Congenital stromal corneal dystrophy (CSCD) is an autosomal dominant condition with clouding of t... more Congenital stromal corneal dystrophy (CSCD) is an autosomal dominant condition with clouding of the cornea due to stromal opacities. It is caused by mutations in the decorin gene (DCN) leading to the expression of a truncated form of decorin. In an attempt to replicate this condition in mice, a knock-in mouse strain, 952delT Dcn, was created. Mice were constructed by targeted mutation. Sequencing of genomic DNA confirmed correct genotype. Mouse and human corneas, including corneas from patients with CSCD, and primary keratocyte cultures were subjected to Western blot analysis, transmission electron microscopy, and immunofluorescence microscopy. Histologically, the mice did not show any organ pathology. Corneas were clear, and the electron-lucent deposits observed in CSCD were not present. Furthermore, while nearly equivalent amounts of normal and truncated decorin are present in CSCD corneas, truncated decorin was hardly detectable in the mouse corneas. By immunofluorescence analysis of corneas from 952delT Dcn homozygous mice, decorin was found only in keratocytes. In primary cultures of mouse corneal explants, truncated decorin was retained intracellularly in contrast with human corneal explants where truncated decorin was exported into the culture medium. Immunofluorescence analysis revealed that native mouse decorin localized to the Golgi complex, whereas the truncated decorin accumulated in the endoplasmic reticulum (ER). The ER retention of truncated decorin may explain why the mouse corneas remained clear. The consequences of the decorin mutation are different in mice and humans, and 952delT Dcn knock-in mice are therefore not a suitable model for CSCD.
Congenital stromal corneal dystrophy (CSCD) is an autosomal dominant condition with clouding of t... more Congenital stromal corneal dystrophy (CSCD) is an autosomal dominant condition with clouding of the cornea due to stromal opacities. It is caused by mutations in the decorin gene (DCN) leading to the expression of a truncated form of decorin. In an attempt to replicate this condition in mice, a knock-in mouse strain, 952delT Dcn, was created. Mice were constructed by targeted mutation. Sequencing of genomic DNA confirmed correct genotype. Mouse and human corneas, including corneas from patients with CSCD, and primary keratocyte cultures were subjected to Western blot analysis, transmission electron microscopy, and immunofluorescence microscopy. Histologically, the mice did not show any organ pathology. Corneas were clear, and the electron-lucent deposits observed in CSCD were not present. Furthermore, while nearly equivalent amounts of normal and truncated decorin are present in CSCD corneas, truncated decorin was hardly detectable in the mouse corneas. By immunofluorescence analysis of corneas from 952delT Dcn homozygous mice, decorin was found only in keratocytes. In primary cultures of mouse corneal explants, truncated decorin was retained intracellularly in contrast with human corneal explants where truncated decorin was exported into the culture medium. Immunofluorescence analysis revealed that native mouse decorin localized to the Golgi complex, whereas the truncated decorin accumulated in the endoplasmic reticulum (ER). The ER retention of truncated decorin may explain why the mouse corneas remained clear. The consequences of the decorin mutation are different in mice and humans, and 952delT Dcn knock-in mice are therefore not a suitable model for CSCD.
A three-step detergent/salt extraction procedure (Vedeler et al., Mol Cell Biochem 100: 183-193, ... more A three-step detergent/salt extraction procedure (Vedeler et al., Mol Cell Biochem 100: 183-193, 1991) was used to isolate free polysomes (FP), cytoskeletal-bound polysomes (CBP) and membrane-bound polysomes (MBP) from MPC-11 and Krebs II ascites cells. Polysomes were pelleted, washed with high salt buffer and re-pelleted. Proteins in the dialysed high-salt extracts were subjected to poly(A) Sepharose chromatography and poly(A) binding and non-binding proteins were separated by SDS-PAGE. In MPC-11 cells the FP fraction contains thirteen poly(A) binding proteins and four non-poly(A) binding proteins while the corresponding fraction in Krebs II ascites cells has four poly(A) binding proteins and six proteins which do not bind poly(A). The CBP fraction isolated from MPC-11 cells has a complement of ten poly(A) binding proteins, four which are non-poly(A) binding, and a protein of 105 kDa which has both poly(A) binding and non-poly(A) binding properties. In the CBP fraction prepared from Krebs II ascites cells a protein band at 32 kDa exhibits both poly(A) binding and non-poly(A) binding properties. In this fraction there are six poly(A) binding proteins and an additional eight which do not bind poly(A). Of the total number of proteins eight of these have a molecular weight below 40 kDa. The MBP fraction in MPC-11 cells contains three poly(A) binding proteins and eleven with non-poly(A) binding properties. In contrast this fraction in Krebs II ascites cells has a complement of thirteen poly(A) binding and ten non-poly(A) binding proteins.(ABSTRACT TRUNCATED AT 250 WORDS)
... m'GpppG >> m'.'-7GpppG, m2,7GpppG)indicating that a ... more ... m'GpppG >> m'.'-7GpppG, m2,7GpppG)indicating that a transacting recognition factor may be ... The best documented role for polyadenylation is maintenance of mRNA stability, and it has ... During these processes several control steps regulate the transport of the mRNA molecule. ...
Messenger RNA trafficking, which provides a mechanism for local protein synthesis, is dependent o... more Messenger RNA trafficking, which provides a mechanism for local protein synthesis, is dependent on cis-acting sequences in the 3′ untranslated regions (3′UTRs) of the mRNAs concerned acting together with trans-acting proteins. The C-MYC transcription factor is a proto-oncogene product involved in cell proliferation, differentiation and apoptosis. Localization of c-myc mRNA to the perinuclear cytoplasm and its association with the cytoskeleton is determined by a signal in the 3′UTR. Here we show the specific binding of a trans-acting factor to the perinuclear localization element in the 3′UTR of c-myc mRNA and identify this protein as annexin A2. Gel retardation and UV cross-linking experiments showed that proteins in fibroblast extracts formed complexes with the region of c-myc 3′UTR implicated in localization; a protein of ≈ 36 kDa exhibited specific, Ca2+-dependent binding. Binding was reduced by introduction of a mutation that abrogates localization. Using RNA-affinity columns followed by gel electrophoresis and mass spectrometry this protein was identified as annexin A2. The RNA–protein complex formed by cell extracts was further retarded by anti-(annexin A2). Purified annexin A2 bound to the same region of the c-myc 3′UTR but binding was reduced by introduction of a mutation, as with cell extracts. It is proposed that binding of annexin A2 to the localization signal in the c-myc mRNA leads to association with the cytoskeleton and perinuclear localization. The data indicate a novel functional role for the RNA-binding properties of annexin A2 in perinuclear localization of mRNA and the association with the cytoskeleton.
Congenital stromal corneal dystrophy (CSCD) is an autosomal dominant condition with clouding of t... more Congenital stromal corneal dystrophy (CSCD) is an autosomal dominant condition with clouding of the cornea due to stromal opacities. It is caused by mutations in the decorin gene (DCN) leading to the expression of a truncated form of decorin. In an attempt to replicate this condition in mice, a knock-in mouse strain, 952delT Dcn, was created. Mice were constructed by targeted mutation. Sequencing of genomic DNA confirmed correct genotype. Mouse and human corneas, including corneas from patients with CSCD, and primary keratocyte cultures were subjected to Western blot analysis, transmission electron microscopy, and immunofluorescence microscopy. Histologically, the mice did not show any organ pathology. Corneas were clear, and the electron-lucent deposits observed in CSCD were not present. Furthermore, while nearly equivalent amounts of normal and truncated decorin are present in CSCD corneas, truncated decorin was hardly detectable in the mouse corneas. By immunofluorescence analysis of corneas from 952delT Dcn homozygous mice, decorin was found only in keratocytes. In primary cultures of mouse corneal explants, truncated decorin was retained intracellularly in contrast with human corneal explants where truncated decorin was exported into the culture medium. Immunofluorescence analysis revealed that native mouse decorin localized to the Golgi complex, whereas the truncated decorin accumulated in the endoplasmic reticulum (ER). The ER retention of truncated decorin may explain why the mouse corneas remained clear. The consequences of the decorin mutation are different in mice and humans, and 952delT Dcn knock-in mice are therefore not a suitable model for CSCD.
Congenital stromal corneal dystrophy (CSCD) is an autosomal dominant condition with clouding of t... more Congenital stromal corneal dystrophy (CSCD) is an autosomal dominant condition with clouding of the cornea due to stromal opacities. It is caused by mutations in the decorin gene (DCN) leading to the expression of a truncated form of decorin. In an attempt to replicate this condition in mice, a knock-in mouse strain, 952delT Dcn, was created. Mice were constructed by targeted mutation. Sequencing of genomic DNA confirmed correct genotype. Mouse and human corneas, including corneas from patients with CSCD, and primary keratocyte cultures were subjected to Western blot analysis, transmission electron microscopy, and immunofluorescence microscopy. Histologically, the mice did not show any organ pathology. Corneas were clear, and the electron-lucent deposits observed in CSCD were not present. Furthermore, while nearly equivalent amounts of normal and truncated decorin are present in CSCD corneas, truncated decorin was hardly detectable in the mouse corneas. By immunofluorescence analysis of corneas from 952delT Dcn homozygous mice, decorin was found only in keratocytes. In primary cultures of mouse corneal explants, truncated decorin was retained intracellularly in contrast with human corneal explants where truncated decorin was exported into the culture medium. Immunofluorescence analysis revealed that native mouse decorin localized to the Golgi complex, whereas the truncated decorin accumulated in the endoplasmic reticulum (ER). The ER retention of truncated decorin may explain why the mouse corneas remained clear. The consequences of the decorin mutation are different in mice and humans, and 952delT Dcn knock-in mice are therefore not a suitable model for CSCD.
A three-step detergent/salt extraction procedure (Vedeler et al., Mol Cell Biochem 100: 183-193, ... more A three-step detergent/salt extraction procedure (Vedeler et al., Mol Cell Biochem 100: 183-193, 1991) was used to isolate free polysomes (FP), cytoskeletal-bound polysomes (CBP) and membrane-bound polysomes (MBP) from MPC-11 and Krebs II ascites cells. Polysomes were pelleted, washed with high salt buffer and re-pelleted. Proteins in the dialysed high-salt extracts were subjected to poly(A) Sepharose chromatography and poly(A) binding and non-binding proteins were separated by SDS-PAGE. In MPC-11 cells the FP fraction contains thirteen poly(A) binding proteins and four non-poly(A) binding proteins while the corresponding fraction in Krebs II ascites cells has four poly(A) binding proteins and six proteins which do not bind poly(A). The CBP fraction isolated from MPC-11 cells has a complement of ten poly(A) binding proteins, four which are non-poly(A) binding, and a protein of 105 kDa which has both poly(A) binding and non-poly(A) binding properties. In the CBP fraction prepared from Krebs II ascites cells a protein band at 32 kDa exhibits both poly(A) binding and non-poly(A) binding properties. In this fraction there are six poly(A) binding proteins and an additional eight which do not bind poly(A). Of the total number of proteins eight of these have a molecular weight below 40 kDa. The MBP fraction in MPC-11 cells contains three poly(A) binding proteins and eleven with non-poly(A) binding properties. In contrast this fraction in Krebs II ascites cells has a complement of thirteen poly(A) binding and ten non-poly(A) binding proteins.(ABSTRACT TRUNCATED AT 250 WORDS)
... m'GpppG >> m'.'-7GpppG, m2,7GpppG)indicating that a ... more ... m'GpppG >> m'.'-7GpppG, m2,7GpppG)indicating that a transacting recognition factor may be ... The best documented role for polyadenylation is maintenance of mRNA stability, and it has ... During these processes several control steps regulate the transport of the mRNA molecule. ...
Messenger RNA trafficking, which provides a mechanism for local protein synthesis, is dependent o... more Messenger RNA trafficking, which provides a mechanism for local protein synthesis, is dependent on cis-acting sequences in the 3′ untranslated regions (3′UTRs) of the mRNAs concerned acting together with trans-acting proteins. The C-MYC transcription factor is a proto-oncogene product involved in cell proliferation, differentiation and apoptosis. Localization of c-myc mRNA to the perinuclear cytoplasm and its association with the cytoskeleton is determined by a signal in the 3′UTR. Here we show the specific binding of a trans-acting factor to the perinuclear localization element in the 3′UTR of c-myc mRNA and identify this protein as annexin A2. Gel retardation and UV cross-linking experiments showed that proteins in fibroblast extracts formed complexes with the region of c-myc 3′UTR implicated in localization; a protein of ≈ 36 kDa exhibited specific, Ca2+-dependent binding. Binding was reduced by introduction of a mutation that abrogates localization. Using RNA-affinity columns followed by gel electrophoresis and mass spectrometry this protein was identified as annexin A2. The RNA–protein complex formed by cell extracts was further retarded by anti-(annexin A2). Purified annexin A2 bound to the same region of the c-myc 3′UTR but binding was reduced by introduction of a mutation, as with cell extracts. It is proposed that binding of annexin A2 to the localization signal in the c-myc mRNA leads to association with the cytoskeleton and perinuclear localization. The data indicate a novel functional role for the RNA-binding properties of annexin A2 in perinuclear localization of mRNA and the association with the cytoskeleton.
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