NEXT-GENERATION SEQUENCING AND MOTIF GRAFTING APPLICATIONS IN SYNTHETIC ANTIBODY DISCOVERY

The overall objective of this PhD project was to develop and validate methods for advancing the applications of two techniques, next-generation sequencing (NGS) and motif grafting, in synthetic antibody discovery. In the first part of this project, we developed an NGS-assisted antibody discovery platform by integrating phage-displayed single-framework synthetic antigen- binding fragment (Fab) libraries with Ion Torrent sequencing. We constructed a new single- framework synthetic Fab library containing 8.5 billion unique Fab clones, and validated its functionality by generating high affinity Fabs against Notch and Jagged receptors. We developed a rapid and simple method to link and sequence all diversified complementarity-determining regions (CDRs) in phage Fab pools without losing the CDR pairing information. We identified and reconstructed low-frequency rare Fab clones from NGS information in a reliable and high- throughput manner. In some cases, reconstructed rare clones (frequency ~0.1%) showed higher affinity and better specificity than high-frequency top clones isolated by Sanger sequencing, highlighting the importance of NGS in synthetic antibody discovery. In the second part of this project, we employed motif grafting to semi-rationally design phage-displayed synthetic Fab libraries that are biased towards interacting with a specific site on a receptor. We used structural information on the epidermal growth factor receptor (EGFR) homo-dimerization interaction to design a structure-guided Fab library that was biased towards interacting with domain II of EGFR. We used this structure-guided Fab library to obtain Fabs against the EGFR extracellular domain. For comparison, we used a naïve synthetic Fab library to generate an anti-EGFR Fab whose binding overlapped with the Fab isolated from the structure-guided Fab library. Both Fabs possessed low-nM binding values for recombinant and cell-surface EGFR and inhibited EGF- mediated EGFR activation. Epitope mapping showed that domain II is partially responsible for the interaction of Fabs with EGFR. Further, both Fabs target unique epitopes that are different from previously validated epitopes on EGFR. In total, this PhD project resulted in novel methods for discovering synthetic antibodies using NGS and motif grafting techniques, three functional Fab libraries and numerous high-affinity Fabs against Notch, Jagged and EGF receptors

Lariat peptide inhibitors of Abl kinase

A majority of kinase inhibitors predominantly occupy the highly conserved adenine-binding pocket located in the kinase catalytic cleft, and therefore the target selectivity of these molecules is a major concern. In order to design highly specific next-generation drugs, it is essential to exploit the less-conserved binding pockets, which lie adjacent to the adenine-binding pocket. Small peptides that can function as adenosine triphosphate (ATP) competitive inhibitors would prove useful in identifying and validating new druggable surfaces in the kinase catalytic cleft. These peptides, being larger than small molecules, have the potential to target the ATP binding pocket as well as surfaces that lie adjacent to this pocket. Such peptides recognizing novel binding pockets can assist the drug discovery process in several ways. In this thesis, we describe the isolation and characterization of a novel class of cyclic peptides, referred to as lariats, against Abl kinase, a drug target important in chronic myeloid leukemia and other disorders. Using a yeast two-hybrid approach, we first isolated two related lariats, named A1 and A2, from a pool of five million lariats, which interact with the catalytic domain of Abl kinase. In vitro studies indicated that the synthetic A1 lariat competitively inhibits ATP binding by targeting the catalytic cleft that lies between the N- and C- lobes of the kinase catalytic domain. To obtain tighter-binding variants of the A1 lariat, we developed an affinity maturation protocol consisting of two steps. In the first step, we defined acceptable and tolerable substitutions at each position of the A1 lariat using site-saturation mutagenesis (SSM). In the second step, we designed specific mutations to the A1 lariat based on the SSM results and evolved higher affinity variants. Synthetic and recombinant higher affinity lariats exhibited a strong inhibition of Abl kinase activity in vitro and Bcr-Abl kinase activity in vivo, respectively, illustrating the potential of lariats as chemical genetic tools. Resistance mutation profiling showed that the lariats are not affected by the activating mutations located in the activation loop of kinase, and instead bind preferentially to the kinase active conformation. Selectivity analysis indicated that the lariats do not recognize Src family kinases, which share a high structural similarity with Abl kinase in their active conformation. These findings, coupled with preliminary results from modeling studies, strongly suggest that the lariats have identified novel allosteric drug-binding pockets in the kinase catalytic cleft

High performance concrete with steel slag aggregate

U radu se analizira utjecaj starenja čeličanske zgure kao agregata na mehanička svojstva betona visokih uporabnih svojstava. Razmatra se utjecaj raznih vremena starenja na mehanička svojstva betona. Uočeno je da proces starenja zgure utječe na svojstva ovog betona. Tlačna čvrstoća betona raste usporedo s porastom vremena starenja. Savojna čvrstoća, Youngov modul i udarna čvrstoća rastu slično kao i tlačna čvrstoća. Obradivost betona i gubitak abrazijom smanjuju se s povećanjem vremena starenja.The effect of the steel slag aggregate aging on mechanical properties of the high performance concrete is analysed in the paper. The effect of different aging periods of steel slag aggregate on mechanical properties of high performance concrete is studied. It was observed that properties of this concrete are affected by the steel slag aggregate aging process. The compressive strength increases with an increase in the aging period of steel slag aggregate. The flexural strength, Young’s modulus, and impact strength of concrete, increase at the rate similar to that of the compressive strength. The workability and the abrasion loss of concrete decrease with an increase of the steel slag aggregate aging period

Catastrophic chromosomal restructuring during genome elimination in plants.

Genome instability is associated with mitotic errors and cancer. This phenomenon can lead to deleterious rearrangements, but also genetic novelty, and many questions regarding its genesis, fate and evolutionary role remain unanswered. Here, we describe extreme chromosomal restructuring during genome elimination, a process resulting from hybridization of Arabidopsis plants expressing different centromere histones H3. Shattered chromosomes are formed from the genome of the haploid inducer, consistent with genomic catastrophes affecting a single, laggard chromosome compartmentalized within a micronucleus. Analysis of breakpoint junctions implicates breaks followed by repair through non-homologous end joining (NHEJ) or stalled fork repair. Furthermore, mutation of required NHEJ factor DNA Ligase 4 results in enhanced haploid recovery. Lastly, heritability and stability of a rearranged chromosome suggest a potential for enduring genomic novelty. These findings provide a tractable, natural system towards investigating the causes and mechanisms of complex genomic rearrangements similar to those associated with several human disorders

EXPERIMENTAL INVESTIGATION ON BAGASSE ASH AS AN ECO-FRIENDLY BUILDING MATERIAL

ABSTRAC

AtMND1 is required for homologous pairing during meiosis in Arabidopsis

BACKGROUND: Pairing of homologous chromosomes at meiosis is an important requirement for recombination and balanced chromosome segregation among the products of meiotic division. Recombination is initiated by double strand breaks (DSBs) made by Spo11 followed by interaction of DSB sites with a homologous chromosome. This interaction requires the strand exchange proteins Rad51 and Dmc1 that bind to single stranded regions created by resection of ends at the site of DSBs and promote interactions with uncut DNA on the homologous partner. Recombination is also considered to be dependent on factors that stabilize interactions between homologous chromosomes. In budding yeast Hop2 and Mnd1 act as a complex to promote homologous pairing and recombination in conjunction with Rad51 and Dmc1. RESULTS: We have analyzed the function of the Arabidopsis orthologue of the budding yeast MND1 gene (AtMND1). Loss of AtMND1 did not affect normal vegetative development but caused fragmentation and missegregation of chromosomes in male and female meiosis, formation of inviable gametes, and sterility. Analysis of the Atmnd1 Atspo11-1 double mutant indicated that chromosome fragmentation in Atmnd1 was suppressed by loss of Atspo11-1. Fluorescence in situ hybridization (FISH) analysis showed that homologous pairing failed to occur and homologues remained apart throughout meiosis. AtMND1 showed strong expression in meiocytes as revealed by RNA in situs. CONCLUSION: We conclude that AtMND1 is required for homologous pairing and is likely to play a role in the repair of DNA double strand breaks during meiosis in Arabidopsis, thus showing conservation of function with that of MND1 during meiosis in yeast

Identification of Pathogenicity-Related Genes in the Vascular Wilt Fungus Verticillium dahliae by Agrobacterium tumefaciens-Mediated T-DNA Insertional Mutagenesis

Verticillium dahliae is the causal agent of vascular wilt in many economically important crops worldwide. Identification of genes that control pathogenicity or virulence may suggest targets for alternative control methods for this fungus. In this study, Agrobacteriumtumefaciens-mediated transformation (ATMT) was applied for insertional mutagenesis of V. dahliae conidia. Southern blot analysis indicated that T-DNAs were inserted randomly into the V. dahliae genome and that 69% of the transformants were the result of single copy T-DNA insertion. DNA sequences flanking T-DNA insertion were isolated through inverse PCR (iPCR), and these sequences were aligned to the genome sequence to identify the genomic position of insertion. V. dahliae mutants of particular interest selected based on culture phenotypes included those that had lost the ability to form microsclerotia and subsequently used for virulence assay. Based on the virulence assay of 181 transformants, we identified several mutant strains of V. dahliae that did not cause symptoms on lettuce plants. Among these mutants, T-DNA was inserted in genes encoding an endoglucanase 1 (VdEg-1), a hydroxyl-methyl glutaryl-CoA synthase (VdHMGS), a major facilitator superfamily 1 (VdMFS1), and a glycosylphosphatidylinositol (GPI) mannosyltransferase 3 (VdGPIM3). These results suggest that ATMT can effectively be used to identify genes associated with pathogenicity and other functions in V. dahliae

Meiosis-Specific Loading of the Centromere-Specific Histone CENH3 in Arabidopsis thaliana

Centromere behavior is specialized in meiosis I, so that sister chromatids of homologous chromosomes are pulled toward the same side of the spindle (through kinetochore mono-orientation) and chromosome number is reduced. Factors required for mono-orientation have been identified in yeast. However, comparatively little is known about how meiotic centromere behavior is specialized in animals and plants that typically have large tandem repeat centromeres. Kinetochores are nucleated by the centromere-specific histone CENH3. Unlike conventional histone H3s, CENH3 is rapidly evolving, particularly in its N-terminal tail domain. Here we describe chimeric variants of CENH3 with alterations in the N-terminal tail that are specifically defective in meiosis. Arabidopsis thaliana cenh3 mutants expressing a GFP-tagged chimeric protein containing the H3 N-terminal tail and the CENH3 C-terminus (termed GFP-tailswap) are sterile because of random meiotic chromosome segregation. These defects result from the specific depletion of GFP-tailswap protein from meiotic kinetochores, which contrasts with its normal localization in mitotic cells. Loss of the GFP-tailswap CENH3 variant in meiosis affects recruitment of the essential kinetochore protein MIS12. Our findings suggest that CENH3 loading dynamics might be regulated differently in mitosis and meiosis. As further support for our hypothesis, we show that GFP-tailswap protein is recruited back to centromeres in a subset of pollen grains in GFP-tailswap once they resume haploid mitosis. Meiotic recruitment of the GFP-tailswap CENH3 variant is not restored by removal of the meiosis-specific cohesin subunit REC8. Our results reveal the existence of a specialized loading pathway for CENH3 during meiosis that is likely to involve the hypervariable N-terminal tail. Meiosis-specific CENH3 dynamics may play a role in modulating meiotic centromere behavior