Perfil da expressão gênica de larvas de Tetrapedia diversipes (Hymenoptera: Apidae) em diapausa / Gene expression profile of diapause larvae of Tetrapedia diversipes (Hymenoptera: Apidae)

Priscila Karla Ferreira dos Santos

17 December 2015

A diapausa é um fenômeno amplamente presente nos artrópodes e é considerada como primordial para o sucesso evolutivo da Classe Insecta, pois possibilita a sobrevivência em condições adversas, como estações frias e secas. Sabe-se que durante a diapausa ocorre o silenciamento de muitos genes e que outros são unicamente expressos nesta fase. Embora existam evidências de que o processo da diapausa tenha se mantido conservado durante a evolução das espécies, ainda há lacunas no conhecimento sobre o nível de conservação dos padrões metabólicos. Um bom modelo para se estudar a diapausa é Tetrapedia diversipes, uma espécie bivoltina de abelha solitária. Os indivíduos que nascem na primeira geração seguem o desenvolvimento desde ovo até adulto em tempo bem menor do que aqueles que nascem na segunda geração; estes retardam o desenvolvimento na fase larval. Além disso, essa espécie é de fácil obtenção no seu ambiente natural, pois apresenta alta taxa de nidificação em ninhos-armadilha. O objetivo deste trabalho foi comparar o perfil de expressão de genes entre as larvas da 1ª geração (que não entram em diapausa), larvas da 2ª geração (que entrariam em diapausa) e das larvas em diapausa. Foram identificados 196 genes diferencialmente expressos, destes 87 foram anotados. Muitos destes genes já foram descritos na literatura como relacionados à diapausa em outras espécies, no entanto, o padrão de expressão não é conservado. Os genes aqui identificados foram divididos em cinco grupos: relacionados à desintoxicação celular, cutícula e citoesqueleto, metabolismo de lipídeos e esteróis, ciclo celular e outros genes relacionados à diapausa / The diapause is broadly distributed among the arthropods and has had an important role for the evolutionary success of the Class Insecta, mainly because this process permits insects to explore adverse conditions, such as cold and dry seasons. It is known that there are many genes being silenced and others being uniquely expressed during diapause. And although there are evidences that the diapause process has remained conserved during the evolution of species, it is still not clear how conserved are the metabolic patterns involved in this behavior. Tetrapedia diversipes is a solitary bee and a good model to study diapause. Individuals from the first generation do not enter in diapause and develop faster than individuals from the second generation, which enter in diapause during the winter. Moreover, this species is easy to capture in natural conditions due to the high rate of nesting in trap nests. The aim of this work was to compare the gene expression profile among non-diapause larvae from first and second generation (about to enter diapause) and larvae already in diapause, trough transcriptome data. One hundred ninety-four genes were identified as differentially expressed and 87 of them were annotated. Many of these genes have already been described as related to diapause in others species, but the expression pattern was not conserved. These genes were divided in five groups: related to cellular detoxification, cuticle and cytoskeleton, lipids and steroids metabolism, cell cycle and other genes related to diapause

Abelha

Expressão gênica

Bee

Gene expression

The effects of polysomal mRNA association and cap methylation on gene expression in Trypanosoma brucei

Kelner, Anna

January 2014

Contrasting physiological requirements for T. brucei survival between procyclic (vector) and bloodstream (mammal) forms necessitate different molecular processes and therefore changes in protein expression. Transcriptional regulation is unusual in T. brucei because the arrangement of genes is polycistronic; however, genes which are transcribed together are subsequently cleaved into separate mRNAs by trans-splicing and are individually regulated. During the process of trans-splicing, a 39-nucleotide splice-leader RNA is added to the 5´ end of mRNA. In this study, gene regulation in trypanosomes will be examined in the context of the 7-methylguanosine cap attached to the 5´ end of the splice-leader. Interestingly, in addition to the capping enzymes identified in other eukaryotes, trypanosomatids have an additional guanylyltransferase and methyltransferase in the form of a bifunctional enzyme (TbCGM1). TbCGM1 was found to be essential in bloodstream form T. brucei, although the purpose of this bifunctional capping enzyme remains unclear. Null mutants of a related enzyme, monomeric methyltransferase TbCMT1, did not show an effect on cell viability in culture, however, the enzyme proved to be important for virulence in vivo. Complementary to the study of T. brucei capping enzymes, we worked to develop a method to allow structural analysis of the 5´mRNA cap by mass spectrometry. Following pre-mRNA processing, regulation of the mature mRNAs is a tightly controlled cellular process. While multiple stage-specific transcripts have been identified, previous studies using RNA-seq found that the changes in overall transcript level do not necessarily reflect the abundance of the corresponding proteins. We hypothesized that in addition to mRNA stability, mRNA recruitment to ribosomes may play a significant role in the regulation of gene expression in T. brucei. To approach this question, we performed RNA-seq of total, subpolysomal, and polysomal mRNA. This transcriptomic data was then correlated with published proteomic studies to obtain a global picture of the relative translation efficiencies and their relationship to steady-state protein levels between bloodstream and procyclic form T. brucei.

572.8

Identification and functional characterisation of RAM, a novel and essential component of RNA guanine-7 methylation

Gonatopoulos-Pournatzis, Thomas

January 2012

Gene expression in eukaryotes is dependent on the N-7 methylguanosine cap, located at the 5’ end of RNA pol II transcripts, which marks pre-mRNA for processing, stabilisation and translation initiation. The enzymes that catalyse the formation of the N-7 methylguanosine cap are recruited to RNA pol II at the initial stages of transcription. The final step in this process, N-7 methylation of the guanosine cap, is catalysed by the RNA guanine-7 methyltransferase, RNMT. RNA guanine-7 methylation is an essential process for cell viability and its up-regulation has been associated with cell transformation. However, the mechanistic details of RNMT function in mammalian cells remain elusive. In order to gain better understanding of the molecular mechanisms associated with RNA guanine-7 methylation, cellular RNMT complexes were purified from human cells and constituent proteins were identified using mass spectrometry. A novel component of the RNA guanine-7 methyltransferase complex was identified and designated as RAM (RNMT activating mini-protein). The vast majority of RNMT is found in a complex with RAM and vice versa.RAM is an RNA-binding protein, promoting recruitment of RNA to RNMT. RAM increases recombinant and cellular RNMT cap methyltransferase activity and is required for cap methylation in vivo. We therefore, describe RAM as an “obligate activator” of the human cap methyltransferase. As expected of a protein essential for cap methylation, RAM is required for gene expression, and RAM depletion results in loss of cell viability. Current studies are being focused on determining RAM/RNMT crystal structure as well as determining how the RNA guanine-7 methyltransferase complex is regulated within cells.

616

Factors that affect the extension of dendrites and the expression of nicotinic acetylcholine receptors by rat peripheral neurons

De Koninck, Paul

January 1995

No description available.

Gene expression

Dendrites

Neurons -- Growth

Nicotinic receptors

The effects of regulatory variation in multiple mouse tissues

Cowley, Mark, Biotechnology & Biomolecular Sciences, Faculty of Science, UNSW

January 2009

Recently, it has been shown that genetic variation that perturbs the regulation of gene expression is widespread in eukaryotic genomes. Regulatory variation (RV) is expected to be an important driver of phenotypic differences, evolutionary change, and susceptibility to complex genetic diseases. Because trans-acting regulators of gene expression control mRNA levels of multiple genes simultaneously, we hypothesise that RV that affects these components will have a shared-influence upon the expression levels of multiple genes. Since genes are regulated in trans by combinations of basal and tissue specific factors, we further hypothesise that RV in these components may have different effects in each tissue. We used microarrays to identify 755 genes that were affected by RV in at least one of the brain, kidney and liver of two inbred mouse strains, C57BL/6J and DBA/2J. Just 2% were affected in all three tissues, suggesting that the influence of RV is predominantly tissue specific. To study shared-RV, we measured the expression levels of these 755 genes in the same 3 tissues from a panel of recombinant inbred mice, and identified groups of correlated genes that are putatively under the influence of shared trans-acting RV. Using methods that we developed for studying the effects of RV in multiple tissues, we identified 212 genes that are correlated in all three tissues, which include 10 groups of at least 3 genes. We developed a novel method called coherency analysis to show that RV consistently affected the expression levels of these groups of genes in different genetic backgrounds. Strikingly, the relative up- or down-regulation of genes in each group was markedly different in the three tissues of the same mouse, suggesting that the influence of RV itself is not tissue specific as previously expected, but that RV can influence genes with differing outcomes in each tissue. These observations are compatible with RV affecting combinations of basal and tissue specific regulatory factors. This is the first cross-tissue investigation into the influence of shared-RV in multiple tissues, which has important implications in humans, where access to the phenotypically relevant tissue may be necessarily limited.

Genetics

Microarray

Bioinformatics

Regulatory Variation

Gene Expression

The effects of regulatory variation in multiple mouse tissues

Cowley, Mark, Biotechnology & Biomolecular Sciences, Faculty of Science, UNSW

January 2009

Recently, it has been shown that genetic variation that perturbs the regulation of gene expression is widespread in eukaryotic genomes. Regulatory variation (RV) is expected to be an important driver of phenotypic differences, evolutionary change, and susceptibility to complex genetic diseases. Because trans-acting regulators of gene expression control mRNA levels of multiple genes simultaneously, we hypothesise that RV that affects these components will have a shared-influence upon the expression levels of multiple genes. Since genes are regulated in trans by combinations of basal and tissue specific factors, we further hypothesise that RV in these components may have different effects in each tissue. We used microarrays to identify 755 genes that were affected by RV in at least one of the brain, kidney and liver of two inbred mouse strains, C57BL/6J and DBA/2J. Just 2% were affected in all three tissues, suggesting that the influence of RV is predominantly tissue specific. To study shared-RV, we measured the expression levels of these 755 genes in the same 3 tissues from a panel of recombinant inbred mice, and identified groups of correlated genes that are putatively under the influence of shared trans-acting RV. Using methods that we developed for studying the effects of RV in multiple tissues, we identified 212 genes that are correlated in all three tissues, which include 10 groups of at least 3 genes. We developed a novel method called coherency analysis to show that RV consistently affected the expression levels of these groups of genes in different genetic backgrounds. Strikingly, the relative up- or down-regulation of genes in each group was markedly different in the three tissues of the same mouse, suggesting that the influence of RV itself is not tissue specific as previously expected, but that RV can influence genes with differing outcomes in each tissue. These observations are compatible with RV affecting combinations of basal and tissue specific regulatory factors. This is the first cross-tissue investigation into the influence of shared-RV in multiple tissues, which has important implications in humans, where access to the phenotypically relevant tissue may be necessarily limited.

Genetics

Microarray

Bioinformatics

Regulatory Variation

Gene Expression

The effects of regulatory variation in multiple mouse tissues

Cowley, Mark James, Biotechnology & Biomolecular Sciences, Faculty of Science, UNSW

January 2009

Recently, it has been shown that genetic variation that perturbs the regulation of gene expression is widespread in eukaryotic genomes. Regulatory variation (RV) is expected to be an important driver of phenotypic differences, evolutionary change, and susceptibility to complex genetic diseases. Because trans-acting regulators of gene expression control mRNA levels of multiple genes simultaneously, we hypothesise that RV that affects these components will have a shared-influence upon the expression levels of multiple genes. Since genes are regulated in trans by combinations of basal and tissue specific factors, we further hypothesise that RV in these components may have different effects in each tissue. We used microarrays to identify 755 genes that were affected by RV in at least one of the brain, kidney and liver of two inbred mouse strains, C57BL/6J and DBA/2J. Just 2% were affected in all three tissues, suggesting that the influence of RV is predominantly tissue specific. To study shared-RV, we measured the expression levels of these 755 genes in the same 3 tissues from a panel of recombinant inbred mice, and identified groups of correlated genes that are putatively under the influence of shared trans-acting RV. Using methods that we developed for studying the effects of RV in multiple tissues, we identified 212 genes that are correlated in all three tissues, which include 10 groups of at least 3 genes. We developed a novel method called coherency analysis to show that RV consistently affected the expression levels of these groups of genes in different genetic backgrounds. Strikingly, the relative up- or down-regulation of genes in each group was markedly different in the three tissues of the same mouse, suggesting that the influence of RV itself is not tissue specific as previously expected, but that RV can influence genes with differing outcomes in each tissue. These observations are compatible with RV affecting combinations of basal and tissue specific regulatory factors. This is the first cross-tissue investigation into the influence of shared-RV in multiple tissues, which has important implications in humans, where access to the phenotypically relevant tissue may be necessarily limited.

Genetics

Microarray

Bioinformatics

Regulatory Variation

Gene Expression

The phosphite responsive transcriptome of phytophthora cinnamomi

M.King@murdoch.edu.au, Michaela King

January 2007

Phosphite has been used to effectively control the soil borne plant pathogen Phytophthora cinnamomi in many horticultural crops, forest trees and natural ecosystems. However, the molecular mechanisms behind phosphite action on this pathogen are poorly understood. Several studies have shown that phosphite inhibits growth and zoospore production of P. cinnamomi and in addition induces significant physiological and metabolic changes in the mycelium. As an approach to understanding the mechanisms and relevance of these changes in the pathogen, the effect of phosphite on gene expression was investigated using microarray analysis. To construct the microarray, RNA was extracted from phosphite-treated (40 ug/ml) mycelium of P. cinnamomi isolate MP 80. The chosen phosphite concentration inhibited the mycelial growth by 70% but provided sufficient mycelium for RNA extractions after 4 days growth at 25C. The mRNA was reverse transcribed into cDNA and cloned into lambda to construct a library consisting of 2 million pfu of which 80 % were recombinant phage. The inserts were sequenced for a random selection of clones from the library. The nucleotide sequences generated revealed a range of different P. cinnamomi genes being expressed and demonstrated that the cDNA library provided a good representation of the transcripts expressed in P. cinnamomi. The types of genes found to be expressed in the mycelium of P. cinnamomi included genes encoding GTP binding proteins involved in vesicle transport, structural proteins involved in maintaining cell membrane integrity,elicitors, phosphatases and ribosomal proteins. Over nine thousand cDNA transcripts were randomly selected from the cDNA library and prepared by PCR amplification and purification for microarray construction. Custom made cDNA arrays containing 9216 cDNA transcripts were constructed and probed with RNA from untreated mycelium and mycelium grown in medium with 40 ug/ml phosphite. Two genes, EF-1 alpha and cinnamomin gene, identified by qRT-PCR as being constitutively expressed were also positioned on the arrays as positive controls. In the process of identifying constitutively expressed genes, qRT PCR revealed that phosphite down-regulated a gene encoding ubiquitin-conjugating enzyme, a component of the ubiquitin/proteasome pathway involved in the removal of abnormal and short lived-regulatory proteins and rate limiting enzymes. From the arrays a further seventy-two transcripts with altered patterns in gene expression (fold change > 2) were identified. The majority of the cDNA transcripts spotted on the array were down-regulated with changes in gene expression ranging from 2- to 3.5-fold. Thirty-two cDNA transcripts were up-regulated with changes in gene expression ranging from 2- to 16-fold. Characterisation by sequencing revealed that the most highly induced transcripts coded for ADP-ribosylation factors, an ABC cassette transporter and a glycosyl transferase. A transcript encoding a vitamin B6 biosynthesis protein was also identified as up-regulated by 2.9-fold. In contrast, the down-regulated transcripts coded for cellulose synthase I, annexin, glutamine synthetase, metallothionein and an alternative oxidase. The results are discussed in terms of possible roles and mechanism(s) of phosphite action within the mycelium of P.cinnamomi. This work is the first comprehensive screen for phosphite regulated-gene expression in P. cinnamomi and represents a significant step towards an understanding of the mode of action of phosphite on this organism. This thesis provides valuable information on the molecular interaction between phosphite and P. cinnamomi, which in future studies may stimulate the discovery of novel methods and cellular targets for the control of plant pathogenic Oomycetes.

Phytophthora cinnamomi

phosphite

gene expression

microarrays

The Role of RhoA in Early Heart Development

Kaarbo, Mari, n/a

January 2005

RhoA is a small GTPase that acts as a molecular switch to control a variety of signal transduction pathways in eukaryotes. From an initial established role in the regulation of the actin cytoskeleton, RhoA has now been implicated in a range of functions that include gene transcription and regulation of cell morphology. In earlier studies from this laboratory that employed differential display and in situ hybridisation, RhoA was indicated as being up-regulated during the stages of early heart development in the developing chick embryo. Given the important effects of RhoA on both gene expression and morphology in other systems, it was hypothesised that RhoA plays a central role in the molecular mechanisms controlling cardiogenesis. This thesis describes investigations undertaken to elucidate the role of RhoA in these processes. As an initial approach to corroborate the earlier gene expression findings and provide further evidence for a role in tissue developmental mechanisms, RhoA proteins levels in the developing chick embryo were analysed using immunocytochemistry. These experiments demonstrated that RhoA is most abundant in heart-forming regions, findings compatible with the earlier gene expression studies and the proposed role of this protein in early heart development. Preliminary studies from this laboratory had also suggested that chick RhoA is expressed as different length mRNA transcripts that vary only in the 3' untranslated region (UTR). This thesis presents additional evidence for the existence of these different RhoA transcripts from experiments using Northern hybridisation and RT-PCR analyses. These analyses also serve to demonstrate that the second shortest RhoA transcript (designated RhoA2) is the most abundant transcript in developing heart tissue, in contrast to the situation in other embryonic tissues, findings that could be taken to suggest a possible role for this 3'UTR in developmental mechanisms that is yet to be elucidated. One potentially informative approach for testing the function of a protein in a biological system is to inhibit its expression and/or activity and observe the changes induced. The effects of inhibiting RhoA in early heart development and early organogenesis in the chick embryo model were investigated using small interfering RNAs (siRNA). Reduction in RhoA expression by siRNA treatment, as confirmed by real-time PCR, resulted in loss of heart tube fusion and abnormal head development, the former result providing further direct evidence of a role for RhoA in heart developmental processes. In order to investigate the function of RhoA specifically during the process of cardiomyocyte differentiation, an inducible model of cardiomyogenesis, P19CL6 cells, was used in combination with over-expression of different forms of mouse RhoA. The striking result from these investigations was that over-expression of the dominant negative mutant of mouse RhoA (mRhoAN19) prevented the differentiation of induced P19CL6 cells to the cardiomyocyte phenotype, results consistent with an essential role for RhoA in this cellular transition. The mechanism by which RhoA mediates its different cellular functions is unclear, however some studies have implicated RhoA in the regulation of transcription factors. To investigate such a mechanism as a possible explanation for the requirement of RhoA in cardiomyocyte differentiation, the P19CL6 inducible cell system over-expressing different forms of RhoA was analysed through real-time PCR to quantify the levels of transcription of genes known to play an important role in early heart development. These investigations indicated that RhoA inhibition causes an accumulation of the cardiac transcription factors SRF and GATA4 and the early cardiac marker cardiac-cx-actin. The expression of a protein is controlled by, among other factors, regulatory proteins that control transcription. To investigate factors in heart that potentially regulate RhoA expression at the molecular level, the chick RhoA gene organisation was analysed. The gene was shown to contain three introns that interrupt the protein coding sequence and at least one intron in the 5'UTR. Comparative RhoA gene studies indicated both an almost identical organisation and coding sequence of the chick, mouse and human RhoA genes, indicative of strict conservation of this gene during evolution. The putative promoter region of RhoA was predicted by computer analyses and tested for promoter activity using luciferase reporter analyses in non-differentiated and differentiated cardiomyocytes, using the inducible P19CL6 cell system. These investigations served to define a putative core promoter region that exhibited significantly higher promoter activity in differentiated cardiomyocytes than in non-differentiated cells, and other elements upstream of this core region that appear to be required for transcriptional regulation of RhoA. The majority of the consensus transcription factor sites identified in this putative promoter have been previously implicated in either heart development and/or organogenesis. These results therefore provide further, although indirect, evidence for an important role for RhoA in the molecular mechanisms controlling both cardiogenesis and embryogenesis in general. In summary, this thesis provides novel information on the role of RhoA in the processes of cardiogenesis and provides a firm foundation for continuing investigations aimed at elucidating the molecular basis of this contribution.

RhoA

GTPase

gene expression

cardiogenesis

cardiomyogenesis

Osteogenic gene expression by human periodontal ligament cells under cyclic mechanical tension

Wescott, David Clark, n/a

January 2008

Background and objectives: The most widely accepted tooth movement model is defined by the pressure-tension hypothesis. An orthodontic force applied to a tooth generates areas of compression and tension in the periodontal ligament (PDL), which are transmitted to the alveolar bone. Areas of tissue exposed to tensile strain undergo bone deposition, whereas areas of tissue exposed to compressive strain undergo bone resorption. We propose that human PDL cells in monolayer culture exposed to tensile mechanical strain would express multiple genes involved in osteogenesis. Materials and Methods: Human PDL cells were isolated and cultured from premolar teeth that were extracted for orthodontic reasons. These cells were plated on control and experimental Uniflex[TM] plates. Using a Flexercell FX4000 strain unit, PDL cells on experimental plates were exposed to a 12% uni-axial cyclic strain for 6 seconds out of every 90 seconds over a 24 hour period. RNA was extracted from the PDL cells at 6 hours, 12 hours and 24 hours. The differential expression of 78 genes implicated in osteoblast differentiation and bone metabolism was analysed using real-time reverse transcriptase polymerase chain reaction (RT-PCR) array technology. Results: Of the 78 genes tested, sixteen genes showed statistically significant (p<0.05) changes in expression in response to the mechanical strain regime. Eight genes were up-regulated (ALPL, BMP2, BMP6, COL2A1, ICAM1, PHEX, SOX9, and VEGFA) and eight genes were down-regulated (ANXA5, BMP4, COL11A1, COL3A1, EGF, ITGB1, MSX and SMAD1). Conclusions: This study has demonstrated that cultured human PDL cells express multiple osteogenic genes under tensile strain, which suggests that PDL cells may have a potential role in osseous remodeling during tooth movement. Key Words: Tooth movement, human PDL cells, tensile mechanical strain, osteogenic genes, real-time RT-PCR array, and Flexercell FX4000.

gene expression

periodontal ligament

periodontium

molecular aspects