A tale of two waves: Delineating diverse genomic and transmission landscapes driving the COVID-19 pandemic in Pune, India

BACKGROUND

Modern response to pandemics, critical for effective public health measures, is shaped by the availability and integration of diverse epidemiological outbreak data. Tracking variants of concern (VOC) is integral to understanding the evolution of SARS-CoV-2 in space and time, both at the local level and global context. This potentially generates actionable information when integrated with epidemiological outbreak data.

METHODS

A city-wide network of researchers, clinicians, and pathology diagnostic laboratories was formed for genome surveillance of COVID-19 in Pune, India. The genomic landscapes of 10,496 sequenced samples of SARS-CoV-2 driving peaks of infection in Pune between December-2020 to March-2022, were determined. As a modern response to the pandemic, a "band of five" outbreak data analytics approach was used. This integrated the genomic data (Band 1) of the virus through molecular phylogenetics with key outbreak data including sample collection dates and case numbers (Band 2), demographics like age and gender (Band 3-4), and geospatial mapping (Band 5).

RESULTS

The transmission dynamics of VOCs in 10,496 sequenced samples identified B.1.617.2 (Delta) and BA(x) (Omicron formerly known as B.1.1.529) variants as drivers of the second and third peaks of infection in Pune. Spike Protein mutational profiling during pre and post-Omicron VOCs indicated differential rank ordering of high-frequency mutations in specific domains that increased the charge and binding properties of the protein. Time-resolved phylogenetic analysis of Omicron sub-lineages identified a highly divergent BA.1 from Pune in addition to recombinant X lineages, XZ, XQ, and XM.

CONCLUSIONS

The band of five outbreak data analytics approach, which integrates five different types of data, highlights the importance of a strong surveillance system with high-quality meta-data for understanding the spatiotemporal evolution of the SARS-CoV-2 genome in Pune. These findings have important implications for pandemic preparedness and could be critical tools for understanding and responding to future outbreaks.

Study of leprosy in children

Leprosy, a disease as oId a mankind, has been a public health problem in many developing countries and among children, it reflects disease transmission in the community and efficiency of control programmes study on childhood leprosy was carried out Gandhi Hospital, spread over 4 years. There were 32 children among 280 diagnosed cases of leprosy. The study revealed an incidence of 11.43% among leprosy patients with more number of boy being affected than girls. Most of children presented with hypopigmented anaesthetic patches. Hansen's BT was the most common clinical type of leprosy with extremities being the common site of involvement. Slit-skin smear was positive in 25% of children. We could find significant positive clinico-pathological correlation among 12 children who were subjected to biopsy. Reactional states and deformites were less common in our study.

Multicentric reticulohistiocytosis

A 41 -year-old man presented with multiple, painful and tender nodules on the palms, soles, scalp; and on the limbs predominantly around the joints with associated arthropathies. Smaller nodules were seen on the ear helices. There was no other clinically evident or investigative abnormality. Histopathological study confirmed a diagnosis of multicentric reticulo histiocytosis.

Effects of a potato cysteine proteinase inhibitor on midgut proteolytic enzyme activity and growth of the southern corn rootworm, Diabrotica undecimpunctata howardi (Coleoptera: Chrysomelidae)

The major proteinase activity in extracts of larval midguts from the southern corn rootworm (SCR), Diabrotica undecimpunctata howardi, was identified as a cysteine proteinase that prefers substrates containing an arginine residue in the P1 position. Gelatin-zymogram analysis of the midgut proteinases indicated that the artificial diet-fed SCR, corn root-fed SCR, and root-fed western corn rootworms (Diabrotica virgifera virgifera) possess a single major proteinase with an apparent molecular mass of 25kDa and several minor proteinases. Similar proteinase activity pH profiles were exhibited by root-fed and diet-fed rootworms with the optimal activity being slightly acidic. Rootworm larvae reared on corn roots exhibited significantly less caseinolytic activity than those reared on the artificial diet. Midgut proteolytic activity from SCR was most sensitive to inhibition by inhibitors of cysteine proteinases. Furthermore, rootworm proteinase activity was particularly sensitive to inhibition by a commercial protein preparation from potato tubers (PIN-II). One of the proteins, potato cysteine proteinase inhibitor-10', PCPI-10', obtained from PIN-II by ion-exchange chromatography, was the major source of inhibitory activity against rootworm proteinase activity. PCPI-10' and E-64 were of comparable potency as inhibitors of southern corn rootworm proteinase activity (IC(50) =31 and 35nM, respectively) and substantially more effective than chicken egg white cystatin (IC(50) =121nM). Incorporation of PCPI-10' into the diet of SCR larvae in feeding trials resulted in a significant increase in mortality and growth inhibition. We suggest that expression of inhibitors such as PCPI-10' by transgenic corn plants in the field is a potentially attractive method of host plant resistance to these Diabrotica species.

Rapid gastric fluid digestion and biochemical characterization of engineered proteins enriched in essential amino acids

The barley high lysine (BHL) proteins are nutritionally enhanced derivatives of barley chymotrypsin inhibitor-2 (CI-2). A compactly folded new CI-2 derivative, BHL9, was engineered with the highest content of threonine, tryptophan, and isoleucine yet achieved in this protein family (15.1, 9.4, and 12.1 wt %, respectively). BHL9 had an unfolding midpoint of 5.5 M guanidinium chloride, significantly greater than values for wild type (3.9 M) or for the previously most stable BHL protein, BHL8 (3.6 M). BHL9 and all other derivatives were digested within 15 s in simulated gastric fluid (SGF), suggesting nutritional availability upon ingestion. Denaturation of the proteins in SGF minus pepsin was revealed by changes in their fluorescence emission spectra and/or far UV circular dichroism spectra. The proteins lack homology to known allergens. Significantly, the BHL8 and BHL9 proteins were stable to proteases at pH 7.5 or 8.0, attesting to their potential for high expression in plants.

Strategies to generate antibodies capable of distinguishing between proteins with >90% amino acid identity

Protein engineering is a common strategy for the generation of protein variants with new properties. The engineered variants often have a high degree of similarity with the wild-type progenitor protein, necessitating a tool (e.g., antibody) to distinguish the wild-type and variant protein forms. As part of an overall effort to understand the process of incorporation of amino acids into storage proteins during seed fill in soybean, we have engineered a variant of soybean vegetative storage protein beta (VSPbeta) that is 91.8% identical in amino acid sequence to the wild-type protein, but contains 10% methionine (VSPbeta-Met, unpublished results). Thus, it would be desirable to have antibodies that specifically recognize VSPbeta-Met over the endogenously expressed wild-type protein in transgenic plants. To this end, we compared three strategies for the isolation of VSPbeta-Met-specific antibodies: (1) hybridoma production using VSPbeta-Met protein as the antigen, (2) polyclonal antibody production in rabbits using a peptide antigen corresponding to a methionine-rich region of VSPbeta-Met, and (3) subtractive immunization in mice using VSPbeta-WT as the tolerogen, cyclophosphamide for immunosuppression and VSPbeta-Met as the immunogen. While the first strategy generated antibodies cross-reactive to both antigens, the second strategy generated polyclonal antibodies that preferentially recognized the variant protein in immunoblots. However, using subtractive immunization, we were able to generate mouse polyclonal antibodies that exhibited 10-fold greater reactivity with VSPbeta-Met than VSPbeta-WT in an ELISA.

A single disulfide bond restores thermodynamic and proteolytic stability to an extensively mutated protein

The potential for engineering stable proteins with multiple amino acid substitutions was explored. Eleven lysine, five methionine, two tryptophan, one glycine, and three threonine substitutions were simultaneously made in barley chymotrypsin inhibitor-2 (CI-2) to substantially improve the essential amino acid content of the protein. These substitutions were chosen based on the three-dimensional structure of CI-2 and an alignment of homologous sequences. The initial engineered protein folded into a wild-type-like structure, but had a free energy of unfolding of only 2.2 kcal/mol, considerably less than the wild-type value of 7.5 kcal/mol. Restoration of the lysine mutation at position 67 to the wild-type arginine increased the free energy of unfolding to 3.1 kcal/mol. Subsequent cysteine substitutions at positions 22 and 82 resulted in disulfide bond formation and a protein with nearly wild-type thermodynamic stability (7.0 kcal/mol). None of the engineered proteins retained inhibitory activity against chymotrypsin or elastase, and all had substantially reduced inhibitory activity against subtilisin. The proteolytic stabilities of the proteins correlated with their thermodynamic stabilities. Reduction of the disulfide bond resulted in substantial loss of both thermodynamic and proteolytic stabilities, confirming that the disulfide bond, and not merely the cysteine substitutions, was responsible for the increased stability. We conclude that it is possible to replace over a third of the residues in CI-2 with minimal disruption of stability and structural integrity.

Involvement of cysteine residues and domain interactions in the reversible unfolding of lipoxygenase-1

Urea-induced unfolding of lipoxygenase-1 (LOX1) at pH 7.0 was followed by enzyme activity, spectroscopic measurements, and limited proteolysis experiments. Complete unfolding of LOX1 in 9 M urea in the presence of thiol reducing or thiol modifying reagents was observed. The aggregation and oxidative reactions prevented the reversible unfolding of the molecule. The loss of enzyme activity was much earlier than the structural loss of the molecule during the course of unfolding, with the midpoint concentrations being 4.5 and 7.0 M for activity and spectroscopic measurements, respectively. The equilibrium unfolding transition could be adequately fitted to a three-state, two-step model (N left arrow over right arrow I left arrow over right arrow U) and the intermediate fraction was maximally populated at 6.3 M urea. The free energy change (DeltaG(H(2)O)) for the unfolding of native (N) to intermediate (I) was 14.2 +/- 0.28 kcal/mol and for the intermediate to the unfolded state (U) was 11.9 +/- 0.12 kcal/mol. The ANS binding measurements as a function of urea concentration indicated that the maximum binding of ANS was in 6.3 M urea due to the exposure of hydrophobic groups; this intermediate showed significant amount of tertiary structure and retained nearly 60% of secondary structure. The limited proteolysis measurements showed that the initiation of unfolding was from the C-terminal domain. Thus, the stable intermediate observed could be the C-terminal domain unfolded with exposed hydrophobic domain-domain interface. Limited proteolysis experiments during refolding process suggested that the intermediate refolded prior to completely unfolded LOX1. These results confirmed the role of cysteine residues and domain-domain interactions in the reversible unfolding of LOX1. This is the first report of the reversible unfolding of a very large monomeric, multi-domain protein, which also has a prosthetic group.

Conformation and stability of barley chymotrypsin inhibitor-2 (CI-2) mutants containing multiple lysine substitutions

A major goal of agricultural biotechnology is to increase the nutritional value of maize seed through the expression of heterologous proteins enriched in lysine. One promising candidate is barley chymotrypsin inhibitor-2 (CI-2), a plant protein that has been extensively characterized with respect to structure and function. Based on the tertiary structure of wild-type (WT) CI-2, five mutants with lysine contents ranging from 20 to 25 mol percent were designed, expressed in Escherichia coli and purified by ion exchange and gel permeation chromatography. Inasmuch as previous transgenic experiments suggested that proper folding and stability may be essential for in vivo accumulation of the engineered proteins in plant cells, we first undertook an in vitro study of the conformation and thermodynamic stability of the CI-2 mutants in order to select an ideal candidate for plant expression. Mutant and WT CI-2 proteins had similar circular dichroism spectra, suggesting similar secondary structures. However, differences in the accessibility of the sole tryptophan residue, Trp24, indicated that the local conformation differed among the mutants. The thermodynamic stability of the mutants ranged from <2 to 4.9 kcal/mol compared with approximately 7 kcal/mol for the wild-type protein. In conjunction with proteolytic stability studies, we have identified one mutant that has the potential to be expressed in a stable manner in plant cells.

Affinity properties of phosvitin: interaction of phosvitin with serine hydroxymethyl transferase

The affinity of phosvitin with serine hydroxymethyl transferase (SHMT), an acidic multi-subunit protein, was evaluated by measurements of enzyme activity, sedimentation velocity, steady-state fluorescence, circular dichroism and kinetic thermal stability. While the presence of phosvitin had no effect on the SHMT activity, the sedimentation coefficient of SHMT increased from 8.7 S to 12.5 S suggesting the formation of a complex at a SHMT:phosvitin molar ratio of 2:1. Based on steady-state fluorescence quenching measurements an association constant of 2.4 +/- 0.2 x 10(5) M-1 at 25 degrees C was obtained for the interaction of phosvitin with SHMT. The temperature dependency of the association constant in the range 15-35 degrees C suggests the involvement of ionic forces in the interaction. The thermal inactivation of SHMT followed first order kinetics. In the presence of phosvitin the rate constant decreased and half time increased. The circular dichroism measurements suggest that phosvitin interaction does not involve pyridoxal phosphate binding domain of the enzyme. Although minor changes in the secondary structure of the enzyme were observed, the environment around aromatic amino acids did not change significantly.

Conformation and antimicrobial activity of linear derivatives of tachyplesin lacking disulfide bonds

Tachyplesin is a potent antimicrobial peptide isolated from the hemocytes of the horseshoe crab, Tachypleus tridentatus. Previous studies have shown that the 17-residue peptide has an intrinsic amphipathic structure conferred by two antiparallel beta-sheets held rigidly by two disulfide bonds. Taking its short length into account and the potential of such a small polypeptide to take on multiple conformational states, one may assume that the disulfide bonds are relevant determinants of function. However, in order to gain a global perspective on the tolerance of cysteine residues in tachyplesin to amino acid substitutions, a series of linear peptides have been synthesized and their physicochemical properties analyzed. In these linear peptides, the cysteines have been replaced with amino acids possessing different side-chain properties, i.e., aliphatic hydrophobic (Ala, Leu, Ile, Val, and Met), aromatic hydrophobic (Phe and Tyr), and acidic (Asp). Activity assays using natural and synthetic membranes, and conformational measurements, highlight the subtle influence and variability of the amino acid side-chain properties on peptide structure. While an unequivocal interpretation of the results will have to await more refined structural measurements, our results indicate that a rigidly held disulfide-bonded beta-pleated sheet structure may not be absolutely essential for antimicrobial activity. Furthermore, the results challenge the accepted dogma of structure-activity relationships among antimicrobial peptides and suggest that the maintenance of peptide hydrophobic-hydrophilic balance may be a critical parameter, in addition to structure, in the design of peptides with pharmaceutical relevance.

Conformation of polygalacturonase-II from Aspergillus carbonarius--a spectroscopic study

Solution conformation of polygalacturonase from Aspergillus carbonarius was determined by spectroscopy. UV absorption, second derivative, near-UV CD, fluorescence emission spectra and fluorescence quenching measurements suggest that the tryptophan fluorophores are in a hydrophobic environment. Of the nine tryptophan residues, only one is exposed to the solvent. In the near UV region the enzyme exhibits very weak CD bands, the far UV CD spectrum has a minimum at 218 nm; the enzyme is rich in parallel beta structure. Modification of solvent exposed tryptophan by N-bromosuccinimide resulted in the complete loss of enzyme activity. The enzyme is very sensitive towards urea induced unfolding, with complete loss of activity at 3 M urea concentration.

Rapid method to separate the domains of soybean lipoxygenase-1: identification of the interdomain interactions

Lipoxygenase-1 (LOX1) from soybeans was cleaved with chymotrypsin (Ramachandran et al., 31 (1992) 7700-7706). The domains were separated on a Sephadex G-50 column by minimising domain interactions at pH 4.0. The molecular weight and apparent homogeneity of the domains were established by SDS-PAGE. The solution conformation of the 60 kDa and 30 kDa fragments was compared with that of native LOX1. 1-Anilino-8-naphthalene sulphonate (ANS) binding measurements confirmed the exposure of large hydrophobic residues on the surface of the 60 kDa due to separation of the domains. The monomeric nature of the 60 kDa fragment was confirmed by HPLC gel filtration. The increased number of binding sites and magnitude of binding constant suggested the involvement of extensive hydrophobic interactions between the two domains. The essential cofactor iron was with the C-terminal domain. The attempts to resolve and reconstitute the catalytic activity of isolated domains were not successful.

The detection of kinetic intermediates during the unfolding of lipoxygenase-1 by urea or guanidine hydrochloride

The unfolding of lipoxygenase-1 by urea and guanidine hydrochloride has been followed at the optimum pH of enzyme activity. The unfolding of lipoxygenase-1 by urea or guanidine hydrochloride was characterized by equilibrium transition curves for different parameters like (i) enzyme activity, (ii) change in ellipticity values at 222 nm, and (iii) relative fluorescence intensity at 332 nm could not be superimposed. The transition curves displayed more than one plateau region suggesting the presence of stable intermediates during unfolding. At urea concentrations less than 1 M there was no significant loss in activity although loss in secondary structure was approximately 20%. At 4.0 M urea concentration there was complete loss of activity with a midpoint concentration of 2.5 M urea. The loss in secondary structure was biphasic. The first transition had a midpoint concentration of 1.2 M, while the second transition which was complete at 8.0 M urea had a midpoint concentration of 3.5 M urea. The changes in relative fluorescence intensity and shift in emission maximum were complete at 8.0 M urea. The Stern-Volmer constant for acrylamide and potassium iodide did not change at urea concentrations less than 4 M and then at higher concentrations increased. The reactivity of sulfhydryl groups to Ellman's reagent increased during the course of unfolding. The kinetics of unfolding supported the presence of stable intermediates during unfolding. The unfolding was irreversible and complex because of the multidomain nature. The apparent irreversibility could be related to aggregation during unfolding which precluded the determination of thermodynamic parameters.

In vitro activity of the antimicrobial peptides human and rabbit defensins and porcine leukocyte protegrin against Mycobacterium tuberculosis

Three independent assay methods were used to investigate the activities of antimicrobial peptides (human and rabbit defensins and protegrin from porcine leukocytes) against Mycobacterium tuberculosis in vitro. M. tuberculosis H37Ra was cultured in the presence of human neutrophil peptide 1, synthetic rabbit neutrophil peptide 1, or porcine protegrin 1 at 37 degrees C for 6 to 48 h, and antimycobacterial activity was measured by CFU assay. These peptides at a concentration of 50 microg/ml showed significant antibacterial effects on M. tuberculosis after 24 and 48 h of incubation (85.9 to 97.5% at 24 h and 91.6 to 99.4% at 48 h). A radiometric method and a radial diffusion assay confirmed these observations. Antibacterial activity against M. tuberculosis was independent of calcium (1.0 mM) or magnesium (1.0 mM) and not inhibited by sodium chloride (100 mM). The optimal pH for antibacterial activity against M. tuberculosis was greater than 4.0. Three clinical isolates of M. tuberculosis were also studied, and these peptides showed 86.3 to 99.0% reduction in CFU of these organisms. Morphological studies using scanning electron microscopy showed that defensins caused lesions on the surface of H37Ra. These observations suggest that antimicrobial peptides such as defensins and protegrins may represent an important component of the host defense mechanism against M. tuberculosis and offer a potential new approach to therapy.

Role of disulfide linkages in structure and activity of proteinase inhibitor from horsegram (Dolichos biflorus)

Proteinase inhibitor isolated from horsegram (Dolichos biflorus or Macrotyloma uniflorum) inhibited specifically the enzymes trypsin and chymotrypsin. The inhibitor contained seven disulfide linkages and was free from thiol groups. The inhibitor is resistant to denaturation by urea, guanidine hydrochloride or sodium dodecyl sulfate. Reduction of the inhibitor with dithiothreitol abolished both trypsin and chymotrypsin inhibitory activities. The kinetic plots of the reduction as followed by activity and loss in structure as reflected in the 257 nm CD band could be superposed; loss in the activity paralleled the loss in structure. The kinetics of the reduction process was complex; reduction of the inhibitor was slow and depended on the concentration of DTT. Reduction of the disulfide linkages with DTT affected the tertiary structure significantly and secondary structure was not affected considerably. Fluorescence quenching by acrylamide and potassium iodide suggested the unfolding of the molecule due to reduction. Thus, disulfide linkages play a predominant role in maintaining the three-dimensional structure of the inhibitor.

Design and synthesis of amphipathic antimicrobial peptides

A large proportion of antimicrobial peptides share a common structural feature that is critical to their antimicrobial activity, i.e. amphipathic alpha-helices. The amphipathy of a polypeptide chain can be quantitated through the value of the hydrophobic moment. Generally, antimicrobial peptides are characterized by high hydrophobic moment and low hydrophobicity values. Using these criteria we have identified two short segments that possess hydrophobic moment properties associated with known antimicrobial peptides. Using in vitro assays the segment derived from the protein perforin displays no antifungal or antibacterial activity and, while showing no alpha-helicity in buffer or liposomes, exhibits a modest degree of alpha-helical structure in the presence of the alpha-helical inducer, 2,2,2-trifluoroethanol. However, rational modifications result in a derivative which assumes an alpha-helical conformation in the presence of liposomes, exhibits potent antifungal activity against plant fungal pathogens, has significant antibacterial activity, effects leakage of a fluorescent dye from acidic liposomes and is devoid of hemolytic activity. Results are also presented for a segment derived from the human immunodeficiency virus envelope protein. We suggest that the identification of putative amphipathic structures in proteins may provide a useful starting strategy in the design and synthesis of antimicrobial peptides.

Structure-function validation of high lysine analogs of alpha-hordothionin designed by protein modeling

Cereal grains and legume seeds, which are key protein sources for the vegetarian diet, are generally deficient in essential amino acids. Maize, in particular, is deficient in lysine. The inherent lack of lysine-rich proteins in maize has necessitated the search for heterologous proteins enriched in this amino acid, the isolation of the corresponding gene and its ultimate introduction into maize through plant transformation techniques. However, a rate-limiting step to this strategy has been the availability of plant-derived lysine-rich proteins. An appealing solution to the problem is to artificially increase the lysine content of a given protein by mutating appropriate residues to lysine. Here, we expound this strategy, starting with the protein alpha-hordothionin that is derived from barley seeds and consists of five lysine residues in a total of 45 amino acids (11% lysine). To facilitate rational substitutions, the 3-D structure of the protein has been determined by homology modeling with crambin. Based on this model, we have identified surface residues amenable to substitution with lysine. Furthermore, the acceptability of the mutations has been validated through the synthesis and characterization of the derivatives. To this end, our approach has permitted the creation of a modified alpha-hordothionin protein that has a lysine content of approximately 27% and retains the antifungal activity of the wild-type protein.

Characterization of the lectin from the bulbs of Eranthis hyemalis (winter aconite) as an inhibitor of protein synthesis

The lectin from Eranthis hyemalis has been previously characterized as consisting of two polypeptide chains covalently linked by disulfide bond(s) (Cammue, B. P., Peeters, B., and Peumans, W. J. (1985) Biochem. J. 227, 949-955). We have further characterized the biochemical properties of the lectin and demonstrated that it possesses the property of inhibition of protein synthesis using in vitro eukaryotic translation systems. The protein also possesses antiviral activity against the plant virus, alfalfa mosaic virus, and larvicidal activity against the southern corn rootworm, Diabrotica undecimpunctata howardii, a major insect pest of the maize plant. Both isoelectric focusing on gels and chromatofocusing indicated heterogeneity of the protein, with three species having isoelectric points in the range 4-5. The disulfide bond(s) can be rapidly reduced with beta-mercaptoethanol under native conditions. The reduced alkylated polypeptide chains remain associated under native conditions to form a species, EHL', that elutes at the same position as the native protein and has the same molecular weight by sedimentation equilibrium experiments. However, circular dichroism and fluorescence measurements indicated conformational differences between the species.

Synthesis and characterization of defensin NP-1

Defensins are a group of small, cationic, antimicrobial proteins found in the cytoplasmic granules of neutrophils and macrophages of a variety of mammalian species. One such defensin, NP-1, isolated from rabbit neutrophils, has been shown to consist of 33 amino acids rich in arginine and cysteine residues. We have synthesized NP-1 on an Applied Biosystems Model 431A peptide synthesizer using FastMoc chemistry involving HBtu [2-1H-benzotriazol-1-yl)-1,1,3,3-tetramethyluronium hexafluorophosphate] activation for coupling amino acids. The linear peptide was folded by air oxidation to the biologically active form containing three disulfide bonds and purified by reverse phase chromatography. The amino acid sequence of the synthetic peptide was confirmed by Edman degradation. Molecular weight determination by plasma desorption mass spectroscopy (PDMS) gave a value of 3898.6, in agreement with the expected molecular weight of 3898. The biological activity of the synthetic peptide, as measured by its antifungal activity against several pathogenic fungi, was indistinguishable from that of the natural NP-1. Also, the CD spectrum was equivalent to that of natural NP-1, indicating conformational identity of the two species.

Purification and characterization of a novel antimicrobial peptide from maize (Zea mays L.) kernels

Several small, acid-soluble, basic peptides with anti-microbial properties have been isolated from maize (inbred B73) kernels. One of these peptides (MBP-1) has been purified to homogeneity and characterized. The peptide has a molecular weight of 4127.08 as determined by plasma desorption mass spectroscopy, has no free cysteines, and is predominantly alpha-helical as determined by circular dichroism. The primary sequence of the peptide (33 residues) has been determined by Edman degradation and shows no homology to the thionins, a group of cysteine-rich peptides found in some cereals including wheat, barley, and sorghum, as well as several dicot species. Like the thionins, however, MBP-1 has been found to have antimicrobial properties in vitro. MBP-1 inhibits spore germination or hyphal elongation of several plant pathogenic fungi, including two seed pathogens of maize (Fusarium moniliforme Sheld. and Fusarium graminearum (Gibberella zeae (Schw.) Petsch)), and several bacteria, including a bacterial pathogen of maize (Clavibacter michiganense ssp. nebraskense). A synthetic MBP-1 peptide, air-oxidized and purified by reverse phase chromatography, was equally antifungal as compared with the naturally occurring peptide.

A stoichiometric analysis of bovine serum albumin-gossypol interactions: a fluorescence quenching study

The interaction of gossypol with bovine serum albumin, human serum albumin and n-bromosuccinimide-modified bovine serum albumin has been followed by fluorescence quenching measurements. The presence of a high affinity site (association constant K = 2.2 x 10(6) M-1) for gossypol on bovine serum albumin and human serum albumin is indicated. The stoichiometry of binding for the high affinity site was evaluated using Job's method of continuous variation, thereby suggesting the formation of 1:1 complex. Modification of the tryptophan residues on bovine serum albumin does not affect the binding of gossypol to either high or low affinity site of albumin.

Interactions of methoxyamine with pyridoxal-5'-phosphate-Schiff's base at the active site of sheep liver serine hydroxymethyltransferase

The mechanism of interaction of methoxyamine with sheep liver serine hydroxymethyltransferase (EC 2.1.2.1) (SHMT) was established by measuring changes in enzyme activity, visible absorption spectra, circular dichroism and fluorescence, and by evaluating the rate constant by stopped-flow spectrophotometry. Methoxyamine can be considered as the smallest substituted aminooxy derivative of hydroxylamine. It was a reversible noncompetitive inhibitor (Ki = 25 microM) of SHMT similar to O-amino-D-serine. Like in the interaction of O-amino-D-serine and aminooxyacetic acid, the first step in the reaction was very fast. This was evident by the rapid disappearance of the enzyme-Schiff base absorbance at 425 nm with a rate constant of 1.3 x 10(3) M-1 sec-1 and CD intensity at 430 nm. Concomitantly, there was an increase in absorbance at 388 nm (intermediate I). The next step in the reaction was the unimolecular conversion (1.1 x 10(-3) sec-1) of this intermediate to the final oxime absorbing at 325 nm. The identity of the oxime was established by its characteristic fluorescence emission at 460 nm when excited at 360 nm and by high performance liquid chromatography. These results highlight the specificity in interactions of aminooxy compounds with sheep liver serine hydroxymethyltransferase and that the carboxyl group of the inhibitors enhances the rate of the initial interaction with the enzyme.

Structural and functional changes associated with cyanogen bromide treatment of wheat germ agglutinin

The lectin, wheat germ agglutinin (WGA), has been shown to have a significant larvicidal effect on the European corn borer, a major insect pest of corn. In order to characterize this toxic effect, we have undertaken structure-function studies on WGA. To this extent, the effect of cyanogen bromide (CNBr) on the conformation, subunit interactions, and biological activity of WGA has been investigated. The CNBr-modified lectin exhibits no toxicity to the ECB, cannot dimerize, does not bind to N-acetylglucosamine or its polymers, has no or vastly reduced hemagglutinating activity against red blood cells of different animals, and shows loss of an antigenic determinant by immunodiffusion. The CD spectrum of CNBr-WGA is not significantly different from that of native WGA, although the intrinsic fluorescence shows about 30% quenching. Our results suggest that the integrity of the N-terminal domain of WGA is essential for dimer formation. Furthermore, toxicity of WGA to ECB may be intrinsically related to its ability to dimerize and bind to sugar residues.

An immunoaffinity immobilized enzyme assay for neomycin phosphotransferase II in crude cell extracts

An immunoaffinity immobilized enzyme assay for neomycin phosphotransferase II (NPT II) has been developed. This method combines affinity purification with an enzyme-catalyzed reaction. The assay is mechanically simple and can be semiautomatable since all steps are performed in a microtiter plate. An immunoaffinity step separates NPT II from endogenous kinases, which may produce false positive results, and from endogenous phosphatases and inhibitors, which decrease the apparent NPT activity. This method thus exploits two modes of specificity: antigen-antibody specificity and enzyme catalysis specificity. This gives a high degree of specificity and allows quantitation of 0.1 ppm NPT in crude plant protein extracts. The catalytic ability of the NPT is not significantly hampered by its attachment to the gel, in the Km values for ATP and neomycin and the catalytic number for immobilized NPT are comparable to those for the NPT in solution.

A fluorometric study of the interaction of bradykinin with lipids

The interaction of bradykinin (BK) with lipids has been followed by steady-state fluorescence measurements. Addition of either cerebroside sulfate (CS) or phosphatidylinositol (PI), solubilized with the nonionic surfactant C12E8, to BK or its analogue [Gly6]-BK enhances the relative fluorescence intensity of peptide emission at 288 nm. Fluorometric titration of the peptide with lipid has been used to quantitate the interactions in terms of stoichiometry and equilibrium constant. Job's method of continuous variation for the BK-CS interaction gave a stoichiometry of 1:2 for the complex. The value of the equilibrium constant, K, for the interaction of either BK or [Gly6]-BK with CS is 1.5.10(4) M-1. The BK-PI interaction is weaker; K = 5.0.10(3) M-1. Although electrostatic forces no doubt play a major role in these interactions, measurements on the model peptide Gly-Phe-Gly indicate that the phenylalanine residues of BK are disposed in the hydrophobic environment provided by the lipid-C12E8 mixed micelle. 13C-NMR measurements on [99% 13C alpha-Gly6]-BK show that there is no change in its cis/trans ratio upon interaction with CS. The increase in the relative fluorescence intensity of BK accompanying its cooperative interaction with sodium dodecyl sulfate (SDS) implicates the role of hydrophobic forces in this interaction as well. These results bear on the interpretation of the changes in circular dichroism (CD) of BK caused by SDS.

Numerical and experimental demonstrations of the need for caution in the use of zonal gel chromatography for characterizing ligand interactions with small acceptors

Quantitative expressions are presented for the evaluation of equilibrium constants for interactions of the type A + B in equilibrium C from experiments entailing the application of a small zone of acceptor-ligand mixture to a column of gel preequilibrated with ligand solution [J.P. Hummel and W.J. Dreyer (1962) Biochim. Biophys. Acta 63, 530-532]. Only in the event that identical elution volumes pertain to acceptor and complex does the steady-state binding constant (Kss) obtained by that method equal the thermodynamic equilibrium constant (K). Simulated elution profiles are then generated with parameters relevant to gel chromatography of the ATP-Mg2+ system on Sephadex G-10 in order to demonstrate the practical importance of the need for distinction between Kss and K in situations where acceptor and complex do not comigrate. A study of the interaction between soybean trypsin inhibitor and cytochrome c by gel chromatography on Sephadex G-75 is then used to illustrate the feasibility of combining information from Hummel-Dreyer experiments with the theoretical expressions to characterize systems under the more general conditions that the elution volumes of A and C differ. A finding of considerable theoretical interest in relation to the simulation of mass migration behavior is the demonstration that a truncation error is the source of zonal spreading in the theoretical-plate model of chromatography. This truncation error is shown to be the source of spreading generated whenever solution of an abbreviated (diffusion-free) continuity equation involves substituting first differences for first derivatives in the differential equation describing mass transport.

The eighth component of human complement: evidence that it is an oligomeric serum protein assembled from products of three different genes

The eighth component of human complement (C8) consists of three nonidentical subunits arranged asymmetrically as a disulfide-linked alpha-gamma dimer and a noncovalently associated beta chain. Genetic studies of C8 polymorphisms established that alpha-gamma and beta are encoded at different loci. Implicit in this finding was the existence of two different genes and the likelihood that alpha-gamma would be synthesized in single-chain precursor form. However, recent characterization of cDNA clones revealed separate mRNAs for human alpha and beta but no evidence of a single-chain precursor for alpha-gamma. A cDNA clone containing the entire coding region for human gamma has now been characterized, and its sequence supports the existence of a separate gamma mRNA. Included are a consensus translation initiation sequence, an apparent initiation methionine, and a signal peptide. By use of cDNA probes specific for human alpha, beta, or gamma, analysis of poly(A) RNA from normal baboon liver revealed separate mRNAs of 2.5, 2.6, and 1.0 kilobases (kb), respectively. Parallel analysis of poly(A) RNA from rat liver identified mRNAs of 3.4, 2.3, and 0.9 kb. These results argue against the possibility that C8 is assembled from products of two different genes (alpha-gamma and beta) and suggest it is comprised of three different gene products (alpha, beta, and gamma) that undergo both covalent and noncovalent association to yield the mature protein.

Complementary DNA and derived amino acid sequence of the alpha subunit of human complement protein C8: evidence for the existence of a separate alpha subunit messenger RNA

The entire amino acid sequence of the alpha subunit (Mr 64,000) of the eighth component of complement (C8) was determined by characterizing cDNA clones isolated from a human liver cDNA library. Two clones with overlapping inserts of net length 2.44 kilobases (kb) were isolated and found to contain the entire alpha coding region [1659 base pairs (bp)]. The 5' end consists of an untranslated region and a leader sequence of 30 amino acids. This sequence contains an apparent initiation Met, signal peptide, and propeptide which ends with an arginine-rich sequence that is characteristic of proteolytic processing sites found in the pro form of protein precursors. The 3' untranslated region contains two polyadenylation signals and a poly(A) sequence. RNA blot analysis of total cellular RNA from the human hepatoma cell line HepG2 revealed a message size of approximately 2.5 kb. Features of the 5' and 3' sequences and the message size suggest that a separate mRNA codes for alpha and argues against the occurrence of a single-chain precursor form of the disulfide-linked alpha-gamma subunit found in mature C8. Analysis of the derived amino acid sequence revealed several membrane surface seeking domains and a possible transmembrane domain. These occur in a cysteine-free region of the subunit and may constitute the structural basis for alpha interaction with target membranes. Analysis of the carbohydrate composition indicates 1 or 2 asparagine-linked but no O-linked oligosaccharide chains, a result consistent with predictions from the amino acid sequence.(ABSTRACT TRUNCATED AT 250 WORDS)

Complementary DNA and derived amino acid sequence of the beta subunit of human complement protein C8: identification of a close structural and ancestral relationship to the alpha subunit and C9

A cDNA clone encoding the beta subunit (Mr 64,000) of the eighth component of complement (C8) has been isolated from a human liver cDNA library. This clone has a cDNA insert of 1.95 kilobases (kb) and contains the entire beta sequence [1608 base pairs (bp)]. Analysis of total cellular RNA isolated from the hepatoma cell line HepG2 revealed the mRNA for beta to be approximately 2.5 kb. This is similar to the message size for the alpha subunit of C8 and confirms the existence of different mRNAs for alpha and beta. This finding supports genetic evidence that alpha and beta are encoded at different loci. Analysis of the derived amino acid sequence revealed several membrane surface seeking segments that may facilitate beta interaction with target membranes during complement-mediated cytolysis. Determination of the carbohydrate composition indicated 1 or 2 asparagine-linked but no O-linked oligosaccharide chains. Comparison of the beta sequence to that reported for alpha in the preceding paper [Rao, A. G., Howard, O. M. Z., Ng, S. C., Whitehead, A. S., Colten, H. R. & Sodetz, J. M. (1987) Biochemistry (preceding paper in this issue)] and to that of human C9 revealed a striking homology between all three proteins. For beta and alpha, the overall homology is 33% on the basis of identity and 53% when conserved substitutions are allowed. For beta and C9, the values are 26% and 47%, respectively.(ABSTRACT TRUNCATED AT 250 WORDS)

Spectroscopic study of the interaction of gossypol with bovine serum albumin

The interaction of gossypol with bovine serum albumin (BSA) at pH 7.6 in 0.02 M borax-borate buffer has been followed by circular dichroism (CD) and difference spectroscopy. From the extrinsic CD band at 390 nm, a binding constant of 2.7 X 10(3) M-1 was calculated. At 54 degrees the induced CD spectrum was abolished, suggesting that the interaction is not favoured at that temperature. The effect of various solvents and salts on the interaction has been followed by difference spectroscopy. The modification of epsilon-amino groups of lysine did not affect the interaction. Binding of gossypol to BSA does not cause a change in its secondary structure or sedimentation coefficient.

Kinetic mechanism of the interaction of D-cycloserine with serine hydroxymethyltransferase

The kinetic mechanism for the interaction of D-cycloserine with serine hydroxymethyltransferase (EC 2.1.2.1) from sheep liver was established by measuring changes in the activity, absorbance, and circular dichoism (CD) of the enzyme. The irreversible inhibition of the enzyme was characterized by three detectable steps: an initial rapid step followed by two successive steps with rate constants of 5.4 X 10(-3) s-1 and 1.4 X 10(-4) s-1. The first step was distinguished by a rapid disappearance of the enzyme absorbance peak at 425 nm, a decrease in the enzyme activity to 25% of the uninhibited velocity, and a lowering of the CD intensity at 432 nm to about 65% of the original value. The second step of the interaction was accompanied by a complete loss of enzyme activity and a marginal increase in the CD intensity at 432 nm. The final step resulted in the complete loss of the enzyme absorbance at 425 nm and of the CD band at 432 nm. The products of the reaction were identified as (a) apoenzyme by absorbance measurements, CD spectra, and reconstitution with pyridoxal 5'-phosphate and (b) a pyridoxal 5'-phosphate-D-cycloserine Schiff's base complex identified by its fluorescence and absorbance spectra. The Schiff base complex was expelled from the enzyme active site in the final step of the reaction. The proposed mechanism, which is different from those operative in other pyridoxal phosphate dependent enzymes, probably accounts for the selective inhibition of serine hydroxymethyltransferase by the drug in vivo.

Purification of Functional Subunits of the Eighth Component of Human Complement (C8) under Nondenaturing Conditions

A simple procedure is described for purifying the noncovalently associated alpha-gamma and beta subunits of human C8 in the absence of denaturants and in yields significantly higher than previously obtainable. The procedure utilizes either conventional or high-pressure molecular sieve chromatography in the presence of 1.5 M NaCl. This ionic strength promotes dissociation of alpha-gamma from beta and facilitates their physical separation under mild conditions. Yields are typically 60-75% and, as judged by several criteria, each subunit is functionally identical to those isolated by earlier methods using sodium dodecyl sulfate. This new procedure eliminates the need for this detergent and thereby avoids the major solubility and yield problems encountered during its removal.

Subunit interactions of 7 S nerve growth factor. Gamma-esterase activity, rates, and conformational changes during reassociation

The gamma-esterase activity of 7 S nerve growth factor (NGF) is depressed relative to free subunit because of constraints within the oligomer. 4 M urea causes a reversible dissociation of 7 S NGF and concomitant increase in esterase activity. The gamma-esterase activity with tosyl-arginyl-methyl-ester increased between 1 and 4 M urea and was inhibited at higher concentrations. Upon dilution of 7 S NGF from 6 M urea, the esterase activity was initially identical with that of the similarly treated gamma-subunit but decayed rapidly (10 min) to approach that of the native 7 S NGF. In the presence of 100 microM EDTA the activity was higher, but still required the same length of time to reach a constant depressed value. Upon dilution of 7 S NGF from 2 M NaCl the rapid decay was not observed and the activity remained constant at about the same level as the equilibrium values for the urea-treated and renatured 7 S NGF. A red shift in the fluorescence maximum and a concomitant increase in quantum yield occurred for the 7 S in 8 M urea. Dilution into buffer resulted in a rapid decay and return to native 7 S fluorescence but not when EDTA was included. Both the decay in esterase activity and in fluorescence intensity upon dilution from urea were first order reactions with a rate constant of about 8 X 10(-3) s-1 suggesting that both methods were measuring a unimolecular renaturation process. Renaturation from NaCl or recombination of isolated subunits was much more rapid, indicating a simple combination of subunits in a native conformation. The circular dichroism spectra of urea and NaCl-treated 7 S NGF were different, and spectra of the renatured species with and without EDTA differed. Reassociation to a conformationally different 7 S NGF probably occurs in the presence of EDTA. The results emphasize the role of zinc in 7 S NGF formation and the influence of conformational changes in the effect of beta-NGF on the activity of the gamma-esterase in 7 S NGF.

Tryptophan residues of the gamma subunit of 7S nerve growth factor: intrinsic fluorescence, solute quenching, and N-bromosuccinimide oxidation

The environment of tryptophan residues of the gamma subunit derived from the 7S nerve growth factor has been studied by intrinsic fluorescence, solute quenching, and oxidation with N-bromosuccinimide (NBS). The native protein has a fluorescence emission maximum of 345 nm with a tryptophan quantum yield of 0.10. A red shift in the emission maximum occurs between 3 and 6 M urea; a 20% increase in quantum yield occurred at 7-8 M urea. NBS (20-24 mol of NBS/mol of protein) completely oxidized one tryptophan of the gamma subunit, causing a 70% quenching of the intrinsic fluorescence, a complete loss of esterolytic activity toward synthetic substrates, an inability to combine with alpha and beta subunits to re-form the 7S complex, and a shift of about 12% of the structure from beta strands to random coil as determined by circular dichroism. About 80% of the fluorescing tryptophans are accessible to quenching by acrylamide but not to potassium iodide. These results suggest the presence of an exposed tryptophan contributing greater than or equal to 70% of the native fluorescence, located near a negative charge, critical to the esterase activity and possibly to interaction with the beta subunit to re-form 7S NGF.

Effect of succinylation on the oligomeric structure of glycinin

By varying the ratio of succinic anhydride to the protein, glycinin, one of the major fractions of soybean proteins, is succinylated to various levels. Sedimentation velocity experiments indicate the dissociation of the protein due to succinylation. Viscosity increases and a blue shift occurs in the absorption spectrum. The rate of proteolysis increases. Both dissociation and denaturation of the protein appear to occur. The effect of syccinylation on glycinin and arachin, the major protein of groundnuts, appears to be different.

Effect of sodium dodecyl sulphate on the 12S fraction of mustard proteins (B. juncea)

The effect of SDS on the 12S protein fraction of mustard seed (B. juncea) has been followed by the techniques of ultracentrifugation, gel filtration, gel electrophoresis, viscosity, ultraviolet difference spectra and fluorescence spectra. At low concentrations of SDS, up to 0.1%, both aggregation and dissociation of the protein occurs. Only dissociation occurs at higher SDS concentrations and is complete at 0.5% SDS. Viscosity increases sharply up to 0.15% SDS, remains constant between 0.15 and 0.30% and then increases markedly again. SDS induces also difference spectra with minima at 280, 288 and 295 nm. Fluorescence emission intensity increases at SDS concentrations less than 0.05% and quenching occurs at higher SDS concentrations. The results suggest that SDS causes association, dissociation and denaturation of the protein molecule.

A circular dichroism study of the interaction of chlorpromazine with mouse brain tubulin

A circular dichroism study with subsidiary ultracentrifuge measurements on the interaction of chlorpromazine with mouse brain tubulin establishes the previous inference from binding studies that the drug induces a change in the structure of the protein. Binding of the first mole of chlorpromazine causes an alteration in secondary structure, which is reversible with respect to drug concentration, without detected change in tertiary structure or significant change in the state of association of the protein. The conformationally altered tubulin binds additional chlorpromazine molecules without further change in secondary structure.