Dept. of Obstetrics & Gynecology, College of Physicians & Surgeons, Columbia University, New York, NY, USA
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Abstract |
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Key words: azoospermia/gene deletion/genetics/infertility/Y chromosome
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Introduction |
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Essential to the argument that Y microdeletions cause infertility is the observation that fertile men rarely manifest Y microdeletions. Microdeletions in four out of 200 fertile men studied have been reported (Pryor et al., 1997). However, the deletions in these men were very small and most likely represented insignificant polymorphism. Relatively large deletions of the kind associated with male infertility have not been reported in men with normal fertility. Although it is generally assumed that these deletions arise de novo and that father to son transmission of Y microdeletion would not be expected, a few rare instances of father to one son transmission of Y chromosome microdeletion have been reported (Kobayashi et al., 1994
; Stuppia et al., 1996
; Vogt et al., 1996
; Pryor et al., 1997
). However, vertical transmission of a microdeletion involving the deleted in azoospermia (DAZ) locus from father to one son has been reported in only three cases (Kobayashi et al., 1994
; Vogt et al., 1996
; Pryor et al., 1997
). We now describe a four-generation family in which an azoospermic father and his four infertile sons all share an apparently identical microdeletion that includes the DAZ locus. This family represents the first and only report of spontaneous vertical transmission of DAZ deletion to multiple offspring. It provides evidence that a single Yq microdeletion can result in varying phenotypic expression in different individuals. It is clinically significant, in that the presence of a microdeletion is not an absolute marker for infertility and can be associated with apparently normal fertility.
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Materials and methods |
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Semen analysis
Results were analysed using WHO criteria with a Nikon phase contrast microscope.
Serum hormone concentrations
Follicle stimulating hormone (FSH), luteinizing hormone (LH), and testosterone were measured by solid-phase, two site chemiluminescent enzyme immunometric assay (Immulite; Diagnostic Products Corporation, Los Angeles, CA, USA). Normal ranges for men are FSH <10 mIU/ml; LH <10 mIU/ml; and testosterone 2701070 ng/dl.
Genomic DNA
Extraction of genomic DNA from whole blood was performed by lysis of red blood cells, followed by lysis of white blood cells and their nuclei. Cellular proteins were removed by salt precipitation, and genomic DNA was precipitated with isopropanol using Puregene DNA extraction kit (Gentra Systems, Inc. Minneapolis, MN, USA; catalogue no. D-5004).
Polymerase chain reaction (PCR)
Primers were produced as dried oligonucleotides on an automated DNA synthesizer (Perkin-Elmer Applied Biosystems Inc., Foster City, CA, USA). A total of 27 Y chromosome specific sequence tagged sites (STS) (Figure 1) were selected from an STS map (Vollrath et al., 1992
). They include the three proposed spermatogenesis loci AZFa, AZFb, and AZFc (as per Vogt et al., 1996) spanning Yq intervals 5, 6 and 7. As a rapid screening protocol, a PCR multiplex system composed of two to six different primer pairs was used in a total of six multiplexed reactions (Table I
). With each PCR run, a female control and a normal male control were included. All PCR reactions were run in polycarbonate (Techne®) plates in an MJ Research® machine. The PCR conditions were essentially as previously described (Henegariu et al., 1993
). Briefly, in a 14 µl total volume reaction, 50 ng of genomic DNA was used as template, 1 µl of primer standard solution (mix I or II or III or IV or V or VI consisting of 10 pmol per primer), 12 µl of `PCR cold mix' (1.5 mmol/l MgCl2, 0.2 mmol/l of each dNTP, 5% DMSO, 1x Taq polymerase reaction buffer without Mg2+), 1.25 IU Taq DNA polymerase (Promega) and 1 drop of oil. The complete mixes were placed directly in a thermocycler preheated to 94°C. Cycling conditions for 27 cycles were: 94°C, 30 s (melting); 55°C, 45 s (annealing); and 72°C, 60 s (extension). The final extension time was 5 min. The PCR reaction products were then separated on 3% agarose gels (Bio-Rad, ultra-pure grade) by electrophoresis in TBE buffer. PCR products were stained with ethidium bromide and visualized by exposure to ultraviolet light. STS showing no amplification in multiplex reactions were confirmed by single reaction PCR with appropriate positive and negative controls. An STS was considered to be absent after three amplification failures.
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Paternity determination
Paternity of all four sons was confirmed by showing the expected segregation of four highly polymorphic autosomal markers (Weber and May, 1989). These were D21S156, D21S270, D13S132, and D13S159 with heterozygosities of 0.83, 0.86, 0.84 and 0.90 respectively.
Fluorescent in-situ hybridization (FISH)
FISH for DAZ was performed with Cosmid 63C9 (Saxena et al., 1996), using established methods (Yu et al., 1996
).
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Results |
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Table II summarizes the results of semen analysis and endocrine work-up on relevant family members. The proband (III-8), his father (II-1) and two of his three brothers (III-4, III-6) were found to be either azoospermic or severely oligozoospermic. The proband's oldest brother (III-1) declined semen analysis. In addition, the proband's uncle (II-8) was found to have azoospermia and elevated FSH with low testosterone. As shown in Figure 1
, the proband, his father and three brothers were all found to have microdeletion of Yq by STS PCR analysis. Southern blotting with the DAZ (Figure 3
) and RBM (data not shown) probes confirmed that the deletion included the DAZ locus but not the RNA binding motif (RBM) locus. FISH analysis with the DAZ Cosmid 63C9 (Saxena et al., 1996
) of the proband's father's (II-1) leukocytes showed uniform absence of the DAZ locus (Figure 4
).
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The proband (III-8) and his older brother (III-6) were seeking infertility treatment. After extensive counselling, they opted for in-vitro fertilization (IVF) and intracytoplasmic sperm injection (ICSI). The proband (III-8) and his wife (III-9) underwent two IVF-ICSI cycles that failed to produce a pregnancy secondary to poor ovarian response. The proband's brother (III-6) and his wife (III-7) underwent one cycle of controlled ovarian hyperstimulation and nine oocytes were retrieved. Eleven mature spermatozoa were found in three ejaculates on the day of retrieval and used for ICSI. Three oocytes fertilized which subsequently cleaved and were transferred. She delivered a healthy female baby (IV-2).
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Discussion |
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This family raises several issues with regards to the association between Yq microdeletion and infertility. First, it confirms that vertical transmission of Yq microdeletion is possible and can lead to subsequent infertility in the male offspring. Second, it is obvious that the same deletion can result in different phenotypes in different individuals. Although the father (II-1) of the four boys in this family was azoospermic at the time of analysis, he fathered his first child at the age of 25 and his last one at the age of 38 years. Thus, he possessed some degree of fertility over a large span of years. Likewise, microdeletion of the Y chromosome, specifically DAZ, does not necessarily imply a lifelong history of azoospermia nor does it preclude the formation of a large family. His four sons, on the other hand, are infertile and either azoospermic or severely oligozoospermic.
The DAZ gene has been proposed as the azoospermia factor on the Y chromosome. This family shows clearly that while DAZ may have a critical role in spermatogenesis, it is not essential for fertility. Furthermore, total loss of the DAZ gene cluster can be associated with a histological picture of `Sertoli cell only' as well as sperm maturation arrest (Foresta et al., 1997; Pryor et al., 1997
). Several authors have found a poor correlation between the location of Y microdeletions (including DAZ deletions) with the clinical and histological phenotype of the patients (Reijo et al., 1995
, 1996
; Vogt et al.; 1996; Silber et al., 1998
). The findings in this family agree that such a correlation may turn out to be quite problematic. Testicular biopsy of the proband's brother (III-6) showed a picture of `Sertoli cell only' whereas the proband (III-8 with sperm count 0.5x106/ml) clearly would be expected to have some degree of sperm maturation on biopsy. Furthermore, testicular biopsy may not be representative of the entire testicle because there may be geographic heterogeneity for spermatogenesis as in individual III-6 whose ejaculates contained mature spermatozoa.
We can only speculate about the basis for phenotypic differences between family members with the same deletion. It is well known that identical deletions within autosomes may result in different phenotypes (Schinzel, 1994). One can postulate that such differences are consequences of each individual's exposure to his environment or expression of various modifying genes. A fertile father has been described with a microdeletion that widened when transmitted to his infertile son (Stuppia et al., 1996
). Although variable extensions at the borders of the deletion may exist between our different family members, these molecular extensions cannot be distinguished by interval mapping. By PCR analysis, the same STSs failed to amplify in our five individuals and Southern hybridization with the DAZ probe confirmed a complete deletion of this gene cluster. Although it is possible that the deletions observed are, in fact, not identical and adjacent areas may contain important genes that modulate the degree of phenotypic expression, these results still indicate a large overlap of deleted Y DNA (including the loss of DAZ gene cluster) in each individual of this unique family.
We were fascinated by the fact that the proband's uncle (II-8) has infertility and azoospermia but no apparent microdeletion by STS testing. Since southern blot analysis using both the RBM and DAZ probes as well as FISH analyses using a DAZ cosmid were all entirely normal, we are forced to conclude he has a different aetiology underlying his infertility. Admittedly, it is possible that he may have a smaller or point mutation/perturbation or proximal/distal rearrangement that is not detectable by current methods. He gave no history of exposure to gonadotoxins or other definable factors that were likely to affect spermatogenesis.
Until recently, Y microdeletion has had little clinical significance, since a man with a deletion will not, in general, reproduce. However, utilizing ICSI and testicular sperm aspiration (TESA), combined with IVF, it is now possible for oligo/azoospermic men with Y microdeletion to achieve pregnancies (Mulhall et al., 1997; Silber et al., 1998, and individual III-6). This has fostered concerns that such pregnancies may produce male offspring with similar microdeletions and subsequent infertility (Reijo et al., 1996; Girardi et al., 1997
; Kremer et al., 1997
). Indeed, Yq microdeletion can be transmitted to male offspring via ICSI (Kent-First et al., 1996
). The family we report suggests that men with Yq microdeletions (such as individual II-1) who achieve pregnancies will transmit the same microdeletion and the risk of infertility to their sons (individuals III-1, III-4, III-6, III-8). Therefore, patients should be offered Y microdeletion screening prior to ICSI and they should be counselled on the certainty of transmitting the Yq microdeletion and possibly infertility to their sons. As more research is focused on genetic aetiologies of male infertility, identification of genes involved in spermatogenesis should provide insight into the pathophysiology of male infertility and a more rational basis for initiating therapy.
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Acknowledgments |
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This study was funded in part by the Columbia Presbyterian Medical Center Office of Clinical Trials House Staff Awards.
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Notes |
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References |
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Submitted on March 25, 1999; accepted on July 27, 1999.