The management of acute hip pain in the military: femoral neck stress fractures and tears of the acetabular labrum

Acute hip pain is a common presenting complaint amongst the military population. It can present in a variety of ways, with a broad range of differential diagnoses to consider. Most cases of acute hip pain in military patients tend to be traumatic in origin. Pathology within the hip can be a diagnostic challenge, as symptoms often overlap between differential diagnoses and examination findings are not always sensitive or specific. Any hip injury will potentially downgrade a military patient and can also be a significant cause of long-term morbidity. Being able to manage the patient with acute hip pain effectively will ensure that patients spend less time in the diagnostic chain and reach the definitive treatment they require to continue to carry out their primary role. This paper describes how best to manage military patients who present with acute hip pain. It covers the diagnostic challenges faced by clinicians, the differential diagnoses of acute hip pain and describes the management of some common injuries of the hip: tears of the acetabular labrum and femoral neck stress fractures.

Thermodynamics of the binding of biotin and some analogues by avidin

1. The reaction between avidin and biotin was found to be exothermic, DeltaH being -20.3kcal./mole of biotin bound. The corresponding value of DeltaH for streptavidin was -23kcal./mole. 2. The heat evolved was independent of the pH (between 5 and 9), of the buffer (borate or ammonia) and of the fractional saturation of the avidin with biotin. 3. The entropy change for the reaction was zero, and it is suggested that the entropy increase to be expected from hydrophobic interactions was counterbalanced by a decrease in entropy accompanying the formation of buried hydrogen bonds. 4. Modification of the potential hydrogen-bonding sites of the imidazolidone ring led to a decreased heat output and a positive entropy of reaction.

Structural and mechanistic implications of the amino acid sequence of calcium-transporting ATPases

Work is reviewed in which the amino acid sequences of two Ca2+-transporting ATPases of sarcoplasmic reticulum (SR) from slow (or cardiac) and fast skeletal muscle were determined from the nucleotide sequences of cloned cDNAs. Analysis of hydrophobicity and secondary structure, combined with the known shape derived from electron micrographs, leads to a model of five domains with functional implications. The major globular part of the molecule is in the cytoplasm and consists of one antiparallel and two parallel beta-sheet domains. One of the latter binds ATP, which, in the presence of Ca2+, phosphorylates an aspartic acid on the other domain. It is proposed that subsequent kinase-like movements are transmitted to the SR membrane via a penta-helical, calcium-binding stalk. The Ca2+ is first trapped and then translocated via the ten helices which constitute the transmembrane (channel) region. The difference in requirements for counter ions between the Ca2+- and Na+/K+-ATPases can be explained in terms of differing charge distributions in this channel.

Phospholamban domain IB forms an interaction site with the loop between transmembrane helices M6 and M7 of sarco(endo)plasmic reticulum Ca2+ ATPases

Transmembrane helix M6 of the sarco(endo)plasmic reticulum Ca2+ ATPase (SERCA) has been shown to form a site of interaction with phospholamban (PLN). Site-directed mutagenesis was carried out in the cytoplasmic loop (L67) between M6 and M7 in SERCA1a to detect other SERCA-PLN binding sites. Mutants N810A, D813A, and R822A had diminished ability to interact functionally with PLN, but only D813A and R822A had reduced physical interaction with PLN. PLN mutants R25A, Q26A, N27A, L28A, Q29A, and N30A had enhanced physical interaction with wild-type (wt) SERCA1a, but physical interaction of these PLN mutants with SERCA1a mutants D813A and R822A was reduced about 2.5 fold (range 1.44-2.82). Exceptions were the interactions of PLN N27A and N30A with SERCA1a D813A, which were reduced by 7.3- and 5.8-fold, respectively. A superinhibitory PLN deletion mutant, PLNDelta21-29, had strong physical interactions with SERCA1a and with SERCA1a mutant D813A. Physical interactions with SERCA1a and mutant D813A were sharply diminished, however, for the PLN deletion mutant, PLNDelta21-30, lacking PLN N30. Physical interactions between SERCA1a and a PLN-cytochrome b(5) chimera containing PLN residues 1-29 were much stronger than those between a PLN-cytochrome b(5) chimera containing PLN residues 1-21 and lacking N27. These results suggest that a SERCA1-PLN interaction site occurs between L67 of SERCA1a and domain IB of PLN, which involves SERCA1a D813 and PLN N27 and N30.

Multilocus analysis of extracellular putative virulence proteins made by group A Streptococcus: population genetics, human serologic response, and gene transcription

Species of pathogenic microbes are composed of an array of evolutionarily distinct chromosomal genotypes characterized by diversity in gene content and sequence (allelic variation). The occurrence of substantial genetic diversity has hindered progress in developing a comprehensive understanding of the molecular basis of virulence and new therapeutics such as vaccines. To provide new information that bears on these issues, 11 genes encoding extracellular proteins in the human bacterial pathogen group A Streptococcus identified by analysis of four genomes were studied. Eight of the 11 genes encode proteins with a LPXTG(L) motif that covalently links Gram-positive virulence factors to the bacterial cell surface. Sequence analysis of the 11 genes in 37 geographically and phylogenetically diverse group A Streptococcus strains cultured from patients with different infection types found that recent horizontal gene transfer has contributed substantially to chromosomal diversity. Regions of the inferred proteins likely to interact with the host were identified by molecular population genetic analysis, and Western immunoblot analysis with sera from infected patients confirmed that they were antigenic. Real-time reverse transcriptase-PCR (TaqMan) assays found that transcription of six of the 11 genes was substantially up-regulated in the stationary phase. In addition, transcription of many genes was influenced by the covR and mga trans-acting gene regulatory loci. Multilocus investigation of putative virulence genes by the integrated approach described herein provides an important strategy to aid microbial pathogenesis research and rapidly identify new targets for therapeutics research.

Modeling a dehalogenase fold into the 8-A density map for Ca(2+)-ATPase defines a new domain structure

Members of the large family of P-type pumps use active transport to maintain gradients of a wide variety of cations across cellular membranes. Recent structures of two P-type pumps at 8-A resolution have revealed the arrangement of transmembrane helices but were insufficient to reveal the architecture of the cytoplasmic domains. However, recent proposals of a structural homology with a superfamily of hydrolases offer a new basis for modeling these domains. In the current work, we have extended the sequence comparison for the superfamily and delineated domains in the 8-A density map of Ca(2+)-ATPase. The homology suggests a new domain structure for Ca(2+)-ATPase and, specifically, that the phosphorylation domain adopts a Rossman fold. Accordingly, the atomic structure of L-2 haloacid dehalogenase has been fitted into the relevant domain of Ca(2+)-ATPase. The resulting model suggests the existence of two ATP sites at the interface between two domains. Based on this new model, we are able to reconcile numerous results of mutagenesis and chemical cross-linking within the catalytic domains. Furthermore, we have used the model to predict the configuration of Mg.ATP at its binding site. Based on this prediction, we propose a mechanism, involving a change in Mg(2+) liganding, for initiating the domain movements that couple sites of ion transport to ATP hydrolysis.

Structure-function relationships in the Ca(2+)-binding and translocation domain of SERCA1: physiological correlates in Brody disease

Alanine-scanning mutagenesis of all amino acids in transmembrane helices M4, M5, M6 and M8, which contain known Ca2+ binding residues in the Ca(2+)-ATPase of skeletal muscle sarcoplasmic reticulum, revealed patches of mutation-sensitivity in M4, M5 and M6, but in M8. A six-residue motif, (E/D)GLPA(T/V), in M4 and M6 and its counterpart in M5 were highlighted by mutagenesis. Site-directed disulfide mapping of helices M4 and M6 demonstrated that these transmembrane helices associate as a right-handed coiled-coil. This structural information, combined with the earlier analysis of the association of each Ca2+ binding residue with either Ca2+ binding site I or site II, permitted the development of a "side-by-side" model for the two Ca2+ binding sites in the Ca(2+)-ATPase. In about half of Brody disease families, mutations create stop codons which delete all or part of the Ca2+ binding and translocation domain, resulting in loss of SERCA1 function and muscle disease.

Structure of the calcium pump from sarcoplasmic reticulum at 8-A resolution

The calcium pump from sarcoplasmic reticulum (Ca2+-ATPase) is typical of the large family of P-type cation pumps. These couple ATP hydrolysis with cation transport, generating cation gradients across membranes. Ca2+-ATPase specifically maintains the low cytoplasmic calcium concentration of resting muscle by pumping calcium into the sarcoplasmic reticulum; subsequent release is used to initiate contraction. No high-resolution structure of a P-type pump has yet been determined, although a 14-A structure of Ca2+-ATPase, obtained by electron microscopy of frozen-hydrated, tubular crystals, showed a large cytoplasmic head connected to the transmembrane domain by a narrow stalk. We have now improved the resolution to 8A and can discern ten transmembrane alpha-helices, four of which continue into the stalk On the basis of constraints from transmembrane topology, site-directed mutagenesis and disulphide crosslinking, we have made tentative assignments for these alpha-helices within the amino-acid sequence. A distinct cavity leads to the putative calcium-binding site, providing a plausible path for calcium release to the lumen of the sarcoplasmic reticulum.

Site-directed disulfide mapping of helices M4 and M6 in the Ca2+ binding domain of SERCA1a, the Ca2+ ATPase of fast twitch skeletal muscle sarcoplasmic reticulum

In an attempt to define the spatial relationships among SERCA1a transmembrane helices M4, M5, M6, and M8, involved in Ca2+ binding, all six cysteine residues were removed from predicted transmembrane sequences by substitution with Ser or Ala. The cysteine-depleted protein retained 44% of wild type Ca2+ transport activity. Pairs of cysteine residues were then reintroduced to determine whether their juxtaposition would result in the formation of disulfide cross-links between transmembrane helices. In initial studies designed to map the juxtaposition of Ca2+ binding residues, Cys was substituted for Glu309 or Gly310 in transmembrane sequence M4, in combination with the substitution of Cys for Glu771 in M5; for Asn796, Thr799, or Asp800 in M6; or for Glu908 in M8. These double mutants all retained the capacity to form a phosphoenzyme intermediate from Pi (but not from ATP in the presence of Ca2+), and in all but mutants E309C/N796C and G310C/N796C, phosphoenzyme formation was insensitive to 100 microM Ca2+. These results support the view that both Glu309 and Asn796 contribute to Ca2+ binding site II, which is not required for conversion of E2, the substrate for Pi phosphorylation, to E1. Cross-linking in mutants E309C/N796C and G310C/D800C established reference points for the orientation of M4 and M6 relative to each other and provided the basis for the prediction of potential additional cross-links. Strong links were formed with the pairs T317C/A804C and T317C/L807C near the cytoplasmic ends of the two helices and with A305C/L792C and A305C/L793C near the lumenal ends. These combined results support the conclusion that M4 and M6 form a right-handed coiled-coil structure that forms part of the pathway of Ca2+ translocation. In addition to providing a possible explanation for the mutation sensitivity of several pairs of residues in these helices, the proposed association of M4 and M6 supports a new model for the orientation of the two Ca2+ binding sites among transmembrane helices M4, M5, and M6.

Structure, transmembrane topology and helix packing of P-type ion pumps

Electron microscopy has recently provided improved structures for P-type ion pumps. In the case of Ca(2+)-ATPase, the use of unstained specimens revealed the structure of the transmembrane domain. The composition of this domain has been controversial due to the variety of methods used to study the number and exact locations of transmembrane crossings within the sequence. After reviewing the results from several members of the family, we found a consensus for 10 transmembrane segments, and also that 10 helices fitted well into the structure of Ca(2+)-ATPase. Thus, we present the most detailed model for transmembrane structure so far, in the hope of stimulating more precise experimental strategies.

A method for alpha-helical integral membrane protein fold prediction

Integral membrane proteins (of the alpha-helical class) are of central importance in a wide variety of vital cellular functions. Despite considerable effort on methods to predict the location of the helices, little attention has been directed toward developing an automatic method to pack the helices together. In principle, the prediction of membrane proteins should be easier than the prediction of globular proteins: there is only one type of secondary structure and all helices pack with a common alignment across the membrane. This allows all possible structures to be represented on a simple lattice and exhaustively enumerated. Prediction success lies not in generating many possible folds but in recognizing which corresponds to the native. Our evaluation of each fold is based on how well the exposed surface predicted from a multiple sequence alignment fits its allocated position. Just as exposure to solvent in globular proteins can be predicted from sequence variation, so exposure to lipid can be recognized by variable-hydrophobic (variphobic) positions. Application to both bacteriorhodopsin and the eukaryotic rhodopsin/opsin families revealed that the angular size of the lipid-exposed faces must be predicted accurately to allow selection of the correct fold. With the inherent uncertainties in helix prediction and parameter choice, this accuracy could not be guaranteed but the correct fold was typically found in the top six candidates. Our method provides the first completely automatic method that can proceed from a scan of the protein sequence databanks to a predicted three-dimensional structure with no intervention required from the investigator. Within the limited domain of the seven helix bundle proteins, a good chance can be given of selecting the correct structure. However, the limited number of sequences available with a corresponding known structure makes further characterization of the method difficult.

Identification of amino acid residues photolabeled with 8-azidoadenosine 5'-diphosphate in the catalytic site of sarcoplasmic reticulum Ca-ATPase

The photoreactive ADP analogue 8-N3-ADP binds in the dark to the catalytic site of the sarcoplasmic reticulum Ca-ATPase. An apparent Kd value of 30 microM has been deduced from competition with ADP in the presence of EGTA. Photoirradiation of Ca-ATPase with 8-N3-[3H]ADP in the presence of calcium results in irreversible inhibition of ATPase activity with corresponding stoichiometries of covalently and specifically photolabeled Ca-ATPase. The site of photolabeling of the Ca-ATPase in the presence of calcium has been explored. Controlled trypsin digestion of the labeled protein shows that 8-azido-ADP is incorporated in the B subfragment. Extensive trypsin digestion of the labeled protein releases a small peptide as revealed by gel filtration chromatography (Sephadex G-50). Further HPLC purification on a reverse-phase column (C8) eluted with a water/acetonitrile gradient buffered at pH 6 or at pH 2 gives a single labeled peptide. Edman degradation of that isolated peptide, as well as the amino acid composition, shows that it contains five amino acid residues (Val-530-Arg-534) with the radioactivity localized on Thr-532 and Thr-533.

A hypothetical model for the peptide binding domain of hsp70 based on the peptide binding domain of HLA

The sequences of the peptide binding domains of 33 70 kd heat shock proteins (hsp70) have been aligned and a consensus secondary structure has been deduced. Individual members showed no significant deviation from the consensus, which showed a beta 4 alpha motif repeated twice, followed by two further helices and a terminus rich in Pro and Gly. The repeated motif could be aligned with the secondary structure of the functionally equivalent peptide binding domain of human leucocyte antigen (HLA) class I maintaining equivalent residues in structurally important positions in the two families and a model was built based on this alignment. The interaction of this domain with the ATP domain is considered. The overall model is shown to be consistent with the properties of products of chymotryptic cleavage.

Calreticulin is a candidate for a calsequestrin-like function in Ca2(+)-storage compartments (calciosomes) of liver and brain

In a search for the non-muscle equivalent of calsequestrin (the low-affinity high-capacity Ca2(+)-binding protein responsible for Ca2+ storage within the terminal cisternae of the sarcoplasmic reticulum), acidic proteins were extracted from rat liver and brain microsomal preparations and purified by column chromatography. No calsequestrin was observed in these extracts, but the N-terminal amino acid sequence of the major Ca2(+)-binding protein of the liver microsomal fraction was determined and found to correspond to that of calreticulin. This protein was found to bind approx. 50 mol of Ca2+/mol of protein, with low affinity (average Kd approx. 1.0 mM). A monoclonal antibody, C6, raised against skeletal-muscle calsequestrin cross-reacted with calreticulin in SDS/PAGE immunoblots, but polyclonal antibodies reacted with native calreticulin only weakly, or not at all, after SDS denaturation. Immuno-gold decoration of liver ultrathin cryosections with affinity-purified antibodies against liver calreticulin revealed luminal labelling of vacuolar profiles indistinguishable from calciosomes, the subcellular structures previously identified by the use of anti-calsequestrin antibodies. We conclude that calreticulin is the Ca2(+)-binding protein segregated within the calciosome lumen, previously described as being calsequestrin-like. Because of its properties and intraluminal location, calreticulin might play a critical role in Ca2+ storage and release in non-muscle cells, similar to that played by calsequestrin in the muscle sarcoplasmic reticulum.

Molecular cloning of cDNA encoding the Ca2+ release channel (ryanodine receptor) of rabbit cardiac muscle sarcoplasmic reticulum

We have cloned and sequenced cDNA encoding the Ca2+ release channel (ryanodine receptor) of rabbit cardiac muscle sarcoplasmic reticulum. The cDNA, 16,532 base pairs in length, encodes a protein of 4,969 amino acids with a Mr of 564,711. The deduced amino acid sequence is 66% identical with that of the skeletal muscle ryanodine receptor, but analysis of predicted secondary structures and hydropathy plots suggests that the two isoforms exhibit the same topology in both transmembrane and cytoplasmic domains. A potential ATP binding domain was identified at residues 2619-2652, a potential phosphorylation site at residue 2809, and potential calmodulin binding sites at residues 2775-2807, 2877-2898, and 2998-3016. We suggest that a modulator binding domain in the protein lies between residues 2619 and 3016. Northern blot analysis of mRNA from a variety of tissues demonstrated that the cardiac isoform is expressed in heart and brain, while the skeletal muscle isoform is expressed in both fast- and slow-twitch muscle. No ryanodine receptor mRNA was detected in extracts from smooth muscle or any other non-muscle tissue examined. The two receptors are clearly the products of separate genes, and the gene encoding the cardiac muscle ryanodine receptor was localized to chromosome 1.

Structure of CaATPase: electron microscopy of frozen-hydrated crystals at 6 A resolution in projection

Thin, three-dimensional crystals of CaATPase have been studied at high resolution by electron crystallography. These crystals were grown by adding purified CaATPase to appropriate concentrations of lipid, detergent and calcium. A thin film of crystals was then rapidly frozen and maintained in the frozen-hydrated state during electron microscopy. The resulting electron diffraction patterns extend to 4.1 A resolution and images contain phase data to 6 A resolution. By combining Fourier amplitudes from electron diffraction patterns with phases from images, a density map has been calculated in projection. Comparison of this map from unstained crystals with a previously determined map from negatively stained crystals reveals distinct contributions from intramembranous and extramembranous protein domains. On the basis of this distinction and of the packing of molecules in the crystal, we have proposed a specific arrangement for the ten alpha-helices that have been suggested as spanning the bilayer.

Molecular cloning of cDNA encoding human and rabbit forms of the Ca2+ release channel (ryanodine receptor) of skeletal muscle sarcoplasmic reticulum

We have cloned cDNAs encoding the rabbit and human forms of the Ca2+ release channel of sarcoplasmic reticulum. The human cDNA encodes a protein of 5032 amino acids, with a molecular weight of 563,584, which is made without an NH2-terminal signal sequence. Amino acid substitutions between rabbit and human sequences were noted in 163 positions and deletions or insertions in eight regions accounted for additional sequence differences between the two proteins. Analysis of the sequence indicates that 10 potential transmembrane sequences in the COOH-terminal fifth of the molecule and two additional, potential transmembrane sequences nearer to the center of the molecule could contribute to the formation of the Ca2+ conducting pore. The remainder of the molecule is hydrophilic and presumably constitutes the cytoplasmic domain of the protein. A 114-120 amino acid motif is repeated four times in the protein, in residues 841-954, 955-1068, 2725-2844, and 2845-2958 and a 16 amino acid part of the motif is repeated twice more in residues 1344-1359 and 1371-1386. Although the channel is modulated by Ca2+, ATP, and calmodulin, no clear high affinity Ca2(+)-binding domain of the EF hand type and no clear high affinity ATP-binding domain were detected in the primary sequence. An acidic sequence in residues 1872-1923 contains 79% glutamate or aspartate residues and this sequence is a potential low affinity Ca2(+)-binding site. Several potential calmodulin-binding sites were observed in the sequence, in the region 2800 to 3050.

Three-dimensional crystals of CaATPase from sarcoplasmic reticulum. Symmetry and molecular packing

Structural studies of CaATPase from sarcoplasmic reticulum have so far been restricted to low resolution due to the poor order of two-dimensional crystal forms. However, we report that three-dimensional microcrystals of detergent-solubilized CaATPase diffract to 7.2 A in x-ray powder patterns and may therefore provide an opportunity to study CaATPase structure at higher resolutions. In the present study, we have characterized the symmetry and molecular packing of negatively stained crystals by electron microscopy (em). By altering the detergent-to-lipid ratio, different sized crystals were produced, which adhere to an em grid in different orientations. Thus, we obtained micrographs of three different projections and from these determined unit cell dimensions to be 151 X 51 X 158 A and the three-dimensional space group to be C2 with an angle beta very close to 90 degrees; x-ray powder patterns of hydrated, unstained crystals yielded dimensions of 166 X 58 X 164 A. Micrographs from each of two principal projections were averaged to produce two-dimensional density maps. Based on these maps and on the previously determined low-resolution structure of CaATPase, a packing diagram for these three-dimensional crystals is presented and major intermolecular contacts are proposed.

Molecular cloning and expression of cDNA encoding a lumenal calcium binding glycoprotein from sarcoplasmic reticulum

Antibody screening was used to isolate a cDNA encoding the 160-kDa glycoprotein of rabbit skeletal muscle sarcoplasmic reticulum. The cDNA is identical to that encoding the 53-kDa glycoprotein except that it contains an in-frame insertion of 1308 nucleotides near its 5' end, apparently resulting from alternative splicing. The protein encoded by the cDNA would contain a 19-residue NH2-terminal signal sequence and a 453-residue COOH-terminal sequence identical to the 53-kDa glycoprotein. It would also contain a 436-amino acid insert between these sequences. This insert would be highly acidic, suggesting that it might bind Ca2+. The purified 160-kDa glycoprotein and the glycoprotein expressed in COS-1 cells transfected with cDNA encoding the 160-kDa glycoprotein were shown to bind 45Ca2+ in a gel overlay assay. The protein was shown to be located in the lumen of the sarcoplasmic reticulum and to be associated through Ca2+ with the membrane. We propose that this lumenal Ca2+ binding glycoprotein of the sarcoplasmic reticulum be designated "sarcalumenin."

Evidence for the cytoplasmic location of the N- and C-terminal segments of sarcoplasmic reticulum (Ca2+-Mg2+)-ATPase

Antibodies were produced against 5 peptides corresponding to segments of the (Ca2+-Mg2+)-ATPase of fast-twitch rabbit skeletal muscle sarcoplasmic reticulum (SR) including the N- and C-terminal regions. With the exception of antibodies directed against the peptide corresponding to residues 567-582 all antibodies bound strongly to the ATPase in intact SR vesicles, indicating that the epitopes were located on the cytoplasmic face of the SR. When the vesicles were disrupted, by solubilisation in SDS, binding of these antibodies was unchanged, further supporting the idea that these epitopes were located on the cytoplasmic face of SR. This is the first demonstration of the location of the N- and C-terminal regions of SR (Ca2+-Mg2+)-ATPase. These observations are discussed in the light of current structural models of the ATPase.

Molecular cloning and expression of cDNA encoding the 53,000-dalton glycoprotein of rabbit skeletal muscle sarcoplasmic reticulum

The 53-kDa glycoprotein of rabbit skeletal muscle sarcoplasmic reticulum was purified by lentil lectin affinity chromatography and preparative polyacrylamide gel electrophoresis and partially sequenced. Polyclonal and monoclonal antibodies were raised against the 53-kDa glycoprotein and found to cross-react with the 160-kDa glycoprotein. A combination of antibody and synthetic oligonucleotide screening was used to isolate a cDNA encoding the 53-kDa glycoprotein of rabbit fast-twitch skeletal muscle sarcoplasmic reticulum. The cDNA encodes a protein of 453 amino acids with Mr of 52,421 and a 19-residue amino-terminal signal sequence. The deduced sequence contains two potential glycosylation sites and is largely hydrophilic. The presence of a glycine-rich sequence in the glycoprotein with homology to mononucleotide binding domains supports earlier observations that the glycoprotein binds ATP with high affinity. Although two sequences appear to be hydrophobic on a hydropathy plot, they are not sufficiently long nor sufficiently hydrophobic to qualify unambiguously as transmembrane sequences. The glycoprotein, like calsequestrin, was shown to be inaccessible to trypsin in intact sarcoplasmic reticulum. It can be eluted from the sarcoplasmic reticulum by extraction with [ethylenebis(oxyethylenenitrilo)]tetraacetic acid under hypotonic conditions. Thus, the glycoprotein appears to be localized entirely in the lumen of the sarcoplasmic reticulum and to be associated with the inner membrane surface through Ca2+-dependent mechanisms. Cotransfection of COS-1 cells with cDNAs encoding the glycoprotein and the Ca2+-ATPase led to expression of both proteins with a common localization in the microsomal fraction. The Ca2+ pumping activity of the microsomes isolated from transfected cells was unaltered by the presence of the glycoprotein. Thus the glycoprotein does not appear to modulate Ca2+-ATPase function.

The predicted secondary structures of the nucleotide-binding sites of six cation-transporting ATPases lead to a probable tertiary fold

Six cation-dependent transporting ATPases have homologous sequences in the region asigned by chemical labelling to nucleotide binding. Comparison of the most highly conserved segments with other nucleotide-binding domains showed that the sequences were consistent with a mononucleotide-binding fold and enabled a number of likely folding topologies to be limited to two or three alternatives. One of these possible folds was topologically equivalent to adenylate kinase; this was taken as a model in which the significance of conserved amino acids was investigated. In this model conserved amino acids were grouped around a postulated ATP-binding cleft, satisfactorily accounting for their degree of conservation.

The fast-twitch muscle calsequestrin isoform predominates in rabbit slow-twitch soleus muscle

The major form of calsequestrin in rabbit slow-twitch soleus muscle is shown to be identical to that isolated and cloned from rabbit fast-twitch muscle on the following bases: identity of cDNAs cloned from mRNAs from the two muscle sources; equivalent hybridization of a fast-twitch calsequestrin cDNA probe to mRNAs isolated from fast-twitch and slow-twitch muscles; identity of the 23 amino-terminal amino acids; strong binding of 45Ca2+ in a gel overlay of slow muscle sarcoplasmic reticulum protein to a band at the level of the fast-twitch calsequestrin isoform and only weak binding at the level of the cardiac isoform. No evidence was obtained for developmentally regulated alternative splicing of the calsequestrin transcript in mature slow or fast-twitch muscle.

Electron microscopy and structural model of human fibronectin receptor

Highly-purified human fibronectin receptor (a heterodimer of two distinct subunits, alpha and beta) was studied using electron microscopy and a variety of preparative procedures. It was found that the receptor consists of a globular head approximately 80 by 120 A and two tails about 20 A thick and 180-200 A long. The whole complex is approximately 280 A long. At low concentrations of detergent the receptor forms doublets, triplets or rosettes associated with the tails which possess the transmembrane portion of the molecule. Computer-assisted structure prediction using the published amino acid sequence of both subunits showed differences in the secondary structure of the tails, the alpha-tail being rich in beta-strands, the beta-tail having five cysteine-rich repeats analogous to the EGF-like repeats of laminin. Estimates of the length of the tails from the predicted structure conformed well with the dimensions obtained from electron micrographs.

Tryptic cleavage inhibits but does not uncouple Ca2+ATPase of sarcoplasmic reticulum

Sarcoplasmic reticulum Ca2+ATPase is cleaved by trypsin at two sites, T1 and T2. Cleavage at T1 is complete, whereas only about 50% of the Ca2+ATPase is digested at the T2 site. In the absence of Ca2+ ionophor, Ca2+-ATPase activity of the digested enzyme remains virtually unchanged. In the presence of Ca2+ ionophor, however, the calculated specific activity of the doubly cleaved Ca2+ATPase is decreased by about 40%. The decrease in Ca2+ transport activity is much more rapid than cleavage of the T2 site, and could be correlated with an increased leak of Ca2+ from the digested vesicles. We obtained evidence that this leakiness is independent of the digestion of the Ca2+ATPase itself and is presumably due to the digestion of some other components of the sarcoplasmic reticulum vesicles. Examination of steady-state phosphoenzyme levels resulting from phosphorylation by ATP and Pi, or dephosphorylation by ADP or ADP/EGTA revealed no difference between the digested and the undigested Ca2+ATPase indicating no change in the equilibria caused by the T2 cleavage. Analysis of the substrate concentration dependence of the Ca2+ATPase activity also led to the conclusion that the digestion at T2 reduced the Vmax of ATP hydrolysis but leaves the Km unchanged. The above results are consistent with the model that cleavage at the T2 site reduces the turnover rate of the Ca2+ATPase reaction cycle by about 40% by slowing down or altering the rate-limiting step without affecting the equilibrium constants of the examined steps. We found no evidence of true uncoupling of Ca2+ transport from ATP hydrolysis correlated with cleavage at the T2 site.

Structure of the rabbit fast-twitch skeletal muscle Ca2+-ATPase gene

We have isolated two genomic clones which together encode the Ca2+-ATPase of rabbit fast-twitch skeletal muscle sarcoplasmic reticulum. One of the two 16.5 kilobase (kb) genomic inserts in the lambda phage vector Charon 4A contains 23 exons extending from the polyadenylation site at the 3' end of the ATPase gene to within 38 nucleotides of the translation initiation codon in the 5' exon. An overlapping genomic insert of 16.5 kb contains the remainder of the 5' exon and a further 8 kb of upstream sequence. S1 nuclease mapping and primer extension analysis of the 5' end of the Ca2+-ATPase mRNA indicate that the transcription initiation site is located 185 base pairs (bp) upstream of the translation initiation codon. A "TATA" box (CA-TAAA) was found at position -30 and the sequence CCAAT was found at position -78 relative to the transcription initiation site. In a previous study (Brandl, C. J., de Leon, S., Martin, D. R., and MacLennan, D. H. (1987) J. Biol. Chem. 262, 3768-3774) cDNAs for neonatal and adult forms of the fast-twitch Ca2+-ATPase were shown to encode different carboxyl-terminal sequences, presumably as a result of alternative splicing. We have now found that these different DNA sequences encoding different carboxyl-terminal sequences are located in different exons. Exon boundaries of the Ca2+-ATPase gene did not correlate well with proposed domain boundaries for the Ca2+-ATPase protein. The locations of exon/intron boundaries were only partially conserved between the Ca2+-ATPase gene and a Na+/K+-ATPase gene (Ovchinnikov, Y. A., Monastyrskaya, G. S., Broude, N. E., Allikmets, R. L., Ushkaryov, Y. A., Melkov, A. M., Smirnov, Y. V., Malyshev, I. V., Dulubova, I. E., Petrukhin, K. E., Gryshin, A. V., Sverdlov, V. E., Kiyatkin, N. I., Kostina, M. B., Modyanov, N. N., and Sverdlov, E. D. (1987) FEBS Lett. 213, 73-80) and they did not follow closely the boundaries of amino acid sequences that are highly conserved among a group of ion transport ATPases.

Precursor-product relationship between vitellogenin and the yolk proteins as derived from the complete sequence of a Xenopus vitellogenin gene

In Xenopus laevis four estrogen-responsive genes are expressed simultaneously to produce vitellogenin, the precursor of the yolk proteins. One of these four genes, the gene A2, was sequenced completely, as well as cDNAs representing 75% of the coding region of the gene. From this data the exon-intron structure of the gene was established, revealing 35 exons that give a transcript of 5,619 bp without the poly A-tail. This A2 transcript encodes a vitellogenin of 1,807 amino acids, whose structure is discussed with respect to its function. At the nucleic acid as well as at the protein level no extensive homologies with any sequences other than vitellogenin were observed. Comparison of the amino acid sequence of the vitellogenin A2 molecule with biochemical data obtained from the different yolk proteins allowed us to localize the cleavage products on the vitellogenin precursor as follows: NH2 - lipovitellin I - phosvitin (or phosvette II - phosvette I) - lipovitellin II - COOH.

Does intrinsic fluorescence reflect conformational changes in the Ca2+-ATPase of sarcoplasmic reticulum?

We have investigated the kinetics of the intrinsic fluorescence drop observed when ATP is added to purified sarcoplasmic reticulum ATPase in a potassium-free medium containing magnesium and calcium, at pH 6 and 20 degrees C. Under these conditions, analysis of the fluorescence drop is complex. Several events contributed to the rate of the fluorescence drop initiated by turnover, including phosphorylation, conformational transition of the phosphorylated complex, and dephosphorylation. On the other hand, when 75% of total fluorescence was quenched by energy transfer to the membrane-bound ionophore A23187, the observed turnover-dependent drop in residual fluorescence mainly reflected the conformational transition of the phosphorylated ATPase. Combination of fast kinetics with the quenching of selected tryptophan residues is suggested to be a promising tool for the study of proteins containing many of these residues.

Primary structure of the nucleotide binding domain of the Ca,Mg-ATPase from cardiac sarcoplasmic reticulum

The nucleotide binding domain of the active site of the Ca,Mg-ATPase of cardiac sarcoplasmic reticulum (SR) has been isolated using fluorescein isothiocyanate (FITC) as an active site label and sequenced. After removal of non-specifically incorporated FITC with hydroxylamine, the amount of label incorporated was stoichiometric with residual ATPase activity, demonstrating that the label was incorporated uniquely at the active site. The SR was succinylated before digestion by trypsin in order to obtain a peptide of sufficient length to determine if the cardiac SR ATPase is a candidate for the unidentified cDNA clone recently sequenced by MacLennan et al. (Nature 316: 696-700, 1985). The sequence of the labeled SR peptide, obtained by affinity chromatography on a FITC antibody column, was T S M S K M F K G P E V I D R. This sequence was identical with that predicted by the unidentified clone and is significantly different from the sequence reported by Kirley et al. (Biochem. Biophys. Res. Commun. 130: 732-738, 1985) for a FITC labeled peptide isolated from cardiac SR.

Two Ca2+ ATPase genes: homologies and mechanistic implications of deduced amino acid sequences

Rabbit genomic DNA contains two genes that encode Ca2+ ATPases of fast twitch and of slow twitch (and cardiac) sarcoplasmic reticulum, respectively. The deduced amino acid sequences of the products of the two genes are highly conserved in putative Ca2+ binding regions, in sectors leading from cytoplasmic domains into transmembrane domains, and in transmembrane helices. A transport mechanism is proposed in which Ca2+ binds to negatively charged groups on amphipathic stalk sectors, becoming occluded during enzyme phosphorylation by bound ATP. Rotation of the stalk sectors is induced as the energy in the phosphorylated enzyme (E1P) is utilized in conformational changes leading to the low energy form, E2P. Rotation leads to disruption of high affinity Ca2+ binding sites and release of Ca2+ into a charge-lined membrane channel. Ca2+ then traverses the membrane by exchange diffusion.

The sequence of two peptides isolated from the Ca2+-transporting ATPase of rabbit sarcoplasmic reticulum after cleavage at tryptophan

Cleavage of reduced, carboxymethylated, delipidated CA2+-transporting ATPase protein from rabbit sarcoplasmic reticulum with dimethyl sulphoxide/HBr yielded two long peptides (38 and 73 residues), distinct from the known major sequences of the ATPase. The longer peptide contained at least two cysteine residues, which were disulphide-linked in the native protein. It was therefore derived from the B-fragment of the ATPase in which the disulphides had previously been located. It probably formed a loop on the luminal side of the membrane, spanning two membrane-buried tryptophan residues. The N-terminal sequence of this peptide, (Trp)-Phe-Met-Tyr-Ala, forms the basis for an oligodeoxynucleotide probe, the use of which to identify cDNA corresponding to the ATPase is described elsewhere [MacLennan, Brandl, Korczak & Green (1985) Nature (London) 316, 696-700].

Sequencing of laminin B chain cDNAs reveals C-terminal regions of coiled-coil alpha-helix

cDNAs for laminin B chains have been isolated from a parietal endoderm cDNA library in pUC8 and pUC9. Identification is based on: ability to direct the synthesis in Escherichia coli of polypeptides carrying laminin antigen determinants, in vitro translation of hybrid selected mRNA, and hybridization to high mol. wt. RNA differentially expressed in cells synthesizing large amounts of laminin. The plasmid pPE9 hybrid selects mRNA for the B2 (mol. wt. 185 000) chain and provides 217 residues of C-terminal amino acid sequence. The plasmids pPE386 and 49 both hybrid select mRNAs for the B1a (mol. wt. 205 000) and B1b (mol. wt. 200 000) chains. These two cDNAs are identical over much of their sequence, but pPE386 includes 133 nucleotides of 3' non-coding sequence and a poly(A) tail. Together they provide 495 residues of C-terminal amino acid sequence. Analysis of the predicted sequences reveals a striking heptad repeat, with a high probability that residues a and d are hydrophobic. Such a repeat is typical of the coiled-coil alpha-helices found in proteins such as myosin, tropomyosin and desmin (2-stranded) and fibrinogen (3-stranded).

Evidence for a repeating cross-beta sheet structure in the adenovirus fibre

The amino acid sequence of the adenovirus fibre protein reveals an approximately repeating motif of 15 residues. A diagonal comparison matrix established that these repeats extended from residue 43 to residue 400 of the 581 residue sequence. Assignment of secondary structure combined with model building showed that each 15-residue segment contained two short beta-strands and two beta-bends, one of which incorporated an extra residue in a beta-bulge of the Gx type. The 44 strands together gave a long (210 A) narrow, amphipathic beta-sheet, which could be stabilised by dimer formation to give the shaft of the fibre. The knob could arise from a dimer of the C-terminal 180 residue segment, predicted to be an 8-10 stranded beta-sandwich. This model is consistent with the electron micrographs of the fibre and it was supported by measurements of c.d. and of electron diffraction from microcrystals. The latter gave a pair of wide angle arcs, corresponding to a repeat of 4.7 A, oriented appropriately for a cross-beta structure. The relation of this structure to globular structures is discussed and a folding pathway is proposed. In its general features the structure resembles that proposed for the tail fibre of bacteriophage T4.

The reaction of fluorescein isothiocyanate with thiols: a method for assay of isothiocyanates

The reversible formation of dithiourethanes from fluorescein isothiocyanate and mercaptoethanol or mercaptoethylamine has been studied. It is shown that it is possible to use the reaction as the basis for a spectrophotometric titration of a number of isothiocyanates with mercaptoethanol.

1H-NMR studies on nucleotide binding to the sarcoplasmic reticulum Ca2+ ATPase. Determination of the conformations of bound nucleotides by the measurement of proton-proton transferred nuclear Overhauser enhancements

The glycosidic bond torsion angles and the conformations of the ribose of Mg2+ATP, Mg2+ADP and Mg2+AdoPP[NH]P (magnesium adenosine 5'-[beta, gamma-imido]triphosphate) bound to Ca2+ATPase, both native and modified with fluorescein isothiocyanate (FITC), in intact sarcoplasmic reticulum have been determined by the measurement of proton-proton transferred nuclear Overhauser enhancements by 1H-NMR spectroscopy. This method shows clearly the existence of a low-affinity ATP binding site after modification of the high-affinity site with FITC. For all three nucleotides bound to both the high-affinity (catalytic) site and the low-affinity site, we find that the conformation about the glycosidic bond is anti, the conformation of the ribose 3'-endo of the N type and the conformation about the ribose C4'-C5' bond either gauche-trans or trans-gauche. The values for the glycosidic bond torsion angles chi (O4'-C1'-N9-C4) for Mg2+ATP, Mg2+ADP and Mg2+AdoPP[NH]P bound to the low-affinity site of FITC-modified Ca2+ATPase are approximately equal to 270 degrees, approximately equal to 260 degrees and approximately equal to 240 degrees respectively. In the case of the nucleotides bound to the high-affinity (catalytic) site of native Ca2+ATPase, chi lies in the range 240-280 degrees.