The role of MicroRNAs as fine-tuners in the onset of puberty: a comprehensive review

Article information

Ann Pediatr Endocrinol Metab. 2024;29(4):211-219
Publication date (electronic) : 2024 August 31
doi : https://doi.org/10.6065/apem.2346238.119
1Department of Pediatrics, Soonchunhyang University College of Medicine, Cheonan, Korea
2Department of Pediatrics, Kangdong Sacred Heart Hospital, Hallym University College of Medicine, Seoul, Korea
Address for correspondence: Il Tae Hwang Department of Pediatrics, Kangdong sacred Heart Hospital, Hallym University College of Medicine, 150 Seonganro, Gangdong-gu, Seoul, 05338, Korea Email: ithwang83@hallym.or.kr
Received 2023 November 29; Revised 2024 January 19; Accepted 2024 February 6.

Abstract

MicroRNA (miRNA) are small, noncoding RNA molecules that play pivotal roles in gene expression, various biological processes, and development of disease. MiRNAs exhibit distinct expression patterns depending on time points and tissues, indicating their relevance to the development, differentiation, and somatic growth of organisms. MiRNAs are also involved in puberty onset and fertility. Although puberty is a universal stage in the life cycles of most organisms, the precise mechanisms initiating this process remain elusive. Genetic, hormonal, nutritional, environmental, and epigenetic factors are presumed contributors. The intricate regulation of puberty during growth also suggests that miRNAs are involved. This study aims to provide insight into the understanding of miRNAs roles in the initiation of puberty by reviewing the existing research.

Highlights

· This study explores the impact of miRNAs on the onset of central precocious puberty (CPP), with a particular focus on the roles of various miRNAs, including the Lin28/let-7 system, miR-200, miR-29, miR-30, miR-505-3p, and others.

· The research highlights how miRNAs act as key regulators in different pathways that control the initiation of puberty in the hypothalamus.

· The expression patterns of miRNAs indicate their potential as biomarkers for CPP, and targeting these miRNAs may contribute to the development of new diagnostic methods.

Introduction

Puberty is a pivotal milestone in both sexual and somatic maturation, marking a significant phase in an individual's life cycle [1]. Unsurprisingly, the orchestration of puberty involves a sophisticated network of regulatory signals from central and peripheral sources, ensuring its timely occurrence and appropriate response to endogenous variables and environmental cues [1-6]. Puberty is intricately linked to preceding developmental events, such as brain sexual differentiation [7], which represents the process leading to reproductive competence. Recent advances in systems biology have gradually unveiled sets of genes and proteins that have the potential to globally regulate the timing of puberty [2]. Puberty emerges as a result of the harmonious and hierarchical activation/inactivation of excitatory and inhibitory networks rather than being a consequence of a single trigger. The regulation of these networks requires precise and multifaceted control mechanisms, which are not yet fully elucidated.

MicroRNAs (miRNA) are short noncoding RNAs that bind to the 3'-untranslated regions (UTR) of target genes. They play a crucial role in modulating gene expression by either targeting mRNAs for deregulation or causing translational repression [8]. MiRNA biogenesis (Fig. 1) is a complex and tightly regulated process that results in the production of the small RNA molecules. MiRNAs play a crucial role in posttranscriptional gene regulation by binding to specific messenger RNA (mRNA) molecules, influencing their stability and translation. The process of miRNA biogenesis begins in the nucleus, where miRNA genes are transcribed by RNA polymerase II to generate primary miRNA transcripts (pri-miRNAs). Pri-miRNAs can be transcribed as independent genes or can be part of introns within protein-coding genes. The pri-miRNA transcript typically forms hairpin structures with stem and loop regions. The microprocessor complex, which consists of the RNA III enzyme Drosha and its cofactor DiGeorge syndrome critical region gene 8, recognizes and cleaves the stem-loop structure in the nucleus, generating precursor miRNAs (pre-miRNAs). Pre-miRNAs are short hairpin structures with a characteristic stem-loop. Exportin-5, a nuclear transport receptor, transports pre-miRNAs from the nucleus to the cytoplasm. In the cytoplasm, the enzyme Dicer further processes pre-miRNAs by recognizing their structure and cleaving it into a short double-stranded RNA molecule, which is typically approximately 22 nucleotides in length. One strand of the short RNA duplex, known as the guide strand, is selected to be incorporated into the NRA-inducing silencing complex (RISC). The RISC complex is a key player in the miRNA-mediated gene silencing mechanism. The guide strand of the miRNA within the RISC complex binds to the 3’ UTR of target mRNAs through partial sequence complementarity. This binding can lead to mRNA degradation or translational repression depending on the degree of complementarity. If the miRNA is perfectly complementary to its target mRNA, it can induce mRNA degradation. If there is imperfect complementarity, it usually results in translational repression without mRNA degradation. The entire process of miRNA biogenesis is highly regulated; its dysregulation can have significant impacts on cellular processes and contribute to various diseases. MiRNA play essential roles in the regulation of gene expression and are involved in various biological processes, including development, cell differentiation, and response to environmental stimuli.

Fig. 1.

Biogenesis of microRNA. miRNA, microRNA; mRNA, messenger RNA; RISC, NRA-inducing silencing complex.

With finely regulated expression and the ability to modulate numerous target genes, miRNAs emerge as promising candidates for regulating complex biological processes such as puberty. Notably abundant in the brain, miRNAs function as 'master regulators' or 'fine-tuners' of gene expression, contributing to regulatory roles spanning from neuronal development to various functions [9]. Despite suggestive evidence from Genome-Wide Association Studies (GWAS) and functional genomic studies, the direct involvement of miRNA regulatory pathways, particularly the Lin28/let-7 system, in orchestrating the central developmental events leading to pubertal activation remains unexplored. More than 210 miRNAs have been detected in the arcuate (ARC) and paraventricular (PVN) nuclei of the rat hypothalamus [10], where the machinery modulating puberty onset is located; however, only a small portion of them appears to regulate puberty onset in mammals based on direct evidence. Experimenting with the regulation processes of puberty using actual mammalian hypothalamic tissue is challenging. As an alternative, GT1-7 cells are widely employed in numerous studies. These cells, derived from mouse hypothalamic neurons, are immortalized GnRH neurons that offer an ideal model system for investigating the regulation of Gnrh1 expression. While the majority of studies predominantly relies on animal experiments or experiments using GT1-7 cells, in this review, we aim to discuss the expression patterns of miRNA and their potential role in regulating the onset of puberty.

Lin28/let-7 miR system

GWAS have suggested the potential involvement of the Lin28/let-7 axils in the control of puberty. These investigations have unveiled a plausible link between variations in or around the LIN28b locus and alterations in crucial developmental processes in humans. Lin28b, in conjunction with several targets of let-7, is associated with variations in human height [11]. LIN28b is involved in the regulation of growth and the age of menarche in humans [12-14].

Lin28, which was initially discovered in the nematode Caenorhabditis elegans (C. elegans), exhibits distinct patterns of expression specific to the particular tissue and developmental stage. Mutations in Lin28 lead to either accelerated or delayed maturational events [15]. Lin28 paralogs exhibit a high degree of conservation across evolutionary timelines, suggesting similar regulatory functions. In mammals, 2 Lin28-related genes called Lin28 and Lin 28b have been identified. Lin28 and Lin28b are RNA-binding proteins that share a common function in suppressing the maturation of miRNAs belonging to the let-7 family. While Lin28 is broadly expressed during embryonic development, its expression is confined to specific tissues in adulthood [16]. The let-7 miRNAs are known for their remarkable conservation, being widely and abundantly expressed across numerous species [17]. Members of the let-7 family, along with Lin28 counterparts, play a pivotal role in regulating essential developmental events in various species, including mammals.

In recent studies, the dynamic interplay of Lin28/Lin28b, c-Myc, and let-7 has emerged as a key regulator orchestrating diverse cellular pathways [18]. The Lin 28 proteins have been demonstrated to bind to the terminal loops of precursors of the let-7 family of miRNAs; in doing so, the Lin28 proteins inhibit the formation of mature miRNAs [19]. Redundant Lin28/Lin28b represses the synthesis of mature let-7 miRNAs, which can suppress Lin28 levels. Additionally, one of the upstream regulators in the c-Myc/Lin28/let-7 axis, mir-145, inhibits c-Myc expression at the posttranscriptional level [20]. Moreover, Lin28/Lin28b downregulates c-Myc by suppressing mature let-7 synthesis; c-Myc, in turn, transcriptionally activates the expression of both Lin28 and Lin28b [18]. Bioinformatics analyses have suggested that miR-132 and miR-9 are potential miRNA that could repress Lin28.

In both male and female rats, the mRNAs of Lin28 and Lin28b, as well as c-Myc, exhibit prominent expression in the hypothalamus during the neonatal period. However, this expression significantly decreases during the transition from infancy to juvenility and reaches minimal levels around or before puberty. Notably, experiments involving Lin28 overexpression in mice have validated the presumed function of Lin 28 members in the regulation of postnatal growth and puberty. The outcome of Lin28 overexpression in mice includes delayed puberty and increased body size, providing further evidence of the involvement of Lin28 members in these developmental processes [21].

Previous studies have demonstrated that miR-145 suppresses c-Myc expression, leading to a reduction in Lin28/Lin28b transcription and consequently allowing the maturation of the let-7 family of miRNAs to proceed without inhibition [20,22]. In adult rats, miRNA of the let-7 family are notably more highly expressed in the hypothalamic arcuate and paraventricular nuclei [10]. In the nematode C. elegans, Lin28 exhibits high levels at the beginning of the first larval stage and gradually decreases until the late larval stage; in contrast, let-7 levels progressively increase to reach their maximum level in the adult stage [23]. The reciprocal equilibrium between the level and timing of mature let-7 miRNA expression and Lin28 plays a crucial role in defining key aspects of C. elegans development.

The Lin28/let-7 miR system has been implicated in the maturation of the postnatal hypothalamus and the induction of puberty, particularly in a mouse model of hypogonadotropic hypogonadism [24,25]. Sangiao-Alvarellos et al. [24] reported that developmental changes in hypothalamic Lin28/let-7 expression may be involved in the mechanisms facilitating or leading to puberty onset. This study analyzed the expression profiles of c-Myc, Lin28, and Lin28b mRNAs, as well as let-7a, let-7b, mir-145, mir-132, and mir-9 miRNAs in the hypothalamus of male and female rats. The finding revealed that Lin28/Lin28b and c-Myc mRNAs were abundant in the hypothalamus of both male and female rats during the neonatal period, with values declining significantly during the infant-to-juvenile transition. The expression levels of c-Myc mRNA in the rat hypothalamus mirrored those of Lin28b in both male and female rats. In contrast, let-7a, let-7b, mir-132, and mir-145 miRNA levels were minimal during the neonatal period and progressively increased during postnatal maturation in both male and female rats. The authors suggested that Lin28b and its associated miRNA complex play a permissive role in the initiation of puberty. However, they emphasized that further functional studies and human studies are required for validation.

Obesity and high-fat intake have been demonstrated to induce premature activation of the hypothalamic-pituitary-gonadal (HPG) axis and central precocious puberty. In a study by Chen et al. [26], mice fed a high-fat diet showed increased expression of p53 in the hypothalamus compared to that in the control group. The timing of vaginal opening, a marker of puberty onset, was also earlier in the high-fat diet group. In contrast, inhibiting p53 expression led to a relative delay in vaginal opening. This finding suggests that a high-fat diet accelerates the onset of puberty through the upregulation of p53 expression in the hypothalamus. The study proposed that p53 might act as a crucial mediator linking metabolic changes to pubertal regulation. Moreover, the overexpression of p53 was suggested to potentially expedite the activation of the HPG axis through the c-Myc/Lin28/let-7 system. This implicates p53 as a key player in the intricate interplay between metabolic alterations and the regulation of puberty.

MiR-200/429 and miRNA-155

The miR-200 family has been identified as a key player in the intricate regulation of neurogenesis, the migration of Gonadotropin hormone-releasing hormone (GnRH) neurons, and the process of sexual maturation [27]. In a study by Messina et al. [28] in 2016, it was reported that microRNAs, specifically miRNA-200/429 and miRNA-155, are critical components of a complex developmental switch that controls Gnrh promoter activity. The researchers generated mice in which Dicer, an RNAse-III endonuclease essential for miRNA biogenesis, was selectively inactivated in GnRH neurons. Despite exhibiting normal body weights by adulthood, both male and female mutant mice showed signs of hypogonadotropic hypogonadism and infertility. Markedly reduced serum levels of luteinizing hormone (LH) and follicle-stimulating hormone (FSH) were observed in both female and male adult mice. Notably, the pituitary function appeared intact, as LH levels increased after systemic GnRH injection; therefore, the mice had hypogonadotropic hypogonadism due to GnRH deficiency. Immunoreactivity for GnRH was completely absent in the hypothalamus of adult mutant mice. While some of the mutant female mice experienced vaginal opening during postnatal development, they never reached puberty despite normal somatic growth. Examination of the impact of Dicer inactivation on the migration of mouse GnRH neurons revealed that selective invalidation of Dicer expression in GnRH neurons did not result in migratory defects during embryogenesis. However, in mutant mice, hypothalamic GnRH immunoreactivity started to disappear during the infantile period, and this accelerated during the juvenile period. The deficiency of GnRH in mutant mice was attributed not to a developmental absence of GnRH neurons, but rather to an acquired postnatal deficit.

Among the differentially expressed miRNAs at different postnatal ages (P7 vs. P12), the miRNA-200 family and miR-429 emerged as the most highly enriched miRNAs in infantile GnRH neurons. These miRNAs are known to silence the transcriptional repressor Zeb1 in pituitary gonadotropes, where it regulates LH expression. Both human and mouse Gnrh promoters were found to contain a putative Zeb1 binding site. Through a series of experiments, the researchers hypothesized that increased Zeb1 expression in the absence of miRNA biosynthesis could mediate the downregulation of the GnRH activators. To test this hypothesis, they administered a targetsite blocker (TSB), which was selectively designed to silence the activity of target miRNA, directly into the brain of mice. TSB-200 selectively inhibits the activity of miR-200. This inhibition leads to a significant increase in the Zeb1 mRNA level within GnRH neurons, while concurrently reducing transcripts of the Gnrh promoter activator and Gnrh. This miR-200-Zeb1 network actively participates in the switch in Gnrh transcriptional control in the infantile mouse hypothalamus. MicroRNA-155 was also found to regulate the expression of Cebpb, Gnrh, and Zeb1 mRNA in infantile GnRH neurons. TSB-155 upregulates Cebpb and Zeb1 transcripts while indirectly suppressing Gnrh gene transcription. Both miR- 200 and miR-155 facilitate the expression of Gnrh1 by inhibiting the repressors of the Gnrh1 promoter, specifically Zeb1 and Cebpb, respectively. Remarkably, when TSB-200 and/or TSB-155 were injected into the brains of female wild-type mice during the infant–juvenile critical period, TSB-injected mice exhibited a precocious onset of puberty compared to control mice. The authors suggested that selectively blocking GnRH production and then releasing the block prematurely can trigger precocious puberty, possibly due to a rebound effect.

1. MiR-29 family

The miR-29 family is notably enriched in the central nervous syste, particularly in mature neurons [29]. Numerous studies have highlighted the regulatory role of miR-29s in puberty onset and reproduction. In the porcine developing hypothalamus, miR-29a-3p showed differential expression [30]. In mice, the expression level of miR-29 family members in GnRH neurons was higher on postnatal day (PND) 12 than it was on PND 7; the abundance of these miR-29 family members was greater in GnRH neurons than in non-GnRH neurons [28]. Takeda and Tanabe [31] reported that mice with brain-targeted miR-29 knockdown were developmentally indistinguishable from wild-type mice. However, mutant males exhibited subfertility, while mutant females showed hyperfertility. Similarly, turquoise killifish with neuron-specific miR-29 knockdown displayed reduced fertility and posthatch survival [32]. GT1-7 cells, an immortalized clonal line of differentiated GnRH neurons derived from mouse hypothalamic neurons, were utilized as an ideal model system to study the regulation of Gnrh1 expression [33,34]. Li et al. [35] found that the absence of miR-29s resulted in elevated expression of Gnrh1 and its target Tbx21, which promotes puberty onset. In GI1-7 cells, miR-29a, miR-29b, and miR29c all have binding sites on the 3’UTR of the Tbx21 gene. In this study, the transcription factor Tbx21 was demonstrated to directly and indirectly promote Gnrh1 expression. TBX21 and GnRH were co-expressed in the hypothalamus, exhibiting a concurrent increasing trend during the onset of mouse puberty. When mice were subjected to stereotactic brain infusions of an miR-29a inhibitor, they exhibited a precocious onset of puberty compared with the control. The repression of miR-29a, mediated by the overexpression of Tbx21, promotes the onset of puberty and reproductive processes in mice. These findings suggest that miR-29 family members play a crucial role in regulating Gnrh1 expression and, consequently, the onset of puberty.

2. MiRNA-375

MiR-375 is prominently expressed in the mouse pituitary gland and exerts a negative regulatory effect on pro-opiomelanocortin and related hormone secretion [36]. According to Li et al. [37], miR-375 enhances Gnrh expression in GT1-7 cell by suppressing the levels of Sp1 and Tle4. Tle4 is known to repress the transcriptional activity of the Gnrh gene. Sp1, in contrast, negatively regulates Gnrh expression by directly binding to the Gnrh promoter to repress Gnrh transcription. Sp1 also attaches to the promoters of Cebpb, Msx1, and Tle4, which act as repressors for the Gnrh promoter. This indirect mechanism affects Gnrh expression. The enhanced expression of miR-375 results in the reduced transcription activities of Sp1, Cebpb, Msx1, and Tle4. By doing so, miR-375 releases their repressive actions on Gnrh transcription, ultimately leading to an elevation in Gnrh expression.

3. MiR-505-3p

MiR-505-3p is commonly recognized as a biomarker of various diseases, including Parkinson disease and inflammatory bowel disease. Prenatal stress has been shown to lead to the downregulation of miR-505-3p in newborn rat brains. Target of miR-505-3p is the alternative splicing factor/splicing factor2 (ASF/SF2 of SRSF1) [38], which acts as a regulator of the mammalian target of rapamycin (mTOR) pathway. Activation of the mTOR signaling pathway has been associated with an accelerated onset of vaginal opening in female rats [39,40]. In a study by Zhou et al. [41], the role of miR-505-3p in the onset of puberty was investigated. The researchers found that miR-505-3p expression, which is most abundant in the female hypothalamus, reaches its peak during the neonatal period and gradually decreases thereafter. Overexpression of miR-505-3p resulted in delayed puberty, growth retardation, and reduced fertility. Conversely, female mice lacking miR-505-3p exhibited an increased growth rate, earlier vaginal opening, and larger litter sizes compared to those of wild-type mice. Furthermore, the serum levels of LH and FSH, as well as the expressions of Srsf1, Kiss1, and Gnrh in the hypothalamus, were significantly increased in knockout mice. Srsf1 was identified as a target gene of the miR-505-3p gene in the GT1-7 cell line, primarily binding to ribosomal protein. Knocking down Srsf1 expression in the GT1-7 cells inhibited the expression of the puberty-related genes Kiss1 and Gnrh. The study concluded that miR 505-3p acts as a repressor of puberty onset in female mice by regulating the expression of Srsf1.

4. MiR-199-3p

Kisspeptin neurons are integral components of the hypothalamic GnRH pulse generators that play a crucial role in triggering the central mechanism that controls the onset of puberty [42]. Li et al. [43] investigated the regulatory mechanism influencing the onset of puberty through miRNA associated with Kiss1. The researchers observed that overexpression of miR-199-3p inhibited the expression of Kiss1, resulting in delayed puberty onset in mice. Furthermore, inhibition of the p38 mitogen-activated protein kinase (MAPK) pathway was found to delay puberty onset and decrease serum LH levels in both female and male mice. MiR-199-3p was shown to effectively repress the activity of the p38 MAPK pathway. Reduced p38 MAPK activity, in turn, inhibited the transcription of the Kiss1 gene by blocking the activation of its transcription factors, c-FOS and cAMP response element-binding protein (CREB). The study proposed that sustained downregulation of miR-199-3p gradually ceases inhibition of the p38 MAPK pathway. This regulatory process, in turn, modulates the expression of Kiss1 and plays a role in the precise timing of puberty onset in mice.

5. MiR-664-2

N-Methyl-D-aspartate (NMDA) signaling has been associated with the activation of GnRH neurons and linked to early menarche [44]. NMDA receptors (NMDARs) are heteromeric receptors composed of various combinations of its 7 identified subunits [45]; they are present in different regions of the hypothalamus [46]. Agonists and antagonists of NMDAR1 can influence the secretion of GnRH [47]. Coexpression of NMDAR1 and GnRH within the same cellular environment has been noted in previous studies, highlighting the role of upregulated NMDAR1 expression in the increased release of GnRH at the initiation of puberty [48].

In a study by Ju et al. [49], the expression of hypothalamic NMDARs in rats was assessed to elucidate the role of hypothalamic NMDARs and the associated miRNA in the pathogenesis of precocious puberty. In normal female rats, the average timing of vaginal opening typically occurred around PND 35. Concurrently, GnRH, LH, FSH, and estradiol serum levels reached their peak on PND 35, coinciding with the peak in hypothalamic NMDAR1 mRNA and protein levels. The researchers identified that miR-664-2 targets NMDAR1 in rat hypothalamic neurons, and the inhibition of miR-664-2 significantly increased NMDAR1 protein expression. Reduction in hypothalamic miR-664-2 levels was proposed to contribute to the pathogenesis of precocious puberty by enhancing NMDAR1 signaling. This study sheds light on the potential involvement of miR-664-2 and NMDAR1 in the regulation of puberty onset.

6. MiR-30 family

Recent evidence points to Mkrn3, a maternally imprinted gene encoding the makorin RING-finger protein-3 (MKRN3), as a crucial inhibitory element in the gene regulatory network governing puberty [50]. Loss-of-function mutations in MKRN3 have been identified as the most common genetic cause of central precocious puberty. Additionally, a prepubertal decrease in MKRN3 serum levels has been observed in both boys and girls [51,52]. The diminished hypothalamic expression of Mkrn3 mRNA and protein before puberty onset in mice suggest its potential role as a repressive factor in the central control of puberty. The 3’ UTR of the MKRN3 transcript has been identified as a crucial miRNA-mediated regulatory element, which is highly conserved in both mice and humans [50,53].

Heras et al. [54] investigated the potential role of miRNAs in regulating Mkrn3 activity and their functional contribution to puberty timing. The miR-30 family, identified through 4 miRNA-target prediction tools, was considered a strong candidate for regulating the Mkrn3 gene. Specifically, miR-30b was selected for analysis. The expression profiles of miR-30b and Mkrn3 in the hypothalamus of mice during postnatal maturation were examined. Mkrn3 exhibited peak expression during the neonatal-infantile period, significantly decreased in expression during the transition to juvenile, reached minimal levels during the peripubertal period, and maintained low levels in adulthood. In contrast, the miR-30b levels were lowest during the neonatal period, gradually increased during postnatal maturation, and peaked during the peripubertal period in both female and male rats. Hypothalamic Mkrn3 protein expression significantly declined during the transition from juvenile to pubertal stages in female rats. LH serum levels, serving as a surrogate marker for GnRH neuron activity, exhibited patterns inversely related to hypothalamic miR-30b expression in both female and male rats. The lowest LH levels were observed during the infantile period, followed by a progressive increase toward the peripubertal stage, and a peak during adulthood. It was confirmed that miR-30b targets the 3' UTR of Mkrn3 and exerts a repressive signal on Mkrn3 expression in vitro. To prevent miR-30 from binding to its seed regions at the 3' UTR of Mkrn3, TSB-miR-30 was intracerebroventricularly injected. When TSB-miR-30 treatment was administered during the juvenile period, a delayed onset of puberty was observed. Additionally, the concentration of Mkrn3 in the hypothalamus increased in mice with delayed puberty after the administration of TSB-miR-30b. This study highlights the contrasting expression profile of Mkrn3 and miR-30b in the central control of puberty.

Mørup et al. [55] conducted a study measuring the serum levels of miR-30b-5p, miR-200b-3p, and miR-155-5p in 46 boys from the longitudinal part of the Copenhagen puberty cohort study. They observed a significant increase in the circulating levels of miR-30b-5p when comparing pre- and peripubertal samples with postpubertal levels. In prepubertal boys, the circulating levels of miR-30b were low, while the MKRN3 levels were high. However, as puberty progressed, the levels of miR-30b increased, with a larger fraction becoming biologically active; concurrently, the MKRN3 level decreased. The researchers concluded that circulating levels of miR-30b-5p increase during the pubertal transition in boys. They suggested that miR-30b-5p may play a role in the activation of the HPG axis in the onset of puberty. This finding supports the idea that miRNAs, specifically miR-30b-5p, may contribute to the regulatory processes involved in the activation of the reproductive axis during the pubertal transition in boys.

Sexual dimorphism of miRNA expression

Sex chromosome-linked genes play a significant role in the sex dimorphism of gene expression, but they can only explain a limited number of sexually dimorphic genes. In fact, numerous sexually dimorphic genes are located on autosomes, which constitute 95% of the annotated human genome. The differential expression of autosomal genes between males and females is influenced by epigenetic controls and regulated by sex hormones [56,57]. While sex differences in pituitary function and associated disease are well recognized, the underlying gene regulatory networks that contribute to these differences remain unclear. The pituitary gland exhibits sex differences in its regulation of physiological function, including stress response, somatic growth, reproduction, and pubertal timing. Hormone production and various physiological processes controlled by the pituitary gland are sex-biased.

Hou et al. [58] conducted a study on the pituitary gene and miRNA profile in mice during postnatal development, encompassing the pubertal transition. They found that miRNA that was differentially expressed in the pituitary glands of male and female mice contributed to the sex difference observed in postnatal pituitary development and function.

In addition, miRNA expression has been extensively studied in the testes and ovaries of various species, including the human testis [59-63]. Differentially expressed miRNAs in these reproductive organs indicate the crucial role of miRNAs in guiding the development and function of gonadal tissues. Moreover, sex hormones such as estrogen and androgen stimulate and regulate miRNA expression in various diseases. Sex differences in miRNA expression are not limited to gonadal tissues; they have also been observed in diverse somatic tissues such as the liver, lung, and brain.

In a study by Ziats and Rennert [64], differentially expressed miRNAs in normal human donor brains were examined from infancy through adolescence. Notably, 40 miRNAs exhibited a significant sex-biased expression pattern in the prefrontal cortex, particularly during adolescence. These sex-biased miRNA-targeted genes are associated with Wnt and transforming growth factor-beta pathways. Additionally, besides inherent sex differences in miRNA expression, males and females exhibit sex-specific miRNA expression in response to environmental stimuli and/or pathological changes [65]. It is plausible that miRNAs are expressed differentially between males and females across various diseases, leading to sex differences in disease susceptibility and severity.

Potential biomarkers for measuring puberty onset

MiRNA that exhibit distinct expression patterns based on developmental stage have the potential to be utilized as biomarkers for the onset of puberty. Han et al. [66] suggested that circulating miRNAs are potential biomarkers for measuring puberty onset in chicken. They proposed a 7 miRNA panel (including miR-29c, miR-375, miR-215, miR-217, miR-19b, miR-133a, and let-7a) that displays a substantial potential to serve as a novel biomarker for evaluating puberty onset in chickens. Mørup et al. [55] observed an increase in circulating levels of miR-30b-5p in boys as puberty progressed, suggesting the potential utility of circulating miRNA as a biological indicator within the context of reproductive maturation.

Conclusions

In conclusion, miRNAs play a crucial role as delicate regulators in the onset of puberty (Table 1). Changes in the expression patterns of miRNAs in the hypothalamus can influence the timing of puberty onset and may contribute to the development of precocious or delayed puberty.

MicroRNA (miRNA) related to pubertal onset

There are several limitations to the clinical application of miRNA research. First, the lack of a consensus regarding methodologies for quantifying miRNA poses a significant obstacle to the broader utilization of transcripts. Additionally, there is a lack of reproducibility across various technologies used for biomarker discovery. Most studies have been conducted in animals, with limited research in humans, especially in children. Furthermore, the majority of studies are based on case-control designs. The scarcity of large-scale cohort studies means that result may vary between studies. Despite several limitations, the identification and characterization of the miRNA profile during puberty are expected to provide valuable insights into the enigmatic processes of puberty. MiRNA research holds the potential to clarify the underlying processes of puberty and could help to predict the onset of puberty and treat associated disorders.

Notes

Conflicts of interest

No potential conflict of interest relevant to this article was reported.

Funding

This study was supported by the NRF grant, funded by the Korean government (MSIT; no. 2022R1G1A1009727).

Author contribution

Conceptualization: HRJ, ITH; Data curation: HRJ; Funding acquisition: HRJ; Project administration: ITH; Writing - original draft: HRJ; Writing - review & editing: HRJ, ITH

References

1. Parent AS, Teilmann G, Juul A, Skakkebaek NE, Toppari J, Bourguignon JP. The timing of normal puberty and the age limits of sexual precocity: variations around the world, secular trends, and changes after migration. Endocr Rev 2003;24:668–93.
2. Mancini A, Magnotto JC, Abreu AP. Genetics of pubertal timing. Best Pract Res Clin Endocrinol Metab 2022;36:101618.
3. Palmert MR, Hirschhorn JN. Genetic approaches to stature, pubertal timing, and other complex traits. Mol Genet Metab 2003;80:1–10.
4. Juul A, Teilmann G, Scheike T, Hertel NT, Holm K, Laursen EM, et al. Pubertal development in Danish children: comparison of recent European and US data. Int J Androl 2006;29:247–55. discussion 286-90.
5. Livadas S, Chrousos GP. Molecular and environmental mechanisms regulating puberty initiation: an integrated approach. Front Endocrinol (Lausanne) 2019;10:828.
6. Kim MR, Jung MK, Jee HM, Ha EK, Lee S, Han MY, et al. The association between phthalate exposure and pubertal development. Eur J Pediatr 2024;183:1675–82.
7. Peper JS, Burke SM, Wierenga LM. Sex differences and brain development during puberty and adolescence. Handb Clin Neurol 2020;175:25–54.
8. Bartel DP. MicroRNAs: genomics, biogenesis, mechanism, and function. Cell 2004;116:281–97.
9. Rajman M, Schratt G. MicroRNAs in neural development: from master regulators to fine-tuners. Development 2017;144:2310–22.
10. Amar L, Benoit C, Beaumont G, Vacher CM, Crepin D, Taouis M, et al. MicroRNA expression profiling of hypothalamic arcuate and paraventricular nuclei from single rats using Illumina sequencing technology. J Neurosci Methods 2012;209:134–43.
11. Lettre G, Jackson AU, Gieger C, Schumacher FR, Berndt SI, Sanna S, et al. Identification of ten loci associated with height highlights new biological pathways in human growth. Nat Genet 2008;40:584–91.
12. He C, Kraft P, Chen C, Buring JE, Paré G, Hankinson SE, et al. Genome-wide association studies identify loci associated with age at menarche and age at natural menopause. Nat Genet 2009;41:724–8.
13. Ong KK, Elks CE, Li S, Zhao JH, Luan J, Andersen LB, et al. Genetic variation in LIN28B is associated with the timing of puberty. Nat Genet 2009;41:729–33.
14. Tommiska J, Wehkalampi K, Vaaralahti K, Laitinen EM, R aivio T, Dunkel L. LIN28B in constitutional delay of growth and puberty. J Clin Endocrinol Metab 2010;95:3063–6.
15. Ambros V, Horvitz HR. Heterochronic mutants of the nematode Caenorhabditis elegans. Science 1984;226:409–16.
16. Yang DH, Moss EG. Temporally regulated expression of Lin-28 in diverse tissues of the developing mouse. Gene Expr Patterns 2003;3:719–26.
17. Roush S, Slack FJ. The let-7 family of microRNAs. Trends Cell Biol 2008;18:505–16.
18. Chang TC, Zeitels LR, Hwang HW, Chivukula RR, Wentzel EA, Dews M, et al. Lin-28B transactivation is necessary for Myc-mediated let-7 repression and proliferation. Proc Natl Acad Sci U S A 2009;106:3384–9.
19. Viswanathan SR, Daley GQ. Lin28: a microRNA regulator with a macro role. Cell 2010;140:445–9.
20. Sachdeva M, Zhu S, Wu F, Wu H, Walia V, Kumar S, et al. p53 represses c-Myc through induction of the tumor suppressor miR-145. Proc Natl Acad Sci U S A 2009;106:3207–12.
21. Zhu H, Shah S, Shyh-Chang N, Shinoda G, Einhorn WS, Viswanathan SR, et al. Lin28a transgenic mice manifest size and puberty phenotypes identified in human genetic association studies. Nat Genet 2010;42:626–30.
22. Sachdeva M, Mo YY. miR-145-mediated suppression of cell growth, invasion and metastasis. Am J Transl Res 2010;2:170–80.
23. Reinhart BJ, Slack FJ, Basson M, Pasquinelli AE, Bettinger JC, Rougvie AE, et al. The 21-nucleotide let-7 RNA regulates developmental timing in Caenorhabditis elegans. Nature 2000;403:901–6.
24. Sangiao-Alvarellos S, Manfredi-Lozano M, Ruiz-Pino F, Navarro VM, Sánchez-Garrido MA, Leon S, et al. Changes in hypothalamic expression of the Lin28/let-7 system and related microRNAs during postnatal maturation and after experimental manipulations of puberty. Endocrinology 2013;154:942–55.
25. Gaytan F, Sangiao-Alvarellos S, Manfredi-Lozano M, García-Galiano D, Ruiz-Pino F, Romero-Ruiz A, et al. Distinct expression patterns predict differential roles of the miRNA-binding proteins, Lin28 and Lin28b, in the mouse testis: studies during postnatal development and in a model of hypogonadotropic hypogonadism. Endocrinology 2013;154:1321–36.
26. Chen T, Chen C, Wu H, Chen X, Xie R, Wang F, et al. Overexpression of p53 accelerates puberty in high-fat diet-fed mice through Lin28/let-7 system. Exp Biol Med (Maywood) 2021;246:66–71.
27. Garaffo G, Conte D, Provero P, Tomaiuolo D, Luo Z, Pinciroli P, et al. The Dlx5 and Foxg1 transcription factors, linked via miRNA-9 and -200, are required for the development of the olfactory and GnRH system. Mol Cell Neurosci 2015;68:103–19.
28. Messina A, Langlet F, Chachlaki K, Roa J, Rasika S, Jouy N, et al. A microRNA switch regulates the rise in hypothalamic GnRH production before puberty. Nat Neurosci 2016;19:835–44.
29. Nolan K, Mitchem MR, Jimenez-Mateos EM, Henshall DC, Concannon CG, Prehn JH. Increased expression of microRNA-29a in ALS mice: functional analysis of its inhibition. J Mol Neurosci 2014;53:231–41.
30. Zhang L, Cai Z, Wei S, Zhou H, Zhou H, Jiang X, et al. MicroRNA expression profiling of the porcine developing hyp ot hal amus and pituit ar y tissue. Int J Mol S ci 2013;14:20326–39.
31. Takeda T, Tanabe H. Lifespan and reproduction in brain-specific miR-29-knockdown mouse. Biochem Biophys Res Commun 2016;471:454–8.
32. Ripa R, Dolfi L, Terrigno M, Pandolfini L, Savino A, Arcucci V, et al. MicroRNA miR-29 controls a compensatory response to limit neuronal iron accumulation during adult life and aging. BMC Biol 2017;15:9.
33. Keynes R, Lumsden A. Segmentation and the origin of regional diversity in the vertebrate central nervous system. Neuron 1990;4:1–9.
34. Mellon PL, Windle JJ, Goldsmith PC, Padula CA, Roberts JL, Weiner RI. Immortalization of hypothalamic GnRH neurons by genetically targeted tumorigenesis. Neuron 1990;5:1–10.
35. Li X, Xiao J, Fan Y, Yang K, Li K, Wang X, et al. miR-29 family regulates the puberty onset mediated by a novel Gnrh1 transcription factor TBX21. J Endocrinol 2019;242:185–97.
36. Zhang N, Lin JK, Chen J, Liu XF, Liu JL, Luo HS, et al. MicroRNA 375 mediates the signaling pathway of corticotropin-releasing factor (CRF) regulating pro-opiomelanocortin (POMC) expression by targeting mitogen-activated protein k inas e 8. J Biol Chem 2013;288:10361–73.
37. Li H, Li X, Zhang D, Li J, Cui S. MiR-375 potentially enhances GnRH expression by targeting Sp1 in GT1-7 cells. In Vitro Cell Dev Biol Anim 2021;57:438–47.
38. Verduci L, Simili M, Rizzo M, Mercatanti A, Evangelista M, Mariani L, et al. MicroRNA (miRNA)-mediated interaction between leukemia/lymphoma-related factor (LRF) and alternative splicing factor/splicing factor 2 (ASF/SF2) affects mouse embryonic fibroblast senescence and apoptosis. J Biol Chem 2010;285:39551–63.
39. Karni R, Hippo Y, Lowe SW, Krainer AR. The splicing-factor oncoprotein SF2/ASF activates mTORC1. Proc Natl Acad Sci U S A 2008;105:15323–7.
40. Roa J, Garcia-Galiano D, Varela L, Sánchez-Garrido MA, Pineda R, Castellano JM, et al. The Mammalian Target of Rapamycin as Novel Central Regulator of Puberty Onset via Modulation of Hypothalamic Kiss1 System. Endocrinology 2009;150:5016–26.
41. Zhou Y, Tong L, Wang M, Chang X, Wang S, Li K, et al. miR-505-3p is a repressor of the puberty onset in female mice. J Endocrinol 2018;Dec. 1. JOE-18-0533.R2. doi: 10.1530/JOE-18-0533. [Epub].
42. Plant TM. The neurobiological mechanism underlying hypothalamic GnRH pulse generation: the role of kisspeptin neurons in the arcuate nucleus. F1000Res 2019;8F1000 Faculty Rev-982.
43. Li X, Xiao J, Li K, Zhou Y. MiR-199-3p modulates the onset of puberty in rodents probably by regulating the expression of Kiss1 via the p38 MAPK pathway. Mol Cell Endocrinol 2020;518:110994.
44. Urbanski HF, Ojeda SR. A role for N-methyl-D-aspartate (NMDA) receptors in the control of LH secretion and initiation of female puberty. Endocrinology 1990;126:1774–6.
45. Mahesh VB, Brann DW. Regulatory role of excitatory amino acids in reproduction. Endocrine 2005;28:271–80.
46. Maffucci JA, Noel ML, Gillette R, Wu D, Gore AC. Age- and hormone-regulation of N-methyl-D-aspartate receptor subunit NR2b in the anteroventral periventricular nucleus of the female rat: implications for reproductive senescence. J Neuroendocrinol 2009;21:506–17.
47. Bourguignon JP, Gérard A, Alvarez Gonzalez ML, Franchimont P. Neuroendocrine mechanism of onset of puberty. Sequential reduction in activity of inhibitory and facilitatory N-methyl-D-aspartate receptors. J Clin Invest 1992;90:1736–44.
48. Gore AC, Wu TJ, Rosenberg JJ, Roberts JL. Gonadotropin-releasing hormone and NMDA receptor gene expression and colocalization change during puberty in female rats. J Neurosci 1996;16:5281–9.
49. Ju M, Yang L, Zhu J, Chen Z, Zhang M, Yu J, et al. MiR-664- 2 impacts pubertal development in a precocious-puberty rat model through targeting the NMDA receptor-1†. Biol Reprod 2019;100:1536–48.
50. Abreu AP, Dauber A, Macedo DB, Noel SD, Brito VN, Gill JC, et al. Central precocious puberty caused by mutations in the imprinted gene MKRN3. N Engl J Med 2013;368:2467–75.
51. Hagen CP, Sørensen K, Mieritz MG, Johannsen TH, Almstrup K, Juul A. Circulating MKRN3 levels decline prior to pubertal onset and through puberty: a longitudinal study of healthy girls. J Clin Endocrinol Metab 2015;100:1920–6.
52. Busch AS, Hagen CP, Almstrup K, Juul A. Circulating MKRN3 levels decline during puberty in healthy boys. J Clin Endocrinol Metab 2016;101:2588–93.
53. Jong MT, Carey AH, Caldwell KA, Lau MH, Handel MA, Driscoll DJ, et al. Imprinting of a RING zinc-finger encoding gene in the mouse chromosome region homologous to the Prader-Willi syndrome genetic region. Hum Mol Genet 1999;8:795–803.
54. Heras V, Sangiao-Alvarellos S, Manfredi-Lozano M, Sanchez-Tapia MJ, Ruiz-Pino F, Roa J, et al. Hypothalamic miR-30 regulates puberty onset via repression of the puberty-suppressing factor, Mkrn3. PLoS Biol 2019;17e3000532.
55. Mørup N, Stakaitis R, Main AM, Golubickaite I, Hagen CP, Juul A, et al. Circulating levels and the bioactivity of miR-30b increase during pubertal progression in boys. Front Endocrinol (Lausanne) 2023;14:1120115.
56. Wijchers PJ, Festenstein RJ. Epigenetic regulation of autosomal gene expression by sex chromosomes. Trends Genet 2011;27:132–40.
57. Morgan CP, Bale TL. Sex differences in microRNA regulation of gene expression: no smoke, just miRs. Biol Sex Differ 2012;3:22.
58. Hou H, Chan C, Yuki KE, Sokolowski D, Roy A, Qu R, et al. Postnatal developmental trajectory of sex-biased gene expression in the mouse pituitary gland. Biol Sex Differ 2022;13:57.
59. Hossain MM, Ghanem N, Hoelker M, Rings F, Phatsara C, Tholen E, et al. Identification and characterization of miRNAs expressed in the bovine ovary. BMC Genomics 2009;10:443.
60. Mishima T, Takizawa T, Luo SS, Ishibashi O, Kawahigashi Y, Mizuguchi Y, et al. MicroRNA (miRNA) cloning analysis reveals sex differences in miRNA expression profiles between adult mouse testis and ovary. Reproduction 2008;136:811–22.
61. Torley KJ, da Silveira JC, Smith P, Anthony RV, Veeramachaneni DN, Winger QA, et al. Expression of miRNAs in ovine fetal gonads: potential role in gonadal differentiation. Reprod Biol Endocrinol 2011;9:2.
62. Bannister SC, Tizard ML, Doran TJ, Sinclair AH, Smith CA. Sexually dimorphic microRNA expression during chicken embryonic gonadal development. Biol Reprod 2009;81:165–76.
63. Yang Q, Hua J, Wang L, Xu B, Zhang H, Ye N, et al. MicroRNA and piRNA profiles in normal human testis detected by next generation sequencing. PLoS One 2013;8e66809.
64. Ziats MN, Rennert OM. Identification of differentially expressed microRNAs across the developing human brain. Mol Psychiatry 2014;19:848–52.
65. Dai R, Ahmed SA. S exual dimorphism of miRNA expression: a new perspective in understanding the sex bias of autoimmune diseases. Ther Clin Risk Manag 2014;10:151–63.
66. Han W, Zhu Y, Su Y, Li G, Qu L, Zhang H, et al. High-throughput sequencing reveals circulating miRNAs as potential biomarkers for measuring puberty onset in chicken (Gallus gallus). PLoS One 2016;11e0154958.

Article information Continued

Fig. 1.

Biogenesis of microRNA. miRNA, microRNA; mRNA, messenger RNA; RISC, NRA-inducing silencing complex.

Table 1.

MicroRNA (miRNA) related to pubertal onset

MiRNA Target gene Potential relation to pubertal onset
Lin28/let-7 system - Permissive role
Lin28 gradually decreased
Let7 gradually increased
MiR-200 Zeb1 Promote Gnrh1 expression
MiR-155 Cebpb
MiR-29 Tbx21 Suppress Gnrh1 expression
MiR-375 Tle4 and Sp1 Promotes Gnrh expression
MiR-505-3p Srsf1 Repressor of pubertal onset
MiR-199-3p p38 MAPK pathway Inhibits Kiss1 expression
MiR-664-2 NMDAR1 Reduced expression of miR-664-2 may contribute to precocious puberty
MiR-30b Mkrn3 Repress Mkrn3 and contribute to the activation of the HPG axis

HPG, hypothalamic-pituitary-gonadal.