MicroRNAs Protect the Robustness of Distal Tip Cell Migrations from Temperature Changes in Caenorhabditis elegans: A Dissertation

Burke, Samantha L.

03 August 2015

MicroRNAs play an important role in protecting biological robustness during development. Biological robustness is the ability to maintain a consistent output despite variation in input, such as transcriptional noise or environmental stresses. Here, we show that the conserved microRNAs mir-34 and mir-83 promote the robust migration of the distal tip cells in Caenorhabditis elegans when stressed by changing environmental temperature. Our results show that distal tip cell migration is sensitive to temperature changes occurring within a two hour period during the first larval stage. mir-34 and mir-83 protect distal tip cell migration by regulating potential targets cdc-42, pat-3, and peb-1. cdc-42 and pat-3 are known components of the integrin signaling network controlling pathfinding during migration, while the involvement of peb-1 is a novel finding. Additionally, loss of the two microRNAs leads to a reduction in both fecundity and lifespan, suggesting that the loss of developmental robustness leads to a decrease in fitness. mir-34 and mir-83 are not only conserved in higher organisms, but duplicated. Both have been implicated as tumor suppressor genes in mammalian work. Our work has found a role for both microRNAs in integrin-regulated cell migrations that is potentially conserved in higher organisms. Additionally, our work supports the growing appreciation for the role of microRNAs in both stress response and promoting developmental robustness.

MicroRNAs

Caenorhabditis elegans

Cell Movement

Temperature

Dissertations, UMMS

Developmental Biology

Genetics and Genomics

Characterization of a new role for plakoglobin in suppressing epithelial cell translocation

Marsh, Randall Glenn

11 October 2001

No description available.

cell motility

plakoglobin

cadherin

TCF/LEF signaling

cell movement

cell translocation

Actin polymerization dynamics at the leading edge

Hu, Xiaohua

13 November 2012

Actin-based cell motility plays crucial role throughout the lifetime of an organism. While the dendritic nucleation model explains the initiation and organization of the actin network in lamellipodia, two questions need to be answered. In this study, I reconstructed cellular motility in vitro to investigate how actin filaments are organized to coordinate elongation and attachment to leading edge. Using total internal reflection fluorescence microscopy of actin filaments, we tested how profilin, Arp2/3, and capping protein (CP) function together to propel beads or thin glass nanofibers coated with N-WASP WCA domains. During sustained motility, physiological concentrations of Mg²⁺ generated actin filament bundles that processively attached to the nanofiber. Reduction of total Mg²⁺ abolished particle motility and actin attachment to the particle surface without affecting actin polymerization, Arp2/3 nucleation, filament capping, or actin shell formation. Addition of other types of crosslinkers restored both comet tail attachment and particle motility. We propose a model in which polycation-induced filament bundling sustains processive barbed end attachment to the leading edge. I lowered actin, profilin, Arp2/3, and CP concentrations to address the generation of actin filament orientation during the initiation of motility. In the absence of CP, Arp2/3 nucleates barbed ends that grow away from the nanofiber surface and branches remain stably attached to nanofiber. CP addition causes shedding of short branches and barbed end capture by the nanofiber. Barbed end retention by nanofibers is coupled with capping, indicating that WWCA and CP bind simultaneously to barbed ends. In pull-down assays, saturating CP addition only blocks WWCA binding to barbed end by half. Labeled WWCA bound to barbed ends with an affinity of 14 pM and unlabeled WWCA with an affinity of 75 pM. CP addition increased WWCA binding slightly at low CP concentrations and decreased WWCA binding to 50% at high CP concentrations. Molecular models of CP and WH2 domains bound respectively to the terminal and penultimate actin subunit showed no overlap and that CP orientation might blocks WWCA dissociation from the penultimate subunit. Simultaneous binding of CP and WWCA to barbed ends is essential to the establishment of filament orientation at the leading edge. / Ph. D.

Actin capping proteins

Actin-related protein 2-3 complex

Actin

Cell movement

Dystroglycan function is a novel determinant of tumor growth and behavior in prostate cancer

Mitchell, Andrew, Mathew, G., Jiang, T., Hamdy, F.C., Cross, S.S., Eaton, C., Winder, S.J.

January 2013

No / Dystroglycan is a ubiquitously expressed cell adhesion molecule frequently found to be altered or reduced in adenocarcinomas, however the mechanisms or consequences of dystroglycan loss have not been studied extensively. We examined the consequence of overexpression or RNAi depletion of dystroglycan on properties of in vitro growth migration and invasion of LNCaP, PC3, and DU145 prostate cancer cell lines. RESULTS: Using LNCaP cells we observed cell density-dependent changes in beta-dystroglycan with the appearance of several lower molecular weight species ranging in size from 43 to 26 kDa. The bands of 31 and 26 kDa were attributed to proteolysis, whereas bands between 43 and 38 kDa were a consequence of mis-glycosylation. The localization of beta-dystroglycan in LNCaP colonies in culture also varied, cells with a mesenchymal appearance at the periphery of the colony had more pronounced membrane localization of dystroglycan. Whereas some cells demonstrated nuclear dystroglycan. Increased dystroglycan levels were inhibitory to growth in soft agar but promoted Matrigel invasion, whereas reduced dystroglycan levels promoted growth in soft agar but inhibited invasion. Similar results were also obtained for PC3 and DU145 cells. This study suggests that changes in beta-dystroglycan distribution within the cell and/or the loss of dystroglycan during tumorigenesis, through a combination of proteolysis and altered glycosylation, leads to an increased ability to grow in an anchorage independent manner, however dystroglycan may need to be re-expressed for cell invasion and metastasis to occur.

Adenocarcinoma

Cell line

Cell movement

Dystroglycans

Humans

Male

Neoplasm invasiveness

Prostatic neoplasms

Tumor cells

Molecules involved in the regulation of enteric neural crest cell migration: 影響腸道神經脊細胞正常遷移的基因表達的研究. / 影響腸道神經脊細胞正常遷移的基因表達的研究 / Molecules involved in the regulation of enteric neural crest cell migration: Ying xiang chang dao shen jing ji xi bao zheng chang qian yi de ji yin biao da de yan jiu. / Ying xiang chang dao shen jing ji xi bao zheng chang qian yi de ji yin biao da de yan jiu

January 2014

腸神經系統(enteric nervous system, ENS)是由大量神經元和神經膠質細胞聚集而成的最複雜的周圍神經系統。這些腸道的神經元和神經膠質細胞來源于迷走神經脊和骶神經脊細胞，在胚胎發育過程中，這些神經脊細胞沿著腸道移動最終占滿整個腸道。儘管神經脊細胞的遷移對於腸道神經系統的形成及功能的正常發揮起到很重要的作用，然而影響神經脊細胞遷移的分子機制的研究卻相對較少。因此找出參與調控神經脊細胞遷移的基因對於更好的瞭解腸道神經脊系統的發育起到非常重要的作用，並且為治療腸道神經系統紊亂所導致的相關疾病提供治療靶點。 / 本研究論文是由兩部份實驗課題所組成來研究影響腸和調控道神經脊細胞遷移及腸道神經系統發育的相關基因。第一部份課題主要研究的是Semaphorin3A (Sema3A)對於骶神經脊細胞遷移的影響。本論文的研究發現Sema3A不僅被腸道內的上皮細胞所表達，腸道兩側的盆神經節周圍的間質細胞也表達Sema3A。同時Sema3A的受體neuropilin-1被骶神經脊細胞所表達。體外培養的實驗表明Sema3A能夠抑制骶神經脊細胞的遷移。另外，當表達Sema3A的腸道末端與骶神經脊細胞共同培養時，骶神經脊細胞的遷移同樣也受到抑制。這些研究結果表明由腸道末端的上皮細胞和腸道外圍的間質細胞所表達的Sema3A共同作用來調控骶神經脊細胞在停滯時期的遷移活動。 / 第二部份的研究課題主要研究的是轉錄因子Sox10以及其靶基因對於迷走神經脊細胞遷移的影響。Dominant megacolon (Dom)是一種攜帶有Sox10突變的巨結腸癥小鼠模型。本研究利用這種小鼠模型來發現突變鼠中可能影響迷走神經脊細胞遷移的基因。從迷走神經脊細胞體外培養發現： 由於Sox10突變，迷走神經脊細胞在體外培養24小時后，細胞遷移延遲，細胞的分化能力被改變，並且細胞死亡增加。利用基因芯片的方法比較了純和變異鼠迷走神經脊細胞和正常鼠迷走神經脊細胞的基因表達的差異。螢光素酶報告基因分析顯示，Sox10可以結合Lama4, Itga4和Gfra2的啟動子并激活它們的表達。 Sox10能與Gfra2啟動子上-116bp到-58bp之間序列的結合誘導Gfra2的表達。在純和變異鼠迷走神經脊細胞中，通過上調Gfra2信使RNA的表達，細胞死亡的數目大大下降，表明Gfra2作為Sox10的靶基因，對迷走神經脊細胞的存亡有著重要作用。 / 綜上所述，我們發現在骶神經脊細胞未進入腸道末端的這段停滯期內，Sema3A對於骶神經脊細胞的遷移起到抑制作用，Sema3A通過其表達在這段停滯期內的時空改變來調控骶神經脊細胞進入腸道。另外我們發現由於Sox10的突變，迷走神經脊細胞表現出非正常的遷移和基因表達的變化。作為Sox10的靶基因，Gfra2對於迷走神經脊細胞的死亡有重要的作用。 / The enteric nervous system (ENS) is the most complex part of the peripheral nervous system which is composed of a vast number of neurons and glial cells. The enteric neurons and glial cells arise from vagal and sacral neural crest cells (NCCs) which migrate along the gastrointestinal tract to colonize the whole gut during the embryonic development. The molecular mechanisms regulating the NCC migration are poorly characterized despite the importance of this migration process in the ENS formation. Therefore, identification and characterization of molecules involved in the modulation of NCC migration are essential to understand the ENS development and could provide potential therapeutic targets for the treatment of human ENS disorders. / The present study was aimed to identify and characterize the molecules involved in modulating the NCC migration during the ENS development, and was divided into two parts. The first part focused on semaphorin3A (Sema3A) signaling, Sema3A was found to be expressed in the hindgut epithelium and also the adjacent regions of pelvic ganglia, while its receptor, neuropilin-1, was expressed by sacral NCCs before sacral NCCs entered the hindgut. Sacral NCC migration and neuronal fiber extension in vitro were retarded in the culture medium containing Sema3A. When a hindgut segment expressing Sema3A was co-cultured with sacral NCCs, sacral NCC migration and neuronal fiber extension were also suppressed by the hindgut segment. These findings provide evidence for the repulsive activity of Sema3A before the entry of sacral NCCs to the hindgut. / The second part focused on the potential target genes of the transcription factor Sox10 which is expressed by migrating NCCs. A naturally occurring mouse mutant Dominant megacolon (Sox10Dom) which expresses a mutant Sox10 was used to identify candidate molecules which may possibly affect the NCC migration. After 24 hours in culture, vagal NCCs from Sox10Dom/Dom embryos showed retarded migration, abnormal cell differentiation and excessive cell death in vitro when compared to Sox10⁺/⁺ vagal NCCs. Results of microarray analyses revealed differentially expressed genes in Sox10Dom/Dom as compared to Sox10⁺/⁺ vagal NCCs after 24 hours in culture. Among these genes, Sox10 was able to bind to the promoter of Itga4, Lama4, and Gfra2 to induce their expression. Sox10 activated Gfra2 promoter by direct binding to the critical region located between -116bp and -58bp upstream of the Gfra2 transcription start site. Finally, re-expression of Gfra2 in Sox10Dom/Dom vagal NCCs resulted in decreased cell death, suggesting that down-regulation of Gfra2 in the mutant mice played an important role in early cell death of vagal NCCs. / In conclusion, before sacral NCCs entered into the hindgut, Sema3A inhibited the sacral NCC migration, and the spatiotemporal change of the Sema3A distribution regulated the entry of sacral NCCs into hindgut. Furthermore, retarded cell migration, abnormal cell differentiation, increased cell death and differential gene expression were found in Sox10Dom/Dom vagal NCCs as compared with those from Sox10⁺/⁺ embryos in vitro. The expression of Gfra2, a potential target gene of Sox10, promoted the cell viability of vagal NCCs. / Detailed summary in vernacular field only. / Detailed summary in vernacular field only. / Detailed summary in vernacular field only. / Detailed summary in vernacular field only. / Wang, Cuifang. / Thesis (Ph.D.) Chinese University of Hong Kong, 2014. / Includes bibliographical references (leaves 180-196). / Abstracts also in Chinese. / Wang, Cuifang.

Neural crest--Cytology

Neural crest--Molecular aspects

Cell migration

Neural Crest--cytology

Cell Movement--genetics

Molecular Biology

Developmental abnormalities in dominant megacolon mice.

January 2003

Tam Wing-yip. / Thesis (M.Phil.)--Chinese University of Hong Kong, 2003. / Includes bibliographical references (leaves 91-113). / Abstracts in English and Chinese. / Abstract --- p.i / Chinese Abstract --- p.iv / Acknowledgements --- p.vi / Table of Contents --- p.vii / Chapter Chapter 1 --- General Introduction --- p.1 / Chapter 1.1 --- Hirschsprung's disease --- p.1 / Chapter 1.2 --- Neural crest cells and enteric nervous system --- p.3 / Chapter 1.3 --- Genetics of Hirschsprun´gةs disease --- p.10 / Chapter 1.3.1 --- RET/GDNF/NTN signaling pathway --- p.10 / Chapter 1.3.2 --- EDNRB/EDN3/ECE-1 signaling pathway --- p.13 / Chapter 1.3.3 --- Dominant megacolon and Sox10 --- p.15 / Chapter 1.3.4 --- Other genes involved in intestinal aganglionosis --- p.16 / Chapter 1.4 --- Objectives of the present study --- p.19 / Chapter Chapter 2 --- Enteric Neural Crest Cells Migration in Dominant Megacolon Mouse Embryos --- p.21 / Chapter 2.1 --- Introduction --- p.21 / Chapter 2.2 --- Materials and Methods --- p.26 / Chapter 2.2.1 --- Animal --- p.26 / Chapter 2.2.2 --- Preparation of rat serum --- p.26 / Chapter 2.2.3 --- Isolation of embryos from pregnant mice --- p.27 / Chapter 2.2.4 --- Preparation of wheat germ agglutinin-gold (WGA-Au) --- p.28 / Chapter 2.2.5 --- Microinjection of WGA-Au conjugate --- p.28 / Chapter 2.2.6 --- Whole embryo culture --- p.29 / Chapter 2.2.7 --- Examination of cultured embryos --- p.30 / Chapter 2.2.8 --- Histological preparation of WGA-Au injected embryos --- p.30 / Chapter 2.2.9 --- Silver enhancement staining and histological examination of the sections --- p.31 / Chapter 2.2.10 --- Genotyping by polymerase chain reaction --- p.32 / Chapter 2.2.11 --- TUNEL assays --- p.33 / Chapter 2.3 --- Results --- p.35 / Chapter 2.3.1 --- In vivo development of Dominant megacolon mouse embryos of different genotypes --- p.35 / Chapter 2.3.2 --- In vitro development of embryos in control and experimental groups --- p.35 / Chapter 2.3.3 --- Migration of vagal neural crest cells in Dom embryos --- p.36 / Chapter 2.3.4 --- Apoptotic cells detection at the vagal region by TUNEL assay --- p.37 / Chapter 2.3.5 --- Migration of sacral neural crest cells in Dom embryos --- p.37 / Chapter 2.3.6 --- Apoptotic cells detection at the sacral region by TUNEL assay --- p.38 / Figures and Tables / Chapter 2.4 --- Discussion --- p.40 / Chapter 2.4.1 --- In vitro culture system supporting the normal development of mouse embryos --- p.40 / Chapter 2.4.2 --- WGA-Au as a cell marker for tracing the NCCs migration --- p.41 / Chapter 2.4.3 --- Vagal neural crest cells migration in Dom mouse embryos --- p.42 / Chapter 2.4.4 --- Apoptotic cell death does not contribute to the total aganglionosis in Dom homozygous embryos --- p.43 / Chapter 2.4.5 --- Sacral neural crest cells migration in Dom mouse embryos --- p.45 / Chapter 2.4.6 --- NCCs migration in zebrafish colourless mutant --- p.47 / Chapter 2.4.7 --- Limitation of the method used in this study --- p.49 / Chapter 2.4.8 --- Conclusions --- p.49 / Appendices / Chapter Chapter 3 --- Migration of Enteric Neural Crest-derived Cells in the Developing Gut of Dominant Megacolon Mouse Embryos --- p.51 / Chapter 3.1 --- Introduction --- p.51 / Chapter 3.2 --- Materials and Methods --- p.55 / Chapter 3.2.1 --- Isolation of the gut from Dom mouse embryos --- p.55 / Chapter 3.2.2 --- Whole mount immunohistochemistry --- p.55 / Chapter 3.3 --- Results --- p.57 / Chapter 3.3.1 --- PGP9.5 immunoreactivity in the 12.5 d.p.c. Dom embryos --- p.57 / Chapter 3.3.2 --- TH immunoreactivity in the 12.5 d.p.c. Dom embryos --- p.58 / Chapter 3.3.3 --- PGP9.5 immunoreactivity in the 14.5 d.p.c. Dom embryos --- p.59 / Figures and Tables / Chapter 3.4 --- Discussion --- p.61 / Chapter 3.4.1 --- The use of PGP9.5 and TH antibodies as markers for studying the migration of enteric neural crest-derived cells --- p.61 / Chapter 3.4.2 --- Incomplete migration of neural crest-derived cells within the gut of Dom heterozygous embryos --- p.62 / Chapter 3.4.3 --- Failure of sacral NCCs to invade the hindgut of Dom heterozygous embryos --- p.63 / Chapter 3.4.4 --- PGP9.5 and TH positive signals in the gut of Dom homozygous embryos --- p.64 / Chapter 3.4.5 --- Early differentiation of neural crest-derived cells into neurons due to haploinsufficiency of Sox10 --- p.65 / Chapter 3.4.6 --- Conclusions --- p.66 / Chapter Chapter 4 --- Localization of Interstitial Cells of Cajal in the Gut of Dominant Megacolon Mice --- p.67 / Chapter 4.1 --- Introduction --- p.67 / Chapter 4.2. --- Materials and Methods --- p.72 / Chapter 4.2.1 --- Isolation of the gut from mouse embryos and adult mice --- p.72 / Chapter 4.2.2 --- Cryosection and immunohistochemistry --- p.73 / Chapter 4.2.3 --- Whole-mount immunohistochemistry --- p.73 / Chapter 4.2.4 --- Total RNA extraction --- p.74 / Chapter 4.2.5 --- Reverse transcription for the first strand cDNA synthesis --- p.75 / Chapter 4.2.4 --- Reverse transcription-Polymerase chain reaction (RT-PCR) --- p.76 / Chapter 4.3 --- Results --- p.77 / Chapter 4.3.1 --- PGP9.5 and c-kit immunoreactivity in the Dom wild type colon --- p.77 / Chapter 4.3.2 --- c-kit immunoreactivity in the Dom heterozygous adult colon --- p.78 / Chapter 4.3.3 --- c-kit and SCF expression during gut development --- p.78 / Figures and Tables / Chapter 4.4 --- Discussion --- p.80 / Chapter 4.4.1 --- The importance in studying the development of ICCs in aganglionic gut --- p.80 / Chapter 4.4.2 --- ICCs development in Dominant megacolon mice --- p.81 / Chapter 4.4.3 --- The relationship between enteric neurons and ICCs development --- p.83 / Chapter 4.4.4 --- Advantages of using confocal microscopy and whole- mount preparations to study the ICCs development --- p.85 / Chapter 4.4.5 --- Conclusions --- p.86 / Chapter Chapter 5 --- General Discussion and Conclusions --- p.87 / References --- p.91

Neural Crest

Intestines--cytology

Neural Pathways

Cell Movement

Synaptic Transmission

Neurons--cytology

Hirschsprung Disease--embryology

Hirschsprung Disease--etiology

Migration of mouse sacral neural crest cells.

January 2006

Dong Ming. / Thesis submitted in: December 2005. / Thesis (M.Phil.)--Chinese University of Hong Kong, 2006. / Includes bibliographical references (leaves 118-152). / Abstracts in English and Chinese. / Abstract (English) --- p.i / Abstract (Chinese) --- p.iii / Acknowledgement --- p.iv / Table of Contents --- p.v / Abbreviation list --- p.xi / Chapter Chapter 1 --- General introduction / Chapter 1.1 --- Preamble --- p.1 / Chapter 1.2 --- Neural Crest Cells (NCCs) --- p.2 / Chapter 1.3 --- Enteric Nervous System (ENS) and Vagal Neural Crest Cells (Vagal NCCs) --- p.4 / Chapter 1.4 --- Sacral Neural Crest Cells (Sacral NCCs) --- p.7 / Chapter 1.5 --- Signalling Mechanisms of Sacral Neural Crest Cells --- p.17 / Chapter 1.6 --- Hirschsprung's Disease (HSCR) --- p.20 / Chapter 1.7 --- Objective of the Study and Contents of the Following Chapters --- p.21 / Chapter Chapter 2 --- Migration from the dorsal neural tube to the pelvic mesenchyme / Chapter 2.1 --- Introduction --- p.24 / Chapter 2.2 --- Materials and Methods --- p.32 / Chapter 2.2.1 --- Animal --- p.32 / Chapter 2.2.2 --- Isolation of embryos from pregnant mice at E9.5 to --- p.32 / Chapter 2.2.3 --- Histological preparation of the caudal segments --- p.33 / Chapter 2.2.4 --- p75 immunohistochemical staining --- p.33 / Chapter 2.2.5 --- Preparation of rat serum --- p.34 / Chapter 2.2.6 --- Preparation of the culture medium --- p.34 / Chapter 2.2.7 --- Preparation of wheat germ agglutinin-gold conjugates (WGA-Au) --- p.35 / Chapter 2.2.8 --- Preparation of CMFDA --- p.35 / Chapter 2.2.9 --- Preparation of DiI --- p.36 / Chapter 2.2.10 --- "Microinjection of WGA-Au, DiI and CMFDA" --- p.36 / Chapter 2.2.11 --- Whole embryo culture --- p.37 / Chapter 2.2.12 --- Examination of cultured embryos --- p.37 / Chapter 2.2.13 --- Histological preparation of WGA-Au labelled embryos --- p.38 / Chapter 2.2.14 --- Silver enhancement staining of the sections of WGA-Au labelled embryos --- p.39 / Chapter 2.2.15 --- Cryosectioning of the embryos labelled with DiI --- p.39 / Chapter 2.2.16 --- p75 immunohistochemical staining of DiI-labelled cells --- p.40 / Chapter 2.3 --- Results --- p.41 / Chapter 2.3.1 --- Observations on embryos developed in vivo --- p.41 / Chapter 2.3.2 --- Closed yolk sac culture vs open yolk sac culture --- p.42 / Chapter 2.3.3 --- Neural crest cell labelling in the caudal part of embryos --- p.43 / Chapter 2.3.4 --- Neural crest cell labelling with DiI in the caudal part of the neural tube followed by in vitro culture from E9.5 to E11.0 --- p.45 / Chapter 2.3.5 --- Neural crest labelling with DiI in the caudal part of the neural tube followed by in vitro culture from E10.5 to E11.5 --- p.46 / Chapter 2.3.6 --- Focal labelling at the levels of the 26th and 29th somites followed by in vitro culture --- p.48 / Chapter 2.3.7 --- p75 immunohistochemical staining on the caudal part of the embryo at E10.5 --- p.49 / Chapter 2.3.8 --- p75 immunohistochemical staining on embryos labelled with DiI --- p.50 / Chapter 2.4 --- Discussion --- p.51 / Chapter 2.4.1 --- Embryos at E9.5 cultured with an intact yolk sac membrane grew better than those with the yolk sac membrane cut open --- p.52 / Chapter 2.4.2 --- Migration at the levels of the 24th to 28th somite --- p.53 / Chapter 2.4.3 --- Migration at the levels of the 29th to 33th somite --- p.58 / Chapter 2.4.4 --- Sacral NCCs migrate along a straight dorsolateral pathway --- p.60 / Chapter 2.4.5 --- "Most of the DiI positive cells are p75 positive, but not all of the p75 positive cells are DiI positive" --- p.62 / Chapter Chapter 3 --- Migration from the pelvic mesenchyme to the hindgut / Chapter 3.1 --- Introduction --- p.65 / Chapter 3.2 --- Materials and Methods --- p.73 / Chapter 3.2.1 --- Isolation of hindguts with or without adjacent tissues from embryos at E10.5 to E13.5 --- p.73 / Chapter 3.2.2 --- Microinjection of DiI into the pelvic mesenchymal tissue of the h indguts --- p.74 / Chapter 3.2.3 --- Preparation of the culture medium --- p.74 / Chapter 3.2.4 --- Preparation of the culture dish --- p.74 / Chapter 3.2.5 --- Gut culture --- p.75 / Chapter 3.2.6 --- Cryosections of the hindguts after in vitro culture --- p.75 / Chapter 3.3 --- Results --- p.76 / Chapter 3.3.1 --- "Hindguts isolated from embryos at E10.5, E11.5, E12.5 and E14.5" --- p.76 / Chapter 3.3.2 --- p75 immunohistochemical staining of the serial sections through the caudal part of the embryos --- p.78 / Chapter 3.3.3 --- Observations on hindgut without pelvic plexus cultured from E11.5 to E14.5 --- p.81 / Chapter 3.3.4 --- "Culture of hindguts with pelvic mesenchyme cultured from E11.5 to E14.25, E14.5 and E15.5" --- p.82 / Chapter 3.3.5 --- Culture of the whole length of the gut tube without pelvic mesenchyme from E11.5 to E15.5 --- p.84 / Chapter 3.3.6 --- Culture of the whole length of the gut tube with pelvic mesenchyme from E11.5 to E15.5 --- p.84 / Chapter 3.3.7 --- "Culture of hindguts with Dil labelling in the pelvic mesenchyme from E11.5 to E14.0, E14.2 5, E14.5 and" --- p.85 / Chapter 3.3.8 --- Culture of the whole length of the gut tube with DiI labelling in the pelvic mesenchyme from E11.5 to E14.5 --- p.86 / Chapter 3.4 --- Discussion --- p.88 / Chapter 3.4.1 --- Development of the hindgut and the urogenital system from E10.5 to E14.5 --- p.88 / Chapter 3.4.2 --- No p75 positive cells were found in the hindgut before E13.5 --- p.89 / Chapter 3.4.3 --- The sacral neural crest cells migrate into the hindgut at around E14.5 --- p.91 / Chapter 3.4.4 --- "The sacral neural crest cells migrated in the serosa, and entered the myenteric plexus prior to populating the submucosal plexus" --- p.95 / Chapter 3.4.5 --- Most of DiI labelled sacral neural crest cells in the hindgut also expressed p75 --- p.98 / Chapter Chapter 4 --- Migration from the neural tube to the hindgut / Chapter 4.1 --- Introduction --- p.101 / Chapter 4.2 --- Materials and Methods --- p.104 / Chapter 4.3 --- Results --- p.106 / Chapter 4.3.1 --- Morphology observations on the hindguts isolated from DiI-labelled embryos --- p.106 / Chapter 4.3.2 --- Distribution of the DiI-labelled cells and p75 positive cells before the culture of the hindgut explant --- p.106 / Chapter 4.3.3 --- Culture of hindgut explanted from Dil-labelled embyos for 3.5 days from E11.0 to E14.5 --- p.107 / Chapter 4.4 --- Discussion --- p.109 / Chapter Chapter 5 --- General discussion and conclusions --- p.113 / References --- p.118 / Figures and Legends --- p.153 / Tables and Graphs --- p.203 / Appendix --- p.209

Neural crest

Cell migration

Mice--Embryology

Neural Crest

Cell Movement

Nervous System--embryology

Nervous System--growth & development

Mice--embryology

Modulation of sacral neural crest cell migration in the hindgut of mouse embryos by interactions with nerve fibers, vagal neural crest cells and molecules within the gut microenvironment. / 迷走源性神經脊細胞, 神經纖維和腸內微環境對小鼠骶源性神經脊細胞遷移的作用 / Mi zou yuan xing shen jing ji xi bao, shen jing xian wei he chang nei wei huan jing dui xiao shu di yuan xing shen jing ji xi bao qian yi de zuo yong

January 2012

人類先天性巨結腸症（HSCR）主要表現為結腸末端的神經節缺失或稀少。 結腸末端的神經節來源於迷走源性神經脊細胞和骶源性神經脊細胞。迷走源性神經脊細胞是腸神經系統的主要來源，已被廣泛研究，而關於哺乳類包括人類的骶源性神經脊細胞的研究卻相當稀少。小鼠胚胎的骶源性神經脊細胞遷移途徑近期已被闡釋，其由神經管背側遷出並向腹側移動，於後腸附近聚集成旁神經節然後進入腸內。本研究運用一系列實驗鑒定了對小鼠骶源性神經脊細胞由旁神經節遷移至腸內過程有影響作用的因素。 / 研究發現骶源性神經脊細胞是沿著神經纖維並向口端方向遷移進腸內，同時由於迷走源性神經脊細胞於腸內向尾端遷移，它們在後腸末端相遇並相互作用，我們首先研究了這種相互作用以瞭解迷走源性神經脊細胞如何影響骶源性神經脊細胞的遷移。利用帶綠色螢光的小鼠骶源性神經脊細胞和可變螢光的小鼠迷走源性神經脊細胞（鐳射激發下由綠色變為紅色），以及鐳射共聚焦顯微鏡活細胞成像術，我們觀察了這兩種細胞在腸內相遇時的行為。當骶源性神經脊細胞和迷走源性神經脊細胞在神經纖維上相遇是，它們都停止了移動，不能前行。培養3天以後，骶源性神經脊細胞和迷走源性神經脊細胞在後腸中共同形成了神經細胞網路，其中骶源性神經脊細胞相對只占了小部分細胞。 / 由於骶源性神經脊細胞沿著由旁神經節發出的神經纖維遷移至腸內並且當在神經纖維上遇到迷走性源性神經脊細胞時便停止移動，我們進而研究了神經纖維在骶源性神經脊細胞遷移中的地位。活細胞成像術和免疫組化實驗表明旁神經節發出的神經纖維對骶源性神經脊細胞的遷移是非常重要的，它有助於細胞遷移同時，但當細胞到達纖維末端時它便也限制了細胞的遷移。儘管如此，體外實驗表明在一定培養條件下，骶源性神經脊細胞的遷移並不需要這些神經纖維。 / 由於有報導表明腸內微環境能影響腸神經脊細胞的遷移，我們利用2D電泳和質譜檢測了12.5天（骶源性神經脊細胞進入後腸之前）和13.5天（骶源性神經脊細胞進入後腸）胎鼠後腸中的蛋白表達情況。大多數鑒定到有差異表達的蛋白都與蛋白折疊、細胞生長和細胞骨架組織有關。我們選取了與細胞粘附和肌肉收縮有關的鈣離子依賴膜結合蛋白Anxa6，並結合腸內的平滑肌發育進行了進一步的研究。結果顯示在13.5天胎鼠中，旁神經節的口端方向有一段約600微米的腸的腹側的平滑肌還沒有發育，可能與腸神經脊細胞的遷移有關。但腸內平滑肌發育是否及如何影響腸神經脊細胞的遷移還需要進一步的研究。 / 綜上所述，骶源性神經脊細胞的遷移是一個複雜的過程，迷走源性神經脊細胞，神經纖維和腸內微環境都參與並能影響這個遷移過程。 / Hirschsprung’s disease (HSCR) in humans is characterized by the absence or reduction of enteric ganglia in the distal part of the colon. It is known that all enteric ganglia in the distal colon originate from neural crest cells (NCCs) at both vagal and sacral levels during embryonic development. Vagal NCCs have been well characterized as the main cellular source of the enteric nervous system (ENS), but however, information on the mammalian, including human, sacral NCCs is still scarce. Sacral NCCs in mouse embryos have been recently identified to be able to migrate from the dorsal neural tube to the mesenchyme, aggregate as pelvic ganglia adjacent to the hindgut and then enter the distal hindgut. In the present study, a series of experiments were performed to determine the factors that were involved in modulating their entry to the hindgut and their migration within the distal hindgut, using mouse embryos. / Having entered the hindgut, sacral NCCs migrated along nerve fibers in a caudal-to-rostral direction while vagal NCCs were colonizing the hindgut in a reverse, rostral-to-caudal direction. The migratory behaviors of the vagal and sacral NCCs were examined at the time when these two populations of NCCs met each other with live cell confocal imaging in the distal hindgut using GFP-expressing sacral NCCs (green fluorescent) and Ednrb-Kikume labeled vagal NCCs (red fluorescent) from transgenic mice. The rostral migration of sacral NCCs was observed to be temporarily affected when they met vagal NCCs on the nerve fiber. However, after 3 days in organotypic culture, sacral and vagal NCCs were found to intermingle with each other to form an interconnected cellular network in the hindgut with much greater cellular contribution from vagal NCCs than sacral NCCs. Hence, vagal NCCs were able to affect the migration and thus the final location of sacral NCCs within the hindgut. / Since sacral NCCs have been observed to enter the hindgut by migrating on the nerve fibers extending from pelvic ganglia, the role the nerve fibers in migration was then examined. Results obtained from time-lapse confocal live cell imaging and immunohistochemical localization indicated that nerve fibers extending from pelvic ganglia were very important for sacral NCCs migration. It was found that these nerve fibers could both assist in sacral NCC migration and also restrain their migration once the cells reached the distal tip of the fibers. However, under specific in vitro conditions, sacral NCCs were still able to migrate without the presence of nerve fibers. / The gut microenvironment surrounding the migrating NCCs has also been reported to affect NCCs migration. Therefore, protein molecules with differential expression levels prior to and after the entry of sacral NCCs to the distal hindgut between E12.5 to E13.5 were examined with 2-dimensional gel electrophoresis and mass spectrometry. The proteins identified with significant changes of expression (more than 1.5 folds) were grouped according to their predicted biological functions and involved in protein folding, cell growth and cytoskeletal organization. Among them, Anxa6, a calcium-dependent membrane binding protein related to cell adhesion and muscle contraction, was further examined for its relationship with the muscle development in the hindgut at E12.5 to E14.5. The results showed that a segment of the hindgut (about 600μm) rostral to pelvic ganglia exhibited an incomplete layer of smooth muscle at E13.5. Whether Anxa6 and the smooth muscle are involved in the sacral NCC migration is worth further investigations. / In summary, sacral NCCs migration is a complex process regulated by their interactions with nerve fibers, vagal neural crest cells and possibly molecules in the hindgut microenvironment through which they migrate. / Detailed summary in vernacular field only. / Detailed summary in vernacular field only. / Detailed summary in vernacular field only. / Detailed summary in vernacular field only. / Detailed summary in vernacular field only. / Chen, Jielin. / Thesis (Ph.D.)--Chinese University of Hong Kong, 2012. / Includes bibliographical references (leaves 201-214). / Abstract also in Chinese. / Abstract --- p.I / 摘要 --- p.IV / Acknowledgements --- p.VI / Table of contents --- p.XII / Abbreviation --- p.XIII / Chapter Chapter 1 --- General Introduction --- p.1 / Chapter 1.1 --- The enteric nervous system (ENS) --- p.1 / Chapter 1.1.1 --- Embryonic origin and development of the ENS --- p.2 / Chapter 1.1.2 --- Hirschsprung’s disease (HSCR) --- p.5 / Chapter 1.2 --- Enteric neural crest cells (ENCCs) --- p.7 / Chapter 1.2.1 --- Vagal neural crest cells (NCCs) --- p.8 / Chapter 1.2.2 --- Sacral neural crest cells (NCCs) and pelvic ganglia --- p.10 / Chapter 1.2.3 --- Interactions between neural crest cells (NCCs) --- p.14 / Chapter 1.3 --- Microenvironment within the gut --- p.16 / Chapter 1.3.1 --- Effect of molecules on ENCCs migration --- p.16 / Chapter 1.3.2 --- Effect of tissue age on ENCC migration --- p.19 / Chapter 1.3.3 --- Absence of ENCCs facilitates ENCC colonization --- p.20 / Chapter 1.4 --- Objectives of the present study --- p.22 / Chapter Figures and Legends --- p.25 / Chapter Chapter 2 --- Migratory behaviors of sacral and vagal neural crest cells in the distal hindgut --- p.32 / Chapter 2.1 --- Introduction --- p.32 / Chapter 2.2 --- Materials and methods --- p.36 / Chapter 2.2.1 --- Mouse strains --- p.36 / Chapter 2.2.2 --- Isolation of gut tubes and pelvic ganglia --- p.36 / Chapter 2.2.3 --- Photo-conversion of Ednrb-kikume labeled neural crest cells within the gut --- p.37 / Chapter 2.2.4 --- Preparation of general culture medium and organ culture agarose gel --- p.38 / Chapter 2.2.5 --- Organotypic culture --- p.39 / Chapter 2.2.6 --- Time-lapse live cell confocal microscopic imaging --- p.39 / Chapter 2.2.7 --- Whole mount gut preparations for immunohistochemical staining --- p.41 / Chapter 2.3 --- Results --- p.42 / Chapter 2.3.1 --- Conversion of green fluorescent, Ednrb-kikume labeled vagal NCCs into red fluorescent --- p.42 / Chapter 2.3.2 --- Ednrb-kikume labeled cells were Sox10 immunorecative --- p.42 / Chapter 2.3.3 --- No discernible photo-toxicity after photo-conversion --- p.43 / Chapter 2.3.4 --- Sacral NCCs migration was hindered by vagal NCCs when they met on the nerve fiber --- p.43 / Chapter 2.3.5 --- Vagal NCCs migrated toward each other to form an interconnected network --- p.45 / Chapter 2.3.6 --- Sacral NCCs contributed much fewer cells than vagal NCCs in the terminal hindgut --- p.46 / Chapter 2.4 --- Discussion --- p.47 / Chapter 2.4.1 --- Ednrb-kikume mouse is a potentially ideal animal model for studies of NCCs migratory behaviors --- p.47 / Chapter 2.4.2 --- Migration of sacral NCCs in the hindgut was affected by vagal NCCs --- p.49 / Chapter 2.4.3 --- Migratory behaviors of vagal NCCs --- p.52 / Chapter 2.4.4 --- Vagal NCCs potentially preferred to move on nerve fibers --- p.53 / Chapter 2.4.5 --- Sacral NCCs contributed much less to the cellular network than vagal NCCs --- p.53 / Chapter 2.5 --- Summary --- p.55 / Chapter Table 2-1 --- Primary and secondary antibodies used in the experiments --- p.56 / Chapter Figures and Legends --- p.57 / Chapter Chapter 3 --- The relationship between nerve fiber extension and sacral neural crest cell migration in vitro --- p.81 / Chapter 3.1 --- Introduction --- p.81 / Chapter 3.2 --- Materials and methods --- p.86 / Chapter 3.2.1 --- Mouse strains --- p.86 / Chapter 3.2.2 --- Preparation of fibronectin (FN) coated coverslips and confocal dishes --- p.86 / Chapter 3.2.3 --- Preparation of media --- p.87 / Chapter 3.2.4 --- Isolation of pelvic ganglia --- p.87 / Chapter 3.2.5 --- In vitro culture of pelvic ganglia in 4-well plates or confocal dishes --- p.88 / Chapter 3.2.6 --- Live cell imaging using Nikon live cell imaging system --- p.88 / Chapter 3.2.7 --- WGA treatments on the pelvic ganglia culture --- p.89 / Chapter 3.2.8 --- Effect of embryonic cell proliferation medium and stem cell proliferation medium on pelvic ganglia growth in vitro --- p.90 / Chapter 3.2.9 --- Immunohistochemical staining --- p.90 / Chapter 3.3 --- Results --- p.92 / Chapter 3.3.1 --- Sacral NCCs and nerve fibers from the pelvic ganglia were in close association in vitro --- p.92 / Chapter 3.3.2 --- Migratory behaviors of sacral NCCs on the nerve fiber in vitro --- p.92 / Chapter 3.3.3 --- WGA treatments affected the growth of nerve fibers and sacral NCCs migration in vitro --- p.93 / Chapter 3.3.4 --- Sacral NCCs migrated without nerve fibers when cultured in proliferation media --- p.95 / Chapter 3.4 --- Discussion --- p.97 / Chapter 3.4.1 --- In vitro culture of pelvic ganglion --- p.97 / Chapter 3.4.2 --- Migratory behaviors of sacral NCCs in vitro --- p.98 / Chapter 3.4.3 --- Sacral NCCs migration was affected by the extension of nerve fibers from pelvic ganglia in vitro --- p.101 / Chapter 3.4.4 --- Nerve fibers from the pelvic ganglia were not necessary for sacral NCCs migration in vitro --- p.103 / Chapter 3.5 --- Summary --- p.106 / Chapter Figures and Legends --- p.107 / Chapter Chapter 4 --- Differentially expressed protein molecules in the distal hindgut before and after the entry of sacral neural crest cells --- p.128 / Chapter 4.1 --- Introduction --- p.128 / Chapter 4.2 --- Materials and methods --- p.132 / Chapter 4.2.1 --- Mouse strain --- p.132 / Chapter 4.2.2 --- Preparation of solutions for 2-dimensional (2D) gel electrophoresis --- p.132 / Chapter 4.2.3 --- Preparation of solutions for mass spectrometry --- p.133 / Chapter 4.2.4 --- Isolation of the distal hindgut and protein extraction --- p.133 / Chapter 4.2.5 --- Measurement of protein concentration --- p.134 / Chapter 4.2.6 --- 2D gel electrophoresis --- p.135 / Chapter 4.2.7 --- Mass spectrometry --- p.138 / Chapter 4.2.8 --- SDS-PAGE and Western blot --- p.139 / Chapter 4.2.9 --- Immunohistochemical staining of gut tubes and embryos --- p.140 / Chapter 4.2.10 --- Distal hindgut model reconstruction --- p.141 / Chapter 4.3 --- Results --- p.143 / Chapter 4.3.1 --- E13.5 was the critical stage at which sacral NCCs started to enter the hindgut --- p.143 / Chapter 4.3.2 --- Protein molecules identified by 2D electrophoresis and mass spectrometry --- p.144 / Chapter 4.3.3 --- Western blot analysis and immunostaining confirmed expression levels of Anxa6 --- p.145 / Chapter 4.3.4 --- Smooth muscle actin (SMA) and Anxa6 partially co-localized within the E13.5 hindgut --- p.146 / Chapter 4.3.5 --- Expression of SMA and Anxa6 before and after sacral NCC entry to the distal hindgut --- p.146 / Chapter 4.3.6 --- Reconstruction of distal hindgut images from serial sections with SMA and Anxa6 immunoreactivities --- p.147 / Chapter 4.4 --- Discussion --- p.149 / Chapter 4.4.1 --- Tissue age affected enteric NCC colonization --- p.149 / Chapter 4.4.2 --- Proteomics used in modern biological research --- p.150 / Chapter 4.4.3 --- Molecules differentially expressed in the distal hindgut at E12.5 and E13.5 --- p.151 / Chapter 4.4.4 --- Anxa6 and SMA expression in the distal hindgut --- p.153 / Chapter 4.4.5 --- The role of the smooth muscle development in sacral NCC entry into the hindgut --- p.155 / Chapter 4.5 --- Summary --- p.157 / Chapter Table 4-1 --- Identification of proteins by MALDI-TOF analysis and the MASCOT search program --- p.158 / Chapter Table 4-2 --- Differentially expressed proteins identified by 2-D electro-phoresis and MALDI-TOF/TOF and their predicted biological functions --- p.159 / Figures and Legends --- p.160 / Chapter Chapter 5 --- Conclusions and discussion --- p.182 / Chapter 5.1 --- Vagal NCCs hindered sacral NCC migration when they coalesced on the nerve fiber --- p.182 / Chapter 5.2 --- Nerve fibers from pelvic ganglia were important but not necessary for sacral NCCs migration in vitro --- p.186 / Chapter 5.3 --- Possible involvement of smooth muscle development in modulating sacral NCCs migration --- p.189 / Chapter 5.4 --- Future prospects --- p.191 / Chapter 5.4.1 --- Interactions of vagal and sacral NCCs within the hindgut of mouse embryos --- p.191 / Chapter 5.4.2 --- Role of nerve fibers for sacral NCCs migration ex vivo --- p.192 / Chapter 5.4.3 --- Role of Anxa6 in muscle development of the gut and NCCs migration --- p.193 / Chapter Appendix I --- Solutions used in 2-D electrophoresis --- p.195 / Chapter Appendix II --- Solutions for Colloidal Coomassie staining --- p.198 / Chapter Appendix III --- Procedures for embryo processing --- p.199 / Chapter Appendix IV --- Other solutions --- p.200 / References --- p.201

Neural crest

Cell migration

Mice--Embryology

Neural Crest

Cell Movement

Nervous System--embryology

Nervous System--growth & development

Mice--embryology

Migration of neural crest cells in normal ICR mouse and mutant dominant megacolon mouse embryos.

January 2001

Mok Wing Fai Simon. / Thesis (M.Phil.)--Chinese University of Hong Kong, 2001. / Includes bibliographical references (leaves 91-97). / Abstracts in English and Chinese. / Abstract (English) --- p.i / Abstract (Chinese) --- p.iii / Acknowledgements --- p.iv / Table of content --- p.v / List of Figures --- p.viii / List of Tables --- p.x / Chapter CHAPTER ONE: --- INTRODUCTION / Chapter 1.1 --- Origin of the Neural Crest Cells / Chapter 1.1.1 --- Formation of the Neural Tube --- p.1 / Chapter 1.1.2 --- The Neural Crest cells and the Vagal Neural Crest Cells --- p.2 / Chapter 1.1.3 --- The migration profiles of Neural Crest Cells Originated from the Axial level other than Vagal Neural Crest --- p.4 / Chapter 1.1.4 --- Development of the Gastrointestinal Tract and the Enteric Nervous System --- p.5 / Chapter CHAPTER TWO: --- MIGRATION OF NEURAL CREST CELLS IN NORMAL ICR AND DOM MUTANT MOUSE EMBRYOS / Chapter 2.1 --- Introduction --- p.27 / Chapter 2.2 --- Materials / Chapter 2.2.1 --- Pregnant mice --- p.39 / Chapter 2.2.2 --- The Handling Medium --- p.39 / Chapter 2.2.3 --- The Culture Medium --- p.40 / Chapter 2.2.4 --- Preparation of Wheat Germ Agglutinin-Gold Conjugates (WGA-Au) --- p.42 / Chapter 2.2.5 --- "Preparation of 1,´1ة-dioctadecyl-´3ة 3,3 '3,3 226}0ة-tetramethyl indocarbocyanine perchlorate (Di-I) " --- p.43 / Chapter 2.2.6 --- Preparation of Carnoýةs Solution --- p.43 / Chapter 2.2.7 --- Preparation of Paraformaldehyde --- p.43 / Chapter 2.2.8 --- Pregnont Dominant Megacolon (Dom) Mice --- p.44 / Chapter 2.2.9 --- DNA Extraction for Genotyping of Dom Embryos --- p.45 / Chapter 2.2.10 --- Primers Used in PCR for Genotyping of Dom Embryos --- p.45 / Chapter 2.2.11 --- PCR Reagent System --- p.46 / Chapter 2.2.12 --- 10XTBE --- p.46 / Chapter 2.3 --- Methods / Chapter 2.3.1 --- Isolation of Embryos from Pregnant Mice --- p.47 / Chapter 2.3.2 --- In situ labeling of exogenous dye --- p.48 / Chapter 2.3.3 --- Whole Embryo Culture --- p.49 / Chapter 2.3.4 --- Morphological Examination of Cultured Embryos --- p.49 / Chapter 2.3.5 --- Histological Examination of Cultured embryos --- p.50 / Chapter 2.3.6 --- Genotyping of Dom F1 Generation --- p.51 / Chapter 2.3.7 --- Genotyping of Dom Embryos by PCR --- p.52 / Chapter 2.3.8 --- Gel Electrophoresis --- p.52 / Chapter 2.3.9 --- Counting of WGA-Au Labelled Cells --- p.53 / Chapter 2.4 --- Results / Chapter 2.4.1 --- Genotyping --- p.54 / Chapter 2.4.2 --- Examination on Gross morphology of Control and Experimental Embryos --- p.54 / Chapter 2.4.3 --- Morphological Examination of DOM Mutant Embryo after culture --- p.57 / Chapter 2.4.4 --- Initial Stage of Vagal and Trunk Neural Crest Cells Migration in Mouse Embryos --- p.62 / Chapter 2.4.5 --- Initial Stage of Vagal and Trunk Neural Crest Cells Migration in DOM Embryos --- p.64 / Chapter 2.4.6 --- Distribution of Labelled Cells in ICR Embryos after WGA-Au Labelling --- p.65 / Chapter 2.4.7 --- Distribution of WGA-Au Labelled Cells in DOM Embryos --- p.69 / Chapter CHAPTER THREE: --- DISCUSSION / Chapter 3.1 --- Development of embryos in vitro --- p.78 / Chapter 3.2 --- Comparison of the Two Exogenous Dyes --- p.80 / Chapter 3.3 --- Migration Pathway of the Vagal and Trunk Neural Crest Cells --- p.81 / Chapter 3.4 --- Counting of Labelled Cells in DOM Embryos --- p.83 / Chapter 3.5 --- Initial Stage of Vagal and Trunk Neural Crest Cells Migration of Different Genotypes of the DOM Embryos --- p.84 / Chapter 3.6 --- Differences in Distribution of WGA-Au Labelled Cells in Different Genotypes of DOM Embryos --- p.85 / Chapter CHAPTER FOUR: --- CONCLUSION --- p.88 / REFERENCES --- p.91 / "FIGURES, LEGEND TABLE AND APPENDIX"

Neural Crest

Cell Movement

Nervous System--embryology

Nervous System--growth & development

Mice, Inbred ICR--embryology

Mice, Neurologic Mutants--embryology

Efeitos da terapia com laser baixa potência em melanoma: ensaios in vitro / Efects of low level laser therapy on melanoma an in vitro study

Santos, Antonio José da Silva

14 December 2012

Embora a terapia com uso de laser de baixa potência (TLBP) seja uma modalidade terapêutica amplamente estudada no meio científico, sua aplicação na clínica médica ainda gera controvérsias, já que a literatura reporta que a TLBP é capaz de promover a proliferação e diferenciação de células tumorais. O objetivo deste estudo foi avaliar os efeitos da TLBP no crescimento celular usando como modelo a linhagem B16F10 de melanoma murino em estado de homeostase e estado redox, além de verificar o comportamento quimiotáxico da linhagem B16F10 por meio do ensaio de migração transwell em resposta à TLBP em diferentes densidades de energia. Foram montados cinco grupos experimentais utilizando um laser de emissão vermelha em λ = 660 nm: Grupo controle (GC) onde nenhuma irradiação foi realizada; G30 (30J/cm2); G60 (60J/cm2); G90 (90J/cm2); G120 (120J/cm2); G150 (150J/cm2), com as respectivas doses utilizadas. Todos os experimentos foram realizados em triplicata e os resultados obtidos foram submetidos à análise estatística. Sob as condições experimentais deste estudo, nossos resultados mostram que a TLBP neste comprimento de onda não promoveu mudanças no metabolismo celular nos tempos de 48 h e 72 h, independente do estado nutricional. Foi possível observar mudança no padrão de comportamento quimiotáxico da linhagem celular B16F10 irradiadas com laser de emissão vermelha. / The low power lasers (TLBP) is a therapeutic modality widely studied in scientific field, its application in clinical medicine still generates many conflicts since literature reports proliferation in cancer cells. The objective of this study was to evaluate the effects of TLBP on cell growth using as model the line B16F10 in state of homeostasis and redox state and investigate the chemotactic behavior of B16F10 lineage through transwell migration assay in response to TLBP in different energy densities. For this purpose five experimental groups were assembled using a laser emission at λ = 660 nm: control group (G0) where no irradiation was performed; G30 (30J/cm2), G60 (60J/cm2), G90 (90J/cm2); G120 (120J/cm2); G150 (150J/cm2) with the respective doses used. All experiments were performed in triplicate and the results were statistically analyzed. Under the experimental conditions of this study, our results show that TLBP did not induced changes in cellular metabolism that influence proliferation at 48 h and 72 h, independent nutritional status. It was possible to observe changes in behavior pattern chemotactic of cell line B16F10 with TLBP at red emission.

cell movement

cell survival

low-level laser therapy

melanoma

melanoma

migração celular

terapia a laser de baixa intensidade

viabilidade celular