Insect apolipophorin III. Purification and properties.

Apolipophorin III (apoLp-III) from the migratory locust, Locusta migratoria, represents the only full-length apolipoprotein whose three-dimensional structure has been solved. In the present study, spectroscopic methods have been employed to investigate the effects of deglycosylation (via endoglycosidase F treatment) and complexation with lipid on the stability and conformation of this protein. Addition of isolated lipid-free apoLp-III to sonicated vesicles of dimyristoylphosphatidylcholine (DMPC) resulted in the formation of relatively uniform disklike complexes with an average Strokes diameter of 13.5 nm. Flotation equilibrium experiments conducted in the analytical ultracentrifuge revealed a particle molecular mass of 588 500 Da. Chemical cross-linking and compositional analysis of apoLp-III.DMPC complexes indicated five apoLp-III molecules per disk and an overall DMPC:apoLp-III molar ratio of 122:1. Circular dichroism (CD) spectra of apoLp-III samples suggested a loss of alpha-helical structure upon deglycosylation, while complexation with DMPC did not significantly alter the helix content (estimated to be > 75%). Fluorescence spectroscopy revealed that the apoLp-III tryptophan fluorescence emission maximum was blue-shifted from 347 to 332 and 321 nm upon deglycosylation and complexation with DMPC, respectively. In quenching experiments with native apoLp-III, tryptophan residues were shielded from the positively charged quencher, CsCl. Increased exposure to KI, CsCl, and acrylamide was observed upon deglycosylation, whereas complexation with DMPC yielded lower Ksv values for KI and acrylamide and an increased value for CsCl versus native lipid-free apoLp-III. In guanidine hydrochloride denaturation studies monitored by CD or fluorescence, native, lipid-free apoLp-III displayed a denaturation midpoint of 0.60 M, and delta GDH2O = 5.37 kcal/mol was calculated.(ABSTRACT TRUNCATED AT 250 WORDS)

Section: Discussionmentioning

confidence: 99%

Factors Affecting the Stability and Conformation of Locusta migratoria Apolipophorin III

Pm¹,

Cm²,

Oikawa³

et al. 1994

“…The primary sequence of apoLp-III, which lacks tryptophan and cysteine, consists of 166 amino acid residues and is nonglycosylated (Cole et al, 1987;Kawooya et al, 1984).…”

mentioning

confidence: 99%

Structural and Binding Characteristics of the Carboxyl Terminal Fragment of Apolipophorin III from Manduca sexta

Narayanaswami¹,

Kay²,

Oikawa³

et al. 1994

The molecular basis of the interaction of apolipophorin III (apoLp-III), an exchangeable apolipoprotein from hemolymph of the sphinx moth. Manduca sexta, with lipoprotein surfaces and phospholipids was studied by investigating the structural and binding properties of the C-terminal fragment of the native protein. A 4K peptide, corresponding to the terminal helical segment of the native protein, was generated by cyanogen bromide treatment, purified by gel filtration and reverse-phase HPLC, and characterized by N-terminal sequencing and amino acid and mass spectrometric analysis. Circular dichroism (CD) spectroscopy of the peptide in buffer indicated a predominantly unstructured state while addition of trifluoroethanol (TFE), a helix-inducing agent, resulted in an alpha-helical structure. Sedimentation equilibrium studies revealed that the 4K peptide was monomeric in buffer. The 4K peptide assumed an alpha-helical conformation in the presence of sodium dodecyl sulfate (SDS) and lysolecithin, but was unstructured in the presence of dimyristoylphosphatidylcholine, either when added to preformed vesicles or upon cosonication, indicating an ability to bind to detergent micelles but not to phospholipid bilayers. Unlike native apoLp-III, the 4K peptide did not confer protection against turbidity development to human low density lipoprotein upon incubation with phospholipase C, indicating an inability to interact with the surface of lipoproteins. Upon interaction with SDS micelles, both the 4K peptide and apoLp-III were resistant to urea-induced denaturation when compared to free apoLp-III, as evaluated by CD spectroscopy. The structural stability conferred upon interaction with detergents was similar for both the peptide and the native protein.(ABSTRACT TRUNCATED AT 250 WORDS)

“…When moths are injected with AKH, large amounts of neutral lipid are released from the fat body and are associated with the high-density adult lipophorin (HDLp-A, Mt == 7.63 X 10s, p = 1.076 g/mL) to form the lipid-enriched low-density lipophorin particle (LDLp, M, 1.56 X 106, p = 1.030 g/mL). The stability of LDLp in the hemolymph is reenforced by a third apolipoprotein, apolipophorin III (apoLp-III, Mr «= 1.8 X 104) (Kawooya et al, 1984(Kawooya et al, , 1986aWells et al, 1987;Cole et al, 1987) which binds to the hydrophobic surface of the LDLp. ApoLp-III possesses unique properties which enable it to associate reversibly with LDLp (Kawooya et al, 1986a).…”

mentioning

confidence: 99%

A strategy for solubilizing delipidated apolipoprotein with lysophosphatidylcholine and reconstitution with phosphatidylcholine

Kawooya

Wells²,

Law³

1989

The apolipoproteins of insect lipophorin were dissociated in guanidinium chloride and isolated by gel permeation chromatography. Over 98% of the total lipid in lipophorin was associated with apolipophorin I (apoLp-I), thus suggesting this apolipoprotein to be the lipid binding component of the particle. ApoLp-I was delipidated with ethanol/ether and solubilized in buffer that contained radioactive lysophosphatidylcholine ([3H]LPC) above the critical micellar concentration. Sonic irradiation of radioactive phosphatidylcholine ([14C]PC) with [3H]LPC-solubilized apoLp-I at a molar ratio of 318 resulted in reconstituted lipophorin (RLp-I). [3H]LPC was bound to fatty acid free bovine serum albumin and was separated from RLp-I by density gradient ultracentrifugation and gel permeation chromatography. Negatively stained RLp-I particles were quasispherical with an average radium of 55 A, and their overall morphology and secondary structure were similar to those of native hemolymph lipophorin. The RLp-I particle had a rho = 1.137 g/mL, a Mr approximately 5.2 X 10(5), and a [14C]PC:apoLp-I molar ratio of 308. From the compositional analysis, molecular size, trypsinization, and lipolysis with phospholipase A2, we concluded that each RLp-I particle contained one molecule of apoLp-I and a monomolecular layer of [14C]PC. When injected into the hemolymph of adult moths in vivo, RLp-I was loaded with lipid, as judged by a decrease in its density both in the presence and in the absence of adipokinetic hormone. The similarities in morphology and immunology of RLp-I and native lipophorin, together with the ability of RLp-I to load lipid, suggest that reconstituted lipophorins may serve as models to probe lipophorin structure and function.