بازسازی شبکه ژن‌های هم‌بیان مرتبط با رشد و تکامل فولیکول‌های الیاف در جنین بز کرکی

برازنده, ارسلان; مختاری, مرتضی; بهدانی, الهام; رودباری, زهرا

doi:10.22067/ijasr.v12i2.81710

بازسازی شبکه ژن‌های هم‌بیان مرتبط با رشد و تکامل فولیکول‌های الیاف در جنین بز کرکی

نوع مقاله : علمی پژوهشی- ژنتیک و اصلاح دام و طیور

نویسندگان

¹ گروه علوم دامی، دانشکده کشاورزی، دانشگاه جیرفت، جیرفت، ایران.

² دانشگاه دانشگاه کشاورزی و منابع طبیعی رامین ، خوزستان، ایران.و منابع طبیعی رامین ، خوزستان

10.22067/ijasr.v12i2.81710

چکیده

فولیکول مو قسمتی از پوست است که مو را تولید و چرخه رشد مو را کنترل می‌کند. فولیکول مو مرکزی برای رشد الیاف مهم از نظر اقتصادی در صنعت دامپروری است. مطالعات نشان داده‌اند که تغییرات در سطح بیان ژن ها در رشد و نمو فولیکول مو تاثیر دارد. با وجود پیشرفت های اخیر در شناسایی شبکه های هم بیانی ژن ها و سیگنال های مولکولی که بر توسعه پوست و رشد فولیکول مو حاکم است، مکانیسم های تنظیم کننده ساخت الیاف بز کرکی، هنوز شناسایی نشده است. از این‌رو، پژوهش کنونی برای بررسی مهمترین مولکولهای کنترل کننده رشد و نمو فولیکولهای الیاف در بز کرکی و رمزگشایی ژن های درگیر در رشد و نمو فولیکول‌های الیاف انجام شد. به این منظور، از دادههای مربوط به توالی یابی رونوشت های پوست جنین بزهای کرکی شانبی در سه مرحله رشد استفاده شد. آنالیز بیان افتراقی رونوشت ها نشان داد که در تمام طول روند رشد فولیکول بیان 145 ژن افزایش و بیان 650 ژن کاهش داشته است. از بین ژن‌هایی با بیان افتراقی، ژنهای تنظیمی هم بیان بر اساس نتایج واکاوی پارامترهای آماری شبکه و مستند سازی کارکردی شناسایی شدند که شامل: SHH، KLF4، MMP9،MSX1، KRT17 ، COL2A1و VEGFA بودند. بر اساس نتایج حاصل از پژوهش کنونی ژن هایی با اثرات عمده شناسایی شدند که تنظیم کننده شبکه‌های بیانی ژن ها و سیگنال‌های مولکولی مرتبط با ساخت الیاف بز کرکی هستند. این ژن ها با توجه به مستند سازی عملکردی می توانند نقش قابل توجهی در بهبود اصلاح نژاد بز کرکی ایفا کنند.

کلیدواژه‌ها

20.1001.1.20083106.1399.12.2.7.6

عنوان مقاله [English]

Reconstruction of genes co-expression network related to the growth and development of fiber follicle in Cashmere goat fetus

نویسندگان [English]

Arsalan Barazandeh ¹
Morteza Mokhtari ¹
Elham Behdani ²
Zahra Roudbari ¹

¹ Department of Animal Science, Faculty of Agriculture, University of Jiroft, Jiroft, Iran,

چکیده [English]

Introduction[1] In most mammals, each hair follicle is a mammalian skin organ that produces hair and controls the hair growth cycle. The hair follicle is central to most economically important fiber growth in livestock. Previous studies have shown that changes in the level of genes expression play a role in the development and growth of hair follicles. With the advent of high throughput, next-generation sequencing technology measuring the level of expression of thousands of genes was possible simultaneously. As a result, many regulatory conflicts between genes can be extracted from these data. Expression profiles are generated by combining expression levels resulting from experiments in various conditions or times. Similarities and differences between expression profiles reveal many of these regulatory relationships. Despite recent advances in the identification of the molecular signaling/co-expression networks that govern the development of the skin and hair follicle, the mechanisms controlling of fiber production in Cashmere goat still remains unclear. Therefore, the present study was conducted to investigate the most important molecules controlling the growth and development of hair follicles in cashmere goats in order to decode the genes involved in the growth and development of hair follicles in cashmere goats.
Materials and Methods Publicly available preprocessed transcript data (accession no. SRP059481) was downloaded from the NCBI database in the SRA section. In this investigation, nine goats were selected at the same stage of gestation. Three fetuses were obtained at 55-65 days’ gestation (60-days old) and three fetuses were obtained at 105-125 days’ gestation (120 –day- old) through cesarean operation and three fetuses were also sacrificed within two hours of birth (newborn). For analysis of RNA-seq data, a random sampling from the right mid-side of the fetal skin and each time point had three replicates. The 60 days (E60) of gestation represented the initiation stage of growth, and the 120 d (E120) represented the development stage, as well as the newborn samples, represented the primary hair follicle maturation stage. The FastQC software (Version 11.7) was used to check the quality of the readings. This software check the quality of the reads, in case of low-quality sequencing, the data were edited by Trimmomatic software (Version 0.39), and filtered reads were evaluated with FastQC software, After removing low-quality reads mapping was performed on the goat reference genome (GCA_001704415.1) downloaded from the ensemble site using the Hisat2 software(Version 2.1.0). The HTSeq2 (Version 10.0) was used to create the count matrix, changes in the expression of genes between the groups (E60, E120, and newborns) was identified using the software Deseq2 (Version 1.24). In this stage, the genes between the two groups were compared to give an expression difference 1- Genes that are expressed throughout the growth process of the follicle 2. Co-Expression networks of up and down genes were created using the STRING database (Version 11) at https://string-db.org. The PPI network was constructed by Cytoscape software (Version 3.6.0). Cytoscape is commonly used for analysis and visualization of biological networks. Gene ontology analysis of effective gene related to development stage of hair follicle in Cashmere goat from fetal to birth was done using DAVID database.
Results and Discussion After determining the level of expression of each gene at different stages of sampling, genes that increased expression in all comparisons were considered as up-regulated genes that, by increasing their expression, control the growth and development of hair follicle. On the other hand, those genes that have been shown to reduce expression in all of the follicle growth stages comparisons were considered as genes which by decreasing their expression, causes the growth and development of the hair follicle. The interaction relations were investigated between the increased and reduced genes expressed separately by STRING database. Among the up-regulated genes, the relationships between 145 genes with 203 edge were confirmed. Also, the interaction network between the down-regulated genes confirmed between 650 genes with 1302 edge. Among the genes with differential expression, the co-expression genes (genes with the most interacting) were identified based on the results of the analysis of the statistical parameters of the network using computational algorithms in Cytoscape software. These results led to the identification of seven unique genes that were SHH, KLF4, MMP9, MSX1, KRT17, COL2A1 and VEGFA, ontology analysis of these genes showed that involved the hair cycle process, hair follicle development, skin epidermis development, epidermis morphogenesis and epidermal cell differentiation that these pathways are activated in the cashmere production process. Therefore, these genes have been used as regulators of cashmere growth and development to better understand the cashmere production process and improve its quality.
Conclusion The results have been able to introduce genes with major effects that regulate the expression of genes and molecular signals associated with the production of fiber that including KLF4, MMP9, MSX1, KRT17, COL2A1 and VEGFA in Cashmere goats. Based on functional analysis, these genes can play a significant role in the improvement of cashmere goats breeding. We hope that the obtained results would be beneficial toward finding the smart strategies for Cashmere production improvement.

کلیدواژه‌ها [English]

Cashmere goat
Differential expression
Regulatory network
Transcriptome analysis

مراجع

1- Anders, S., P. T. Pyl, and W. Huber. 2015. HTSeq--a Python framework to work with high-throughput sequencing data. Bioinformatics (Oxford, England), 31 (2): 166–169.

2- Ansari-renani, H. R., Z. Ebadi, S. Moradi, H. R. Baghershah, M. Y. Ansari-renani, and S. H. Ameli. 2011. Determination of hair follicle characteristics , density and activity of Iranian cashmere goat breeds. Small Ruminant Research, 95 (2–3): 128–132.

3- Ayaz, A., Z. Iqbal, B. Ahmad, N. A. Ganai, N. Singh, A. Ali, T. Mumtaz, M. A. Dar, M. Shabir, and S. Shanaz. 2017. Impact of high glycine tyrosine KAP genes on Cashmere fibre trait characteristics. Biotechnology Journal International, 19 (3): 1–5.

4- Barazandeh, A., S. M. Moghbeli, N. G. Hossein-Zadeh, and M. Vatankhah. 2012. Genetic evaluation of growth in Raini goat using random regression models. Livestock Science, 145 (1–3): 1–6.

5- Blin-Wakkach, C., F. Lezot, S. Ghoul-Mazgar, D. Hotton, S. Monteiro, C. Teillaud, L. Pibouin, S. Orestes-Cardoso, P. Papagerakis, and M. Macdougall. 2001. Endogenous Msx1 antisense transcript: in vivo and in vitro evidences, structure, and potential involvement in skeleton development in mammals. Proceedings of the National Academy of Sciences, 98 (13): 7336–7341.

6- Bolger, A. M., M. Lohse, and B. Usadel. 2014. Trimmomatic: a flexible trimmer for Illumina sequence data. Bioinformatics (Oxford, England), 30 (15): 2114–2120.

7- Dosch, R. 2015. Next generation mothers: maternal control of germline development in zebrafish. Critical Reviews in Biochemistry and Molecular Biology, 50 (1): 54–68.

8- Gao, Y., X. Wang, H. Yan, J. Zeng, S. Ma, Y. Niu, G. Zhou, Y. Jiang, and Y. Chen. 2016. Comparative transcriptome analysis of fetal skin reveals key genes related to hair follicle morphogenesis in cashmere goats. PLoS ONE, 11 (3): 1–20.

9- Geng, R., C. Yuan, and Y. Chen. 2013. Exploring differentially expressed genes by RNA-Seq in cashmere goat (Capra hircus) skin during hair follicle development and cycling. PloS One, 8 (4): e62704.

10- Georgantas, R. W., V. Tanadve, M. Malehorn, S. Heimfeld, C. Chen, L. Carr, F. Martinez-Murillo, G. Riggins, J. Kowalski, and C. I. Civin. 2004. Microarray and serial analysis of gene expression analyses identify known and novel transcripts overexpressed in hematopoietic stem cells. Cancer Research, 64 (13): 4434–4441.

11- Gong, H., H. Wang, Y. Wang, X. Bai, B. Liu, J. He, J. Wu, W. Qi, and W. Zhang. 2018. Skin transcriptome reveals the dynamic changes in the Wnt pathway during integument morphogenesis of chick embryos. PloS One, 13 (1): e0190933.

12- Jiang, J., and C. Hui. 2008. Hedgehog signaling in development and cancer. Developmental Cell, 15 (6): 801–812.

13- Kim, D., B. Langmead, and S. L. Salzberg. 2015. HISAT: a fast spliced aligner with low memory requirements. Nature Methods, 12 (4): 357–360.

14- Li, J., H. Zheng, J. Wang, F. Yu, R. J. Morris, T. C. Wang, S. Huang, and W. Ai. 2012. Expression of Kruppel-like factor KLF4 in mouse hair follicle stem cells contributes to cutaneous wound healing. PLoS ONE, 7 (6): e39663–e39663.

15- Liu, B., F. Gao, J. Guo, D. Wu, B. Hao, Y. Li, and C. Zhao. 2016. A microarray-based analysis reveals that a short photoperiod promotes hair growth in the Arbas Cashmere goat. PloS One, 11 (1): e0147124–e0147124.

16- Liu, G., R. Liu, X. Tang, J. Cao, S. Zhao, and M. Yu. 2015. Expression profiling reveals genes involved in the regulation of wool follicle bulb regression and regeneration in sheep. International Journal of Molecular Sciences, 16 (5): 9152–9166.

17- Liu, H., C.-W. Yue, W. Zhang, X. Zhu, G. Yang, and Z. Jia. 2011. Association of the KAP 8.1 gene polymorphisms with fibre traits in inner mongolian cashmere goats. Asian-Australasian Journal of Animal Sciences, 24 (10): 1341–1347.

18- Love, M. I., W. Huber, and S. Anders. 2014. Moderated estimation of fold change and dispersion for RNA-seq data with DESeq2. Genome Biology, 15 (12): 550.

19- Nie, Y., S. Li, X. Zheng, W. Chen, X. Li, Z. Liu, Y. Hu, H. Qiao, Q. Qi, and Q. Pei. 2018. Transcriptome reveals long non-coding RNAs and mRNAs involved in primary wool follicle induction in carpet sheep fetal skin. Frontiers in Physiology, 9 446.

20- Nothnick, W. B. 2008. Regulation of uterine matrix metalloproteinase-9 and the role of microRNAs. Seminars in Reproductive Medicine, 26 (6): 494–499.

21- Ozeki, M., and Y. Tabata. 2003. In vivo promoted growth of mice hair follicles by the controlled release of growth factors. Biomaterials, 24 (13): 2387–2394.

22- Qiao, X., J. H. Wu, R. B. Wu, R. Su, C. Li, Y. J. Zhang, R. J. Wang, Y. H. Zhao, Y. X. Fan, and W. G. Zhang. 2016. Discovery of differentially expressed genes in cashmere goat (Capra hircus) hair follicles by RNA sequencing. Genetics and Molecular Research, 15 (3): gmr.15038589.

23- Qu, B. O., Y. Qiu, Z. Zhen, and F. Zhao. 2016. Computational identification and characterization of novel microRNA in the mammary gland of dairy goat ( Capra hircus ). 95 (3): 1–31.

24- Sennett, R., and M. Rendl. 2012. Mesenchymal–epithelial interactions during hair follicle morphogenesis and cycling. Seminars in Cell and Developmental Biology Developmental Biology, 23 (8): 917–927.

25- Shannon, P., A. Markiel, O. Ozier, N. S. Baliga, J. T. Wang, D. Ramage, N. Amin, B. Schwikowski, and T. Ideker. 2003. Cytoscape: a software environment for integrated models of biomolecular interaction networks. Genome Research, 13 (11): 2498–2504.

26- Sharov, A. A., M. Schroeder, T. Y. Sharova, A. N. Mardaryev, E. M. J. Peters, D. J. Tobin, and V. A. Botchkarev. 2011. Matrix metalloproteinase-9 is involved in regulation of the hair canal formation. The Journal of Investigative Dermatology, 131 (1): 257.

27- Song, S., M. Yang, Y. Li, M. Rouzi, Q. Zhao, Y. Pu, X. He, J. M. Mwacharo, N. Yang, Y. Ma, and L. Jiang. 2018. Genome-wide discovery of lincRNAs with spatiotemporal expression patterns in the skin of goat during the cashmere growth cycle. BMC Genomics, 19 (1): 1–12.

28- St-Jacques, B., H. R. Dassule, I. Karavanova, V. A. Botchkarev, J. Li, P. S. Danielian, J. A. McMahon, P. M. Lewis, R. Paus, and A. P. McMahon. 1998. Sonic hedgehog signaling is essential for hair development. Current Biology, 8 (19): 1058–1069.

29- Stelnicki, E. J., M. R. Harrison, D. Holmes, N. S. Adzick, L. G. Kömüves, W. Clavin, and C. Largman. 1997. The human homeobox genes MSX-1, MSX-2, and MOX-1 are differentially expressed in the dermis and epidermis in fetal and adult skin. Differentiation, 62 (1): 33–41.

30- Temizkan, M. C., and A. G. Bayraktaroglu. 2017. Effective Gene on Hair Follicle Growth. Mae Vet Fak Derg, 2 (1): 61–73.

31- Wang, L., Y. Zhang, M. Zhao, R. Wang, R. Su, and J. Li. 2015. SNP discovery from transcriptome of cashmere goat skin. Asian-Australasian Journal of Animal Sciences, 28 (9): 1235.

32- Yang, M., S. Song, K. Dong, X. Chen, X. Liu, M. Rouzi, Q. Zhao, X. He, Y. Pu, W. Guan, Y. Ma, and L. Jiang. 2017. Skin transcriptome reveals the intrinsic molecular mechanisms underlying hair follicle cycling in Cashmere goats under natural and shortened photoperiod conditions. Scientific Reports, 7 (1): 1–12.

33- Yano, K., L. F. Brown, and M. Detmar. 2001. Control of hair growth and follicle size by VEGF-mediated angiogenesis. The Journal of Clinical Investigation, 107 (4): 409–417.