Derivatization of posttranslationally modified amino acids

After a brief overview of posttranslational modifications of protein amino acids, the use of various derivatizing reagents for amino acid analysis is discussed. Derivatization and chromatographic separation of hydroxyproline, methylhistidine, and phosphorylated amino acids are discussed in detail to illustrate some of the strategies that can be applied to the analysis of posttranslationally modified amino acids.     

The amino terminus of high-voltage-activated calcium channels

Voltage-gated calcium channels (VGCCs), calmodulin (CaM), and calmodulin kinase II (CaMKII) are essential for various nervous system functions. CaM and CaMKII differentially regulate calcium dependent facilitation (CDF) and calcium dependent inactivation (CDI) of the Cav1 and Cav2 families of VGCCs. It is generally accepted that conserved structures in the C-terminus of these channels regulate CDF and CDI, and yet recent evidence indicates that other intracellular regions may be involved. We recently discovered that N-terminal sequences in Cav1.2 bind CaM and CaMKII, and function to regulate CDI as well as surface expression and open probability, respectively. Cav1 and Cav2 share significant portions of N-terminal sequence and therefore we explored whether homologous binding sites might exist in Cav2.1. Here, we show that like the proximal N-terminus of Cav1.2, the homologous region of Cav2.1 contains sequences which interact either directly or indirectly with CaM.     

Co-translational targeting and translocation of the amino terminus of opsin across the endoplasmic membrane requires GTP but not ATP

The tight coupling between ongoing translation and translocation across the mammalian endoplasmic reticulum has made it difficult to determine the requirements that are specific for translocation. We have developed an in vitro assay that faithfully mimics the co-translational targeting and translocation of the amino terminus of opsin without ongoing translation. Using this system we demonstrate that this post-translational targeting and translocation requires nucleotide triphosphates but not cytosolic proteins. The addition of GTP alone was sufficient to fully restore targeting. The addition of ATP was not specifically required, and non-hydrolyzable analogs of ATP that blocked 90% of the ATPase activity also had no inhibitory effect on translocation.     

The amino terminus of the aspartate chemoreceptor is formylmethionine

The amino terminus of the Salmonella typhimurium aspartate receptor has been identified as formylmethionine by mass spectral analysis of the amino-terminal tryptic peptide. Purification and analysis of the blocked amino-terminal peptide was facilitated by the use of a mutant aspartate receptor which has a cysteine residue at position 3. The sequence of this peptide confirms the translational start site predicted from the nucleotide sequence of the tar gene. Furthermore, in vivo labeling experiments reveal that the formyl group is present on chemotaxis receptors produced at wild-type levels in Escherichia coli, indicating that the presence of the formyl group is not a consequence of over-production of the receptor. The stability of the amino-terminal formyl group on the receptor may be a consequence of the membrane localization of the receptor and the dependence of this localization on the membrane transport machinery of the cell.     

The site of amino acid addition to posttranslationally modified proteins of regenerating rat sciatic nerves

The posttranslational modification of proteins by amino acids has been described in a variety of biological systems. These reactions occur at low levels in intact sciatic nerves of rats but are increased 10-fold following nerve injury and during subsequent regeneration of the nerve. While it has been shown in brain and liver that the site of addition of Arg is to the N-terminus, there is no information on the location at which the other amino acids add on to targeted proteins nor the site of addition of Arg in regenerating nerves. In the present study, we have used manual micro-Edman degradation combined with HPLC, and digestion with carboxypeptidase A and B to determine the site of addition of various amino acids to targeted proteins. Of the 3H-labelled amino acids incorporated posttranslationally into proteins of regenerating sciatic nerves (Arg, Lys, Leu, Phe, Val, Ala, Pro and Ser), only [3H]Arg was found to be present at the N-terminus. To determine whether amino acid additions were occurring at the C-terminus, proteins modified by two of the amino acids incorporated in greatest amounts (Lys and Leu) were incubated with specific carboxypeptidases. [3H]Leucine was not liberated following incubation with carboxypeptidase, suggesting that Leu is not added at the C-terminus of modified proteins. Under similar conditions, some [3H]Lys was liberated, but in amounts not significantly different from controls incubated without carboxypeptidase, indicating a non-specific degradation of Lys modified proteins rather than a specific release of Lys from the C-terminus. These experiments show that in regenerating sciatic nerves of rats, Arg is the only amino acid added posttranslationally to the amino terminus of target proteins, and that Leu, and probably Lys, are not conjugated to proteins at the C-terminus.     

The amino terminus of the yeast F1-ATPase beta-subunit precursor functions as a mitochondrial import signal

The ATP2 gene of Saccharomyces cerevisiae codes for the cytoplasmically synthesized beta-subunit protein of the mitochondrial F1-ATPase. To define the amino acid sequence determinants necessary for the in vivo targeting and import of this protein into mitochondria, we have constructed gene fusions between the ATP2 gene and either the Escherichia coli lacZ gene or the S. cerevisiae SUC2 gene (which codes for invertase). The ATP2-lacZ and ATP2-SUC2 gene fusions code for hybrid proteins that are efficiently targeted to yeast mitochondria in vivo. The mitochondrially associated hybrid proteins fractionate with the inner mitochondrial membrane and are resistant to proteinase digestion in the isolated organelle. Results obtained with the gene fusions and with targeting-defective ATP2 deletion mutants provide evidence that the amino-terminal 27 amino acids of the beta-subunit protein precursor are sufficient to direct both specific sorting of this protein to yeast mitochondria and its import into the organelle. Also, we have observed that certain of the mitochondrially associated Atp2-LacZ and Atp2-Suc2 hybrid proteins confer a novel respiration-defective phenotype to yeast cells.     

Unusual metabolism of the yeast actin amino terminus

In this paper we have examined the post-translational modifications of the NH2 terminus of actin from the yeast Saccharomyces cerevisiae. Like actins examined previously, this actin contains an acetylated NH2 terminus. Actins in other organisms undergo a unique post-translational processing event in which the initial amino acid(s) are removed by an actin-specific processing enzyme in an acetylation-dependent reaction. This is defined as actin processing. In yeast, actin retains its initiator Met in vivo and is thus not processed even though a rat liver actin processing enzyme can process yeast actin in vitro. This lack of actin processing appears to be a general property of fungi, as the actin from three other species, Aspergillus nidulans, Schizosaccharomyces pombe, and Candida albicans are not NH2 terminally processed either. Yeast actin is a class I actin; its initiator Met directly precedes an acidic residue. We converted yeast actin to a class II species by inserting a Cys codon between the Met-1 and Asp-2 codons. In normal class II actins the Cys residue is removed as acetyl-Cys during processing. Neither the mutant actin nor chick beta-actin (a class I actin) are processed when expressed in yeast. S. cerevisiae thus appears to be also incapable of processing exogenous actins. Further study of the mutant actin containing a Cys at position 2 shows that 30-40% of this actin is stably unacetylated. This unacetylated actin does not have a shorter half-life than the acetylated form. From these studies we conclude that 1) NH2-terminal actin-specific processing is not required for actin function in yeast and three other fungi, 2) yeast are apparently incapable of processing any type of actin precursor, and 3) the stability of a yeast pseudo-class II actin is not affected by the acetylation state of the NH2 terminus.     

Tau polymerization: role of the amino terminus

The abnormal polymerization of the tau molecule into insoluble filaments is a seminal event in the neurodegenerative process underlying Alzheimer's disease. Previous experimentation has shown that the microtubule-binding repeat region of the molecule is vital for its ability to polymerize in vitro into filaments similar to those found in Alzheimer's disease. However, it is becoming clear that regions outside the microtubule-binding repeat, such as exons 2 and 3 and the carboxy-terminal tail, can greatly influence its polymerization. Since it has been previously postulated that the amino terminus of tau could be involved in generating pathological conformations in the disease state, its role in the polymerization process was investigated. This report demonstrates that the removal of the amino terminus greatly inhibits the polymerization of the tau molecule, reducing both the rate and extent of polymerization. These results support the hypothesis that the ability of tau to form specific conformations involving the amino terminus is an early event in the formation of tau polymers in the disease state. Furthermore, the mutation of arginine 5 to leucine ((R)5(L)), mimicking an amino-terminal tau mutation found in a single case of FTDP-17, enhances the polymerization of the tau molecule. Therefore, the amino terminus of the tau molecule, while largely overlooked in studies of its polymerization, is a significant contributor to the polymerization process.     

The amino terminus regulates binding to and activation of cGMP-dependent protein kinase

The allosteric regulation of binding to and the activation of cGMP-dependent protein kinase (cGMP kinase) was studied under identical conditions at 30 degrees C using three forms of cGMP-kinase which differed in the amino-terminal segment, e.g. native cGMP kinase, phosphorylated cGMP kinase which contained 1.4 +/- 0.4 mol phosphate/subunit and constitutively active cGMP kinase which lacked the amino-terminal dimerization domain. These three enzyme forms have identical kinetic constants, e.g. number of cGMP-binding sites, Km values for MgATP and the heptapeptide kemptide, and Vmax values. In the native enzyme, MgATP decreases the affinity for binding site 1. This effect is abolished by 1 M NaCl. In contrast, high concentrations of Kemptide increase the affinity of binding site 2 about fivefold. Under the latter conditions, identical Kd values of 0.2 microM were obtained for sites 1 and 2. Salt, MgATP and Kemptide do not affect the binding kinetics of the phosphorylated or the constitutively active enzyme, suggesting that allosteric regulation depends solely on the presence of a native amino-terminal segment. Cyclic GMP activates the native enzyme at Ka values which are identical with the Kd values for both binding sites. The activation of cGMP-dependent protein kinase is noncooperative but the Ka value depends on the substrate peptide concentration. These results show that the activity of cGMP kinase is primarily regulated by conformational changes within the amino-terminal domain.     

The amino terminus of muscle tropomyosin is a major determinant for function

The amino-terminal region of muscle tropomyosin is highly conserved among muscle and 284-residue non-muscle tropomyosins. Analysis of fusion and nonfusion striated alpha-tropomyosins and a mutant in which residues 1-9 have been deleted has shown that the amino terminus is crucial for function. The presence of 80 amino acids of a nonstructural influenza virus protein (NS1) on the amino terminus of tropomyosin allows magnesium-independent binding of tropomyosin to actin. The fusion tropomyosin inhibits the actomyosin S1 ATPase at all myosin S1 concentrations tested, indicating that the presence of the fusion peptide prevents myosin S1 from switching the actin filament from the inhibited to the potentiated state. Nonfusion tropomyosin, an unacetylated form, has no effect on the actomyosin S1 ATPase, though it regulates normally with troponin. Deletion of residues 1-9, which are believed to overlap with the carboxyl-terminal end of tropomyosin in the thin filament, results in loss of tropomyosin function. The mutant is unable to bind to actin, in the presence and absence of troponin, and it has no regulatory function. The removal of the first 9 residues of tropomyosin is much more deleterious than removal of the last 11 by carboxypeptidase digestion. We suggest that the structure of the amino-terminal region and acetylation of the initial methionine are crucial for tropomyosin function.     

Characterization of the promoter, signal sequence, and amino terminus of a secreted beta-galactosidase from "Streptomyces lividans"

The gene for a secreted 130-kilodalton beta-galactosidase from "Streptomyces lividans" has been cloned, its promoter, signal sequence, and amino terminal region have been localized, and their nucleotide sequence has been determined. The signal sequence extends over 56 amino acids and shows the characteristic-features of signal sequences, including a hydrophilic amino terminus followed by a hydrophobic core near the signal cleavage site. The secretion of beta-galactosidase depends on the presence of the signal sequence. beta-Galactosidase is the major protein in culture supernatants and extracts of strains expressing the cloned beta-galactosidase gene and represents a valuable tool in the study of protein secretion in Streptomyces spp.     

The rod transducin alpha subunit amino terminus is heterogeneously fatty acylated.

Rod transducin (Tr), a heterotrimeric GTP-binding protein composed of alpha, beta, and gamma subunits, couples photolysis of rhodopsin to the activation of cyclic GMP phosphodiesterase in the vertebrate visual signal transduction cascade. To determine if T alpha r is covalently modified, we analyzed tryptic fragments of bovine retinal T alpha r using electrospray mass spectrometry, liquid chromatography/mass spectrometry, tandem mass spectrometry, and gas chromatography. A novel heterogeneous fatty acylation was detected at the NH2 terminus. Four types of NH2-terminal tryptic fragments of T alpha r were isolated, and each contained either a lauroyl (C12:0), myristoyl (C14:0), (cis-delta 5)-tetradecaenoyl (C14:1) or (cis,cis-delta 5, delta 8)-tetradecadienoyl (C14:2) fatty acyl residue amide-linked to the NH2-terminal glycine residue. NH2-terminal fatty acylation does not anchor T alpha r permanently in the membrane, since T alpha r used in these experiments was eluted without detergent from rod outer segment membranes.     

Post-translational processing of the amino terminus affects actin function

We have studied the importance of N-terminal processing for normal actin function using the Drosophila Act88F actin gene transcribed and translated in vitro. Despite having different charges as determined by two-dimensional (2D) gel electrophoresis, Act88F expressed in vivo and in vitro in rabbit reticulocyte lysate bind to DNase I with equal affinity and are able to copolymerise with bulk rabbit actin equally well. Using peptide mapping and thin-layer electrophoresis we have shown that bestatin [( 3-amino-2-hydroxy-4-phenyl-butanoyl]-L-leucine), an inhibitor of aminopeptidases, can inhibit actin N-terminal processing in rabbit reticulocyte lysate. Although processed and unprocessed actins translated in vitro are able to bind to DNase I equally well, unprocessed actins are less able to copolymerise with bulk actins. This effect is more pronounced when bulk rabbit actin is used but is still seen with bulk Lethocerus actin. Also, the unprocessed actins reduce the polymerisation of the processed actin translated in vitro with the bulk rabbit actin. This suggests that individual actins do interact, even in non-polymerising conditions. The reduced ability of unprocessed actin to polymerise shows that correct post-translational modification of the N terminus is required for normal actin function.     

The amino terminus of the fourth cytoplasmic loop of rhodopsin modulates rhodopsin-transducin interaction

Rhodopsin is a seven-transmembrane helix receptor that binds and catalytically activates the heterotrimeric G protein transducin (G(t)). This interaction involves the cytoplasmic surface of rhodopsin, which comprises four putative loops and the carboxyl-terminal tail. The fourth loop connects the carboxyl end of transmembrane helix 7 with Cys(322) and Cys(323), which are both modified by membrane-inserted palmitoyl groups. Published data on the roles of the fourth loop in the binding and activation of G(t) are contradictory. Here, we attempt to reconcile these conflicts and define a role for the fourth loop in rhodopsin-G(t) interactions. Fluorescence experiments demonstrated that a synthetic peptide corresponding to the fourth loop of rhodopsin inhibited the activation of G(t) by rhodopsin and interacted directly with the alpha subunit of G(t). A series of rhodopsin mutants was prepared in which portions of the fourth loop were replaced with analogous sequences from the beta(2)-adrenergic receptor or the m1 muscarinic receptor. Chimeric receptors in which residues 310-312 were replaced could not efficiently activate G(t). The defect in G(t) interaction in the fourth loop mutants was not affected by preventing palmitoylation of Cys(322) and Cys(323). We suggest that the amino terminus of the fourth loop interacts directly with G(t), particularly with Galpha(t), and with other regions of the intracellular surface of rhodopsin to support G(t) binding.     

A potyvirus vector efficiently targets recombinant proteins to chloroplasts,mitochondria and nuclei in plant cells when expressed at the amino terminus of the polyprotein

Plant virus‐based expression systems allow quick and efficient production of recombinant proteins in plant biofactories. Among them, a system derived from tobacco etch virus (TEV; genus potyvirus) permits coexpression of equimolar amounts of several recombinant proteins. This work analyzed how to target recombinant proteins to different subcellular localizations in the plant cell using this system. We constructed TEV clones in which green fluorescent protein (GFP), with a chloroplast transit peptide (cTP), a nuclear localization signal (NLS) or a mitochondrial targeting peptide (mTP) was expressed either as the most amino‐terminal product or embedded in the viral polyprotein. Results showed that cTP and mTP mediated efficient translocation of GFP to the corresponding organelle only when present at the amino terminus of the viral polyprotein. In contrast, the NLS worked efficiently at both positions. Viruses expressing GFP in the amino terminus of the viral polyprotein produced milder symptoms. Untagged GFPs and cTP and NLS tagged amino‐terminal GFPs accumulated to higher amounts in infected tissues. Finally, viral progeny from clones with internal GFPs maintained the extra gene better. These observations will help in the design of potyvirus‐based vectors able to coexpress several proteins while targeting different subcellular localizations, as required in plant metabolic engineering.     

The amino terminus of polyomavirus middle T antigen is required for transformation.

In polyomavirus-transformed cells, pp60c-src is activated by association with polyomavirus middle T antigen. These complexes have a higher tyrosine kinase activity compared with that of unassociated pp60c-src. Genetic analyses have revealed that the carboxy-terminal 15 amino acids of pp60c-src and the amino-terminal half of middle T antigen are required for this association and consequent activation of the tyrosine kinase. To define in greater detail the borders of the domain in middle T antigen required for activation of pp60c-src, we constructed a set of unidirectional amino-terminal deletion mutants of middle T antigen. Analysis of these mutants revealed that the first six amino acids of middle T antigen are required for it to activate the kinase activity of pp60c-src and to transform Rat-1 fibroblasts. Analysis of a series of insertion and substitution mutants confirmed these observations and further revealed that mutations affecting the first four amino acids of middle T antigen reduced or abolished its capacity to activate the kinase activity of pp60c-src and to transform Rat-1 cells in culture. Our results suggest that the first four amino acids of middle T antigen constitute part of a domain required for activation of the pp60c-src tyrosyl kinase activity and for consequent cellular transformation.     

The sterol carrier protein-2 amino terminus: a membrane interaction domain.

Sterol carrier protein-2 (SCP2) is a small, 123 amino acid, protein postulated to play a role in intracellular transport and metabolism of lipids such as cholesterol, phospholipids, and branched chain fatty acids. While it is thought that interaction of SCP2 with membranes is necessary for lipid transfer, evidence for this possibility and identification of a membrane interaction domain within SCP2 has remained elusive. As shown herein with circular dichroism and a direct binding assay, SCP2 bound to small unilamellar vesicle (SUV) membranes to undergo significant alteration in secondary structure. The SCP2 amphipathic N-terminal 32 amino acids, comprised of two alpha-helical segments, were postulated to represent a putative phospholipid interaction site. This hypothesis was tested with a series of SCP2 N-terminal peptides, circular dichroism, and direct binding studies. The SCP2 N-terminal peptide (1-32)SCP2, primarily random coil in aqueous buffer, adopted alpha-helical structure upon interaction with membranes. The induction of alpha-helical structure in the peptide was maximal when the membranes contained a high mole percent of negatively charged phospholipid and of cholesterol. While deletion of the second alpha-helical segment within this peptide had no effect on formation of the first alpha-helix, it significantly weakened the peptide interaction with membranes. Substitution of Leu(20) with Glu(20) in the N-terminal peptide disrupted the alpha-helix structure and greatly weakened the peptide interaction with membranes. Finally, deletion of the first nine nonhelical amino acids had no effect either on formation of alpha-helix or on peptide binding to membranes. N-Terminal peptide (1-32)SCP2 competed with SCP2 for binding to SUV. These data were consistent with the N-terminus of SCP2 providing a membrane interaction domain that preferentially bound to membranes rich in anionic phospholipid and cholesterol.