Randomised controlled double blind study of role of recombinant erythropoietin in the prevention of chronic lung disease

AIM

To evaluate the role of recombinant human erythropoietin (R-HuEpo) in reducing iron infusion, which may exacerbate free radical damage, leading to chronic lung disease.

METHODS

A multicentre, randomised, placebo controlled, double blind study was carried out in four neonatal intensive care units in Yorkshire. Infants were randomly allocated and received either R-HuEpo (480 U/kg/wk) or placebo by twice weekly subcutaneous injection. The primary outcome measure was the number of days on respiratory support and a secondary outcome the number of blood transfusions required.

RESULTS

Forty two very low birthweight (VLBW) infants were randomly allocated. There was little difference in the need for respiratory support one month after randomisation, but subsequently there was a trend towards a reduction in the proportion requiring respiratory support in the R-HuEpo group (difference at three months -0.50, 95% confidence interval -1.00, 0.17). During stay in hospital, the median number of blood transfusions was lower for infants in the R-HuEpo group (difference in medians -2, 95% CI -4, 0). The study was stopped early because of failure to recruit babies at the expected rate.

CONCLUSIONS

R-HuEpo seems to reduce the number of days in oxygen for ill VLBW infants. These data could be used to construct a larger multicentre study to evaluate this effect further.

Accumulation of sphingolipids in SAP-precursor (prosaposin)-deficient fibroblasts occurs as intralysosomal membrane structures and can be completely reversed by treatment with human SAP-precursor

The degradation of glycosphingolipids takes place in lysosomes by action of specific exohydrolases, with the assistance of sphingolipid activator proteins (SAPs). Four of the SAPs, SAP-A to -D (also called saposins A to D), are synthesized from a single protein, the SAP-precursor (prosaposin). Deficiency in this precursor protein, a rare inherited disease in humans, results in the storage of sphingolipids with short oligosaccharide head groups within the patients' tissues, and electron microscopy revealed the accumulation of large multivesicular storage organelles. In this study we analyze the multivesicular storage organelles in cultivated fibroblasts from these patients. The results support our hypothesis that endocytosis of plasma membrane-derived lipids occurs via small intraendosomal and intralysosomal vesicles and membrane structures that are then digested within the lysosomes (Sandhoff, K., T. Kolter, Trends in Cell Biol. 6, 98-103 (1996). First, we show that the storage compartment consists of late endosomes and lysosomes by immunogold labeling for marker proteins of these organelles. The transport of endocytosed bovine serum albumin-colloidal gold or cationized ferritin into the compartment occurs with the timing expected for transport to late endocytic organelles. Second, complementation of the medium of the SAP-precursor-deficient fibroblasts with only nanomolar concentrations of purified SAP-precursor nearly completely reversed the aberrant accumulation of multivesicular structures, thereby abolishing most of the intralysosomal membrane structures. Analysis of the sphingolipid pattern of the cells after metabolic labeling with [14C]serine reveals that the cells' ability to degrade glycosphingolipids is completely restored by feeding of SAP-precursor at the same concentrations. This is the first demonstration in vivo that endocytosed SAP-precursor is processed into functional active SAPs A,- B,- C, and D and that the degradation of the vesicular structures within the lysosomes depends on the presence of the SAPs. Moreover, these studies suggest that a therapy program based on feeding purified SAP-precursor may be valuable in treating the entire family of diseases which result from the loss of one or more of the SAPs.

Dissociation of coatomer from membranes is required for brefeldin A-induced transfer of Golgi enzymes to the endoplasmic reticulum

Addition of brefeldin A (BFA) to mammalian cells rapidly results in the removal of coatomer from membranes and subsequent delivery of Golgi enzymes to the endoplasmic reticulum (ER). Microinjected anti-EAGE (intact IgG or Fab-fragments), antibodies against the "EAGE"-peptide of beta-COP, inhibit BFA-induced redistribution of beta-COP in vivo and block transfer of resident proteins of the Golgi complex to the ER; tubulo-vesicular clusters accumulate and Golgi membrane proteins concentrate in cytoplasmic patches containing beta-COP. These patches are devoid of marker proteins of the ER, the intermediate compartment (IC), and do not contain KDEL receptor. Interestingly, relocation of KDEL receptor to the IC, where it colocalizes with ERGIC53 and ts-O45-G, is not inhibited under these conditions. While no stacked Golgi cisternae remain in these injected cells, reassembly of stacks of Golgi cisternae following BFA wash-out is inhibited to only approximately 50%. Mono- or divalent anti-EAGE stabilize binding of coatomer to membranes in vitro, at least as efficiently as GTP(gamma)S. Taken together these results suggest that enhanced binding of coatomer to membranes completely inhibits the BFA-induced retrograde transport of Golgi resident proteins to the ER, probably by inhibiting fusion of Golgi with ER membranes, but does not interfere with the disassembly of the stacked Golgi cisternae and recycling of KDEL receptor to the IC. These results confirm our previous results suggesting that COPI is involved in anterograde membrane transport from the ER/IC to the Golgi complex (Pepperkok et al., 1993), and corroborate that COPI regulates retrograde membrane transport between the Golgi complex and ER in mammalian cells.

Molecular requirements for bi-directional movement of phagosomes along microtubules

Microtubules facilitate the maturation of phagosomes by favoring their interactions with endocytic compartments. Here, we show that phagosomes move within cells along tracks of several microns centrifugally and centripetally in a pH- and microtubule-dependent manner. Phagosome movement was reconstituted in vitro and required energy, cytosol and membrane proteins of this organelle. The activity or presence of these phagosome proteins was regulated as the organelle matured, with "late" phagosomes moving threefold more frequently than "early" ones. The majority of moving phagosomes were minus-end directed; the remainder moved towards microtubule plus-ends and a small subset moved bi-directionally. Minus-end movement showed pharmacological characteristics expected for dyneins, was inhibited by immunodepletion of cytoplasmic dynein and could be restored by addition of cytoplasmic dynein. Plus-end movement displayed pharmacological properties of kinesin, was inhibited partially by immunodepletion of kinesin and fully by addition of an anti-kinesin IgG. Immunodepletion of dynactin, a dynein-activating complex, inhibited only minus-end directed motility. Evidence is provided for a dynactin-associated kinase required for dynein-mediated vesicle transport. Movement in both directions was inhibited by peptide fragments from kinectin (a putative kinesin membrane receptor), derived from the region to which a motility-blocking antibody binds. Polypeptide subunits from these microtubule-based motility factors were detected on phagosomes by immunoblotting or immunoelectron microscopy. This is the first study using a single in vitro system that describes the roles played by kinesin, kinectin, cytoplasmic dynein, and dynactin in the microtubule-mediated movement of a purified membrane organelle.

Effect of n-6 polyunsaturated fatty acids on growth and lipid composition of neoplastic and non-neoplastic canine prostate epithelial cell cultures

BACKGROUND

Polyunsaturated fatty acids (n-6) are reported to selectively kill malignant cells. Most investigations, however, did not compare neoplastic with non-neoplastic cells from the same tissue type. Here we evaluate the effects of n-6 fatty acids on a non-neoplastic epithelium cell line (CAPE) and a spontaneous carcinoma cell line (CPA) derived from the canine prostate.

METHODS

Cell lines were cultured in DME in the presence of fatty acids and their effects on cell proliferation monitored by coulter counting. Lipids were extracted and quantitized by gas chromatography.

RESULTS

Cell proliferation was reduced more in CAPE. A neoplastic strain (CPA-GLA) tolerant to prolonged culture in 18:3n-6 was isolated. CPA grown in an 18:2n-6 or 18:3n-6 supplemented media accumulated 20:3n-6 and contained little 20:4n-6.

CONCLUSIONS

Polyenoic n-6 fatty acids are not specifically inhibitory to neoplastic cells which exhibited a marked alteration in the metabolism of 20:4n-6.

Preformed cytoplasmic nucleocapsids are not necessary for alphavirus budding

According to the present model for assembly of alphaviruses, e.g. Semliki Forest virus (SFV), the viral genome is first encapsidated into a nucleocapsid (NC) in cytoplasm and this is then used for budding at plasma membrane (PM). The preformed NC is thought to act as a template on which the viral envelope can be organized. In the present work we have characterized two SFV deletion mutants which did not assemble NCs in the cytoplasm but which instead appeared to form NCs at the PM simultaneously with virus budding. The deletions were introduced in a conserved 14 residue long linker peptide that joins the amino-terminal RNA-binding domain with the carboxy-terminal serine-protease domain of the capsid protein. Despite the deletions and the change in morphogenesis, wild-type (wt)-like particles were produced with almost wt efficiency. It is suggested that the NC assembly defect of the mutants is rescued through spike-capsid interactions at PM. The results show that the preassembly of NCs in the cytoplasm is not a prerequisite for alphavirus budding. The apparent similarities of the morphogenesis pathways of wt and mutant SFV with those of type D and type C retroviruses are discussed.

The mammalian homolog of yeast Sec13p is enriched in the intermediate compartment and is essential for protein transport from the endoplasmic reticulum to the Golgi apparatus

The role of COPII components in endoplasmic reticulum (ER)-Golgi transport, first identified in the yeast Saccharomyces cerevisiae, has yet to be fully characterized in higher eukaryotes. A human cDNA whose predicted amino acid sequence showed 70% similarity to the yeast Sec13p has previously been cloned. Antibodies raised against the human SEC13 protein (mSEC13) recognized a cellular protein of 35 kDa in both the soluble and membrane fractions. Like the yeast Sec13p, mSEC13 exist in the cytosol in both monomeric and higher-molecular-weight forms. Immunofluorescence microscopy localized mSEC13 to the characteristic spotty ER-Golgi intermediate compartment (ERGIC) in cells of all species examined, where it colocalized well with the KDEL receptor, an ERGIC marker, at 15 degrees C. Immunoelectron microscopy also localized mSEC13 to membrane structures close to the Golgi apparatus. mSEC13 is essential for ER-to-Golgi transport, since both the His6-tagged mSEC13 recombinant protein and the affinity-purified mSEC13 antibody inhibited the transport of restrictive temperature-arrested vesicular stomatitis virus G protein from the ER to the Golgi apparatus in a semi-intact cell assay. Moreover, cytosol immunodepleted of mSEC13 could no longer support ER-Golgi transport. Transport could be restored in a dose-dependent manner by a cytosol fraction enriched in the high-molecular-weight mSEC13 complex but not by a fraction enriched in either monomeric mSEC13 or recombinant mSEC13. As a putative component of the mammalian COPII complex, mSEC13 showed partially overlapping but mostly different properties in terms of localization, membrane recruitment, and dynamics compared to that of beta-COP, a component of the COPI complex.

p230 is associated with vesicles budding from the trans-Golgi network

Transport vesicle formation requires the association of cytosolic proteins with the membrane. We have previously described a brefeldin-A sensitive, hydrophilic protein (p230), containing a very high frequency of heptad repeats, found in the cytosol and associated with Golgi membranes. We show here that p230 is localised on the trans-Golgi network, by immunogold labeling of HeLa cell cryosections using alpha 2,6 sialyltransferase as a compartment-specific marker. The role of G protein activators on the binding of p230 to Golgi membranes and in vesicle biogenesis has been investigated. Treatment of streptolysin-O permeabilised HeLa cells with either GTP gamma S or AlF4- resulted in accumulation of p230 on Golgi membranes. Furthermore, immunolabeling of isolated Golgi membranes treated with AlF4-, to induce the accumulation of vesicles, showed that p230 is predominantly localised to the cytoplasmic surface of trans-Golgi network-derived budding structures and small coated vesicles. p230-labeled vesicles have a thin (approximately 10 nm) electron dense cytoplasmic coat and could be readily distinguished from clathrin-coated vesicles. Dual immunogold labeling of perforated cells, or of cryosections of treated Golgi membranes, revealed that p230 and the trans-Golgi network-associated p200, which we show here to be distinct molecules, appear to be localised on separate populations of vesicles budding from the trans-Golgi network. These results strongly suggest the presence of distinct populations of non-clathrin coated vesicles derived from the trans-Golgi network. As p230 recycles between the cytosol and buds/vesicles of TGN membranes, a process regulated by G proteins, we propose that p230 is involved in the biogenesis of a specific population of non-clathrin coated vesicles.

Isolation and characterization of early endosomes, late endosomes and terminal lysosomes: their role in protein degradation

Although endosomal proteolysis has been reported (e.g. for peptide hormones and lysosomal enzymes), lysosomes are believed to be the main site of degradation in the endocytic pathway. We have studied the separate roles of lysosomes and prelysosomal endocytic organelles in the degradation of ovalbumin in J774 cells. The ovalbumin was labelled with 125I-tyramine cellobiose (125I-TC-ova). The labelled degradation products formed from this probe are trapped at the site of formation. To separate lysosomes efficiently from prelysosomal endocytic organelles we allowed the cells to endocytose a pulse of colloidal gold particles complexed with ovalbumin. By combining this density shift technique with subcellular fractionation of a postnuclear supernatant in Percoll gradients we could isolate three fractions that were sequentially involved in the endocytic pathway: a light Percoll fraction, a dense Percoll fraction and a gold fraction. The light Percoll fraction contained early endosomes since it was transferrin positive and received endocytic markers such as ovalbumin and horseradish peroxidase (HRP) early (< 5 minutes) after internalization. The dense Percoll fraction was transferrin negative, rab7 positive and received endocytic markers after 10–15 minutes of internalization. The gold-filled fraction was negative for both transferrin and rab7 but highly enriched in the lysosomal enzyme beta-hexosaminidase and was therefore defined as a lysosome. To study the role of endosomes and lysosomes in the degradation of endocytosed material we allowed the cells to take up (via the mannose receptor) 125I-TC-ova. It was found that the main degradation of 125I-TC-ova (measured as acid soluble radioactivity trapped in the organelle) took place in the late endosomes (and not in the lysosomes containing the bulk of the lysosomal enzymes). Our data therefore suggest that the late endosomes operate as an early lysosomal compartment. The terminal lysosomes may serve as storage bodies for acid hydrolases that may be called upon when needed (for instance during phagocytosis).

Identification of the major membrane and core proteins of vaccinia virus by two-dimensional electrophoresis

Vaccinia virus assembly has been well studied at the ultrastructural level, but little is known about the molecular events that occur during that process. Towards this goal, we have identified the major membrane and core proteins of the intracellular mature virus (IMV). Pure IMV preparations were subjected to Nonidet P-40 (NP-40) and dithiothreitol (DTT) treatment to separate the core proteins from the membrane proteins. These proteins were subsequently separated by two-dimensional (2D) gel electrophoresis, and the major polypeptide spots, as detected by silver staining and 35S labeling, were identified by either matrix-assisted laser desorption/ionization mass spectrometry, N-terminal amino acid sequencing, or immunoprecipitation with defined antibodies. Sixteen major spots that partitioned into the NP-40-DTT-soluble fraction were identified; 11 of these were previously described virally encoded proteins and 5 were cellular proteins, mostly of mitochondrial origin. The core fraction revealed four major spots of previously described core proteins, two of which were also detected in the membrane fraction. Subsequently, the NP-40-DTT-soluble and -insoluble fractions from purified virus preparations, separated by 2D gels, were compared with postnuclear supernatants of infected cells that had been metabolically labeled at late times (6 to 8 h) postinfection. This relatively short labeling period as well as the apparent shutoff of host protein synthesis allowed the selective detection in such postnuclear supernatants of virus-encoded proteins. These postnuclear supernatants were subsequently treated with Triton X-114 or with sodium carbonate to distinguish the membrane proteins from the soluble proteins. We have identified the major late membrane and nonmembrane proteins of the IMV as they occur in the virus as well as in infected cells. This 2D gel map should provide an important reference for future molecular studies of vaccinia virus morphogenesis.

A vaccinia virus core protein, p39, is membrane associated

We describe herein the characterization of p39, the product of the A4L gene of vaccinia virus. By immunolabelling of thawed cryosections from infected HeLa cells, we show that this protein is initially located in the central region, or viroplasm, of the viral factories, as well as in the immature virions, with very small amounts of labelling observed on the surrounding membranes. The localization of p39 changes dramatically during the transition of the immature virion to the intracellular mature virus (IMV), coincident with the appearance of the core structure in the center of the IMV, with p39 located between this core and the surrounding membranes. Complementary biochemical data, such as partitioning into the Triton X-114 detergent phase and stripping of the viral membranes with Nonidet P-40 and dithiothreitol, suggest that p39 is associated with the innermost of the two membranes surrounding the core. Sodium carbonate treatment also indicates that p39 is associated with membranes, even at the early stages of viral assembly. However, following in vitro translation of p39 in the presence of microsomal membranes, we failed to detect any association of the independently expressed protein with membranes. We also failed to detect any posttranslational acylation of p39 with myristate or palmitate, suggesting that p39 does not achieve its membrane association through lipid anchors. Therefore, p39 is most likely membrane associated through an interaction with an integral membrane protein(s) present in the innermost of the two membranes surrounding the IMV. These data, together with our recent data showing that p39 colocalizes with the spike-like protrusions on the IMV core (N. Roos, M. Cyrklaff, S. Cudmore, R. Blasco, J. Krijnse-Locker, and G. Griffiths, EMBO J. 15:2343-2355, 1996), suggest that p39 may form part of this spike and that it possibly functions as a matrix-like linker protein between the core and the innermost of the two membranes surrounding the IMV.

Vaccinia virus: a model system for actin-membrane interactions

Our understanding of the interactions between the actin cytoskeleton and cellular membranes at the molecular level is rudimentary. One system that offers an opportunity to examine these interactions in greater detail is provided by vaccinia virus, which induces the nucleation of actin tails from the outer membrane surrounding the virion. To further understand the mechanism of their formation and how they generate motility, we have examined the structure of these actin tails in detail. Actin filaments in vaccinia tails are organized so they splay out at up to 45 degrees from the centre of the tail and are up to 0.74 micron in length, which is considerably longer than those reported in the Listeria system. Actin filaments show unidirectional polarity with their barbed filament ends pointing towards the surface of the virus particle. Rhodamine-actin incorporation experiments show that the first stage of tail assembly involves a polarized recruitment of G-actin, and not pre-formed actin filaments, to the membrane surrounding the virion. Incorporation of actin into the tail only occurs by nucleation from the viral surface, suggesting filament ends in the tail are blocked against further actin addition. As virus particles fuse with the plasma membrane during the extention of projections, actin nucleation sites previously in the viral membrane become localized to the plasma membrane, where they are able to nucleate actin polymerization in a manner analogous to the leading edge of motile cells.

The role of a 21-kDa viral membrane protein in the assembly of vaccinia virus from the intermediate compartment

We have recently provided morphological evidence that a key event in the assembly of vaccinia virus is the formation of a novel cisternal domain of the intermediate compartment (IC) between the endoplasmic reticulum and the Golgi complex (Sodeik, B., Doms, R. W., Ericsson, M., Hiller, G., Machamer, C. E., van't Hof, W., van Meer, G., Moss, B., and Griffiths, G. (1993) J. Cell Biol. 121, 521-541). This tightly apposed cisternal domain incompletely surrounds the spherical immature virus that matures into the first of the two distinct infectious forms of vaccinia, the intracellular mature virus (IMV). In this study we describe the characterization of an abundant membrane protein of the IMV, the gene product of A17L, a 21-kDa protein that has recently been shown to be essential for the formation of the viral membranes (Rodriguez, D., Esteban, M., and Rodriguez, J. R. (1995) J. Virol. 69, 4640-4648). Upon translation in vitro, p21 associated with rough microsomal membranes in a co-translational manner. Using NH2- and COOH-terminal specific antibodies, we show that both in vitro as well as in vivo, p21 adopts a topology where the NH2 and COOH termini are cytoplasmically orientated. Immunocytochemical experiments demonstrated that p21 is a component of the inner of the two cisternal membranes of the immature virus as well as of membranes of the IC, identified using antibodies against Rab1. Taken together, these data provide the first molecular evidence in support of our assembly model; they show that an essential membrane protein of the IMV inserts into the rough endoplasmic reticulum, but gets efficiently targeted to the IC and membranes of the viral factory.

The polyether bistratene A activates protein kinase C-delta and induces growth arrest in HL60 cells

Bistratene A (BisA) induced growth arrest in G2/M in HL60 cells. In addition, BisA-treated cells (50 nM for 48 h) became adherent and expressed the adhesion molecule CD11c, but did not express the monocyte enzyme alpha-napthyl acetate esterase or phagocytose complement coated yeasts. BisA activated protein kinase C (PKC)-delta and induced translocation of PKC-delta to the nucleus. This suggests that activation of PKC-delta can induce growth arrest and cell adhesion, but is insufficient to mediate full differentiation of HL60 cells. BisA has potential as a new probe for determining the function of PKC isoenzymes, specifically PKC-delta.

A novel immunogold cryoelectron microscopic approach to investigate the structure of the intracellular and extracellular forms of vaccinia virus

We introduce a novel approach for combining immunogold labelling with cryoelectron microscopy of thin vitrified specimens. The method takes advantage of the observation that particles in suspension are concentrated at the air-water interface and remain there during the subsequent immunogold labelling procedure. Subsequently, a thin aqueous film can be formed that is vitrified and observed by cryoelectron microscopy. In our view, a key early step in the assembly of vaccinia virus, the formation of the spherical immature virus, involves the formation of a specialized cisternal domain of the intermediate compartment between the endoplasmic reticulum and the Golgi. Using this novel cryoelectron microscopy approach, we show that in the intracellular mature virus (IMV) the core remains surrounded by a membrane cisterna that comes off the viral core upon treatment with dithiothreitol, exposing an antigen on the surface of the viral core. Complementary protease studies suggest that the IMV may be sealed not by membrane fusion but by a proteinaceous structure that interrupts the outer membrane. We also describe the structure and membrane topology of the second infectious form of vaccinia, the extracellular enveloped virus, and confirm that this form possesses an extra membrane overlying the IMV.

Microtubule-associated protein-dependent binding of phagosomes to microtubules

In macrophages, phagosome movement is microtubule-dependent. Microtubules are a prerequisite for phagosome maturation because they facilitate interactions between phagosomes and organelles of the endocytic pathway. We have established an in vitro assay that measures the binding of purified phagosomes to microtubules. This binding depends on the presence of membrane proteins, most likely integral to the surface of phagosomes, and on macrophage cytosol. The cytosolic binding factor can interact with microtubules prior to the addition of phagosomes to the assay, suggesting that it is a microtubule-associated protein (MAP). Consistent with this, depletion of MAPs from the cytosol by microtubule affinity removes all binding activity. Microtubule motor proteins show no binding activity, whereas a crude MAP preparation is sufficient to support binding and to restore full binding activity to MAP-depleted cytosol. We show that the activating MAP factor is a heat-sensitive protein(s) that migrates at around 150 kDa by gel filtration.

Purification and characterization of oil-bodies (oleosomes) and oil-body boundary proteins (oleosins) from the developing cotyledons of sunflower (Helianthus annuus L.)

Oil-bodies, from the immature cotyledons of sunflower (Helianthus annuus L.), were difficult to purify to homogeneity using conventional techniques. The major protein contaminants were albumin and globulin storage proteins. A protocol has been developed, therefore, based upon the stringent washing of the oil-body fraction in 9 M urea, which effectively removed almost all the contaminating protein as judged by SDS/PAGE. The urea-washed oil-bodies were enriched in two major proteins of M(r) 19000 and 20000. These proteins were oleosins as demonstrated by their amino acid compositions and the sequence analysis of peptides produced by CNBr cleavage. Far-UV CD spectra of the oleosins in trifluoroethanol, trifluoroethanol/water mixtures and as mixed micelles in SDS, were typical of alpha-helical proteins with alpha-helical contents of some 55%. The phospholipid content of the urea-washed preparations was less than 0.1% of that required to form a half-unit membrane surrounding the oil-body. The oil-body surface therefore appears to be an unusual and novel structure, covered largely by an oleosin protein coat or pellicle rather than a conventional fluid membrane, half-unit or otherwise.

Mannose 6-phosphate receptors and ADP-ribosylation factors cooperate for high affinity interaction of the AP-1 Golgi assembly proteins with membranes

Clathrin coat assembly in the trans-Golgi network, leading to the sequestration of the mannose 6-phosphate receptors (MPRs) into nascent vesicles, requires the ARF-1-dependent translocation of the cytosolic AP-1 Golgi assembly proteins onto the membranes of this organelle. The mechanistic role of the MPRs, i.e. the cargo molecules, in coat assembly is at present unclear. Using a GTP-dependent, brefeldin A-sensitive in vitro AP-1 binding assay, we have determined here the parameters of the AP-1 binding reaction. We demonstrate that, in addition of ARF-1, the MPRs contribute to create high affinity AP-1 binding sites (Kd approximately 25 mM), since their number correlates the number of MPR molecules expressed in MPR-negative cells. The quantitative electron microscopy shows that these high affinity binding sites are present on trans-Golgi network membranes, as expected, and to some extent on early endosomes. The high affinity binding sites are lost when the MPRs or ARF-1 become rate-limiting components. Conversely, GTP gamma S (guanosine 5'-O-(3-thiotriphosphate)), which increases the amount of membrane-bound ARF-1, most uncovers low affinity AP-1 binding sites (Kd approximately 150 nM) on trans-Golgi network membranes, normally not detected in its absence. Collectively, these results argue that MPR sorting is highly coupled to the first step of coat assembly and that the MPRs, ARF-1, and possibly other proteins cooperate for high affinity interactions of AP-1.

Genetic influence on bone turnover in postmenopausal twins

Postmenopausal bone mass is determined by both peak bone mass and subsequent bone loss. Previous studies have shown that peak bone mass is under genetic influence mediated partly by factors affecting bone formation. The rate of bone loss increases markedly after the menopause, but is highly variable from subject to subject. The aims of this study were to determine whether postmenopausal bone turnover was under genetic control, which should be linked to the genetic influence on the rate of postmenopausal bone loss. A classical twin study was performed that compared the intraclass correlations in monozygotic (MZ) twins with those in dizygotic (DZ) twins, with any difference assumed to be due to genetic factors. Markers of bone formation and resorption were measured in 240 untreated postmenopausal twins, aged 45-69 yr, on the average 12.3 yr (SD, 6.0) postmenopause, including 61 MZ pairs and 59 DZ pairs. The intraclass correlation coefficient of MZ twin pairs, rMZ (95% confidence interval), for 2 specific markers of bone formation, serum osteocalcin and bone-specific alkaline phosphatase, were higher than the corresponding rDZ [0.67 (range, 0.59-0.75) vs. 0.48 (range, 0.35-0.61; P = 0.06) for osteocalcin and 0.53 (range, 0.41-0.65) vs. 0.21 (range, 0.01-0.41; P = 0.02) for bone-specific alkaline phosphatase]. For serum propeptide of type I collagen, a type I collagen synthesis marker that exhibits only a slight increase after menopause, a high proportion of its variance was explained by genetic factors [rMZ = 0.82 (0.77-0.87), rDZ = 0.33 (0.16-0.50); P < 0.001]. The correlations for bone resorption measured by three distinct urinary markers, total deoxypyridinoline and two cross-linked type I collagen peptides (CrossLaps and NTX), that increase markedly after menopause were higher in MZ than in DZ pairs, but the difference reached significance only for NTX (P = 0.03). For urinary free dexoypyridinoline, a marker reflecting bone collagen degradation that increases moderately after menopause, the proportion of the variance explained by genetic factors was highly significant (P = 0.002). In conclusion, our data indicate that a proportion of the variance in postmenopausal levels of both bone formation and resorption markers are explained by genetic factors, but this contribution was clearly significant only for markers that do not change markedly at the menopause. These data suggest that the contribution of genetic factors to overall postmenopausal bone turnover and possibly bone loss is likely to be small.

Actin-based motility of vaccinia virus

The role of the cytoskeleton during viral infection is poorly understood. Here we show, using a combination of mutant and drug studies, that the intracellular enveloped form of vaccinia virus is capable of inducing the formation of actin tails that are strikingly similar to those seen in Listeria, Shigella and Rickettsia infections. Analysis using video microscopy reveals that single viral particles are propelled in vivo on the tip of actin tails, at a speed of 2.8 mumol min-1. On contact with the cell surface, virus particles extend outwards on actin projections at a similar rate, to contact and infect neighboring cells. Given the similarities between the motility of vaccinia virus and bacterial pathogens, we suggest that intracellular pathogens have developed a common mechanism to exploit the actin cytoskeleton as a means to facilitate their direct spread between cells.

Gaining insight into a complex organelle, the phagosome, using two-dimensional gel electrophoresis

Phagosomes are the organelles formed de novo in a variety of cells by the internalization of large particulate materials, including a wide range of pathogenic microorganisms. We present here a systematic approach that can be used to study the polypeptide composition of phagosomes/phagolysosomes and to yield analytical information on the characteristics of their proteins. A density shift approach was used to isolate pure preparations of phagosomes filled with low density latex beads from mouse J774 and human U937 macrophages. High resolution two-dimensional (2-D) gel electrophoresis was performed to generate a map of the overall [35S]methionine-labeled protein profile of the isolated phagosomes. The resulting map showed the minimal presence of over 200 polypeptides, indicating the complexity of this organelle. Comigration experiments showed that several phagosome polypeptides, among them several known proteins, are shared by the two species. Extraction with Triton X-114 and sodium carbonate was performed to distinguish between membrane and soluble proteins, and sensitivity to a panel of proteases was measured to identify proteins exposed on the cytoplasmic face of the phagosome membrane. The general value of the 2-D gel approach in the mapping of organelle proteins is discussed.