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dietary supplementation of aged mice with the probiotic bacterium Lactobacillus reuteri makes them appear to be younger than their matched untreated sibling mice

These results indicate that gut microbiota induce modulation of local gastrointestinal immunity resulting in systemic effects on the immune system which activate metabolic pathways that restore tissue homeostasis and overall health

all these studies we consistently observed that young and aged mice consuming purified L. reuteri organisms had particularly large testes and a dominant male behavior.

The testes of probiotic-fed aged mice were rescued from both seminiferous tubule atrophy and interstitial Leydig cell area reduction typical of the normal aging process. Preservation of testicular architecture despite advanced age or high-fat diet coincided with remarkably high levels of circulating testosterone. The beneficial effects of probiotic consumption were recapitulated by the depletion of the pro-inflammatory cytokine Il-17.

feeding of L. reuteri consistently increased the gonadal weights, consumption of a non-pathogenic strain of Escherichia coli (E. coli) K12 organisms did not affect testicular weight

mice with dietary L. reuteri supplements were rescued from diet-induced obesity and had normal body weight and lean physique

Despite the comparable numbers of ST profiles, we determined that testes from L. reuteri-treated mice had increased ST cross-sectioned profiles

the probiotic organism induced prominent Leydig cell accumulations in the interstitial tissue between the ST's

The probiotic-associated increase of interstitial Leydig cell areas was sustained with advancing age at 7 (CD vs CD+LR, P = 0.0025; CD+E.coli vs CD+LR, P = 0.0251) and 12 months

mice eating L. reuteri had profoundly increased levels of circulating testosterone regardless of the type of diet they consumed

blocking pro-inflammatory Il-17 signaling entirely recapitulates the beneficial effects of probiotics

previous studies we found that dietary probiotics counteract obesity [19] and age-related integumentary pathology [18] at least in part by down-regulating systemic pro-inflammatory IL-17A-dependent signaling

Testes histomorphometry and serum androgen concentration data were both suggestive of a probiotic-associated up-regulation of spermatogenesis in mice

Lactobacillus reuteri we discovered that aging male animals had larger testes compared to their age-matched controls

xamined testes of probiotic microbe-fed mice and found that they had less testicular atrophy coinciding with higher levels of circulating testosterone compared to their age-matched controls

Similar testicular health benefits were produced using systemic depletion of the pro-inflammatory cytokine Il-17 alone, implicating a chronic inflammatory pathway in hypogonadism

One specific aspect of this paradigm is reciprocal activities of pro-inflammatory Th-17 and anti-inflammatory Treg cells

Feeding of L. reuteri organisms was previously shown to up-regulate IL-10 levels and reduce levels of IL-17 [19] serving to lower systemic inflammation

insufficient levels of IL-10 may increase the risk for autoimmunity, obesity, and other inflammatory disease syndromes

Westernized diets are also low in vitamin D, a nutrient that when present normally works together with IL-10 to protect against inflammatory disorders

Physiological feedback loops apparently exist between microbes, host hormones, and immunity

The hormone testosterone has been shown to act directly through androgen receptors on CD4+ cells to increase IL-10 expression

studies in both humans and rodents suggest that hypogonadism is due to age-related lesions in testes rather than irregular LH metabolism

We postulate that probiotic gut microbes function symbiotically with their mammalian hosts to impart immune homeostasis to maintain systemic and testicular health [34]–[35] despite suboptimal dietary conditions.

Dietary factors and diet-induced obesity were previously shown to increase risk for age-associated male hypogonadism, reduced spermatogenesis, and low testosterone production in both humans and mice [2]–[4], [8]–[11], [14]–[17], phenotypic features that in this study were inhibited by oral probiotic therapy absent milk sugars, extra protein, or vitamin D supplied in yogurt.

Similar beneficial effects of probiotic microbes on testosterone levels and sperm indices were reported in male mice that had been simultaneously supplemented with selenium

L. reuteri-associated prevention of age- and diet-related testicular atrophy correlates with increased numbers and size of Leydig cells

the initial changes of testicular atrophy begin to occur in mice from the age of 6 moths onwards [7] and indicates that the trophic effect of L. reuteri on Leydig cells is a key event which precedes and prevents age-related changes in the testes of mice. This effect is reminiscent of earlier studies describing Leydig cell hyperplasia and/or hypertrophy in the mouse and the rat testis that were achievable by the administration of gonadotropins, including human chorionic gonadotropin, FSH and LH

Obesity was associated with progressively lower total and free T independent of the simultaneous decrease in SHBG.

our data highlight the fact that LH was unchanged or even lower in older men in the face of lower T in obesity, suggesting that there may be a failure at the hypothalamic-pituitary level.

a change in BMI from nonobese to obese may be equivalent to a 15 yr fall in T.

This pattern supports the hypothesis that different underlying mechanisms influence the functions of the HPT axis: age predominantly affects testicular function, whereas obesity impairs hypothalamic/pituitary function.

the effects of aging on testicular function can be moderated by increased LH compensation for many decades

obesity impairs hypothalamic/pituitary function independent of age, arguably an adaptive response for which there should be no compensatory mechanism.

the concurrent but opposite (and separate) effects of obesity and age on SHBG

SHBG was negatively associated with increasing strata of obesity

Obesity is associated with insulin resistance (28), and the increased circulating insulin inhibits hepatic SHBG synthesis

the SHBG increase with age may be related to relative IGF-I deficiency (27), although this has not been directly proven.

Obesity is associated with peripheral and central insulin resistance (30) and proinflammatory cytokine production (TNFα and IL-6) from adipocytes (31) and central nervous system endocannibinoid release (32), all of which are potential candidates for abrogating hypothalamic endocrine and downstream reproductive axis functions.

The relationship between obesity and T can be bidirectional: low T may be the cause rather than consequence of obesity

chronic alcohol abuse is known to suppress LH (40), our data showed no significant association among the three hormones or SHBG and alcohol intake.

increase in total T in smokers occurs through a primary increase in SHBG with a compensatory rise in LH

the effects of obesity (BMI or waist circumference) was by far the most important determinant of variance in total T, whereas age per se was important for SHBG, LH, and free T with comorbidity and smoking being comparatively minor contributors

It is noteworthy that these predisposing lifestyle and health factors are modifiable. This implies that the apparent age-related decline in T may constitute a barometer of health and thus be potentially preventable and/or reversible.

In longitudinal studies, decreased levels of total testosterone and SHBG predicted an increased incidence of metabolic syndrome in nonobese men

Free testosterone level is not associated with the prevalence of metabolic syndrome in middle-aged and older men

Levels of free, bioavailable and total testosterone are lower in men with T2DM than in age-matched controls,34, 35 and decreased total testosterone level predicts incident T2DM in middle-aged men.

men with T2DM commonly have low total or free testosterone levels

Total, bioavailable and free testosterone levels are inversely correlated with fasting insulin level and insulin resistance in middle-aged men without T2DM

total testosterone is positively correlated with insulin sensitivity in men with normal or impaired glucose tolerance or T2DM

low SHBG level is more strongly associated with metabolic syndrome than low total testosterone in aging men

the recognized association between low SHBG level and insulin resistance

Low levels of SHBG are also associated with smaller, denser LDL-cholesterol molecules in nondiabetic men,58 and were found to predict increased cardiovascular disease mortality in one study of older men

Low levels of SHBG might reflect obesity, insulin resistance and overall poor health

Compared with those who have normal testosterone levels, men aged 40 years or more with total testosterone levels <9.8 nmol/l or elevated LH level have greater CIMT

In men aged 73–94 years, total testosterone was inversely correlated with CIMT

a prospective analysis of men aged 73–91 years, progression of CIMT was not related to total testosterone level, but it was inversely related to free testosterone level

A study of men aged 55 years or more found that those with total and bioavailable testosterone levels in the highest tertile had a lower risk of severe aortic atherosclerosis (detected by radiography as abdominal aortic calcification) than those with the lowest testosterone levels.

a large study of men aged 69–80 years, those with total or free testosterone in the lowest quartile had increased odds of lower-extremity peripheral arterial disease

the possibility of reverse causation has to be considered, as systemic illness can result in decreased testosterone levels

previous case–control studies and longitudinal studies have failed to identify low testosterone levels as strong predictors of clinically significant coronary disease

Reviews of trials on testosterone therapy in men with either low or low-to-normal testosterone levels have not shown consistent beneficial effects either on lipid profiles or on actual cardiovascular events.24, 54, 55 These trials, however, have not been designed or powered to detect treatment-related differences in cardiovascular outcome

SHBG decreases in response to androgens, and in the presence of hypothyroidism, and insulin resistance.

Plasma SHBG levels tend to increase with increasing age

The apparent metabolic clearance rate of testosterone is decreased in elderly as compared to younger men

Testosterone circulates predominantly bound to the plasma proteins SHBG and albumin, with high and low affinity respectively

Testosterone is secreted in a pulsatile fashion

Current clinical guidelines suggest at least two measurements

In adult men, there is a well-documented diurnal variation (particularly in younger subjects) in testosterone levels, which are highest in the early morning and progressively decline throughout the day to a nadir in the evening

In older men, the diurnal variation is blunted

it is standard practice for samples to be obtained between 0800 and 1100 h.

Testosterone and DHEA decline, whereas LH, FSH, and SHBG rise

DHT remains constant despite the decline of its precursor testosterone

Longitudinal studies show an average annual decline of 1–2% total testosterone levels, with decline in free testosterone more rapid because of increases in SHBG with aging

Massachusetts Male Aging Study (MMAS) data show DHEA, DHEAS, and Ae declining at 2–3% per year

DHT showed no cross-sectional age trend

Androstanediol glucuronide (AAG) declined cross-sectionally with age in the MMAS sample, at 0.6% per year

The EMAS data show that, consistent with the longitudinal findings of MMAS (Figure 1), the core hormonal pattern with increasing age is suggestive of incipient primary testicular dysfunction with maintained total testosterone and progressively blunted free testosterone associated with higher LH

obesity impairs hypothalamic/pituitary function

Androgen deprivation in men with prostate cancer has been associated with increased insulin resistance, worse glycemic control, and a significant increase in risk of incident diabetes

Low serum testosterone is associated with the development of metabolic syndrome 116, 117 and type 2 diabetes. 118 SHBG has been inversely correlated with type 2 diabetes

Improvement in insulin sensitivity with testosterone treatment has been reported in healthy 121 and diabetic 122 adult men

In studies conducted in men with central adiposity, testosterone has been shown to inhibit lipoprotein lipase activity in abdominal adipose tissue leading to decreased triglyceride uptake in central fat depots. 123

Researchers tried to examine whether serum total or free testosterone would be a better/more reliable choice when studying the effect of testosterone. The results were mixed. Some reported significant associations of both serum total and free testosterone level with clinical parameters25, whereas others reported that only serum free testosterone26 or only serum total testosterone6 showed significant associations.

−0.124 nmol/L/year in serum total testosterone

In experimental studies, androgen receptor knockout mice developed significant insulin resistance rapidly

In mouse models, testosterone promoted differentiation of pluripotent stem cells to the myogenic lineage

testosterone decreased insulin resistance by enhancing catecholamine induced lipolysis in vitro, and reducing lipoprotein lipase activity and triglyceride uptake in human abdominal tissue in vivo

by promoting lipolysis and myogenesis, testosterone might lead to improved insulin resistance

testosterone regulated skeletal muscle genes involved in glucose metabolism that led to decreased systemic insulin resistance

In the liver, hepatic androgen receptor signaling inhibited development of insulin resistance in mice

independent and inverse association of testosterone with hepatic steatosis shown in a cross-sectional study carried out in humans

In short, androgen improves insulin resistance by changing body composition and reducing body fat.

Although a low serum testosterone level could contribute to the development of obesity and type 2 diabetes through changes in body composition, obesity might also alter the metabolism of testosterone

In obese men, the peripheral conversion from testosterone to estrogen could attenuate the amplitude of luteinizing hormone pulses and centrally inhibit testosterone production

leptin, an adipokine, has been shown to be inversely correlated with serum testosterone level in men

Leydig cells expressed leptin receptors and leptin has been shown to inhibit testosterone secretion, suggesting a role of obesity and leptin in the pathogenesis of low testosterone

Baltimore Longitudinal Study of Aging (BLSA) cohort made up of 3,565 middle-class, mostly Caucasian men from the USA, the incidence of low serum total testosterone increased from approximately 20% of men aged over 60 years, 30% over 70 years, to 50% over 80 years-of-age

30–44% sex hormone binding globulin (SHBG)-bound testosterone and 54–68% albumin-bound testosterone

As the binding of testosterone to albumin is non-specific and therefore not tight, the sum of free and albumin-bound testosterone is named bioavailable testosterone, which reflects the hormone available at the cellular level

Serum total testosterone is composed of 0.5–3.0% of free testosterone unbound to plasma proteins

alterations in SHBG concentration might affect total serum testosterone level without altering free or bioavailable testosterone

listed in Table​T

A significant, independent and longitudinal effect of age on testosterone has been observed with an average change of −0.124 nmol/L/year in serum total testosterone28. The same trend has been shown in Europe and Australia

Asian men residing in HK and Japan, but not those living in the USA, had 20% higher serum total testosterone than in Caucasians living in the USA, as shown in a large multinational observational prospective cohort of the Osteoporotic Fractures in Men Study

subjects with chronic diseases consistently had a 10–15% lower level compared with age-matched healthy subjects

In Caucasians, the mean serum total testosterone level for men in large epidemiological studies has been reported to range from 15.1 to 16.6 nmol/L

Asians, higher values, ranging from 18.1 to 19.1 nmol/L, were seen in Korea and Japan

Chinese middle-aged men reported a similar mean serum testosterone level of 17.1 nmol/L in 179 men who had a family history of type 2 diabetes and 17.8 nmol/L in 128 men who had no family history of type 2 diabetes

The reduction of total testosterone was 0.4% per year in both groups

HK involving a cohort of 1,489 community-dwelling men with a mean age of 72 years, a mean serum total testosterone of 19.0 nmol/L was reported

pro-inflammatory factors, such as tumor necrosis factor-α in the testes, could locally inhibit testosterone biosynthesis in Leydig cells47, and testosterone treatment in men was shown to reduce the level of tumor necrosis factor-α

In Asians, a genetic deletion polymorphism of uridine diphosphate-glucuronosyltransferase UGT2B17 was associated with reduced androgen glucuronidation. This resulted in higher level of active androgen in Asians as compared to Caucasians, as Caucasians' androgen would be glucuronidated into inactive forms faster.

Compared with Caucasians, the frequency of this deletion polymorphism of UGT2B17 was 22-fold higher in Asian subjects

Other researchers have suggested that environmental, but not genetic, factors influenced serum total testosterone

The basal and ligand-induced activity of the AR is inversely associated with the length of the CAG repeat chain

In the European Male Aging Study, increased estrogen/androgen ratio in association with longer AR CAG repeat was observed

a smaller number of AR CAG repeat had been shown to be associated with benign prostate hypertrophy and faster prostate growth during testosterone treatment

In India, men with CAG ≤19 had increased risk of prostate cancer

the odds of having a short CAG repeat (≤17) were substantially higher in patients with lymph node-positive prostate cancer than in those with lymph node-negative disease or in the general population

assessing the polymorphism at the AR level could be a potential tool towards individualized assessment and treatment of hypogonadism.

In elderly men, there was reduced testicular response to gonadotropins with suppressed and altered pulsatility of the hypothalamic pulse generator

a significant, independent and longitudinal effect of age on serum total testosterone level had been observed

A significant graded inverse association between serum testosterone level and insulin levels independent of age has also been reported in Caucasian men

Low testosterone is commonly associated with a high prevalence of MES

most studies showed that changes in serum testosterone level led to changes in body composition, insulin resistance and the presence of MES, the reverse might also be possible

MES predicted a 2.6-fold increased risk of development of low serum testosterone level independent of age, smoking and other potential confounders

Other prospective studies have shown that development of MES accelerated the age-related decline in serum testosterone level

In men with type 2 diabetes, changes in serum testosterone level over time correlated inversely with changes in insulin resistance

weight loss by either diet control or bariatric surgery led to a substantial increase in total testosterone, especially in morbidly obese men, and the rise in serum testosterone level was proportional to the amount of weight lost

To date, published clinical trials are small, of short duration and often used pharmacological, not physiological, doses of testosterone

In the population-based Osteoporotic Fractures in Men Study cohort from Sweden, men in the highest quartile of serum testosterone level had the lowest risk of cardiovascular events compared with men in the other three quartiles (hazard ratio [HR] 0.70

low serum total testosterone was associated with a significant fourfold higher risk of cardiovascular events when comparing men from the lowest testosterone tertile with those in the highest tertile

Shores et al. were the first to report that low serum testosterone level, including both serum total and free testosterone, was associated with increased mortality

low serum total testosterone predicted increased risk of cardiovascular mortality with a HR of 1.38

low serum total testosterone increased all-cause (HR 1.35, 95% CI 1.13–1.62, P < 0.001) and cardiovascular mortality (HR 1.25

European Association for the Study of Diabetes 2013 suggested there was an inverse relationship between serum testosterone level and acute myocardial infarction

Diabetic men in the highest quartile of serum total testosterone had a significantly reduced risk of acute MI when compared with those in the lower quartiles

serum total testosterone level in the middle two quartiles at baseline predicted reduced incidence of death compared with having the highest and lowest levels

primary hypogonadism (probably the genuine form of LOH) is strongly associated with age

Compensated hypogonadism represents a distinct clinical entity that warrants continued monitoring to prevent or preempt further deterioration

The RRs were 0.95 (0.54, 1.67) under 55 years

1.35 (0.77, 2.38) at 55–59

1.29 (0.71, 2.35) at 60–64,

1.35 (0.44, 4.18) at 65–69, 1.62

3.43 (1.54, 7.66) at 75 years and older

The adjusted post/pre RR for PDE5I across all ages was 1.08

For TT prescription, in men under age 65 years, the RR was 2.90 (1.49, 5.62) for those with a history of heart disease and 0.90 (0.61, 1.34) for those without

In men aged 65 year and older, the RR was 2.16 (0.92, 5.10) for those with a history of heart disease and 2.21 (1.09, 4.45) for those without.

Among men aged 65 years and older, we observed a two-fold increase in the risk of MI in the 90 days after filling an initial TT prescription

Among younger men with a history of heart disease, we observed a two to three-fold increased risk of MI in the 90 days following an initial TT prescription and no excess risk in younger men without such a history

Among older men, the two-fold increased risk was associated with TT prescription regardless of cardiovascular disease history

our own findings appear consistent with a higher frequency of thrombotic events following TT prescription among men with more extensive coronary vascular disease.

Our findings are consistent with a recent meta-analysis of placebo-controlled randomized trials of testosterone therapy lasting 12 or more weeks among mainly older men, which reported that testosterone therapy increased the risk of adverse cardiovascular-related events (OR = 1.54, 95%CI:1.09, 2.18), as well as serious adverse cardiovascular-related events (OR = 1.61, 95%CI:1.01, 2.56) which included myocardial infarction along with other conditions

This association appeared unrelated to average baseline testosterone level (p = 0.70) but varied by source of funding (p = 0.03), with a stronger summary effect in a meta-analysis of studies not funded by the pharmaceutical industry (OR = 2.06, 95%CI:1.34, 3.17) compared with studies funded by the pharmaceutical industry

the evidence supports an association between testosterone therapy and risk of serious, adverse cardiovascular-related events–including non-fatal myocardial infarction–in men

there is some evidence that low endogenous testosterone levels may also be positively associated with cardiovascular events

effects of endogenous and exogenous testosterone may differ. Exogenous testosterone (TT) is associated with physiologic changes that predispose to clotting and thrombotic disorders including increased blood pressure [18], polycythemia [19], reductions in HDL cholesterol [18], [20], and hyperviscosity of the blood and platelet aggregation. [20]–[23]; TT also increases circulating estrogens [24], [25] which may play a role in the observed excess of adverse cardiovascular-related events, given that estrogen therapy has been associated with this excess in both men and women

did not include information on the serologic or diagnostic indications for treatment.

no association between PDE5I prescriptions and the risk of MI

Recently TT has been increasing extraordinarily rapidly, including among younger men and among those without hormone measurement

aging in men is associated with decreases in bone mineral density (BMD) (18, 19), lean body and muscle mass

strength (22, 23) and aerobic capacity (24), as well as with increases in total and abdominal body fat, low-density lipoprotein cholesterol, and/or low-density lipoprotein/high-density lipoprotein cholesterol ratios (25, 26, 27, 28), all of which also occur in nonelderly hypogonadal men

Most (1, 5, 6, 7, 8, 9), but not all (10, 11, 12), cross-sectional studies have demonstrated a decrease, with age, in total T in men

total T, but not free T index, tended to decrease with greater BMI is consistent with prior studies showing that obesity is associated with decreases in both SHBG and total T, with an unchanged T-to-SHBG ratio

The conventional definition for T levels is statistical (values more than 2 sd below the mean), rather than functional. Such a definition does not reflect clinical realities, such as the existence of characteristic individual set points for circulating hormone levels, below which one, but not another, individual may develop metabolic changes of hormone deficiency; nor does it address the concept of reserve capacity, the possibility that persons with hormone levels 2 sd below the population mean still may have adequate hormone concentrations to meet their metabolic needs.

both T and free T index (a calculated value related to free or bioavailable T) decreased progressively at a rate that did not vary significantly with age, from the third to the ninth decades.

contrasts with other studies showing diminished free, as well as total, T in with increasing total (48) or abdominal (49) obesity in men.

Our analysis of date-adjusted T and free T index levels, by decade, showed that relatively high numbers of older men in this generally healthy population had at least one hypogonadal value (defined as below the 2.5th percentile for young men)

The issue of how properly to define hypogonadism, or indeed any hormone deficiency, remains problematic

The decrease in free T index was somewhat steeper than that of total T, owing to a trend for an increase in SHBG with age

LH for gonadal function

It would clearly be better to define the lower limit of normal for a hormone as: the blood level at which metabolic and/or clinical sequelae of hormone deficiency begin to appear, or the level below which definite benefits can be demonstrated for hormone supplementation for a significant proportion of the population

an effect of aging to lower both total and bioavailable circulating T levels at a relatively constant rate, independent of obesity, illness, medications, cigarette smoking, or alcohol intake

Bioavailable and free testosterone are known to correlate better than total testosterone with clinical sequelae of androgenization such as bone mineral density and muscle strength

peak levels seen in the morning following sleep, which can be maintained into the seventh decade

Samples should always be taken in the morning before 11 am

The reliable measurement of serum free testosterone requires equilibrium dialysis. This is not appropriate for clinical use as it is very time consuming and therefore expensive.

With increasing age, a greater number of men have total testosterone levels just below the normal range or in the low-normal range. In these patients total testosterone can be an unreliable indicator of hypogonadal status.

It is advised that at least two serum testosterone measurements, taken before 11 am on different mornings, are necessary to confirm the diagnosis.

Patients with serum total testosterone consistently below 8 nmol/l invariably demonstrate the clinical syndrome of hypogonadism and are likely to benefit from treatment. Patients with serum total testosterone in the range 8–12 nmol/l often have symptoms attributable to hypogonadism and it may be decided to offer either a clinical trial of testosterone treatment or to make further efforts to define serum bioavailable or free testosterone and then reconsider treatment. Patients with serum total testosterone persistently above 12 nmol/l do not have hypogonadism and symptoms are likely to be due to other disease states or ageing per se so testosterone treatment is not indicated.

Total testosterone levels fall at an average of 1.6% per year whilst free and bioavailable levels fall by 2%–3% per year.

With advancing age there is also a reduction in androgen receptor concentration in some target tissues and this may contribute to the clinical syndrome of LOH

Metabolic clearance declines with age

Gonadotrophin levels rise during aging (Feldman et al 2002) and testicular secretory responses to recombinant human chorionic gonadotrophin (hCG) are reduced

There are changes in the lutenising hormone (LH) production which consist of decreased LH pulse frequency and amplitude, (Veldhuis et al 1992; Pincus et al 1997) although pituitary production of LH in response to pharmacological stimulation with exogenous GnRH analogues is preserved

the decreases in testosterone levels with aging seem to reflect changes at all levels of the hypothalamic-pituitary-testicular axis

The Boston Area Community Health Study reported that 5.6% of men aged 30 to 70 were hypogonadal, as defined by total serum T < 300 ng/dL; or, free serum T < 5 ng/dL plus 3 or more symptoms of hypogonadism

In a health screening project among 819 men in Taiwan, the prevalence of hypogonadism (total serum T < 300 ng/dL) ranged from 16.5% for men in their 40s, 23.0% for men in their 50s, 28.9% for men in their 60s, and 37.2% for men older than 70 years of age

The prevalence of hypogonadism among men in Taiwan is higher than the prevalence reported in the Massachusetts Male Aging Study

CAG repeat sequence, within the androgen receptor (AR). Rajender et al[12] reviewed over 30 studies on the AR trinucleotide repeat and infertility

suggestion that CAG repeat length may determine androgen responsiveness, this issue is not clearly settled

reported prevalence of low T in older men range from 5.6% to 50%

Those in the hypogonadal group (n = 4269) had direct health care costs, that exceeded the eugonadal group (n = 4269) by an average of $7100 over the course of the observation window

higher economic burden and presence of co-morbidities for hypogonadism

minor to moderate improvements in lean mass and muscle strength

increased bone mineral density

modest enhancement in sexual function

reduced adiposity

lessening of depressive symptoms

Meta-analyses of clinical TRT trials as of 2010 have identified three major adverse events resulting from TRT: (1) polycythemia; (2) an increase in prostate-related events; and (3) and a slight reduction in serum high-density lipoprotein (HDL) cholesterol

polycythemia (> 3.5-fold increase in risk

TRT produced a 40% prostate enlargement in older hypogonadal male Veterans over 12 mo

no published analysis has reported measurable increases in prostate cancer risk or Gleason score in men undergoing TRT, or in hypogonadal men with a history of prostate cancer undergoing TRT

the prostate which highly expresses the type II 5α-reductase enzyme. Inhibition of this enzyme via finasteride (a type II 5α-reductase inhibitor) or dutasteride (a dual type I and II 5α-reductase inhibitor) reduces circulating DHT 50%-75% and > 90%, respectively[47], and reduces prostate mass[48] and prostate cancer risk

Normally estradiol partially regulates testosterone levels, at the hypothalamus, blunting LH and FSH release from the pituitary. As a selective estrogen receptor modulator, CC interrupts this pathway, and consequently there is a greater stimulation for the production of testosterone in Leydig cells

advanced age, obesity, a diagnosis of metabolic syndrome, and poor general health status were predictors of LOH

Diabetes mellitus was correlated with hypogonadism in most studies

coronary heart disease, hypertension, stroke, and peripheral arterial disease did not predict hypogonadism, they did correlate with the incidence of low testosterone

LOH can be defined by the presence of at least three sexual symptoms associated with a total testosterone level of less than 11 nmol/L (3.2 ng/mL) and a free testosterone level of less than 220 pmol/L (64 pg/mL)

Mean weight decreased

Waist circumference decreased

Total cholesterol decreased

Low-density lipoprotein decreased

Triglycerides decreased

High-density lipoprotein (HDL) increased

ratio of total cholesterol to HDL improved

Prostate volume increased

PSA increased

The benefits for men older than 65 years of age were compared with those of younger men, and the improvements in body weight, metabolic factors, psychological functioning, and sexual functioning were of the same magnitude in both age groups

weight loss was progressive over the 6-year period, effects of testosterone on lipids and on psychological and sexual functioning reached a plateau after approximately 3 years and these effects were sustained

Effects of testosterone on hematopoiesis, on the prostate, and on bladder function were not more severe in older men than in younger men

observe a mild increase in prostate volume and serum PSA over time, which is a normal finding in aging men. Maybe somewhat surprising, postvoiding residue and the IPSS did not deteriorate with aging but showed a degree of improvement

the severity of the metabolic syndrome is associated with the severity of lower urinary tract symptoms

The symptoms of the metabolic syndrome improve upon testosterone treatment and testosterone may thus have a favorable effect on lower urinary tract symptoms

it seems reasonable to conclude that the risks of testosterone administration to elderly men are not disproportionately higher in elderly men than in younger men.

Despite evidence to the contrary, physicians still harbor a wrongful association between testosterone and the development of prostate pathology (prostate cancer and benign prostate hyperplasia)

Not surprisingly, the incidence of prostate cancer was higher in older men; however, it was lower than expected in both groups

These observations suggest that the incidence of prostate cancer in patients receiving testosterone therapy, both in the younger and in the older group, was not greater than in the general population not receiving testosterone treatment

The historical fear that raising testosterone levels will result in more prostate cancer has been dispelled, particularly by the work of Abraham Morgentaler

Higher serum testosterone levels fail to show an increased risk of prostate cancer, and supraphysiological testosterone does not increase prostate volume or PSA in healthy men

This apparent paradox is explained by the "saturation model,"

Recent studies indicate no increased risk of prostate cancer among men with serum testosterone in the therapeutic range

In the present observational study, no cases of major adverse cardiovascular events occurred.

the benefits of testosterone therapy are fully achieved only by long-term treatment

To achieve maximal benefits, good patient adherence is a prerequisite

The presence of symptoms was more closely linked to increasing age than to testosterone levels

Findings similar to type 2 diabetes were reported for men with the metabolic syndrome, which were associated with reductions in total testosterone of −2.2 nmol/l (95% CI −2.41 to 1.94) and in free testosterone

low testosterone is more predictive of the metabolic syndrome in lean men

Cross-sectional studies uniformly show that 30–50% of men with type 2 diabetes have lowered circulating testosterone levels, relative to references based on healthy young men

In a recent cross-sectional study of 240 middle-aged men (mean age 54 years) with either type 2 diabetes, type 1 diabetes or without diabetes (Ng Tang Fui et al. 2013b), increasing BMI and age were dominant drivers of low total and free testosterone respectively.

both diabetes and the metabolic syndrome are associated with a modest reduction in testosterone, in magnitude comparable with the effect of 10 years of ageing

In a cross-sectional study of 490 men with type 2 diabetes, there was a strong independent association of low testosterone with anaemia

In men, low testosterone is a marker of poor health, and may improve our ability to predict risk

low testosterone identifies men with an adverse metabolic phenotype

Diabetic men with low testosterone are significantly more likely to be obese or insulin resistant

increased inflammation, evidenced by higher CRP levels

Bioavailable but not free testosterone was independently predictive of mortality

It remains possible that low testosterone is a consequence of insulin resistance, or simply a biomarker, co-existing because of in-common risk factors.

In prospective studies, reviewed in detail elsewhere (Grossmann et al. 2010) the inverse association of low testosterone with metabolic syndrome or diabetes is less consistent for free testosterone compared with total testosterone

In a study from the Framingham cohort, SHBG but not testosterone was prospectively and independently associated with incident metabolic syndrome

low SHBG (Ding et al. 2009) but not testosterone (Haring et al. 2013) with an increased risk of future diabetes

In cross-sectional studies of men with (Grossmann et al. 2008) and without (Bonnet et al. 2013) diabetes, SHBG but not testosterone was inversely associated with worse glycaemic control

SHBG may have biological actions beyond serving as a carrier protein for and regulator of circulating sex steroids

In men with diabetes, free testosterone, if measured by gold standard equilibrium dialysis (Dhindsa et al. 2004), is reduced

Low free testosterone remains inversely associated with insulin resistance, independent of SHBG (Grossmann et al. 2008). This suggests that the low testosterone–dysglycaemia association is not solely a consequence of low SHBG.

Experimental evidence reviewed below suggests that visceral adipose tissue is an important intermediate (rather than a confounder) in the inverse association of testosterone with insulin resistance and metabolic disorders.

testosterone promotes the commitment of pluripotent stem cells into the myogenic lineage and inhibits their differentiation into adipocytes

testosterone regulates the metabolic functions of mature adipocytes (Xu et al. 1991, Marin et al. 1995) and myocytes (Pitteloud et al. 2005) in ways that reduce insulin resistance.

Pre-clinical evidence (reviewed in Rao et al. (2013)) suggests that at the cellular level, testosterone may improve glucose metabolism by modulating the expression of the glucose-transported Glut4 and the insulin receptor, as well as by regulating key enzymes involved in glycolysis.

More recently testosterone has been shown to protect murine pancreatic β cells against glucotoxicity-induced apoptosis

Interestingly, a reciprocal feedback also appears to exist, given that not only chronic (Cameron et al. 1990, Allan 2013) but also, as shown more recently (Iranmanesh et al. 2012, Caronia et al. 2013), acute hyperglycaemia can lower testosterone levels.

There is also evidence that testosterone regulates insulin sensitivity directly and acutely

In men with prostate cancer commencing androgen deprivation therapy, both total as well as, although not in all studies (Smith 2004), visceral fat mass increases (Hamilton et al. 2011) within 3 months

More prolonged (>12 months) androgen deprivation therapy has been associated with increased risk of diabetes in several large observational registry studies

Testosterone has also been shown to reduce the concentration of pro-inflammatory cytokines in some, but not all studies, reviewed recently in Kelly & Jones (2013). It is not know whether this effect is independent of testosterone-induced changes in body composition.

the observations discussed in this section suggest that it is the decrease in testosterone that causes insulin resistance and diabetes. One important caveat remains: the strongest evidence that low testosterone is the cause rather than consequence of insulin resistance comes from men with prostate cancer (Grossmann & Zajac 2011a) or biochemical castration, and from mice lacking the androgen receptor.

Several large prospective studies have shown that weight gain or development of type 2 diabetes is major drivers of the age-related decline in testosterone levels

there is increasing evidence that healthy ageing by itself is generally not associated with marked reductions in testosterone

Circulating testosterone, on an average 30%, is lower in obese compared with lean men

increased visceral fat is an important component in the association of low testosterone and insulin resistance

The vast majority of men with metabolic disorders have functional gonadal axis suppression with modest reductions in testosterone levels

obesity is a dominant risk factor

men with Klinefelter syndrome have an increased risk of metabolic disorders. Interestingly, greater body fat mass is already present before puberty

Only 5% of men with type 2 diabetes have elevated LH levels

inhibition of the gonadal axis predominantly takes place in the hypothalamus, especially with more severe obesity

Metabolic factors, such as leptin, insulin (via deficiency or resistance) and ghrelin are believed to act at the ventromedial and arcuate nuclei of the hypothalamus to inhibit gonadotropin-releasing hormone (GNRH) secretion from GNRH neurons situated in the preoptic area

kisspeptin has emerged as one of the most potent secretagogues of GNRH release

hypothesis that obesity-mediated inhibition of kisspeptin signalling contributes to the suppression of the HPT axis, infusion of a bioactive kisspeptin fragment has been recently shown to robustly increase LH pulsatility, LH levels and circulating testosterone in hypotestosteronaemic men with type 2 diabetes

A smaller study with a similar experimental design found that acute testosterone withdrawal reduced insulin sensitivity independent of body weight, whereas oestradiol withdrawal had no effects

suppression of the diabesity-associated HPT axis is functional, and may hence be reversible

Obesity and dysglycaemia and associated comorbidities such as obstructive sleep apnoea (Hoyos et al. 2012b) are important contributors to the suppression of the HPT axis

weight gain and development of diabetes accelerate the age-related decline in testosterone

Modifiable risk factors such as obesity and co-morbidities are more strongly associated with a decline in circulating testosterone levels than age alone

55% of symptomatic androgen deficiency reverted to a normal testosterone or an asymptomatic state after 8-year follow-up, suggesting that androgen deficiency is not a stable state

Weight loss can reactivate the hypothalamic–pituitary–testicular axis

Leptin treatment resolves hypogonadism in leptin-deficient men

The hypothalamic–pituitary–testicular axis remains responsive to treatment with aromatase inhibitors or selective oestrogen receptor modulators in obese men

Kisspeptin treatment increases LH secretion, pulse frequency and circulating testosterone levels in hypotestosteronaemic men with type 2 diabetes

change in BMI was associated with the change in testosterone (Corona et al. 2013a,b).

weight loss can lead to genuine reactivation of the gonadal axis by reversal of obesity-associated hypothalamic suppression

There is pre-clinical and observational evidence that chronic hyperglycaemia can inhibit the HPT axis

in men who improved their glycaemic control over time, testosterone levels increased. By contrast, in those men in whom glycaemic control worsened, testosterone decreased

testosterone levels should be measured after successful weight loss to identify men with an insufficient rise in their testosterone levels. Such men may have HPT axis pathology unrelated to their obesity, which will require appropriate evaluation and management.

diacylglycerol O-acyltransferase 2 (DGAT2), mechanistically implicated in this differential storage, [10] is regulated by dihydrotestosterone, [11] suggesting a potential role for androgens to influence the genetic predisposition to either the MHO or MONW phenotype.

bariatric surgery achieves 10%-30% long-term weight loss in controlled studies

The fact that obese men have lower testosterone compared to lean men has been recognized for more than 30 years

Reductions in testosterone levels correlate with the severity of obesity and men

epidemiological data suggest that the single most powerful predictor of low testosterone is obesity, and that obesity is a major contributor of the age-associated decline in testosterone levels.

healthy ageing by itself is uncommonly associated with marked reductions in testosterone levels

obesity blunts this LH rise, obesity leads to hypothalamic-pituitary suppression irrespective of age which cannot be compensated for by physiological mechanisms

Reductions in total testosterone levels are largely a consequence of reductions in sex hormone binding globulin (SHBG) due to obesity-associated hyperinsulinemia

although controversial, measurement of free testosterone levels may provide a more accurate assessment of androgen status than the (usually preferred) measurement of total testosterone in situations where SHBG levels are outside the reference range

SHBG increases with age

marked obesity however is associated with an unequivocal reduction of free testosterone levels, where LH and follicle stimulating hormone (FSH) levels are usually low or inappropriately normal, suggesting that the dominant suppression occurs at the hypothalamic-pituitary level

adipose tissue, especially when in the inflamed, insulin-resistant state, expresses aromatase which converts testosterone to estradiol (E 2 ). Adipose E 2 in turn may feedback negatively to decrease pituitary gonadotropin secretion

diabetic obesity is associated with decreases in circulatory E 2

In addition to E 2 , increased visceral fat also releases increased amounts of pro-inflammatory cytokines, insulin and leptin; all of which may inhibit the activity of the HPT axis at multiple levels

In the prospective Massachusetts Male Aging Study (MMAS), moving from a non-obese to an obese state resulted in a decline of testosterone levels

weight loss, whether by diet or surgery, increases testosterone levels proportional to the amount of weight lost

fat is androgen-responsive

low testosterone may augment the effects of a hypercaloric diet

In human male ex vivo adipose tissue, testosterone decreased adipocyte differentiation by 50%.

Testosterone enhances catecholamine-induced lipolysis in vitro and reduces lipoprotein lipase activity and triglyceride uptake in human abdominal adipose tissue in vivo

in men with prostate cancer receiving 12 months of androgen deprivation therapy, fat mass increased by 3.4 kg and abdominal VAT by 22%, with the majority of these changes established within 6 months

severe sex steroid deficiency can increase fat mass rapidly

bidirectional relationship between testosterone and obesity

increasing body fat suppresses the HPT axis by multiple mechanisms [30] via increased secretion of pro-inflammatory cytokines, insulin resistance and diabetes; [19],[44] while on the other hand low testosterone promotes further accumulation of total and visceral fat mass, thereby exacerbating the gonadotropin inhibition

androgens may play a more significant role in VAT than SAT

men undergoing androgen depletion for prostate cancer show more marked increases in visceral compared to subcutaneous fat following treatment