Specifications for biotechnology-derived protein drugs.

Specifications are the regulatory and legal standards that a product must meet to be suitable for use in humans. Specifications evolve in parallel with drug development and are refined prior to marketing authorization and, in some cases, after marketing. Recent changes in regulatory procedures for biotechnology-derived protein products have placed much emphasis on the use of characterization and final product specifications to provide assurance of overall quality of these products. In addition, harmonized guidelines for the testing and specifications for biotechnology products have been developed through the International Conference on Harmonization process. The availability of sensitive, quantitative, and specific analytical methods for characterization has made this possible, thus providing regulatory flexibility in the development of biotechnology-derived protein products. Further refinement of these analytical tools will undoubtedly enhance this regulatory flexibility.

Irreversible inhibition of forskolin interactions with type I adenylyl cyclase by a 6-isothiocyanate derivative of forskolin.

Forskolin (Fsk) has been demonstrated to interact directly with the enzyme adenylyl cyclase (EC 4.6.1.1) in diverse tissues. However, the ability of Fsk to bind to and activate adenylyl cyclase varies depending on the tissue being studied. Different adenylyl cyclase subtypes have been cloned and expressed in a recombinant Sf9 expression system. This provides an opportunity to study the effects of chemically reactive derivatives of Fsk on individual adenylyl cyclase subtypes in the absence of Gs alpha. Reaction of type I adenylyl cyclase with an isothiocyanate derivative of Fsk (6-[[N-(2-isothiocyanatoethyl)amino]carbonyl]forskolin) causes irreversible inhibition of Fsk binding with an IC50 of 300 nM and irreversible inhibition of Fsk activation with an IC50 of 10 microM, suggesting that there are two sites of 6-[[N-(2-isothiocyanatoethyl)amino]carbonyl]forskolin interaction. These studies establish the usefulness of the isothiocyanate derivative of Fsk in localizing the site(s) of Fsk interaction with type I adenylyl cyclase.

Forskolin carbamates: binding and activation studies with type I adenylyl cyclase.

Three series of analogs were regioselectively prepared from a protected forskolin precursor to afford 7-carbamoyl-7-desacetylforskolins (series 1), 6-carbamoyl-7-desacetylforskolins (series 2), and 6-carbamoylforskolins (series 3). The analogs were pharmacologically evaluated for binding (IC50) to and activation (EC50) of type I adenylyl cyclase in membranes from stably transfected Sf9 cell lines expressing a single adenylate cyclase subtype. The following ranges were determined for the IC50's and EC50's of each individual series: series 1, IC50 = 43-1600 nM, EC50 = 0.5-9.6 microM; series 2, IC50 = 65-680 nM, EC50 = 0.63-6.5 microM; series 3, IC50 = 21-271 nM, EC50 = 0.5-8.1 microM (forskolin IC50 = 41 nM and EC50 = 0.5 microM). Activation paralleled binding; however, some analogs exhibited poor binding and good activation whereas others demonstrated good binding but poor activation. Steric bulk tended to diminish binding and activation when at the 6- or 7-position, although bulk was accommodated at the 6-position if the 7-site was reacetylated. Acylation of the 7-position by the carbamoyl linker or acetyl was important for obtaining good binding and activation; however, the effect was more pronounced with binding. For both binding and activation, small, linear, lipophilic substituents (propyl, allyl, isopropyl) are well tolerated at the 7-position but less so in the 6-position, even when the 7-site is reacetylated. Planar aromatic moieties (phenyl and 2-pyridinyl) demonstrated moderate to good potency for binding and activation when located at either the 6- or 7-positions. There is an overall trend toward increasing potency for both binding and activation with polar substituents.

Purification of bovine brain adenylyl cyclase with a novel derivative of forskolin: evidence for a high specific activity form of the enzyme.

An improved affinity support for the purification of adenylyl cyclase was prepared from 7-desacetyl-7-aminoethylaminocarbonyl forskolin. This analog allows convenient synthesis of an affinity matrix that is chemically stable, with-standing repeated use for up to two years, and efficient, yielding purifications of adenylyl cyclase from solubilized bovine brain membranes of 2,000-6,000 fold in a single step. Immunoblotting data suggest that the majority of the enzyme purified in this fashion differs from forms described previously. Since the specific activity of this preparation is substantially higher than that described in previous reports, it is possible that the purification described here selects, presumably on the basis of affinity for forskolin, for a form of adenylyl cyclase with higher specific activity than any described previously.

Regulation of forskolin interactions with type I, II, V, and VI adenylyl cyclases by Gs alpha.

Several forms of adenylyl cyclase (types I, II, V, and VI) have been expressed using the recombinant baculovirus expression system in Sf9 cells. The activation of type I adenylyl cyclase by forskolin and Gs alpha was not greater than additive. In contrast, there was synergistic activation of type II, V, and VI adenylyl cyclases by Gs alpha and forskolin. Gs alpha potentiated the effect of forskolin on type II adenylyl cyclase to the greatest extent. Type I and II adenylyl cyclases were photolabeled specifically by an iodinated photoaffinity derivative of forskolin ([125I]-6-AIPP-Fsk). Type I adenylyl cyclase was photolabeled efficiently in the absence of Gs alpha, and the addition of Gs alpha only slightly increased the labeling efficiency. In contrast, type II adenylyl cyclase was not photolabeled efficiently in the absence of Gs alpha, and the addition of Gs alpha greatly enhanced the labeling efficiency. Photolabeling of type V and VI adenylyl cyclases was detected only in the presence of Gs alpha. Neither calcium/calmodulin nor G protein beta gamma subunits modulated the photolabeling of type I or II adenylyl cyclases. Another iodinated derivative of forskolin, [125I]-6-IHPP-fsk, bound to Sf9 cell membranes expressing type I adenylyl cyclase with high affinity in a filtration binding assay, and the specific binding was not enhanced by the addition of Gs alpha. In contrast, specific binding of [125I]-6-IHPP-Fsk to membranes expressing type II adenylyl cyclase was detected only in the presence of Gs alpha.(ABSTRACT TRUNCATED AT 250 WORDS)

Interaction of an estramustine photoaffinity analogue with cytoskeletal proteins in prostate carcinoma cells.

To identify specific drug targets of the antimitotic drug estramustine, a photoaffinity analogue, 17-O-[[2-[3-(4-azido-3-[125I] iodophenyl)propionamido]ethyl]carbamyl]estradiol-3-N-bis(2- chloroethyl)carbamate, was synthesized and reacted in competition assays with cytoskeletal protein preparations. By attaching the photoaffinity ligand to the 17 beta-position of the steroid D-ring, the cytotoxic properties of the drug were maintained. In cytoskeletal protein preparations from human prostate carcinoma cells (DU 145) or a clonally selected, estramustine-resistant cell line (E4), the major microtubule-associated protein (MAP) present was MAP4. In both cytoskeletal fractions and reconstituted microtubules, 17-O-[[2-[3-(4-azido-3-[125I]iodophenyl)propionamido] ethyl]carbamyl]estradiol-3-N-bis(2-chloroethyl)carbamate bound to both MAP4 and tubulin. From competition assays, the apparent binding constant for MAP4 from DU 145 cells was 15 microM. Similar calculations for tubulin gave values of 13 microM (bovine brain), 19 microM (DU 145 wild-type cells), and 25 microM (E4 cells). The identification of these cytoskeletal proteins as specific drug targets provides a direct explanation for the antimicrotubule and antimitotic effects of estramustine.

Forskolin specifically inhibits the bacterial galactose-H+ transport protein, GalP.

Forskolin is a potent inhibitor of mammalian passive glucose transporters. Here we show that forskolin is a remarkably specific inhibitor of energized D-galactose transport by the GalP sugar-H+ symport protein of Escherichia coli. Surprisingly, it does not inhibit transport of L-arabinose or D-xylose by the related E. coli AraE and XylE transporters, even though the amino acid sequences of their proteins are 30-64% identical to GalP and to the mammalian GLUT family. However, unlike GLUT1, photoactivation of the [3H]forskolin-GalP complex fails to incorporate radioactivity covalently into the protein, in contrast to the effective incorporation of radioactivity from [3H]cytochalasin B into both proteins. However, 3-[125I]iodo-4-azidophenethylamido-7-O-succinyldesacetylforskol in ([125I]APS-forskolin), which labels GLUT1, is a potent labeling reagent for GalP and, to a lesser extent, for AraE. The appropriate sugar substrates of each transporter protect it against the [125I]APS-forskolin. Equilibrium binding studies using membranes from an E. coli strain that overexpresses GalP reveal a single set of high affinity binding sites for [3H]forskolin with a Kd of 1.3-1.4 microM, probably forming a 1:1 complex, compared with a value of 7.5 microM for GLUT1. Sugar substrates of GalP and cytochalasin B displace forskolin from the protein. The nonhomologous sugar-H+ symporters for L-rhamnose (RhaT), L-fucose (FucP) and lactose (LacY) in E. coli are insensitive to forskolin. Forskolin and [125I]APS-forskolin, therefore, constitute novel probes for exploring the structure-activity relationship of the bacterial GalP protein. GalP will provide an excellent model for the human glucose transporters and for elucidating the molecular basis of subtle differences in substrate and inhibitor recognition by individual members of this widespread family of transport proteins.

Localization of the forskolin labeling sites to both halves of P-glycoprotein: similarity of the sites labeled by forskolin and prazosin.

An iodinated derivative of forskolin, 6-O-[[2-[3-(4-azido-3-[125I] iodophenyl)propionamido]ethyl]carbamyl]forskolin ([125I]6-AIPP-Fsk), photolabels the multidrug efflux pump P-glycoprotein in membranes prepared from the multidrug-resistant cell lines KB-V1 and KB-C1. The labeling site for [125I]6-AIPP-Fsk was localized by immunoprecipitation of tryptic fragments of P-glycoprotein labeled in KB-C1 membranes. A 6-kDa, photolabeled, tryptic fragment was immunoprecipitated by antiserum raised against residues 348-419 of P-glycoprotein, PEPG9, but not by antisera raised against flanking regions PEPG7 and PEPG11. A peptide that corresponds to residues 343-359 of P-glycoprotein inhibited immunoprecipitation of the 6-kDa fragment by antiserum against PEPG9 but had no effect on the immunoprecipitation of photolabeled fragments by antiserum against PEPG7. A second peptide, corresponding to residues 360-376, had no effect on the immunoprecipitation by antiserum against PEPG9. [125I]6-AIPP-Fsk labels the carboxyl-terminal half of P-glycoprotein, because low molecular mass tryptic fragments were immunoprecipitated by three carboxyl-terminal antisera. Therefore, [125I]6-AIPP-Fsk labels both halves of P-glycoprotein, and labeling in the amino-terminal half can be localized to residues 291-359, which span proposed transmembrane regions 5 and 6. KB-V1 membranes photolabeled with [125I]6-AIPP-Fsk and [125I]iodoarylazidoprazosin were digested with either Staphylococcus aureus V8 protease or chymotrypsin and had similar digestion patterns, suggesting that the two drugs label the same sites on P-glycoprotein.

Interaction of 7-bromoacetyl-7-desacetylforskolin, and alkylating derivative of forskolin, with bovine brain adenylyl cyclase and human erythrocyte glucose transporter.

7-Bromoacetyl-7-desacetylforskolin (BrAcFsk), an alkylating derivative of forskolin, activated adenylyl cyclase and irreversibly blocked high affinity forskolin binding sites in human platelet membranes and rat brain membranes (Laurenza et al., 1990). Photoincorporation of an iodinated arylazido derivative of forskolin, 125I-6-AIPP-Fsk, into adenylyl cyclase in bovine brain membranes was irreversibly inhibited by BrAcFsk but not by 1,9-dideoxy-BrAcFsk, suggesting that BrAcFsk was reacting specifically with a nucleophilic group(s) at the forskolin binding site of adenylyl cyclase. Immunoblotting with antiforskolin antiserum demonstrated that partially purified bovine brain adenylyl cyclase had incorporated BrAcFsk. The interaction of BrAcFsk with the glucose transporter in human erythrocyte membranes was examined in a similar manner. Photoincorporation of 125I-7-AIPP-Fsk, an iodinated arylazido derivative of forskolin which is specific for the glucose transporter, into the glucose transporter was not irreversibly inhibited by BrAcFsk, suggesting that, in contrast to adenylyl cyclase, there is no reactive nucleophilic group at the forskolin binding site on the human erythrocyte glucose transporter. The immunoblotting procedure with antiforskolin antiserum confirmed that BrAcFsk was not covalently attached to human erythrocyte glucose transporter.

[125I]-labeled forskolin analogs which discriminate adenylyl cyclase and a glucose transporter: pharmacological characterization and localization of binding sites in rat brain by in vitro receptor autoradiography.

Aminoalkylcarbamate derivatives of forskolin have been synthesized at the 6- and 7-hydroxyl positions which have different selectivity for adenylyl cyclase and a glucose transporter, respectively. They were radioiodinated using the Bolton-Hunter reagent to yield [125I]-2-[3-(4-hydroxy-3-iodophenyl)propanamido]-N-ethyl-6- (aminocarbonyl)forskolin ([125I]6-IHPP-Fsk) and [125I]-2-[3-(4-hydroxy-3-iodophenyl)(propanamidol]-N-ethyl-7- (aminocarbonyl)-7-desacetylforskolin ([125I]7-IHPP-Fsk) and tested as autoradiographic probes for adenylyl cyclase and a glucose transporter. In slide-mounted rat brain sections [125I]6-IHPP-Fsk binding was potently inhibited by 1 microM 6-HPP-Fsk (95%) but unaffected by 500 mM D-glucose. In contrast, [125I]7-IHPP-Fsk was only partially inhibited by 1 microM 6-HPP-Fsk (37%), but residual [125I]7-IHPP-Fsk binding was further inhibited 56% by 500 mM D-glucose. These data suggest that while [125I]6-IHPP-Fsk binds exclusively to adenylyl cyclase, a significant fraction of [125I]7-IHPP-Fsk is binding to a glucose transporter in brain. Autoradiographic patterns of [125I]6-IHPP-Fsk and glucose-sensitive [125I]7-IHPP-Fsk binding were different. [125I]6-IHPP-Fsk binding was heterogeneously distributed and resembled [3H] forskolin binding. Highest densities of binding sites were noted in olfactory tubercle, caudate putamen, nucleus accumbens, pyramidal and granule cell layers of hippocampus, molecular layer of cerebellum and substantia nigra. In contrast, of glucose-sensitive [125I]7-IHPP-Fsk, binding appeared more homogeneous and similar to [3H]cytochalasin B, a compound which inhibits glucose transport. Highest densities of binding were noted in caudate putamen, nucleus accumbens, cerebral cortex and molecular layer of cerebellum.(ABSTRACT TRUNCATED AT 250 WORDS)

Identification of single amino acid substitutions in the staphylococcal nuclease protein that enhance and diminish T cell clone recognition of naturally processed peptides.

It has been inferred that residue changes that affect T cell recognition of synthetic peptides will have a similar effect in the intact protein. However, since small peptides do not require antigen processing it is possible that residue changes in synthetic peptides will not have an equivalent effect in the intact protein. Mutant proteins of staphylococcal nuclease (Nase) and 15mer synthetic peptides with corresponding substitutions were compared to determine if residue changes within an immunodominant epitope have an effect on the generation of naturally processed peptides. Five different substitutions in the synthetic peptide resulted in loss of reactivity of individual Nase-specific clones. When the same single amino acid changes were made in the intact protein, the naturally-processed peptides were also unable to stimulate the Nase-specific clones. However, two other substitutions in the synthetic peptide were stimulatory for a T cell clone even though the same changes in the intact protein were non-stimulatory. These results suggest that certain residue changes affect recognition of the naturally processed peptide but not the synthetic peptide with the same amino acid change. In addition, these results demonstrate that the effects of amino acid substitutions in synthetic peptides on T cell recognition may not always reflect the effects of these substitutions in the intact protein. Substitutions located outside Nase-specific T cell epitopes were also examined. Thirty different mutant proteins were all stimulatory. Moreover, a number of these mutants proteins were 50- to 100-fold more efficient in their stimulatory capacity than the native Nase protein.(ABSTRACT TRUNCATED AT 250 WORDS)

Frog secretions and hunting magic in the upper Amazon: identification of a peptide that interacts with an adenosine receptor.

A frog used for "hunting magic" by several groups of Panoan-speaking Indians in the borderline between Brazil and Peru is identified as Phyllomedusa bicolor. This frog's skin secretion, which the Indians introduce into the body through fresh burns, is rich in peptides. These include vasoactive peptides, opioid peptides, and a peptide that we have named adenoregulin, with the sequence GLWSKIKEVGKEAAKAAAKAAGKAALGAVSEAV as determined from mass spectrometry and Edman degradation. The natural peptide may contain a D amino acid residue, since it is not identical in chromatographic properties to the synthetic peptide. Adenoregulin enhances binding of agonists to A1 adenosine receptors; it is accompanied in the skin secretion by peptides that inhibit binding. The vasoactive peptide sauvagine, the opioid peptides, and adenoregulin and related peptides affect behavior in mice and presumably contribute to the behavioral sequelae observed in humans.

Differential identification and localization of adenylyl cyclase and glucose transporter in brain using iodinated derivatives of forskolin.

Two radioiodinated derivatives of forskolin, [125I]6-IHPP-Fsk and [125I]7-IHPP-Fsk, were synthesized as specific ligands for adenylyl cyclase and glucose transporter, respectively. [125I]6-IHPP-Fsk bound to bovine brain homogenates with a Kd of 9 nM and binding was inhibited by forskolin but not 1,9-dideoxyforskolin, cytochalasin B, or D-glucose. [125I]7-IHPP-Fsk bound to bovine brain homogenates at two classes of binding sites with Kd's of 56 nM and 4.7 microM; cytochalasin B and D-glucose inhibited 75% of the high affinity binding while having no effect on the low affinity binding. [125I]6-IHPP-Fsk and [125I]7-IHPP-Fsk were used to localize adenylyl cyclase and glucose transporter in rat brain by receptor autoradiography. The pattern of binding obtained with [125I]6-IHPP-Fsk was similar to that observed using [3H]forskolin to detect adenylyl cyclase. In contrast, the pattern of binding obtained with [125I]7-IHPP-Fsk was similar to that observed by others using [3H]cytochalasin B to detect glucose transporter. These iodinated ligands are selective for adenylyl cyclase and glucose transporter and require significantly shorter exposure times to yield autoradiographs than tritiated ligands.

Interaction of aminoalkylcarbamates of forskolin with adenylyl cyclase: synthesis of an iodinated derivative of forskolin with high affinity for adenylyl cyclase.

7-(2-Aminoethyl)aminocarbonyl-7-desacetylforskolin (7-AEC-Fsk) and 6-(2-aminoethyl)aminocarbonylforskolin (6-AEC-Fsk) were synthesized and tested for their ability to activate adenylyl cyclase and inhibit the high affinity binding of [3H]forskolin to bovine brain membranes. Forskolin and 7-AEC-Fsk were equipotent in activating adenylyl cyclase, with EC50 values of about 4 microM, whereas 6-AEC-Fsk had an EC50 of about 2 microM. 6-AEC-Fsk and 7-AEC-Fsk stimulated adenylyl cyclase about 7-fold over basal levels at 100 microM, whereas forskolin produced a 5-fold stimulation. Forskolin and 6-AEC-Fsk inhibited the binding of [3H]forskolin to bovine brain membranes with Kd values of 41 nM and 28 nM, respectively, whereas 7-AEC-Fsk had a Kd of 83 nM. The 3-(3-iodo-4-hydroxyphenyl)propionamide derivative of 6-AEC-Fsk (6-I-HPP-Fsk) was more potent than forskolin in inhibiting [3H]forskolin binding to bovine brain membranes, with a Kd of 14 nM. 6-AEC-Fsk was reacted with 125I-labeled Bolton-Hunter reagent to produce 6-125I-HPP-Fsk with a specific activity of 2175 Ci/mmol. 6-125I-HPP-Fsk bound to bovine brain membranes with a Kd of 13 nM and a Bmax of 3.8 pmol/mg of protein. Forskolin inhibited the binding of 6-125I-HPP-Fsk to bovine brain membranes with a Kd of 31 nM, whereas 1,9-dideoxyforskolin only slightly inhibited the binding at 10 microM. The binding of 6-125I-HPP-Fsk was not inhibited by agents that inhibit forskolin binding to the glucose transporter, such as D-glucose or cytochalasin B. There was no displaceable binding of 6-125I-HPP-Fsk to red blood cell membranes, which contain a large concentration of the glucose transporter. Pretreatment of bovine brain membranes with an alkylating derivative of forskolin, 7-bromoacetyl-7-desacetylforskolin (BrAcFsk), led to an irreversible decrease in the binding of [3H]forskolin and 6-125I-HPP-Fsk. The time dependence and concentration dependence for the BrAcFsk-induced decrease in [3H]forskolin binding sites were identical to those observed for the decrease in 6-125I-HPP-Fsk binding sites. 6-125I-HPP-Fsk binding was determined in human platelet membranes in the presence of Mg2+ alone and in combination with guanosine 5'-O-(3-thio)triphosphate (GTP gamma S) or AIF4-. The presence of GTP gamma S or AIF4- increased the binding of 6-125I-HPP-Fsk by 4.5-fold and 4-fold, respectively.(ABSTRACT TRUNCATED AT 400 WORDS)

(Aminoalkyl)carbamates of forskolin: intermediates for the synthesis of functionalized derivatives of forskolin with different specificities for adenylyl cyclase and the glucose transporter.

(Aminoalkyl)carbamates of forskolin were synthesized at the 6- and 7-hydroxyl positions of forskolin with the length of the alkyl chain varying from ethyl to heptyl. Two of these derivatives, 7-[[(2-aminoethyl)amino]carbonyl]-7-desacetylforskolin (2) and 6-[[(2-aminoethyl)amino]carbonyl]forskolin (3), were used to synthesize iodinated derivatives of forskolin that bind with high affinity to adenylyl cyclase in bovine brain membranes and the glucose transporter in human erythrocyte membranes, respectively. Hydroxyphenyl derivatives of forskolin were prepared from the (aminoalkyl)carbamates and tested for their ability to bind to adenylyl cyclase in bovine brain membranes and the glucose transporter in human erythrocyte membranes. The 6-derivative (18) of forskolin had a Kd of 9 nM at adenylyl cyclase and was more potent than either the 7-derivatives or the 6-derivatives of 7-desacetylforskolin. The 7-derivatives were more potent at binding to the glucose transporter than forskolin. In contrast, the 6-derivatives had Kd's greater than 100 microM at the glucose transporter. Isothiocyanates and N-bromoacetyl derivatives were synthesized from 2 and 3 as potential alkylating agents for forskolin binding sites. The alkylating agents produced an irreversible loss of forskolin binding to adenylyl cyclase. In contrast, the alkylating agents bound reversibly to the glucose transporter.

High prevalence of antibodies to the gp120 V3 region principal neutralizing determinant of HIV-1MN in sera from Africa and the Americas.

Neutralizing antibodies (NA) against HIV-1MN and HIV-1IIIB, and antibodies binding to synthetic peptides (BA) derived from the gp120 envelope V3 region principal neutralizing determinants (PND) of the HIV-1MN, HIV-1IIIB, and HIV-1Z3 virus strains were assayed in HIV-1 antibody-positive sera from the United States, Haiti, Brazil, Zaire, and Zimbabwe. The ability of soluble PND peptide to block neutralization of the corresponding virus by representative sera was also tested. In each country, NA and BA titers were highest against the HIV-1MN strain, and compared with other countries, NA and BA titers against HIV-1MN were higher in sera from the United States and Haiti. When NA titers were compared with BA titers against either HIV-1MN or HIV-1IIIB, no correlation was found for the HIV-1IIIB strain, but there was a significant correlation for HIV-1MN. Addition of the HIV-1MN strain peptide to a neutralization assay for HIV-1MN resulted in a four- to tenfold reduction in NA titers in sera from the United States, Zaire, and Brazil. The results suggest that HIV-1MN and closely related variants are prevalent in many parts of the world, and that antibodies directed against the PND account for most of the neutralizing activity in sera of infected individuals.

PIP: Virologists assessed the extent of neutralizing antibody cross-reactivity to multiple virus strains in sera from 112 HIV-1 infected individuals from the US, Brazil, Haiti, Zaire, and Zimbabwe. They also looked at the association between virus neutralization and the level of antibody binding to synthetic peptides representing the HIV-1 gp120 V3 region principal neutralizing determinant (PND) sequences. The 3 strains observed included HIV-1 MN, HIV-1 Z3, and HIV-1 IIIB. Neutralizing antibodies (NA) and antibodies binding to synthetic peptides (BA) titers ranked highest against the PND sequence HIV-1 MN in all countries (p.01). These titers were higher in sera from the US and Haiti than sera from Brazil and Africa (p.05). A significant correlation existed between the NA and BA titers for HIV-1 MN (p.01), but not for HIV-1 IIIB. When the virologists added HIV-1 MN strain peptide to a neutralization assay for HIV-1 MN, NA titers in sera from the US, Zaire, and Brazil fell 4-10 fold. These findings intimated that HIV-1 MN and closely related variants are commonplace in several locations around the world, and that antibodies directed against HIV--1 gp120 V3 region PND sequences make up most of the neutralizing activity in sera of infected individuals. In conclusion, virologists need to conduct more studies that examine the true extent of strain variation worldwide. These studies could lay the groundwork for the development of an effective HIV-1 vaccine.

Interaction of forskolin with the P-glycoprotein multidrug transporter.

Forskolin and 1,9-dideoxyforskolin, an analogue that does not activate adenylyl cyclase, were tested for their ability to enhance the cytotoxic effects of adriamycin in human ovarian carcinoma cells, SKOV3, which are sensitive to adriamycin and express low levels of P-glycoprotein, and a variant cell line, SKVLB, which overexpresses the P-glycoprotein and has the multidrug resistance (MDR) phenotype. Forskolin and 1,9-dideoxyforskolin both increased the cytotoxic effects of adriamycin in SKVLB cells, yet had no effect on SKOV3 cells. Two photoactive derivatives of forskolin have been synthesized, 7-O-[[2-[3-(4-azido-3- [125I]iodophenyl)propionamido]ethyl] carbamyl]-7-deacetylforskolin, 125I-7-AIPP-Fsk, and 6-O-[[2-[3-(4-azido-3- [125I]iodophenyl)propionamido]ethyl]carbamyl]forskolin, 125I-6-AIPP-Fsk, which exhibit specificity for labeling the glucose transporter and adenylyl cyclase, respectively (Morris et al., 1991). Both photolabels identified a 140-kDa protein in membranes from SKVLB cells whose labeling was inhibited by forskolin and 1,9-dideoxyforskolin. There was no specific labeling of proteins in membranes from the SKOV3 cells. The overexpressed 140-kDa protein in SKVLB membranes was identified as the P-glycoprotein by immunoblot analysis and immunoprecipitation using anti-P-glycoprotein antiserum. Total inhibition of photolabeling of the P-glycoprotein was observed with verapamil, nifedipine, diltiazem, and vinbalastine, and partial inhibition was observed with colchicine and cytochalasin B. Forskolin was less effective at inhibiting the photolabeling of the P-glycoprotein than 1,9-dideoxyforskolin or a lipophilic derivative of forskolin. The data are consistent with forskolin binding to the P-glycoprotein analogous to that of other chemosensitizing drugs that have been shown to partially reverse MDR.(ABSTRACT TRUNCATED AT 250 WORDS)