1 ouble-strand DNA end-binding protein, Gam of
bacteriophage Mu.
2 e bound to a strong gyrase binding site from
bacteriophage Mu.
3 mechanism underlying target immunity by the
bacteriophage Mu.
4 , and in particular the MuA transposase from
bacteriophage Mu.
5 ed to a maximum of 2 kb and mutagenized with
bacteriophage Mud.
6 rt the complete 36,717 bp genome sequence of
bacteriophage Mu and provide an analysis of the sequence
7 cialized activities of genetic elements like
bacteriophage Mu and the F plasmid.
8 quence specificity of the invertase Gin from
bacteriophage Mu and Tn3 resolvase from Escherichia coli
9 classic transposase systems, such as Tn7 and
bacteriophage Mu,
and provides insights into IS21 transp
10 The
bacteriophage Mu C gene encodes a 16.5 kDa site-specific
11 Originally discovered in the
bacteriophage Mu DNA inversion system gin, Fis (Factor f
12 Initiation of
bacteriophage Mu DNA replication by transposition requir
13 richia coli plays two distinct functions for
bacteriophage Mu DNA replication by transposition.
14 at this primosome plays an essential role in
bacteriophage Mu DNA replication by transposition.
15 Bacteriophage Mu DNA synthesis is initiated during trans
16 Replication of
bacteriophage Mu DNA, a process requiring efficient syna
17 The repressor protein of
bacteriophage Mu establishes and maintains lysogeny by s
18 The immunity repressor (Rep) of
bacteriophage Mu establishes and maintains lysogeny by s
19 The repressor of
bacteriophage Mu functions in the establishment and main
20 is located midway between the termini of the
bacteriophage Mu genome and is required for efficient re
21 The
bacteriophage Mu genome contains a centrally located str
22 hia coli chromosome for the insertion of the
bacteriophage Mu genome.
23 The C-terminal domain (CTD) of
bacteriophage Mu immunity repressor (Rep) regulates DNA
24 Rapid degradation of the
bacteriophage Mu immunity repressor can be induced in tr
25 The
bacteriophage Mu immunity repressor is a conformationall
26 infected cells revealed enhanced regions of
bacteriophage Mu insertion near the ends of HIV-1 cDNA,
27 Lytic development of
bacteriophage Mu is controlled by a regulatory cascade a
28 ial for replicative DNA transposition by the
bacteriophage Mu,
is an ATPase that assembles into a pol
29 Transcription of the
bacteriophage Mu mom operon is strongly repressed by the
30 Transcription of the
bacteriophage Mu mom operon requires transactivation by
31 Gene expression during lytic development of
bacteriophage Mu occurs in three phases: early, middle,
32 Lytic development of
bacteriophage Mu proceeds through three phases of transc
33 Bacteriophage Mu replicates as a transposable element, e
34 Conversion of
bacteriophage Mu repressor to ClpXP-sensitive form corre
35 Middle transcription of
bacteriophage Mu requires Escherichia coli RNA polymeras
36 Middle transcription of
bacteriophage Mu requires Escherichia coli RNA polymeras
37 anscription from the middle promoter, Pm, of
bacteriophage Mu requires the phage-encoded activator pr
38 ons in an N-terminal 70-amino acid domain of
bacteriophage Mu'
s repressor cause temperature-sensitive
39 The transposition of
bacteriophage Mu serves as a model system for understand
40 The
bacteriophage Mu strong gyrase site (SGS) is required fo
41 The
bacteriophage Mu strong gyrase site (SGS), required for
42 Like enteric
bacteriophage Mu,
the BcepMu genomic DNA is flanked by v
43 he MuA transposase mediates transposition of
bacteriophage Mu through two distinct mechanisms.
44 amines the contribution of domain II beta of
bacteriophage Mu transposase (A protein), a subdomain of
45 During transposition
bacteriophage Mu transposase (MuA) catalyzes the transfe
46 ity to the better understood turnover of the
bacteriophage Mu transposase and functions of integrase
47 ntegrase, avian sarcoma virus integrase, and
bacteriophage Mu transposase.
48 To trigger
bacteriophage Mu transposition and replication in respon
49 helicase DnaB for replisome assembly during
bacteriophage Mu transposition and replication.
50 Studies of
bacteriophage Mu transposition paved the way for underst
51 Transposition of
bacteriophage Mu uses two DNA cleavage sites and six tra
52 Target specificity for
bacteriophage Mu was studied using a new phage derivativ