Mycobacterium Smegmatis RecA And SSB : Structure-Function Relationships, Interaction With Cofactors And Accessory Proteins

Manjunath, G P

10 1900

Homologous genetic recombination, because of its fundamental roles in the maintenance of genome stability and evolution, is an essential cellular function common to all organisms. This process also plays important roles in the repair of damaged DNA molecules, generation of genetic diversity and proper segregation of chromosomes. The genetic exchange is a highly orchestrated process that entails a plethora of control mechanisms and a large number of proteins, of which RecA and SSB are two proteins that have been chosen for further investigation(s) in the present study. In addition, we have also investigated the interaction between SSB and UvrD1, which plays an important role in DNA repair pathways, especially nucleotide excision repair (NER) and mismatch repair as well as DNA replication and recombination. Chapter 1 reviews the literature regarding various aspects of homologous recombination, with an emphasis on the biochemical and the biophysical aspects of RecA and SSB proteins. In addition, it provides an overview of the study of DNA repair and recombination in mycobacteria. RecA protein is ubiquitous and well conserved among bacterial species. Many archaeal species possess two RecA homologues (RadA and RadB) and eukarya possess multiple homologues of RecA including, Rad51, Rad51B, Rad51C, Rad51D, DMC1, XRCC2, or XRCC3. RecA or its homologues function as polymers, consisting of hundreds of monomers that cooperatively polymerize on single-stranded DNA to form a nucleoprotein filament. E. coli RecA protein participates in Trans Lesion Synthesis (TLS) of DNA and forms the minimal mutasome in association with DNA polymerase V (UmuD’2C). The fundamental mechanism underlying HR, i.e. DNA strand exchange, is one of the most fascinating examples of molecular recognition and exchange between biological macromolecules. Since the isolation of E. coli recA gene and the subsequent purification of its gene product and also from other organisms, RecA protein has been studied extensively for more than three decades. E. coli RecA protein has pivotal roles in DNA recombination and repair, and binding to DNA in the presence of ATP, is a fundamental property of RecA protein resulting in the formation of a nucleoprotein filament. This is the slow step of the HR process, and is considerably faster on ssDNA than on duplex DNA. Binding of RecA to dsDNA is slower at physiological pH, is accelerated at acidic pH, and the lag in binding at the higher pH values is due to slow nucleation. The ATP and the DNA binding functions of RecA display allosteric interaction such that ATP- binding leads to an increase in affinity to ssDNA-binding and vice-versa. X-ray structures of E. coli RecA complexed with nucleotide cofactors have implicated a highly conserved Gln196 in Mycobacterium smegmatis RecA in the coupling of ATP and the DNA binding domains. The carboxyamide group of Gln196 makes an H-bond with the γ-phosphate group of ATP and the side chain of this residue is observed to move by approximately 2Å towards the ATP, relative to the other residues involved in ATP binding. In addition, a highly conserved Arg198 has also been postulated to interact with the γ-phosphate group of bound ATP and position it for a nucleophilic attack by a conserved residue-Glu96 leading to ATP hydrolyses. To elucidate the role of Gln196 and Arg198 in the allosteric modulation of RecA functions, we generated MsRecA variant proteins, where in Gln196 was substituted with alanine, asparagine or glutamate; Arg198 was mutated to a lysine. The biochemical characterization of MsRecA and its variant proteins with the objective of defining the allosteric interaction between the ATP- and the DNA-binding sites has been described with in Chapter 2. We observed that while the mutant MsRecA proteins were proficient in ATP-binding they were deficient in ATP hydrolyses. We assayed for the ability of these proteins to bind ssDNA using either nitrocellulose filter binding or Surface Plasmon Resonance (SPR). While we did not detect any ssDNA-binding by the mutant MsRecA proteins in the filter binding assay, we observed only ten-fold reduction in the affinity for ssDNA as compared to wild type MsRecA protein in MsRecAQ196A, Q196N and R198K in the SPR assay. MsRecA Q196E did not show any binding to ssDNA, in both nitrocellulose filter-binding as well as SPR assays. We assayed for the ability of the mutant RecA proteins for their ability to promote DNA-pairing as well as DNA strand exchange. While we observed limited pairing promoted by the mutant proteins relative to the wild-type MsRecA, we observed a complete abrogation of strand exchange in the case of mutant proteins. In addition, we assayed for the co-protease function of MsRecA, by monitoring the cleavage of MtLexA. We observed that only the wild-type MsRecA protein was able to cleave MtLexA, while none of the mutant RecA proteins were able to do so. In order to understand the differences observed between the wild -type and the mutant MsRecA proteins, we analyzed the conformational state of MsRecA and its variant proteins by circular dichroism spectroscopy upon ATP-binding. We observed that while MsRecA and MsRecAQ196N displayed a reduction in the absorbance at 220 nm upon ATP binding, we did not observe any such structural transitions in the other mutant MsRecA proteins that we tested. Based on our observations and the crystal structure of E. coli RecA bound to ssDNA, in Chapter 2, we propose a dual role for the Gln196 and Arg198 in modulating RecA activities. In the presynaptic filament Gln196 and Arg198 sense the presence of the nucleotide in the nucleotide binding pocket and initiate a series of conformation changes that culminate in the transition to an active RecA nucleoprotein filament. In the active RecA nucleoprotein filament these residues are repositioned such that they now form a part of the protomer-protomer interface. As such they perform two vital functions; they stabilize the protomer-protomer interface by participating in the formation of hydrogen bonds that span the interface as well transmit the wave of ATP hydrolysis across the interface leading to a coordinated hydrolyses of ATP essential for the heteroduplex extension phase of strand exchange reaction. The members of the super family of single stranded DNA binding proteins (SSB) play an important role in all aspects of DNA metabolism including DNA replication, repair, transcription and recombination. Prokaryotic SSBs bind ssDNA with high affinity and generally with positive cooperativity. Several lines of evidence suggest that prokaryotic SSBs are modularly organized into three distinct domains: the N-terminal DNA binding domain and acidic C-terminal domain are linked by a flexible spacer. Studies from our laboratory have revealed that M. smegmatis SSB plays a concerted role in recombination-like activities promoted by the cognate RecA. The C- terminal of SSB is known to be involved in its ability to interact with other proteins. We have previously reported that the C-terminal domain of M. smegmatis SSB, which is not essential for interaction with DNA, is the site for the binding of cognate RecA. The data in Chapter 3 describes the characterization of the SSB C-terminus with the objective of delineating the elements responsible for mediating protein-protein interaction, as well as to define the mechanism by which SSB is able to modulate the activities of RecA. To map the RecA interaction domain of SSB we created deletion mutants in MsSSB lacking 5, 10, 15 or 20 residues from the C-terminal. The truncated SSB proteins were expressed with a His- tag at the N- terminus and purified to homogeneity using a Ni-NTA affinity matrix. We observed unlike MsSSB, MsSSB∆C5 and MsSSB∆C10, MsSSB∆C15 and MsSSB∆C20 were unable to support three-strand exchange catalyzed by MsRecA. Based on the observation that interaction with SSB is essential for MsRecA to catalyze the strand Exchange reaction, we postulate that the RecA interacting domain of SSB is situated between the 15th and the 20th residue from the C-terminal. Further, the C-terminal of MsSSB modulates the transitions between DNA binding modes. Unlike the case with EcSSB where deletion of the last 8 residues from the C-terminal stabilizes the (SSB)35 mode of ssDNA binding, we observe that in case of MsSSB the deletion of C-terminal seems to destabilize the (SSB)35. In addition, the transition from the low density binding mode to a high density mode involves the formation of several intermediates when the C-terminal residues are deleted. With the objective of understanding the functions to the C-terminal of SSB independent of its DNA-binding domain in modulating RecA functions, we employed a peptide corresponding to the 35 residues from the C-terminal of the MsSSB. We observed that the C-terminal region alone is capable of interacting with RecA. In addition we also observed that the C-terminal domain of SSB stimulates RecA functions independent of its DNA binding domain. To address the question, whether the stimulatory effect of the C-terminal domain of SSB in the absence of its DNA-binding domain is restricted to RecA or is a generalized phenomenon associated with all SSB interacting proteins; we tested the effect of C-terminal domain of SSB on UvrD which is known to interact with SSB. UvrD participates in several pathways of DNA metabolism, which include the nucleotide excision repair (NER) and mismatch repair pathway, replication and recombination. Genetic evidence suggests that UvrD and SSB interact in vivo. We tested the effect of mycobacterial SSB on M. tuberculosis UvrD1 (MtUvrD1) functions in vitro. We observe that MtUvrd1 physically interacts with SSB. Further, presence of SSB has an inhibitory effect on the helicase activity of MtUvrD1 and that this effect is dependent on the C-terminal region as the deletion of residues from the C-terminal of SSB abrogates the inhibitory effect of SSB. However, unlike RecA, the C-terminal region of SSB alone had no effect on the helicase activity of UvrD1. We also observed that MsSSB has opposing effects on the ATPase activity of MtUvrD1. In the presence of low concentrations of SSB the ATPase activity is enhanced, while we observed an inhibition when the concentration of MsSSB is high. The precise mechanistic details of how SSB is able to act as an accessory protein to RecA, in context of homologous recombination and stimulates its biochemical activities have been a subject of debate. Whereas research from some groups has shown that the stimulatory effect SSB is mediated through its ability to melt DNA secondary structure, thereby allowing RecA to overcome the kinetic barrier imposed by the presence of secondary structure in ssDNA, others postulate that SSB plays a direct role in the stabilization of RecA nucleoprotein filament and prevents its dissociation. Chapter 3 discusses the experimental evidence in favor of the aforesaid models and based on the results of our experiments; we propose that the accessory functions of SSB may be mediated by a mechanism that involves elements of both models. While interaction with SSB can bring about a conformational change in RecA that is reflected in the enhanced levels of strand exchange and co-protease activity, the helix destabilizing function of SSB is essential during heteroduplex extension and to sequester the displaced strand such that it does not participate in any further pairing reactions. The novel finding that we present in Chapter 3 is that the interaction of SSB C-terminal alone has a stimulatory effect upon RecA activities. Furthermore, we observed that M. tuberculosis UvrD1 is a weak interaction partner of SSB. The physical and functional interactions between MsSSB with RecA on the one hand, and MsSSB and UvrD1 on the other highlight different types of cross-talk between the components of HR and DNA repair pathways. In contrast to the results of earlier studies, our results indicate that protein-protein interactions alone between SSB and RecA may modulate the RecA mediated processes of presynapsis, homologous pairing and strand exchange between homologous DNA molecules as well as modulate its co-protease activity. In addition, our studies indicate that a direct protein-protein interaction is responsible for the modulation of UvrD1 activities by SSB.

Bacteria - Proteins

Mycobacterium Smegmatis

Homologous Genetic Recombination

Recombinase A Protein

DNA Repair

Mycobacteria - DNA Repair

Mycobacteria - DNA Recombination

DNA Replication

Recombinant DNA

RecA Protein

SSB Protein

Biochemistry

Components Of Fatty Acid Synthesis In Plasmodium Falciparum

Sharma, Shilpi

10 1900

The disease malaria afflicts more than a billion people and kills almost one to three million of them every year. Of the four species of Plasmodium affecting man viz., P. falciparum, P. vivax, P. ovale and P. malariae, Plasmodium falciparum is the deadliest as it causes cerebral malaria. The situation has become worse with the continuous emergence of drug resistance in the parasite. Therefore, improving existing drugs and deciphering new pathways for drug development are the need of the hour. The discovery of the type II fatty acid biosynthesis pathway in Plasmodium falciparum (Surolia and Surolia, 2001) has opened up new avenues for the development of new antimalarials as this pathway is entirely different from the human host in which type I pathway exists. Although many biochemical pathways such as the purine, pyrimidine and carbohydrate metabolic pathways, and the phospholipid, folate and heme biosynthetic pathways operate in the malaria parasite and are being investigated for their amenability as antimalarial therapeutic targets, no antimalarial of commercial use based on the direct use of these biochemical pathways as targets has emerged so far. This is due to the fact that the structure and function of the targets of these drugs overlaps with that of the human host. A description of such pathways forms the Chapter 1 of the thesis. This is followed by a description of the discovery and the importance of fatty acid biosynthesis pathway and the available literature on the various enzymes that are targets of potential antimalarials. Three isoforms are known for condensing enzymes - FabH which functions in initiation, and FabB and FabF which function in elongation. These isoforms differ in their biochemical properties and have unique roles to play in deciding the membrane composition of any organism. This aspect is also discussed in this chapter. Cloning and expression of -ketoacyl-ACP synthase, FabB/F from Plasmodium falciparum is described in Chapter 2. PfFabB/F is coded by the nuclear genome and is targeted to the apicoplast. The gene is coded by the locus MAL6P1.165 and the putative amino acid sequence of the protein exists in PlasmoDB. All apicoplast targeted proteins have a characteristic bipartite leader sequence consisting of a signal and a transit peptide sequence (Waller et al., 1998). Since the mature protein start site was not known and none of the software packages could predict the site, I aligned the PfFabB/F sequence with the sequences of other -ketoacyl-ACP synthases. On the basis of similarity with E. coli synthases and the mature protein start site of plant synthases, I cloned the first construct of PfFabB/F. The sequence was amplified by PCR and ligated in pET as well as pGEX vector. Expression in various hosts under different temperature and induction conditions could not solubilize the protein in significant quantities and most of the protein was found in inclusion bodies. Next I expressed the sequence with five more amino acids towards the N-terminal and expressed it as an N- terminal NusA fusion. The protein was purified by single step Ni-NTA affinity chromatography. Along with the full length protein (108 kDa), a truncated version of the protein was also obtained. The identity of the protein was confirmed by western blotting using anti-His antibody and anti-FabB/F antibody. In Chapter 3, the substrate specificity of PfFabB/F has been elucidated. PfFabB/F condenses malonyl-ACP with a range of acyl-ACPs. In vivo, acyl carrier protein (ACP) shuttles the acyl substrates between various enzymes of the fatty acid biosynthesis pathway. Enzymes of the pathway other than synthases can accept substrate analogs like acyl-CoA and acyl-NAC’s also in vitro. Acyl-ACPs are not very stable species and thus are not commercially available. Therefore, they have to be synthesized. Since malonyl-ACP could not be synthesized by chemical means, enzymatic synthesis of acyl-ACPs was done. Acyl-ACP synthetase (Aas) or holo-ACP synthase (ACPS) can be used for enzymatic synthesis. Aas is specific only for longer chain substrates; therefore, I decided to use holo-ACP synthase, an enzyme responsible for converting apo-ACP to holo-ACP in the presence of CoA in vivo (Lambalot and Walsch, 1995). When acyl-CoAs are supplied in place of CoA, acyl-ACP is produced. Malonyl-ACP and acyl-ACPs (C4-C16:1) were thus synthesized using holo-ACP synthase from E. coli. The reaction went to almost 95% completion, indicating broad substrate specificity of this enzyme. Bacterial or plant acyl-ACPs of different chain lengths can be resolved by Conformation Sensitive PAGE (Heath and Rock, 1995, Post- Beittenmiller et al., 1991). However, Pfacyl-ACPs synthesized using ACPS did not show any significant shift on CS-PAGE. Therefore I resorted to MALDI-TOF (Matrix Assisted Laser Desorption and Ionization- Time Of Flight) for monitoring the PfFabB/F condensation reactions. PfFabB/F condensed C4-C12-ACPs with malonyl-ACP to their corresponding -ketoacyl-ACP products, with C6, C8 and C10-ACPs being most readily elongated. C14-ACP was very sluggishly elongated, and C16 and C16:1-ACPs were not elongated at all. The condensation reaction was also followed by autoradiography using14C labeled malonyl-ACP, exploiting the clear mobility shift between malonyl-ACP and the other acyl-ACPs. The inhibitory effect of cerulenin, a known inhibitor of condensing enzymes was also checked. PfFabB/F also exhibited malonyl decarboxylase activity resulting in the production of acetyl-ACP in the absence of any significant condensation activity. All the enzymes of fatty acid synthesis pathway required to complete a cycle were assembled together for the in vitro reconstitution of Plasmodium fatty acid synthesis cycle which is described in Chapter 4. Earlier studies of Surolia & Surolia have shown that C12 and C14 fatty acids are the major constituents of Plasmodium lipids. One of my objectives was to determine the maximum length of the acyl ACP product that is synthesized when all the functionally active enzymes of fatty acid synthesis are put together (Kapoor et. al, 2001, Sharma et al., 2003, Karmodiya and Surolia, 2006). Condensing enzymes have a deterministic role in the fatty acid composition as they catalyze the only irreversible step in fatty acid biosynthesis. By analyzing products of the elongation cycle by mass spectrometry it was apparent that C14-ACP is the longest species formed. As already mentioned, PfFabB/F readily elongates C12-ACP but C14-ACP is weakly elongated. Thus the end product of the Plasmodium FAB pathway is influenced by the substrate specificity of PfFabB/F. This confirms the role of PfFabB/F as a decisive enzyme in determining the length of fatty acids synthesized. The inhibition of the cycle by cerulenin and triclosan is also described in this chapter. Chapter 5 describes the ability of the PffabB/F gene to complement for the mutation of condensing enzymes in CY244 cells (fabBtsfabF-, Yasuno et al., 2004). CY244 cells were transformed with pBAD alone or PfFabB/F cloned in pBAD vector (pBADPffabB/F) and the growth was monitored at non-permissive temperature. The product of PfFabB/F could rescue the growth of mutant cells at high temperature but only in the presence of oleic acid. FabB and FabF are the isoforms of condensing enzymes involved in elongation of the fatty acid synthesis cycle but they have a unique role to play (Garwin et al., 1980). FabB is responsible for unsaturated fatty acid synthesis, and fabB-mutants require oleic acid supplementation for growth. FabF is utilized in temperature regulation of membrane fluidity and E. coli FabF elevates the level of C18:1 or cis-vaccenic acid at lower growth temperature but FabF-mutants have no growth phenotype (Ulrich et al., 1983). Rescue of CY244 cells in the presence of oleic acid supplementation indicated that the PffabB/F gene behaves like FabF and not FabB. Analysis of the fatty acid composition of membrane lipids of CY244 cells transformed with pBAD vector or pBADPffabB/F by GC-MS demonstrated no elevated levels of cis-vaccenic acid in transformed cells. This observation is in agreement with the in vitro determined substrate specificity data which shows that PfFabB/F does not elongate C16:1ACP. The thesis ends with a summary of the findings in Chapter 6 in the context of FabB and FabF enzymes known from other sources. 2, 4, 4’-Trichloro-2’hydroxydiphenylether, commonly known as triclosan, has been used as a topical antibacterial agent for decades. I determined its efficacy in treating acute systemic bacterial infection in mouse model. Triclosan, as compared to other well known antibiotics, could extend the survival time of mice by 48 hours. This work is described in Appendix I. (Sharma et al., 2003)

Malaria - Microbiology

Recombinant DNA

Fatty Acid Synthesis

Fatty Acid Biosynthesis Pathway

Enzymes - Antimalarials

PfFabB/F

Microbiology

The versatile role of homologous recombination in plant cell : repair of DNA damage, stress-directed genome evolution and foreign DNA integration

Boyko, Oleksandr, University of Lethbridge. Faculty of Arts and Science

January 2008

Homologous recombination represents a DNA repair pathway. Its role in a plant cell is not limited to double strand break repair. It also extends to genome evolution via rearranging of DNA sequences, and has an important application in foreign DNA integration in the plant genome. Our study demonstrated that effects exerted by stress on homologous recombination and genome stability are not restricted to the exposed generation. The progeny of plants exposed to stress exhibited elevated spontaneous homologous recombination, changes in DNA methylation and higher tolerance to stress. These heritable changes are mediated by an unknown stress-inducible epigenetic signal. Furthermore, we demonstrated that using factors that enhance homologous recombination can improve the efficiency of genetic transformation by Agrobacterium. We have developed and patented a plant growth medium enhancing homologous recombination and significantly increasing the transformation frequency. The role of several other chemicals for the improvement of transformation was also evaluated. / xxi, 246 leaves : ill. ; 29 cm. --

Dissertations, Academic

Electronic dissertations

Plants -- Effect of stress on

Plant molecular genetics

Plant genome mapping

Genetic recombination -- Research

Recombinant DNA

DNA repair

DNA damage

Plants -- Adaptation

Amplificação, clonagem e expressão de proteína recombinante do vírus da doença de Aujeszky em sistema de baculovírus para utilização em programa de controle e erradicação / Amplification, cloning and expression of the recombinant protein of the Aujessky s disease vírus in baculovirus system for use in control and eradication program

Dambros, Régia Maria Feltrin

04 July 2006

Made available in DSpace on 2016-12-08T16:24:24Z (GMT). No. of bitstreams: 1 PGCV06MA014.pdf: 2536288 bytes, checksum: 2ced4e5eb18884533f8a66a86da4f665 (MD5) Previous issue date: 2006-07-04 / Coordenação de Aperfeiçoamento de Pessoal de Nível Superior / Aujeszky s disease (AD) is an infect-contagious illness that causes serious economical damages to the producer and the swine industry. Aiming to develop mechanisms and to improve technologies that are faster, more sensitive and more specific for diagnosis and for use in free areas or in AD s eradication programs, the sequence codifier of the glycoprotein E (gE) of Aujeszky s disease virus (ADV) was amplified, cloned and expressed. Through genetic engineering the sequence of the gE gene was propagated in an host organism. The gE was amplified by the technique of polimerase chain reaction (PCR), cloned in the vector pGem®-T Easy and transformed in competent cells of Escherichia coli, DH-5a . The clone obtained was sub-cloned in the expression plasmid pFastBac 1, which contains the promoter gene of the polyhedrin. The obtained subclone was analyzed inside for certification of its correct plasmid orientation with the restriction endonucleases BamH I and EcoR I. The sub-clone with the correct orientation had its DNA extracted and used for transposition inside the bacmid (recombinant baculovirus and helper plasmid with competent DH10Bac cell). Colonies with inserted gE were selected by the phenotype of the colony, which expresses white color when cloned. White recombinant colonies had their DNA extracted and used for cotransfection in insect cells Trichoplusia ni (BTI-Tn5B1-4). The recombinant-gE baculovirus was inoculated in cultured cells and expressed the recombinant gE by PCR and Western blotting . The recombinant-gE baculovirus containing only the gE gene of the VDA will be used for antigen and monoclonal antibodies production, which will aid in the development of a more sensitive, specific and safer for the use in VDA free regions / A doença de Aujeszky (DA) é uma enfermidade infecto-contagiosa que causa graves prejuízos econômicos ao produtor e à agroindústria suinícola. Com o objetivo de desenvolver insumos e aprimorar tecnologias que sejam mais rápidas, sensíveis e específicas de diagnóstico para uso em regiões livres ou em erradicação da DA, a seqüência codificadora da glicoproteína E (gE) do vírus da doença de Aujeszky (VDA) foi amplificada, clonada e expressada. Através da engenharia genética a seqüência do gene da gE foi propagada em um organismo hospedeiro. A gE foi amplificada pela técnica da reação em cadeia da polimerase (PCR) , clonada no vetor pGem®-T Easy e transformada em células competentes de Escherichia coli, DH-5a . O clone obtido foi subclonado no plasmídeo de expressão pFastBac 1, o qual possui o sítio promotor do gene da poliedrina. O subclone obtido foi analisado para certificação de sua orientação correta dentro do plasmídeo com as endonucleases de restrição BamH I e EcoR I. O subclone com a orientação correta teve seu DNA extraído e usado para a transposição dentro do bacmid (baculovírus recombinante e plasmídeo helper em célula competente DH10Bac ). As colônias com inserto gE foram selecionadas pelo fenótipo da colônia, a qual expressa cor branca quando clonada. As colônias brancas recombinantes tiveram seu DNA extraído e usado para a co-transfecção em células do inseto Trichoplusia ni (BTITn5B1- 4). O baculovírus gE-recombinante ao ser inoculado em cultivo celular, expressou a gE recombinante, comprovada pela técnica de PCR e Western blotting . O baculovírus gE-recombinante contendo apenas o gene da gE do VDA será utilizado para produção de antígeno e de anticorpos monoclonais, o que auxiliará no desenvolvimento de um teste de diagnóstico mais sensível, específico e mais seguro para uso em áreas livres do VDA

Suíno - Doeças

DNA recombinante

Engenharia genética

Swine - Diseases

Recombinant DNA

Genetic engineering

Desenvolvimento de seqüências de DNA microsatélite para estudo de populações remanescentes de Jacaré-de-Papo-Amarelo (Caiman latirostris), da região central do Estado de São Paulo / Development of microsatellite DNA sequencies for the study of remnant populations of Broad-snouted caiman (Caiman latirostris), of central region of Sao Paulo State

Rodrigo Barban Zucoloto

24 February 2003

Novos marcadores genéticos foram caracterizados para jacaré-de-papo-amarelo (Caiman latirostris) pela construção de bibliotecas enriquecidas de DNA microssatélite. Um microssatélite foi desenvolvido a partir de uma biblioteca enriquecida de DNA microssatélite (ACC/TGG)n e 12 a partir de uma biblioteca enriquecida de DNA microssatélite (AC/TG)n. Esses marcadores foram testados em indivíduos da espécie Caiman latirostris e resultaram em sete novos microssatélites polimórficos. Adicionalmente quatro marcadores microssatélites de Alligator mississipiensis previamente transferidos para Caiman latirostris foram utilizados. Amostras de sangue jacarés-de-papo-amarelo originárias de várzeas associadas ao Rio Piracicaba e alguns de seus tributários no estado de São Paulo, Brasil, foram avaliadas quanto à variação genética entre populações e o parentesco entre indivíduos. Foi detectada variabilidade entre indivíduos originários de sitos diferentes, mesmo entre aqueles com pequena distância geográfica. Os resultados sugerem que os grupos amostrados em cada sítio são compostos predominantemente por indivíduos aparentados. Uma possível combinação de alta taxa de mortalidade e baixa taxa de natalidade pode ser a explicação do baixo número de indivíduos dispersos com sucesso por geração entre os sítios estudados. Esses marcadores podem auxiliar na compreensão dos processos metapopulacionais que aparentemente ocorrem na espécie. / New genetic markers were characterized for the broad-snouted caiman (Caiman latirostris) by constructing libraries enriched for microsatellite DNA. One microsatellite was developed from a (ACC/TGG)n enriched microsatellite DNA library and 12 from a (AC/TG)n enriched microsatellite DNA library. These markers were tested in Caiman latirostris individuals and resulted in seven new polymorphic microsatellites for the specie. Additionally four Alligator mississipiensis microsatellite markers previously transferred for Caiman latirostris were used. Samples from broad-snouted caimans from small wetlands associated with the Piracicaba River and some of its tributaries in the state of São Paulo, Brazil were used to study the genetic variation between populations and parentage between individuals. Genetic variability was detected among individuals from different sites, even those within a small geographic distance. The results suggest that the groups sampled at each site are composed predominantly of related individuals. A possible combination of high mortality and low natality rates in the fragmented Caiman latirostris populations may explain the low number of successfully dispersed individuals per generation observed between the sites studied. These markers might help to understand the metapopulation processes that are occurring within this species.

Conservação biológica

DNA recombinante

ecologia molecular

genética de populações

populações animais

SSR

STR

animal populations

Conservation biology

molecular ecology

population genetics

recombinant DNA

SSR

STR

Testing the reliability and selectivity of different bone-cell-specific Cre- expressing mouse models for studying bone cell metabolism

Kambrath, Anuradha Valiya

05 1900

Indiana University-Purdue University Indianapolis (IUPUI) / The Cre/loxP system is a tool for targeted recombination of DNA. For applying Cre recombinase-mediated genome modifications, there is a requirement for reliable, high-fidelity, and specific transgenic expression of the Cre recombinase. This study focuses on the reliability of different bone cell specific Cre models in the Cre/loxP system. In this study, DMP1-Cre transgenic mouse which has a transgene driven by DMP1 promotor that allows Cre-expression only in late stage osteoblasts and osteocytes was used. Ctsk-Cre mouse with a driven by Ctsk promoter was used so that only osteoclasts would undergo Cre-mediated recombination. E2A-Cre mouse where the Cre recombinase is driven by a global promoter E2A was also included in this study as a control line to test the Cre reporter line Ai9. Dmp1-Cre, Ctsk-Cre and E2A-Cre mice were crossed to the fluorescent Cre-reporter line—Ai9, which harbors a floxed stop codon, followed by the fluorophoremTomato, inserted into the Rosa26 locus. This construct is expected to give red fluorescence when it recombines with Cre-expressing mouse cells and no fluorescence in non-recombinant mouse cells. Double positive (Ai9+/Cre+) offspring selected by PCR were perfused, and 5mu-m thick section of bone and soft tissues were examined for red fluorescent expression. Cre positive cells were quantitated using ‘ImageJ’ software program. The DMP1-vi Cre mouse results showed significant expression in the targeted osteocytes and osteoblasts. In addition, skeletal muscle tissue also showed significant Cre- expression. Ctsk-Cre mice showed significant expression in targeted osteoclasts. But brain tissue was positive in Cre-expression. Bone-Cre mouse models are expected to express Cre recombinase only in their respective bone cells and they have been used for gene deletion studies in bone cells. However, this study has revealed that the bone cell specific Cre mouse models DMP1-Cre and Ctsk-Cre have unexpected expression in muscle and brain respectively. In order to use these models for targeted gene deletion in bone cells, further testing and studies have to be conducted.

DMP1-Cre

Ctsk-Cre

Bones -- Growth

Bones -- Growth -- Molecular aspects

Genetic recombination -- Research

Recombinant DNA

Gene targeting

Osteocytes

Bone cells

Osteoblasts

Uttryck av ett nytt rekombinant protein Cp149 (HBV-kapsidprotein) modifierat med TfR apical domän / Expression of a new recombinant protein Cp149 (HBV capsid protein) modified with TfR apical domain

Noorzai, Hamida

January 2022

Hepatit-B är en leversjukdom som orsakas av hepatit-B-virus (HBV) vilket är en kapslad DNA-virus. Kapsidprotein (Cp) har stor betydelse i virusets livscykel exempelvis DNA-replikation, interaktion med värdceller och andra virala glykoproteiner. HBV, som många andra virus, tar sig in i cellen genom att binda till cellreceptorer. Transferrinreceptor är en välkänd receptor som mögliggör virus inträde i cellen genom att binda till virusproteiner, intraktionen sker i apikala domänen i TfR. Båda Cp149, kapsidsammansättnings domänen i Cp, och apikala domänen i TfR är betydelsefulla ändamål för utveckling av antivirala läkemedel. Syftet med arbetet var att klona och uttrycka olika varianter av ett nytt modifierat Cp149, där Cp149 har modifierats med AP01 (lösliga formen av apikala dömanen),  och analysera intraktioner mellan proteinerna och viralt glykoprotein, MGP1. Modifierade proteingener klonades i plasmid (pET-11a) med hjälp av rekombinant DNA-teknik och användning av restriktionsenzymer NdeI och BamHI. Agarosgelelektrofores och DNA-sekvensering användes för att  kontrollera förekomst av eftersökta DNA-sekvenser. Nya plasmider fördes över till bakterieceller, Escherichia coli, och  proteinutrycket inducerades i bakteriecellerna genom kemiskbehandling. Framrenade proteiner från respektive provlösning analyserades med Sodium dodecyl sulphate polyakrylamid gel electrophoresis (SDS-PAGE) och proteinernas funktion undersöktes med flödescytometri genom att besämma bindningsförmågan till MGP1, som uttrycktes på jästceller, i närvaro av TfR. Rekombinant plasmid innehållande proteingen kodande Cp149 för varianter A-D samt F lyckades att framställas. Resultatet från SDS-PAGE påvisade inga tydlyga protein-band och flödescytometri resultatet var svårt att bedömma, troligen då ytterliggare proteinupprening behövdes för att isolera kapsidproteinerna. Syftet med arbetet har erhållits delvis och fortsatt undersökningar på nya proteiner förslås. / Hepatitis B is one av the major worldwide health problems that is caused by enveloped DNA virus, Hepatitis B virus (HBV). HBV’s capsid protein (Cp) has an important role in the virus life cycle, för example DNA replication, intraction with host cells, and other viral glycoproteins. HBV, like many other viruses, enters the cells by binding to cell receptors. Transferrin receptor (TfR) is a well-known receptor that enables virus entry into the cell by binding to viral proteins. The interaction takes place in the apical domain of TfR. Both Cp149, the capsid’s composition domain of Cp, and the soluble form of the apical domain, AP01, from TfR are important builing parts to be explored as starting building blocks for the development of antiviral therapeutics. Modification of Cp149 with AP01 is an interesting combination to produce new protein-based drugs to prevent viral infections. The aim of this project was to clone and express six different variants of a AP01 modified Cp149 protein as a starting points to analyze interactions between the proteins and Machupo virus glykoprotein 1 (MGP1). All target DNA templates and plasmids (pET-11a) were digested with restriction enzymes, NdeI and BamHI, and ligated by T4 DNA ligase. Agarose gel electrophoresis and DNA sequencing were used as validation methods to confirm the presence of desired and corrected DNA sequences, respectively, during gene cloning. DNA transformation and induction of Escherichia coli cells was used to express the desired proteins. The purified proteins were validated for their binding ability to MGP1, expressed on yeast cells by flow cytometry in a competition assay with TfR. Recombinant plasmid including the expected DNA sequence encoding Cp149 for variants A-D and F was successfully produced. There was no clear detection of protein bands on Sodium dodecyl sulphate polyakrylamid gel electrophoresis (SDS-PAGE) gel and flow cytometry results were difficult to interpret due to insufficient protein purification during ammonium sulphate percipitation. The purpose of the project has been obtained partially and more studies have to be carried out to produce pure proteins that can be used for further analysis.

Gene cloning

Recombinant DNA

Transformation

Protein expression

SDS-PAGE

Flow Cytometry

Genkloning

rekombinant DNA

Transformering

Proteinuttryck

SDS-PAGE

Flödescytometri

Biomedical Laboratory Science/Technology

Flödescytometrisk undersökning av inbindning mellan designade topdomänen från transferrinreceptorn till virala glykoproteiner för potentiell användning inom läkemedelsframtagning / Flow cytometric investigation of binding between the designed top domain of the transferrin receptor to viral glycoproteins for potential use in drug development

Rydell, Emma

January 2022

Machupovirus är ett virus som kan orsaka hemorragisk feber hos människor. Efter utvärdering av bindning mellan designade proteiner och virala glykoproteiner skulle proteinerna potentiellt kunna användas vid framtagning av ett proteinbasserat läkemedel mot hemorragisk feber. Syftet med studien var att efter riktad evolution och framrening av optimerade varianter av proteinet AP01 undersöka inbindningen till virala glykoproteiner mellan designade AP01 proteiner och transferrinreceptorn med hjälp av flödescytometrisk undersökning. Den fysiologiska nivån av järn i kroppen upprätthålls av transferrin (Tf) och transferrinreceptorn (TfR), ett transmembranprotein bestående av tre domäner. TfR apikala domän används av glykoprotein 1 (MGP1) och Plasmodium vivax för att ta sig in i celler genom receptormedierad endocytos. Med rekombinant genteknik kan rekombinanta plasmider skapas där en gen av intresse ligeras in i en plasmid med hjälp av DNA-ligas. I studien skapades rekombinanta plasmider pET29b+/AP01 S2.1, S2.2, S2.3, S3.3, S3.4 och S3.6 som transformerades till E. coli. Erhållna resultat från sekvensering visade att samtliga sex AP01-gener hade ligerats i vektorn men sekvensering av rekombinanta plasmider visade att endast pET29b+/AP01 S2.1, S2.2, S2.3 och S3.6 hade nukleotidsekvens utan mutationer. Proteinuttryck inducerades innan proteiner renades fram med immobilized metal ion affinity chromatography (IMAC). Den uppskattade molekylvikten hos de framrenade proteinerna var 18 kDa som bestämdes med sodium dodecyl sulfate – polyacrylamid gel electrophoresis (SDS-PAGE) vilket överrenstämde med den teoretiska molekylvikten. Flödescytometri användes för att undersöka inbindningsförmågan mellan de uttryckta proteinerna och glykoprotein 1 (MGP1). Interaktionsbindningen mellan de designade proteinerna och MGP1 är bättre än interaktionen mellan originalgen AP01 och MGP1. De designade proteinerna visar på en svag effekt i den utförda ”competition assay” som gjorts vilket kan förklaras med en ej optimal struktur hos de designade proteinerna eller närvaro av BSA. / Machupovirus is a virus that can cause hemorragic fever in humans. After evaluating the binding between designed proteins and viral glycoproteins, the proteins could potentially be used in the development of a protein-based drug for hemorrhagic fever. The aim of the study was to investigate the binding to viral glycoproteins between designed AP01 proteins and the transferrin receptor after directed evolution and purification of optimized variants of the AP01 protein by means of flow cytometric examination. The physiological level of iron in the body is maintained by transferrin (Tf) and the transferrin receptor (TfR), a transmembrane protein consisting of three domains. The apical domain of TfR is used by glycoprotein 1 (MGP1) and Plasmodium vivax to enter cells through receptor mediated endocytosis. With recombinant DNA technology, recombinant plasmids can be created where a gene of interest is ligated into a plasmid using DNA ligase. In this study, recombinant plasmids pET29b+/AP01 S2.1, S2.2, S2.3, S3.3, S3.4 and S3.6 were created and transformed into E. coli. Sequencing results showed that all six AP01 genes had been ligated into the vector but sequencing of recombinant plasmids showed that only endast pET29b+/AP01 S2.1, S2.2, S2.3 and S3.6 had nucleotid sequence without mutations. Protein expression was induced before proteins were purified by immobilized metal ion affinity chromatography (IMAC). The estimated molecular weight of the purified proteins was 18 kDa as determined by sodium dodecyl sulfate – polyacrylamid gel electrophoresis (SDS-PAGE) which was consistent with the theoretical molecular weight. Flow cytometry was used to examine the binding ability between the expressed proteins and glycoprotein 1 (MGP1). The interaction binding between the designed proteins and MGP1 is better than the interaction between the original gene AP01 and MGP1. The designed proteins show a weak effect in the “competition assay” preformed, wich can be explained by a non-optimal structure how the designed proteins or the presence of BSA.

Transferrin receptor

recombinant DNA techniques

protein purification

yeast surface display

flow cytometry

Transferrinreceptor

rekombinant genteknik

proteinupprening

yeast surface display

flödescytometri

Biochemistry and Molecular Biology

Biokemi och molekylärbiologi

Politically Corrected Science: The Early Negotiation of U.S. Agricultural Biotechnology Policy

Jones, Mary Ellen

11 April 1999

This social history of science policy development emphasizes the impact on the agricultural community of federal policies regarding release of recombinant DNA (rDNA) organisms into the environment. The history also demonstrates that the U.S. Coordinated Framework for Biotechnology Regulation (1986) is based principally in political criteria, not solidly based in science as its proponents claimed. The power struggle among policy negotiators with incompatible belief systems resulted in a political correction of biotechnology. I also demonstrate that episodes in the rDNA controversy occur in repetitive and periodic patterns. During the 1980s, the first rDNA microbial pesticide, Ice-Minus, struggled through a policy gauntlet of federal agency approval processes, a Congressional hearing, and many legal actions before it was finally released into the environment. At the height of the controversy (1984-1986), the Reagan Administration would admit no new laws or regulations to slow the development of technologies or hinder American international competitiveness. At the same time, Jeremy Rifkin, a radical activist representing a green world view, used the controversy to agitate for social and economic reform. Meanwhile, a group of Congressional aides who called themselves the "Cloneheads" used the debate to fight for more public participation in the science policy-making process. Conflicting perspectives regarding biotechnology originated, not in level of understanding of the science involved, but in personal perspectives that were outwardly expressed as political group affiliations. The direction of federal biotechnology policy was influenced most successfully by politically best-positioned individuals (what I call a "hierarchy effect") who based decisions on how biotechnology harmonized with their pre-existing beliefs. The success of their actions also depended on timing. Historical events during the rDNA controversy followed the same periodic pattern--gestation, threshold, crisis/conflict, and quasi-quiescence--through two consecutive eras--the Containment Era (1970s) and the Release Era (1980s). These periods are modeled after Fletcher's stages through which ethical issues evolve (1990). However, an agricultural perspective on the debate reveals that such stages also occur in finer detail on repeating, overlapping, and multi-level scales. Knowledge of this periodicity may be useful in predicting features of future episodes of the rDNA controversy. / Ph. D.

genetic engineering

rDNA

Jeremy Rifkin

Reagan Administration

periodicity of technological controversy

Cloneheads

recombinant DNA in agriculture

science and politics

Construção e análise funcional de vetores lentivirais de interesse biotecnológico / Construction and functional analysis of lentiviral vectors for biotechnological purposes

Vedoveli, Naiara Cristina Pulzi Saito

16 May 2016

Vetores lentivirais são ferramentas fundamentais para modificação celular. Sua utilização ganhou destaque devido à capacidade desses em integrar ao genoma de células que estão ou não em divisão. Grande parte dos vetores desenvolvidos são derivados do genoma do Vírus da Imunodeficiência Humana (HIV-1), portanto, modificações foram necessárias a fim de evitar a formação de Partículas Competentes em Replicação (RCLs) e garantir uma utilização segura. Com as modificações, foram produzidos os vetores lentivirais de terceira geração utilizados atualmente. Esses vetores podem ser usados para expressão constitutiva de genes, produção de proteínas recombinantes, produção de animais transgênicos e terapia gênica. Com isso, torna-se necessário o desenvolvimento de vetores lentivirais para aplicação em pesquisa básica e ensaios clínicos. Dessa forma, o presente estudo teve por objetivo a construção de vetores de expressão lentivirais aplicáveis à: 1- expressão constitutiva de genes de interesse e 2-vetores com promotores específicos para expressão de proteínas em megacariócitos. Esse trabalho descreve a construção desses vetores, sua importância e discute suas possíveis aplicações. As sequências selecionadas para produção dos vetores foram: os genes Runx1C e VkorC1 e os promotores proPF4 e proITGA2b. Todas as sequências encontram-se clonadas em vetor de clonagem e estoques de bactérias com esses vetores congeladas em glicerol foram confeccionados. Para a confecção dos vetores lentivirais, o gene Runx1C foi subclonado no vetor lentiviral base p1054-CIGWS sob controle do promotor forte CMV, enquanto o promotor proITGA2b foi subclonado no vetor base p1054-FVIII, em substituição ao promotor CMV, de forma a controlar a expressão de FVIII. Os dois vetores produzidos apresentam ainda o gene para proteína verde GFP precedida do sítio de ligação do ribossomo IRES, com expressão controlada pelo mesmo promotor interno do vetor. O trabalho possibilitou, portanto, a produção de dois vetores lentivirais bi-cistrônicos: p1054-Runx1C e pL-proITGA2b-FVIII. A construção p1054-Runx1C ainda não foi sequenciada, mas foi confirmada por restrição enzimática e apresenta potencial para aplicação em estudos de diferenciação hematopoética. Já a construção pL-proITGA2b-FVIII foi sequenciada, porém sem confirmação da região de ligação do proITGA2b ao vetor. Reações de PCR e de restrição enzimática confirmaram a ligação e sequenciamento mostrou 67% de similaridade entre a região sequenciada e o promotor ITGA2b depositado no banco de dados. Análise funcional foi realizada através da transfecção desse vetor em células HEK-293T. As células transfectadas apresentaram expressão positiva para GFP e secreção de FVIII no sobrenadante celular, evidenciando que o promotor proITGA2b clonado no vetor encontra-se ativo. Esse vetor apresenta potencial para aplicação em terapia gênica para hemofilias, pois apresenta expressão do fator de coagulação direcionado a megacariócitos e plaquetas, células que estão diretamente relacionadas ao processo de coagulação, representando grandes veículos para secreção desses fatores. Ainda, os dois vetores lentivirais gerados apresentam segurança e eficiência elevadas, pois são vetores de terceira geração auto-inativantes (SIN) e apresentam elementos regulatórios que melhoram o transporte e integração do DNA ao genoma hospedeiro. / Lentiviral vectors are fundamental tools for cell modification that gained prominence due to their ability to integrate the genome of non-dividing cells. Most of developed lentiviral vectors are derived from the genome of Human Immunodeficiency Virus (HIV-1), so modifications were necessary in order to avoid the formation of Competent Replication Particles (RCLs) and ensure safer operations. The modifications led to development of third generation lentiviral vectors currently used. These vectors can be used for constitutive gene expression, production of recombinant protein, production of transgenic animals and gene therapy. It\'s evident the need to develop lentiviral vectors for application in basic research and clinical trials. Thus this study aimed to construct lentiviral expression vectors applicable to: 1- constitutive expression of genes of interest and 2-vectors with specific promoters for expression of proteins in megakaryocytes and platelets. This paper describes the construction of these vectors, their importance and discuss their possible applications. Sequences were selected for production of the vectors: genes Runx1C and VkorC1 and proPF4 and proITGA2b promoters. All four sequences are cloned into cloning vectors and stocks of bacteria with these vectors frozen in glycerol were prepared. Lentiviral vectors were engineered from subcloning the sequence Runx1C into the basic lentiviral vector p1054- CIGWS under control of the strong CMV promoter, and from subcloning proITGA2b promoter into p1054-FVIII basic vector, replacing the CMV promoter in order to control the expression of FVIII. Both vectors exhibit the green fluorescence protein GFP gene preceded by a ribosome binding site IRES under control of vector\'s internal promoter. Therefore, this work resulted in the production of two bi-cistronic lentiviral vectors: p1054-Runx1C and pLproITGA2b-FVIII. The p1054-Runx1C construction has not yet been sequenced, but it was confirmed by digestion and has potential for use in hematopoietic differentiation studies. Though, pL-proITGA2b-FVIII construct was sequenced, but the technique didn\'t allow to confirm the binding region between proITGA2b and the vector. Although PCR reaction and digestion confirmed the construction. Sequence analysis showed 67% similarity between the sequenced region and ITGA2b promoter deposited in the database. Functional analysis was performed by transfection of this vector in HEK-293T cells. The transfected cells showed positive expression of GFP and FVIII secretion in cell supernatant, indicating that the proITGA2b promoter cloned into the vector is active. This vector has potential usage in gene therapy for hemophilia, since it can be used to express coagulation factors in megakaryocytes and platelets and these cells are directly related to the clotting process, representing great vehicles for secretion of these factors. Even more, the two lentiviral vectors generated have higher safety and efficiency, as they are self-inactivating (SIN) third-generation vectors and have regulatory elements that enhance transport and integration of DNA into the host genome.

clonagem molecular

diferenciação hematopoética

hematopoietic differentiation

HIV-1

HIV-1

ITGA2b

lentiviral vectors

lentivirus

lentivírus

megacariócitos

megakaryocytes

plaquetas

platelets

promotores específicos

Runx1

Runx1

SIN vectors

specific promoters, ITGA2b

tecnologia do DNA recombinante

vetores lentivirais

vetores SIN