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1 e the impact of the EBOV gene borders during viral transcription.
2 erase II function during the early stages of viral transcription.
3 L-BC cap snatching is also activated by viral transcription.
4 e papillomavirus (PV) genome maintenance and viral transcription.
5 by humans bind to such particles and inhibit viral transcription.
6 reby switch the host elongation machinery to viral transcription.
7 rotein (CREB) and downregulates Tax-mediated viral transcription.
8 bodies resulted in the absence of detectable viral transcription.
9 This phenotypic change required active viral transcription.
10 ng filamentation, were also nonessential for viral transcription.
11 so abolished profilin's ability to stimulate viral transcription.
12 gration, and the Mediator complex (Med28) in viral transcription.
13 ernatively spliced viral mRNAs and may alter viral transcription.
14 ins are the key activators and regulators of viral transcription.
15 in the viral promoter and mediate high-level viral transcription.
16 ded oncoprotein Tax is a potent activator of viral transcription.
17 ocalize to the nucleus, where they stimulate viral transcription.
18 ification of Tat affects its activity during viral transcription.
19 identify a new role of vPK as a modulator of viral transcription.
20 n heterochromatin associated with a block in viral transcription.
21 replication origin (Ori-Lyt) and to regulate viral transcription.
22 ssays down-regulates Tax oncoprotein-induced viral transcription.
23 ducts increased NFAT activity to further aid viral transcription.
24 of genomic nucleocapsids and suppression of viral transcription.
25 ticle assembly, and acting as a modulator of viral transcription.
26 viral genome to ND10 to efficiently initiate viral transcription.
27 so exhibited distinct modes of regulation of viral transcription.
28 V) utilize the viral Tat protein to activate viral transcription.
29 host cell factor that is required for HIV-1 viral transcription.
30 d a PBX1-associated protein, PREP1, enhanced viral transcription.
31 observed phenotypes is absent elongation of viral transcription.
32 thesis resulted in a significant decrease in viral transcription.
33 on assay showed that the M protein inhibited viral transcription.
34 tors regulate HPV DNA replication as well as viral transcription.
35 factors in basal keratinocytes, E2 promotes viral transcription.
36 ed in the immune response, inflammation, and viral transcription.
37 This complex activates the elongation of viral transcription.
38 onse elements (TAR) to increase the rates of viral transcription.
39 cinia virus expression system also inhibited viral transcription.
40 us direct polyadenylation and termination of viral transcription.
41 e, in the absence of actin, did not activate viral transcription.
42 (TAR) RNA to increase rates of elongation of viral transcription.
43 teins that are involved in the regulation of viral transcription.
44 as VP16, require functional cdks to activate viral transcription.
45 NA element TAR is critical for activation of viral transcription.
46 ting cells after growth arrest by increasing viral transcription.
47 by activating long terminal repeat-directed viral transcription.
48 gesterone regulates productive infection and viral transcription.
49 perate to stimulate productive infection and viral transcription.
50 cruited to viral genomes in order to repress viral transcription.
51 from host capped RNAs and uses them to prime viral transcription.
52 suppressing NF-kappaB-mediated activation of viral transcription.
53 ation, and had only minimal effects on early viral transcription.
54 levels and govern polymerase behavior during viral transcription.
55 y infected cells with a higher proclivity to viral transcription.
56 o multiple viral gene promoters and enhances viral transcription.
57 ng terminal repeat (LTR) promoter suppresses viral transcription.
58 closed circular (CCC) DNA, the template for viral transcription.
59 structurally unique EBOV gene borders during viral transcription.
60 reservoir by combining ART with inducers of viral transcription.
61 (RNA-Seq) analysis showed that cessation of viral transcription 7 dpi coincides with a robust antivi
64 were replaced by a constitutively expressed viral transcription activator, RTA, which dictates the v
65 arly protein IE1 is a principal regulator of viral transcription and a contributor to origin-specific
66 rvations provide new essential insights into viral transcription and a possible low mutagenic target
69 ssessing a 5'-triphosphate are a hallmark of viral transcription and can trigger the host antiviral r
72 nd E2 proteins play key roles in controlling viral transcription and DNA replication, how these facto
73 scription, which requires cdks, or that both viral transcription and DNA replication, independently,
74 ne cells display more extensive but aberrant viral transcription and do not support either viral DNA
75 ased expression of HNF3beta modestly reduces viral transcription and dramatically inhibits replicatio
80 type I (HTLV-I), is required for high level viral transcription and HTLV-I-associated malignant tran
82 HBZ, APH-2 is able to inhibit Tax-2-mediated viral transcription and is detectable in most primary ly
83 I oncoprotein Tax is required for high level viral transcription and is strongly linked to HTLV-I-ass
84 type I (HTLV-I), is required for high-level viral transcription and is strongly linked to HTLV-I-ass
86 ition in this patient cohort correlated with viral transcription and patient HBV early antigen (HBeAg
88 factor (HBZ), which inhibits Tax-1-mediated viral transcription and promotes cell proliferation, a h
91 specific DNA binding protein that regulates viral transcription and replication and is responsible f
93 hypothesize that the resulting inhibition of viral transcription and replication in basal epithelial
94 nd S to D also resulted in reduction of both viral transcription and replication in full-length infec
95 ious nuclear receptors capable of supporting viral transcription and replication in the adult in vivo
97 is of an unphosphorylated N and reduction of viral transcription and replication in the minigenome.
99 virus gene probes revealed that the rates of viral transcription and replication were reduced by as m
100 ional protein: it plays an essential role in viral transcription and replication, and in addition, RA
101 n proteases (M(pro)s) play a pivotal role in viral transcription and replication, making them an idea
102 a critical role of VP30 phosphorylation for viral transcription and replication, suggesting a mechan
103 vRNPs must be imported into the nucleus for viral transcription and replication, which requires part
118 omplex (SEC) that is essential for efficient viral transcription and represents a focal point for ant
119 on response element (TAR) RNA transactivates viral transcription and represents a paradigm for the wi
121 NA (cccDNA), the genomic form that templates viral transcription and sustains viral persistence.
122 omain of the polymerase that is essential to viral transcription and that shares sequence homology wi
123 n our screen reveals that CCDC92 can inhibit viral transcription and the formation of complete virion
124 E2 regulatory protein has essential roles in viral transcription and the initiation of viral DNA repl
125 ycin prevented SG formation, suggesting that viral transcription and translation are not required for
126 iple stages of the HCV lifecycle, inhibiting viral transcription and translation leading to a degrada
127 all molecules derived from the cellular and viral transcription and translation machinery results in
128 ession and to prolong the G1 phase, allowing viral transcription and translation to proceed at the ea
129 TLR3 stimulation had disparate effects on viral transcription and viral replication, because poly(
132 on, and overexpression of ITK increased both viral transcription and virus-like particle formation.
133 nent of virosomes and has been implicated in viral transcription and, as a substrate of the B1 kinase
134 tion 389 to alanine resulted in reduction of viral transcription and/or replication of a rabies virus
135 CCA could provide sufficient specificity for viral transcription, and consequently amplification, in
136 specifically synergizes with RTA to activate viral transcription, and overexpression of MGC2663 in th
137 temperature-sensitive polymerase to shut off viral transcription, and we demonstrate that SINV RNAs a
138 l where origin-dependent DNA replication and viral transcription are coupled by the binding of Sp1 an
139 profilin, expressed in bacteria, stimulated viral transcription as effectively as the native protein
140 l replication, IFI16 was also able to reduce viral transcription, as demonstrated by viral-gene expre
141 implicated as a critical control element for viral transcription, as well as viral DNA replication an
142 tu hybridization of lungs revealed increased viral transcription associated with areas of inflammatio
145 ies confers protection in vivo by inhibiting viral transcription at the start of the intracellular ph
146 e absence of RTF2 leads not only to enhanced viral transcription but also to reduced expression of an
148 ndividuals, both HDACi significantly induced viral transcription, but not splicing nor supernatant HI
149 rus (HIV) Tat protein has a critical role in viral transcription, but this study focuses on its addit
150 ncodes Tat, a small protein that facilitates viral transcription by binding an RNA structure (trans-a
151 host and early viral transcription to middle viral transcription by binding to the sigma(70) subunit
152 host and early viral transcription to middle viral transcription by binding to the sigma(70) subunit
153 ential protein involved in the initiation of viral transcription by cleaving capped mRNA bound to PB2
154 We have uncovered a mechanism for effective viral transcription by focal assembly of RNA polymerase
155 These results suggest that activation of viral transcription by ICP0 and transcriptional activati
158 ication in the infected cell at the level of viral transcription by interrupting the ability of Tat o
162 ication of strain NL4.3; a partial rescue of viral transcription could be seen following the transfec
164 is characterized by reversible silencing of viral transcription driven by the long terminal repeat (
166 virus genomes at specific sites and regulate viral transcription during latent and lytic cycles of re
167 To better understand the temporal pattern of viral transcription during Xp10 development, we performe
170 This protein was previously shown to be a viral transcription elongation factor, and the present f
172 (HBZ), a protein that inhibits Tax-mediated viral transcription, enhances T-cell proliferation, and
174 oplasm, IRF-1 can no longer serve as an anti-viral transcription factor but, instead, colocalizes wit
175 c region leucine zipper (bZIP) domain of the viral transcription factor BZLF1, which is encoded by th
176 lomavirus type 1 DNA absolutely requires the viral transcription factor E2 as well as the initiator E
178 irus type-1, DNA replication begins when the viral transcription factor E2 recruits the viral initiat
179 e in B cells by enhancing the ability of the viral transcription factor EBNA2 to activate methylated
181 fore in common with its eukaryotic host, the viral transcription factor ICP4 utilizes disordered regi
182 eplication and transcription activator (RTA) viral transcription factor is required for the induction
185 plex virus infection is initiated by VP16, a viral transcription factor that activates the viral imme
186 e we provide the first example of an archaeo-viral transcription factor that directly targets the hos
187 osi sarcoma-associated herpesvirus vIRF is a viral transcription factor that inhibits interferon sign
190 y into the lytic cycle is coordinated by the viral transcription factor, Zta (BZLF1, ZEBRA, and EB1),
193 ng for manipulation of critical cellular and viral transcription factors in such a way as to maximize
194 t for specific cdk-activated cellular and/or viral transcription factors or a more global requirement
196 r elements are targeted by TBP that recruits viral transcription factors to assemble a functional com
199 loped macroarrays to determine the extent of viral transcription from all 70 predicted SVV open readi
200 ulation of c-Fos promotes the progression of viral transcription from early to late stages and accele
201 ay, the altered motifs that led to increased viral transcription from the intact genome also greatly
202 he importance of ERK-RSK activation for KSHV viral transcription has been shown; however, which trans
203 use of its uncommon property and key role in viral transcription, HBx represents an attractive target
204 t HCF1 and OCT2 function at OriP to regulate viral transcription, histone modifications, and episome
207 As and uses the capped RNA fragment to prime viral transcription in a mechanism called 'cap snatching
208 nosis in childhood ALL, demonstrating active viral transcription in leukemia blasts as well as intact
209 tant proteins except hCycT1(C261Y) activated viral transcription in murine cells, no other cysteine o
211 receptors are more critical determinants of viral transcription in the HBV transgenic mouse model of
212 n inhibitors (BETi) are reported to activate viral transcription in vitro in HIV-1 latency cell lines
214 nhancing serum protein (HESP), might promote viral transcription in vivo and consequently play a role
218 viral genomic RNA plays an important role in viral transcription initiation and packaging of the vira
219 esults provide insight into the mechanism of viral transcription initiation and reveal the diversity
221 ata suggest that PRC2-mediated repression of viral transcription is a key step in the establishment a
222 ors and the HIV-1 Tat protein to ensure that viral transcription is induced strongly in activated T c
224 PPP sites.IMPORTANCE These data suggest that viral transcription is regulated not only by Pol II recr
225 immunity against viral replication in which viral transcription is repressed via the recruitment of
227 ly that the sole role of the Tat/TAR axis in viral transcription is to permit the recruitment of CycT
228 V-1 Tat, in addition to its critical role in viral transcription, is secreted from infected cells and
230 suggest that TAK1 inhibits HBV primarily at viral transcription level through activation of MAPK-JNK
231 gated the role of HCF-1 in both cellular and viral transcription, little is known about other process
232 rticular phosphoprotein (P) component of the viral transcription machinery, preventing the synthesis
234 onset of viral genome replication, but that viral transcription occurs prior to inclusion body forma
235 y of reovirus virions to form ISVPs, but not viral transcription or subsequent steps in viral replica
237 t HEV replication, possibly by inhibition of viral transcription or/and translation without a signifi
239 broad capabilities of affecting cellular and viral transcription patterns in this highly relevant cel
240 We have now characterized highly aberrant viral transcription patterns that developed in some stoc
243 failure to establish a characteristic latent viral transcription profile in sensory ganglia, where we
245 suggests imperfect epigenetic maintenance of viral transcription programs, perhaps due to variability
246 UV/psoralen (Ps)-inactivated virus to block viral transcription, Ps-inactivated virus stimulated pri
250 e bovine papillomavirus E2 proteins regulate viral transcription, replication, and episomal genome ma
251 that regulate their properties and roles in viral transcription, replication, and genome maintenance
252 ts RNF8 for degradation and thereby promotes viral transcription, replication, and progeny production
253 lated type I IFN production independently of viral transcription, replication, and TLR signaling.
256 ISGs interfere with virus entry, six affect viral transcription/replication, and two inhibit virion
258 3 inhibitory function of VP35 do not disrupt viral transcription/replication, suggesting that the two
261 LC3) as well as by overexpression of Bcl-2, viral transcription, sigmaC protein synthesis, and virus
263 annot interact fail to relocalize RNAP II to viral transcription sites, suggesting a role for ICP27 i
266 on with Aly/REF failed to recruit Aly/REF to viral transcription sites; however, ICP27 export to the
267 iply spliced viral mRNA (a measure of active viral transcription) stabilized and remained greater tha
268 on by TNF blocks nuclear accumulation of the viral transcription template, maintenance of which is es
269 es simplex virus 1 (HSV-1) is a regulator of viral transcription that is required for productive infe
271 al replication, stimulating cell cycling and viral transcription through interactions with critical c
272 HV lytic replication, consequently promoting viral transcription through the direct binding of c-Fos
274 rchestrates a switch from the host and early viral transcription to middle viral transcription by bin
275 rchestrates a switch from the host and early viral transcription to middle viral transcription by bin
277 uctures, termed virus factories (VFs), where viral transcription, translation, and replication occur.
278 fe cycle leading to efficient nuclear entry, viral transcription, translation, and ultimately replica
279 ms viral factories (VFs), which are sites of viral transcription, translation, assembly, and replicat
280 y adenoviruses, we investigated whether this viral transcription unit is also necessary for Ad9 to ge
281 REB) bound to the HTLV-1 promoter facilitate viral transcription via the recruitment of the large cel
282 nd its knockdown results in the reduction of viral transcription, viral genome copy number and virus
284 de treatment of infected cells revealed that viral transcription was also reduced when the N was not
285 Finally, the ability of Vpr to upregulate viral transcription was dependent on a minimal promoter
290 whether the E2F1/DP1 complexes were used for viral transcription, we scanned the viral genome for gen
291 nvestigate the role of methyltransferases in viral transcription, we utilized adenosine-2,3-dialdehyd
292 acts as a feedback inhibitor down-regulating viral transcription when adequate levels of plus-strand
293 tion factor b (P-TEFb) complex, can activate viral transcription when tethered to the heterologous Re
294 Mutations in the PCE completely inhibited viral transcription whereas overexpression of PBX1 and a
295 ing of the host transcriptional apparatus to viral transcription, which begins within 5 to 10 min p.i
296 appaB transcription to levels sufficient for viral transcription while limiting cellular responses to
298 e show that phosphorylation of VP30 inhibits viral transcription while viral replication is increased
299 ent of ATFx to the HTLV-1 LTR serves to link viral transcription with critical events in cellular hom