A basic trypsin- and chymotrypsin-inhibitor from groundnuts (Arachis hypogaea)

Plant Protease Inhibitors in Therapeutics-Focus on Cancer Therapy

Plants are known to have many secondary metabolites and phytochemical compounds which are highly explored at biochemical and molecular genetics level and exploited enormously in the human health care sector. However, there are other less explored small molecular weight proteins, which inhibit proteases/proteinases. Plants are good sources of protease inhibitors (PIs) which protect them against diseases, insects, pests, and herbivores. In the past, proteinaceous PIs were considered primarily as protein-degrading enzymes. Nevertheless, this view has significantly changed and PIs are now treated as very important signaling molecules in many biological activities such as inflammation, apoptosis, blood clotting and hormone processing. In recent years, PIs have been examined extensively as therapeutic agents, primarily to deal with various human cancers. Interestingly, many plant-based PIs are also found to be effective against cardiovascular diseases, osteoporosis, inflammatory diseases and neurological disorders. Several plant PIs are under further evaluation in in vitro clinical trials. Among all types of PIs, Bowman-Birk inhibitors (BBI) have been studied extensively in the treatment of many diseases, especially in the field of cancer prevention. So far, crops such as beans, potatoes, barley, squash, millet, wheat, buckwheat, groundnut, chickpea, pigeonpea, corn, and pineapple have been identified as good sources of PIs. The PI content of such foods has a significant influence on human health disorders, particularly in the regions where people mostly depend on these kind of foods. These natural PIs vary in concentration, protease specificity, heat stability, and sometimes several PIs may be present in the same species or tissue. However, it is important to carry out individual studies to identify the potential effects of each PI on human health. PIs in plants make them incredible sources to determine novel PIs with specific pharmacological and therapeutic effects due to their peculiarity and superabundance.

Purification, crystallization and preliminary X-ray crystallographic analysis of rice Bowman-Birk inhibitor from Oryza sativa

Bowman-Birk inhibitors (BBIs) are cysteine-rich proteins with inhibitory activity against proteases that are widely distributed in monocot and dicot species. The expression of rice BBI from Oryza sativa is up-regulated and induced by pathogens or insects during germination of rice seeds. The rice BBI (RBTI) of molecular weight 15 kDa has been crystallized using the hanging-drop vapour-diffusion method. According to the diffraction of rice BBI crystals at a resolution of 2.07 A, the unit cell belongs to space group P2(1)2(1)2(1), with unit-cell parameters a = 74.37, b = 96.69, c = 100.36 A. Preliminary analysis indicates four BBI molecules in an asymmetric unit, with a solvent content of 58.29%.

Structural features and molecular evolution of Bowman-Birk protease inhibitors and their potential application

The Bowman-Birk inhibitors (BBIs) are well-studied serine protease inhibitors that are abundant in dicotyledonous and monocotyledonous plants. BBIs from dicots usually have a molecular weight of 8k and are double-headed with two reactive sites, whereas those from monocots can be divided into two classes, one approximately 8 kDa in size with one reactive site (another reactive site was lost) and the other approximately 16 kDa in size with two reactive sites. The reactive site is located at unique exposed surfaces formed by a disulfide-linked beta-sheet loop that is highly conserved, rigid and mostly composed of nine residues. The structural features and molecular evolution of inhibitors are described, focusing on the conserved disulfide bridges. The sunflower trypsin inhibitor-1 (SFTI-1), with 14 amino acid residues, is a recently discovered bicyclic inhibitor, and is the most small and potent naturally occurring Bowman-Birk inhibitor. Recently, BBIs have become a hot topic because of their potential applications. BBIs are now used for defense against pathogens and insects in transgenic plants, which has advantages over using toxic and polluting insecticides. BBIs could also be applied in the prevention of cancer, Dengue fever, and inflammatory and allergic disorders, because of their inhibitory activity with respect to the serine proteases that play a pivotal role in the development and pathogenesis of these diseases. The canonical nine-residue loop of BBIs/STFI-1 provides an ideal template for drug design of specific inhibitors to target their respective proteases.

Peptide mimics of the Bowman-Birk inhibitor reactive site loop

Bowman-Birk Inhibitors (BBIs) are small highly cross-linked proteins that typically display an almost symmetrical "double-headed" structure. Each "head" contains an independent proteinase binding domain. The realization that one BBI molecule could form a 1:1:1 complex with two enzymes led early workers to dissect this activity. Now, after three decades of research, it has been possible to isolate the antiproteinase activity as small ( approximately 11 residues), cyclic, synthetic peptides, which display most of the functional aspects of the protein. More recently, it has been found that these peptide fragments are not just a synthetic curiosity-a natural 14-residue cyclic peptide (SFTI-1), which too encapsulates the BBI inhibitory motif, is found to occur in sunflowers. This article reviews the properties of BBI-based peptides (including SFTI-1) and discusses the features that are important for inhibitory activity.

Nutritional improvement of legume proteins through disulfide interchange

Treatment of raw soy flour with L-cysteine or N-acetyl-L-cysteine results in the introduction of new half-cystine residues into sulfur-poor legume proteins, with a corresponding improvement in nutritional quality as measured by the protein efficiency ratio (PER) in rats. The proteins are modified through formation of mixed disulfide bonds among added sulfhydryl compounds, proteolytic enzyme inhibitors, and structural legume proteins. This modification leads to loss of inhibitory activity and increased protein digestibility and nutritive value. Sodium sulfite is more effective than cysteine in facilitating inactivation of trypsin inhibitors in soy flour. The synergistic effect of sodium sulfite and heat may be due to ability to induce rearrangement of protein disulfide bonds to produce new structural entities without altering the amino acid composition and to the fact that the new structures lose their ability to complex with trypsin or chymotrypsin. The same treatment inactivated hemagglutinins (lectins) in lima bean flour. These considerations suggest a key role for sulfur amino acids in the nutritional quality and safety of legumes.

Plant inhibitors of proteolytic enzymes

The presence of inhibitors of proteinases was stated in many species of plants. There are macropeptides of the molecular weight ranging from 3700 to 8000, often bound to carbohydrates. Potential sources of inhibitors of proteinases are legumes, cereals, potatoes and also some fruits. They are characterized by different activity. "Single-headed" inhibitors inhibit one type of proteolytic enzyme, when "double-headed" inhibitors, possessing two independent active sites, can inhibit several types of proteolytic enzymes at the same time. They also differ in the resistance to temperature and change of pH. The role and importance of inhibitors of proteinases is not exactly explained. They are used in the pharmaceutical, baking and beer-industry as well as in the therapy of numerous diseases.

Stability of enzyme inhibitors and lectins in foods and the influence of specific binding interactions

Proteins with actual or potential antinutrient or toxicant activity found in foodstuffs include (1) enzyme inhibitors, especially those specific for serine proteinases and alpha-amylases, and (2) lectins (hemagglutinins). These inhibitors and lectins must be inactivated during processing or food preparation, usually by heat, to avoid possible undesirable effects. Knowledge of their heat stabilities thus helps determine conditions required for their inactivation or denaturation. Many are heat-stable proteins, and their conformations can be stabilized or destabilized by interactions with other constituents present in the food or the digestive tract. Differential scanning calorimetric (DSC) results show that specific binding interactions can lead to substantial increases in kinetic thermal stability of proteins. Examples of such stabilization include serine proteinase-proteinase inhibitor, alpha-amylase-amylase inhibitor, and metal ion-lectin complexes. The extent of thermal stabilization of proteinases in complexes with inhibitors is correlated with the equilibrium association constant. Presence of more than one denaturing unit revealed by DSC in complexes involving multiheaded inhibitors can be interpreted in relation to domain structures of the inhibitors. Basic information on stability of the enzyme inhibitors and lectins is relevant to food processing, quality, and safety.

Isolation and characterization of a specific enterokinase inhibitor from kidney bean (Phaseolus vulgaris)

A specific enterokinase inhibitor from kidney bean (Phaseolus vulgaris) was purified to homogeneity. It showed a single protein band on sodium dodecyl sulphate/polyacryl-amide-gel electrophoresis in the presence of mercaptoethanol, and the Mr was 31000. Aspartic acid was identified as the N-terminus of the inhibitor. The Mr by gel chromatography on Sephadex G-200 was found to be 60000, indicating the dimeric nature of the inhibitor. The inhibitor was found to be a glycoprotein. The monosaccharide moieties were glucose, mannose, glucuronic acid and glucosamine in the proportions 3.15%, 5.0%, 0.85% and 1.3% respectively. The inhibitor was most active on pig enterokinase, followed by bovine and human enterokinases. Maximal inhibitory activity was elicited by preincubation of the inhibitor with the enzyme for 15 min. Digestion with pepsin resulted in loss of inhibitory activity. The inhibitor was stable to exposure to a wide range of pH values (2-10), and exposure to pH above 10 resulted in loss of inhibitory activity. Modification of arginine residues by cyclohexane 1,2-dione and ninhydrin led to complete loss of enterokinase-inhibitory activity.

Purification, partial characterization, and immunological relationships of multiple low molecular weight protease inhibitors of soybean

Five protease inhibitors, I--V, in the molecular weight range 7000--8000 were purified from Tracy soybeans by ammonium sulfate precipitation, gel filtration on Sephadex G-100 and G-75, and column chromatography on DEAE-cellulose. In common with previously described trypsin inhibitors from legumes, I--V have a high content of half-cystine and lack tryptophan. By contrast with other legume inhibitors, inhibitor II contains 3 methionine residues. Isoelectric points range from 6.2 to 4.2 in order from inhibitor I to V. Molar ratios (inhibitor/enzyme) for 50% trypsin inhibition are I = 4.76, II = 1.32, III = 3.22, IV = 2.17, V = 0.97. Only V inhibit chymotrypsin significantly (molar ratio = 1.33 for 50% inhibition). The sequence of the first 16 N-terminal amino acid residued of inhibitor V is identical to that of the Bowman-Birk inhibitor; all other observations also indicate that inhibitor V and Bowman-Birk are identical. The first 20 N-terminal amino acid residues of inhibitor II show high homology to those of Bowman-Birk inhibitor, differing by 1 deletion and 5 substitutions. Immunological tests show that inhibitors I through IV are fully cross-reactive with each other but are distinct from inhibitor V.

The reactive sites of Kunitz bovine-trypsin inhibitor. Role of lysine-15 in the interaction with chymotrypsin

Kunitz bovine trypsin inhibitor gave with alpha-chymotrypsin a stoichiometric complex stable at neutral pH. The complex has been characteristized by amino acid composition, molecular sieving and zone electrophoresis. Complete dissociation occurred at pH 4.0 as shown by gel filtration, alpha-Chymotrypsin was displaced from the complex by trypsin either in solution or by affinity chromatography on trypsin-Sepharos: alpha-chymotrypsin was recovered in the filtrate (yield about 100%) and the inhibitor was eluted from trypsin-Sepharose with 0.1 M HCl (yield: 83%). Lysine-15 of the inhibitor was shown to be involved in the interaction between alpha-chymotrypsin and the inhibitor. When the complex was maleylated, the maleylated chymotrypsin-bound inhibitor was displaced by affinity chromatography on trypsin-Sepharose. Teh recovered derivative was oxidized, subjected to tryptic hydrolysis and the products separated by peptide mapping and analyzed. The peptides were compared with those obtained with non-maleylated inhibitor and fully maleylated free inhibitor. In the fully maleylated inhibitor, the four lysyl residues of the molecule were blocked but in the maleylated chymotrypsin-bound inhibitor, Lys-15 was unmodified in contrast to Lys-26, Lys-41 and Lys-46; therefore Lys-15 is shielded by chymotrypsin in the complex. On the other hand, when inhibitor with a selectively reduced carboxamidomethylated Cys-14-Cys-38 dislufide bridge was allowed to react with chymotrypsin, cleavage occurred not only at Tyr-21, Tyr-35 and Phe-45 but also at Lys-15, cleavage not observed in the case of the fully oxidized inhibitor. This result shows that under particular conditions the bond Lys-15-Ala-16 can be the substrate for chymotrypsin and the side chain of Lys-15 can be inserted in the chymotrypsin specificity pocket. Apparently the contact area of inhibitor with chymotrypsin seems to be similar to that with trypsin [J. Chauvet and R. Acher (1967) J. Biol. Chem. 242, 4274-4275].

Biological and physiological factors in soybeans

There are limitations to which one is justified in drawing broad generalizations concerning the diverse biological and physiological effects of soy protein products. Nevertheless, there appear to be two distinct situations: (A.) Proper heat treatment exerts a beneficial effect upon the nutritive value of whole soybeans, full‐fat and defatted meal. Associated with proper heating is inactivation of trypsin inhibitor and other heat‐labile factors and conversion of raw refractory proteins to forms that are more readily digested. (B.) Moist heat also has a beneficial effect upon the nutritive value of soy protein isolates. However, a deficiency of certain essential nutrients and the interaction of phytic acid with protein, vitamins, and minerals during processing are the primary factors responsible for the poor nutritive value of soy isolates. Occasionally mineral deficiency symptoms do occur in animals fed soybean meal. It is a misnomer to refer to the growth‐inhibiting and pancreatic hypertrophic properties as a “toxic” effect since both properties are reversible. Modern analytical techniques should be used to reinvestigate the relationship between phytic acid and availability of minerals and vitamins in soy protein isolate diets. Research also is needed to determine more accurately vitamin and mineral contents of soy protein isolates and the availability of vitamins and minerals in soy protein concentrates. Breeding soybean varieties genetically deficient in antinutritional and nonflatulent factors does not appear promising. More research is needed to determine whether fermentation and enzyme processes can be used to prepare flatulent‐free soy products. Minor factors to be considered in assessing the nutritive value of soy products include a weak goitrogen present in soybeans, and a very low estrogenic activity.