were
labeled with isotopic tags and analyzed by mass spectrometry to obtain
quantitative data on the extent of cleavage. A related series of experiments
tested the effect of overexpression of EP24.15 on the cellular levels of
peptides in HEK293 cells. Finally, synthetic peptides that corresponded to 10
of the cellular peptides were incubated with purified EP24.15 in
vitro, and the cleavage was monitored by high pressure liquid
chromatography and mass spectrometry. Many of the EP24.15 substrates
identified by these approaches are 9–11 amino acids in length,
supporting the proposal that EP24.15 can function in the degradation of
peptides that could be used for antigen presentation. However, EP24.15 also
converts some peptides into products that are 8–10 amino acids, thus
contributing to the formation of peptides for antigen presentation. In
addition, the intracellular peptides described here are potential candidates
to regulate protein interactions within cells.Intracellular protein turnover is a crucial step for cell functioning, and
if this process is impaired, the elevated levels of aged proteins usually lead
to the formation of intracellular insoluble aggregates that can cause severe
pathologies (1). In mammalian
cells, most proteins destined for degradation are initially tagged with a
polyubiquitin chain in an energy-dependent process and then digested to small
peptides by the 26 S proteasome, a large proteolytic complex involved in the
regulation of cell division, gene expression, and other key processes
(2,
3). In eukaryotes, 30–90%
of newly synthesized proteins may be degraded by proteasomes within minutes of
synthesis (3,
4). In addition to proteasomes,
other extralysosomal proteolytic systems have been reported
(5,
6). The proteasome cleaves
proteins into peptides that are typically 2–20 amino acids in length
(7). In most cases, these
peptides are thought to be rapidly hydrolyzed into amino acids by
aminopeptidases
(8–10).
However, some intracellular peptides escape complete degradation and are
imported into the endoplasmic reticulum where they associate with major
histocompatibility complex class I
(MHC-I)3 molecules and
traffic to the cell surface for presentation to the immune system
(10–12).
Additionally, based on the fact that free peptides added to the intracellular
milieu can regulate cellular functions mediated by protein interactions such
as gene regulation, metabolism, cell signaling, and protein targeting
(13,
14), intracellular peptides
generated by proteasomes that escape degradation have been suggested to play a
role in regulating protein interactions
(15). Indeed, oligopeptides
isolated from rat brain tissue using the catalytically inactive EP24.15 (EC
3.4.24.15) were introduced into Chinese hamster ovarian-S and HEK293 cells and
were found capable of altering G protein-coupled receptor signal transduction
(16). Moreover, EP24.15
overexpression itself changed both angiotensin II and isoproterenol signal
transduction, suggesting a physiological function for its intracellular
substrates/products (16).EP24.15 is a zinc-dependent peptidase of the metallopeptidase M3 family
that contains the HEXXH motif
(17). This enzyme was first
described as a neuropeptide-degrading enzyme present in the soluble fraction
of brain homogenates (18).
Whereas EP24.15 can be secreted
(19,
20), its predominant location
in the cytosol and nucleus suggests that the primary function of this enzyme
is not the extracellular degradation of neuropeptides and hormones
(21,
22). EP24.15 was shown in
vivo to participate in antigen presentation through MHC-I
(23–25)
and in vitro to bind
(26) or degrade
(27) some MHC-I associated
peptides. EP24.15 has also been shown in vitro to degrade peptides
containing 5–17 amino acids produced after proteasome digestion of
β-casein (28). EP24.15
shows substrate size restriction to peptides containing from 5 to 17 amino
acids because of its catalytic center that is located in a deep channel
(29). Despite the size
restriction, EP24.15 has a broad substrate specificity
(30), probably because a
significant portion of the enzyme-binding site is lined with potentially
flexible loops that allow reorganization of the active site following
substrate binding (29).
Recently, it has also been suggested that certain substrates may be cleaved by
an open form of EP24.15 (31).
This characteristic is supported by the ability of EP24.15 to accommodate
different amino acid residues at subsites S4 to S3′, which even includes
the uncommon post-proline cleavage
(30). Such biochemical and
structural features make EP24.15 a versatile enzyme to degrade structurally
unrelated oligopeptides.Previously, brain peptides that bound to catalytically inactive EP24.15
were isolated and identified using mass spectrometry
(22). The majority of peptides
captured by the inactive enzyme were intracellular protein fragments that
efficiently interacted with EP24.15; the smallest peptide isolated in these
assays contained 5 and the largest 17 amino acids
(15,
16,
22,
32), which is within the size
range previously reported for natural and synthetic substrates of EP24.15
(18,
30,
33,
34). Interestingly, the
peptides released by the proteasome are in the same size range of EP24.15
competitive inhibitors/substrates
(7,
35,
36). Taken altogether, these
data suggest that in the intracellular environment EP24.15 could further
cleave proteasome-generated peptides unrelated to MHC-I antigen presentation
(15).Although the mutated inactive enzyme “capture” assay was
successful in identifying several cellular protein fragments that were
substrates for EP24.15, it also found some interacting peptides that were not
substrates. In this study, we used several approaches to directly screen for
cellular peptides that were cleaved by EP24.15. The first approach involved
the extraction of cellular peptides from the HEK293 cell line, incubation
in vitro with purified EP24.15, labeling with isotopic tags, and
analysis by mass spectrometry to obtain quantitative data on the extent of
cleavage. The second approach examined the effect of EP24.15 overexpression on
the cellular levels of peptides in the HEK293 cell line. The third set of
experiments tested synthetic peptides with purified EP24.15 in vitro,
and examined cleavage by high pressure liquid chromatography and mass
spectrometry. Collectively, these studies have identified a large number of
intracellular peptides, including those that likely represent the endogenous
substrates and products of EP24.15, and this original information contributes
to a better understanding of the function of this enzyme in vivo. 相似文献
994.
Giovanni Maga Barbara van Loon Emmanuele Crespan Giuseppe Villani Ulrich H��bscher 《The Journal of biological chemistry》2009,284(21):14267-14275
Abasic (AP) sites are very frequent and dangerous DNA lesions. Their
ability to block the advancement of a replication fork has been always viewed
as a consequence of their inhibitory effect on the DNA synthetic activity of
replicative DNA polymerases (DNA pols). Here we show that AP sites can also
affect the strand displacement activity of the lagging strand DNA pol δ,
thus preventing proper Okazaki fragment maturation. This block can be overcome
through a polymerase switch, involving the combined physical and functional
interaction of DNA pol β and Flap endonuclease 1. Our data identify a
previously unnoticed deleterious effect of the AP site lesion on normal cell
metabolism and suggest the existence of a novel repair pathway that might be
important in preventing replication fork stalling.Loss of purine and pyrimidine bases is a significant source of DNA damage
in prokaryotic and eukaryotic organisms. Abasic (apurinic and apyrimidinic)
lesions occur spontaneously in DNA; in eukaryotes it has been estimated that
about 104 depurination and 102 depyrimidation events
occur per genome per day. An equally important source of abasic DNA lesions
results from the action of DNA glycosylases, such as uracil glycosylase, which
excises uracil arising primarily from spontaneous deamination of cytosines
(1). Although most AP sites are
removed by the base excision repair
(BER)5 pathway, a
small fraction of lesions persists, and DNA with AP lesions presents a strong
block to DNA synthesis by replicative DNA polymerases (DNA pols)
(2,
3). Several studies have been
performed to address the effects of AP sites on the template DNA strand on the
synthetic activity of a variety of DNA pols. The major replicative enzyme of
eukaryotic cells, DNA pol δ, was shown to be able to bypass an AP
lesion, but only in the presence of the auxiliary factor proliferating cell
nuclear antigen (PCNA) and at a very reduced catalytic efficiency if compared
with an undamaged DNA template
(4). On the other hand, the
family X DNA pols β and λ were shown to bypass an AP site but in a
very mutagenic way (5). Recent
genetic evidence in Saccharomyces cerevisiae cells showed that DNA
pol δ is the enzyme replicating the lagging strand
(6). According to the current
model for Okazaki fragment synthesis
(7–9),
the action of DNA pol δ is not only critical for the extension of the
newly synthesized Okazaki fragment but also for the displacement of an RNA/DNA
segment of about 30 nucleotides on the pre-existing downstream Okazaki
fragment to create an intermediate Flap structure that is the target for the
subsequent action of the Dna2 endonuclease and the Flap endonuclease 1
(Fen-1). This process has the advantage of removing the entire RNA/DNA hybrid
fragment synthesized by the DNA pol α/primase, potentially containing
nucleotide misincorporations caused by the lack of a proofreading exonuclease
activity of DNA pol α/primase. This results in a more accurate copy
synthesized by DNA pol δ. The intrinsic strand displacement activity of
DNA pol δ, in conjunction with Fen-1, PCNA, and replication protein A
(RP-A), has been also proposed to be essential for the S phase-specific long
patch BER pathway (10,
11). Although it is clear that
an AP site on the template strand is a strong block for DNA pol
δ-dependent synthesis on single-stranded DNA, the functional
consequences of such a lesion on the ability of DNA pol δ to carry on
strand displacement synthesis have never been investigated so far. Given the
high frequency of spontaneous hydrolysis and/or cytidine deamination events,
any detrimental effect of an AP site on the strand displacement activity of
DNA pol δ might have important consequences both for lagging strand DNA
synthesis and for long patch BER. In this work, we addressed this issue by
constructing a series of synthetic gapped DNA templates with a single AP site
at different positions with respect to the downstream primer to be displaced
by DNA pol δ (see Fig.
1A). We show that an AP site immediately upstream of a
single- to double-strand DNA junction constitutes a strong block to the strand
displacement activity of DNA pol δ, even in the presence of RP-A and
PCNA. Such a block could be resolved only through a “polymerase
switch” involving the concerted physical and functional interaction of
DNA pol β and Fen-1. The closely related DNA pol λ could only
partially substitute for DNA pol β. Based on our data, we propose that
stalling of a replication fork by an AP site not only is a consequence of its
ability to inhibit nucleotide incorporation by the replicative DNA pols but
can also stem from its effects on strand displacement during Okazaki fragment
maturation. In summary, our data suggest the existence of a novel repair
pathway that might be important in preventing replication fork stalling and
identify a previously unnoticed deleterious effect of the AP site lesion on
normal cell metabolism.Open in a separate windowFIGURE 1.An abasic site immediately upstream of a double-stranded DNA region
inhibits the strand displacement activity of DNA polymerase δ. The
reactions were performed as described under “Experimental
Procedures.” A, schematic representation of the various DNA
templates used. The size of the resulting gaps is indicated in nt. The
position of the AP site on the 100-mer template strand is indicated relative
to the 3′ end. Base pairs in the vicinity of the lesion are indicated by
dashes. The size of the gaps (35–38 nt) is consistent with the
size of ssDNA covered by a single RP-A molecule, which has to be released
during Okazaki fragment synthesis when the DNA pol is approaching the
5′-end of the downstream fragment. When the AP site is covered by the
downstream terminator oligonucleotide (Gap-3 and Gap-1 templates) the
nucleotide placed on the opposite strand is C to mimic the situation generated
by spontaneous loss of a guanine or excision of an oxidized guanine, whereas
when the AP site is covered by the primer (nicked AP template), the nucleotide
placed on the opposite strand is A to mimic the most frequent incorporation
event occurring opposite an AP site. B, human PCNA was titrated in
the presence of 15 nm (lanes 2–4 and
10–12) or 30 nm (lanes 6–8 and
14–16) recombinant human four subunit DNA pol δ, on a
linear control (lanes 1–8) or a 38-nt gap control (lanes
9–16) template. Lanes 1, 5, 9, and 13, control
reactions in the absence of PCNA. C, human PCNA was titrated in the
presence of 60 nm DNA pol δ, on a linear AP (lanes
2–4) or 38-nt gap AP (lanes 6–9) template. Lanes
1 and 5, control reactions in the absence of PCNA. 相似文献
995.
Scavenger Chemokine (CXC Motif) Receptor 7 (CXCR7) Is a Direct Target Gene of HIC1 (Hypermethylated in Cancer 1) 总被引:1,自引:0,他引:1
996.
Karen Gilio Imke C. A. Munnix Pierre Mangin Judith M. E. M. Cosemans Marion A. H. Feijge Paola E. J. van der Meijden Serv�� Olieslagers Magdalena B. Chrzanowska-Wodnicka Rivka Lillian Simone Schoenwaelder Shigeo Koyasu Stewart O. Sage Shaun P. Jackson Johan W. M. Heemskerk 《The Journal of biological chemistry》2009,284(49):33750-33762
Platelets are activated by adhesion to vascular collagen via the immunoglobulin receptor, glycoprotein VI (GPVI). This causes potent signaling toward activation of phospholipase Cγ2, which bears similarity to the signaling pathway evoked by T- and B-cell receptors. Phosphoinositide 3-kinase (PI3K) plays an important role in collagen-induced platelet activation, because this activity modulates the autocrine effects of secreted ADP. Here, we identified the PI3K isoforms directly downstream of GPVI in human and mouse platelets and determined their role in GPVI-dependent thrombus formation. The targeting of platelet PI3Kα or -β strongly and selectively suppressed GPVI-induced Ca2+ mobilization and inositol 1,4,5-triphosphate production, thus demonstrating enhancement of phospholipase Cγ2 by PI3Kα/β. That PI3Kα and -β have a non-redundant function in GPVI-induced platelet activation and thrombus formation was concluded from measurements of: (i) serine phosphorylation of Akt, (ii) dense granule secretion, (iii) intracellular Ca2+ increases and surface expression of phosphatidylserine under flow, and (iv) thrombus formation, under conditions where PI3Kα/β was blocked or p85α was deficient. In contrast, GPVI-induced platelet activation was insensitive to inhibition or deficiency of PI3Kδ or -γ. Furthermore, PI3Kα/β, but not PI3Kγ, contributed to GPVI-induced Rap1b activation and, surprisingly, also to Rap1b-independent platelet activation via GPVI. Together, these findings demonstrate that both PI3Kα and -β isoforms are required for full GPVI-dependent platelet Ca2+ signaling and thrombus formation, partly independently of Rap1b. This provides a new mechanistic explanation for the anti-thrombotic effect of PI3K inhibition and makes PI3Kα an interesting new target for anti-platelet therapy. 相似文献
997.
The chronic exposure to Aluminum (Al) may compromise different liver functions, mainly during the hepatic regeneration. The
aim of this study is to investigate the interactions between the chronic i.p. exposure to Al and hepatic regeneration (HR)
on bile flow and organic anion transport in experimental animals. For this purpose, we studied bile flow and fractional transfer
rates for the transport of hepatic organic anions (hepatic uptake, sinusoidal efflux, and canalicular excretion), as well
as parameters related with the oxidative stress (OS), on rats chronically treated with Al at 0 and 2 days of HR. The Al treatment
and time of HR caused a decrease in the biliary flow and in the hepatic uptake and canalicular excretion constants. In addition,
Al and HR increased the lipoperoxidation associated with a reduction of the glutathione content and glutathione peroxidase
and catalase enzyme’s activities. Since the effects of Al and HR on biliary flow and transport systems were additive, but
not on the oxidative status, different mechanisms might be involved on these alterations. Even though the OS may play a key
role on the hepatic deleterious effects, there is no unique cause–effect relationship between OS and liver dysfunction in
this experimental animal model. 相似文献
998.
Frederick SB Kibenge Marcos G Godoy Yingwei Wang Molly JT Kibenge Valentina Gherardelli Soledad Mansilla Angelica Lisperger Miguel Jarpa Geraldine Larroquete Fernando Avendaño Marcela Lara Alicia Gallardo 《Virology journal》2009,6(1):1-16
Background
All viruses in the family Bunyaviridae possess a tripartite genome, consisting of a small, a medium, and a large RNA segment. Bunyaviruses therefore possess considerable evolutionary potential, attributable to both intramolecular changes and to genome segment reassortment. Hantaviruses (family Bunyaviridae, genus Hantavirus) are known to cause human hemorrhagic fever with renal syndrome or hantavirus pulmonary syndrome. The primary reservoir host of Sin Nombre virus is the deer mouse (Peromyscus maniculatus), which is widely distributed in North America. We investigated the prevalence of intramolecular changes and of genomic reassortment among Sin Nombre viruses detected in deer mice in three western states.Methods
Portions of the Sin Nombre virus small (S) and medium (M) RNA segments were amplified by RT-PCR from kidney, lung, liver and spleen of seropositive peromyscine rodents, principally deer mice, collected in Colorado, New Mexico and Montana from 1995 to 2007. Both a 142 nucleotide (nt) amplicon of the M segment, encoding a portion of the G2 transmembrane glycoprotein, and a 751 nt amplicon of the S segment, encoding part of the nucleocapsid protein, were cloned and sequenced from 19 deer mice and from one brush mouse (P. boylii), S RNA but not M RNA from one deer mouse, and M RNA but not S RNA from another deer mouse.Results
Two of 20 viruses were found to be reassortants. Within virus sequences from different rodents, the average rate of synonymous substitutions among all pair-wise comparisons (πs) was 0.378 in the M segment and 0.312 in the S segment sequences. The replacement substitution rate (πa) was 7.0 × 10-4 in the M segment and 17.3 × 10-4 in the S segment sequences. The low πa relative to πs suggests strong purifying selection and this was confirmed by a Fu and Li analysis. The absolute rate of molecular evolution of the M segment was 6.76 × 10-3 substitutions/site/year. The absolute age of the M segment tree was estimated to be 37 years. In the S segment the rate of molecular evolution was 1.93 × 10-3 substitutions/site/year and the absolute age of the tree was 106 years. Assuming that mice were infected with a single Sin Nombre virus genotype, phylogenetic analyses revealed that 10% (2/20) of viruses were reassortants, similar to the 14% (6/43) found in a previous report.Conclusion
Age estimates from both segments suggest that Sin Nombre virus has evolved within the past 37–106 years. The rates of evolutionary changes reported here suggest that Sin Nombre virus M and S segment reassortment occurs frequently in nature. 相似文献999.
Esteve Fernández Marcela Fu José A. Pascual María J. López Mónica Pérez-Ríos Anna Schiaffino Jose M. Martínez-Sánchez Carles Ariza Esteve Saltó Manel Nebot and the Spanish Smoking Law Evaluation Group 《PloS one》2009,4(1)
Background
A smoke-free law came into effect in Spain on 1st January 2006, affecting all enclosed workplaces except hospitality venues, whose proprietors can choose among totally a smoke-free policy, a partial restriction with designated smoking areas, or no restriction on smoking on the premises. We aimed to evaluate the impact of the law among hospitality workers by assessing second-hand smoke (SHS) exposure and the frequency of respiratory symptoms before and one year after the ban.Methods and Finding
We formed a baseline cohort of 431 hospitality workers in Spain and 45 workers in Portugal and Andorra. Of them, 318 (66.8%) were successfully followed up 12 months after the ban, and 137 nonsmokers were included in this analysis. We obtained self-reported exposure to SHS and the presence of respiratory symptoms, and collected saliva samples for cotinine measurement. Salivary cotinine decreased by 55.6% after the ban among nonsmoker workers in venues where smoking was totally prohibited (from median of 1.6 ng/ml before to 0.5 ng/ml, p<0.01). Cotinine concentration decreased by 27.6% (p = 0.068) among workers in venues with designated smoking areas, and by 10.7% (p = 0.475) among workers in venues where smoking was allowed. In Portugal and Andorra, no differences between cotinine concentration were found before (1.2 ng/ml) and after the ban (1.2 ng/ml). In Spain, reported respiratory symptom declined significantly (by 71.9%; p<0.05) among workers in venues that became smoke-free. After adjustment for potential confounders, salivary cotinine and respiratory symptoms decreased significantly among workers in Spanish hospitality venues where smoking was totally banned.Conclusions
Among nonsmoker hospitality workers in bars and restaurants where smoking was allowed, exposure to SHS after the ban remained similar to pre-law levels. The partial restrictions on smoking in Spanish hospitality venues do not sufficiently protect hospitality workers against SHS or its consequences for respiratory health. 相似文献1000.
The best-known attribute of the prion protein (PrP) is its tendency to misfold into a rogue isoform. Much less understood is how this misfolded isoform causes deadly brain illnesses. Neurodegeneration in prion disease is often seen as a consequence of abnormal PrP function yet, amazingly little is known about the normal, physiological role of PrP. In particular, the absence of obvious phenotypes in PrP knockout mice has prevented scientists from answering this important question. Using knockdown approaches, we previously produced clear PrP loss-of-function phenotypes in zebrafish embryos. Analysis of these phenotypes revealed that PrP can modulate E-cadherin-based cell-cell adhesion, thereby controlling essential morphogenetic cell movements in the early gastrula. Our data also showed that PrP itself can elicit homophilic cell-cell adhesion and trigger intracellular signaling via Src-related kinases. Importantly, these molecular functions of PrP are conserved from fish to mammals. Here we discuss the use of the zebrafish in prion biology and how it may advance our understanding of the roles of PrP in health and disease.Key words: PrP, zebrafish, development, cell adhesion, signaling 相似文献