|Year : 2018 | Volume
| Issue : 3 | Page : 291-296
Steroidogenesis and VEGF production doesn't alter in leydig cells within the homeostatic range of testicular temperature
Atul Kumar Goyal1, Jyoti Saini2
1 Department of Otolaryngology and Head Neck Surgery, Postgraduate Institute of Medical Education and Research, Chandigarh, India
2 Department of Biotechnology, National Institute of Pharmaceutical Education and Research, Guwahati, Assam, India
|Date of Web Publication||20-Nov-2018|
Atul Kumar Goyal
Department of Otolaryngology and Head Neck Surgery, Postgraduate Institute of Medical Education and Research, Chandigarh - 160 012
Source of Support: None, Conflict of Interest: None
| Abstract|| |
Context: Physiologically defined homeostatic temperature range for human testis falls within 32°C–37°C and any deviation outside that range can result in impaired steroidogenesis. However, whether temperature deviation within the homeostatic range can affect the steroidogenesis, is still a question of the investigation. Aim: In the present study, we investigated the production of progesterone, testosterone, and vascular endothelial growth factor (VEGF) within the homeostatic temperature range of testis, i.e., 32°C–37°C. Setting and Design: We used mouse Leydig tumor cells-1 (MLTC-1) cell line as a model in the present study. Materials and Methods: Progesterone and testosterone production by MLTC-1 cells was measured by radioimmunoassay and VEGF production was measured using ELISA. Statistical Analysis Used: Data were analyzed using GraphPad Prism software version 7.04. Student's t-test and ANOVA were used to calculate the P value. P < 0.05 was considered statistically significant. Results and Conclusions: Results of our study indicate that there is no significant difference in production of progesterone, testosterone, and VEGF within the homeostatic range of the testicular temperature. Thus, we concluded that testicular cells are able to regulate the steroidogenesis and VEGF production under the homeostatic range of the testicular temperature.
Keywords: Heat, Leydig cells, progesterone, testosterone, VEGF
|How to cite this article:|
Goyal AK, Saini J. Steroidogenesis and VEGF production doesn't alter in leydig cells within the homeostatic range of testicular temperature. J Hum Reprod Sci 2018;11:291-6
|How to cite this URL:|
Goyal AK, Saini J. Steroidogenesis and VEGF production doesn't alter in leydig cells within the homeostatic range of testicular temperature. J Hum Reprod Sci [serial online] 2018 [cited 2020 Nov 24];11:291-6. Available from: https://www.jhrsonline.org/text.asp?2018/11/3/291/245878
| Introduction|| |
Physiologically, the homeostatic temperature range for human testicular cells falls within the 32°C–37°C. This temperature homeostasis is necessary for normal testicular function and any deviation outside that conditions can have a profound effect on fertility. The homeostatic conditions of the testicular temperature is maintained by the countercurrent heat exchange system between incoming arterial blood and outgoing venous blood and consequent heat loss through the skin of the scrotum. A mild increase in the testicular temperature could be the potential contraceptive for men which was reported in the clinical conditions (cryptorchidism and varicocele) and certain occupations (bakers, welders, and professional drivers). Although it is well established that the deviation in temperature outside the homeostatic range can affect the testicular functions, whether the temperature deviation within the homeostatic range can have any effect, is still a question of the investigation. It is important to note that the minor changes in temperature, even in Fahrenheit, can disturb the physiology of body, but in the testis, there occurs a temperature range (32°C–37°C) with the difference of 5°C which could possibly affect the basic functions such as steroidogenesis. However, no study has shown any proof till date with respect to such concept; therefore, in the present study, we investigated the steroidogenesis within the homeostatic range of testicular temperature.
The process of steroidogenesis starts with the release of gonadotropin-releasing hormone from hypothalamus which acts on the anterior pituitary and stimulates it for releasing of luteinizing hormone (LH). LH acts on the Leydig cells by binding to the cell surface G protein-coupled receptors and activate adenylate cyclase, leading to the production of cyclic adenomonophosphate (cAMP), which in turn activates the protein kinase A (PKA). Activated PKA leads to the steroidogenesis and vascular endothelial growth factor (VEGF) production. Because both steroidogenesis and VEGF production appear to be dependent on the gonadotropin-stimulated cAMP formation, it is possible to postulate that the increased steroid formation by Leydig cells in response to the gonadotropic stimulation may be the trigger for the induction of VEGF which was reported as one of the key factors responsible for the fine regulation of cross-talk among the endocrine, endothelial, and gametogenic compartments of the testes. However, it is not known till date whether the deviation in testicular temperature can have any effect on the VEGF production, and therefore, we investigated the VEGF production in Leydig cells along with the steroidogenesis in the present study.
In our study, we hypothesise that steroidogenesis and VEGF production should show the significant difference at two extreme points of the homeostatic temperature range. Therefore, we study the difference in the progesterone, testosterone, and VEGF production at two different temperatures, i.e., 32°C and 37°C in the mouse Leydig tumor cells-1 (MLTC-1) in the basal conditions as well as by stimulating the cells through 8-bromoadenosine 3′,5′ (8-Br-cAMP).
| Materials and Methods|| |
MLTC-1 cells were used in the present study. The whole study was divided into two groups, i.e., basal and cAMP groups. In a basal group, cells were incubated separately at 32°C and 37°C for 6 h in the basal cell culture medium. In a cAMP group, 8-Br-cAMP was added in basal cell culture medium and then cells were incubated separately at 32°C and 37°C for 6 h. Temperature conditions of 32°C and 37°C were provided by maintaining respective temperatures in humidified Incubator.
Culture of MLTC-1 cells
MLTC-1 cells purchased from ATCC (Manassas, USA) were cultured in a T-75 flask in Waymouth MB 752/1 medium (Sigma-Aldrich, St. Louis, MO, USA) supplemented with 10% heat-inactivated fetal bovine serum (Sigma-Aldrich) at pH 7.3 at 37°C in 5% CO2 in a humidified incubator. All experiments for this study were conducted on MLTC-1 cells between passage numbers 10 and 30. The number of cells to be used in experiments was standardized and was seeded at a density of 2 × 105 cells/ml/well for estimating steroid and VEGF production.
MTT assay for cell viability test
Five milligrams of 3-(4,5-Dimethylthiazol-2-yl)-2,5-diphenyltetrazolium (MTT) was dissolved in 5 ml of phosphate-buffered saline. Fifty microliters of the solution was added to each well containing 450 μL of the fresh serum-free medium (SFM). The plate was incubated at 37°C in 5% CO2 for 4 h. The reaction was terminated by adding dimethyl sulfoxide. The supernatant was transferred to a 96-well plates. The plate was read at a wavelength of 570 nm using multidetector microplate reader.
2 × 105 cells/ml per well were plated in a serum-containing medium culture plate for 24 h. Thereafter, the medium was replaced with fresh SFM supplemented with 0.1% bovine serum albumin. Cells were then incubated with 1 mm 8-Br-cAMP (8-Bromoadenosine 3',5'-cyclic monophosphate) for 6 h. After that, the medium was removed and stored at −20°C till assayed for VEGF.
Progesterone and testosterone secretion was measured in cell supernatant by radioimmunoassay (RIA). Tritium-labeled radioactive progesterone and testosterone were obtained from Perkin Elmer (Waltham, MA, USA). Mouse monoclonal testosterone antibody (clone 4E1G2) and rabbit polyclonal progesterone antibody were procured from Bio-Rad (Hercules, CA, USA) and used at a dilution of 1:500.
VEGF secretion was measured in the cell supernatant using Mouse Quantikine VEGF ELISA kit from R&D Systems (Minneapolis, MN, USA) according to the manufacturer's instructions. This kit specifically measures mouse VEGF164 protein.
All the experiments were carried out at least in two replicates to ensure accuracy, and each experiment was performed at least twice to check the reproducibility. Data were analyzed using GraphPad Prism software version 7.04. Student's t-test and ANOVA were used to calculate the P value. P < 0.05 was considered statistically significant.
Present study does not contain any studies with human participants or animals, performed by any of the authors. We used commercially available established cell line which doe s not involve ethical concerns.
Language, grammar, and plagiarism
The references were inserted using EndNote software version 7.4. Language and grammar were checked by Grammarly software version 6.6. Plagiarism is corrected with the help of Plagiarism X software version 5.1. Present work was also edited by the professional proofreading and editing service (doc navigator, Chandigarh).
| Results|| |
Cell number standardization
The number of cells to be used during the experiments was standardized by initially taking the 0.5, 1, 2, and 4 lakhs cells and measuring the respective progesterone/testosterone produced by them. In the basal conditions, the cells did not show any significant difference in progesterone production, but in the cAMP group, the cells showed a major significant difference between 1 and 2 lakh cells and showed a minor difference between 2 and 4 lakh cells [Table 1] and [Figure 1]. In case of testosterone, a significant difference was observed between 1 and 2 lakhs in both basal and cAMP group [Table 1] and [Figure 2]. Based on these results, 2 lakh cells were taken as final cell number for further experiments as progesterone/testosterone production show minor change beyond this number.
|Table 1: Mean progesterone (ng/ml) and testosterone (ng/ml) production with respect to cell number in basal and cAMP group|
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|Figure 1: Mean progesterone (ng/ml) production with respect to cell numbers in basal and cAMP group (*** indicates P < 0.0001 and ** indicates P < 0.0095)|
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|Figure 2: Mean testosterone (ng/ml) production with respect to cell numbers in basal and cyclic adenomonophosphate group (* indicates P < 0.0327 and *** indicates P < 0.0001)|
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Cell viability analysis
The cell viability analyzed by MTT assay at two temperature conditions (32°C and 37°C) does not show any significant difference in the basal group as well as in cAMP group [Table 2] and [Figure 3]. The mean difference in cell viability in the basal group at 32°C and 37°C was 0.01 ± 0.1675 which is nonsignificant (P < 0.6645). Similarly, the mean difference in cell viability in the cAMP group was 0.025 ± 0.1491 which is also nonsignificant (P < 0.6502).
|Table 2: Mean optical density taken at 570 nm for the basal and cAMPe group at 32°C and 37°C. Optical density gives the indirect measure of cell viability|
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|Figure 3: Mean optical density taken at 570 nm for the basal and cAMP group at 32°C and 37°C. Optical density gives the indirect measure of cell viability|
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Progesterone production does not show any difference in two temperature conditions (32°C and 37°C) in basal as well as in a cAMP group [Table 3] and [Figure 4]. The mean difference in progesterone production in the basal group at 32°C and 37°C was 0 ± 0.1155 which is nonsignificant (P < 0.5340). Similarly, the mean difference in the cAMP group was 0.375 ± 1.978 which was also nonsignificant (P < 0.4154).
|Table 3: Mean progesterone (ng/ml) produced by MLTC-1 cells in basal and cAMP group at 32°C and 37°C|
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|Figure 4: Mean progesterone (ng/ml) production by MLTC-1 cells in basal and cAMP group at 32°C and 37°C|
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Testosterone production does not show any difference in two temperature conditions (32°C and 37°C) in basal as well as in a cAMP group [Table 4] and [Figure 5]. The mean difference in progesterone production in the basal group at 32°C and 37°C was 0.01 ± 0.01904 which is nonsignificant (P < 0.1976). Similarly, the mean difference in the cAMP group was −0.3 ± 0.3182 which was also nonsignificant (P < 0.9581).
|Table 4: Mean progesterone (ng/ml) produced by MLTC-1 in basal and cAMP group at 32°C and 37°C|
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|Figure 5: Mean testosterone (ng/ml) production by MLTC-1 cells in basal and cAMP group at 32°C and 37°C|
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Measurement of VEGF
VEGF production also does not show any difference at two temperature conditions (32°C and 37°C) in basal as well as in a cAMP group [Table 5] and [Figure 6]. The mean difference in VEGF production in the basal group at 32°C and 37°C was 13.37 ± 16.57 which is nonsignificant (P < 0.6227). Similarly, the mean difference in the cAMP group was 12.03 ± 14.69, which was also nonsignificant (P < 0.7100).
|Table 5: Mean VEGF (pg/ml) produced by MLTC-1 in basal and cAMP group at 32°C and 37°C|
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|Figure 6: Mean VEGF (pg/ml) production by MLTC-1 cells in basal and cAMP group at 32°C and 37°C|
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| Discussion|| |
Recent studies on the effects of heat on the testis in humans, either applied directly, by insulating the scrotum or by making the testis cryptorchid have provided information on harmful effects of temperature deviation on testicular functions. Apart from humans, several rodent models have been used to study the impact of heat stress on the testis including transient exposure of the testes to elevated temperatures (typically >40°C), surgical induction of cryptorchidism resulting in long-term exposure of the testes to core body temperature (37°C), or housing of males at elevated temperatures (e.g., 35°C–36°C) for several hours and all of them suggested the similar results. Although the link between increases in testicular temperature and impaired spermatogenesis is well established, it is not clearly established whether or not the steroidogenic function of the Leydig cells is affected by elevated temperature. The study of steroidogenesis in Leydig cells is requisite because the process of spermatogenesis ultimately depends on Leydig cells for an adequate supply of testosterone. Therefore, we conducted the present study which is exclusively focused around the steroidogenesis in Leydig cells.
In the previous study, it has been shown that, when gonadal cells subjected to heat shock, they faced the impaired steroidogenesis. The testosterone level in blood was found to be reduced in rats after exposure to a hot bath at 43°C for 10 min. Adult rats, when subjected to a single local testicular heat treatment of water at 43°C for 30 min, lead to insufficient testosterone biosynthesis. The mechanism behind the impaired steroidogenesis could be the disturbance in the cytosolic lipid pool reserve of Leydig cells. Cholesterol in the Leydig cells is stored as lipid droplets and a disruption of lipid droplet homeostasis can affect steroid hormone production by Leydig cells. Several large lipid drops were detected in Leydig cells of rats subjected to heat treatment when compared with nonexposed rats in which few small lipid droplets were detected. Disrupted lipid metabolism by raised testicular temperature further can lead to endocrine disturbance. However, our study suggests that Leydig cells is are able to produce testosterone generally within homeostatic limits of testicular temperature.
Leydig cell viability following a heat shock is least studied area and most of the studies primarily focused on the germ cells and some of them on the Sertoli cells More Details. Leydig cell viability was found to be not affected within the homeostatic range of testicular temperature in our study which is consistent with the available literature. Although VEGF plays several essential roles in the maintenance of testicular functioning such as it facilitates blood-borne hormones and nutritional elements transport, stimulates Leydig cell proliferation and testosterone secretion, and regulates spermatogenesis, but overexpression of VEGF in the testes can also lead to a massive disruption of spermatogenesis. Till date, only a few studies are available establishing the relation of heat stress to the VEGF production. It has been documented that the VEGF pathway may play a role in neutralized the heat stress in the testicular cells. The detailed pathway by which VEGF act is not well understood, but still there is evidence suggesting that the scrotal heating may activate the testicular stress responses by increasing the expression of hypoxia-inducible factor 1 alpha which further induced the VEGF expression. In the present study, we also tried to investigate whether VEGF production alters within homeostatic range of the testicular temperature or not and found that it remains unaltered.
The aspect which makes our study unique is that we investigated the steroidogenesis and VEGF production within the homeostatic range of testicular temperature not by providing heat or cold shock. That was important because restricting the experiments under consideration of physiological limits is much relevant than to performing them outside the physiological limits of the body. To the best of our knowledge, the current study is the first study in which the effect of temperature on steroidogenesis and VEGF production was investigated within a homeostatic range. Although the results from our study is not same as our hypotheses, still, the present study gives important information about testis microenvironment.
| Conclusions|| |
Although several studies had been conducted to investigate the effect of temperature on the testicular functions, the main question still remains unanswered, is there any effect on the testicular function within the homeostatic range of testicular temperature. The present study put forward an evidence-based answer to the question by showing that the steroidogenesis and VEGF production does not alter within the homeostatic range of the testicular temperature.
The study was carried out at the Department of Reproductive Biology, All India Institute of Medical Science, New Delhi, by the first author who is formerly a Research Fellow in that institute. Authors highly acknowledge institute for providing laboratory facilities to carry out the present study. Authors also acknowledge all the colleagues who reviewed the present work.
Financial support and sponsorship
The present work was funded by the department's internal funds provided by the institution and Junior Research Fellowship (JRF) provided by ICMR, New Delhi wide file no. 3/13/JRF -2015/HRD.
Conflicts of interest
The authors declare that the research was conducted in the absence of any commercial or financial relationships that could be construed as a potential conflict of interest.
Atul K Goyal designed and conducted the experiments and, generated the raw data. Jyoti Saini compiled the raw data, did the statistical analysis and drafted the manuscript.
| References|| |
Paul C, Murray AA, Spears N, Saunders PT. A single, mild, transient scrotal heat stress causes DNA damage, subfertility and impairs formation of blastocysts in mice. Reproduction 2008;136:73-84.
Thonneau P, Bujan L, Multigner L, Mieusset R. Occupational heat exposure and male fertility: A review. Hum Reprod 1998;13:2122-5.
Nakamura M, Namiki M, Okuyama A, Matsui T, Doi Y, Takeyama M, et al.
Temperature sensitivity of human spermatogonia and spermatocytes in vitro
. Arch Androl 1987;19:127-32.
Anand RJ, Paust HJ, Altenpohl K, Mukhopadhyay AK. Regulation of vascular endothelial growth factor production by leydig cells in vitro
: The role of protein kinase A and mitogen-activated protein kinase cascade. Biol Reprod 2003;68:1663-73.
Setchell B. The effects of heat on the testes of mammals. Anim Reprod 2006;3:81-91.
Murphy BD, Lalli E, Walsh LP, Liu Z, Soh J, Stocco DM, et al.
Heat shock interferes with steroidogenesis by reducing transcription of the steroidogenic acute regulatory protein gene. Mol Endocrinol 2001;15:1255-63.
Hwang EC, Min KD, Jung SI, Ryu SB, Ahn KY, Lee K, et al.
Testicular steroidogenesis is decreased by hyperthermia in old rats. Urol Int 2010;84:347-52.
Li Z, Tian J, Cui G, Wang M, Yu D. Effects of local testicular heat treatment on leydig cell hyperplasia and testosterone biosynthesis in rat testes. Reprod Fertil Dev 2015;28:1424-32.
Miller WL, Bose HS. Early steps in steroidogenesis: Intracellular cholesterol trafficking. J Lipid Res 2011;52:2111-35.
Danno S, Itoh K, Matsuda T, Fujita J. Decreased expression of mouse Rbm3, a cold-shock protein, in Sertoli cells of cryptorchid testis. Am J Pathol 2000;156:1685-92.
Hwang GS, Wang SW, Tseng WM, Yu CH, Wang PS. Effect of hypoxia on the release of vascular endothelial growth factor and testosterone in mouse TM3 leydig cells. Am J Physiol Endocrinol Metab 2007;292:E1763-9.
Sargent KM, Clopton DT, Lu N, Pohlmeier WE, Cupp AS. VEGFA splicing: Divergent isoforms regulate spermatogonial stem cell maintenance. Cell Tissue Res 2016;363:31-45.
Garolla A, Torino M, Sartini B, Cosci I, Patassini C, Carraro U, et al.
Seminal and molecular evidence that sauna exposure affects human spermatogenesis. Hum Reprod 2013;28:877-85.
[Figure 1], [Figure 2], [Figure 3], [Figure 4], [Figure 5], [Figure 6]
[Table 1], [Table 2], [Table 3], [Table 4], [Table 5]