Does finasteride treatment for benign prostatic hyperplasia influence sperm DNA integrity in dogs?

BACKGROUND: Benign prostatic hyperplasia (BPH) is one of the most common reproductive disorders in both male dogs and men. Finasteride, a synthetic inhibitor of the enzyme 5α-reductase, is widely used as medical treatment. Although sperm can be affected by both BPH and finasteride treatment, the direct influence on DNA integrity remains unclear. Thus, the aim of this study was to verify the direct effect of BPH and/or finasteride treatment on DNA integrity of dog spermatozoa. A 2 × 2 factorial experiment was designed with 20 male dogs assigned to 4 experimental groups: BPH Group (n = 5), BPH-Finasteride Group (n = 5), Non-BPH Finasteride-Treated Group (n = 5) and Non-BPH Untreated Group (n = 5). Sperm evaluation was performed monthly for 60 days after the start of finasteride therapy or BPH diagnosis (D0, D30 and D60). Sperm DNA integrity was analyzed through fragmentation susceptibility (toluidine blue staining and Sperm Chromatic Structure Assay - SCSA), direct evaluation of DNA fragmentation (Sperm Chromatin Dispersion Assay - SCDA) and sperm protamination (chromomycin A3). RESULTS: Sperm DNA integrity was not affected by finasteride treatment. However, BPH dogs had higher susceptibility to sperm DNA acid denaturation (SCSA) compared to dogs not presenting BPH, as well as lower percentage of sperm with DNA integrity (toluidine blue staining). CONCLUSION: In conclusion, benign prostatic hyperplasia causes post-testicular sperm DNA damage, albeit finasteride treatment itself does not directly influence sperm DNA integrity.

CONTEXTE: L'hyperplasie bénigne de la prostate (HBP) est l'un des troubles de la reproduction les plus courants chez le chien et chez l'homme. Le finastéride, un inhibiteur synthétique de l'enzyme 5α-réductase, est largement utilisé comme traitement médical. Bien que le sperme puisse être affecté à la fois par l'HBP et par le traitement avec le finastéride, l'influence directe sur l'intégrité de l'ADN reste peu claire.Le but de cette étude était ainsi de vérifier l'effet direct de l'HBP et/ou du traitement par finastéride sur l'intégrité de l'ADN des spermatozoïdes de chien. Dans la présente étude, 20 chiens mâles ont été randomisés selon un plan factoriel en 2x2 à l'un des 4 groupes expérimentaux suivants : Groupe HBP (n=5), Groupe HBP-Finastéride (n=5), Groupe non-HBP traité par Finastéride (n=5), et Groupe non-HBP non traité (n=5). L'analyse Le sperme a été réalisée mensuellement pendant 60 jours (J0, J30 et J60) soit après le début du traitement par finastéride ou à partir du diagnostic de HBP. L'intégrité de l'ADN des spermatozoïdes a été analysée par l'évaluation de la susceptibilité à la fragmentation (coloration au bleu de toluidine ; détermination de la structure de la chromatine des spermatozoïdes - SCSA), par l'évaluation directe de la fragmentation de l'ADN des spermatozoïdes (détermination de la dispersion de la chromatine des spermatozoïdes - SCDA) et par l'évaluation de la protamination des spermatozoïdes (chromomycine A3). RÉSULTATS: L'intégrité de l'ADN des spermatozoïdes n'a pas été affectée par le traitement par finastéride. Cependant, les chiens avec HBP ont une susceptibilité plus élevée à la dénaturation acide de l'ADN des spermatozoïdes (SCSA) par comparaison aux chiens ne présentant pas d'HBP, ainsi qu'un pourcentage plus bas de spermatozoïdes avec intégrité de l'ADN (coloration au bleu de toluidine). CONCLUSIONS: L'hyperplasie bénigne de la prostate induit des altérations de l'ADN des spermatozoïdes, alors que le traitement par finastéride n'influence pas directement par lui-même l'intégrité de l'ADN des spermatozoïdes.

Haematological and immunophenotypic evaluation of peripheral blood cells of cattle naturally infected with bovine papillomavirus.

Papillomaviruses are among the most widespread animal viruses, with many hosts harbouring multiple virus types. The present study aimed to evaluate the haematological and immunophenotypic profile of cattle infected with bovine papillomavirus (BPV). Blood samples were collected from 10 animals with clinical cutaneous BPV and without clinical papillomatosis (control). Haematological analysis demonstrated a significant reduction in haemoglobin and haematocrit for BPV-infected animals. The results also showed an increase of natural killer cells and a decrease of γδ+ T-cells and the CD4+/CD8+ ratio for the BPV group when compared to the control group. The infection was also found to stimulate a pro-inflammatory profile with the participation of CD8+T cells producing elevated IFN-γ and IL-17. These findings, although preliminary, provide a better understanding of the immune response of cattle infected with BPV.

Booster dose after 10 years is recommended following 17DD-YF primary vaccination.

A single vaccination of Yellow Fever vaccines is believed to confer life-long protection. In this study, results of vaccinees who received a single dose of 17DD-YF immunization followed over 10 y challenge this premise. YF-neutralizing antibodies, subsets of memory T and B cells as well as cytokine-producing lymphocytes were evaluated in groups of adults before (NVday0) and after (PVday30-45, PVyear1-4, PVyear5-9, PVyear10-11, PVyear12-13) 17DD-YF primary vaccination. YF-neutralizing antibodies decrease significantly from PVyear1-4 to PVyear12-13 as compared to PVday30-45, and the seropositivity rates (PRNT≥2.9Log10mIU/mL) become critical (lower than 90%) beyond PVyear5-9. YF-specific memory phenotypes (effector T-cells and classical B-cells) significantly increase at PVday30-45 as compared to naïve baseline. Moreover, these phenotypes tend to decrease at PVyear10-11 as compared to PVday30-45. Decreasing levels of TNF-α(+) and IFN-γ(+) produced by CD4(+) and CD8(+) T-cells along with increasing levels of IL-10(+)CD4(+)T-cells were characteristic of anti-YF response over time. Systems biology profiling represented by hierarchic networks revealed that while the naïve baseline is characterized by independent micro-nets, primary vaccinees displayed an imbricate network with essential role of central and effector CD8(+) memory T-cell responses. Any putative limitations of this cross-sectional study will certainly be answered by the ongoing longitudinal population-based investigation. Overall, our data support the current Brazilian national immunization policy guidelines that recommend one booster dose 10 y after primary 17DD-YF vaccination.

Evaluation of parameters related to libido and semen quality in Zebu bulls naturally infected with Trypanosoma vivax.

BACKGROUND: Trypanosomiasis is a disease caused by Trypanosoma (Dutonella) vivax, a hemoprotozoa that can affect bovines. In South America, the sanguineous form is mechanically transmitted from one mammalian host (ruminant) to another by the bite of a blood-sucking insect or by needles contaminated with infected blood. The negative impact of the parasitosis caused by T. vivax infection on the reproductive activity of male and female ruminants is known to reduce fertility. In males, alterations such as degeneration, diffuse or interlobular inflammatory infiltrate found in ovine and bovine testicles, can affect fertility through decreased sperm quality. This study evaluated the impact of natural infection with T. vivax on Zebu bulls from the Central Station of Artificial Insemination (CSAI) with regard to libido and the negative effects caused by this protozoan on semen quality. METHODS: Blood samples of 44 animals were collected to evaluate the presence of the trypomastigote form of T. vivax in blood smears obtained from hematocrit and buffy coat, and antibody titer IgG anti T. vivax in indirect Immunoflorescence (IFI). Furthermore, data related to libido, ejaculate volume, spermatic concentration, and seminal vigor were recorded for these animals employing the criteria of the CSAI. RESULTS: Nine animals (20.45 %) showed T. vivax trypomastigotes and parasitemia between 0.02 and 0.07, and antibody titers from 1:80 to 1:320 in IFI. Twenty nine negative animals in parasitological tests were not reactive in IFI, and six animals presented the antibodies IgG anti T. vivax in IFI. Data on reproductive activity showed that animals infected with T. vivax have a decreased libido and an increased spermatic volume, whereas other factors related to the reproductive process such as spermatic concentration, motility and spermatic force, were unchanged in infected bulls. CONCLUSIONS: The T. vivax infection in Zebu bulls from CSAI caused patent parasitemia, induced a febrile state, promoted reduction in the libido and increased the ejaculate volume. These conditions together may account to decrease the performance of these animals.