Glucocorticoid-stimulated, transcription-independent release of annexin A1 by cochlear Hensen cells.

BACKGROUND AND PURPOSE: The current clinical strategy to protect the auditory organ against inflammatory damage by migrating leukocytes is the local delivery of glucocorticoids. However, the mechanism by which glucocorticoids confer this protection remains unknown. Therefore, we investigated the cellular and molecular targets of glucocorticoids in the cochlea that could be involved in preventing leukocyte migration. EXPERIMENTAL APPROACH: We used microscopy as well as immunocytochemical and microfluidic techniques to elucidate the effect of dexamethasone, hydrocortisone and prednisolone on the cellular and intracellular distribution of annexin A1 (ANXA1) - a glucocorticoid target known to inhibit leukocyte migration by receptor-mediated signalling - in the cochlea and isolated cochlear cells of guinea pigs. KEY RESULTS: All the cells lining the scala media - the cochlear compartment containing the auditory organ - express ANXA1 and the ANXA1 receptor FPR2/ALX is present in the scala media, as well as in other cochlear ducts. The majority of ANXA1 in the scala media is stored inside lipid droplets within cochlear Hensen cells. Glucocorticoids activate a myosin IIC-mediated mechanism that drives ANXA1 from the lipid droplets to the apical region of the Hensen cells, where ANXA1 is released to the external milieu by a process involving ABC transporters. CONCLUSIONS AND IMPLICATIONS: These findings suggest that ANXA1 could be a major mediator of the anti-inflammatory effects of glucocorticoids in the cochlea and identify new molecular targets for prevention of sudden sensorineural hearing loss.

Small slipped register genetic instabilities in Escherichia coli in triplet repeat sequences associated with hereditary neurological diseases.

Genetic instability investigations on three triplet repeat sequences (TRS) involved in human hereditary neurological diseases (CTG.CAG, CGG.CCG, and GAA.TTC) revealed a high frequency of small expansions or deletions in 3-base pair registers in Escherichia coli. The presence of G to A polymorphisms in the CTG.CAG sequences served as reporters for the size and location of these instabilities. For the other two repeat sequences, length determinations confirmed the conclusions found for CTG.CAG. These studies were conducted in strains deficient in methyl-directed mismatch repair or nucleotide excision repair in order to investigate the involvement of these postreplicative processes in the genetic instabilities of these TRS. The observation that small and large instabilities for (CTG.CAG)175 fall into distinct size classes (1-8 repeats and approximate multiples of 41 repeats, respectively) leads to the conclusion that more than one DNA instability process is involved. The slippage of the complementary strands of the TRS is probably responsible for the small deletions and expansions in methyl-directed mismatch repair-deficient and nucleotide excision repair-deficient cells. A model is proposed to explain the observed instabilities via strand misalignment, incision, or excision, followed by DNA synthesis and ligation. This slippage-repair mechanism may be responsible for the small expansions in type 1 hereditary neurological diseases involving polyglutamine expansions. Furthermore, these observations may relate to the high frequency of small deletions versus a lower frequency of large instabilities observed in lymphoblastoid cells from myotonic dystrophy patients.

Flexible DNA: genetically unstable CTG.CAG and CGG.CCG from human hereditary neuromuscular disease genes.

The properties of duplex CTG.CAG and CGG.CCG, which are involved in the etiology of several hereditary neurodegenerative diseases, were investigated by a variety of methods, including circularization kinetics, apparent helical repeat determination, and polyacrylamide gel electrophoresis. The bending moduli were 1.13 x 10(-19) erg.cm for CTG and 1.27 x 10(-19) erg.cm for CGG, approximately 40% less than for random B-DNA. Also, the persistence lengths of the triplet repeat sequences were approximately 60% the value for random B-DNA. However, the torsional moduli and the helical repeats were 2.3 x 10(-19) erg.cm and 10.4 base pairs (bp)/turn for CTG and 2.4 x 10(-19) erg.cm and 10.3 bp/turn for CGG, respectively, all within the range for random B-DNA. Determination of the apparent helical repeat by the band shift assay indicated that the writhe of the repeats was different from that of random B-DNA. In addition, molecules of 224-245 bp in length (64-71 triplet repeats) were able to form topological isomers upon cyclization. The low bending moduli are consistent with predictions from crystallographic variations in slide, roll, and tilt. No unpaired bases or non-B-DNA structures could be detected by chemical and enzymatic probe analyses, two-dimensional agarose gel electrophoresis, and immunological studies. Hence, CTG and CGG are more flexible and highly writhed than random B-DNA and thus would be expected to act as sinks for the accumulation of superhelical density.

Triplet repeat instability and DNA topology: an expansion model based on statistical mechanics.

The variance of writhe, the contribution of writhe to supercoiling, and the free energies of supercoiling were calculated for (CTG.CAG)n and (CGG.CCG)n triplet repeat sequences (TRS) by statistical mechanics from the bending and torsional moduli previously determined. Expansions of these sequences are inherited by non-mendelian transmission and are linked with several hereditary neuromuscular diseases. The variance of writhe was greater for the TRS than for random B-DNA. For random B-DNA, (CGG)n, and (CTG)n, the contribution of writhe to supercoiling was 70, 78, and 79%, whereas the free energy of supercoiling at a length of 10 kilobase pairs was 1040.RT, 760.RT, and 685.RT, respectively. These data indicate that the TRS are preferential sites for the partitioning of supercoiling. Calculations of the differences in free energy of supercoiling between the TRS and random B-DNA revealed a local minimum at approximately 520 base pairs. Human medical genetic studies have shown that individuals carrying up to 180-200 copies of TRS (540-600 base pairs, premutations) in the fragile X or myotonic dystrophy gene loci are usually asymptomatic, whereas large expansions (>200 repeats, full mutations), which lead to disease, are observed in their offspring. Therefore, the length corresponding to the local minimum in free energy of supercoiling correlates with the genetic breakpoint between premutation and full mutation. We propose that (a) TRS instability is mediated by DNA mispairing caused by the accumulation of supercoiling within the repeats, and (b) the expansions that take place at the premutation to full mutation threshold are associated with increased mispairing caused by the optimal partitioning of writhe within the TRS at this length.

Long CCG triplet repeat blocks exclude nucleosomes: a possible mechanism for the nature of fragile sites in chromosomes.

The rare folate-sensitive, fragile sites on chromsomes X, 11, and 16 contain blocks of CCG triplet repeats and large expansions of the CCG block at the FRAXA site produce the fragile X syndrome (FraX). The fragile, poorly staining nature of these sites suggested an altered chromatin structure. Here, repeating CCG DNAs from FraX patients were tested for their ability to assemble into nucleosomes, the basic subunits of chromatin, using in vitro nucleosome reconstitution, electron microscopy and competitive assembly gel retardation assays. CCG blocks of >50 repeats displayed strong nucleosome exclusion, providing a possible explanation for the nature of these sites.

Cloning, characterization and properties of plasmids containing CGG triplet repeats from the FMR-1 gene.

The FMR-1 gene for the human fragile-chi syndrome, a mental retardation disease inherited by non-Mendelian transmission, contains a genetically unstable CGG region in the 5' non-translated region. The severity of the disease is correlated with the length of the CGG tract. The cloning of 28 stable plasmids containing (CGG)n inserts (where n = 6 to 240) with different extents and types of sequence interruptions (polymorphisms), and in different orientations was accomplished by three strategies in Escherichia coli. Some shorter tracts were prepared by the direct cloning of synthetic oligonucleotides, and longer runs were clones of multimers of (CGG)61, (CGG)11AGG(CGG)60CAG(CGG)8, from a cDNA from a fragile-chi patient or from expansions or deletions of these sequences in E. coli. The genetic stability of the inserts, especially for the longer tracts, was dependent on the sequence length, the presence of polymorphisms, the host cell genotypes, the orientation of the inserts in the vector and the position of cloning in a vector. Two-dimensional agarose gel electrophoresis studies on fully methylated and on non-methylated plasmids as well as chemical probe studies revealed the absence of underwound structures or accessible base-pairs. These DNAs enable a range of genetic and biochemical investigations into the molecular basis of the fragile-chi syndrome.

Mismatch repair in Escherichia coli enhances instability of (CTG)n triplet repeats from human hereditary diseases.

Long CTG triplet repeats which are associated with several human hereditary neuromuscular disease genes are stabilized in ColE1-derived plasmids in Escherichia coli containing mutations in the methyl-directed mismatch repair genes (mutS, mutL, or mutH). When plasmids containing (CTG)180 were grown for about 100 generations in mutS, mutL, or mutH strains, 60-85% of the plasmids contained a full-length repeat, whereas in the parent strain only about 20% of the plasmids contained the full-length repeat. The deletions occur only in the (CTG)180 insert, not in DNA flanking the repeat. While many products of the deletions are heterogeneous in length, preferential deletion products of about 140, 100, 60, and 20 repeats were observed. We propose that the E. coli mismatch repair proteins recognize three-base loops formed during replication and then generate long single-stranded gaps where stable hairpin structures may form which can be bypassed by DNA polymerase during the resynthesis of duplex DNA. Similar studies were conducted with plasmids containing CGG repeats; no stabilization of these triplets was found in the mismatch repair mutants. Since prokaryotic and human mismatch repair proteins are similar, and since several carcinoma cell lines which are defective in mismatch repair show instability of simple DNA microsatellites, these mechanistic investigations in a bacterial cell may provide insights into the molecular basis for some human genetic diseases.