Comparative study of the effects of fetal bovine serum versus horse serum on growth and differentiation of primary equine bronchial fibroblasts

Franke, Jana, Abs, Vanessa, Zizzadoro, Claudia, Abraham, Getu

January 2014

Background: Airway fibroblasts have become a critical addition to all facets of structural lung tissue changes such as in human asthma and chronic obstructive pulmonary disease, but little is known about their role in the equine recurrent airway obstruction, a disease that resembles to the human asthma. Since the equine bronchial fibroblasts (EBF) have not been isolated and characterized yet, the use of defined medium was investigated. Results: Primary EBF were cultured on non-collagen coated flasks without serum or in the presence of feta bovine serum (FBS) or horse serum (HS) or in serum depleted medium. EBF cultured in serum-free basal media and those serum deprived were not able to proliferate and even exhibited considerable cell death. In media containing FBS or HS, proliferation of the cells was reproducible between different primary cultures and cells demonstrated expression of vimentin. Large variations were found in the ability of FBS and HS to support growth and differentiation of EBF in monolayer culture. Indications of growth-promoting actions, increasing passage number as well as maintaining fibroblast morphology were found rather in FBS than in HS. EBF culturing in HS needed longer doubling and confluence time. The protein content of the cell pellets was higher in EBF cultured in medium containing HS than FBS. Alpha-smooth muscle actin seemed to be less expressed in EBF cultured in medium containing FBS than those in HS. Conclusions: In sum, serum addition to basal EBF medium enhanced EBF differentiation into myofibroblasts, and these findings are useful to develop in vitro fibroblast culture models that mimic in vivo physiological processes and to study airway disease mechanisms and remodeling.:Background; Results; Discussion; Conclusions

info:eu-repo/classification/ddc/610

ddc:610

Mitofusin 2 regulates actin cytoskeleton and cell migration

Yueyang Wang (12464439)

27 April 2022

<p>  </p> <p>Zebrafish (<em>Danio rerio</em>) is a well-established model to study neutrophil biology. However, a lack of standard tissue-specific knockdown or knockout technique in the zebrafish field has limited the power of this model organism when studying developmental essential genes, such as those related to mitochondrial function. We have developed a robust and flexible neutrophil-restricted knockout in zebrafish based on CRISPR/Cas9 system, with which we gained insights into the role of Rac2 in regulating the actin cytoskeleton and the subcellular location of Rac activation in zebrafish neutrophils.</p> <p>Previous study in our lab using another neutrophil-specific knockout system addressed multiple mitochondrial proteins regulate neutrophil motility in zebrafish. Interestingly, we observed <em>Mfn2</em>-deficient neutrophils trapped in the vasculature in zebrafish embryos. Here we further characterized the function of MFN2 in regulating cell migration with neutrophil-like HL-60 cells and mice embryonic fibroblasts (MEFs). We found significant changes in actin organization in both <em>MFN2</em>-deficient neutrophil-like cells and MEFs and mechanistically, disrupted mitochondria-ER interaction, increased intracellular Ca2+ levels. We also investigated the cytoskeleton proteins and observed hyperactivation of RhoA and Myosin light chain kinase, along with accumulation of phosphorylated myosin light chain at the cell boundary in <em>MFN2</em>-deficient MEFs. These altered MFN2-Ca2+-RhoA/MLCK-myosin signaling finally affects the peripheral actin bundle architecture and forms the “Peripheral Actin Myosin Belt (PAMB)” structure. The formation of PAMB hampered cell adhesive migration in <em>Mfn2</em>-null MEFs. </p> <p>Altogether, our research gained new insights into the essential role of MFN2 in cytoskeleton regulation and the underlying molecular mechanisms, which may provide a new direction to understand the relevance of this gene in immune cell dysfunction and other MFN2-associated diseases.</p>

Cell Biology

mitofusin-2

Cytoskeleton

tissue specific knock out

Zebrafish model system

mice embryonic fibroblast

Stromal PTEN Expression Regulates Extracellular Matrix Deposition and Organization in the Mammary Gland

Jones, Caitlin

13 November 2020

No description available.

Biomedical Engineering

tumor stroma

fibroblast

PTEN

SPARC

extracellular matrix

ECM

extracellular matrix alignment

breast cancer

mammographic density

collagen

Expression, purification, and characterization of recombinant basic fibroblast growth factor in pichia pastoris

Le, Henry Hieu Minh

01 January 2019

Wounds in the mouth, occurring after oral surgery, take time to heal. No ointment can be added to help with the healing process because mouth saliva will constantly wash it away. In order to combat this problem, we propose engineering a normal flora microbe to grow at the site of injury and secrete a recombinant growth factor to promote healing of the damaged tissue. Our goal is to have the yeast Pichia pastoris produce human basic fibroblast growth factor (bFGF), which aids in cellular proliferation. P. pastoris is a good choice for this application because not only is it considered generally recognized as safe (GRAS) by the FDA, but it is a eukaryote that is able to perform posttranslational modifications and secrete large amounts of recombinant protein. Previous studies have shown that a strain of P. pastoris can be engineered to express bFGF from a methanol-sensitive promoter. The study also showed that the bFGF, which was purified from the yeast’s extracellular medium, was able to promote the growth of NIH/3T3 cells (mice fibroblasts). Because we needed the P. pastoris to express the bFGF in glucose –based tissue culture medium in the presence of mammalian cells, we expressed the bFGF from the constitutive promoter GAP promoter. Along with optimizing and characterizing expression of bFGF, we also investigated the effect of the recombinant protein on mammalian cell growth using both scratch ad MTS assays. In addition, the effects of the yeast being co-cultured with mammalian cells was studied. Our results provide a basis for how a recombinant protein can be clinically used to improve wound healing in the mouth using a yeast strain to produce and secrete a growth factor at the site of injury.

Bioengineering

Basic Fibroblast Growth Factor

bFGF

NIH/3T3

Pichia Pastoris

P. pastoris

Biology

Life Sciences

Novel synonymous and missense variants in FGFR1 causing Hartsfield syndrome

Courage, Carolina, Jackson, Christopher B., Owczarek-Lipska, Marta, Jamsheer, Aleksander, Sowinska-Seidler, Anna, Piotrowicz, Małgorzata, Jakubowski, Lucjusz, Dallèves, Fanny, Riesch, Erik, Neidhardt, John, Lemke, Johannes R.

21 June 2023

Hartsfield syndrome is a rare clinical entity characterized by holoprosencephaly and ectrodactyly with the variable feature of cleft lip/palate. In addition to these symptoms patients with Hartsfield syndrome can show developmental delay of variable severity, isolated hypogonadotropic hypogonadism, central diabetes insipidus, vertebral anomalies, eye anomalies, and cardiac malformations. Pathogenic variants in FGFR1 have been described to cause phenotypically different FGFR1-related disorders such as Hartsfield syndrome, hypogonadotropic hypogonadism with or without anosmia, Jackson–Weiss syndrome, osteoglophonic dysplasia, Pfeiffer syndrome, and trigonocephaly Type 1. Here, we report three patients with Hartsfield syndrome from two unrelated families. Exome sequencing revealed two siblings harboring a novel de novo heterozygous synonymous variant c.1029G>A, p.Ala343Ala causing a cryptic splice donor site in exon 8 of FGFR1 likely due to gonadal mosaicism in one parent. The third case was a sporadic patient with a novel de novo heterozygous missense variant c.1868A>G, p.(Asp623Gly).

info:eu-repo/classification/ddc/610

ddc:610

PKA-Rap1A Dependent Regulation of Age-Rage Signaling in Type II Diabetes Mellitus

Worsham, Rebecca Anne

07 May 2016

Type II diabetes mellitus is associated with many detrimental health situations including heart complications. The purpose of this study was to identify a role for PKA-dependent Rap1a signaling in the AGE-RAGE cascade. My hypothesis was Rap1a GTPase increased the downstream effects of AGE-RAGE signaling in diabetes via a PKA-dependent pathway leading to elevated ECM remodeling in the heart. Cardiac fibroblasts were isolated from heterozygous (Het) and diabetic (db/db) mice. To test the hypothesis, gain-ofunction and loss-ofunction treatments were used. PKC-Zeta is known as a major signaling hub that potentially links PKA-dependent and AGE-RAGE signaling cascades so PKC-Zeta inhibition to downregulate PKA-dependent cascade at PKC-Zeta was also used. Results showed a downregulation of signaling markers in the AGE-RAGE cascade when disrupting Rap1a crosstalk at PKC-Zeta. By understanding where the PKA-dependent and AGE-RAGE signaling cascades crosstalk, a new molecular mechanism is understood possibly leading to decreasing remodeling in a diabetic heart.

siRNA

collagen production

RAGE expression

fibroblast differentiation

myofibroblasts

collagen

AGEs

advanced glycation end-products

western blot analysis

cAMP

EPAC

The use of a synthetic hedgehog agonist in mouse models of chondrodysplasia /

Morrison, David, 1981-

January 2008

No description available.

Bone Development -- physiology.

Mice.

Achondroplasia -- genetics.

Mice, Mutant Strains.

Hedgehog Proteins -- agonists.

The role of fibroblast growth factor receptor 3 in post-natal cartilage and bone metabolism /

Valverde Franco, Gladys, 1972-

January 2008

No description available.

Mice, Transgenic.

Mice.

Bone and Bones -- metabolism.

Cartilage -- metabolism.

Growth factor expression and release in the ischemic heart

Vos, Lynette Christine

01 January 2004

The angiogenic and cardioprotective effects of basic fibroblast growth factor (FGF-2) and vascular endothelial growth factor (VEGF) in the ischemic myocardium have been studied, but expression and release of endogenous FGF-2 and VEGF during myocardial ischemia are poorly understood. In addition, nitric oxide synthase isoforms eNOS and iNOS may play a role in myocardial ischemia. The purpose of this study was to investigate the release of FGF-2 and expression of FGF-2, VEGF, eNOS, and iNOS in the normal and ischemic heart. In Phase I, serum FGF-2 levels in patients undergoing treadmill stress test were measured to investigate correlation between serum FGF-2 levels and presence of ischemic heart disease. The study found that serum FGF-2 in ischemia-positive and ischemia-negative patients was not significantly elevated after treadmill stress test, and serum FGF-2 levels did not differ significantly between ischemia-positive and ischemia-negative patients. In Phase II, FGF-2 levels in coronary effluent from isolated perfused rabbit hearts subjected to low-flow ischemia was measured. Results suggest that FGF-2 is released into the coronary effluent of isolated perfused hearts over time and that this release may be elevated in ischemic (50% flow) hearts. Furthermore, the present study indicates that FGF-2 is released immediately after surgical isolation and instrumentation of the isolated heart. A linear model was developed to describe the release of FGF-2 from the isolated heart as a function of the coronary flow rate Q : [special characters omitted]where t = time and Q = 1 and 3.01 for normal and 50% flow rates respectively. In Phase III, effect of acute low-flow ischemia on FGF-2, VEGF, eNOS, and iNOS mRNA expression was measured in isolated perfused hearts using RT/PCR. Preliminary results indicate that FGF-2, VEGF, and iNOS mRNA expression is upregulated and eNOS expression is decreased in ischemic hearts suggesting that these growth factors play a role in short-term response of the myocardium to ischemia. The results of this study suggest that FGF-2, VEGF, and iNOS mRNA expression are increased, eNOS expression is decreased, and FGF-2 is released in response to low-flow ischemia in the isolated perfused heart.

Anatomy & physiology

Animals

Pathology

Health and environmental sciences

Biological sciences

Fibroblast growth factor

Heart

Ischemic

bFGF

Pharmacy and Pharmaceutical Sciences

Role of activator protein-1 (AP-1) family in RSV-transformed chicken embryonic fibroblasts (CEF)

Wang, Lizhen

05 1900

<p> Proper gene expression programs cellular activities, while aberrant manipulation of transcription factors often leads to devastating consequences, such as cancer or cell death. The transcription factor family activator protein-1 (AP-1) plays an important role in many cellular activities including cell transformation, proliferation and survival (Shaulian and Karin 2002). However, little has been done to obtain a global view of the role of individual AP-1 members and how they cooperate in many cellular activities. We have discovered that blocking the AP-1 pathway by a c-Jun dominant negative mutant, TAM67, induced cell death in RSV-transformed primary chicken embryo fibroblasts (CEF), suggesting that AP-1 activity is vital for cell survival upon v-Src transformation. In addition, accumulation of cytoplasmic vesicles was observed in the cytoplasm of a proportion of RSV-transformed CEF expressing TAM67. Oil-red staining of these vesicles indicated the presence of lipid droplets in these cells, suggesting that the inhibition of AP-1 promotes the adipogenic conversion of v-Src transformed CEF. To understand the role of individual members of the AP-1 family, a retroviral-based shRNA expressing system was designed to stably downregulate individual AP-1 members. This retroviral-based RNAi system provided sustained gene downregulation of AP-1 family members. Reduction of the c-Jun protein level by shRNA induced senescence in normal CEF, while it modestly downregulated AP-1 activity in RSV -transformed CEF indicating that c-Jun is not the main component of the AP-1 complex in RSV-transformed CEF. Inhibition of JunD expression induced apoptosis and was deleterious to both normal and RSV-transformed CEF, suggesting that JunD is crucial for the survival of CEF. Transient express10n reporter-assays also showed that loss-of-function of JunD by shRNA dramatically repressed AP-1 activity. Hence JunD is the main component of the AP-1 complex that regulates the survival of CEF. Furthermore, we determined that loss of JunD expression resulted in an elevated level of tumour suppressor p53. Co-inhibition of p53 and JunD restored the transforming ability of v-Src transformed CEF, as indicated by foci formation in soft agar assays. Hence, repression of p53 induction was able to bypass the death signal released as a result of AP-1 inhibition in v-Src transformed CEF. Downregulation of Fra-2 (Fos-related antigen 2) level by shRNA did not affect the proliferation of normal CEF. However, RSV -transformed CEFs expressing fra -2 shRNA were transformation-defective with the presence of multiple vesicles in cytoplasm. Oil-red staining of these vesicles indicated the presence of lipid droplets, which resembles the effect of T AM67 in RSV -transformed CEF indicating that Fra-2 blocks differentiation. These findings help us to understand the role of individual members of the AP-1 transcription factor family in normal and RSV -transformed CEF. Importantly, global gene profiling of v-Src transformed CEF expressing shRNA for individual AP-1 members will improve our knowledge of the transformation process. Functional characterization of the cascade will rely on the use of retroviral-based shRNA expressing system as described above. </p> / Thesis / Doctor of Philosophy (PhD)

activator protein-1

RSV-transformed CEF

chicken embryonic fibroblast

transcription factor family

retroviral-based shRNA

gene downregulation