anti-DNP Antibody Research Articles

Exploration of Solid Phase Peptoid Synthesis for the Design of Trifunctional Hapten-Lipid-TLR7/8 Agonist Antibody-Recruiting Oligomers That Combine Innate Effector with Innate Activation Function.

The strategic engagement of innate immunity is a promising avenue for cancer treatment. Antibody-recruiting molecules (ARMs) direct endogenous antibodies to target tumor sites, eliciting innate immune effector killing responses. In this study, we report the synthesis of ARMs by employing solid-phase peptoid synthesis to construct three libraries of antibody-recruiting oligomers. Using dinitrophenyl (DNP) as a model hapten and alkyl lipid chains for cell surface anchoring, we tailored oligomers with variations in valency and spatial configuration. Among these, an oligomer design featuring DNP connected to the oligomer backbone through an extended PEG linker and flanked by two lipid motifs emerged as the most effective in antibody recruitment in vitro. This oligomer was further functionalized to include an imidazoquinoline, creating a trifunctional hapten-lipid-TLR7/8 agonist oligomer, and a parallel variant was conjugated with rhodamine, resulting in a trifunctional hapten-lipid-dye oligomer. Upon intratumorally administration in a murine model, these oligomers induced localized immune activation within tumors. Subsequent ex vivo analysis of single-cell suspensions from excised tumors confirmed the enhanced binding of anti-DNP antibodies. These findings underscore the potential of custom-designed ARMs in orchestrating precise immune-mediated tumor targeting and highlight the adaptability of solid-phase synthesis in oligomer design for the design of multifunctional antibody recruiting molecules.

Chemoenzymatic Synthesis of DNP-Functionalized FGFR1-Binding Peptides as Novel Peptidomimetic Immunotherapeutics for Treating Lung Cancer.

Receptor-binding peptides are promising candidates for tumor target therapy. However, the inability to occupy "hot spots" on the PPI interface and rapid metabolic instability are significant limitations to their clinical application. We investigated a new strategy in which an FGFR1-binding peptide (Pep1) was site-specifically functionalized with the dinitrophenyl (DNP) hapten at the C-terminus. The resulting Pep1-DNP conjugates retained FGFR1 binding affinity and exhibited a similar potency in inhibiting FGF2-dependent cell proliferation, comparable to that of native Pep1 in vitro. In addition, three conjugates could recruit anti-DNP antibodies onto the surface of cancer cells, thereby mediating the CDC efficacy. In vivo pharmacokinetic studies and antitumor studies demonstrated that optimal conjugate 9 exhibited significantly prolonged half-lives and improved antitumor efficacy without prominent toxicity compared to those of native Pep1. This is a general and cost-effective approach for generating peptidomimetic immunotherapeutics with multiple antitumor mechanisms that may have broad applications in cancer therapy.

Hapten/Myristoyl Functionalized Poly(propyleneimine) Dendrimers as Potent Cell Surface Recruiters of Antibodies for Mediating Innate Immune Killing.

Recruiting endogenous antibodies to the surface of cancer cells using antibody-recruiting molecules has the potential to unleash innate immune effector killing mechanisms against antibody-bound cancer cells. The affinity of endogenous antibodies is relatively low, and many currently explored antibody-recruiting strategies rely on targeting over-expressed receptors, which have not yet been identified in most solid tumors. Here, both challenges are addressed by functionalizing poly(propyleneimine) (PPI) dendrimers with both multiple dinitrophenyl (DNP) motifs, as anti-hapten antibody-recruiting motifs, and myristoyl motifs, as universal phospholipid cell membrane anchoring motifs, to recruit anti-hapten antibodies to cell surfaces. By exploiting the multivalency of the ligand exposure on the dendrimer scaffold, it is demonstrated that dendrimers featuring ten myristoyl and six DNP motifs exhibit the highest antibody-recruiting capacity in vitro. Furthermore, it is shown that treating cancer cells with these dendrimers in vitro marks them for phagocytosis by macrophages in the presence of anti-hapten antibodies. As a proof-of-concept, it is shown that intratumoral injection of these dendrimers in vivo in tumor-bearing mice results in the recruitment of anti-DNP antibodies to the cell surface in the tumor microenvironment. These findings highlight the potential of dendrimers as a promising class of novel antibody-recruiting molecules for use in cancer immunotherapy.

Immune Targeting of Mycobacteria through Cell Surface Glycan Engineering.

Mycobacteria and other organisms in the order Mycobacteriales cause a range of significant human diseases, including tuberculosis, leprosy, diphtheria, Buruli ulcer, and non-tuberculous mycobacterial (NTM) disease. However, the intrinsic drug tolerance engendered by the mycobacterial cell envelope undermines conventional antibiotic treatment and contributes to acquired drug resistance. Motivated by the need to augment antibiotics with novel therapeutic approaches, we developed a strategy to specifically decorate mycobacterial cell surface glycans with antibody-recruiting molecules (ARMs), which flag bacteria for binding to human-endogenous antibodies that enhance macrophage effector functions. Mycobacterium-specific ARMs consisting of a trehalose targeting moiety and a dinitrophenyl hapten (Tre-DNPs) were synthesized and shown to specifically incorporate into outer-membrane glycolipids of Mycobacterium smegmatis via trehalose metabolism, enabling recruitment of anti-DNP antibodies to the mycobacterial cell surface. Phagocytosis of Tre-DNP-modified M. smegmatis by macrophages was significantly enhanced in the presence of anti-DNP antibodies, demonstrating proof-of-concept that our strategy can augment the host immune response. Because the metabolic pathways responsible for cell surface incorporation of Tre-DNPs are conserved in all Mycobacteriales organisms but absent from other bacteria and humans, the reported tools may be enlisted to interrogate host-pathogen interactions and develop immune-targeting strategies for diverse mycobacterial pathogens.

Oxime blot: A novel method for reliable and sensitive detection of carbonylated proteins in diverse biological systems

Oxidative stress and oxidative protein damage occur in various biological processes and diseases. The carbonyl group on amino acid side chains is the most widely used protein oxidation biomarker. Carbonyl groups are commonly detected indirectly through their reaction with 2,4-dinitrophenylhydrazine (DNPH) and subsequent labeling with an anti-DNP antibody. However, the DNPH immunoblotting method lacks protocol standardization, exhibits technical bias, and has low reliability. To overcome these shortcomings, we have developed a new blotting method in which the carbonyl group reacts with the biotin-aminooxy probe to form a chemically stable oxime bond. The reaction speed and the extent of the carbonyl group derivatization are increased by adding a p-phenylenediamine (pPDA) catalyst under neutral pH conditions. These improvements are crucial since they ensure that the carbonyl derivatization reaction reaches a plateau within hours and increases the sensitivity and robustness of protein carbonyl detection. Furthermore, derivatization under pH-neutral conditions facilitates a good SDS-PAGE protein migration pattern, avoids protein loss by acidic precipitation, and is directly compatible with protein immunoprecipitation. This work describes the new Oxime blot method and demonstrates its use in detecting protein carbonylation in complex matrices from diverse biological samples.

Sequence-defined antibody-recruiting macromolecules.

Antibody-recruiting molecules represent a novel class of therapeutic agents that mediate the recruitment of endogenous antibodies to target cells, leading to their elimination by the immune system. Compared to single-ligand copies, macromolecular scaffolds presenting multiple copies of an antibody-binding ligand offer advantages in terms of increased complex avidity. In this study, we describe the synthesis of sequence-defined macromolecules designed for antibody recruitment, utilising dinitrophenol (DNP) as a model antibody-recruiting motif. The use of discrete macromolecules gives access to varying the spacing between DNP motifs while maintaining the same chain length. This characteristic enables the investigation of structure-dependent binding interactions with anti-DNP antibodies. Through solid-phase thiolactone chemistry, we synthesised a series of oligomers with precisely localised DNP motifs along the backbone and a terminal biotin motif for surface immobilisation. Utilising biolayer interferometry analysis, we observed that oligomers with adjacent DNP motifs exhibited enhanced avidity for anti-DNP antibodies. Molecular modelling provided insights into the structures and dynamics of the various macromolecules, shedding light on the accessibility of the ligands to the antibodies. Overall, our findings highlight that the use of sequence-defined macromolecules can contribute to our understanding of structure-activity relationships and provide insights for the design of novel antibody-recruiting therapeutic agents.

Multifunctional regulation of VAMP3 in exocytic and endocytic pathways of RBL-2H3 cells.

Mast cells (MCs) are inflammatory cells involved in allergic reactions. Crosslinking of the high-affinity receptor for IgE (FcϵRI) with multivalent antigens (Ags) induces secretory responses to release various inflammatory mediators. These responses are largely mediated by soluble N-ethylmaleimide-sensitive factor attachment protein receptors (SNAREs). Vesicle-associated membrane protein 3 (VAMP3) is a vesicular-SNARE that interacts with targeted SNARE counterparts, driving the fusion of MC secretory granules with the membrane and affecting subsequent assembly of the plasma membrane. However, the role of VAMP3 in FcϵRI-mediated MC function remains unclear. In this study, we comprehensively examined the role of VAMP3 and the molecular mechanisms underlying VAMP3-mediated MC function upon FcϵRI activation. VAMP3 shRNA transduction considerably decreased VAMP3 expression compared with non-target shRNA-transduced (NT) cells. VAMP3 knockdown (KD) cells were sensitized with an anti-DNP IgE antibody and subsequently stimulated with Ag. The VAMP3 KD cells showed decreased degranulation response upon Ag stimulation. Next, we observed intracellular granule formation using CD63-GFP fluorescence. The VAMP3 KD cells were considerably impaired in their capacity to increase the size of granules when compared to NT cells, suggesting that VAMP3 mediates granule fusion and therefore promotes granule exocytosis in MCs. Analysis of FcϵRI-mediated activation of signaling events (FcϵRI, Lyn, Syk, and intracellular Ca2+ response) revealed that signaling molecule activation was enhanced in VAMP3 KD cells. We also found that FcϵRI expression on the cell surface decreased considerably in VAMP3 KD cells, although the amount of total protein did not vary. VAMP3 KD cells also showed dysregulation of plasma membrane homeostasis, such as endocytosis and lipid raft formation. The difference in the plasma membrane environment in VAMP3 KD cells might affect FcϵRI membrane dynamics and the subsequent signalosome formation. Furthermore, IgE/Ag-mediated secretion of TNF-α and IL-6 is oppositely regulated in the absence of VAMP3, which appears to be attributed to both the activation of FcϵRI and defects in VAMP3-mediated membrane fusion. Taken together, these results suggest that enhanced FcϵRI-mediated signal transduction in VAMP3 KD cells occurs due to the disruption of plasma membrane homeostasis. Hence, a multifunctional regulation of VAMP3 is involved in complex secretory responses in MCs.

Purification of Emu IgY for Therapeutic and Diagnostic Use Based on Monoclonal Secondary Antibodies Specific to Emu IgY.

The emu is the second largest ratite; thus, their sera and egg yolks, obtained after immunization, could provide therapeutic and diagnostically important immunoglobulins with improved production efficiency. Reliable purification tools are required to establish a pipeline for supplying practical emu-derived antibodies, the majority of which belongs to the immunoglobulin Y (IgY) class. Therefore, we generated a monoclonal secondary antibody specific to emu IgY. Initially, we immunized an emu with bovine serum albumin multiply haptenized with 2,4-dinitrophenyl (DNP) groups. Polyclonal emu anti-DNP antibodies were partially purified using conventional precipitation method and used as antigen for immunizing a BALB/c mouse. Splenocytes were fused with myeloma cells and a hybridoma clone secreting a desirable secondary antibody (mAb#2-16) was established. The secondary antibody bound specifically to emu-derived IgY, distinguishing IgYs from chicken, duck, ostrich, quail, and turkey, as well as human IgGs. Affinity columns immobilizing the mAb#2-16 antibodies enabled purification of emu IgY fractions from sera and egg yolks via simple protocols, with which we succeeded in producing IgYs specific to the severe acute respiratory syndrome coronavirus type 2 (SARS-CoV-2) spike protein with a practical binding ability. We expect that the presented purification method, and the secondary antibody produced in this study, will facilitate the utilization of emus as a novel source of therapeutic and diagnostic antibodies.

Antibody-dependent cellular phagocytosis of tropomyosin receptor kinase C (TrkC) expressing cancer cells for targeted immunotherapy.

Conventional cancer therapies such as chemotherapy are non-selective and induce immune system anergy, which lead to serious side effects and tumor relapse. It is a challenge to prime the body's immune system in the cancer-bearing subject to produce cancer antigen-targeting antibodies, as most tumor-associated antigens are expressed abundantly in cancer cells and some of normal cells. This study illustrates how hapten-based pre-immunization (for anti-hapten antibodies production) combined with cancer receptor labeling with hapten antigen constructs can elicit antibody-dependent cellular phagocytosis (ADCP). Thus, the hapten antigen 2,4-dinitrophenol (DNP) was covalently combined with a cancer receptor-binding dipeptide (IYIY) to form a dipeptide-hapten construct (IYIY-DNP, MW = 1322.33) that targets the tropomyosin receptor kinase C (TrkC)-expressed on the surface of metastatic cancer cells. IYIY-DNP facilitated selective association of RAW264.7 macrophages to the TrkC expressing 4T1 cancer cells in vitro, forming cell aggregates in the presence of anti-DNP antibodies, suggesting initiation of anti-DNP antibody-dependent cancer cell recognition of macrophages by the IYIY-DNP. In in vivo, IYIY-DNP at 10mg/kg suppressed growth of 4T1 tumors in DNP-immunized BALB/c mice by 45% (p < 0.05), when comparing the area under the tumor growth curve to that of the saline-treated DNP-immunized mice. Meanwhile, IYIY-DNP at 10mg/kg had no effect on TrkC-negative 67NR tumor-bearing mice immunized with DNP. Tumor growth suppression activity of IYIY-DNP in DNP-immunized mice was associated with an increase in the anti-DNP IgG (7.3 × 106 ± 1.6 U/mL) and IgM (0.9 × 106 ± 0.07 U/mL) antibodies after five cycles of DNP treatment, demonstrated potential for hapten-based pre-immunization then treatment with IYIY-DNP to elicit ADCP for improved immunotherapy of TrkC expressing cancers.

Front Cover: Dinitrophenol‐Hyaluronan Conjugates as Multivalent Antibody‐Recruiting Glycopolymers for Targeted Cancer Immunotherapy (ChemMedChem 19/2021)

The Front Cover shows the Multivalent Antibody-Recruiting Glycopolymers (MARGs) prepared by grafting multiple copies of dinitrophenol (DNP, pink) onto hyaluronan acid polymers (HA, cyan) for cancer immunotherapy. The MARGs are able to recognize the CD44 marker on the cancer cell surface and concomitantly recruit endogenous anti-DNP antibodies to kill cancer cells through immune effector functions in vitro and in vivo. The designed constructs represent an excellent example of using natural glycopolymers as a multivalent scaffold to translate the multivalency power into the improved tumor-killing capability. Cover design by Dr. Jie Shi. More information can be found in the Full Paper by Jie Shi, Zhimeng Wu et al.

Dinitrophenol-Hyaluronan Conjugates as Multivalent Antibody-Recruiting Glycopolymers for Targeted Cancer Immunotherapy.

Multivalent antibody-recruiting glycopolymers (MARGs) composed of hyaluronic acid (HA) grafted with multiple copies of dinitrophenol (DNP) were developed for targeted cancer immunotherapy. Structure-activity studies demonstrated that the MARGs were able to specifically recognize CD44-positive cancer cells and displayed remarkable antibody-recruiting capacities and tumor cell killing activities dependent on the introduced multivalent effect and the length of PEG linker. One of the MARGs, HA-[PEG3 -DNP]8 , showed the best capacity for clustering anti-DNP antibodies onto CD44-positive cancer cells and displayed potent in vitro anti-cancer activity by triggering complement dependent cytotoxicity (CDC) and antibody-dependent cell-mediated cytotoxicity (ADCC). Moreover, we found that HA-[PEG3 -DNP]8 significantly inhibited the xenograft tumor growth of Babl/c nude mice bearing triple negative breast cancer cells, while it did not cause detectable histological cytotoxicity. Given the easy access of this type of natural glycopolymer and the practical synthesis approach, these MARGs provide promising immunotherapeutics for cancer immunotherapy.

Synthesis of DNP-modified GM3-based anticancer vaccine and evaluation of its immunological activities for cancer immunotherapy

Tumor-associated carbohydrate antigens (TACAs) are attractive targets for vaccine development. In this context, we described a strategy combining artificial TACA and glycoengineering for cancer vaccine development. A 2,4-ditrophenyl (DNP)-modified GM3 intermediate was synthesized chemoenzymatically and conjugated to keyhole limpet hemocyanin (KLH), and the resulting bioconjugate was tested for its potential as a vaccine candidate. Mice immunological studies revealed that the DNP-modified GM3 (GM3-NHDNP) analog elicited strong and rapid immune responses by recruiting anti-DNP antibodies to facilitate the targeted delivery of the vaccine construct to antigen processing cells (APCs). Moreover, the endogenously produced anti-DNP antibodies, together with the elicited antibodies against GM3-NHDNP, may synergistically promote tumor binding and cancer cell death when the cancer cell surfaces are glycoengineered to express the GM3-NHDNP antigen.

Exendin 4-Hapten Conjugate Capable of Binding with Endogenous Antibodies for Peptide Half-life Extension and Exerting Long-Acting Hypoglycemic Activity.

Hapten-specific endogenous antibodies are naturally occurring antibodies present in human blood. Herein, we investigated a new strategy in which small-molecule haptens were utilized as naturally occurring antibody binders for peptide half-life extension. The glucagon-like peptide 1 receptor agonist exendin 4 was site-specifically functionalized with the dinitrophenyl (DNP) hapten at the C-terminus via sortase A-mediated ligation. The resulting Ex4-DNP conjugates retained GLP-1 receptor activation potency in vitro and had a similar in vivo acute glucose-lowering effect comparable to that of native Ex4. Pharmacokinetic studies and hypoglycemic duration tests demonstrated that the Ex4-DNP conjugates displayed significantly elongated half-lives and improved long-acting antidiabetic activity in the presence of endogenous anti-DNP antibodies. In chronic treatment studies, once-daily administration of optimal conjugate 7 demonstrated more beneficial effects without prominent toxicity compared with Ex4. This strategy provides a new approach and represents an alternative to the well-established peptide-Fc fusion strategy to improve the peptide half-life and the therapeutic efficacy.

Quencher based chemical tag technology using exchangeable probes for live-cell super-resolution imaging

Fluorescence imaging has made it possible to observe biomolecular distribution inside living cells. While a variety of fluorescent proteins are widely used, imaging tools using small-molecular organic fluorophores has attracted much attention due to their superior properties such as photostability. We have developed DeQODE chemical tag technology for genetically targeted fluorescence imaging. In this labeling system, a small-molecular QODE probe consisting of an organic fluorophore and a dinitrophenyl (DNP) quencher is almost non-fluorescent but becomes highly fluorescent upon binding to an anti-DNP single-chain antibody, DeQODE tag, expressed in cells. Since the probe reversibly binds to the tag protein, fluorescent signal can be continuously obtained, even if the bound probe photobleaches by strong excitation usually used in super-resolution imaging, by an exchange reaction in which another intact probe binds to the tag after the photobleaced probe is dissociated. We applied DeQODE chemical tag to live-cell STED microscopy, and achieved continuous super-resolution imaging of synaptic protein Homer in rat hippocampal neurons. This result clearly showed that DeQODE chemical tag technology is a powerful tool for super-resolution imaging by avoiding the problem of photobleaching.

Polyreactive antibodies as potential humoral biomarkers of host resistance to cystic echinococcosis.

Polyreactive antibodies (pAb) bind to a broad range of unrelated structures, providing hosts with functional components able to rapidly recognize and protect against different pathogens. However, their roles against helminth parasites are still unexplored. Here, pAb profiles were analysed in cystic echinococcosis (CE), a zoonosis caused by the cestode Echinococcus granulosus sensu lato. Levels of anti-DNP (2,4-dinitrophenyl-hapten) antibodies were measured as a surrogate parameter of pAb in different biological settings. Firstly, levels of serum and peritoneal pAb were measured during early experimental secondary CE, using both high (Balb/c) and low (C57Bl/6) susceptible mouse strains. Serum pAb mostly differed in normal mice, being pAb levels of IgG subclasses with poor anti-parasite activities predominant in Balb/c animals. Conversely, peritoneal pAb isotypes/subclasses with efficient anti-parasite activities predominated in normal and infected C57Bl/6 mice. Secondly, sera from potentially resistant patients, susceptible individuals and healthy donors were analysed, showing higher pAb levels of the IgA and IgG-particularly IgG1-isotypes in potentially resistant individuals compared to control groups. Finally, since remarkable differences were observed in pAb profiles according to the intrinsic host susceptibility to the infection, we proposed here that pAb might be considered as potential humoral biomarkers for host resistance to CE.

Fiber Optic Particle Plasmon Resonance-Based Immunoassay Using a Novel Multi-Microchannel Biochip.

A novel multi-microchannel biochip fiber-optic particle plasmon resonance (FOPPR) sensor system for the simultaneous detection of multiple samples. The system integrates a novel photoelectric system, a lock-in module, and an all-in-one platform incorporating optical design and mechanical design together to improve system stability and the sensitivity of the FOPPR sensor. The multi-microchannel FOPPR biochip has been developed by constructing a multi-microchannel flow-cell composed of plastic material to monitor and analyze five samples simultaneously. The sensor system requires only 30 μL of sample for detection in each microchannel. Moreover, the total size of the multi-microchannel FOPPR sensor chip is merely 40 mm × 30 mm × 4 mm; thus, it is very compact and cost-effective. The analysis was based on calibration curves obtained from real-time sensor response data after injection of sucrose solution, streptavidin and anti-dinitrophenyl (anti-DNP) antibody of known concentrations over the chips. The results show that the multi-microchannel FOPPR sensor system not only has good reproducibility (coefficient of variation (CV) < 10%), but also excellent refractive index resolution (6.23 ± 0.10 × 10−6 refractive index unit (RIU)). The detection limits are 2.92 ± 0.28 × 10−8 g/mL (0.53 ± 0.01 nM) and 7.48 ± 0.40 × 10−8 g/mL (0.34 ± 0.002 nM) for streptavidin and anti-DNP antibody, respectively.

Nature Inspired Anti-Biofouling Strategy for the Detection of Protein Biomarkers Directly in a Drop of Blood

Electrode biofouling in complex biological fluids is one of the major problems in analytical electrochemistry. Direct electrochemical detection in human blood remains challenging due to quick surface passivation by proteins present in blood, degrading sensor’s sensitivity. This challenge has dramatically slowed down commercialization efforts of point-of-care devices. Here we have developed a simple nature-inspired electrochemical DNA hybridization (e-hyb) assay based on steric hindrance which enable electrodes to detect nanomolar concentration of proteins (i.e. antibody) directlywithin a drop ofblood without any sample preparation. This e-hyb assay involves two DNA strands; one-captured DNA immobilized on electrode surface and another complementary reporter DNA labelled with an electroactive molecule (methylene blue) at one end and a specific recognition element at the another end. In presence of a specific large analyte binding to the small recognition element, the reporter DNA cannot reach to the electrode surface due to steric hindrance. This simple strategy enables us to quantify different protein biomarkers (HIV antibody, anti-DNP antibody, anti-DIG antibodyetc) in human blood without being limited affected by biofouling.Figure 1: e-DNA hybridization based anti-biofouling strategy for the detection of antibody in human blood Figure 1

Immunodiagnosis of Systemic Lupus Erythematosus (SLE) in a tertiary care hospital

Objectives To diagnose patients with Systemic lupus erythematosus clinically and compare various immunological tests available to detect their specificity and sensitivity of the various parameters employed. Methods It was a hospital-based cross-sectional study. All patients satisfying the revised American College of Rheumatology criteria (1982) for SLE were included in the study over a period of 3 years. A total of two hundred and four individuals were included. The patients were divided into three groups- (Group I- Confirmed SLE patients-32, Group II- Incomplete SLE patients- 60, and Group III -patients with other autoimmune disorders- 42) and 70 persons were included as controls. Results Patients were divided into three groups I, II, III and their clinical & laboratory features were compared. Females (90.6%) were more affected than males (9.4%) and 69% were in the age group of 20-40 years. The average age of onset of disease was 24.4 years. Predominant clinical features were arthritis (81.25%), skin rashes (72%), myalgia (68.75%), alopecia (68.75%), fever (65%) and oral ulcers 18(56.25%). Anti-ds-DNA test and ANA test were positive in all the patients and the anti-DNP test was positive in 59.3% patients. Females were more affected (81.7%) than males (18.3%). 85% were between 21-50 years The average age of patients was 30.16 years with a range of 10-70 years. Patients were regularly followed up and 32 patients (26.67%) developed complete SLE. The most common manifestations were arthritis (88.3%), fever (43.3%) skin rashes (68.3%). 10.34% of ILE patients developed full SLE and all were females. Average age of disease onset was 24years. Anti-ds-DNA antibodies was detected in 28 patients (23.4%), ANA in (25%) patients and Anti-DNP antibodies in 12 (10%) patients. Females (81%) were affected than males (19%). 86% were between 21-50 years. The average age of patients was 33.24 years. The predominant clinical features were arthritis (78.6%) and myalgia (76.2%). Anti-ds-DNA antibodies were detected in 6%, ANA in 35.7% patients & Anti-DNP antibodies in 3.6%. Antibodies to ds-DNA were present in low titers in this group. Conclusion A clear separation between SLE and other autoimmune disorder was found with the anti-ds-DNA test. It has a high specificity for the differential diagnosis of SLE. Our study, comparing three assays with respect to their ability to predict disease activity, indicated that ds- DNA ELISA is the best method.

Engineering a human IgG2 antibody stable at low pH.

IgG2 subclass antibodies have unique properties that include low effector function and a rigid hinge region. Although some IgG2 subclasses have been clinically tested and approved for therapeutic use, they have a higher propensity than IgG1 for aggregation, which can curtail or abolish their biological activity and enhance their immunogenicity. In this regard, acid-induced aggregation of monoclonal antibodies during purification and virus inactivation must be prevented. In the present study, we replaced the constant domain of IgG2 with that of IgG1, using anti-2,4-dinitrophenol (DNP) IgG2 as a model antibody, and investigated whether that would confer greater stability. While the anti-DNP IgG2 antibody showed significant aggregation at low pH, this was reduced for the IgG2 antibody containing the IgG1 CH2 domain. Substituting three amino acids within the CH2 domain-namely, F300Y, V309L, and T339A (IgG2_YLA)-reduced aggregation at low pH and increased CH2 transition temperature, as determined by differential scanning calorimetric analysis. IgG2_YLA exhibited similar antigen-binding capacity to IgG2, low affinity for FcγRIIIa, and low binding ability to C1q. The same YLA substitution also reduced the aggregation of panitumumab, another IgG2 antibody, at low pH. Our engineered human IgG2 antibody showed reduced aggregation during bioprocessing and provides a basis for designing improved IgG2 antibodies for therapeutic applications.

Identification of oxidant susceptible proteins in Salmonella Typhimurium.

The human gut pathogen, Salmonella Typhimurium (S. Typhimurium) not only survives but also replicates inside the phagocytic cells. Bacterial proteins are the primary targets of phagocyte generated oxidants. Because of the different amino acid composition, some proteins are more prone to oxidation than others. Many oxidant induced modifications to amino acids have been described. Introduction of carbonyl group is one of such modifications, which takes place quite early following exposure of proteins to oxidants and is quite stable. Therefore, carbonyl groups can be exploited to identify oxidant susceptible proteins. Hypochlorous acid (HOCl) is one of the most potent oxidants produced by phagocytes. Incubation of S. Typhimurium with 3mM HOCl resulted in more than 150 folds loss of bacterial viability. Proteins extracted from HOCl exposed S. Typhimurium cells showed about 60 folds (p < 0.001) more carbonyl levels as compared to unexposed cells. Similarly, 2, 4-Dinitrophenylhydrazine (2, 4-DNPH) derivatized proteins of HOCl treated S. Typhimurium cultures reacted strongly with anti-DNP antibodies as compared to buffer treated counterpart. Next, we have derivatized carbonyl groups on the proteins with biotin hydrazide. The derivatized proteins were then isolated by avidin affinity chromatography. Mass spectrometry based analysis revealed the presence of 204 proteins.