Amino acid sequences of porcine fast and slow troponin T isoforms

In this study, 10 troponin T isoforms from adult porcine skeletal muscle messenger RNA were clarified. These were eight fast- and two slow-type isoforms. Fast-type isoforms had three and two variable exons in the N-terminal and the C-terminal region respectively. Slow-type isoforms had one variable exon in the N-terminal region.     

Dissecting the sequence specific functions of alternative N-terminal isoforms of mouse bullous pemphigoid antigen 1

Bullous pemphigoid antigen 1 (BPAG1) is a member of the plakin family of proteins that is involved in cross-linking the cytoskeletal elements and attaching them to cell junctions. BPAG1 null mice develop severe degeneration of sensory neurons that was attributed in part due to the absence of a splice variant called BPAG1a that harbors an actin-binding domain at the N-terminus. Additional alternative splicing also results in BPAG1a isoforms with different first exons, leading to three additional types of BPAG1a called isoforms 1, 2 and 3 (or BPAG1a1, BPAG1a2, and BPAG1a3). These unique N-terminal extensions of the BPAG1a isoforms are of variable length. In this study, we characterized these N-terminal isoforms and evaluated the influence of these unique N-terminal sequences to the actin-binding properties. The unique N-terminal region of isoform 1 is very short and was not expected to affect the property of the ABD that followed it. In contrast, transfection studies and mutagenesis analyses signified that the N-terminal sequences of isoform 2 had the ability to bundle actin filaments and the N-terminal region that contained isoform 3 showed cortical localization. Isoforms 1, 2 and 3 also displayed differential tissue expression profiles. Taken together, these data suggested that the unique N-terminal regions of these isoforms have different roles that may be tailored to meet tissue specific functions.     

Expression of cDNAs encoding mouse cardiac troponin T isoforms: characterization of a large sample of independent clones

We have isolated 52 mouse cardiac troponin-T-encoding cDNA clones (TnT) by specific antibody screening of a λZAPII expression library. Sequencing data from the large sample of independent cDNAs demonstrated relationships among the expression of four alternatively-spliced exons of the cardiac TnT gene, producing seven classes of cDNAs encoding four protein isoforms differing in two variable regions. In the N-terminal variable region and next to the embryonic-specific exon 4, an alternatively spliced exon 3a was identified in 20% of the adult isoforms. The alternatively spliced exon 12, corresponding to a central variable region between the two functional domains of TnT, was found in approx. 79% of the 52 mouse cardiac TnT cDNAs with a single base mutation completely abolishing the splicing at an internal acceptor site. Three novel alternative splicing acceptor sites in the 5'-untranslated portion of exon 2 have been identified with different frequencies.     

Microtubule bundling by tau proteins in vivo: analysis of functional domains.

Tau varies both in the N-terminal region (three types) and in the C-terminal repeated microtubule binding domain (two types), generating six isoforms through alternative splicing. To understand the differences between the isoforms and to determine which domains are important for microtubule bundling, we performed transfection studies on fibroblasts using tau isoforms and deletion mutants to quantify their ability to bundle microtubules. By comparing the isoforms, we found that a longer N-terminal region induced microtubule bundling more efficiently, but changes in the microtubule binding domain did not. Mutants lacking the proline rich region or the repeated domain did not bind to microtubules. Although all the other mutants could bind to and bundle microtubules, deletion in the N-terminal neutral region or the first half of the C-terminal tail caused a significant decrease in microtubule bundling, indicating the importance of these regions in microtubule bundling.     

Identification, expression pattern, and subcellular location of human RIP isoforms

XRIP alpha was identified as an adapter protein involved in RAP nuclear import. Several homologs were reported in mammal EST analysis, but the expression pattern and genomic organization of hRIP isoforms were not clarified yet. We isolated nine isoforms of hRIP from a premade human fetal brain library. hRIP alpha is the longest isoform with 219 residues, containing a N-terminal arginine-rich basic region, followed by an acidic region and two C-terminal Zn finger-like structures. hRIP beta deletes one Zn-finger-like structure. Three hRIP alpha isoforms and four hRIP sigma isoforms express truncated proteins due to frame shift. hRIP gamma isoforms lost the C-terminal Zn-finger-like structure. hRIP delta isoforms only contain the N-terminal arginine-rich basic region and the core sequence of the acidic region. The genomic organization of hRIP was identified by bioinformatic analysis. hRIP, containing seven exons, is located at human chromosome 17p13. hRIP was expressed in all 16 detected human tissues with a similar pattern. All EGFP-hRIP fusion proteins were located at the nucleus in the HEK293 cell. The two-polar molecular structure of hRIP might be involved in the basic cell function, and plays a role in the alternative nuclear ingress.     

Determination and analyses of the N-termini of oil-body proteins, steroleosin, caleosin and oleosin.

Seed oil bodies comprise a triacylglycerol matrix shielded by a monolayer of phospholipids and proteins. These surface proteins include an abundant structural protein, oleosin, and at least two minor protein classes termed caleosin and steroleosin. Two steroleosin isoforms (41 and 39 kDa), one caleosin (27 kDa), and two oleosin isoforms (17 and 15 kDa) have been identified in oil bodies isolated from sesame seeds. The signal peptides responsible for targeting of these proteins to oil bodies have not been experimentally determined. Hydropathy analyses indicate that the hydrophobic domain putatively responsible for oil-body anchoring is located in the N-terminal region of steroleosin, but in the central region of caleosin or oleosin. Direct amino acid sequencing showed that both steroleosin isoforms possessed a free methionine residue at their N-termini while caleosin and oleosin isoforms were N-terminally blocked. Mass spectrometry analyses revealed that N-termini of both caleosin and 17 kDa oleosin were acetylated after the removal of the first methionine. In addition, deamidation was observed at a glutamine residue in the N-terminal region of 17 kDa oleosin.     

Cardiac troponin T isoforms affect the Ca2+ sensitivity and inhibition of force development. Insights into the role of troponin T isoforms in the heart

At least four isoforms of troponin T (TnT) exist in the human heart, and they are expressed in a developmentally regulated manner. To determine whether the different N-terminal isoforms are functionally distinct with respect to structure, Ca(2+) sensitivity, and inhibition of force development, the four known human cardiac troponin T isoforms, TnT1 (all exons present), TnT2 (missing exon 4), TnT3 (missing exon 5), and TnT4 (missing exons 4 and 5), were expressed, purified, and utilized in skinned fiber studies and in reconstituted actomyosin ATPase assays. TnT3, the adult isoform, had a slightly higher alpha-helical content than the other three isoforms. The variable region in the N terminus of cardiac TnT was found to contribute to the determination of the Ca(2+) sensitivity of force development in a charge-dependent manner; the greater the charge the higher the Ca(2+) sensitivity, and this was primarily because of exon 5. These studies also demonstrated that removal of either exon 4 or exon 5 from TnT increased the cooperativity of the pCa force relationship. Troponin complexes reconstituted with the four TnT isoforms all yielded the same maximal actin-tropomyosin-activated myosin ATPase activity. However, troponin complexes containing either TnT1 or TnT2 (both containing exon 5) had a reduced ability to inhibit this ATPase activity when compared with wild type troponin (which contains TnT3). Interestingly, fibers containing these isoforms also showed less relaxation suggesting that exon 5 of cardiac TnT affects the ability of Tn to inhibit force development and ATPase activity. These results suggest that the different N-terminal TnT isoforms would produce different functional properties in the heart that would directly affect myocardial contraction.     

M.(phi)BssHII, a novel cytosine-C5-DNA-methyltransferase with target-recognizing domains at separated locations of the enzyme.

In all cytosine-C5-DNA-methyltransferases (MTases) from prokaryotes and eukaryotes, remarkably conserved amino acid sequence elements responsible for general enzymatic functions are arranged in the same canonical order. In addition, one variable region, which includes the target-recognizing domain(s) (TRDs) characteristic for each enzyme, has been localized in one region between the same blocks of these conserved elements. This conservation in the order of conserved and variable sequences suggests stringent structural constraints in the primary structure to obtain the correct folding of the enzymes. Here we report the characterization of a new type of a multispecific MTase, M.(phiphi)BssHII, which is expressed as two isoforms. Isoform I is an entirely novel type of MTase which has, in addition to the TRDs at the conventional location, one TRD located at a non-canonical position at its N-terminus. Isoform II is represented by the same MTase, but without the N-terminal TRD. The N-terminal TRD provides HaeII methylation specificity to isoform I. The TRD is fully functional when engineered into either the conventional variable region of M.(phiphi)BssHII or the related monospecific M.phi3TII MTase. The implications of this structural plasticity with respect to the evolution of MTases are discussed.     

Large-scale analysis of human alternative protein isoforms: pattern classification and correlation with subcellular localization signals

We investigated human alternative protein isoforms of >2600 genes based on full-length cDNA clones and SwissProt. We classified the isoforms and examined their co-occurrence for each gene. Further, we investigated potential relationships between these changes and differential subcellular localization. The two most abundant patterns were the one with different C-terminal regions and the one with an internal insertion, which together account for 43% of the total. Although changes of the N-terminal region are less common than those of the C-terminal region, extension of the C-terminal region is much less common than that of the N-terminal region, probably because of the difficulty of removing stop codons in one isoform. We also found that there are some frequently used combinations of co-occurrence in alternative isoforms. We interpret this as evidence that there is some structural relationship which produces a repertoire of isoformal patterns. Finally, many terminal changes are predicted to cause differential subcellular localization, especially in targeting either peroxisomes or mitochondria. Our study sheds new light on the enrichment of the human proteome through alternative splicing and related events. Our database of alternative protein isoforms is available through the internet.     

LAP2 binds to BAF.DNA complexes: requirement for the LEM domain and modulation by variable regions

LAP2 belongs to a family of nuclear membrane proteins sharing a 43 residue LEM domain. All LAP2 isoforms have the same N-terminal 'constant' region (LAP2-c), which includes the LEM domain, plus a C-terminal 'variable' region. LAP2-c polypeptide inhibits nuclear assembly in Xenopus extracts, and binds in vitro to barrier-to-autointegration factor (BAF), a DNA-bridging protein. We tested 17 Xenopus LAP2-c mutants for nuclear assembly inhibition, and binding to BAF and BAF small middle dotDNA complexes. LEM domain mutations disrupted all activities tested. Some mutations outside the LEM domain had no effect on binding to BAF, but disrupted activity in Xenopus extracts, suggesting that LAP2-c has an additional unknown function required to inhibit nuclear assembly. Mutagenesis results suggest that BAF changes conformation when complexed with DNA. The binding affinity of LAP2 was higher for BAF small middle dotDNA complexes than for BAF, suggesting that these interactions are physiologically relevant. Nucleoplasmic domains of XENOPUS: LAP2 isoforms varied 9-fold in their affinities for BAF, but all isoforms supershifted BAF small middle dotDNA complexes. We propose that the LEM domain is a core BAF-binding domain that can be modulated by the variable regions of LAP2 isoforms.     

Substitution of the N-terminal segment of the plasma membrane Ca pump isoform 4 by that of isoform 1 results in a fully functional chimeric enzyme.

The N-terminal segment of the plasma membrane Ca2+ pump (PMCA) is one of the most variable regions among the four isoforms of the enzyme and its functional importance is unknown. In the present work, the N-terminal segment of the highly active C-terminally truncated h4 mutant, h4(ct120) was modified either by substituting residues 18-43 by residues 43-75 or by replacing residues 1-75 by the homologous region from isoform h1 (residues 1-79). Immunoblot analysis of microsomal membranes from transfected COS-1 cells showed that the two N-terminally mutated proteins were correctly expressed at a level similar to that of h4(ct120). Measurements of the Ca2+ uptake by microsomal vesicles from transfected COS-1 cells indicated that mutant (18-43-->43-75)h4(ct120) had only negligible Ca2+ transport activity while the chimeric (n1-79)h1h4(ct120) enzyme was fully capable of functioning as a calcium pump.Like h4(ct120), the chimeric mutant was not stimulated further by calmodulin, and was inhibited to a similar degree by the C28R2 peptide corresponding to the calmodulin binding autoinhibitory region of the pump. Moreover, the apparent affinity for Ca2+ and the ATP dependence of the chimeric enzyme were similar to those of the h4(ct120) pump suggesting that the variability of sequence between the N-terminal segment of PMCA isoforms h1 and h4 involves amino acid substitutions that do not substantially change the behavior of the h4 enzyme. Altogether, these results demonstrate that for activity the h4 Ca pump requires a specific amino acid sequence at its N-terminus, and the essential elements for a fully active enzyme can be provided by the N-terminal segment of isoform h1 despite the variability.     

Divergent N-terminal sequences target an inducible testis deubiquitinating enzyme to distinct subcellular structures

Ubiquitin-specific processing proteases (UBPs) presently form the largest enzyme family in the ubiquitin system, characterized by a core region containing conserved motifs surrounded by divergent sequences, most commonly at the N-terminal end. The functions of these divergent sequences remain unclear. We identified two isoforms of a novel testis-specific UBP, UBP-t1 and UBP-t2, which contain identical core regions but distinct N termini, thereby permitting dissection of the functions of these two regions. Both isoforms were germ cell specific and developmentally regulated. Immunocytochemistry revealed that UBP-t1 was induced in step 16 to 19 spermatids while UBP-t2 was expressed in step 18 to 19 spermatids. Immunoelectron microscopy showed that UBP-t1 was found in the nucleus while UBP-t2 was extranuclear and was found in residual bodies. For the first time, we show that the differential subcellular localization was due to the distinct N-terminal sequences. When transfected into COS-7 cells, the core region was expressed throughout the cell but the UBP-t1 and UBP-t2 isoforms were concentrated in the nucleus and the perinuclear region, respectively. Fusions of each N-terminal end with green fluorescent protein yielded the same subcellular localization as the native proteins, indicating that the N-terminal ends were sufficient for determining differential localization. Interestingly, UBP-t2 colocalized with anti-gamma-tubulin immunoreactivity, indicating that like several other components of the ubiquitin system, a deubiquitinating enzyme is associated with the centrosome. Regulated expression and alternative N termini can confer specificity of UBP function by restricting its temporal and spatial loci of action.     

Cloning and Localization of Exon 5-Containing Isoforms of the NMDAR1 Subunit in Human and Rat Brains

Abstract: Nine isoforms of the rat NMDAR1 receptor subunit have been previously identified, of which several have an alternatively spliced N-terminal insert believed to be important in proton sensitivity of the receptor. The cloning of the human homologues of NMDAR1-3b (hNMDA1-1) and NMDAR1-4b (hNMDA1-2), both bearing the insert, is reported here. A monoclonal antibody generated against the N-terminal region of these isoforms showed reactivity with at least two distinct human brain proteins of ∼115 kDa. This antibody was further characterized by using a series of truncated fusion proteins and splice variants of NMDAR1 demonstrating its specific recognition of an epitope within the 21-amino acid N-terminal insert, encoded by exon 5. Western blot and immunocytochemical studies were performed to examine the expression of the exon 5-containing isoforms of the NMDAR1 subunit in both rat and human brain.     

A double S shape provides the structural basis for the extraordinary binding specificity of Dscam isoforms

Drosophila Dscam encodes a vast family of immunoglobulin (Ig)-containing proteins that exhibit isoform-specific homophilic binding. This diversity is essential for cell recognition events required for wiring the brain. Each isoform binds to itself but rarely to other isoforms. Specificity is determined by "matching" of three variable Ig domains within an approximately 220 kD ectodomain. Here, we present the structure of the homophilic binding region of Dscam, comprising the eight N-terminal Ig domains (Dscam(1-8)). Dscam(1-8) forms a symmetric homodimer of S-shaped molecules. This conformation, comprising two reverse turns, allows each pair of the three variable domains to "match" in an antiparallel fashion. Structural, genetic, and biochemical studies demonstrate that, in addition to variable domain "matching," intramolecular interactions between constant domains promote homophilic binding. These studies provide insight into how "matching" at all three pairs of variable domains in Dscam mediates isoform-specific recognition.     

The N-terminal region of neuregulin isoforms determines the accumulation of cell surface and released neuregulin ectodomain

Two neuregulin-1 isoforms highly expressed in the nervous system are the type III neuregulin III-beta1a and the type I neuregulin I-beta1a. The sequence of these two isoforms differs only in the region that is N-terminal of the bioactive epidermal growth factor-like domain. While the biosynthetic processing of the I-beta1a isoform has been well characterized, the processing of III-beta1a has not been reported. In this study, we compared III-beta1a and I-beta1a processing. Both III-beta1a and I-beta1a were synthesized as transmembrane proproteins that were proteolytically cleaved to produce an N-terminal fragment containing the bioactive epidermal growth factor-like domain. For I-beta1a, this product was released into the medium. However, for III-beta1a, this product was a transmembrane protein. In cultures of cells expressing III-beta1a, the amount of neuregulin at the cell surface was much greater, and the amount in the medium was much less than in cultures expressing I-beta1a. Phorbol ester treatment and truncation of the cytoplasmic tail had markedly different effects on III-beta1a and I-beta1a processing. These results demonstrate an important role for the N-terminal region in determining neuregulin biosynthetic processing and show that a major product of III-beta1a processing is a tethered ligand that may act as a cell surface signaling molecule.     

An unstable head-rod junction may promote folding into the compact off-state conformation of regulated myosins

The N-terminal region of myosin's rod-like subfragment 2 (S2) joins the two heads of this dimeric molecule and is key to its function. Previously, a crystal structure of this predominantly coiled-coil region was determined for a short fragment (51 residues plus a leucine zipper) of the scallop striated muscle myosin isoform. In that study, the N-terminal 10-14 residues were found to be disordered. We have now determined the structure of the same scallop peptide in three additional crystal environments. In each of two of these structures, improved order has allowed visualization of the entire N-terminus in one chain of the dimeric peptide. We have also compared the melting temperatures of this scallop S2 peptide with those of analogous peptides from three other isoforms. Taken together, these experiments, along with examination of sequences, point to a diminished stability of the N-terminal region of S2 in regulated myosins, compared with those myosins whose regulation is thin filament linked. It seems plain that this isoform-specific instability promotes the off-state conformation of the heads in regulated myosins. We also discuss how myosin isoforms with varied thermal stabilities share the basic capacity to transmit force efficiently in order to produce contraction in their on states.     

Relationship of the flavodoxin isoforms from Porphyra umbilicalis.

The macroalga Porphyra umbilicalis contained two flavodoxins in approximately 5:1 ratio and differing in Mr by ca 1000. The N-terminal sequences of the isoforms were identical and there was strong immunochemical identity. Peptide mapping gave similar fragments which differed in Mr by constant amount for the two isoforms. The flavodoxins may therefore differ only at the C-terminus, possibly as a consequence of in vivo processing since inclusion of protease inhibitors during extraction had no effect on the ratio of the isoforms.     

Structural organization of distinct domains within the non-collagenous N-terminal region of collagen type XI

Collagen XI is a heterotrimeric molecule found predominantly in heterotypic cartilage fibrils, where it is involved in the regulation of fibrillogenesis. This function is thought to involve the complex N-terminal domain. The goal of this current study was to examine its structural organization to further elucidate the regulatory mechanism. The amino-propeptide (alpha1-Npp) alone or with isoforms of the variable region were recombinantly expressed and purified by affinity and molecular sieve chromatography. Cys-1-Cys-4 and Cys-2-Cys-3 disulfide bonds were detected by liquid chromatography-tandem mass spectrometry. This pattern is identical to the homologous alpha2-Npp, indicating that the recombinant proteins were folded correctly. Anomalous elution on molecular sieve chromatography suggested that the variable region was extended, which was confirmed using rotary shadowing; the alpha1-Npp formed a globular "head" and the variable region an extended "tail." Circular dichroism spectra analysis determined that the alpha1-Npp comprised 33% beta-sheet, whereas the variable region largely comprised non-periodic structure. Taken together, these results imply that the alpha1-Npp cannot be accommodated within the core of the fibril and that the variable region and/or minor helix facilitates its exclusion to the fibril surface. This provides further support for regulation of fibril diameter by steric hindrance or by interactions with other matrix components that affect fibrillogenesis.     

Comparative characterization of hyperglycemic neuropeptides from the lobster Homarus americanus

With the use of a two-step HPLC purification procedure, two sets of two isoforms of the crustacean hyperglycemic hormone (CHH) were isolated from sinus glands of the lobster Homarus americanus. Structural differences between the two groups of isoforms were found in their amino acid sequences, amino acid compositions and precise molecular weights. Using peptide mapping, the difference between the isoforms in each group was located within the first eight amino acids at the N-termini. The nature of this difference remained unclear as all four peptides had the same N-terminal amino acid sequence unto residue 19.     

Genomic organization of the human retinoic acid receptor beta 2.

Recently three isoforms of the mouse retinoic acid receptor (mRAR beta 1, mRAR beta 2, mRAR beta 3) have been described, generated from the same gene (Zelent et al., 1991). The isoforms differ in their 5'-untranslated (5'-UTR) and A region, but have identical B to F regions. The N-terminal variability of mRAR beta 1/beta 3 is encoded in the first two exons (E1 and E2), while exon E3 includes N-terminal sequences of the mRAR beta 2 isoform. We have determined the structure of the human RAR beta 2 gene, using a genomic library from K562 cells. The open reading frame is split into eight exons: E3 contains sequences for the N-terminal A region and E4 to E10 encode the common part of the receptor, including the DNA-binding domain and ligand-binding domain. Corresponding to other nuclear receptors, both 'zinc-fingers' of the DNA-binding domain are encoded separately in two exons and the ligand-binding domain is assembled from five exons.