Polycystic ovary syndrome (PCOS) is a reproductive disorder characterized by chronic anovulatory ovarian follicles and hyperandrogenism, often associated with obesity. It is the major cause of anovulatory infertility, affecting approximately 5–10% of women of reproductive age. PCOS is one of several health disorders associated with Metabolic Syndrome (Syndrome X), or subclinical insulin resistance. A decrease in insulin sensitivity leads to a compensatory increase in insulin secretion to maintain normal glucose tolerance. Hyperinsulinemia is thought to be a major contributing factor to the hyperandrogenism and ovulatory dysfunction in PCOS 12.

It has become common practice to treat women with PCOS with insulin-sensitizing drugs. The two classes of insulin-sensitizing agents currently used most often in clinical practice are biguanides (e.g. metformin) and thiazolidinediones (TZD), which include rosiglitazone and pioglitazone. These classes of drugs act via different mechanisms which are not thoroughly understood. In general, metformin reduces hepatic glucose synthesis leading to a direct reduction in insulin secretion 3. TZD are ligands for the peroxisome proliferator-activated receptor γ (PPARγ), which enhances transcription of a variety of genes that collectively promote glucose disposal.

Metformin has been much more widely used and studied in women with PCOS than have TZD. Women treated with metformin have significantly improved spontaneous ovulation and ovulatory response to gonadotropins, diminished androgen levels, lowered blood pressure, and enhanced fertility 4567. Limited studies with TZD have shown similar results 89.

Although overall improvement in symptoms appears to be similar with metformin or TZD, these drugs clearly act via distinct mechanisms. For example, TZD (troglitazone), but not metformin, reduced androgen levels by directly suppressing 3β-hydroxysteroid dehydrogenase and cytochrome P450 17α-hydroxylase, two key enzymes in the androgenic pathway 10. Moreover, insulin and insulin-like growth factor cellular signaling were differentially altered in ovarian cells from women with PCOS, but after TZD treatment cell signaling was similar to cells from non-PCOS women 11. In that study, insulin receptor substrate (IRS)-1 and -2 expression by ovarian granulosa cells from women with PCOS was altered relative to cells from women without PCOS; IRS-1 expression was higher and IRS-2 expression was lower in PCOS cells. However, after troglitazone treatment in vitro, IRS-1 expression was reduced and IRS-2 expression was enhanced bringing the levels of expression similar to those found in non-PCOS cells 11.

Mice heterozygous for the Lethal Yellow (LY) mutation at the agouti locus exhibit distinct characteristics including yellow coat color, adult onset obesity, and accelerated reproductive senescence 12. Moreover, as these mice age, they progressively develop insulin resistance and hyperinsulinemia 13, hyperleptinemia 14, and central leptin resistance 15. Diminishing ovarian function in aging LY mice is directly related to increasing obesity and the progression of altered metabolic regulation 16. LY mice provide a useful animal model for investigating the effects of insulin-sensitizing drugs on ovarian gene expression in a hyperinsulinemic/insulin resistant state. The current study tested the hypothesis that chronic treatment of aging LY mice with the insulin-sensitizing drug, pioglitazone, alters the ovarian expression of genes that may be involved in insulin signaling or other aspects of ovarian function.

Oral pioglitazone treatment for 60 days in LY mice did not significantly alter body weight, or fasting serum glucose, insulin, or leptin levels (Table 1), although fasting insulin tended (p = 0.09) to be slightly lower in pioglitazone-treated mice. Body weight, insulin, and leptin levels were all higher in LY mice than in age-matched, untreated BL mice.

Of 3.3 × 10⁴ genes on the array, approximately 1500 showed a significant (p < 0.05) difference in expression. Unidentified genes and expressed sequence tags (EST) were removed from further analysis. In addition, those genes whose expression was less than 0.2 relative intensity units (the limit of sensitivity) in both control and treatment groups were excluded. After these exclusions, 27 genes representing a diversity of function exhibited a 2-fold or greater significant (p < 0.05) difference in expression level between groups (Table 2). Genes with reduced expression in pioglitazone-treated mice included leptin, angiopoietin, angiopoietin-like 4, Foxa3, and tenascin. Conversely, RELMα, prostaglandin (PG) D receptor, and PGE1 receptor all exhibited elevated expression in pioglitazone-treated LY mice. The data set for these DNA microarrays has been deposited at the National Center for Biotechnology Information Gene Expression Omnibus 19 as recommended by Minimum Information About a Microarray Experment (MIAME) standards 20 and can be accessed through accession number GSE8806.

Relative expression of these 27 genes in untreated BL mice (n = 2) was included for comparison (Table 2). For most genes, pioglitazone tended to alter expression towards levels seen in the BL control mice. Exceptions were RELMα and dipeptidypeptidase 10, whose expression was similar in vehicle-treated LY mice and untreated BL mice, but greatly elevated in pioglitazone-treated LY mice.

Expression of RELMα in the ovary has not been previously reported. Therefore microarray results were verified by Real Time RT-PCR. The difference in expression of RELMα by RT-PCR was nearly eight-fold (Figure 1), confirming a significant increase in mRNA levels in pioglitazone-treated mice. Since gonadal fat is a known source of RELMα 21, we sought to confirm that the RELMα expression was within the ovary proper. RELMα protein was detected in mouse ovarian sections from untreated age-matched LY mice by immunocytochemistry, confirming that RELMα was expressed within the ovary rather than in adhering fat tissue. RELMα primarily localized in perivascular cells, which on the basis of morphology and distribution were likely to be macrophages, although this was not confirmed (Figure 2). Western blot analysis of protein extracts of vehicle- and pioglitazone-treated LY mice did not reveal a significant difference in protein expression (Figure 3).

Because of limited quantities of RNA extracts available after microarray analyses, no other genes could be verified by RT-PCR. Attempts to confirm three additional genes yielded inconclusive results, which could not be repeated due to depletion of the samples.

We have previously shown that progressive obesity in aging LY mice is associated with a concomitant diminution in ovarian function, which is paralleled by acquired insulin and leptin resistance 16. To our knowledge, this is the first report demonstrating that prolonged in vivo exposure to TZD alters intraovarian gene expression in an aging obese mouse model. The altered expression of numerous genes involved in diverse cellular functions such as cell signaling, cell proliferation and survival, cell adhesion, and differentiation suggest that the positive effects of TZD on ovarian function observed in PCOS patients may be multifactorial.

TZD are primarily characterized as ligands for the PPARγ. However, pioglitazone may also activate PPARα, which may explain its broader spectrum of clinical action relative to other TZD 22. Ligand binding of either of the two PPARγ isoforms results in heterodimerization with a retinoid X receptor (RXR), followed by the PPARγ/RXR complex binding to and activating PPAR response elements on target genes 23. In general, PPARγ activation in adipose cells has anti-angiogenic actions and suppresses the synthesis and secretion of proinflammatory and proinsulin resistant adipokines 24.

PPAR are widely expressed in vascular and inflammatory cells 25. In the ovary, PPARγ are localized in granulosa cells of maturing follicles 2627 and in thecal and stromal macrophages 28. In contrast, PPARα are expressed throughout thecal and stromal regions of rodent ovaries 2627 consistent with vascular and peri-vascular expression.

TZD actions in the ovary have not been widely investigated. Troglitazone suppressed LH and insulin-stimulated androgen production by isolated porcine thecal cells 29. Moreover, in human follicular fragments, TZD (pioglitazone and rosiglitazone) modestly inhibited testosterone and estradiol production, but enhanced progesterone and IGFBP-1 production 30. These results in isolated ovarian cells imply a direct action of TZD on steroidogenesis, although the mechanisms remain unclear. In addition, troglitazone suppressed inducible nitric oxide synthase (NOS2) in mouse ovarian macrophages isolated from preovulatory ovaries 28. Perivascular/anti-inflammatory actions of TZD in the ovary may also alter ovarian function.

Among genes responding to pioglitazone with altered expression were several that participate in vascular remodeling. An increase in angiogenesis and stromal blood flow are characteristic of PCOS 3132. Notably, leptin, angiopoietin, angiopoietin-like 4, and RELMα were among the genes whose expression was altered most by pioglitazone treatment. The three-fold reductions in leptin and angiopoietin mRNA expression in the current study would be consistent with reduced angiogenesis. In contrast, RELMα has generally been reported to have angiogenic actions 33, so the significant increase in its gene expression in the current study may appear inconsistent. Angiopoietin-like 4, has been reported to be both angiogenic 34 and anti-angiogenic 35.

A novel finding was the intraovarian expression of RELMα and its up-regulation by pioglitazone. Resistin and RELMα are often co-regulated 36. Resistin has been shown to have significantly lower expression in mouse models of obesity, e.g. ob/ob and db/db mice, but is stimulated by PPARγ agonists 37. Therefore the increased expression of RELMα by pioglitazone in the current study would be consistent, although resistin expression was not significantly altered by pioglitazone in this study. RELMα, also known as hypoxia-induced mitogenic factor (HIMF) or FIZZ1, has not previously been shown to be significantly expressed in the ovary, although it is expressed in high levels in gonadal fat of lactating mice 21. RELMα is reported to be primarily associated with adipose tissue, specifically localized in the vascular fraction 36. The present study demonstrates RELMα protein expression in perivascular cells within the ovary, which are consistent in appearance and distribution with macrophages, known targets of TZD. However, RELMα protein levels on Western blot were not siginificantly greater in pioglitazone-treated ovaries. Considering the proximity of the immunoactive cells to blood vessels, it is possible that if RELMα is secreted by these cells it could be primarily carried off in the circulation and would not show accumulation in the tissue.

Prolonged oral administration of pioglitazone to aging obese LY mice altered the ovarian expression of a several genes. The results suggest that PPARγ may mediate diverse actions in the ovary, and that the positive effects of TZD observed in women with PCOS might involve mechanisms not directly related to insulin sensitivity. Further research is needed to investigate the wide range of potential regulatory actions of PPARγ agonists in normal ovarian physiology and PCOS.

JB and MD conceived and designed the study. MW carried out the treatments and tissue collection, and prepared preliminary data summaries. KE performed RNA extractions and microarray analyses, and performed statistical analyses on microarray data. JB and MD performed final data analysis, and JB drafted the manuscript.