Optimization and Identification of Single Mutation in Hemoglobin Variants with 2,2,2 Trifluoroethanol Modified Digestion Method and Nano-LC Coupled MALDI MS/MS.

Background: Hemoglobin (Hb) variants arise due to point mutations in globin chains and their pathological treatments rely heavily on the identification of the nature and location of the mutation in the globin chains. Traditional methods for diagnosis such as HPLC and electrophoresis have their own limitations. Therefore, the present study aims to develop and optimize a specific method of sample processing that could lead to improved sequence coverage and analysis of Hb variants by nano LC-MALDI MS/MS. Methods: In our study, we primarily standardized various sample processing methods such as conventional digestion with trypsin followed by 10% acetonitrile treatment, digestion with multiple proteases like trypsin, Glu-C, Lys-C, and trypsin digestion subsequent to 2,2,2 trifluoroethanol (TFE) treatment. Finally, the peptides were identified by LC-MALDI MS/MS. All of these sample processing steps were primarily tested with recombinant Hb samples. After initial optimization, we found that the TFE method was the most suitable one and the efficiency of this method was applied in Hb variant identification based on high sequence coverage. Results: We developed and optimized a method using an organic solvent TFE and heat denaturation prior to digestion, resulting in 100% sequence coverage in the ß-chains and 95% sequence coverage in the α-chains, which further helped in the identification of Hb mutations. A Hb variant protein sequence database was created to specify the search and reduce the search time. Conclusion: All of the mutations were identified using a bottom-up non-target approach. Therefore, a sensitive, robust and reproducible method was developed to identify single substitution mutations in the Hb variants from the sequence of the entire globin chains. Biological Significance: Over 330,000 infants are born annually with hemoglobinopathies and it is the major cause of morbidity and mortality in early childhood. Hb variants generally arise due to point mutation in the globin chains. There is high sequence homology between normal Hb and Hb variant chains. Due to this high homology between the two forms, identification of variants by mass spectrometry is very difficult and requires the full sequence coverage of α- and ß-chains. As such, there is a need for a suitable method that provides 100% sequence coverage of globin chains for variant analysis by mass spectrometry. Our study provides a simple, robust, and reproducible method that is suitable for LC-MALDI and provides nearly complete sequence coverage in the globin chains. This method may be used in the near future in routine diagnosis for Hb variant analysis.

Advances in mass spectrometric methods for detection of hemoglobin disorders.

Hemoglobin disorders are caused due to alterations in the hemoglobin molecules. These disorders are categorized in two broad classes - hemoglobin variants and thalassemias. The hemoglobin variants arise due to point mutations in the alpha (α), beta (ß), gamma (γ), delta (δ), or epsilon (ε) globin chains of these proteins, while thalassemias are caused due to the under-production of α or ß globin chain. Hemoglobin disorders account for 7 % of the major health issues globally. Mass Spectrometry is an extensively used analytical tool in the field of protein identification, protein-protein interaction, biomarker discovery and diagnosis of several impairments including hemoglobin related disorders. The remarkable advancements in the technology and method development have enormously augmented the clinical significance of mass spectrometry in these fields. The present review describes hemoglobin disorders and the recent advancements in mass spectrometry in the detection of such disorders, including its advantages, lacunae, and future directions. The literature evidence concludes that mass spectrometry can be potentially used as a 'First Line Screening Assay' for the detection of hemoglobin disorders in the near future.

Role of DAF-21protein in Caenorhabditis elegans immunity against Proteus mirabilis infection.

UNLABELLED: Caenorhabditis elegans is emerging as one of the handy model for proteome related studies due to its simplest system biology. The present study, deals with changes in protein expression in C. elegans infected with Proteus mirabilis. Proteins were separated using two-dimensional differential gel electrophoresis (2D-DIGE) and identified using MALDI-TOF. Twelve distinctly regulated proteins identified in the infected worms, included heat shock proteins involved stress pathway (HSP-1 and HSP-6), proteins involved in immune response pathway (DAF-21), enzymes involved in normal cellular process (Eukaryotic translation Elongation Factor, actin family member, S-adenosyl homocysteine hydrolase ortholog, glutamate dehydrogenase and Vacuolar H ATPase family member) and few least characterized proteins (H28O16.1 and H08J11.2). The regulation of selected players at the transcriptional level during Proteus mirabilis infection was analyzed using qPCR. Physiological experiments revealed the ability of P. mirabilis to kill daf-21 mutant C. elegans significantly compared with the wild type. This is the first report studying proteome changes in C. elegans and exploring the involvement of MAP Kinase pathway during P. mirabilis infection. BIOLOGICAL SIGNIFICANCE: This is the first report studying proteome changes in C. elegans during P. mirabilis infection. The present study explores the role and contribution of MAP Kinase pathway and its regulator protein DAF-21 involvement in the immunity against opportunistic pathogen P. mirabilis infection. Manipulation of this DAF-21 protein in host, may pave the way for new drug development or disease control strategy during opportunistic pathogen infections.

Structural investigation of a novel N-acetyl glucosamine binding chi-lectin which reveals evolutionary relationship with class III chitinases.

The glycosyl hydrolase 18 (GH18) family consists of active chitinases as well as chitinase like lectins/proteins (CLPs). The CLPs share significant sequence and structural similarities with active chitinases, however, do not display chitinase activity. Some of these proteins are reported to have specific functions and carbohydrate binding property. In the present study, we report a novel chitinase like lectin (TCLL) from Tamarindus indica. The crystal structures of native TCLL and its complex with N-acetyl glucosamine were determined. Similar to the other CLPs of the GH18 members, TCLL lacks chitinase activity due to mutations of key active site residues. Comparison of TCLL with chitinases and other chitin binding CLPs shows that TCLL has substitution of some chitin binding site residues and more open binding cleft due to major differences in the loop region. Interestingly, the biochemical studies suggest that TCLL is an N-acetyl glucosamine specific chi-lectin, which is further confirmed by the complex structure of TCLL with N-acetyl glucosamine complex. TCLL has two distinct N-acetyl glucosamine binding sites S1 and S2 that contain similar polar residues, although interaction pattern with N-acetyl glucosamine varies extensively among them. Moreover, TCLL structure depicts that how plants utilize existing structural scaffolds ingenuously to attain new functions. To date, this is the first structural investigation of a chi-lectin from plants that explore novel carbohydrate binding sites other than chitin binding groove observed in GH18 family members. Consequently, TCLL structure confers evidence for evolutionary link of lectins with chitinases.

Purification and biophysical characterization of an 11S globulin from Wrightia tinctoria exhibiting hemagglutinating activity.

Wrightia tinctoria globulin (WTG), one of the major seed storage proteins, was isolated for the first time from seeds of the medicinal plant. WTG was extracted and purified to homogeneity in two steps using anion-exchange and size-exclusion chromatographies. On an SDS-PAGE gel under non-reducing conditions, a major band of ~56 kDa was observed; under reducing conditions, however, two major polypeptides, one with molecular weight ~32-34 kDa and the other with molecular weight ~22-26 kDa were observed. Intact mass determination by MALDI-TOF supported this observation. The N-terminal amino acid sequence of WTG matched in NCBI database with an expressed sequence tag obtained from the c-DNA of developing embryo m-RNA of Wrightia tinctoria. The EST sequence was further substantiated by partial de novo internal sequencing using MALDI-TOF/TOF. The high sequence homology with seed storage protein 11S globulin confirmed that WTG is a type of 11S globulin. Circular dichroism analysis showed that the secondary structure of WTG consists predominantly of ß-sheets (44.2%) and moderate content of α-helices (10.3%). WTG showed hemagglutinating property indicating that the protein may possess lectin-like activity. WTG was crystallized at 20 Å°C by the vapour diffusion method using PEG 400 as precipitant. The crystals belonged to the orthorhombic space group P212121 with cell dimensions of a=109.9Å, b=113.2Å and c=202.2Å with six molecules per asymmetric unit. Diffraction data were collected to a resolution of 2.2Å under cryocondition. Preliminary structure solution of WTG indicated the possibility of a hexameric assembly in its asymmetric unit.