The Possible Involvement of Apoptotic Decay of Terminal Deoxynucleotidyl Transferase-Positive Lymphocytes in the Reutilization of the Extracellular DNA Fragments by Surrounding Living Cells ()
1. Introduction
The fundamental property of circulating HSCs is their beneficial effect on cellular renewal and regeneration of tissues of various histotypes. The components of the lymphoid line of hematopoiesis, such as prolymphocytes of bone marrow and cortical thymocytes, may participate in this morphogenic effect of HSC, too. Only they have a specific marker Terminal deoxynucleotidyl Transferase (TdT). About 15% of the circulating CD34+ and CD133+ hematopoietic stem cells are TdT positive lymphoid progenitors [1]. Thus, they can participate in all processes of the morphogenesis provided by HSCs in peripheral organs and tissues. The enzyme does not require a template for activity. It catalyzes the incorporation of deoxynucleotides into the 3’-OH termini of single- or double-stranded DNA, using as a primer even short oligodeoxynucleotide of at least three bases. It is generally accepted only that the enzyme acts intracellularly, providing a variety of antigen receptors at the V(D)J junction of gene segment (N-region) by the random import of one of the four Deoxyribonucleotides Monophosphates (dNMP) in it. Therefore, enzyme TdT should belong to the group of intracellular potassium-dependent polymerases as all template-dependent DNA polymerases, losing activity tenfold in extracellular media with a physiological concentration of sodium (≈ 0.15 M NaCl) [2]. However, the function of TdT may be more complex because it does not change in the range of NaCl content for plasma and extracellular media 0.14 M and even increases unexpectedly up to 50% in the media with 0.22 M of Na+ [2]. Besides this extracellular property, TdT incorporates a dNMP into primer in the presence of divalent metal ions, for example, Zn2+, which basal concentrations level in extracellular media (10 nM) is much higher than that in intracellular space (100 pM) [3]. Moreover, only TdT-positive lymphocytes lose their viability after blocking the 3’-OH primers in their DNA, though the blockers do not affect the viability of TdT-negative cells [4]. Eventually/Yet, antigenic stimulation of circulating T-cells can re-activate V(D)J recombination and re-express the gene TdT, re-rejuvenating the mature cells [5]. The ability of TdT to polymerize both deoxy-deoxyribonucleotides, and ribonucleotides does not confirm its ultimate specificity for V(D)J recombination [6]. All these data indicate the possible function of the TdT-enzyme outside the cells is not in consideration until now [7]. On the other hand, the well-recognized existence of free DNA in extracellular media (exDNA) generally discusses in the context of horizontal gene transfer or, as a source of energy and nutrients to other cells after fragmentation by extracellular DNase, avoiding its possible interaction with extracellular polymerases, like TdT [8] [9].
The circulating cells with this unique enzyme do not yet find a place in the traditional pathophysiological schemes describing the health of mammals. Indeed, this fact seems to be an omission, taking into account the appearance of TdT too far from the bone marrow and thymus, where new vessels arise around artificial scaffolds [10]. In this article, we present data in vitro to support the expected trophic function of extracellular TdT.
2. Methods
2.1. Objects
The source of thymocytes were glands of non-in-bread albino male rats (120 - 130 g) taken from animals before, 0.5 and 6 hours after total body X-irradiation in dose 8 Gy at a dose rate of 0.91 Gy/min, a 200 kV, a 15 ma, filters of 0.5 mm Cu and 1.0 mm Al. Thymocytes were isolated in iso-osmotic buffered Hanks Balanced Saline Solution (HBSS) and incubated at 37˚C at different cells densities (from 2.5 to 23 × 107 cells/ml) and rotating two times per minute at angle 450 during 15 - 115 minutes. Cell viability controls by trypan blue exclusion at dye’s concentration of 0.1%. For conditioning of extra Cellular Media (CM), 23 × 107 cells/ml incubated 60 minutes. After centrifugation (800 ×g, 5 min), supernatant adjusts to a NaCl concentration of 0.25 M for an avoiding of template-dependent intracellular transcriptional activities (3 - 4 S DNA directed-DNA polymerase, 6 - 7 polyribosyl adenylic acid-dependent DNA polymerase), and uses after second centrifugation (1.2 × 105 g, 60 min) as the source of both natural the extracellular enzyme and the primers (further, conditioned media-CM).
2.2. Analyses of CM with Diethyl-Aminoethyl (DEAE)-Cellulose Paper Chromatography
DEAE-cellulose paper chromatography permits to divide CM onto six fractions which correspond to average molecular weight 6 × 102 (1), 2 × 103 (2), 5 × 104 (3), 1 × 105 (4), 1 × 106 (5), and 5 × 106 (6) Dalton of pure DNA [11]. The presence of free extracellular DNA in the fractions CM was evaluated by photometry in a quartz chamber with optical length 4cm or 10 cm, before and after treatment of the CM with DNase I (Merck; 25 μg/mL, 10 minutes). The DNase-sensitive extra cellular substance with optical density (OD) at 260 nm and extinction coefficients 260/230 and 260/280 ≈ 2 accepted as free endogenous DNA expected to be the primer for the TdT enzyme. The polymeric substances with abnormal extinction coefficients 260/230 and 260/280 classify as a nucleoid. The concentration of free endogenous DNA evaluates as 1 μg = 0.02 OD/cm of the optical length.
Detection of spontaneous extracellular TdT-activity as result of template-independent monomer’s polymerization with endogenous primers performers after the addition into CM of 5 × 10−7 M single substrate (deoxyguanosine triphosphate labeled by tritium [8-3H] dGTP, 1.3 Ci/mmol; Perkin Elmer) for 15 - 60 minutes at 37˚C. After DEAE chromatography, the radioactivity of CM fractions collects on MF-Millipore Membrane Filter, 0.22/0.45 µm (Merck), washes, dries, and such samples measured in 10 ml scintillation fluid (Ultima Gold, Perkin Elmer, USA) (Hionic Fluor, Packard) by spectrometer Hidex 300SL, Finland) with effectiveness around 17%. Then, a nucleoid’s radioactivity infraction normalizes to free DNA found in it by parallel DNase I-analyses.
2.3. Preparation of Exogenous Labeled DNA and Its Uptake by Cells
The exogenous chicken DNA (Reanal, Hungary) were labeled with tritium (3H-DNA) by the method of isotopic exchange between hydrogen at C-8 of purine bases of the polymer and hydrogen of heavy-tritium (T)-water (THO) [12] in our modification [13] to simulate a possible biological activity of DNA-like byproducts of TdT in CM. Tritium-labeled DNA had a specific radioactivity of about 410 dpm/µg (i.e., about 60.4 µCi/mmol of nucleotides).
Fragmentation of exogenous DNA, if needs, before use was performed in HBSS (Gibco) by ultrasonic set URSK-7H (NE Bauman’s Moscow Higher Technical School, Russia) at resonance frequency 26.5 kHz adjusting the exposure time under the control of DEAE-chromatography.
During incubation of cells (2.7 × 107/mL) with prepared 3H-DNA (2.5 µg/mL) in Hanks solution for 120 minutes at 37˚C and constant mixing, aliquot samples of cells, if they were, washes three times with Hanks solution, leases in sodium dodecyl sulfate buffer [14]. DNA isolates by well-recognized method Schmidt and Thangauser [15], and its radioactivity counts with beta-spectrometer Liquimat 220, Picker-Nuclear, USA, as described [13].
2.4. Influence of Extra Cellular DNA on Spontaneous (Not Stimulated) DNA Synthesis in Cells
Spontaneous (non-stimulated) DNA synthesis in intact and irradiated in vivo cells 6 hours after exposure (2.7 × 107 cells/mL of Hanks solution) controls by the joint incubation with labeled methyl-3H thymidine (3H-TdR, 26 Ci/mmol, 0.8 µg/mL; MP Biomedicals, Fisher Scientific) during 115 min at 37˚C. The cellular DNA in aliquots was isolated, and its radioactivity was measured, as described above. In parallel, the experiment repeats with exogenous unlabelled DNA (2.5 µg/mL) added by the 55th minute of incubation.
2.5. Statistical Analyses
Single parameters were evaluated statistically with the calculation of an average, Standard Deviation (SD) and Standard Error (SE). The average values M were compared using t-criterion and probability p. We described the trends of the aggregate parameters before and after sonication by mathematical functions generated automatically using non-linear approximations in the Excel program.
The coefficient determination R2 used as a statistical measure of the goodness of fit of the regression line to the data. Satisfactory R2 values were confirmed using Equation (1) for t-parameter:
(1)
3. Results
Figure 1 shows the extracellular nucleoid in conditioned media (CM) of normal and injured thymocytes CM of normal cells obtained from intact animals after shame-irradiation (a) as well as CM since 0.5 (b) and 6 hours after irradiation (c) have the different fractions of nucleoid with absorption at 260 nm wavelength. DNase-sensitive parts of nucleoid are free DNA. Application only in lower the
Figure 1. The extracellular nucleoid in thymocytes’ CM from animals sacrificed before (a), since 0.5 (b), and 6 hours (c) after single total body X-irradiation of rats at dose 8 Gy. Abscissa: ascending numbers of DNA-like fractions with average molecular weight (Mw) 5 × 102, 2 × 103, 5 × 104, 1 × 105, 1 × 106, and 5 × 106 Daltons, according to a CM’ fractionation on DEAE-paper. Ordinate: Units of Optical Density (OD Units) at 260 nm received at 4 cm of optical length. Columns-base data before DNase treatment. Circles with dotted lines-the data after DNase treatment. Columns’ data satisfy only one or none of two additional ratios (OD260/OD230 ≥ 2 and OD260/OD230 ≥ 2) that are typical for free double strand DNA (i.e., these fractions include proteins and monomers of DNA like bases, nucleoside, nucleotides, and their deoxynucleic forms). The pure DNase-sensitive DNA in fractions shown in the boxes like black columns.
average quantities of such DNA were 0.825, 1.55, and 0.665 μg/ml for normal, and injured cells by 0.5 and 6 hours correspondently. They associate mostly with fraction 5 (1 × 106 Da) before irradiation and fractions 6 (5 × 106 Da) after it, presenting potential primers for enzyme before, 0.5, and 6 hours after irradiation (≈ 8.3 × 10−1, 3.1 × 10−1, and 1.3 × 10−1 pmol DNA/mL).
Figure 2 shows the kinetics of spontaneous polymerization of 3H-dTTP on endogenous DNA-primers of CM by (a) time of incubation (minutes), by (b) concentration of DNase-sensitive DNA in CM (µg/mL) without cells in CM (b), and in the presence of them (c).
Taking into account the specific activity of 3H-dTTP (1.3 Ci/mmol) and effectiveness of counting (17%), the polymerization’s activity of TdT in CM were 1.18, 0.080, 5.66 pmol/mL without cells, and 0.316, 0.036, 0.328 pmole/ml with them for before and 0.5, 6 hours after radiation exposure. Then, the cells uptake 0.864 and 0.044, 5.33 pmoles were with effectiveness 76%, 53%, and 92% before, 0.5, and 6 hours after irradiation correspondently (dotted line in Figure 2(c)).
The effectiveness of the uptake of labeled enzyme’s product by cells depends on the numbers of labeled primers-molecules, in pmoles, but opposes to it bulk quantity of DNA-primers, in μg (Figure 2(c)). None of the relation of uptake’s effectiveness with the unlabeled primers in pmoles, as well as nucleoid’s concentration in terms of absorption at 260 nm wavelength were found. These data point mainly to the consumption of the labeled products after their selective separation from nucleoids, i.e. in the form of free polymers.
Figure 2. The polymerization of 3H-dTTP on extracellular DNA-primer in CM of thymocytes from animals sacrificed before (circles), since a 0.5 hour (rhombuses) and 6 hours after (triangles) single total body X-irradiation of rats at dose 8 Gy. Abscissa: (a) time of incubation at 37˚C, minutes. (b) and (c) quantity of a DNase-sensitive DNA (free-DNA) in the fractions of nucleoid found by the spectrophotometry and DNase analysis in CM, μg/mL. Ordinate: (a), (b) radioactivity of a free DNA-fractions (number 5 and 6) of CM after 15 minutes of incubation, cpm. Dark symbols-CM without cells (WO), white symbols-CM with them (W); (c, black symbols) radioactivity of a free DNA captured by cells as a difference between WO and W results; (c, white symbols, dotted line) effectiveness of a capture as a ratio (WO-W)/W results, %.
Figure 3(a) shows the artificial uptake of pure exogenous DNA (average Mw ≈ 4.5 × 106 and 1.5 × 105 Da) by intact cells from extracellular media (6 μg/mL, i.e. ≈ 1.3 pmol/mL of polymeric molecules and ≈ 40 pmole/mL of fragmented ones).
According to Figure 3(a), the uptake reaches 0.48 - 0.55 µg by maximums, i.e. only ≈ 8% - 9% of the extracellular amount, independently of the difference of Mw. But the number of captured molecules of polymeric DNA (1 × 10−1 pmol) is significantly less than the fragmented one (3.6 pmol). It is remarkable that the longer the time of conditioning the extracellular media is, the less the quantity of captured DNA is registered (Figure 3(a)). It is a sign of the wholeness of the uptake, i.e., an intracellular equilibrium between polymeric (acid-insoluble, reutilized) and degraded (acid-soluble) forms.
According to Figure 3(c), the transfer (Δ90) of exogenous DNA from media into cells 6 hours after their irradiation (8.7%, 1.1 × 10−1 pmole) is comparable with that for intact cells (6.1%, 7.9 × 10−2 pmol) in Figure 3(b). Thus, data 3b and 3c proof the ability of cells to consume large amounts of free DNA from extracellular space.
Does the template-free extracellular polymerization of deoxinucleotides, on the one hand, and consumption of the polymeric forms of DNA by cells, on the other hand, affect the viability of the cells, being the steps of a common mechanism?
Figure 4(a) shows that the low viability of cells at low concentration can be improved by conditioned media up to the level typical for cells suspension concentrated more than a hundredfold.
Figure 3. The uptake of exogenous 3H-DNA (6 μg/ml) by thymocytes (2.5 × 107/mL) from conditioned media (a) and spontaneous fragmentation of 3H-DNA outside the sells by 90th minute of incubation. Abscissa: (a) time of incubation of exogenous DNA with intact cells, minutes; (b) and (c) DEAE-fractions of 3H-DNA in conditioned media for intact cells (b) and cells 6 hours after their irradiation in vivo (c). White and black columns-fractions 5 and 6 correspondently, other fractions are not shown; B-original 3H-DNA before incubation (Mw ≈ 4.5 × 106 Da), WO and W-3H-DNA by 90th minute of incubation in media without cells (WO) or with them (W); Δ-total 3H-DNA captured by cells by 90th minute of the incubation. Ordinate: (a) radioactivity of acid-insoluble fraction of cells’ DNA, cpm. In the box: solid line-fractions of original (before incubation) 3H-DNA (Mw ≈ 4.5 × 106 Da), dotted line-original 3H-DNA after preliminary fragmentation (M.w. ≈ 1.5 × 105 Da), % in the media. (b) and (c) radioactivity of DEAE-fractions of labeled exogenous DNA in CM by 90th minute of incubation, cpm in white boxes. Patterned columns—the part of the total labeled DNA captured by cells: Δ90 = cpmWO − cpmW.
Figure 4. Phenomenon of thymocyte’s CM (a) and its simulation with exogenous unlabeled DNA (b) and (c). Abscissa: ((a), (b), (c)) time of incubation, minutes. Ordinate: (a) cells viability, %; circles-unconditioned media (control), rhombuses-preliminary Conditioned Media (CM) by 2 × 107 irradiated cells/mL; white symbols-1 × 105 cells/mL, black symbols-2 × 107 cells/mL; (b) and (c)) radioactivity of 3H-TdR incorporated into cellular DNA (acid-insoluble fraction). (b)-intact cells, (c)-irradiated in vivo cells; thick solid lines-without exogenous DNA, thin solid lines-fragmented DNA, added by 45th minute of incubation; dotted lines-additional 3H-TdR’ uptake in the presence of exogenous DNA. The approximating equations are in the boxes with corresponding line’s characters.
A low level of 3H-TdR incorporation is typical for irradiated cells (Figure 4(c)). Only for them, the small amounts of exogenous DNA added to media can increase the 3H-TdR uptake by cells significantly. The reproducing similar phenomenon with intact cells is impossible, though the same cell concentration (Figure 4(b)).
4. Discussion
Intracellular synthesis of dNTP is not autonomy, because missing metabolites or precursors can be imported into cells from neighboring cells or hemolymph. The mechanisms of such a rescue are uncovered [16].
The deficit of the intracellular pool of dNTP in the normal, embryonic and malignant tissues limits strongly cells proliferation via arrest the cycle in S-phase [17] [18]. The six hours after irradiation covers the phenomenon of reversible arrest in cell cycle progression, which is lasting about an hour for every 1 Gy delivered and resulting in a reduced mitotic index [19]. This time corresponds in situ to linear increasing of apoptotic cells number in irradiated gland from 0.8% - 1.8% to 3% - 11% [20], which accompanies by increasing of single-strand breaks (SSB) of cellular DNA [21].
Quick SSB repair by intracellular DNA-polymerase is completed as early as 1 - 0.75 hours after irradiation [22]. The chromatin of rat thymocytes selected 6 hours after total body irradiation, is already cleaved but has still not been eliminated, as one supposed [23]. Therefore, the maximal level of the high polymeric, acid-insoluble nucleoid in the media (Figure 1) appears in vitro due to the cell’s decay at the time of conditioning of CM.
Simultaneously, the maximal concentration of bulk optically active acid-soluble short fractions of nucleoid number 1 increase plainly from control level to 0.5 and 6 hours after irradiation, reflecting the destruction of dead cells during conditioning, which may deliver into CM around 100 - 120 pmol of dNTP per one million lysing cells [24] [25]. Accordingly, at real 6% - 8% apoptotic death of 2.3 × 108 thymocytes/ml, a maximal amount of endogenous dNTP can reach around 2 nmol/mL (2 × 10−6 M) in CM [19]. This amount of substrates is quite compatible with the average natural concentration of precursors of DNA synthesis in plasma and other extracellular fluids (the range of 0.4 - 6 μM) [18].
However, phosphorylating precursors, being negatively charged, are disable penetrate negatively charged cells membrane. One of the possible transporters of needed phosphorylated metabolites inside the cells is pinocytosis, can be thought of as an equal-opportunity importer. It contains surrounding extracellular fluid along with biopolymers and any negatively charged deoxinucleotides into membrane vesicles and imports them easily [26]. The TdT enzyme may be a link in this pathway, leading to restore the intracellular pools of deoxinucleotides and rescue the spontaneous death of young lymphocytes [27]. They migrated into target organs and tissues as lymphoid progenitors with morphogenic (trophic) function [28]. If to consider their apoptosis as physiological suicide (i.e. holocrine type of secretion), then cell-free DNA-primers [29] and TdT enzyme delivered in extracellular media can convert single extracellular deoxynucleotides into oligomers which are captured by neighboring cells, especially if they injured and needed in quick replenishment of exhausted pool of the phosphorylated precursors. Such transfer pinocytosis of blocking precursors is more effective than separated/single ones.
Apart from this general mechanism, the more specific function of TdT might be expected too. Among four deoxynucleosides triphosphate (dNTP), the concentrations of dGTP in dividing cells are 5 - 8 fold lower than in tree others dATP, dCTP, and dTTP [18] [25] [30]. Surprisingly, the preferred order of incorporation by TdT is dGTP > dCTP > dTTP > dATP [31], seeming as a process for compensation of intracellular deficit of dGTP. Tight control of the dNTP pool is essential for cellular homeostasis, especially for deoxyguanosine nucleotides during radiation [32] or chemical damages, for example, the therapeutic toxicant gemcitabine [33]. The deficit dGMP in lymphoid cells follows oxidative stress of different origins when the excess of reactive oxygen species (ROS) modifies normal precourses into mutagen 8-Oxo-7,8-dihydro-2-deoxyguanosine (8-oxo-dG). 8-oxo-dG is removed from the polymer by base excision repair and is excreted into the extracellular environment [34] [35].
Generally recognized the only intracellular function, as noted in the introduction, does not explain several biological features of TdT+ cells. Another forgotten but mysterious property of TdT+ lymphocytes is their mass and speed emigration from the gland in response to the somatic injury remoted distantly.
In parallel with artificial lymphocytopenia performed by extracorporeal irradiation of circulating blood, 55% of the TdT-positive cortical thymocytes leaves intact gland during 6 hours remotely. The speed of such devastation is highest: fifth-fold faster than the white pulp cells of intact spleen along with yet unchangeable pools of lymph nodes. Thus, by 6 hours after irradiation thymus cells population contains the excess of resistible and slowly mobilizable lymphocytes in medullae though the 45% of rest cortical cells and, probably, the resident progenitors coming from bone marrow, start already the repopulation of the devastated cortex [36].
5. Conclusions
Though the functional outcome of the TdT+ cells emigration looks nonsense in the view of intrathymic providing a variety of antigen receptors at the V(D)J junction of gene segment, the feeding/morphogenic function of these circulating cells for renewing the other tissues and organs seems logical. It follows from the property of TdT-positive young emigrating lymphocytes to achieve the other tissues and organs, dies via apoptosis/suicide/holocrine secretion, and take part in the renewing tissues of different histological types [37].
Future studies will undoubtedly shed more insight into the biological role and molecular mechanisms of young lymphocytes transient in different tissues of a body.
Acknowledgements
Aleksei N. Shoutko thanks the Ministry of Health Care of Russian Federation for financial support of this research.