On the identity of the dissociation-linked chloride binding sites in human hemoglobin. Studies with hemoglobin modified with 4-isothiocyanatobenzenesulfonic acid and 4-isothiocyanatobenzenesulfonamide

The binding of chloride ions to specific sites on the human hemoglobin molecule has well-known effects on the oxygen equilibrium and on the stability of the tetrameric structure. Several lines of evidence suggest that the oxygen-linked and the dissociation-linked chloride binding sites differ. Direct evidence for this difference has been obtained from the chloride dependence of the dimer-tetramer equilibrium of oxyhemoglobin modified with 4-isothiocyanatobenzenesulfonic acid, in which all the oxygen-linked chloride binding sites are blocked, or with 4-isothiocyanatobenzenesulfonamide, in which the linkage between chloride and oxygen is unperturbed. Thus, the chloride dependence of the dimer-tetramer assembly is unaffected by the chemical modification in both proteins and resembles that of unreacted hemoglobin. It is suggested that histidines alpha-103, alpha-122 and beta-97 may constitute, at least in part, the dissociation-linked chloride binding sites.     

Roles of hnRNP A1, SR proteins,and p68 helicase in c-H-ras alternative splicing regulation

Human ras genes play central roles in coupling extracellular signals with complex intracellular networks controlling proliferation, differentiation, and apoptosis, among others processes. c-H-ras pre-mRNA can be alternatively processed into two mRNAs due to the inclusion or exclusion of the alternative exon IDX; this renders two proteins, p21H-Ras and p19H-RasIDX, which differ only at the carboxy terminus. Here, we have characterized some of the cis-acting sequences and trans-acting factors regulating IDX splicing. A downstream intronic silencer sequence (rasISS1), acting in concert with IDX, negatively regulates upstream intron splicing. This effect is mediated, at least in part, by the binding of hnRNP A1. Depletion and add-back experiments in nuclear extracts have confirmed hnRNP A1's inhibitory role in IDX splicing. Moreover, the addition of two SR proteins, SC35 and SRp40, can counteract this inhibition by strongly promoting the splicing of the upstream intron both in vivo and in vitro. Further, the RNA-dependent helicase p68 is also associated with both IDX and rasISS1 RNA, and suppression of p68 expression in HeLa cells by RNAi experiments results in a marked increase of IDX inclusion in the endogenous mRNA, suggesting a role for this protein in alternative splicing regulation.     

Distinctive features of Drosophila alternative splicing factor RS domain: implication for specific phosphorylation, shuttling, and splicing activation

The human splicing factor 2, also called human alternative splicing factor (hASF), is the prototype of the highly conserved SR protein family involved in constitutive and regulated splicing of metazoan mRNA precursors. Here we report that the Drosophila homologue of hASF (dASF) lacks eight repeating arginine-serine dipeptides at its carboxyl-terminal region (RS domain), previously shown to be important for both localization and splicing activity of hASF. While this difference has no effect on dASF localization, it impedes its capacity to shuttle between the nucleus and cytoplasm and abolishes its phosphorylation by SR protein kinase 1 (SRPK1). dASF also has an altered splicing activity. While being competent for the regulation of 5' alternative splice site choice and activation of specific splicing enhancers, dASF fails to complement S100-cytoplasmic splicing-deficient extracts. Moreover, targeted overexpression of dASF in transgenic flies leads to higher deleterious developmental defects than hASF overexpression, supporting the notion that the distinctive structural features at the RS domain between the two proteins are likely to be functionally relevant in vivo.     

Sam68 sequestration and partial loss of function are associated with splicing alterations in FXTAS patients

Fragile X‐associated Tremor/Ataxia Syndrome (FXTAS) is a neurodegenerative disorder caused by expansion of 55–200 CGG repeats in the 5′‐UTR of the FMR1 gene. FXTAS is characterized by action tremor, gait ataxia and impaired executive cognitive functioning. It has been proposed that FXTAS is caused by titration of RNA‐binding proteins by the expanded CGG repeats. Sam68 is an RNA‐binding protein involved in alternative splicing regulation and its ablation in mouse leads to motor coordination defects. Here, we report that mRNAs containing expanded CGG repeats form large and dynamic intranuclear RNA aggregates that recruit several RNA‐binding proteins sequentially, first Sam68, then hnRNP‐G and MBNL1. Importantly, Sam68 is sequestered by expanded CGG repeats and thereby loses its splicing‐regulatory function. Consequently, Sam68‐responsive splicing is altered in FXTAS patients. Finally, we found that regulation of Sam68 tyrosine phosphorylation modulates its localization within CGG aggregates and that tautomycin prevents both Sam68 and CGG RNA aggregate formation. Overall, these data support an RNA gain‐of‐function mechanism for FXTAS neuropathology, and suggest possible target routes for treatment options.     

Relationship between integrated and nonintegrated viral DNA in rat cells transformed by polyoma virus

Fischer rat fibroblasts transformed by polyoma virus contain, in addition to viral sequences integrated into the host genome, nonintegrated viral DNA molecules, whose presence is under the control of the viral A gene. To understand the mechanism of production of the "free" viral DNA, we have characterized the DNA species produced by several rat lines transformed by wild-type virus or by ts-a polyoma virus and compared them with the integrated viral sequences. Every cell line tested yielded a characteristic number of discrete species of viral DNA. The presence of defectives was a very common occurrence, and these molecules generally carried deletions mapping in the viral "late" region. The production of multiple species of free viral DNA was not due to heterogeneity of the transformed rat cell population, and its pattern did not change upon fusion with permissive mouse cells. Analysis of the integrated viral DNA sequences in the same cell lines showed, in most cases, a full head-to-tail tandem arrangement of normal-size and defective molecules. The free DNA produced by these lines faithfully reflected the integrated species. This was true also in the case of a cell line which contained a viral insertion corresponding to approximately 1.3 polyoma genomes, with each of the repeated portions of the viral DNA molecule carrying a different-size deletion. These results support the hypothesis that the free DNA derives from the integrated form through a mechanism of homologous recombination leading to excision and limited replication.