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1 g an immune response and may represent a CTL escape mutant.
2 on acts both as a CTL and protease inhibitor escape mutant.
3 n of the hepatic allograft with the YMDD HBV escape mutant.
4 ld have public health relevance as a vaccine escape mutant.
5 he same peptide retained potency against ENF-escape mutants.
6 uppressed viral replication and generated no escape mutants.
7 ations of a neutralizing antibody to isolate escape mutants.
8 ll responses and limits recognition of viral escape mutants.
9 umventing or limiting the emergence of viral escape mutants.
10 at these plasma Nef variants represent novel escape mutants.
11 topes and minimizes the likely generation of escape mutants.
12 d results in cumulative toxicities and viral-escape mutants.
13 mals without the emergence of drug-resistant escape mutants.
14 n, which in turn could have selected for new escape mutants.
15 an unbiased approach to isolate and analyze escape mutants.
16 nd may limit the emergence of neutralization-escape mutants.
17 ed B6 mice suppressed the development of CTL escape mutants.
18 ereby reducing the probability of generating escape mutants.
19 e emergence and competitive advantage of CTL escape mutants.
20 susceptible to the problem of drug-resistant escape mutants.
21 e ability of the response to recognize virus escape mutants.
22 that such variants represent neutralization escape mutants.
23 evolution of antiviral resistance or vaccine-escape mutants.
24 shown to reduce drastically the selection of escape mutants.
25 immune pressure leading to the selection of escape mutants.
26 be more widely useful and less vulnerable to escape mutants.
27 nanobody fusions suppressed the emergence of escape mutants.
28 identifying a drug's mechanism of action and escape mutants.
29 ompletely inhibited the replication of these escape mutants.
30 rry the benefit of mitigating risks of viral escape mutants.
31 r the emergence of drug-resistance or immune-escape mutants.
32 munodeficient hosts failed to generate viral escape mutants.
33 public health risk linked with generation of escape mutants.
34 ding domain (RBD) and generated 50 different escape mutants.
35 g the likelihood of selecting neutralisation-escape mutants.
36 synergistically and limits the emergence of escape mutants.
37 everal Ags may limit the generation of viral escape mutants.
38 ficacy can be undermined by the emergence of escape mutants.
39 DNA within the host genome, which can harbor escape mutants.
40 an and zoonotic SARS-CoVs and neutralization escape mutants.
41 clonal Abs (mAbs) to sequentially select IAV escape mutants.
42 antiviral-resistant variants and host immune escape mutants.
43 ll immunity against commonly occurring virus escape mutants.
44 esistance and increasing the risk of vaccine escape mutants.
48 the interaction as previously determined by escape mutant analysis and site-directed mutation, is lo
49 Epitope-mapping studies using neutralization escape mutant analysis, deuterium exchange mass spectrom
53 ance monitoring is essential to detect assay escape mutants and ensure universal detection of evolvin
54 her epitope characterization by selection of escape mutants and epitope mapping by flow cytometry ana
55 of resolving infection without selecting for escape mutants and is applicable to other virus-host int
57 The structure also rationalizes inhibitor escape mutants and mutations observed in live-attenuated
58 e present study, we generated neutralization escape mutants and studied the effect of these neutraliz
59 ity-matured HC-1 antibodies yielded no viral escape mutants and, with the affinity-matured IgG1, need
60 pe does not preclude the selection of T cell escape mutants, and epitope-specific T cells are still p
61 ibody responses to secondary infections with escape mutants are dominated by specificities to the ori
62 a lymphocytic choriomeningitis virus-derived escape mutant as demonstrated by the sustained activatio
63 development of cytotoxic T lymphocyte (CTL) escape mutants, as compared to the lung memory NP-specif
69 probability that the population develops an escape mutant before extinction, is encoded in the risk
70 temporary human influenza viruses identified escape mutants before they caused an epidemic in 2014-20
72 at Wyeth/IL-15/5Flu does not generate T cell escape mutants but increases stochastic events for virus
73 ergence and immune presentation of viral CTL escape mutants but rather arise de novo following primin
74 roved potency of inhibitory peptides against escape mutants by increasing enthalpic release of energy
77 dynamics profiles of the A92E and G94D CypA escape mutants closely resemble that of wild-type CA ass
78 tent activity without the emergence of viral escape mutants, co-administration of different bNAbs is
83 suggested that cytotoxic T-lymphocyte (CTL) escape mutants contributed to virus amplification and th
86 in different MERS-CoV isolates and antibody escape mutants, cross-neutralization of divergent MERS-C
88 the higher dose and that while GCV resistant escape mutants did arise, a significant fraction of the
89 of specific CTLs to the frequency of Tat SL8 escape mutants during acute SIV infection allowed us to
90 anticipates the possible evolution of viral escape mutants during the use of therapies targeting thi
92 ics of immune escape, we found that multiple escape mutants emerge simultaneously during the escape,
96 linical improvement and did not induce viral escape mutants, encouraging the future use of remdesivir
98 orating the receptor-blocking hypothesis, T2 escape mutants evolve resistance to PinQ anti-phage defe
101 c barrier to the generation and selection of escape mutants following exposure to host-targeted imino
105 rther characterization of the neutralization escape mutant generated using this MAb showed that three
106 ould also consider the potential risk of the escape mutants generated by mAb treatment to public heal
108 oV-2 and its variants of concern, as well as escape mutants generated by the parental monoclonal anti
110 ncy of the appearance of monoclonal antibody escape mutants generated when the virus is pressured to
112 ious experiments have identified an antibody escape mutant (H310A1) of a myocarditic variant of CVB3
113 was His to Tyr at amino acid 44; additional escape mutants had a His-to-Arg mutation at amino acid 4
115 inhibitory compounds, indicating that the F escape mutants have a reduced conformational stability a
118 Seasonal vaccines are often ineffective and escape mutants have been reported to all treatments for
119 Previous studies of natural neutralization escape mutants have predominantly focused on gp120 and g
121 s, including the isolation of neutralization escape mutants, hydrogen/deuterium exchange mass spectro
123 k-derived decomplementing factors, then OspA escape mutants, if infectious, could seriously diminish
125 Next-generation sequencing of a putative RHV escape mutant in a vaccinated rat identified mutations i
127 However, HF5 quickly selected pH1N1 virus escape mutants in both prophylactic and therapeutic trea
129 ssible routes for the evolution of fit viral escape mutants in HIV-1YU-2-infected humanized mice, wit
132 ape; new pandemic variants, as well as viral escape mutants in seasonal influenza, compromise the bui
136 We generated palivizumab and motavizumab escape mutants in vitro and examined the development of
140 g antibody classes that can neutralize viral escape mutants is critical for universal influenza virus
142 ated ability to suppress generation of HIV-1 escape mutants is significantly lower than the activity
143 oned the env genes from the the parental and escape mutant isolates and made chimeric infectious mole
144 ments reveal a high barrier for emergence of escape mutants, making it a good candidate for clinical
145 tically stable virus antigens, suggests that escape mutants may be a serious problem when CTL therapy
149 had broad neutralizing capabilities, and its escape mutant N149D had reduced viral stability and huma
150 h enhanced bnAb lineage envelope binding and escape mutant neutralization-traits associated with incr
151 e inhibition of that mutant but not of other escape mutants nor of the ancestral, unevolved phage.
152 re have been no significant strain shifts or escape mutants noted since the introduction of rotavirus
155 sible role of outer surface protein A (OspA) escape mutants of Borrelia burgdorferi in decreasing the
157 Cytotoxic T lymphocytes select for virus escape mutants of HIV and SIV, and this limits the effec
158 protein would be less likely to promote the escape mutants of SARS-CoV-2 as frequently as did those
160 ctedly, given the complete dependence of the escape mutant on CCR5 for entry, monomeric gp120 protein
161 a HLA-B27 restricted cytotoxic T lymphocyte escape mutant on the nucleoprotein that emerged in the 1
163 erating enhanced protection against pathogen escape mutants, or novel specificities after vaccination
164 he present study, we report the isolation of escape mutant phage that are able to replicate more effi
166 with the wild-type virus revealed that some escape mutants possessing an amino acid substitution oth
168 ins a large number of cytotoxic T lymphocyte escape mutants, presenting another challenge to HIV cure
170 nts using single shRNAs, multiple SARS-CoV-2 escape mutants quickly emerged from infected cells withi
172 e responses, the longer-term impact of viral escape mutants remains unclear, as these variants can al
175 of a new, perfect, antisense RNA against an escape mutant resulted in the inhibition of that mutant
176 luenza A virus and attempts to select for an escape mutant resulted in variants that conformed to hos
177 a panel of monoclonal antibody hemagglutinin escape mutants revealed a positive correlation between r
180 ural and biochemical analyses and engineered escape mutants revealed that these inhibitors restrict a
183 A/NWS/33(HA)-A/Mem/31/98(NA) (H1N2) and nine escape mutants selected by these monoclonal antibodies.
189 However, there is a risk of selecting viral escape mutants, so a new combination is needed using dif
190 these were mapped in distinct epitopes using escape mutants, structure analyses, and competition assa
191 Sequence analysis of the evolution of the escape mutants suggested that the most relevant changes
192 tibodies decrease the in vitro generation of escape mutants, suggesting their potential in mitigating
194 thought to have a higher genetic barrier to escape mutants than directly acting antivirals, yet ther
199 dies, we previously identified H9N2 antibody escape mutants that contained deletions of amino acids i
201 pressed, preventing the evolution of antigen escape mutants that drive resistance to CAR T cell thera
202 , these neutralizing antibodies selected for escape mutants that harbored substitutions and deletions
204 alize the TF virus but also can select virus escape mutants that in turn select affinity-matured neut
205 essure in patients to drive the evolution of escape mutants that lead to sustained chromatin occupanc
206 hat aims to decrease the potential for virus escape mutants that might arise in response to selective
208 olution and between-host transmission of CTL escape mutants that predicts the prevalence of escape mu
209 A-B*57, are associated with the selection of escape mutants that reduce viral replicative capacity.
210 ification, we selected a population of viral escape mutants that resist stringent neutralization with
211 envelope region (loop D) and selected virus escape mutants that resulted in both enhanced bnAb linea
212 udies with past influenza viruses identified escape mutants that were antigenically similar to varian
213 not against the emergence of neutralization escape mutants that were found to be already present in
214 accinated mice challenged with WT vs. H28-A2 escape mutants, the selective advantage conferred by gly
215 been demonstrated in previous studies of CTL escape mutants, this is the first illustration of signif
216 HN proteins, and the characterization of an escape mutant to localize the binding site of AVS-I to t
218 fic host conditions are required for epitope escape mutants to display increased virulence, and the N
220 anisms of CTL and reveal the possibility for escape mutants to prevail in the hostile environment of
223 ession on the potential development of virus escape mutants using a permissive T-cell line cultured u
224 e present study, we generated neutralization-escape mutants, using 6 different monoclonal antibodies,
225 have broad strain recognition, and the only escape mutants, V339I and D348E, are located on the C'D'
226 hemagglutinin antigenic sites by generating escape mutant variants against the neutralizing antibodi
227 Both in vitro and in vivo, individual RSV PZ escape mutants varied in their susceptibility to PZ.
229 Epitope mapping of the neutralizing mAbs via escape mutant virus generation revealed a shared binding
234 sion machinery, and the selection of COV1-65 escape mutant viruses identified critical residues Y886H
235 ure on the HA stalk can lead to expansion of escape mutant viruses in study participants challenged w
236 Interestingly, in mice the neutralization escape mutant viruses showed either attenuation (Urbani
237 To investigate the potential threat of serum escape mutant viruses to humans and poultry, the impact
241 hich suggests that the rate of generation of escape mutants was a significant factor in the efficacy
242 ic sequencing, no evidence of neutralization-escape mutants was detected.CONCLUSIONIn adults hospital
244 pe, revealed that attenuation of the epitope escape mutants was not due to the loss of a pathogenic i
245 ndicated that the net selective advantage of escape mutants was slight, further underscoring the impo
246 lay epitope mapping assay and neutralization escape mutant, we show that mAb11 recognizes the fusion
247 re a response to emergence of neutralization escape mutants, we cloned expressed and characterized en
248 ctra of wild-type and the A92E and G94D CypA escape mutants, we demonstrate that assembled CA is dyna
249 be subject to sequence variations leading to escape mutants, we examined sequence variations of one I
250 he antibodies in vivo, as mice infected with escape mutants were 100% protected after only a single t
252 tope achieved fitness-balanced escape, these escape mutants were each maintained in the viral populat
256 ls [PBMCs]; not significant [NS]), and viral escape mutants were observed in both KY9 and KK10, resul
257 g mutations within the S510 epitope (epitope escape mutants) were associated with persistent virus an
258 azeb protects against the rapid emergence of escape mutants, whereas monotherapies even against conse
259 scFv before inoculation into mice grew into escape mutants, whereas spirochetes incubated with an ir
260 ed in previous studies, we isolated 66 phage escape mutants which had become insensitive to 13 distin
261 229 features a high barrier for selection of escape mutants, which are rare and associated with reduc
263 ses while decreasing the prevalence of viral escape mutants, which could cause the therapeutic to no
264 rotein on 80R versus ACE2 binding, including escape mutants, which should facilitate the design of im
265 gens might play a role in generating vaccine-escape mutants, while substitutions at positions S195D a
268 tment with P28 alone led to the emergence of escape mutants with mutations in the P28 target region.
271 ically to increase immune escape, (2) immune-escape mutants with replication deficiencies relative to
272 ail and used to select a total of 26 unique 'escape' mutants with substitutions across nine different
273 ressure can lead to the development of viral escape mutants, with consequent loss of immune control.