Dutasteride in men receiving testosterone therapy: a randomised,double‐blind study

We investigate the impact of dutasteride on prostate specific antigen (PSA) and prostate volume in men receiving testosterone (T) therapy. Twenty‐three men on stable dose T therapy were randomised to receive either dutasteride or placebo for 12 months. Serum levels of PSA, T and dihydrotestosterone (DHT) and responses to the International Index of Erectile Function (IIEF) and Male Sexual Health Questionnaire (MSHQ) questionnaires were determined at baseline and at 3, 6, 9 and 12 months. Prostate volume (PV) was measured using transrectal ultrasound (TRUS) at baseline and again after 12 months. A total of 22 men (mean age 57.3) completed the study, with 11 men receiving placebo and 11 receiving dutasteride. Men receiving dutasteride had a significant decrease in PSA (?0.46 ± 0.81 ng ml^?1; P = 0.04) and in PV (?6.65 ± 11.0%; P = 0.03) from baseline over 12 months. DHT decreased significantly for men on dutasteride compared with men receiving placebo (P = 0.02). When compared with men who received placebo, men who received dutasteride demonstrated nonsignificant trends towards decreased PSA (?0.46 versus 0.21 ng ml^?1; P = 0.11), PV (?6.65% versus 3.4%; P = 0.08) and MSHQ scores (?10.2 versus 5.6; P = 0.06). Dutasteride reduces PSA and PV for men on T therapy, but perhaps less so than in men without T therapy.     

Albumin-associated free fatty acids induce macropinocytosis in podocytes

Podocytes are specialized epithelial cells in the kidney glomerulus that play important structural and functional roles in maintaining the filtration barrier. Nephrotic syndrome results from a breakdown of the kidney filtration barrier and is associated with proteinuria, hyperlipidemia, and edema. Additionally, podocytes undergo changes in morphology and internalize plasma proteins in response to this disorder. Here, we used fluid-phase tracers in murine models and determined that podocytes actively internalize fluid from the plasma and that the rate of internalization is increased when the filtration barrier is disrupted. In cultured podocytes, the presence of free fatty acids (FFAs) associated with serum albumin stimulated macropinocytosis through a pathway that involves FFA receptors, the Gβ/Gγ complex, and RAC1. Moreover, mice with elevated levels of plasma FFAs as the result of a high-fat diet were more susceptible to Adriamycin-induced proteinuria than were animals on standard chow. Together, these results support a model in which podocytes sense the disruption of the filtration barrier via FFAs bound to albumin and respond by enhancing fluid-phase uptake. The response to FFAs may function in the development of nephrotic syndrome by amplifying the effects of proteinuria.     

All Men with Vasculogenic Erectile Dysfunction Require a Cardiovascular Workup

An association between erectile dysfunction and cardiovascular disease has long been recognized, and studies suggest that erectile dysfunction is an independent marker of cardiovascular disease risk. Therefore, assessment and management of erectile dysfunction may help identify and reduce the risk of future cardiovascular events, particularly in younger men. The initial erectile dysfunction evaluation should distinguish between predominantly vasculogenic erectile dysfunction and erectile dysfunction of other etiologies. For men believed to have predominantly vasculogenic erectile dysfunction, we recommend that initial cardiovascular risk stratification be based on the Framingham Risk Score. Management of men with erectile dysfunction who are at low risk for cardiovascular disease should focus on risk-factor control; men at high risk, including those with cardiovascular symptoms, should be referred to a cardiologist. Intermediate-risk men should undergo noninvasive evaluation for subclinical atherosclerosis. A growing body of evidence supports the use of emerging prognostic markers to further understand cardiovascular risk in men with erectile dysfunction, but few markers have been prospectively evaluated in this population. In conclusion, we support cardiovascular risk stratification and risk-factor management in all men with vasculogenic erectile dysfunction.     

Efficacy and safety of plecanatide in treating constipation predominant irritable bowel syndrome

Introduction: Uroguanylin interacting with intestinal Guanylate Cyclase C (GC-C) receptors plays an important role in gastrointestinal fluid and electrolyte homeostasis. Plecanatide is the first uroguanylin analog that stimulates GC-C receptors on gastrointestinal mucosa with pH-sensitive receptor binding. Binding to the GC-C receptor activates intracellular conversion of GTP to cGMP resulting in the stimulation of intestinal fluid secretion.

Areas covered: Herein, all published research regarding the development of and clinical experience with plecanatide is reviewed. Clinical study results in patients with Chronic Idiopathic Constipation (CIC) and Irritable Bowel Syndrome with Constipation (IBS-C) are also reviewed. Success in the treatment of CIC and IBS-C is supported by beneficial effects on stool viscosity, Complete Spontaneous Bowel Movements and visceral sensation. Finally, the discussion within focuses on the importance of plecanatide in understanding the physiology of uroguanylin, the pathophysiology of IBS-C and the potential for development of uroguanylin and guanylin analogs.

Expert opinion: Given this broad spectrum of potential activity for GC-C agonists, it would not be surprising to see that the use of agents such as plecanatide in new areas grow to a level even greater than the use for the present CIC and IBS-C indications.     

腹腔镜全结直肠切除回肠储袋-肛管吻合手术疗效

全结直肠切除回肠储袋-肛管吻合术(ileal pouch-anal anastomosis,IPAA)最早由Parks和Nicholls[1]于1978年报道,现已成为溃疡性结肠炎(ulcerative colitis,UC)、家族性腺瘤性息肉病的首选手术方式[2-3]。该术式在切除全部结直肠后,再用末段回肠构建储袋与肛管进行吻合。全结直肠切除术范围较广,需要从回盲部一直游离至盆底,传统开腹手术创伤较大。一、腹腔镜全结直肠切除-IPAA的安全性与可行性腹腔镜全结直肠切除术最早于1992年报道[4]。腹腔镜手术具有清晰良好的手术视野,更注重沿正确的层面进行解剖,超声刀的使用减少了术中出血,因而减少手术对患者的创伤打击、减轻术后疼痛,加快术后康复、缩短术后住院时间。     

Neonatal Fc Receptor Promotes Immune Complex–Mediated Glomerular Disease

The neonatal Fc receptor (FcRn) is a major regulator of IgG and albumin homeostasis systemically and in the kidneys. We investigated the role of FcRn in the development of immune complex–mediated glomerular disease in mice. C57Bl/6 mice immunized with the noncollagenous domain of the α3 chain of type IV collagen (α3NC1) developed albuminuria associated with granular capillary loop deposition of exogenous antigen, mouse IgG, C3 and C5b-9, and podocyte injury. High-resolution imaging showed abundant IgG deposition in the expanded glomerular basement membrane, especially in regions corresponding to subepithelial electron dense deposits. FcRn-null and -humanized mice immunized with α3NC1 developed no albuminuria and had lower levels of serum IgG anti-α3NC1 antibodies and reduced glomerular deposition of IgG, antigen, and complement. Our results show that FcRn promotes the formation of subepithelial immune complexes and subsequent glomerular pathology leading to proteinuria, potentially by maintaining higher serum levels of pathogenic IgG antibodies. Therefore, reducing pathogenic IgG levels by pharmacologic inhibition of FcRn may provide a novel approach for the treatment of immune complex–mediated glomerular diseases. As proof of concept, we showed that a peptide inhibiting the interaction between human FcRn and human IgG accelerated the degradation of human IgG anti-α3NC1 autoantibodies injected into FCRN-humanized mice as effectively as genetic ablation of FcRn, thus preventing the glomerular deposition of immune complexes containing human IgG.The MHC class I–like neonatal Fc receptor (FcRn), a heterodimer comprising a heavy chain and β₂-microglobulin light chain, is the major regulator of IgG and albumin homeostasis.¹ Perinatally, FcRn mediates the transfer of IgG from mother to offspring, across the placenta in primates and trans-intestinally in suckling rodents. Throughout life, FcRn protects IgG and albumin from catabolism, explaining the unusually long t_1/2 and high serum levels of these proteins. IgG and albumin taken up by cells by pinocytosis bind strongly to FcRn at pH 6.0–6.5 in endosomes. FcRn-bound ligands are then recycled to the plasma membrane, where they dissociate at pH 7.4, whereas IgG and albumin not bound to FcRn are targeted to lysosomes for degradation. FcRn is thought to promote some autoimmune diseases because it protects pathogenic IgG from degradation. For instance, Fcrn^−/− mice are resistant to passive transfer of arthritis by K/BxN sera and autoimmune skin pathology induced by antibodies targeting autoantigens at the dermal–epidermal junction, although this protection can be overcome by excess autoantibodies.^2–4In kidneys, FcRn is expressed in podocytes and proximal tubular epithelial cells.⁵ Overall, renal FcRn reclaims albumin but facilitates elimination of IgG.⁶ Tubular FcRn mediates IgG transcytosis.⁷ Podocytes use FcRn to clear IgG from the glomerular basement membrane (GBM).⁸ IgG accumulates in the glomeruli of aged Fcrn^−/− mice due to impaired clearance of IgG from the GBM, and saturating this clearance mechanism by excess ligand potentiates the pathogenicity of nephrotoxic sera in wild-type mice. Podocyte FcRn has been postulated to be involved in the clearance of immune complexes (ICs) present in pathologic conditions such as membranous nephropathy.⁵ Expression of FcRn in human podocytes is increased in various immune-mediated glomerular diseases.⁹ Given its role in IgG and albumin handling in the kidneys and systemically, FcRn can be expected to influence the development of immune-mediated kidney diseases at multiple levels. This conjecture awaits experimental verification.To determine the role of FcRn in IgG-mediated glomerular disease, we asked how FcRn deficiency alters the course of disease in mice immunized with the NC1 domain of α3 type IV collagen (α3NC1). We chose this antigen because of its reported ability to induce disease in C57Bl/6 (B6) mice,¹⁰ corroborated in pilot studies (Supplemental Figure 1). Fcrn^−/− mice are hypoalbuminemic due to impaired albumin recycling,¹¹ and also exhibit reduced urinary albumin excretion.¹² As a control for this potential confounder, we used FCRN-humanized mice, which have normal serum albumin because human FcRn recycles mouse albumin but not mouse IgG.¹³All mice immunized with α3NC1 developed circulating mouse IgG anti-α3NC1 antibodies, which reached the maximum titer about 6 weeks later and gradually declined thereafter. At all times, the levels of mouse IgG anti-α3NC1 antibodies in sera from Fcrn^−/− mice and FCRN-humanized mice were approximately 50%–70% lower than those in wild-type mouse sera (Figure 1A). The results were similar for mouse IgG1, IgG2b, and IgG2c anti-α3NC1 antibodies (Supplemental Figure 2). Wild-type B6 mice immunized with α3NC1 started developing progressive albuminuria 8–10 weeks later (Figure 1B). By week 14, the urinary albumin creatinine ratio increased approximately 100-fold, and hypoalbuminemia developed (Figure 1C). Urinary albumin excretion in Fcrn^−/− mice and FCRN-humanized mice immunized with α3NC1 was not significantly higher than in adjuvant-immunized control mice. No mice developed renal failure (Supplemental Figure 3).Open in a separate windowFigure 1.FcRn ablation reduces serum levels of mouse IgG anti-α3NC1 antibodies and prevents the development of albuminuria in α3NC1-immunized mice. (A) The left panel shows circulating mIgG anti-α3NC1 antibodies from C57Bl6 wild-type mice (○), Fcrn^−/− mice (□), FCRN-humanized (hFCRN) mice (◇), and the control CFA group (△), which are assayed by indirect ELISA in plates coated with α3NC1 (100 ng/well). Mouse sera are diluted 1:5000. The right panel shows the significance of circulating mIgG anti-α3NC1 antibody differences among groups at week 12, as assessed by one-way ANOVA followed by Bonferroni post tests for pairwise comparisons. (B) The left panel shows that the urinary albumin creatinine ratio (mean±SEM) time course is monitored in C57Bl6 wild-type mice (○), Fcrn^−/− mice (□), and hFCRN mice (◇) immunized with α3NC1 (n=5–8 mice in each group, from two separate experiments). Mice in the control group (△) are immunized with adjuvant alone (n=9). The right panel shows the urinary albumin creatinine ratio (mean±SEM) at 14 weeks, when mice are euthanized. The significance of differences among groups is assessed by one-way ANOVA followed by Bonferroni post tests for pairwise comparisons. (C) The left panel shows SDS-PAGE analysis of serum (0.5 µl/lane) and urine samples (2 µl/lane) from CFA-immunized control mice (a) and α3NC1-immunized wild-type mice (b), Fcrn^−/− mice (c), and hFCRN mice (d) collected at week 14. The right panel presents a densitometric analysis of the relative levels of albumin in mouse serum samples showing that α3NC1-immunized wild-type mice developed hypoalbuminemia. *P<0.05 by two-tailed t test versus CFA-immunized wild-type mice; **P<0.01; ***P<0.001. ns, not significant; WT, wild type.At 14 weeks after α3NC1 immunization, kidneys examined by light microscopy showed mild glomerular pathology, with few crescents and relatively little inflammation (Figure 2A), similar to α3NC1-immunized DBA/1 mice with comparable albuminuria.^14,15 Electron microscopy showed extensive subepithelial IC deposits surrounded by an expanded GBM and effacement of podocyte foot processes in α3NC1-immunized B6 mice, whereas Fcrn^−/− mice had fewer subepithelial deposits (Figure 2B, Supplemental Figure 4). Immunofluorescence staining showed granular capillary loop deposition of mouse IgG, exogenous antigen, C3, and C5b-9, more intense in wild-type mice than in Fcrn^−/− mice and FCRN-humanized mice (Figure 2, Ca–Cp, Supplemental Figure 5). A loss of nephrin staining, indicative of podocyte injury, occurred in α3NC1-immunized B6 mice but not in Fcrn^−/− mice or FCRN-humanized mice (Figure 2, Cq–Ct).Open in a separate windowFigure 2.FcRn deficiency reduces formation of pathogenic subepithelial ICs. (A) Light microscopic evaluation of kidneys from adjuvant-immunized control mice (a) and α3NC1-immunized wild-type mice (b) and Fcrn^−/− mice (c) revealed few pathogenic changes and the absence of glomerular inflammation (periodic acid–Schiff staining). (B) Transmission electron microscopy shows normal GBM (arrow) and podocyte foot processes in control mice (a), extensive subepithelial electron dense deposits (arrowhead), thickened GBM, and podocyte foot process effacement in α3NC1-immunized wild-type mice (b), and fewer IC deposits in the Fcrn^−/− mice (c). (C) Immunofluorescence analysis of kidneys from adjuvant-immunized control mice (a, e, i, m, and q) and α3NC1-immunized wild-type mice (b, f, j, n, and r), FcRn^−/− mice (c, g, k, o, and s), and hFCRN mice (d, h, l, p, and t) evaluate the deposition of mouse IgG (a–d), exogenous α3NC1 antigen stained by mAb RH34 (e–h), mouse C3c (i–l), C5b-9 (m–p), and nephrin staining (q–t) at 14 weeks. Wild-type mice exhibit linear-granular GBM deposition of mouse IgG and granular GBM deposition of exogenous antigen, C3, and C5b-9, which are attenuated in Fcrn^−/− mice and hFCRN mice and essentially absent in control mice. Compared with control mice, α3NC1-immunized wild-type mice but not Fcrn^−/− or hFCRN mice exhibit a loss of nephrin staining, indicative of podocyte injury. WT, wild type; EM, electron microscopy, PAS, periodic acid–Schiff. Original magnification, ×400 in A; ×2850 in B; ×200 in C.Because B6 mice immunized with bovine GBM NC1 hexamers have normal kidney function and histology despite linear GBM deposition of IgG autoantibodies binding to mouse α345(IV) collagen (Supplemental Figure 1), the question arises as to what causes proteinuria in α3NC1-immunized mice. Because the clinical presentation, morphology, and effector mechanisms depend on where ICs are localized in the capillary wall, we compared IgG distribution in α3NC1-immunized mice and mice injected with anti-α3NC1 antibodies modeling anti-GBM autoantibodies. The distribution and relative abundance of mouse IgG, as imaged by immunoperoxidase immunoelectron microscopy and stochastic optical reconstruction microscopy (STORM), a method for super-resolution fluorescence microscopy, were concordant. In α3NC1-immunized mice, IgG deposition was abundant in the areas of expanded GBM and especially in regions corresponding to the subepithelial dense deposits seen by routine electron microscopy. By contrast, in mice injected with α3NC1-specific anti-GBM mAb, the IgG was confined to an ultrastructurally normal GBM that lacked subepithelial deposits (Figure 3).Open in a separate windowFigure 3.Localization of IgG by high-resolution imaging. The localization of mouse IgG in glomerular capillary walls of wild-type mice immunized with α3NC1 (A, C–E), or intravenously injected with anti-mouse α3NC1 IgG mAb 8D1 (B, F–H) is determined by immunoperoxidase electron microscopy (A and B) and STORM imaging (C–H). In A, the GBM is irregularly thickened, and abundant electron dense peroxidase reaction product is present in discontinuous, subepithelial patterns beneath broadly effaced podocyte foot processes (arrows). In B, the peroxidase reaction product is diffusely present throughout the GBM (arrowhead), but less abundant compared with A. Electron dense deposits are absent, and podocyte foot process architecture appears normal. (C–E) By STORM imaging, anti-agrin (blue) identifies both normal and thickened areas of the GBM, both of which contain dense accumulations of mouse IgG throughout (red). The electron microscopy correlation in E shows GBM staining with respect to the podocytes and endothelial cells. (F–H) IgG mAb 8D1 (red) is present in the GBM, which shows no evidence of thickening. CL, capillary lumen; EM, electron microscopy En, endothelium;Po, podocyte.Subepithelial ICs, a hallmark of human membranous nephropathy (MN), form when IgG antibodies bind to podocyte antigens, such as phospholipase A2 receptor (PLA2R) and neutral endopeptidase (NEP), or to planted antigens, such as cationic BSA.^16–18 Subsequent expansion of the GBM, complement activation, and podocyte injury by C5b-9 cause proteinuria. Although it is unexpected, formation of subepithelial ICs in α3NC1-immunized mice may be explained by exogenous α3NC1 deposited in glomeruli acting as a planted antigen.¹⁹ Alternatively, anti-α3NC1 antibodies in complex with α3NC1 antigen may act as surrogate antipodocyte antibodies, because α3NC1-containing ICs bind to podocytes.²⁰ After four immunizations with α3NC1 monomers, B6 mice and DBA/1 mice eventually develop crescentic GN by 26 and 10 weeks, respectively.^10,14 The combination of subepithelial ICs and crescentic anti-GBM antibody GN was most recently described in a series of eight patients with circulating anti-α3NC1 autoantibodies but undetectable anti-PLA2R autoantibodies.²¹In contrast to wild-type B6 mice, congenic Fcrn^−/− mice and FCRN-humanized mice did not develop albuminuria after α3NC1 immunization. Their resistance to proteinuria was associated with lower serum titers of anti-α3NC1 IgG antibodies and reduced glomerular deposition of IgG, antigen, C3, and C5b-9. Because C5b-9 is an essential mediator of podocyte damage and proteinuria by subepithelial ICs,^22,23 reduced complement activation potentially explains the attenuated glomerular pathology in FcRn-deficient mice. The resistance of FCRN-humanized mice indicates that FcRn promotes IC-mediated glomerular disease due to its interaction with IgG rather than albumin. We propose that FcRn promotes the development of subepithelial ICs and subsequent glomerular injury primarily by maintaining higher serum levels of pathogenic IgG (Supplemental Figure 6). However, we cannot formally exclude a possible pathogenic role of podocyte FcRn, whose stimulation by ICs may induce maladaptive signaling.⁹ Future studies in mice with podocyte-specific ablation of FcRn would address this possibility.Our findings identify FcRn as a potential target for therapeutic intervention in IC-mediated glomerular diseases, typically treated with nonspecific immunosuppressants that are toxic and sometimes ineffective. More specific therapies include ablation of B cells by rituximab. In patients with idiopathic MN who respond to rituximab therapy, serum levels of anti-PLA2R IgG autoantibodies decline over a period of many months, and their disappearance is followed by resolution of proteinuria.²⁴ The slow decline in proteinuria is problematic for patients already suffering from complications of nephrotic syndrome, who would benefit from ancillary therapies that reduce pathogenic IgG antibodies more rapidly. This may be achieved by inhibiting FcRn.One implementation of this concept is therapy with high-dose intravenous Ig (HD-IVIG). HD-IVIG accelerates the degradation of IgG by saturating FcRn,²⁵ one of the mechanisms that explain the beneficial effects of HD-IVIG therapy in some autoimmune diseases.³ In pregnant women with circulating anti-NEP alloantibodies mediating antenatal MN, treatment with HD-IVIG reduces the titers of IgG alloantibodies by approximately 30% within 2–3 weeks.²⁶ However, HD-IVIG is inefficient, because large amounts of IgG (1–2 g/kg) cause relatively modest reductions in pathogenic IgG titers. Specific FcRn inhibitors recapitulate this activity of HD-IVIG more effectively at lower doses. By reducing pathogenic IgG levels, function-blocking anti-FcRn mAbs ameliorate experimental myasthenia gravis in rats,²⁷ and engineered IgG “Abdegs” that bind with high affinity to FcRn ameliorate arthritis transferred by K/BxN serum.²⁸To assess the translational potential of our findings, we asked whether pharmacologic blockade of human FcRn can reproduce the effects of genetic FcRn deficiency. To this end, FCRN-humanized and Fcrn^−/− mice were passively immunized with human IgG containing anti-α3NC1 (Goodpasture) autoantibodies. To inhibit human FcRn, we used a lysine analog of SYN1436 (Figure 4A),²⁹ a peptide that binds with subnanomolar affinity to human FcRn, thus preventing IgG binding.³⁰ In vivo, SYN1436 reduces IgG levels in cynomolgus monkeys by 80%.³⁰ Serum anti-α3NC1 autoantibodies in FCRN-humanized mice treated with anti-FcRn peptide, but not with control peptide, sharply decreased to the same levels as in Fcrn^−/− mice (Figure 4B), and were no longer detected after 4 days. In mice, human IgG elicits murine anti-human IgG antibodies, forming ICs that can deposit in glomeruli, as shown in active serum sickness models. Glomerular deposition of ICs containing human IgG was abolished in mice treated with anti-FcRn peptide, but not with control peptide (Figure 4C). Linear GBM deposition of human anti-GBM IgG was not observed, because the epitopes recognized by Goodpasture autoantibodies are completely inaccessible in the mouse GBM.³¹ These results provide proof of concept that therapies targeting human FcRn effectively lower serum levels of pathogenic human IgG autoantibodies, which could be beneficial in patients with IgG-mediated kidney diseases. Because FcRn also mediates the trans-placental transfer of IgG from mother to the fetus, FcRn inhibition may be particularly attractive for preventing antenatal MN caused by maternal anti-NEP alloantibodies.Open in a separate windowFigure 4.Pharmacologic blockade of human FcRn accelerates the catabolism of human IgG autoantibodies in FCRN-humanized mice. (A) Structure of a peptide that binds with high affinity to human FcRn, competitively inhibiting its interaction with human IgG (top). The control peptide (bottom) containing D-amino acids does not bind to human FcRn. Pen, Sar, and NMeLeu denote penicillamine, sarcosine, and N-methyl-leucine, respectively. (B) Serum level of human IgG anti-α3NC1 antibodies in FCRN-humanized mice treated with anti-FcRn peptide (▪) or control peptide (●) and in Fcrn^−/− (▲) mice sera (n=3 in each group) is analyzed by indirect ELISA in plates coated with α3NC1 (100 ng/well). Mouse sera are diluted 1:500. (C) Kidney deposition of human IgG (a and b) and mouse IgG (c and d) in FCRN-humanized mice treated with control peptide (a and c) or anti-FcRn peptide (b and d) is evaluated by direct immunofluorescence staining. Treatment with anti-FcRn peptide prevents the glomerular deposition of ICs containing human IgG.