Gene/Protein
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Symptom
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Query: EC:2.5.1.18 (
glutathione S-transferase
)
22,582
document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)
Apical and narrow cells of the initial segment and intermediate zone of the adult rat epididymis were glutaraldehyde fixed and Epon embedded for routine light (LM) and electron (EM) microscopic analysis and Bouin fixed and paraffin embedded for LM immunocytochemical analysis in order to examine their structural features, distribution, and functions. The goblet-shaped apical cells comprised 10.7 +/- 1.0% of the total epithelial population in the proximal initial segment but only 1.3 +/- 0.5% in the intermediate zone. In the EM, these cells presented numerous mitochondria, few C-shaped vesicles, and a pale round or oblong nucleus located in the upper half of their cytoplasm. The slender elongated narrow cells increased from 2.8 +/- 0.3% in the proximal initial segment to 6.3 +/- 0.4% in the intermediate zone. In an EM analysis, these cells presented numerous C-shaped vesicles and mitochondria and a small flattened nucleus located in the upper half of their cytoplasm. The structural features of both these cell types differed not only from each other but also from the neighboring principal and basal cells of each region. Of the various antibodies examined to lysosomal proteins, narrow and apical cells expressed high levels of cathepsin D, while beta-hexosaminidase A was expressed at high levels in narrow cells but only moderately in apical cells. Apical cells were intensely reactive for the Yf subunit of
glutathione S-transferase
(
GST
)-P, whereas no reaction was seen in narrow cells; the Yo subunit of
GST
was localized within both cell types but only in the proximal initial segment. Narrow cells exclusively expressed
carbonic anhydrase II
. Selective differences in the immunolocalization of these various proteins were also noted between these two cell types and principal and basal cells. The localization of cathepsin D and beta-hexosaminidase A within narrow and apical cells suggests these cells may be involved in the degradation of specific proteins within their lysosomes, whereas the presence of GSTs may aid in protecting spermatozoa from a changing environment of harmful electrophiles. Localization of
carbonic anhydrase II
exclusively within narrow cells suggests that these cells may modify the pH of the lumen resulting in the quiescence of sperm motility in the proximal end of the epididymis. Together, the data indicate that apical and narrow cells differ not only from each other but also from principal and basal cells in their structure and relative distribution. They also express different proteins within the distinct epididymal regions, indicating that they perform different functions.
...
PMID:Apical and narrow cells are distinct cell types differing in their structure, distribution, and functions in the adult rat epididymis. 879 11
In this study, we provide evidence that the 33-residue carboxyl-terminal (Ct) region of the human erythrocyte chloride/bicarbonate exchanger, band 3, binds
carbonic anhydrase II
(
CAII
). Immunofluorescence showed that tomato lectin-mediated clustering of band 3 in ghost membranes caused a similar clustering of
CAII
, indicating an in situ association.
CAII
cosolubilized and coimmunoprecipitated with band 3, suggesting that the two proteins form a complex. Band 3 (K1/2 = 70 nM) or the membrane domain of band 3 (K1/2 = 100 nM) bound saturably to immobilized
CAII
in a solid phase binding assay. The interaction with
CAII
was specifically blocked by an antibody to the Ct of band 3. Affinity blotting showed that a
glutathione S-transferase
(
GST
)-fusion protein (
GST
-Ct) containing the last 33 residues of human band 3 bound to
CAII
. The solid phase binding assay showed that binding of
GST
-Ct to immobilized
CAII
was saturable (K1/2 = 20 nM). The binding rate was slow (t1/2 = 12 h) at physiological ionic strength and pH but was enhanced at low ionic strength or acidic pH. Intact band 3 (Ki = 15 nM), the membrane domain of band 3 (Ki = 100 nM), or antibodies to the Ct of band 3 were able to block
GST
-Ct binding to
CAII
, confirming the specificity of the interaction. Affinity chromatography showed that
CAII
bound to immobilized
GST
-Ct with a 1:1 stoichiometry. This work indicates that
CAII
, the bicarbonate supplier, is directly coupled to band 3, the chloride/bicarbonate exchanger in red blood cells.
...
PMID:Carbonic anhydrase II binds to the carboxyl terminus of human band 3, the erythrocyte C1-/HCO3- exchanger. 977 71
The human Cl(-)/HCO(3)(-) anion exchanger (AE1) possesses a binding site within its 33 residue carboxyl-terminal region (Ct) for
carbonic anhydrase II
(
CAII
). The amino acid sequence comprising this
CAII
binding site was determined by peptide competition and by testing the ability of truncation and point mutants of the Ct sequence to bind
CAII
with a sensitive microtiter plate binding assay. A synthetic peptide consisting of the entire 33 residues of the Ct (residues 879-911) could compete with a
GST
fusion protein of the Ct (GST-Ct) for binding to immobilized
CAII
, while a peptide consisting of the last 16 residues (896-911) could not. A series of truncation mutants of the
GST
-Ct showed that the terminal 21 residues of AE1 were not required for binding
CAII
. Removal of four additional residues (887-890) from the Ct resulted in loss of
CAII
binding. Acidic residues in this region (D887ADD) were critical for binding since mutating this sequence in the
GST
-Ct to DAAA, AAAA, or NANN caused loss of
CAII
binding. A
GST
-Ct construct mutated to D887ANE, the homologous sequence in AE2, could bind
CAII
. AE2 is a widely expressed anion exchanger and has a homologous Ct region with 60% sequence identity to AE1. A
GST
fusion protein of the 33 residue Ct of AE2 could bind to
CAII
similarly to the Ct of AE1. Tethering of
CAII
to an acidic motif within the Ct of anion exchangers may be a general mechanism for promoting bicarbonate transport across cell membranes.
...
PMID:Identification of the carbonic anhydrase II binding site in the Cl(-)/HCO(3)(-) anion exchanger AE1. 1082 26
Human
carbonic anhydrase II
(
CAII
) possesses a binding site for an acidic motif (D887ADD) within the carboxyl-terminal region (Ct) of the human erythrocyte chloride/bicarbonate anion exchanger, AE1. In this study, the amino acid sequence comprising this AE1 binding site was localized to the first 17 residues of
CAII
, which form a basic patch on the surface of the protein. Truncation of the amino terminal of
CAII
by five residues resulted in a 3-fold reduction in the apparent affinity of the interaction with a
GST
fusion protein of the Ct of AE1 (GST-Ct) measured by a sensitive microtiter plate binding assay. Further amino-terminal truncation of
CAII
by 17 or 24 residues caused a loss of binding. The homologous isoform CAI does not bind AE1, despite having 60% sequence identity to
CAII
. One major difference between the two CA isoforms, within the amino-terminal region, is a high content of histidine residues in
CAII
(His3, -4, -10, -15, -17) not found in CAI. Mutation of pairs of these histidines (and one lysine) in
CAII
to the analogous residues in CAI (H3P/H4D or K9D/H10K or H15Q/H17S), or combinations of these various double mutants, did not greatly affect binding between
GST
-Ct and the mutant
CAII
. However, when all six of the targeted
CAII
residues were mutated to the corresponding sequence in CAI, binding of
GST
-Ct was lost. These results indicate that the AE1 binding site is located within the first 17 residues of
CAII
, and that the interaction is mediated by electrostatic interactions involving histidine and/or lysine residues. Further specificity for the interaction of AE1 and
CAII
is provided by a conserved leucine residue (L886) in AE1 that, when mutated to alanine, resulted in loss of
GST
-Ct binding to immobilized
CAII
. The binding of the basic amino-terminal region of
CAII
to an acidic Ct in AE1 provides a structural basis for linking bicarbonate transport across the cell membrane to intracellular bicarbonate metabolism.
...
PMID:Localization of the Cl-/HCO3- anion exchanger binding site to the amino-terminal region of carbonic anhydrase II. 1106 70
Fourteen goat populations were studied regarding their genetic relationship and structure. Parameters of genetic diversity (HT, HS and
GST
) and F statistic (FIS, FIT and FST) were estimated. Undefined breed populations presented high homogeneity, as did imported breed populations. Naturalized breed populations showed high differentiation. The genetic distances separating these 14 goat populations were calculated from gene frequency data for eight blood genetic markers (esterase D, phosphoglucomutase 1,
carbonic anhydrase II
, peptidase B, amylase, haemoglobin, transferrin, and protein X). Working with the genetic distance matrix of Nei corrected for small samples (DA), we constructed a dendrogram using the unweighted pair group method with arithmetic mean. DA values ranged from 0.0027 to 0.1518. The dendrogram divided the populations into two groups, one consisting of three populations of naturalized breeds, and another including the other populations (imported breeds, undefined breeds and some other naturalized breeds).
...
PMID:Structure and genetic relationship among Brazilian naturalized and imported goat breeds. 1130 14
We analysed the expression profiles of 70 kidney tumors of different histological subtypes to determine if these subgroups can be distinguished by their gene expression profiles, and to gain insights into the molecular mechanisms underlying each subtype. In all, 39 clear cell renal cell carcinomas (RCC), seven primary and one metastatic papillary RCC, six granular RCC from old classification, five chromophobe RCC, five sarcomatoid RCC, two oncocytomas, three transitional cell carcinomas (TCC) of the renal pelvis and five Wilms' tumors were compared with noncancerous kidney tissues using microarrays containing 19,968 cDNAs. Based on global gene clustering of 3560 selected cDNAs, we found distinct molecular signatures in clear cell, papillary, chromophobe RCC/oncocytoma, TCC and Wilms' subtypes. The close clustering in each of these subtypes points to different tumorigenic pathways as reflected by their histological characteristics. In the clear cell RCC clustering, two subgroups emerged that correlated with clinical outcomes, confirming the potential use of gene expression signatures as a predictor of survival. In the so-called granular cell RCC (terminology for a subtype that is no longer preferred), none of the six cases clusters together, supporting the current view that they do not represent a single entity. Blinded histological re-evaluation of four cases of 'granular RCC' led to their reassignment to other existing histological subtypes, each compatible with our molecular classification. Finally, we found gene sets specific to each subtype. In order to establish the use of some of these genes as novel subtype markers, we selected four genes and performed immunohistochemical analysis on 40 cases of primary kidney tumors. The results were consistent with the gene expression microarray data:
glutathione S-transferase
alpha was highly expressed in clear cell RCC, alpha methylacyl racemase in papillary RCC,
carbonic anhydrase II
in chromophobe RCC and K19 in TCC. In conclusion, we demonstrated that molecular profiles of kidney cancers closely correlated with their histological subtypes. We have also identified in these subtypes differentially expressed genes that could have important diagnostic and therapeutic implications.
...
PMID:Molecular subclassification of kidney tumors and the discovery of new diagnostic markers. 1455 94
Hypokalemic nephropathy caused by prolonged K(+) deficiency is associated with metabolic alkalosis, polydipsia, polyuria, growth retardation, hypertension, and progressive tubulointerstitial injury. Its pathophysiology, however, remains unclear. We performed gel-based, differential proteomics analysis of kidneys from BALB/c mice fed with high-normal-K(+) (HNK), low-normal-K(+) (LNK), or K(+)-depleted diet for 8 wk (n = 6 in each group). Plasma K(+) levels were 4.62 +/- 0.35, 4.46 +/- 0.23, and 1.51 +/- 0.21 mmol/L for HNK, LNK, and KD mice, respectively (p < 0.0001; KD vs. others). With comparable amounts of food intake, the KD mice drank significantly more water than the other two groups and had polyuria. Additionally, the KD mice had growth retardation, metabolic alkalosis, markedly enlarged kidneys, renal tubular dilation, intratubular deposition of amorphous and laminated hyaline materials, and tubular atrophy. A total of 33 renal proteins were differentially expressed between the KD mice and others, whereas only eight proteins were differentially expressed between the HNK and LNK groups, as determined by quantitative intensity analysis and ANOVA with Tukey's post hoc multiple comparisons. Using MALDI-MS and/or quadrupole-TOF MS/MS, 30 altered proteins induced by K(+)-depletion were identified as metabolic enzymes (e.g.,
carbonic anhydrase II
, aldose reductase,
glutathione S-transferase
GT41A, etc.), signaling proteins (14-3-3 epsilon, 14-3-3 zeta, and cofilin 1), and cytoskeletal proteins (gamma-actin and tropomyosin). Some of these altered proteins, particularly metabolic enzymes and signaling proteins, have been demonstrated to be involved in metabolic alkalosis, polyuria, and renal tubular injury. Our findings may lead to a new road map for research on hypokalemic nephropathy and to better understanding of the pathophysiology of this medical disease when the functional and physiological significances of these altered proteins are defined.
...
PMID:Proteomic identification of alterations in metabolic enzymes and signaling proteins in hypokalemic nephropathy. 1650 68
Based on solid-phase binding assays with enzyme-linked immunosorbent assay detection, previous investigators suggested that intracellular
carbonic anhydrase II
(CA II) interacts at high affinity with the C-terminal (Ct) domains of SLC4 bicarbonate-transport proteins, expressed as
glutathione S-transferase
(
GST
) fusion proteins, to form functional HCO3- metabolons. Here we re-evaluated this protein-protein interaction using two solid-phase binding assays. We first compared the ability of the Ct domain of three SLC4 transporters, SLC4-A1 (AE1), SLC4-A4 (NBCe1), and SLC4-A8 (NDCBE), to bind immobilized CA II, using enzyme-linked immunosorbent assay detection. We found that when expressed as
GST
fusion proteins, all three bind to CA II (Kd 300-600 nM) better than does pure
GST
. However, we detected no binding of pure SLC4-Ct peptides to immobilized CA II. Second, we reversed assay orientation by immobilizing the SLC4-Ct fusion proteins or peptides. We found that more CA II binds to
GST
than to any of the three
GST
-SLC4-Ct fusion proteins. Furthermore, we detected no binding of CA II to any of the immobilized pure SLC4-Ct peptides. Finally, we used surface plasmon resonance to detect possible rapid interactions between CA II and the pure peptides. Although we detected acetazolamide binding to immobilized CA II and specific antibodies binding to immobilized SLC4-Ct peptides, we detected no binding of CA II to immobilized SLC4-Ct or vice versa. Thus, although an HCO3 metabolon may exist, CA II cannot bind directly to pure SLC4-Ct peptides and can bind to
GST
-SLC4-Ct fusion proteins only when the CA II is immobilized and the fusion protein is soluble, and not vice versa.
...
PMID:Evidence against a direct interaction between intracellular carbonic anhydrase II and pure C-terminal domains of SLC4 bicarbonate transporters. 1709 May 40
Cystic fibrosis (CF) is a major genetic disease in Caucasians affecting 1 in 2500 newborns. Hepatobiliary pathology is a major cause of morbidity and mortality in CF second only to pulmonary disease. SULT1E1 activity is significantly elevated, generally 20-30-fold, in hepatocytes of mouse models of CF. SULT1E1 is responsible for the inactivation of beta-estradiol (E2) at physiological concentrations via conjugation with sulfonate. The increase in SULT1E1 activity results in the alteration of E2-regulated protein expression in CF mouse liver. To investigate the mechanism by which the absence of CFTR in human cholangiocytes induces SULT1E1 expression in hepatocytes, a membrane-separated human MMNK-1 cholangiocyte and human HepG2 hepatocyte co-culture system was developed. The cystic fibrosis transmembrane conductance regulator (CFTR) is expressed in bile duct cholangiocytes but not hepatocytes, whereas SULT1E1 is expressed in hepatocytes but not cholangiocytes. CFTR expression in MMNK-1 cells was inhibited with siRNA by >90% as determined by immunoblot and immunohistochemical analysis. Control and CFTR-siRNA-MMNK-1 cells were co-cultured with HepG2 cells in a Transwell membrane-separated system. After 8h of co-culture, HepG2 cells were removed from exposure to MMNK-1 cells and placed in fresh medium. After 24-48h, expression of SULT1E1 and selected E2-regulated proteins was analyzed in the HepG2 cells. Results demonstrated that SULT1E1 message and activity were selectively induced in HepG2 cells co-cultured with CFTR-deficient MMNK-1 cells. The expression of E2-regulated proteins (IGF-1,
GST
-P1 and
carbonic anhydrase II
) was also altered in response to decreased E2 levels. Thus, the loss of CFTR activity in cholangiocytes stimulates the expression of SULT1E1 in hepatocytes by a paracrine mechanism. SULT1E1 expression in HepG2 cells is inducible by sterol mediated liver-X-receptor (LXR) activation although not by progestins that induce SULT1E1 in the endometrium. SULT1E1 induction in the human cholangiocyte/hepatocyte co-culture system is consistent with and supports the results observed in CF mice. The changes in hepatocyte gene expression affect liver biochemistry and may facilitate the development of CF liver disease.
...
PMID:Regulation of hepatic sulfotransferase (SULT) 1E1 expression and effects on estrogenic activity in cystic fibrosis (CF). 1942 40
The soluble enzyme
carbonic anhydrase II
(
CAII
) plays an important role in CO(2) influx and efflux by red blood cells (RBCs), a process initiated by changes in the extracellular [CO(2)] (CO(2)-initiated CO(2) transport). Evidence suggests that
CAII
may be part of a macromolecular complex at the inner surface of the RBC membrane. Some have suggested
CAII
specifically binds to a motif on the cytoplasmic C terminus (Ct) of the Cl-HCO(3) exchanger AE1 and some other members of the SLC4 family of HCO(3)(-) transporters, a transport metabolon. Moreover, others have suggested that this bound
CAII
enhances the transport of HCO(3)(-)-related species-HCO(3)(-), CO(3)(), or CO(3)() ion pairs-when the process is initiated by altering the activity of the transporter (HCO(3)(-)-initiated HCO(3)(-) transport). In this review, I assess the theoretical roles of CAs in the transport of CO(2) and HCO(3)(-)-related species, concluding that although the effect of bound
CAII
on CO(2)-initiated CO(2) transport is expected to be substantial, the effect of bound CAs on HCO(3)(-)-initiated HCO(3)(-) transport is expected to be modest at best. I also assess the experimental evidence for
CAII
binding to AE1 and other transporters, and the effects of this binding on HCO(3)(-)-initiated HCO(3)(-) transport. The early conclusion that
CAII
binds to the Ct of AE1 appears to be the result of unpredictable effects of
GST
in the
GST
fusion proteins used in the studies. The early conclusion that bound
CAII
speeds HCO(3)(-)-initiated HCO(3)(-) transport appears to be the result of
CAII
accelerating the pH changes used as a read-out of transport. Thus, it appears that
CAII
does not bind directly to AE1 or other SLC4 proteins, and that bound
CAII
does not substantially accelerate HCO(3)(-)-initiated HCO(3)(-) transport.
...
PMID:Evaluating the role of carbonic anhydrases in the transport of HCO3--related species. 1987 80
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