High rate of detected variants in male PLCZ1 and ACTL7A genes causing failed fertilization after ICSI.

Abstract

Study question: What is the frequency of PLCZ1, ACTL7A, and ACTL9 variants in male patients showing fertilization failure after ICSI, and how effective is assisted oocyte activation (AOA) for them?

Summary answer: Male patients with fertilization failure after ICSI manifest variants in PLCZ1 (29.09%), ACTL7A (14.81%), and ACTL9 (3.70%), which can be efficiently overcome by AOA treatment with ionomycin.

What is known already: Genetic variants in PLCZ1, and more recently, in ACTL7A, and ACTL9 male genes, have been associated with total fertilization failure or low fertilization after ICSI. A larger patient cohort is required to understand the frequency at which these variants occur, and to assess their effect on the calcium ion (Ca²⁺) release during oocyte activation. AOA, using ionomycin, can restore fertilization and pregnancy rates in patients with PLCZ1 variants, but it remains unknown how efficient this is for patients with ACTL7A and ACTL9 variants.

Study design size duration: This prospective study involved two patient cohorts. In the first setting, group 1 (N = 28, 2006-2020) underwent only PLCZ1 genetic screening, while group 2 (N = 27, 2020-2023) underwent PLCZ1, ACTL7A, and ACTL9 genetic screening. Patients were only recruited when they had a mean fertilization rate of ≤33.33% in at least one ICSI cycle with at least four MII oocytes. Patients underwent a mouse oocyte activation test (MOAT) and at least one ICSI-AOA cycle using calcium chloride (CaCl₂) injection and double ionomycin exposure at our centre. All patients donated a saliva sample for genetic screening and a sperm sample for further diagnostic tests, including Ca²⁺ imaging.

Participants/materials setting methods: Genetic screening was performed via targeted next-generation sequencing. Identified variants were classified by applying the revised ACMG guidelines into a Bayesian framework and were confirmed by bidirectional Sanger sequencing. If variants of uncertain significance or likely pathogenic or pathogenic variants were found, patients underwent additional determination of the sperm Ca²⁺-releasing pattern in mouse (MOCA) and in IVM human (HOCA) oocytes. Additionally, ACTL7A immunofluorescence and acrosome ultrastructure analyses by transmission electron microscopy (TEM) were performed for patients with ACTL7A and/or ACTL9 variants.

Main results and the role of chance: Overall, the frequency rate of PLCZ1 variants was 29.09%. Moreover, 14.81% of patients carried ACTL7A variants and 3.70% carried ACTL9 variants. Seven different PLCZ1 variants were identified (p.Ile74Thr, p.Gln94*, p.Arg141His, p.His233Leu, p.Lys322*, p.Ile379Thr, and p.Ser500Leu), five of which are novel. Interestingly, PLCZ1 variants p.Ser500Leu and p.His233Leu occurred in 14.55% and 9.09% of cases. Five different variants were found in ACTL7A (p.Tyr183His, p.Gly214Ser, p.Val340Met, p.Ser364Glnfs*9, p.Arg373Cys), four of them being identified for the first time. A novel variant in ACTL9 (p.Arg271Pro) was also described. Notably, both heterozygous and homozygous variants were identified.The MOCA and HOCA tests revealed abnormal or absent Ca²⁺ release during fertilization in all except one patient, including patients with PLCZ1 heterozygous variants. TEM analysis revealed abnormal acrosome ultrastructure in three patients with ACTL7A variants, but only patients with homozygous ACTL7A variants showed reduced fluorescence intensity in comparison to the control.AOA treatment significantly increased the fertilization rate in the 19 patients with detected variants (from 11.24% after conventional ICSI to 61.80% after ICSI-AOA), as well as positive hCG rate (from 10.64% to 60.00%) and live birth rate (from 6.38% to 37.14%), resulting in 13 healthy newborns. In particular, four live births and two ongoing pregnancies were produced using sperm from patients with ACTL7A variants.

Limitations reasons for caution: Genetic screening included exonic and outflanking intronic regions, which implies that deep intronic variants were missed. In addition, other male genes or possible female-related factors affecting the fertilization process remain to be investigated.

Wider implications of the findings: Genetic screening of PLCZ1, ACTL7A, and ACTL9 offers a fast, cost-efficient, and easily implementable diagnostic test for total fertilization failure or low fertilization after ICSI, eliminating the need for complex diagnostic tests like MOAT or Ca²⁺ analysis. Nonetheless, HOCA remains the most sensitive functional test to reveal causality of uncertain significance variants. Interestingly, heterozygous PLCZ1 variants are sufficient to cause inadequate Ca²⁺ release during ICSI. Most importantly, AOA treatment using CaCl₂ injection followed by double ionomycin exposure is highly effective for this patient group, including those with ACTL7A variants, who also display a Ca²⁺-release deficiency.

Study funding/competing interests: This study was supported by the Flemish Fund for Scientific Research (FWO) (TBM-project grant T002223N awarded to B.H.) and by the Special Research Fund (BOF) (starting grant BOF.STG.2021.0042.01 awarded to B.H.). A.C.B., R.R.G., C.C., E.V.D.V., A.R., D.S., L.L., P.C., S.S., A.B., and F.V.M. have nothing to disclose. B.H. reports a research grant from FWO and BOF, and reports being a board member of the Belgian Ethical Committee on embryo research.

Trial registration number: N/A.