O-N-acetyl-D-glucosamine moiety on discrete peptide of multiple protein 4.1 isoforms regulated by alternative pathways

Erythrocyte protein 4.1 is a cytoplasmic protein that possesses a protein-saccharide modification structure, an O-N-acetyl-D-glucosamine (GlcNAc) moiety. We determined the amino acid sequence of the proteolytic fragment containing the O-GlcNAc moiety after labeling the saccharide with [3H]galactose in the presence of bovine milk galactosyltransferase. Glycosylation appears to occur on one or more serine or threonine residues in the following sequence: Thr-Ala-Gln-Thr-Ile-Thr-Ser-Glu-Thr-Pro-Ser-Ser-Thr-Thr-Thr-Thr-Gln-Ile-Thr-Lys . This sequence corresponds to the carboxyl-terminal half of the 34-amino acid peptide in the 22/24-kDa carboxyl-terminal domain of protein 4.1, which is one of the discrete peptides regulated by alternative RNA splicing. Multiple protein 4.1 isoforms in erythroid and nonerythroid cells including major components of erythrocyte membrane proteins, 4.1a and 4.1b, appear to contain this sequence since most immunochemically reactive proteins were labeled with [3H]galactose, with the exception of several variant polypeptides. These results appear to suggest the functional or biological significance of the O-GlcNAc linkage in protein 4.1.     

Human mucin MUC1 RNA undergoes different types of alternative splicing resulting in multiple isoforms

MUC1 is a transmembrane mucin with important functions in normal and transformed cells, carried out by the extracellular domain or the cytoplasmic tail. A characteristic feature of the MUC1 extracellular domain is the variable number of tandem repeats (VNTR) region. Alternative splicing may regulate MUC1 expression and possibly function. We developed an RT-PCR method for efficient isolation of MUC1 mRNA isoforms that allowed us to evaluate the extent of alternative splicing of MUC1 and elucidate some of the rules that govern this process. We cloned and analyzed 21, 24, and 36 isoforms from human tumor cell lines HeLa, MCF7, and Jurkat, respectively, and 16 from normal activated human T cells. Among the 78 MUC1 isoforms we isolated, 76 are new and different cells showed varied MUC1 expression patterns. The VNTR region of exon 2 was recognized as an intron with a fixed 5′ splice site but variable 3′ splice sites. We also report that the 3506 A/G SNP in exon 2 can regulate 3′ splice sites selection in intron 1 and produce different MUC1 short isoform proteins. Furthermore, the SNP A to G mutation was also observed in vivo, during de novo tumor formation in MUC1^+/?Kras^G12D/+Pten^loxP/loxP mice. No specific functions have been associated with previously reported short isoforms. We now report that one new G SNP-associated isoform MUC1/Y-LSP, but not the A SNP-associated isoform MUC1/Y, inhibits tumor growth in immunocompetent but not immunocompromised mice.     

Intrasplicing coordinates alternative first exons with alternative splicing in the protein 4.1R gene

In the protein 4.1R gene, alternative first exons splice differentially to alternative 3' splice sites far downstream in exon 2'/2 (E2'/2). We describe a novel intrasplicing mechanism by which exon 1A (E1A) splices exclusively to the distal E2'/2 acceptor via two nested splicing reactions regulated by novel properties of exon 1B (E1B). E1B behaves as an exon in the first step, using its consensus 5' donor to splice to the proximal E2'/2 acceptor. A long region of downstream intron is excised, juxtaposing E1B with E2'/2 to generate a new composite acceptor containing the E1B branchpoint/pyrimidine tract and E2 distal 3' AG-dinucleotide. Next, the upstream E1A splices over E1B to this distal acceptor, excising the remaining intron plus E1B and E2' to form mature E1A/E2 product. We mapped branchpoints for both intrasplicing reactions and demonstrated that mutation of the E1B 5' splice site or branchpoint abrogates intrasplicing. In the 4.1R gene, intrasplicing ultimately determines N-terminal protein structure and function. More generally, intrasplicing represents a new mechanism by which alternative promoters can be coordinated with downstream alternative splicing.     

An analogue of the erythroid membrane skeletal protein 4.1 in nonerythroid cells

Protein 4.1 is a crucial component of the erythrocyte membrane skeleton. Responsible for the amplification of the spectrin-actin interaction, its presence is required for the maintenance of erythrocyte integrity. We have demonstrated a 4.1-like protein in nonerythroid cells. An antibody was raised to erythrocyte protein 4.1 purified by KCl extraction (Tyler, J. M., W. R. Hargreaves, and D. Branton, 1979, Proc. Natl. Acad. Sci. USA, 76:5192-5196), and used to identify a serologically cross-reactive protein in polymorphonuclear leukocytes, platelets, and lymphoid cells. The cross-reactive protein(s) were localized to various regions of the cells by immunofluorescence microscopy. Quantitative adsorption studies indicated that at least 30-60% of the anti-4.1 antibodies reacted with this protein, demonstrating significant homology between the erythroid and nonerythroid species. A homologous peptide doublet was observed on immunopeptide maps, although there was not complete identity between the two proteins. When compared with erythrocyte protein 4.1, the nonerythroid protein(s) displayed a lower molecular weight--68,000 as compared with 78,000-and did not bind spectrin or the nonerythroid actin-binding protein filamin. There was no detectable cross-reactivity between human acumentin or human tropomyosin-binding protein, which are similarly sized actin-associated proteins, and erythrocyte protein 4.1. The possible origin and significance of 4.1-related protein(s) in nonerythroid cells are discussed.     

Intricate combinatorial patterns of exon splicing generate multiple Rh-related isoforms in human erythroid cells

The Rhesus (Rh) blood group system shows complex polymorphisms in the human. Some of the heterogeneity may be generated by alternative RNA splicing. For a systematic analysis of Rh-related mRNA isoforms expressed in reticulocytes, we isolated mRNA, which was then reverse transcribed and amplified by the polymerase chain reaction (PCR) to give Rh-related cDNAs of two segments of 704 bp and 975 bp. The PCR amplification of the 5-region yielded a single PCR product, whereas a complex electrophoretic pattern of PCR bands was derived from the 3-region. A highly reproducible ladder of multiple additional bands migrated below the PCR products corresponding to the full-size cDNAs for RhPI and RhPII and encoding two different Rh polypeptides. Eleven and five truncated isoforms of the RhPI and RhPII cDNAs, respectively, were identified in the PCR products. These isoforms appear to be generated by combinatorial splicing of six RhPI and three RhPII exons. Our results suggest that the Rh-related polypeptides consist of a mixture of RhPI and RhPII polypeptide isoforms differing at the C terminus. Multiple RNA splicing pathways are thus operative in the two Rh-related genes even within a single cell lineage of human erythroid cells.     

Multifunctional protein 4.1R regulates the asymmetric segregation of Numb during terminal erythroid maturation

The asymmetric cell division of stem or progenitor cells generates daughter cells with distinct fates that balance proliferation and differentiation. Asymmetric segregation of Notch signaling regulatory protein Numb plays a crucial role in cell diversification. However, the molecular mechanism remains unclear. Here, we examined the unequal distribution of Numb in the daughter cells of murine erythroleukemia cells (MELCs) that undergo DMSO-induced erythroid differentiation. In contrast to the cytoplasmic localization of Numb during uninduced cell division, Numb is concentrated at the cell boundary in interphase, near the one-spindle pole in metaphase, and is unequally distributed to one daughter cell in anaphase in induced cells. The inheritance of Numb guides this daughter cell toward erythroid differentiation while the other cell remains a progenitor cell. Mitotic spindle orientation, critical for distribution of cell fate determinants, requires complex communication between the spindle microtubules and the cell cortex mediated by the NuMA-LGN-dynein/dynactin complex. Depletion of each individual member of the complex randomizes the position of Numb relative to the mitotic spindle. Gene replacement confirms that multifunctional erythrocyte protein 4.1R (4.1R) functions as a member of the NuMA-LGN-dynein/dynactin complex and is necessary for regulating spindle orientation, in which interaction between 4.1R and NuMA plays an important role. These results suggest that mispositioning of Numb is the result of spindle misorientation. Finally, disruption of the 4.1R-NuMA-LGN complex increases Notch signaling and decreases the erythroblast population. Together, our results identify a critical role for 4.1R in regulating the asymmetric segregation of Numb to mediate erythropoiesis.     

The PTB interacting protein raver1 regulates alpha-tropomyosin alternative splicing

Regulated switching of the mutually exclusive exons 2 and 3 of alpha-tropomyosin (TM) involves repression of exon 3 in smooth muscle cells. Polypyrimidine tract-binding protein (PTB) is necessary but not sufficient for regulation of TM splicing. Raver1 was identified in two-hybrid screens by its interactions with the cytoskeletal proteins actinin and vinculin, and was also found to interact with PTB. Consistent with these interactions raver1 can be localized in either the nucleus or cytoplasm. Here we show that raver1 is able to promote the smooth muscle-specific alternative splicing of TM by enhancing PTB-mediated repression of exon 3. This activity of raver1 is dependent upon characterized PTB-binding regulatory elements and upon a region of raver1 necessary for interaction with PTB. Heterologous recruitment of raver1, or just its C-terminus, induced very high levels of exon 3 skipping, bypassing the usual need for PTB binding sites downstream of exon 3. This suggests a novel mechanism for PTB-mediated splicing repression involving recruitment of raver1 as a potent splicing co-repressor.     

Alternative splicing regulates the subcellular localization of A-kinase anchoring protein 18 isoforms

The cAMP-dependent protein kinase (PKA) is localized to specific subcellular compartments by association with A-kinase anchoring proteins (AKAPs). AKAPs are a family of functionally related proteins that bind the regulatory (R) subunit of PKA with high affinity and target the kinase to specific subcellular organelles. Recently, AKAP18, a low molecular weight plasma membrane AKAP that facilitates PKA-mediated phosphorylation of the L-type Ca(2+) channel, was cloned. We now report the cloning of two additional isoforms of AKAP18, which we have designated AKAP18beta and AKAP18gamma, that arise from alternative mRNA splicing. The AKAP18 isoforms share a common R subunit binding site, but have distinct targeting domains. The original AKAP18 (renamed AKAP18alpha) and AKAP18beta target the plasma membrane when expressed in HEK-293 cells, while AKAP18gamma is cytosolic. When expressed in epithelial cells, AKAP18alpha is targeted to lateral membranes, whereas AKAP18beta is accumulated at the apical membrane. A 23-amino acid insert, following the plasma membrane targeting domain, facilitates the association of AKAP18beta with the apical membrane. The data suggest that AKAP18 isoforms are differentially targeted to modulate distinct intracellular signaling events. Furthermore, the data suggest that plasma membrane AKAPs may be targeted to subdomains of the cell surface, adding additional specificity in intracellular signaling.     

The role of alternative pre-mRNA splicing in regulating the structure and function of skeletal protein 4.1

Alternative pre-mRNA splicing plays a major role in regulating cell type-specific expression of the protein 4.1 family of skeletal proteins. The biological importance of alternative splicing as a mechanism for 4.1 gene regulation is underscored by studies of the prototypical 4.1R gene in erythroid cells: activation of exon 16 inclusion in mRna at the erythroblast stage greatly enhances the ability of newly synthesized 4.1R protein to bind spectrin and actin, and thus assemble into a stable membrane skeleton. This gain-of- function has profound effects on the biophysical properties of deformability and membrane strength that are critical to red cell survival in the circulation. Another example of developmentally regulated splicing occurs in differentiating mammary epithelial cells in culture, where cell morphogenesis is accompanied by a splicing switch that reversibly activates inclusion of alternative exon muscle. Few other genes are known to be so richly endowed with regulated switches in pre-mRna splicing making the 4.1R gene an interesting paradigm for the role of alternative splicing as a mediator of cell function. Recent evidence that other members of the 4.1 gene family are also regulated by alternative splicing suggests, moreover, that this phenomenon is of general importance in regulating the structure of this class of skeletal proteins.     

The polypyrimidine tract binding protein regulates desaturase alternative splicing and PUFA composition

The Δ6 desaturase, encoded by FADS2, plays a crucial role in omega-3 and omega-6 fatty acid synthesis. These fatty acids are essential components of the central nervous system, and they act as precursors for eicosanoid signaling molecules and as direct modulators of gene expression. The polypyrimidine tract binding protein (PTB or hnRNP I) is a splicing factor that regulates alternative pre-mRNA splicing. Here, PTB is shown to bind an exonic splicing silencer element and repress alternative splicing of FADS2 into FADS2 AT1. PTB and FADS2AT1 were inversely correlated in neonatal baboon tissues, implicating PTB as a major regulator of tissue-specific FADS2 splicing. In HepG2 cells, PTB knockdown modulated alternative splicing of FADS2, as well as FADS3, a putative desaturase of unknown function. Omega-3 fatty acids decreased by nearly one half relative to omega-6 fatty acids in PTB knockdown cells compared with controls, with a particularly strong decrease in eicosapentaenoic acid (EPA) concentration and its ratio to arachidonic acid (ARA). This is a rare demonstration of a mechanism specifically altering the cellular omega-3 to omega-6 fatty acid ratio without any change in diet/media. These findings reveal a novel role for PTB, regulating availability of membrane components and eicosanoid precursors for cell signaling.     

A splicing silencer that regulates smooth muscle specific alternative splicing is active in multiple cell types

Alternative splicing of α-tropomyosin (α-TM) involves mutually exclusive selection of exons 2 and 3. Selection of exon 2 in smooth muscle (SM) cells is due to inhibition of exon 3, which requires both binding sites for polypyrimidine tract-binding protein as well as UGC (or CUG) repeat elements on both sides of exon 3. Point mutations or substitutions of the UGC-containing upstream regulatory element (URE) with other UGC elements disrupted the α-TM splicing pattern in transfected cells. Multimerisation of the URE caused enhanced exon skipping in SM and various non-SM cells. In the presence of multiple UREs the degree of splicing regulation was decreased due to the high levels of exon skipping in non-SM cell lines. These results suggest that the URE is not an intrinsically SM- specific element, but that its functional strength is fine tuned to exploit differences in the activities of regulatory factors between SM and other cell types. Co-transfection of tropomyosin reporters with members of the CUG-binding protein family, which are candidate URE-binding proteins, indicated that these factors do not mediate repression of tropomyosin exon 3.     

Molecular cloning and expression of two chicken invariant chain isoforms produced by alternative splicing

The biosynthesis of distinct forms of the invariant chain (Ii) protein from a unique gene as the result of differential splicing patterns has been observed in humans and mice. However, there have been no reports on the existence of Ii isoforms in avian species. In the present study, we identified two chicken Ii cDNAs by RT-PCR and RACE, and examined the Ii gene copy number, mRNA expression and protein expression by Southern blotting, Northern blotting and immunofluorescence confocal microscopy, respectively. One of the Ii cDNAs, named Ii-1, was 1,151 bp in length, and had an open reading frame (ORF) of 672 nucleotides, in agreement with a previously identified chicken Ii sequence; the other, named Ii-2, was 1,337 bp long and had an ORF of 861 nucleotides. Southern blotting confirmed that these cDNAs were derived from a single copy gene. Northern blotting performed with total RNA from various tissues of 6-week-old chickens revealed high levels of Ii-1 and Ii-2 mRNA expression in the spleen and bursa of Fabricius, and low levels of Ii-1 expression in the thymus, heart and liver, while Ii-2 was not expressed in these tissues. High levels of expression of both Ii isoforms were detected in the spleen and bursa of Fabricius during late embryogenesis. Immunofluorescence staining showed that Ii proteins were expressed in the cell membranes of the splenocytes. These data suggest that chicken Ii exists in two isoforms resulting from alternative splicing, and is strongly expressed in the major immune organs.