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1 inactivation by alpha1-proteinase inhibitor (alpha1-antitrypsin).
2 nation and proteasomal degradation of mutant alpha1-antitrypsin.
3 emphysema caused by mutations in the serpin alpha1-antitrypsin.
4 ned significant amounts of human albumin and alpha1-antitrypsin.
5 bsence of polarity, and reduced secretion of alpha1-antitrypsin.
6 iver disease associated with the Z allele of alpha1-antitrypsin.
7 albumin, transferrin, alpha-fetoprotein, and alpha1-antitrypsin.
8 used by reduced level or loss of function of alpha1-antitrypsin.
9 -14, and cathepsin B and increased levels of alpha1-antitrypsin.
10 of repopulating liver cells expressing human alpha1-antitrypsin.
11 hepsins-K, -L, and -S) and the inhibition of alpha1-antitrypsin.
12 two GVHD severity markers, calprotectin and alpha1-antitrypsin.
13 , and -S and the ability of IL-13 to inhibit alpha1-antitrypsin.
14 fter its fragmentation in cells expressing Z-alpha1-antitrypsin.
15 ut compromising the inhibitory activity of Z alpha1-antitrypsin.
16 a loss of anti-inflammatory signalling by M alpha1-antitrypsin.
17 , and this could be inhibited by addition of alpha1-antitrypsin.
18 it remains stable at approximately 3.5 A in alpha(1)-antitrypsin.
19 misfolded protein, null Hong Kong variant of alpha(1)-antitrypsin.
20 h region and in beta-strand 1C compared with alpha(1)-antitrypsin.
21 oserpin while no such movement is evident in alpha(1)-antitrypsin.
22 cognizes the pathological polymers formed by alpha(1)-antitrypsin.
23 d secretion when compared to the wild-type M alpha(1)-antitrypsin.
24 diate their effects on the shutter region of alpha(1)-antitrypsin.
25 cy of the key anti-elastase within the lung: alpha(1)-antitrypsin.
26 e immune response and is homologous to human alpha(1)-antitrypsin.
27 heet in heparin-complexed antithrombin or in alpha(1)-antitrypsin.
28 rences between the pathogenic Z and normal M alpha(1)-antitrypsin.
29 be partially inserted into beta-sheet A in Z alpha(1)-antitrypsin.
30 (FLEAIG) that selectively and stably bound Z alpha(1)-antitrypsin.
31 the major target of inhibition of the serpin alpha(1)-antitrypsin.
33 ction of a point mutation (Glu342Lys) in the alpha(1)-antitrypsin (A1AT, also known as SERPINA1) gene
34 bly, upon transplantation, human albumin and alpha1-antitrypsin (A1AT) in mouse sera secreted by enca
50 istration of the serine proteinase inhibitor alpha1-antitrypsin (AAT) prevents type 1 diabetes develo
52 uble/insoluble distribution of two misfolded alpha1-antitrypsin (AAT) variants responsible for AAT de
54 s were selected from the proteomic analysis, alpha1-antitrypsin (AAT), hemopexin (HX), and gelsolin (
55 g misfolded N-glycosylated variants of human alpha1-antitrypsin (AAT), Null Hong Kong (NHK), and Z (A
63 probe the mechanism of peptide modulation of alpha(1)-antitrypsin (alpha(1)-AT) polymerization and de
66 rrhosis and emphysema caused by mutations in alpha(1)-antitrypsin (alpha(1)AT), and thrombosis caused
70 ription of three HNF-4alpha sensitive genes, alpha1-antitrypsin (alpha1-AT), transthyretin (TTR), and
76 s control region (LCR) upstream of the human alpha1-antitrypsin (alpha1AT) gene that is required for
78 (Glu342Lys) in the serine protease inhibitor alpha1-antitrypsin (alpha1AT), which is found in more th
80 serpin family: protein C inhibitor (PCI) and alpha1-antitrypsin (alpha1AT); however, both exhibit poo
82 production could be recovered by addition of alpha1-antitrypsin, an endogenous inhibitor of serine pr
88 )-antitrypsin and antichymotrypsin, measured alpha(1)-antitrypsin and antichymotrypsin throughout lac
89 termined whether the mammary gland expresses alpha(1)-antitrypsin and antichymotrypsin, measured alph
91 We show here that monomers of plasma serpins alpha(1)-antitrypsin and antithrombin are stable on incu
92 he peptide prevented the polymerization of Z alpha(1)-antitrypsin and did not significantly anneal to
93 17Phe mutations stabilise the native fold of alpha(1)-antitrypsin and increase secretion of monomeric
95 rotein secretion and secretion of endogenous alpha(1)-antitrypsin and serum albumin from HepG2 cells.
97 diazole) was used to label peroxide-modified alpha1-antitrypsin and demonstrate that the Cys-232 in v
99 se had measurements of fecal lactoferrin and alpha1-antitrypsin and underwent pouch endoscopy with bi
100 correlate well with immunological levels of alpha1-antitrypsin and, thus, may prove useful for asses
101 f two serine protease inhibitors [Serpina1a (alpha1-antitrypsin) and Elafin] was dysregulated in Fbln
102 enteropathy (calprotectin, myeloperoxidase, alpha1-antitrypsin) and the prevalence of bacterial but
103 sponse genes such as SERPINA1, which encodes alpha1 antitrypsin, and FOXP4, an inhibitor of mucus pro
104 itors of metalloproteinase 2, -3, and -4 and alpha1-antitrypsin, and fibrosis was associated with inc
105 R1, TNFR2, Bid), optimal IL-13 inhibition of alpha1-antitrypsin, and IL-13-induction of and activatio
106 molecules, the solubility of mutant forms of alpha1-antitrypsin, and interactions with newly synthesi
107 oembryonic antigen, retinol binding protein, alpha1-antitrypsin, and squamous cell carcinoma antigen-
108 termined levels of carcinoembryonic antigen, alpha1-antitrypsin, and squamous cell carcinoma antigen.
111 tracellular serpins such as antithrombin and alpha1-antitrypsin are the quintessential regulators of
112 ave assessed a surface hydrophobic cavity in alpha1-antitrypsin as a potential target for rational dr
113 ts identifying cathepsin C, cathepsin Z, and alpha1-antitrypsin as additional potential cargoes for L
114 R spectroscopy to patient-derived samples of alpha(1)-antitrypsin at natural isotopic abundance to in
118 hial epithelial cells with purified plasma M alpha1-antitrypsin attenuates this inflammatory response
119 echanism due to accumulation of the mutant Z alpha1-antitrypsin (ATZ) and is a key example of an dise
121 nzymes retain vulnerability to inhibition by alpha(1)-antitrypsin, but demonstrate variable avidity f
123 mutation reduces concentrations in serum of alpha1 antitrypsin by retaining polymerised molecules wi
125 reduced the intracellular accumulation of Z alpha1-antitrypsin by 70% in a cell model of disease.
126 biomarkers, followed by IL-2 receptor alpha, alpha1-antitrypsin, C-reactive protein, YKL-40, cellular
127 inhibited by alpha(1)-proteinase inhibitor (alpha(1)-antitrypsin), C1 inhibitor, and most efficientl
129 ility of the GeneSwitch, we cloned the human alpha(1)-antitrypsin cDNA into the optimal lentiviral ve
130 f interleukin-6, interleukin-8, and elastase-alpha1-antitrypsin complexes compared with presurgery le
131 f interleukin-8, interleukin-6, and elastase-alpha1-antitrypsin complexes were elevated compared with
132 ls of interleukin-6, interleukin-8, elastase-alpha1-antitrypsin complexes, thrombin-antithrombin comp
133 Treatment with the serine protease inhibitor alpha1-antitrypsin decreased serum levels of HS, leading
136 result from mutations in the genes SERPINA1 (alpha(1)-antitrypsin deficiency), JAG1 (Alagille syndrom
138 as up-regulated in livers from patients with alpha(1)-antitrypsin deficiency, and the degree of up-re
140 distinct form of "ER stress" that occurs in alpha(1)-antitrypsin deficiency, presumably determined b
145 y centres in 13 countries if they had severe alpha1 antitrypsin deficiency (serum concentration <11 m
146 sensitive measure of disease progression in alpha1 antitrypsin deficiency emphysema than spirometry
147 inhibitor (A1PI) augmentation treatment for alpha1 antitrypsin deficiency has not been substantiated
148 mphysema progression in patients with severe alpha1 antitrypsin deficiency in a randomised controlled
156 verity and distribution in 119 subjects with alpha1-antitrypsin deficiency (PiZ phenotype) and groupe
159 ng of genetic and nongenetic modifiers in ZZ alpha1-antitrypsin deficiency and other disorders of pro
160 the end-stage liver disease associated with alpha1-antitrypsin deficiency and underscore the contrib
161 he most frequent mutation that causes severe alpha1-antitrypsin deficiency arises in the SERPINA 1 ge
163 ents with CF, primary ciliary dyskinesia, or alpha1-antitrypsin deficiency exhibited 3-fold higher mu
170 nically relevant PiZZ mutation, which causes alpha1-antitrypsin deficiency, and editing of phosphotyr
171 Less common causes include hemochromatosis, alpha1-antitrypsin deficiency, autoimmune hepatitis, and
172 ess of augmentation therapy (Aug) for severe alpha1-antitrypsin deficiency, comparing strategies of:
173 abolic conditions studied in further detail (alpha1-antitrypsin deficiency, familial hypercholesterol
184 ecognizes polymers formed by Z and His334Asp alpha(1)-antitrypsin despite the mutations directing the
185 ther hereditary iron overload disorders, and alpha1-antitrypsin disease-are the focus of this review.
186 se diseases are typified by the Z variant of alpha(1)-antitrypsin (E342K), which causes the retention
188 equence corresponding to residues 359-374 of alpha1-antitrypsin, enhances gene expression from DNA na
190 Replacing the RCL sequence with that from alpha1-antitrypsin fails to restore specificity against
192 are identical to the Z-deficiency variant of alpha(1)-antitrypsin form urea-stable polymers in vivo.
193 eatments for emphysema, infusion of purified alpha1 antitrypsin from pooled human plasma represents a
194 of an 8-kb DNA segment upstream of the human alpha1-antitrypsin gene yields a mutant serpin allele th
197 Donor hepatocytes were derived from human alpha(1)-antitrypsin (hAAT) transgenic mice of the FVB s
201 gents, monotherapy with clinical-grade human alpha1-antitrypsin (hAAT), the major serum serine-protea
202 eactive protein, alpha(1)-acid glycoprotein, alpha(1)-antitrypsin, haptoglobin, and fibrinogen concen
203 e fractional and absolute synthesis rates of alpha(1)-antitrypsin, haptoglobin, and fibrinogen were m
205 Both mutations increase the secretion of Z alpha(1)-antitrypsin in the native conformation, but the
206 educe the polymerisation of wild-type native alpha(1)-antitrypsin in vitro and increase secretion in
207 pidly inactivated by the human plasma serpin alpha(1)-antitrypsin in vitro, administration of recombi
208 This is best described for the Z variant of alpha(1)-antitrypsin in which the proinflammatory proper
209 denoassociated virus vector expressing human alpha1-antitrypsin in murine liver progenitor cells.
210 re derived, such as aggregation of misfolded alpha1-antitrypsin in the endoplasmic reticulum, deficie
211 e accumulation of the misfolded Z variant of alpha1-antitrypsin in the hepatocyte endoplasmic reticul
217 findings have indicated that a deficiency in alpha1-antitrypsin is associated with increased risk of
218 ellular portion of the pIgR, linked to human alpha1-antitrypsin is effectively ferried across human t
220 nd a novel shutter domain mutant (His334Asp; alpha(1)-antitrypsin King's) identified in a 6-week-old
221 disease, whereas low levels of circulating Z alpha1-antitrypsin lead to emphysema by loss of inhibiti
224 cal production of polymers by mutant S and Z alpha1-antitrypsin may have also provided protection aga
225 in addition to its antielastolytic effects, alpha1-antitrypsin may have broader biological effects i
226 n-originated cells expressing liver-specific alpha1-antitrypsin messenger RNA, albumin and hepatocyte
227 lt in a conformational transition within the alpha1-antitrypsin molecule and the formation of polymer
229 se protective, proinflammatory properties of alpha1-antitrypsin mutants have become detrimental to ca
231 ts were effective at ratios of compound to Z alpha1-antitrypsin of 2.5:1 and reduced the intracellula
232 helium protease is not highly susceptible to alpha1-antitrypsin or secretory leukocyte protease inhib
234 the generation of an mAb (4B12) that blocked alpha1-antitrypsin polymerization in vitro at a 1:1 mola
235 substrate decanoyl-RVKR-chloromethylketone, alpha1-antitrypsin Portland and by its own propeptide.
236 study, we show that inducible expression of alpha1-antitrypsin Portland, a furin inhibitor, inhibits
238 ific promoter (murine albumin enhancer/human alpha1-antitrypsin promoter) further enhanced transgene
240 lation of the TGF-beta signaling pathway and alpha1-antitrypsin protein (a serine protease inhibitor)
241 e disease, inefficient secretion of a mutant alpha1-antitrypsin protein (AAT-Z) results in its accumu
242 of these regions in neuroserpin relative to alpha(1)-antitrypsin provides a basis for neuroserpin's
244 ummary, this work provides new insights into alpha1-antitrypsin reactivity in oxidizing environments
248 ion of structural alveolar cell apoptosis by alpha1-antitrypsin represents a novel protective mechani
251 ssociated with HLA-DP and the genes encoding alpha(1)-antitrypsin (SERPINA1) and proteinase 3 (PRTN3)
252 -fold; apolipoprotein A-1 [APOA1], 3.2-fold; alpha1-antitrypsin [SERPINA1], 2.5-fold; and complement
253 s containing an immobile matrix of polymeric alpha1-antitrypsin, small ER resident proteins can diffu
254 Ab technology to identify interactors with Z alpha1-antitrypsin that comply with both requirements.
255 tify a peptide corresponding to a portion of alpha1-antitrypsin that potently inhibits entry of HIV-1
256 intrabody also increased the secretion of Z alpha1-antitrypsin that retained inhibitory activity aga
258 but did increase the levels of mRNA encoding alpha1-antitrypsin, tissue inhibitor of metalloproteinas
259 proteolysis, and determined the potential of alpha(1)-antitrypsin to affect the survival of other mil
260 ons predispose the serine protease inhibitor alpha(1)-antitrypsin to misfolding and polymerisation wi
262 ughout lactation, assessed the resistance of alpha(1)-antitrypsin to proteolysis, and determined the
263 a newly created fusion gene of exendin-4 and alpha1-antitrypsin to control obesity and obesity-associ
264 tissue and the high risk of patients lacking alpha1-antitrypsin to develop emphysema, much interest h
265 rved multiply charged states at m/z 72,160 ([alpha1-antitrypsin + trypsin + H](+)) and 86,585 ([IgG +
266 atrix for the detection of several proteins (alpha1-antitrypsin, trypsin, IgG, protein G) and their c
267 detection of weak protein complexes, such as alpha1-antitrypsin-trypsin and IgG-protein G complexes,
268 86,585 ([IgG + protein G + 2H](2+)) for the alpha1-antitrypsin-trypsin and IgG-protein G complexes,
269 otected by the exosomes from inactivation by alpha1 antitrypsin, ultimately causing the pathological
272 NTS, AND MAIN RESULTS: Transduction of human alpha1-antitrypsin via replication-deficient adeno-assoc
276 ggested that a significant fraction of their alpha(1)-antitrypsin was tied up in high molecular mass
278 errant form of the hepatic secretory protein alpha1-antitrypsin was stably expressed in a human embry
279 addition, transgene expression (serum human alpha1-antitrypsin) was sustained for the length of the
280 ch corresponds to Met(358), the P(1) site of alpha1-antitrypsin, was the inhibitory site for elastase
282 noassociated virus 1-vector-expressing human alpha1 antitrypsin were transplanted into the liver of m
283 tive-to-latent transition of another serpin, alpha1-antitrypsin, which does not readily go latent.
284 commonest pathogenic gene mutation yields Z-alpha1-antitrypsin, which has a propensity to self-assoc
286 2E1 (CYP2E1) by measuring the expression of alpha1-antitrypsin, which is controlled by these promote
290 t of soluble secretory proteins (albumin and alpha1-antitrypsin) with that of supramolecular cargoes
291 ation of polymers underlies the retention of alpha(1)-antitrypsin within hepatocytes and of neuroserp
292 e to inactivation by protein C inhibitor and alpha(1)-antitrypsin yet maintained their primary antico
293 ve indicated that the accumulation of mutant alpha(1)-antitrypsin Z in the ER specifically activates
296 tracellular accumulation of misfolded mutant alpha1-antitrypsin Z (ATZ) in hepatocytes causes hepatic
297 characterized by accumulation of the mutant alpha1-antitrypsin Z (ATZ) variant inside cells, causing
299 modifiers affecting the accumulation of the alpha1-antitrypsin Z mutant (ATZ) in a Caenorhabditis el
300 transgenic for the common misfolded variant alpha1-antitrypsin Z, is a model of respiratory epitheli