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1 human viruses, bovine viruses, protozoa, and pathogenic bacteria).
2 secretion system found in environmental and pathogenic bacteria.
3 in of diverse prokaryotic species, including pathogenic bacteria.
4 rapies can suppress villus injury induced by pathogenic bacteria.
5 romised by the evolution of resistance among pathogenic bacteria.
6 opment of tools against infections caused by pathogenic bacteria.
7 ynthesis of beta-Kdo-containing glycans from pathogenic bacteria.
8 system and can protect the host from various pathogenic bacteria.
9 rms a lethal pore on the cellular surface of pathogenic bacteria.
10 r that uncovers the corresponding epitope in pathogenic bacteria.
11 ally inducing antibiotic hypersensitivity in pathogenic bacteria.
12 enium compounds as urease inhibitors against pathogenic bacteria.
13 oxide, thus contributing to the virulence of pathogenic bacteria.
14 bolism and is crucial for virulence for some pathogenic bacteria.
15 pression is a common feature of host-adapted pathogenic bacteria.
16 at displays antivirulence phenotypes against pathogenic bacteria.
17 biosynthesis of essential terpenoids in most pathogenic bacteria.
18 with similar odds ratios for all viruses and pathogenic bacteria.
19 e, which is shown to facilitate avoidance of pathogenic bacteria.
20 te and adaptive immune response against this pathogenic bacteria.
21 plant pathogen, a feature shared with human pathogenic bacteria.
22 dically acquired infections caused by common pathogenic bacteria.
23 s and E3-ligase-mimicking effectors in plant pathogenic bacteria.
24 is also required for autophagic clearance of pathogenic bacteria.
25 re also critical for urinary defense against pathogenic bacteria.
26 of novel drugs against multi-drug resistant pathogenic bacteria.
27 gellum is a major virulence factor of motile pathogenic bacteria.
28 not in culture supernatants of several other pathogenic bacteria.
29 and selectivity to E. coli compared to other pathogenic bacteria.
30 iotics due to the increase in drug-resistant pathogenic bacteria.
31 Blood culture growing pathogenic bacteria.
32 une system provides critical defense against pathogenic bacteria.
33 s, and 496 (58%) had at least one species of pathogenic bacteria.
34 ic determinants of thermoregulation in plant-pathogenic bacteria.
35 roles in immunity and neuronal responses to pathogenic bacteria.
36 of the antibody coated surfaces against the pathogenic bacteria.
37 ive level that impaired the control of these pathogenic bacteria.
38 e rapidly increasing of multi-drug-resistant pathogenic bacteria.
39 other shipworm symbiont strains and various pathogenic bacteria.
40 implicated in the survival and virulence of pathogenic bacteria.
41 act as important virulence factors for many pathogenic bacteria.
42 road-spectrum molecular diagnostic assay for pathogenic bacteria.
43 ivating plant defense against hemibiotrophic pathogenic bacteria.
44 ound in Vibrio cholerae and other marine and pathogenic bacteria.
45 y molecules targeting AI-2 quorum sensing in pathogenic bacteria.
46 nomaterials for the detection and sensing of pathogenic bacteria.
47 uced by GI leakage and the administration of pathogenic bacteria.
48 for investigating its role in LCFA-utilizing pathogenic bacteria.
49 GM, reduced probiotic bacteria, and enriched pathogenic bacteria.
50 ced with graphene for sensitive detection of pathogenic bacteria.
51 more widespread than anticipated, notably in pathogenic bacteria.
52 of interest as biosensors, particularly for pathogenic bacteria.
53 sted with chicken meat spiked with the three pathogenic bacteria.
54 odulate multidrug efflux pathways in several pathogenic bacteria.
55 osts interface intimately with commensal and pathogenic bacteria.
56 terials potentially capable of targeting any pathogenic bacteria.
57 general metabolism and cellular defenses of pathogenic bacteria.
58 of these sensing architectures for detecting pathogenic bacteria.
59 all sugars are conserved across a variety of pathogenic bacteria.
60 ical for the virulence of many Gram-negative pathogenic bacteria.
61 proven useful against a number of different pathogenic bacteria.
62 is not well understood, particularly in non-pathogenic bacteria.
63 xins that includes many representatives from pathogenic bacteria.
64 confer resistance to or promote infection by pathogenic bacteria.
67 between 25(OH)D and more than one species of pathogenic bacteria (adjusted OR for adequate compared t
68 hat serve to protect C. elegans from various pathogenic bacteria also play a role in combating S. mal
73 egatively regulates plant innate immunity to pathogenic bacteria and can associate with RBOHD before
74 s, and it follows that communication between pathogenic bacteria and commensal bacteria is a subject
77 ant virulence factors on the surface of many pathogenic bacteria and have been implicated in a wide r
79 he type IV secretion systems present in many pathogenic bacteria and is absolutely necessary for the
82 otects multicellular organisms from invading pathogenic bacteria and microbial infections, but can al
83 increasing the rate of biofilm formation in pathogenic bacteria and mitigating amyloid toxicity in d
84 potent activity against a broad spectrum of pathogenic bacteria and negligible toxicity to mammals.
85 proteins and nucleic acids from a variety of pathogenic bacteria and operates in a continuous and ult
87 with RA was found, importance of periodontal pathogenic bacteria and rheumatoid parameters in the int
88 roviding a physical barrier against entry of pathogenic bacteria and secreting antimicrobial peptides
89 and lactic acid, the decrease of potentially pathogenic bacteria and the increase of bifidobacteria,
90 of the heme-sensing and transport systems of pathogenic bacteria and the potential of these systems a
92 ilor the intestinal inflammatory response to pathogenic bacteria and to pathobionts that are only occ
93 ere prospectively examined for common airway pathogenic bacteria and viruses during acute wheezy epis
95 ptomatic neonates, also after adjustment for pathogenic bacteria and viruses, indicating that sibling
98 D superfamily confer multidrug resistance to pathogenic bacteria, and are essential for cholesterol m
100 e determinant production are often linked in pathogenic bacteria, and several regulatory elements hav
101 cs that may lead to multi-drug resistance in pathogenic bacteria, aptamer-based technologies potentia
103 odulatory surface molecules of commensal and pathogenic bacteria are critical to microorganisms' surv
111 tric oxide reductases (FNORs), found in many pathogenic bacteria, are able to detoxify NO by reducing
113 proteins highlighted gene transfers from non-pathogenic bacteria as a key factor in the evolution of
114 we used outer membrane vesicles (OMVs) from pathogenic bacteria as a physiological mechanism to deli
118 at our device may be useful for detection of pathogenic bacteria at clinically relevant concentration
119 e is a body of literature on the survival of pathogenic bacteria at different environmental condition
121 e hydroxamate siderophores employed by human pathogenic bacteria belonging to the genus Burkholderia.
122 e with GI leakage plus the administration of pathogenic bacteria but not with GI leakage induction al
123 ector cells of the innate immune response to pathogenic bacteria, but excessive neutrophilic inflamma
124 of proteins that act as virulence factors of pathogenic bacteria, but similar proteins are found in a
126 work provides a generic biosensor for other pathogenic bacteria by enabling multivalent binding, imm
127 enic nanotoxoids for use as vaccines against pathogenic bacteria by leveraging the natural affinity o
128 ted with the detection and identification of pathogenic bacteria, by providing an introduction to the
129 recent increase in antibiotic resistance in pathogenic bacteria calls for new approaches to drug-tar
130 Candida species and Aspergillus species) and pathogenic bacteria can be particularly significant in t
131 icrobiome has established that commensal and pathogenic bacteria can influence obesity, cancer, and a
135 propose that an abnormal immune response to pathogenic bacteria colonizing the airways in early life
136 In other Gram-positive and Gram-negative pathogenic bacteria, conserved high-temperature requirem
142 ell growth retardation could be observed for pathogenic bacteria (e.g., Staphylococcus aureus and Pse
145 we report that autolysins from Gram-positive pathogenic bacteria, enzymes capable of hydrolyzing pept
148 no visible cross-reaction with other common pathogenic bacteria, even at concentrations as high as 1
151 Genetically modified Lactococcus lactis, non-pathogenic bacteria expressing the FNIII(7-10) fibronect
152 ectins play important roles in infections by pathogenic bacteria, for example, in host colonization,
154 inhibits the transport of both commensal and pathogenic bacteria from the lumen to a key immune induc
156 NA amplification reaction (LAMP) targeting a pathogenic bacteria gene, showing benefits of the new st
157 trains of Zika and Dengue virus, distinguish pathogenic bacteria, genotype human DNA, and identify mu
158 used to target a range of difficult-to-treat pathogenic bacteria, given that cell wall hydrolases are
160 sistance to multiple antimicrobial agents by pathogenic bacteria has become a significant global publ
162 he rise of antimicrobial resistance in human pathogenic bacteria has increased the necessity for the
165 t two decades, chemical antagonists of QS in pathogenic bacteria have attracted substantial interest
166 n system effector (T3Es) proteins from plant pathogenic bacteria have been shown to suppress this lay
169 e(3+)) via siderophore receptor systems, and pathogenic bacteria have further lowered this barrier by
171 Antibiotic resistance genes (ARGs), human pathogenic bacteria (HPB), and HPB carrying ARGs pose a
172 onjugative elements (ICE) from commensal and pathogenic bacteria identified a conserved DsbC/DsbG hom
173 In unadjusted analyses, all viruses and pathogenic bacteria identified during episodes of troubl
176 ed for rapid methods to detect and determine pathogenic bacteria in food products as alternatives to
181 Effective and sensitive monitoring of human pathogenic bacteria in municipal wastewater treatment is
182 that can evaluate antibiotic resistance for pathogenic bacteria in order to deliver targeted antibio
183 he ability to quickly detect the presence of pathogenic bacteria in patient samples is of the outmost
185 r and widely implemented technique to detect pathogenic bacteria in routine analysis but a typical EL
188 to consider that antibiotics not only target pathogenic bacteria in the gut, but also can have damagi
190 target genes and improved host resistance to pathogenic bacteria in the short term, chronic inactivat
193 ellular processes, inhibiting growth of many pathogenic bacteria, including the major respiratory pat
194 per and zinc, altered gut microbiota to more pathogenic bacteria, increased inflammatory markers, and
195 d detections of human and bovine viruses and pathogenic bacteria indicating influence of multiple con
199 ranscription factors, predominantly found in pathogenic bacteria interact with the DNA via a relative
203 emergence of antibiotic-resistant strains of pathogenic bacteria is an increasing threat to global he
205 n of human dendritic cells (DCs) with a live pathogenic bacteria is associated with rapid and active
206 uding aminoglycosides, against intracellular pathogenic bacteria is compromised due to their inabilit
209 e conserved in other bacteria, including the pathogenic bacteria lacking the assembly factor CcoH as
210 e infected EEC aggregates with commensal and pathogenic bacteria: Lactobacillus crispatus, Gardnerell
212 hors show that in Drosophila, infection with pathogenic bacteria leads to increased pheromone release
215 ence of rapid evolution of resistance within pathogenic bacteria, made worse by widespread misuse of
223 e increasingly aware that, during infection, pathogenic bacteria often grow in multicellular biofilms
226 irst evaluation of the alterations caused by pathogenic bacteria on symbiotic microbiota using C. ele
227 el antibiotics that disrupt the signaling of pathogenic bacteria or it could help to guide the treatm
229 evention of contamination from and growth of pathogenic bacteria, particularly S. typhimurium, during
230 and investigated their response against two pathogenic bacteria (Photorhabdus luminescens and Entero
232 epithelium from noxious agents, viruses, and pathogenic bacteria present in the gastrointestinal trac
236 al elicitor beta-amino butyric acid, the non-pathogenic bacteria Pseudomonas fluorescens, or by the p
237 of genes encoding exDNase activity in plant-pathogenic bacteria (Ralstonia solanacearum) and fungi (
240 all "the macrophage paradox:" why do so many pathogenic bacteria replicate in the very cells equipped
241 Staphylococcus aureus is one of the common pathogenic bacteria responsible for bacterial infectious
243 ow that exposing newly hatched C. elegans to pathogenic bacteria results in persistent aversion to th
244 uation of these compounds against a panel of pathogenic bacteria revealed that the majority of these
245 -of-concept, the assay was applied to detect pathogenic bacteria Salmonella spp. and to identify bovi
247 -inositol phosphatases (PTPLPs) from the non-pathogenic bacteria Selenomonas ruminantium (PhyAsr) and
248 with the increasing antibiotic resistance of pathogenic bacteria, severe infections are reported more
249 have served as powerful therapeutics against pathogenic bacteria since the golden age of antibiotics
254 The isoforms are differentially regulated by pathogenic bacteria, such as Salmonella species and adhe
255 haem biosynthesis within many Gram positive pathogenic bacteria suggests that this route has the pot
256 od was able to clearly distinguish among the pathogenic bacteria tested within 50 min, with detection
258 ould play a key role in combating strains of pathogenic bacteria that are resistant to existing antib
262 nthomonas genus includes Gram-negative plant-pathogenic bacteria that collectively infect a broad ran
263 ng genotoxins produced by many Gram-negative pathogenic bacteria that disrupt the normal progression
264 cal for the expression of virulence genes in pathogenic bacteria that infect warm-blooded hosts.
265 he secretion systems from the perspective of pathogenic bacteria that proliferate within plant tissue
268 driving horizontal gene transfer (HGT) among pathogenic bacteria, the underlying molecular mechanisms
269 T domains of several genera of gram-positive pathogenic bacteria, these results suggest that specific
270 Given the prevalence of this protein fold in pathogenic bacteria, this work also lays the foundation
271 on the carriage of antibiotic resistance in pathogenic bacteria to a broader concept of an oral resi
272 gen interactions and are required by certain pathogenic bacteria to establish a successful infection.
273 ion system is a widespread apparatus used by pathogenic bacteria to inject effectors directly into th
274 decay, RppH is important for the ability of pathogenic bacteria to invade host cells, yet little is
275 hanism used by both antibiotic-producing and pathogenic bacteria to resist the effects of antibiotics
278 t control is responsible for the survival of pathogenic bacteria under stress conditions, and contrib
279 ial cells to withstand infection when facing pathogenic bacteria under the intact or wounded conditio
282 ave specific implications for the control of pathogenic bacteria using antibiotics and for understand
283 ions, and decreased the virulence factors of pathogenic bacteria (VF 0073-ClpE, VF0124-LPS, and VF035
287 r (SAM) of mercaptohexadecanoic acid and the pathogenic bacteria were detected by electrochemical imp
291 oglycans (GAGs) are typical targets for some pathogenic bacteria, which allow adherence to host cells
292 t accumulation in YW flies infected with the pathogenic bacteria, which suggests a possible decline i
293 opment of these tools for the mutagenesis of pathogenic bacteria will permit forward genetic analysis
294 actions between the microbiota, the host and pathogenic bacteria will produce strategies for manipula
295 a new sepsis model of oral administration of pathogenic bacteria with GI leakage induced by either an
296 a gallotannins have the potential to inhibit pathogenic bacteria with potential application in foods
297 hr- and Tyr-specific phosphatases present in pathogenic bacteria, with an emphasis on the regulation
298 conjugate effectively cleared intracellular pathogenic bacteria within macrophages more potently tha
299 of effective anti-viral therapies, targeting pathogenic bacteria within the NP microbiome could repre
300 cule ligands targeted to the surface of live pathogenic bacteria would enable an entirely new class o
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