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1 tigen-specific Tregs and constrained antigen-specific immunity.
2 with multiple genotypes, suggesting genotype-specific immunity.
3 fects for the development of robust Borrelia-specific immunity.
4 ious sites of the Ad fiber to elicit epitope-specific immunity.
5 sease (GVHD) rates, but also impair pathogen-specific immunity.
6 t S. flexneri interferes with the priming of specific immunity.
7 with HIV, but also to recapitulate human HIV-specific immunity.
8 G significantly inhibiting adaptive allergen-specific immunity.
9 rtant role in infant acquisition of pathogen-specific immunity.
10 for several developmental processes and race-specific immunity.
11 ed immune suppression and facilitating tumor-specific immunity.
12 al inoculation to elicit significant antigen-specific immunity.
13 tion of whether soluble CEA influences tumor-specific immunity.
14 ization with ASPH-loaded DCs induced antigen-specific immunity.
15 ses to HIV-1 Ags despite the presence of Ad5-specific immunity.
16 s radiotherapy-induced mobilization of tumor-specific immunity.
17 e pathogen can infect), innate immunity, and specific immunity.
18 activation, which may limit induction of RSV-specific immunity.
19 assessed for their ability to elicit antigen-specific immunity.
20 strategy to potentiate DC activation of HIV-specific immunity.
21 recognition of pathogens, leading to strain-specific immunity.
22 mmunopathogenic in cancers by impeding tumor-specific immunity.
23 the studies of HIV-1 pathobiology and virus-specific immunity.
24 kin 4 (IL-4) in the regulation of mycoplasma-specific immunity.
25 either preexisting or vaccine-induced vector-specific immunity.
26 ion, suggesting a protective role for strain-specific immunity.
27 of the chemotherapy doses that maximize HER2-specific immunity.
28 fection, before the typical onset of antigen-specific immunity.
29 lerance induction in other models of antigen-specific immunity.
30 inborn errors that selectively disrupt liver-specific immunity.
31 onse or the time to detection of HPV16/18 E7-specific immunity.
32 induced both humoral and cellular antigenic specific immunity.
33 r memory cell lineage development and tissue-specific immunity.
34 hat chemotherapy enhances tumor antigen (TA)-specific immunity.
35 Compared to CAs, AAs have weaker HCV-specific immunity.
36 kinase activity was absolutely required for specific immunity.
37 help B cell responses and promote influenza-specific immunity.
38 CMV viremia did not appear to boost CMV-specific immunity.
39 athogens and directing the development of Ag-specific immunity.
40 Rs for the development of posttransplant CMV-specific immunity.
41 rvival and persistence of systemic ovalbumin-specific immunity.
42 latory T (T reg) cells that suppress antigen-specific immunity.
43 reassortant vaccines predicated on serotype-specific immunity.
44 llenge, and the apparent maturation of virus-specific immunity.
45 une response but also dampen foreign antigen specific immunity.
46 lls (DC) is critical for the induction of Ag-specific immunity.
47 diated cell transformation, and modulate EBV-specific immunity.
48 ar adjuvant and potentially promoting tissue-specific immunity.
49 myosin and myoglobin did not induce T. cruzi-specific immunity.
50 s both the innate and adaptive arms of tumor-specific immunity.
51 design of novel molecules for invoking tumor-specific immunity.
52 lastoma and generates systemic neuroblastoma-specific immunity.
53 omas, regression is known to involve antigen-specific immunity.
54 en established for the reconstitution of EBV-specific immunity.
55 replication, but it is unable to restore HIV-specific immunity.
56 mmune mechanisms are important for cruzipain-specific immunity.
57 this might not reflect alterations in tissue-specific immunity.
58 n that compromise both leukemia and pathogen-specific immunity.
59 mune responses, thereby possibly shaping the specific immunity.
60 ng CD8 T cell activity and boosting pathogen-specific immunity.
61 arly after antigen challenge retards antigen-specific immunity.
62 mor-associated antigens, resulting in cancer-specific immunity.
63 cells, no patients developed impaired virus-specific immunity.
64 minate various large tumors and induce tumor-specific immunity.
65 pecific tolerance while maintaining pathogen-specific immunity.
66 the efferent lymphatics that may enhance Ag-specific immunity.
67 s a key role in the development of influenza-specific immunity.
68 A-BN-Filo resulted in sustained elevation of specific immunity.
69 for the establishment of effective pathogen-specific immunity.
70 s, enhance tumor-specific and, likely, virus-specific immunity.
71 lements into CRISPR loci to provide sequence-specific immunity.
72 ll recovery and transfer of protective virus-specific immunity.
73 ation of latent virus and improvement of HIV-specific immunity.
74 amatic and long-term consequences for tissue-specific immunity.
75 s, thereby obviating the requirement for HIV-specific immunity.
76 at B. burgdorferi exposure may elicit strain-specific immunity.
77 ental for the development of robust Borrelia-specific immunity.
78 vaccine design is the phenomenon of "strain-specific" immunity.
79 ance coincided with the development of virus-specific immunity (3-6 weeks postinfection), suggestive
80 s have shown that despite induction of virus specific immunity, a curative response is often not atta
81 s enhanced in mice with established SIINFEKL-specific immunity after AAV2-OVA/alpha1 anti-trypsin (AA
85 time it takes to induce protective pathogen-specific immunity after vaccination limits protection in
86 N-Filo) vaccine regimen is safe and provides specific immunity against Ebola glycoprotein, and is cur
87 d with LCMV develop a transient defect in Ag-specific immunity against heterologous viral infection.
89 ned accurate estimates for the degree of age-specific immunity against monkeypox, influenza A(H5N1) a
93 low bacteria and archaea to acquire sequence-specific immunity against selfish genetic elements such
94 n-modulation was accompanied by increased Ag-specific immunity against the neu protein, a self Ag.
95 as systems provide prokaryotes with sequence-specific immunity against viruses and plasmids based on
97 MV) delayed tumor growth and activated tumor-specific immunity although the mechanism was unclear.
98 on in CD4(+) T cells while maintaining virus-specific immunity, an objective critical in the developm
100 ments of virus load, target cells, and virus-specific immunity and applied it to a comprehensive data
101 T cell receptors (TCRs) are key to antigen-specific immunity and are increasingly being explored as
103 g the RIG-I pathway to enhance viral-vaccine-specific immunity and have broader implications for desi
104 rogrammed cell death 1 (PD-1) activate tumor-specific immunity and have shown remarkable efficacy in
105 future include vaccine development, pathogen-specific immunity and identification of risk factors for
106 human immunodeficiency virus type 1 (HIV-1)-specific immunity and increase clearance of HIV-1-expres
108 , those who succumbed have minimal influenza-specific immunity and little evidence of T-cell activati
110 iotic-treated animals cannot stimulate viral-specific immunity and microglia depletion leads to worse
111 deletion may contribute significantly to CMV-specific immunity and might therefore also influence chi
113 SV) are characterized by short-lasting virus-specific immunity and often long-term airway morbidity,
115 oung mice, and MDSC depletion improved tumor-specific immunity and reduced tumor growth in aged mice.
116 n increase in naturally occurring neoantigen-specific immunity and revealed previously undetected hum
118 CXCL12 and CCL5 in activation of melanocyte-specific immunity and suggest inhibition of these chemot
119 nsitization affect the evolution of filarial-specific immunity and susceptibility to W. bancrofti inf
121 ation of antiretroviral therapy (ART) on HIV-specific immunity and the balance of the CD4(+) T-cell t
122 results improve our understanding of subtype-specific immunity and the neutralization breadth require
123 nal effects of these cytokines on innate HIV-specific immunity and their impact on cells harboring HI
125 (DT)-mediated Treg depletion improved tumor-specific immunity and was clinically effective only in y
126 safety, successful in vivo induction of PSA-specific immunity, and impact on surrogate clinical endp
127 FRalpha-loaded DCs is safe, induces antigen-specific immunity, and is associated with prolonged remi
128 lls in an MLR, inducing human papillomavirus-specific immunity, and migrating from epidermal tissue.
129 is evidence that irradiation mobilizes tumor-specific immunity, and recent studies showed that the ef
133 parasite-mediated myocytolysis and parasite-specific immunity, are coincident during active infectio
134 tored the effects of gene deficiencies on PG-specific immunity, arthritis severity, leukocyte traffic
135 is thought to limit late stages of pathogen-specific immunity as a means of minimizing associated ti
137 contribute to early imprinting of influenza-specific immunity as well as the increased susceptibilit
140 a paradigm shift in our understanding of HCV-specific immunity at the MFI as well as novel insights i
141 he generation of effective levels of antigen-specific immunity at the mucosal sites of pathogen entry
142 ation was made between the presence of tumor-specific immunity at the time of diagnosis and overall s
144 titer CMVIG preparations provide passive CMV-specific immunity but also exert complex immunomodulator
145 s-infected immature DCs would activate virus-specific immunity, but facilitating virus dissemination.
146 ammatory cytokines but also directly affects specific immunity by differentiating monocytes into macr
147 esenting cells are thought to shape pathogen-specific immunity by inducing secretion of costimulatory
148 events was likely due to inhibition of donor-specific immunity by the immunosuppressive regimen.
149 sized that IRX-2 enhanced tumor antigen-(TA)-specific immunity by up-regulating functions of dendriti
150 though research into the induction of tissue-specific immunity by vaccines and with age is still limi
152 e evidence of partial type-specific or clade-specific immunity conferred by seropositivity to HPV 16
154 d on: establishing the longevity of poxvirus-specific immunity, defining key immune epitopes targeted
157 elated differences in the development of HIV-specific immunity during acute infection, we evaluated t
160 ion as an approach to initiate local antigen-specific immunity, enhance previously existing systemic
161 nd the treatment-mediated promotion of tumor-specific immunity, especially the antitumor CD8(+) T-cel
164 hin these DNAs suggests that most or all fat-specific immunity genes contain a common organization of
165 enon termed "memory inflation." Elevated CMV-specific immunity has been correlated with an increased
168 es that are based on heterotypic or serotype-specific immunity has prompted many countries to establi
169 Time to development of detectable HER-2/neu-specific immunity, however, was significantly earlier fo
170 Vaccination of individuals with existing HIV-specific immunity improved the magnitude, breadth, and p
171 ction and VZV reactivation, we characterized specific immunity in 207 nonsymptomatic immunocompetent
172 ns capable of inducing antiviral CD8+ T-cell-specific immunity in a manner compatible with human deli
175 , 4 years after clearance, regulation of HCV-specific immunity in blood by regulatory T cells (Tregs)
179 naive mice had no impact on priming antigen-specific immunity in mice immunized with a recombinant L
181 The development of vaccines to induce tumor-specific immunity in patients with cancer has as emerged
182 or with CY and DOX is safe and induces HER2-specific immunity in patients with metastatic breast can
183 sults demonstrate that the presence of FVIII-specific immunity in recipients does not negate engraftm
184 th particular DCs for efficient induction of specific immunity in the absence of additional adjuvant.
185 ted larval stages produces a substantial and specific immunity in the absence of egg-induced patholog
187 Here we provide evidence for acquired strain-specific immunity in the crustacean Daphnia magna infect
190 alaria, its impact on development of malaria-specific immunity in these children remains poorly under
191 red mechanisms leading to this change in EBV-specific immunity in untreated patients with MS and heal
194 ding, the development of effective, pathogen-specific immunity in young mice requires alphabeta T cel
195 component of gene expression for innate and specific immunity, in the hematopoietic system, in cellu
196 fferential upregulation of influenza vaccine-specific immunity including hemagglutination inhibition
198 attenuated virus, nor WT mice with Th2 RABV-specific immunity induced by immunization with inactivat
199 gies of vaccination can enhance the level of specific immunity induced by nucleic acid vaccines.
203 ived virus-specific T cells to restore virus-specific immunity is an effective strategy to control CM
205 o rickettsiae and that generation of antigen-specific immunity is crucial to complete protection.
208 st acute T. cruzi infection; 2) effective TS-specific immunity is maintained during chronic T. cruzi
213 s diversity has led to concerns about allele-specific immunity limiting the effectiveness of vaccines
214 es, DBP allelic variation eliciting a strain-specific immunity may be a major challenge for developme
215 Enhanced human immunodeficiency virus (HIV)-specific immunity may be required for HIV eradication.
217 enhance and/or restore the function of virus-specific immunity may protect from disease progression.
219 ceiving the highest dose developed HER-2/neu-specific immunity more rapidly than those who received t
220 nnection between cell identity and cell type-specific immunity networks that might guide cell types i
221 gulatory patterns underlying these cell type-specific immunity networks, we developed a tool to analy
224 he impact of preexisting cardiac myosin (CM)-specific immunity on murine heart transplant recipients
225 ing infections and hypotheses about genotype-specific immunity or a limit on the number of infections
231 In mice with preexisting L. monocytogenes-specific immunity, priming of naive T cells was not prev
232 id (TT) immunity by quantifying age- and sex-specific immunity prior to and 2 years after introductio
233 We investigated the ability of each colicin-specific immunity protein (Im2, Im7, Im8 and Im9) to bin
235 toxins into neighboring bacteria and produce specific immunity proteins that protect against self-int
236 tion mechanism explains the ability of DNase-specific immunity proteins to display dual recognition s
238 e and appears to be due to a defect in HIV-1-specific immunity rather than infection with attenuated
241 ction to limit the recall responses of tumor-specific immunity, remain poorly understood and interfer
242 es the efficiency with which proteins elicit specific immunity, setting the stage for proof-of-concep
245 vation of dendritic cells and enhancement of specific immunity, similar to selected synthetic dsRNA m
248 ter intrinsic capacity to reconstitute HIV-1-specific immunity than adults, and may be excellent cand
249 gainst tissue of solid organs leads to organ-specific immunity that can be transferred by DLI was unk
250 an be used as a tumor vaccine to elicit DKK1-specific immunity that can control myeloma growth or eve
251 ered dendritic cells (DC) generate strong Ag-specific immunity that has an absolute requirement for b
252 In contrast, BCG stimulates long-term tumor-specific immunity that primarily depends on CD4 T cells.
253 C6VL-DC vaccines stimulated potent tumor-specific immunity that protected mice against lethal cha
254 c vaccination often induces markers of tumor-specific immunity, therapeutic responses remain rare.
255 to explore the possibility of inducing tumor-specific immunity through active immunization in the abs
256 G subclasses provide pathogen- and cell type-specific immunity through differential metabolic reprogr
257 in binding portion of coagulases confer type-specific immunity through the neutralization of S. aureu
259 proposed as a strategy that could boost HIV-specific immunity, through controlled exposure to autolo
260 tor-ligand interaction and propose that host-specific immunity to a particular Gram-negative bacteriu
261 h the known 3- to 6-month lag in recovery of specific immunity to CMV after initiating cART and sugge
263 e also examined the contribution of T. cruzi-specific immunity to inflammation by injection of T. cru
266 t seems to wax and wane on the importance of specific immunity to malignant cell antigens by previous
268 derstanding if oral vaccination provides non-specific immunity to other infections so that the conseq
269 vDBPII antibodies are associated with strain-specific immunity to P. vivax and support the use of PvD
270 VSTs) is a strategy to rapidly restore virus-specific immunity to prevent or treat viral diseases aft
272 indicate that Hsp70.PC-F vaccine can induce specific immunity to radioresistant populations of mamma
274 complete regression of metastatic tumor and specific immunity to subsequent rechallenge in the major
275 nks the role of the microbiota and microbial-specific immunity to the development of murine SGVHD.
276 demonstration that there is infection stage-specific immunity to tuberculosis has implications for v
277 -Cas adaptive immune system confers sequence-specific immunity to viral infection and has the potenti
278 eptibility to W. bancrofti and skews filaria-specific immunity toward a Th2-type cytokine response.
279 cy of the passive transfer of protective HSV-specific immunity under conditions of acute psychologica
280 containment and may support induction of HBV-specific immunity upon HBV infection, but may also contr
282 ecipients, we show that an assessment of CMV-specific immunity using a novel ELISPOT assay is able to
288 pes virus and tumor-associated antigen (TAA)-specific immunity was measured with HLA-class I-restrict
291 e that dbp allelic diversity plays in strain-specific immunity, we examined the ability of an anti-Sa
292 immune enhancement (e.g. tumor- and pathogen-specific immunity), whereas boosting these factors will
293 n direct tumor cell death and augments tumor-specific immunity, which enhances tumor control both loc
294 herapeutics, with the goal of inducing tumor-specific immunity while preventing premature virus clear
296 mmon pathogens, leading to acquired pathogen-specific immunity with a robust memory T-cell repertoire
298 hin 7-9 months (between epidemics) and group-specific immunity within 2-4 months (during an epidemic
299 primary infection, some infants lose strain-specific immunity within 7-9 months (between epidemics)
300 ones, provides a means of augmenting antigen-specific immunity without the in vivo constraints that c