High molecular weight renin identified in cytosol fractions of mouse renal cortices

In an attempt to confirm that high molecular weight renin was indeed true renin, we used a specific renin antibody and high performance liquid chromatography to determine characteristics of this protein. In mouse renin granules, renin was stored in a low molecular weight form of 38,000 daltons (LMW renin) and this molecular weight remained unchanged with application 20 mM of sodium tetrathionate. In the cytosol fraction of the renal cortex, LMW renin was partially converted to high molecular weight renin (HMW renin) of 65,000 daltons, as determined using tetrathionate. In both the LMW and HMW renin, enzymatic activity was completely neutralized by application of a specific antiserum of renin and an absolute amount of renin was identified by direct radioimmunoassay. The Km values of HMW and LMW renin were similar. Thus, LMW renin probably binds with renin binding substance and forms HMW renin.     

Urokinase separation from cell culture broth of a human kidney cell line

A single step ion-exchange chromatography on a sulfo-propyl (SP)- Sepharose column was performed to separate both the high molecular weight (HMW)- and low molecular weight (LMW)- forms of enzymatically active urokinase type plasminogen activator from human kidney (HT1080) cell culture media. The level of urokinase secreted by the cell line reached to about 145 Plough units/ml culture broth within 48 h of cultivation. The conditioned cell culture media was applied directly to the column without any prior concentration steps. Polyacrylamide gel electrophoresis of the column eluates in the presence of sodium dodecyl sulphate showed that the cell line secretes three forms of two-chain high molecular weight (HMW) urokinase of molecular weights (M(r)) 64,000, 60,900 and 55,000. In addition, two low molecular weight (LMW) forms of M(r) 22,000 and 20,000; proteolytic cleavage products of HMW, were also found. The HMW and LMW forms had intrinsic plasminogen dependent proteolytic activity as judged by zymographic analysis. The specific activity of the pooled peak fractions increased (approximately 93-fold) to values as high as 1481 Plough units/ mg protein. Both HMW as well as LMW forms were obtained in significantly high yields.     

Stimulation of rat hepatocyte proliferation in vitro and in vivo by factors derived from the bovine small intestinal mucosa

Summary A factor with a molecular weight of less than 1 kDa in the mucosa of the bovine small intestine (low molecular weight factor or LMW factor) stimulated DNA synthesis in rat hepatocytes in primary culture. This factor only showed its activity when it was added with a larger factor with a molecular weight of 30 kDa that was also found in the same tissue (high molecular weight factor or HMW factor). The LMW factor probably acts to enhance the action of a hepatotrophic growth factor, since EGF and HGF can substitute for the HMW factor. The action of the LMW factor was not due to the actions of low molecular weight substances such as norepinephrine, estradiol, triiodothyronine, and putrescine, which enhance the action of EGF or HGF, since substantial amounts of these substances were not found in the extract. When intraperitoneally administered into rats, after two-thirds hepatectomy, the LMW factor enhanced hepatocyte proliferation without the administration of the HMW factor. In the regenerating liver, a hepatotrophic growth factor(s), which acts synergistically with the LMW factor, might be properly provided, but the supply of the LMW factor might be below the level that maximally stimulates hepatocyte proliferation.     

Nuclear activities of basic fibroblast growth factor: potentiation of low-serum growth mediated by natural or chimeric nuclear localization signals

Human basic fibroblast growth factor (FGF-2) occurs in four isoforms: a low molecular weight (LMW FGF-2, 18 kDa) and three high molecular weight (HMW FGF-2, 22, 22.5, and 24 kDa) forms. LMW FGF-2 is primarily cytoplasmic and functions in an autocrine manner, whereas HMW FGF-2s are nuclear and exert activities through an intracrine, perhaps nuclear, pathway. Selective overexpression of HMW FGF-2 forms in fibroblasts promotes growth in low serum, whereas overexpression of LMW FGF-2 does not. The HMW FGF-2 forms have two functional domains: an amino-terminal extension and a common 18-kDa amino acid sequence. To investigate the role of these regions in the intracrine signaling of HMW FGF-2, we produced stable transfectants of NIH 3T3 fibroblasts overexpressing either individual HMW FGF-2 forms or artificially nuclear-targeted LMW FGF-2. All of these forms of FGF-2 localize to the nucleus/nucleolus and induce growth in low serum. The nuclear forms of FGF-2 trigger a mitogenic stimulus under serum starvation conditions and do not specifically protect the cells from apoptosis. These data indicate the existence of a specific role for nuclear FGF-2 and suggest that LMW FGF-2 represents the biological messenger in both the autocrine/paracrine and intracrine FGF-2 pathways.     

Kininogenase activity of alpha and beta/gamma forms of bovine thrombin

The kininogenase activity of alpha- and beta/gamma-forms of bovine thrombin with respect to the high molecular weight (HMW) and low molecular weight (LMW) human kininogens was studied. It was shown that both forms of the enzyme split of bradykinin from these kininogens. The kininogenase activity of alpha-thrombin is completely blocked by the highly specific thrombin inhibitor Nalpha-dansyl-L-arginine-p-ethylpiperidineamide, but not by the soya bean trypsin inhibitor. The alpha- and beta/gamma-forms of thrombin hydrolyze HMW (Km(app) = 4.5 and 3.3 microM, respectively) and LMW (Km(app) = 10.1 and 4.7 microM, respectively). The specific constants (kcat/Km(app) ) for thrombin with respect to the substrates differ about 7-fold, predominantly due to the high catalytic rates of HMW as compared to LMW; the kcat values are 0.18 and 0.06 min-1, respectively. alpha-Thrombin upon a long-term (over 1 hour) exposure to HMW, besides bradykinin, splits off the product inhibiting the kininogenase activity of thrombin. No differences in the specificity of the beta/gamma-form of thrombin with resect to HMW and LMW were detected.     

Mapping of functional domains of human high molecular weight and low molecular weight kininogens using murine monoclonal antibodies

Thirty-four monoclonal antibodies directed against human high molecular weight (HMW) and low molecular weight (LMW) kininogens and their derivatives were obtained, and the specificities of the antibodies were assayed by enzyme-linked immunosorbent assay (ELISA). By use of HMW kininogen, kinin-free HMW kininogen, kinin-free and fragment 1.2 (fr 1.2) free HMW kininogen, fr 1.2-light chain of HMW kininogen, LMW kininogen, kinin-free LMW kininogen, heavy chain of LMW kininogen, and light chain of LMW kininogen, the monoclonal antibodies were characterized and classified into four groups: (A) 20 monoclonal antibodies reacting with only the heavy chain, a common region of HMW and LMW kininogens; each of these monoclonal antibodies possessed the specificity to domain 1 (2 monoclonal antibodies), domain 2 (2 monoclonal antibodies), domain 3 (7 monoclonal antibodies), and both domains 2 and 3 (7 monoclonal antibodies) of the heavy chain; (B) 7 monoclonal antibodies reacting with fr 1.2, a unique histidine-rich region; (C) 5 monoclonal antibodies reacting with the light chain of HMW kininogen; (D) 2 monoclonal antibodies reacting with the light chain of LMW kininogen. Two monoclonal antibodies in the first group (group A), designated HKG H7 and H12, effectively suppressed the thiol proteinase inhibitor activity of HMW kininogen to papain and calpains and of LMW kininogen to papain, but the others did not affect it. Further, all the monoclonal antibodies which recognized the fr 1.2 or light chain of HMW kininogen (groups B and C) suppressed the clotting activity.(ABSTRACT TRUNCATED AT 250 WORDS)     

Localization of DNA sequences governing alternative mRNA production of rat kininogen genes

The two types of the rat kininogen genes show different modes of mRNA production. The K gene encodes two distinct mRNAs for high molecular weight (HMW) and low molecular weight (LMW) kininogens. These two mRNAs are generated by differential usage of the 3'-terminal exon (LMW exon) and the one next to this exon (HMW exon) through alternative polyadenylation and splicing. In contrast, the two T genes selectively generate the LMW form of the mRNA, although the T genes are extremely homologous to the K gene, including the sequence (psi HMW region) corresponding to the HMW exon of the K gene. In this study, we constructed a series of chimeric kininogen genes by exchanging equivalent restriction fragments of the K and T genes and examined the sequences and the mechanisms governing the different expression patterns of the kininogen genes by introducing the chimeric genes into heterologous COS cells. The results indicate that the formation of the two forms of the mRNA is controlled by two separate 3' sequences of the kininogen genes. One is located within the internal sequence of the HMW/psi HMW region, whereas the other is within the LMW exon and its preceding region. Our data also suggest that the different expression patterns of the kininogen genes are primarily governed by differing splicing efficiency.     

The high molecular weight and the low molecular weight acid phosphatases of the frog liver and their phosphotyrosine activity

1. Two molecular weight classes of non-specific acid phosphatases (AcPases) (3.1.3.2) are present in the frog (Rana esculenta) liver: a higher molecular weight (HMW) of Mr 140,560 and a lower molecular weight (LMW) of Mr 38,180 enzyme. 2. The LMW AcPase was described earlier and the HMW AcPase of optimum pH 4.8 is shown to be a L(+)-tartrate sensitive, thermolabile, dimeric glycoenzyme slightly activated by DTT. 3. The HMW and the LMW AcPases exhibit activity for phosphotyrosine which showed similar sensitivity to various effectors as the p-nitrophenyl phosphatase activity; however, both enzymes differed substantially in this respect suggesting that they might be involved in different metabolic steps.     

Adiponectin multimers and metabolic syndrome traits: relative adiponectin resistance in African Americans

African Americans (AAs) tend to have lower total adiponectin levels compared to European Americans (EA); however, it is not known whether race affects adiponectin multimer distribution and their relationships to metabolic traits. We measured total adiponectin, high molecular weight (HMW), low molecular weight (LMW) (i.e., hexamer), and trimer adiponectin in 132 normoglycemic premenopausal women (75 AAs, 57 EAs), together with measures of total and abdominal fat, plasma lipids, insulin sensitivity (S(i)), and genetic admixture estimates. We found that lower total adiponectin in AAs was explained by reduced LMW, and trimer forms because levels of HMW did not differ between races. In EAs, HMW was highly correlated with multiple metabolic syndrome traits. In contrast, the LMW and trimer forms were most highly correlated with metabolic traits in AAs, including abdominal adiposity, lipids, and S(i). At similar levels of visceral adiposity, AAs exhibited significantly lower LMW adiponectin than EAs. Similarly, at comparable levels of HMW and LMW adiponectin, AAs were more insulin resistant than their EA counterparts. In conclusion, (i) serum adiponectin is lower in AAs predominantly as a result of reduced concentrations of LMW and trimers multimeric forms; (ii) LMW and trimer, not HMW, are most broadly correlated with metabolic traits in AAs. Thus, HMW adiponectin may exert less bioactivity in explaining the metabolic syndrome trait cluster in populations of predominant African genetic background.     

Control of antibody high and low molecular weight species by depth filtration-based cell culture harvesting

Depth filtration-based harvesting is widely used in mAb manufacturing to remove cell and process-related impurities. However, it has not been studied on control of product-related impurities, which are very critical for product quality. In this article, we studied the interactions of depth filter with high and low molecular weight species (HMWs and LMWs) for their direct removal from cell culture. The process parameters (filter, loading, temperature, and flux) were evaluated for adsorption of HMWs and LMWs by depth filters. The adsorption is significantly dependent on filter media and loading capacity and is mainly on the basis of hydrophobic interaction during harvesting. The HMW and LMW species were characterized as HMW1, HMW2, LMW1, and LMW2. The increasing binding from LMW2 to LMW1, HMW1, and HMW2 is correlated with their increasing hydrophobicity score. Adsorption using enriched HMW sample demonstrated similar total protein binding capacity (36–40 g/m²) between depth filters D0HC and X0HC. However, X0HC has stronger HMW binding than D0HC (71% vs 43% of bound protein), indicating more hydrophobic interaction in X0HC. HMW2 DBC on X0HC reached 12 g/m², similar to protein binding on hydrophobic interaction membrane adsorbers. Further study showed LMW can induce HMW formation. This study provides a critical understanding of HMW and LMW interaction with depth filters. The strategy of HMW and LMW control by depth filtration-based harvesting was implemented successfully in mAb manufacturing.     

Regulation of Sarcoplasmic Reticulum Ca2+ ATPase 2 (SERCA2) Activity by Phosphodiesterase 3A (PDE3A) in Human Myocardium: PHOSPHORYLATION-DEPENDENT INTERACTION OF PDE3A1 WITH SERCA2*

Cyclic nucleotide phosphodiesterase 3A (PDE3) regulates cAMP-mediated signaling in the heart, and PDE3 inhibitors augment contractility in patients with heart failure. Studies in mice showed that PDE3A, not PDE3B, is the subfamily responsible for these inotropic effects and that murine PDE3A1 associates with sarcoplasmic reticulum Ca²⁺ ATPase 2 (SERCA2), phospholamban (PLB), and AKAP18 in a multiprotein signalosome in human sarcoplasmic reticulum (SR). Immunohistochemical staining demonstrated that PDE3A co-localizes in Z-bands of human cardiac myocytes with desmin, SERCA2, PLB, and AKAP18. In human SR fractions, cAMP increased PLB phosphorylation and SERCA2 activity; this was potentiated by PDE3 inhibition but not by PDE4 inhibition. During gel filtration chromatography of solubilized SR membranes, PDE3 activity was recovered in distinct high molecular weight (HMW) and low molecular weight (LMW) peaks. HMW peaks contained PDE3A1 and PDE3A2, whereas LMW peaks contained PDE3A1, PDE3A2, and PDE3A3. Western blotting showed that endogenous HMW PDE3A1 was the principal PKA-phosphorylated isoform. Phosphorylation of endogenous PDE3A by rPKAc increased cAMP-hydrolytic activity, correlated with shift of PDE3A from LMW to HMW peaks, and increased co-immunoprecipitation of SERCA2, cav3, PKA regulatory subunit (PKARII), PP2A, and AKAP18 with PDE3A. In experiments with recombinant proteins, phosphorylation of recombinant human PDE3A isoforms by recombinant PKA catalytic subunit increased co-immunoprecipitation with rSERCA2 and rat rAKAP18 (recombinant AKAP18). Deletion of the recombinant human PDE3A1/PDE3A2 N terminus blocked interactions with recombinant SERCA2. Serine-to-alanine substitutions identified Ser-292/Ser-293, a site unique to human PDE3A1, as the principal site regulating its interaction with SERCA2. These results indicate that phosphorylation of human PDE3A1 at a PKA site in its unique N-terminal extension promotes its incorporation into SERCA2/AKAP18 signalosomes, where it regulates a discrete cAMP pool that controls contractility by modulating phosphorylation-dependent protein-protein interactions, PLB phosphorylation, and SERCA2 activity.     

Mechanical Properties of Mammalian and Fish Gelatins as a Function of the Contents of α-Chain, β-Chain,and Low and High Molecular Weight Fractions

Small-strain oscillatory measurements and size-exclusion chromatography coupled to multiangle laser light scattering were used to study the mechanical properties and the molecular weight distribution, respectively, of acid porcine skin gelatins (type A), lime bovine bone gelatins (type B), and cold water fish gelatins, while principal component analysis (PCA) and partial least squares regression were used to relate the mechanical properties with the molecular weight distribution. The present study suggests a linear relationship between the mechanical properties and the fractions of low molecular weight (LMW) molecules, α-chains, β-chains, and high molecular weight (HMW) molecules. The Bloom value for mammalian gelatin was positively correlated with the fractions of α-chains, β-chains, and HMW molecules and negatively correlated with the fraction of LMW molecules. The dynamic storage modulus for cold water fish gelatin was positively correlated with the fractions of β-chains and HMW molecules and negatively correlated with the fractions of LMW molecules and α-chains.     

The contribution of apoptosis-inducing factor, caspase-activated DNase, and inhibitor of caspase-activated DNase to the nuclear phenotype and DNA degradation during apoptosis

We have assessed the contribution of apoptosis-inducing factor (AIF) and inhibitor of caspase-activated DNase (ICAD) to the nuclear morphology and DNA degradation pattern in staurosporine-induced apoptosis. Expression of D117E ICAD, a mutant that is resistant to caspase cleavage at residue 117, prevented low molecular weight (LMW) DNA fragmentation, stage II nuclear morphology, and detection of terminal deoxynucleotidyl transferase staining. However, high molecular weight (HMW) DNA fragmentation and stage I nuclear morphology remained unaffected. On the other hand, expression of either D224E or wild type ICAD had no effect on DNA fragmentation or nuclear morphology. In addition, both HMW and LMW DNA degradation required functional executor caspases. Interestingly, silencing of endogenous AIF abolished type I nuclear morphology without any effect on HMW or LMW DNA fragmentation. Together, these results demonstrate that AIF is responsible for stage I nuclear morphology and suggest that HMW DNA degradation is a caspase-activated DNase and AIF-independent process.     

Effect of overexpressing fibroblast growth factor 2 protein isoforms in osteoblastic ROS 17/2.8 cells

Fibroblast growth factor-2 (FGF-2) is made by osteoblasts and modulates their function. There are high molecular weight (HMW) protein isoforms of FGF-2 that have nuclear localization sequences and a low molecular weight (LMW) 18 kDa FGF-2 protein that is exported from cells. Since FGF-2 is a trophic factor and potent mitogen for osteoblasts, the goal of this study was to utilize targeted overexpression of FGF-2 as a novel means of assessing different FGF-2 isoforms on osteoblastic cell viability and proliferation. Either LMW or HMW human Fgf2 cDNAs were cloned downstream of 3.6 kb alpha1(I)-collagen 5' regulatory elements (Col 3.6). A set of expression vectors, called Col3.6-Fgf2 isoforms-IRES-GFPsaph, capable of concurrently overexpressing either LMW or HMW FGF-2 isoforms concomitant with GFPsaph from a single bicistronic mRNA were built. Viable cell number in ROS 17/2.8 cells stably transfected with Vector (Col3.6-IRES-GFPsaph) versus each of the Col3.6-Fgf2-IRES-GFPsaph constructs were compared. In the presence of 1 or 10% serum, DNA synthesis was increased in cells expressing any isoform of FGF-2 compared with vector. However, cells transfected with HMW isoform had augmented DNA synthesis in 1 or 10% serum compared with cells expressing either ALL or LMW FGF-2 isoforms. A neutralizing FGF-2 antibody significantly reduced the mitogenic response in cells harboring ALL or the LMW FGF-2 isoforms but did not block the mitogenic effect of cells harboring the HMW isoforms. In summary, overexpression of any isoform of FGF-2 protein increased viable cell number and OB proliferation in the presence of low or high concentrations of serum. However, the HMW/nuclear isoforms preferentially mediate augmented OB proliferation. We conclude that differential expression of FGF-2 proteins isoforms is important in modulating OB function.     

Expression of the high molecular weight fibroblast growth factor-2 isoform of 210 amino acids is associated with modulation of protein kinases C delta and epsilon and ERK activation

The high molecular weight (HMW) fibroblast growth factor (FGF)-2 isoform of 210 amino acids initiated at a CUG start codon possesses a nuclear localization sequence and is not secreted. In contrast, the low molecular weight (LMW) isoform of 155 amino acids initiated at the AUG start codon can be secreted and activates the cell surface FGF receptors. The two isoforms possess different biological properties; however, little is known about the intracrine regulatory mechanisms involved in the biological effects of the HMW FGF-2 isoform. Using pancreatic cells stably transfected with cDNAs leading to the expression of either the HMW FGF-2 (A3 cells) or the LMW form (A5 cells), we provide evidence that the two FGF-2 isoforms differentially modulate PKC levels. The LMW FGF-2 up-regulated the PKC epsilon levels by 1.6-fold; by contrast the HMW isoform down-regulated the level of this PKC isotype by about 3-fold and increased the amount of PKC delta by 1.7-fold. PKC mRNAs were also modified, suggesting that PKC expression was regulated at a pretranslational level. Additionally, expression of different levels of the HMW FGF-2 with an inducible expression system confirmed the role of this isoform on PKC delta and epsilon expressions. Increased activation of ERK-1 and -2 was also observed in cells expressing the HMW FGF-2. By using different PKC inhibitors and a dominant negative PKC delta, it was found that ERK activation was PKC delta-dependent. These data indicate that expression of HMW FGF-2 can modify PKC levels by acting at the intracellular level and that the overexpression of PKC delta induces ERK-1/2 activation. The expression of a dominant negative FGFR1 did not reduce ERK-1/2 activation by the HMW FGF-2, suggesting that ERK activation does not require FGFR activity. The signaling cascade downstream of ERK might be involved in the known mitogenic effect exerted by this FGF-2 isoform.     

A set of U1 snRNA-complementary sequences involved in governing alternative RNA splicing of the kininogen genes

The rat K and T kininogen genes show different modes of mRNA production. The K gene encodes two distinct mRNAs for high molecular weight (HMW) and low molecular weight (LMW) kininogens. These two mRNAs are generated by differential usage of the 3'-terminal exon (LMW exon) and the exon next to and upstream from the LMW exon (HMW exon) through alternative splicing and polyadenylation. In contrast, the T gene generates one mRNA by using selectively the LMW exon, although the T gene is extremely homologous to the K gene. In this study, we constructed a series of chimeric kininogen genes by not only exchanging equivalent restriction fragments of the two genes but also replacing nucleotides that differ between the two genes. We then examined the sequences and the mechanisms governing the different expression patterns of the two genes by transfecting the chimeric genes into heterologous COS cells. The results indicated that the different expression patterns of the K and T genes are governed by two separate internal sequences of the HMW and LMW exons. The internal HMW sequence contains a set of five repetitive sequences, and these repetitive sequences are highly complementary to the 5' portion of U1 snRNA. Furthermore, the nucleotide differences in the U1 snRNA-complementary sequences between the K and T genes have marked effects on the relative formation of the HMW and LMW mRNAs; this indicates that the repetitive sequences complementary to U1 snRNA play a crucial role in determining the relative expression of the two mRNAs. Based on these findings, we discuss a novel mechanism for alternative RNA processing, in which splicing efficiency is controlled by the interaction of U1 small nuclear ribonucleoproteins and the U1 snRNA-complementary repetitive sequences of the kininogen pre-mRNA.     

Rat Serum Factors Inhibiting the G1-S Transition In Hepatocytes

An attempt was made to detect the serum factors inhibiting the G₁-S transition in synchronized, baby rat hepatocytes. In untreated adult rat serum, this inhibitory activity was always linked to high molecular weight (HMW) compounds. Incubation of serum with trypsin or chymotrypsin resulted in the formation of a low molecular weight (LMW) G₁-S inhibitory factor. the same result was obtained with fractions from adult rat liver but not with kidney or spleen fractions. Separation of the LMW factor by ultrafiltration increased its specific activity by about 10³. the active period in the cell cycle of both the LMW and HMW factors was the same: the late G₁ phase. However, the activity of the LMW factor was not blocked by the Kunitz factor. an enzymatic transformation of the HMW factor might be induced by liver cell membrane-bound proteases and constitute a mechanism regulating hepatocyte proliferation.     

Cloning and sequence analysis of cDNAs for human high molecular weight and low molecular weight prekininogens. Primary structures of two human prekininogens

cDNA sequences for both human high molecular weight (HMW) and low molecular weight (LMW) prekininogens have been isolated by molecular cloning and determined by sequence analysis. The sequence determination together with the S1 nuclease mapping and RNA blot-hybridization analyses indicate that human HMW and LMW prekininogen mRNAs share an identical sequence throughout the 5'-untranslated region and the protein-coding region up to the sequence encoding the 12 amino acids distal to the bradykinin sequence, and the two mRNAs then completely diverge from each other. The signal peptide, the heavy chain (H chain), and the bradykinin moiety, which are common between the two prekininogens, consist of 18, 362, and 9 amino acids, respectively, while the light chains (L chains) of the HMW and LMW prekininogens are composed of 255 and 38 amino acids, respectively. All 17 cysteine residues present in the human and bovine H chains are located at exactly equivalent positions, indicating that the human H chain, like the bovine counterpart, can form 8 loop structures, each connected by two adjacent cysteine residues. The L chains of human and bovine kininogens differ in the protein lengths as well as in some amino acids crucial for the processing of the kininogens by kallikrein. Based upon this finding, we have discussed the molecular basis for the different modes of processing of human and bovine HMW kininogens and for the different kinetics of contact activation reactions exhibited by the two HMW kininogens.     

Microencapsulation of Linoleic Acid with Low- and High-molecular-weight Components of Soluble Soybean Polysaccharide and Its Oxidation Process

Soluble soybean polysaccharide (SSPS) was fractionated into its low- (LMW) and high-molecular-weight (HMW) components to test their antioxidative and emulsifying properties. Linoleic acid was emulsified with an aqueous solution of SSPS, HMW, a mixture of LMW or HMW with maltodextrin, or maltodextrin alone. The emulsions prepared with SSPS, HWM and the mixture of HMW with maltodextrin were stable. These emulsions were spay-dried to produce microcapsules. The encapsulated linoleic acid was oxidized at 37°C and at various levels of relative humidity. Linoleic acid encapsulated with the mixture of LMW with maltodextrin or HMW was stable to oxidation, and this stability increased as the weight fraction of LMW in the mixture was increased. The LMW components also had high DPPH-radical scavenging activity. These results indicate that LMW played an important role in suppressing or retarding the oxidation of linoleic acid encapsulated with SSPS. The oxidative stability of linoleic acid encapsulated with a mixture of the LMW and HMW components was high at low and high relative humidity, but not at intermediate levels of relative humidity.     

Microencapsulation of linoleic acid with low- and high-molecular-weight components of soluble soybean polysaccharide and its oxidation process

Soluble soybean polysaccharide (SSPS) was fractionated into its low- (LMW) and high-molecular-weight (HMW) components to test their antioxidative and emulsifying properties. Linoleic acid was emulsified with an aqueous solution of SSPS, HMW, a mixture of LMW or HMW with maltodextrin, or maltodextrin alone. The emulsions prepared with SSPS, HWM and the mixture of HMW with maltodextrin were stable. These emulsions were spay-dried to produce microcapsules. The encapsulated linoleic acid was oxidized at 37 degrees C and at various levels of relative humidity. Linoleic acid encapsulated with the mixture of LMW with maltodextrin or HMW was stable to oxidation, and this stability increased as the weight fraction of LMW in the mixture was increased. The LMW components also had high DPPH-radical scavenging activity. These results indicate that LMW played an important role in suppressing or retarding the oxidation of linoleic acid encapsulated with SSPS. The oxidative stability of linoleic acid encapsulated with a mixture of the LMW and HMW components was high at low and high relative humidity, but not at intermediate levels of relative humidity.