ライフサイエンスコーパス: phosphopeptide

1 Recovery is 90% for a pure phosphopeptide.

2 (D) of 0.35 nm in 1:1 binding to its cognate phosphopeptide.

3 er been used for the selective enrichment of phosphopeptides.

4 dues, interfering with the identification of phosphopeptides.

5 R, and EDX and employed in the enrichment of phosphopeptides.

6 r abilities to enrich for different types of phosphopeptides.

7 ave selective affinity and can interact with phosphopeptides.

8 percentage of longer, basic, and hydrophilic phosphopeptides.

9 mined 14-3-3-binding motifs from non-binding phosphopeptides.

10 ble quantitation across tens of thousands of phosphopeptides.

11 simultaneous enrichment of glycopeptides and phosphopeptides.

12 ysate, representing a more natural source of phosphopeptides.

13 omatography for the sequential enrichment of phosphopeptides.

14 cles to create membranes that rapidly enrich phosphopeptides.

15 uced efficiency, indicating a preference for phosphopeptides.

16 ation and enrichment of different classes of phosphopeptides.

17 tion-specific amino acid patterns in sets of phosphopeptides.

18 ation allows the selective identification of phosphopeptides.

19 ylation at 258 phosphosites, from 219 unique phosphopeptides.

20 lic QPSSSR peptide library as well as common phosphopeptides.

21 e CZE-MS/MS-based platform identified 11,555 phosphopeptides.

22 ntensity from low concentrations of enriched phosphopeptides.

23 hment provided more than 90% selectivity for phosphopeptides.

24 monoliths with surface layers selective for phosphopeptides.

25 ocols yielded comparable numbers of distinct phosphopeptides, 1693 and 1842, respectively, from micro

26 We provide temporal profiles of 4797 phosphopeptides, 608 of which showed significant regulat

27 he phosphoproteomic results of increased T31 phosphopeptide abundance with decreased MKK2 abundance i

28 Phosphopeptide abundances of five phosphoproteins involv

29 as also demonstrated on the basic and acidic phosphopeptides: acidophilic phosphorylation sites were

30 echniques that reproducibly measure the same phosphopeptides across multiple replicates, conditions,

31 ntibody fragment (Fab30) that recognizes the phosphopeptide-activated state of beta-arrestin-1.

32 ptide, and the interaction with the tyrosine phosphopeptide affects the pyruvate kinase activity of P

33 explored comparative binding pattern of GLI3 phosphopeptides against betaTrCP1.

34 inase:substrate relationship analysis of the phosphopeptides also revealed ABL1 and SRC tyrosine kina

35 Here, we employ a library of synthetic phosphopeptide analogues of the GPCR rhodopsin C-terminu

36 Using genetic, biochemical, and quantitative phosphopeptide analyses, we found that the E3 ubiquitin

37 Mass spectrometry-based phosphopeptide analysis demonstrated that the relative r

38 (i) ratio distortion remained a problem for phosphopeptide analysis in multiplexed quantitative work

39 /RP-nanoUPLC to compare their performance in phosphopeptide analysis.

40 e the suitability of the TMTpro reagents for phosphopeptide analysis.

41 ical binding interface to recognize the Cdc7 phosphopeptide and a non-canonical interface to bind Dbf

42 To this end, we performed and compared phosphopeptide and phosphoprotein enrichment methodologi

43 enabled us to identify nearly 10,000 unique phosphopeptides and 1,500 unique N-glycopeptides.

44 tative phosphoproteomic dataset yielded 2250 phosphopeptides and 1314 localized phosphosites with exc

45 enriched considerably longer and more acidic phosphopeptides and consequently, we identified 327 phos

46 to global proteome, the workflow identified phosphopeptides and glycopeptides from the PTM enrichmen

47 ncrease the number of identified hydrophilic phosphopeptides and improve MS detection signals.

48 localizing sites of phosphorylation in both phosphopeptides and intact phosphoproteins.

49 Phosphopeptides and lysine-acetylated peptides were quan

50 an updated workflow to sequentially isolate phosphopeptides and N-glycopeptides, enabling multiple P

51 r studying weak bonds between metal ions and phosphopeptides and provided a direct means of thermodyn

52 ID fragmentation analysis between unmodified phosphopeptides and those modified online with FBDSA or

53 monstrated that PKM2 interacts with tyrosine phosphopeptide, and the interaction with the tyrosine ph

54 A total of 8202 unique phosphopeptides, and 4317 unique proteins were identifie

55 compensation voltage settings for unlabeled phosphopeptides, and demonstrate the advantages of FAIMS

56 ytes tested include steroids, phospholipids, phosphopeptides, and sialylated glycans.

57 esence of nano-TiO2 for selective binding of phosphopeptides, and the magnetic responsiveness of magn

58 signal intensities were enhanced for most pY-phosphopeptides (approximately 70%) when using the pY-MI

59 thodologies to enrich heterogeneous types of phosphopeptides are critical for comprehensive mapping o

60 present study, the fragmentation patterns of phosphopeptides are improved through ion/ion-mediated pe

61 Phosphopeptides are of interest in enzymes and phosphory

62 To demonstrate the potential of these phosphopeptides as asymmetric catalysts, enantioselectiv

63 phosphoproteomic study identified additional phosphopeptides as possible targets that show the involv

64 Several studies identified short phosphopeptides as tight BRCT binders.

65 a designed phospholipid-inspired amphiphilic phosphopeptide at 0.8 A resolution is presented.

66 absorption and high cleavage coverage of the phosphopeptides at much lower irradiation fluence than f

67 serum samples are used for the detection of phosphopeptides based biomarkers.

68 re-affinity relationship studies showed that phosphopeptides based on Tyr631 from IL-4Ralpha bind wit

69 A phosphopeptide-based proteomic screen identified ROCK (R

70 bitor of MKP5 using a p38alpha MAPK-derived, phosphopeptide-based small-molecule screen.

71 A phosphopeptide bearing the antagonistic motif (AVPI) to

72 7 phosphorylation sites from 13029 different phosphopeptides belonging to 3163 different phosphoprote

73 tivity to Src kinase while products (ADP and phosphopeptide) bind with positive cooperativity.

74 d of yellow and blue fluorescent proteins, a phosphopeptide binding domain, a MAPK substrate domain a

75 e R377A does not cause a significant loss of phosphopeptide binding, but rather a tandem substitution

76 bryonic DNA damage responses by means of its phosphopeptide-binding ability: activating Mnk in the nu

77 rupting effect on the structure of the N-SH2 phosphopeptide-binding cleft mediating the interaction o

78 ylates UBF1 at Ser-412, thereby generating a phosphopeptide-binding epitope that binds the ECT2 BRCT

79 Plant 14-3-3 proteins are phosphopeptide-binding proteins, belonging to a large fa

80 A triple mutation in the phosphopeptide-binding site of the forkhead-associated (

81 ures revealed that the monobodies occupy the phosphopeptide-binding sites of the SH2 domains and thus

82 In addition, we found that the ETS1 SRR phosphopeptide binds to distantly related PU.1 in vitro,

83 structures of inactive, preactivated p44 and phosphopeptide-bound arrestins and will guide our unders

84 Detection and characterization of phosphopeptides by infrared multiphoton dissociation two

85 re minimal differences between enrichment of phosphopeptides by TiO2 and Ti(4+)-IMAC when considering

86 Mapping of rat striatal DAT phosphopeptides by two-dimensional thin layer chromatogr

87 h throughput approach, based on high density phosphopeptide chips, to determine the in vitro substrat

88 thesis by determining the structure of a FHA:phosphopeptide complex, from which we design a constitut

89 Mass spectroscopy analysis of Gp78 phosphopeptides confirmed S538 as a major p38 MAPK phosp

90 We identified a total of 2,001 phosphopeptides containing 1,026 unambiguous phosphoryla

91 demonstrate that electrophoretic mobility of phosphopeptides containing one phosphoryl group can be p

92 derived for only a few 14-3-3 complexes with phosphopeptide-containing proteins and a variety of comp

93 Phosphoproteomic analysis revealed that 19 phosphopeptides corresponding to 12 proteins were differ

94 ptides, we extracted 849 uniquely identified phosphopeptides corresponding to 425 proteins and identi

95 n total, the SPS-MS3 method quantified 38247 phosphopeptides, corresponding to 11000 phosphorylation

96 In all, 6579 unique phosphopeptides, corresponding to 1701 unique phosphoryl

97 The phosphopeptide data set is at least 100% larger than tha

98 nt glycopeptides can be found in a published phosphopeptide data set.

99 ochemical properties of pY-MIP-TiO2-enriched phosphopeptides demonstrated that this protocol retrieve

100 rative evaluations of enrichment methods for phosphopeptides depend highly on the experimental protoc

101 s not directly contact pTyr(1087) of a bound phosphopeptide derived from p190RhoGAP; rather, it makes

102 was synergistic with activation by a soluble phosphopeptide derived from receptor tyrosine kinases.

103 Phosphopeptides derived from aberrantly phosphorylated p

104 these in vitro phosphorylated peptides with phosphopeptides derived from endogenous proteins isolate

105 this method to detect and quantify predicted phosphopeptides derived from T-bet.

106 is study, we evaluated two HLA-A2-restricted phosphopeptides derived from the insulin receptor substr

107 -metal ion complexes during LC which hampers phosphopeptide detection.

108 To date, hundreds of phosphopeptides displayed on melanoma, ovarian cancer, l

109 proteins, >300 protein kinases, and >15,000 phosphopeptides, enabled deep insight into signaling rec

110 14-3-3 isotypes gamma, theta, and zeta with phosphopeptides encompassing pS910, pS935, or pS1444 dem

111 thetic phosphopeptide reference data set and phosphopeptide-enriched samples.

112 d human blood serum, are used to explore its phosphopeptide enrichment ability from complex samples f

113 hieve precise quantitation, followed by TiO2 phosphopeptide enrichment and high resolution mass spect

114 The combination of TiO(2) phosphopeptide enrichment and MudPIT analysis revealed 8

115 ere determined by a strategic combination of phosphopeptide enrichment and nano-ultra-performance liq

116 In each phosphopeptide enrichment and purification process, only

117 Automated phosphopeptide enrichment demonstrates reproducible synt

118 As a result, automated phosphopeptide enrichment enables statistical analysis o

119 Phosphopeptide enrichment from complicated peptide mixtu

120 Phosphopeptide enrichment from digested peptide mixtures

121 Reproducible, comprehensive phosphopeptide enrichment is essential for studying phos

122 nd inactive states of kinases but performing phosphopeptide enrichment made it possible to measure th

123 rbents (Strata X-AW and Oasis WAX) and three phosphopeptide enrichment materials based on affinity ch

124 ffinity purification, mass spectrometry, and phosphopeptide enrichment of isotope-labeled peptides, w

125 Phosphopeptide enrichment onto the synthesized amine-fun

126 We provide a free downloadable automated phosphopeptide enrichment program to facilitate uniform

127 been identified using these highly selective phosphopeptide enrichment protocols in combination with

128 The combination of pY-MIP- and TiO2-based phosphopeptide enrichment provided more than 90% selecti

129 ere, we simplified the assay by removing the phosphopeptide enrichment step, increasing throughput wh

130 Here, we report a novel phosphopeptide enrichment strategy and its application t

131 Here, we report an unbiased phosphopeptide enrichment strategy based on strong anion

132 se unique properties render the pY-MIP-based phosphopeptide enrichment technique an attractive altern

133 Most of them combine different phosphopeptide enrichment techniques and require startin

134 e composite exhibits enhanced capability for phosphopeptide enrichment with sensitivity assessed to b

135 amino acids in cell culture, affinity-based phosphopeptide enrichment, and high-resolution mass spec

136 an inverse strategy based on TiO2 selective phosphopeptide enrichment, fractionation by strong catio

137 Furthermore, by integrating with phosphopeptide enrichment, the nanoFAC 2D RPLC platform

138 ication technology (MudPIT), without or with phosphopeptide enrichment, was applied to study the prot

139 d Ti-IMAC microspheres for uniform automated phosphopeptide enrichment.

140 re for visualization, and a biotin group for phosphopeptide enrichment.

141 the engineering of an affinity material for phosphopeptide enrichment.

142 The sol-gel network was then used for phosphopeptide enrichment.

143 was compatible with previous data on TiO(2) phosphopeptide enrichment.

144 provides immobilized metal ion affinity for phosphopeptides enrichment.

145 Robust phosphopeptide enrichments that are suitable for low inp

146 devised a strategy that enhances analysis of phosphopeptides, especially multiply phosphorylated pept

147 reacted with HPO4(2-), phosphoserine, and a phosphopeptide (FQpSEEQQQTEDELQDK, abbreviated "betacas"

148 tituted up to 8% of the pY-MIP-TiO2-enriched phosphopeptide fractions.

149 fragments and comigration of PKC-stimulated phosphopeptide fragments with NDAT Ser-7 phosphopeptide

150 t in base signal-to-noise for distinguishing phosphopeptide from unphosphorylated peptide.

151 broblast cell lysate a total of 1,944 unique phosphopeptides from 1,087 unique phosphoproteins were i

152 anoFAC 2D RPLC platform can identify ~20,000 phosphopeptides from 100 mug of MCF-7 cell lysate.

153 bserved in cancer, we quantified 7566 unique phosphopeptides from 3279 proteins.

154 methodology for the selective extraction of phosphopeptides from 40 muL of tryptic beta-casein diges

155 tem was applied for the enrichment of casein phosphopeptides from a simulated tryptic digest with bov

156 The nanoparticles enrich phosphopeptides from casein variants, nonfat milk, egg y

157 e protocols to enrich for subfemtomole-level phosphopeptides from cell line and human tissue samples

158 be developed to characterize HLA-associated phosphopeptides from clinical samples that are limited b

159 Capturing glycopeptides and phosphopeptides from complicated biological samples is i

160 gated for the enrichment and purification of phosphopeptides from digested protein mixture solutions.

161 affinity capture and identification of 3,908 phosphopeptides from fractionated whole-heart homogenate

162 lipovitellin from egg yolk and phospholipids/phosphopeptides from human serum.

163 iochemical WIP1 activity assays that utilize phosphopeptides from native WIP1 substrates.

164 We first reassess efficient sorting of phosphopeptides from nonphosphopeptides based on IR-abso

165 Several methods were employed for isolating phosphopeptides from proteolytically digested plasma mem

166 ses is carried out for the identification of phosphopeptides from serum digest and HeLa cell extract.

167 e rounds to enable the maximum extraction of phosphopeptides from the whole cell lysates.

168 This facilitates the separation of phosphopeptides from unmodified acidic peptides.

169 ty, the composite was employed for enriching phosphopeptides from yeast protein digests.

170 otypes comprising 14,165 proteins and 18,405 phosphopeptides (from 4,511 proteins), quantified across

171 These phosphopeptides had more serine phosphorylated residues

172 At a pH higher than 5, phosphopeptides have two negative charges per residue an

173 s as a central filtering rule for maximizing phosphopeptide identification and quantitation.

174 d LC-MS/MS were complementary in large-scale phosphopeptide identifications and produced different ph

175 From 8,075 unique phosphopeptides identified, we observe that aberrant act

176 confidence datasets, since information about phosphopeptide identity, site-localization, and quantita

177 However, water molecules interact with the phosphopeptide in the hydrophilic region of the lattice.

178 The system identifies >30,000 phosphopeptides in 12 h and protein-protein or protein-d

179 sphatase domain that confers specificity for phosphopeptides in a specific sequence context.

180 Cancer cells display novel phosphopeptides in association with MHC class I and II m

181 ed to the determination of glycopeptides and phosphopeptides in clinical specimens, cell lysates, and

182 a model for predicting the migration time of phosphopeptides in CZE.

183 al of ultra-low flow ESI for the analysis of phosphopeptides in liquid based separation techniques.

184 of phosphoangiotensin and recover 70% of the phosphopeptides in mixtures with a 15-fold excess of non

185 oproteomics to compare the global changes in phosphopeptides in WT and snrk2.2/2.3/2.6 triple mutant

186 Typical methods for enriching phosphopeptides include immobilized metal affinity chrom

187 Target motif analysis of the phosphopeptides increased in PKA-null cells indicates th

188 Whereas all functional phosphopeptides interact with a common phosphate binding

189 at, based on structurally characterized BRCT-phosphopeptide interactions, were presumed critical for

190 ner proteins usually bind via insertion of a phosphopeptide into an amphipathic groove of 14-3-3.

191 on or reactivation affected largely distinct phosphopeptides, introducing a concept of nonoverlapping

192 We conclude that chromatography of phosphopeptides is best performed at low pH in the ERLIC

193 An expanded library of 967 unique phosphopeptides is detected using significantly reduced

194 f-of-concept 10-plex experiment, we compared phosphopeptide levels from five murine brains to five li

195 We have applied FAIMS to the analysis of a phosphopeptide library comprising the sequences GPSGXVpS

196 yme binding and activity with a microarrayed phosphopeptide library printed on chips coated with eith

197 d mutagenesis of NEM1 and SPO7, coupled with phosphopeptide mapping and immunoblotting with a phospho

198 Phosphopeptide mapping by mass spectrometry indicates an

199 Phosphoamino acid analysis coupled with phosphopeptide mapping of the CKI-phosphorylated Pah1 in

200 Phosphoamino acid analysis and phosphopeptide mapping revealed that lipin 1beta is phos

201 ncation analysis, site-directed mutagenesis, phosphopeptide mapping, and phosphoamino acid analysis,

202 s, coupled with phosphorylation analysis and phosphopeptide mapping, to identify Ser-45 and Ser-46 of

203 ion analysis, site-directed mutagenesis, and phosphopeptide mapping, we identified Ser-677, Ser-769,

204 normal as assayed by in vitro kinase and MT phosphopeptide mapping.

205 ry identified 14,155 spectra of 3,371 unique phosphopeptides mapping to 1,159 proteins (false discove

206 ted phosphopeptide fragments with NDAT Ser-7 phosphopeptide markers.

207 The major components of the pipeline include phosphopeptide meta-analysis, correlation network analys

208 al challenge to analysis is the formation of phosphopeptide-metal ion complexes during LC which hampe

209 Phosphopeptides migrate significantly slower than corres

210 A cell permeant phosphopeptide mimetic of Niban (NiPp) was generated.

211 We are developing phosphopeptide mimetics targeting the SH2 domain of STAT

212 ryptic digest of bovine serum albumin, and a phosphopeptide mixture.

213 lculated Cscore from a large data set (>7000 phosphopeptide MS/MS spectra) was approximately 32 compa

214 ncy of EV isolation, protein extraction, and phosphopeptide/N-glycopeptide enrichment to achieve sens

215 e of pY-MIP for enrichment and sequencing of phosphopeptides obtained by tryptic digestion of protein

216 iron fortified goat and cow milks and casein phosphopeptides obtained from each species of milk was d

217 itors that disrupt the interaction between a phosphopeptide of SLAM (signaling lymphocytic activation

218 Quantitative phosphoproteomics identified phosphopeptides of increased abundance in hai1-2 in unst

219 Characteristic phosphopeptides of phosphoproteins are identified from h

220 identification of over 10,000 unique "basic" phosphopeptides of which many represent putative targets

221 ntially expressed proteins and 11 543 unique phosphopeptides, of which 80% are novel and 7% preferent

222 Polar analytes, including neurotransmitters, phosphopeptides, oligonucleotides, illicit drugs, and ph

223 We also cataloged 144 unique phosphopeptides on known OCT4 interacting partners, incl

224 affect activation of p85/p110beta dimers by phosphopeptides or Gbetagamma.

225 estigated the thermodynamic properties of 18 phosphopeptides or peptide with phosphate mimic and thre

226 r, methodological limitations (e.g. in MS of phosphopeptides, or antibodies against phosphoepitopes)

227 We identified distinct phosphopeptide patterns in metastatic tissues compared w

228 We started by comparing the phosphopeptide patterns of cells treated with WNT3A for

229 Phosphopeptides/phosphoproteins enrichment from biologic

230 Phosphopeptides play a crucial role in many biological p

231 a search engine that detects and quantifies phosphopeptide positional isomers from parallel reaction

232 strategies, we succeeded in quantifying 1371 phosphopeptides present in the CE-MS data set and found

233 enables the identification of HLA-associated phosphopeptides presented by human tissue samples contai

234 Selective enrichment of phosphopeptides prior to their analysis by mass spectrom

235 tor interaction between a glycopeptide and a phosphopeptide produces sPGPs that form nanoparticles, w

236 to which phosphate neutral loss occurs from phosphopeptide product ions due to the infrared photoact

237 IRMPD in the top-down analysis of peptides, phosphopeptides, proteins, phosphoproteins, ribonucleopr

238 r2 >/= 0.80) and high-fidelity (>90% purity) phosphopeptide purification in a 96-well format.

239 on interference, we assessed the accuracy of phosphopeptide quantitation across a variety of experime

240 otope-assisted mass spectrometric methods of phosphopeptide quantitation to characterize proteins in

241 ivity is directed to specific substrates via phosphopeptide recognition by its carboxyl-terminal polo

242 Forkhead-associated (FHA) domains are phosphopeptide recognition modules found in many signali

243 richment demonstrates reproducible synthetic phosphopeptide recovery across 2 orders of magnitude, "w

244 d SWATH-MS and benchmarked using a synthetic phosphopeptide reference data set and phosphopeptide-enr

245 ptides showed large sequence homology in the phosphopeptides released by tryptic hydrolysis and simul

246 Analysis of phosphopeptides requires enrichment, and even after the

247 0.1 fmol and 0.05 fmol for glycopeptides and phosphopeptides, respectively), and good reusability.

248 Specifically, the phosphopeptide self-assembles to form nanoparticles, whi

249 The comparison showed significantly improved phosphopeptide sensitivity in equal sample load and equa

250 indicate that the FHA domain is a consensus phosphopeptide sensor, and that the ligand for activatio

251 native because CZE and LC are orthogonal for phosphopeptide separation and because the migration time

252 e separation method that produces orthogonal phosphopeptide separation to the widely used LC needs to

253 A complex mixture of phosphopeptides showed similar coverage could be achieve

254 s in human CD8 T cells imparted high-avidity phosphopeptide-specific recognition and cytotoxic and cy

255 ed a peptide esterification step to increase phosphopeptide specificity from these low-input samples.

256 ow that AI-ETD can identify 24,503 localized phosphopeptide spectral matches enriched from mouse brai

257 ides from caseins, bovine serum albumin, and phosphopeptide standards.

258 o a well plate containing lysis buffer and a phosphopeptide substrate.

259 Two phosphopeptides, termed pIRS-21097-1105 and pCDC25b38-46

260 limited repeatability and linearity for most phosphopeptides tested, and different phosphopeptides we

261 involved the microinjection of a fluorescent phosphopeptide that is hydrolyzed specifically by PTPs.

262 t TiO2 enrichment does not fully recover the phosphopeptides that are not identified with the corresp

263 However, phosphopeptides that are unique to IMAC enrichment showe

264 The phosphopeptides that are unique to IMAC enrichment, uniq

265 Cortical phosphopeptides that distinguished female and male CRF-O

266 es demonstrated that this protocol retrieved phosphopeptides that tend to be smaller (<24 residues),

267 Notably, phosphopeptides that were more abundant in female CRF-OE

268 With 10 measurements recorded for each phosphopeptide, this equates to more than 628000 binary

269 sin-digested tumor samples were enriched for phosphopeptides through immobilized metal ion affinity c

270 ir activities are further enhanced by an RTK phosphopeptide to levels markedly exceeding that of acti

271 he intermediate oxazoline ring formed in the phosphopeptide to the metal-phosphate complex.

272 s present in the CE-MS data set and found 49 phosphopeptides to be differentially regulated in the tw

273 sphoproteomics requires better separation of phosphopeptides to boost the coverage of the phosphoprot

274 ficient protection against phosphate loss in phosphopeptides upon collision-induced dissociation tand

275 ratio of (18)O- versus (16)O-labeled tryptic phosphopeptide using high mass accuracy mass spectrometr

276 lls with the quantification of 11,266 unique phosphopeptides using multiplexed quantitative mass spec

277 with the vasopressin V2 receptor C-terminal phosphopeptide (V2Rpp).

278 The phosphopeptide was shown to self-assemble into semi-elli

279 A mixture of phosphopeptides was analyzed by 2DMS without any prior s

280 binding affinities of Ga(3+) and Fe(3+) for phosphopeptides, we designed a metal-directed immobilize

281 ized metal affinity chromatography to enrich phosphopeptides, we extracted 849 uniquely identified ph

282 Phosphopeptides were adsorbed onto the amine-functionali

283 whereas only 10% of 5069 monophosphorylated phosphopeptides were commonly enriched in both fractions

284 PAH and control cells, 170 proteins and 240 phosphopeptides were differentially expressed; of these,

285 de enrichment and purification process, only phosphopeptides were enriched and separated from the oth

286 r most phosphopeptides tested, and different phosphopeptides were found to have different linear rang

287 Several thousand phosphopeptides were identified after TiO2 enrichment, a

288 erties and resolution in MALDI-TOF-MS, these phosphopeptides were identified as suitable markers for

289 However, only about 60% as many phosphopeptides were identified with SAX at pH 6 than vi

290 In one ERLIC run, 12467 phosphopeptides were identified, including 4233 with mor

291 ally expressed; of these, 45 proteins and 18 phosphopeptides were located in the mitochondria.

292 In addition, up to 92% of the 6283 phosphopeptides were uniquely enriched in either the fir

293 quantitations and identifications even from phosphopeptides with a low number of spectral matches.

294 tially phosphorylated proteins (DP) from 350 phosphopeptides with a total of 399 phosphorylated sites

295 th IMAC and TiO2 enriched similar amounts of phosphopeptides with comparable enrichment efficiency.

296 he IMAC and TiO2 procedures clearly enriched phosphopeptides with different motifs.

297 ains challenging, especially for hydrophilic phosphopeptides with enriched regions of serines, threon

298 e present a straightforward method to enrich phosphopeptides with multiple basic residues, an under-r

299 ue allowed the identification of 2560 unique phosphopeptides with only 8% overlap.

300 identified and quantified over 13,000 unique phosphopeptides, with a large percentage dependent on Sy