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Vertebrate reproductive science and technology
RESEARCH ARTICLE

An insight into testis and gubernaculum dynamics of INSL3–RXFP2 signalling during testicular descent in the dog

S. Arrighi A C , G. Bosi A , D. Groppetti B , M. Aralla A and F. Cremonesi B
+ Author Affiliations
- Author Affiliations

A Department of Veterinary Sciences and Technologies for Food Safety, Laboratory of Anatomy, Università degli Studi di Milano, Italy.

B Department of Veterinary Clinical Science, Reproduction Unit, Faculty of Veterinary Medicine, Università degli Studi di Milano, Italy.

C Corresponding author. Email: silvana.arrighi@unimi.it

Reproduction, Fertility and Development 22(5) 751-760 https://doi.org/10.1071/RD09260
Submitted: 23 October 2009  Accepted: 24 November 2009   Published: 7 April 2010

Abstract

Insulin-like 3 (INSL3) plays a prominent role in male development and is supposed to induce the growth of the gubernaculum testis (g.t.), thus being directly involved in testicular descent in humans and rodents. This happens through activation of the RXFP2 receptor (GREAT or LGR8). The INSL3–RXFP2 complex is reputed to play an additional paracrine role in the testis, possibly acting as part of an autocrine feedback loop. The present work provides evidence of the immunolocalisation of INSL3 in the Leydig cells of canine fetuses and of the expression of RXFP2 receptor in different tissues of the g.t. of the same specimens. RXFP2 was localised at the cell membrane of g.t. muscle and connective cells, as well as in the epithelial cells of the developing excurrent ducts. Notably, RXFP2 immunoreactivity of the g.t. was limited to fetuses at ~35–45 days of gestation, which is also the fetal period when the endocrine compartment of the dog testis is active endocrinologically, as confirmed by the anti-P450c17 and anti-INSL3 immunoreactivities of the fetal Leydig cells, and by anti-Müllerian hormone immunoreactivity of the Sertoli cells. The same immunoreactivities were also evaluated in the testes of cryptorchid dogs of different ages. RXFP2 immunoreactivity was absent from genital tracts of cryptorchid testes and g.t. remnants.

Additional keywords: anti-Müllerian hormone, cryptorchidism, GREAT, RLF, testicular ligaments.


Acknowledgements

Prof. Alan J. Conley, U. C. Davis School of Veterinary Medicine, USA is warmly acknowledged for kindly providing the anti-P450c17 antibodies and for his skilful suggestions during the preparation of the manuscript. Mr. Paolo Stortini (VSA, University of Milan) is gratefully acknowledged for his experienced and competent technical support. This work was supported by the University of Milan (PUR 2008). Part of this work was published in a special issue of Veterinary Research Communications (33, Suppl 1:S67–S71, 2009), containing a selection of abstracts from the LXII Meeting of the Italian Society of Veterinary Sciences (S.I.S.Vet.), held in San Benedetto del Tronto (Italy) in September 2008.


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