首页 | 本学科首页   官方微博 | 高级检索  
文章检索
  按 检索   检索词:      
出版年份:   被引次数:   他引次数: 提示:输入*表示无穷大
  收费全文   425324篇
  免费   41992篇
  国内免费   141篇
  2016年   4646篇
  2015年   6194篇
  2014年   7363篇
  2013年   10970篇
  2012年   11930篇
  2011年   12361篇
  2010年   8437篇
  2009年   7769篇
  2008年   11042篇
  2007年   11693篇
  2006年   10963篇
  2005年   10441篇
  2004年   10531篇
  2003年   10304篇
  2002年   10039篇
  2001年   17381篇
  2000年   17407篇
  1999年   14007篇
  1998年   4880篇
  1997年   5181篇
  1996年   4875篇
  1995年   4750篇
  1994年   4641篇
  1993年   4648篇
  1992年   12281篇
  1991年   12083篇
  1990年   12090篇
  1989年   11858篇
  1988年   11171篇
  1987年   10501篇
  1986年   9817篇
  1985年   10239篇
  1984年   8453篇
  1983年   7280篇
  1982年   5612篇
  1981年   5024篇
  1980年   4689篇
  1979年   8087篇
  1978年   6302篇
  1977年   5941篇
  1976年   5679篇
  1975年   6136篇
  1974年   6695篇
  1973年   6571篇
  1972年   6122篇
  1971年   5544篇
  1970年   4769篇
  1969年   4783篇
  1968年   4456篇
  1967年   3811篇
排序方式: 共有10000条查询结果,搜索用时 78 毫秒
1.
Past studies have suggested that a key feature of the mechanism of heparin allosteric activation of the anticoagulant serpin, antithrombin, is the release of the reactive center loop P14 residue from a native state stabilizing interaction with the hydrophobic core. However, more recent studies have indicated that this structural change plays a secondary role in the activation mechanism. To clarify this role, we expressed and characterized 15 antithrombin P14 variants. The variants exhibited basal reactivities with factors Xa and IXa, heparin affinities and thermal stabilities that were dramatically altered from wild type, consistent with the P14 mutations perturbing native state stability and shifting an allosteric equilibrium between native and activated states. Rapid kinetic studies confirmed that limiting rate constants for heparin allosteric activation of the mutants were altered in conjunction with the observed shifts of the allosteric equilibrium. However, correlations of the P14 mutations'' effects on parameters reflecting the allosteric activation state of the serpin were inconsistent with a two-state model of allosteric activation and suggested multiple activated states. Together, these findings support a minimal three-state model of allosteric activation in which the P14 mutations perturb equilibria involving distinct native, intermediate, and fully activated states wherein the P14 residue retains an interaction with the hydrophobic core in the intermediate state but is released from the core in the fully activated state, and the bulk of allosteric activation has occurred in the intermediate.  相似文献   
2.

Aims

This study investigated Cu uptake and accumulation as well as physiological and biochemical changes in grapevines grown in soils containing excess Cu.

Methods

The grapevines were collected during two productive cycles from three vineyards with increasing concentrations of Cu in the soil and at various growth stages, before and after the application of Cu-based fungicides. The Cu concentrations in the grapevine organs and the macronutrients and biochemical parameters in the leaf blades were analyzed.

Results

At close to the flowering stage of the grapevines, the concentration and content of Cu in the leaves were increased. However, the Cu concentrations in the roots, stem, shoots and bunches did not correlate with the metal concentrations in the soil. The application of Cu-based fungicides to the leaves increased the Cu concentrations in the shoots, leaves and rachis; however, the effect of the fungicides on the Cu concentration in the berries was not significant. The biochemical analyses of the leaf blades demonstrated symptoms of oxidative stress that correlated with the Cu concentrations in soil.

Conclusions

The increased availability of Cu in soil had a slight effect on the levels and accumulation of Cu in mature grapevines during the productive season and did not alter the nutritional status of the plant. However, increased Cu concentrations were observed in the leaves. The evidence of oxidative stress in the leaves correlated with the increased levels of Cu in soil.  相似文献   
3.
4.
5.
The carbon dioxide (CO2)-concentrating mechanism of cyanobacteria is characterized by the occurrence of Rubisco-containing microcompartments called carboxysomes within cells. The encapsulation of Rubisco allows for high-CO2 concentrations at the site of fixation, providing an advantage in low-CO2 environments. Cyanobacteria with Form-IA Rubisco contain α-carboxysomes, and cyanobacteria with Form-IB Rubisco contain β-carboxysomes. The two carboxysome types have arisen through convergent evolution, and α-cyanobacteria and β-cyanobacteria occupy different ecological niches. Here, we present, to our knowledge, the first direct comparison of the carboxysome function from α-cyanobacteria (Cyanobium spp. PCC7001) and β-cyanobacteria (Synechococcus spp. PCC7942) with similar inorganic carbon (Ci; as CO2 and HCO3) transporter systems. Despite evolutionary and structural differences between α-carboxysomes and β-carboxysomes, we found that the two strains are remarkably similar in many physiological parameters, particularly the response of photosynthesis to light and external Ci and their modulation of internal ribulose-1,5-bisphosphate, phosphoglycerate, and Ci pools when grown under comparable conditions. In addition, the different Rubisco forms present in each carboxysome had almost identical kinetic parameters. The conclusions indicate that the possession of different carboxysome types does not significantly influence the physiological function of these species and that similar carboxysome function may be possessed by each carboxysome type. Interestingly, both carboxysome types showed a response to cytosolic Ci, which is of higher affinity than predicted by current models, being saturated by 5 to 15 mm Ci. This finding has bearing on the viability of transplanting functional carboxysomes into the C3 chloroplast.Cyanobacteria inhabit a diverse range of ecological habitats, including both freshwater and marine ecosystems. The flexibility to occupy these different habitats is thought to come in part from the carbon-concentrating mechanism (CCM) present in all species (Badger et al., 2006). The CCM comprises inorganic carbon (Ci; as carbon dioxide [CO2] and HCO3) transporters for Ci uptake and protein microbodies called carboxysomes for CO2 concentration and fixation by Rubisco (Badger and Price, 2003). The CCM is believed to have evolved in response to changes in the absolute and relative levels of CO2 and oxygen (O2) in the atmosphere during the evolution of oxygenic photosynthesis in cyanobacteria (Price et al., 2008).There are two main phylogenetic groups within the cyanobacteria based on Rubisco and carboxysome phylogenies; α-cyanobacteria have α-carboxysomes with Form-IA Rubisco, whereas β-cyanobacteria have β-carboxysomes with Form-IB Rubisco (Tabita, 1999; Badger et al., 2002). Rubisco large subunit protein sequences from these two groups are closely related but nevertheless, distinguishable (Supplemental Fig. S1). In general, α-cyanobacteria and β-cyanobacteria occupy a quite different range of ecological habitats. The α-cyanobacteria are mostly marine organisms, with the majority of species living in the open ocean (Badger et al., 2006). Marine α-cyanobacteria live in very stable environments with high pH (pH 8.2) and dissolved carbon levels but low nutrients. They are characterized by small cells, very small genomes (1.6–2.8 Mb), and a few constitutively expressed carbon uptake transporters (Rae et al., 2011; Beck et al., 2012). They have been described as low flux, low energy cyanobacteria with a minimal CCM (Badger et al., 2006). Although these species are slow growing, oceanic cyanobacteria contribute as much as one-half of oceanic primary productivity (Liu et al., 1997, 1999; Field et al., 1998), suggesting that they may contribute up to 25% to net global productivity every year.In comparison, β-cyanobacteria occupy a much more diverse range of habitats, including freshwater, estuarine, and hot springs and never reach the same levels of global abundance (Badger et al., 2006). They are characterized by larger cells, larger genomes (2.2–3.6 Mb), and an array of carbon uptake transporters, including those transporters induced under low Ci (Rae et al., 2011, 2013). In addition to these broadly defined α-groups and β-groups, there are small numbers of α-cyanobacteria that have been termed transitional strains (Price, 2011; Rae et al., 2011). These species (e.g. Cyanobium spp. PCC7001, Synechococcus spp. WH5701, and Cyanobium spp. PCC6307; Supplemental Fig. S1) live in marginal marine and freshwater environments and have a number of characteristics similar to β-cyanobacteria. For example, they have a more diverse range of Ci uptake systems and a significantly larger genome than closely related α-cyanobacteria, and it has been suggested that the additional genes encoding transport systems were acquired by horizontal gene transfer (HGT) from β-cyanobacteria (Rae et al., 2011).Although the carboxysomes from α-cyanobacteria and β-cyanobacteria are very similar in overall structure, in that they share an outer protein shell of common phylogenetic origin (Kerfeld et al., 2005), they are distinguished from each other largely by differences in the proteins, which seem to make up or interact with the interior of the carboxysome compartment (Supplemental Table S1). This finding suggests that their different structures today have arisen through periods of common and convergent evolution. Certain carboxysome shell proteins from α-carboxysomes and β-carboxysomes show regions of significant sequence homology. These proteins are denoted as CsoS1 to CsoS4 (in α-cyanobacteria) and CcmKLO (in β-cyanobacteria), and the homologous regions have been termed bacterial microcompartment domains (Kerfeld et al., 2010; Rae et al., 2013). Proteins with these domains are also found in bacterial microcompartments in proteobacteria. However, other identified carboxysome proteins do not show any sequence homology between α-carboxysomes and β-carboxysomes but may perform similar functional roles. For example, carbonic anhydrase activity is essential for carboxysome function, but its activity seems to be provided by a range of different proteins (β-CcaA, β-CcmM, and α-CsoSCA; Kupriyanova et al., 2013). Similarly, β-CcmM and α-CsoS2 could play similar roles in organizing the interface between the shell and Rubisco within the carboxysomes (Gonzales et al., 2005; Long et al., 2007).The functioning of a carboxysome relies on a number of biochemical properties associated with the protein microbody structure. These properties include the biochemical/kinetic properties of Rubisco contained within carboxysomes, the conductance of the carboxysome shell to the influx of substrate ribulose-1,5-bisphosphate (RuBP) and the efflux of the carboxylation product phosphoglycerate (PGA), the conductance of the shell to the influx of bicarbonate and the efflux of CO2, and lastly, the manner in which bicarbonate is converted to CO2 within the carboxysomes. α-Carboxysomes and β-carboxysomes have the potential to differ in each of these properties. The flux of phosphorylated sugars across the shell has been postulated to be mediated by the pores in the hexameric shell proteins (Yeates et al., 2010; Kinney et al., 2011), which although similar, do differ between the two carboxysomes types. Bicarbonate and CO2 uptake processes are less well-defined but probably involve aspects of the way in which unique shell interface proteins interact with Rubisco, which also differs in that CsoS2 and CsoSCA are probably the interacting proteins involved in α-carboxysomes (Espie and Kimber, 2011), whereas CcmM and β-carboxysomal CA are variably involved in β-carboxysomes (Long et al., 2010). Finally, the Form-IA and Form-IB Rubisco proteins at the heart of carboxylation, although similar, have the potential to show different kinetic properties. Although Form-IB Rubiscos from β-cyanobacteria are well-characterized, the Form-IA counterparts have received very little attention. In addition, the CCM of very few strains of cyanobacteria have been studied at the level of biochemistry and physiology, and they have been almost exclusively β-cyanobacteria. As a result, there are significant gaps in our knowledge about the similarities and differences in functional traits between α-cyanobacterial and β-cyanobacterial strains. One important question that remains to be answered is whether α-carboxysomes and β-carboxysomes have intrinsic differences in their biochemical properties that influence the nature of the CCM, which is established within each broad cell type.Because of the difficulties in isolating and assaying intact carboxysomes in vitro, the characterization of biochemical properties of carboxysomes is not easily addressed. One way forward is to study the properties of the CCM in detail in a model representative strain from each group and compare their characteristics to contrast the intracellular function of α-cell types and β-cell types. In the past, it has been restricted because of the difficulties in growing many of the open ocean α-cyanobacteria and their very different natures in relation to inorganic transporter composition. However, the availability of α-cyanobacteria transition strains, which grow well in the laboratory, has provided an opportunity to address this question. The α-cyanobacteria Cyanobium spp. PCC7001 (hereafter Cyanobium spp.), in particular, grows in standard freshwater media (BG11) and has growth and photosynthetic performance properties that closely match the model β-cyanobacteria, Synechococcus spp. PCC7942 (hereafter Synechococcus spp.); for this reason, Cyanobium spp. is ideal for a balanced comparison of the in vivo physiological properties of α-carboxysomes and β-carboxysomes in two species with relatively similar Ci-uptake properties.Genome analysis of both strains indicates that Cyanobium spp. have many of the same carbon uptake systems present in Synechococcus spp. (Rae et al., 2011). In using two strains with such similar transport capacities, we aimed to shed light on aspects of the functional properties of carboxysomes in each strain and how these properties affect the operation of the CCM in α-cyanobacteria and β-cyanobacteria. Using both membrane inlet mass spectrometry (MIMS) and silicon oil centrifugation, we investigated Ci pool sizes and CO2 uptake rates in both species for cells grown at high and low CO2. Comparative Rubisco properties and photosynthetic rates of each species were determined, and intracellular pools of RuBP and PGA were measured. In addition, we characterized a number of cellular properties to determine differences in the biochemical environments in which each carboxysome type exists. Together, the results provide a unique functional comparison of two distinct carboxysome types from phylogenetically disparate cyanobacteria.  相似文献   
6.
The delivery of proteins instead of DNA into plant cells allows for a transient presence of the protein or enzyme that can be useful for biochemical analysis or genome modifications. This may be of particular interest for genome editing, because it can avoid DNA (transgene) integration into the genome and generate precisely modified “nontransgenic” plants. In this work, we explore direct protein delivery to plant cells using mesoporous silica nanoparticles (MSNs) as carriers to deliver Cre recombinase protein into maize (Zea mays) cells. Cre protein was loaded inside the pores of gold-plated MSNs, and these particles were delivered by the biolistic method to plant cells harboring loxP sites flanking a selection gene and a reporter gene. Cre protein was released inside the cell, leading to recombination of the loxP sites and elimination of both genes. Visual selection was used to select recombination events from which fertile plants were regenerated. Up to 20% of bombarded embryos produced calli with the recombined loxP sites under our experimental conditions. This direct and reproducible technology offers an alternative for DNA-free genome-editing technologies in which MSNs can be tailored to accommodate the desired enzyme and to reach the desired tissue through the biolistic method.Introducing DNA-modifying enzymes rather than DNA-based expression cassettes is an attractive alternative for genetic engineering and genome-editing applications such as gene targeting or site-specific recombination. It offers a transient presence of the enzymes, and the process can be coordinated with high levels of enzymatic activity at the time and sites of the desired DNA recombination events. Many DNA-metabolizing enzymes (endonucleases, transposases, and topoisomerases), when delivered in an unrestrained manner, show adverse effects on cell viability. Delivery in the form of protein or RNA may help to mitigate these effects (Cui et al., 2011; Sander et al., 2011; Watanabe et al., 2012). In addition, by introducing proteins, one can avoid the need to remove the protein-encoding DNA fragments from the engineered plant genome. This may help shorten the time from laboratory to field for future improved germplasms.Site-specific recombinases such as Cre or FLP have been widely used in genetic engineering applications (Sorrell and Kolb, 2005). The 38-kD Cre enzyme specifically binds to and recombines the 34-bp loxP sequences, allowing the removal, integration, or inversion of the DNA fragment flanked by these sequences (for review, see Wang et al., 2011). There are a number of established methodologies designed to provide the Cre recombinase activity for site-specific recombination in eukaryotic cells that do not involve the delivery of DNA. These methods include lipofection (Baubonis and Sauer, 1993), microinjection of protein or mRNA (de Wit et al., 1998; Luckow et al., 2009), electroporation of protein or mRNA (Kolb and Siddell, 1996; Ponsaerts et al., 2004), or using modified microorganisms for Cre delivery to their host cells (Vergunst et al., 2000; Koshy et al., 2010). Another strategy that has been used is the incubation or injection of tissues/cell cultures with cell-permeant Cre, a modified Cre protein fused to protein transduction domains or cell-penetrating peptides (Jo et al., 2001; Will et al., 2002; Lin et al., 2004; Nolden et al., 2006).For biotechnological applications in plant sciences, protein delivery systems have been developed, including microinjection (Wymer et al., 2001), protein immobilization to gold particles (Wu et al., 2011), and protein transduction through cell-penetrating peptides (for review, see Chugh et al., 2010). The cell-penetrating peptides were shown to enable intracellular delivery of the Cre recombinase protein to rice (Oryza sativa) callus tissues (Cao et al., 2006). Nanobiotechnology is offering an attractive alternative, since nanoparticles can be precisely tailored to deliver a particular biomolecule to the cell, tissue, or organism of interest when needed (for review, see Du et al., 2012). Mesoporous silica nanoparticles (MSNs) are particularly suited for this purpose. These porous nanoparticles are formed by a matrix of well-ordered pores that confers high loading capacity of molecules like proteins (for review, see Popat et al., 2011). Additionally, surfaces of MSNs can be readily modified, permitting the customization of nanoparticles to particular experimental needs (for review, see Trewyn et al., 2007). In our previous studies, it was shown that MSNs can be used for the codelivery of DNA and chemicals (Torney et al., 2007) as well as DNA and proteins (Martin-Ortigosa et al., 2012a) to plant cells via biolistics. To improve MSN performance as a projectile, gold plating of MSN surfaces was performed, increasing nanoparticle density and, subsequently, the ability to pass through the plant cell wall upon bombardment (Martin-Ortigosa et al., 2012b).In this work, the Cre recombinase enzyme was loaded into the pores of gold-plated MSNs and delivered through the biolistic method to maize (Zea mays) cells containing loxP sites integrated into chromosomal DNA (Lox-corn; Fig. 1A). Lox-corn expressed the glyphosate acetyltransferase gene (gat) and the Anemonia majano cyan fluorescent protein gene (AmCyan1) flanked by loxP sites. The MSN-released Cre enzyme recombined the loxP sites, thus removing the DNA fragment flanked by these sequences. Such excisions led to the expression of a variant of Discosoma sp. red fluorescent protein gene (DsRed2) and the loss of the selectable marker gene (Fig. 1A). Visual selection was used to recover the recombination events. Subsequently, fertile maize plants were regenerated from the recombined events and DNA analyses confirmed the recombination events. To our knowledge, this is the first time that MSNs have been used for the delivery of a functional recombinase into plant tissues, leading to successful genome editing.Open in a separate windowFigure 1.A, Schematic representation of the MSN-based bombardment technology. Cre protein is loaded into the pores of gold-plated MSN (Cre-6x-MSN) and subsequently bombarded onto immature embryos of a transgenic maize line carrying a loxP construct (Lox-corn). The parental transgenic Lox-corn tissues are blue fluorescence and herbicide resistant because they harbor a cassette with the glyphosate acetyltransferase (gat) selection gene and the AmCyan1 (cyan) marker gene flanked by the loxP sites. The DsRed2 (dsred) gene for the expression of a red fluorescent protein is placed downstream of the cassette. Once Cre recombinase is released inside the cell, it performs the recombination, excising gat-AmCyan1 genes and leading to the expression of the DsRed2 gene, switching the cell fluorescence pattern from blue to red. P, Promoter; T, terminator. UBINTRF, CYANF, and DSRED2R are primers for DNA analysis. B, Transmission electron microscope image showing the typical hexagonal shape and the well-ordered pore structure of a 6x-MSN. C, Scanning electron microscope image showing gold nanoparticle deposition (white dots) in all surfaces of 6x-MSN. D, Western blot showing Cre protein loading and release dynamics from 6x-MSN. The protein loading is almost immediate, even though some protein can be detected in the buffer even after 1 h of loading. For the release, some Cre protein can be observed after 24 h of incubation. Most of the protein remains in the 6x-MSN pellet. C+, 400 ng of Cre protein; Empty, a lane with no protein loading. The bands observed in the Empty lane were the spillover from the neighboring Pellet lane, which represents Cre-loaded 6x-MSN after the release experiment resuspended in Laemmli loading buffer (see “Materials and Methods”).  相似文献   
7.
There is increasing evidence that the thyroid hormone (TH) receptors (THRs) can play a role in aging, cancer and degenerative diseases. In this paper, we demonstrate that binding of TH T3 (triiodothyronine) to THRB induces senescence and deoxyribonucleic acid (DNA) damage in cultured cells and in tissues of young hyperthyroid mice. T3 induces a rapid activation of ATM (ataxia telangiectasia mutated)/PRKAA (adenosine monophosphate–activated protein kinase) signal transduction and recruitment of the NRF1 (nuclear respiratory factor 1) and THRB to the promoters of genes with a key role on mitochondrial respiration. Increased respiration leads to production of mitochondrial reactive oxygen species, which in turn causes oxidative stress and DNA double-strand breaks and triggers a DNA damage response that ultimately leads to premature senescence of susceptible cells. Our findings provide a mechanism for integrating metabolic effects of THs with the tumor suppressor activity of THRB, the effect of thyroidal status on longevity, and the occurrence of tissue damage in hyperthyroidism.  相似文献   
8.
Developmental axon branching dramatically increases synaptic capacity and neuronal surface area. Netrin-1 promotes branching and synaptogenesis, but the mechanism by which Netrin-1 stimulates plasma membrane expansion is unknown. We demonstrate that SNARE-mediated exocytosis is a prerequisite for axon branching and identify the E3 ubiquitin ligase TRIM9 as a critical catalytic link between Netrin-1 and exocytic SNARE machinery in murine cortical neurons. TRIM9 ligase activity promotes SNARE-mediated vesicle fusion and axon branching in a Netrin-dependent manner. We identified a direct interaction between TRIM9 and the Netrin-1 receptor DCC as well as a Netrin-1–sensitive interaction between TRIM9 and the SNARE component SNAP25. The interaction with SNAP25 negatively regulates SNARE-mediated exocytosis and axon branching in the absence of Netrin-1. Deletion of TRIM9 elevated exocytosis in vitro and increased axon branching in vitro and in vivo. Our data provide a novel model for the spatial regulation of axon branching by Netrin-1, in which localized plasma membrane expansion occurs via TRIM9-dependent regulation of SNARE-mediated vesicle fusion.  相似文献   
9.
Plasma lipidome is now increasingly recognized as a potentially important marker of chronic diseases, but the exact extent of its contribution to the interindividual phenotypic variability in family studies is unknown. Here, we used the rich data from the ongoing San Antonio Family Heart Study (SAFHS) and developed a novel statistical approach to quantify the independent and additive value of the plasma lipidome in explaining metabolic syndrome (MS) variability in Mexican American families recruited in the SAFHS. Our analytical approach included two preprocessing steps: principal components analysis of the high-resolution plasma lipidomics data and construction of a subject-subject lipidomic similarity matrix. We then used the Sequential Oligogenic Linkage Analysis Routines software to model the complex family relationships, lipidomic similarities, and other important covariates in a variance components framework. Our results suggested that even after accounting for the shared genetic influences, indicators of lipemic status (total serum cholesterol, TGs, and HDL cholesterol), and obesity, the plasma lipidome independently explained 22% of variability in the homeostatic model of assessment-insulin resistance trait and 16% to 22% variability in glucose, insulin, and waist circumference. Our results demonstrate that plasma lipidomic studies can additively contribute to an understanding of the interindividual variability in MS.  相似文献   
10.
Single-stranded DNA binding proteins (SSBs) selectively bind single-stranded DNA (ssDNA) and facilitate recruitment of additional proteins and enzymes to their sites of action on DNA. SSB can also locally diffuse on ssDNA, which allows it to quickly reposition itself while remaining bound to ssDNA. In this work, we used a hybrid instrument that combines single-molecule fluorescence and force spectroscopy to directly visualize the movement of Escherichia coli SSB on long polymeric ssDNA. Long ssDNA was synthesized without secondary structure that can hinder quantitative analysis of SSB movement. The apparent diffusion coefficient of E. coli SSB thus determined ranged from 70,000 to 170,000 nt2/s, which is at least 600 times higher than that determined from SSB diffusion on short ssDNA oligomers, and is within the range of values reported for protein diffusion on double-stranded DNA. Our work suggests that SSB can also migrate via a long-range intersegment transfer on long ssDNA. The force dependence of SSB movement on ssDNA further supports this interpretation.  相似文献   
设为首页 | 免责声明 | 关于勤云 | 加入收藏

Copyright©北京勤云科技发展有限公司  京ICP备09084417号