[Serratia marcescens osteomyelitis as the first manifestation of chronic granulomatous disease]. / Granulomatose septique chronique révélée par une ostéomyélite à Serratia marcescens.

Chronic granulomatous disease is a rare, primary immunodeficiency disorder characterized by a defect in oxidative metabolism in phagocytes and recurrent bacterial and fungal infections. We report a case in a 2-month-old infant admitted with metacarpic osteomyelitis due to Serratia marcescens. Chronic granulomatous disease is rare but must be considered in cases of uncommon or atypical infection.

[Recurrent chromomycosis of the face and extremities: first case report from Iibya]. / Chromomycose récidivante du visage et des membres: a propos du 1er cas libyen.

Chromomycosis is a chronic cutaneous fungal infection most prevalent in tropical and subtropical countries. It mainly affects adults working in rural areas. This purpose of this report is to describe the first cases in Libya in a 16-year-old girl. This case is also remarkable with regard to location on the face and members, lack of association with trauma and long delay for recurrence, i.e., 6 years after first occurrence.

Pharmacophore determination of a gp120 C terminal-derived anti-HIV peptide construct interfering with membrane fusion suggesting that processing of the gp120 C terminus is a prelude to fusion.

A multiple antigen peptide [CLIV; (PTKAKRR1VVQREKR2)4-K2-K-betaA] from the C terminus of the gp120 subunit of HIV Env inhibits Env-mediated cell-to-cell fusion through direct interference with the process (Virology 2000;273:169). We have examined various CLIV analogs using a cell-to-cell fusion assay, receptor binding assays, and molecular modeling to further address the characteristics of the peptide responsible for its anti-HIV activity. We show that (1) CLIV does not interfere with Env binding to CD4 and does not interact with the binding site of Env on CXCR4; (2) CLIV does not inhibit protease activities already reported to play a role in fusion; and (3) the pharmacophore is composed of cleavage site1 with amino acid residues at its C terminal end. Based on our data and on the literature, we propose that CLIV interferes with processing of the gp120 C terminus at site1 by the lymphocyte surface after CD4 binding. Our hypothesis implies that the cleavage region of Env is submitted to a stepwise processing including the known intracellular cleavage of gp160 at site2 in order to set the activation of the fusion peptide and a yet unexplored cleavage at site1 by the target cell surface that triggers fusion.

The catalytic activity of protein disulfide isomerase is involved in human immunodeficiency virus envelope-mediated membrane fusion after CD4 cell binding.

Protein disulfide isomerase (PDI) is a multifunctional protein with thiol-disulfide redox-isomerase activities. It catalyzes thiol-disulfide interchange reactions on the cell surface that may cause structural modifications of exofacial proteins. PDI inhibitors alter human immunodeficiency virus (HIV) spread, and it has been suggested that PDI may be necessary to trigger HIV entry. This study examined this hypothesis by using cell-to-cell fusion assays, in which the HIV envelope (Env) expressed on the cell surface interacts with CD4(+) lymphocytes. PDI is clustered at the lymphocyte surface in the vicinity of CD4-enriched regions, but both antigens essentially do not colocalize. Anti-PDI antibodies and 2 inhibitors of its catalytic function altered Env-mediated membrane fusion at a post-CD4 cell binding step. The fact that the PDI catalytic activity present on lymphocytes is required for fusion supports the hypothesis that catalysts assist post-CD4 cell binding conformational changes within Env.

An anti-human immunodeficiency virus multiple antigen peptide encompassing the cleavage region of the env precursor interferes with membrane fusion at a post-CD4 binding step.

CLIV is a multiple antigen peptide ([PTKAKRRVVQREKR](4)-K(2)-K-betaA) that encompasses the cleavage region of the human immunodeficiency virus type 1 (HIV-1) envelope precursor. It displays an antiviral activity against HIV-1 and HIV-2 and inhibits HIV-1 Env-mediated cell-to-cell fusion. This effect has previously been attributed to interference with Env processing, resulting in the expression of a nonfusogenic envelope [Virology (1998) 247, 137]. However, we show here that CLIV does not alter the status of Env cleavage at steady state. Using various aggregation/syncytium assays that allow us to discriminate between gp120/CD4 binding and binding followed by gp41-mediated fusion, we demonstrate that CLIV inhibits a step of the cell-to-cell fusion process after CD4 binding. We demonstrate also that CLIV binds at 37 degrees C to a single class of protein present at the CD4(+) cell surface (Scatchard analysis: K(d) = 8 nM; B(max) = 10(4) sites/cell) and that the fusion inhibition activity seems to correlate with binding to this proteic component. In contrast, CLIV interacts with neither membrane-inserted nor CD4-associated Env. We therefore propose that CLIV interferes after Env/CD4 binding with a step of the membrane fusion process that may involve the C-terminal domain of gp120.

Relationships between the anti-HIV V(3)-derived peptide SPC(3) and lymphocyte membrane properties involved in virus entry: SPC(3) interferes with CXCR(4).

SPC(3) is a multiple antigen peptide derived from the V(3) loop of human immunodeficiency virus (HIV) envelope (Env). It exerts a potent anti-HIV activity whereas it alters neither Env expression nor binding to CD(4). Here, SPC(3) binding characteristics, its subsequent intracellular fate and the fact that it inhibited SDF(1)alpha binding to the lymphocyte surface provided strong arguments to conclude that it exerts its anti-HIV activity through interference with the CXCR(4) coreceptor. In contrast, it interferes with none of the other major surface proteins and mechanisms involving V(3) and implicated in infection, as shown here. This work identifies the target mechanism of SPC(3).

Anti-platelet activity of the peptides composing the lebetin 1 family, a new class of inhibitors of platelet aggregation.

We have purified from Vipera lebetina venom a family of inhibitors of platelet aggregation, named Lebetins. They are composed of two peptide groups of short (Lebetin 1: L1alpha: GDNKPPKKGPPNG; L1beta: DNKPPKKGPPNG) and long (Lebetin 2: L2alpha: GDNKPPKKGPPNGCFGHKIDRIGSHSGLGCNKVDDNKG; L2beta: DNKPPKKGPPNGCFGHKIDRIGSHSGLGCNKVDDNKG) size. The sequence presenting anti-platelet activity is mainly present within the Lebetin 1 sequence [Barbouche, R. Marrakchi, N., Mansuelle, P., Krifi, M., Fenouillet, E., Rochat, H. and El Ayeb, M. (1996) Novel anti-platelet aggregation polypeptides from Vipera lebetina venom: isolation and characterization. FEBS Lett. 392, 6-10]. Here, the peptides that compose the Lebetin 1 family were synthesized. Their respective activity was determined. Synthetic L1alpha and L1beta inhibited collagen-induced platelet aggregation in the nanomolar range. A peptide corresponding to L1beta deleted by D at its N terminus (L1gamma) also inhibited platelet aggregation potently; further truncation of L1gamma impaired its activity. Because L1 peptides efficiently inhibited fibrinogen-induced alpha-chymotrypsin treated-platelet aggregation, we tested whether they act mainly through the inhibition of platelet binding to fibrinogen and showed that they failed to inhibit platelet binding to fibrinogen-coated wells. The activity of L1 peptides was also tested in vivo: their intravenous administration strongly inhibited collagen-induced thrombocytopenia in rats.

Properties of HIV envelope expressed in the presence of SPC3, an Env-derived peptide drug under phase II clinical trials.

A multibranched peptide construct (SPC3) derived from the conserved sequence of the third variable domain (V3) of the human immunodeficiency virus (HIV) envelope (Env) inhibits HIV infectivity. It is being tested in phase II clinical trials (FDA protocol 257A). Because some Env-derived peptides inhibit HIV infectivity through alteration of Env biosynthetic pathway, we studied whether SPC3 displays its activity through interference with Env biosynthesis or with its functions at the membrane. Syncytium formation was impaired when human CD4+ cells expressed recombinant HIV Env in the presence of SPC3. This inhibition was not due to an effect of SPC3 on the amount of Env expressed at the cell membrane. As assessed using antibodies, the conformation of the receptor binding site and of V3 presented on membrane Env was not affected by the presence of SPC3 during biosynthesis. Finally, despite the ability of SPC3 to bind to CD4+ cell membrane, SPC3 did not interfere with Env binding to CD4. These data suggest that SPC3 interferes with the infection process at a post-CD4 binding step, and not with the folding of Env.

An anti-HIV peptide construct derived from the cleavage region of the Env precursor acts on Env fusogenicity through the presence of a functional cleavage sequence.

A 22-amino-acid-long multibranched peptide construct (CLV) derived from the cleavage region (KIEPLGVAPTKAKRR*VVQREKR*) of the human immunodeficiency virus (HIV) type-1 envelope precursor inhibits HIV infection (Virology, 1996, 223, 406-408). We attempted to characterize its activity for Env expressed via a recombinant vaccinia virus (rVV): gp 160 cleavage was delayed, but not impaired, in the presence of CLV (10 microM), whereas neither Env production nor Env membrane expression was significantly altered. Through the synthesis of analogs, we concluded that the presence of a cleavage sequence was required for inhibition of syncytium formation by CLV in rVV-infected CD(4+) cell cultures: indeed, a single amino acid residue substitution (R* > S) in the cleavage sites presented by CLV abolished its activity. Other analogs allowed us to further determine the region of CLV which mediates its activity. The ability of a radiolabeled CLV analog to enter cells was also shown. Although, these data strongly suggest that CLV acts on Env fusogenicity at least partially through interference with gp160 processing.

SPC3, an anti-HIV peptide construct derived from the viral envelope, binds and enters HIV target cells.

SPC3 is a peptide construct (eight branches of the GPGRAF motif) derived from the consensus sequence present at the apex of the third variable domain of the human immunodeficiency virus (HIV) envelope (Env). It presents a potent anti-HIV activity and is currently tested in phase II clinical trials (FDA protocol 257A). Its mode of action remains unclear. It was thought that SPC3 exerts its effect both during HIV interaction with CD4+ cells but also through interference either with a post-binding event or with Env processing. Accordingly, SPC3 was supposed to be able to bind and to enter CD4+ cells. In this work, we addressed these points. SPC3 was found to interact with CD4+ cell membrane with a K0.5 value in the range of 500 nM. The binding of SPC3 to CD4+ cells involves its interaction with a cell membrane associated protein which is pronase sensitive and different from CD4. This interaction was similar from 2 to 37 degrees C. The maximum binding occurred at acidic pH whereas the interaction was inhibited in alkaline conditions. We observed also that SPC3 was internalized rapidly into the cells - the maximal intracell amount was reached within 30 min - where it remained stable for at least 24 h. Altogether, these data suggest that SPC3 can exert its antiviral activity via interference with events occurring at the cell surface but also into the target cell.

Cerastotin, a serine protease from Cerastes cerastes venom, with platelet-aggregating and agglutinating properties.

Cerastotin, a thrombin-like enzyme from the venom of the desert viper Cerastes cerastes, has been purified by gel filtration on Sephadex G-75 and two ion-exchange chromatographies on Mono S columns. It is a neutral glycoprotein (pI = 6.6), present as a single polypeptide chain of 40 kDa. Its N-terminal sequence shows strong similarity with those of other thrombin-like enzymes from snake venoms. Cerastotin possesses esterase and amidolytic activities measured with N(alpha)-tosyl-L-arginine methyl ester and the thrombin chromogenic substrate D-phenylalanyl-L-pipecolyl-L-arginine p-nitroanilide, respectively. The amidolytic activity is inhibited by phenylmethylsulfonyl fluoride, N(alpha)-tosyl-L-lysine chloromethane, N(alpha)-tosyl-L-phenylalanyl chloromethane, D-phenylalanyl-L-prolyl-L-arginyl chloromethane and benzamidine, suggesting that cerastotin is a serine protease. Cerastotin efficiently clots human plasma and cleaves preferentially the alpha chain of fibrinogen. Cerastotin did not induce aggregation of washed normal platelets, but did aggregate platelets in the presence of exogenous fibrinogen. A monoclonal antibody directed against glycoprotein (GPIb), which specifically inhibits induced agglutination by ristocetin also completely blocks platelet aggregation induced by cerastotin. However, another anti-GPIb monoclonal antibody, which specifically inhibits alpha-thrombin binding to GPIb, did not prevent this aggregation. Furthermore, platelets which were desensitised by alpha-thrombin still aggregate in the presence of cerastotin, but not alpha-thrombin. Similarly a monoclonal antibody, anti-GPIIb-IIIa, which blocks fibrinogen binding, did not inhibit cerastotin-induced platelet aggregation. This activity is abolished in the presence of 1 mM phenylmethylsulfonyl fluoride and/or 10 mM EDTA. Cerastotin also agglutinates formalin-fixed and washed platelets, only in the simultaneous presence of fibrinogen and of Von Willebrand factor.

Procoagulant and platelet-aggregating properties of cerastocytin from Cerastes cerastes venom.

Cerastocytin is a thrombin-like serine protease with potent platelet-proaggregating properties. It is able to activate factor XIII but is less active than thrombin on plasma coagulation. The aggregation induced by cerastocytin resembles that induced by thrombin, since rabbit washed platelets desensitized by a pretreatment with thrombin do not aggregate in the presence of cerastocytin. Furthermore, preincubation of platelets with monoclonal antibodies specific for glycoproteins GPIb or GPIIbIIIa blocks receptor sites for thrombin and fibrinogen, respectively, and prevents their aggregation induced by thrombin or cerastocytin. A monoclonal antibody, inhibitor of von Willebrand factor (VWF)-dependent agglutination, blocks the aggregation induced by cerastocytin. After activation with cerastocytin, washed rabbit platelets degranulate and secrete ATP and phospholipase A2. However, cerastocytin is less potent in inducing the release of phospholipase A2 than in inducing ATP secretion.

Cerastatin, a new potent inhibitor of platelet aggregation from the venom of the Tunisian viper, Cerastes cerastes.

Cerastatin, a potent platelet aggregation inhibitor, was purified by gel filtration on Sephadex G-75, followed by two ion exchange chromatographies on Mono-S columns. Cerastatin is a neutral glycoprotein (pI = 6.2) of 32 kDa, made up of at least three subunits. It is devoid of phospholipase A2, esterase, fibrinogenolytic and amidolytic activities. It inhibits aggregation of washed platelets, induced by either collagen, PAF acether or thrombin, with similar IC50 of 2.3 nM. Cerastatin also inhibits the thrombin-induced clot retraction of platelet-rich plasma. It does not inhibit the amidolytic or the procoagulant activities of thrombin Cerastatin caused no lytic effect on platelet membranes since it did not cause release of lactate dehydrogenase. Pretreatment of platelets with cerastatin irreversibly inhibits the aggregation induced by thrombin. Also cerastatin completely inhibits the fibrinogen-induced aggregation of alpha chymotrypsin-treated platelets. Cerastatin therefore inhibits platelet aggregation by interfering with the interaction of fibrinogen with fibrinogen receptors.

Novel anti-platelet aggregation polypeptides from Vipera lebetina venom: isolation and characterization.

Lebetins 1 and Lebetins 2, two polypeptide groups that inhibit platelet aggregation, were isolated from Vipera lebetina venom by gel filtration and reverse phase chromatography. Amino acid sequencing indicated that the first group contains two major polypeptides of 13 and 12 residues; their molecular weight was determined by electrospray mass spectrometry. The second was composed of two peptides of 38 and 37 residues, each with one disulfide bond. Sequence analysis revealed neither RGD sequence nor homology with other proteins including known snake or tick polypeptides. Lebetins 1 were Pro and Lys rich peptides and their sequences were identical to the N-terminus of Lebetins 2. Lebetins inhibited platelet aggregation induced by thrombin, collagen and PAF-acether. The 50% concentration that inhibited human and rabbit platelet aggregation induced by thrombin was 590 nM and 125 nM for Lebetins 1 and 100 nM and 8 nM for Lebetins 2, respectively. Lebetins 1 and Lebetins 2 also inhibited fibrinogen-induced aggregation of alpha-chymotrypsin-treated platelets as well as in vivo collagen-induced thrombocytopenia in rats with half effective doses of 2 nmol/kg and 4.2 nmol/kg, respectively. Lebetins were not toxic after intravenous injection into mice and rats. These polypeptides form novel platelet inhibitors that could be used to delineate further the mechanisms of platelet aggregation and serve as a model for developing antithrombotic agents.