ライフサイエンスコーパス: stock

1 rican individuals among a survey of European stock.

2 oint viral loads than the parental SHIV-325c stock.

3 plicative capacity to the parental SHIV-AE16 stock.

4 positively correlated with NPP and standing stock.

5 origins with separate introgressions of wild stock.

6 climate change impacts on the forest carbon stock.

7 distinguished from their official definitive stock.

8 easonal closures to recover these overfished stocks.

9 ers from marine secondary production to fish stocks.

10 IV prior to generating large-scale challenge stocks.

11 iscernible increments across selected carbon stocks.

12 s, business sectors, markets, and local fish stocks.

13 ltural management options for increasing SOC stocks.

14 a widespread habitat supporting large soil C stocks.

15 usehold goods or becomes part of other urban stocks.

16 aris, and led to a reduction in vegetation C stocks.

17 nt larval supply to replenish exploited fish stocks.

18 egularly observed in all-female farmed trout stocks.

19 and -c precursors in the roots of wild-type stocks.

20 mposition and in soil and vegetation C and P stocks.

21 h free-living stages between farmed and wild stocks.

22 ved to be successful in delineating arapaima stocks.

23 and thermal reaction norms within and across stocks.

24 mation available for data-rich and data-poor stocks.

25 m the primary target of efforts to build SOC stocks.

26 nd 23) have been detected in various tilapia stocks.

27 of this contaminant in freshly prepared M13 stocks.

28 d relieve fishing pressure on nearshore fish stocks.

29 od assay for selection of hygienic honey bee stocks.

30 bout longer term gains in aboveground carbon stocks?

31 d not lead to an increase in net ecosystem C stock 12 or 39 years after planting.

32 ampled, there was no net gain in ecosystem C stocks 12-39 years after afforestation-indeed we found a

33 sate such decline (i.e. maintain current SOC stocks), a 3% increase of NPP is required.

34 Soil carbon stocks accounted for >98% of TECS in the seagrass and ma

35 plore whether effective management of carbon stocks accumulating in shelf seas could contribute towar

36 We discovered distinct effects of stocking across different dimensions of diversity, inclu

37 s from 20 wild populations and five cultured stocks across the United States and China using eight mi

38 Artemisinin Combination Therapies (ACTs) in stock (adjusted OR 1.60; 95% CI:1.04-2.46).

39 n at a facility with diagnostic equipment in stock (adjusted OR 3.67; 95% CI: 2.72-4.95) and, in the

40 l organic carbon is the third-largest carbon stock after oceanic and geological pools.

41 T] CO(2) +/-9.1 MMT CO(2)) per year by fully stocking all understocked productive forestland.

42 Results of a Bayesian mixed-stock analysis reveals that the two foraging grounds are

43 ion of the geo-localized, bottom-up material stock analysis with primary data on building material in

44 ulture conversion removed 60% of soil carbon stock and 85% of live biomass carbon stock, relative to

45 number of barcoded variants of the original stock and an additional barcoded stock with suboptimal n

46 ion target for 2050 due to a growing housing stock and continued use of fossil fuels (natural gas, pr

47 The stock and emissions of PBDE congeners were estimated usi

48 thogen that originated within European dairy stock and expanded transcontinentally via unisexual mati

49 e gaps in research on distribution, depth, C stock and fluxes in these ecosystems which play an impor

50 project, which would require coupled C(org) stock and GHG flux enhancement measurements, or determin

51 ce does not reflect the net change in soil N stock and might be overestimated for three reasons: (a)

52 e find positive relationships between carbon stock and tree diversity recovery.

53 is often recreational, or other factors like stocking and invasive species influence patterns.

54 ith possible serious consequences for soil C stocks and atmospheric CO(2) concentrations.

55 ecosystems, through overexploitation of fish stocks and bycatch of threatened species, innovative way

56 o characterize above- and belowground carbon stocks and combustion rates in relation to historical la

57 ry high-resolution map of aboveground carbon stocks and emissions for the country of Peru by combinin

58 ly explicit indicators of aboveground carbon stocks and emissions for tropical countries will serve a

59 ions to reduce plastic pollution, we modeled stocks and flows of municipal solid waste and four sourc

60 al forests vary widely in biomass carbon (C) stocks and fluxes even after controlling for forest age.

61 oducts come from fisheries with less healthy stocks and greater impacts of fishing on other species.

62 soils, but ESM remains underutilized for SOC stocks and has rarely been used for other soil propertie

63 tifying changes in soil organic carbon (SOC) stocks and other soil properties is essential for unders

64 rors than FD when quantifying changes in SOC stocks and other soil properties.

65 without PCR amplification to cultured viral stocks and patient plasma samples from HIV-2-infected in

66 epth would greatly underestimate both carbon stocks and potential greenhouse gas emissions from land-

67 to isolate new bz mutations from several Bz stocks and recovered spontaneous stable mutations only i

68 Using multiple mutant stocks and stable isotope-assisted metabolic analyses, w

69 e TECS included the total aboveground carbon stocks and the entire soil profile (to as deep as 3 m).

70 -known IPAT equation is adapted for building stocks and three dynamics are defined: spatial, evolutio

71 o shrimp pond conversion on ecosystem carbon stocks, and carbon losses and gains over time after pond

72 ack carbon coming into, being added to urban stocks, and eventually leaving the city.

73 ed during the development of axolotl genetic stocks, and precisely mapping several phenotypes includi

74 n land cover change which can release carbon stocks, and, carbon sequestration by in situ vegetation.

75 enges that are becoming more complex as fish stocks are depleted; and illegal, unregulated, and unrep

76 Wild oily fish stocks are insufficient to feed the world's population,

77 fe history parameters critical for improving stock assessment models.

78 eys is to provide independent data to inform stock assessment of commercially important populations,

79 thesized data derived from models during the stock assessment process has emerged as a low-cost alter

80 Using a global database of stock assessments, we show that Standard Fisheries Model

81 nce dissolution of SIC, altering their local stock at decadal timescales.

82 ugh they are widely used, comparisons of SOC stocks at fixed depth (FD) intervals are subject to erro

83 from Sierra Leone) were generated from viral stocks at the US Centers for Disease Control and Prevent

84 population model of 2 Cayman Nassau grouper stocks based on both diver-collected mark-resight observ

85 rm southernmost sites, with NPP and standing stock being around 1.5 and 2.5 times greater in the nort

86 re application significantly enhanced soil P stocks below the plough layer despite a small P input.

87 differences between NPP and carbon standing stock between our cold northernmost sites and our warm s

88 previous year; measured by herring spawning stock biomass, Calanus spp. abundance, overall copepod a

89 tible to errors not only for quantifying SOC stocks but also for soil mass-based properties such as S

90 t options for increasing soil organic carbon stocks but each approach must be evaluated in context of

91 endently detectable prior to the recovery of stocks, but that combining these two signals provides th

92 a have increased standing aboveground carbon stocks by 0.11 +/- 0.05 Pg C y(-1) during 2002-2017.

93 ural pasture to perennial crop decreased SOC stocks by 1% over 0-30 cm (-2.5 +/- 4.2 Mg/ha) and 10% o

94 results show a potential increase in soil C stocks by 2.35 +/- 0.4 t C ha(-1) year(-1) in sugarcane

95 ote the prevalence of the resistance in wild stocks by increasing the parasite population in the wild

96 d from robotics yield 85% recovery of global stocks by midcentury, higher economic returns, and great

97 ght to enhance the infectivity of three SHIV stocks by optimization of a key residue in human immunod

98 plant species richness and vegetation carbon stock can be substantial, and may be related to the hete

99 cts of paleoclimatic extremes on soil carbon stock can shed light on the vulnerability of permafrost

100 y small changes in soil organic carbon (SOC) stocks can significantly alter atmospheric C and global

101 Seed-stocks carrying insertions for vitamin pathway genes are

102 tribution via the Maize Genetics Cooperation Stock Center.

103 re available from the Nottingham Arabidopsis Stock Centre.

104 -1) yr(-1)), while emissions from the carbon stock change due to land conversion varied much more (-3

105 th potassium and micronutrients, soil carbon stocks changed considerably, with an average increase of

106 ld be the standard method for evaluating SOC stock changes in mineral soils, but we further suggest t

107 e, over millennia, accumulated legacy carbon stocks comparable to all human CO(2) emissions since the

108 s would be imperiled if the growth of cement stocks continues.

109 The large carbon stocks coupled with other ecosystem services suggest val

110 f functionality in the maintenance of master stock-cultures of an industrially relevant, lipid-produc

111 ity and functionality are retained by stored stock-cultures.

112 ter market integration can mitigate the fish stock decline, but this reduces the local income benefit

113 benefits of a slightly lower planned maximum stocking density for Breed B and further health benefits

114 o welfare concerns regarding growth rate and stocking density.

115 systems varying in breed and planned maximum stocking density: (1) Breed A, 30 kg/m(2); (2) Breed B,

116 el enables the reliable estimation of cattle stocking density; this is an important predictor of the

117 Impacts on local fish stocks depend on the extent to which markets link fishin

118 ing did not significantly affect soil carbon stocks, despite an elevated dead wood density relative t

119 However, soil C stocks did not respond to nutrient treatments.

120 We predict that global SOC stocks (down to 2 m) will decline by 4% (~80 Pg) on aver

121 s and the subsequent temporal changes in SOC stocks during the perennial crop cycle.

122 xpansion into water-stressed and high-carbon stock ecosystems.

123 g, contrary to decreasing global blue carbon stocks elsewhere.

124 Our analyses found that the stock enhancement program reduced genetic diversity of t

125 lations of one of the world's largest marine stock enhancement programs-the red sea bream (Pagrus maj

126 re are still considerable uncertainties in C stock estimates as well as a lack of information about d

127 tive to the biomass production of individual stocks for a major inland recreational fishery.

128 the early screening of candidate hiPSC seed stocks for clinical use by facilitating safety and poten

129 y used as a tool to increase growth of virus stocks for research and for the generation of vaccines.

130 the paleoclimate effects, and find that the stock ([Formula: see text] PgC) is triple that predicted

131 'genetically improved farmed tilapia' (GIFT) stock, founded from multiple Nile tilapia (Oreochromis n

132 Analyzing 109 well-sampled stocks from all oceans, we show that current practices m

133 We also generated 4 barcoded stocks from subtype B and C SHIV clones each containing

134 called stock units, SU) from two continental stock groups (CSG) in North America (NA) and Southern Eu

135 SRIG stocks have been depleted.

136 Since the 1980s lobster stocks have increased fivefold.

137 that account for geographic, behavioral, and stock heterogeneities.

138 Furthermore, we found that stocking impacts were moderated by cross-scale interacti

139 heses concerning environmental moderation of stocking impacts.

140 consequence of mass mortality of adult brood stock in 2016 and 2017 owing to heat stress(6), the amou

141 We estimated the biomass C stock in 2080 to be 6.13 and 6.50 Pg C under RCP4.5 and

142 ices, climate and feedbacks from current SOM stock in each layer.

143 Biomass C stock in Northeast Asia has increased by 20%-46% over th

144 se maps, we estimated that current biomass C stock in northeastern China, the Democratic People's Rep

145 l) distribution of 46 construction materials stocked in buildings (residential and nonresidential), r

146 ns per capita) of construction materials are stocked in Odense, in which aboveground stock only makes

147 he significant amount of secondary materials stocked in products, buildings, and infrastructures has

148 The legacy of historical sportfish stocking in mountainous regions of western North America

149 (<5 m depth) had significantly higher C(org) stocks in 50 cm thick soils (4.5 +/- 0.7 kg C(org) /m(2)

150 communities and sustainably conserved carbon stocks in a protected tropical forest.

151 Soil carbon stocks in both topsoil and subsoil are positively relate

152 We found more carbon stocks in live trees, but a fewer number of standing-dea

153 d in lieu of FD for assessing changes in SOC stocks in mineral soils, but ESM remains underutilized f

154 (5) collapse of northern Atlantic planktonic stocks in response to a weakened Atlantic Meridional Ove

155 ed to forecast changes in global soil carbon stocks in response to warming.

156 In deeper areas (>5 m), however, soil C(org) stocks in seagrass and bare but previously vegetated are

157 is will probably change in the future, as Zn stocks in the 0-20 cm layer will increase by 22-68% in t

158 linity will likely decrease ecosystem carbon stocks in the absence of upslope wetland migration buffe

159 core" species in an ecosystem or noting when stocks in the core-dominant sector begin to move in lock

160 ility assessment to 36 fish and invertebrate stocks in the eastern Bering Sea (EBS), a data-rich ecos

161 ical interactions and the management of fish stocks in the face of climate change.

162 Soil organic carbon stocks in the top 30 cm ranged from 30 to 118 tons C ha(

163 nd a positive recovery trajectory for carbon stocks in the upper soil layer (0-15 cm) of a chronosequ

164 line in SOC cancelled out the increment in C stocks in tree biomass on decadal timescales.

165 rge trees are critical to determining carbon stocks in tropical forests, but the mechanisms of tropic

166 latinum use and possess the highest platinum stocks in use by 2016; however, when closed loop recycli

167 these, increasing soil organic carbon (SOC) stocks is an important lever because carbon in soils can

168 If action to reduce per capita steel stocks is delayed by more than five years, then it is li

169 n peatland ecological communities and carbon stocks is unknown.

170 sequences of introductions in the future and stocked lakes may be less impacted by subsequent warming

171 developing more comprehensive and successful stock management plans.

172 ng traffic management, epidemic control, and stock market dynamics.

173 Our results suggest that stock market efficiency is a collective phenomenon that

174 p transitions in the core composition of the stock market from a mix of industries to domination by o

175 ithin sliding time-windows of log-returns of stock market indices.

176 ere we define the time-varying efficiency of stock markets by calculating the permutation entropy wit

177 We show that major world stock markets can be hierarchically classified into seve

178 We thus propose a network representation of stock markets that aggregates their short-term efficienc

179 indicating and quantifying the efficiency of stock markets, most studies assume this efficiency to be

180 ture that consists of two distinct groups of stock markets.

181 Moreover, the clade C SHIV-325cH challenge stock may prove useful for evaluating prophylactic or th

182 n and thus recent increases in forest carbon stocks may be transient due to lagged increases in morta

183 Global soil organic carbon (SOC) stocks may decline with a warmer climate.

184 one, while also underscoring that rebuilding stocks may still be achieved by improved decision-making

185 the most widely dispersed detected in an in-stock New Hampshire sample.

186 This will include vendor information, stock number, and feeding schedules within the STAR Meth

187 productivity, with reduced NPP and standing stock observed in warmer waters.

188 ntic herring has an estimated total breeding stock of about 1 trillion (10(12)) and has colonized the

189 This review takes stock of alternative technologies currently available in

190 he COVID-19 pandemic makes it timely to take stock of evidence for the involvement of neutrophils and

191 A stock of HuNoV strain Norwalk virus ([NV] GI.1) was prep

192 et Plateau in the future, and that the large stock of living roots exert a dominant impact on nutrien

193 particular research area in mind, they take stock of the current state of play and emphasize the wor

194 funding priorities over half a century, take stock of the most important sociological breakthroughs i

195 This study highlights the need to take stock of unique Arctic marine biodiversity.

196 full measure of time, is it possible to take stock of what has worked and what could have been done b

197 management is positively correlated with the stocking of essential commodities and is somewhat improv

198 rbed mangroves stored total ecosystem carbon stocks of 182-2,730 (mean +/- SD: 1,087 +/- 584) Mg C/ha

199 d ~20% (72 Mg/ha) of the above-ground carbon stocks of a primary forest (PF), with cattle pasture con

200 We quantify the AGB stocks of an OP plantation on drained peat in Malaysia f

201 Standing stocks of dissolved iron are maintained by association w

202 The global (a) in-use and (b) waste stocks of E(5)BDE(28, 47, 99, 153, 183) and BDE209 are e

203 l fluxes are expected to increase as massive stocks of frozen organic matter in permafrost are libera

204 Yet, little data exist for the carbon stocks of major tidal wetland types in the Pacific North

205 Ecosystem C stocks of mangrove stands exceeded mudflats by 434 +/- 3

206 gement actions aimed at recovering collapsed stocks of Nassau grouper.

207 s, our results indicate that both inputs and stocks of ocean plastics are much higher than determined

208 Stocks of precious metals and rare earths will increase

209 to allow the destruction of our institute's stocks of RPV while maintaining the ability to recover t

210 observed significant reductions in standing stocks of total carbon and chlorophyll a, and a shift to

211 een monsoon rainfall and soil organic carbon stocks on a millennial timescale.

212 Aboveground biomass stocks on peat accumulated at ~6.39 +/- 1.12 Mg ha(-1) p

213 are stocked in Odense, in which aboveground stock only makes up for a third of the weight but hosts

214 a facility with diagnostics and medicines in stock, only a predicted 37.2% (95% CI: 34.2%-40.1%) woul

215 tigation into the drivers of pre-fire carbon stocks or subsequent combustion.

216 eir historically dominant small pelagic fish stocks, or have experienced environmental shifts favouri

217 ries managers weighing the costs/benefits of stocking-or removing established non-native populations-

218 in situ observations of a wide range of SOC stocks over large spatial scales before their introducti

219 eals a serial depletion of some oceanic fish stocks over time, resulting in fisheries focusing on inc

220 tool and integrated directly on the MaizeGDB Stock Pages.

221 tanding and quantification of biomass carbon stocks, particularly in tropics, lead to large uncertain

222 ieve the emissions cut; conversely, reducing stocks per capita from the current ~11 tons/capita towar

223 four key steel cycle parameters (U.S. steel stocks per capita, recycling rate, product lifespan, and

224 per kilogram of steel produced and the steel stocks per capita.

225 This might facilitate producing and stock-piling adjuvant doses and therefore aide in pandem

226 contaminant PEG inside the freshly produced stocks, potentially hampering the reactivity of the indi

227 As arctic carbon (C) stocks predominantly are located belowground, the effect

228 the oceans, including a substantial standing stock, previous research has not detected a temporal tre

229 e efficient market hypothesis, the idea that stock prices fully reflect all available information is

230 d to quantitatively link reef degradation to stock production parameters is needed.

231 erfishing if habitat loss caused declines in stock productivity.

232 ses in estimated above-ground biomass (EAGB) stocks, productivity, and mortality in old-growth tropic

233 lated with fine root biomass and soil carbon stocks (r(2) = 0.62-0.71; p < 0.1), suggesting a feedbac

234 1,598 outbred male and female heterogeneous stock rats were screened for Pavlovian conditioned appro

235 Here we synthesize fish stocking records and zooplankton relative abundance for

236 reater combustion rates due to faster carbon stock recovery rates than sites recovering from wildfire

237 entral Alaska, using a hierarchical Bayesian stock-recruitment model.

238 ly filtered (denoised without using explicit stock-recruitment models).

239 ee approach that does not presume a specific stock-recruitment relationship is better than SFMs at pr

240 The collapse in stock-recruitment relationships indicates that the low r

241 Here we document a regional-scale shift in stock-recruitment relationships of corals along the Grea

242 will be able to recover from the collapse in stock-recruitment relationships remains uncertain, given

243 y predict synthesized data based on presumed stock-recruitment relationships, however, they are gener

244 ), with cattle pasture containing just 3% of stocks relative to PFs.

245 carbon stock and 85% of live biomass carbon stock, relative to reference sites.

246 ing of StMSI1-OE or StBMI1-1-AS on wild-type stock resulted in reduced root biomass and showed increa

247 emergence of an interconnected sub-graph of stock returns co-movements from a broader market index i

248 ty of self-organizing processes arising from stock returns' co-movements.

249 cal characteristics, distribution and carbon stock, role in the global climate, the impacts of direct

250 DO mouse stock samples nearly the entire genetic repertoire of th

251 pplied this strategy to three SHIV challenge stocks (SHIV-SF162p3, SHIV-AE16, and SHIV-325c) and obse

252 w simian-human immunodeficiency virus (SHIV) stocks: SHIV-SF162p3S/wild type, SHIV-AE16W, and SHIV-32

253 pared a second-generation barcoded SIVmac239 stock (SIVmac239M2) with over 16 times the number of bar

254 e development of accurate estimates to track stock size through time.

255 rong MB peak and matched with that of the MB stock solution.

256 at Talpha-1 peptides prepared from different stock solutions have equivalent biological activity.

257 lead at nanomole-scale amounts as DMSO-d(6) stock solutions with a known structure and concentration

258 al fisheries remain debated due to uncertain stock status, variable management success, and disruptiv

259 n's primary productivity than their standing stocks suggest.

260 opted as a pre-grazing target for rotational stocking systems to optimize sheep nutrition on pastures

261 We quantified the total ecosystem carbon stocks (TECS) in seagrass, emergent marshes, and foreste

262 xperiments produce emergent ecosystem carbon stock temperature sensitivities inconsistent with emerge

263 years after land-use changes, indicating SIC stocks that were stable for millennia can rapidly adjust

264 unique outbred rat population (heterogeneous stock) that better models the behavioral and genetic div

265 possibly due to severe depletion of natural stocks, the species sedentary behaviour and possible sam

266 derive a new estimate of modern soil carbon stock to 3 m depth by including the paleoclimate effects

267 ance of system stabilization prior to larval stocking to improve rearing success and probiotic perfor

268 Managing soil organic matter (SOM) stocks to address global change challenges requires well

269 bon sequestration and the sensitivity of SOC stocks to climate and land-use changes.

270 entury, the long-term response of planktonic stocks to climate forcing is unknown.

271 tation data for 1,338 commercially important stocks to derive an optimized network of MPAs globally.

272 hts into the sensitivity of grassland carbon stocks to nutrient enrichment can facilitate biochemical

273 cates that the low resistance of adult brood stocks to repeated episodes of coral bleaching is inexor

274 a loosely understood association of pelagic stocks to the ocean environment, and the tyranny of dist

275 rs/presenters disclosed ownership (including stock) to ASCO.

276 originate-there were fewer live and growing-stock trees and less carbon in soils with every year of

277 Dynamic analysis of stock trends found that coral trout and red throat emper

278 redators were present, with either native or stocked trout.

279 adaptation scenarios, leading to similar SOC stocks under different climate change scenarios.

280 d is a key mechanism impacting terrestrial C stocks under global change.

281 al of 13 large groups of populations (called stock units, SU) from two continental stock groups (CSG)

282 , and were 8%-14% higher than the baseline C stock value (5.70 Pg C).

283 ly, which exceeded the present region-wide C stock value by 2.85-3.22 Pg C, and were 8%-14% higher th

284 The sex-determining mechanism in the GIFT stock was unknown, but potentially complicated due to it

285 eriod, a depletion of basin-wide soil carbon stocks was triggered by increasing rainfall and associat

286 The highest carbon stocks were found in estuarine interior (EI) mangroves,

287 , coarse wood biomass and aboveground carbon stocks were reduced by 65 and 62%, respectively, relativ

288 lobally significant organic carbon (C(org) ) stocks which, if disturbed, can lead to CO(2) emissions,

289 tation in the filamin gene fln-2 in the male stock, which reduces early mortality caused by pharyngea

290 Tropical soils contain huge carbon stocks, which climate warming is projected to reduce by

291 ols natural dynamics of mangrove blue carbon stocks, while long-term land-use changes affect carbon l

292 n regions with considerable pre-existing SOC stocks will have the intended policy and climate change

293 te quantification of secondary forest carbon stocks will support the production of appropriate manage

294 he original stock and an additional barcoded stock with suboptimal nucleotides corrected (SIVmac239Op

295 thus may accelerate development of honey bee stocks with greater resistance to Varroa and associated

296 ing meta-analysis, that reductions in soil C stocks with warming are associated with increased ratios

297 using two methods as well as carbon standing stock within kelp forests (Laminaria hyperborea) at mult

298 atory trout are absent, native, or have been stocked within the last 25 years.

299 tributes for timberland structure and carbon stocks within 123 procurement landscapes of wood pellet

300 nsport, is the main control on observed iron stocks within intermediate waters globally and upper oce