Ultrastructural analysis of progressive endometrial hypercytolipidemia induced by obese (ob/ob) and diabetes (db/db) genotype mutations: structural basis of female reproductive tract involution

Obesity modulates cell-cell interactions during ovarian folliculogenesis

Obesity is known to affect female reproduction, as evidenced by obese patients suffering from subfertility and abnormal oogenesis. However, the underlying mechanisms by which obesity impairs folliculogenesis are poorly documented. Here, we performed comprehensive single-cell transcriptome analysis in both regular diet (RD) and obese mouse models to systematically uncover how obesity affects ovarian follicle cells and their interactions. We found an increased proportion of Inhbb highly expressed granulosa cells (GCs) among all the GC subpopulations in obese mice. Under obese conditions, excessive androgen secreted from endocrine theca cells (ETCs) may contribute to the imbalanced change of GC subtypes through ETCs-GCs interactions. This is alleviated by enzalutamide, an androgen receptor antagonist. We also identified and confirmed typical GC markers, such as Marcks and Prkar2b, for sensitive evaluation of female fertility in obesity. These data represent a resource for studying transcriptional networks and cell-cell interactions during folliculogenesis under physiological and pathological conditions.

Elevated non-esterified fatty acids impair survival and promote lipid accumulation and pro-inflammatory cytokine production in bovine endometrial epithelial cells

Elevated non-esterified fatty acids (NEFAs) are associated with negative effects on bovine theca, granulosa and oviductal cells but the effects of NEFAs on bovine endometrial epithelial cells (bEECs) are not as well documented. The objective of this study was to define the effects of NEFAs on bEECs. Postprimary bEECs were treated with 150, 300 or 500µM of either palmitic acid (PA), stearic acid (SA) or oleic acid (OA) or a mixture of NEFAs (150µM of each FA) or 0.5% final concentration of vehicle ethanol (control). Viability and proliferation of bEECs exposed to 150µM of each NEFA or a mixture of NEFAs were unaffected. Increased lipid accumulation was found in all treated groups (P<0.01). In cells exposed to 500µM of each NEFA and 300µM PA decreased cell viability (P<0.001), proliferation (P<0.05) and increased apoptosis (P<0.05) were observed. Treatment with 500µM OA, PA and SA had the strongest effects on cell viability, proliferation and apoptosis (P<0.05). Treatment with PA and OA increased interleukin-6 (IL-6) concentrations (P<0.05), whereas only the highest concentration of PA, OA and SA stimulated IL-8 production (P<0.05). These results suggest that high concentrations of NEFAs may impair endometrial function with more or less pronounced effects depending on the type of NEFA and time of exposure.

Combined losartan and nitro-oleic acid remarkably improves diabetic nephropathy in mice

Diabetic nephropathy (DN) is a leading cause of end-stage renal disease (ESRD). The inhibitors of renin-angiotensin-aldosterone system (RAAS) can alleviate some of the symptoms of DN but fail to stop the progression to ESRD. Our previous studies demonstrate renoprotective action of nitro-oleic acid (OA-NO2) in several rodent models of renal disease. Here we examined the therapeutic potential and the underlying mechanism of combination of losartan and OA-NO2 in db/db mice. OA-NO2 was infused at 5 mg·kg(-1)·day(-1) via osmotic minipump, and losartan was incorporated into diet at 10 mg·kg(-1)·day(-1), each administered alone or in combination for 2 wk. Diabetic db/db mice developed progressive albuminuria and glomerulosclerosis, accompanied by podocytes loss, increased indexes of renal fibrosis, oxidative stress, and inflammation. Treatment of the diabetic mice with OA-NO2 or losartan alone moderately ameliorated kidney injury; however, the combined treatment remarkably reduced albuminuria, restored glomerular filtration barrier structure, and attenuated glomerulosclerosis, accompanied with significant suppression of renal oxidative stress and inflammation. These data demonstrate that combination of losartan and OA-NO2 effectively reverses renal injury in DN.

Selenium-vitamin E combination modulates endometrial lipid peroxidation and antioxidant enzymes in streptozotocin-induced diabetic rat

Diabetes mellitus is associated with diabetic impairment of uterine function, ultimately leading to reduced fertility. Its etiology may involve oxidative damage by reactive oxygen substances, and protection against this damage can be offered by antioxidant supplementation. In the present study, the effects of a vitamin E-plus-selenium (VESe) combination on lipid peroxidation (MDA) and the scavenging enzyme activity in the uterine endometrium of streptozotocin (STZ)-induced diabetic rats were investigated. Twenty-four female rats were equally divided into three groups as follows: group I (control); group II (diabetic); group III (diabetic + VESe), STZ + vitamin E (60 mg/kg over 1 day) + selenium-treated (Na2SeO3, 1 mg/kg over 1 day). After 4 weeks of receiving the VESe treatment, endometrium samples were taken from the uterus. Although the VESe treatment decreased the MDA and blood glucose levels in the STZ group, the observed values remained significantly higher than in the controls. Catalase, superoxide dismutase, and glutathione peroxidase activities and body weight gain were significantly (p < 0.01) lower in STZ groups as compared to control group, whereas their activities were (p < 0.01) increased by VESe treatment. However, there was no significant difference on body weight gain and uterine weights between control and STZ + VESe groups. In conclusion, the endometrial complications caused by oxidative stress, and the abnormal blood glucose levels in diabetic of rats, can be alleviated by strengthening the physiological antioxidative defense through the administration of vitamin E and Se.

Hypercytolipidemia-induced cellular lipoapoptosis: Cytostructural and endometabolic basis of progressive organo-involution following expression of diabetes (db/db) and obese (ob/ob) mutation syndromes

Onset expression of Type 2 (NIDDM) diabetes and obesity metabolic syndromes (DOS) are characterized by premature, progressive cytoatrophy and organo-involution induced by dysregulated cellular gluco- and lipo-metabolic cascades. The consequential systemic, interstitial and intracellular hyperlipidemia disrupts normal cytointegrity and metabolic responsivity to the established hypercaloric pericellular environments. The sequential cytostructural, metabolic and endocrine disturbances associated with the development of progressive DOS-associated hypercytolipidemia compromises cellular metabolic response cascades and promotes cytochemical disturbances which culminate with nuclear lipoapoptosis and cytoatrophy. The dramatic alterations in interstitial glucose and lipid (free fatty acids/triglycerides) concentrations are recognized to influence interstitial and cytoplasmic microchemical environments, which markedly alter cellular nutrient diffusion and active trans-membrane flux rates. The progressive exacerbation of interstitial and cytoplasmic lipid imbibition has been demonstrated to be associated with DNA fragmentation by lipo-infiltration into the chromatin matrix, inducing structural disruption and physical dissolution, indexed as nuclear lipoapoptosis. Therapeutic reduction of the severity of hypercytolipidemia-induced structural and cytochemical compromise promotes the restoration of homeostatic metabolic support for normalized cytostructural indices and supportive cellular gluco- and lipo-metabolic cascades. The re-establishment of a homeostatic interstitial microenvironment moderates the severity of cytolipidemic compromise within affected cell types, reduces nuclear lipo-infiltration and DNA lipo-dissolution, resulting in the preservation of cytostructural integrity. Through the therapeutic restoration of extra- and intra-cellular microchemical environments in genetically dysregulated metabolic syndrome models, the coincident cytochemical, endocrine and metabolic disturbances associated with progressive hypercytolipidemia, resulting from the expressed systemic hypercaloric environmental and hepato-pancreatic endometabolic disturbances which characterize Type 2 (NIDDM) diabetes-obesity and metabolic (X) syndromes, may be ameliorated.

Gonadal steroid modulation of the diabetes (db/db) mutation-induced hyperlipometabolic, hypogonadal syndrome: Restoration of female reproductive tract cytochemical and structural indices

The gonadal steroids, 17-B-estradiol (E2) and progesterone (P), are recognized to stimulate cellular gluco- and lipo-metabolic compensatory cascades which counteract the deleterious influences of the diabetes (db/db) mutation (i.e., leptin membrane receptor defect) which promotes a progressive, hypercytolipidemia-induced premature involution of the female reproductive tract (FRT). The current studies define the therapeutic efficacy of E2 (1 microg/3.5 days) and P (1 mg/3.5 days) treatments (HRx) on utero-ovarian structural and cytochemical (gluco-/lipo-metabolic) maintenance, and the prevention of premature nuclear apoptosis and cytostructural disruption, following the expression of progressive db/db-induced hypercytolipidemia. Control (normal: +/+ and +/?) and diabetes (db/db) genotype groups of 8-week-old (i.e., overt phase of the db/db-hypogonadal syndrome) C57BL/KsJ mice were prepared for high resolution (HRLM) cytochemical and transmission electron (TEM) microscopic analysis of cytolipidemia and nuclear apoptosis (TUNEL-labeled 3'-DNA fragmentation) indices from uterine and ovarian secondary (early antral) follicular tissue samples. Compared to HRx controls, the db/db mutation induced a dramatic increase in cytolipid vacuole volume and density within all ovarian follicular granulosa cells (GC) and uterine endometrial epithelial (UEE) layers. The co-localization of nuclear apoptotic 3'-DNA fragments within identified hyperlipidemic granulosa cells was coincident with the cytochemical and ultrastructural identification of lipid penetration through the nuclear envelope in db/db mutants. P-HRx moderated the severity of db/db-induced GC and UEE hypercytolipidemia, reducing the cytodensity of lipid vacuole accumulations and maintaining cytoplasmic organelle structure, organization, and nuclear membrane integrity. In contrast, E2-HRx resulted in a dramatic reduction in db/db cytolipidemia in both ovarian GC and UEE tissue compartments. Following E2-HRx, UEE cells demonstrated non-pycnotic nuclear profiles, reduced nuclear apoptosis TUNEL-labeling, increased cytoplasmic organelle density profiles and a pronounced cytoplasmic cisternal expansion indicative of active cellular nutrient/metabolite trafficking. Ovarian follicular GC populations demonstrated minimal cytolipidemia, a restored cytoarchitecture with prominent organelle compartments and reduced TUNEL-indexed nuclear lipoapoptosis. These results are the first cytochemical and ultrastructural indications that P- and E2-HRx compensate for the genetic db/db mutation-induced metabolic disturbances, which promote utero-ovarian hypercytolipidemia and the coincident nuclear lipoapoptosis culminating in the expressed diabetes hypogonadal syndrome. The capability of P-HRx to moderate the severity of utero-ovarian involution in db/db mutants, and of E2-HRx to restore and maintain viable GC and UEE cyto-chemical and -structural indices under normoglycemic conditions, suggests that chronic, low-dose cyclic P- and E2-HRx stimulate cellular gluco- and lipo-metabolic cascades which compensate for the lack of leptin signaling in these single-gene, obese-Type II diabetic mutants. The compensatory endometabolic maintenance of utero-ovarian cellular and nuclear architecture suggests that the gluco- and lipo-metabolic disregulation may be therapeutically prevented or reversed, restoring reproductive tract cytointegrity and function, reducing the manifestation of hypogonadal reproductive sterility and db/db compromise of the female reproductive tract.

Cytochemical analysis of pancreatic islet lipoapoptosis: hyperlipidemia-induced cytoinvolution following expression of the diabetes (db/db) mutation

The diabetes (db/db) genotype mutation induces a hyperglycemic-hyperinsulinemic endometabolic state in C57BL/KsJ mice, manifesting a type II NIDDM diabetes-obesity syndrome (DOS) associated with intrinsic leptin receptor expression defects. The severity of the DOS-induced premature pancreatic dysfunction and cytoatrophic involution has been linked to the severity of hypercytolipidemia which develops in pancreatic islets following systemic lipoidosis. The current studies define the cytochemical changes associated with pancreatic islet and acinar vesicular degranulation (deproteinization), cytoinvolution and B-cell dysfunction relative to the onset of cellular (nuclear DNA fragmentation) apoptosis in 20- to 26-week-old chronic db/db mutants relative to control (+/?) indices. The db/db mutation induced dramatic increases in body weights, blood glucose as well as serum and tissue triglyceride concentrations relative to +/? parameters. In contrast, pancreatic tissue weights and insulin concentrations were significantly decreased in db/db groups in association with premature islet cytoatrophy relative to +/? indices. Concurrent elevations in db/db tissue triglyceride concentrations and islet cytolipid depositions accompanied the progressive pancreatic cytoatrophic alterations. Diminished B-cell vesicular (insulin) granulation was pronounced in atrophic pancreatic islets, which were also characterized by hyperplasic acinar cellular intrusion and subsequent proteolytic B-cell dissolution coincident with 3'-DNA fragmentation-indexed (TUNEL-labeled) nuclear apoptosis. The chronic expression of the db/db mutation exacerbated these pancreatic islet B-cell atrophy indices, characterized by insulin vesicular degranulation, suppressed systemic insulin concentrations, invasive hypercytolipidemia, progressive cellular atrophy and hyperplasic acinar proteolytic dissolution, culminating in islet volume/mass reduction and chronic db/db-related pancreatic involution. The results of these studies indicate that pancreatic islet B-cell apoptosis is coincident with the progressive hypercytolipidemia component of the type II DOS promoted by the db/db genotypic mutation. These data suggest that the severity of progressive pancreatic lipoapoptosis disrupts regulatory cellular metabolic cascades, resulting in nuclear fragmentation, organelle dissolution and the subsequent promotion of a nonhomeostatic cytochemical milieu which ultimately renders islet B-cell populations susceptible to acinar proteolytic dissolution and progressive pancreatic involution.

Ovarian follicular lipoapoptosis: structural, cytochemical and metabolic basis of reproductive tract atrophy following expression of the hypogonadal diabetes (db/db) syndrome

The diabetes (db/db) mutation (i.e., leptin membrane receptor defect) promotes a progressive, hypercytolipidemia within ovarian follicular granulosa, thecal and interstitial layers of C57BL/KsJ mice which manifests an infertile, acyclic hypogonadal syndrome. The current studies focus on the structural, cytochemical and gluco-/lipo-metabolic changes which induce cellular lipoapoptosis and the resulting cytostructural disruption of db/db follicular populations, relative to littermate control indices, following the expression of progressive ovarian hypercytolipidemia. Control (normal: +/+ and +/?) and diabetes (db/db) genotype groups were prepared for high resolution light microscopic (HRLM) analysis of cytolipidemia and nuclear apoptosis (TUNEL-labeled 3'-DNA fragmentation) indices and compared to the transmission electron (TEM) microscopic analysis of ovarian follicular samples collected from 8-16-week-old groups. Compared to controls, the db/db mutation induced a dramatic increase in cytolipid vacuole volume and density within all ovarian follicular layers. TEM analysis revealed that the lipid vacuoles initially aggregated along the inner membrane compartments of affected thecal and granulosa cells in response to the interstitial and vaso-lipidemic-hyperglycemic conditions which characterized the ovarian microenvironment of db/db follicles. Progressive cytoplasmic movement of lipid pools into the perinuclear compartment of affected granulosa cells induced nuclear isolation from cytoplasmic organelles that were displaced towards peripheral intracellular compartments. Cytochemical analysis of lipid vacuole accumulations indicated attraction towards, and incorporation within, the nuclear envelope of hyperlipidemic cells. Co-localization of nuclear apoptotic 3'-DNA fragments within identified hyperlipidemic granulosa cells was coincident with the cytochemical and ultrastructural identification of lipid penetration through the nuclear envelope in db/db mutants. These results are the first cytochemical evidence that the lipometabolic disturbances in db/db mutants, which promote hypercytolipidemia-induced premature ovarian involution, are coincident with lipoapoptosis-induced nuclear dissolution within follicular granulosa layers. The lipidemia-induced alterations in cellular and nuclear architecture suggests that the disturbances in glucose and lipid metabolic cascade activities in diabetes (db/db) mutants disrupts follicular cytointegrity, culminating in nuclear disregulation (as indicated by lipoapoptosis) which results in premature reproductive tract organo-involution and manifest reproductive sterility.

Diabetes (db/db) mutation-induced endometrial epithelial lipoapoptosis: ultrastructural and cytochemical analysis of reproductive tract atrophy

BACKGROUND

The diabetes (db/db) mutation in C57BL/KsJ mice promotes a progressive cytolipidemia within the endometrial epithelial (EE) layer of the female reproductive tract which results in premature cellular and organ atrophy. The current studies focus on the ultrastructural and cytochemical changes which promote nuclear apoptosis and cytostructural disruption following the expression of endometrial hypercytolipidemia which promotes diabetes-associated organoinvolution and manifest infertility.

METHODS

Control (normal:+/+) and diabetes (db/db) genotype groups were prepared for high resolution light microscopic analysis of cytolipidemia and nuclear apoptosis (TUNEL-labeled 3'-DNA fragmentation) indices and compared to the transmission electron (TEM) microscopic analysis of endometrial tissue samples collected from 8-16 week-old groups.

RESULTS

Compared to controls, db/db mutation expression induced a dramatic increase in EE cytolipid vacuole volume and density within the epithelial endometrial layer. TEM analysis revealed that cytolipid vacuole accumulations initially aggregated at the baso-polar regions of UEE cells in response to the systemic hyperglycemic/hypertriglyceridemic conditions which characterized the (db/db) groups. Progressive cytoplasmic movement of the lipid pools into perinuclear compartments of affected EE cells induced nuclear isolation from organelles that were displaced towards peripheral cytoplasmic compartments. Cytochemical analysis of lipid vacuole accumulations indicated attraction towards, and incorporation within, the nuclear envelope of hyperlipidemic cells. Co-localization of nuclear apoptotic 3'-DNA fragments within identified hyperlipidemic EE cells was coincident with the cytochemical and ultrastructural identification of lipid penetration through the nuclear envelope in db/db mutants.

CONCLUSION

These results are the first cytochemical indication that the metabolic disturbances in db/db mutants which promote hypercytolipidemia are coincident with lipoapoptosis-induced nuclear dissolution, as denoted by DNA fragmentation analysis. The lipidemia-induced alterations in intracellular organelle and nuclear architectures suggests that the metabolic disturbances in glucose and lipid metabolic cascades in diabetes (db/db) mutants disrupts cytointegrity, culminating in nuclear disregulation (as indicated by lipoapoptosis) and eventual premature reproductive tract organoinvolution and resultant, manifest, reproductive sterility.

Diabetes (db/db) mutation-induced female reproductive tract hypercytolipidemia: estrogenic restoration of utero-ovarian indices

The diabetes (db/db) mutation (leptin-receptor defect) induces a hyperglycemic-hyperinsulinemic endometabolic environment that promotes hypercytolipidemic, utero-ovarian involution in C57BL/KsJ mice, resulting in reproductive sterility and eventual organoatrophy. The effectiveness of low-dose, 17-B-estradiol therapy (E2-HRx), initiated prior to the genetic expression of the overt diabetes-obesity syndrome (DOS) on preventing female reproductive tract involution was evaluated by analysis of cytochemical, endocrine and tissue lipo-metabolic indices relative to oil (O)-vehicle treated (HRx) control (+/?) and (db/db) groups. All HRx treatments started at 4 weeks of age (i.e., pre-overt DOS stage) and continued through 16 weeks of age (i.e., chronic DOS expression) when tissue parameters were evaluated. The DOS promoted a dramatic increase in phenotypic obesity, hyperglycemia and hyperinsulinemia in (db/db) groups, relative to (+/?) indices, throughout the experimental period. In contrast, utero-ovarian weights were dramatically reduced in (db/db) groups relative to (+/?). Chronic low-dose E2-HRx moderated these DOS-induced trends in (db/db) groups, maintaining lowered body weights and normoglycemic parameters while stimulating utero-ovarian weight indices. In addition, E2-HRx prevented the dramatic hypercytolipidemic condition which promotes utero-ovarian involution in (db/db) mice as evidenced by the maintenance of normal reproductive cytoarchitecture. The concurrent moderation of tissue lipase activity and stimulated glucose uptake rates by (db/db) utero-ovarian compartments, under persistent hyperinsulinemic influences, indicated that E2-HRx effectively reduced both the structural and endometabolic consequences of the DOS from promoting (db/db)-associated reproductive organoatrophy. These results indicate that the pathophysiological alterations induced by the (db/db) mutation may be ameliorated through low-dose steroidal therapy, the efficacy of which is suspected to occur via membrane metabolic cascade induction mechanisms or by direct nuclear transcription modulation in reproductive target cells. The subsequent re-establishment of insulin-coupled glucose utilization and suppressed caloric shunting towards lipogenesis promotes the normalization of utero-ovarian structural and metabolic homeostasis in C57BL/KsJ-db/db mutants.

Ovarian hypercytolipidemia induced by obese (ob/ob) and diabetes (db/db) mutations: basis of female reproductive tract involution II

The diabetes (db/db) and obese (ob/ob) genotype mutations induce a progressive, hypercytolipidemic condition within the ovarian compartments of the female reproductive tract that results in sterility and premature organ involution in C57BL/KsJ mice. The current studies focus on the ultrastructural changes that occur within the ovarian interstitial, thecal, and follicular granulosa cell layers during the progressive expression of these mutations which promote tissue cytolipidemia-induced organoinvolution. Control (normal: +/?), diabetes (db/db), and obese (ob/ob) genotype groups were prepared for high resolution light (HRLM) and transmission electron microscopic (TEM) analysis of ovarian tissue samples collected from 4 (young)- to 20 (aged)-week-old mice, allowing for the progressive influences of the mutational aberrations on tissue structure to be evaluated. Compared to controls, both (ob/ob) and (db/db) mutations induced a dramatic increase in ovarian interstitial, thecal and follicular granulosa cytolipid vacuole accumulations, which increased in density between 4 and 20 weeks of age. Initially, lipid vacuoles aggregated in the interstitial and thecal regions of ovarian follicles in response to the hyperglycemic-hypertriglyceridemic metabolic conditions typical of both (ob/ob) and (db/db) groups. Progressive cytoplasmic movement of the lipid pools established a perinuclear isolation from associated cytoplasmic organelles. Progressive lipid accumulations forced cytoplasmic organelles to peripheral cell compartments and altered the follicular cell profile towards that of adipocyte-like entities relative to controls. The progressive hypercytolipidemia-induced alterations in cell structure disrupted normal tissue continuity, which culminated in premature ovarian organo-involution and female reproductive sterility.