Laura Cristina Ceafalan

C-kit immunopositive interstitial cells (Cajal-type) in human myometrium.

Previous reports describing Cajal‐like interstitial cells in human uterus are contradictory in terms of c‐kit immunoreactivity: either negative (but vimentin‐positive) in pregnant myometrium, or positive, presumably in the endometrium. The aim of this study was to verify the existence of human myometrial Cajal‐like interstitial cells (m‐CLIC). Six different, complementary approaches were used: 1) methylene‐blue supravital staining of tissue samples (cryosections), 2) methylene blue and Janus green B vital staining (m‐CLIC and mitochondrial markers, respectively), and 3) extracellular single‐unit electrophysiological recordings in cell cultures, 4) non‐conventional light microscopy on glutaraldehyde/osmium fixed, Epon‐embedded semi‐thin sections (less than 1μm) stained with toluidine blue (TSM), 5) transmission electron microscopy (TEM), and 6) immunofluorescence (IF). We found m‐CLIC in myometrial cryosections and in cell cultures. In vitro, m‐CLIC represented ∼7% of the total cell number. m‐CLIC had 2–3 characteristic processes which were very long (∼ 60 μm), very thin (±0.5μm) and moniliform. The dilated portions of processes usually accomodated mitochondria. In vitro, m‐CLIC exhibited spontaneous electrical activity (62.4 ± 7.22 mV field potentials, short duration: 1.197 ± 0.04ms). Moreover, m‐CLIC fulfilled the usual TEM criteria, the so‐called ‘gold’ or ‘platinum’ standards (e.g. the presence of discontinuos basal lamina, caveolae, endoplasmic reticulum, and close contacts between each other, with myocytes, nerve fibers and/or capillaries etc.). IF showed that m‐CLIC express CD117/c‐kit, sometimes associated with CD34 and with vimentin along their processes.

Telocytes in human skin – are they involved in skin regeneration?

Telocytes (TCs), a particular interstitial cell type, have been recently described in a wide variety of mammalian organs (www.telocytes.com). The TCs are identified morphologically by a small cell body and extremely long (tens to hundreds of μm), thin prolongations (less than 100 nm in diameter, below the resolving power of light microscopy) called telopodes. Here, we demonstrated with electron microscopy and immunofluorescence that TCs were present in human dermis. In particular, TCs were found in the reticular dermis, around blood vessels, in the perifollicular sheath, outside the glassy membrane and surrounding sebaceous glands, arrector pili muscles and both the secretory and excretory portions of eccrine sweat glands. Immunofluorescence screening and laser scanning confocal microscopy showed two subpopulations of dermal TCs; one expressed c‐kit/CD117 and the other was positive for CD34. Both subpopulations were also positive for vimentin. The TCs were connected to each other by homocellular junctions, and they formed an interstitial 3D network. We also found TCs adjoined to stem cells in the bulge region of hair follicles. Moreover, TCs established atypical heterocellular junctions with stem cells (clusters of undifferentiated cells). Given the frequency of allergic skin pathologies, we would like to emphasize the finding that close, planar junctions were frequently observed between TCs and mast cells. In conclusion, based on TC distribution and intercellular connections, our results suggested that TCs might be involved in skin homeostasis, skin remodelling, skin regeneration and skin repair.

Insights into the interstitium of ventricular myocardium: interstitial Cajal-like cells (ICLC).

We have previously described interstitial Cajal‐like cells (ICLC) in human atrial myocardium. Several complementary approaches were used to verify the existence of ICLC in the interstitium of rat or human ventricular myocardium: primary cell cultures, vital stainings (e.g.: methylene blue), traditional stainings (including silver impregnation), phase contrast and non‐conventional light microscopy (Epon‐embedded semithin sections), transmission electron microscopy (TEM) (serial ultrathin sections), stereology, immunohistochemistry (IHC) and immunofluorescence (IF) with molecular probes. Cardiomyocytes occupy about 75% of rat ventricular myocardium volume. ICLC represent ∼32% of the number of interstitial cells and the ratio cardiomyocytes/ICLC is about 70/1. In the interstitium, ICLC establish close contacts with nerve fibers, myocytes, blood capillaries and with immunoreactive cells (stromal synapses). ICLC show characteristic cytoplasmic processes, frequently two or three, which are very long (tens up to hundreds of μm), very thin (0.1‐0.5μm thick), with uneven caliber, having dilations, resulting in a moniliform aspect. Gap junctions between such processes can be found. Usually, the dilations are occupied by mitochondria (as revealed by Janus green B and Mito Tracker Green FM) and elements of endoplasmic reticulum. Characteristically, some prolongations are flat, with a veil‐like appearance, forming a labyrinthic system. ICLC display caveolae (about 1 caveola/1μm cell membrane length, or 2‐4% of the relative cytoplasmic volume, Mitochondria and endoplasmic reticulum (rough and smooth) occupy 5‐10% and 1‐2% of cytoplasmic volume, respectively. IHC revealed positive staining for CD34, EGFR and vimentin and, only in a few cases for CD117. IHC was negative for: desmin, CD57, tau, chymase, tryptase and CD13. IF showed that ventricular ICLC expressed connexin 43. We may speculate that possible ICLC roles might be: intercellular signaling (neurons, myocytes, capillaries etc.) and/or chemomechanical sensors. For pathology, it seems attractive to think that ICLC might participate in the process of cardiac repair/remodeling, arrhythmogenesis and, eventually, sudden death.

Telocytes in meninges and choroid plexus.

Telocytes (TCs) are a recently identified type of interstitial cells present in a wide variety of organs in humans and mammals (www.telocytes.com). They are characterized by a small cell body, but extremely long cell processes - telopodes (Tp), and a specific phenotype. TCs establish close contacts with blood capillaries, nerve fibers and stem cells. We report here identification of TCs by electron microscopy and immunofluorescence in rat meninges and choroid plexus/subventricular zone, in the vicinity of putative stem cells. The presence of TCs in brain areas involved in adult neurogenesis might indicate that they have a role in modulation of neural stem cell fate.

Cellular Players in Skeletal Muscle Regeneration

Skeletal muscle, a tissue endowed with remarkable endogenous regeneration potential, is still under focused experimental investigation mainly due to treatment potential for muscle trauma and muscular dystrophies. Resident satellite cells with stem cell features were enthusiastically described quite a long time ago, but activation of these cells is not yet controlled by any medical interventions. However, after thorough reports of their existence, survival, activation, and differentiation there are still many questions to be answered regarding the intimate mechanism of tissue regeneration. This review delivers an up-to-date inventory of the main known key players in skeletal muscle repair, revealed by various models of tissue injuries in mechanical trauma, toxic lesions, and muscular dystrophy. A better understanding of the spatial and temporal relationships between various cell populations, with different physical or paracrine interactions and phenotype changes induced by local or systemic signalling, might lead to a more efficient approach for future therapies.

Isolated human uterine telocytes: immunocytochemistry and electrophysiology of T-type calcium channels

Recently, telocytes (TCs) were described as a new cell type in the interstitial space of many organs, including myometrium. TCs are cells with very long, distinctive extensions named telopodes (Tps). It is suggested that TCs play a major role in intercellular signaling, as well as in morphogenesis, especially in morphogenetic bioelectrical signaling. However, TC plasma membrane is yet unexplored regarding the presence and activity of ion channels and pumps. Here, we used a combination of in vitro immunofluorescence and patch-clamp technique to characterize T-type calcium channels in TCs. Myometrial TCs were identified in cell culture (non-pregnant and pregnant myometrium) as cells having very long Tps and which were positive for CD34 and platelet-derived growth factor receptor-α. Immunofluorescence analysis of the subfamily of T-type (transient) calcium channels CaV3.1 and CaV3.2 presence revealed the expression of these ion channels on the cell body and Tps of non-pregnant and pregnant myometrium TCs. The expression in TCs from the non-pregnant myometrium is less intense, being confined to the cell body for CaV3.2, while CaV3.1 was expressed both on the cell body and in Tps. Moreover, the presence of T-type calcium channels in TCs from non-pregnant myometrium is also confirmed by applying brief ramp depolarization protocols. In conclusion, our results show that T-type calcium channels are present in TCs from human myometrium and could participate in the generation of endogenous bioelectric signals responsible for the regulation of the surrounding cell behavior, during pregnancy and labor.

Interstitial Cajal-like cells (ICLC) as steroid hormone sensors in human myometrium: immunocytochemical approach.

Expression of estrogen (ER) and progesterone (PR) receptors was investigated in cultured human normal myometrial cells (non‐pregnant uterus, fertile period). The ER and PR expression was studied by immunohistochemistry and immunofluorescence on either myocytes or interstitial Cajal‐like cells (ICLC). Only those cells double immunostained for c‐kit and steroid receptors were considered as ICLC. ER and/or PR immunoreactivity was localized in ICLC, primarily concentrated at the nucleus level, but it was also observed in the cell body (cytoplasm) and processes. Stronger immunopositive reaction in the ICLC nucleus for PR than for ER was noted. Under our experimental conditions, a clear positive repeatable reaction for steroid receptors could not be detected in myocytes. In conclusion, these data suggest that ICLC could be true hormonal ‘sensors’, possibly participating in the regulation of human myometrial contractions (via gap junctions with myocytes and/or by paracrine signaling).

Cajal-type cells from human mammary gland stroma: phenotype characteristics in cell culture.

We report here the in vitro isolation of Cajal‐like interstitial cells from human inactive mammary‐gland Stroma. Primary cell cultures examined in phase‐contrast microscopy or after vital methylene‐blue staining revealed a cell population with characteristic morphological phenotype: fusiforms, triangular or polygonal cell body and the corresponding (very) long, slender, moniliform cytoplasmic processes. Giremsa staining pointed out the typical knobbed aspect of cell prolongations. Immunofluorescence (IF) showed, like in situ immunohistochemistry, that Cajal‐type cells in vitro (primary culltures), expressed c‐kit/CD117 and vimentin. In conclusion, the images presented here reinforce our previous hypothesis that human mammary glands have a distinct population of Cajal‐like cells in non‐epithelial tissue compartments.

Interstitial outburst of angiogenic factors during skeletal muscle regeneration after acute mechanical trauma

Angiogenesis is a key event during tissue regeneration, but the intimate mechanisms controlling this process are still largely unclear. Therefore, the cellular and molecular interplay along normal tissue regeneration should be carefully unveiled. To this matter, we investigated by xMAP assay the dynamics of some angiogenic factors known to be involved in tissue repair, such as follistatin (FST), Placental Growth Factor‐2 (PLGF‐2), epidermal growth factor (EGF), betacellulin (BTC), and amphiregulin (AREG) using an animal model that mimics acute muscle contusion injuries. In situ immunofluorescence was used for the evaluation and tissue distribution of their cellular sources. Tissue levels of explored factors increased significantly during degeneration and inflammatory stage of regeneration, peaking first week postinjury. However, except for PLGF‐2 and EGF, their levels remained significantly elevated after the inflammatory process started to fade. Serum levels were significantly increased only after 24 h for AREG and EGF. Though, for all factors except FST, the levels in injured samples did not correlate with serum or contralateral tissue levels, excluding the systemic influence. We found significant correlations between the levels of EGF and AREG, BTC, FST and FST and AREG in injured samples. Interstitial cells expressing these factors were highlighted by in situ immunolabeling and their number correlated with measured levels dynamics. Our study provides evidence of a dynamic level variation along the regeneration process and a potential interplay between selected angiogenic factors. They are synthesized, at least partially, by cell populations residing in skeletal muscle interstitium during regeneration after acute muscle trauma. Anat Rec, 298:1864–1879, 2015.

Skeletal muscle regeneration involves macrophage-myoblast bonding

ABSTRACT Regeneration in adult skeletal muscle relies on the activation, proliferation, and fusion of myogenic precursor cells (MPC), mostly resident satellite cells (SC). However, the regulatory mechanism during this process is still under evaluation, with the final aim to manipulate regeneration when the intrinsic mechanism is corrupted. Furthermore, intercellular connections during skeletal muscle regeneration have not been previously thoroughly documented. Our hypothesis was that a direct and close cellular interaction between SC/MPC and invading myeloid cells is a key step to control regeneration. We tested this hypothesis during different steps of skeletal muscle regeneration: (a) the recruitment of activated SC; (b) the differentiation of MPC; (c) myotubes growth, in a mouse model of crush injury. Samples harvested (3 and 5 days) post-injury were screened by light and confocal microscopy. Ultrastructural analysis was performed by conventional transmission electron microscopy (TEM) and scanning transmission electron microscopy (STEM) followed by 3D modeling of electron tomography (ET) data. This revealed a new type of interaction between macrophages and myogenic cells by direct heterocellular surface apposition over large areas and long linear distances. In the analyzed volume, regions spaced below 20 nm, within molecular range, represented 31% of the macrophage membrane surface and more than 27% of the myotube membrane. The constant interaction throughout all stages of myogenesis suggests a potential new type of regulatory mechanism for the myogenic process. Thus, deciphering structural and molecular mechanisms of SC-macrophage interaction following injury might open promising perspectives for improving muscle healing.