GLIPR1L1 is an IZUMO-binding protein required for optimal fertilization in the mouse

Background: The sperm protein IZUMO1 (Izumo sperm-egg fusion 1) and its recently identified binding partner on the oolemma, IZUMO1R, are among the first ligand-receptor pairs shown to be essential for gamete recognition and adhesion. However, the IZUMO1-IZUMO1R interaction does not appear to be directly responsible for promoting the fusion of the gamete membranes, suggesting that this critical phase of the fertilization cascade requires the concerted action of alternative fusogenic machinery. It has therefore been proposed that IZUMO1 may play a secondary role in the organization and/or stabilization of higher-order heteromeric complexes in spermatozoa that are required for membrane fusion. Results: Here, we show that fertilization-competent (acrosome reacted) mouse spermatozoa harbor several high molecular weight protein complexes, a subset of which are readily able to adhere to solubilized oolemmal proteins. At least two of these complexes contain IZUMO1 in partnership with GLI pathogenesis-related 1 like 1 (GLIPR1L1). This interaction is associated with lipid rafts and is dynamically remodeled upon the induction of acrosomal exocytosis in preparation for sperm adhesion to the oolemma. Accordingly, the selective ablation of GLIPR1L1 leads to compromised sperm function characterized by a reduced ability to undergo the acrosome reaction and a failure of IZUMO1 redistribution. Conclusions: Collectively, this study characterizes multimeric protein complexes on the sperm surface and identifies GLIPRL1L1 as a physiologically relevant regulator of IZUMO1 function and the fertilization process.Avinash S. Gaikwad, Amanda L. Anderson, D. Jo Merriner, Anne E. O’Connor, Brendan J. Houston, R. John Aitken, Moira K. O’Bryan, and Brett Nixo

A framework for high-resolution phenotyping of candidate male infertility mutants: from human to mouse

Published: 04 April 2020Male infertility is a heterogeneous condition of largely unknown etiology that affects at least 7% of men worldwide. Classical genetic approaches and emerging next-generation sequencing studies support genetic variants as a frequent cause of male infertility. Meanwhile, the barriers to transmission of this disease mean that most individual genetic cases will be rare, but because of the large percentage of the genome required for spermatogenesis, the number of distinct causal mutations is potentially large. Identifying bona fide causes of male infertility thus requires advanced filtering techniques to select for high-probability candidates, including the ability to test causality in animal models. The mouse remains the gold standard for defining the genotype-phenotype connection in male fertility. Here, we present a best practice guide consisting of (a) major points to consider when interpreting next-generation sequencing data performed on infertile men, and, (b) a systematic strategy to categorize infertility types and how they relate to human male infertility. Phenotyping infertility in mice can involve investigating the function of multiple cell types across the testis and epididymis, as well as sperm function. These findings will feed into the diagnosis and treatment of male infertility as well as male health broadly.Brendan J. Houston, Donald F. Conrad and Moira K. O’Brya

An optimised STAPUT method for the purification of mouse spermatocyte and spermatid populations

The purification of individual male germ cell populations is integral for the molecular and biochemical characterisation of specific spermatogenic phases. Although a number of more contemporary techniques have been developed, velocity sedimentation using the STAPUT method remains as a gold standard for this purpose. The gentle nature of the technique, wherein germ cell subpopulations are separated by sedimentation at unit gravity, results in the isolation of viable and high-purity cells. We provide an updated and simplified step-by-step version of the STAPUT protocol for the purification of mouse male germ cells. As per the original method, the protocol described herein allows for the purification of mouse spermatocyte and round spermatids, however it also allows for successful purification of elongating, and elongated spermatid populations, and is optimised for the preservation of cellular ultrastructure. This method yields sufficient numbers of high-purity cells from one adult mouse for RNA or protein extraction or for immunolocalisation studies.Jessica E.M. Dunleavy, Anne E. O’Connor, and Moira K. O’Brya

The cytoskeleton in spermatogenesis

As germ cells progress through spermatogenesis, they undergo a dramatic transformation, wherein a single, diploid spermatogonial stem cell ultimately produces thousands of highly specialised, haploid spermatozoa. The cytoskeleton is an integral aspect of all eukaryotic cells. It concomitantly provides both structural support and functional pliability, performing key roles in many fundamental processes including, motility, intracellular trafficking, differentiation and cell division. Accordingly, cytoskeletal dynamics underlie many key spermatogenic processes. This review summarises the organisational and functional aspects of the four major cytoskeletal components (actin, microtubules, intermediate filaments and septins) during the various spermatogenic phases in mammals. We focus on the cytoskeletal machinery of both germ cells and Sertoli cells, and thus, highlight the critical importance of a dynamic and precisely regulated cytoskeleton for male fertility.Jessica E M Dunleavy, Moira K O’Bryan, Peter G Stanton and Liza O’Donnel

Germ cell arrest associated with aSETX mutation in ataxia oculomotor apraxia type 2

Ataxia with oculomotor apraxia type 2 (AOA2) is a rare autosomal recessive neurodegenerative disorder characterized by cerebellar atrophy, peripheral neuropathy and oculomotor apraxia. It is caused by mutations in the SETX gene that encodes senataxin, a ubiquitously expressed protein that mediates processes, including transcription, transcription termination, DNA repair, RNA processing, DNA-RNA hybrid (R-loop) elimination and telomere stability. In mice, senataxin is essential for male germ cell development and fertility through its role in meiotic recombination and sex chromosome inactivation. AOA2 is associated with hypogonadism in women, but there are no reports of hypogonadism or infertility in men. We describe the first case of human male infertility caused by germ cell arrest in a man with AOA2. Our patient has a homozygous mutation in the SETX gene (NC_000009.11:g.135158775dup), which results in a frameshift and premature protein termination (NM_015046.6:c.6422dup, p.[Ser2142Glufs*23]). In accordance with the murine phenotype, testis histology revealed disrupted seminiferous tubules with spermatogonia and primary spermatocytes, but absent spermatids. Collectively, these data support an essential role of senataxin in human spermatogenesis, and provide a compelling case that men with AOA2 should be counselled at diagnosis about the possibility of infertility.SR Catford, MK O'Bryan, RI McLachlan, MB Delatycki, L Rombaut

GSK3 inhibition, but not epigenetic remodeling, mediates efficient derivation of germline embryonic stem cells from nonobese diabetic mice

The nonobese diabetic (NOD) mouse strain is a predominant animal model of type 1 diabetes. However, this mouse strain is considered to be non-permissive for embryonic stem cell (ESC) derivation using conventional methods. We examined small molecule inhibition of glycogen synthase kinase 3 (GSK3) to block spontaneous cell differentiation and promote pluripotency persistence. Here we show a single pharmacological GSK3 inhibitor, 6-bromoindirubin-3'-oxime (BIO), in combination with leukemia inhibition factor (LIF), promoted generation of stable NOD ESC lines at >80% efficiency. Significantly, expansion of the established NOD ESC lines no longer required treatment with BIO. These NOD ESC lines contributed to chimeric mice and transmitted to germline progeny that spontaneously developed diabetes. By contrast, 5-aza-2'-deoxycytidine (AZA), a small molecule inhibitor of DNA methylation, and trichostatin A (TSA) and valproic acid (VPA), small molecule inhibitors of histone deacetylase, could not promote generation of NOD ESCs by epigenetic remodeling. These combined findings provide strategic insights for imposing pluripotency in cells isolated from a non-permissive strain.Jun Liu, Michelle P.Ashton, Moira K.O'Bryan, Thomas C.Brodnicki, Paul J. Verm

LRGUK1 is part of a multiprotein complex required for manchette function and male fertility

Infertility occurs in 1 in 20 young men and is idiopathic in origin in most. We have reported that the leucine-rich repeat (LRR) and guanylate kinase-like domain containing, isoform (LRGUK)-1 is essential for sperm head shaping, via the manchette, and the initiation of sperm tail growth from the centriole/basal body, and thus, male fertility. Within this study we have used a yeast 2-hybrid screen of an adult testis library to identify LRGUK1-binding partners, which were then validated with a range of techniques. The data indicate that LRGUK1 likely achieves its function in partnership with members of the HOOK family of proteins (HOOK-1-3), Rab3-interacting molecule binding protein (RIMBP)-3 and kinesin light chain (KLC)-3, all of which are associated with intracellular protein transport as cargo adaptor proteins and are localized to the manchette. LRGUK1 consists of 3 domains; an LRR, a guanylate kinase (GUK)-like and an unnamed domain. In the present study, we showed that the GUK-like domain is essential for binding to HOOK2 and RIMBP3, and the LRR domain is essential for binding to KLC3. These findings establish LRGUK1 as a key component of a multiprotein complex with an essential role in microtubule dynamics within haploid male germ cells.Hidenobu Okuda, Kathleen DeBoer, Anne E. O’Connor, D. Jo Merriner, Duangporn Jamsai, and Moira K. O’Brya

The antidepressant fluoxetine alters mechanisms of pre- and post-copulatory sexual selection in the eastern mosquitofish (Gambusia holbrooki)

Abstract not availableMichael G.Bertram, Tiarne E.Ecker, Bob B.M.Wong, Moira K.O'Bryan, John B.Baumgartner Jake M.Martin, Minna Saarist

CBE1 is a manchette- and mitochondria-associated protein with a potential role in somatic cell proliferation

Ciliated bronchial epithelium 1 (CBE1) is a microtubule-associated protein localized to the manchette and developing flagellum during spermiogenesis, and associated with sperm maturation arrest in humans. It was hypothesized that CBE1 functions in microtubule-mediated transport mechanisms and sperm tail formation. To test this hypothesis, we analysed Cbe1 expression and localization during spermiogenesis, and in mouse IMCD3 cells as a model of ciliogenesis. Further, we generated and analysed the fertility of a Cbe1 mutant mouse line. Mice containing a homozygous deletion in the long forms of Cbe1 were born at a lower frequency than predicted by Mendelian inheritance, however, adult male mice were fertile. An in-depth analysis of the Cbe1 gene revealed alternative transcript variants, which were not affected by the exon 2 mutation. To assess whether short variants compensate for the loss of long variants, exons 2 and 4 (which affect all variants) were individually mutated in IMCD3 cells and the effect on cell proliferation and ciliogenesis analysed. In wild type IMCD3 cells, both variants were upregulated during cilia assembly. CBE1 protein was not a structural component of cilia, rather, CBE1 localised to the mitochondria and the contractile ring of dividing IMCD3 cells. While IMCD3 cells carrying the mutation in long variants showed no phenotypic alterations, the mutation in exon 4 resulted in a significantly decreased proliferation rate. This study reveals that long isoforms of CBE1 are not essential for male fertility. Data, however, suggests that CBE1 is associated to intra-manchette transport and mid-piece formation of the sperm tail.Christiane Pleuger, Mari S. Lehti, Madeleine Cooper, Anne E. O’Connor, D. Jo Merriner, Ian M. Smyth, Denny L. Cottle, Daniela Fietz, Martin Bergmann, and Moira K. O’Brya