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1 l C. jejuni factors essential throughout its life cycle.
2 ave focused on single stages of the parasite life cycle.
3 y vital roles in all the stages of the viral life cycle.
4 ication and likely other stages of the viral life cycle.
5 mRNAs were imaged throughout their complete life cycle.
6 y every step in the early phase of the viral life cycle.
7 vigorous seedling is crucial in the plant's life cycle.
8 17 has unique characteristics and an unusual life cycle.
9 yces to deviate from its classically-defined life cycle.
10 optimal E1-E2 replication and for the viral life cycle.
11 arget during the maintenance stage of the PV life cycle.
12 the cell during different stages of the KSHV life cycle.
13 profound effects at all stages of the plant life cycle.
14 th a complex, aquatic-terrestrial (biphasic) life cycle.
15 V DNA replication, a central part of the JCV life cycle.
16 RNA genome and therefore is central for its life cycle.
17 quired for the different stages of the viral life cycle.
18 isoforms have differential roles in the bleb life cycle.
19 rget this essential step of the dengue virus life cycle.
20 nctions of these ncRNAs may impact the viral life cycle.
21 isperse geographically via the D. discoideum life cycle.
22 onment to time critical transitions in their life cycle.
23 afety of novel therapeutics throughout their life cycle.
24 udy a post-entry role of endocytosis in HCMV life cycle.
25 formation are changed during an entire algal life cycle.
26 evolution of a fish species with an uncommon life cycle.
27 xan actin is important during the parasite's life cycle.
28 production at different stages of the viral life cycle.
29 ation of the parasite throughout its complex life cycle.
30 ynamic and plays multiple roles in the viral life cycle.
31 conditions to which it is exposed during its life cycle.
32 ptional network that controls the Plasmodium life cycle.
33 tness across models reflecting stages in its life cycle.
34 ts metabolism in two different stages of the life cycle.
35 ferent life-history stages across the annual life cycle.
36 ntial to regulate this key part of the viral life cycle.
37 developmental decisions throughout the plant life cycle.
38 r protease activity for the remainder of its life cycle.
39 ng poxviruses and is essential for the viral life cycle.
40 y, cell entry, and other stages of the viral life cycle.
41 ule that plays a central role in the biofilm life cycle.
42 understanding of the hepatitis C virus (HCV) life cycle.
43 ric division herald the start of the plant's life cycle.
44 s that target specific stages of the malaria life cycle.
45 sical and chemical analysis during the fruit life cycle.
46 , and affects almost every stage of the mRNA life cycle.
47 displayed by Rep68 and Rep78 during the AAV life cycle.
48 llular and extracellular stages of the virus life cycle.
49 infected hosts as an integral part of their life cycle.
50 IV-1 infection by interfering with the viral life cycle.
51 and characterized their effects on the viral life cycle.
52 V replication at an early stage of the viral life cycle.
53 in intercellular communication and the viral life cycle.
54 which is critical to completion of the virus life cycle.
55 inant cause of environmental impact over the life cycle.
56 eotactic response at some stage during their life cycle.
57 for a previously unknown event in the viral life cycle.
58 ts of plant development throughout a plant's life cycle.
59 ted for each stage of the algae-derived fuel life cycle.
60 s and provide energy to complete the plant's life cycle.
61 V genome, may play a significant role in HBV life cycle.
62 f DNA bacteriophages play essential roles in life cycles.
63 , have acquired different roles in the virus life cycles.
64 renewable feedstocks and exhibit closed-loop life cycles.
65 osine to inosine modifications in retroviral life cycles.
66 odifications may play in more complex fungal life cycles.
67 er than a driver, of incipient multicellular life cycles.
68 es due to their small size and often complex life cycles.
69 t diverse viruses at various stages of their life cycles.
70 es across ontogeny in organisms with complex life cycles.
71 is a herpesvirus with both lytic and latent life cycles.
72 different niches in order to complete their life-cycles.
73 mbda of Escherichia coli has two alternative life cycles after infection-host survival with lysogen f
74 simple terrestrial-only (direct developing) life cycle also had a higher rate of adult body form evo
75 ts a population bottleneck in the Plasmodium life cycle and a key intervention target of ongoing effo
77 cription of a carrier protein throughout its life cycle and demonstrate how a network of dynamic resi
79 reatments targeting this aspect of the viral life cycle and for the production of new viral particle-
80 n Nef controls multiple aspects of the viral life cycle and host immune response, making it an attrac
81 ility in order to better understand the PEDV life cycle and identify suitable targets for antiviral o
83 These genes are integral to the baculovirus life cycle and may be good focal genes for developing ba
84 he host genome is not required for the viral life cycle and might not be necessary for cellular trans
85 l mechanisms modulating LTCC trafficking and life cycle and provide proof of concept for the use of C
86 S-HUHEP mice, HBV infection completes a full life cycle and recapitulates some of the immunopathology
89 tifying host proteins critical for the viral life cycle and/or pathogenesis represents a useful strat
90 conserved motile system is critical to their life cycles and drives directional gliding motility betw
91 ET) family regulate multiple stages of viral life cycles and provide promising intervention targets.
92 micro-ecological challenges of its enzootic life-cycle and long-term residence in the tissues of its
93 small genome size (1 C = 0.34 pg), an annual life cycle, and greater genetic diversity as assessed by
94 e development is a crucial step in the plant life cycle, and the timing of this transition is an impo
97 These results highlight that a more complete life-cycle approach that incorporates the possibility of
101 are expressed during the Mesorhizobium lo ti life cycle as well as no information concerning their na
102 ification in nearly every aspect of the mRNA life cycle, as well as in various cellular, developmenta
104 of 100 years and applied the factors to five life cycle assessment (LCA) case studies of bioproducts.
107 ap in the current literature, we completed a life cycle assessment (LCA) of the decentralized water s
111 The data were analysed using an advanced life cycle assessment (LCA) tool(9), yielding metrics of
113 circumvent the limitations of scenario-based life cycle assessment (LCA), we develop a multiobjective
117 this research uses biokinetics modelling and life cycle assessment philology to explore this notion,
119 Here, we therefore propose a framework using life cycle assessment that enables the quantification of
124 k scale are regularly used as input data for life cycle assessments and techno-economic analyses for
127 sociated with human diseases, control the L1 life cycle at the transcriptional or the post-transcript
128 differentially expressed not only during the life cycle but also within the cell as part of the solub
129 ities against three stages of the parasite's life cycle, but a lengthy synthetic route to these compo
130 NS5A has multiple functions during the virus life cycle, but the biochemical details of these roles r
131 lerae's survival during its aquatic and host life cycles, but also influences its evolution by facili
132 fidelity is closely monitored throughout its life cycle by multiple mitochondrial quality control pro
133 by evaluating groups in the context of their life cycle can we unravel the evolutionary trajectory of
136 volution can follow long-term transitions in life cycle complexity, which may reflect underlying stag
137 of developmental patterns, including complex life cycles composed of morphologically disparate stages
144 riety of assays used to dissect the poxvirus life cycle demonstrate that bisbenzimides inhibit viral
146 to simulate temperature- and food-dependent life cycle development of C. glacialis annually from 198
148 highly dynamic histone PTM landscape during life cycle development, with a set of histone PTMs (H3K4
149 y for Eimeria in relation to its specialized life cycle, distribution across the globe, and the chall
150 ct species (a fast life-cycle mayfly, a slow life-cycle dragonfly and an ostracod) found optimal trad
151 significant burdens to the environment from life cycle emissions associated with their production, b
152 se studies, in conjunction with estimates of life cycle environmental and health benefits of nanopart
153 te change is altering the seasonal timing of life cycle events in organisms across the planet, but th
154 nces, few studies have tested the impacts of life cycle evolution on broad-scale patterns of trait di
155 lso demonstrate a critical role in the viral life cycle for the second receptor binding region of the
157 nts of A. edgeworthii grown throughout their life cycle from aerial seeds (ASP) and from subterranean
158 biological mechanisms controlling macroalgal life cycles - from the production of germ cells to the g
159 es across generations suggest that different life cycle genotypes can coexist in natural populations.
160 not purchase alternative fuels unless their life cycle GHG emissions are less than those of conventi
161 The LCA case studies showed that the total life cycle GHG emissions were closely related to GWPbio
163 The literature analyzing the fuel saving, life cycle greenhouse gas (GHG) emission, and ownership
164 y Laboratory produced a well-to-wheels (WTW) life cycle greenhouse gas analysis of petroleum-based fu
165 l, and generally positive, and can influence life-cycle greenhouse gas emissions of switchgrass ethan
166 s with a simple, aquatic-only (paedomorphic) life cycle had an increased rate of vertebral column and
169 al role for SIRT1 in regulation of the HPV31 life cycle; here, we report that SIRT1 can directly regu
173 cupational exposures to organic chemicals in life cycle impact assessment (LCIA) by building on the c
175 as an initial screening tool for estimating life-cycle impacts of chemicals for certain impact categ
176 information, we trained multilayer ANNs for life-cycle impacts of chemicals using six impact categor
178 y increasing, while our understanding of the life-cycle impacts of these chemicals lags considerably.
180 potential role of this protein in the viral life cycle.IMPORTANCE HPV are causative agents in a numb
181 atent and the replicative stages of the KSHV life cycle.IMPORTANCE Kaposi's sarcoma-associated herpes
182 ty in the capsid assembly stage of the HIV-1 life cycle.IMPORTANCE The HIV-1 capsid protein is an att
186 it is unknown how plants that complete their life cycle in the forest understory and are shade tolera
187 Despite the vital role of the intracellular life cycle in the pathogenesis of the bacteria, the rang
189 regulates several light responses during the life cycle, including de-etiolation, and is also involve
190 However, fundamental aspects of the AAV life cycle, including how AAV interacts with host cellul
192 into several other stages of the poliovirus life cycle, including the mechanism of receptor-triggere
194 blished under the auspices of the UNEP/SETAC Life Cycle Initiative a coupled indoor-outdoor emission-
197 petroleum refinery model, Petroleum Refinery Life-cycle Inventory Model (PRELIM), that estimates ener
200 ease, is a protozoan parasite with a complex life cycle involving a triatomine insect and mammals.
201 spp. and Toxoplasma gondii, undergo complex life cycles involving multiple stages with distinct biol
209 ant participant in many aspects of the viral life cycle, its best-characterized activity is self-asse
210 g example using three insect species (a fast life-cycle mayfly, a slow life-cycle dragonfly and an os
214 te traits across life stages; however, these life-cycle models primarily evaluate effects of lethal c
218 is involved in the regulation of the sexual life cycle of C. reinhardtii, which is controlled by blu
219 aCRY plays an important role in the sexual life cycle of C. reinhardtii: It controls the germinatio
220 show that iPSdMs support the full infectious life cycle of C. trachomatis in a manner that mimics the
223 ylation reprogramming during the sporophytic life cycle of flowering plants regulates genes is presen
224 nt information for further understanding the life cycle of HCV and its interaction with the host cell
226 t studies also elucidate a key aspect of the life cycle of HK2, specifically addressing how they do,
230 rfluoroalkanesulfonic acids (PFSAs) from the life cycle of perfluorooctanesulfonyl fluoride (POSF)-ba
231 imate the emissions associated with the full life cycle of pipeline construction, maintenance, and di
232 of nanoparticles may take place through the life cycle of products embedding nanomaterials, thus res
233 me, mechanisms by how SAgs contribute to the life cycle of S. pyogenes remain poorly understood.
240 erstanding the mechanisms of the replicative life cycle of the virus may bring to light direct target
242 life cycle, providing new insights into the life cycle of this poorly characterized family of viruse
243 l stochasticity, due to random events in the life cycle of wild organisms, yet no study thus far has
244 with the amoeba for months, through multiple life cycles of amoebae grown on the lawns of other bacte
249 s showed that BPH was unable to complete its life cycle on L. sayanuka, and N. muiri could not comple
251 it stresses the paramount importance of the life cycle: only by evaluating groups in the context of
252 monstrates the applicability of S-LCC to SWM life-cycle optimization through a case study based on an
253 replication at different stages of the viral life cycle or productive replication on macrophage funct
254 of host factors or drugs on steps of the HIV life cycle, or its reactivation from the latent state, t
255 rmancy and flowering time shape annual plant life cycles over multiple generations, we established na
260 occurring in diatoms in a key phase of their life cycle, providing hints on the evolution and putativ
261 lation of NO production during the sapovirus life cycle, providing new insights into the life cycle o
266 costs on insects showing diapause and other life cycle responses, threatening population persistence
267 e expression in late events during the viral life cycle, RNA-Seq was carried out on triplicate differ
268 ld provide phase-specific support across the life cycle, securing the gains of investment in the firs
270 e only four proteins to accomplish the viral life cycle, so each arenavirus protein likely plays unap
271 in the lipid rafts of an organism employing life cycle-specific sterols and have implications for tr
272 eal-time qPCR has confirmed the differential life-cycle stage expression of a set of selected lincRNA
276 Here, I analyse the swimming of the insect life cycle stages of two human parasites; Trypanosoma br
277 We wondered whether the insect and mammalian life cycle stages possess chemically different lipid raf
278 rall, we expand our view of the sex-specific life cycle stages that can drive sex chromosome evolutio
279 on haploid genotypes during less conspicuous life cycle stages, e.g., competition among sperm/pollen
282 velopments targeting different molecular HBV life cycle steps are being pre-clinically tested or have
284 atures with parasitic nematodes with complex life cycles, such as the production of few males after o
285 Subsequently, during the lytic phase of the life cycle, the maturing viral particles undergo orchest
287 ects of methyl-6-adenosine in distinct viral life cycles, the role of 2' O-methyl modifications in RN
288 lls allowed completion of steps in the HIV-1 life cycle through integration but suppressed HIV-1 gene
289 isk human papillomaviruses (HPVs) link their life cycle to epithelial differentiation and require act
290 al that CRISPR-Cas systems exploit the phage life cycle to generate a pattern of spacer acquisition t
292 uely associated with AT during part of their life cycle: Trypanosoma cruzi, the causative agent of Ch
294 cell, HIV-1 completes the early phase of its life cycle upon integration of reverse-transcribed viral
295 lmark of all herpesviruses is their biphasic life cycle-viral latency and the productive lytic cycle-
296 in eukaryotes is the evolution of a biphasic life cycle with alternating diploid and haploid phases.
297 and physiological adaptations to land, and a life cycle with an alternation between multicellular hap
298 earchers to image multiple steps of the mRNA life cycle with high temporal and spatial resolution.
299 Following HBV infection, a complete viral life cycle, with production of HBV DNA, hepatitis B e (H
300 azoan hosts and insect vectors through their life cycles, with the need to respond quickly and revers
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