Abstract
Pelvic organ prolapse (POP) decreases quality of life for many women, but its pathophysiology is poorly understood. We have previously shown that Lysyl oxidase‐like 1 knockout (Loxl1 KO) mice reliably prolapse with age and increased parity, similar to women. Both this model and clinical studies also indicate that altered elastin metabolism in pelvic floor tissues plays a role in POP manifestation, although it is unknown if this is a cause or effect. Using Loxl1 KO mice, we investigated the effects of genetic absence of Loxl1, vaginal parity, and presence of POP on the expression of genes and proteins key to the production and regulation of elastic matrix. Cultured cells isolated from vaginal explants of mice were assayed with Fastin for elastic matrix, as well as RT‐PCR and Western blot for expression of genes and proteins important for elastin homeostasis. Elastin synthesis significantly decreased with absence of LOXL1 and increased with parity (p < .001), but not with POP. Cells from prolapsed mice expressed significantly decreased MMP‐2 (p < .05) and increased TIMP‐4 (p < .05). The results suggest changes to elastin structure rather than amounts in prolapsed mice as well as poor postpartum elastin turnover, resulting in accumulation of damaged elastic fibers leading to abnormal tropoelastin deposition. POP may thus, be the result of an inability to initiate the molecular mechanisms necessary to clear and replace damaged elastic matrix in pelvic floor tissues after vaginal birth.
Highlights
Pelvic organ prolapse (POP) is characterized by the downward descent and abnormal protrusion of pelvic organs, which reduces quality of life for many women (Jelovsek et al, 2007)
These similarities to the human condition suggest that lysyl oxidase-like-1 (Loxl1) KO mice are appropriate to investigate changes in elastic fiber homeostasis and its relation to how POP develops after vaginal delivery
With the long-term goal of elucidating the biochemical pathophysiology of POP, this study focused on identifying key changes in elastic fiber metabolism in mouse vaginal tissue as they related to the absence of the Loxl1 gene, the influence of multiparity, and the presence of vaginal prolapse
Summary
This project was funded by a grant (R21HD078820) from the National Institutes of Health/National Institute for Child Health and Disease awarded to M.D. and A.R with support from the Cleveland Clinic Lerner Research Institute and the US Department of Veterans Affairs.
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