V. V. Terskikh scite author profile

Hair follicle (HF) reconstruction in vitro is a promising field in alopecia treatment and human HF development research. Here, we combined postnatal human dermal papilla (DP) cells and skin epidermal keratinocytes (KCs) in a hanging drop culture to develop an artificial HF germ. The method is based on DP cell hair-inducing properties and KC self-organization. We evaluated two protocols of aggregate assembling. Mixed HF germ-like structures demonstrated the initiation of epithelial-mesenchymal interaction, including WNT pathway activation and expression of follicular markers. We analyzed the influence of possible DP cell niche components including soluble factors and extracellular matrix (ECM) molecules in the process of the organoid assembling and growth. Our results demonstrated that soluble factors had little impact on HF germ generation and Ki67+ cell score inside the organoids although BMP6 and VD3 maintained effectively the DP identity in the monolayer culture. Aggrecan, biglycan, fibronectin, and hyaluronic acid (HA) significantly stimulated cell proliferation in DP cell monolayer culture without any effect on DP cell identity. Most of ECM compounds prevented the formation of cell aggregates while HA promoted the formation of larger organoids. In conclusion, our model could be suitable to study cell-cell and cell-niche interactions during HF reconstruction in vitro.

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Dermal papilla cells induce keratinocyte tubulogenesis in culture

Chermnykh

Vorotelyak

Gnedeva

et al. 2010

Histochem Cell Biol

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The ability of dermal papilla (DP) cells to induce hair growth was reported in many studies. However, early stages of hair follicle development and signals that govern this process are poorly understood. Therefore, an in vitro model may be a convenient system to study epithelial-mesenchymal interactions and early stages of epidermal morphogenesis, especially in humans. To investigate the role of DP cells in epidermal morphogenesis we modified the method of isolation of DP cells from hair follicle of human scalp and developed the three-dimensional model of epidermal morphogenesis. Isolated DP cells were able to differentiate in adipogenic and osteogenic directions and retained activity of alkaline phosphatase (AP) for seven passages in culture. DP cells were able to induce tubule-like structures in three-dimensional model in vitro and to reorganize collagen matrix. Prolonged cultivation of DP cells has been a big problem because of the loss of hair follicle-inducing ability and growth activity after several passages. To solve this problem we immortalized DP cells by the transfection of the human telomerase reverse transcriptase cDNA (hTERT). Immortalized DP-hTERT cells retained AP activity and demonstrated low ability to osteogenic differentiation. The conditioned medium collected from actively proliferated cells as well as DP-hTERT cells themselves were capable to induce tubulogenesis after prolonged keratinocyte cultivation.

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The Role of Integrins in the Development and Homeostasis of the Epidermis and Skin Appendages

2013

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Integrins play a critical role in the regulation of adhesion, migration, proliferation, and differentiation of cells. Because of the variety of the functions they play in the cell, they are necessary for the formation and maintenance of tissue structure integrity. The trove of data accumulated by researchers suggests that integrins participate in the morphogenesis of the epidermis and its appendages. The development of mice with tissue-specific integrin genes knockout and determination of the genetic basis for a number of skin diseases in humans showed the significance of integrins in the biology, physiology, and morphogenesis of the epidermis and hair follicles. This review discusses the data on the role of different classes of integrin receptors in the biology of epidermal cells, as well as the development of the epidermis and hair follicles.

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Label Retaining Cells and Cutaneous Stem Cells

Terskikh

Vasiliev

Vorotelyak

2011

Stem Cell Rev and Rep

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This is a comprehensive review on label retaining cells (LRC) in epidermal development and homeostasis. The precise in vivo identification and location of epidermal stem cells is a crucial issue in cutaneous biology. We discuss here the following problems: (1) Identification and location of LRC in the interfollicular epithelium and hair follicle; (2) The proliferative potential of LRC and their role in cutaneous homeostasis (3); LRC phenomenon and the Immortal Strand Hypothesis, which suggests an alternative mechanism for retention of genetic information; (4) Significance of LRC studies for development of stem cell concept. Now, it seems evident that LRC are a frequent feature of stem cell niches and revealing highly dormant LRC may be used for identification of stem cell niches in different tissues. LRC were used for screening specific markers of epidermal stem cells. Within a given tissue stem cells have different proliferative characteristics. There are more frequently cycling stem cells which function primarily in homeostasis, while LRC form a reserve of dormant, may be ultimate, stem cells, which are set aside for regeneration of injury or unforeseen need. The authors suggest that LRC dormancy described in Mammalia has much in common with developmental quiescence found in some other animals. For example in C. elegans reproductive system, vulval precursor cells have developmentally programmed cell-cycle arrest in the first larval stage, and then undergo an extended period of quiescence before resuming proliferation. Another example of developmental quiescence is the diapause, a widespread phenomenon exhibited by animals ranging from nematodes to mammals, often occurring at genetically predetermined life history stage.

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Cultivation and Transplantation of Epidermal Keratinocytes

Terskikh

Vasiliev

1999

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On the Resting Periods in the Cell Life Cycle*

Epifanova

Terskikh

1969

Cell Proliferation

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The review is concerned with the transition of cells into a specific physiological state—the resting period—in which they may stay for an indefinite time interval without undergoing division or differentiation but retaining both of these potentials. When stimulated such cells may enter into mitotic cycle, divide and differentiate. No direct correlation between the onset of the differentiated state and the transition of cells through the mitotic cycle has been established. It cannot be excluded that sometimes cells may differentiate directly from the resting period. However, there is a large body of evidence that the entry of cells into mitotic cycle is a necessary prerequisite for subsequent differentiation. The susceptibility of cells to differentiative stimuli is retained during the mitotic cycle. The completion of mitosis itself does not imply that a cell will undergo differentiation; in the absence of adequate stimulus it may pass again into a resting period. According to what is known at present it is suggested that cells may pass into a true resting stage not only after completing mitosis but also after doubling their DNA content. It is also conceivable that a cell may pass into a resting period at different stages of its life cycle. The essential feature of the cell life cycle is the alternation of resting periods and periods of active proliferation. This general principle of organization provides conditions necessary for population‐size control, cell differentiation, interaction of a given population with other systems, and the reactions of cells to a changing environment.

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Hair Follicle Reconstruction and Stem Cells

Kalabusheva¹,

Chermnykh²,

Terskikh³

et al. 2017

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De novo hair follicle (HF) formation in embryonic skin and hair growth in postnatal skin are the result of epithelial-mesenchymal interactions between specialized mesenchymal dermal papilla (DP) and epithelial stem cells that give rise to hairs. Adult HF is a valuable source of diferent lineages of stem cells (SCs) with morphogenetic potential. Epithelial stem cells are residing in the special compartment of HF (the bulge) and can be mobilized to regenerate the new follicle with each hair cycle and to reepithelialize epidermis during wound repair. This review summarizes the current knowledge on key characteristics of HF SC populations in terms of regenerative potential. General biological principles that govern the mesenchymal-epithelial interactions within the HF and the signaling pathways that control HF development are discussed. The main focus is on recent approaches to reconstruct folliculogenesis in vitro and perspectives of the tissue engineering in alopecia therapy.

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Differentiation capacity of stromal fibroblast-like cells from human bone marrow, adipose tissue, hair follicle dermal papilla and derma

Chermnykh

Vorotelyak

et al. 2009

Cell Tiss. Biol.

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V. V. Terskikh

Hair Germ Model In Vitro via Human Postnatal Keratinocyte-Dermal Papilla Interactions: Impact of Hyaluronic Acid

Dermal papilla cells induce keratinocyte tubulogenesis in culture

The Role of Integrins in the Development and Homeostasis of the Epidermis and Skin Appendages

Label Retaining Cells and Cutaneous Stem Cells

Cultivation and Transplantation of Epidermal Keratinocytes

On the Resting Periods in the Cell Life Cycle*

Hair Follicle Reconstruction and Stem Cells

Differentiation capacity of stromal fibroblast-like cells from human bone marrow, adipose tissue, hair follicle dermal papilla and derma

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