Identification and characterization of CEP131 as a novel BBSome interacting protein

Chamling, Xitiz

01 May 2014

Bardet-Biedl syndrome (BBS) is a pleiotropic and genetically heterogeneous disorder, and a well-known ciliopathy. Nineteen different genes have been reported for BBS, mutations in which cause characteristic phenotypes including retinal degeneration, obesity, polydactyly, renal abnormalities, hypogenitalism and cognitive impairment. Protein products of eleven BBS genes are part of two major complexes: the BBSome complex and a CCT/CTRiC/BBS complex. The CCT/CTRiC/BBS complex assists in the formation of the BBSome complex, which in turn traffics numerous receptor proteins to the cilia. However, the precise mechanism by which BBSome ciliary trafficking activity is regulated is not fully understood. In fact, a complete picture of the cellular functions of BBS proteins is still missing, and gaps remain in our understanding of the pleiotropy and heterogeneity of the disease. With the aim of bridging those gaps, this thesis project was designed to identify tissue specific cargoes of the BBSome and to characterize their BBS-related functions. To this end, we generated a transgenic LAP-BBS4 mouse, which expresses the transgene in various tissues including brain, eye, testis, heart, kidney, and adipose tissue. We found that despite tissue specific variable expression, LAP-BBS4 was able to complement the deficiency of Bbs4 and rescue all the BBS phenotypes in the Bbs4 null mice. The finding provides an encouraging prospective for gene therapy for BBS related phenotypes and potentially for other ciliopathies. We also utilized the transgenic mice to search for tissue specific BBSome cargo proteins and identified CEP131 as a novel BBSome interacting protein. Using in vitro cell culture models we show that CEP131 interacts with the BBSome through BBS4. CEP131 is not involved in BBSome assembly, but accumulation of the BBSome in cilia is enhanced upon CEP131 depletion. Our in vitro data implicate CEP131 as a negative regulator of ciliary BBSome trafficking. Finally, we show that cep131 knockdown in zebrafish embryos results in typical BBS phenotypes including Kupffer's vesicle abnormalities and melanosome transport delay. This finding confirms the association of CEP131 with the BBS pathway. Overall, the work performed for this thesis provides further insight into the regulation of BBSome ciliary trafficking and suggests CEP131 as a BBS candidate gene.

Bardet-Biedl Syndrome

BBS4

BBSome

CEP131

Ciliopathy

primary cilia

Genetics

Architecture of the BBSome and its role in ciliary protein trafficking / BBSomeの構築様式と繊毛内タンパク質輸送における役割

Nozaki, Shohei

25 March 2019

京都大学 / 0048 / 新制・課程博士 / 博士(薬科学) / 甲第21709号 / 薬科博第100号 / 新制||薬科||11(附属図書館) / 京都大学大学院薬学研究科薬科学専攻 / (主査)教授 中山 和久, 教授 竹島 浩, 教授 土居 雅夫 / 学位規則第4条第1項該当 / Doctor of Pharmaceutical Sciences / Kyoto University / DFAM

cilia

intraflagellar transport

BBSome

IFT-B complex

VIP assay

499.3

Assessing neuronal ciliary localization of Melanin Concentrating Hormone Receptor 1 in vivo

Kamba, Tisianna K.

08 1900

Indiana University-Purdue University Indianapolis (IUPUI) / Obesity is a growing pandemic that claims close to three hundred thousand lives per year in the United States alone. Despite strong interest and investment in potential treatments, obesity remains a complex and challenging disorder. In the study of obesity, mouse models have been excellent tools that help in understanding the function of different genes that contribute to this disease of energy homeostasis. However, it was surprising when disfunction in primary cilia was found to be linked to syndromic obesity. To understand the role of primary cilia in obesity, a growing subset of GPCRs have been identified to selectively localize to the organelle. Several of which have known roles in energy homeostasis. In some examples, ciliary GPCRs appear to dynamically localize to the organelle; such is the case of GPR161 and smoothened in the hedgehog signaling pathway. Thus, we were interested to see if other GPCRs dynamically localize to the primary cilia as part of their regulation of energy homeostasis. For example, the GPCR MCHR1 selectively localizes to the cilia and is involved in energy homeostasis. Although much is known about the expression of the receptor in the brain, how its ciliary subcellular localization impacts its roles in energy homeostasis is unknown. Observing neuronal cilia in vivo remains a difficult task as some of the available tools such as tagged alleles rely on overexpression of ciliary protein which may impact function. Additionally, most of the work is done in vitro, leaving much to be discovered about neuronal cilia in vivo. In this thesis, we show that using a newly constructed reporter allele mCherryMCHR1, we can see ciliary expression of MCHR1 in the brain of developing and adult mice; more specifically in the ARC and PVN. Subsequently, using a novel Artificial intelligence analysis approach, we measured the length and composition of MCHR1 positive cilia under physiological conditions associated with MCHR1 function. Although in this work we are reporting no changes in dynamic localization of MCHR1 in the hypothalamus specifically, we are not excluding the potential for changes in other regions of the brain or under other conditions; and we are suggesting that pharmacological approaches may help highlight potential ciliary GPCR dynamic localization.

cilia

ciliary

obesity

Hh

HFD

Fasted

in vivo

MCHR1

GPCR

Magnetic Nanocomposite Cilia Sensors

Alfadhel, Ahmed

19 July 2016

Recent progress in the development of artificial skin concepts is a result of the increased demand for providing environment perception such as touch and flow sensing to robots, prosthetics and surgical tools. Tactile sensors are the essential components of artificial skins and attracted considerable attention that led to the development of different technologies for mimicking the complex sense of touch in humans. This dissertation work is devoted to the development of a bioinspired tactile sensing technology that imitates the extremely sensitive hair-like cilia receptors found in nature. The artificial cilia are fabricated from permanent magnetic, biocompatible and highly elastic nanocomposite material, and integrated on a giant magneto-impedance magnetic sensor to measure the stray field. A force that bends the cilia changes the stray field and is therefore detected with the magnetic sensor, providing high performance in terms of sensitivity, power consumption and versatility. The nanocomposite is made of Fe nanowires (NWs) incorporated into polydimethylsiloxane (PDMS). Fe NWs have a high remanent magnetization, due the shape anisotropy; thus, they are acting as permanent nano-magnets. This allows remote device operation and avoids the need for a magnetic field to magnetize the NWs, benefiting miniaturization and the possible range of applications. The magnetic properties of the nanocomposite can be easily tuned by modifying the NWs concentration or by aligning the NWs to define a magnetic anisotropy. Tactile sensors are realized on flexible and rigid substrates that can detect flow, vertical and shear forces statically and dynamically, with a high resolution and wide operating range. The advantage to operate the sensors in liquids and air has been utilized to measure flows in different fluids in a microfluidic channel. Various dynamic studies were conducted with the tactile sensor demonstrating the detection of moving objects or the texture of objects. Overall, the results confirm the possibility to easily control the sensors’ performance with the cilia arrangement and dimensions. The cost effective mold-based microfabrication process and magnetic operation enable a high degree of integration, which together with the extremely low power consumption make the artificial cilia sensor reported in this dissertation an attractive solution for many applications.

Tactile sensors

Nanowires

magnetic

Nanocomposite

Artificial Skin

Cilia

Characterization of Primary Cilia and Intraflagellar Transport 20 in the Epidermis

Su, Steven

January 2020

Mammalian skin is a dynamic organ that constantly undergoes self-renewal during homeostasis and regenerates in response to injury. Crucial for the skin’s self-renewal and regenerative capabilities is the epidermis and its stem cell populations. Here we have interrogated the role of primary cilia and Intraflagellar Transport 20 (Ift20) in epidermal development as well as during homeostasis and wound healing in postnatal, adult skin. Using a transgenic mouse model with fluorescent markers for primary cilia and basal bodies, we characterized epidermal primary cilia during embryonic development as well as in postnatal and adult skin and find that both the Interfollicular Epidermis (IFE) and hair follicles (HFs) are highly ciliated throughout development as well as in postnatal and adult skin. Leveraging this transgenic mouse, we also developed a technique for live imaging of epidermal primary cilia in ex vivo mouse embryos and discovered that epidermal primary cilia undergo ectocytosis, a ciliary mechanism previously only observed in vitro. We also generated a mouse model for targeted ablation of Ift20 in the hair follicle stem cells (HF-SCs) of adult mice. We find that loss of Ift20 in HF-SCs inhibits ciliogenesis, as expected, but strikingly it also inhibits hair regrowth. Closer examination of these mice reveals that Ift20 is crucial in maintaining HF-SC identity. Specifically, ablation of Ift20 in HF-SCs results in loss of SOX9 expression in HF-SCs and results in ectopic expression of the IFE marker KLF5 in HF-SCs. Additionally, ectopic differentiation is observed in HF-SCs following loss of Ift20. Finally, using both in vitro and in vivo models, we also characterize the role of primary cilia and Ift20 in epidermal wound healing. We find that loss of Ift20 slows collective keratinocyte migration in vitro and also slows HF-SC migration in vivo during wound repair. Interestingly our data suggests that Ift20 regulates keratinocyte migration in a primary cilia-independent manner. Instead, we find that Ift20 mediates focal adhesion (FA) turnover during keratinocyte migration. Specifically, Ift20 together with Rab5, regulates recycling of FA integrins and loss of Ift20 inhibits proper return of integrins to the keratinocyte surface. Overall, we demonstrate that the epidermis is highly ciliated throughout development and in postnatal skin. We show that Ift20 is crucial in maintaining HF-SC identity and the telogen to anagen transition in HFs. We finally demonstrate that Ift20 regulates keratinocyte migration independent of its function in ciliogenesis and instead regulates recycling of FA integrins through a Rab5 dependent mechanism.

Cytology

Biology

Medicine

Skin

Stem cells--Research

Cilia and ciliary motion

Effects of Peripheral Nerve Injury on the Cells of the Dorsal Root Ganglion: a Role for Primary Cilia

Smith, Sarah K.

12 1900

Primary cilia are ubiquitous sensory organelles found on most cell types including cells of the dorsal root ganglia (DRG). The DRG are groups of peripheral neurons that relay sensory information from the periphery to the CNS. Other cell types in the DRG include a type of glial cell, the satellite glial cells (SGCs). The SGCs surround the DRG neurons and, with the neurons, form functional sensory units. Currently are no reports describing the numbers of DRG cells that have cilia. We found that 26% of the SGCs had primary cilia. The incidence of cilia on neurons varied with neuron size, a property that roughly correlates with physiological characteristics. We found that 29% of the small, 16% of the medium and 5% of the large neurons had primary cilia. Primary cilia have been shown to have a role in cell proliferation in a variety of cell types. In some of the cells the cilia mediate the proliferative effects of Sonic hedgehog (Shh). In the CNS, Shh signaling through primary cilia affects proliferation during development as well as following injury, but no studies have looked at this function in the PNS. The SGCs and neurons of the DRG undergo complex changes following peripheral nerve injury such as axotomy. One marked change seen after axotomy is SGC proliferation and at later stages, neuronal death. We found that following axotomy there is a significant increase in the percentage of SGCs with primary cilia. We also found a significant increase in the percentage of medium-sized neurons with primary cilia. In other experiments we tested the idea that Shh plays a role in SGC proliferation. When Shh signaling was blocked following axotomy we found decreased proliferation of SGCs. This is the first report of a change in the percentage of cells with cilia following injury in the PNS, and the first report of a role for Shh in SGC proliferation following axotomy.

Peripheral nervous system

primary cilia

satellite glial cells

proliferation

Cilia Proteins Control Cerebellar Morphogenesis by Promoting Expansion of the Granule Progenitor Pool

Chizhikov, Victor V., Davenport, James, Zhang, Qihong, Shih, Evelyn Kim, Cabello, Olga A., Fuchs, Jannon L., Yoder, Bradley K., Millen, Kathleen J.

05 September 2007

Although human congenital cerebellar malformations are common, their molecular and developmental basis is still poorly understood. Recently, cilia-related gene deficiencies have been implicated in several congenital disorders that exhibit cerebellar abnormalities such as Joubert syndrome, Meckel-Gruber syndrome, Bardet-Biedl syndrome, and Orofaciodigital syndrome. The association of cilia gene mutations with these syndromes suggests that cilia may be important for cerebellar development, but the nature of cilia involvement has not been elucidated. To assess the importance of cilia-related proteins during cerebellar development, we studied the effects of CNS-specific inactivation of two mouse genes whose protein products are critical for cilia formation and maintenance, IFT88, (also known as polaris or Tg737), which encodes intraflagellar transport 88 homolog, and Kif3a, which encodes kinesin family member 3a. We showed that loss of either of these genes caused severe cerebellar hypoplasia and foliation abnormalities, primarily attributable to a failure of expansion of the neonatal granule cell progenitor population. In addition, granule cell progenitor proliferation was sensitive to partial loss of IFT function in a hypomorphic mutant of IFT88 (IFT88orpk), an effect that was modified by genetic background. IFT88 and Kif3a were not required for the specification and differentiation of most other cerebellar cell types, including Purkinje cells. Together, our observations constitute the first demonstration that cilia proteins are essential for normal cerebellar development and suggest that granule cell proliferation defects may be central to the cerebellar pathology in human cilia-related disorders.

cerebellar hypoplasia

cerebellum

cilia

granule neuron progenitors

Joubert syndrome

Shh

Hydrodynamics of squirming locomotion at low Reynolds numbers / 低レイノルズ数における微生物遊泳の流体力学

Ishimoto, Kenta

23 March 2015

京都大学 / 0048 / 新制・課程博士 / 博士(理学) / 甲第18770号 / 理博第4028号 / 新制||理||1580(附属図書館) / 31721 / 京都大学大学院理学研究科数学・数理解析専攻 / (主査)教授 山田 道夫, 教授 玉川 安騎男, 准教授 竹広 真一 / 学位規則第4条第1項該当 / Doctor of Science / Kyoto University / DFAM

low Reynolds number flow

microorganism

cilia and flagella

propulsion

400

Roles of kinesin-2 motor proteins involved in intraciliary protein trafficking / 繊毛内タンパク質輸送に関与するモータータンパク質キネシン2の機能

Funabashi, Teruki

26 March 2018

京都大学 / 0048 / 新制・課程博士 / 博士(薬科学) / 甲第21044号 / 薬科博第87号 / 新制||薬科||9(附属図書館) / 京都大学大学院薬学研究科薬科学専攻 / (主査)教授 中山 和久, 教授 竹島 浩, 教授 井垣 達吏 / 学位規則第4条第1項該当 / Doctor of Pharmaceutical Sciences / Kyoto University / DFAM

cilia

intraflagellar transport

IFT-B complex

KIF17

KIF3B

ciliogenesis

499.3

DEPHOSPHORYLATION OF INNER ARM 1 IS REQUIRED FOR CILIARY REVERSALS IN TETRAHYMENA THERMOPHILA

Deckman, Cassandra M.

05 June 2003

No description available.

cilia

Tetrahymena

dynein

axoneme

cell motility

ciliary reversal